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- This is gccint.info, produced by makeinfo version 6.5 from gccint.texi.
-
- Copyright (C) 1988-2020 Free Software Foundation, Inc.
-
- Permission is granted to copy, distribute and/or modify this document
- under the terms of the GNU Free Documentation License, Version 1.3 or
- any later version published by the Free Software Foundation; with the
- Invariant Sections being "Funding Free Software", the Front-Cover Texts
- being (a) (see below), and with the Back-Cover Texts being (b) (see
- below). A copy of the license is included in the section entitled "GNU
- Free Documentation License".
-
- (a) The FSF's Front-Cover Text is:
-
- A GNU Manual
-
- (b) The FSF's Back-Cover Text is:
-
- You have freedom to copy and modify this GNU Manual, like GNU software.
- Copies published by the Free Software Foundation raise funds for GNU
- development.
- INFO-DIR-SECTION Software development
- START-INFO-DIR-ENTRY
- * gccint: (gccint). Internals of the GNU Compiler Collection.
- END-INFO-DIR-ENTRY
-
- This file documents the internals of the GNU compilers.
-
- Copyright (C) 1988-2020 Free Software Foundation, Inc.
-
- Permission is granted to copy, distribute and/or modify this document
- under the terms of the GNU Free Documentation License, Version 1.3 or
- any later version published by the Free Software Foundation; with the
- Invariant Sections being "Funding Free Software", the Front-Cover Texts
- being (a) (see below), and with the Back-Cover Texts being (b) (see
- below). A copy of the license is included in the section entitled "GNU
- Free Documentation License".
-
- (a) The FSF's Front-Cover Text is:
-
- A GNU Manual
-
- (b) The FSF's Back-Cover Text is:
-
- You have freedom to copy and modify this GNU Manual, like GNU software.
- Copies published by the Free Software Foundation raise funds for GNU
- development.
-
-
- File: gccint.info, Node: Top, Next: Contributing
-
- Introduction
- ************
-
- This manual documents the internals of the GNU compilers, including how
- to port them to new targets and some information about how to write
- front ends for new languages. It corresponds to the compilers (GNU Arm
- Embedded Toolchain 10-2020-q4-major) version 10.2.1. The use of the GNU
- compilers is documented in a separate manual. *Note Introduction:
- (gcc)Top.
-
- This manual is mainly a reference manual rather than a tutorial. It
- discusses how to contribute to GCC (*note Contributing::), the
- characteristics of the machines supported by GCC as hosts and targets
- (*note Portability::), how GCC relates to the ABIs on such systems
- (*note Interface::), and the characteristics of the languages for which
- GCC front ends are written (*note Languages::). It then describes the
- GCC source tree structure and build system, some of the interfaces to
- GCC front ends, and how support for a target system is implemented in
- GCC.
-
- Additional tutorial information is linked to from
- <http://gcc.gnu.org/readings.html>.
-
- * Menu:
-
- * Contributing:: How to contribute to testing and developing GCC.
- * Portability:: Goals of GCC's portability features.
- * Interface:: Function-call interface of GCC output.
- * Libgcc:: Low-level runtime library used by GCC.
- * Languages:: Languages for which GCC front ends are written.
- * Source Tree:: GCC source tree structure and build system.
- * Testsuites:: GCC testsuites.
- * Options:: Option specification files.
- * Passes:: Order of passes, what they do, and what each file is for.
- * poly_int:: Representation of runtime sizes and offsets.
- * GENERIC:: Language-independent representation generated by Front Ends
- * GIMPLE:: Tuple representation used by Tree SSA optimizers
- * Tree SSA:: Analysis and optimization of GIMPLE
- * RTL:: Machine-dependent low-level intermediate representation.
- * Control Flow:: Maintaining and manipulating the control flow graph.
- * Loop Analysis and Representation:: Analysis and representation of loops
- * Machine Desc:: How to write machine description instruction patterns.
- * Target Macros:: How to write the machine description C macros and functions.
- * Host Config:: Writing the 'xm-MACHINE.h' file.
- * Fragments:: Writing the 't-TARGET' and 'x-HOST' files.
- * Collect2:: How 'collect2' works; how it finds 'ld'.
- * Header Dirs:: Understanding the standard header file directories.
- * Type Information:: GCC's memory management; generating type information.
- * Plugins:: Extending the compiler with plugins.
- * LTO:: Using Link-Time Optimization.
-
- * Match and Simplify:: How to write expression simplification patterns for GIMPLE and GENERIC
- * Static Analyzer:: Working with the static analyzer.
- * User Experience Guidelines:: Guidelines for implementing diagnostics and options.
- * Funding:: How to help assure funding for free software.
- * GNU Project:: The GNU Project and GNU/Linux.
-
- * Copying:: GNU General Public License says
- how you can copy and share GCC.
- * GNU Free Documentation License:: How you can copy and share this manual.
- * Contributors:: People who have contributed to GCC.
-
- * Option Index:: Index to command line options.
- * Concept Index:: Index of concepts and symbol names.
-
-
- File: gccint.info, Node: Contributing, Next: Portability, Up: Top
-
- 1 Contributing to GCC Development
- *********************************
-
- If you would like to help pretest GCC releases to assure they work well,
- current development sources are available via Git (see
- <http://gcc.gnu.org/git.html>). Source and binary snapshots are also
- available for FTP; see <http://gcc.gnu.org/snapshots.html>.
-
- If you would like to work on improvements to GCC, please read the
- advice at these URLs:
-
- <http://gcc.gnu.org/contribute.html>
- <http://gcc.gnu.org/contributewhy.html>
-
- for information on how to make useful contributions and avoid
- duplication of effort. Suggested projects are listed at
- <http://gcc.gnu.org/projects/>.
-
-
- File: gccint.info, Node: Portability, Next: Interface, Prev: Contributing, Up: Top
-
- 2 GCC and Portability
- *********************
-
- GCC itself aims to be portable to any machine where 'int' is at least a
- 32-bit type. It aims to target machines with a flat (non-segmented)
- byte addressed data address space (the code address space can be
- separate). Target ABIs may have 8, 16, 32 or 64-bit 'int' type. 'char'
- can be wider than 8 bits.
-
- GCC gets most of the information about the target machine from a
- machine description which gives an algebraic formula for each of the
- machine's instructions. This is a very clean way to describe the
- target. But when the compiler needs information that is difficult to
- express in this fashion, ad-hoc parameters have been defined for machine
- descriptions. The purpose of portability is to reduce the total work
- needed on the compiler; it was not of interest for its own sake.
-
- GCC does not contain machine dependent code, but it does contain code
- that depends on machine parameters such as endianness (whether the most
- significant byte has the highest or lowest address of the bytes in a
- word) and the availability of autoincrement addressing. In the
- RTL-generation pass, it is often necessary to have multiple strategies
- for generating code for a particular kind of syntax tree, strategies
- that are usable for different combinations of parameters. Often, not
- all possible cases have been addressed, but only the common ones or only
- the ones that have been encountered. As a result, a new target may
- require additional strategies. You will know if this happens because
- the compiler will call 'abort'. Fortunately, the new strategies can be
- added in a machine-independent fashion, and will affect only the target
- machines that need them.
-
-
- File: gccint.info, Node: Interface, Next: Libgcc, Prev: Portability, Up: Top
-
- 3 Interfacing to GCC Output
- ***************************
-
- GCC is normally configured to use the same function calling convention
- normally in use on the target system. This is done with the
- machine-description macros described (*note Target Macros::).
-
- However, returning of structure and union values is done differently on
- some target machines. As a result, functions compiled with PCC
- returning such types cannot be called from code compiled with GCC, and
- vice versa. This does not cause trouble often because few Unix library
- routines return structures or unions.
-
- GCC code returns structures and unions that are 1, 2, 4 or 8 bytes long
- in the same registers used for 'int' or 'double' return values. (GCC
- typically allocates variables of such types in registers also.)
- Structures and unions of other sizes are returned by storing them into
- an address passed by the caller (usually in a register). The target
- hook 'TARGET_STRUCT_VALUE_RTX' tells GCC where to pass this address.
-
- By contrast, PCC on most target machines returns structures and unions
- of any size by copying the data into an area of static storage, and then
- returning the address of that storage as if it were a pointer value.
- The caller must copy the data from that memory area to the place where
- the value is wanted. This is slower than the method used by GCC, and
- fails to be reentrant.
-
- On some target machines, such as RISC machines and the 80386, the
- standard system convention is to pass to the subroutine the address of
- where to return the value. On these machines, GCC has been configured
- to be compatible with the standard compiler, when this method is used.
- It may not be compatible for structures of 1, 2, 4 or 8 bytes.
-
- GCC uses the system's standard convention for passing arguments. On
- some machines, the first few arguments are passed in registers; in
- others, all are passed on the stack. It would be possible to use
- registers for argument passing on any machine, and this would probably
- result in a significant speedup. But the result would be complete
- incompatibility with code that follows the standard convention. So this
- change is practical only if you are switching to GCC as the sole C
- compiler for the system. We may implement register argument passing on
- certain machines once we have a complete GNU system so that we can
- compile the libraries with GCC.
-
- On some machines (particularly the SPARC), certain types of arguments
- are passed "by invisible reference". This means that the value is
- stored in memory, and the address of the memory location is passed to
- the subroutine.
-
- If you use 'longjmp', beware of automatic variables. ISO C says that
- automatic variables that are not declared 'volatile' have undefined
- values after a 'longjmp'. And this is all GCC promises to do, because
- it is very difficult to restore register variables correctly, and one of
- GCC's features is that it can put variables in registers without your
- asking it to.
-
-
- File: gccint.info, Node: Libgcc, Next: Languages, Prev: Interface, Up: Top
-
- 4 The GCC low-level runtime library
- ***********************************
-
- GCC provides a low-level runtime library, 'libgcc.a' or 'libgcc_s.so.1'
- on some platforms. GCC generates calls to routines in this library
- automatically, whenever it needs to perform some operation that is too
- complicated to emit inline code for.
-
- Most of the routines in 'libgcc' handle arithmetic operations that the
- target processor cannot perform directly. This includes integer
- multiply and divide on some machines, and all floating-point and
- fixed-point operations on other machines. 'libgcc' also includes
- routines for exception handling, and a handful of miscellaneous
- operations.
-
- Some of these routines can be defined in mostly machine-independent C.
- Others must be hand-written in assembly language for each processor that
- needs them.
-
- GCC will also generate calls to C library routines, such as 'memcpy'
- and 'memset', in some cases. The set of routines that GCC may possibly
- use is documented in *note (gcc)Other Builtins::.
-
- These routines take arguments and return values of a specific machine
- mode, not a specific C type. *Note Machine Modes::, for an explanation
- of this concept. For illustrative purposes, in this chapter the
- floating point type 'float' is assumed to correspond to 'SFmode';
- 'double' to 'DFmode'; and 'long double' to both 'TFmode' and 'XFmode'.
- Similarly, the integer types 'int' and 'unsigned int' correspond to
- 'SImode'; 'long' and 'unsigned long' to 'DImode'; and 'long long' and
- 'unsigned long long' to 'TImode'.
-
- * Menu:
-
- * Integer library routines::
- * Soft float library routines::
- * Decimal float library routines::
- * Fixed-point fractional library routines::
- * Exception handling routines::
- * Miscellaneous routines::
-
-
- File: gccint.info, Node: Integer library routines, Next: Soft float library routines, Up: Libgcc
-
- 4.1 Routines for integer arithmetic
- ===================================
-
- The integer arithmetic routines are used on platforms that don't provide
- hardware support for arithmetic operations on some modes.
-
- 4.1.1 Arithmetic functions
- --------------------------
-
- -- Runtime Function: int __ashlsi3 (int A, int B)
- -- Runtime Function: long __ashldi3 (long A, int B)
- -- Runtime Function: long long __ashlti3 (long long A, int B)
- These functions return the result of shifting A left by B bits.
-
- -- Runtime Function: int __ashrsi3 (int A, int B)
- -- Runtime Function: long __ashrdi3 (long A, int B)
- -- Runtime Function: long long __ashrti3 (long long A, int B)
- These functions return the result of arithmetically shifting A
- right by B bits.
-
- -- Runtime Function: int __divsi3 (int A, int B)
- -- Runtime Function: long __divdi3 (long A, long B)
- -- Runtime Function: long long __divti3 (long long A, long long B)
- These functions return the quotient of the signed division of A and
- B.
-
- -- Runtime Function: int __lshrsi3 (int A, int B)
- -- Runtime Function: long __lshrdi3 (long A, int B)
- -- Runtime Function: long long __lshrti3 (long long A, int B)
- These functions return the result of logically shifting A right by
- B bits.
-
- -- Runtime Function: int __modsi3 (int A, int B)
- -- Runtime Function: long __moddi3 (long A, long B)
- -- Runtime Function: long long __modti3 (long long A, long long B)
- These functions return the remainder of the signed division of A
- and B.
-
- -- Runtime Function: int __mulsi3 (int A, int B)
- -- Runtime Function: long __muldi3 (long A, long B)
- -- Runtime Function: long long __multi3 (long long A, long long B)
- These functions return the product of A and B.
-
- -- Runtime Function: long __negdi2 (long A)
- -- Runtime Function: long long __negti2 (long long A)
- These functions return the negation of A.
-
- -- Runtime Function: unsigned int __udivsi3 (unsigned int A, unsigned
- int B)
- -- Runtime Function: unsigned long __udivdi3 (unsigned long A, unsigned
- long B)
- -- Runtime Function: unsigned long long __udivti3 (unsigned long long
- A, unsigned long long B)
- These functions return the quotient of the unsigned division of A
- and B.
-
- -- Runtime Function: unsigned long __udivmoddi4 (unsigned long A,
- unsigned long B, unsigned long *C)
- -- Runtime Function: unsigned long long __udivmodti4 (unsigned long
- long A, unsigned long long B, unsigned long long *C)
- These functions calculate both the quotient and remainder of the
- unsigned division of A and B. The return value is the quotient,
- and the remainder is placed in variable pointed to by C.
-
- -- Runtime Function: unsigned int __umodsi3 (unsigned int A, unsigned
- int B)
- -- Runtime Function: unsigned long __umoddi3 (unsigned long A, unsigned
- long B)
- -- Runtime Function: unsigned long long __umodti3 (unsigned long long
- A, unsigned long long B)
- These functions return the remainder of the unsigned division of A
- and B.
-
- 4.1.2 Comparison functions
- --------------------------
-
- The following functions implement integral comparisons. These functions
- implement a low-level compare, upon which the higher level comparison
- operators (such as less than and greater than or equal to) can be
- constructed. The returned values lie in the range zero to two, to allow
- the high-level operators to be implemented by testing the returned
- result using either signed or unsigned comparison.
-
- -- Runtime Function: int __cmpdi2 (long A, long B)
- -- Runtime Function: int __cmpti2 (long long A, long long B)
- These functions perform a signed comparison of A and B. If A is
- less than B, they return 0; if A is greater than B, they return 2;
- and if A and B are equal they return 1.
-
- -- Runtime Function: int __ucmpdi2 (unsigned long A, unsigned long B)
- -- Runtime Function: int __ucmpti2 (unsigned long long A, unsigned long
- long B)
- These functions perform an unsigned comparison of A and B. If A is
- less than B, they return 0; if A is greater than B, they return 2;
- and if A and B are equal they return 1.
-
- 4.1.3 Trapping arithmetic functions
- -----------------------------------
-
- The following functions implement trapping arithmetic. These functions
- call the libc function 'abort' upon signed arithmetic overflow.
-
- -- Runtime Function: int __absvsi2 (int A)
- -- Runtime Function: long __absvdi2 (long A)
- These functions return the absolute value of A.
-
- -- Runtime Function: int __addvsi3 (int A, int B)
- -- Runtime Function: long __addvdi3 (long A, long B)
- These functions return the sum of A and B; that is 'A + B'.
-
- -- Runtime Function: int __mulvsi3 (int A, int B)
- -- Runtime Function: long __mulvdi3 (long A, long B)
- The functions return the product of A and B; that is 'A * B'.
-
- -- Runtime Function: int __negvsi2 (int A)
- -- Runtime Function: long __negvdi2 (long A)
- These functions return the negation of A; that is '-A'.
-
- -- Runtime Function: int __subvsi3 (int A, int B)
- -- Runtime Function: long __subvdi3 (long A, long B)
- These functions return the difference between B and A; that is 'A -
- B'.
-
- 4.1.4 Bit operations
- --------------------
-
- -- Runtime Function: int __clzsi2 (unsigned int A)
- -- Runtime Function: int __clzdi2 (unsigned long A)
- -- Runtime Function: int __clzti2 (unsigned long long A)
- These functions return the number of leading 0-bits in A, starting
- at the most significant bit position. If A is zero, the result is
- undefined.
-
- -- Runtime Function: int __ctzsi2 (unsigned int A)
- -- Runtime Function: int __ctzdi2 (unsigned long A)
- -- Runtime Function: int __ctzti2 (unsigned long long A)
- These functions return the number of trailing 0-bits in A, starting
- at the least significant bit position. If A is zero, the result is
- undefined.
-
- -- Runtime Function: int __ffsdi2 (unsigned long A)
- -- Runtime Function: int __ffsti2 (unsigned long long A)
- These functions return the index of the least significant 1-bit in
- A, or the value zero if A is zero. The least significant bit is
- index one.
-
- -- Runtime Function: int __paritysi2 (unsigned int A)
- -- Runtime Function: int __paritydi2 (unsigned long A)
- -- Runtime Function: int __parityti2 (unsigned long long A)
- These functions return the value zero if the number of bits set in
- A is even, and the value one otherwise.
-
- -- Runtime Function: int __popcountsi2 (unsigned int A)
- -- Runtime Function: int __popcountdi2 (unsigned long A)
- -- Runtime Function: int __popcountti2 (unsigned long long A)
- These functions return the number of bits set in A.
-
- -- Runtime Function: int32_t __bswapsi2 (int32_t A)
- -- Runtime Function: int64_t __bswapdi2 (int64_t A)
- These functions return the A byteswapped.
-
-
- File: gccint.info, Node: Soft float library routines, Next: Decimal float library routines, Prev: Integer library routines, Up: Libgcc
-
- 4.2 Routines for floating point emulation
- =========================================
-
- The software floating point library is used on machines which do not
- have hardware support for floating point. It is also used whenever
- '-msoft-float' is used to disable generation of floating point
- instructions. (Not all targets support this switch.)
-
- For compatibility with other compilers, the floating point emulation
- routines can be renamed with the 'DECLARE_LIBRARY_RENAMES' macro (*note
- Library Calls::). In this section, the default names are used.
-
- Presently the library does not support 'XFmode', which is used for
- 'long double' on some architectures.
-
- 4.2.1 Arithmetic functions
- --------------------------
-
- -- Runtime Function: float __addsf3 (float A, float B)
- -- Runtime Function: double __adddf3 (double A, double B)
- -- Runtime Function: long double __addtf3 (long double A, long double
- B)
- -- Runtime Function: long double __addxf3 (long double A, long double
- B)
- These functions return the sum of A and B.
-
- -- Runtime Function: float __subsf3 (float A, float B)
- -- Runtime Function: double __subdf3 (double A, double B)
- -- Runtime Function: long double __subtf3 (long double A, long double
- B)
- -- Runtime Function: long double __subxf3 (long double A, long double
- B)
- These functions return the difference between B and A; that is,
- A - B.
-
- -- Runtime Function: float __mulsf3 (float A, float B)
- -- Runtime Function: double __muldf3 (double A, double B)
- -- Runtime Function: long double __multf3 (long double A, long double
- B)
- -- Runtime Function: long double __mulxf3 (long double A, long double
- B)
- These functions return the product of A and B.
-
- -- Runtime Function: float __divsf3 (float A, float B)
- -- Runtime Function: double __divdf3 (double A, double B)
- -- Runtime Function: long double __divtf3 (long double A, long double
- B)
- -- Runtime Function: long double __divxf3 (long double A, long double
- B)
- These functions return the quotient of A and B; that is, A / B.
-
- -- Runtime Function: float __negsf2 (float A)
- -- Runtime Function: double __negdf2 (double A)
- -- Runtime Function: long double __negtf2 (long double A)
- -- Runtime Function: long double __negxf2 (long double A)
- These functions return the negation of A. They simply flip the
- sign bit, so they can produce negative zero and negative NaN.
-
- 4.2.2 Conversion functions
- --------------------------
-
- -- Runtime Function: double __extendsfdf2 (float A)
- -- Runtime Function: long double __extendsftf2 (float A)
- -- Runtime Function: long double __extendsfxf2 (float A)
- -- Runtime Function: long double __extenddftf2 (double A)
- -- Runtime Function: long double __extenddfxf2 (double A)
- These functions extend A to the wider mode of their return type.
-
- -- Runtime Function: double __truncxfdf2 (long double A)
- -- Runtime Function: double __trunctfdf2 (long double A)
- -- Runtime Function: float __truncxfsf2 (long double A)
- -- Runtime Function: float __trunctfsf2 (long double A)
- -- Runtime Function: float __truncdfsf2 (double A)
- These functions truncate A to the narrower mode of their return
- type, rounding toward zero.
-
- -- Runtime Function: int __fixsfsi (float A)
- -- Runtime Function: int __fixdfsi (double A)
- -- Runtime Function: int __fixtfsi (long double A)
- -- Runtime Function: int __fixxfsi (long double A)
- These functions convert A to a signed integer, rounding toward
- zero.
-
- -- Runtime Function: long __fixsfdi (float A)
- -- Runtime Function: long __fixdfdi (double A)
- -- Runtime Function: long __fixtfdi (long double A)
- -- Runtime Function: long __fixxfdi (long double A)
- These functions convert A to a signed long, rounding toward zero.
-
- -- Runtime Function: long long __fixsfti (float A)
- -- Runtime Function: long long __fixdfti (double A)
- -- Runtime Function: long long __fixtfti (long double A)
- -- Runtime Function: long long __fixxfti (long double A)
- These functions convert A to a signed long long, rounding toward
- zero.
-
- -- Runtime Function: unsigned int __fixunssfsi (float A)
- -- Runtime Function: unsigned int __fixunsdfsi (double A)
- -- Runtime Function: unsigned int __fixunstfsi (long double A)
- -- Runtime Function: unsigned int __fixunsxfsi (long double A)
- These functions convert A to an unsigned integer, rounding toward
- zero. Negative values all become zero.
-
- -- Runtime Function: unsigned long __fixunssfdi (float A)
- -- Runtime Function: unsigned long __fixunsdfdi (double A)
- -- Runtime Function: unsigned long __fixunstfdi (long double A)
- -- Runtime Function: unsigned long __fixunsxfdi (long double A)
- These functions convert A to an unsigned long, rounding toward
- zero. Negative values all become zero.
-
- -- Runtime Function: unsigned long long __fixunssfti (float A)
- -- Runtime Function: unsigned long long __fixunsdfti (double A)
- -- Runtime Function: unsigned long long __fixunstfti (long double A)
- -- Runtime Function: unsigned long long __fixunsxfti (long double A)
- These functions convert A to an unsigned long long, rounding toward
- zero. Negative values all become zero.
-
- -- Runtime Function: float __floatsisf (int I)
- -- Runtime Function: double __floatsidf (int I)
- -- Runtime Function: long double __floatsitf (int I)
- -- Runtime Function: long double __floatsixf (int I)
- These functions convert I, a signed integer, to floating point.
-
- -- Runtime Function: float __floatdisf (long I)
- -- Runtime Function: double __floatdidf (long I)
- -- Runtime Function: long double __floatditf (long I)
- -- Runtime Function: long double __floatdixf (long I)
- These functions convert I, a signed long, to floating point.
-
- -- Runtime Function: float __floattisf (long long I)
- -- Runtime Function: double __floattidf (long long I)
- -- Runtime Function: long double __floattitf (long long I)
- -- Runtime Function: long double __floattixf (long long I)
- These functions convert I, a signed long long, to floating point.
-
- -- Runtime Function: float __floatunsisf (unsigned int I)
- -- Runtime Function: double __floatunsidf (unsigned int I)
- -- Runtime Function: long double __floatunsitf (unsigned int I)
- -- Runtime Function: long double __floatunsixf (unsigned int I)
- These functions convert I, an unsigned integer, to floating point.
-
- -- Runtime Function: float __floatundisf (unsigned long I)
- -- Runtime Function: double __floatundidf (unsigned long I)
- -- Runtime Function: long double __floatunditf (unsigned long I)
- -- Runtime Function: long double __floatundixf (unsigned long I)
- These functions convert I, an unsigned long, to floating point.
-
- -- Runtime Function: float __floatuntisf (unsigned long long I)
- -- Runtime Function: double __floatuntidf (unsigned long long I)
- -- Runtime Function: long double __floatuntitf (unsigned long long I)
- -- Runtime Function: long double __floatuntixf (unsigned long long I)
- These functions convert I, an unsigned long long, to floating
- point.
-
- 4.2.3 Comparison functions
- --------------------------
-
- There are two sets of basic comparison functions.
-
- -- Runtime Function: int __cmpsf2 (float A, float B)
- -- Runtime Function: int __cmpdf2 (double A, double B)
- -- Runtime Function: int __cmptf2 (long double A, long double B)
- These functions calculate a <=> b. That is, if A is less than B,
- they return -1; if A is greater than B, they return 1; and if A and
- B are equal they return 0. If either argument is NaN they return
- 1, but you should not rely on this; if NaN is a possibility, use
- one of the higher-level comparison functions.
-
- -- Runtime Function: int __unordsf2 (float A, float B)
- -- Runtime Function: int __unorddf2 (double A, double B)
- -- Runtime Function: int __unordtf2 (long double A, long double B)
- These functions return a nonzero value if either argument is NaN,
- otherwise 0.
-
- There is also a complete group of higher level functions which
- correspond directly to comparison operators. They implement the ISO C
- semantics for floating-point comparisons, taking NaN into account. Pay
- careful attention to the return values defined for each set. Under the
- hood, all of these routines are implemented as
-
- if (__unordXf2 (a, b))
- return E;
- return __cmpXf2 (a, b);
-
- where E is a constant chosen to give the proper behavior for NaN. Thus,
- the meaning of the return value is different for each set. Do not rely
- on this implementation; only the semantics documented below are
- guaranteed.
-
- -- Runtime Function: int __eqsf2 (float A, float B)
- -- Runtime Function: int __eqdf2 (double A, double B)
- -- Runtime Function: int __eqtf2 (long double A, long double B)
- These functions return zero if neither argument is NaN, and A and B
- are equal.
-
- -- Runtime Function: int __nesf2 (float A, float B)
- -- Runtime Function: int __nedf2 (double A, double B)
- -- Runtime Function: int __netf2 (long double A, long double B)
- These functions return a nonzero value if either argument is NaN,
- or if A and B are unequal.
-
- -- Runtime Function: int __gesf2 (float A, float B)
- -- Runtime Function: int __gedf2 (double A, double B)
- -- Runtime Function: int __getf2 (long double A, long double B)
- These functions return a value greater than or equal to zero if
- neither argument is NaN, and A is greater than or equal to B.
-
- -- Runtime Function: int __ltsf2 (float A, float B)
- -- Runtime Function: int __ltdf2 (double A, double B)
- -- Runtime Function: int __lttf2 (long double A, long double B)
- These functions return a value less than zero if neither argument
- is NaN, and A is strictly less than B.
-
- -- Runtime Function: int __lesf2 (float A, float B)
- -- Runtime Function: int __ledf2 (double A, double B)
- -- Runtime Function: int __letf2 (long double A, long double B)
- These functions return a value less than or equal to zero if
- neither argument is NaN, and A is less than or equal to B.
-
- -- Runtime Function: int __gtsf2 (float A, float B)
- -- Runtime Function: int __gtdf2 (double A, double B)
- -- Runtime Function: int __gttf2 (long double A, long double B)
- These functions return a value greater than zero if neither
- argument is NaN, and A is strictly greater than B.
-
- 4.2.4 Other floating-point functions
- ------------------------------------
-
- -- Runtime Function: float __powisf2 (float A, int B)
- -- Runtime Function: double __powidf2 (double A, int B)
- -- Runtime Function: long double __powitf2 (long double A, int B)
- -- Runtime Function: long double __powixf2 (long double A, int B)
- These functions convert raise A to the power B.
-
- -- Runtime Function: complex float __mulsc3 (float A, float B, float C,
- float D)
- -- Runtime Function: complex double __muldc3 (double A, double B,
- double C, double D)
- -- Runtime Function: complex long double __multc3 (long double A, long
- double B, long double C, long double D)
- -- Runtime Function: complex long double __mulxc3 (long double A, long
- double B, long double C, long double D)
- These functions return the product of A + iB and C + iD, following
- the rules of C99 Annex G.
-
- -- Runtime Function: complex float __divsc3 (float A, float B, float C,
- float D)
- -- Runtime Function: complex double __divdc3 (double A, double B,
- double C, double D)
- -- Runtime Function: complex long double __divtc3 (long double A, long
- double B, long double C, long double D)
- -- Runtime Function: complex long double __divxc3 (long double A, long
- double B, long double C, long double D)
- These functions return the quotient of A + iB and C + iD (i.e., (A
- + iB) / (C + iD)), following the rules of C99 Annex G.
-
-
- File: gccint.info, Node: Decimal float library routines, Next: Fixed-point fractional library routines, Prev: Soft float library routines, Up: Libgcc
-
- 4.3 Routines for decimal floating point emulation
- =================================================
-
- The software decimal floating point library implements IEEE 754-2008
- decimal floating point arithmetic and is only activated on selected
- targets.
-
- The software decimal floating point library supports either DPD
- (Densely Packed Decimal) or BID (Binary Integer Decimal) encoding as
- selected at configure time.
-
- 4.3.1 Arithmetic functions
- --------------------------
-
- -- Runtime Function: _Decimal32 __dpd_addsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal32 __bid_addsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal64 __dpd_adddd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal64 __bid_adddd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal128 __dpd_addtd3 (_Decimal128 A,
- _Decimal128 B)
- -- Runtime Function: _Decimal128 __bid_addtd3 (_Decimal128 A,
- _Decimal128 B)
- These functions return the sum of A and B.
-
- -- Runtime Function: _Decimal32 __dpd_subsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal32 __bid_subsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal64 __dpd_subdd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal64 __bid_subdd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal128 __dpd_subtd3 (_Decimal128 A,
- _Decimal128 B)
- -- Runtime Function: _Decimal128 __bid_subtd3 (_Decimal128 A,
- _Decimal128 B)
- These functions return the difference between B and A; that is,
- A - B.
-
- -- Runtime Function: _Decimal32 __dpd_mulsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal32 __bid_mulsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal64 __dpd_muldd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal64 __bid_muldd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal128 __dpd_multd3 (_Decimal128 A,
- _Decimal128 B)
- -- Runtime Function: _Decimal128 __bid_multd3 (_Decimal128 A,
- _Decimal128 B)
- These functions return the product of A and B.
-
- -- Runtime Function: _Decimal32 __dpd_divsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal32 __bid_divsd3 (_Decimal32 A, _Decimal32
- B)
- -- Runtime Function: _Decimal64 __dpd_divdd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal64 __bid_divdd3 (_Decimal64 A, _Decimal64
- B)
- -- Runtime Function: _Decimal128 __dpd_divtd3 (_Decimal128 A,
- _Decimal128 B)
- -- Runtime Function: _Decimal128 __bid_divtd3 (_Decimal128 A,
- _Decimal128 B)
- These functions return the quotient of A and B; that is, A / B.
-
- -- Runtime Function: _Decimal32 __dpd_negsd2 (_Decimal32 A)
- -- Runtime Function: _Decimal32 __bid_negsd2 (_Decimal32 A)
- -- Runtime Function: _Decimal64 __dpd_negdd2 (_Decimal64 A)
- -- Runtime Function: _Decimal64 __bid_negdd2 (_Decimal64 A)
- -- Runtime Function: _Decimal128 __dpd_negtd2 (_Decimal128 A)
- -- Runtime Function: _Decimal128 __bid_negtd2 (_Decimal128 A)
- These functions return the negation of A. They simply flip the
- sign bit, so they can produce negative zero and negative NaN.
-
- 4.3.2 Conversion functions
- --------------------------
-
- -- Runtime Function: _Decimal64 __dpd_extendsddd2 (_Decimal32 A)
- -- Runtime Function: _Decimal64 __bid_extendsddd2 (_Decimal32 A)
- -- Runtime Function: _Decimal128 __dpd_extendsdtd2 (_Decimal32 A)
- -- Runtime Function: _Decimal128 __bid_extendsdtd2 (_Decimal32 A)
- -- Runtime Function: _Decimal128 __dpd_extendddtd2 (_Decimal64 A)
- -- Runtime Function: _Decimal128 __bid_extendddtd2 (_Decimal64 A)
- -- Runtime Function: _Decimal32 __dpd_truncddsd2 (_Decimal64 A)
- -- Runtime Function: _Decimal32 __bid_truncddsd2 (_Decimal64 A)
- -- Runtime Function: _Decimal32 __dpd_trunctdsd2 (_Decimal128 A)
- -- Runtime Function: _Decimal32 __bid_trunctdsd2 (_Decimal128 A)
- -- Runtime Function: _Decimal64 __dpd_trunctddd2 (_Decimal128 A)
- -- Runtime Function: _Decimal64 __bid_trunctddd2 (_Decimal128 A)
- These functions convert the value A from one decimal floating type
- to another.
-
- -- Runtime Function: _Decimal64 __dpd_extendsfdd (float A)
- -- Runtime Function: _Decimal64 __bid_extendsfdd (float A)
- -- Runtime Function: _Decimal128 __dpd_extendsftd (float A)
- -- Runtime Function: _Decimal128 __bid_extendsftd (float A)
- -- Runtime Function: _Decimal128 __dpd_extenddftd (double A)
- -- Runtime Function: _Decimal128 __bid_extenddftd (double A)
- -- Runtime Function: _Decimal128 __dpd_extendxftd (long double A)
- -- Runtime Function: _Decimal128 __bid_extendxftd (long double A)
- -- Runtime Function: _Decimal32 __dpd_truncdfsd (double A)
- -- Runtime Function: _Decimal32 __bid_truncdfsd (double A)
- -- Runtime Function: _Decimal32 __dpd_truncxfsd (long double A)
- -- Runtime Function: _Decimal32 __bid_truncxfsd (long double A)
- -- Runtime Function: _Decimal32 __dpd_trunctfsd (long double A)
- -- Runtime Function: _Decimal32 __bid_trunctfsd (long double A)
- -- Runtime Function: _Decimal64 __dpd_truncxfdd (long double A)
- -- Runtime Function: _Decimal64 __bid_truncxfdd (long double A)
- -- Runtime Function: _Decimal64 __dpd_trunctfdd (long double A)
- -- Runtime Function: _Decimal64 __bid_trunctfdd (long double A)
- These functions convert the value of A from a binary floating type
- to a decimal floating type of a different size.
-
- -- Runtime Function: float __dpd_truncddsf (_Decimal64 A)
- -- Runtime Function: float __bid_truncddsf (_Decimal64 A)
- -- Runtime Function: float __dpd_trunctdsf (_Decimal128 A)
- -- Runtime Function: float __bid_trunctdsf (_Decimal128 A)
- -- Runtime Function: double __dpd_extendsddf (_Decimal32 A)
- -- Runtime Function: double __bid_extendsddf (_Decimal32 A)
- -- Runtime Function: double __dpd_trunctddf (_Decimal128 A)
- -- Runtime Function: double __bid_trunctddf (_Decimal128 A)
- -- Runtime Function: long double __dpd_extendsdxf (_Decimal32 A)
- -- Runtime Function: long double __bid_extendsdxf (_Decimal32 A)
- -- Runtime Function: long double __dpd_extendddxf (_Decimal64 A)
- -- Runtime Function: long double __bid_extendddxf (_Decimal64 A)
- -- Runtime Function: long double __dpd_trunctdxf (_Decimal128 A)
- -- Runtime Function: long double __bid_trunctdxf (_Decimal128 A)
- -- Runtime Function: long double __dpd_extendsdtf (_Decimal32 A)
- -- Runtime Function: long double __bid_extendsdtf (_Decimal32 A)
- -- Runtime Function: long double __dpd_extendddtf (_Decimal64 A)
- -- Runtime Function: long double __bid_extendddtf (_Decimal64 A)
- These functions convert the value of A from a decimal floating type
- to a binary floating type of a different size.
-
- -- Runtime Function: _Decimal32 __dpd_extendsfsd (float A)
- -- Runtime Function: _Decimal32 __bid_extendsfsd (float A)
- -- Runtime Function: _Decimal64 __dpd_extenddfdd (double A)
- -- Runtime Function: _Decimal64 __bid_extenddfdd (double A)
- -- Runtime Function: _Decimal128 __dpd_extendtftd (long double A)
- -- Runtime Function: _Decimal128 __bid_extendtftd (long double A)
- -- Runtime Function: float __dpd_truncsdsf (_Decimal32 A)
- -- Runtime Function: float __bid_truncsdsf (_Decimal32 A)
- -- Runtime Function: double __dpd_truncdddf (_Decimal64 A)
- -- Runtime Function: double __bid_truncdddf (_Decimal64 A)
- -- Runtime Function: long double __dpd_trunctdtf (_Decimal128 A)
- -- Runtime Function: long double __bid_trunctdtf (_Decimal128 A)
- These functions convert the value of A between decimal and binary
- floating types of the same size.
-
- -- Runtime Function: int __dpd_fixsdsi (_Decimal32 A)
- -- Runtime Function: int __bid_fixsdsi (_Decimal32 A)
- -- Runtime Function: int __dpd_fixddsi (_Decimal64 A)
- -- Runtime Function: int __bid_fixddsi (_Decimal64 A)
- -- Runtime Function: int __dpd_fixtdsi (_Decimal128 A)
- -- Runtime Function: int __bid_fixtdsi (_Decimal128 A)
- These functions convert A to a signed integer.
-
- -- Runtime Function: long __dpd_fixsddi (_Decimal32 A)
- -- Runtime Function: long __bid_fixsddi (_Decimal32 A)
- -- Runtime Function: long __dpd_fixdddi (_Decimal64 A)
- -- Runtime Function: long __bid_fixdddi (_Decimal64 A)
- -- Runtime Function: long __dpd_fixtddi (_Decimal128 A)
- -- Runtime Function: long __bid_fixtddi (_Decimal128 A)
- These functions convert A to a signed long.
-
- -- Runtime Function: unsigned int __dpd_fixunssdsi (_Decimal32 A)
- -- Runtime Function: unsigned int __bid_fixunssdsi (_Decimal32 A)
- -- Runtime Function: unsigned int __dpd_fixunsddsi (_Decimal64 A)
- -- Runtime Function: unsigned int __bid_fixunsddsi (_Decimal64 A)
- -- Runtime Function: unsigned int __dpd_fixunstdsi (_Decimal128 A)
- -- Runtime Function: unsigned int __bid_fixunstdsi (_Decimal128 A)
- These functions convert A to an unsigned integer. Negative values
- all become zero.
-
- -- Runtime Function: unsigned long __dpd_fixunssddi (_Decimal32 A)
- -- Runtime Function: unsigned long __bid_fixunssddi (_Decimal32 A)
- -- Runtime Function: unsigned long __dpd_fixunsdddi (_Decimal64 A)
- -- Runtime Function: unsigned long __bid_fixunsdddi (_Decimal64 A)
- -- Runtime Function: unsigned long __dpd_fixunstddi (_Decimal128 A)
- -- Runtime Function: unsigned long __bid_fixunstddi (_Decimal128 A)
- These functions convert A to an unsigned long. Negative values all
- become zero.
-
- -- Runtime Function: _Decimal32 __dpd_floatsisd (int I)
- -- Runtime Function: _Decimal32 __bid_floatsisd (int I)
- -- Runtime Function: _Decimal64 __dpd_floatsidd (int I)
- -- Runtime Function: _Decimal64 __bid_floatsidd (int I)
- -- Runtime Function: _Decimal128 __dpd_floatsitd (int I)
- -- Runtime Function: _Decimal128 __bid_floatsitd (int I)
- These functions convert I, a signed integer, to decimal floating
- point.
-
- -- Runtime Function: _Decimal32 __dpd_floatdisd (long I)
- -- Runtime Function: _Decimal32 __bid_floatdisd (long I)
- -- Runtime Function: _Decimal64 __dpd_floatdidd (long I)
- -- Runtime Function: _Decimal64 __bid_floatdidd (long I)
- -- Runtime Function: _Decimal128 __dpd_floatditd (long I)
- -- Runtime Function: _Decimal128 __bid_floatditd (long I)
- These functions convert I, a signed long, to decimal floating
- point.
-
- -- Runtime Function: _Decimal32 __dpd_floatunssisd (unsigned int I)
- -- Runtime Function: _Decimal32 __bid_floatunssisd (unsigned int I)
- -- Runtime Function: _Decimal64 __dpd_floatunssidd (unsigned int I)
- -- Runtime Function: _Decimal64 __bid_floatunssidd (unsigned int I)
- -- Runtime Function: _Decimal128 __dpd_floatunssitd (unsigned int I)
- -- Runtime Function: _Decimal128 __bid_floatunssitd (unsigned int I)
- These functions convert I, an unsigned integer, to decimal floating
- point.
-
- -- Runtime Function: _Decimal32 __dpd_floatunsdisd (unsigned long I)
- -- Runtime Function: _Decimal32 __bid_floatunsdisd (unsigned long I)
- -- Runtime Function: _Decimal64 __dpd_floatunsdidd (unsigned long I)
- -- Runtime Function: _Decimal64 __bid_floatunsdidd (unsigned long I)
- -- Runtime Function: _Decimal128 __dpd_floatunsditd (unsigned long I)
- -- Runtime Function: _Decimal128 __bid_floatunsditd (unsigned long I)
- These functions convert I, an unsigned long, to decimal floating
- point.
-
- 4.3.3 Comparison functions
- --------------------------
-
- -- Runtime Function: int __dpd_unordsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_unordsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_unorddd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_unorddd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_unordtd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_unordtd2 (_Decimal128 A, _Decimal128 B)
- These functions return a nonzero value if either argument is NaN,
- otherwise 0.
-
- There is also a complete group of higher level functions which
- correspond directly to comparison operators. They implement the ISO C
- semantics for floating-point comparisons, taking NaN into account. Pay
- careful attention to the return values defined for each set. Under the
- hood, all of these routines are implemented as
-
- if (__bid_unordXd2 (a, b))
- return E;
- return __bid_cmpXd2 (a, b);
-
- where E is a constant chosen to give the proper behavior for NaN. Thus,
- the meaning of the return value is different for each set. Do not rely
- on this implementation; only the semantics documented below are
- guaranteed.
-
- -- Runtime Function: int __dpd_eqsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_eqsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_eqdd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_eqdd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_eqtd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_eqtd2 (_Decimal128 A, _Decimal128 B)
- These functions return zero if neither argument is NaN, and A and B
- are equal.
-
- -- Runtime Function: int __dpd_nesd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_nesd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_nedd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_nedd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_netd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_netd2 (_Decimal128 A, _Decimal128 B)
- These functions return a nonzero value if either argument is NaN,
- or if A and B are unequal.
-
- -- Runtime Function: int __dpd_gesd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_gesd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_gedd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_gedd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_getd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_getd2 (_Decimal128 A, _Decimal128 B)
- These functions return a value greater than or equal to zero if
- neither argument is NaN, and A is greater than or equal to B.
-
- -- Runtime Function: int __dpd_ltsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_ltsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_ltdd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_ltdd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_lttd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_lttd2 (_Decimal128 A, _Decimal128 B)
- These functions return a value less than zero if neither argument
- is NaN, and A is strictly less than B.
-
- -- Runtime Function: int __dpd_lesd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_lesd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_ledd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_ledd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_letd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_letd2 (_Decimal128 A, _Decimal128 B)
- These functions return a value less than or equal to zero if
- neither argument is NaN, and A is less than or equal to B.
-
- -- Runtime Function: int __dpd_gtsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __bid_gtsd2 (_Decimal32 A, _Decimal32 B)
- -- Runtime Function: int __dpd_gtdd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __bid_gtdd2 (_Decimal64 A, _Decimal64 B)
- -- Runtime Function: int __dpd_gttd2 (_Decimal128 A, _Decimal128 B)
- -- Runtime Function: int __bid_gttd2 (_Decimal128 A, _Decimal128 B)
- These functions return a value greater than zero if neither
- argument is NaN, and A is strictly greater than B.
-
-
- File: gccint.info, Node: Fixed-point fractional library routines, Next: Exception handling routines, Prev: Decimal float library routines, Up: Libgcc
-
- 4.4 Routines for fixed-point fractional emulation
- =================================================
-
- The software fixed-point library implements fixed-point fractional
- arithmetic, and is only activated on selected targets.
-
- For ease of comprehension 'fract' is an alias for the '_Fract' type,
- 'accum' an alias for '_Accum', and 'sat' an alias for '_Sat'.
-
- For illustrative purposes, in this section the fixed-point fractional
- type 'short fract' is assumed to correspond to machine mode 'QQmode';
- 'unsigned short fract' to 'UQQmode'; 'fract' to 'HQmode';
- 'unsigned fract' to 'UHQmode'; 'long fract' to 'SQmode';
- 'unsigned long fract' to 'USQmode'; 'long long fract' to 'DQmode'; and
- 'unsigned long long fract' to 'UDQmode'. Similarly the fixed-point
- accumulator type 'short accum' corresponds to 'HAmode';
- 'unsigned short accum' to 'UHAmode'; 'accum' to 'SAmode';
- 'unsigned accum' to 'USAmode'; 'long accum' to 'DAmode';
- 'unsigned long accum' to 'UDAmode'; 'long long accum' to 'TAmode'; and
- 'unsigned long long accum' to 'UTAmode'.
-
- 4.4.1 Arithmetic functions
- --------------------------
-
- -- Runtime Function: short fract __addqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __addhq3 (fract A, fract B)
- -- Runtime Function: long fract __addsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __adddq3 (long long fract A, long
- long fract B)
- -- Runtime Function: unsigned short fract __adduqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __adduhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __addusq3 (unsigned long fract
- A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __addudq3 (unsigned long
- long fract A, unsigned long long fract B)
- -- Runtime Function: short accum __addha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __addsa3 (accum A, accum B)
- -- Runtime Function: long accum __addda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __addta3 (long long accum A, long
- long accum B)
- -- Runtime Function: unsigned short accum __adduha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __addusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __adduda3 (unsigned long accum
- A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __adduta3 (unsigned long
- long accum A, unsigned long long accum B)
- These functions return the sum of A and B.
-
- -- Runtime Function: short fract __ssaddqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __ssaddhq3 (fract A, fract B)
- -- Runtime Function: long fract __ssaddsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __ssadddq3 (long long fract A,
- long long fract B)
- -- Runtime Function: short accum __ssaddha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __ssaddsa3 (accum A, accum B)
- -- Runtime Function: long accum __ssaddda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __ssaddta3 (long long accum A,
- long long accum B)
- These functions return the sum of A and B with signed saturation.
-
- -- Runtime Function: unsigned short fract __usadduqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __usadduhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __usaddusq3 (unsigned long
- fract A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __usaddudq3 (unsigned
- long long fract A, unsigned long long fract B)
- -- Runtime Function: unsigned short accum __usadduha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __usaddusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __usadduda3 (unsigned long
- accum A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __usadduta3 (unsigned
- long long accum A, unsigned long long accum B)
- These functions return the sum of A and B with unsigned saturation.
-
- -- Runtime Function: short fract __subqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __subhq3 (fract A, fract B)
- -- Runtime Function: long fract __subsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __subdq3 (long long fract A, long
- long fract B)
- -- Runtime Function: unsigned short fract __subuqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __subuhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __subusq3 (unsigned long fract
- A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __subudq3 (unsigned long
- long fract A, unsigned long long fract B)
- -- Runtime Function: short accum __subha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __subsa3 (accum A, accum B)
- -- Runtime Function: long accum __subda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __subta3 (long long accum A, long
- long accum B)
- -- Runtime Function: unsigned short accum __subuha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __subusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __subuda3 (unsigned long accum
- A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __subuta3 (unsigned long
- long accum A, unsigned long long accum B)
- These functions return the difference of A and B; that is, 'A - B'.
-
- -- Runtime Function: short fract __sssubqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __sssubhq3 (fract A, fract B)
- -- Runtime Function: long fract __sssubsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __sssubdq3 (long long fract A,
- long long fract B)
- -- Runtime Function: short accum __sssubha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __sssubsa3 (accum A, accum B)
- -- Runtime Function: long accum __sssubda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __sssubta3 (long long accum A,
- long long accum B)
- These functions return the difference of A and B with signed
- saturation; that is, 'A - B'.
-
- -- Runtime Function: unsigned short fract __ussubuqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __ussubuhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __ussubusq3 (unsigned long
- fract A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __ussubudq3 (unsigned
- long long fract A, unsigned long long fract B)
- -- Runtime Function: unsigned short accum __ussubuha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __ussubusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __ussubuda3 (unsigned long
- accum A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __ussubuta3 (unsigned
- long long accum A, unsigned long long accum B)
- These functions return the difference of A and B with unsigned
- saturation; that is, 'A - B'.
-
- -- Runtime Function: short fract __mulqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __mulhq3 (fract A, fract B)
- -- Runtime Function: long fract __mulsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __muldq3 (long long fract A, long
- long fract B)
- -- Runtime Function: unsigned short fract __muluqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __muluhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __mulusq3 (unsigned long fract
- A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __muludq3 (unsigned long
- long fract A, unsigned long long fract B)
- -- Runtime Function: short accum __mulha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __mulsa3 (accum A, accum B)
- -- Runtime Function: long accum __mulda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __multa3 (long long accum A, long
- long accum B)
- -- Runtime Function: unsigned short accum __muluha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __mulusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __muluda3 (unsigned long accum
- A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __muluta3 (unsigned long
- long accum A, unsigned long long accum B)
- These functions return the product of A and B.
-
- -- Runtime Function: short fract __ssmulqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __ssmulhq3 (fract A, fract B)
- -- Runtime Function: long fract __ssmulsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __ssmuldq3 (long long fract A,
- long long fract B)
- -- Runtime Function: short accum __ssmulha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __ssmulsa3 (accum A, accum B)
- -- Runtime Function: long accum __ssmulda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __ssmulta3 (long long accum A,
- long long accum B)
- These functions return the product of A and B with signed
- saturation.
-
- -- Runtime Function: unsigned short fract __usmuluqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __usmuluhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __usmulusq3 (unsigned long
- fract A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __usmuludq3 (unsigned
- long long fract A, unsigned long long fract B)
- -- Runtime Function: unsigned short accum __usmuluha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __usmulusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __usmuluda3 (unsigned long
- accum A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __usmuluta3 (unsigned
- long long accum A, unsigned long long accum B)
- These functions return the product of A and B with unsigned
- saturation.
-
- -- Runtime Function: short fract __divqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __divhq3 (fract A, fract B)
- -- Runtime Function: long fract __divsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __divdq3 (long long fract A, long
- long fract B)
- -- Runtime Function: short accum __divha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __divsa3 (accum A, accum B)
- -- Runtime Function: long accum __divda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __divta3 (long long accum A, long
- long accum B)
- These functions return the quotient of the signed division of A and
- B.
-
- -- Runtime Function: unsigned short fract __udivuqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __udivuhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __udivusq3 (unsigned long
- fract A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __udivudq3 (unsigned long
- long fract A, unsigned long long fract B)
- -- Runtime Function: unsigned short accum __udivuha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __udivusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __udivuda3 (unsigned long
- accum A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __udivuta3 (unsigned long
- long accum A, unsigned long long accum B)
- These functions return the quotient of the unsigned division of A
- and B.
-
- -- Runtime Function: short fract __ssdivqq3 (short fract A, short fract
- B)
- -- Runtime Function: fract __ssdivhq3 (fract A, fract B)
- -- Runtime Function: long fract __ssdivsq3 (long fract A, long fract B)
- -- Runtime Function: long long fract __ssdivdq3 (long long fract A,
- long long fract B)
- -- Runtime Function: short accum __ssdivha3 (short accum A, short accum
- B)
- -- Runtime Function: accum __ssdivsa3 (accum A, accum B)
- -- Runtime Function: long accum __ssdivda3 (long accum A, long accum B)
- -- Runtime Function: long long accum __ssdivta3 (long long accum A,
- long long accum B)
- These functions return the quotient of the signed division of A and
- B with signed saturation.
-
- -- Runtime Function: unsigned short fract __usdivuqq3 (unsigned short
- fract A, unsigned short fract B)
- -- Runtime Function: unsigned fract __usdivuhq3 (unsigned fract A,
- unsigned fract B)
- -- Runtime Function: unsigned long fract __usdivusq3 (unsigned long
- fract A, unsigned long fract B)
- -- Runtime Function: unsigned long long fract __usdivudq3 (unsigned
- long long fract A, unsigned long long fract B)
- -- Runtime Function: unsigned short accum __usdivuha3 (unsigned short
- accum A, unsigned short accum B)
- -- Runtime Function: unsigned accum __usdivusa3 (unsigned accum A,
- unsigned accum B)
- -- Runtime Function: unsigned long accum __usdivuda3 (unsigned long
- accum A, unsigned long accum B)
- -- Runtime Function: unsigned long long accum __usdivuta3 (unsigned
- long long accum A, unsigned long long accum B)
- These functions return the quotient of the unsigned division of A
- and B with unsigned saturation.
-
- -- Runtime Function: short fract __negqq2 (short fract A)
- -- Runtime Function: fract __neghq2 (fract A)
- -- Runtime Function: long fract __negsq2 (long fract A)
- -- Runtime Function: long long fract __negdq2 (long long fract A)
- -- Runtime Function: unsigned short fract __neguqq2 (unsigned short
- fract A)
- -- Runtime Function: unsigned fract __neguhq2 (unsigned fract A)
- -- Runtime Function: unsigned long fract __negusq2 (unsigned long fract
- A)
- -- Runtime Function: unsigned long long fract __negudq2 (unsigned long
- long fract A)
- -- Runtime Function: short accum __negha2 (short accum A)
- -- Runtime Function: accum __negsa2 (accum A)
- -- Runtime Function: long accum __negda2 (long accum A)
- -- Runtime Function: long long accum __negta2 (long long accum A)
- -- Runtime Function: unsigned short accum __neguha2 (unsigned short
- accum A)
- -- Runtime Function: unsigned accum __negusa2 (unsigned accum A)
- -- Runtime Function: unsigned long accum __neguda2 (unsigned long accum
- A)
- -- Runtime Function: unsigned long long accum __neguta2 (unsigned long
- long accum A)
- These functions return the negation of A.
-
- -- Runtime Function: short fract __ssnegqq2 (short fract A)
- -- Runtime Function: fract __ssneghq2 (fract A)
- -- Runtime Function: long fract __ssnegsq2 (long fract A)
- -- Runtime Function: long long fract __ssnegdq2 (long long fract A)
- -- Runtime Function: short accum __ssnegha2 (short accum A)
- -- Runtime Function: accum __ssnegsa2 (accum A)
- -- Runtime Function: long accum __ssnegda2 (long accum A)
- -- Runtime Function: long long accum __ssnegta2 (long long accum A)
- These functions return the negation of A with signed saturation.
-
- -- Runtime Function: unsigned short fract __usneguqq2 (unsigned short
- fract A)
- -- Runtime Function: unsigned fract __usneguhq2 (unsigned fract A)
- -- Runtime Function: unsigned long fract __usnegusq2 (unsigned long
- fract A)
- -- Runtime Function: unsigned long long fract __usnegudq2 (unsigned
- long long fract A)
- -- Runtime Function: unsigned short accum __usneguha2 (unsigned short
- accum A)
- -- Runtime Function: unsigned accum __usnegusa2 (unsigned accum A)
- -- Runtime Function: unsigned long accum __usneguda2 (unsigned long
- accum A)
- -- Runtime Function: unsigned long long accum __usneguta2 (unsigned
- long long accum A)
- These functions return the negation of A with unsigned saturation.
-
- -- Runtime Function: short fract __ashlqq3 (short fract A, int B)
- -- Runtime Function: fract __ashlhq3 (fract A, int B)
- -- Runtime Function: long fract __ashlsq3 (long fract A, int B)
- -- Runtime Function: long long fract __ashldq3 (long long fract A, int
- B)
- -- Runtime Function: unsigned short fract __ashluqq3 (unsigned short
- fract A, int B)
- -- Runtime Function: unsigned fract __ashluhq3 (unsigned fract A, int
- B)
- -- Runtime Function: unsigned long fract __ashlusq3 (unsigned long
- fract A, int B)
- -- Runtime Function: unsigned long long fract __ashludq3 (unsigned long
- long fract A, int B)
- -- Runtime Function: short accum __ashlha3 (short accum A, int B)
- -- Runtime Function: accum __ashlsa3 (accum A, int B)
- -- Runtime Function: long accum __ashlda3 (long accum A, int B)
- -- Runtime Function: long long accum __ashlta3 (long long accum A, int
- B)
- -- Runtime Function: unsigned short accum __ashluha3 (unsigned short
- accum A, int B)
- -- Runtime Function: unsigned accum __ashlusa3 (unsigned accum A, int
- B)
- -- Runtime Function: unsigned long accum __ashluda3 (unsigned long
- accum A, int B)
- -- Runtime Function: unsigned long long accum __ashluta3 (unsigned long
- long accum A, int B)
- These functions return the result of shifting A left by B bits.
-
- -- Runtime Function: short fract __ashrqq3 (short fract A, int B)
- -- Runtime Function: fract __ashrhq3 (fract A, int B)
- -- Runtime Function: long fract __ashrsq3 (long fract A, int B)
- -- Runtime Function: long long fract __ashrdq3 (long long fract A, int
- B)
- -- Runtime Function: short accum __ashrha3 (short accum A, int B)
- -- Runtime Function: accum __ashrsa3 (accum A, int B)
- -- Runtime Function: long accum __ashrda3 (long accum A, int B)
- -- Runtime Function: long long accum __ashrta3 (long long accum A, int
- B)
- These functions return the result of arithmetically shifting A
- right by B bits.
-
- -- Runtime Function: unsigned short fract __lshruqq3 (unsigned short
- fract A, int B)
- -- Runtime Function: unsigned fract __lshruhq3 (unsigned fract A, int
- B)
- -- Runtime Function: unsigned long fract __lshrusq3 (unsigned long
- fract A, int B)
- -- Runtime Function: unsigned long long fract __lshrudq3 (unsigned long
- long fract A, int B)
- -- Runtime Function: unsigned short accum __lshruha3 (unsigned short
- accum A, int B)
- -- Runtime Function: unsigned accum __lshrusa3 (unsigned accum A, int
- B)
- -- Runtime Function: unsigned long accum __lshruda3 (unsigned long
- accum A, int B)
- -- Runtime Function: unsigned long long accum __lshruta3 (unsigned long
- long accum A, int B)
- These functions return the result of logically shifting A right by
- B bits.
-
- -- Runtime Function: fract __ssashlhq3 (fract A, int B)
- -- Runtime Function: long fract __ssashlsq3 (long fract A, int B)
- -- Runtime Function: long long fract __ssashldq3 (long long fract A,
- int B)
- -- Runtime Function: short accum __ssashlha3 (short accum A, int B)
- -- Runtime Function: accum __ssashlsa3 (accum A, int B)
- -- Runtime Function: long accum __ssashlda3 (long accum A, int B)
- -- Runtime Function: long long accum __ssashlta3 (long long accum A,
- int B)
- These functions return the result of shifting A left by B bits with
- signed saturation.
-
- -- Runtime Function: unsigned short fract __usashluqq3 (unsigned short
- fract A, int B)
- -- Runtime Function: unsigned fract __usashluhq3 (unsigned fract A, int
- B)
- -- Runtime Function: unsigned long fract __usashlusq3 (unsigned long
- fract A, int B)
- -- Runtime Function: unsigned long long fract __usashludq3 (unsigned
- long long fract A, int B)
- -- Runtime Function: unsigned short accum __usashluha3 (unsigned short
- accum A, int B)
- -- Runtime Function: unsigned accum __usashlusa3 (unsigned accum A, int
- B)
- -- Runtime Function: unsigned long accum __usashluda3 (unsigned long
- accum A, int B)
- -- Runtime Function: unsigned long long accum __usashluta3 (unsigned
- long long accum A, int B)
- These functions return the result of shifting A left by B bits with
- unsigned saturation.
-
- 4.4.2 Comparison functions
- --------------------------
-
- The following functions implement fixed-point comparisons. These
- functions implement a low-level compare, upon which the higher level
- comparison operators (such as less than and greater than or equal to)
- can be constructed. The returned values lie in the range zero to two,
- to allow the high-level operators to be implemented by testing the
- returned result using either signed or unsigned comparison.
-
- -- Runtime Function: int __cmpqq2 (short fract A, short fract B)
- -- Runtime Function: int __cmphq2 (fract A, fract B)
- -- Runtime Function: int __cmpsq2 (long fract A, long fract B)
- -- Runtime Function: int __cmpdq2 (long long fract A, long long fract
- B)
- -- Runtime Function: int __cmpuqq2 (unsigned short fract A, unsigned
- short fract B)
- -- Runtime Function: int __cmpuhq2 (unsigned fract A, unsigned fract B)
- -- Runtime Function: int __cmpusq2 (unsigned long fract A, unsigned
- long fract B)
- -- Runtime Function: int __cmpudq2 (unsigned long long fract A,
- unsigned long long fract B)
- -- Runtime Function: int __cmpha2 (short accum A, short accum B)
- -- Runtime Function: int __cmpsa2 (accum A, accum B)
- -- Runtime Function: int __cmpda2 (long accum A, long accum B)
- -- Runtime Function: int __cmpta2 (long long accum A, long long accum
- B)
- -- Runtime Function: int __cmpuha2 (unsigned short accum A, unsigned
- short accum B)
- -- Runtime Function: int __cmpusa2 (unsigned accum A, unsigned accum B)
- -- Runtime Function: int __cmpuda2 (unsigned long accum A, unsigned
- long accum B)
- -- Runtime Function: int __cmputa2 (unsigned long long accum A,
- unsigned long long accum B)
- These functions perform a signed or unsigned comparison of A and B
- (depending on the selected machine mode). If A is less than B,
- they return 0; if A is greater than B, they return 2; and if A and
- B are equal they return 1.
-
- 4.4.3 Conversion functions
- --------------------------
-
- -- Runtime Function: fract __fractqqhq2 (short fract A)
- -- Runtime Function: long fract __fractqqsq2 (short fract A)
- -- Runtime Function: long long fract __fractqqdq2 (short fract A)
- -- Runtime Function: short accum __fractqqha (short fract A)
- -- Runtime Function: accum __fractqqsa (short fract A)
- -- Runtime Function: long accum __fractqqda (short fract A)
- -- Runtime Function: long long accum __fractqqta (short fract A)
- -- Runtime Function: unsigned short fract __fractqquqq (short fract A)
- -- Runtime Function: unsigned fract __fractqquhq (short fract A)
- -- Runtime Function: unsigned long fract __fractqqusq (short fract A)
- -- Runtime Function: unsigned long long fract __fractqqudq (short fract
- A)
- -- Runtime Function: unsigned short accum __fractqquha (short fract A)
- -- Runtime Function: unsigned accum __fractqqusa (short fract A)
- -- Runtime Function: unsigned long accum __fractqquda (short fract A)
- -- Runtime Function: unsigned long long accum __fractqquta (short fract
- A)
- -- Runtime Function: signed char __fractqqqi (short fract A)
- -- Runtime Function: short __fractqqhi (short fract A)
- -- Runtime Function: int __fractqqsi (short fract A)
- -- Runtime Function: long __fractqqdi (short fract A)
- -- Runtime Function: long long __fractqqti (short fract A)
- -- Runtime Function: float __fractqqsf (short fract A)
- -- Runtime Function: double __fractqqdf (short fract A)
- -- Runtime Function: short fract __fracthqqq2 (fract A)
- -- Runtime Function: long fract __fracthqsq2 (fract A)
- -- Runtime Function: long long fract __fracthqdq2 (fract A)
- -- Runtime Function: short accum __fracthqha (fract A)
- -- Runtime Function: accum __fracthqsa (fract A)
- -- Runtime Function: long accum __fracthqda (fract A)
- -- Runtime Function: long long accum __fracthqta (fract A)
- -- Runtime Function: unsigned short fract __fracthquqq (fract A)
- -- Runtime Function: unsigned fract __fracthquhq (fract A)
- -- Runtime Function: unsigned long fract __fracthqusq (fract A)
- -- Runtime Function: unsigned long long fract __fracthqudq (fract A)
- -- Runtime Function: unsigned short accum __fracthquha (fract A)
- -- Runtime Function: unsigned accum __fracthqusa (fract A)
- -- Runtime Function: unsigned long accum __fracthquda (fract A)
- -- Runtime Function: unsigned long long accum __fracthquta (fract A)
- -- Runtime Function: signed char __fracthqqi (fract A)
- -- Runtime Function: short __fracthqhi (fract A)
- -- Runtime Function: int __fracthqsi (fract A)
- -- Runtime Function: long __fracthqdi (fract A)
- -- Runtime Function: long long __fracthqti (fract A)
- -- Runtime Function: float __fracthqsf (fract A)
- -- Runtime Function: double __fracthqdf (fract A)
- -- Runtime Function: short fract __fractsqqq2 (long fract A)
- -- Runtime Function: fract __fractsqhq2 (long fract A)
- -- Runtime Function: long long fract __fractsqdq2 (long fract A)
- -- Runtime Function: short accum __fractsqha (long fract A)
- -- Runtime Function: accum __fractsqsa (long fract A)
- -- Runtime Function: long accum __fractsqda (long fract A)
- -- Runtime Function: long long accum __fractsqta (long fract A)
- -- Runtime Function: unsigned short fract __fractsquqq (long fract A)
- -- Runtime Function: unsigned fract __fractsquhq (long fract A)
- -- Runtime Function: unsigned long fract __fractsqusq (long fract A)
- -- Runtime Function: unsigned long long fract __fractsqudq (long fract
- A)
- -- Runtime Function: unsigned short accum __fractsquha (long fract A)
- -- Runtime Function: unsigned accum __fractsqusa (long fract A)
- -- Runtime Function: unsigned long accum __fractsquda (long fract A)
- -- Runtime Function: unsigned long long accum __fractsquta (long fract
- A)
- -- Runtime Function: signed char __fractsqqi (long fract A)
- -- Runtime Function: short __fractsqhi (long fract A)
- -- Runtime Function: int __fractsqsi (long fract A)
- -- Runtime Function: long __fractsqdi (long fract A)
- -- Runtime Function: long long __fractsqti (long fract A)
- -- Runtime Function: float __fractsqsf (long fract A)
- -- Runtime Function: double __fractsqdf (long fract A)
- -- Runtime Function: short fract __fractdqqq2 (long long fract A)
- -- Runtime Function: fract __fractdqhq2 (long long fract A)
- -- Runtime Function: long fract __fractdqsq2 (long long fract A)
- -- Runtime Function: short accum __fractdqha (long long fract A)
- -- Runtime Function: accum __fractdqsa (long long fract A)
- -- Runtime Function: long accum __fractdqda (long long fract A)
- -- Runtime Function: long long accum __fractdqta (long long fract A)
- -- Runtime Function: unsigned short fract __fractdquqq (long long fract
- A)
- -- Runtime Function: unsigned fract __fractdquhq (long long fract A)
- -- Runtime Function: unsigned long fract __fractdqusq (long long fract
- A)
- -- Runtime Function: unsigned long long fract __fractdqudq (long long
- fract A)
- -- Runtime Function: unsigned short accum __fractdquha (long long fract
- A)
- -- Runtime Function: unsigned accum __fractdqusa (long long fract A)
- -- Runtime Function: unsigned long accum __fractdquda (long long fract
- A)
- -- Runtime Function: unsigned long long accum __fractdquta (long long
- fract A)
- -- Runtime Function: signed char __fractdqqi (long long fract A)
- -- Runtime Function: short __fractdqhi (long long fract A)
- -- Runtime Function: int __fractdqsi (long long fract A)
- -- Runtime Function: long __fractdqdi (long long fract A)
- -- Runtime Function: long long __fractdqti (long long fract A)
- -- Runtime Function: float __fractdqsf (long long fract A)
- -- Runtime Function: double __fractdqdf (long long fract A)
- -- Runtime Function: short fract __fracthaqq (short accum A)
- -- Runtime Function: fract __fracthahq (short accum A)
- -- Runtime Function: long fract __fracthasq (short accum A)
- -- Runtime Function: long long fract __fracthadq (short accum A)
- -- Runtime Function: accum __fracthasa2 (short accum A)
- -- Runtime Function: long accum __fracthada2 (short accum A)
- -- Runtime Function: long long accum __fracthata2 (short accum A)
- -- Runtime Function: unsigned short fract __fracthauqq (short accum A)
- -- Runtime Function: unsigned fract __fracthauhq (short accum A)
- -- Runtime Function: unsigned long fract __fracthausq (short accum A)
- -- Runtime Function: unsigned long long fract __fracthaudq (short accum
- A)
- -- Runtime Function: unsigned short accum __fracthauha (short accum A)
- -- Runtime Function: unsigned accum __fracthausa (short accum A)
- -- Runtime Function: unsigned long accum __fracthauda (short accum A)
- -- Runtime Function: unsigned long long accum __fracthauta (short accum
- A)
- -- Runtime Function: signed char __fracthaqi (short accum A)
- -- Runtime Function: short __fracthahi (short accum A)
- -- Runtime Function: int __fracthasi (short accum A)
- -- Runtime Function: long __fracthadi (short accum A)
- -- Runtime Function: long long __fracthati (short accum A)
- -- Runtime Function: float __fracthasf (short accum A)
- -- Runtime Function: double __fracthadf (short accum A)
- -- Runtime Function: short fract __fractsaqq (accum A)
- -- Runtime Function: fract __fractsahq (accum A)
- -- Runtime Function: long fract __fractsasq (accum A)
- -- Runtime Function: long long fract __fractsadq (accum A)
- -- Runtime Function: short accum __fractsaha2 (accum A)
- -- Runtime Function: long accum __fractsada2 (accum A)
- -- Runtime Function: long long accum __fractsata2 (accum A)
- -- Runtime Function: unsigned short fract __fractsauqq (accum A)
- -- Runtime Function: unsigned fract __fractsauhq (accum A)
- -- Runtime Function: unsigned long fract __fractsausq (accum A)
- -- Runtime Function: unsigned long long fract __fractsaudq (accum A)
- -- Runtime Function: unsigned short accum __fractsauha (accum A)
- -- Runtime Function: unsigned accum __fractsausa (accum A)
- -- Runtime Function: unsigned long accum __fractsauda (accum A)
- -- Runtime Function: unsigned long long accum __fractsauta (accum A)
- -- Runtime Function: signed char __fractsaqi (accum A)
- -- Runtime Function: short __fractsahi (accum A)
- -- Runtime Function: int __fractsasi (accum A)
- -- Runtime Function: long __fractsadi (accum A)
- -- Runtime Function: long long __fractsati (accum A)
- -- Runtime Function: float __fractsasf (accum A)
- -- Runtime Function: double __fractsadf (accum A)
- -- Runtime Function: short fract __fractdaqq (long accum A)
- -- Runtime Function: fract __fractdahq (long accum A)
- -- Runtime Function: long fract __fractdasq (long accum A)
- -- Runtime Function: long long fract __fractdadq (long accum A)
- -- Runtime Function: short accum __fractdaha2 (long accum A)
- -- Runtime Function: accum __fractdasa2 (long accum A)
- -- Runtime Function: long long accum __fractdata2 (long accum A)
- -- Runtime Function: unsigned short fract __fractdauqq (long accum A)
- -- Runtime Function: unsigned fract __fractdauhq (long accum A)
- -- Runtime Function: unsigned long fract __fractdausq (long accum A)
- -- Runtime Function: unsigned long long fract __fractdaudq (long accum
- A)
- -- Runtime Function: unsigned short accum __fractdauha (long accum A)
- -- Runtime Function: unsigned accum __fractdausa (long accum A)
- -- Runtime Function: unsigned long accum __fractdauda (long accum A)
- -- Runtime Function: unsigned long long accum __fractdauta (long accum
- A)
- -- Runtime Function: signed char __fractdaqi (long accum A)
- -- Runtime Function: short __fractdahi (long accum A)
- -- Runtime Function: int __fractdasi (long accum A)
- -- Runtime Function: long __fractdadi (long accum A)
- -- Runtime Function: long long __fractdati (long accum A)
- -- Runtime Function: float __fractdasf (long accum A)
- -- Runtime Function: double __fractdadf (long accum A)
- -- Runtime Function: short fract __fracttaqq (long long accum A)
- -- Runtime Function: fract __fracttahq (long long accum A)
- -- Runtime Function: long fract __fracttasq (long long accum A)
- -- Runtime Function: long long fract __fracttadq (long long accum A)
- -- Runtime Function: short accum __fracttaha2 (long long accum A)
- -- Runtime Function: accum __fracttasa2 (long long accum A)
- -- Runtime Function: long accum __fracttada2 (long long accum A)
- -- Runtime Function: unsigned short fract __fracttauqq (long long accum
- A)
- -- Runtime Function: unsigned fract __fracttauhq (long long accum A)
- -- Runtime Function: unsigned long fract __fracttausq (long long accum
- A)
- -- Runtime Function: unsigned long long fract __fracttaudq (long long
- accum A)
- -- Runtime Function: unsigned short accum __fracttauha (long long accum
- A)
- -- Runtime Function: unsigned accum __fracttausa (long long accum A)
- -- Runtime Function: unsigned long accum __fracttauda (long long accum
- A)
- -- Runtime Function: unsigned long long accum __fracttauta (long long
- accum A)
- -- Runtime Function: signed char __fracttaqi (long long accum A)
- -- Runtime Function: short __fracttahi (long long accum A)
- -- Runtime Function: int __fracttasi (long long accum A)
- -- Runtime Function: long __fracttadi (long long accum A)
- -- Runtime Function: long long __fracttati (long long accum A)
- -- Runtime Function: float __fracttasf (long long accum A)
- -- Runtime Function: double __fracttadf (long long accum A)
- -- Runtime Function: short fract __fractuqqqq (unsigned short fract A)
- -- Runtime Function: fract __fractuqqhq (unsigned short fract A)
- -- Runtime Function: long fract __fractuqqsq (unsigned short fract A)
- -- Runtime Function: long long fract __fractuqqdq (unsigned short fract
- A)
- -- Runtime Function: short accum __fractuqqha (unsigned short fract A)
- -- Runtime Function: accum __fractuqqsa (unsigned short fract A)
- -- Runtime Function: long accum __fractuqqda (unsigned short fract A)
- -- Runtime Function: long long accum __fractuqqta (unsigned short fract
- A)
- -- Runtime Function: unsigned fract __fractuqquhq2 (unsigned short
- fract A)
- -- Runtime Function: unsigned long fract __fractuqqusq2 (unsigned short
- fract A)
- -- Runtime Function: unsigned long long fract __fractuqqudq2 (unsigned
- short fract A)
- -- Runtime Function: unsigned short accum __fractuqquha (unsigned short
- fract A)
- -- Runtime Function: unsigned accum __fractuqqusa (unsigned short fract
- A)
- -- Runtime Function: unsigned long accum __fractuqquda (unsigned short
- fract A)
- -- Runtime Function: unsigned long long accum __fractuqquta (unsigned
- short fract A)
- -- Runtime Function: signed char __fractuqqqi (unsigned short fract A)
- -- Runtime Function: short __fractuqqhi (unsigned short fract A)
- -- Runtime Function: int __fractuqqsi (unsigned short fract A)
- -- Runtime Function: long __fractuqqdi (unsigned short fract A)
- -- Runtime Function: long long __fractuqqti (unsigned short fract A)
- -- Runtime Function: float __fractuqqsf (unsigned short fract A)
- -- Runtime Function: double __fractuqqdf (unsigned short fract A)
- -- Runtime Function: short fract __fractuhqqq (unsigned fract A)
- -- Runtime Function: fract __fractuhqhq (unsigned fract A)
- -- Runtime Function: long fract __fractuhqsq (unsigned fract A)
- -- Runtime Function: long long fract __fractuhqdq (unsigned fract A)
- -- Runtime Function: short accum __fractuhqha (unsigned fract A)
- -- Runtime Function: accum __fractuhqsa (unsigned fract A)
- -- Runtime Function: long accum __fractuhqda (unsigned fract A)
- -- Runtime Function: long long accum __fractuhqta (unsigned fract A)
- -- Runtime Function: unsigned short fract __fractuhquqq2 (unsigned
- fract A)
- -- Runtime Function: unsigned long fract __fractuhqusq2 (unsigned fract
- A)
- -- Runtime Function: unsigned long long fract __fractuhqudq2 (unsigned
- fract A)
- -- Runtime Function: unsigned short accum __fractuhquha (unsigned fract
- A)
- -- Runtime Function: unsigned accum __fractuhqusa (unsigned fract A)
- -- Runtime Function: unsigned long accum __fractuhquda (unsigned fract
- A)
- -- Runtime Function: unsigned long long accum __fractuhquta (unsigned
- fract A)
- -- Runtime Function: signed char __fractuhqqi (unsigned fract A)
- -- Runtime Function: short __fractuhqhi (unsigned fract A)
- -- Runtime Function: int __fractuhqsi (unsigned fract A)
- -- Runtime Function: long __fractuhqdi (unsigned fract A)
- -- Runtime Function: long long __fractuhqti (unsigned fract A)
- -- Runtime Function: float __fractuhqsf (unsigned fract A)
- -- Runtime Function: double __fractuhqdf (unsigned fract A)
- -- Runtime Function: short fract __fractusqqq (unsigned long fract A)
- -- Runtime Function: fract __fractusqhq (unsigned long fract A)
- -- Runtime Function: long fract __fractusqsq (unsigned long fract A)
- -- Runtime Function: long long fract __fractusqdq (unsigned long fract
- A)
- -- Runtime Function: short accum __fractusqha (unsigned long fract A)
- -- Runtime Function: accum __fractusqsa (unsigned long fract A)
- -- Runtime Function: long accum __fractusqda (unsigned long fract A)
- -- Runtime Function: long long accum __fractusqta (unsigned long fract
- A)
- -- Runtime Function: unsigned short fract __fractusquqq2 (unsigned long
- fract A)
- -- Runtime Function: unsigned fract __fractusquhq2 (unsigned long fract
- A)
- -- Runtime Function: unsigned long long fract __fractusqudq2 (unsigned
- long fract A)
- -- Runtime Function: unsigned short accum __fractusquha (unsigned long
- fract A)
- -- Runtime Function: unsigned accum __fractusqusa (unsigned long fract
- A)
- -- Runtime Function: unsigned long accum __fractusquda (unsigned long
- fract A)
- -- Runtime Function: unsigned long long accum __fractusquta (unsigned
- long fract A)
- -- Runtime Function: signed char __fractusqqi (unsigned long fract A)
- -- Runtime Function: short __fractusqhi (unsigned long fract A)
- -- Runtime Function: int __fractusqsi (unsigned long fract A)
- -- Runtime Function: long __fractusqdi (unsigned long fract A)
- -- Runtime Function: long long __fractusqti (unsigned long fract A)
- -- Runtime Function: float __fractusqsf (unsigned long fract A)
- -- Runtime Function: double __fractusqdf (unsigned long fract A)
- -- Runtime Function: short fract __fractudqqq (unsigned long long fract
- A)
- -- Runtime Function: fract __fractudqhq (unsigned long long fract A)
- -- Runtime Function: long fract __fractudqsq (unsigned long long fract
- A)
- -- Runtime Function: long long fract __fractudqdq (unsigned long long
- fract A)
- -- Runtime Function: short accum __fractudqha (unsigned long long fract
- A)
- -- Runtime Function: accum __fractudqsa (unsigned long long fract A)
- -- Runtime Function: long accum __fractudqda (unsigned long long fract
- A)
- -- Runtime Function: long long accum __fractudqta (unsigned long long
- fract A)
- -- Runtime Function: unsigned short fract __fractudquqq2 (unsigned long
- long fract A)
- -- Runtime Function: unsigned fract __fractudquhq2 (unsigned long long
- fract A)
- -- Runtime Function: unsigned long fract __fractudqusq2 (unsigned long
- long fract A)
- -- Runtime Function: unsigned short accum __fractudquha (unsigned long
- long fract A)
- -- Runtime Function: unsigned accum __fractudqusa (unsigned long long
- fract A)
- -- Runtime Function: unsigned long accum __fractudquda (unsigned long
- long fract A)
- -- Runtime Function: unsigned long long accum __fractudquta (unsigned
- long long fract A)
- -- Runtime Function: signed char __fractudqqi (unsigned long long fract
- A)
- -- Runtime Function: short __fractudqhi (unsigned long long fract A)
- -- Runtime Function: int __fractudqsi (unsigned long long fract A)
- -- Runtime Function: long __fractudqdi (unsigned long long fract A)
- -- Runtime Function: long long __fractudqti (unsigned long long fract
- A)
- -- Runtime Function: float __fractudqsf (unsigned long long fract A)
- -- Runtime Function: double __fractudqdf (unsigned long long fract A)
- -- Runtime Function: short fract __fractuhaqq (unsigned short accum A)
- -- Runtime Function: fract __fractuhahq (unsigned short accum A)
- -- Runtime Function: long fract __fractuhasq (unsigned short accum A)
- -- Runtime Function: long long fract __fractuhadq (unsigned short accum
- A)
- -- Runtime Function: short accum __fractuhaha (unsigned short accum A)
- -- Runtime Function: accum __fractuhasa (unsigned short accum A)
- -- Runtime Function: long accum __fractuhada (unsigned short accum A)
- -- Runtime Function: long long accum __fractuhata (unsigned short accum
- A)
- -- Runtime Function: unsigned short fract __fractuhauqq (unsigned short
- accum A)
- -- Runtime Function: unsigned fract __fractuhauhq (unsigned short accum
- A)
- -- Runtime Function: unsigned long fract __fractuhausq (unsigned short
- accum A)
- -- Runtime Function: unsigned long long fract __fractuhaudq (unsigned
- short accum A)
- -- Runtime Function: unsigned accum __fractuhausa2 (unsigned short
- accum A)
- -- Runtime Function: unsigned long accum __fractuhauda2 (unsigned short
- accum A)
- -- Runtime Function: unsigned long long accum __fractuhauta2 (unsigned
- short accum A)
- -- Runtime Function: signed char __fractuhaqi (unsigned short accum A)
- -- Runtime Function: short __fractuhahi (unsigned short accum A)
- -- Runtime Function: int __fractuhasi (unsigned short accum A)
- -- Runtime Function: long __fractuhadi (unsigned short accum A)
- -- Runtime Function: long long __fractuhati (unsigned short accum A)
- -- Runtime Function: float __fractuhasf (unsigned short accum A)
- -- Runtime Function: double __fractuhadf (unsigned short accum A)
- -- Runtime Function: short fract __fractusaqq (unsigned accum A)
- -- Runtime Function: fract __fractusahq (unsigned accum A)
- -- Runtime Function: long fract __fractusasq (unsigned accum A)
- -- Runtime Function: long long fract __fractusadq (unsigned accum A)
- -- Runtime Function: short accum __fractusaha (unsigned accum A)
- -- Runtime Function: accum __fractusasa (unsigned accum A)
- -- Runtime Function: long accum __fractusada (unsigned accum A)
- -- Runtime Function: long long accum __fractusata (unsigned accum A)
- -- Runtime Function: unsigned short fract __fractusauqq (unsigned accum
- A)
- -- Runtime Function: unsigned fract __fractusauhq (unsigned accum A)
- -- Runtime Function: unsigned long fract __fractusausq (unsigned accum
- A)
- -- Runtime Function: unsigned long long fract __fractusaudq (unsigned
- accum A)
- -- Runtime Function: unsigned short accum __fractusauha2 (unsigned
- accum A)
- -- Runtime Function: unsigned long accum __fractusauda2 (unsigned accum
- A)
- -- Runtime Function: unsigned long long accum __fractusauta2 (unsigned
- accum A)
- -- Runtime Function: signed char __fractusaqi (unsigned accum A)
- -- Runtime Function: short __fractusahi (unsigned accum A)
- -- Runtime Function: int __fractusasi (unsigned accum A)
- -- Runtime Function: long __fractusadi (unsigned accum A)
- -- Runtime Function: long long __fractusati (unsigned accum A)
- -- Runtime Function: float __fractusasf (unsigned accum A)
- -- Runtime Function: double __fractusadf (unsigned accum A)
- -- Runtime Function: short fract __fractudaqq (unsigned long accum A)
- -- Runtime Function: fract __fractudahq (unsigned long accum A)
- -- Runtime Function: long fract __fractudasq (unsigned long accum A)
- -- Runtime Function: long long fract __fractudadq (unsigned long accum
- A)
- -- Runtime Function: short accum __fractudaha (unsigned long accum A)
- -- Runtime Function: accum __fractudasa (unsigned long accum A)
- -- Runtime Function: long accum __fractudada (unsigned long accum A)
- -- Runtime Function: long long accum __fractudata (unsigned long accum
- A)
- -- Runtime Function: unsigned short fract __fractudauqq (unsigned long
- accum A)
- -- Runtime Function: unsigned fract __fractudauhq (unsigned long accum
- A)
- -- Runtime Function: unsigned long fract __fractudausq (unsigned long
- accum A)
- -- Runtime Function: unsigned long long fract __fractudaudq (unsigned
- long accum A)
- -- Runtime Function: unsigned short accum __fractudauha2 (unsigned long
- accum A)
- -- Runtime Function: unsigned accum __fractudausa2 (unsigned long accum
- A)
- -- Runtime Function: unsigned long long accum __fractudauta2 (unsigned
- long accum A)
- -- Runtime Function: signed char __fractudaqi (unsigned long accum A)
- -- Runtime Function: short __fractudahi (unsigned long accum A)
- -- Runtime Function: int __fractudasi (unsigned long accum A)
- -- Runtime Function: long __fractudadi (unsigned long accum A)
- -- Runtime Function: long long __fractudati (unsigned long accum A)
- -- Runtime Function: float __fractudasf (unsigned long accum A)
- -- Runtime Function: double __fractudadf (unsigned long accum A)
- -- Runtime Function: short fract __fractutaqq (unsigned long long accum
- A)
- -- Runtime Function: fract __fractutahq (unsigned long long accum A)
- -- Runtime Function: long fract __fractutasq (unsigned long long accum
- A)
- -- Runtime Function: long long fract __fractutadq (unsigned long long
- accum A)
- -- Runtime Function: short accum __fractutaha (unsigned long long accum
- A)
- -- Runtime Function: accum __fractutasa (unsigned long long accum A)
- -- Runtime Function: long accum __fractutada (unsigned long long accum
- A)
- -- Runtime Function: long long accum __fractutata (unsigned long long
- accum A)
- -- Runtime Function: unsigned short fract __fractutauqq (unsigned long
- long accum A)
- -- Runtime Function: unsigned fract __fractutauhq (unsigned long long
- accum A)
- -- Runtime Function: unsigned long fract __fractutausq (unsigned long
- long accum A)
- -- Runtime Function: unsigned long long fract __fractutaudq (unsigned
- long long accum A)
- -- Runtime Function: unsigned short accum __fractutauha2 (unsigned long
- long accum A)
- -- Runtime Function: unsigned accum __fractutausa2 (unsigned long long
- accum A)
- -- Runtime Function: unsigned long accum __fractutauda2 (unsigned long
- long accum A)
- -- Runtime Function: signed char __fractutaqi (unsigned long long accum
- A)
- -- Runtime Function: short __fractutahi (unsigned long long accum A)
- -- Runtime Function: int __fractutasi (unsigned long long accum A)
- -- Runtime Function: long __fractutadi (unsigned long long accum A)
- -- Runtime Function: long long __fractutati (unsigned long long accum
- A)
- -- Runtime Function: float __fractutasf (unsigned long long accum A)
- -- Runtime Function: double __fractutadf (unsigned long long accum A)
- -- Runtime Function: short fract __fractqiqq (signed char A)
- -- Runtime Function: fract __fractqihq (signed char A)
- -- Runtime Function: long fract __fractqisq (signed char A)
- -- Runtime Function: long long fract __fractqidq (signed char A)
- -- Runtime Function: short accum __fractqiha (signed char A)
- -- Runtime Function: accum __fractqisa (signed char A)
- -- Runtime Function: long accum __fractqida (signed char A)
- -- Runtime Function: long long accum __fractqita (signed char A)
- -- Runtime Function: unsigned short fract __fractqiuqq (signed char A)
- -- Runtime Function: unsigned fract __fractqiuhq (signed char A)
- -- Runtime Function: unsigned long fract __fractqiusq (signed char A)
- -- Runtime Function: unsigned long long fract __fractqiudq (signed char
- A)
- -- Runtime Function: unsigned short accum __fractqiuha (signed char A)
- -- Runtime Function: unsigned accum __fractqiusa (signed char A)
- -- Runtime Function: unsigned long accum __fractqiuda (signed char A)
- -- Runtime Function: unsigned long long accum __fractqiuta (signed char
- A)
- -- Runtime Function: short fract __fracthiqq (short A)
- -- Runtime Function: fract __fracthihq (short A)
- -- Runtime Function: long fract __fracthisq (short A)
- -- Runtime Function: long long fract __fracthidq (short A)
- -- Runtime Function: short accum __fracthiha (short A)
- -- Runtime Function: accum __fracthisa (short A)
- -- Runtime Function: long accum __fracthida (short A)
- -- Runtime Function: long long accum __fracthita (short A)
- -- Runtime Function: unsigned short fract __fracthiuqq (short A)
- -- Runtime Function: unsigned fract __fracthiuhq (short A)
- -- Runtime Function: unsigned long fract __fracthiusq (short A)
- -- Runtime Function: unsigned long long fract __fracthiudq (short A)
- -- Runtime Function: unsigned short accum __fracthiuha (short A)
- -- Runtime Function: unsigned accum __fracthiusa (short A)
- -- Runtime Function: unsigned long accum __fracthiuda (short A)
- -- Runtime Function: unsigned long long accum __fracthiuta (short A)
- -- Runtime Function: short fract __fractsiqq (int A)
- -- Runtime Function: fract __fractsihq (int A)
- -- Runtime Function: long fract __fractsisq (int A)
- -- Runtime Function: long long fract __fractsidq (int A)
- -- Runtime Function: short accum __fractsiha (int A)
- -- Runtime Function: accum __fractsisa (int A)
- -- Runtime Function: long accum __fractsida (int A)
- -- Runtime Function: long long accum __fractsita (int A)
- -- Runtime Function: unsigned short fract __fractsiuqq (int A)
- -- Runtime Function: unsigned fract __fractsiuhq (int A)
- -- Runtime Function: unsigned long fract __fractsiusq (int A)
- -- Runtime Function: unsigned long long fract __fractsiudq (int A)
- -- Runtime Function: unsigned short accum __fractsiuha (int A)
- -- Runtime Function: unsigned accum __fractsiusa (int A)
- -- Runtime Function: unsigned long accum __fractsiuda (int A)
- -- Runtime Function: unsigned long long accum __fractsiuta (int A)
- -- Runtime Function: short fract __fractdiqq (long A)
- -- Runtime Function: fract __fractdihq (long A)
- -- Runtime Function: long fract __fractdisq (long A)
- -- Runtime Function: long long fract __fractdidq (long A)
- -- Runtime Function: short accum __fractdiha (long A)
- -- Runtime Function: accum __fractdisa (long A)
- -- Runtime Function: long accum __fractdida (long A)
- -- Runtime Function: long long accum __fractdita (long A)
- -- Runtime Function: unsigned short fract __fractdiuqq (long A)
- -- Runtime Function: unsigned fract __fractdiuhq (long A)
- -- Runtime Function: unsigned long fract __fractdiusq (long A)
- -- Runtime Function: unsigned long long fract __fractdiudq (long A)
- -- Runtime Function: unsigned short accum __fractdiuha (long A)
- -- Runtime Function: unsigned accum __fractdiusa (long A)
- -- Runtime Function: unsigned long accum __fractdiuda (long A)
- -- Runtime Function: unsigned long long accum __fractdiuta (long A)
- -- Runtime Function: short fract __fracttiqq (long long A)
- -- Runtime Function: fract __fracttihq (long long A)
- -- Runtime Function: long fract __fracttisq (long long A)
- -- Runtime Function: long long fract __fracttidq (long long A)
- -- Runtime Function: short accum __fracttiha (long long A)
- -- Runtime Function: accum __fracttisa (long long A)
- -- Runtime Function: long accum __fracttida (long long A)
- -- Runtime Function: long long accum __fracttita (long long A)
- -- Runtime Function: unsigned short fract __fracttiuqq (long long A)
- -- Runtime Function: unsigned fract __fracttiuhq (long long A)
- -- Runtime Function: unsigned long fract __fracttiusq (long long A)
- -- Runtime Function: unsigned long long fract __fracttiudq (long long
- A)
- -- Runtime Function: unsigned short accum __fracttiuha (long long A)
- -- Runtime Function: unsigned accum __fracttiusa (long long A)
- -- Runtime Function: unsigned long accum __fracttiuda (long long A)
- -- Runtime Function: unsigned long long accum __fracttiuta (long long
- A)
- -- Runtime Function: short fract __fractsfqq (float A)
- -- Runtime Function: fract __fractsfhq (float A)
- -- Runtime Function: long fract __fractsfsq (float A)
- -- Runtime Function: long long fract __fractsfdq (float A)
- -- Runtime Function: short accum __fractsfha (float A)
- -- Runtime Function: accum __fractsfsa (float A)
- -- Runtime Function: long accum __fractsfda (float A)
- -- Runtime Function: long long accum __fractsfta (float A)
- -- Runtime Function: unsigned short fract __fractsfuqq (float A)
- -- Runtime Function: unsigned fract __fractsfuhq (float A)
- -- Runtime Function: unsigned long fract __fractsfusq (float A)
- -- Runtime Function: unsigned long long fract __fractsfudq (float A)
- -- Runtime Function: unsigned short accum __fractsfuha (float A)
- -- Runtime Function: unsigned accum __fractsfusa (float A)
- -- Runtime Function: unsigned long accum __fractsfuda (float A)
- -- Runtime Function: unsigned long long accum __fractsfuta (float A)
- -- Runtime Function: short fract __fractdfqq (double A)
- -- Runtime Function: fract __fractdfhq (double A)
- -- Runtime Function: long fract __fractdfsq (double A)
- -- Runtime Function: long long fract __fractdfdq (double A)
- -- Runtime Function: short accum __fractdfha (double A)
- -- Runtime Function: accum __fractdfsa (double A)
- -- Runtime Function: long accum __fractdfda (double A)
- -- Runtime Function: long long accum __fractdfta (double A)
- -- Runtime Function: unsigned short fract __fractdfuqq (double A)
- -- Runtime Function: unsigned fract __fractdfuhq (double A)
- -- Runtime Function: unsigned long fract __fractdfusq (double A)
- -- Runtime Function: unsigned long long fract __fractdfudq (double A)
- -- Runtime Function: unsigned short accum __fractdfuha (double A)
- -- Runtime Function: unsigned accum __fractdfusa (double A)
- -- Runtime Function: unsigned long accum __fractdfuda (double A)
- -- Runtime Function: unsigned long long accum __fractdfuta (double A)
- These functions convert from fractional and signed non-fractionals
- to fractionals and signed non-fractionals, without saturation.
-
- -- Runtime Function: fract __satfractqqhq2 (short fract A)
- -- Runtime Function: long fract __satfractqqsq2 (short fract A)
- -- Runtime Function: long long fract __satfractqqdq2 (short fract A)
- -- Runtime Function: short accum __satfractqqha (short fract A)
- -- Runtime Function: accum __satfractqqsa (short fract A)
- -- Runtime Function: long accum __satfractqqda (short fract A)
- -- Runtime Function: long long accum __satfractqqta (short fract A)
- -- Runtime Function: unsigned short fract __satfractqquqq (short fract
- A)
- -- Runtime Function: unsigned fract __satfractqquhq (short fract A)
- -- Runtime Function: unsigned long fract __satfractqqusq (short fract
- A)
- -- Runtime Function: unsigned long long fract __satfractqqudq (short
- fract A)
- -- Runtime Function: unsigned short accum __satfractqquha (short fract
- A)
- -- Runtime Function: unsigned accum __satfractqqusa (short fract A)
- -- Runtime Function: unsigned long accum __satfractqquda (short fract
- A)
- -- Runtime Function: unsigned long long accum __satfractqquta (short
- fract A)
- -- Runtime Function: short fract __satfracthqqq2 (fract A)
- -- Runtime Function: long fract __satfracthqsq2 (fract A)
- -- Runtime Function: long long fract __satfracthqdq2 (fract A)
- -- Runtime Function: short accum __satfracthqha (fract A)
- -- Runtime Function: accum __satfracthqsa (fract A)
- -- Runtime Function: long accum __satfracthqda (fract A)
- -- Runtime Function: long long accum __satfracthqta (fract A)
- -- Runtime Function: unsigned short fract __satfracthquqq (fract A)
- -- Runtime Function: unsigned fract __satfracthquhq (fract A)
- -- Runtime Function: unsigned long fract __satfracthqusq (fract A)
- -- Runtime Function: unsigned long long fract __satfracthqudq (fract A)
- -- Runtime Function: unsigned short accum __satfracthquha (fract A)
- -- Runtime Function: unsigned accum __satfracthqusa (fract A)
- -- Runtime Function: unsigned long accum __satfracthquda (fract A)
- -- Runtime Function: unsigned long long accum __satfracthquta (fract A)
- -- Runtime Function: short fract __satfractsqqq2 (long fract A)
- -- Runtime Function: fract __satfractsqhq2 (long fract A)
- -- Runtime Function: long long fract __satfractsqdq2 (long fract A)
- -- Runtime Function: short accum __satfractsqha (long fract A)
- -- Runtime Function: accum __satfractsqsa (long fract A)
- -- Runtime Function: long accum __satfractsqda (long fract A)
- -- Runtime Function: long long accum __satfractsqta (long fract A)
- -- Runtime Function: unsigned short fract __satfractsquqq (long fract
- A)
- -- Runtime Function: unsigned fract __satfractsquhq (long fract A)
- -- Runtime Function: unsigned long fract __satfractsqusq (long fract A)
- -- Runtime Function: unsigned long long fract __satfractsqudq (long
- fract A)
- -- Runtime Function: unsigned short accum __satfractsquha (long fract
- A)
- -- Runtime Function: unsigned accum __satfractsqusa (long fract A)
- -- Runtime Function: unsigned long accum __satfractsquda (long fract A)
- -- Runtime Function: unsigned long long accum __satfractsquta (long
- fract A)
- -- Runtime Function: short fract __satfractdqqq2 (long long fract A)
- -- Runtime Function: fract __satfractdqhq2 (long long fract A)
- -- Runtime Function: long fract __satfractdqsq2 (long long fract A)
- -- Runtime Function: short accum __satfractdqha (long long fract A)
- -- Runtime Function: accum __satfractdqsa (long long fract A)
- -- Runtime Function: long accum __satfractdqda (long long fract A)
- -- Runtime Function: long long accum __satfractdqta (long long fract A)
- -- Runtime Function: unsigned short fract __satfractdquqq (long long
- fract A)
- -- Runtime Function: unsigned fract __satfractdquhq (long long fract A)
- -- Runtime Function: unsigned long fract __satfractdqusq (long long
- fract A)
- -- Runtime Function: unsigned long long fract __satfractdqudq (long
- long fract A)
- -- Runtime Function: unsigned short accum __satfractdquha (long long
- fract A)
- -- Runtime Function: unsigned accum __satfractdqusa (long long fract A)
- -- Runtime Function: unsigned long accum __satfractdquda (long long
- fract A)
- -- Runtime Function: unsigned long long accum __satfractdquta (long
- long fract A)
- -- Runtime Function: short fract __satfracthaqq (short accum A)
- -- Runtime Function: fract __satfracthahq (short accum A)
- -- Runtime Function: long fract __satfracthasq (short accum A)
- -- Runtime Function: long long fract __satfracthadq (short accum A)
- -- Runtime Function: accum __satfracthasa2 (short accum A)
- -- Runtime Function: long accum __satfracthada2 (short accum A)
- -- Runtime Function: long long accum __satfracthata2 (short accum A)
- -- Runtime Function: unsigned short fract __satfracthauqq (short accum
- A)
- -- Runtime Function: unsigned fract __satfracthauhq (short accum A)
- -- Runtime Function: unsigned long fract __satfracthausq (short accum
- A)
- -- Runtime Function: unsigned long long fract __satfracthaudq (short
- accum A)
- -- Runtime Function: unsigned short accum __satfracthauha (short accum
- A)
- -- Runtime Function: unsigned accum __satfracthausa (short accum A)
- -- Runtime Function: unsigned long accum __satfracthauda (short accum
- A)
- -- Runtime Function: unsigned long long accum __satfracthauta (short
- accum A)
- -- Runtime Function: short fract __satfractsaqq (accum A)
- -- Runtime Function: fract __satfractsahq (accum A)
- -- Runtime Function: long fract __satfractsasq (accum A)
- -- Runtime Function: long long fract __satfractsadq (accum A)
- -- Runtime Function: short accum __satfractsaha2 (accum A)
- -- Runtime Function: long accum __satfractsada2 (accum A)
- -- Runtime Function: long long accum __satfractsata2 (accum A)
- -- Runtime Function: unsigned short fract __satfractsauqq (accum A)
- -- Runtime Function: unsigned fract __satfractsauhq (accum A)
- -- Runtime Function: unsigned long fract __satfractsausq (accum A)
- -- Runtime Function: unsigned long long fract __satfractsaudq (accum A)
- -- Runtime Function: unsigned short accum __satfractsauha (accum A)
- -- Runtime Function: unsigned accum __satfractsausa (accum A)
- -- Runtime Function: unsigned long accum __satfractsauda (accum A)
- -- Runtime Function: unsigned long long accum __satfractsauta (accum A)
- -- Runtime Function: short fract __satfractdaqq (long accum A)
- -- Runtime Function: fract __satfractdahq (long accum A)
- -- Runtime Function: long fract __satfractdasq (long accum A)
- -- Runtime Function: long long fract __satfractdadq (long accum A)
- -- Runtime Function: short accum __satfractdaha2 (long accum A)
- -- Runtime Function: accum __satfractdasa2 (long accum A)
- -- Runtime Function: long long accum __satfractdata2 (long accum A)
- -- Runtime Function: unsigned short fract __satfractdauqq (long accum
- A)
- -- Runtime Function: unsigned fract __satfractdauhq (long accum A)
- -- Runtime Function: unsigned long fract __satfractdausq (long accum A)
- -- Runtime Function: unsigned long long fract __satfractdaudq (long
- accum A)
- -- Runtime Function: unsigned short accum __satfractdauha (long accum
- A)
- -- Runtime Function: unsigned accum __satfractdausa (long accum A)
- -- Runtime Function: unsigned long accum __satfractdauda (long accum A)
- -- Runtime Function: unsigned long long accum __satfractdauta (long
- accum A)
- -- Runtime Function: short fract __satfracttaqq (long long accum A)
- -- Runtime Function: fract __satfracttahq (long long accum A)
- -- Runtime Function: long fract __satfracttasq (long long accum A)
- -- Runtime Function: long long fract __satfracttadq (long long accum A)
- -- Runtime Function: short accum __satfracttaha2 (long long accum A)
- -- Runtime Function: accum __satfracttasa2 (long long accum A)
- -- Runtime Function: long accum __satfracttada2 (long long accum A)
- -- Runtime Function: unsigned short fract __satfracttauqq (long long
- accum A)
- -- Runtime Function: unsigned fract __satfracttauhq (long long accum A)
- -- Runtime Function: unsigned long fract __satfracttausq (long long
- accum A)
- -- Runtime Function: unsigned long long fract __satfracttaudq (long
- long accum A)
- -- Runtime Function: unsigned short accum __satfracttauha (long long
- accum A)
- -- Runtime Function: unsigned accum __satfracttausa (long long accum A)
- -- Runtime Function: unsigned long accum __satfracttauda (long long
- accum A)
- -- Runtime Function: unsigned long long accum __satfracttauta (long
- long accum A)
- -- Runtime Function: short fract __satfractuqqqq (unsigned short fract
- A)
- -- Runtime Function: fract __satfractuqqhq (unsigned short fract A)
- -- Runtime Function: long fract __satfractuqqsq (unsigned short fract
- A)
- -- Runtime Function: long long fract __satfractuqqdq (unsigned short
- fract A)
- -- Runtime Function: short accum __satfractuqqha (unsigned short fract
- A)
- -- Runtime Function: accum __satfractuqqsa (unsigned short fract A)
- -- Runtime Function: long accum __satfractuqqda (unsigned short fract
- A)
- -- Runtime Function: long long accum __satfractuqqta (unsigned short
- fract A)
- -- Runtime Function: unsigned fract __satfractuqquhq2 (unsigned short
- fract A)
- -- Runtime Function: unsigned long fract __satfractuqqusq2 (unsigned
- short fract A)
- -- Runtime Function: unsigned long long fract __satfractuqqudq2
- (unsigned short fract A)
- -- Runtime Function: unsigned short accum __satfractuqquha (unsigned
- short fract A)
- -- Runtime Function: unsigned accum __satfractuqqusa (unsigned short
- fract A)
- -- Runtime Function: unsigned long accum __satfractuqquda (unsigned
- short fract A)
- -- Runtime Function: unsigned long long accum __satfractuqquta
- (unsigned short fract A)
- -- Runtime Function: short fract __satfractuhqqq (unsigned fract A)
- -- Runtime Function: fract __satfractuhqhq (unsigned fract A)
- -- Runtime Function: long fract __satfractuhqsq (unsigned fract A)
- -- Runtime Function: long long fract __satfractuhqdq (unsigned fract A)
- -- Runtime Function: short accum __satfractuhqha (unsigned fract A)
- -- Runtime Function: accum __satfractuhqsa (unsigned fract A)
- -- Runtime Function: long accum __satfractuhqda (unsigned fract A)
- -- Runtime Function: long long accum __satfractuhqta (unsigned fract A)
- -- Runtime Function: unsigned short fract __satfractuhquqq2 (unsigned
- fract A)
- -- Runtime Function: unsigned long fract __satfractuhqusq2 (unsigned
- fract A)
- -- Runtime Function: unsigned long long fract __satfractuhqudq2
- (unsigned fract A)
- -- Runtime Function: unsigned short accum __satfractuhquha (unsigned
- fract A)
- -- Runtime Function: unsigned accum __satfractuhqusa (unsigned fract A)
- -- Runtime Function: unsigned long accum __satfractuhquda (unsigned
- fract A)
- -- Runtime Function: unsigned long long accum __satfractuhquta
- (unsigned fract A)
- -- Runtime Function: short fract __satfractusqqq (unsigned long fract
- A)
- -- Runtime Function: fract __satfractusqhq (unsigned long fract A)
- -- Runtime Function: long fract __satfractusqsq (unsigned long fract A)
- -- Runtime Function: long long fract __satfractusqdq (unsigned long
- fract A)
- -- Runtime Function: short accum __satfractusqha (unsigned long fract
- A)
- -- Runtime Function: accum __satfractusqsa (unsigned long fract A)
- -- Runtime Function: long accum __satfractusqda (unsigned long fract A)
- -- Runtime Function: long long accum __satfractusqta (unsigned long
- fract A)
- -- Runtime Function: unsigned short fract __satfractusquqq2 (unsigned
- long fract A)
- -- Runtime Function: unsigned fract __satfractusquhq2 (unsigned long
- fract A)
- -- Runtime Function: unsigned long long fract __satfractusqudq2
- (unsigned long fract A)
- -- Runtime Function: unsigned short accum __satfractusquha (unsigned
- long fract A)
- -- Runtime Function: unsigned accum __satfractusqusa (unsigned long
- fract A)
- -- Runtime Function: unsigned long accum __satfractusquda (unsigned
- long fract A)
- -- Runtime Function: unsigned long long accum __satfractusquta
- (unsigned long fract A)
- -- Runtime Function: short fract __satfractudqqq (unsigned long long
- fract A)
- -- Runtime Function: fract __satfractudqhq (unsigned long long fract A)
- -- Runtime Function: long fract __satfractudqsq (unsigned long long
- fract A)
- -- Runtime Function: long long fract __satfractudqdq (unsigned long
- long fract A)
- -- Runtime Function: short accum __satfractudqha (unsigned long long
- fract A)
- -- Runtime Function: accum __satfractudqsa (unsigned long long fract A)
- -- Runtime Function: long accum __satfractudqda (unsigned long long
- fract A)
- -- Runtime Function: long long accum __satfractudqta (unsigned long
- long fract A)
- -- Runtime Function: unsigned short fract __satfractudquqq2 (unsigned
- long long fract A)
- -- Runtime Function: unsigned fract __satfractudquhq2 (unsigned long
- long fract A)
- -- Runtime Function: unsigned long fract __satfractudqusq2 (unsigned
- long long fract A)
- -- Runtime Function: unsigned short accum __satfractudquha (unsigned
- long long fract A)
- -- Runtime Function: unsigned accum __satfractudqusa (unsigned long
- long fract A)
- -- Runtime Function: unsigned long accum __satfractudquda (unsigned
- long long fract A)
- -- Runtime Function: unsigned long long accum __satfractudquta
- (unsigned long long fract A)
- -- Runtime Function: short fract __satfractuhaqq (unsigned short accum
- A)
- -- Runtime Function: fract __satfractuhahq (unsigned short accum A)
- -- Runtime Function: long fract __satfractuhasq (unsigned short accum
- A)
- -- Runtime Function: long long fract __satfractuhadq (unsigned short
- accum A)
- -- Runtime Function: short accum __satfractuhaha (unsigned short accum
- A)
- -- Runtime Function: accum __satfractuhasa (unsigned short accum A)
- -- Runtime Function: long accum __satfractuhada (unsigned short accum
- A)
- -- Runtime Function: long long accum __satfractuhata (unsigned short
- accum A)
- -- Runtime Function: unsigned short fract __satfractuhauqq (unsigned
- short accum A)
- -- Runtime Function: unsigned fract __satfractuhauhq (unsigned short
- accum A)
- -- Runtime Function: unsigned long fract __satfractuhausq (unsigned
- short accum A)
- -- Runtime Function: unsigned long long fract __satfractuhaudq
- (unsigned short accum A)
- -- Runtime Function: unsigned accum __satfractuhausa2 (unsigned short
- accum A)
- -- Runtime Function: unsigned long accum __satfractuhauda2 (unsigned
- short accum A)
- -- Runtime Function: unsigned long long accum __satfractuhauta2
- (unsigned short accum A)
- -- Runtime Function: short fract __satfractusaqq (unsigned accum A)
- -- Runtime Function: fract __satfractusahq (unsigned accum A)
- -- Runtime Function: long fract __satfractusasq (unsigned accum A)
- -- Runtime Function: long long fract __satfractusadq (unsigned accum A)
- -- Runtime Function: short accum __satfractusaha (unsigned accum A)
- -- Runtime Function: accum __satfractusasa (unsigned accum A)
- -- Runtime Function: long accum __satfractusada (unsigned accum A)
- -- Runtime Function: long long accum __satfractusata (unsigned accum A)
- -- Runtime Function: unsigned short fract __satfractusauqq (unsigned
- accum A)
- -- Runtime Function: unsigned fract __satfractusauhq (unsigned accum A)
- -- Runtime Function: unsigned long fract __satfractusausq (unsigned
- accum A)
- -- Runtime Function: unsigned long long fract __satfractusaudq
- (unsigned accum A)
- -- Runtime Function: unsigned short accum __satfractusauha2 (unsigned
- accum A)
- -- Runtime Function: unsigned long accum __satfractusauda2 (unsigned
- accum A)
- -- Runtime Function: unsigned long long accum __satfractusauta2
- (unsigned accum A)
- -- Runtime Function: short fract __satfractudaqq (unsigned long accum
- A)
- -- Runtime Function: fract __satfractudahq (unsigned long accum A)
- -- Runtime Function: long fract __satfractudasq (unsigned long accum A)
- -- Runtime Function: long long fract __satfractudadq (unsigned long
- accum A)
- -- Runtime Function: short accum __satfractudaha (unsigned long accum
- A)
- -- Runtime Function: accum __satfractudasa (unsigned long accum A)
- -- Runtime Function: long accum __satfractudada (unsigned long accum A)
- -- Runtime Function: long long accum __satfractudata (unsigned long
- accum A)
- -- Runtime Function: unsigned short fract __satfractudauqq (unsigned
- long accum A)
- -- Runtime Function: unsigned fract __satfractudauhq (unsigned long
- accum A)
- -- Runtime Function: unsigned long fract __satfractudausq (unsigned
- long accum A)
- -- Runtime Function: unsigned long long fract __satfractudaudq
- (unsigned long accum A)
- -- Runtime Function: unsigned short accum __satfractudauha2 (unsigned
- long accum A)
- -- Runtime Function: unsigned accum __satfractudausa2 (unsigned long
- accum A)
- -- Runtime Function: unsigned long long accum __satfractudauta2
- (unsigned long accum A)
- -- Runtime Function: short fract __satfractutaqq (unsigned long long
- accum A)
- -- Runtime Function: fract __satfractutahq (unsigned long long accum A)
- -- Runtime Function: long fract __satfractutasq (unsigned long long
- accum A)
- -- Runtime Function: long long fract __satfractutadq (unsigned long
- long accum A)
- -- Runtime Function: short accum __satfractutaha (unsigned long long
- accum A)
- -- Runtime Function: accum __satfractutasa (unsigned long long accum A)
- -- Runtime Function: long accum __satfractutada (unsigned long long
- accum A)
- -- Runtime Function: long long accum __satfractutata (unsigned long
- long accum A)
- -- Runtime Function: unsigned short fract __satfractutauqq (unsigned
- long long accum A)
- -- Runtime Function: unsigned fract __satfractutauhq (unsigned long
- long accum A)
- -- Runtime Function: unsigned long fract __satfractutausq (unsigned
- long long accum A)
- -- Runtime Function: unsigned long long fract __satfractutaudq
- (unsigned long long accum A)
- -- Runtime Function: unsigned short accum __satfractutauha2 (unsigned
- long long accum A)
- -- Runtime Function: unsigned accum __satfractutausa2 (unsigned long
- long accum A)
- -- Runtime Function: unsigned long accum __satfractutauda2 (unsigned
- long long accum A)
- -- Runtime Function: short fract __satfractqiqq (signed char A)
- -- Runtime Function: fract __satfractqihq (signed char A)
- -- Runtime Function: long fract __satfractqisq (signed char A)
- -- Runtime Function: long long fract __satfractqidq (signed char A)
- -- Runtime Function: short accum __satfractqiha (signed char A)
- -- Runtime Function: accum __satfractqisa (signed char A)
- -- Runtime Function: long accum __satfractqida (signed char A)
- -- Runtime Function: long long accum __satfractqita (signed char A)
- -- Runtime Function: unsigned short fract __satfractqiuqq (signed char
- A)
- -- Runtime Function: unsigned fract __satfractqiuhq (signed char A)
- -- Runtime Function: unsigned long fract __satfractqiusq (signed char
- A)
- -- Runtime Function: unsigned long long fract __satfractqiudq (signed
- char A)
- -- Runtime Function: unsigned short accum __satfractqiuha (signed char
- A)
- -- Runtime Function: unsigned accum __satfractqiusa (signed char A)
- -- Runtime Function: unsigned long accum __satfractqiuda (signed char
- A)
- -- Runtime Function: unsigned long long accum __satfractqiuta (signed
- char A)
- -- Runtime Function: short fract __satfracthiqq (short A)
- -- Runtime Function: fract __satfracthihq (short A)
- -- Runtime Function: long fract __satfracthisq (short A)
- -- Runtime Function: long long fract __satfracthidq (short A)
- -- Runtime Function: short accum __satfracthiha (short A)
- -- Runtime Function: accum __satfracthisa (short A)
- -- Runtime Function: long accum __satfracthida (short A)
- -- Runtime Function: long long accum __satfracthita (short A)
- -- Runtime Function: unsigned short fract __satfracthiuqq (short A)
- -- Runtime Function: unsigned fract __satfracthiuhq (short A)
- -- Runtime Function: unsigned long fract __satfracthiusq (short A)
- -- Runtime Function: unsigned long long fract __satfracthiudq (short A)
- -- Runtime Function: unsigned short accum __satfracthiuha (short A)
- -- Runtime Function: unsigned accum __satfracthiusa (short A)
- -- Runtime Function: unsigned long accum __satfracthiuda (short A)
- -- Runtime Function: unsigned long long accum __satfracthiuta (short A)
- -- Runtime Function: short fract __satfractsiqq (int A)
- -- Runtime Function: fract __satfractsihq (int A)
- -- Runtime Function: long fract __satfractsisq (int A)
- -- Runtime Function: long long fract __satfractsidq (int A)
- -- Runtime Function: short accum __satfractsiha (int A)
- -- Runtime Function: accum __satfractsisa (int A)
- -- Runtime Function: long accum __satfractsida (int A)
- -- Runtime Function: long long accum __satfractsita (int A)
- -- Runtime Function: unsigned short fract __satfractsiuqq (int A)
- -- Runtime Function: unsigned fract __satfractsiuhq (int A)
- -- Runtime Function: unsigned long fract __satfractsiusq (int A)
- -- Runtime Function: unsigned long long fract __satfractsiudq (int A)
- -- Runtime Function: unsigned short accum __satfractsiuha (int A)
- -- Runtime Function: unsigned accum __satfractsiusa (int A)
- -- Runtime Function: unsigned long accum __satfractsiuda (int A)
- -- Runtime Function: unsigned long long accum __satfractsiuta (int A)
- -- Runtime Function: short fract __satfractdiqq (long A)
- -- Runtime Function: fract __satfractdihq (long A)
- -- Runtime Function: long fract __satfractdisq (long A)
- -- Runtime Function: long long fract __satfractdidq (long A)
- -- Runtime Function: short accum __satfractdiha (long A)
- -- Runtime Function: accum __satfractdisa (long A)
- -- Runtime Function: long accum __satfractdida (long A)
- -- Runtime Function: long long accum __satfractdita (long A)
- -- Runtime Function: unsigned short fract __satfractdiuqq (long A)
- -- Runtime Function: unsigned fract __satfractdiuhq (long A)
- -- Runtime Function: unsigned long fract __satfractdiusq (long A)
- -- Runtime Function: unsigned long long fract __satfractdiudq (long A)
- -- Runtime Function: unsigned short accum __satfractdiuha (long A)
- -- Runtime Function: unsigned accum __satfractdiusa (long A)
- -- Runtime Function: unsigned long accum __satfractdiuda (long A)
- -- Runtime Function: unsigned long long accum __satfractdiuta (long A)
- -- Runtime Function: short fract __satfracttiqq (long long A)
- -- Runtime Function: fract __satfracttihq (long long A)
- -- Runtime Function: long fract __satfracttisq (long long A)
- -- Runtime Function: long long fract __satfracttidq (long long A)
- -- Runtime Function: short accum __satfracttiha (long long A)
- -- Runtime Function: accum __satfracttisa (long long A)
- -- Runtime Function: long accum __satfracttida (long long A)
- -- Runtime Function: long long accum __satfracttita (long long A)
- -- Runtime Function: unsigned short fract __satfracttiuqq (long long A)
- -- Runtime Function: unsigned fract __satfracttiuhq (long long A)
- -- Runtime Function: unsigned long fract __satfracttiusq (long long A)
- -- Runtime Function: unsigned long long fract __satfracttiudq (long
- long A)
- -- Runtime Function: unsigned short accum __satfracttiuha (long long A)
- -- Runtime Function: unsigned accum __satfracttiusa (long long A)
- -- Runtime Function: unsigned long accum __satfracttiuda (long long A)
- -- Runtime Function: unsigned long long accum __satfracttiuta (long
- long A)
- -- Runtime Function: short fract __satfractsfqq (float A)
- -- Runtime Function: fract __satfractsfhq (float A)
- -- Runtime Function: long fract __satfractsfsq (float A)
- -- Runtime Function: long long fract __satfractsfdq (float A)
- -- Runtime Function: short accum __satfractsfha (float A)
- -- Runtime Function: accum __satfractsfsa (float A)
- -- Runtime Function: long accum __satfractsfda (float A)
- -- Runtime Function: long long accum __satfractsfta (float A)
- -- Runtime Function: unsigned short fract __satfractsfuqq (float A)
- -- Runtime Function: unsigned fract __satfractsfuhq (float A)
- -- Runtime Function: unsigned long fract __satfractsfusq (float A)
- -- Runtime Function: unsigned long long fract __satfractsfudq (float A)
- -- Runtime Function: unsigned short accum __satfractsfuha (float A)
- -- Runtime Function: unsigned accum __satfractsfusa (float A)
- -- Runtime Function: unsigned long accum __satfractsfuda (float A)
- -- Runtime Function: unsigned long long accum __satfractsfuta (float A)
- -- Runtime Function: short fract __satfractdfqq (double A)
- -- Runtime Function: fract __satfractdfhq (double A)
- -- Runtime Function: long fract __satfractdfsq (double A)
- -- Runtime Function: long long fract __satfractdfdq (double A)
- -- Runtime Function: short accum __satfractdfha (double A)
- -- Runtime Function: accum __satfractdfsa (double A)
- -- Runtime Function: long accum __satfractdfda (double A)
- -- Runtime Function: long long accum __satfractdfta (double A)
- -- Runtime Function: unsigned short fract __satfractdfuqq (double A)
- -- Runtime Function: unsigned fract __satfractdfuhq (double A)
- -- Runtime Function: unsigned long fract __satfractdfusq (double A)
- -- Runtime Function: unsigned long long fract __satfractdfudq (double
- A)
- -- Runtime Function: unsigned short accum __satfractdfuha (double A)
- -- Runtime Function: unsigned accum __satfractdfusa (double A)
- -- Runtime Function: unsigned long accum __satfractdfuda (double A)
- -- Runtime Function: unsigned long long accum __satfractdfuta (double
- A)
- The functions convert from fractional and signed non-fractionals to
- fractionals, with saturation.
-
- -- Runtime Function: unsigned char __fractunsqqqi (short fract A)
- -- Runtime Function: unsigned short __fractunsqqhi (short fract A)
- -- Runtime Function: unsigned int __fractunsqqsi (short fract A)
- -- Runtime Function: unsigned long __fractunsqqdi (short fract A)
- -- Runtime Function: unsigned long long __fractunsqqti (short fract A)
- -- Runtime Function: unsigned char __fractunshqqi (fract A)
- -- Runtime Function: unsigned short __fractunshqhi (fract A)
- -- Runtime Function: unsigned int __fractunshqsi (fract A)
- -- Runtime Function: unsigned long __fractunshqdi (fract A)
- -- Runtime Function: unsigned long long __fractunshqti (fract A)
- -- Runtime Function: unsigned char __fractunssqqi (long fract A)
- -- Runtime Function: unsigned short __fractunssqhi (long fract A)
- -- Runtime Function: unsigned int __fractunssqsi (long fract A)
- -- Runtime Function: unsigned long __fractunssqdi (long fract A)
- -- Runtime Function: unsigned long long __fractunssqti (long fract A)
- -- Runtime Function: unsigned char __fractunsdqqi (long long fract A)
- -- Runtime Function: unsigned short __fractunsdqhi (long long fract A)
- -- Runtime Function: unsigned int __fractunsdqsi (long long fract A)
- -- Runtime Function: unsigned long __fractunsdqdi (long long fract A)
- -- Runtime Function: unsigned long long __fractunsdqti (long long fract
- A)
- -- Runtime Function: unsigned char __fractunshaqi (short accum A)
- -- Runtime Function: unsigned short __fractunshahi (short accum A)
- -- Runtime Function: unsigned int __fractunshasi (short accum A)
- -- Runtime Function: unsigned long __fractunshadi (short accum A)
- -- Runtime Function: unsigned long long __fractunshati (short accum A)
- -- Runtime Function: unsigned char __fractunssaqi (accum A)
- -- Runtime Function: unsigned short __fractunssahi (accum A)
- -- Runtime Function: unsigned int __fractunssasi (accum A)
- -- Runtime Function: unsigned long __fractunssadi (accum A)
- -- Runtime Function: unsigned long long __fractunssati (accum A)
- -- Runtime Function: unsigned char __fractunsdaqi (long accum A)
- -- Runtime Function: unsigned short __fractunsdahi (long accum A)
- -- Runtime Function: unsigned int __fractunsdasi (long accum A)
- -- Runtime Function: unsigned long __fractunsdadi (long accum A)
- -- Runtime Function: unsigned long long __fractunsdati (long accum A)
- -- Runtime Function: unsigned char __fractunstaqi (long long accum A)
- -- Runtime Function: unsigned short __fractunstahi (long long accum A)
- -- Runtime Function: unsigned int __fractunstasi (long long accum A)
- -- Runtime Function: unsigned long __fractunstadi (long long accum A)
- -- Runtime Function: unsigned long long __fractunstati (long long accum
- A)
- -- Runtime Function: unsigned char __fractunsuqqqi (unsigned short
- fract A)
- -- Runtime Function: unsigned short __fractunsuqqhi (unsigned short
- fract A)
- -- Runtime Function: unsigned int __fractunsuqqsi (unsigned short fract
- A)
- -- Runtime Function: unsigned long __fractunsuqqdi (unsigned short
- fract A)
- -- Runtime Function: unsigned long long __fractunsuqqti (unsigned short
- fract A)
- -- Runtime Function: unsigned char __fractunsuhqqi (unsigned fract A)
- -- Runtime Function: unsigned short __fractunsuhqhi (unsigned fract A)
- -- Runtime Function: unsigned int __fractunsuhqsi (unsigned fract A)
- -- Runtime Function: unsigned long __fractunsuhqdi (unsigned fract A)
- -- Runtime Function: unsigned long long __fractunsuhqti (unsigned fract
- A)
- -- Runtime Function: unsigned char __fractunsusqqi (unsigned long fract
- A)
- -- Runtime Function: unsigned short __fractunsusqhi (unsigned long
- fract A)
- -- Runtime Function: unsigned int __fractunsusqsi (unsigned long fract
- A)
- -- Runtime Function: unsigned long __fractunsusqdi (unsigned long fract
- A)
- -- Runtime Function: unsigned long long __fractunsusqti (unsigned long
- fract A)
- -- Runtime Function: unsigned char __fractunsudqqi (unsigned long long
- fract A)
- -- Runtime Function: unsigned short __fractunsudqhi (unsigned long long
- fract A)
- -- Runtime Function: unsigned int __fractunsudqsi (unsigned long long
- fract A)
- -- Runtime Function: unsigned long __fractunsudqdi (unsigned long long
- fract A)
- -- Runtime Function: unsigned long long __fractunsudqti (unsigned long
- long fract A)
- -- Runtime Function: unsigned char __fractunsuhaqi (unsigned short
- accum A)
- -- Runtime Function: unsigned short __fractunsuhahi (unsigned short
- accum A)
- -- Runtime Function: unsigned int __fractunsuhasi (unsigned short accum
- A)
- -- Runtime Function: unsigned long __fractunsuhadi (unsigned short
- accum A)
- -- Runtime Function: unsigned long long __fractunsuhati (unsigned short
- accum A)
- -- Runtime Function: unsigned char __fractunsusaqi (unsigned accum A)
- -- Runtime Function: unsigned short __fractunsusahi (unsigned accum A)
- -- Runtime Function: unsigned int __fractunsusasi (unsigned accum A)
- -- Runtime Function: unsigned long __fractunsusadi (unsigned accum A)
- -- Runtime Function: unsigned long long __fractunsusati (unsigned accum
- A)
- -- Runtime Function: unsigned char __fractunsudaqi (unsigned long accum
- A)
- -- Runtime Function: unsigned short __fractunsudahi (unsigned long
- accum A)
- -- Runtime Function: unsigned int __fractunsudasi (unsigned long accum
- A)
- -- Runtime Function: unsigned long __fractunsudadi (unsigned long accum
- A)
- -- Runtime Function: unsigned long long __fractunsudati (unsigned long
- accum A)
- -- Runtime Function: unsigned char __fractunsutaqi (unsigned long long
- accum A)
- -- Runtime Function: unsigned short __fractunsutahi (unsigned long long
- accum A)
- -- Runtime Function: unsigned int __fractunsutasi (unsigned long long
- accum A)
- -- Runtime Function: unsigned long __fractunsutadi (unsigned long long
- accum A)
- -- Runtime Function: unsigned long long __fractunsutati (unsigned long
- long accum A)
- -- Runtime Function: short fract __fractunsqiqq (unsigned char A)
- -- Runtime Function: fract __fractunsqihq (unsigned char A)
- -- Runtime Function: long fract __fractunsqisq (unsigned char A)
- -- Runtime Function: long long fract __fractunsqidq (unsigned char A)
- -- Runtime Function: short accum __fractunsqiha (unsigned char A)
- -- Runtime Function: accum __fractunsqisa (unsigned char A)
- -- Runtime Function: long accum __fractunsqida (unsigned char A)
- -- Runtime Function: long long accum __fractunsqita (unsigned char A)
- -- Runtime Function: unsigned short fract __fractunsqiuqq (unsigned
- char A)
- -- Runtime Function: unsigned fract __fractunsqiuhq (unsigned char A)
- -- Runtime Function: unsigned long fract __fractunsqiusq (unsigned char
- A)
- -- Runtime Function: unsigned long long fract __fractunsqiudq (unsigned
- char A)
- -- Runtime Function: unsigned short accum __fractunsqiuha (unsigned
- char A)
- -- Runtime Function: unsigned accum __fractunsqiusa (unsigned char A)
- -- Runtime Function: unsigned long accum __fractunsqiuda (unsigned char
- A)
- -- Runtime Function: unsigned long long accum __fractunsqiuta (unsigned
- char A)
- -- Runtime Function: short fract __fractunshiqq (unsigned short A)
- -- Runtime Function: fract __fractunshihq (unsigned short A)
- -- Runtime Function: long fract __fractunshisq (unsigned short A)
- -- Runtime Function: long long fract __fractunshidq (unsigned short A)
- -- Runtime Function: short accum __fractunshiha (unsigned short A)
- -- Runtime Function: accum __fractunshisa (unsigned short A)
- -- Runtime Function: long accum __fractunshida (unsigned short A)
- -- Runtime Function: long long accum __fractunshita (unsigned short A)
- -- Runtime Function: unsigned short fract __fractunshiuqq (unsigned
- short A)
- -- Runtime Function: unsigned fract __fractunshiuhq (unsigned short A)
- -- Runtime Function: unsigned long fract __fractunshiusq (unsigned
- short A)
- -- Runtime Function: unsigned long long fract __fractunshiudq (unsigned
- short A)
- -- Runtime Function: unsigned short accum __fractunshiuha (unsigned
- short A)
- -- Runtime Function: unsigned accum __fractunshiusa (unsigned short A)
- -- Runtime Function: unsigned long accum __fractunshiuda (unsigned
- short A)
- -- Runtime Function: unsigned long long accum __fractunshiuta (unsigned
- short A)
- -- Runtime Function: short fract __fractunssiqq (unsigned int A)
- -- Runtime Function: fract __fractunssihq (unsigned int A)
- -- Runtime Function: long fract __fractunssisq (unsigned int A)
- -- Runtime Function: long long fract __fractunssidq (unsigned int A)
- -- Runtime Function: short accum __fractunssiha (unsigned int A)
- -- Runtime Function: accum __fractunssisa (unsigned int A)
- -- Runtime Function: long accum __fractunssida (unsigned int A)
- -- Runtime Function: long long accum __fractunssita (unsigned int A)
- -- Runtime Function: unsigned short fract __fractunssiuqq (unsigned int
- A)
- -- Runtime Function: unsigned fract __fractunssiuhq (unsigned int A)
- -- Runtime Function: unsigned long fract __fractunssiusq (unsigned int
- A)
- -- Runtime Function: unsigned long long fract __fractunssiudq (unsigned
- int A)
- -- Runtime Function: unsigned short accum __fractunssiuha (unsigned int
- A)
- -- Runtime Function: unsigned accum __fractunssiusa (unsigned int A)
- -- Runtime Function: unsigned long accum __fractunssiuda (unsigned int
- A)
- -- Runtime Function: unsigned long long accum __fractunssiuta (unsigned
- int A)
- -- Runtime Function: short fract __fractunsdiqq (unsigned long A)
- -- Runtime Function: fract __fractunsdihq (unsigned long A)
- -- Runtime Function: long fract __fractunsdisq (unsigned long A)
- -- Runtime Function: long long fract __fractunsdidq (unsigned long A)
- -- Runtime Function: short accum __fractunsdiha (unsigned long A)
- -- Runtime Function: accum __fractunsdisa (unsigned long A)
- -- Runtime Function: long accum __fractunsdida (unsigned long A)
- -- Runtime Function: long long accum __fractunsdita (unsigned long A)
- -- Runtime Function: unsigned short fract __fractunsdiuqq (unsigned
- long A)
- -- Runtime Function: unsigned fract __fractunsdiuhq (unsigned long A)
- -- Runtime Function: unsigned long fract __fractunsdiusq (unsigned long
- A)
- -- Runtime Function: unsigned long long fract __fractunsdiudq (unsigned
- long A)
- -- Runtime Function: unsigned short accum __fractunsdiuha (unsigned
- long A)
- -- Runtime Function: unsigned accum __fractunsdiusa (unsigned long A)
- -- Runtime Function: unsigned long accum __fractunsdiuda (unsigned long
- A)
- -- Runtime Function: unsigned long long accum __fractunsdiuta (unsigned
- long A)
- -- Runtime Function: short fract __fractunstiqq (unsigned long long A)
- -- Runtime Function: fract __fractunstihq (unsigned long long A)
- -- Runtime Function: long fract __fractunstisq (unsigned long long A)
- -- Runtime Function: long long fract __fractunstidq (unsigned long long
- A)
- -- Runtime Function: short accum __fractunstiha (unsigned long long A)
- -- Runtime Function: accum __fractunstisa (unsigned long long A)
- -- Runtime Function: long accum __fractunstida (unsigned long long A)
- -- Runtime Function: long long accum __fractunstita (unsigned long long
- A)
- -- Runtime Function: unsigned short fract __fractunstiuqq (unsigned
- long long A)
- -- Runtime Function: unsigned fract __fractunstiuhq (unsigned long long
- A)
- -- Runtime Function: unsigned long fract __fractunstiusq (unsigned long
- long A)
- -- Runtime Function: unsigned long long fract __fractunstiudq (unsigned
- long long A)
- -- Runtime Function: unsigned short accum __fractunstiuha (unsigned
- long long A)
- -- Runtime Function: unsigned accum __fractunstiusa (unsigned long long
- A)
- -- Runtime Function: unsigned long accum __fractunstiuda (unsigned long
- long A)
- -- Runtime Function: unsigned long long accum __fractunstiuta (unsigned
- long long A)
- These functions convert from fractionals to unsigned
- non-fractionals; and from unsigned non-fractionals to fractionals,
- without saturation.
-
- -- Runtime Function: short fract __satfractunsqiqq (unsigned char A)
- -- Runtime Function: fract __satfractunsqihq (unsigned char A)
- -- Runtime Function: long fract __satfractunsqisq (unsigned char A)
- -- Runtime Function: long long fract __satfractunsqidq (unsigned char
- A)
- -- Runtime Function: short accum __satfractunsqiha (unsigned char A)
- -- Runtime Function: accum __satfractunsqisa (unsigned char A)
- -- Runtime Function: long accum __satfractunsqida (unsigned char A)
- -- Runtime Function: long long accum __satfractunsqita (unsigned char
- A)
- -- Runtime Function: unsigned short fract __satfractunsqiuqq (unsigned
- char A)
- -- Runtime Function: unsigned fract __satfractunsqiuhq (unsigned char
- A)
- -- Runtime Function: unsigned long fract __satfractunsqiusq (unsigned
- char A)
- -- Runtime Function: unsigned long long fract __satfractunsqiudq
- (unsigned char A)
- -- Runtime Function: unsigned short accum __satfractunsqiuha (unsigned
- char A)
- -- Runtime Function: unsigned accum __satfractunsqiusa (unsigned char
- A)
- -- Runtime Function: unsigned long accum __satfractunsqiuda (unsigned
- char A)
- -- Runtime Function: unsigned long long accum __satfractunsqiuta
- (unsigned char A)
- -- Runtime Function: short fract __satfractunshiqq (unsigned short A)
- -- Runtime Function: fract __satfractunshihq (unsigned short A)
- -- Runtime Function: long fract __satfractunshisq (unsigned short A)
- -- Runtime Function: long long fract __satfractunshidq (unsigned short
- A)
- -- Runtime Function: short accum __satfractunshiha (unsigned short A)
- -- Runtime Function: accum __satfractunshisa (unsigned short A)
- -- Runtime Function: long accum __satfractunshida (unsigned short A)
- -- Runtime Function: long long accum __satfractunshita (unsigned short
- A)
- -- Runtime Function: unsigned short fract __satfractunshiuqq (unsigned
- short A)
- -- Runtime Function: unsigned fract __satfractunshiuhq (unsigned short
- A)
- -- Runtime Function: unsigned long fract __satfractunshiusq (unsigned
- short A)
- -- Runtime Function: unsigned long long fract __satfractunshiudq
- (unsigned short A)
- -- Runtime Function: unsigned short accum __satfractunshiuha (unsigned
- short A)
- -- Runtime Function: unsigned accum __satfractunshiusa (unsigned short
- A)
- -- Runtime Function: unsigned long accum __satfractunshiuda (unsigned
- short A)
- -- Runtime Function: unsigned long long accum __satfractunshiuta
- (unsigned short A)
- -- Runtime Function: short fract __satfractunssiqq (unsigned int A)
- -- Runtime Function: fract __satfractunssihq (unsigned int A)
- -- Runtime Function: long fract __satfractunssisq (unsigned int A)
- -- Runtime Function: long long fract __satfractunssidq (unsigned int A)
- -- Runtime Function: short accum __satfractunssiha (unsigned int A)
- -- Runtime Function: accum __satfractunssisa (unsigned int A)
- -- Runtime Function: long accum __satfractunssida (unsigned int A)
- -- Runtime Function: long long accum __satfractunssita (unsigned int A)
- -- Runtime Function: unsigned short fract __satfractunssiuqq (unsigned
- int A)
- -- Runtime Function: unsigned fract __satfractunssiuhq (unsigned int A)
- -- Runtime Function: unsigned long fract __satfractunssiusq (unsigned
- int A)
- -- Runtime Function: unsigned long long fract __satfractunssiudq
- (unsigned int A)
- -- Runtime Function: unsigned short accum __satfractunssiuha (unsigned
- int A)
- -- Runtime Function: unsigned accum __satfractunssiusa (unsigned int A)
- -- Runtime Function: unsigned long accum __satfractunssiuda (unsigned
- int A)
- -- Runtime Function: unsigned long long accum __satfractunssiuta
- (unsigned int A)
- -- Runtime Function: short fract __satfractunsdiqq (unsigned long A)
- -- Runtime Function: fract __satfractunsdihq (unsigned long A)
- -- Runtime Function: long fract __satfractunsdisq (unsigned long A)
- -- Runtime Function: long long fract __satfractunsdidq (unsigned long
- A)
- -- Runtime Function: short accum __satfractunsdiha (unsigned long A)
- -- Runtime Function: accum __satfractunsdisa (unsigned long A)
- -- Runtime Function: long accum __satfractunsdida (unsigned long A)
- -- Runtime Function: long long accum __satfractunsdita (unsigned long
- A)
- -- Runtime Function: unsigned short fract __satfractunsdiuqq (unsigned
- long A)
- -- Runtime Function: unsigned fract __satfractunsdiuhq (unsigned long
- A)
- -- Runtime Function: unsigned long fract __satfractunsdiusq (unsigned
- long A)
- -- Runtime Function: unsigned long long fract __satfractunsdiudq
- (unsigned long A)
- -- Runtime Function: unsigned short accum __satfractunsdiuha (unsigned
- long A)
- -- Runtime Function: unsigned accum __satfractunsdiusa (unsigned long
- A)
- -- Runtime Function: unsigned long accum __satfractunsdiuda (unsigned
- long A)
- -- Runtime Function: unsigned long long accum __satfractunsdiuta
- (unsigned long A)
- -- Runtime Function: short fract __satfractunstiqq (unsigned long long
- A)
- -- Runtime Function: fract __satfractunstihq (unsigned long long A)
- -- Runtime Function: long fract __satfractunstisq (unsigned long long
- A)
- -- Runtime Function: long long fract __satfractunstidq (unsigned long
- long A)
- -- Runtime Function: short accum __satfractunstiha (unsigned long long
- A)
- -- Runtime Function: accum __satfractunstisa (unsigned long long A)
- -- Runtime Function: long accum __satfractunstida (unsigned long long
- A)
- -- Runtime Function: long long accum __satfractunstita (unsigned long
- long A)
- -- Runtime Function: unsigned short fract __satfractunstiuqq (unsigned
- long long A)
- -- Runtime Function: unsigned fract __satfractunstiuhq (unsigned long
- long A)
- -- Runtime Function: unsigned long fract __satfractunstiusq (unsigned
- long long A)
- -- Runtime Function: unsigned long long fract __satfractunstiudq
- (unsigned long long A)
- -- Runtime Function: unsigned short accum __satfractunstiuha (unsigned
- long long A)
- -- Runtime Function: unsigned accum __satfractunstiusa (unsigned long
- long A)
- -- Runtime Function: unsigned long accum __satfractunstiuda (unsigned
- long long A)
- -- Runtime Function: unsigned long long accum __satfractunstiuta
- (unsigned long long A)
- These functions convert from unsigned non-fractionals to
- fractionals, with saturation.
-
-
- File: gccint.info, Node: Exception handling routines, Next: Miscellaneous routines, Prev: Fixed-point fractional library routines, Up: Libgcc
-
- 4.5 Language-independent routines for exception handling
- ========================================================
-
- document me!
-
- _Unwind_DeleteException
- _Unwind_Find_FDE
- _Unwind_ForcedUnwind
- _Unwind_GetGR
- _Unwind_GetIP
- _Unwind_GetLanguageSpecificData
- _Unwind_GetRegionStart
- _Unwind_GetTextRelBase
- _Unwind_GetDataRelBase
- _Unwind_RaiseException
- _Unwind_Resume
- _Unwind_SetGR
- _Unwind_SetIP
- _Unwind_FindEnclosingFunction
- _Unwind_SjLj_Register
- _Unwind_SjLj_Unregister
- _Unwind_SjLj_RaiseException
- _Unwind_SjLj_ForcedUnwind
- _Unwind_SjLj_Resume
- __deregister_frame
- __deregister_frame_info
- __deregister_frame_info_bases
- __register_frame
- __register_frame_info
- __register_frame_info_bases
- __register_frame_info_table
- __register_frame_info_table_bases
- __register_frame_table
-
-
- File: gccint.info, Node: Miscellaneous routines, Prev: Exception handling routines, Up: Libgcc
-
- 4.6 Miscellaneous runtime library routines
- ==========================================
-
- 4.6.1 Cache control functions
- -----------------------------
-
- -- Runtime Function: void __clear_cache (char *BEG, char *END)
- This function clears the instruction cache between BEG and END.
-
- 4.6.2 Split stack functions and variables
- -----------------------------------------
-
- -- Runtime Function: void * __splitstack_find (void *SEGMENT_ARG, void
- *SP, size_t LEN, void **NEXT_SEGMENT, void **NEXT_SP, void
- **INITIAL_SP)
- When using '-fsplit-stack', this call may be used to iterate over
- the stack segments. It may be called like this:
- void *next_segment = NULL;
- void *next_sp = NULL;
- void *initial_sp = NULL;
- void *stack;
- size_t stack_size;
- while ((stack = __splitstack_find (next_segment, next_sp,
- &stack_size, &next_segment,
- &next_sp, &initial_sp))
- != NULL)
- {
- /* Stack segment starts at stack and is
- stack_size bytes long. */
- }
-
- There is no way to iterate over the stack segments of a different
- thread. However, what is permitted is for one thread to call this
- with the SEGMENT_ARG and SP arguments NULL, to pass NEXT_SEGMENT,
- NEXT_SP, and INITIAL_SP to a different thread, and then to suspend
- one way or another. A different thread may run the subsequent
- '__splitstack_find' iterations. Of course, this will only work if
- the first thread is suspended while the second thread is calling
- '__splitstack_find'. If not, the second thread could be looking at
- the stack while it is changing, and anything could happen.
-
- -- Variable: __morestack_segments
- -- Variable: __morestack_current_segment
- -- Variable: __morestack_initial_sp
- Internal variables used by the '-fsplit-stack' implementation.
-
-
- File: gccint.info, Node: Languages, Next: Source Tree, Prev: Libgcc, Up: Top
-
- 5 Language Front Ends in GCC
- ****************************
-
- The interface to front ends for languages in GCC, and in particular the
- 'tree' structure (*note GENERIC::), was initially designed for C, and
- many aspects of it are still somewhat biased towards C and C-like
- languages. It is, however, reasonably well suited to other procedural
- languages, and front ends for many such languages have been written for
- GCC.
-
- Writing a compiler as a front end for GCC, rather than compiling
- directly to assembler or generating C code which is then compiled by
- GCC, has several advantages:
-
- * GCC front ends benefit from the support for many different target
- machines already present in GCC.
- * GCC front ends benefit from all the optimizations in GCC. Some of
- these, such as alias analysis, may work better when GCC is
- compiling directly from source code then when it is compiling from
- generated C code.
- * Better debugging information is generated when compiling directly
- from source code than when going via intermediate generated C code.
-
- Because of the advantages of writing a compiler as a GCC front end, GCC
- front ends have also been created for languages very different from
- those for which GCC was designed, such as the declarative
- logic/functional language Mercury. For these reasons, it may also be
- useful to implement compilers created for specialized purposes (for
- example, as part of a research project) as GCC front ends.
-
-
- File: gccint.info, Node: Source Tree, Next: Testsuites, Prev: Languages, Up: Top
-
- 6 Source Tree Structure and Build System
- ****************************************
-
- This chapter describes the structure of the GCC source tree, and how GCC
- is built. The user documentation for building and installing GCC is in
- a separate manual (<http://gcc.gnu.org/install/>), with which it is
- presumed that you are familiar.
-
- * Menu:
-
- * Configure Terms:: Configuration terminology and history.
- * Top Level:: The top level source directory.
- * gcc Directory:: The 'gcc' subdirectory.
-
-
- File: gccint.info, Node: Configure Terms, Next: Top Level, Up: Source Tree
-
- 6.1 Configure Terms and History
- ===============================
-
- The configure and build process has a long and colorful history, and can
- be confusing to anyone who doesn't know why things are the way they are.
- While there are other documents which describe the configuration process
- in detail, here are a few things that everyone working on GCC should
- know.
-
- There are three system names that the build knows about: the machine
- you are building on ("build"), the machine that you are building for
- ("host"), and the machine that GCC will produce code for ("target").
- When you configure GCC, you specify these with '--build=', '--host=',
- and '--target='.
-
- Specifying the host without specifying the build should be avoided, as
- 'configure' may (and once did) assume that the host you specify is also
- the build, which may not be true.
-
- If build, host, and target are all the same, this is called a "native".
- If build and host are the same but target is different, this is called a
- "cross". If build, host, and target are all different this is called a
- "canadian" (for obscure reasons dealing with Canada's political party
- and the background of the person working on the build at that time). If
- host and target are the same, but build is different, you are using a
- cross-compiler to build a native for a different system. Some people
- call this a "host-x-host", "crossed native", or "cross-built native".
- If build and target are the same, but host is different, you are using a
- cross compiler to build a cross compiler that produces code for the
- machine you're building on. This is rare, so there is no common way of
- describing it. There is a proposal to call this a "crossback".
-
- If build and host are the same, the GCC you are building will also be
- used to build the target libraries (like 'libstdc++'). If build and
- host are different, you must have already built and installed a cross
- compiler that will be used to build the target libraries (if you
- configured with '--target=foo-bar', this compiler will be called
- 'foo-bar-gcc').
-
- In the case of target libraries, the machine you're building for is the
- machine you specified with '--target'. So, build is the machine you're
- building on (no change there), host is the machine you're building for
- (the target libraries are built for the target, so host is the target
- you specified), and target doesn't apply (because you're not building a
- compiler, you're building libraries). The configure/make process will
- adjust these variables as needed. It also sets '$with_cross_host' to
- the original '--host' value in case you need it.
-
- The 'libiberty' support library is built up to three times: once for
- the host, once for the target (even if they are the same), and once for
- the build if build and host are different. This allows it to be used by
- all programs which are generated in the course of the build process.
-
-
- File: gccint.info, Node: Top Level, Next: gcc Directory, Prev: Configure Terms, Up: Source Tree
-
- 6.2 Top Level Source Directory
- ==============================
-
- The top level source directory in a GCC distribution contains several
- files and directories that are shared with other software distributions
- such as that of GNU Binutils. It also contains several subdirectories
- that contain parts of GCC and its runtime libraries:
-
- 'boehm-gc'
- The Boehm conservative garbage collector, optionally used as part
- of the ObjC runtime library when configured with
- '--enable-objc-gc'.
-
- 'config'
- Autoconf macros and Makefile fragments used throughout the tree.
-
- 'contrib'
- Contributed scripts that may be found useful in conjunction with
- GCC. One of these, 'contrib/texi2pod.pl', is used to generate man
- pages from Texinfo manuals as part of the GCC build process.
-
- 'fixincludes'
- The support for fixing system headers to work with GCC. See
- 'fixincludes/README' for more information. The headers fixed by
- this mechanism are installed in 'LIBSUBDIR/include-fixed'. Along
- with those headers, 'README-fixinc' is also installed, as
- 'LIBSUBDIR/include-fixed/README'.
-
- 'gcc'
- The main sources of GCC itself (except for runtime libraries),
- including optimizers, support for different target architectures,
- language front ends, and testsuites. *Note The 'gcc' Subdirectory:
- gcc Directory, for details.
-
- 'gnattools'
- Support tools for GNAT.
-
- 'include'
- Headers for the 'libiberty' library.
-
- 'intl'
- GNU 'libintl', from GNU 'gettext', for systems which do not include
- it in 'libc'.
-
- 'libada'
- The Ada runtime library.
-
- 'libatomic'
- The runtime support library for atomic operations (e.g. for
- '__sync' and '__atomic').
-
- 'libcpp'
- The C preprocessor library.
-
- 'libdecnumber'
- The Decimal Float support library.
-
- 'libffi'
- The 'libffi' library, used as part of the Go runtime library.
-
- 'libgcc'
- The GCC runtime library.
-
- 'libgfortran'
- The Fortran runtime library.
-
- 'libgo'
- The Go runtime library. The bulk of this library is mirrored from
- the master Go repository (https://github.com/golang/go).
-
- 'libgomp'
- The GNU Offloading and Multi Processing Runtime Library.
-
- 'libiberty'
- The 'libiberty' library, used for portability and for some
- generally useful data structures and algorithms. *Note
- Introduction: (libiberty)Top, for more information about this
- library.
-
- 'libitm'
- The runtime support library for transactional memory.
-
- 'libobjc'
- The Objective-C and Objective-C++ runtime library.
-
- 'libquadmath'
- The runtime support library for quad-precision math operations.
-
- 'libphobos'
- The D standard and runtime library. The bulk of this library is
- mirrored from the master D repositories (https://github.com/dlang).
-
- 'libssp'
- The Stack protector runtime library.
-
- 'libstdc++-v3'
- The C++ runtime library.
-
- 'lto-plugin'
- Plugin used by the linker if link-time optimizations are enabled.
-
- 'maintainer-scripts'
- Scripts used by the 'gccadmin' account on 'gcc.gnu.org'.
-
- 'zlib'
- The 'zlib' compression library, used for compressing and
- uncompressing GCC's intermediate language in LTO object files.
-
- The build system in the top level directory, including how recursion
- into subdirectories works and how building runtime libraries for
- multilibs is handled, is documented in a separate manual, included with
- GNU Binutils. *Note GNU configure and build system: (configure)Top, for
- details.
-
-
- File: gccint.info, Node: gcc Directory, Prev: Top Level, Up: Source Tree
-
- 6.3 The 'gcc' Subdirectory
- ==========================
-
- The 'gcc' directory contains many files that are part of the C sources
- of GCC, other files used as part of the configuration and build process,
- and subdirectories including documentation and a testsuite. The files
- that are sources of GCC are documented in a separate chapter. *Note
- Passes and Files of the Compiler: Passes.
-
- * Menu:
-
- * Subdirectories:: Subdirectories of 'gcc'.
- * Configuration:: The configuration process, and the files it uses.
- * Build:: The build system in the 'gcc' directory.
- * Makefile:: Targets in 'gcc/Makefile'.
- * Library Files:: Library source files and headers under 'gcc/'.
- * Headers:: Headers installed by GCC.
- * Documentation:: Building documentation in GCC.
- * Front End:: Anatomy of a language front end.
- * Back End:: Anatomy of a target back end.
-
-
- File: gccint.info, Node: Subdirectories, Next: Configuration, Up: gcc Directory
-
- 6.3.1 Subdirectories of 'gcc'
- -----------------------------
-
- The 'gcc' directory contains the following subdirectories:
-
- 'LANGUAGE'
- Subdirectories for various languages. Directories containing a
- file 'config-lang.in' are language subdirectories. The contents of
- the subdirectories 'c' (for C), 'cp' (for C++), 'objc' (for
- Objective-C), 'objcp' (for Objective-C++), and 'lto' (for LTO) are
- documented in this manual (*note Passes and Files of the Compiler:
- Passes.); those for other languages are not. *Note Anatomy of a
- Language Front End: Front End, for details of the files in these
- directories.
-
- 'common'
- Source files shared between the compiler drivers (such as 'gcc')
- and the compilers proper (such as 'cc1'). If an architecture
- defines target hooks shared between those places, it also has a
- subdirectory in 'common/config'. *Note Target Structure::.
-
- 'config'
- Configuration files for supported architectures and operating
- systems. *Note Anatomy of a Target Back End: Back End, for details
- of the files in this directory.
-
- 'doc'
- Texinfo documentation for GCC, together with automatically
- generated man pages and support for converting the installation
- manual to HTML. *Note Documentation::.
-
- 'ginclude'
- System headers installed by GCC, mainly those required by the C
- standard of freestanding implementations. *Note Headers Installed
- by GCC: Headers, for details of when these and other headers are
- installed.
-
- 'po'
- Message catalogs with translations of messages produced by GCC into
- various languages, 'LANGUAGE.po'. This directory also contains
- 'gcc.pot', the template for these message catalogues, 'exgettext',
- a wrapper around 'gettext' to extract the messages from the GCC
- sources and create 'gcc.pot', which is run by 'make gcc.pot', and
- 'EXCLUDES', a list of files from which messages should not be
- extracted.
-
- 'testsuite'
- The GCC testsuites (except for those for runtime libraries). *Note
- Testsuites::.
-
-
- File: gccint.info, Node: Configuration, Next: Build, Prev: Subdirectories, Up: gcc Directory
-
- 6.3.2 Configuration in the 'gcc' Directory
- ------------------------------------------
-
- The 'gcc' directory is configured with an Autoconf-generated script
- 'configure'. The 'configure' script is generated from 'configure.ac'
- and 'aclocal.m4'. From the files 'configure.ac' and 'acconfig.h',
- Autoheader generates the file 'config.in'. The file 'cstamp-h.in' is
- used as a timestamp.
-
- * Menu:
-
- * Config Fragments:: Scripts used by 'configure'.
- * System Config:: The 'config.build', 'config.host', and
- 'config.gcc' files.
- * Configuration Files:: Files created by running 'configure'.
-
-
- File: gccint.info, Node: Config Fragments, Next: System Config, Up: Configuration
-
- 6.3.2.1 Scripts Used by 'configure'
- ...................................
-
- 'configure' uses some other scripts to help in its work:
-
- * The standard GNU 'config.sub' and 'config.guess' files, kept in the
- top level directory, are used.
-
- * The file 'config.gcc' is used to handle configuration specific to
- the particular target machine. The file 'config.build' is used to
- handle configuration specific to the particular build machine. The
- file 'config.host' is used to handle configuration specific to the
- particular host machine. (In general, these should only be used
- for features that cannot reasonably be tested in Autoconf feature
- tests.) *Note The 'config.build'; 'config.host'; and 'config.gcc'
- Files: System Config, for details of the contents of these files.
-
- * Each language subdirectory has a file 'LANGUAGE/config-lang.in'
- that is used for front-end-specific configuration. *Note The Front
- End 'config-lang.in' File: Front End Config, for details of this
- file.
-
- * A helper script 'configure.frag' is used as part of creating the
- output of 'configure'.
-
-
- File: gccint.info, Node: System Config, Next: Configuration Files, Prev: Config Fragments, Up: Configuration
-
- 6.3.2.2 The 'config.build'; 'config.host'; and 'config.gcc' Files
- .................................................................
-
- The 'config.build' file contains specific rules for particular systems
- which GCC is built on. This should be used as rarely as possible, as
- the behavior of the build system can always be detected by autoconf.
-
- The 'config.host' file contains specific rules for particular systems
- which GCC will run on. This is rarely needed.
-
- The 'config.gcc' file contains specific rules for particular systems
- which GCC will generate code for. This is usually needed.
-
- Each file has a list of the shell variables it sets, with descriptions,
- at the top of the file.
-
- FIXME: document the contents of these files, and what variables should
- be set to control build, host and target configuration.
-
-
- File: gccint.info, Node: Configuration Files, Prev: System Config, Up: Configuration
-
- 6.3.2.3 Files Created by 'configure'
- ....................................
-
- Here we spell out what files will be set up by 'configure' in the 'gcc'
- directory. Some other files are created as temporary files in the
- configuration process, and are not used in the subsequent build; these
- are not documented.
-
- * 'Makefile' is constructed from 'Makefile.in', together with the
- host and target fragments (*note Makefile Fragments: Fragments.)
- 't-TARGET' and 'x-HOST' from 'config', if any, and language
- Makefile fragments 'LANGUAGE/Make-lang.in'.
- * 'auto-host.h' contains information about the host machine
- determined by 'configure'. If the host machine is different from
- the build machine, then 'auto-build.h' is also created, containing
- such information about the build machine.
- * 'config.status' is a script that may be run to recreate the current
- configuration.
- * 'configargs.h' is a header containing details of the arguments
- passed to 'configure' to configure GCC, and of the thread model
- used.
- * 'cstamp-h' is used as a timestamp.
- * If a language 'config-lang.in' file (*note The Front End
- 'config-lang.in' File: Front End Config.) sets 'outputs', then the
- files listed in 'outputs' there are also generated.
-
- The following configuration headers are created from the Makefile,
- using 'mkconfig.sh', rather than directly by 'configure'. 'config.h',
- 'bconfig.h' and 'tconfig.h' all contain the 'xm-MACHINE.h' header, if
- any, appropriate to the host, build and target machines respectively,
- the configuration headers for the target, and some definitions; for the
- host and build machines, these include the autoconfigured headers
- generated by 'configure'. The other configuration headers are
- determined by 'config.gcc'. They also contain the typedefs for 'rtx',
- 'rtvec' and 'tree'.
-
- * 'config.h', for use in programs that run on the host machine.
- * 'bconfig.h', for use in programs that run on the build machine.
- * 'tconfig.h', for use in programs and libraries for the target
- machine.
- * 'tm_p.h', which includes the header 'MACHINE-protos.h' that
- contains prototypes for functions in the target 'MACHINE.c' file.
- The 'MACHINE-protos.h' header is included after the 'rtl.h' and/or
- 'tree.h' would have been included. The 'tm_p.h' also includes the
- header 'tm-preds.h' which is generated by 'genpreds' program during
- the build to define the declarations and inline functions for the
- predicate functions.
-
-
- File: gccint.info, Node: Build, Next: Makefile, Prev: Configuration, Up: gcc Directory
-
- 6.3.3 Build System in the 'gcc' Directory
- -----------------------------------------
-
- FIXME: describe the build system, including what is built in what
- stages. Also list the various source files that are used in the build
- process but aren't source files of GCC itself and so aren't documented
- below (*note Passes::).
-
-
- File: gccint.info, Node: Makefile, Next: Library Files, Prev: Build, Up: gcc Directory
-
- 6.3.4 Makefile Targets
- ----------------------
-
- These targets are available from the 'gcc' directory:
-
- 'all'
- This is the default target. Depending on what your
- build/host/target configuration is, it coordinates all the things
- that need to be built.
-
- 'doc'
- Produce info-formatted documentation and man pages. Essentially it
- calls 'make man' and 'make info'.
-
- 'dvi'
- Produce DVI-formatted documentation.
-
- 'pdf'
- Produce PDF-formatted documentation.
-
- 'html'
- Produce HTML-formatted documentation.
-
- 'man'
- Generate man pages.
-
- 'info'
- Generate info-formatted pages.
-
- 'mostlyclean'
- Delete the files made while building the compiler.
-
- 'clean'
- That, and all the other files built by 'make all'.
-
- 'distclean'
- That, and all the files created by 'configure'.
-
- 'maintainer-clean'
- Distclean plus any file that can be generated from other files.
- Note that additional tools may be required beyond what is normally
- needed to build GCC.
-
- 'srcextra'
- Generates files in the source directory that are not
- version-controlled but should go into a release tarball.
-
- 'srcinfo'
- 'srcman'
- Copies the info-formatted and manpage documentation into the source
- directory usually for the purpose of generating a release tarball.
-
- 'install'
- Installs GCC.
-
- 'uninstall'
- Deletes installed files, though this is not supported.
-
- 'check'
- Run the testsuite. This creates a 'testsuite' subdirectory that
- has various '.sum' and '.log' files containing the results of the
- testing. You can run subsets with, for example, 'make check-gcc'.
- You can specify specific tests by setting 'RUNTESTFLAGS' to be the
- name of the '.exp' file, optionally followed by (for some tests) an
- equals and a file wildcard, like:
-
- make check-gcc RUNTESTFLAGS="execute.exp=19980413-*"
-
- Note that running the testsuite may require additional tools be
- installed, such as Tcl or DejaGnu.
-
- The toplevel tree from which you start GCC compilation is not the GCC
- directory, but rather a complex Makefile that coordinates the various
- steps of the build, including bootstrapping the compiler and using the
- new compiler to build target libraries.
-
- When GCC is configured for a native configuration, the default action
- for 'make' is to do a full three-stage bootstrap. This means that GCC
- is built three times--once with the native compiler, once with the
- native-built compiler it just built, and once with the compiler it built
- the second time. In theory, the last two should produce the same
- results, which 'make compare' can check. Each stage is configured
- separately and compiled into a separate directory, to minimize problems
- due to ABI incompatibilities between the native compiler and GCC.
-
- If you do a change, rebuilding will also start from the first stage and
- "bubble" up the change through the three stages. Each stage is taken
- from its build directory (if it had been built previously), rebuilt, and
- copied to its subdirectory. This will allow you to, for example,
- continue a bootstrap after fixing a bug which causes the stage2 build to
- crash. It does not provide as good coverage of the compiler as
- bootstrapping from scratch, but it ensures that the new code is
- syntactically correct (e.g., that you did not use GCC extensions by
- mistake), and avoids spurious bootstrap comparison failures(1).
-
- Other targets available from the top level include:
-
- 'bootstrap-lean'
- Like 'bootstrap', except that the various stages are removed once
- they're no longer needed. This saves disk space.
-
- 'bootstrap2'
- 'bootstrap2-lean'
- Performs only the first two stages of bootstrap. Unlike a
- three-stage bootstrap, this does not perform a comparison to test
- that the compiler is running properly. Note that the disk space
- required by a "lean" bootstrap is approximately independent of the
- number of stages.
-
- 'stageN-bubble (N = 1...4, profile, feedback)'
- Rebuild all the stages up to N, with the appropriate flags,
- "bubbling" the changes as described above.
-
- 'all-stageN (N = 1...4, profile, feedback)'
- Assuming that stage N has already been built, rebuild it with the
- appropriate flags. This is rarely needed.
-
- 'cleanstrap'
- Remove everything ('make clean') and rebuilds ('make bootstrap').
-
- 'compare'
- Compares the results of stages 2 and 3. This ensures that the
- compiler is running properly, since it should produce the same
- object files regardless of how it itself was compiled.
-
- 'profiledbootstrap'
- Builds a compiler with profiling feedback information. In this
- case, the second and third stages are named 'profile' and
- 'feedback', respectively. For more information, see the
- installation instructions.
-
- 'restrap'
- Restart a bootstrap, so that everything that was not built with the
- system compiler is rebuilt.
-
- 'stageN-start (N = 1...4, profile, feedback)'
- For each package that is bootstrapped, rename directories so that,
- for example, 'gcc' points to the stageN GCC, compiled with the
- stageN-1 GCC(2).
-
- You will invoke this target if you need to test or debug the stageN
- GCC. If you only need to execute GCC (but you need not run 'make'
- either to rebuild it or to run test suites), you should be able to
- work directly in the 'stageN-gcc' directory. This makes it easier
- to debug multiple stages in parallel.
-
- 'stage'
- For each package that is bootstrapped, relocate its build directory
- to indicate its stage. For example, if the 'gcc' directory points
- to the stage2 GCC, after invoking this target it will be renamed to
- 'stage2-gcc'.
-
- If you wish to use non-default GCC flags when compiling the stage2 and
- stage3 compilers, set 'BOOT_CFLAGS' on the command line when doing
- 'make'.
-
- Usually, the first stage only builds the languages that the compiler is
- written in: typically, C and maybe Ada. If you are debugging a
- miscompilation of a different stage2 front-end (for example, of the
- Fortran front-end), you may want to have front-ends for other languages
- in the first stage as well. To do so, set 'STAGE1_LANGUAGES' on the
- command line when doing 'make'.
-
- For example, in the aforementioned scenario of debugging a Fortran
- front-end miscompilation caused by the stage1 compiler, you may need a
- command like
-
- make stage2-bubble STAGE1_LANGUAGES=c,fortran
-
- Alternatively, you can use per-language targets to build and test
- languages that are not enabled by default in stage1. For example, 'make
- f951' will build a Fortran compiler even in the stage1 build directory.
-
- ---------- Footnotes ----------
-
- (1) Except if the compiler was buggy and miscompiled some of the
- files that were not modified. In this case, it's best to use 'make
- restrap'.
-
- (2) Customarily, the system compiler is also termed the 'stage0' GCC.
-
-
- File: gccint.info, Node: Library Files, Next: Headers, Prev: Makefile, Up: gcc Directory
-
- 6.3.5 Library Source Files and Headers under the 'gcc' Directory
- ----------------------------------------------------------------
-
- FIXME: list here, with explanation, all the C source files and headers
- under the 'gcc' directory that aren't built into the GCC executable but
- rather are part of runtime libraries and object files, such as
- 'crtstuff.c' and 'unwind-dw2.c'. *Note Headers Installed by GCC:
- Headers, for more information about the 'ginclude' directory.
-
-
- File: gccint.info, Node: Headers, Next: Documentation, Prev: Library Files, Up: gcc Directory
-
- 6.3.6 Headers Installed by GCC
- ------------------------------
-
- In general, GCC expects the system C library to provide most of the
- headers to be used with it. However, GCC will fix those headers if
- necessary to make them work with GCC, and will install some headers
- required of freestanding implementations. These headers are installed
- in 'LIBSUBDIR/include'. Headers for non-C runtime libraries are also
- installed by GCC; these are not documented here. (FIXME: document them
- somewhere.)
-
- Several of the headers GCC installs are in the 'ginclude' directory.
- These headers, 'iso646.h', 'stdarg.h', 'stdbool.h', and 'stddef.h', are
- installed in 'LIBSUBDIR/include', unless the target Makefile fragment
- (*note Target Fragment::) overrides this by setting 'USER_H'.
-
- In addition to these headers and those generated by fixing system
- headers to work with GCC, some other headers may also be installed in
- 'LIBSUBDIR/include'. 'config.gcc' may set 'extra_headers'; this
- specifies additional headers under 'config' to be installed on some
- systems.
-
- GCC installs its own version of '<float.h>', from 'ginclude/float.h'.
- This is done to cope with command-line options that change the
- representation of floating point numbers.
-
- GCC also installs its own version of '<limits.h>'; this is generated
- from 'glimits.h', together with 'limitx.h' and 'limity.h' if the system
- also has its own version of '<limits.h>'. (GCC provides its own header
- because it is required of ISO C freestanding implementations, but needs
- to include the system header from its own header as well because other
- standards such as POSIX specify additional values to be defined in
- '<limits.h>'.) The system's '<limits.h>' header is used via
- 'LIBSUBDIR/include/syslimits.h', which is copied from 'gsyslimits.h' if
- it does not need fixing to work with GCC; if it needs fixing,
- 'syslimits.h' is the fixed copy.
-
- GCC can also install '<tgmath.h>'. It will do this when 'config.gcc'
- sets 'use_gcc_tgmath' to 'yes'.
-
-
- File: gccint.info, Node: Documentation, Next: Front End, Prev: Headers, Up: gcc Directory
-
- 6.3.7 Building Documentation
- ----------------------------
-
- The main GCC documentation is in the form of manuals in Texinfo format.
- These are installed in Info format; DVI versions may be generated by
- 'make dvi', PDF versions by 'make pdf', and HTML versions by 'make
- html'. In addition, some man pages are generated from the Texinfo
- manuals, there are some other text files with miscellaneous
- documentation, and runtime libraries have their own documentation
- outside the 'gcc' directory. FIXME: document the documentation for
- runtime libraries somewhere.
-
- * Menu:
-
- * Texinfo Manuals:: GCC manuals in Texinfo format.
- * Man Page Generation:: Generating man pages from Texinfo manuals.
- * Miscellaneous Docs:: Miscellaneous text files with documentation.
-
-
- File: gccint.info, Node: Texinfo Manuals, Next: Man Page Generation, Up: Documentation
-
- 6.3.7.1 Texinfo Manuals
- .......................
-
- The manuals for GCC as a whole, and the C and C++ front ends, are in
- files 'doc/*.texi'. Other front ends have their own manuals in files
- 'LANGUAGE/*.texi'. Common files 'doc/include/*.texi' are provided which
- may be included in multiple manuals; the following files are in
- 'doc/include':
-
- 'fdl.texi'
- The GNU Free Documentation License.
- 'funding.texi'
- The section "Funding Free Software".
- 'gcc-common.texi'
- Common definitions for manuals.
- 'gpl_v3.texi'
- The GNU General Public License.
- 'texinfo.tex'
- A copy of 'texinfo.tex' known to work with the GCC manuals.
-
- DVI-formatted manuals are generated by 'make dvi', which uses
- 'texi2dvi' (via the Makefile macro '$(TEXI2DVI)'). PDF-formatted
- manuals are generated by 'make pdf', which uses 'texi2pdf' (via the
- Makefile macro '$(TEXI2PDF)'). HTML formatted manuals are generated by
- 'make html'. Info manuals are generated by 'make info' (which is run as
- part of a bootstrap); this generates the manuals in the source
- directory, using 'makeinfo' via the Makefile macro '$(MAKEINFO)', and
- they are included in release distributions.
-
- Manuals are also provided on the GCC web site, in both HTML and
- PostScript forms. This is done via the script
- 'maintainer-scripts/update_web_docs_git'. Each manual to be provided
- online must be listed in the definition of 'MANUALS' in that file; a
- file 'NAME.texi' must only appear once in the source tree, and the
- output manual must have the same name as the source file. (However,
- other Texinfo files, included in manuals but not themselves the root
- files of manuals, may have names that appear more than once in the
- source tree.) The manual file 'NAME.texi' should only include other
- files in its own directory or in 'doc/include'. HTML manuals will be
- generated by 'makeinfo --html', PostScript manuals by 'texi2dvi' and
- 'dvips', and PDF manuals by 'texi2pdf'. All Texinfo files that are
- parts of manuals must be version-controlled, even if they are generated
- files, for the generation of online manuals to work.
-
- The installation manual, 'doc/install.texi', is also provided on the
- GCC web site. The HTML version is generated by the script
- 'doc/install.texi2html'.
-
-
- File: gccint.info, Node: Man Page Generation, Next: Miscellaneous Docs, Prev: Texinfo Manuals, Up: Documentation
-
- 6.3.7.2 Man Page Generation
- ...........................
-
- Because of user demand, in addition to full Texinfo manuals, man pages
- are provided which contain extracts from those manuals. These man pages
- are generated from the Texinfo manuals using 'contrib/texi2pod.pl' and
- 'pod2man'. (The man page for 'g++', 'cp/g++.1', just contains a '.so'
- reference to 'gcc.1', but all the other man pages are generated from
- Texinfo manuals.)
-
- Because many systems may not have the necessary tools installed to
- generate the man pages, they are only generated if the 'configure'
- script detects that recent enough tools are installed, and the Makefiles
- allow generating man pages to fail without aborting the build. Man
- pages are also included in release distributions. They are generated in
- the source directory.
-
- Magic comments in Texinfo files starting '@c man' control what parts of
- a Texinfo file go into a man page. Only a subset of Texinfo is
- supported by 'texi2pod.pl', and it may be necessary to add support for
- more Texinfo features to this script when generating new man pages. To
- improve the man page output, some special Texinfo macros are provided in
- 'doc/include/gcc-common.texi' which 'texi2pod.pl' understands:
-
- '@gcctabopt'
- Use in the form '@table @gcctabopt' for tables of options, where
- for printed output the effect of '@code' is better than that of
- '@option' but for man page output a different effect is wanted.
- '@gccoptlist'
- Use for summary lists of options in manuals.
- '@gol'
- Use at the end of each line inside '@gccoptlist'. This is
- necessary to avoid problems with differences in how the
- '@gccoptlist' macro is handled by different Texinfo formatters.
-
- FIXME: describe the 'texi2pod.pl' input language and magic comments in
- more detail.
-
-
- File: gccint.info, Node: Miscellaneous Docs, Prev: Man Page Generation, Up: Documentation
-
- 6.3.7.3 Miscellaneous Documentation
- ...................................
-
- In addition to the formal documentation that is installed by GCC, there
- are several other text files in the 'gcc' subdirectory with
- miscellaneous documentation:
-
- 'ABOUT-GCC-NLS'
- Notes on GCC's Native Language Support. FIXME: this should be part
- of this manual rather than a separate file.
- 'ABOUT-NLS'
- Notes on the Free Translation Project.
- 'COPYING'
- 'COPYING3'
- The GNU General Public License, Versions 2 and 3.
- 'COPYING.LIB'
- 'COPYING3.LIB'
- The GNU Lesser General Public License, Versions 2.1 and 3.
- '*ChangeLog*'
- '*/ChangeLog*'
- Change log files for various parts of GCC.
- 'LANGUAGES'
- Details of a few changes to the GCC front-end interface. FIXME:
- the information in this file should be part of general
- documentation of the front-end interface in this manual.
- 'ONEWS'
- Information about new features in old versions of GCC. (For recent
- versions, the information is on the GCC web site.)
- 'README.Portability'
- Information about portability issues when writing code in GCC.
- FIXME: why isn't this part of this manual or of the GCC Coding
- Conventions?
-
- FIXME: document such files in subdirectories, at least 'config', 'c',
- 'cp', 'objc', 'testsuite'.
-
-
- File: gccint.info, Node: Front End, Next: Back End, Prev: Documentation, Up: gcc Directory
-
- 6.3.8 Anatomy of a Language Front End
- -------------------------------------
-
- A front end for a language in GCC has the following parts:
-
- * A directory 'LANGUAGE' under 'gcc' containing source files for that
- front end. *Note The Front End 'LANGUAGE' Directory: Front End
- Directory, for details.
- * A mention of the language in the list of supported languages in
- 'gcc/doc/install.texi'.
- * A mention of the name under which the language's runtime library is
- recognized by '--enable-shared=PACKAGE' in the documentation of
- that option in 'gcc/doc/install.texi'.
- * A mention of any special prerequisites for building the front end
- in the documentation of prerequisites in 'gcc/doc/install.texi'.
- * Details of contributors to that front end in
- 'gcc/doc/contrib.texi'. If the details are in that front end's own
- manual then there should be a link to that manual's list in
- 'contrib.texi'.
- * Information about support for that language in
- 'gcc/doc/frontends.texi'.
- * Information about standards for that language, and the front end's
- support for them, in 'gcc/doc/standards.texi'. This may be a link
- to such information in the front end's own manual.
- * Details of source file suffixes for that language and '-x LANG'
- options supported, in 'gcc/doc/invoke.texi'.
- * Entries in 'default_compilers' in 'gcc.c' for source file suffixes
- for that language.
- * Preferably testsuites, which may be under 'gcc/testsuite' or
- runtime library directories. FIXME: document somewhere how to
- write testsuite harnesses.
- * Probably a runtime library for the language, outside the 'gcc'
- directory. FIXME: document this further.
- * Details of the directories of any runtime libraries in
- 'gcc/doc/sourcebuild.texi'.
- * Check targets in 'Makefile.def' for the top-level 'Makefile' to
- check just the compiler or the compiler and runtime library for the
- language.
-
- If the front end is added to the official GCC source repository, the
- following are also necessary:
-
- * At least one Bugzilla component for bugs in that front end and
- runtime libraries. This category needs to be added to the Bugzilla
- database.
- * Normally, one or more maintainers of that front end listed in
- 'MAINTAINERS'.
- * Mentions on the GCC web site in 'index.html' and 'frontends.html',
- with any relevant links on 'readings.html'. (Front ends that are
- not an official part of GCC may also be listed on 'frontends.html',
- with relevant links.)
- * A news item on 'index.html', and possibly an announcement on the
- <gcc-announce@gcc.gnu.org> mailing list.
- * The front end's manuals should be mentioned in
- 'maintainer-scripts/update_web_docs_git' (*note Texinfo Manuals::)
- and the online manuals should be linked to from
- 'onlinedocs/index.html'.
- * Any old releases or CVS repositories of the front end, before its
- inclusion in GCC, should be made available on the GCC web site at
- <https://gcc.gnu.org/pub/gcc/old-releases/>.
- * The release and snapshot script 'maintainer-scripts/gcc_release'
- should be updated to generate appropriate tarballs for this front
- end.
- * If this front end includes its own version files that include the
- current date, 'maintainer-scripts/update_version' should be updated
- accordingly.
-
- * Menu:
-
- * Front End Directory:: The front end 'LANGUAGE' directory.
- * Front End Config:: The front end 'config-lang.in' file.
- * Front End Makefile:: The front end 'Make-lang.in' file.
-
-
- File: gccint.info, Node: Front End Directory, Next: Front End Config, Up: Front End
-
- 6.3.8.1 The Front End 'LANGUAGE' Directory
- ..........................................
-
- A front end 'LANGUAGE' directory contains the source files of that front
- end (but not of any runtime libraries, which should be outside the 'gcc'
- directory). This includes documentation, and possibly some subsidiary
- programs built alongside the front end. Certain files are special and
- other parts of the compiler depend on their names:
-
- 'config-lang.in'
- This file is required in all language subdirectories. *Note The
- Front End 'config-lang.in' File: Front End Config, for details of
- its contents
- 'Make-lang.in'
- This file is required in all language subdirectories. *Note The
- Front End 'Make-lang.in' File: Front End Makefile, for details of
- its contents.
- 'lang.opt'
- This file registers the set of switches that the front end accepts
- on the command line, and their '--help' text. *Note Options::.
- 'lang-specs.h'
- This file provides entries for 'default_compilers' in 'gcc.c' which
- override the default of giving an error that a compiler for that
- language is not installed.
- 'LANGUAGE-tree.def'
- This file, which need not exist, defines any language-specific tree
- codes.
-
-
- File: gccint.info, Node: Front End Config, Next: Front End Makefile, Prev: Front End Directory, Up: Front End
-
- 6.3.8.2 The Front End 'config-lang.in' File
- ...........................................
-
- Each language subdirectory contains a 'config-lang.in' file. This file
- is a shell script that may define some variables describing the
- language:
-
- 'language'
- This definition must be present, and gives the name of the language
- for some purposes such as arguments to '--enable-languages'.
- 'lang_requires'
- If defined, this variable lists (space-separated) language front
- ends other than C that this front end requires to be enabled (with
- the names given being their 'language' settings). For example, the
- Obj-C++ front end depends on the C++ and ObjC front ends, so sets
- 'lang_requires="objc c++"'.
- 'subdir_requires'
- If defined, this variable lists (space-separated) front end
- directories other than C that this front end requires to be
- present. For example, the Objective-C++ front end uses source
- files from the C++ and Objective-C front ends, so sets
- 'subdir_requires="cp objc"'.
- 'target_libs'
- If defined, this variable lists (space-separated) targets in the
- top level 'Makefile' to build the runtime libraries for this
- language, such as 'target-libobjc'.
- 'lang_dirs'
- If defined, this variable lists (space-separated) top level
- directories (parallel to 'gcc'), apart from the runtime libraries,
- that should not be configured if this front end is not built.
- 'build_by_default'
- If defined to 'no', this language front end is not built unless
- enabled in a '--enable-languages' argument. Otherwise, front ends
- are built by default, subject to any special logic in
- 'configure.ac' (as is present to disable the Ada front end if the
- Ada compiler is not already installed).
- 'boot_language'
- If defined to 'yes', this front end is built in stage1 of the
- bootstrap. This is only relevant to front ends written in their
- own languages.
- 'compilers'
- If defined, a space-separated list of compiler executables that
- will be run by the driver. The names here will each end with
- '\$(exeext)'.
- 'outputs'
- If defined, a space-separated list of files that should be
- generated by 'configure' substituting values in them. This
- mechanism can be used to create a file 'LANGUAGE/Makefile' from
- 'LANGUAGE/Makefile.in', but this is deprecated, building everything
- from the single 'gcc/Makefile' is preferred.
- 'gtfiles'
- If defined, a space-separated list of files that should be scanned
- by 'gengtype.c' to generate the garbage collection tables and
- routines for this language. This excludes the files that are
- common to all front ends. *Note Type Information::.
-
-
- File: gccint.info, Node: Front End Makefile, Prev: Front End Config, Up: Front End
-
- 6.3.8.3 The Front End 'Make-lang.in' File
- .........................................
-
- Each language subdirectory contains a 'Make-lang.in' file. It contains
- targets 'LANG.HOOK' (where 'LANG' is the setting of 'language' in
- 'config-lang.in') for the following values of 'HOOK', and any other
- Makefile rules required to build those targets (which may if necessary
- use other Makefiles specified in 'outputs' in 'config-lang.in', although
- this is deprecated). It also adds any testsuite targets that can use
- the standard rule in 'gcc/Makefile.in' to the variable 'lang_checks'.
-
- 'all.cross'
- 'start.encap'
- 'rest.encap'
- FIXME: exactly what goes in each of these targets?
- 'tags'
- Build an 'etags' 'TAGS' file in the language subdirectory in the
- source tree.
- 'info'
- Build info documentation for the front end, in the build directory.
- This target is only called by 'make bootstrap' if a suitable
- version of 'makeinfo' is available, so does not need to check for
- this, and should fail if an error occurs.
- 'dvi'
- Build DVI documentation for the front end, in the build directory.
- This should be done using '$(TEXI2DVI)', with appropriate '-I'
- arguments pointing to directories of included files.
- 'pdf'
- Build PDF documentation for the front end, in the build directory.
- This should be done using '$(TEXI2PDF)', with appropriate '-I'
- arguments pointing to directories of included files.
- 'html'
- Build HTML documentation for the front end, in the build directory.
- 'man'
- Build generated man pages for the front end from Texinfo manuals
- (*note Man Page Generation::), in the build directory. This target
- is only called if the necessary tools are available, but should
- ignore errors so as not to stop the build if errors occur; man
- pages are optional and the tools involved may be installed in a
- broken way.
- 'install-common'
- Install everything that is part of the front end, apart from the
- compiler executables listed in 'compilers' in 'config-lang.in'.
- 'install-info'
- Install info documentation for the front end, if it is present in
- the source directory. This target should have dependencies on info
- files that should be installed.
- 'install-man'
- Install man pages for the front end. This target should ignore
- errors.
- 'install-plugin'
- Install headers needed for plugins.
- 'srcextra'
- Copies its dependencies into the source directory. This generally
- should be used for generated files such as Bison output files which
- are not version-controlled, but should be included in any release
- tarballs. This target will be executed during a bootstrap if
- '--enable-generated-files-in-srcdir' was specified as a 'configure'
- option.
- 'srcinfo'
- 'srcman'
- Copies its dependencies into the source directory. These targets
- will be executed during a bootstrap if
- '--enable-generated-files-in-srcdir' was specified as a 'configure'
- option.
- 'uninstall'
- Uninstall files installed by installing the compiler. This is
- currently documented not to be supported, so the hook need not do
- anything.
- 'mostlyclean'
- 'clean'
- 'distclean'
- 'maintainer-clean'
- The language parts of the standard GNU '*clean' targets. *Note
- Standard Targets for Users: (standards)Standard Targets, for
- details of the standard targets. For GCC, 'maintainer-clean'
- should delete all generated files in the source directory that are
- not version-controlled, but should not delete anything that is.
-
- 'Make-lang.in' must also define a variable 'LANG_OBJS' to a list of
- host object files that are used by that language.
-
-
- File: gccint.info, Node: Back End, Prev: Front End, Up: gcc Directory
-
- 6.3.9 Anatomy of a Target Back End
- ----------------------------------
-
- A back end for a target architecture in GCC has the following parts:
-
- * A directory 'MACHINE' under 'gcc/config', containing a machine
- description 'MACHINE.md' file (*note Machine Descriptions: Machine
- Desc.), header files 'MACHINE.h' and 'MACHINE-protos.h' and a
- source file 'MACHINE.c' (*note Target Description Macros and
- Functions: Target Macros.), possibly a target Makefile fragment
- 't-MACHINE' (*note The Target Makefile Fragment: Target Fragment.),
- and maybe some other files. The names of these files may be
- changed from the defaults given by explicit specifications in
- 'config.gcc'.
- * If necessary, a file 'MACHINE-modes.def' in the 'MACHINE'
- directory, containing additional machine modes to represent
- condition codes. *Note Condition Code::, for further details.
- * An optional 'MACHINE.opt' file in the 'MACHINE' directory,
- containing a list of target-specific options. You can also add
- other option files using the 'extra_options' variable in
- 'config.gcc'. *Note Options::.
- * Entries in 'config.gcc' (*note The 'config.gcc' File: System
- Config.) for the systems with this target architecture.
- * Documentation in 'gcc/doc/invoke.texi' for any command-line options
- supported by this target (*note Run-time Target Specification:
- Run-time Target.). This means both entries in the summary table of
- options and details of the individual options.
- * Documentation in 'gcc/doc/extend.texi' for any target-specific
- attributes supported (*note Defining target-specific uses of
- '__attribute__': Target Attributes.), including where the same
- attribute is already supported on some targets, which are
- enumerated in the manual.
- * Documentation in 'gcc/doc/extend.texi' for any target-specific
- pragmas supported.
- * Documentation in 'gcc/doc/extend.texi' of any target-specific
- built-in functions supported.
- * Documentation in 'gcc/doc/extend.texi' of any target-specific
- format checking styles supported.
- * Documentation in 'gcc/doc/md.texi' of any target-specific
- constraint letters (*note Constraints for Particular Machines:
- Machine Constraints.).
- * A note in 'gcc/doc/contrib.texi' under the person or people who
- contributed the target support.
- * Entries in 'gcc/doc/install.texi' for all target triplets supported
- with this target architecture, giving details of any special notes
- about installation for this target, or saying that there are no
- special notes if there are none.
- * Possibly other support outside the 'gcc' directory for runtime
- libraries. FIXME: reference docs for this. The 'libstdc++'
- porting manual needs to be installed as info for this to work, or
- to be a chapter of this manual.
-
- The 'MACHINE.h' header is included very early in GCC's standard
- sequence of header files, while 'MACHINE-protos.h' is included late in
- the sequence. Thus 'MACHINE-protos.h' can include declarations
- referencing types that are not defined when 'MACHINE.h' is included,
- specifically including those from 'rtl.h' and 'tree.h'. Since both RTL
- and tree types may not be available in every context where
- 'MACHINE-protos.h' is included, in this file you should guard
- declarations using these types inside appropriate '#ifdef RTX_CODE' or
- '#ifdef TREE_CODE' conditional code segments.
-
- If the backend uses shared data structures that require 'GTY' markers
- for garbage collection (*note Type Information::), you must declare
- those in 'MACHINE.h' rather than 'MACHINE-protos.h'. Any definitions
- required for building libgcc must also go in 'MACHINE.h'.
-
- GCC uses the macro 'IN_TARGET_CODE' to distinguish between
- machine-specific '.c' and '.cc' files and machine-independent '.c' and
- '.cc' files. Machine-specific files should use the directive:
-
- #define IN_TARGET_CODE 1
-
- before including 'config.h'.
-
- If the back end is added to the official GCC source repository, the
- following are also necessary:
-
- * An entry for the target architecture in 'readings.html' on the GCC
- web site, with any relevant links.
- * Details of the properties of the back end and target architecture
- in 'backends.html' on the GCC web site.
- * A news item about the contribution of support for that target
- architecture, in 'index.html' on the GCC web site.
- * Normally, one or more maintainers of that target listed in
- 'MAINTAINERS'. Some existing architectures may be unmaintained,
- but it would be unusual to add support for a target that does not
- have a maintainer when support is added.
- * Target triplets covering all 'config.gcc' stanzas for the target,
- in the list in 'contrib/config-list.mk'.
-
-
- File: gccint.info, Node: Testsuites, Next: Options, Prev: Source Tree, Up: Top
-
- 7 Testsuites
- ************
-
- GCC contains several testsuites to help maintain compiler quality. Most
- of the runtime libraries and language front ends in GCC have testsuites.
- Currently only the C language testsuites are documented here; FIXME:
- document the others.
-
- * Menu:
-
- * Test Idioms:: Idioms used in testsuite code.
- * Test Directives:: Directives used within DejaGnu tests.
- * Ada Tests:: The Ada language testsuites.
- * C Tests:: The C language testsuites.
- * LTO Testing:: Support for testing link-time optimizations.
- * gcov Testing:: Support for testing gcov.
- * profopt Testing:: Support for testing profile-directed optimizations.
- * compat Testing:: Support for testing binary compatibility.
- * Torture Tests:: Support for torture testing using multiple options.
- * GIMPLE Tests:: Support for testing GIMPLE passes.
- * RTL Tests:: Support for testing RTL passes.
-
-
- File: gccint.info, Node: Test Idioms, Next: Test Directives, Up: Testsuites
-
- 7.1 Idioms Used in Testsuite Code
- =================================
-
- In general, C testcases have a trailing '-N.c', starting with '-1.c', in
- case other testcases with similar names are added later. If the test is
- a test of some well-defined feature, it should have a name referring to
- that feature such as 'FEATURE-1.c'. If it does not test a well-defined
- feature but just happens to exercise a bug somewhere in the compiler,
- and a bug report has been filed for this bug in the GCC bug database,
- 'prBUG-NUMBER-1.c' is the appropriate form of name. Otherwise (for
- miscellaneous bugs not filed in the GCC bug database), and previously
- more generally, test cases are named after the date on which they were
- added. This allows people to tell at a glance whether a test failure is
- because of a recently found bug that has not yet been fixed, or whether
- it may be a regression, but does not give any other information about
- the bug or where discussion of it may be found. Some other language
- testsuites follow similar conventions.
-
- In the 'gcc.dg' testsuite, it is often necessary to test that an error
- is indeed a hard error and not just a warning--for example, where it is
- a constraint violation in the C standard, which must become an error
- with '-pedantic-errors'. The following idiom, where the first line
- shown is line LINE of the file and the line that generates the error, is
- used for this:
-
- /* { dg-bogus "warning" "warning in place of error" } */
- /* { dg-error "REGEXP" "MESSAGE" { target *-*-* } LINE } */
-
- It may be necessary to check that an expression is an integer constant
- expression and has a certain value. To check that 'E' has value 'V', an
- idiom similar to the following is used:
-
- char x[((E) == (V) ? 1 : -1)];
-
- In 'gcc.dg' tests, '__typeof__' is sometimes used to make assertions
- about the types of expressions. See, for example,
- 'gcc.dg/c99-condexpr-1.c'. The more subtle uses depend on the exact
- rules for the types of conditional expressions in the C standard; see,
- for example, 'gcc.dg/c99-intconst-1.c'.
-
- It is useful to be able to test that optimizations are being made
- properly. This cannot be done in all cases, but it can be done where
- the optimization will lead to code being optimized away (for example,
- where flow analysis or alias analysis should show that certain code
- cannot be called) or to functions not being called because they have
- been expanded as built-in functions. Such tests go in
- 'gcc.c-torture/execute'. Where code should be optimized away, a call to
- a nonexistent function such as 'link_failure ()' may be inserted; a
- definition
-
- #ifndef __OPTIMIZE__
- void
- link_failure (void)
- {
- abort ();
- }
- #endif
-
- will also be needed so that linking still succeeds when the test is run
- without optimization. When all calls to a built-in function should have
- been optimized and no calls to the non-built-in version of the function
- should remain, that function may be defined as 'static' to call 'abort
- ()' (although redeclaring a function as static may not work on all
- targets).
-
- All testcases must be portable. Target-specific testcases must have
- appropriate code to avoid causing failures on unsupported systems;
- unfortunately, the mechanisms for this differ by directory.
-
- FIXME: discuss non-C testsuites here.
-
-
- File: gccint.info, Node: Test Directives, Next: Ada Tests, Prev: Test Idioms, Up: Testsuites
-
- 7.2 Directives used within DejaGnu tests
- ========================================
-
- * Menu:
-
- * Directives:: Syntax and descriptions of test directives.
- * Selectors:: Selecting targets to which a test applies.
- * Effective-Target Keywords:: Keywords describing target attributes.
- * Add Options:: Features for 'dg-add-options'
- * Require Support:: Variants of 'dg-require-SUPPORT'
- * Final Actions:: Commands for use in 'dg-final'
-
-
- File: gccint.info, Node: Directives, Next: Selectors, Up: Test Directives
-
- 7.2.1 Syntax and Descriptions of test directives
- ------------------------------------------------
-
- Test directives appear within comments in a test source file and begin
- with 'dg-'. Some of these are defined within DejaGnu and others are
- local to the GCC testsuite.
-
- The order in which test directives appear in a test can be important:
- directives local to GCC sometimes override information used by the
- DejaGnu directives, which know nothing about the GCC directives, so the
- DejaGnu directives must precede GCC directives.
-
- Several test directives include selectors (*note Selectors::) which are
- usually preceded by the keyword 'target' or 'xfail'.
-
- 7.2.1.1 Specify how to build the test
- .....................................
-
- '{ dg-do DO-WHAT-KEYWORD [{ target/xfail SELECTOR }] }'
- DO-WHAT-KEYWORD specifies how the test is compiled and whether it
- is executed. It is one of:
-
- 'preprocess'
- Compile with '-E' to run only the preprocessor.
- 'compile'
- Compile with '-S' to produce an assembly code file.
- 'assemble'
- Compile with '-c' to produce a relocatable object file.
- 'link'
- Compile, assemble, and link to produce an executable file.
- 'run'
- Produce and run an executable file, which is expected to
- return an exit code of 0.
-
- The default is 'compile'. That can be overridden for a set of
- tests by redefining 'dg-do-what-default' within the '.exp' file for
- those tests.
-
- If the directive includes the optional '{ target SELECTOR }' then
- the test is skipped unless the target system matches the SELECTOR.
-
- If DO-WHAT-KEYWORD is 'run' and the directive includes the optional
- '{ xfail SELECTOR }' and the selector is met then the test is
- expected to fail. The 'xfail' clause is ignored for other values
- of DO-WHAT-KEYWORD; those tests can use directive 'dg-xfail-if'.
-
- 7.2.1.2 Specify additional compiler options
- ...........................................
-
- '{ dg-options OPTIONS [{ target SELECTOR }] }'
- This DejaGnu directive provides a list of compiler options, to be
- used if the target system matches SELECTOR, that replace the
- default options used for this set of tests.
-
- '{ dg-add-options FEATURE ... }'
- Add any compiler options that are needed to access certain
- features. This directive does nothing on targets that enable the
- features by default, or that don't provide them at all. It must
- come after all 'dg-options' directives. For supported values of
- FEATURE see *note Add Options::.
-
- '{ dg-additional-options OPTIONS [{ target SELECTOR }] }'
- This directive provides a list of compiler options, to be used if
- the target system matches SELECTOR, that are added to the default
- options used for this set of tests.
-
- 7.2.1.3 Modify the test timeout value
- .....................................
-
- The normal timeout limit, in seconds, is found by searching the
- following in order:
-
- * the value defined by an earlier 'dg-timeout' directive in the test
-
- * variable TOOL_TIMEOUT defined by the set of tests
-
- * GCC,TIMEOUT set in the target board
-
- * 300
-
- '{ dg-timeout N [{target SELECTOR }] }'
- Set the time limit for the compilation and for the execution of the
- test to the specified number of seconds.
-
- '{ dg-timeout-factor X [{ target SELECTOR }] }'
- Multiply the normal time limit for compilation and execution of the
- test by the specified floating-point factor.
-
- 7.2.1.4 Skip a test for some targets
- ....................................
-
- '{ dg-skip-if COMMENT { SELECTOR } [{ INCLUDE-OPTS } [{ EXCLUDE-OPTS }]] }'
- Arguments INCLUDE-OPTS and EXCLUDE-OPTS are lists in which each
- element is a string of zero or more GCC options. Skip the test if
- all of the following conditions are met:
- * the test system is included in SELECTOR
-
- * for at least one of the option strings in INCLUDE-OPTS, every
- option from that string is in the set of options with which
- the test would be compiled; use '"*"' for an INCLUDE-OPTS list
- that matches any options; that is the default if INCLUDE-OPTS
- is not specified
-
- * for each of the option strings in EXCLUDE-OPTS, at least one
- option from that string is not in the set of options with
- which the test would be compiled; use '""' for an empty
- EXCLUDE-OPTS list; that is the default if EXCLUDE-OPTS is not
- specified
-
- For example, to skip a test if option '-Os' is present:
-
- /* { dg-skip-if "" { *-*-* } { "-Os" } { "" } } */
-
- To skip a test if both options '-O2' and '-g' are present:
-
- /* { dg-skip-if "" { *-*-* } { "-O2 -g" } { "" } } */
-
- To skip a test if either '-O2' or '-O3' is present:
-
- /* { dg-skip-if "" { *-*-* } { "-O2" "-O3" } { "" } } */
-
- To skip a test unless option '-Os' is present:
-
- /* { dg-skip-if "" { *-*-* } { "*" } { "-Os" } } */
-
- To skip a test if either '-O2' or '-O3' is used with '-g' but not
- if '-fpic' is also present:
-
- /* { dg-skip-if "" { *-*-* } { "-O2 -g" "-O3 -g" } { "-fpic" } } */
-
- '{ dg-require-effective-target KEYWORD [{ SELECTOR }] }'
- Skip the test if the test target, including current multilib flags,
- is not covered by the effective-target keyword. If the directive
- includes the optional '{ SELECTOR }' then the effective-target test
- is only performed if the target system matches the SELECTOR. This
- directive must appear after any 'dg-do' directive in the test and
- before any 'dg-additional-sources' directive. *Note
- Effective-Target Keywords::.
-
- '{ dg-require-SUPPORT args }'
- Skip the test if the target does not provide the required support.
- These directives must appear after any 'dg-do' directive in the
- test and before any 'dg-additional-sources' directive. They
- require at least one argument, which can be an empty string if the
- specific procedure does not examine the argument. *Note Require
- Support::, for a complete list of these directives.
-
- 7.2.1.5 Expect a test to fail for some targets
- ..............................................
-
- '{ dg-xfail-if COMMENT { SELECTOR } [{ INCLUDE-OPTS } [{ EXCLUDE-OPTS }]] }'
- Expect the test to fail if the conditions (which are the same as
- for 'dg-skip-if') are met. This does not affect the execute step.
-
- '{ dg-xfail-run-if COMMENT { SELECTOR } [{ INCLUDE-OPTS } [{ EXCLUDE-OPTS }]] }'
- Expect the execute step of a test to fail if the conditions (which
- are the same as for 'dg-skip-if') are met.
-
- 7.2.1.6 Expect the test executable to fail
- ..........................................
-
- '{ dg-shouldfail COMMENT [{ SELECTOR } [{ INCLUDE-OPTS } [{ EXCLUDE-OPTS }]]] }'
- Expect the test executable to return a nonzero exit status if the
- conditions (which are the same as for 'dg-skip-if') are met.
-
- 7.2.1.7 Verify compiler messages
- ................................
-
- Where LINE is an accepted argument for these commands, a value of '0'
- can be used if there is no line associated with the message.
-
- '{ dg-error REGEXP [COMMENT [{ target/xfail SELECTOR } [LINE] ]] }'
- This DejaGnu directive appears on a source line that is expected to
- get an error message, or else specifies the source line associated
- with the message. If there is no message for that line or if the
- text of that message is not matched by REGEXP then the check fails
- and COMMENT is included in the 'FAIL' message. The check does not
- look for the string 'error' unless it is part of REGEXP.
-
- '{ dg-warning REGEXP [COMMENT [{ target/xfail SELECTOR } [LINE] ]] }'
- This DejaGnu directive appears on a source line that is expected to
- get a warning message, or else specifies the source line associated
- with the message. If there is no message for that line or if the
- text of that message is not matched by REGEXP then the check fails
- and COMMENT is included in the 'FAIL' message. The check does not
- look for the string 'warning' unless it is part of REGEXP.
-
- '{ dg-message REGEXP [COMMENT [{ target/xfail SELECTOR } [LINE] ]] }'
- The line is expected to get a message other than an error or
- warning. If there is no message for that line or if the text of
- that message is not matched by REGEXP then the check fails and
- COMMENT is included in the 'FAIL' message.
-
- '{ dg-bogus REGEXP [COMMENT [{ target/xfail SELECTOR } [LINE] ]] }'
- This DejaGnu directive appears on a source line that should not get
- a message matching REGEXP, or else specifies the source line
- associated with the bogus message. It is usually used with 'xfail'
- to indicate that the message is a known problem for a particular
- set of targets.
-
- '{ dg-line LINENUMVAR }'
- This DejaGnu directive sets the variable LINENUMVAR to the line
- number of the source line. The variable LINENUMVAR can then be
- used in subsequent 'dg-error', 'dg-warning', 'dg-message' and
- 'dg-bogus' directives. For example:
-
- int a; /* { dg-line first_def_a } */
- float a; /* { dg-error "conflicting types of" } */
- /* { dg-message "previous declaration of" "" { target *-*-* } first_def_a } */
-
- '{ dg-excess-errors COMMENT [{ target/xfail SELECTOR }] }'
- This DejaGnu directive indicates that the test is expected to fail
- due to compiler messages that are not handled by 'dg-error',
- 'dg-warning' or 'dg-bogus'. For this directive 'xfail' has the
- same effect as 'target'.
-
- '{ dg-prune-output REGEXP }'
- Prune messages matching REGEXP from the test output.
-
- 7.2.1.8 Verify output of the test executable
- ............................................
-
- '{ dg-output REGEXP [{ target/xfail SELECTOR }] }'
- This DejaGnu directive compares REGEXP to the combined output that
- the test executable writes to 'stdout' and 'stderr'.
-
- 7.2.1.9 Specify environment variables for a test
- ................................................
-
- '{ dg-set-compiler-env-var VAR_NAME "VAR_VALUE" }'
- Specify that the environment variable VAR_NAME needs to be set to
- VAR_VALUE before invoking the compiler on the test file.
-
- '{ dg-set-target-env-var VAR_NAME "VAR_VALUE" }'
- Specify that the environment variable VAR_NAME needs to be set to
- VAR_VALUE before execution of the program created by the test.
-
- 7.2.1.10 Specify additional files for a test
- ............................................
-
- '{ dg-additional-files "FILELIST" }'
- Specify additional files, other than source files, that must be
- copied to the system where the compiler runs.
-
- '{ dg-additional-sources "FILELIST" }'
- Specify additional source files to appear in the compile line
- following the main test file.
-
- 7.2.1.11 Add checks at the end of a test
- ........................................
-
- '{ dg-final { LOCAL-DIRECTIVE } }'
- This DejaGnu directive is placed within a comment anywhere in the
- source file and is processed after the test has been compiled and
- run. Multiple 'dg-final' commands are processed in the order in
- which they appear in the source file. *Note Final Actions::, for a
- list of directives that can be used within 'dg-final'.
-
-
- File: gccint.info, Node: Selectors, Next: Effective-Target Keywords, Prev: Directives, Up: Test Directives
-
- 7.2.2 Selecting targets to which a test applies
- -----------------------------------------------
-
- Several test directives include SELECTORs to limit the targets for which
- a test is run or to declare that a test is expected to fail on
- particular targets.
-
- A selector is:
- * one or more target triplets, possibly including wildcard
- characters; use '*-*-*' to match any target
- * a single effective-target keyword (*note Effective-Target
- Keywords::)
- * a logical expression
-
- Depending on the context, the selector specifies whether a test is
- skipped and reported as unsupported or is expected to fail. A context
- that allows either 'target' or 'xfail' also allows '{ target SELECTOR1
- xfail SELECTOR2 }' to skip the test for targets that don't match
- SELECTOR1 and the test to fail for targets that match SELECTOR2.
-
- A selector expression appears within curly braces and uses a single
- logical operator: one of '!', '&&', or '||'. An operand is another
- selector expression, an effective-target keyword, a single target
- triplet, or a list of target triplets within quotes or curly braces.
- For example:
-
- { target { ! "hppa*-*-* ia64*-*-*" } }
- { target { powerpc*-*-* && lp64 } }
- { xfail { lp64 || vect_no_align } }
-
-
- File: gccint.info, Node: Effective-Target Keywords, Next: Add Options, Prev: Selectors, Up: Test Directives
-
- 7.2.3 Keywords describing target attributes
- -------------------------------------------
-
- Effective-target keywords identify sets of targets that support
- particular functionality. They are used to limit tests to be run only
- for particular targets, or to specify that particular sets of targets
- are expected to fail some tests.
-
- Effective-target keywords are defined in 'lib/target-supports.exp' in
- the GCC testsuite, with the exception of those that are documented as
- being local to a particular test directory.
-
- The 'effective target' takes into account all of the compiler options
- with which the test will be compiled, including the multilib options.
- By convention, keywords ending in '_nocache' can also include options
- specified for the particular test in an earlier 'dg-options' or
- 'dg-add-options' directive.
-
- 7.2.3.1 Endianness
- ..................
-
- 'be'
- Target uses big-endian memory order for multi-byte and multi-word
- data.
-
- 'le'
- Target uses little-endian memory order for multi-byte and
- multi-word data.
-
- 7.2.3.2 Data type sizes
- .......................
-
- 'ilp32'
- Target has 32-bit 'int', 'long', and pointers.
-
- 'lp64'
- Target has 32-bit 'int', 64-bit 'long' and pointers.
-
- 'llp64'
- Target has 32-bit 'int' and 'long', 64-bit 'long long' and
- pointers.
-
- 'double64'
- Target has 64-bit 'double'.
-
- 'double64plus'
- Target has 'double' that is 64 bits or longer.
-
- 'longdouble128'
- Target has 128-bit 'long double'.
-
- 'int32plus'
- Target has 'int' that is at 32 bits or longer.
-
- 'int16'
- Target has 'int' that is 16 bits or shorter.
-
- 'longlong64'
- Target has 64-bit 'long long'.
-
- 'long_neq_int'
- Target has 'int' and 'long' with different sizes.
-
- 'int_eq_float'
- Target has 'int' and 'float' with the same size.
-
- 'ptr_eq_long'
- Target has pointers ('void *') and 'long' with the same size.
-
- 'large_double'
- Target supports 'double' that is longer than 'float'.
-
- 'large_long_double'
- Target supports 'long double' that is longer than 'double'.
-
- 'ptr32plus'
- Target has pointers that are 32 bits or longer.
-
- 'size20plus'
- Target has a 20-bit or larger address space, so at least supports
- 16-bit array and structure sizes.
-
- 'size32plus'
- Target has a 32-bit or larger address space, so at least supports
- 24-bit array and structure sizes.
-
- '4byte_wchar_t'
- Target has 'wchar_t' that is at least 4 bytes.
-
- 'floatN'
- Target has the '_FloatN' type.
-
- 'floatNx'
- Target has the '_FloatNx' type.
-
- 'floatN_runtime'
- Target has the '_FloatN' type, including runtime support for any
- options added with 'dg-add-options'.
-
- 'floatNx_runtime'
- Target has the '_FloatNx' type, including runtime support for any
- options added with 'dg-add-options'.
-
- 'floatn_nx_runtime'
- Target has runtime support for any options added with
- 'dg-add-options' for any '_FloatN' or '_FloatNx' type.
-
- 'inf'
- Target supports floating point infinite ('inf') for type 'double'.
-
- 7.2.3.3 Fortran-specific attributes
- ...................................
-
- 'fortran_integer_16'
- Target supports Fortran 'integer' that is 16 bytes or longer.
-
- 'fortran_real_10'
- Target supports Fortran 'real' that is 10 bytes or longer.
-
- 'fortran_real_16'
- Target supports Fortran 'real' that is 16 bytes or longer.
-
- 'fortran_large_int'
- Target supports Fortran 'integer' kinds larger than 'integer(8)'.
-
- 'fortran_large_real'
- Target supports Fortran 'real' kinds larger than 'real(8)'.
-
- 7.2.3.4 Vector-specific attributes
- ..................................
-
- 'vect_align_stack_vars'
- The target's ABI allows stack variables to be aligned to the
- preferred vector alignment.
-
- 'vect_avg_qi'
- Target supports both signed and unsigned averaging operations on
- vectors of bytes.
-
- 'vect_mulhrs_hi'
- Target supports both signed and unsigned
- multiply-high-with-round-and-scale operations on vectors of
- half-words.
-
- 'vect_sdiv_pow2_si'
- Target supports signed division by constant power-of-2 operations
- on vectors of 4-byte integers.
-
- 'vect_condition'
- Target supports vector conditional operations.
-
- 'vect_cond_mixed'
- Target supports vector conditional operations where comparison
- operands have different type from the value operands.
-
- 'vect_double'
- Target supports hardware vectors of 'double'.
-
- 'vect_double_cond_arith'
- Target supports conditional addition, subtraction, multiplication,
- division, minimum and maximum on vectors of 'double', via the
- 'cond_' optabs.
-
- 'vect_element_align_preferred'
- The target's preferred vector alignment is the same as the element
- alignment.
-
- 'vect_float'
- Target supports hardware vectors of 'float' when
- '-funsafe-math-optimizations' is in effect.
-
- 'vect_float_strict'
- Target supports hardware vectors of 'float' when
- '-funsafe-math-optimizations' is not in effect. This implies
- 'vect_float'.
-
- 'vect_int'
- Target supports hardware vectors of 'int'.
-
- 'vect_long'
- Target supports hardware vectors of 'long'.
-
- 'vect_long_long'
- Target supports hardware vectors of 'long long'.
-
- 'vect_check_ptrs'
- Target supports the 'check_raw_ptrs' and 'check_war_ptrs' optabs on
- vectors.
-
- 'vect_fully_masked'
- Target supports fully-masked (also known as fully-predicated)
- loops, so that vector loops can handle partial as well as full
- vectors.
-
- 'vect_masked_store'
- Target supports vector masked stores.
-
- 'vect_scatter_store'
- Target supports vector scatter stores.
-
- 'vect_aligned_arrays'
- Target aligns arrays to vector alignment boundary.
-
- 'vect_hw_misalign'
- Target supports a vector misalign access.
-
- 'vect_no_align'
- Target does not support a vector alignment mechanism.
-
- 'vect_peeling_profitable'
- Target might require to peel loops for alignment purposes.
-
- 'vect_no_int_min_max'
- Target does not support a vector min and max instruction on 'int'.
-
- 'vect_no_int_add'
- Target does not support a vector add instruction on 'int'.
-
- 'vect_no_bitwise'
- Target does not support vector bitwise instructions.
-
- 'vect_bool_cmp'
- Target supports comparison of 'bool' vectors for at least one
- vector length.
-
- 'vect_char_add'
- Target supports addition of 'char' vectors for at least one vector
- length.
-
- 'vect_char_mult'
- Target supports 'vector char' multiplication.
-
- 'vect_short_mult'
- Target supports 'vector short' multiplication.
-
- 'vect_int_mult'
- Target supports 'vector int' multiplication.
-
- 'vect_long_mult'
- Target supports 64 bit 'vector long' multiplication.
-
- 'vect_extract_even_odd'
- Target supports vector even/odd element extraction.
-
- 'vect_extract_even_odd_wide'
- Target supports vector even/odd element extraction of vectors with
- elements 'SImode' or larger.
-
- 'vect_interleave'
- Target supports vector interleaving.
-
- 'vect_strided'
- Target supports vector interleaving and extract even/odd.
-
- 'vect_strided_wide'
- Target supports vector interleaving and extract even/odd for wide
- element types.
-
- 'vect_perm'
- Target supports vector permutation.
-
- 'vect_perm_byte'
- Target supports permutation of vectors with 8-bit elements.
-
- 'vect_perm_short'
- Target supports permutation of vectors with 16-bit elements.
-
- 'vect_perm3_byte'
- Target supports permutation of vectors with 8-bit elements, and for
- the default vector length it is possible to permute:
- { a0, a1, a2, b0, b1, b2, ... }
- to:
- { a0, a0, a0, b0, b0, b0, ... }
- { a1, a1, a1, b1, b1, b1, ... }
- { a2, a2, a2, b2, b2, b2, ... }
- using only two-vector permutes, regardless of how long the sequence
- is.
-
- 'vect_perm3_int'
- Like 'vect_perm3_byte', but for 32-bit elements.
-
- 'vect_perm3_short'
- Like 'vect_perm3_byte', but for 16-bit elements.
-
- 'vect_shift'
- Target supports a hardware vector shift operation.
-
- 'vect_unaligned_possible'
- Target prefers vectors to have an alignment greater than element
- alignment, but also allows unaligned vector accesses in some
- circumstances.
-
- 'vect_variable_length'
- Target has variable-length vectors.
-
- 'vect_widen_sum_hi_to_si'
- Target supports a vector widening summation of 'short' operands
- into 'int' results, or can promote (unpack) from 'short' to 'int'.
-
- 'vect_widen_sum_qi_to_hi'
- Target supports a vector widening summation of 'char' operands into
- 'short' results, or can promote (unpack) from 'char' to 'short'.
-
- 'vect_widen_sum_qi_to_si'
- Target supports a vector widening summation of 'char' operands into
- 'int' results.
-
- 'vect_widen_mult_qi_to_hi'
- Target supports a vector widening multiplication of 'char' operands
- into 'short' results, or can promote (unpack) from 'char' to
- 'short' and perform non-widening multiplication of 'short'.
-
- 'vect_widen_mult_hi_to_si'
- Target supports a vector widening multiplication of 'short'
- operands into 'int' results, or can promote (unpack) from 'short'
- to 'int' and perform non-widening multiplication of 'int'.
-
- 'vect_widen_mult_si_to_di_pattern'
- Target supports a vector widening multiplication of 'int' operands
- into 'long' results.
-
- 'vect_sdot_qi'
- Target supports a vector dot-product of 'signed char'.
-
- 'vect_udot_qi'
- Target supports a vector dot-product of 'unsigned char'.
-
- 'vect_sdot_hi'
- Target supports a vector dot-product of 'signed short'.
-
- 'vect_udot_hi'
- Target supports a vector dot-product of 'unsigned short'.
-
- 'vect_pack_trunc'
- Target supports a vector demotion (packing) of 'short' to 'char'
- and from 'int' to 'short' using modulo arithmetic.
-
- 'vect_unpack'
- Target supports a vector promotion (unpacking) of 'char' to 'short'
- and from 'char' to 'int'.
-
- 'vect_intfloat_cvt'
- Target supports conversion from 'signed int' to 'float'.
-
- 'vect_uintfloat_cvt'
- Target supports conversion from 'unsigned int' to 'float'.
-
- 'vect_floatint_cvt'
- Target supports conversion from 'float' to 'signed int'.
-
- 'vect_floatuint_cvt'
- Target supports conversion from 'float' to 'unsigned int'.
-
- 'vect_intdouble_cvt'
- Target supports conversion from 'signed int' to 'double'.
-
- 'vect_doubleint_cvt'
- Target supports conversion from 'double' to 'signed int'.
-
- 'vect_max_reduc'
- Target supports max reduction for vectors.
-
- 'vect_sizes_16B_8B'
- Target supports 16- and 8-bytes vectors.
-
- 'vect_sizes_32B_16B'
- Target supports 32- and 16-bytes vectors.
-
- 'vect_logical_reduc'
- Target supports AND, IOR and XOR reduction on vectors.
-
- 'vect_fold_extract_last'
- Target supports the 'fold_extract_last' optab.
-
- 7.2.3.5 Thread Local Storage attributes
- .......................................
-
- 'tls'
- Target supports thread-local storage.
-
- 'tls_native'
- Target supports native (rather than emulated) thread-local storage.
-
- 'tls_runtime'
- Test system supports executing TLS executables.
-
- 7.2.3.6 Decimal floating point attributes
- .........................................
-
- 'dfp'
- Targets supports compiling decimal floating point extension to C.
-
- 'dfp_nocache'
- Including the options used to compile this particular test, the
- target supports compiling decimal floating point extension to C.
-
- 'dfprt'
- Test system can execute decimal floating point tests.
-
- 'dfprt_nocache'
- Including the options used to compile this particular test, the
- test system can execute decimal floating point tests.
-
- 'hard_dfp'
- Target generates decimal floating point instructions with current
- options.
-
- 7.2.3.7 ARM-specific attributes
- ...............................
-
- 'arm32'
- ARM target generates 32-bit code.
-
- 'arm_little_endian'
- ARM target that generates little-endian code.
-
- 'arm_eabi'
- ARM target adheres to the ABI for the ARM Architecture.
-
- 'arm_fp_ok'
- ARM target defines '__ARM_FP' using '-mfloat-abi=softfp' or
- equivalent options. Some multilibs may be incompatible with these
- options.
-
- 'arm_fp_dp_ok'
- ARM target defines '__ARM_FP' with double-precision support using
- '-mfloat-abi=softfp' or equivalent options. Some multilibs may be
- incompatible with these options.
-
- 'arm_hf_eabi'
- ARM target adheres to the VFP and Advanced SIMD Register Arguments
- variant of the ABI for the ARM Architecture (as selected with
- '-mfloat-abi=hard').
-
- 'arm_softfloat'
- ARM target uses the soft-float ABI with no floating-point
- instructions used whatsoever (as selected with '-mfloat-abi=soft').
-
- 'arm_hard_vfp_ok'
- ARM target supports '-mfpu=vfp -mfloat-abi=hard'. Some multilibs
- may be incompatible with these options.
-
- 'arm_iwmmxt_ok'
- ARM target supports '-mcpu=iwmmxt'. Some multilibs may be
- incompatible with this option.
-
- 'arm_neon'
- ARM target supports generating NEON instructions.
-
- 'arm_tune_string_ops_prefer_neon'
- Test CPU tune supports inlining string operations with NEON
- instructions.
-
- 'arm_neon_hw'
- Test system supports executing NEON instructions.
-
- 'arm_neonv2_hw'
- Test system supports executing NEON v2 instructions.
-
- 'arm_neon_ok'
- ARM Target supports '-mfpu=neon -mfloat-abi=softfp' or compatible
- options. Some multilibs may be incompatible with these options.
-
- 'arm_neon_ok_no_float_abi'
- ARM Target supports NEON with '-mfpu=neon', but without any
- -mfloat-abi= option. Some multilibs may be incompatible with this
- option.
-
- 'arm_neonv2_ok'
- ARM Target supports '-mfpu=neon-vfpv4 -mfloat-abi=softfp' or
- compatible options. Some multilibs may be incompatible with these
- options.
-
- 'arm_fp16_ok'
- Target supports options to generate VFP half-precision
- floating-point instructions. Some multilibs may be incompatible
- with these options. This test is valid for ARM only.
-
- 'arm_fp16_hw'
- Target supports executing VFP half-precision floating-point
- instructions. This test is valid for ARM only.
-
- 'arm_neon_fp16_ok'
- ARM Target supports '-mfpu=neon-fp16 -mfloat-abi=softfp' or
- compatible options, including '-mfp16-format=ieee' if necessary to
- obtain the '__fp16' type. Some multilibs may be incompatible with
- these options.
-
- 'arm_neon_fp16_hw'
- Test system supports executing Neon half-precision float
- instructions. (Implies previous.)
-
- 'arm_fp16_alternative_ok'
- ARM target supports the ARM FP16 alternative format. Some
- multilibs may be incompatible with the options needed.
-
- 'arm_fp16_none_ok'
- ARM target supports specifying none as the ARM FP16 format.
-
- 'arm_thumb1_ok'
- ARM target generates Thumb-1 code for '-mthumb'.
-
- 'arm_thumb2_ok'
- ARM target generates Thumb-2 code for '-mthumb'.
-
- 'arm_nothumb'
- ARM target that is not using Thumb.
-
- 'arm_vfp_ok'
- ARM target supports '-mfpu=vfp -mfloat-abi=softfp'. Some multilibs
- may be incompatible with these options.
-
- 'arm_vfp3_ok'
- ARM target supports '-mfpu=vfp3 -mfloat-abi=softfp'. Some
- multilibs may be incompatible with these options.
-
- 'arm_arch_v8a_hard_ok'
- The compiler is targeting 'arm*-*-*' and can compile and assemble
- code using the options '-march=armv8-a -mfpu=neon-fp-armv8
- -mfloat-abi=hard'. This is not enough to guarantee that linking
- works.
-
- 'arm_arch_v8a_hard_multilib'
- The compiler is targeting 'arm*-*-*' and can build programs using
- the options '-march=armv8-a -mfpu=neon-fp-armv8 -mfloat-abi=hard'.
- The target can also run the resulting binaries.
-
- 'arm_v8_vfp_ok'
- ARM target supports '-mfpu=fp-armv8 -mfloat-abi=softfp'. Some
- multilibs may be incompatible with these options.
-
- 'arm_v8_neon_ok'
- ARM target supports '-mfpu=neon-fp-armv8 -mfloat-abi=softfp'. Some
- multilibs may be incompatible with these options.
-
- 'arm_v8_1a_neon_ok'
- ARM target supports options to generate ARMv8.1-A Adv.SIMD
- instructions. Some multilibs may be incompatible with these
- options.
-
- 'arm_v8_1a_neon_hw'
- ARM target supports executing ARMv8.1-A Adv.SIMD instructions.
- Some multilibs may be incompatible with the options needed.
- Implies arm_v8_1a_neon_ok.
-
- 'arm_acq_rel'
- ARM target supports acquire-release instructions.
-
- 'arm_v8_2a_fp16_scalar_ok'
- ARM target supports options to generate instructions for ARMv8.2-A
- and scalar instructions from the FP16 extension. Some multilibs
- may be incompatible with these options.
-
- 'arm_v8_2a_fp16_scalar_hw'
- ARM target supports executing instructions for ARMv8.2-A and scalar
- instructions from the FP16 extension. Some multilibs may be
- incompatible with these options. Implies arm_v8_2a_fp16_neon_ok.
-
- 'arm_v8_2a_fp16_neon_ok'
- ARM target supports options to generate instructions from ARMv8.2-A
- with the FP16 extension. Some multilibs may be incompatible with
- these options. Implies arm_v8_2a_fp16_scalar_ok.
-
- 'arm_v8_2a_fp16_neon_hw'
- ARM target supports executing instructions from ARMv8.2-A with the
- FP16 extension. Some multilibs may be incompatible with these
- options. Implies arm_v8_2a_fp16_neon_ok and
- arm_v8_2a_fp16_scalar_hw.
-
- 'arm_v8_2a_dotprod_neon_ok'
- ARM target supports options to generate instructions from ARMv8.2-A
- with the Dot Product extension. Some multilibs may be incompatible
- with these options.
-
- 'arm_v8_2a_dotprod_neon_hw'
- ARM target supports executing instructions from ARMv8.2-A with the
- Dot Product extension. Some multilibs may be incompatible with
- these options. Implies arm_v8_2a_dotprod_neon_ok.
-
- 'arm_fp16fml_neon_ok'
- ARM target supports extensions to generate the 'VFMAL' and 'VFMLS'
- half-precision floating-point instructions available from ARMv8.2-A
- and onwards. Some multilibs may be incompatible with these
- options.
-
- 'arm_v8_2a_bf16_neon_ok'
- ARM target supports options to generate instructions from ARMv8.2-A
- with the BFloat16 extension (bf16). Some multilibs may be
- incompatible with these options.
-
- 'arm_v8_2a_i8mm_ok'
- ARM target supports options to generate instructions from ARMv8.2-A
- with the 8-Bit Integer Matrix Multiply extension (i8mm). Some
- multilibs may be incompatible with these options.
-
- 'arm_v8_1m_mve_ok'
- ARM target supports options to generate instructions from ARMv8.1-M
- with the M-Profile Vector Extension (MVE). Some multilibs may be
- incompatible with these options.
-
- 'arm_v8_1m_mve_fp_ok'
- ARM target supports options to generate instructions from ARMv8.1-M
- with the Half-precision floating-point instructions (HP),
- Floating-point Extension (FP) along with M-Profile Vector Extension
- (MVE). Some multilibs may be incompatible with these options.
-
- 'arm_mve_hw'
- Test system supports executing MVE instructions.
-
- 'arm_v8m_main_cde'
- ARM target supports options to generate instructions from ARMv8-M
- with the Custom Datapath Extension (CDE). Some multilibs may be
- incompatible with these options.
-
- 'arm_v8m_main_cde_fp'
- ARM target supports options to generate instructions from ARMv8-M
- with the Custom Datapath Extension (CDE) and floating-point (VFP).
- Some multilibs may be incompatible with these options.
-
- 'arm_v8_1m_main_cde_mve'
- ARM target supports options to generate instructions from ARMv8.1-M
- with the Custom Datapath Extension (CDE) and M-Profile Vector
- Extension (MVE). Some multilibs may be incompatible with these
- options.
-
- 'arm_prefer_ldrd_strd'
- ARM target prefers 'LDRD' and 'STRD' instructions over 'LDM' and
- 'STM' instructions.
-
- 'arm_thumb1_movt_ok'
- ARM target generates Thumb-1 code for '-mthumb' with 'MOVW' and
- 'MOVT' instructions available.
-
- 'arm_thumb1_cbz_ok'
- ARM target generates Thumb-1 code for '-mthumb' with 'CBZ' and
- 'CBNZ' instructions available.
-
- 'arm_divmod_simode'
- ARM target for which divmod transform is disabled, if it supports
- hardware div instruction.
-
- 'arm_cmse_ok'
- ARM target supports ARMv8-M Security Extensions, enabled by the
- '-mcmse' option.
-
- 'arm_coproc1_ok'
- ARM target supports the following coprocessor instructions: 'CDP',
- 'LDC', 'STC', 'MCR' and 'MRC'.
-
- 'arm_coproc2_ok'
- ARM target supports all the coprocessor instructions also listed as
- supported in *note arm_coproc1_ok:: in addition to the following:
- 'CDP2', 'LDC2', 'LDC2l', 'STC2', 'STC2l', 'MCR2' and 'MRC2'.
-
- 'arm_coproc3_ok'
- ARM target supports all the coprocessor instructions also listed as
- supported in *note arm_coproc2_ok:: in addition the following:
- 'MCRR' and 'MRRC'.
-
- 'arm_coproc4_ok'
- ARM target supports all the coprocessor instructions also listed as
- supported in *note arm_coproc3_ok:: in addition the following:
- 'MCRR2' and 'MRRC2'.
-
- 'arm_simd32_ok'
- ARM Target supports options suitable for accessing the SIMD32
- intrinsics from 'arm_acle.h'. Some multilibs may be incompatible
- with these options.
-
- 'arm_qbit_ok'
- ARM Target supports options suitable for accessing the Q-bit
- manipulation intrinsics from 'arm_acle.h'. Some multilibs may be
- incompatible with these options.
-
- 'arm_softfp_ok'
- ARM target supports the '-mfloat-abi=softfp' option.
-
- 'arm_hard_ok'
- ARM target supports the '-mfloat-abi=hard' option.
-
- 7.2.3.8 AArch64-specific attributes
- ...................................
-
- 'aarch64_asm_<ext>_ok'
- AArch64 assembler supports the architecture extension 'ext' via the
- '.arch_extension' pseudo-op.
- 'aarch64_tiny'
- AArch64 target which generates instruction sequences for tiny
- memory model.
- 'aarch64_small'
- AArch64 target which generates instruction sequences for small
- memory model.
- 'aarch64_large'
- AArch64 target which generates instruction sequences for large
- memory model.
- 'aarch64_little_endian'
- AArch64 target which generates instruction sequences for little
- endian.
- 'aarch64_big_endian'
- AArch64 target which generates instruction sequences for big
- endian.
- 'aarch64_small_fpic'
- Binutils installed on test system supports relocation types
- required by -fpic for AArch64 small memory model.
- 'aarch64_sve_hw'
- AArch64 target that is able to generate and execute SVE code
- (regardless of whether it does so by default).
- 'aarch64_sve128_hw'
- 'aarch64_sve256_hw'
- 'aarch64_sve512_hw'
- 'aarch64_sve1024_hw'
- 'aarch64_sve2048_hw'
- Like 'aarch64_sve_hw', but also test for an exact hardware vector
- length.
-
- 'aarch64_fjcvtzs_hw'
- AArch64 target that is able to generate and execute armv8.3-a
- FJCVTZS instruction.
-
- 7.2.3.9 MIPS-specific attributes
- ................................
-
- 'mips64'
- MIPS target supports 64-bit instructions.
-
- 'nomips16'
- MIPS target does not produce MIPS16 code.
-
- 'mips16_attribute'
- MIPS target can generate MIPS16 code.
-
- 'mips_loongson'
- MIPS target is a Loongson-2E or -2F target using an ABI that
- supports the Loongson vector modes.
-
- 'mips_msa'
- MIPS target supports '-mmsa', MIPS SIMD Architecture (MSA).
-
- 'mips_newabi_large_long_double'
- MIPS target supports 'long double' larger than 'double' when using
- the new ABI.
-
- 'mpaired_single'
- MIPS target supports '-mpaired-single'.
-
- 7.2.3.10 PowerPC-specific attributes
- ....................................
-
- 'dfp_hw'
- PowerPC target supports executing hardware DFP instructions.
-
- 'p8vector_hw'
- PowerPC target supports executing VSX instructions (ISA 2.07).
-
- 'powerpc64'
- Test system supports executing 64-bit instructions.
-
- 'powerpc_altivec'
- PowerPC target supports AltiVec.
-
- 'powerpc_altivec_ok'
- PowerPC target supports '-maltivec'.
-
- 'powerpc_eabi_ok'
- PowerPC target supports '-meabi'.
-
- 'powerpc_elfv2'
- PowerPC target supports '-mabi=elfv2'.
-
- 'powerpc_fprs'
- PowerPC target supports floating-point registers.
-
- 'powerpc_hard_double'
- PowerPC target supports hardware double-precision floating-point.
-
- 'powerpc_htm_ok'
- PowerPC target supports '-mhtm'
-
- 'powerpc_p8vector_ok'
- PowerPC target supports '-mpower8-vector'
-
- 'powerpc_popcntb_ok'
- PowerPC target supports the 'popcntb' instruction, indicating that
- this target supports '-mcpu=power5'.
-
- 'powerpc_ppu_ok'
- PowerPC target supports '-mcpu=cell'.
-
- 'powerpc_spe'
- PowerPC target supports PowerPC SPE.
-
- 'powerpc_spe_nocache'
- Including the options used to compile this particular test, the
- PowerPC target supports PowerPC SPE.
-
- 'powerpc_spu'
- PowerPC target supports PowerPC SPU.
-
- 'powerpc_vsx_ok'
- PowerPC target supports '-mvsx'.
-
- 'powerpc_405_nocache'
- Including the options used to compile this particular test, the
- PowerPC target supports PowerPC 405.
-
- 'ppc_recip_hw'
- PowerPC target supports executing reciprocal estimate instructions.
-
- 'vmx_hw'
- PowerPC target supports executing AltiVec instructions.
-
- 'vsx_hw'
- PowerPC target supports executing VSX instructions (ISA 2.06).
-
- 7.2.3.11 Other hardware attributes
- ..................................
-
- 'autoincdec'
- Target supports autoincrement/decrement addressing.
-
- 'avx'
- Target supports compiling 'avx' instructions.
-
- 'avx_runtime'
- Target supports the execution of 'avx' instructions.
-
- 'avx2'
- Target supports compiling 'avx2' instructions.
-
- 'avx2_runtime'
- Target supports the execution of 'avx2' instructions.
-
- 'avx512f'
- Target supports compiling 'avx512f' instructions.
-
- 'avx512f_runtime'
- Target supports the execution of 'avx512f' instructions.
-
- 'avx512vp2intersect'
- Target supports the execution of 'avx512vp2intersect' instructions.
-
- 'cell_hw'
- Test system can execute AltiVec and Cell PPU instructions.
-
- 'coldfire_fpu'
- Target uses a ColdFire FPU.
-
- 'divmod'
- Target supporting hardware divmod insn or divmod libcall.
-
- 'divmod_simode'
- Target supporting hardware divmod insn or divmod libcall for
- SImode.
-
- 'hard_float'
- Target supports FPU instructions.
-
- 'non_strict_align'
- Target does not require strict alignment.
-
- 'pie_copyreloc'
- The x86-64 target linker supports PIE with copy reloc.
-
- 'rdrand'
- Target supports x86 'rdrand' instruction.
-
- 'sqrt_insn'
- Target has a square root instruction that the compiler can
- generate.
-
- 'sse'
- Target supports compiling 'sse' instructions.
-
- 'sse_runtime'
- Target supports the execution of 'sse' instructions.
-
- 'sse2'
- Target supports compiling 'sse2' instructions.
-
- 'sse2_runtime'
- Target supports the execution of 'sse2' instructions.
-
- 'sync_char_short'
- Target supports atomic operations on 'char' and 'short'.
-
- 'sync_int_long'
- Target supports atomic operations on 'int' and 'long'.
-
- 'ultrasparc_hw'
- Test environment appears to run executables on a simulator that
- accepts only 'EM_SPARC' executables and chokes on 'EM_SPARC32PLUS'
- or 'EM_SPARCV9' executables.
-
- 'vect_cmdline_needed'
- Target requires a command line argument to enable a SIMD
- instruction set.
-
- 'xorsign'
- Target supports the xorsign optab expansion.
-
- 7.2.3.12 Environment attributes
- ...............................
-
- 'c'
- The language for the compiler under test is C.
-
- 'c++'
- The language for the compiler under test is C++.
-
- 'c99_runtime'
- Target provides a full C99 runtime.
-
- 'correct_iso_cpp_string_wchar_protos'
- Target 'string.h' and 'wchar.h' headers provide C++ required
- overloads for 'strchr' etc. functions.
-
- 'd_runtime'
- Target provides the D runtime.
-
- 'd_runtime_has_std_library'
- Target provides the D standard library (Phobos).
-
- 'dummy_wcsftime'
- Target uses a dummy 'wcsftime' function that always returns zero.
-
- 'fd_truncate'
- Target can truncate a file from a file descriptor, as used by
- 'libgfortran/io/unix.c:fd_truncate'; i.e. 'ftruncate' or 'chsize'.
-
- 'fenv'
- Target provides 'fenv.h' include file.
-
- 'fenv_exceptions'
- Target supports 'fenv.h' with all the standard IEEE exceptions and
- floating-point exceptions are raised by arithmetic operations.
-
- 'fileio'
- Target offers such file I/O library functions as 'fopen', 'fclose',
- 'tmpnam', and 'remove'. This is a link-time requirement for the
- presence of the functions in the library; even if they fail at
- runtime, the requirement is still regarded as satisfied.
-
- 'freestanding'
- Target is 'freestanding' as defined in section 4 of the C99
- standard. Effectively, it is a target which supports no extra
- headers or libraries other than what is considered essential.
-
- 'gettimeofday'
- Target supports 'gettimeofday'.
-
- 'init_priority'
- Target supports constructors with initialization priority
- arguments.
-
- 'inttypes_types'
- Target has the basic signed and unsigned types in 'inttypes.h'.
- This is for tests that GCC's notions of these types agree with
- those in the header, as some systems have only 'inttypes.h'.
-
- 'lax_strtofp'
- Target might have errors of a few ULP in string to floating-point
- conversion functions and overflow is not always detected correctly
- by those functions.
-
- 'mempcpy'
- Target provides 'mempcpy' function.
-
- 'mmap'
- Target supports 'mmap'.
-
- 'newlib'
- Target supports Newlib.
-
- 'newlib_nano_io'
- GCC was configured with '--enable-newlib-nano-formatted-io', which
- reduces the code size of Newlib formatted I/O functions.
-
- 'pow10'
- Target provides 'pow10' function.
-
- 'pthread'
- Target can compile using 'pthread.h' with no errors or warnings.
-
- 'pthread_h'
- Target has 'pthread.h'.
-
- 'run_expensive_tests'
- Expensive testcases (usually those that consume excessive amounts
- of CPU time) should be run on this target. This can be enabled by
- setting the 'GCC_TEST_RUN_EXPENSIVE' environment variable to a
- non-empty string.
-
- 'simulator'
- Test system runs executables on a simulator (i.e. slowly) rather
- than hardware (i.e. fast).
-
- 'signal'
- Target has 'signal.h'.
-
- 'stabs'
- Target supports the stabs debugging format.
-
- 'stdint_types'
- Target has the basic signed and unsigned C types in 'stdint.h'.
- This will be obsolete when GCC ensures a working 'stdint.h' for all
- targets.
-
- 'stpcpy'
- Target provides 'stpcpy' function.
-
- 'trampolines'
- Target supports trampolines.
-
- 'uclibc'
- Target supports uClibc.
-
- 'unwrapped'
- Target does not use a status wrapper.
-
- 'vxworks_kernel'
- Target is a VxWorks kernel.
-
- 'vxworks_rtp'
- Target is a VxWorks RTP.
-
- 'wchar'
- Target supports wide characters.
-
- 7.2.3.13 Other attributes
- .........................
-
- 'automatic_stack_alignment'
- Target supports automatic stack alignment.
-
- 'branch_cost'
- Target supports '-branch-cost=N'.
-
- 'cxa_atexit'
- Target uses '__cxa_atexit'.
-
- 'default_packed'
- Target has packed layout of structure members by default.
-
- 'exceptions'
- Target supports exceptions.
-
- 'exceptions_enabled'
- Target supports exceptions and they are enabled in the current
- testing configuration.
-
- 'fgraphite'
- Target supports Graphite optimizations.
-
- 'fixed_point'
- Target supports fixed-point extension to C.
-
- 'fopenacc'
- Target supports OpenACC via '-fopenacc'.
-
- 'fopenmp'
- Target supports OpenMP via '-fopenmp'.
-
- 'fpic'
- Target supports '-fpic' and '-fPIC'.
-
- 'freorder'
- Target supports '-freorder-blocks-and-partition'.
-
- 'fstack_protector'
- Target supports '-fstack-protector'.
-
- 'gas'
- Target uses GNU 'as'.
-
- 'gc_sections'
- Target supports '--gc-sections'.
-
- 'gld'
- Target uses GNU 'ld'.
-
- 'keeps_null_pointer_checks'
- Target keeps null pointer checks, either due to the use of
- '-fno-delete-null-pointer-checks' or hardwired into the target.
-
- 'llvm_binutils'
- Target is using an LLVM assembler and/or linker, instead of GNU
- Binutils.
-
- 'lto'
- Compiler has been configured to support link-time optimization
- (LTO).
-
- 'lto_incremental'
- Compiler and linker support link-time optimization relocatable
- linking with '-r' and '-flto' options.
-
- 'naked_functions'
- Target supports the 'naked' function attribute.
-
- 'named_sections'
- Target supports named sections.
-
- 'natural_alignment_32'
- Target uses natural alignment (aligned to type size) for types of
- 32 bits or less.
-
- 'target_natural_alignment_64'
- Target uses natural alignment (aligned to type size) for types of
- 64 bits or less.
-
- 'noinit'
- Target supports the 'noinit' variable attribute.
-
- 'nonpic'
- Target does not generate PIC by default.
-
- 'offload_gcn'
- Target has been configured for OpenACC/OpenMP offloading on AMD
- GCN.
-
- 'pie_enabled'
- Target generates PIE by default.
-
- 'pcc_bitfield_type_matters'
- Target defines 'PCC_BITFIELD_TYPE_MATTERS'.
-
- 'pe_aligned_commons'
- Target supports '-mpe-aligned-commons'.
-
- 'pie'
- Target supports '-pie', '-fpie' and '-fPIE'.
-
- 'rdynamic'
- Target supports '-rdynamic'.
-
- 'scalar_all_fma'
- Target supports all four fused multiply-add optabs for both 'float'
- and 'double'. These optabs are: 'fma_optab', 'fms_optab',
- 'fnma_optab' and 'fnms_optab'.
-
- 'section_anchors'
- Target supports section anchors.
-
- 'short_enums'
- Target defaults to short enums.
-
- 'stack_size'
- Target has limited stack size. The stack size limit can be
- obtained using the STACK_SIZE macro defined by *note
- 'dg-add-options' feature 'stack_size': stack_size_ao.
-
- 'static'
- Target supports '-static'.
-
- 'static_libgfortran'
- Target supports statically linking 'libgfortran'.
-
- 'string_merging'
- Target supports merging string constants at link time.
-
- 'ucn'
- Target supports compiling and assembling UCN.
-
- 'ucn_nocache'
- Including the options used to compile this particular test, the
- target supports compiling and assembling UCN.
-
- 'unaligned_stack'
- Target does not guarantee that its 'STACK_BOUNDARY' is greater than
- or equal to the required vector alignment.
-
- 'vector_alignment_reachable'
- Vector alignment is reachable for types of 32 bits or less.
-
- 'vector_alignment_reachable_for_64bit'
- Vector alignment is reachable for types of 64 bits or less.
-
- 'wchar_t_char16_t_compatible'
- Target supports 'wchar_t' that is compatible with 'char16_t'.
-
- 'wchar_t_char32_t_compatible'
- Target supports 'wchar_t' that is compatible with 'char32_t'.
-
- 'comdat_group'
- Target uses comdat groups.
-
- 'indirect_calls'
- Target supports indirect calls, i.e. calls where the target is not
- constant.
-
- 7.2.3.14 Local to tests in 'gcc.target/i386'
- ............................................
-
- '3dnow'
- Target supports compiling '3dnow' instructions.
-
- 'aes'
- Target supports compiling 'aes' instructions.
-
- 'fma4'
- Target supports compiling 'fma4' instructions.
-
- 'mfentry'
- Target supports the '-mfentry' option that alters the position of
- profiling calls such that they precede the prologue.
-
- 'ms_hook_prologue'
- Target supports attribute 'ms_hook_prologue'.
-
- 'pclmul'
- Target supports compiling 'pclmul' instructions.
-
- 'sse3'
- Target supports compiling 'sse3' instructions.
-
- 'sse4'
- Target supports compiling 'sse4' instructions.
-
- 'sse4a'
- Target supports compiling 'sse4a' instructions.
-
- 'ssse3'
- Target supports compiling 'ssse3' instructions.
-
- 'vaes'
- Target supports compiling 'vaes' instructions.
-
- 'vpclmul'
- Target supports compiling 'vpclmul' instructions.
-
- 'xop'
- Target supports compiling 'xop' instructions.
-
- 7.2.3.15 Local to tests in 'gcc.test-framework'
- ...............................................
-
- 'no'
- Always returns 0.
-
- 'yes'
- Always returns 1.
-
-
- File: gccint.info, Node: Add Options, Next: Require Support, Prev: Effective-Target Keywords, Up: Test Directives
-
- 7.2.4 Features for 'dg-add-options'
- -----------------------------------
-
- The supported values of FEATURE for directive 'dg-add-options' are:
-
- 'arm_fp'
- '__ARM_FP' definition. Only ARM targets support this feature, and
- only then in certain modes; see the *note arm_fp_ok effective
- target keyword: arm_fp_ok.
-
- 'arm_fp_dp'
- '__ARM_FP' definition with double-precision support. Only ARM
- targets support this feature, and only then in certain modes; see
- the *note arm_fp_dp_ok effective target keyword: arm_fp_dp_ok.
-
- 'arm_neon'
- NEON support. Only ARM targets support this feature, and only then
- in certain modes; see the *note arm_neon_ok effective target
- keyword: arm_neon_ok.
-
- 'arm_fp16'
- VFP half-precision floating point support. This does not select
- the FP16 format; for that, use *note arm_fp16_ieee: arm_fp16_ieee.
- or *note arm_fp16_alternative: arm_fp16_alternative. instead. This
- feature is only supported by ARM targets and then only in certain
- modes; see the *note arm_fp16_ok effective target keyword:
- arm_fp16_ok.
-
- 'arm_fp16_ieee'
- ARM IEEE 754-2008 format VFP half-precision floating point support.
- This feature is only supported by ARM targets and then only in
- certain modes; see the *note arm_fp16_ok effective target keyword:
- arm_fp16_ok.
-
- 'arm_fp16_alternative'
- ARM Alternative format VFP half-precision floating point support.
- This feature is only supported by ARM targets and then only in
- certain modes; see the *note arm_fp16_ok effective target keyword:
- arm_fp16_ok.
-
- 'arm_neon_fp16'
- NEON and half-precision floating point support. Only ARM targets
- support this feature, and only then in certain modes; see the *note
- arm_neon_fp16_ok effective target keyword: arm_neon_fp16_ok.
-
- 'arm_vfp3'
- arm vfp3 floating point support; see the *note arm_vfp3_ok
- effective target keyword: arm_vfp3_ok.
-
- 'arm_arch_v8a_hard'
- Add options for ARMv8-A and the hard-float variant of the AAPCS, if
- this is supported by the compiler; see the *note
- arm_arch_v8a_hard_ok: arm_arch_v8a_hard_ok. effective target
- keyword.
-
- 'arm_v8_1a_neon'
- Add options for ARMv8.1-A with Adv.SIMD support, if this is
- supported by the target; see the *note arm_v8_1a_neon_ok:
- arm_v8_1a_neon_ok. effective target keyword.
-
- 'arm_v8_2a_fp16_scalar'
- Add options for ARMv8.2-A with scalar FP16 support, if this is
- supported by the target; see the *note arm_v8_2a_fp16_scalar_ok:
- arm_v8_2a_fp16_scalar_ok. effective target keyword.
-
- 'arm_v8_2a_fp16_neon'
- Add options for ARMv8.2-A with Adv.SIMD FP16 support, if this is
- supported by the target; see the *note arm_v8_2a_fp16_neon_ok:
- arm_v8_2a_fp16_neon_ok. effective target keyword.
-
- 'arm_v8_2a_dotprod_neon'
- Add options for ARMv8.2-A with Adv.SIMD Dot Product support, if
- this is supported by the target; see the *note
- arm_v8_2a_dotprod_neon_ok:: effective target keyword.
-
- 'arm_fp16fml_neon'
- Add options to enable generation of the 'VFMAL' and 'VFMSL'
- instructions, if this is supported by the target; see the *note
- arm_fp16fml_neon_ok:: effective target keyword.
-
- 'bind_pic_locally'
- Add the target-specific flags needed to enable functions to bind
- locally when using pic/PIC passes in the testsuite.
-
- 'floatN'
- Add the target-specific flags needed to use the '_FloatN' type.
-
- 'floatNx'
- Add the target-specific flags needed to use the '_FloatNx' type.
-
- 'ieee'
- Add the target-specific flags needed to enable full IEEE compliance
- mode.
-
- 'mips16_attribute'
- 'mips16' function attributes. Only MIPS targets support this
- feature, and only then in certain modes.
-
- 'stack_size'
- Add the flags needed to define macro STACK_SIZE and set it to the
- stack size limit associated with the *note 'stack_size' effective
- target: stack_size_et.
-
- 'sqrt_insn'
- Add the target-specific flags needed to enable hardware square root
- instructions, if any.
-
- 'tls'
- Add the target-specific flags needed to use thread-local storage.
-
-
- File: gccint.info, Node: Require Support, Next: Final Actions, Prev: Add Options, Up: Test Directives
-
- 7.2.5 Variants of 'dg-require-SUPPORT'
- --------------------------------------
-
- A few of the 'dg-require' directives take arguments.
-
- 'dg-require-iconv CODESET'
- Skip the test if the target does not support iconv. CODESET is the
- codeset to convert to.
-
- 'dg-require-profiling PROFOPT'
- Skip the test if the target does not support profiling with option
- PROFOPT.
-
- 'dg-require-stack-check CHECK'
- Skip the test if the target does not support the '-fstack-check'
- option. If CHECK is '""', support for '-fstack-check' is checked,
- for '-fstack-check=("CHECK")' otherwise.
-
- 'dg-require-stack-size SIZE'
- Skip the test if the target does not support a stack size of SIZE.
-
- 'dg-require-visibility VIS'
- Skip the test if the target does not support the 'visibility'
- attribute. If VIS is '""', support for 'visibility("hidden")' is
- checked, for 'visibility("VIS")' otherwise.
-
- The original 'dg-require' directives were defined before there was
- support for effective-target keywords. The directives that do not take
- arguments could be replaced with effective-target keywords.
-
- 'dg-require-alias ""'
- Skip the test if the target does not support the 'alias' attribute.
-
- 'dg-require-ascii-locale ""'
- Skip the test if the host does not support an ASCII locale.
-
- 'dg-require-compat-dfp ""'
- Skip this test unless both compilers in a 'compat' testsuite
- support decimal floating point.
-
- 'dg-require-cxa-atexit ""'
- Skip the test if the target does not support '__cxa_atexit'. This
- is equivalent to 'dg-require-effective-target cxa_atexit'.
-
- 'dg-require-dll ""'
- Skip the test if the target does not support DLL attributes.
-
- 'dg-require-dot ""'
- Skip the test if the host does not have 'dot'.
-
- 'dg-require-fork ""'
- Skip the test if the target does not support 'fork'.
-
- 'dg-require-gc-sections ""'
- Skip the test if the target's linker does not support the
- '--gc-sections' flags. This is equivalent to
- 'dg-require-effective-target gc-sections'.
-
- 'dg-require-host-local ""'
- Skip the test if the host is remote, rather than the same as the
- build system. Some tests are incompatible with DejaGnu's handling
- of remote hosts, which involves copying the source file to the host
- and compiling it with a relative path and "'-o a.out'".
-
- 'dg-require-mkfifo ""'
- Skip the test if the target does not support 'mkfifo'.
-
- 'dg-require-named-sections ""'
- Skip the test is the target does not support named sections. This
- is equivalent to 'dg-require-effective-target named_sections'.
-
- 'dg-require-weak ""'
- Skip the test if the target does not support weak symbols.
-
- 'dg-require-weak-override ""'
- Skip the test if the target does not support overriding weak
- symbols.
-
-
- File: gccint.info, Node: Final Actions, Prev: Require Support, Up: Test Directives
-
- 7.2.6 Commands for use in 'dg-final'
- ------------------------------------
-
- The GCC testsuite defines the following directives to be used within
- 'dg-final'.
-
- 7.2.6.1 Scan a particular file
- ..............................
-
- 'scan-file FILENAME REGEXP [{ target/xfail SELECTOR }]'
- Passes if REGEXP matches text in FILENAME.
- 'scan-file-not FILENAME REGEXP [{ target/xfail SELECTOR }]'
- Passes if REGEXP does not match text in FILENAME.
- 'scan-module MODULE REGEXP [{ target/xfail SELECTOR }]'
- Passes if REGEXP matches in Fortran module MODULE.
- 'dg-check-dot FILENAME'
- Passes if FILENAME is a valid '.dot' file (by running 'dot -Tpng'
- on it, and verifying the exit code is 0).
-
- 7.2.6.2 Scan the assembly output
- ................................
-
- 'scan-assembler REGEX [{ target/xfail SELECTOR }]'
- Passes if REGEX matches text in the test's assembler output.
-
- 'scan-assembler-not REGEX [{ target/xfail SELECTOR }]'
- Passes if REGEX does not match text in the test's assembler output.
-
- 'scan-assembler-times REGEX NUM [{ target/xfail SELECTOR }]'
- Passes if REGEX is matched exactly NUM times in the test's
- assembler output.
-
- 'scan-assembler-dem REGEX [{ target/xfail SELECTOR }]'
- Passes if REGEX matches text in the test's demangled assembler
- output.
-
- 'scan-assembler-dem-not REGEX [{ target/xfail SELECTOR }]'
- Passes if REGEX does not match text in the test's demangled
- assembler output.
-
- 'scan-hidden SYMBOL [{ target/xfail SELECTOR }]'
- Passes if SYMBOL is defined as a hidden symbol in the test's
- assembly output.
-
- 'scan-not-hidden SYMBOL [{ target/xfail SELECTOR }]'
- Passes if SYMBOL is not defined as a hidden symbol in the test's
- assembly output.
-
- 'check-function-bodies PREFIX TERMINATOR [OPTIONS [{ target/xfail SELECTOR }]]'
- Looks through the source file for comments that give the expected
- assembly output for selected functions. Each line of expected
- output starts with the prefix string PREFIX and the expected output
- for a function as a whole is followed by a line that starts with
- the string TERMINATOR. Specifying an empty terminator is
- equivalent to specifying '"*/"'.
-
- OPTIONS, if specified, is a list of regular expressions, each of
- which matches a full command-line option. A non-empty list
- prevents the test from running unless all of the given options are
- present on the command line. This can help if a source file is
- compiled both with and without optimization, since it is rarely
- useful to check the full function body for unoptimized code.
-
- The first line of the expected output for a function FN has the
- form:
-
- PREFIX FN: [{ target/xfail SELECTOR }]
-
- Subsequent lines of the expected output also start with PREFIX. In
- both cases, whitespace after PREFIX is not significant.
-
- The test discards assembly directives such as '.cfi_startproc' and
- local label definitions such as '.LFB0' from the compiler's
- assembly output. It then matches the result against the expected
- output for a function as a single regular expression. This means
- that later lines can use backslashes to refer back to '(...)'
- captures on earlier lines. For example:
-
- /* { dg-final { check-function-bodies "**" "" "-DCHECK_ASM" } } */
- ...
- /*
- ** add_w0_s8_m:
- ** mov (z[0-9]+\.b), w0
- ** add z0\.b, p0/m, z0\.b, \1
- ** ret
- */
- svint8_t add_w0_s8_m (...) { ... }
- ...
- /*
- ** add_b0_s8_m:
- ** mov (z[0-9]+\.b), b0
- ** add z1\.b, p0/m, z1\.b, \1
- ** ret
- */
- svint8_t add_b0_s8_m (...) { ... }
-
- checks whether the implementations of 'add_w0_s8_m' and
- 'add_b0_s8_m' match the regular expressions given. The test only
- runs when '-DCHECK_ASM' is passed on the command line.
-
- It is possible to create non-capturing multi-line regular
- expression groups of the form '(A|B|...)' by putting the '(', '|'
- and ')' on separate lines (each still using PREFIX). For example:
-
- /*
- ** cmple_f16_tied:
- ** (
- ** fcmge p0\.h, p0/z, z1\.h, z0\.h
- ** |
- ** fcmle p0\.h, p0/z, z0\.h, z1\.h
- ** )
- ** ret
- */
- svbool_t cmple_f16_tied (...) { ... }
-
- checks whether 'cmple_f16_tied' is implemented by the 'fcmge'
- instruction followed by 'ret' or by the 'fcmle' instruction
- followed by 'ret'. The test is still a single regular rexpression.
-
- A line containing just:
-
- PREFIX ...
-
- stands for zero or more unmatched lines; the whitespace after
- PREFIX is again not significant.
-
- 7.2.6.3 Scan optimization dump files
- ....................................
-
- These commands are available for KIND of 'tree', 'ltrans-tree',
- 'offload-tree', 'rtl', 'offload-rtl', 'ipa', and 'wpa-ipa'.
-
- 'scan-KIND-dump REGEX SUFFIX [{ target/xfail SELECTOR }]'
- Passes if REGEX matches text in the dump file with suffix SUFFIX.
-
- 'scan-KIND-dump-not REGEX SUFFIX [{ target/xfail SELECTOR }]'
- Passes if REGEX does not match text in the dump file with suffix
- SUFFIX.
-
- 'scan-KIND-dump-times REGEX NUM SUFFIX [{ target/xfail SELECTOR }]'
- Passes if REGEX is found exactly NUM times in the dump file with
- suffix SUFFIX.
-
- 'scan-KIND-dump-dem REGEX SUFFIX [{ target/xfail SELECTOR }]'
- Passes if REGEX matches demangled text in the dump file with suffix
- SUFFIX.
-
- 'scan-KIND-dump-dem-not REGEX SUFFIX [{ target/xfail SELECTOR }]'
- Passes if REGEX does not match demangled text in the dump file with
- suffix SUFFIX.
-
- 7.2.6.4 Check for output files
- ..............................
-
- 'output-exists [{ target/xfail SELECTOR }]'
- Passes if compiler output file exists.
-
- 'output-exists-not [{ target/xfail SELECTOR }]'
- Passes if compiler output file does not exist.
-
- 'scan-symbol REGEXP [{ target/xfail SELECTOR }]'
- Passes if the pattern is present in the final executable.
-
- 'scan-symbol-not REGEXP [{ target/xfail SELECTOR }]'
- Passes if the pattern is absent from the final executable.
-
- 7.2.6.5 Checks for 'gcov' tests
- ...............................
-
- 'run-gcov SOURCEFILE'
- Check line counts in 'gcov' tests.
-
- 'run-gcov [branches] [calls] { OPTS SOURCEFILE }'
- Check branch and/or call counts, in addition to line counts, in
- 'gcov' tests.
-
- 7.2.6.6 Clean up generated test files
- .....................................
-
- Usually the test-framework removes files that were generated during
- testing. If a testcase, for example, uses any dumping mechanism to
- inspect a passes dump file, the testsuite recognized the dump option
- passed to the tool and schedules a final cleanup to remove these files.
-
- There are, however, following additional cleanup directives that can be
- used to annotate a testcase "manually".
- 'cleanup-coverage-files'
- Removes coverage data files generated for this test.
-
- 'cleanup-modules "LIST-OF-EXTRA-MODULES"'
- Removes Fortran module files generated for this test, excluding the
- module names listed in keep-modules. Cleaning up module files is
- usually done automatically by the testsuite by looking at the
- source files and removing the modules after the test has been
- executed.
- module MoD1
- end module MoD1
- module Mod2
- end module Mod2
- module moD3
- end module moD3
- module mod4
- end module mod4
- ! { dg-final { cleanup-modules "mod1 mod2" } } ! redundant
- ! { dg-final { keep-modules "mod3 mod4" } }
-
- 'keep-modules "LIST-OF-MODULES-NOT-TO-DELETE"'
- Whitespace separated list of module names that should not be
- deleted by cleanup-modules. If the list of modules is empty, all
- modules defined in this file are kept.
- module maybe_unneeded
- end module maybe_unneeded
- module keep1
- end module keep1
- module keep2
- end module keep2
- ! { dg-final { keep-modules "keep1 keep2" } } ! just keep these two
- ! { dg-final { keep-modules "" } } ! keep all
-
- 'dg-keep-saved-temps "LIST-OF-SUFFIXES-NOT-TO-DELETE"'
- Whitespace separated list of suffixes that should not be deleted
- automatically in a testcase that uses '-save-temps'.
- // { dg-options "-save-temps -fpch-preprocess -I." }
- int main() { return 0; }
- // { dg-keep-saved-temps ".s" } ! just keep assembler file
- // { dg-keep-saved-temps ".s" ".i" } ! ... and .i
- // { dg-keep-saved-temps ".ii" ".o" } ! or just .ii and .o
-
- 'cleanup-profile-file'
- Removes profiling files generated for this test.
-
-
- File: gccint.info, Node: Ada Tests, Next: C Tests, Prev: Test Directives, Up: Testsuites
-
- 7.3 Ada Language Testsuites
- ===========================
-
- The Ada testsuite includes executable tests from the ACATS testsuite,
- publicly available at <http://www.ada-auth.org/acats.html>.
-
- These tests are integrated in the GCC testsuite in the 'ada/acats'
- directory, and enabled automatically when running 'make check', assuming
- the Ada language has been enabled when configuring GCC.
-
- You can also run the Ada testsuite independently, using 'make
- check-ada', or run a subset of the tests by specifying which chapter to
- run, e.g.:
-
- $ make check-ada CHAPTERS="c3 c9"
-
- The tests are organized by directory, each directory corresponding to a
- chapter of the Ada Reference Manual. So for example, 'c9' corresponds
- to chapter 9, which deals with tasking features of the language.
-
- The tests are run using two 'sh' scripts: 'run_acats' and 'run_all.sh'.
- To run the tests using a simulator or a cross target, see the small
- customization section at the top of 'run_all.sh'.
-
- These tests are run using the build tree: they can be run without doing
- a 'make install'.
-
-
- File: gccint.info, Node: C Tests, Next: LTO Testing, Prev: Ada Tests, Up: Testsuites
-
- 7.4 C Language Testsuites
- =========================
-
- GCC contains the following C language testsuites, in the 'gcc/testsuite'
- directory:
-
- 'gcc.dg'
- This contains tests of particular features of the C compiler, using
- the more modern 'dg' harness. Correctness tests for various
- compiler features should go here if possible.
-
- Magic comments determine whether the file is preprocessed,
- compiled, linked or run. In these tests, error and warning message
- texts are compared against expected texts or regular expressions
- given in comments. These tests are run with the options '-ansi
- -pedantic' unless other options are given in the test. Except as
- noted below they are not run with multiple optimization options.
- 'gcc.dg/compat'
- This subdirectory contains tests for binary compatibility using
- 'lib/compat.exp', which in turn uses the language-independent
- support (*note Support for testing binary compatibility: compat
- Testing.).
- 'gcc.dg/cpp'
- This subdirectory contains tests of the preprocessor.
- 'gcc.dg/debug'
- This subdirectory contains tests for debug formats. Tests in this
- subdirectory are run for each debug format that the compiler
- supports.
- 'gcc.dg/format'
- This subdirectory contains tests of the '-Wformat' format checking.
- Tests in this directory are run with and without '-DWIDE'.
- 'gcc.dg/noncompile'
- This subdirectory contains tests of code that should not compile
- and does not need any special compilation options. They are run
- with multiple optimization options, since sometimes invalid code
- crashes the compiler with optimization.
- 'gcc.dg/special'
- FIXME: describe this.
-
- 'gcc.c-torture'
- This contains particular code fragments which have historically
- broken easily. These tests are run with multiple optimization
- options, so tests for features which only break at some
- optimization levels belong here. This also contains tests to check
- that certain optimizations occur. It might be worthwhile to
- separate the correctness tests cleanly from the code quality tests,
- but it hasn't been done yet.
-
- 'gcc.c-torture/compat'
- FIXME: describe this.
-
- This directory should probably not be used for new tests.
- 'gcc.c-torture/compile'
- This testsuite contains test cases that should compile, but do not
- need to link or run. These test cases are compiled with several
- different combinations of optimization options. All warnings are
- disabled for these test cases, so this directory is not suitable if
- you wish to test for the presence or absence of compiler warnings.
- While special options can be set, and tests disabled on specific
- platforms, by the use of '.x' files, mostly these test cases should
- not contain platform dependencies. FIXME: discuss how defines such
- as 'STACK_SIZE' are used.
- 'gcc.c-torture/execute'
- This testsuite contains test cases that should compile, link and
- run; otherwise the same comments as for 'gcc.c-torture/compile'
- apply.
- 'gcc.c-torture/execute/ieee'
- This contains tests which are specific to IEEE floating point.
- 'gcc.c-torture/unsorted'
- FIXME: describe this.
-
- This directory should probably not be used for new tests.
- 'gcc.misc-tests'
- This directory contains C tests that require special handling.
- Some of these tests have individual expect files, and others share
- special-purpose expect files:
-
- 'bprob*.c'
- Test '-fbranch-probabilities' using
- 'gcc.misc-tests/bprob.exp', which in turn uses the generic,
- language-independent framework (*note Support for testing
- profile-directed optimizations: profopt Testing.).
-
- 'gcov*.c'
- Test 'gcov' output using 'gcov.exp', which in turn uses the
- language-independent support (*note Support for testing gcov:
- gcov Testing.).
-
- 'i386-pf-*.c'
- Test i386-specific support for data prefetch using
- 'i386-prefetch.exp'.
-
- 'gcc.test-framework'
- 'dg-*.c'
- Test the testsuite itself using
- 'gcc.test-framework/test-framework.exp'.
-
- FIXME: merge in 'testsuite/README.gcc' and discuss the format of test
- cases and magic comments more.
-
-
- File: gccint.info, Node: LTO Testing, Next: gcov Testing, Prev: C Tests, Up: Testsuites
-
- 7.5 Support for testing link-time optimizations
- ===============================================
-
- Tests for link-time optimizations usually require multiple source files
- that are compiled separately, perhaps with different sets of options.
- There are several special-purpose test directives used for these tests.
-
- '{ dg-lto-do DO-WHAT-KEYWORD }'
- DO-WHAT-KEYWORD specifies how the test is compiled and whether it
- is executed. It is one of:
-
- 'assemble'
- Compile with '-c' to produce a relocatable object file.
- 'link'
- Compile, assemble, and link to produce an executable file.
- 'run'
- Produce and run an executable file, which is expected to
- return an exit code of 0.
-
- The default is 'assemble'. That can be overridden for a set of
- tests by redefining 'dg-do-what-default' within the '.exp' file for
- those tests.
-
- Unlike 'dg-do', 'dg-lto-do' does not support an optional 'target'
- or 'xfail' list. Use 'dg-skip-if', 'dg-xfail-if', or
- 'dg-xfail-run-if'.
-
- '{ dg-lto-options { { OPTIONS } [{ OPTIONS }] } [{ target SELECTOR }]}'
- This directive provides a list of one or more sets of compiler
- options to override LTO_OPTIONS. Each test will be compiled and
- run with each of these sets of options.
-
- '{ dg-extra-ld-options OPTIONS [{ target SELECTOR }]}'
- This directive adds OPTIONS to the linker options used.
-
- '{ dg-suppress-ld-options OPTIONS [{ target SELECTOR }]}'
- This directive removes OPTIONS from the set of linker options used.
-
-
- File: gccint.info, Node: gcov Testing, Next: profopt Testing, Prev: LTO Testing, Up: Testsuites
-
- 7.6 Support for testing 'gcov'
- ==============================
-
- Language-independent support for testing 'gcov', and for checking that
- branch profiling produces expected values, is provided by the expect
- file 'lib/gcov.exp'. 'gcov' tests also rely on procedures in
- 'lib/gcc-dg.exp' to compile and run the test program. A typical 'gcov'
- test contains the following DejaGnu commands within comments:
-
- { dg-options "--coverage" }
- { dg-do run { target native } }
- { dg-final { run-gcov sourcefile } }
-
- Checks of 'gcov' output can include line counts, branch percentages,
- and call return percentages. All of these checks are requested via
- commands that appear in comments in the test's source file. Commands to
- check line counts are processed by default. Commands to check branch
- percentages and call return percentages are processed if the 'run-gcov'
- command has arguments 'branches' or 'calls', respectively. For example,
- the following specifies checking both, as well as passing '-b' to
- 'gcov':
-
- { dg-final { run-gcov branches calls { -b sourcefile } } }
-
- A line count command appears within a comment on the source line that
- is expected to get the specified count and has the form 'count(CNT)'. A
- test should only check line counts for lines that will get the same
- count for any architecture.
-
- Commands to check branch percentages ('branch') and call return
- percentages ('returns') are very similar to each other. A beginning
- command appears on or before the first of a range of lines that will
- report the percentage, and the ending command follows that range of
- lines. The beginning command can include a list of percentages, all of
- which are expected to be found within the range. A range is terminated
- by the next command of the same kind. A command 'branch(end)' or
- 'returns(end)' marks the end of a range without starting a new one. For
- example:
-
- if (i > 10 && j > i && j < 20) /* branch(27 50 75) */
- /* branch(end) */
- foo (i, j);
-
- For a call return percentage, the value specified is the percentage of
- calls reported to return. For a branch percentage, the value is either
- the expected percentage or 100 minus that value, since the direction of
- a branch can differ depending on the target or the optimization level.
-
- Not all branches and calls need to be checked. A test should not check
- for branches that might be optimized away or replaced with predicated
- instructions. Don't check for calls inserted by the compiler or ones
- that might be inlined or optimized away.
-
- A single test can check for combinations of line counts, branch
- percentages, and call return percentages. The command to check a line
- count must appear on the line that will report that count, but commands
- to check branch percentages and call return percentages can bracket the
- lines that report them.
-
-
- File: gccint.info, Node: profopt Testing, Next: compat Testing, Prev: gcov Testing, Up: Testsuites
-
- 7.7 Support for testing profile-directed optimizations
- ======================================================
-
- The file 'profopt.exp' provides language-independent support for
- checking correct execution of a test built with profile-directed
- optimization. This testing requires that a test program be built and
- executed twice. The first time it is compiled to generate profile data,
- and the second time it is compiled to use the data that was generated
- during the first execution. The second execution is to verify that the
- test produces the expected results.
-
- To check that the optimization actually generated better code, a test
- can be built and run a third time with normal optimizations to verify
- that the performance is better with the profile-directed optimizations.
- 'profopt.exp' has the beginnings of this kind of support.
-
- 'profopt.exp' provides generic support for profile-directed
- optimizations. Each set of tests that uses it provides information
- about a specific optimization:
-
- 'tool'
- tool being tested, e.g., 'gcc'
-
- 'profile_option'
- options used to generate profile data
-
- 'feedback_option'
- options used to optimize using that profile data
-
- 'prof_ext'
- suffix of profile data files
-
- 'PROFOPT_OPTIONS'
- list of options with which to run each test, similar to the lists
- for torture tests
-
- '{ dg-final-generate { LOCAL-DIRECTIVE } }'
- This directive is similar to 'dg-final', but the LOCAL-DIRECTIVE is
- run after the generation of profile data.
-
- '{ dg-final-use { LOCAL-DIRECTIVE } }'
- The LOCAL-DIRECTIVE is run after the profile data have been used.
-
-
- File: gccint.info, Node: compat Testing, Next: Torture Tests, Prev: profopt Testing, Up: Testsuites
-
- 7.8 Support for testing binary compatibility
- ============================================
-
- The file 'compat.exp' provides language-independent support for binary
- compatibility testing. It supports testing interoperability of two
- compilers that follow the same ABI, or of multiple sets of compiler
- options that should not affect binary compatibility. It is intended to
- be used for testsuites that complement ABI testsuites.
-
- A test supported by this framework has three parts, each in a separate
- source file: a main program and two pieces that interact with each other
- to split up the functionality being tested.
-
- 'TESTNAME_main.SUFFIX'
- Contains the main program, which calls a function in file
- 'TESTNAME_x.SUFFIX'.
-
- 'TESTNAME_x.SUFFIX'
- Contains at least one call to a function in 'TESTNAME_y.SUFFIX'.
-
- 'TESTNAME_y.SUFFIX'
- Shares data with, or gets arguments from, 'TESTNAME_x.SUFFIX'.
-
- Within each test, the main program and one functional piece are
- compiled by the GCC under test. The other piece can be compiled by an
- alternate compiler. If no alternate compiler is specified, then all
- three source files are all compiled by the GCC under test. You can
- specify pairs of sets of compiler options. The first element of such a
- pair specifies options used with the GCC under test, and the second
- element of the pair specifies options used with the alternate compiler.
- Each test is compiled with each pair of options.
-
- 'compat.exp' defines default pairs of compiler options. These can be
- overridden by defining the environment variable 'COMPAT_OPTIONS' as:
-
- COMPAT_OPTIONS="[list [list {TST1} {ALT1}]
- ...[list {TSTN} {ALTN}]]"
-
- where TSTI and ALTI are lists of options, with TSTI used by the
- compiler under test and ALTI used by the alternate compiler. For
- example, with '[list [list {-g -O0} {-O3}] [list {-fpic} {-fPIC -O2}]]',
- the test is first built with '-g -O0' by the compiler under test and
- with '-O3' by the alternate compiler. The test is built a second time
- using '-fpic' by the compiler under test and '-fPIC -O2' by the
- alternate compiler.
-
- An alternate compiler is specified by defining an environment variable
- to be the full pathname of an installed compiler; for C define
- 'ALT_CC_UNDER_TEST', and for C++ define 'ALT_CXX_UNDER_TEST'. These
- will be written to the 'site.exp' file used by DejaGnu. The default is
- to build each test with the compiler under test using the first of each
- pair of compiler options from 'COMPAT_OPTIONS'. When
- 'ALT_CC_UNDER_TEST' or 'ALT_CXX_UNDER_TEST' is 'same', each test is
- built using the compiler under test but with combinations of the options
- from 'COMPAT_OPTIONS'.
-
- To run only the C++ compatibility suite using the compiler under test
- and another version of GCC using specific compiler options, do the
- following from 'OBJDIR/gcc':
-
- rm site.exp
- make -k \
- ALT_CXX_UNDER_TEST=${alt_prefix}/bin/g++ \
- COMPAT_OPTIONS="LISTS AS SHOWN ABOVE" \
- check-c++ \
- RUNTESTFLAGS="compat.exp"
-
- A test that fails when the source files are compiled with different
- compilers, but passes when the files are compiled with the same
- compiler, demonstrates incompatibility of the generated code or runtime
- support. A test that fails for the alternate compiler but passes for
- the compiler under test probably tests for a bug that was fixed in the
- compiler under test but is present in the alternate compiler.
-
- The binary compatibility tests support a small number of test framework
- commands that appear within comments in a test file.
-
- 'dg-require-*'
- These commands can be used in 'TESTNAME_main.SUFFIX' to skip the
- test if specific support is not available on the target.
-
- 'dg-options'
- The specified options are used for compiling this particular source
- file, appended to the options from 'COMPAT_OPTIONS'. When this
- command appears in 'TESTNAME_main.SUFFIX' the options are also used
- to link the test program.
-
- 'dg-xfail-if'
- This command can be used in a secondary source file to specify that
- compilation is expected to fail for particular options on
- particular targets.
-
-
- File: gccint.info, Node: Torture Tests, Next: GIMPLE Tests, Prev: compat Testing, Up: Testsuites
-
- 7.9 Support for torture testing using multiple options
- ======================================================
-
- Throughout the compiler testsuite there are several directories whose
- tests are run multiple times, each with a different set of options.
- These are known as torture tests. 'lib/torture-options.exp' defines
- procedures to set up these lists:
-
- 'torture-init'
- Initialize use of torture lists.
- 'set-torture-options'
- Set lists of torture options to use for tests with and without
- loops. Optionally combine a set of torture options with a set of
- other options, as is done with Objective-C runtime options.
- 'torture-finish'
- Finalize use of torture lists.
-
- The '.exp' file for a set of tests that use torture options must
- include calls to these three procedures if:
-
- * It calls 'gcc-dg-runtest' and overrides DG_TORTURE_OPTIONS.
-
- * It calls ${TOOL}'-torture' or ${TOOL}'-torture-execute', where TOOL
- is 'c', 'fortran', or 'objc'.
-
- * It calls 'dg-pch'.
-
- It is not necessary for a '.exp' file that calls 'gcc-dg-runtest' to
- call the torture procedures if the tests should use the list in
- DG_TORTURE_OPTIONS defined in 'gcc-dg.exp'.
-
- Most uses of torture options can override the default lists by defining
- TORTURE_OPTIONS or add to the default list by defining
- ADDITIONAL_TORTURE_OPTIONS. Define these in a '.dejagnurc' file or add
- them to the 'site.exp' file; for example
-
- set ADDITIONAL_TORTURE_OPTIONS [list \
- { -O2 -ftree-loop-linear } \
- { -O2 -fpeel-loops } ]
-
-
- File: gccint.info, Node: GIMPLE Tests, Next: RTL Tests, Prev: Torture Tests, Up: Testsuites
-
- 7.10 Support for testing GIMPLE passes
- ======================================
-
- As of gcc 7, C functions can be tagged with '__GIMPLE' to indicate that
- the function body will be GIMPLE, rather than C. The compiler requires
- the option '-fgimple' to enable this functionality. For example:
-
- /* { dg-do compile } */
- /* { dg-options "-O -fgimple" } */
-
- void __GIMPLE (startwith ("dse2")) foo ()
- {
- int a;
-
- bb_2:
- if (a > 4)
- goto bb_3;
- else
- goto bb_4;
-
- bb_3:
- a_2 = 10;
- goto bb_5;
-
- bb_4:
- a_3 = 20;
-
- bb_5:
- a_1 = __PHI (bb_3: a_2, bb_4: a_3);
- a_4 = a_1 + 4;
-
- return;
- }
-
- The 'startwith' argument indicates at which pass to begin.
-
- Use the dump modifier '-gimple' (e.g. '-fdump-tree-all-gimple') to make
- tree dumps more closely follow the format accepted by the GIMPLE parser.
-
- Example DejaGnu tests of GIMPLE can be seen in the source tree at
- 'gcc/testsuite/gcc.dg/gimplefe-*.c'.
-
- The '__GIMPLE' parser is integrated with the C tokenizer and
- preprocessor, so it should be possible to use macros to build out test
- coverage.
-
-
- File: gccint.info, Node: RTL Tests, Prev: GIMPLE Tests, Up: Testsuites
-
- 7.11 Support for testing RTL passes
- ===================================
-
- As of gcc 7, C functions can be tagged with '__RTL' to indicate that the
- function body will be RTL, rather than C. For example:
-
- double __RTL (startwith ("ira")) test (struct foo *f, const struct bar *b)
- {
- (function "test"
- [...snip; various directives go in here...]
- ) ;; function "test"
- }
-
- The 'startwith' argument indicates at which pass to begin.
-
- The parser expects the RTL body to be in the format emitted by this
- dumping function:
-
- DEBUG_FUNCTION void
- print_rtx_function (FILE *outfile, function *fn, bool compact);
-
- when "compact" is true. So you can capture RTL in the correct format
- from the debugger using:
-
- (gdb) print_rtx_function (stderr, cfun, true);
-
- and copy and paste the output into the body of the C function.
-
- Example DejaGnu tests of RTL can be seen in the source tree under
- 'gcc/testsuite/gcc.dg/rtl'.
-
- The '__RTL' parser is not integrated with the C tokenizer or
- preprocessor, and works simply by reading the relevant lines within the
- braces. In particular, the RTL body must be on separate lines from the
- enclosing braces, and the preprocessor is not usable within it.
-
-
- File: gccint.info, Node: Options, Next: Passes, Prev: Testsuites, Up: Top
-
- 8 Option specification files
- ****************************
-
- Most GCC command-line options are described by special option definition
- files, the names of which conventionally end in '.opt'. This chapter
- describes the format of these files.
-
- * Menu:
-
- * Option file format:: The general layout of the files
- * Option properties:: Supported option properties
-
-
- File: gccint.info, Node: Option file format, Next: Option properties, Up: Options
-
- 8.1 Option file format
- ======================
-
- Option files are a simple list of records in which each field occupies
- its own line and in which the records themselves are separated by blank
- lines. Comments may appear on their own line anywhere within the file
- and are preceded by semicolons. Whitespace is allowed before the
- semicolon.
-
- The files can contain the following types of record:
-
- * A language definition record. These records have two fields: the
- string 'Language' and the name of the language. Once a language
- has been declared in this way, it can be used as an option
- property. *Note Option properties::.
-
- * A target specific save record to save additional information.
- These records have two fields: the string 'TargetSave', and a
- declaration type to go in the 'cl_target_option' structure.
-
- * A variable record to define a variable used to store option
- information. These records have two fields: the string 'Variable',
- and a declaration of the type and name of the variable, optionally
- with an initializer (but without any trailing ';'). These records
- may be used for variables used for many options where declaring the
- initializer in a single option definition record, or duplicating it
- in many records, would be inappropriate, or for variables set in
- option handlers rather than referenced by 'Var' properties.
-
- * A variable record to define a variable used to store option
- information. These records have two fields: the string
- 'TargetVariable', and a declaration of the type and name of the
- variable, optionally with an initializer (but without any trailing
- ';'). 'TargetVariable' is a combination of 'Variable' and
- 'TargetSave' records in that the variable is defined in the
- 'gcc_options' structure, but these variables are also stored in the
- 'cl_target_option' structure. The variables are saved in the
- target save code and restored in the target restore code.
-
- * A variable record to record any additional files that the
- 'options.h' file should include. This is useful to provide
- enumeration or structure definitions needed for target variables.
- These records have two fields: the string 'HeaderInclude' and the
- name of the include file.
-
- * A variable record to record any additional files that the
- 'options.c' or 'options-save.c' file should include. This is
- useful to provide inline functions needed for target variables
- and/or '#ifdef' sequences to properly set up the initialization.
- These records have two fields: the string 'SourceInclude' and the
- name of the include file.
-
- * An enumeration record to define a set of strings that may be used
- as arguments to an option or options. These records have three
- fields: the string 'Enum', a space-separated list of properties and
- help text used to describe the set of strings in '--help' output.
- Properties use the same format as option properties; the following
- are valid:
- 'Name(NAME)'
- This property is required; NAME must be a name (suitable for
- use in C identifiers) used to identify the set of strings in
- 'Enum' option properties.
-
- 'Type(TYPE)'
- This property is required; TYPE is the C type for variables
- set by options using this enumeration together with 'Var'.
-
- 'UnknownError(MESSAGE)'
- The message MESSAGE will be used as an error message if the
- argument is invalid; for enumerations without 'UnknownError',
- a generic error message is used. MESSAGE should contain a
- single '%qs' format, which will be used to format the invalid
- argument.
-
- * An enumeration value record to define one of the strings in a set
- given in an 'Enum' record. These records have two fields: the
- string 'EnumValue' and a space-separated list of properties.
- Properties use the same format as option properties; the following
- are valid:
- 'Enum(NAME)'
- This property is required; NAME says which 'Enum' record this
- 'EnumValue' record corresponds to.
-
- 'String(STRING)'
- This property is required; STRING is the string option
- argument being described by this record.
-
- 'Value(VALUE)'
- This property is required; it says what value (representable
- as 'int') should be used for the given string.
-
- 'Canonical'
- This property is optional. If present, it says the present
- string is the canonical one among all those with the given
- value. Other strings yielding that value will be mapped to
- this one so specs do not need to handle them.
-
- 'DriverOnly'
- This property is optional. If present, the present string
- will only be accepted by the driver. This is used for cases
- such as '-march=native' that are processed by the driver so
- that 'gcc -v' shows how the options chosen depended on the
- system on which the compiler was run.
-
- * An option definition record. These records have the following
- fields:
- 1. the name of the option, with the leading "-" removed
- 2. a space-separated list of option properties (*note Option
- properties::)
- 3. the help text to use for '--help' (omitted if the second field
- contains the 'Undocumented' property).
-
- By default, all options beginning with "f", "W" or "m" are
- implicitly assumed to take a "no-" form. This form should not be
- listed separately. If an option beginning with one of these
- letters does not have a "no-" form, you can use the
- 'RejectNegative' property to reject it.
-
- The help text is automatically line-wrapped before being displayed.
- Normally the name of the option is printed on the left-hand side of
- the output and the help text is printed on the right. However, if
- the help text contains a tab character, the text to the left of the
- tab is used instead of the option's name and the text to the right
- of the tab forms the help text. This allows you to elaborate on
- what type of argument the option takes.
-
- * A target mask record. These records have one field of the form
- 'Mask(X)'. The options-processing script will automatically
- allocate a bit in 'target_flags' (*note Run-time Target::) for each
- mask name X and set the macro 'MASK_X' to the appropriate bitmask.
- It will also declare a 'TARGET_X' macro that has the value 1 when
- bit 'MASK_X' is set and 0 otherwise.
-
- They are primarily intended to declare target masks that are not
- associated with user options, either because these masks represent
- internal switches or because the options are not available on all
- configurations and yet the masks always need to be defined.
-
-
- File: gccint.info, Node: Option properties, Prev: Option file format, Up: Options
-
- 8.2 Option properties
- =====================
-
- The second field of an option record can specify any of the following
- properties. When an option takes an argument, it is enclosed in
- parentheses following the option property name. The parser that handles
- option files is quite simplistic, and will be tricked by any nested
- parentheses within the argument text itself; in this case, the entire
- option argument can be wrapped in curly braces within the parentheses to
- demarcate it, e.g.:
-
- Condition({defined (USE_CYGWIN_LIBSTDCXX_WRAPPERS)})
-
- 'Common'
- The option is available for all languages and targets.
-
- 'Target'
- The option is available for all languages but is target-specific.
-
- 'Driver'
- The option is handled by the compiler driver using code not shared
- with the compilers proper ('cc1' etc.).
-
- 'LANGUAGE'
- The option is available when compiling for the given language.
-
- It is possible to specify several different languages for the same
- option. Each LANGUAGE must have been declared by an earlier
- 'Language' record. *Note Option file format::.
-
- 'RejectDriver'
- The option is only handled by the compilers proper ('cc1' etc.) and
- should not be accepted by the driver.
-
- 'RejectNegative'
- The option does not have a "no-" form. All options beginning with
- "f", "W" or "m" are assumed to have a "no-" form unless this
- property is used.
-
- 'Negative(OTHERNAME)'
- The option will turn off another option OTHERNAME, which is the
- option name with the leading "-" removed. This chain action will
- propagate through the 'Negative' property of the option to be
- turned off. The driver will prune options, removing those that are
- turned off by some later option. This pruning is not done for
- options with 'Joined' or 'JoinedOrMissing' properties, unless the
- options have either 'RejectNegative' property or the 'Negative'
- property mentions an option other than itself.
-
- As a consequence, if you have a group of mutually-exclusive
- options, their 'Negative' properties should form a circular chain.
- For example, if options '-A', '-B' and '-C' are mutually exclusive,
- their respective 'Negative' properties should be 'Negative(B)',
- 'Negative(C)' and 'Negative(A)'.
-
- 'Joined'
- 'Separate'
- The option takes a mandatory argument. 'Joined' indicates that the
- option and argument can be included in the same 'argv' entry (as
- with '-mflush-func=NAME', for example). 'Separate' indicates that
- the option and argument can be separate 'argv' entries (as with
- '-o'). An option is allowed to have both of these properties.
-
- 'JoinedOrMissing'
- The option takes an optional argument. If the argument is given,
- it will be part of the same 'argv' entry as the option itself.
-
- This property cannot be used alongside 'Joined' or 'Separate'.
-
- 'MissingArgError(MESSAGE)'
- For an option marked 'Joined' or 'Separate', the message MESSAGE
- will be used as an error message if the mandatory argument is
- missing; for options without 'MissingArgError', a generic error
- message is used. MESSAGE should contain a single '%qs' format,
- which will be used to format the name of the option passed.
-
- 'Args(N)'
- For an option marked 'Separate', indicate that it takes N
- arguments. The default is 1.
-
- 'UInteger'
- The option's argument is a non-negative integer consisting of
- either decimal or hexadecimal digits interpreted as 'int'.
- Hexadecimal integers may optionally start with the '0x' or '0X'
- prefix. The option parser validates and converts the argument
- before passing it to the relevant option handler. 'UInteger'
- should also be used with options like '-falign-loops' where both
- '-falign-loops' and '-falign-loops'=N are supported to make sure
- the saved options are given a full integer. Positive values of the
- argument in excess of 'INT_MAX' wrap around zero.
-
- 'Host_Wide_Int'
- The option's argument is a non-negative integer consisting of
- either decimal or hexadecimal digits interpreted as the widest
- integer type on the host. As with an 'UInteger' argument,
- hexadecimal integers may optionally start with the '0x' or '0X'
- prefix. The option parser validates and converts the argument
- before passing it to the relevant option handler. 'Host_Wide_Int'
- should be used with options that need to accept very large values.
- Positive values of the argument in excess of 'HOST_WIDE_INT_M1U'
- are assigned 'HOST_WIDE_INT_M1U'.
-
- 'IntegerRange(N, M)'
- The options's arguments are integers of type 'int'. The option's
- parser validates that the value of an option integer argument is
- within the closed range [N, M].
-
- 'ByteSize'
- A property applicable only to 'UInteger' or 'Host_Wide_Int'
- arguments. The option's integer argument is interpreted as if in
- infinite precision using saturation arithmetic in the corresponding
- type. The argument may be followed by a 'byte-size' suffix
- designating a multiple of bytes such as 'kB' and 'KiB' for kilobyte
- and kibibyte, respectively, 'MB' and 'MiB' for megabyte and
- mebibyte, 'GB' and 'GiB' for gigabyte and gigibyte, and so on.
- 'ByteSize' should be used for with options that take a very large
- argument representing a size in bytes, such as '-Wlarger-than='.
-
- 'ToLower'
- The option's argument should be converted to lowercase as part of
- putting it in canonical form, and before comparing with the strings
- indicated by any 'Enum' property.
-
- 'NoDriverArg'
- For an option marked 'Separate', the option only takes an argument
- in the compiler proper, not in the driver. This is for
- compatibility with existing options that are used both directly and
- via '-Wp,'; new options should not have this property.
-
- 'Var(VAR)'
- The state of this option should be stored in variable VAR (actually
- a macro for 'global_options.x_VAR'). The way that the state is
- stored depends on the type of option:
-
- 'WarnRemoved'
- The option is removed and every usage of such option will result in
- a warning. We use it option backward compatibility.
-
- 'Var(VAR, SET)'
- The option controls an integer variable VAR and is active when VAR
- equals SET. The option parser will set VAR to SET when the
- positive form of the option is used and '!SET' when the "no-" form
- is used.
-
- VAR is declared in the same way as for the single-argument form
- described above.
-
- * If the option uses the 'Mask' or 'InverseMask' properties, VAR
- is the integer variable that contains the mask.
-
- * If the option is a normal on/off switch, VAR is an integer
- variable that is nonzero when the option is enabled. The
- options parser will set the variable to 1 when the positive
- form of the option is used and 0 when the "no-" form is used.
-
- * If the option takes an argument and has the 'UInteger'
- property, VAR is an integer variable that stores the value of
- the argument.
-
- * If the option takes an argument and has the 'Enum' property,
- VAR is a variable (type given in the 'Type' property of the
- 'Enum' record whose 'Name' property has the same argument as
- the 'Enum' property of this option) that stores the value of
- the argument.
-
- * If the option has the 'Defer' property, VAR is a pointer to a
- 'VEC(cl_deferred_option,heap)' that stores the option for
- later processing. (VAR is declared with type 'void *' and
- needs to be cast to 'VEC(cl_deferred_option,heap)' before
- use.)
-
- * Otherwise, if the option takes an argument, VAR is a pointer
- to the argument string. The pointer will be null if the
- argument is optional and wasn't given.
-
- The option-processing script will usually zero-initialize VAR. You
- can modify this behavior using 'Init'.
-
- 'Init(VALUE)'
- The variable specified by the 'Var' property should be statically
- initialized to VALUE. If more than one option using the same
- variable specifies 'Init', all must specify the same initializer.
-
- 'Mask(NAME)'
- The option is associated with a bit in the 'target_flags' variable
- (*note Run-time Target::) and is active when that bit is set. You
- may also specify 'Var' to select a variable other than
- 'target_flags'.
-
- The options-processing script will automatically allocate a unique
- bit for the option. If the option is attached to 'target_flags',
- the script will set the macro 'MASK_NAME' to the appropriate
- bitmask. It will also declare a 'TARGET_NAME' macro that has the
- value 1 when the option is active and 0 otherwise. If you use
- 'Var' to attach the option to a different variable, the bitmask
- macro with be called 'OPTION_MASK_NAME'.
-
- 'InverseMask(OTHERNAME)'
- 'InverseMask(OTHERNAME, THISNAME)'
- The option is the inverse of another option that has the
- 'Mask(OTHERNAME)' property. If THISNAME is given, the
- options-processing script will declare a 'TARGET_THISNAME' macro
- that is 1 when the option is active and 0 otherwise.
-
- 'Enum(NAME)'
- The option's argument is a string from the set of strings
- associated with the corresponding 'Enum' record. The string is
- checked and converted to the integer specified in the corresponding
- 'EnumValue' record before being passed to option handlers.
-
- 'Defer'
- The option should be stored in a vector, specified with 'Var', for
- later processing.
-
- 'Alias(OPT)'
- 'Alias(OPT, ARG)'
- 'Alias(OPT, POSARG, NEGARG)'
- The option is an alias for '-OPT' (or the negative form of that
- option, depending on 'NegativeAlias'). In the first form, any
- argument passed to the alias is considered to be passed to '-OPT',
- and '-OPT' is considered to be negated if the alias is used in
- negated form. In the second form, the alias may not be negated or
- have an argument, and POSARG is considered to be passed as an
- argument to '-OPT'. In the third form, the alias may not have an
- argument, if the alias is used in the positive form then POSARG is
- considered to be passed to '-OPT', and if the alias is used in the
- negative form then NEGARG is considered to be passed to '-OPT'.
-
- Aliases should not specify 'Var' or 'Mask' or 'UInteger'. Aliases
- should normally specify the same languages as the target of the
- alias; the flags on the target will be used to determine any
- diagnostic for use of an option for the wrong language, while those
- on the alias will be used to identify what command-line text is the
- option and what text is any argument to that option.
-
- When an 'Alias' definition is used for an option, driver specs do
- not need to handle it and no 'OPT_' enumeration value is defined
- for it; only the canonical form of the option will be seen in those
- places.
-
- 'NegativeAlias'
- For an option marked with 'Alias(OPT)', the option is considered to
- be an alias for the positive form of '-OPT' if negated and for the
- negative form of '-OPT' if not negated. 'NegativeAlias' may not be
- used with the forms of 'Alias' taking more than one argument.
-
- 'Ignore'
- This option is ignored apart from printing any warning specified
- using 'Warn'. The option will not be seen by specs and no 'OPT_'
- enumeration value is defined for it.
-
- 'SeparateAlias'
- For an option marked with 'Joined', 'Separate' and 'Alias', the
- option only acts as an alias when passed a separate argument; with
- a joined argument it acts as a normal option, with an 'OPT_'
- enumeration value. This is for compatibility with the Java '-d'
- option and should not be used for new options.
-
- 'Warn(MESSAGE)'
- If this option is used, output the warning MESSAGE. MESSAGE is a
- format string, either taking a single operand with a '%qs' format
- which is the option name, or not taking any operands, which is
- passed to the 'warning' function. If an alias is marked 'Warn',
- the target of the alias must not also be marked 'Warn'.
-
- 'Report'
- The state of the option should be printed by '-fverbose-asm'.
-
- 'Warning'
- This is a warning option and should be shown as such in '--help'
- output. This flag does not currently affect anything other than
- '--help'.
-
- 'Optimization'
- This is an optimization option. It should be shown as such in
- '--help' output, and any associated variable named using 'Var'
- should be saved and restored when the optimization level is changed
- with 'optimize' attributes.
-
- 'PerFunction'
- This is an option that can be overridden on a per-function basis.
- 'Optimization' implies 'PerFunction', but options that do not
- affect executable code generation may use this flag instead, so
- that the option is not taken into account in ways that might affect
- executable code generation.
-
- 'Param'
- This is an option that is a parameter.
-
- 'Undocumented'
- The option is deliberately missing documentation and should not be
- included in the '--help' output.
-
- 'Condition(COND)'
- The option should only be accepted if preprocessor condition COND
- is true. Note that any C declarations associated with the option
- will be present even if COND is false; COND simply controls whether
- the option is accepted and whether it is printed in the '--help'
- output.
-
- 'Save'
- Build the 'cl_target_option' structure to hold a copy of the
- option, add the functions 'cl_target_option_save' and
- 'cl_target_option_restore' to save and restore the options.
-
- 'SetByCombined'
- The option may also be set by a combined option such as
- '-ffast-math'. This causes the 'gcc_options' struct to have a
- field 'frontend_set_NAME', where 'NAME' is the name of the field
- holding the value of this option (without the leading 'x_'). This
- gives the front end a way to indicate that the value has been set
- explicitly and should not be changed by the combined option. For
- example, some front ends use this to prevent '-ffast-math' and
- '-fno-fast-math' from changing the value of '-fmath-errno' for
- languages that do not use 'errno'.
-
- 'EnabledBy(OPT)'
- 'EnabledBy(OPT || OPT2)'
- 'EnabledBy(OPT && OPT2)'
- If not explicitly set, the option is set to the value of '-OPT';
- multiple options can be given, separated by '||'. The third form
- using '&&' specifies that the option is only set if both OPT and
- OPT2 are set. The options OPT and OPT2 must have the 'Common'
- property; otherwise, use 'LangEnabledBy'.
-
- 'LangEnabledBy(LANGUAGE, OPT)'
- 'LangEnabledBy(LANGUAGE, OPT, POSARG, NEGARG)'
- When compiling for the given language, the option is set to the
- value of '-OPT', if not explicitly set. OPT can be also a list of
- '||' separated options. In the second form, if OPT is used in the
- positive form then POSARG is considered to be passed to the option,
- and if OPT is used in the negative form then NEGARG is considered
- to be passed to the option. It is possible to specify several
- different languages. Each LANGUAGE must have been declared by an
- earlier 'Language' record. *Note Option file format::.
-
- 'NoDWARFRecord'
- The option is omitted from the producer string written by
- '-grecord-gcc-switches'.
-
- 'PchIgnore'
- Even if this is a target option, this option will not be recorded /
- compared to determine if a precompiled header file matches.
-
- 'CPP(VAR)'
- The state of this option should be kept in sync with the
- preprocessor option VAR. If this property is set, then properties
- 'Var' and 'Init' must be set as well.
-
- 'CppReason(CPP_W_ENUM)'
- This warning option corresponds to 'cpplib.h' warning reason code
- CPP_W_ENUM. This should only be used for warning options of the
- C-family front-ends.
-
-
- File: gccint.info, Node: Passes, Next: poly_int, Prev: Options, Up: Top
-
- 9 Passes and Files of the Compiler
- **********************************
-
- This chapter is dedicated to giving an overview of the optimization and
- code generation passes of the compiler. In the process, it describes
- some of the language front end interface, though this description is no
- where near complete.
-
- * Menu:
-
- * Parsing pass:: The language front end turns text into bits.
- * Gimplification pass:: The bits are turned into something we can optimize.
- * Pass manager:: Sequencing the optimization passes.
- * IPA passes:: Inter-procedural optimizations.
- * Tree SSA passes:: Optimizations on a high-level representation.
- * RTL passes:: Optimizations on a low-level representation.
- * Optimization info:: Dumping optimization information from passes.
-
-
- File: gccint.info, Node: Parsing pass, Next: Gimplification pass, Up: Passes
-
- 9.1 Parsing pass
- ================
-
- The language front end is invoked only once, via
- 'lang_hooks.parse_file', to parse the entire input. The language front
- end may use any intermediate language representation deemed appropriate.
- The C front end uses GENERIC trees (*note GENERIC::), plus a double
- handful of language specific tree codes defined in 'c-common.def'. The
- Fortran front end uses a completely different private representation.
-
- At some point the front end must translate the representation used in
- the front end to a representation understood by the language-independent
- portions of the compiler. Current practice takes one of two forms. The
- C front end manually invokes the gimplifier (*note GIMPLE::) on each
- function, and uses the gimplifier callbacks to convert the
- language-specific tree nodes directly to GIMPLE before passing the
- function off to be compiled. The Fortran front end converts from a
- private representation to GENERIC, which is later lowered to GIMPLE when
- the function is compiled. Which route to choose probably depends on how
- well GENERIC (plus extensions) can be made to match up with the source
- language and necessary parsing data structures.
-
- BUG: Gimplification must occur before nested function lowering, and
- nested function lowering must be done by the front end before passing
- the data off to cgraph.
-
- TODO: Cgraph should control nested function lowering. It would only be
- invoked when it is certain that the outer-most function is used.
-
- TODO: Cgraph needs a gimplify_function callback. It should be invoked
- when (1) it is certain that the function is used, (2) warning flags
- specified by the user require some amount of compilation in order to
- honor, (3) the language indicates that semantic analysis is not complete
- until gimplification occurs. Hum... this sounds overly complicated.
- Perhaps we should just have the front end gimplify always; in most cases
- it's only one function call.
-
- The front end needs to pass all function definitions and top level
- declarations off to the middle-end so that they can be compiled and
- emitted to the object file. For a simple procedural language, it is
- usually most convenient to do this as each top level declaration or
- definition is seen. There is also a distinction to be made between
- generating functional code and generating complete debug information.
- The only thing that is absolutely required for functional code is that
- function and data _definitions_ be passed to the middle-end. For
- complete debug information, function, data and type declarations should
- all be passed as well.
-
- In any case, the front end needs each complete top-level function or
- data declaration, and each data definition should be passed to
- 'rest_of_decl_compilation'. Each complete type definition should be
- passed to 'rest_of_type_compilation'. Each function definition should
- be passed to 'cgraph_finalize_function'.
-
- TODO: I know rest_of_compilation currently has all sorts of RTL
- generation semantics. I plan to move all code generation bits (both
- Tree and RTL) to compile_function. Should we hide cgraph from the front
- ends and move back to rest_of_compilation as the official interface?
- Possibly we should rename all three interfaces such that the names match
- in some meaningful way and that is more descriptive than "rest_of".
-
- The middle-end will, at its option, emit the function and data
- definitions immediately or queue them for later processing.
-
-
- File: gccint.info, Node: Gimplification pass, Next: Pass manager, Prev: Parsing pass, Up: Passes
-
- 9.2 Gimplification pass
- =======================
-
- "Gimplification" is a whimsical term for the process of converting the
- intermediate representation of a function into the GIMPLE language
- (*note GIMPLE::). The term stuck, and so words like "gimplification",
- "gimplify", "gimplifier" and the like are sprinkled throughout this
- section of code.
-
- While a front end may certainly choose to generate GIMPLE directly if
- it chooses, this can be a moderately complex process unless the
- intermediate language used by the front end is already fairly simple.
- Usually it is easier to generate GENERIC trees plus extensions and let
- the language-independent gimplifier do most of the work.
-
- The main entry point to this pass is 'gimplify_function_tree' located
- in 'gimplify.c'. From here we process the entire function gimplifying
- each statement in turn. The main workhorse for this pass is
- 'gimplify_expr'. Approximately everything passes through here at least
- once, and it is from here that we invoke the 'lang_hooks.gimplify_expr'
- callback.
-
- The callback should examine the expression in question and return
- 'GS_UNHANDLED' if the expression is not a language specific construct
- that requires attention. Otherwise it should alter the expression in
- some way to such that forward progress is made toward producing valid
- GIMPLE. If the callback is certain that the transformation is complete
- and the expression is valid GIMPLE, it should return 'GS_ALL_DONE'.
- Otherwise it should return 'GS_OK', which will cause the expression to
- be processed again. If the callback encounters an error during the
- transformation (because the front end is relying on the gimplification
- process to finish semantic checks), it should return 'GS_ERROR'.
-
-
- File: gccint.info, Node: Pass manager, Next: IPA passes, Prev: Gimplification pass, Up: Passes
-
- 9.3 Pass manager
- ================
-
- The pass manager is located in 'passes.c', 'tree-optimize.c' and
- 'tree-pass.h'. It processes passes as described in 'passes.def'. Its
- job is to run all of the individual passes in the correct order, and
- take care of standard bookkeeping that applies to every pass.
-
- The theory of operation is that each pass defines a structure that
- represents everything we need to know about that pass--when it should be
- run, how it should be run, what intermediate language form or
- on-the-side data structures it needs. We register the pass to be run in
- some particular order, and the pass manager arranges for everything to
- happen in the correct order.
-
- The actuality doesn't completely live up to the theory at present.
- Command-line switches and 'timevar_id_t' enumerations must still be
- defined elsewhere. The pass manager validates constraints but does not
- attempt to (re-)generate data structures or lower intermediate language
- form based on the requirements of the next pass. Nevertheless, what is
- present is useful, and a far sight better than nothing at all.
-
- Each pass should have a unique name. Each pass may have its own dump
- file (for GCC debugging purposes). Passes with a name starting with a
- star do not dump anything. Sometimes passes are supposed to share a
- dump file / option name. To still give these unique names, you can use
- a prefix that is delimited by a space from the part that is used for the
- dump file / option name. E.g. When the pass name is "ud dce", the name
- used for dump file/options is "dce".
-
- TODO: describe the global variables set up by the pass manager, and a
- brief description of how a new pass should use it. I need to look at
- what info RTL passes use first...
-
-
- File: gccint.info, Node: IPA passes, Next: Tree SSA passes, Prev: Pass manager, Up: Passes
-
- 9.4 Inter-procedural optimization passes
- ========================================
-
- The inter-procedural optimization (IPA) passes use call graph
- information to perform transformations across function boundaries. IPA
- is a critical part of link-time optimization (LTO) and whole-program
- (WHOPR) optimization, and these passes are structured with the needs of
- LTO and WHOPR in mind by dividing their operations into stages. For
- detailed discussion of the LTO/WHOPR IPA pass stages and interfaces, see
- *note IPA::.
-
- The following briefly describes the inter-procedural optimization (IPA)
- passes, which are split into small IPA passes, regular IPA passes, and
- late IPA passes, according to the LTO/WHOPR processing model.
-
- * Menu:
-
- * Small IPA passes::
- * Regular IPA passes::
- * Late IPA passes::
-
-
- File: gccint.info, Node: Small IPA passes, Next: Regular IPA passes, Up: IPA passes
-
- 9.4.1 Small IPA passes
- ----------------------
-
- A small IPA pass is a pass derived from 'simple_ipa_opt_pass'. As
- described in *note IPA::, it does everything at once and defines only
- the _Execute_ stage. During this stage it accesses and modifies the
- function bodies. No 'generate_summary', 'read_summary', or
- 'write_summary' hooks are defined.
-
- * IPA free lang data
-
- This pass frees resources that are used by the front end but are
- not needed once it is done. It is located in 'tree.c' and is
- described by 'pass_ipa_free_lang_data'.
-
- * IPA function and variable visibility
-
- This is a local function pass handling visibilities of all symbols.
- This happens before LTO streaming, so '-fwhole-program' should be
- ignored at this level. It is located in 'ipa-visibility.c' and is
- described by 'pass_ipa_function_and_variable_visibility'.
-
- * IPA remove symbols
-
- This pass performs reachability analysis and reclaims all
- unreachable nodes. It is located in 'passes.c' and is described by
- 'pass_ipa_remove_symbols'.
-
- * IPA OpenACC
-
- This is a pass group for OpenACC processing. It is located in
- 'tree-ssa-loop.c' and is described by 'pass_ipa_oacc'.
-
- * IPA points-to analysis
-
- This is a tree-based points-to analysis pass. The idea behind this
- analyzer is to generate set constraints from the program, then
- solve the resulting constraints in order to generate the points-to
- sets. It is located in 'tree-ssa-structalias.c' and is described
- by 'pass_ipa_pta'.
-
- * IPA OpenACC kernels
-
- This is a pass group for processing OpenACC kernels regions. It is
- a subpass of the IPA OpenACC pass group that runs on offloaded
- functions containing OpenACC kernels loops. It is located in
- 'tree-ssa-loop.c' and is described by 'pass_ipa_oacc_kernels'.
-
- * Target clone
-
- This is a pass for parsing functions with multiple target
- attributes. It is located in 'multiple_target.c' and is described
- by 'pass_target_clone'.
-
- * IPA auto profile
-
- This pass uses AutoFDO profiling data to annotate the control flow
- graph. It is located in 'auto-profile.c' and is described by
- 'pass_ipa_auto_profile'.
-
- * IPA tree profile
-
- This pass does profiling for all functions in the call graph. It
- calculates branch probabilities and basic block execution counts.
- It is located in 'tree-profile.c' and is described by
- 'pass_ipa_tree_profile'.
-
- * IPA free function summary
-
- This pass is a small IPA pass when argument 'small_p' is true. It
- releases inline function summaries and call summaries. It is
- located in 'ipa-fnsummary.c' and is described by
- 'pass_ipa_free_free_fn_summary'.
-
- * IPA increase alignment
-
- This pass increases the alignment of global arrays to improve
- vectorization. It is located in 'tree-vectorizer.c' and is
- described by 'pass_ipa_increase_alignment'.
-
- * IPA transactional memory
-
- This pass is for transactional memory support. It is located in
- 'trans-mem.c' and is described by 'pass_ipa_tm'.
-
- * IPA lower emulated TLS
-
- This pass lowers thread-local storage (TLS) operations to emulation
- functions provided by libgcc. It is located in 'tree-emutls.c' and
- is described by 'pass_ipa_lower_emutls'.
-
-
- File: gccint.info, Node: Regular IPA passes, Next: Late IPA passes, Prev: Small IPA passes, Up: IPA passes
-
- 9.4.2 Regular IPA passes
- ------------------------
-
- A regular IPA pass is a pass derived from 'ipa_opt_pass_d' that is
- executed in WHOPR compilation. Regular IPA passes may have summary
- hooks implemented in any of the LGEN, WPA or LTRANS stages (*note
- IPA::).
-
- * IPA whole program visibility
-
- This pass performs various optimizations involving symbol
- visibility with '-fwhole-program', including symbol privatization,
- discovering local functions, and dismantling comdat groups. It is
- located in 'ipa-visibility.c' and is described by
- 'pass_ipa_whole_program_visibility'.
-
- * IPA profile
-
- The IPA profile pass propagates profiling frequencies across the
- call graph. It is located in 'ipa-profile.c' and is described by
- 'pass_ipa_profile'.
-
- * IPA identical code folding
-
- This is the inter-procedural identical code folding pass. The goal
- of this transformation is to discover functions and read-only
- variables that have exactly the same semantics. It is located in
- 'ipa-icf.c' and is described by 'pass_ipa_icf'.
-
- * IPA devirtualization
-
- This pass performs speculative devirtualization based on the type
- inheritance graph. When a polymorphic call has only one likely
- target in the unit, it is turned into a speculative call. It is
- located in 'ipa-devirt.c' and is described by 'pass_ipa_devirt'.
-
- * IPA constant propagation
-
- The goal of this pass is to discover functions that are always
- invoked with some arguments with the same known constant values and
- to modify the functions accordingly. It can also do partial
- specialization and type-based devirtualization. It is located in
- 'ipa-cp.c' and is described by 'pass_ipa_cp'.
-
- * IPA scalar replacement of aggregates
-
- This pass can replace an aggregate parameter with a set of other
- parameters representing part of the original, turning those passed
- by reference into new ones which pass the value directly. It also
- removes unused function return values and unused function
- parameters. This pass is located in 'ipa-sra.c' and is described
- by 'pass_ipa_sra'.
-
- * IPA constructor/destructor merge
-
- This pass merges multiple constructors and destructors for static
- objects into single functions. It's only run at LTO time unless
- the target doesn't support constructors and destructors natively.
- The pass is located in 'ipa.c' and is described by
- 'pass_ipa_cdtor_merge'.
-
- * IPA HSA
-
- This pass is part of the GCC support for HSA (Heterogeneous System
- Architecture) accelerators. It is responsible for creation of HSA
- clones and emitting HSAIL instructions for them. It is located in
- 'ipa-hsa.c' and is described by 'pass_ipa_hsa'.
-
- * IPA function summary
-
- This pass provides function analysis for inter-procedural passes.
- It collects estimates of function body size, execution time, and
- frame size for each function. It also estimates information about
- function calls: call statement size, time and how often the
- parameters change for each call. It is located in
- 'ipa-fnsummary.c' and is described by 'pass_ipa_fn_summary'.
-
- * IPA inline
-
- The IPA inline pass handles function inlining with whole-program
- knowledge. Small functions that are candidates for inlining are
- ordered in increasing badness, bounded by unit growth parameters.
- Unreachable functions are removed from the call graph. Functions
- called once and not exported from the unit are inlined. This pass
- is located in 'ipa-inline.c' and is described by 'pass_ipa_inline'.
-
- * IPA pure/const analysis
-
- This pass marks functions as being either const ('TREE_READONLY')
- or pure ('DECL_PURE_P'). The per-function information is produced
- by 'pure_const_generate_summary', then the global information is
- computed by performing a transitive closure over the call graph.
- It is located in 'ipa-pure-const.c' and is described by
- 'pass_ipa_pure_const'.
-
- * IPA free function summary
-
- This pass is a regular IPA pass when argument 'small_p' is false.
- It releases inline function summaries and call summaries. It is
- located in 'ipa-fnsummary.c' and is described by
- 'pass_ipa_free_fn_summary'.
-
- * IPA reference
-
- This pass gathers information about how variables whose scope is
- confined to the compilation unit are used. It is located in
- 'ipa-reference.c' and is described by 'pass_ipa_reference'.
-
- * IPA single use
-
- This pass checks whether variables are used by a single function.
- It is located in 'ipa.c' and is described by 'pass_ipa_single_use'.
-
- * IPA comdats
-
- This pass looks for static symbols that are used exclusively within
- one comdat group, and moves them into that comdat group. It is
- located in 'ipa-comdats.c' and is described by 'pass_ipa_comdats'.
-
-
- File: gccint.info, Node: Late IPA passes, Prev: Regular IPA passes, Up: IPA passes
-
- 9.4.3 Late IPA passes
- ---------------------
-
- Late IPA passes are simple IPA passes executed after the regular passes.
- In WHOPR mode the passes are executed after partitioning and thus see
- just parts of the compiled unit.
-
- * Materialize all clones
-
- Once all functions from compilation unit are in memory, produce all
- clones and update all calls. It is located in 'ipa.c' and is
- described by 'pass_materialize_all_clones'.
-
- * IPA points-to analysis
-
- Points-to analysis; this is the same as the points-to-analysis pass
- run with the small IPA passes (*note Small IPA passes::).
-
- * OpenMP simd clone
-
- This is the OpenMP constructs' SIMD clone pass. It creates the
- appropriate SIMD clones for functions tagged as elemental SIMD
- functions. It is located in 'omp-simd-clone.c' and is described by
- 'pass_omp_simd_clone'.
-
-
- File: gccint.info, Node: Tree SSA passes, Next: RTL passes, Prev: IPA passes, Up: Passes
-
- 9.5 Tree SSA passes
- ===================
-
- The following briefly describes the Tree optimization passes that are
- run after gimplification and what source files they are located in.
-
- * Remove useless statements
-
- This pass is an extremely simple sweep across the gimple code in
- which we identify obviously dead code and remove it. Here we do
- things like simplify 'if' statements with constant conditions,
- remove exception handling constructs surrounding code that
- obviously cannot throw, remove lexical bindings that contain no
- variables, and other assorted simplistic cleanups. The idea is to
- get rid of the obvious stuff quickly rather than wait until later
- when it's more work to get rid of it. This pass is located in
- 'tree-cfg.c' and described by 'pass_remove_useless_stmts'.
-
- * OpenMP lowering
-
- If OpenMP generation ('-fopenmp') is enabled, this pass lowers
- OpenMP constructs into GIMPLE.
-
- Lowering of OpenMP constructs involves creating replacement
- expressions for local variables that have been mapped using data
- sharing clauses, exposing the control flow of most synchronization
- directives and adding region markers to facilitate the creation of
- the control flow graph. The pass is located in 'omp-low.c' and is
- described by 'pass_lower_omp'.
-
- * OpenMP expansion
-
- If OpenMP generation ('-fopenmp') is enabled, this pass expands
- parallel regions into their own functions to be invoked by the
- thread library. The pass is located in 'omp-low.c' and is
- described by 'pass_expand_omp'.
-
- * Lower control flow
-
- This pass flattens 'if' statements ('COND_EXPR') and moves lexical
- bindings ('BIND_EXPR') out of line. After this pass, all 'if'
- statements will have exactly two 'goto' statements in its 'then'
- and 'else' arms. Lexical binding information for each statement
- will be found in 'TREE_BLOCK' rather than being inferred from its
- position under a 'BIND_EXPR'. This pass is found in 'gimple-low.c'
- and is described by 'pass_lower_cf'.
-
- * Lower exception handling control flow
-
- This pass decomposes high-level exception handling constructs
- ('TRY_FINALLY_EXPR' and 'TRY_CATCH_EXPR') into a form that
- explicitly represents the control flow involved. After this pass,
- 'lookup_stmt_eh_region' will return a non-negative number for any
- statement that may have EH control flow semantics; examine
- 'tree_can_throw_internal' or 'tree_can_throw_external' for exact
- semantics. Exact control flow may be extracted from
- 'foreach_reachable_handler'. The EH region nesting tree is defined
- in 'except.h' and built in 'except.c'. The lowering pass itself is
- in 'tree-eh.c' and is described by 'pass_lower_eh'.
-
- * Build the control flow graph
-
- This pass decomposes a function into basic blocks and creates all
- of the edges that connect them. It is located in 'tree-cfg.c' and
- is described by 'pass_build_cfg'.
-
- * Find all referenced variables
-
- This pass walks the entire function and collects an array of all
- variables referenced in the function, 'referenced_vars'. The index
- at which a variable is found in the array is used as a UID for the
- variable within this function. This data is needed by the SSA
- rewriting routines. The pass is located in 'tree-dfa.c' and is
- described by 'pass_referenced_vars'.
-
- * Enter static single assignment form
-
- This pass rewrites the function such that it is in SSA form. After
- this pass, all 'is_gimple_reg' variables will be referenced by
- 'SSA_NAME', and all occurrences of other variables will be
- annotated with 'VDEFS' and 'VUSES'; PHI nodes will have been
- inserted as necessary for each basic block. This pass is located
- in 'tree-ssa.c' and is described by 'pass_build_ssa'.
-
- * Warn for uninitialized variables
-
- This pass scans the function for uses of 'SSA_NAME's that are fed
- by default definition. For non-parameter variables, such uses are
- uninitialized. The pass is run twice, before and after
- optimization (if turned on). In the first pass we only warn for
- uses that are positively uninitialized; in the second pass we warn
- for uses that are possibly uninitialized. The pass is located in
- 'tree-ssa.c' and is defined by 'pass_early_warn_uninitialized' and
- 'pass_late_warn_uninitialized'.
-
- * Dead code elimination
-
- This pass scans the function for statements without side effects
- whose result is unused. It does not do memory life analysis, so
- any value that is stored in memory is considered used. The pass is
- run multiple times throughout the optimization process. It is
- located in 'tree-ssa-dce.c' and is described by 'pass_dce'.
-
- * Dominator optimizations
-
- This pass performs trivial dominator-based copy and constant
- propagation, expression simplification, and jump threading. It is
- run multiple times throughout the optimization process. It is
- located in 'tree-ssa-dom.c' and is described by 'pass_dominator'.
-
- * Forward propagation of single-use variables
-
- This pass attempts to remove redundant computation by substituting
- variables that are used once into the expression that uses them and
- seeing if the result can be simplified. It is located in
- 'tree-ssa-forwprop.c' and is described by 'pass_forwprop'.
-
- * Copy Renaming
-
- This pass attempts to change the name of compiler temporaries
- involved in copy operations such that SSA->normal can coalesce the
- copy away. When compiler temporaries are copies of user variables,
- it also renames the compiler temporary to the user variable
- resulting in better use of user symbols. It is located in
- 'tree-ssa-copyrename.c' and is described by 'pass_copyrename'.
-
- * PHI node optimizations
-
- This pass recognizes forms of PHI inputs that can be represented as
- conditional expressions and rewrites them into straight line code.
- It is located in 'tree-ssa-phiopt.c' and is described by
- 'pass_phiopt'.
-
- * May-alias optimization
-
- This pass performs a flow sensitive SSA-based points-to analysis.
- The resulting may-alias, must-alias, and escape analysis
- information is used to promote variables from in-memory addressable
- objects to non-aliased variables that can be renamed into SSA form.
- We also update the 'VDEF'/'VUSE' memory tags for non-renameable
- aggregates so that we get fewer false kills. The pass is located
- in 'tree-ssa-alias.c' and is described by 'pass_may_alias'.
-
- Interprocedural points-to information is located in
- 'tree-ssa-structalias.c' and described by 'pass_ipa_pta'.
-
- * Profiling
-
- This pass instruments the function in order to collect runtime
- block and value profiling data. Such data may be fed back into the
- compiler on a subsequent run so as to allow optimization based on
- expected execution frequencies. The pass is located in
- 'tree-profile.c' and is described by 'pass_ipa_tree_profile'.
-
- * Static profile estimation
-
- This pass implements series of heuristics to guess propababilities
- of branches. The resulting predictions are turned into edge
- profile by propagating branches across the control flow graphs.
- The pass is located in 'tree-profile.c' and is described by
- 'pass_profile'.
-
- * Lower complex arithmetic
-
- This pass rewrites complex arithmetic operations into their
- component scalar arithmetic operations. The pass is located in
- 'tree-complex.c' and is described by 'pass_lower_complex'.
-
- * Scalar replacement of aggregates
-
- This pass rewrites suitable non-aliased local aggregate variables
- into a set of scalar variables. The resulting scalar variables are
- rewritten into SSA form, which allows subsequent optimization
- passes to do a significantly better job with them. The pass is
- located in 'tree-sra.c' and is described by 'pass_sra'.
-
- * Dead store elimination
-
- This pass eliminates stores to memory that are subsequently
- overwritten by another store, without any intervening loads. The
- pass is located in 'tree-ssa-dse.c' and is described by 'pass_dse'.
-
- * Tail recursion elimination
-
- This pass transforms tail recursion into a loop. It is located in
- 'tree-tailcall.c' and is described by 'pass_tail_recursion'.
-
- * Forward store motion
-
- This pass sinks stores and assignments down the flowgraph closer to
- their use point. The pass is located in 'tree-ssa-sink.c' and is
- described by 'pass_sink_code'.
-
- * Partial redundancy elimination
-
- This pass eliminates partially redundant computations, as well as
- performing load motion. The pass is located in 'tree-ssa-pre.c'
- and is described by 'pass_pre'.
-
- Just before partial redundancy elimination, if
- '-funsafe-math-optimizations' is on, GCC tries to convert divisions
- to multiplications by the reciprocal. The pass is located in
- 'tree-ssa-math-opts.c' and is described by 'pass_cse_reciprocal'.
-
- * Full redundancy elimination
-
- This is a simpler form of PRE that only eliminates redundancies
- that occur on all paths. It is located in 'tree-ssa-pre.c' and
- described by 'pass_fre'.
-
- * Loop optimization
-
- The main driver of the pass is placed in 'tree-ssa-loop.c' and
- described by 'pass_loop'.
-
- The optimizations performed by this pass are:
-
- Loop invariant motion. This pass moves only invariants that would
- be hard to handle on RTL level (function calls, operations that
- expand to nontrivial sequences of insns). With '-funswitch-loops'
- it also moves operands of conditions that are invariant out of the
- loop, so that we can use just trivial invariantness analysis in
- loop unswitching. The pass also includes store motion. The pass
- is implemented in 'tree-ssa-loop-im.c'.
-
- Canonical induction variable creation. This pass creates a simple
- counter for number of iterations of the loop and replaces the exit
- condition of the loop using it, in case when a complicated analysis
- is necessary to determine the number of iterations. Later
- optimizations then may determine the number easily. The pass is
- implemented in 'tree-ssa-loop-ivcanon.c'.
-
- Induction variable optimizations. This pass performs standard
- induction variable optimizations, including strength reduction,
- induction variable merging and induction variable elimination. The
- pass is implemented in 'tree-ssa-loop-ivopts.c'.
-
- Loop unswitching. This pass moves the conditional jumps that are
- invariant out of the loops. To achieve this, a duplicate of the
- loop is created for each possible outcome of conditional jump(s).
- The pass is implemented in 'tree-ssa-loop-unswitch.c'.
-
- Loop splitting. If a loop contains a conditional statement that is
- always true for one part of the iteration space and false for the
- other this pass splits the loop into two, one dealing with one side
- the other only with the other, thereby removing one inner-loop
- conditional. The pass is implemented in 'tree-ssa-loop-split.c'.
-
- The optimizations also use various utility functions contained in
- 'tree-ssa-loop-manip.c', 'cfgloop.c', 'cfgloopanal.c' and
- 'cfgloopmanip.c'.
-
- Vectorization. This pass transforms loops to operate on vector
- types instead of scalar types. Data parallelism across loop
- iterations is exploited to group data elements from consecutive
- iterations into a vector and operate on them in parallel.
- Depending on available target support the loop is conceptually
- unrolled by a factor 'VF' (vectorization factor), which is the
- number of elements operated upon in parallel in each iteration, and
- the 'VF' copies of each scalar operation are fused to form a vector
- operation. Additional loop transformations such as peeling and
- versioning may take place to align the number of iterations, and to
- align the memory accesses in the loop. The pass is implemented in
- 'tree-vectorizer.c' (the main driver), 'tree-vect-loop.c' and
- 'tree-vect-loop-manip.c' (loop specific parts and general loop
- utilities), 'tree-vect-slp' (loop-aware SLP functionality),
- 'tree-vect-stmts.c' and 'tree-vect-data-refs.c'. Analysis of data
- references is in 'tree-data-ref.c'.
-
- SLP Vectorization. This pass performs vectorization of
- straight-line code. The pass is implemented in 'tree-vectorizer.c'
- (the main driver), 'tree-vect-slp.c', 'tree-vect-stmts.c' and
- 'tree-vect-data-refs.c'.
-
- Autoparallelization. This pass splits the loop iteration space to
- run into several threads. The pass is implemented in
- 'tree-parloops.c'.
-
- Graphite is a loop transformation framework based on the polyhedral
- model. Graphite stands for Gimple Represented as Polyhedra. The
- internals of this infrastructure are documented in
- <http://gcc.gnu.org/wiki/Graphite>. The passes working on this
- representation are implemented in the various 'graphite-*' files.
-
- * Tree level if-conversion for vectorizer
-
- This pass applies if-conversion to simple loops to help vectorizer.
- We identify if convertible loops, if-convert statements and merge
- basic blocks in one big block. The idea is to present loop in such
- form so that vectorizer can have one to one mapping between
- statements and available vector operations. This pass is located
- in 'tree-if-conv.c' and is described by 'pass_if_conversion'.
-
- * Conditional constant propagation
-
- This pass relaxes a lattice of values in order to identify those
- that must be constant even in the presence of conditional branches.
- The pass is located in 'tree-ssa-ccp.c' and is described by
- 'pass_ccp'.
-
- A related pass that works on memory loads and stores, and not just
- register values, is located in 'tree-ssa-ccp.c' and described by
- 'pass_store_ccp'.
-
- * Conditional copy propagation
-
- This is similar to constant propagation but the lattice of values
- is the "copy-of" relation. It eliminates redundant copies from the
- code. The pass is located in 'tree-ssa-copy.c' and described by
- 'pass_copy_prop'.
-
- A related pass that works on memory copies, and not just register
- copies, is located in 'tree-ssa-copy.c' and described by
- 'pass_store_copy_prop'.
-
- * Value range propagation
-
- This transformation is similar to constant propagation but instead
- of propagating single constant values, it propagates known value
- ranges. The implementation is based on Patterson's range
- propagation algorithm (Accurate Static Branch Prediction by Value
- Range Propagation, J. R. C. Patterson, PLDI '95). In contrast to
- Patterson's algorithm, this implementation does not propagate
- branch probabilities nor it uses more than a single range per SSA
- name. This means that the current implementation cannot be used
- for branch prediction (though adapting it would not be difficult).
- The pass is located in 'tree-vrp.c' and is described by 'pass_vrp'.
-
- * Folding built-in functions
-
- This pass simplifies built-in functions, as applicable, with
- constant arguments or with inferable string lengths. It is located
- in 'tree-ssa-ccp.c' and is described by 'pass_fold_builtins'.
-
- * Split critical edges
-
- This pass identifies critical edges and inserts empty basic blocks
- such that the edge is no longer critical. The pass is located in
- 'tree-cfg.c' and is described by 'pass_split_crit_edges'.
-
- * Control dependence dead code elimination
-
- This pass is a stronger form of dead code elimination that can
- eliminate unnecessary control flow statements. It is located in
- 'tree-ssa-dce.c' and is described by 'pass_cd_dce'.
-
- * Tail call elimination
-
- This pass identifies function calls that may be rewritten into
- jumps. No code transformation is actually applied here, but the
- data and control flow problem is solved. The code transformation
- requires target support, and so is delayed until RTL. In the
- meantime 'CALL_EXPR_TAILCALL' is set indicating the possibility.
- The pass is located in 'tree-tailcall.c' and is described by
- 'pass_tail_calls'. The RTL transformation is handled by
- 'fixup_tail_calls' in 'calls.c'.
-
- * Warn for function return without value
-
- For non-void functions, this pass locates return statements that do
- not specify a value and issues a warning. Such a statement may
- have been injected by falling off the end of the function. This
- pass is run last so that we have as much time as possible to prove
- that the statement is not reachable. It is located in 'tree-cfg.c'
- and is described by 'pass_warn_function_return'.
-
- * Leave static single assignment form
-
- This pass rewrites the function such that it is in normal form. At
- the same time, we eliminate as many single-use temporaries as
- possible, so the intermediate language is no longer GIMPLE, but
- GENERIC. The pass is located in 'tree-outof-ssa.c' and is
- described by 'pass_del_ssa'.
-
- * Merge PHI nodes that feed into one another
-
- This is part of the CFG cleanup passes. It attempts to join PHI
- nodes from a forwarder CFG block into another block with PHI nodes.
- The pass is located in 'tree-cfgcleanup.c' and is described by
- 'pass_merge_phi'.
-
- * Return value optimization
-
- If a function always returns the same local variable, and that
- local variable is an aggregate type, then the variable is replaced
- with the return value for the function (i.e., the function's
- DECL_RESULT). This is equivalent to the C++ named return value
- optimization applied to GIMPLE. The pass is located in
- 'tree-nrv.c' and is described by 'pass_nrv'.
-
- * Return slot optimization
-
- If a function returns a memory object and is called as 'var =
- foo()', this pass tries to change the call so that the address of
- 'var' is sent to the caller to avoid an extra memory copy. This
- pass is located in 'tree-nrv.c' and is described by
- 'pass_return_slot'.
-
- * Optimize calls to '__builtin_object_size'
-
- This is a propagation pass similar to CCP that tries to remove
- calls to '__builtin_object_size' when the size of the object can be
- computed at compile-time. This pass is located in
- 'tree-object-size.c' and is described by 'pass_object_sizes'.
-
- * Loop invariant motion
-
- This pass removes expensive loop-invariant computations out of
- loops. The pass is located in 'tree-ssa-loop.c' and described by
- 'pass_lim'.
-
- * Loop nest optimizations
-
- This is a family of loop transformations that works on loop nests.
- It includes loop interchange, scaling, skewing and reversal and
- they are all geared to the optimization of data locality in array
- traversals and the removal of dependencies that hamper
- optimizations such as loop parallelization and vectorization. The
- pass is located in 'tree-loop-linear.c' and described by
- 'pass_linear_transform'.
-
- * Removal of empty loops
-
- This pass removes loops with no code in them. The pass is located
- in 'tree-ssa-loop-ivcanon.c' and described by 'pass_empty_loop'.
-
- * Unrolling of small loops
-
- This pass completely unrolls loops with few iterations. The pass
- is located in 'tree-ssa-loop-ivcanon.c' and described by
- 'pass_complete_unroll'.
-
- * Predictive commoning
-
- This pass makes the code reuse the computations from the previous
- iterations of the loops, especially loads and stores to memory. It
- does so by storing the values of these computations to a bank of
- temporary variables that are rotated at the end of loop. To avoid
- the need for this rotation, the loop is then unrolled and the
- copies of the loop body are rewritten to use the appropriate
- version of the temporary variable. This pass is located in
- 'tree-predcom.c' and described by 'pass_predcom'.
-
- * Array prefetching
-
- This pass issues prefetch instructions for array references inside
- loops. The pass is located in 'tree-ssa-loop-prefetch.c' and
- described by 'pass_loop_prefetch'.
-
- * Reassociation
-
- This pass rewrites arithmetic expressions to enable optimizations
- that operate on them, like redundancy elimination and
- vectorization. The pass is located in 'tree-ssa-reassoc.c' and
- described by 'pass_reassoc'.
-
- * Optimization of 'stdarg' functions
-
- This pass tries to avoid the saving of register arguments into the
- stack on entry to 'stdarg' functions. If the function doesn't use
- any 'va_start' macros, no registers need to be saved. If
- 'va_start' macros are used, the 'va_list' variables don't escape
- the function, it is only necessary to save registers that will be
- used in 'va_arg' macros. For instance, if 'va_arg' is only used
- with integral types in the function, floating point registers don't
- need to be saved. This pass is located in 'tree-stdarg.c' and
- described by 'pass_stdarg'.
-
-
- File: gccint.info, Node: RTL passes, Next: Optimization info, Prev: Tree SSA passes, Up: Passes
-
- 9.6 RTL passes
- ==============
-
- The following briefly describes the RTL generation and optimization
- passes that are run after the Tree optimization passes.
-
- * RTL generation
-
- The source files for RTL generation include 'stmt.c', 'calls.c',
- 'expr.c', 'explow.c', 'expmed.c', 'function.c', 'optabs.c' and
- 'emit-rtl.c'. Also, the file 'insn-emit.c', generated from the
- machine description by the program 'genemit', is used in this pass.
- The header file 'expr.h' is used for communication within this
- pass.
-
- The header files 'insn-flags.h' and 'insn-codes.h', generated from
- the machine description by the programs 'genflags' and 'gencodes',
- tell this pass which standard names are available for use and which
- patterns correspond to them.
-
- * Generation of exception landing pads
-
- This pass generates the glue that handles communication between the
- exception handling library routines and the exception handlers
- within the function. Entry points in the function that are invoked
- by the exception handling library are called "landing pads". The
- code for this pass is located in 'except.c'.
-
- * Control flow graph cleanup
-
- This pass removes unreachable code, simplifies jumps to next, jumps
- to jump, jumps across jumps, etc. The pass is run multiple times.
- For historical reasons, it is occasionally referred to as the "jump
- optimization pass". The bulk of the code for this pass is in
- 'cfgcleanup.c', and there are support routines in 'cfgrtl.c' and
- 'jump.c'.
-
- * Forward propagation of single-def values
-
- This pass attempts to remove redundant computation by substituting
- variables that come from a single definition, and seeing if the
- result can be simplified. It performs copy propagation and
- addressing mode selection. The pass is run twice, with values
- being propagated into loops only on the second run. The code is
- located in 'fwprop.c'.
-
- * Common subexpression elimination
-
- This pass removes redundant computation within basic blocks, and
- optimizes addressing modes based on cost. The pass is run twice.
- The code for this pass is located in 'cse.c'.
-
- * Global common subexpression elimination
-
- This pass performs two different types of GCSE depending on whether
- you are optimizing for size or not (LCM based GCSE tends to
- increase code size for a gain in speed, while Morel-Renvoise based
- GCSE does not). When optimizing for size, GCSE is done using
- Morel-Renvoise Partial Redundancy Elimination, with the exception
- that it does not try to move invariants out of loops--that is left
- to the loop optimization pass. If MR PRE GCSE is done, code
- hoisting (aka unification) is also done, as well as load motion.
- If you are optimizing for speed, LCM (lazy code motion) based GCSE
- is done. LCM is based on the work of Knoop, Ruthing, and Steffen.
- LCM based GCSE also does loop invariant code motion. We also
- perform load and store motion when optimizing for speed.
- Regardless of which type of GCSE is used, the GCSE pass also
- performs global constant and copy propagation. The source file for
- this pass is 'gcse.c', and the LCM routines are in 'lcm.c'.
-
- * Loop optimization
-
- This pass performs several loop related optimizations. The source
- files 'cfgloopanal.c' and 'cfgloopmanip.c' contain generic loop
- analysis and manipulation code. Initialization and finalization of
- loop structures is handled by 'loop-init.c'. A loop invariant
- motion pass is implemented in 'loop-invariant.c'. Basic block
- level optimizations--unrolling, and peeling loops-- are implemented
- in 'loop-unroll.c'. Replacing of the exit condition of loops by
- special machine-dependent instructions is handled by
- 'loop-doloop.c'.
-
- * Jump bypassing
-
- This pass is an aggressive form of GCSE that transforms the control
- flow graph of a function by propagating constants into conditional
- branch instructions. The source file for this pass is 'gcse.c'.
-
- * If conversion
-
- This pass attempts to replace conditional branches and surrounding
- assignments with arithmetic, boolean value producing comparison
- instructions, and conditional move instructions. In the very last
- invocation after reload/LRA, it will generate predicated
- instructions when supported by the target. The code is located in
- 'ifcvt.c'.
-
- * Web construction
-
- This pass splits independent uses of each pseudo-register. This
- can improve effect of the other transformation, such as CSE or
- register allocation. The code for this pass is located in 'web.c'.
-
- * Instruction combination
-
- This pass attempts to combine groups of two or three instructions
- that are related by data flow into single instructions. It
- combines the RTL expressions for the instructions by substitution,
- simplifies the result using algebra, and then attempts to match the
- result against the machine description. The code is located in
- 'combine.c'.
-
- * Mode switching optimization
-
- This pass looks for instructions that require the processor to be
- in a specific "mode" and minimizes the number of mode changes
- required to satisfy all users. What these modes are, and what they
- apply to are completely target-specific. The code for this pass is
- located in 'mode-switching.c'.
-
- * Modulo scheduling
-
- This pass looks at innermost loops and reorders their instructions
- by overlapping different iterations. Modulo scheduling is
- performed immediately before instruction scheduling. The code for
- this pass is located in 'modulo-sched.c'.
-
- * Instruction scheduling
-
- This pass looks for instructions whose output will not be available
- by the time that it is used in subsequent instructions. Memory
- loads and floating point instructions often have this behavior on
- RISC machines. It re-orders instructions within a basic block to
- try to separate the definition and use of items that otherwise
- would cause pipeline stalls. This pass is performed twice, before
- and after register allocation. The code for this pass is located
- in 'haifa-sched.c', 'sched-deps.c', 'sched-ebb.c', 'sched-rgn.c'
- and 'sched-vis.c'.
-
- * Register allocation
-
- These passes make sure that all occurrences of pseudo registers are
- eliminated, either by allocating them to a hard register, replacing
- them by an equivalent expression (e.g. a constant) or by placing
- them on the stack. This is done in several subpasses:
-
- * The integrated register allocator (IRA). It is called
- integrated because coalescing, register live range splitting,
- and hard register preferencing are done on-the-fly during
- coloring. It also has better integration with the reload/LRA
- pass. Pseudo-registers spilled by the allocator or the
- reload/LRA have still a chance to get hard-registers if the
- reload/LRA evicts some pseudo-registers from hard-registers.
- The allocator helps to choose better pseudos for spilling
- based on their live ranges and to coalesce stack slots
- allocated for the spilled pseudo-registers. IRA is a regional
- register allocator which is transformed into Chaitin-Briggs
- allocator if there is one region. By default, IRA chooses
- regions using register pressure but the user can force it to
- use one region or regions corresponding to all loops.
-
- Source files of the allocator are 'ira.c', 'ira-build.c',
- 'ira-costs.c', 'ira-conflicts.c', 'ira-color.c', 'ira-emit.c',
- 'ira-lives', plus header files 'ira.h' and 'ira-int.h' used
- for the communication between the allocator and the rest of
- the compiler and between the IRA files.
-
- * Reloading. This pass renumbers pseudo registers with the
- hardware registers numbers they were allocated. Pseudo
- registers that did not get hard registers are replaced with
- stack slots. Then it finds instructions that are invalid
- because a value has failed to end up in a register, or has
- ended up in a register of the wrong kind. It fixes up these
- instructions by reloading the problematical values temporarily
- into registers. Additional instructions are generated to do
- the copying.
-
- The reload pass also optionally eliminates the frame pointer
- and inserts instructions to save and restore call-clobbered
- registers around calls.
-
- Source files are 'reload.c' and 'reload1.c', plus the header
- 'reload.h' used for communication between them.
-
- * This pass is a modern replacement of the reload pass. Source
- files are 'lra.c', 'lra-assign.c', 'lra-coalesce.c',
- 'lra-constraints.c', 'lra-eliminations.c', 'lra-lives.c',
- 'lra-remat.c', 'lra-spills.c', the header 'lra-int.h' used for
- communication between them, and the header 'lra.h' used for
- communication between LRA and the rest of compiler.
-
- Unlike the reload pass, intermediate LRA decisions are
- reflected in RTL as much as possible. This reduces the number
- of target-dependent macros and hooks, leaving instruction
- constraints as the primary source of control.
-
- LRA is run on targets for which TARGET_LRA_P returns true.
-
- * Basic block reordering
-
- This pass implements profile guided code positioning. If profile
- information is not available, various types of static analysis are
- performed to make the predictions normally coming from the profile
- feedback (IE execution frequency, branch probability, etc). It is
- implemented in the file 'bb-reorder.c', and the various prediction
- routines are in 'predict.c'.
-
- * Variable tracking
-
- This pass computes where the variables are stored at each position
- in code and generates notes describing the variable locations to
- RTL code. The location lists are then generated according to these
- notes to debug information if the debugging information format
- supports location lists. The code is located in 'var-tracking.c'.
-
- * Delayed branch scheduling
-
- This optional pass attempts to find instructions that can go into
- the delay slots of other instructions, usually jumps and calls.
- The code for this pass is located in 'reorg.c'.
-
- * Branch shortening
-
- On many RISC machines, branch instructions have a limited range.
- Thus, longer sequences of instructions must be used for long
- branches. In this pass, the compiler figures out what how far each
- instruction will be from each other instruction, and therefore
- whether the usual instructions, or the longer sequences, must be
- used for each branch. The code for this pass is located in
- 'final.c'.
-
- * Register-to-stack conversion
-
- Conversion from usage of some hard registers to usage of a register
- stack may be done at this point. Currently, this is supported only
- for the floating-point registers of the Intel 80387 coprocessor.
- The code for this pass is located in 'reg-stack.c'.
-
- * Final
-
- This pass outputs the assembler code for the function. The source
- files are 'final.c' plus 'insn-output.c'; the latter is generated
- automatically from the machine description by the tool 'genoutput'.
- The header file 'conditions.h' is used for communication between
- these files.
-
- * Debugging information output
-
- This is run after final because it must output the stack slot
- offsets for pseudo registers that did not get hard registers.
- Source files are 'dbxout.c' for DBX symbol table format,
- 'dwarfout.c' for DWARF symbol table format, files 'dwarf2out.c' and
- 'dwarf2asm.c' for DWARF2 symbol table format, and 'vmsdbgout.c' for
- VMS debug symbol table format.
-
-
- File: gccint.info, Node: Optimization info, Prev: RTL passes, Up: Passes
-
- 9.7 Optimization info
- =====================
-
- This section is describes dump infrastructure which is common to both
- pass dumps as well as optimization dumps. The goal for this
- infrastructure is to provide both gcc developers and users detailed
- information about various compiler transformations and optimizations.
-
- * Menu:
-
- * Dump setup:: Setup of optimization dumps.
- * Optimization groups:: Groups made up of optimization passes.
- * Dump files and streams:: Dump output file names and streams.
- * Dump output verbosity:: How much information to dump.
- * Dump types:: Various types of dump functions.
- * Dump examples:: Sample usage.
-
-
- File: gccint.info, Node: Dump setup, Next: Optimization groups, Up: Optimization info
-
- 9.7.1 Dump setup
- ----------------
-
- A dump_manager class is defined in 'dumpfile.h'. Various passes
- register dumping pass-specific information via 'dump_register' in
- 'passes.c'. During the registration, an optimization pass can select
- its optimization group (*note Optimization groups::). After that
- optimization information corresponding to the entire group (presumably
- from multiple passes) can be output via command-line switches. Note
- that if a pass does not fit into any of the pre-defined groups, it can
- select 'OPTGROUP_NONE'.
-
- Note that in general, a pass need not know its dump output file name,
- whether certain flags are enabled, etc. However, for legacy reasons,
- passes could also call 'dump_begin' which returns a stream in case the
- particular pass has optimization dumps enabled. A pass could call
- 'dump_end' when the dump has ended. These methods should go away once
- all the passes are converted to use the new dump infrastructure.
-
- The recommended way to setup the dump output is via 'dump_start' and
- 'dump_end'.
-
-
- File: gccint.info, Node: Optimization groups, Next: Dump files and streams, Prev: Dump setup, Up: Optimization info
-
- 9.7.2 Optimization groups
- -------------------------
-
- The optimization passes are grouped into several categories. Currently
- defined categories in 'dumpfile.h' are
-
- 'OPTGROUP_IPA'
- IPA optimization passes. Enabled by '-ipa'
-
- 'OPTGROUP_LOOP'
- Loop optimization passes. Enabled by '-loop'.
-
- 'OPTGROUP_INLINE'
- Inlining passes. Enabled by '-inline'.
-
- 'OPTGROUP_OMP'
- OMP (Offloading and Multi Processing) passes. Enabled by '-omp'.
-
- 'OPTGROUP_VEC'
- Vectorization passes. Enabled by '-vec'.
-
- 'OPTGROUP_OTHER'
- All other optimization passes which do not fall into one of the
- above.
-
- 'OPTGROUP_ALL'
- All optimization passes. Enabled by '-optall'.
-
- By using groups a user could selectively enable optimization
- information only for a group of passes. By default, the optimization
- information for all the passes is dumped.
-
-
- File: gccint.info, Node: Dump files and streams, Next: Dump output verbosity, Prev: Optimization groups, Up: Optimization info
-
- 9.7.3 Dump files and streams
- ----------------------------
-
- There are two separate output streams available for outputting
- optimization information from passes. Note that both these streams
- accept 'stderr' and 'stdout' as valid streams and thus it is possible to
- dump output to standard output or error. This is specially handy for
- outputting all available information in a single file by redirecting
- 'stderr'.
-
- 'pstream'
- This stream is for pass-specific dump output. For example,
- '-fdump-tree-vect=foo.v' dumps tree vectorization pass output into
- the given file name 'foo.v'. If the file name is not provided, the
- default file name is based on the source file and pass number.
- Note that one could also use special file names 'stdout' and
- 'stderr' for dumping to standard output and standard error
- respectively.
-
- 'alt_stream'
- This steam is used for printing optimization specific output in
- response to the '-fopt-info'. Again a file name can be given. If
- the file name is not given, it defaults to 'stderr'.
-
-
- File: gccint.info, Node: Dump output verbosity, Next: Dump types, Prev: Dump files and streams, Up: Optimization info
-
- 9.7.4 Dump output verbosity
- ---------------------------
-
- The dump verbosity has the following options
-
- 'optimized'
- Print information when an optimization is successfully applied. It
- is up to a pass to decide which information is relevant. For
- example, the vectorizer passes print the source location of loops
- which got successfully vectorized.
-
- 'missed'
- Print information about missed optimizations. Individual passes
- control which information to include in the output. For example,
-
- gcc -O2 -ftree-vectorize -fopt-info-vec-missed
-
- will print information about missed optimization opportunities from
- vectorization passes on stderr.
-
- 'note'
- Print verbose information about optimizations, such as certain
- transformations, more detailed messages about decisions etc.
-
- 'all'
- Print detailed optimization information. This includes OPTIMIZED,
- MISSED, and NOTE.
-
-
- File: gccint.info, Node: Dump types, Next: Dump examples, Prev: Dump output verbosity, Up: Optimization info
-
- 9.7.5 Dump types
- ----------------
-
- 'dump_printf'
-
- This is a generic method for doing formatted output. It takes an
- additional argument 'dump_kind' which signifies the type of dump.
- This method outputs information only when the dumps are enabled for
- this particular 'dump_kind'. Note that the caller doesn't need to
- know if the particular dump is enabled or not, or even the file
- name. The caller only needs to decide which dump output
- information is relevant, and under what conditions. This
- determines the associated flags.
-
- Consider the following example from 'loop-unroll.c' where an
- informative message about a loop (along with its location) is
- printed when any of the following flags is enabled
-
- - optimization messages
- - RTL dumps
- - detailed dumps
-
- int report_flags = MSG_OPTIMIZED_LOCATIONS | TDF_RTL | TDF_DETAILS;
- dump_printf_loc (report_flags, insn,
- "loop turned into non-loop; it never loops.\n");
-
- 'dump_basic_block'
- Output basic block.
- 'dump_generic_expr'
- Output generic expression.
- 'dump_gimple_stmt'
- Output gimple statement.
-
- Note that the above methods also have variants prefixed with
- '_loc', such as 'dump_printf_loc', which are similar except they
- also output the source location information. The '_loc' variants
- take a 'const dump_location_t &'. This class can be constructed
- from a 'gimple *' or from a 'rtx_insn *', and so callers can pass a
- 'gimple *' or a 'rtx_insn *' as the '_loc' argument. The
- 'dump_location_t' constructor will extract the source location from
- the statement or instruction, along with the profile count, and the
- location in GCC's own source code (or the plugin) from which the
- dump call was emitted. Only the source location is currently used.
- There is also a 'dump_user_location_t' class, capturing the source
- location and profile count, but not the dump emission location, so
- that locations in the user's code can be passed around. This can
- also be constructed from a 'gimple *' and from a 'rtx_insn *', and
- it too can be passed as the '_loc' argument.
-
-
- File: gccint.info, Node: Dump examples, Prev: Dump types, Up: Optimization info
-
- 9.7.6 Dump examples
- -------------------
-
- gcc -O3 -fopt-info-missed=missed.all
-
- outputs missed optimization report from all the passes into
- 'missed.all'.
-
- As another example,
- gcc -O3 -fopt-info-inline-optimized-missed=inline.txt
-
- will output information about missed optimizations as well as optimized
- locations from all the inlining passes into 'inline.txt'.
-
- If the FILENAME is provided, then the dumps from all the applicable
- optimizations are concatenated into the 'filename'. Otherwise the dump
- is output onto 'stderr'. If OPTIONS is omitted, it defaults to
- 'optimized-optall', which means dump all information about successful
- optimizations from all the passes. In the following example, the
- optimization information is output on to 'stderr'.
-
- gcc -O3 -fopt-info
-
- Note that '-fopt-info-vec-missed' behaves the same as
- '-fopt-info-missed-vec'. The order of the optimization group names and
- message types listed after '-fopt-info' does not matter.
-
- As another example, consider
-
- gcc -fopt-info-vec-missed=vec.miss -fopt-info-loop-optimized=loop.opt
-
- Here the two output file names 'vec.miss' and 'loop.opt' are in
- conflict since only one output file is allowed. In this case, only the
- first option takes effect and the subsequent options are ignored. Thus
- only the 'vec.miss' is produced which containts dumps from the
- vectorizer about missed opportunities.
-
-
- File: gccint.info, Node: poly_int, Next: GENERIC, Prev: Passes, Up: Top
-
- 10 Sizes and offsets as runtime invariants
- ******************************************
-
- GCC allows the size of a hardware register to be a runtime invariant
- rather than a compile-time constant. This in turn means that various
- sizes and offsets must also be runtime invariants rather than
- compile-time constants, such as:
-
- * the size of a general 'machine_mode' (*note Machine Modes::);
-
- * the size of a spill slot;
-
- * the offset of something within a stack frame;
-
- * the number of elements in a vector;
-
- * the size and offset of a 'mem' rtx (*note Regs and Memory::); and
-
- * the byte offset in a 'subreg' rtx (*note Regs and Memory::).
-
- The motivating example is the Arm SVE ISA, whose vector registers can
- be any multiple of 128 bits between 128 and 2048 inclusive. The
- compiler normally produces code that works for all SVE register sizes,
- with the actual size only being known at runtime.
-
- GCC's main representation of such runtime invariants is the 'poly_int'
- class. This chapter describes what 'poly_int' does, lists the available
- operations, and gives some general usage guidelines.
-
- * Menu:
-
- * Overview of poly_int::
- * Consequences of using poly_int::
- * Comparisons involving poly_int::
- * Arithmetic on poly_ints::
- * Alignment of poly_ints::
- * Computing bounds on poly_ints::
- * Converting poly_ints::
- * Miscellaneous poly_int routines::
- * Guidelines for using poly_int::
-
-
- File: gccint.info, Node: Overview of poly_int, Next: Consequences of using poly_int, Up: poly_int
-
- 10.1 Overview of 'poly_int'
- ===========================
-
- We define indeterminates X1, ..., XN whose values are only known at
- runtime and use polynomials of the form:
-
- C0 + C1 * X1 + ... + CN * XN
-
- to represent a size or offset whose value might depend on some of these
- indeterminates. The coefficients C0, ..., CN are always known at
- compile time, with the C0 term being the "constant" part that does not
- depend on any runtime value.
-
- GCC uses the 'poly_int' class to represent these coefficients. The
- class has two template parameters: the first specifies the number of
- coefficients (N + 1) and the second specifies the type of the
- coefficients. For example, 'poly_int<2, unsigned short>' represents a
- polynomial with two coefficients (and thus one indeterminate), with each
- coefficient having type 'unsigned short'. When N is 0, the class
- degenerates to a single compile-time constant C0.
-
- The number of coefficients needed for compilation is a fixed property
- of each target and is specified by the configuration macro
- 'NUM_POLY_INT_COEFFS'. The default value is 1, since most targets do
- not have such runtime invariants. Targets that need a different value
- should '#define' the macro in their 'CPU-modes.def' file. *Note Back
- End::.
-
- 'poly_int' makes the simplifying requirement that each indeterminate
- must be a nonnegative integer. An indeterminate value of 0 should
- usually represent the minimum possible runtime value, with C0 specifying
- the value in that case.
-
- For example, when targetting the Arm SVE ISA, the single indeterminate
- represents the number of 128-bit blocks in a vector _beyond the minimum
- length of 128 bits_. Thus the number of 64-bit doublewords in a vector
- is 2 + 2 * X1. If an aggregate has a single SVE vector and 16
- additional bytes, its total size is 32 + 16 * X1 bytes.
-
- The header file 'poly-int-types.h' provides typedefs for the most
- common forms of 'poly_int', all having 'NUM_POLY_INT_COEFFS'
- coefficients:
-
- 'poly_uint16'
- a 'poly_int' with 'unsigned short' coefficients.
-
- 'poly_int64'
- a 'poly_int' with 'HOST_WIDE_INT' coefficients.
-
- 'poly_uint64'
- a 'poly_int' with 'unsigned HOST_WIDE_INT' coefficients.
-
- 'poly_offset_int'
- a 'poly_int' with 'offset_int' coefficients.
-
- 'poly_wide_int'
- a 'poly_int' with 'wide_int' coefficients.
-
- 'poly_widest_int'
- a 'poly_int' with 'widest_int' coefficients.
-
- Since the main purpose of 'poly_int' is to represent sizes and offsets,
- the last two typedefs are only rarely used.
-
-
- File: gccint.info, Node: Consequences of using poly_int, Next: Comparisons involving poly_int, Prev: Overview of poly_int, Up: poly_int
-
- 10.2 Consequences of using 'poly_int'
- =====================================
-
- The two main consequences of using polynomial sizes and offsets are
- that:
-
- * there is no total ordering between the values at compile time, and
-
- * some operations might yield results that cannot be expressed as a
- 'poly_int'.
-
- For example, if X is a runtime invariant, we cannot tell at compile
- time whether:
-
- 3 + 4X <= 1 + 5X
-
- since the condition is false when X <= 1 and true when X >= 2.
-
- Similarly, 'poly_int' cannot represent the result of:
-
- (3 + 4X) * (1 + 5X)
-
- since it cannot (and in practice does not need to) store powers greater
- than one. It also cannot represent the result of:
-
- (3 + 4X) / (1 + 5X)
-
- The following sections describe how we deal with these restrictions.
-
- As described earlier, a 'poly_int<1, T>' has no indeterminates and so
- degenerates to a compile-time constant of type T. It would be possible
- in that case to do all normal arithmetic on the T, and to compare the T
- using the normal C++ operators. We deliberately prevent
- target-independent code from doing this, since the compiler needs to
- support other 'poly_int<N, T>' as well, regardless of the current
- target's 'NUM_POLY_INT_COEFFS'.
-
- However, it would be very artificial to force target-specific code to
- follow these restrictions if the target has no runtime indeterminates.
- There is therefore an implicit conversion from 'poly_int<1, T>' to T
- when compiling target-specific translation units.
-
-
- File: gccint.info, Node: Comparisons involving poly_int, Next: Arithmetic on poly_ints, Prev: Consequences of using poly_int, Up: poly_int
-
- 10.3 Comparisons involving 'poly_int'
- =====================================
-
- In general we need to compare sizes and offsets in two situations: those
- in which the values need to be ordered, and those in which the values
- can be unordered. More loosely, the distinction is often between values
- that have a definite link (usually because they refer to the same
- underlying register or memory location) and values that have no definite
- link. An example of the former is the relationship between the inner
- and outer sizes of a subreg, where we must know at compile time whether
- the subreg is paradoxical, partial, or complete. An example of the
- latter is alias analysis: we might want to check whether two arbitrary
- memory references overlap.
-
- Referring back to the examples in the previous section, it makes sense
- to ask whether a memory reference of size '3 + 4X' overlaps one of size
- '1 + 5X', but it does not make sense to have a subreg in which the outer
- mode has '3 + 4X' bytes and the inner mode has '1 + 5X' bytes (or vice
- versa). Such subregs are always invalid and should trigger an internal
- compiler error if formed.
-
- The underlying operators are the same in both cases, but the
- distinction affects how they are used.
-
- * Menu:
-
- * Comparison functions for poly_int::
- * Properties of the poly_int comparisons::
- * Comparing potentially-unordered poly_ints::
- * Comparing ordered poly_ints::
- * Checking for a poly_int marker value::
- * Range checks on poly_ints::
- * Sorting poly_ints::
-
-
- File: gccint.info, Node: Comparison functions for poly_int, Next: Properties of the poly_int comparisons, Up: Comparisons involving poly_int
-
- 10.3.1 Comparison functions for 'poly_int'
- ------------------------------------------
-
- 'poly_int' provides the following routines for checking whether a
- particular condition "may be" (might be) true:
-
- maybe_lt maybe_le maybe_eq maybe_ge maybe_gt
- maybe_ne
-
- The functions have their natural meaning:
-
- 'maybe_lt(A, B)'
- Return true if A might be less than B.
-
- 'maybe_le(A, B)'
- Return true if A might be less than or equal to B.
-
- 'maybe_eq(A, B)'
- Return true if A might be equal to B.
-
- 'maybe_ne(A, B)'
- Return true if A might not be equal to B.
-
- 'maybe_ge(A, B)'
- Return true if A might be greater than or equal to B.
-
- 'maybe_gt(A, B)'
- Return true if A might be greater than B.
-
- For readability, 'poly_int' also provides "known" inverses of these
- functions:
-
- known_lt (A, B) == !maybe_ge (A, B)
- known_le (A, B) == !maybe_gt (A, B)
- known_eq (A, B) == !maybe_ne (A, B)
- known_ge (A, B) == !maybe_lt (A, B)
- known_gt (A, B) == !maybe_le (A, B)
- known_ne (A, B) == !maybe_eq (A, B)
-
-
- File: gccint.info, Node: Properties of the poly_int comparisons, Next: Comparing potentially-unordered poly_ints, Prev: Comparison functions for poly_int, Up: Comparisons involving poly_int
-
- 10.3.2 Properties of the 'poly_int' comparisons
- -----------------------------------------------
-
- All "maybe" relations except 'maybe_ne' are transitive, so for example:
-
- maybe_lt (A, B) && maybe_lt (B, C) implies maybe_lt (A, C)
-
- for all A, B and C. 'maybe_lt', 'maybe_gt' and 'maybe_ne' are
- irreflexive, so for example:
-
- !maybe_lt (A, A)
-
- is true for all A. 'maybe_le', 'maybe_eq' and 'maybe_ge' are
- reflexive, so for example:
-
- maybe_le (A, A)
-
- is true for all A. 'maybe_eq' and 'maybe_ne' are symmetric, so:
-
- maybe_eq (A, B) == maybe_eq (B, A)
- maybe_ne (A, B) == maybe_ne (B, A)
-
- for all A and B. In addition:
-
- maybe_le (A, B) == maybe_lt (A, B) || maybe_eq (A, B)
- maybe_ge (A, B) == maybe_gt (A, B) || maybe_eq (A, B)
- maybe_lt (A, B) == maybe_gt (B, A)
- maybe_le (A, B) == maybe_ge (B, A)
-
- However:
-
- maybe_le (A, B) && maybe_le (B, A) does not imply !maybe_ne (A, B) [== known_eq (A, B)]
- maybe_ge (A, B) && maybe_ge (B, A) does not imply !maybe_ne (A, B) [== known_eq (A, B)]
-
- One example is again 'A == 3 + 4X' and 'B == 1 + 5X', where 'maybe_le
- (A, B)', 'maybe_ge (A, B)' and 'maybe_ne (A, B)' all hold. 'maybe_le'
- and 'maybe_ge' are therefore not antisymetric and do not form a partial
- order.
-
- From the above, it follows that:
-
- * All "known" relations except 'known_ne' are transitive.
-
- * 'known_lt', 'known_ne' and 'known_gt' are irreflexive.
-
- * 'known_le', 'known_eq' and 'known_ge' are reflexive.
-
- Also:
-
- known_lt (A, B) == known_gt (B, A)
- known_le (A, B) == known_ge (B, A)
- known_lt (A, B) implies !known_lt (B, A) [asymmetry]
- known_gt (A, B) implies !known_gt (B, A)
- known_le (A, B) && known_le (B, A) == known_eq (A, B) [== !maybe_ne (A, B)]
- known_ge (A, B) && known_ge (B, A) == known_eq (A, B) [== !maybe_ne (A, B)]
-
- 'known_le' and 'known_ge' are therefore antisymmetric and are partial
- orders. However:
-
- known_le (A, B) does not imply known_lt (A, B) || known_eq (A, B)
- known_ge (A, B) does not imply known_gt (A, B) || known_eq (A, B)
-
- For example, 'known_le (4, 4 + 4X)' holds because the runtime
- indeterminate X is a nonnegative integer, but neither 'known_lt (4, 4 +
- 4X)' nor 'known_eq (4, 4 + 4X)' hold.
-
-
- File: gccint.info, Node: Comparing potentially-unordered poly_ints, Next: Comparing ordered poly_ints, Prev: Properties of the poly_int comparisons, Up: Comparisons involving poly_int
-
- 10.3.3 Comparing potentially-unordered 'poly_int's
- --------------------------------------------------
-
- In cases where there is no definite link between two 'poly_int's, we can
- usually make a conservatively-correct assumption. For example, the
- conservative assumption for alias analysis is that two references
- _might_ alias.
-
- One way of checking whether [BEGIN1, END1) might overlap [BEGIN2, END2)
- using the 'poly_int' comparisons is:
-
- maybe_gt (END1, BEGIN2) && maybe_gt (END2, BEGIN1)
-
- and another (equivalent) way is:
-
- !(known_le (END1, BEGIN2) || known_le (END2, BEGIN1))
-
- However, in this particular example, it is better to use the range
- helper functions instead. *Note Range checks on poly_ints::.
-
-
- File: gccint.info, Node: Comparing ordered poly_ints, Next: Checking for a poly_int marker value, Prev: Comparing potentially-unordered poly_ints, Up: Comparisons involving poly_int
-
- 10.3.4 Comparing ordered 'poly_int's
- ------------------------------------
-
- In cases where there is a definite link between two 'poly_int's, such as
- the outer and inner sizes of subregs, we usually require the sizes to be
- ordered by the 'known_le' partial order. 'poly_int' provides the
- following utility functions for ordered values:
-
- 'ordered_p (A, B)'
- Return true if A and B are ordered by the 'known_le' partial order.
-
- 'ordered_min (A, B)'
- Assert that A and B are ordered by 'known_le' and return the
- minimum of the two. When using this function, please add a comment
- explaining why the values are known to be ordered.
-
- 'ordered_max (A, B)'
- Assert that A and B are ordered by 'known_le' and return the
- maximum of the two. When using this function, please add a comment
- explaining why the values are known to be ordered.
-
- For example, if a subreg has an outer mode of size OUTER and an inner
- mode of size INNER:
-
- * the subreg is complete if known_eq (INNER, OUTER)
-
- * otherwise, the subreg is paradoxical if known_le (INNER, OUTER)
-
- * otherwise, the subreg is partial if known_le (OUTER, INNER)
-
- * otherwise, the subreg is ill-formed
-
- Thus the subreg is only valid if 'ordered_p (OUTER, INNER)' is true.
- If this condition is already known to be true then:
-
- * the subreg is complete if known_eq (INNER, OUTER)
-
- * the subreg is paradoxical if maybe_lt (INNER, OUTER)
-
- * the subreg is partial if maybe_lt (OUTER, INNER)
-
- with the three conditions being mutually exclusive.
-
- Code that checks whether a subreg is valid would therefore generally
- check whether 'ordered_p' holds (in addition to whatever other checks
- are required for subreg validity). Code that is dealing with existing
- subregs can assert that 'ordered_p' holds and use either of the
- classifications above.
-
-
- File: gccint.info, Node: Checking for a poly_int marker value, Next: Range checks on poly_ints, Prev: Comparing ordered poly_ints, Up: Comparisons involving poly_int
-
- 10.3.5 Checking for a 'poly_int' marker value
- ---------------------------------------------
-
- It is sometimes useful to have a special "marker value" that is not
- meant to be taken literally. For example, some code uses a size of -1
- to represent an unknown size, rather than having to carry around a
- separate boolean to say whether the size is known.
-
- The best way of checking whether something is a marker value is
- 'known_eq'. Conversely the best way of checking whether something is
- _not_ a marker value is 'maybe_ne'.
-
- Thus in the size example just mentioned, 'known_eq (size, -1)' would
- check for an unknown size and 'maybe_ne (size, -1)' would check for a
- known size.
-
-
- File: gccint.info, Node: Range checks on poly_ints, Next: Sorting poly_ints, Prev: Checking for a poly_int marker value, Up: Comparisons involving poly_int
-
- 10.3.6 Range checks on 'poly_int's
- ----------------------------------
-
- As well as the core comparisons (*note Comparison functions for
- poly_int::), 'poly_int' provides utilities for various kinds of range
- check. In each case the range is represented by a start position and a
- size rather than a start position and an end position; this is because
- the former is used much more often than the latter in GCC. Also, the
- sizes can be -1 (or all ones for unsigned sizes) to indicate a range
- with a known start position but an unknown size. All other sizes must
- be nonnegative. A range of size 0 does not contain anything or overlap
- anything.
-
- 'known_size_p (SIZE)'
- Return true if SIZE represents a known range size, false if it is
- -1 or all ones (for signed and unsigned types respectively).
-
- 'ranges_maybe_overlap_p (POS1, SIZE1, POS2, SIZE2)'
- Return true if the range described by POS1 and SIZE1 _might_
- overlap the range described by POS2 and SIZE2 (in other words,
- return true if we cannot prove that the ranges are disjoint).
-
- 'ranges_known_overlap_p (POS1, SIZE1, POS2, SIZE2)'
- Return true if the range described by POS1 and SIZE1 is known to
- overlap the range described by POS2 and SIZE2.
-
- 'known_subrange_p (POS1, SIZE1, POS2, SIZE2)'
- Return true if the range described by POS1 and SIZE1 is known to be
- contained in the range described by POS2 and SIZE2.
-
- 'maybe_in_range_p (VALUE, POS, SIZE)'
- Return true if VALUE _might_ be in the range described by POS and
- SIZE (in other words, return true if we cannot prove that VALUE is
- outside that range).
-
- 'known_in_range_p (VALUE, POS, SIZE)'
- Return true if VALUE is known to be in the range described by POS
- and SIZE.
-
- 'endpoint_representable_p (POS, SIZE)'
- Return true if the range described by POS and SIZE is open-ended or
- if the endpoint (POS + SIZE) is representable in the same type as
- POS and SIZE. The function returns false if adding SIZE to POS
- makes conceptual sense but could overflow.
-
- There is also a 'poly_int' version of the 'IN_RANGE_P' macro:
-
- 'coeffs_in_range_p (X, LOWER, UPPER)'
- Return true if every coefficient of X is in the inclusive range
- [LOWER, UPPER]. This function can be useful when testing whether
- an operation would cause the values of coefficients to overflow.
-
- Note that the function does not indicate whether X itself is in the
- given range. X can be either a constant or a 'poly_int'.
-
-
- File: gccint.info, Node: Sorting poly_ints, Prev: Range checks on poly_ints, Up: Comparisons involving poly_int
-
- 10.3.7 Sorting 'poly_int's
- --------------------------
-
- 'poly_int' provides the following routine for sorting:
-
- 'compare_sizes_for_sort (A, B)'
- Compare A and B in reverse lexicographical order (that is, compare
- the highest-indexed coefficients first). This can be useful when
- sorting data structures, since it has the effect of separating
- constant and non-constant values. If all values are nonnegative,
- the constant values come first.
-
- Note that the values do not necessarily end up in numerical order.
- For example, '1 + 1X' would come after '100' in the sort order, but
- may well be less than '100' at run time.
-
-
- File: gccint.info, Node: Arithmetic on poly_ints, Next: Alignment of poly_ints, Prev: Comparisons involving poly_int, Up: poly_int
-
- 10.4 Arithmetic on 'poly_int's
- ==============================
-
- Addition, subtraction, negation and bit inversion all work normally for
- 'poly_int's. Multiplication by a constant multiplier and left shifting
- by a constant shift amount also work normally. General multiplication
- of two 'poly_int's is not supported and is not useful in practice.
-
- Other operations are only conditionally supported: the operation might
- succeed or might fail, depending on the inputs.
-
- This section describes both types of operation.
-
- * Menu:
-
- * Using poly_int with C++ arithmetic operators::
- * wi arithmetic on poly_ints::
- * Division of poly_ints::
- * Other poly_int arithmetic::
-
-
- File: gccint.info, Node: Using poly_int with C++ arithmetic operators, Next: wi arithmetic on poly_ints, Up: Arithmetic on poly_ints
-
- 10.4.1 Using 'poly_int' with C++ arithmetic operators
- -----------------------------------------------------
-
- The following C++ expressions are supported, where P1 and P2 are
- 'poly_int's and where C1 and C2 are scalars:
-
- -P1
- ~P1
-
- P1 + P2
- P1 + C2
- C1 + P2
-
- P1 - P2
- P1 - C2
- C1 - P2
-
- C1 * P2
- P1 * C2
-
- P1 << C2
-
- P1 += P2
- P1 += C2
-
- P1 -= P2
- P1 -= C2
-
- P1 *= C2
- P1 <<= C2
-
- These arithmetic operations handle integer ranks in a similar way to
- C++. The main difference is that every coefficient narrower than
- 'HOST_WIDE_INT' promotes to 'HOST_WIDE_INT', whereas in C++ everything
- narrower than 'int' promotes to 'int'. For example:
-
- poly_uint16 + int -> poly_int64
- unsigned int + poly_uint16 -> poly_int64
- poly_int64 + int -> poly_int64
- poly_int32 + poly_uint64 -> poly_uint64
- uint64 + poly_int64 -> poly_uint64
- poly_offset_int + int32 -> poly_offset_int
- offset_int + poly_uint16 -> poly_offset_int
-
- In the first two examples, both coefficients are narrower than
- 'HOST_WIDE_INT', so the result has coefficients of type 'HOST_WIDE_INT'.
- In the other examples, the coefficient with the highest rank "wins".
-
- If one of the operands is 'wide_int' or 'poly_wide_int', the rules are
- the same as for 'wide_int' arithmetic.
-
-
- File: gccint.info, Node: wi arithmetic on poly_ints, Next: Division of poly_ints, Prev: Using poly_int with C++ arithmetic operators, Up: Arithmetic on poly_ints
-
- 10.4.2 'wi' arithmetic on 'poly_int's
- -------------------------------------
-
- As well as the C++ operators, 'poly_int' supports the following 'wi'
- routines:
-
- wi::neg (P1, &OVERFLOW)
-
- wi::add (P1, P2)
- wi::add (P1, C2)
- wi::add (C1, P1)
- wi::add (P1, P2, SIGN, &OVERFLOW)
-
- wi::sub (P1, P2)
- wi::sub (P1, C2)
- wi::sub (C1, P1)
- wi::sub (P1, P2, SIGN, &OVERFLOW)
-
- wi::mul (P1, C2)
- wi::mul (C1, P1)
- wi::mul (P1, C2, SIGN, &OVERFLOW)
-
- wi::lshift (P1, C2)
-
- These routines just check whether overflow occurs on any individual
- coefficient; it is not possible to know at compile time whether the
- final runtime value would overflow.
-
-
- File: gccint.info, Node: Division of poly_ints, Next: Other poly_int arithmetic, Prev: wi arithmetic on poly_ints, Up: Arithmetic on poly_ints
-
- 10.4.3 Division of 'poly_int's
- ------------------------------
-
- Division of 'poly_int's is possible for certain inputs. The functions
- for division return true if the operation is possible and in most cases
- return the results by pointer. The routines are:
-
- 'multiple_p (A, B)'
- 'multiple_p (A, B, "IENT)'
- Return true if A is an exact multiple of B, storing the result in
- QUOTIENT if so. There are overloads for various combinations of
- polynomial and constant A, B and QUOTIENT.
-
- 'constant_multiple_p (A, B)'
- 'constant_multiple_p (A, B, "IENT)'
- Like 'multiple_p', but also test whether the multiple is a
- compile-time constant.
-
- 'can_div_trunc_p (A, B, "IENT)'
- 'can_div_trunc_p (A, B, "IENT, &REMAINDER)'
- Return true if we can calculate 'trunc (A / B)' at compile time,
- storing the result in QUOTIENT and REMAINDER if so.
-
- 'can_div_away_from_zero_p (A, B, "IENT)'
- Return true if we can calculate 'A / B' at compile time, rounding
- away from zero. Store the result in QUOTIENT if so.
-
- Note that this is true if and only if 'can_div_trunc_p' is true.
- The only difference is in the rounding of the result.
-
- There is also an asserting form of division:
-
- 'exact_div (A, B)'
- Assert that A is a multiple of B and return 'A / B'. The result is
- a 'poly_int' if A is a 'poly_int'.
-
-
- File: gccint.info, Node: Other poly_int arithmetic, Prev: Division of poly_ints, Up: Arithmetic on poly_ints
-
- 10.4.4 Other 'poly_int' arithmetic
- ----------------------------------
-
- There are tentative routines for other operations besides division:
-
- 'can_ior_p (A, B, &RESULT)'
- Return true if we can calculate 'A | B' at compile time, storing
- the result in RESULT if so.
-
- Also, ANDs with a value '(1 << Y) - 1' or its inverse can be treated as
- alignment operations. *Note Alignment of poly_ints::.
-
- In addition, the following miscellaneous routines are available:
-
- 'coeff_gcd (A)'
- Return the greatest common divisor of all nonzero coefficients in
- A, or zero if A is known to be zero.
-
- 'common_multiple (A, B)'
- Return a value that is a multiple of both A and B, where one value
- is a 'poly_int' and the other is a scalar. The result will be the
- least common multiple for some indeterminate values but not
- necessarily for all.
-
- 'force_common_multiple (A, B)'
- Return a value that is a multiple of both 'poly_int' A and
- 'poly_int' B, asserting that such a value exists. The result will
- be the least common multiple for some indeterminate values but not
- necessarily for all.
-
- When using this routine, please add a comment explaining why the
- assertion is known to hold.
-
- Please add any other operations that you find to be useful.
-
-
- File: gccint.info, Node: Alignment of poly_ints, Next: Computing bounds on poly_ints, Prev: Arithmetic on poly_ints, Up: poly_int
-
- 10.5 Alignment of 'poly_int's
- =============================
-
- 'poly_int' provides various routines for aligning values and for
- querying misalignments. In each case the alignment must be a power of
- 2.
-
- 'can_align_p (VALUE, ALIGN)'
- Return true if we can align VALUE up or down to the nearest
- multiple of ALIGN at compile time. The answer is the same for both
- directions.
-
- 'can_align_down (VALUE, ALIGN, &ALIGNED)'
- Return true if 'can_align_p'; if so, set ALIGNED to the greatest
- aligned value that is less than or equal to VALUE.
-
- 'can_align_up (VALUE, ALIGN, &ALIGNED)'
- Return true if 'can_align_p'; if so, set ALIGNED to the lowest
- aligned value that is greater than or equal to VALUE.
-
- 'known_equal_after_align_down (A, B, ALIGN)'
- Return true if we can align A and B down to the nearest ALIGN
- boundary at compile time and if the two results are equal.
-
- 'known_equal_after_align_up (A, B, ALIGN)'
- Return true if we can align A and B up to the nearest ALIGN
- boundary at compile time and if the two results are equal.
-
- 'aligned_lower_bound (VALUE, ALIGN)'
- Return a result that is no greater than VALUE and that is aligned
- to ALIGN. The result will the closest aligned value for some
- indeterminate values but not necessarily for all.
-
- For example, suppose we are allocating an object of SIZE bytes in a
- downward-growing stack whose current limit is given by LIMIT. If
- the object requires ALIGN bytes of alignment, the new stack limit
- is given by:
-
- aligned_lower_bound (LIMIT - SIZE, ALIGN)
-
- 'aligned_upper_bound (VALUE, ALIGN)'
- Likewise return a result that is no less than VALUE and that is
- aligned to ALIGN. This is the routine that would be used for
- upward-growing stacks in the scenario just described.
-
- 'known_misalignment (VALUE, ALIGN, &MISALIGN)'
- Return true if we can calculate the misalignment of VALUE with
- respect to ALIGN at compile time, storing the result in MISALIGN if
- so.
-
- 'known_alignment (VALUE)'
- Return the minimum alignment that VALUE is known to have (in other
- words, the largest alignment that can be guaranteed whatever the
- values of the indeterminates turn out to be). Return 0 if VALUE is
- known to be 0.
-
- 'force_align_down (VALUE, ALIGN)'
- Assert that VALUE can be aligned down to ALIGN at compile time and
- return the result. When using this routine, please add a comment
- explaining why the assertion is known to hold.
-
- 'force_align_up (VALUE, ALIGN)'
- Likewise, but aligning up.
-
- 'force_align_down_and_div (VALUE, ALIGN)'
- Divide the result of 'force_align_down' by ALIGN. Again, please
- add a comment explaining why the assertion in 'force_align_down' is
- known to hold.
-
- 'force_align_up_and_div (VALUE, ALIGN)'
- Likewise for 'force_align_up'.
-
- 'force_get_misalignment (VALUE, ALIGN)'
- Assert that we can calculate the misalignment of VALUE with respect
- to ALIGN at compile time and return the misalignment. When using
- this function, please add a comment explaining why the assertion is
- known to hold.
-
-
- File: gccint.info, Node: Computing bounds on poly_ints, Next: Converting poly_ints, Prev: Alignment of poly_ints, Up: poly_int
-
- 10.6 Computing bounds on 'poly_int's
- ====================================
-
- 'poly_int' also provides routines for calculating lower and upper
- bounds:
-
- 'constant_lower_bound (A)'
- Assert that A is nonnegative and return the smallest value it can
- have.
-
- 'constant_lower_bound_with_limit (A, B)'
- Return the least value A can have, given that the context in which
- A appears guarantees that the answer is no less than B. In other
- words, the caller is asserting that A is greater than or equal to B
- even if 'known_ge (A, B)' doesn't hold.
-
- 'constant_upper_bound_with_limit (A, B)'
- Return the greatest value A can have, given that the context in
- which A appears guarantees that the answer is no greater than B.
- In other words, the caller is asserting that A is less than or
- equal to B even if 'known_le (A, B)' doesn't hold.
-
- 'lower_bound (A, B)'
- Return a value that is always less than or equal to both A and B.
- It will be the greatest such value for some indeterminate values
- but necessarily for all.
-
- 'upper_bound (A, B)'
- Return a value that is always greater than or equal to both A and
- B. It will be the least such value for some indeterminate values
- but necessarily for all.
-
-
- File: gccint.info, Node: Converting poly_ints, Next: Miscellaneous poly_int routines, Prev: Computing bounds on poly_ints, Up: poly_int
-
- 10.7 Converting 'poly_int's
- ===========================
-
- A 'poly_int<N, T>' can be constructed from up to N individual T
- coefficients, with the remaining coefficients being implicitly zero. In
- particular, this means that every 'poly_int<N, T>' can be constructed
- from a single scalar T, or something compatible with T.
-
- Also, a 'poly_int<N, T>' can be constructed from a 'poly_int<N, U>' if
- T can be constructed from U.
-
- The following functions provide other forms of conversion, or test
- whether such a conversion would succeed.
-
- 'VALUE.is_constant ()'
- Return true if 'poly_int' VALUE is a compile-time constant.
-
- 'VALUE.is_constant (&C1)'
- Return true if 'poly_int' VALUE is a compile-time constant, storing
- it in C1 if so. C1 must be able to hold all constant values of
- VALUE without loss of precision.
-
- 'VALUE.to_constant ()'
- Assert that VALUE is a compile-time constant and return its value.
- When using this function, please add a comment explaining why the
- condition is known to hold (for example, because an earlier phase
- of analysis rejected non-constants).
-
- 'VALUE.to_shwi (&P2)'
- Return true if 'poly_int<N, T>' VALUE can be represented without
- loss of precision as a 'poly_int<N, 'HOST_WIDE_INT'>', storing it
- in that form in P2 if so.
-
- 'VALUE.to_uhwi (&P2)'
- Return true if 'poly_int<N, T>' VALUE can be represented without
- loss of precision as a 'poly_int<N, 'unsigned HOST_WIDE_INT'>',
- storing it in that form in P2 if so.
-
- 'VALUE.force_shwi ()'
- Forcibly convert each coefficient of 'poly_int<N, T>' VALUE to
- 'HOST_WIDE_INT', truncating any that are out of range. Return the
- result as a 'poly_int<N, 'HOST_WIDE_INT'>'.
-
- 'VALUE.force_uhwi ()'
- Forcibly convert each coefficient of 'poly_int<N, T>' VALUE to
- 'unsigned HOST_WIDE_INT', truncating any that are out of range.
- Return the result as a 'poly_int<N, 'unsigned HOST_WIDE_INT'>'.
-
- 'wi::shwi (VALUE, PRECISION)'
- Return a 'poly_int' with the same value as VALUE, but with the
- coefficients converted from 'HOST_WIDE_INT' to 'wide_int'.
- PRECISION specifies the precision of the 'wide_int' cofficients; if
- this is wider than a 'HOST_WIDE_INT', the coefficients of VALUE
- will be sign-extended to fit.
-
- 'wi::uhwi (VALUE, PRECISION)'
- Like 'wi::shwi', except that VALUE has coefficients of type
- 'unsigned HOST_WIDE_INT'. If PRECISION is wider than a
- 'HOST_WIDE_INT', the coefficients of VALUE will be zero-extended to
- fit.
-
- 'wi::sext (VALUE, PRECISION)'
- Return a 'poly_int' of the same type as VALUE, sign-extending every
- coefficient from the low PRECISION bits. This in effect applies
- 'wi::sext' to each coefficient individually.
-
- 'wi::zext (VALUE, PRECISION)'
- Like 'wi::sext', but for zero extension.
-
- 'poly_wide_int::from (VALUE, PRECISION, SIGN)'
- Convert VALUE to a 'poly_wide_int' in which each coefficient has
- PRECISION bits. Extend the coefficients according to SIGN if the
- coefficients have fewer bits.
-
- 'poly_offset_int::from (VALUE, SIGN)'
- Convert VALUE to a 'poly_offset_int', extending its coefficients
- according to SIGN if they have fewer bits than 'offset_int'.
-
- 'poly_widest_int::from (VALUE, SIGN)'
- Convert VALUE to a 'poly_widest_int', extending its coefficients
- according to SIGN if they have fewer bits than 'widest_int'.
-
-
- File: gccint.info, Node: Miscellaneous poly_int routines, Next: Guidelines for using poly_int, Prev: Converting poly_ints, Up: poly_int
-
- 10.8 Miscellaneous 'poly_int' routines
- ======================================
-
- 'print_dec (VALUE, FILE, SIGN)'
- 'print_dec (VALUE, FILE)'
- Print VALUE to FILE as a decimal value, interpreting the
- coefficients according to SIGN. The final argument is optional if
- VALUE has an inherent sign; for example, 'poly_int64' values print
- as signed by default and 'poly_uint64' values print as unsigned by
- default.
-
- This is a simply a 'poly_int' version of a wide-int routine.
-
-
- File: gccint.info, Node: Guidelines for using poly_int, Prev: Miscellaneous poly_int routines, Up: poly_int
-
- 10.9 Guidelines for using 'poly_int'
- ====================================
-
- One of the main design goals of 'poly_int' was to make it easy to write
- target-independent code that handles variable-sized registers even when
- the current target has fixed-sized registers. There are two aspects to
- this:
-
- * The set of 'poly_int' operations should be complete enough that the
- question in most cases becomes "Can we do this operation on these
- particular 'poly_int' values? If not, bail out" rather than "Are
- these 'poly_int' values constant? If so, do the operation,
- otherwise bail out".
-
- * If target-independent code compiles and runs correctly on a target
- with one value of 'NUM_POLY_INT_COEFFS', and if the code does not
- use asserting functions like 'to_constant', it is reasonable to
- assume that the code also works on targets with other values of
- 'NUM_POLY_INT_COEFFS'. There is no need to check this during
- everyday development.
-
- So the general principle is: if target-independent code is dealing with
- a 'poly_int' value, it is better to operate on it as a 'poly_int' if at
- all possible, choosing conservatively-correct behavior if a particular
- operation fails. For example, the following code handles an index 'pos'
- into a sequence of vectors that each have 'nunits' elements:
-
- /* Calculate which vector contains the result, and which lane of
- that vector we need. */
- if (!can_div_trunc_p (pos, nunits, &vec_entry, &vec_index))
- {
- if (dump_enabled_p ())
- dump_printf_loc (MSG_MISSED_OPTIMIZATION, vect_location,
- "Cannot determine which vector holds the"
- " final result.\n");
- return false;
- }
-
- However, there are some contexts in which operating on a 'poly_int' is
- not possible or does not make sense. One example is when handling
- static initializers, since no current target supports the concept of a
- variable-length static initializer. In these situations, a reasonable
- fallback is:
-
- if (POLY_VALUE.is_constant (&CONST_VALUE))
- {
- ...
- /* Operate on CONST_VALUE. */
- ...
- }
- else
- {
- ...
- /* Conservatively correct fallback. */
- ...
- }
-
- 'poly_int' also provides some asserting functions like 'to_constant'.
- Please only use these functions if there is a good theoretical reason to
- believe that the assertion cannot fire. For example, if some work is
- divided into an analysis phase and an implementation phase, the analysis
- phase might reject inputs that are not 'is_constant', in which case the
- implementation phase can reasonably use 'to_constant' on the remaining
- inputs. The assertions should not be used to discover whether a
- condition ever occurs "in the field"; in other words, they should not be
- used to restrict code to constants at first, with the intention of only
- implementing a 'poly_int' version if a user hits the assertion.
-
- If a particular asserting function like 'to_constant' is needed more
- than once for the same reason, it is probably worth adding a helper
- function or macro for that situation, so that the justification only
- needs to be given once. For example:
-
- /* Return the size of an element in a vector of size SIZE, given that
- the vector has NELTS elements. The return value is in the same units
- as SIZE (either bits or bytes).
-
- to_constant () is safe in this situation because vector elements are
- always constant-sized scalars. */
- #define vector_element_size(SIZE, NELTS) \
- (exact_div (SIZE, NELTS).to_constant ())
-
- Target-specific code in 'config/CPU' only needs to handle non-constant
- 'poly_int's if 'NUM_POLY_INT_COEFFS' is greater than one. For other
- targets, 'poly_int' degenerates to a compile-time constant and is often
- interchangable with a normal scalar integer. There are two main
- exceptions:
-
- * Sometimes an explicit cast to an integer type might be needed, such
- as to resolve ambiguities in a '?:' expression, or when passing
- values through '...' to things like print functions.
-
- * Target macros are included in target-independent code and so do not
- have access to the implicit conversion to a scalar integer. If
- this becomes a problem for a particular target macro, the possible
- solutions, in order of preference, are:
-
- * Convert the target macro to a target hook (for all targets).
-
- * Put the target's implementation of the target macro in its
- 'CPU.c' file and call it from the target macro in the 'CPU.h'
- file.
-
- * Add 'to_constant ()' calls where necessary. The previous
- option is preferable because it will help with any future
- conversion of the macro to a hook.
-
-
- File: gccint.info, Node: GENERIC, Next: GIMPLE, Prev: poly_int, Up: Top
-
- 11 GENERIC
- **********
-
- The purpose of GENERIC is simply to provide a language-independent way
- of representing an entire function in trees. To this end, it was
- necessary to add a few new tree codes to the back end, but almost
- everything was already there. If you can express it with the codes in
- 'gcc/tree.def', it's GENERIC.
-
- Early on, there was a great deal of debate about how to think about
- statements in a tree IL. In GENERIC, a statement is defined as any
- expression whose value, if any, is ignored. A statement will always
- have 'TREE_SIDE_EFFECTS' set (or it will be discarded), but a
- non-statement expression may also have side effects. A 'CALL_EXPR', for
- instance.
-
- It would be possible for some local optimizations to work on the
- GENERIC form of a function; indeed, the adapted tree inliner works fine
- on GENERIC, but the current compiler performs inlining after lowering to
- GIMPLE (a restricted form described in the next section). Indeed,
- currently the frontends perform this lowering before handing off to
- 'tree_rest_of_compilation', but this seems inelegant.
-
- * Menu:
-
- * Deficiencies:: Topics net yet covered in this document.
- * Tree overview:: All about 'tree's.
- * Types:: Fundamental and aggregate types.
- * Declarations:: Type declarations and variables.
- * Attributes:: Declaration and type attributes.
- * Expressions: Expression trees. Operating on data.
- * Statements:: Control flow and related trees.
- * Functions:: Function bodies, linkage, and other aspects.
- * Language-dependent trees:: Topics and trees specific to language front ends.
- * C and C++ Trees:: Trees specific to C and C++.
-
-
- File: gccint.info, Node: Deficiencies, Next: Tree overview, Up: GENERIC
-
- 11.1 Deficiencies
- =================
-
- There are many places in which this document is incomplet and incorrekt.
- It is, as of yet, only _preliminary_ documentation.
-
-
- File: gccint.info, Node: Tree overview, Next: Types, Prev: Deficiencies, Up: GENERIC
-
- 11.2 Overview
- =============
-
- The central data structure used by the internal representation is the
- 'tree'. These nodes, while all of the C type 'tree', are of many
- varieties. A 'tree' is a pointer type, but the object to which it
- points may be of a variety of types. From this point forward, we will
- refer to trees in ordinary type, rather than in 'this font', except when
- talking about the actual C type 'tree'.
-
- You can tell what kind of node a particular tree is by using the
- 'TREE_CODE' macro. Many, many macros take trees as input and return
- trees as output. However, most macros require a certain kind of tree
- node as input. In other words, there is a type-system for trees, but it
- is not reflected in the C type-system.
-
- For safety, it is useful to configure GCC with '--enable-checking'.
- Although this results in a significant performance penalty (since all
- tree types are checked at run-time), and is therefore inappropriate in a
- release version, it is extremely helpful during the development process.
-
- Many macros behave as predicates. Many, although not all, of these
- predicates end in '_P'. Do not rely on the result type of these macros
- being of any particular type. You may, however, rely on the fact that
- the type can be compared to '0', so that statements like
- if (TEST_P (t) && !TEST_P (y))
- x = 1;
- and
- int i = (TEST_P (t) != 0);
- are legal. Macros that return 'int' values now may be changed to return
- 'tree' values, or other pointers in the future. Even those that
- continue to return 'int' may return multiple nonzero codes where
- previously they returned only zero and one. Therefore, you should not
- write code like
- if (TEST_P (t) == 1)
- as this code is not guaranteed to work correctly in the future.
-
- You should not take the address of values returned by the macros or
- functions described here. In particular, no guarantee is given that the
- values are lvalues.
-
- In general, the names of macros are all in uppercase, while the names
- of functions are entirely in lowercase. There are rare exceptions to
- this rule. You should assume that any macro or function whose name is
- made up entirely of uppercase letters may evaluate its arguments more
- than once. You may assume that a macro or function whose name is made
- up entirely of lowercase letters will evaluate its arguments only once.
-
- The 'error_mark_node' is a special tree. Its tree code is
- 'ERROR_MARK', but since there is only ever one node with that code, the
- usual practice is to compare the tree against 'error_mark_node'. (This
- test is just a test for pointer equality.) If an error has occurred
- during front-end processing the flag 'errorcount' will be set. If the
- front end has encountered code it cannot handle, it will issue a message
- to the user and set 'sorrycount'. When these flags are set, any macro
- or function which normally returns a tree of a particular kind may
- instead return the 'error_mark_node'. Thus, if you intend to do any
- processing of erroneous code, you must be prepared to deal with the
- 'error_mark_node'.
-
- Occasionally, a particular tree slot (like an operand to an expression,
- or a particular field in a declaration) will be referred to as "reserved
- for the back end". These slots are used to store RTL when the tree is
- converted to RTL for use by the GCC back end. However, if that process
- is not taking place (e.g., if the front end is being hooked up to an
- intelligent editor), then those slots may be used by the back end
- presently in use.
-
- If you encounter situations that do not match this documentation, such
- as tree nodes of types not mentioned here, or macros documented to
- return entities of a particular kind that instead return entities of
- some different kind, you have found a bug, either in the front end or in
- the documentation. Please report these bugs as you would any other bug.
-
- * Menu:
-
- * Macros and Functions::Macros and functions that can be used with all trees.
- * Identifiers:: The names of things.
- * Containers:: Lists and vectors.
-
-
- File: gccint.info, Node: Macros and Functions, Next: Identifiers, Up: Tree overview
-
- 11.2.1 Trees
- ------------
-
- All GENERIC trees have two fields in common. First, 'TREE_CHAIN' is a
- pointer that can be used as a singly-linked list to other trees. The
- other is 'TREE_TYPE'. Many trees store the type of an expression or
- declaration in this field.
-
- These are some other functions for handling trees:
-
- 'tree_size'
- Return the number of bytes a tree takes.
-
- 'build0'
- 'build1'
- 'build2'
- 'build3'
- 'build4'
- 'build5'
- 'build6'
-
- These functions build a tree and supply values to put in each
- parameter. The basic signature is 'code, type, [operands]'.
- 'code' is the 'TREE_CODE', and 'type' is a tree representing the
- 'TREE_TYPE'. These are followed by the operands, each of which is
- also a tree.
-
-
- File: gccint.info, Node: Identifiers, Next: Containers, Prev: Macros and Functions, Up: Tree overview
-
- 11.2.2 Identifiers
- ------------------
-
- An 'IDENTIFIER_NODE' represents a slightly more general concept than the
- standard C or C++ concept of identifier. In particular, an
- 'IDENTIFIER_NODE' may contain a '$', or other extraordinary characters.
-
- There are never two distinct 'IDENTIFIER_NODE's representing the same
- identifier. Therefore, you may use pointer equality to compare
- 'IDENTIFIER_NODE's, rather than using a routine like 'strcmp'. Use
- 'get_identifier' to obtain the unique 'IDENTIFIER_NODE' for a supplied
- string.
-
- You can use the following macros to access identifiers:
- 'IDENTIFIER_POINTER'
- The string represented by the identifier, represented as a 'char*'.
- This string is always 'NUL'-terminated, and contains no embedded
- 'NUL' characters.
-
- 'IDENTIFIER_LENGTH'
- The length of the string returned by 'IDENTIFIER_POINTER', not
- including the trailing 'NUL'. This value of 'IDENTIFIER_LENGTH
- (x)' is always the same as 'strlen (IDENTIFIER_POINTER (x))'.
-
- 'IDENTIFIER_OPNAME_P'
- This predicate holds if the identifier represents the name of an
- overloaded operator. In this case, you should not depend on the
- contents of either the 'IDENTIFIER_POINTER' or the
- 'IDENTIFIER_LENGTH'.
-
- 'IDENTIFIER_TYPENAME_P'
- This predicate holds if the identifier represents the name of a
- user-defined conversion operator. In this case, the 'TREE_TYPE' of
- the 'IDENTIFIER_NODE' holds the type to which the conversion
- operator converts.
-
-
- File: gccint.info, Node: Containers, Prev: Identifiers, Up: Tree overview
-
- 11.2.3 Containers
- -----------------
-
- Two common container data structures can be represented directly with
- tree nodes. A 'TREE_LIST' is a singly linked list containing two trees
- per node. These are the 'TREE_PURPOSE' and 'TREE_VALUE' of each node.
- (Often, the 'TREE_PURPOSE' contains some kind of tag, or additional
- information, while the 'TREE_VALUE' contains the majority of the
- payload. In other cases, the 'TREE_PURPOSE' is simply 'NULL_TREE',
- while in still others both the 'TREE_PURPOSE' and 'TREE_VALUE' are of
- equal stature.) Given one 'TREE_LIST' node, the next node is found by
- following the 'TREE_CHAIN'. If the 'TREE_CHAIN' is 'NULL_TREE', then
- you have reached the end of the list.
-
- A 'TREE_VEC' is a simple vector. The 'TREE_VEC_LENGTH' is an integer
- (not a tree) giving the number of nodes in the vector. The nodes
- themselves are accessed using the 'TREE_VEC_ELT' macro, which takes two
- arguments. The first is the 'TREE_VEC' in question; the second is an
- integer indicating which element in the vector is desired. The elements
- are indexed from zero.
-
-
- File: gccint.info, Node: Types, Next: Declarations, Prev: Tree overview, Up: GENERIC
-
- 11.3 Types
- ==========
-
- All types have corresponding tree nodes. However, you should not assume
- that there is exactly one tree node corresponding to each type. There
- are often multiple nodes corresponding to the same type.
-
- For the most part, different kinds of types have different tree codes.
- (For example, pointer types use a 'POINTER_TYPE' code while arrays use
- an 'ARRAY_TYPE' code.) However, pointers to member functions use the
- 'RECORD_TYPE' code. Therefore, when writing a 'switch' statement that
- depends on the code associated with a particular type, you should take
- care to handle pointers to member functions under the 'RECORD_TYPE' case
- label.
-
- The following functions and macros deal with cv-qualification of types:
- 'TYPE_MAIN_VARIANT'
- This macro returns the unqualified version of a type. It may be
- applied to an unqualified type, but it is not always the identity
- function in that case.
-
- A few other macros and functions are usable with all types:
- 'TYPE_SIZE'
- The number of bits required to represent the type, represented as
- an 'INTEGER_CST'. For an incomplete type, 'TYPE_SIZE' will be
- 'NULL_TREE'.
-
- 'TYPE_ALIGN'
- The alignment of the type, in bits, represented as an 'int'.
-
- 'TYPE_NAME'
- This macro returns a declaration (in the form of a 'TYPE_DECL') for
- the type. (Note this macro does _not_ return an 'IDENTIFIER_NODE',
- as you might expect, given its name!) You can look at the
- 'DECL_NAME' of the 'TYPE_DECL' to obtain the actual name of the
- type. The 'TYPE_NAME' will be 'NULL_TREE' for a type that is not a
- built-in type, the result of a typedef, or a named class type.
-
- 'TYPE_CANONICAL'
- This macro returns the "canonical" type for the given type node.
- Canonical types are used to improve performance in the C++ and
- Objective-C++ front ends by allowing efficient comparison between
- two type nodes in 'same_type_p': if the 'TYPE_CANONICAL' values of
- the types are equal, the types are equivalent; otherwise, the types
- are not equivalent. The notion of equivalence for canonical types
- is the same as the notion of type equivalence in the language
- itself. For instance,
-
- When 'TYPE_CANONICAL' is 'NULL_TREE', there is no canonical type
- for the given type node. In this case, comparison between this
- type and any other type requires the compiler to perform a deep,
- "structural" comparison to see if the two type nodes have the same
- form and properties.
-
- The canonical type for a node is always the most fundamental type
- in the equivalence class of types. For instance, 'int' is its own
- canonical type. A typedef 'I' of 'int' will have 'int' as its
- canonical type. Similarly, 'I*' and a typedef 'IP' (defined to
- 'I*') will has 'int*' as their canonical type. When building a new
- type node, be sure to set 'TYPE_CANONICAL' to the appropriate
- canonical type. If the new type is a compound type (built from
- other types), and any of those other types require structural
- equality, use 'SET_TYPE_STRUCTURAL_EQUALITY' to ensure that the new
- type also requires structural equality. Finally, if for some
- reason you cannot guarantee that 'TYPE_CANONICAL' will point to the
- canonical type, use 'SET_TYPE_STRUCTURAL_EQUALITY' to make sure
- that the new type-and any type constructed based on it-requires
- structural equality. If you suspect that the canonical type system
- is miscomparing types, pass '--param verify-canonical-types=1' to
- the compiler or configure with '--enable-checking' to force the
- compiler to verify its canonical-type comparisons against the
- structural comparisons; the compiler will then print any warnings
- if the canonical types miscompare.
-
- 'TYPE_STRUCTURAL_EQUALITY_P'
- This predicate holds when the node requires structural equality
- checks, e.g., when 'TYPE_CANONICAL' is 'NULL_TREE'.
-
- 'SET_TYPE_STRUCTURAL_EQUALITY'
- This macro states that the type node it is given requires
- structural equality checks, e.g., it sets 'TYPE_CANONICAL' to
- 'NULL_TREE'.
-
- 'same_type_p'
- This predicate takes two types as input, and holds if they are the
- same type. For example, if one type is a 'typedef' for the other,
- or both are 'typedef's for the same type. This predicate also
- holds if the two trees given as input are simply copies of one
- another; i.e., there is no difference between them at the source
- level, but, for whatever reason, a duplicate has been made in the
- representation. You should never use '==' (pointer equality) to
- compare types; always use 'same_type_p' instead.
-
- Detailed below are the various kinds of types, and the macros that can
- be used to access them. Although other kinds of types are used
- elsewhere in G++, the types described here are the only ones that you
- will encounter while examining the intermediate representation.
-
- 'VOID_TYPE'
- Used to represent the 'void' type.
-
- 'INTEGER_TYPE'
- Used to represent the various integral types, including 'char',
- 'short', 'int', 'long', and 'long long'. This code is not used for
- enumeration types, nor for the 'bool' type. The 'TYPE_PRECISION'
- is the number of bits used in the representation, represented as an
- 'unsigned int'. (Note that in the general case this is not the
- same value as 'TYPE_SIZE'; suppose that there were a 24-bit integer
- type, but that alignment requirements for the ABI required 32-bit
- alignment. Then, 'TYPE_SIZE' would be an 'INTEGER_CST' for 32,
- while 'TYPE_PRECISION' would be 24.) The integer type is unsigned
- if 'TYPE_UNSIGNED' holds; otherwise, it is signed.
-
- The 'TYPE_MIN_VALUE' is an 'INTEGER_CST' for the smallest integer
- that may be represented by this type. Similarly, the
- 'TYPE_MAX_VALUE' is an 'INTEGER_CST' for the largest integer that
- may be represented by this type.
-
- 'REAL_TYPE'
- Used to represent the 'float', 'double', and 'long double' types.
- The number of bits in the floating-point representation is given by
- 'TYPE_PRECISION', as in the 'INTEGER_TYPE' case.
-
- 'FIXED_POINT_TYPE'
- Used to represent the 'short _Fract', '_Fract', 'long _Fract',
- 'long long _Fract', 'short _Accum', '_Accum', 'long _Accum', and
- 'long long _Accum' types. The number of bits in the fixed-point
- representation is given by 'TYPE_PRECISION', as in the
- 'INTEGER_TYPE' case. There may be padding bits, fractional bits
- and integral bits. The number of fractional bits is given by
- 'TYPE_FBIT', and the number of integral bits is given by
- 'TYPE_IBIT'. The fixed-point type is unsigned if 'TYPE_UNSIGNED'
- holds; otherwise, it is signed. The fixed-point type is saturating
- if 'TYPE_SATURATING' holds; otherwise, it is not saturating.
-
- 'COMPLEX_TYPE'
- Used to represent GCC built-in '__complex__' data types. The
- 'TREE_TYPE' is the type of the real and imaginary parts.
-
- 'ENUMERAL_TYPE'
- Used to represent an enumeration type. The 'TYPE_PRECISION' gives
- (as an 'int'), the number of bits used to represent the type. If
- there are no negative enumeration constants, 'TYPE_UNSIGNED' will
- hold. The minimum and maximum enumeration constants may be
- obtained with 'TYPE_MIN_VALUE' and 'TYPE_MAX_VALUE', respectively;
- each of these macros returns an 'INTEGER_CST'.
-
- The actual enumeration constants themselves may be obtained by
- looking at the 'TYPE_VALUES'. This macro will return a
- 'TREE_LIST', containing the constants. The 'TREE_PURPOSE' of each
- node will be an 'IDENTIFIER_NODE' giving the name of the constant;
- the 'TREE_VALUE' will be an 'INTEGER_CST' giving the value assigned
- to that constant. These constants will appear in the order in
- which they were declared. The 'TREE_TYPE' of each of these
- constants will be the type of enumeration type itself.
-
- 'BOOLEAN_TYPE'
- Used to represent the 'bool' type.
-
- 'POINTER_TYPE'
- Used to represent pointer types, and pointer to data member types.
- The 'TREE_TYPE' gives the type to which this type points.
-
- 'REFERENCE_TYPE'
- Used to represent reference types. The 'TREE_TYPE' gives the type
- to which this type refers.
-
- 'FUNCTION_TYPE'
- Used to represent the type of non-member functions and of static
- member functions. The 'TREE_TYPE' gives the return type of the
- function. The 'TYPE_ARG_TYPES' are a 'TREE_LIST' of the argument
- types. The 'TREE_VALUE' of each node in this list is the type of
- the corresponding argument; the 'TREE_PURPOSE' is an expression for
- the default argument value, if any. If the last node in the list
- is 'void_list_node' (a 'TREE_LIST' node whose 'TREE_VALUE' is the
- 'void_type_node'), then functions of this type do not take variable
- arguments. Otherwise, they do take a variable number of arguments.
-
- Note that in C (but not in C++) a function declared like 'void f()'
- is an unprototyped function taking a variable number of arguments;
- the 'TYPE_ARG_TYPES' of such a function will be 'NULL'.
-
- 'METHOD_TYPE'
- Used to represent the type of a non-static member function. Like a
- 'FUNCTION_TYPE', the return type is given by the 'TREE_TYPE'. The
- type of '*this', i.e., the class of which functions of this type
- are a member, is given by the 'TYPE_METHOD_BASETYPE'. The
- 'TYPE_ARG_TYPES' is the parameter list, as for a 'FUNCTION_TYPE',
- and includes the 'this' argument.
-
- 'ARRAY_TYPE'
- Used to represent array types. The 'TREE_TYPE' gives the type of
- the elements in the array. If the array-bound is present in the
- type, the 'TYPE_DOMAIN' is an 'INTEGER_TYPE' whose 'TYPE_MIN_VALUE'
- and 'TYPE_MAX_VALUE' will be the lower and upper bounds of the
- array, respectively. The 'TYPE_MIN_VALUE' will always be an
- 'INTEGER_CST' for zero, while the 'TYPE_MAX_VALUE' will be one less
- than the number of elements in the array, i.e., the highest value
- which may be used to index an element in the array.
-
- 'RECORD_TYPE'
- Used to represent 'struct' and 'class' types, as well as pointers
- to member functions and similar constructs in other languages.
- 'TYPE_FIELDS' contains the items contained in this type, each of
- which can be a 'FIELD_DECL', 'VAR_DECL', 'CONST_DECL', or
- 'TYPE_DECL'. You may not make any assumptions about the ordering
- of the fields in the type or whether one or more of them overlap.
-
- 'UNION_TYPE'
- Used to represent 'union' types. Similar to 'RECORD_TYPE' except
- that all 'FIELD_DECL' nodes in 'TYPE_FIELD' start at bit position
- zero.
-
- 'QUAL_UNION_TYPE'
- Used to represent part of a variant record in Ada. Similar to
- 'UNION_TYPE' except that each 'FIELD_DECL' has a 'DECL_QUALIFIER'
- field, which contains a boolean expression that indicates whether
- the field is present in the object. The type will only have one
- field, so each field's 'DECL_QUALIFIER' is only evaluated if none
- of the expressions in the previous fields in 'TYPE_FIELDS' are
- nonzero. Normally these expressions will reference a field in the
- outer object using a 'PLACEHOLDER_EXPR'.
-
- 'LANG_TYPE'
- This node is used to represent a language-specific type. The front
- end must handle it.
-
- 'OFFSET_TYPE'
- This node is used to represent a pointer-to-data member. For a
- data member 'X::m' the 'TYPE_OFFSET_BASETYPE' is 'X' and the
- 'TREE_TYPE' is the type of 'm'.
-
- There are variables whose values represent some of the basic types.
- These include:
- 'void_type_node'
- A node for 'void'.
-
- 'integer_type_node'
- A node for 'int'.
-
- 'unsigned_type_node.'
- A node for 'unsigned int'.
-
- 'char_type_node.'
- A node for 'char'.
- It may sometimes be useful to compare one of these variables with a type
- in hand, using 'same_type_p'.
-
-
- File: gccint.info, Node: Declarations, Next: Attributes, Prev: Types, Up: GENERIC
-
- 11.4 Declarations
- =================
-
- This section covers the various kinds of declarations that appear in the
- internal representation, except for declarations of functions
- (represented by 'FUNCTION_DECL' nodes), which are described in *note
- Functions::.
-
- * Menu:
-
- * Working with declarations:: Macros and functions that work on
- declarations.
- * Internal structure:: How declaration nodes are represented.
-
-
- File: gccint.info, Node: Working with declarations, Next: Internal structure, Up: Declarations
-
- 11.4.1 Working with declarations
- --------------------------------
-
- Some macros can be used with any kind of declaration. These include:
- 'DECL_NAME'
- This macro returns an 'IDENTIFIER_NODE' giving the name of the
- entity.
-
- 'TREE_TYPE'
- This macro returns the type of the entity declared.
-
- 'EXPR_FILENAME'
- This macro returns the name of the file in which the entity was
- declared, as a 'char*'. For an entity declared implicitly by the
- compiler (like '__builtin_memcpy'), this will be the string
- '"<internal>"'.
-
- 'EXPR_LINENO'
- This macro returns the line number at which the entity was
- declared, as an 'int'.
-
- 'DECL_ARTIFICIAL'
- This predicate holds if the declaration was implicitly generated by
- the compiler. For example, this predicate will hold of an
- implicitly declared member function, or of the 'TYPE_DECL'
- implicitly generated for a class type. Recall that in C++ code
- like:
- struct S {};
- is roughly equivalent to C code like:
- struct S {};
- typedef struct S S;
- The implicitly generated 'typedef' declaration is represented by a
- 'TYPE_DECL' for which 'DECL_ARTIFICIAL' holds.
-
- The various kinds of declarations include:
- 'LABEL_DECL'
- These nodes are used to represent labels in function bodies. For
- more information, see *note Functions::. These nodes only appear
- in block scopes.
-
- 'CONST_DECL'
- These nodes are used to represent enumeration constants. The value
- of the constant is given by 'DECL_INITIAL' which will be an
- 'INTEGER_CST' with the same type as the 'TREE_TYPE' of the
- 'CONST_DECL', i.e., an 'ENUMERAL_TYPE'.
-
- 'RESULT_DECL'
- These nodes represent the value returned by a function. When a
- value is assigned to a 'RESULT_DECL', that indicates that the value
- should be returned, via bitwise copy, by the function. You can use
- 'DECL_SIZE' and 'DECL_ALIGN' on a 'RESULT_DECL', just as with a
- 'VAR_DECL'.
-
- 'TYPE_DECL'
- These nodes represent 'typedef' declarations. The 'TREE_TYPE' is
- the type declared to have the name given by 'DECL_NAME'. In some
- cases, there is no associated name.
-
- 'VAR_DECL'
- These nodes represent variables with namespace or block scope, as
- well as static data members. The 'DECL_SIZE' and 'DECL_ALIGN' are
- analogous to 'TYPE_SIZE' and 'TYPE_ALIGN'. For a declaration, you
- should always use the 'DECL_SIZE' and 'DECL_ALIGN' rather than the
- 'TYPE_SIZE' and 'TYPE_ALIGN' given by the 'TREE_TYPE', since
- special attributes may have been applied to the variable to give it
- a particular size and alignment. You may use the predicates
- 'DECL_THIS_STATIC' or 'DECL_THIS_EXTERN' to test whether the
- storage class specifiers 'static' or 'extern' were used to declare
- a variable.
-
- If this variable is initialized (but does not require a
- constructor), the 'DECL_INITIAL' will be an expression for the
- initializer. The initializer should be evaluated, and a bitwise
- copy into the variable performed. If the 'DECL_INITIAL' is the
- 'error_mark_node', there is an initializer, but it is given by an
- explicit statement later in the code; no bitwise copy is required.
-
- GCC provides an extension that allows either automatic variables,
- or global variables, to be placed in particular registers. This
- extension is being used for a particular 'VAR_DECL' if
- 'DECL_REGISTER' holds for the 'VAR_DECL', and if
- 'DECL_ASSEMBLER_NAME' is not equal to 'DECL_NAME'. In that case,
- 'DECL_ASSEMBLER_NAME' is the name of the register into which the
- variable will be placed.
-
- 'PARM_DECL'
- Used to represent a parameter to a function. Treat these nodes
- similarly to 'VAR_DECL' nodes. These nodes only appear in the
- 'DECL_ARGUMENTS' for a 'FUNCTION_DECL'.
-
- The 'DECL_ARG_TYPE' for a 'PARM_DECL' is the type that will
- actually be used when a value is passed to this function. It may
- be a wider type than the 'TREE_TYPE' of the parameter; for example,
- the ordinary type might be 'short' while the 'DECL_ARG_TYPE' is
- 'int'.
-
- 'DEBUG_EXPR_DECL'
- Used to represent an anonymous debug-information temporary created
- to hold an expression as it is optimized away, so that its value
- can be referenced in debug bind statements.
-
- 'FIELD_DECL'
- These nodes represent non-static data members. The 'DECL_SIZE' and
- 'DECL_ALIGN' behave as for 'VAR_DECL' nodes. The position of the
- field within the parent record is specified by a combination of
- three attributes. 'DECL_FIELD_OFFSET' is the position, counting in
- bytes, of the 'DECL_OFFSET_ALIGN'-bit sized word containing the bit
- of the field closest to the beginning of the structure.
- 'DECL_FIELD_BIT_OFFSET' is the bit offset of the first bit of the
- field within this word; this may be nonzero even for fields that
- are not bit-fields, since 'DECL_OFFSET_ALIGN' may be greater than
- the natural alignment of the field's type.
-
- If 'DECL_C_BIT_FIELD' holds, this field is a bit-field. In a
- bit-field, 'DECL_BIT_FIELD_TYPE' also contains the type that was
- originally specified for it, while DECL_TYPE may be a modified type
- with lesser precision, according to the size of the bit field.
-
- 'NAMESPACE_DECL'
- Namespaces provide a name hierarchy for other declarations. They
- appear in the 'DECL_CONTEXT' of other '_DECL' nodes.
-
-
- File: gccint.info, Node: Internal structure, Prev: Working with declarations, Up: Declarations
-
- 11.4.2 Internal structure
- -------------------------
-
- 'DECL' nodes are represented internally as a hierarchy of structures.
-
- * Menu:
-
- * Current structure hierarchy:: The current DECL node structure
- hierarchy.
- * Adding new DECL node types:: How to add a new DECL node to a
- frontend.
-
-
- File: gccint.info, Node: Current structure hierarchy, Next: Adding new DECL node types, Up: Internal structure
-
- 11.4.2.1 Current structure hierarchy
- ....................................
-
- 'struct tree_decl_minimal'
- This is the minimal structure to inherit from in order for common
- 'DECL' macros to work. The fields it contains are a unique ID,
- source location, context, and name.
-
- 'struct tree_decl_common'
- This structure inherits from 'struct tree_decl_minimal'. It
- contains fields that most 'DECL' nodes need, such as a field to
- store alignment, machine mode, size, and attributes.
-
- 'struct tree_field_decl'
- This structure inherits from 'struct tree_decl_common'. It is used
- to represent 'FIELD_DECL'.
-
- 'struct tree_label_decl'
- This structure inherits from 'struct tree_decl_common'. It is used
- to represent 'LABEL_DECL'.
-
- 'struct tree_translation_unit_decl'
- This structure inherits from 'struct tree_decl_common'. It is used
- to represent 'TRANSLATION_UNIT_DECL'.
-
- 'struct tree_decl_with_rtl'
- This structure inherits from 'struct tree_decl_common'. It
- contains a field to store the low-level RTL associated with a
- 'DECL' node.
-
- 'struct tree_result_decl'
- This structure inherits from 'struct tree_decl_with_rtl'. It is
- used to represent 'RESULT_DECL'.
-
- 'struct tree_const_decl'
- This structure inherits from 'struct tree_decl_with_rtl'. It is
- used to represent 'CONST_DECL'.
-
- 'struct tree_parm_decl'
- This structure inherits from 'struct tree_decl_with_rtl'. It is
- used to represent 'PARM_DECL'.
-
- 'struct tree_decl_with_vis'
- This structure inherits from 'struct tree_decl_with_rtl'. It
- contains fields necessary to store visibility information, as well
- as a section name and assembler name.
-
- 'struct tree_var_decl'
- This structure inherits from 'struct tree_decl_with_vis'. It is
- used to represent 'VAR_DECL'.
-
- 'struct tree_function_decl'
- This structure inherits from 'struct tree_decl_with_vis'. It is
- used to represent 'FUNCTION_DECL'.
-
-
- File: gccint.info, Node: Adding new DECL node types, Prev: Current structure hierarchy, Up: Internal structure
-
- 11.4.2.2 Adding new DECL node types
- ...................................
-
- Adding a new 'DECL' tree consists of the following steps
-
- Add a new tree code for the 'DECL' node
- For language specific 'DECL' nodes, there is a '.def' file in each
- frontend directory where the tree code should be added. For 'DECL'
- nodes that are part of the middle-end, the code should be added to
- 'tree.def'.
-
- Create a new structure type for the 'DECL' node
- These structures should inherit from one of the existing structures
- in the language hierarchy by using that structure as the first
- member.
-
- struct tree_foo_decl
- {
- struct tree_decl_with_vis common;
- }
-
- Would create a structure name 'tree_foo_decl' that inherits from
- 'struct tree_decl_with_vis'.
-
- For language specific 'DECL' nodes, this new structure type should
- go in the appropriate '.h' file. For 'DECL' nodes that are part of
- the middle-end, the structure type should go in 'tree.h'.
-
- Add a member to the tree structure enumerator for the node
- For garbage collection and dynamic checking purposes, each 'DECL'
- node structure type is required to have a unique enumerator value
- specified with it. For language specific 'DECL' nodes, this new
- enumerator value should go in the appropriate '.def' file. For
- 'DECL' nodes that are part of the middle-end, the enumerator values
- are specified in 'treestruct.def'.
-
- Update 'union tree_node'
- In order to make your new structure type usable, it must be added
- to 'union tree_node'. For language specific 'DECL' nodes, a new
- entry should be added to the appropriate '.h' file of the form
- struct tree_foo_decl GTY ((tag ("TS_VAR_DECL"))) foo_decl;
- For 'DECL' nodes that are part of the middle-end, the additional
- member goes directly into 'union tree_node' in 'tree.h'.
-
- Update dynamic checking info
- In order to be able to check whether accessing a named portion of
- 'union tree_node' is legal, and whether a certain 'DECL' node
- contains one of the enumerated 'DECL' node structures in the
- hierarchy, a simple lookup table is used. This lookup table needs
- to be kept up to date with the tree structure hierarchy, or else
- checking and containment macros will fail inappropriately.
-
- For language specific 'DECL' nodes, their is an 'init_ts' function
- in an appropriate '.c' file, which initializes the lookup table.
- Code setting up the table for new 'DECL' nodes should be added
- there. For each 'DECL' tree code and enumerator value representing
- a member of the inheritance hierarchy, the table should contain 1
- if that tree code inherits (directly or indirectly) from that
- member. Thus, a 'FOO_DECL' node derived from 'struct
- decl_with_rtl', and enumerator value 'TS_FOO_DECL', would be set up
- as follows
- tree_contains_struct[FOO_DECL][TS_FOO_DECL] = 1;
- tree_contains_struct[FOO_DECL][TS_DECL_WRTL] = 1;
- tree_contains_struct[FOO_DECL][TS_DECL_COMMON] = 1;
- tree_contains_struct[FOO_DECL][TS_DECL_MINIMAL] = 1;
-
- For 'DECL' nodes that are part of the middle-end, the setup code
- goes into 'tree.c'.
-
- Add macros to access any new fields and flags
-
- Each added field or flag should have a macro that is used to access
- it, that performs appropriate checking to ensure only the right
- type of 'DECL' nodes access the field.
-
- These macros generally take the following form
- #define FOO_DECL_FIELDNAME(NODE) FOO_DECL_CHECK(NODE)->foo_decl.fieldname
- However, if the structure is simply a base class for further
- structures, something like the following should be used
- #define BASE_STRUCT_CHECK(T) CONTAINS_STRUCT_CHECK(T, TS_BASE_STRUCT)
- #define BASE_STRUCT_FIELDNAME(NODE) \
- (BASE_STRUCT_CHECK(NODE)->base_struct.fieldname
-
- Reading them from the generated 'all-tree.def' file (which in turn
- includes all the 'tree.def' files), 'gencheck.c' is used during
- GCC's build to generate the '*_CHECK' macros for all tree codes.
-
-
- File: gccint.info, Node: Attributes, Next: Expression trees, Prev: Declarations, Up: GENERIC
-
- 11.5 Attributes in trees
- ========================
-
- Attributes, as specified using the '__attribute__' keyword, are
- represented internally as a 'TREE_LIST'. The 'TREE_PURPOSE' is the name
- of the attribute, as an 'IDENTIFIER_NODE'. The 'TREE_VALUE' is a
- 'TREE_LIST' of the arguments of the attribute, if any, or 'NULL_TREE' if
- there are no arguments; the arguments are stored as the 'TREE_VALUE' of
- successive entries in the list, and may be identifiers or expressions.
- The 'TREE_CHAIN' of the attribute is the next attribute in a list of
- attributes applying to the same declaration or type, or 'NULL_TREE' if
- there are no further attributes in the list.
-
- Attributes may be attached to declarations and to types; these
- attributes may be accessed with the following macros. All attributes
- are stored in this way, and many also cause other changes to the
- declaration or type or to other internal compiler data structures.
-
- -- Tree Macro: tree DECL_ATTRIBUTES (tree DECL)
- This macro returns the attributes on the declaration DECL.
-
- -- Tree Macro: tree TYPE_ATTRIBUTES (tree TYPE)
- This macro returns the attributes on the type TYPE.
-
-
- File: gccint.info, Node: Expression trees, Next: Statements, Prev: Attributes, Up: GENERIC
-
- 11.6 Expressions
- ================
-
- The internal representation for expressions is for the most part quite
- straightforward. However, there are a few facts that one must bear in
- mind. In particular, the expression "tree" is actually a directed
- acyclic graph. (For example there may be many references to the integer
- constant zero throughout the source program; many of these will be
- represented by the same expression node.) You should not rely on
- certain kinds of node being shared, nor should you rely on certain kinds
- of nodes being unshared.
-
- The following macros can be used with all expression nodes:
-
- 'TREE_TYPE'
- Returns the type of the expression. This value may not be
- precisely the same type that would be given the expression in the
- original program.
-
- In what follows, some nodes that one might expect to always have type
- 'bool' are documented to have either integral or boolean type. At some
- point in the future, the C front end may also make use of this same
- intermediate representation, and at this point these nodes will
- certainly have integral type. The previous sentence is not meant to
- imply that the C++ front end does not or will not give these nodes
- integral type.
-
- Below, we list the various kinds of expression nodes. Except where
- noted otherwise, the operands to an expression are accessed using the
- 'TREE_OPERAND' macro. For example, to access the first operand to a
- binary plus expression 'expr', use:
-
- TREE_OPERAND (expr, 0)
-
- As this example indicates, the operands are zero-indexed.
-
- * Menu:
-
- * Constants: Constant expressions.
- * Storage References::
- * Unary and Binary Expressions::
- * Vectors::
-
-
- File: gccint.info, Node: Constant expressions, Next: Storage References, Up: Expression trees
-
- 11.6.1 Constant expressions
- ---------------------------
-
- The table below begins with constants, moves on to unary expressions,
- then proceeds to binary expressions, and concludes with various other
- kinds of expressions:
-
- 'INTEGER_CST'
- These nodes represent integer constants. Note that the type of
- these constants is obtained with 'TREE_TYPE'; they are not always
- of type 'int'. In particular, 'char' constants are represented
- with 'INTEGER_CST' nodes. The value of the integer constant 'e' is
- represented in an array of HOST_WIDE_INT. There are enough elements
- in the array to represent the value without taking extra elements
- for redundant 0s or -1. The number of elements used to represent
- 'e' is available via 'TREE_INT_CST_NUNITS'. Element 'i' can be
- extracted by using 'TREE_INT_CST_ELT (e, i)'. 'TREE_INT_CST_LOW'
- is a shorthand for 'TREE_INT_CST_ELT (e, 0)'.
-
- The functions 'tree_fits_shwi_p' and 'tree_fits_uhwi_p' can be used
- to tell if the value is small enough to fit in a signed
- HOST_WIDE_INT or an unsigned HOST_WIDE_INT respectively. The value
- can then be extracted using 'tree_to_shwi' and 'tree_to_uhwi'.
-
- 'REAL_CST'
-
- FIXME: Talk about how to obtain representations of this constant,
- do comparisons, and so forth.
-
- 'FIXED_CST'
-
- These nodes represent fixed-point constants. The type of these
- constants is obtained with 'TREE_TYPE'. 'TREE_FIXED_CST_PTR'
- points to a 'struct fixed_value'; 'TREE_FIXED_CST' returns the
- structure itself. 'struct fixed_value' contains 'data' with the
- size of two 'HOST_BITS_PER_WIDE_INT' and 'mode' as the associated
- fixed-point machine mode for 'data'.
-
- 'COMPLEX_CST'
- These nodes are used to represent complex number constants, that is
- a '__complex__' whose parts are constant nodes. The
- 'TREE_REALPART' and 'TREE_IMAGPART' return the real and the
- imaginary parts respectively.
-
- 'VECTOR_CST'
- These nodes are used to represent vector constants. Each vector
- constant V is treated as a specific instance of an arbitrary-length
- sequence that itself contains 'VECTOR_CST_NPATTERNS (V)'
- interleaved patterns. Each pattern has the form:
-
- { BASE0, BASE1, BASE1 + STEP, BASE1 + STEP * 2, ... }
-
- The first three elements in each pattern are enough to determine
- the values of the other elements. However, if all STEPs are zero,
- only the first two elements are needed. If in addition each BASE1
- is equal to the corresponding BASE0, only the first element in each
- pattern is needed. The number of encoded elements per pattern is
- given by 'VECTOR_CST_NELTS_PER_PATTERN (V)'.
-
- For example, the constant:
-
- { 0, 1, 2, 6, 3, 8, 4, 10, 5, 12, 6, 14, 7, 16, 8, 18 }
-
- is interpreted as an interleaving of the sequences:
-
- { 0, 2, 3, 4, 5, 6, 7, 8 }
- { 1, 6, 8, 10, 12, 14, 16, 18 }
-
- where the sequences are represented by the following patterns:
-
- BASE0 == 0, BASE1 == 2, STEP == 1
- BASE0 == 1, BASE1 == 6, STEP == 2
-
- In this case:
-
- VECTOR_CST_NPATTERNS (V) == 2
- VECTOR_CST_NELTS_PER_PATTERN (V) == 3
-
- The vector is therefore encoded using the first 6 elements ('{ 0,
- 1, 2, 6, 3, 8 }'), with the remaining 10 elements being implicit
- extensions of them.
-
- Sometimes this scheme can create two possible encodings of the same
- vector. For example { 0, 1 } could be seen as two patterns with
- one element each or one pattern with two elements (BASE0 and
- BASE1). The canonical encoding is always the one with the fewest
- patterns or (if both encodings have the same number of petterns)
- the one with the fewest encoded elements.
-
- 'vector_cst_encoding_nelts (V)' gives the total number of encoded
- elements in V, which is 6 in the example above.
- 'VECTOR_CST_ENCODED_ELTS (V)' gives a pointer to the elements
- encoded in V and 'VECTOR_CST_ENCODED_ELT (V, I)' accesses the value
- of encoded element I.
-
- 'VECTOR_CST_DUPLICATE_P (V)' is true if V simply contains repeated
- instances of 'VECTOR_CST_NPATTERNS (V)' values. This is a
- shorthand for testing 'VECTOR_CST_NELTS_PER_PATTERN (V) == 1'.
-
- 'VECTOR_CST_STEPPED_P (V)' is true if at least one pattern in V has
- a nonzero step. This is a shorthand for testing
- 'VECTOR_CST_NELTS_PER_PATTERN (V) == 3'.
-
- The utility function 'vector_cst_elt' gives the value of an
- arbitrary index as a 'tree'. 'vector_cst_int_elt' gives the same
- value as a 'wide_int'.
-
- 'STRING_CST'
- These nodes represent string-constants. The 'TREE_STRING_LENGTH'
- returns the length of the string, as an 'int'. The
- 'TREE_STRING_POINTER' is a 'char*' containing the string itself.
- The string may not be 'NUL'-terminated, and it may contain embedded
- 'NUL' characters. Therefore, the 'TREE_STRING_LENGTH' includes the
- trailing 'NUL' if it is present.
-
- For wide string constants, the 'TREE_STRING_LENGTH' is the number
- of bytes in the string, and the 'TREE_STRING_POINTER' points to an
- array of the bytes of the string, as represented on the target
- system (that is, as integers in the target endianness). Wide and
- non-wide string constants are distinguished only by the 'TREE_TYPE'
- of the 'STRING_CST'.
-
- FIXME: The formats of string constants are not well-defined when
- the target system bytes are not the same width as host system
- bytes.
-
- 'POLY_INT_CST'
- These nodes represent invariants that depend on some
- target-specific runtime parameters. They consist of
- 'NUM_POLY_INT_COEFFS' coefficients, with the first coefficient
- being the constant term and the others being multipliers that are
- applied to the runtime parameters.
-
- 'POLY_INT_CST_ELT (X, I)' references coefficient number I of
- 'POLY_INT_CST' node X. Each coefficient is an 'INTEGER_CST'.
-
-
- File: gccint.info, Node: Storage References, Next: Unary and Binary Expressions, Prev: Constant expressions, Up: Expression trees
-
- 11.6.2 References to storage
- ----------------------------
-
- 'ARRAY_REF'
- These nodes represent array accesses. The first operand is the
- array; the second is the index. To calculate the address of the
- memory accessed, you must scale the index by the size of the type
- of the array elements. The type of these expressions must be the
- type of a component of the array. The third and fourth operands
- are used after gimplification to represent the lower bound and
- component size but should not be used directly; call
- 'array_ref_low_bound' and 'array_ref_element_size' instead.
-
- 'ARRAY_RANGE_REF'
- These nodes represent access to a range (or "slice") of an array.
- The operands are the same as that for 'ARRAY_REF' and have the same
- meanings. The type of these expressions must be an array whose
- component type is the same as that of the first operand. The range
- of that array type determines the amount of data these expressions
- access.
-
- 'TARGET_MEM_REF'
- These nodes represent memory accesses whose address directly map to
- an addressing mode of the target architecture. The first argument
- is 'TMR_SYMBOL' and must be a 'VAR_DECL' of an object with a fixed
- address. The second argument is 'TMR_BASE' and the third one is
- 'TMR_INDEX'. The fourth argument is 'TMR_STEP' and must be an
- 'INTEGER_CST'. The fifth argument is 'TMR_OFFSET' and must be an
- 'INTEGER_CST'. Any of the arguments may be NULL if the appropriate
- component does not appear in the address. Address of the
- 'TARGET_MEM_REF' is determined in the following way.
-
- &TMR_SYMBOL + TMR_BASE + TMR_INDEX * TMR_STEP + TMR_OFFSET
-
- The sixth argument is the reference to the original memory access,
- which is preserved for the purposes of the RTL alias analysis. The
- seventh argument is a tag representing the results of tree level
- alias analysis.
-
- 'ADDR_EXPR'
- These nodes are used to represent the address of an object. (These
- expressions will always have pointer or reference type.) The
- operand may be another expression, or it may be a declaration.
-
- As an extension, GCC allows users to take the address of a label.
- In this case, the operand of the 'ADDR_EXPR' will be a
- 'LABEL_DECL'. The type of such an expression is 'void*'.
-
- If the object addressed is not an lvalue, a temporary is created,
- and the address of the temporary is used.
-
- 'INDIRECT_REF'
- These nodes are used to represent the object pointed to by a
- pointer. The operand is the pointer being dereferenced; it will
- always have pointer or reference type.
-
- 'MEM_REF'
- These nodes are used to represent the object pointed to by a
- pointer offset by a constant. The first operand is the pointer
- being dereferenced; it will always have pointer or reference type.
- The second operand is a pointer constant. Its type is specifying
- the type to be used for type-based alias analysis.
-
- 'COMPONENT_REF'
- These nodes represent non-static data member accesses. The first
- operand is the object (rather than a pointer to it); the second
- operand is the 'FIELD_DECL' for the data member. The third operand
- represents the byte offset of the field, but should not be used
- directly; call 'component_ref_field_offset' instead.
-
-
- File: gccint.info, Node: Unary and Binary Expressions, Next: Vectors, Prev: Storage References, Up: Expression trees
-
- 11.6.3 Unary and Binary Expressions
- -----------------------------------
-
- 'NEGATE_EXPR'
- These nodes represent unary negation of the single operand, for
- both integer and floating-point types. The type of negation can be
- determined by looking at the type of the expression.
-
- The behavior of this operation on signed arithmetic overflow is
- controlled by the 'flag_wrapv' and 'flag_trapv' variables.
-
- 'ABS_EXPR'
- These nodes represent the absolute value of the single operand, for
- both integer and floating-point types. This is typically used to
- implement the 'abs', 'labs' and 'llabs' builtins for integer types,
- and the 'fabs', 'fabsf' and 'fabsl' builtins for floating point
- types. The type of abs operation can be determined by looking at
- the type of the expression.
-
- This node is not used for complex types. To represent the modulus
- or complex abs of a complex value, use the 'BUILT_IN_CABS',
- 'BUILT_IN_CABSF' or 'BUILT_IN_CABSL' builtins, as used to implement
- the C99 'cabs', 'cabsf' and 'cabsl' built-in functions.
-
- 'ABSU_EXPR'
- These nodes represent the absolute value of the single operand in
- equivalent unsigned type such that 'ABSU_EXPR' of 'TYPE_MIN' is
- well defined.
-
- 'BIT_NOT_EXPR'
- These nodes represent bitwise complement, and will always have
- integral type. The only operand is the value to be complemented.
-
- 'TRUTH_NOT_EXPR'
- These nodes represent logical negation, and will always have
- integral (or boolean) type. The operand is the value being
- negated. The type of the operand and that of the result are always
- of 'BOOLEAN_TYPE' or 'INTEGER_TYPE'.
-
- 'PREDECREMENT_EXPR'
- 'PREINCREMENT_EXPR'
- 'POSTDECREMENT_EXPR'
- 'POSTINCREMENT_EXPR'
- These nodes represent increment and decrement expressions. The
- value of the single operand is computed, and the operand
- incremented or decremented. In the case of 'PREDECREMENT_EXPR' and
- 'PREINCREMENT_EXPR', the value of the expression is the value
- resulting after the increment or decrement; in the case of
- 'POSTDECREMENT_EXPR' and 'POSTINCREMENT_EXPR' is the value before
- the increment or decrement occurs. The type of the operand, like
- that of the result, will be either integral, boolean, or
- floating-point.
-
- 'FIX_TRUNC_EXPR'
- These nodes represent conversion of a floating-point value to an
- integer. The single operand will have a floating-point type, while
- the complete expression will have an integral (or boolean) type.
- The operand is rounded towards zero.
-
- 'FLOAT_EXPR'
- These nodes represent conversion of an integral (or boolean) value
- to a floating-point value. The single operand will have integral
- type, while the complete expression will have a floating-point
- type.
-
- FIXME: How is the operand supposed to be rounded? Is this
- dependent on '-mieee'?
-
- 'COMPLEX_EXPR'
- These nodes are used to represent complex numbers constructed from
- two expressions of the same (integer or real) type. The first
- operand is the real part and the second operand is the imaginary
- part.
-
- 'CONJ_EXPR'
- These nodes represent the conjugate of their operand.
-
- 'REALPART_EXPR'
- 'IMAGPART_EXPR'
- These nodes represent respectively the real and the imaginary parts
- of complex numbers (their sole argument).
-
- 'NON_LVALUE_EXPR'
- These nodes indicate that their one and only operand is not an
- lvalue. A back end can treat these identically to the single
- operand.
-
- 'NOP_EXPR'
- These nodes are used to represent conversions that do not require
- any code-generation. For example, conversion of a 'char*' to an
- 'int*' does not require any code be generated; such a conversion is
- represented by a 'NOP_EXPR'. The single operand is the expression
- to be converted. The conversion from a pointer to a reference is
- also represented with a 'NOP_EXPR'.
-
- 'CONVERT_EXPR'
- These nodes are similar to 'NOP_EXPR's, but are used in those
- situations where code may need to be generated. For example, if an
- 'int*' is converted to an 'int' code may need to be generated on
- some platforms. These nodes are never used for C++-specific
- conversions, like conversions between pointers to different classes
- in an inheritance hierarchy. Any adjustments that need to be made
- in such cases are always indicated explicitly. Similarly, a
- user-defined conversion is never represented by a 'CONVERT_EXPR';
- instead, the function calls are made explicit.
-
- 'FIXED_CONVERT_EXPR'
- These nodes are used to represent conversions that involve
- fixed-point values. For example, from a fixed-point value to
- another fixed-point value, from an integer to a fixed-point value,
- from a fixed-point value to an integer, from a floating-point value
- to a fixed-point value, or from a fixed-point value to a
- floating-point value.
-
- 'LSHIFT_EXPR'
- 'RSHIFT_EXPR'
- These nodes represent left and right shifts, respectively. The
- first operand is the value to shift; it will always be of integral
- type. The second operand is an expression for the number of bits
- by which to shift. Right shift should be treated as arithmetic,
- i.e., the high-order bits should be zero-filled when the expression
- has unsigned type and filled with the sign bit when the expression
- has signed type. Note that the result is undefined if the second
- operand is larger than or equal to the first operand's type size.
- Unlike most nodes, these can have a vector as first operand and a
- scalar as second operand.
-
- 'BIT_IOR_EXPR'
- 'BIT_XOR_EXPR'
- 'BIT_AND_EXPR'
- These nodes represent bitwise inclusive or, bitwise exclusive or,
- and bitwise and, respectively. Both operands will always have
- integral type.
-
- 'TRUTH_ANDIF_EXPR'
- 'TRUTH_ORIF_EXPR'
- These nodes represent logical "and" and logical "or", respectively.
- These operators are not strict; i.e., the second operand is
- evaluated only if the value of the expression is not determined by
- evaluation of the first operand. The type of the operands and that
- of the result are always of 'BOOLEAN_TYPE' or 'INTEGER_TYPE'.
-
- 'TRUTH_AND_EXPR'
- 'TRUTH_OR_EXPR'
- 'TRUTH_XOR_EXPR'
- These nodes represent logical and, logical or, and logical
- exclusive or. They are strict; both arguments are always
- evaluated. There are no corresponding operators in C or C++, but
- the front end will sometimes generate these expressions anyhow, if
- it can tell that strictness does not matter. The type of the
- operands and that of the result are always of 'BOOLEAN_TYPE' or
- 'INTEGER_TYPE'.
-
- 'POINTER_PLUS_EXPR'
- This node represents pointer arithmetic. The first operand is
- always a pointer/reference type. The second operand is always an
- unsigned integer type compatible with sizetype. This and
- POINTER_DIFF_EXPR are the only binary arithmetic operators that can
- operate on pointer types.
-
- 'POINTER_DIFF_EXPR'
- This node represents pointer subtraction. The two operands always
- have pointer/reference type. It returns a signed integer of the
- same precision as the pointers. The behavior is undefined if the
- difference of the two pointers, seen as infinite precision
- non-negative integers, does not fit in the result type. The result
- does not depend on the pointer type, it is not divided by the size
- of the pointed-to type.
-
- 'PLUS_EXPR'
- 'MINUS_EXPR'
- 'MULT_EXPR'
- These nodes represent various binary arithmetic operations.
- Respectively, these operations are addition, subtraction (of the
- second operand from the first) and multiplication. Their operands
- may have either integral or floating type, but there will never be
- case in which one operand is of floating type and the other is of
- integral type.
-
- The behavior of these operations on signed arithmetic overflow is
- controlled by the 'flag_wrapv' and 'flag_trapv' variables.
-
- 'MULT_HIGHPART_EXPR'
- This node represents the "high-part" of a widening multiplication.
- For an integral type with B bits of precision, the result is the
- most significant B bits of the full 2B product.
-
- 'RDIV_EXPR'
- This node represents a floating point division operation.
-
- 'TRUNC_DIV_EXPR'
- 'FLOOR_DIV_EXPR'
- 'CEIL_DIV_EXPR'
- 'ROUND_DIV_EXPR'
- These nodes represent integer division operations that return an
- integer result. 'TRUNC_DIV_EXPR' rounds towards zero,
- 'FLOOR_DIV_EXPR' rounds towards negative infinity, 'CEIL_DIV_EXPR'
- rounds towards positive infinity and 'ROUND_DIV_EXPR' rounds to the
- closest integer. Integer division in C and C++ is truncating, i.e.
- 'TRUNC_DIV_EXPR'.
-
- The behavior of these operations on signed arithmetic overflow,
- when dividing the minimum signed integer by minus one, is
- controlled by the 'flag_wrapv' and 'flag_trapv' variables.
-
- 'TRUNC_MOD_EXPR'
- 'FLOOR_MOD_EXPR'
- 'CEIL_MOD_EXPR'
- 'ROUND_MOD_EXPR'
- These nodes represent the integer remainder or modulus operation.
- The integer modulus of two operands 'a' and 'b' is defined as 'a -
- (a/b)*b' where the division calculated using the corresponding
- division operator. Hence for 'TRUNC_MOD_EXPR' this definition
- assumes division using truncation towards zero, i.e.
- 'TRUNC_DIV_EXPR'. Integer remainder in C and C++ uses truncating
- division, i.e. 'TRUNC_MOD_EXPR'.
-
- 'EXACT_DIV_EXPR'
- The 'EXACT_DIV_EXPR' code is used to represent integer divisions
- where the numerator is known to be an exact multiple of the
- denominator. This allows the backend to choose between the faster
- of 'TRUNC_DIV_EXPR', 'CEIL_DIV_EXPR' and 'FLOOR_DIV_EXPR' for the
- current target.
-
- 'LT_EXPR'
- 'LE_EXPR'
- 'GT_EXPR'
- 'GE_EXPR'
- 'LTGT_EXPR'
- 'EQ_EXPR'
- 'NE_EXPR'
- These nodes represent the less than, less than or equal to, greater
- than, greater than or equal to, less or greater than, equal, and
- not equal comparison operators. The first and second operands will
- either be both of integral type, both of floating type or both of
- vector type, except for LTGT_EXPR where they will only be both of
- floating type. The result type of these expressions will always be
- of integral, boolean or signed integral vector type. These
- operations return the result type's zero value for false, the
- result type's one value for true, and a vector whose elements are
- zero (false) or minus one (true) for vectors.
-
- For floating point comparisons, if we honor IEEE NaNs and either
- operand is NaN, then 'NE_EXPR' always returns true and the
- remaining operators always return false. On some targets,
- comparisons against an IEEE NaN, other than equality and
- inequality, may generate a floating-point exception.
-
- 'ORDERED_EXPR'
- 'UNORDERED_EXPR'
- These nodes represent non-trapping ordered and unordered comparison
- operators. These operations take two floating point operands and
- determine whether they are ordered or unordered relative to each
- other. If either operand is an IEEE NaN, their comparison is
- defined to be unordered, otherwise the comparison is defined to be
- ordered. The result type of these expressions will always be of
- integral or boolean type. These operations return the result
- type's zero value for false, and the result type's one value for
- true.
-
- 'UNLT_EXPR'
- 'UNLE_EXPR'
- 'UNGT_EXPR'
- 'UNGE_EXPR'
- 'UNEQ_EXPR'
- These nodes represent the unordered comparison operators. These
- operations take two floating point operands and determine whether
- the operands are unordered or are less than, less than or equal to,
- greater than, greater than or equal to, or equal respectively. For
- example, 'UNLT_EXPR' returns true if either operand is an IEEE NaN
- or the first operand is less than the second. All these operations
- are guaranteed not to generate a floating point exception. The
- result type of these expressions will always be of integral or
- boolean type. These operations return the result type's zero value
- for false, and the result type's one value for true.
-
- 'MODIFY_EXPR'
- These nodes represent assignment. The left-hand side is the first
- operand; the right-hand side is the second operand. The left-hand
- side will be a 'VAR_DECL', 'INDIRECT_REF', 'COMPONENT_REF', or
- other lvalue.
-
- These nodes are used to represent not only assignment with '=' but
- also compound assignments (like '+='), by reduction to '='
- assignment. In other words, the representation for 'i += 3' looks
- just like that for 'i = i + 3'.
-
- 'INIT_EXPR'
- These nodes are just like 'MODIFY_EXPR', but are used only when a
- variable is initialized, rather than assigned to subsequently.
- This means that we can assume that the target of the initialization
- is not used in computing its own value; any reference to the lhs in
- computing the rhs is undefined.
-
- 'COMPOUND_EXPR'
- These nodes represent comma-expressions. The first operand is an
- expression whose value is computed and thrown away prior to the
- evaluation of the second operand. The value of the entire
- expression is the value of the second operand.
-
- 'COND_EXPR'
- These nodes represent '?:' expressions. The first operand is of
- boolean or integral type. If it evaluates to a nonzero value, the
- second operand should be evaluated, and returned as the value of
- the expression. Otherwise, the third operand is evaluated, and
- returned as the value of the expression.
-
- The second operand must have the same type as the entire
- expression, unless it unconditionally throws an exception or calls
- a noreturn function, in which case it should have void type. The
- same constraints apply to the third operand. This allows array
- bounds checks to be represented conveniently as '(i >= 0 && i < 10)
- ? i : abort()'.
-
- As a GNU extension, the C language front-ends allow the second
- operand of the '?:' operator may be omitted in the source. For
- example, 'x ? : 3' is equivalent to 'x ? x : 3', assuming that 'x'
- is an expression without side effects. In the tree representation,
- however, the second operand is always present, possibly protected
- by 'SAVE_EXPR' if the first argument does cause side effects.
-
- 'CALL_EXPR'
- These nodes are used to represent calls to functions, including
- non-static member functions. 'CALL_EXPR's are implemented as
- expression nodes with a variable number of operands. Rather than
- using 'TREE_OPERAND' to extract them, it is preferable to use the
- specialized accessor macros and functions that operate specifically
- on 'CALL_EXPR' nodes.
-
- 'CALL_EXPR_FN' returns a pointer to the function to call; it is
- always an expression whose type is a 'POINTER_TYPE'.
-
- The number of arguments to the call is returned by
- 'call_expr_nargs', while the arguments themselves can be accessed
- with the 'CALL_EXPR_ARG' macro. The arguments are zero-indexed and
- numbered left-to-right. You can iterate over the arguments using
- 'FOR_EACH_CALL_EXPR_ARG', as in:
-
- tree call, arg;
- call_expr_arg_iterator iter;
- FOR_EACH_CALL_EXPR_ARG (arg, iter, call)
- /* arg is bound to successive arguments of call. */
- ...;
-
- For non-static member functions, there will be an operand
- corresponding to the 'this' pointer. There will always be
- expressions corresponding to all of the arguments, even if the
- function is declared with default arguments and some arguments are
- not explicitly provided at the call sites.
-
- 'CALL_EXPR's also have a 'CALL_EXPR_STATIC_CHAIN' operand that is
- used to implement nested functions. This operand is otherwise
- null.
-
- 'CLEANUP_POINT_EXPR'
- These nodes represent full-expressions. The single operand is an
- expression to evaluate. Any destructor calls engendered by the
- creation of temporaries during the evaluation of that expression
- should be performed immediately after the expression is evaluated.
-
- 'CONSTRUCTOR'
- These nodes represent the brace-enclosed initializers for a
- structure or an array. They contain a sequence of component values
- made out of a vector of constructor_elt, which is a ('INDEX',
- 'VALUE') pair.
-
- If the 'TREE_TYPE' of the 'CONSTRUCTOR' is a 'RECORD_TYPE',
- 'UNION_TYPE' or 'QUAL_UNION_TYPE' then the 'INDEX' of each node in
- the sequence will be a 'FIELD_DECL' and the 'VALUE' will be the
- expression used to initialize that field.
-
- If the 'TREE_TYPE' of the 'CONSTRUCTOR' is an 'ARRAY_TYPE', then
- the 'INDEX' of each node in the sequence will be an 'INTEGER_CST'
- or a 'RANGE_EXPR' of two 'INTEGER_CST's. A single 'INTEGER_CST'
- indicates which element of the array is being assigned to. A
- 'RANGE_EXPR' indicates an inclusive range of elements to
- initialize. In both cases the 'VALUE' is the corresponding
- initializer. It is re-evaluated for each element of a
- 'RANGE_EXPR'. If the 'INDEX' is 'NULL_TREE', then the initializer
- is for the next available array element.
-
- In the front end, you should not depend on the fields appearing in
- any particular order. However, in the middle end, fields must
- appear in declaration order. You should not assume that all fields
- will be represented. Unrepresented fields will be cleared
- (zeroed), unless the CONSTRUCTOR_NO_CLEARING flag is set, in which
- case their value becomes undefined.
-
- 'COMPOUND_LITERAL_EXPR'
- These nodes represent ISO C99 compound literals. The
- 'COMPOUND_LITERAL_EXPR_DECL_EXPR' is a 'DECL_EXPR' containing an
- anonymous 'VAR_DECL' for the unnamed object represented by the
- compound literal; the 'DECL_INITIAL' of that 'VAR_DECL' is a
- 'CONSTRUCTOR' representing the brace-enclosed list of initializers
- in the compound literal. That anonymous 'VAR_DECL' can also be
- accessed directly by the 'COMPOUND_LITERAL_EXPR_DECL' macro.
-
- 'SAVE_EXPR'
-
- A 'SAVE_EXPR' represents an expression (possibly involving side
- effects) that is used more than once. The side effects should
- occur only the first time the expression is evaluated. Subsequent
- uses should just reuse the computed value. The first operand to
- the 'SAVE_EXPR' is the expression to evaluate. The side effects
- should be executed where the 'SAVE_EXPR' is first encountered in a
- depth-first preorder traversal of the expression tree.
-
- 'TARGET_EXPR'
- A 'TARGET_EXPR' represents a temporary object. The first operand
- is a 'VAR_DECL' for the temporary variable. The second operand is
- the initializer for the temporary. The initializer is evaluated
- and, if non-void, copied (bitwise) into the temporary. If the
- initializer is void, that means that it will perform the
- initialization itself.
-
- Often, a 'TARGET_EXPR' occurs on the right-hand side of an
- assignment, or as the second operand to a comma-expression which is
- itself the right-hand side of an assignment, etc. In this case, we
- say that the 'TARGET_EXPR' is "normal"; otherwise, we say it is
- "orphaned". For a normal 'TARGET_EXPR' the temporary variable
- should be treated as an alias for the left-hand side of the
- assignment, rather than as a new temporary variable.
-
- The third operand to the 'TARGET_EXPR', if present, is a
- cleanup-expression (i.e., destructor call) for the temporary. If
- this expression is orphaned, then this expression must be executed
- when the statement containing this expression is complete. These
- cleanups must always be executed in the order opposite to that in
- which they were encountered. Note that if a temporary is created
- on one branch of a conditional operator (i.e., in the second or
- third operand to a 'COND_EXPR'), the cleanup must be run only if
- that branch is actually executed.
-
- 'VA_ARG_EXPR'
- This node is used to implement support for the C/C++ variable
- argument-list mechanism. It represents expressions like 'va_arg
- (ap, type)'. Its 'TREE_TYPE' yields the tree representation for
- 'type' and its sole argument yields the representation for 'ap'.
-
- 'ANNOTATE_EXPR'
- This node is used to attach markers to an expression. The first
- operand is the annotated expression, the second is an 'INTEGER_CST'
- with a value from 'enum annot_expr_kind', the third is an
- 'INTEGER_CST'.
-
-
- File: gccint.info, Node: Vectors, Prev: Unary and Binary Expressions, Up: Expression trees
-
- 11.6.4 Vectors
- --------------
-
- 'VEC_DUPLICATE_EXPR'
- This node has a single operand and represents a vector in which
- every element is equal to that operand.
-
- 'VEC_SERIES_EXPR'
- This node represents a vector formed from a scalar base and step,
- given as the first and second operands respectively. Element I of
- the result is equal to 'BASE + I*STEP'.
-
- This node is restricted to integral types, in order to avoid
- specifying the rounding behavior for floating-point types.
-
- 'VEC_LSHIFT_EXPR'
- 'VEC_RSHIFT_EXPR'
- These nodes represent whole vector left and right shifts,
- respectively. The first operand is the vector to shift; it will
- always be of vector type. The second operand is an expression for
- the number of bits by which to shift. Note that the result is
- undefined if the second operand is larger than or equal to the
- first operand's type size.
-
- 'VEC_WIDEN_MULT_HI_EXPR'
- 'VEC_WIDEN_MULT_LO_EXPR'
- These nodes represent widening vector multiplication of the high
- and low parts of the two input vectors, respectively. Their
- operands are vectors that contain the same number of elements ('N')
- of the same integral type. The result is a vector that contains
- half as many elements, of an integral type whose size is twice as
- wide. In the case of 'VEC_WIDEN_MULT_HI_EXPR' the high 'N/2'
- elements of the two vector are multiplied to produce the vector of
- 'N/2' products. In the case of 'VEC_WIDEN_MULT_LO_EXPR' the low
- 'N/2' elements of the two vector are multiplied to produce the
- vector of 'N/2' products.
-
- 'VEC_UNPACK_HI_EXPR'
- 'VEC_UNPACK_LO_EXPR'
- These nodes represent unpacking of the high and low parts of the
- input vector, respectively. The single operand is a vector that
- contains 'N' elements of the same integral or floating point type.
- The result is a vector that contains half as many elements, of an
- integral or floating point type whose size is twice as wide. In
- the case of 'VEC_UNPACK_HI_EXPR' the high 'N/2' elements of the
- vector are extracted and widened (promoted). In the case of
- 'VEC_UNPACK_LO_EXPR' the low 'N/2' elements of the vector are
- extracted and widened (promoted).
-
- 'VEC_UNPACK_FLOAT_HI_EXPR'
- 'VEC_UNPACK_FLOAT_LO_EXPR'
- These nodes represent unpacking of the high and low parts of the
- input vector, where the values are converted from fixed point to
- floating point. The single operand is a vector that contains 'N'
- elements of the same integral type. The result is a vector that
- contains half as many elements of a floating point type whose size
- is twice as wide. In the case of 'VEC_UNPACK_FLOAT_HI_EXPR' the
- high 'N/2' elements of the vector are extracted, converted and
- widened. In the case of 'VEC_UNPACK_FLOAT_LO_EXPR' the low 'N/2'
- elements of the vector are extracted, converted and widened.
-
- 'VEC_UNPACK_FIX_TRUNC_HI_EXPR'
- 'VEC_UNPACK_FIX_TRUNC_LO_EXPR'
- These nodes represent unpacking of the high and low parts of the
- input vector, where the values are truncated from floating point to
- fixed point. The single operand is a vector that contains 'N'
- elements of the same floating point type. The result is a vector
- that contains half as many elements of an integral type whose size
- is twice as wide. In the case of 'VEC_UNPACK_FIX_TRUNC_HI_EXPR'
- the high 'N/2' elements of the vector are extracted and converted
- with truncation. In the case of 'VEC_UNPACK_FIX_TRUNC_LO_EXPR' the
- low 'N/2' elements of the vector are extracted and converted with
- truncation.
-
- 'VEC_PACK_TRUNC_EXPR'
- This node represents packing of truncated elements of the two input
- vectors into the output vector. Input operands are vectors that
- contain the same number of elements of the same integral or
- floating point type. The result is a vector that contains twice as
- many elements of an integral or floating point type whose size is
- half as wide. The elements of the two vectors are demoted and
- merged (concatenated) to form the output vector.
-
- 'VEC_PACK_SAT_EXPR'
- This node represents packing of elements of the two input vectors
- into the output vector using saturation. Input operands are
- vectors that contain the same number of elements of the same
- integral type. The result is a vector that contains twice as many
- elements of an integral type whose size is half as wide. The
- elements of the two vectors are demoted and merged (concatenated)
- to form the output vector.
-
- 'VEC_PACK_FIX_TRUNC_EXPR'
- This node represents packing of elements of the two input vectors
- into the output vector, where the values are converted from
- floating point to fixed point. Input operands are vectors that
- contain the same number of elements of a floating point type. The
- result is a vector that contains twice as many elements of an
- integral type whose size is half as wide. The elements of the two
- vectors are merged (concatenated) to form the output vector.
-
- 'VEC_PACK_FLOAT_EXPR'
- This node represents packing of elements of the two input vectors
- into the output vector, where the values are converted from fixed
- point to floating point. Input operands are vectors that contain
- the same number of elements of an integral type. The result is a
- vector that contains twice as many elements of floating point type
- whose size is half as wide. The elements of the two vectors are
- merged (concatenated) to form the output vector.
-
- 'VEC_COND_EXPR'
- These nodes represent '?:' expressions. The three operands must be
- vectors of the same size and number of elements. The second and
- third operands must have the same type as the entire expression.
- The first operand is of signed integral vector type. If an element
- of the first operand evaluates to a zero value, the corresponding
- element of the result is taken from the third operand. If it
- evaluates to a minus one value, it is taken from the second
- operand. It should never evaluate to any other value currently,
- but optimizations should not rely on that property. In contrast
- with a 'COND_EXPR', all operands are always evaluated.
-
- 'SAD_EXPR'
- This node represents the Sum of Absolute Differences operation.
- The three operands must be vectors of integral types. The first
- and second operand must have the same type. The size of the vector
- element of the third operand must be at lease twice of the size of
- the vector element of the first and second one. The SAD is
- calculated between the first and second operands, added to the
- third operand, and returned.
-
-
- File: gccint.info, Node: Statements, Next: Functions, Prev: Expression trees, Up: GENERIC
-
- 11.7 Statements
- ===============
-
- Most statements in GIMPLE are assignment statements, represented by
- 'GIMPLE_ASSIGN'. No other C expressions can appear at statement level;
- a reference to a volatile object is converted into a 'GIMPLE_ASSIGN'.
-
- There are also several varieties of complex statements.
-
- * Menu:
-
- * Basic Statements::
- * Blocks::
- * Statement Sequences::
- * Empty Statements::
- * Jumps::
- * Cleanups::
- * OpenMP::
- * OpenACC::
-
-
- File: gccint.info, Node: Basic Statements, Next: Blocks, Up: Statements
-
- 11.7.1 Basic Statements
- -----------------------
-
- 'ASM_EXPR'
-
- Used to represent an inline assembly statement. For an inline
- assembly statement like:
- asm ("mov x, y");
- The 'ASM_STRING' macro will return a 'STRING_CST' node for '"mov x,
- y"'. If the original statement made use of the extended-assembly
- syntax, then 'ASM_OUTPUTS', 'ASM_INPUTS', and 'ASM_CLOBBERS' will
- be the outputs, inputs, and clobbers for the statement, represented
- as 'STRING_CST' nodes. The extended-assembly syntax looks like:
- asm ("fsinx %1,%0" : "=f" (result) : "f" (angle));
- The first string is the 'ASM_STRING', containing the instruction
- template. The next two strings are the output and inputs,
- respectively; this statement has no clobbers. As this example
- indicates, "plain" assembly statements are merely a special case of
- extended assembly statements; they have no cv-qualifiers, outputs,
- inputs, or clobbers. All of the strings will be 'NUL'-terminated,
- and will contain no embedded 'NUL'-characters.
-
- If the assembly statement is declared 'volatile', or if the
- statement was not an extended assembly statement, and is therefore
- implicitly volatile, then the predicate 'ASM_VOLATILE_P' will hold
- of the 'ASM_EXPR'.
-
- 'DECL_EXPR'
-
- Used to represent a local declaration. The 'DECL_EXPR_DECL' macro
- can be used to obtain the entity declared. This declaration may be
- a 'LABEL_DECL', indicating that the label declared is a local
- label. (As an extension, GCC allows the declaration of labels with
- scope.) In C, this declaration may be a 'FUNCTION_DECL',
- indicating the use of the GCC nested function extension. For more
- information, *note Functions::.
-
- 'LABEL_EXPR'
-
- Used to represent a label. The 'LABEL_DECL' declared by this
- statement can be obtained with the 'LABEL_EXPR_LABEL' macro. The
- 'IDENTIFIER_NODE' giving the name of the label can be obtained from
- the 'LABEL_DECL' with 'DECL_NAME'.
-
- 'GOTO_EXPR'
-
- Used to represent a 'goto' statement. The 'GOTO_DESTINATION' will
- usually be a 'LABEL_DECL'. However, if the "computed goto"
- extension has been used, the 'GOTO_DESTINATION' will be an
- arbitrary expression indicating the destination. This expression
- will always have pointer type.
-
- 'RETURN_EXPR'
-
- Used to represent a 'return' statement. Operand 0 represents the
- value to return. It should either be the 'RESULT_DECL' for the
- containing function, or a 'MODIFY_EXPR' or 'INIT_EXPR' setting the
- function's 'RESULT_DECL'. It will be 'NULL_TREE' if the statement
- was just
- return;
-
- 'LOOP_EXPR'
- These nodes represent "infinite" loops. The 'LOOP_EXPR_BODY'
- represents the body of the loop. It should be executed forever,
- unless an 'EXIT_EXPR' is encountered.
-
- 'EXIT_EXPR'
- These nodes represent conditional exits from the nearest enclosing
- 'LOOP_EXPR'. The single operand is the condition; if it is
- nonzero, then the loop should be exited. An 'EXIT_EXPR' will only
- appear within a 'LOOP_EXPR'.
-
- 'SWITCH_STMT'
-
- Used to represent a 'switch' statement. The 'SWITCH_STMT_COND' is
- the expression on which the switch is occurring. See the
- documentation for an 'IF_STMT' for more information on the
- representation used for the condition. The 'SWITCH_STMT_BODY' is
- the body of the switch statement. The 'SWITCH_STMT_TYPE' is the
- original type of switch expression as given in the source, before
- any compiler conversions.
-
- 'CASE_LABEL_EXPR'
-
- Use to represent a 'case' label, range of 'case' labels, or a
- 'default' label. If 'CASE_LOW' is 'NULL_TREE', then this is a
- 'default' label. Otherwise, if 'CASE_HIGH' is 'NULL_TREE', then
- this is an ordinary 'case' label. In this case, 'CASE_LOW' is an
- expression giving the value of the label. Both 'CASE_LOW' and
- 'CASE_HIGH' are 'INTEGER_CST' nodes. These values will have the
- same type as the condition expression in the switch statement.
-
- Otherwise, if both 'CASE_LOW' and 'CASE_HIGH' are defined, the
- statement is a range of case labels. Such statements originate
- with the extension that allows users to write things of the form:
- case 2 ... 5:
- The first value will be 'CASE_LOW', while the second will be
- 'CASE_HIGH'.
-
- 'DEBUG_BEGIN_STMT'
-
- Marks the beginning of a source statement, for purposes of debug
- information generation.
-
-
- File: gccint.info, Node: Blocks, Next: Statement Sequences, Prev: Basic Statements, Up: Statements
-
- 11.7.2 Blocks
- -------------
-
- Block scopes and the variables they declare in GENERIC are expressed
- using the 'BIND_EXPR' code, which in previous versions of GCC was
- primarily used for the C statement-expression extension.
-
- Variables in a block are collected into 'BIND_EXPR_VARS' in declaration
- order through their 'TREE_CHAIN' field. Any runtime initialization is
- moved out of 'DECL_INITIAL' and into a statement in the controlled
- block. When gimplifying from C or C++, this initialization replaces the
- 'DECL_STMT'. These variables will never require cleanups. The scope of
- these variables is just the body
-
- Variable-length arrays (VLAs) complicate this process, as their size
- often refers to variables initialized earlier in the block and their
- initialization involves an explicit stack allocation. To handle this,
- we add an indirection and replace them with a pointer to stack space
- allocated by means of 'alloca'. In most cases, we also arrange for this
- space to be reclaimed when the enclosing 'BIND_EXPR' is exited, the
- exception to this being when there is an explicit call to 'alloca' in
- the source code, in which case the stack is left depressed on exit of
- the 'BIND_EXPR'.
-
- A C++ program will usually contain more 'BIND_EXPR's than there are
- syntactic blocks in the source code, since several C++ constructs have
- implicit scopes associated with them. On the other hand, although the
- C++ front end uses pseudo-scopes to handle cleanups for objects with
- destructors, these don't translate into the GIMPLE form; multiple
- declarations at the same level use the same 'BIND_EXPR'.
-
-
- File: gccint.info, Node: Statement Sequences, Next: Empty Statements, Prev: Blocks, Up: Statements
-
- 11.7.3 Statement Sequences
- --------------------------
-
- Multiple statements at the same nesting level are collected into a
- 'STATEMENT_LIST'. Statement lists are modified and traversed using the
- interface in 'tree-iterator.h'.
-
-
- File: gccint.info, Node: Empty Statements, Next: Jumps, Prev: Statement Sequences, Up: Statements
-
- 11.7.4 Empty Statements
- -----------------------
-
- Whenever possible, statements with no effect are discarded. But if they
- are nested within another construct which cannot be discarded for some
- reason, they are instead replaced with an empty statement, generated by
- 'build_empty_stmt'. Initially, all empty statements were shared, after
- the pattern of the Java front end, but this caused a lot of trouble in
- practice.
-
- An empty statement is represented as '(void)0'.
-
-
- File: gccint.info, Node: Jumps, Next: Cleanups, Prev: Empty Statements, Up: Statements
-
- 11.7.5 Jumps
- ------------
-
- Other jumps are expressed by either 'GOTO_EXPR' or 'RETURN_EXPR'.
-
- The operand of a 'GOTO_EXPR' must be either a label or a variable
- containing the address to jump to.
-
- The operand of a 'RETURN_EXPR' is either 'NULL_TREE', 'RESULT_DECL', or
- a 'MODIFY_EXPR' which sets the return value. It would be nice to move
- the 'MODIFY_EXPR' into a separate statement, but the special return
- semantics in 'expand_return' make that difficult. It may still happen
- in the future, perhaps by moving most of that logic into
- 'expand_assignment'.
-
-
- File: gccint.info, Node: Cleanups, Next: OpenMP, Prev: Jumps, Up: Statements
-
- 11.7.6 Cleanups
- ---------------
-
- Destructors for local C++ objects and similar dynamic cleanups are
- represented in GIMPLE by a 'TRY_FINALLY_EXPR'. 'TRY_FINALLY_EXPR' has
- two operands, both of which are a sequence of statements to execute.
- The first sequence is executed. When it completes the second sequence
- is executed.
-
- The first sequence may complete in the following ways:
-
- 1. Execute the last statement in the sequence and fall off the end.
-
- 2. Execute a goto statement ('GOTO_EXPR') to an ordinary label outside
- the sequence.
-
- 3. Execute a return statement ('RETURN_EXPR').
-
- 4. Throw an exception. This is currently not explicitly represented
- in GIMPLE.
-
- The second sequence is not executed if the first sequence completes by
- calling 'setjmp' or 'exit' or any other function that does not return.
- The second sequence is also not executed if the first sequence completes
- via a non-local goto or a computed goto (in general the compiler does
- not know whether such a goto statement exits the first sequence or not,
- so we assume that it doesn't).
-
- After the second sequence is executed, if it completes normally by
- falling off the end, execution continues wherever the first sequence
- would have continued, by falling off the end, or doing a goto, etc.
-
- If the second sequence is an 'EH_ELSE_EXPR' selector, then the sequence
- in its first operand is used when the first sequence completes normally,
- and that in its second operand is used for exceptional cleanups, i.e.,
- when an exception propagates out of the first sequence.
-
- 'TRY_FINALLY_EXPR' complicates the flow graph, since the cleanup needs
- to appear on every edge out of the controlled block; this reduces the
- freedom to move code across these edges. Therefore, the EH lowering
- pass which runs before most of the optimization passes eliminates these
- expressions by explicitly adding the cleanup to each edge. Rethrowing
- the exception is represented using 'RESX_EXPR'.
-
-
- File: gccint.info, Node: OpenMP, Next: OpenACC, Prev: Cleanups, Up: Statements
-
- 11.7.7 OpenMP
- -------------
-
- All the statements starting with 'OMP_' represent directives and clauses
- used by the OpenMP API <https://www.openmp.org>.
-
- 'OMP_PARALLEL'
-
- Represents '#pragma omp parallel [clause1 ... clauseN]'. It has
- four operands:
-
- Operand 'OMP_PARALLEL_BODY' is valid while in GENERIC and High
- GIMPLE forms. It contains the body of code to be executed by all
- the threads. During GIMPLE lowering, this operand becomes 'NULL'
- and the body is emitted linearly after 'OMP_PARALLEL'.
-
- Operand 'OMP_PARALLEL_CLAUSES' is the list of clauses associated
- with the directive.
-
- Operand 'OMP_PARALLEL_FN' is created by 'pass_lower_omp', it
- contains the 'FUNCTION_DECL' for the function that will contain the
- body of the parallel region.
-
- Operand 'OMP_PARALLEL_DATA_ARG' is also created by
- 'pass_lower_omp'. If there are shared variables to be communicated
- to the children threads, this operand will contain the 'VAR_DECL'
- that contains all the shared values and variables.
-
- 'OMP_FOR'
-
- Represents '#pragma omp for [clause1 ... clauseN]'. It has six
- operands:
-
- Operand 'OMP_FOR_BODY' contains the loop body.
-
- Operand 'OMP_FOR_CLAUSES' is the list of clauses associated with
- the directive.
-
- Operand 'OMP_FOR_INIT' is the loop initialization code of the form
- 'VAR = N1'.
-
- Operand 'OMP_FOR_COND' is the loop conditional expression of the
- form 'VAR {<,>,<=,>=} N2'.
-
- Operand 'OMP_FOR_INCR' is the loop index increment of the form 'VAR
- {+=,-=} INCR'.
-
- Operand 'OMP_FOR_PRE_BODY' contains side effect code from operands
- 'OMP_FOR_INIT', 'OMP_FOR_COND' and 'OMP_FOR_INC'. These side
- effects are part of the 'OMP_FOR' block but must be evaluated
- before the start of loop body.
-
- The loop index variable 'VAR' must be a signed integer variable,
- which is implicitly private to each thread. Bounds 'N1' and 'N2'
- and the increment expression 'INCR' are required to be loop
- invariant integer expressions that are evaluated without any
- synchronization. The evaluation order, frequency of evaluation and
- side effects are unspecified by the standard.
-
- 'OMP_SECTIONS'
-
- Represents '#pragma omp sections [clause1 ... clauseN]'.
-
- Operand 'OMP_SECTIONS_BODY' contains the sections body, which in
- turn contains a set of 'OMP_SECTION' nodes for each of the
- concurrent sections delimited by '#pragma omp section'.
-
- Operand 'OMP_SECTIONS_CLAUSES' is the list of clauses associated
- with the directive.
-
- 'OMP_SECTION'
-
- Section delimiter for 'OMP_SECTIONS'.
-
- 'OMP_SINGLE'
-
- Represents '#pragma omp single'.
-
- Operand 'OMP_SINGLE_BODY' contains the body of code to be executed
- by a single thread.
-
- Operand 'OMP_SINGLE_CLAUSES' is the list of clauses associated with
- the directive.
-
- 'OMP_MASTER'
-
- Represents '#pragma omp master'.
-
- Operand 'OMP_MASTER_BODY' contains the body of code to be executed
- by the master thread.
-
- 'OMP_ORDERED'
-
- Represents '#pragma omp ordered'.
-
- Operand 'OMP_ORDERED_BODY' contains the body of code to be executed
- in the sequential order dictated by the loop index variable.
-
- 'OMP_CRITICAL'
-
- Represents '#pragma omp critical [name]'.
-
- Operand 'OMP_CRITICAL_BODY' is the critical section.
-
- Operand 'OMP_CRITICAL_NAME' is an optional identifier to label the
- critical section.
-
- 'OMP_RETURN'
-
- This does not represent any OpenMP directive, it is an artificial
- marker to indicate the end of the body of an OpenMP. It is used by
- the flow graph ('tree-cfg.c') and OpenMP region building code
- ('omp-low.c').
-
- 'OMP_CONTINUE'
-
- Similarly, this instruction does not represent an OpenMP directive,
- it is used by 'OMP_FOR' (and similar codes) as well as
- 'OMP_SECTIONS' to mark the place where the code needs to loop to
- the next iteration, or the next section, respectively.
-
- In some cases, 'OMP_CONTINUE' is placed right before 'OMP_RETURN'.
- But if there are cleanups that need to occur right after the
- looping body, it will be emitted between 'OMP_CONTINUE' and
- 'OMP_RETURN'.
-
- 'OMP_ATOMIC'
-
- Represents '#pragma omp atomic'.
-
- Operand 0 is the address at which the atomic operation is to be
- performed.
-
- Operand 1 is the expression to evaluate. The gimplifier tries
- three alternative code generation strategies. Whenever possible,
- an atomic update built-in is used. If that fails, a
- compare-and-swap loop is attempted. If that also fails, a regular
- critical section around the expression is used.
-
- 'OMP_CLAUSE'
-
- Represents clauses associated with one of the 'OMP_' directives.
- Clauses are represented by separate subcodes defined in 'tree.h'.
- Clauses codes can be one of: 'OMP_CLAUSE_PRIVATE',
- 'OMP_CLAUSE_SHARED', 'OMP_CLAUSE_FIRSTPRIVATE',
- 'OMP_CLAUSE_LASTPRIVATE', 'OMP_CLAUSE_COPYIN',
- 'OMP_CLAUSE_COPYPRIVATE', 'OMP_CLAUSE_IF',
- 'OMP_CLAUSE_NUM_THREADS', 'OMP_CLAUSE_SCHEDULE',
- 'OMP_CLAUSE_NOWAIT', 'OMP_CLAUSE_ORDERED', 'OMP_CLAUSE_DEFAULT',
- 'OMP_CLAUSE_REDUCTION', 'OMP_CLAUSE_COLLAPSE', 'OMP_CLAUSE_UNTIED',
- 'OMP_CLAUSE_FINAL', and 'OMP_CLAUSE_MERGEABLE'. Each code
- represents the corresponding OpenMP clause.
-
- Clauses associated with the same directive are chained together via
- 'OMP_CLAUSE_CHAIN'. Those clauses that accept a list of variables
- are restricted to exactly one, accessed with 'OMP_CLAUSE_VAR'.
- Therefore, multiple variables under the same clause 'C' need to be
- represented as multiple 'C' clauses chained together. This
- facilitates adding new clauses during compilation.
-
-
- File: gccint.info, Node: OpenACC, Prev: OpenMP, Up: Statements
-
- 11.7.8 OpenACC
- --------------
-
- All the statements starting with 'OACC_' represent directives and
- clauses used by the OpenACC API <https://www.openacc.org>.
-
- 'OACC_CACHE'
-
- Represents '#pragma acc cache (var ...)'.
-
- 'OACC_DATA'
-
- Represents '#pragma acc data [clause1 ... clauseN]'.
-
- 'OACC_DECLARE'
-
- Represents '#pragma acc declare [clause1 ... clauseN]'.
-
- 'OACC_ENTER_DATA'
-
- Represents '#pragma acc enter data [clause1 ... clauseN]'.
-
- 'OACC_EXIT_DATA'
-
- Represents '#pragma acc exit data [clause1 ... clauseN]'.
-
- 'OACC_HOST_DATA'
-
- Represents '#pragma acc host_data [clause1 ... clauseN]'.
-
- 'OACC_KERNELS'
-
- Represents '#pragma acc kernels [clause1 ... clauseN]'.
-
- 'OACC_LOOP'
-
- Represents '#pragma acc loop [clause1 ... clauseN]'.
-
- See the description of the 'OMP_FOR' code.
-
- 'OACC_PARALLEL'
-
- Represents '#pragma acc parallel [clause1 ... clauseN]'.
-
- 'OACC_SERIAL'
-
- Represents '#pragma acc serial [clause1 ... clauseN]'.
-
- 'OACC_UPDATE'
-
- Represents '#pragma acc update [clause1 ... clauseN]'.
-
-
- File: gccint.info, Node: Functions, Next: Language-dependent trees, Prev: Statements, Up: GENERIC
-
- 11.8 Functions
- ==============
-
- A function is represented by a 'FUNCTION_DECL' node. It stores the
- basic pieces of the function such as body, parameters, and return type
- as well as information on the surrounding context, visibility, and
- linkage.
-
- * Menu:
-
- * Function Basics:: Function names, body, and parameters.
- * Function Properties:: Context, linkage, etc.
-
-
- File: gccint.info, Node: Function Basics, Next: Function Properties, Up: Functions
-
- 11.8.1 Function Basics
- ----------------------
-
- A function has four core parts: the name, the parameters, the result,
- and the body. The following macros and functions access these parts of
- a 'FUNCTION_DECL' as well as other basic features:
- 'DECL_NAME'
- This macro returns the unqualified name of the function, as an
- 'IDENTIFIER_NODE'. For an instantiation of a function template,
- the 'DECL_NAME' is the unqualified name of the template, not
- something like 'f<int>'. The value of 'DECL_NAME' is undefined
- when used on a constructor, destructor, overloaded operator, or
- type-conversion operator, or any function that is implicitly
- generated by the compiler. See below for macros that can be used
- to distinguish these cases.
-
- 'DECL_ASSEMBLER_NAME'
- This macro returns the mangled name of the function, also an
- 'IDENTIFIER_NODE'. This name does not contain leading underscores
- on systems that prefix all identifiers with underscores. The
- mangled name is computed in the same way on all platforms; if
- special processing is required to deal with the object file format
- used on a particular platform, it is the responsibility of the back
- end to perform those modifications. (Of course, the back end
- should not modify 'DECL_ASSEMBLER_NAME' itself.)
-
- Using 'DECL_ASSEMBLER_NAME' will cause additional memory to be
- allocated (for the mangled name of the entity) so it should be used
- only when emitting assembly code. It should not be used within the
- optimizers to determine whether or not two declarations are the
- same, even though some of the existing optimizers do use it in that
- way. These uses will be removed over time.
-
- 'DECL_ARGUMENTS'
- This macro returns the 'PARM_DECL' for the first argument to the
- function. Subsequent 'PARM_DECL' nodes can be obtained by
- following the 'TREE_CHAIN' links.
-
- 'DECL_RESULT'
- This macro returns the 'RESULT_DECL' for the function.
-
- 'DECL_SAVED_TREE'
- This macro returns the complete body of the function.
-
- 'TREE_TYPE'
- This macro returns the 'FUNCTION_TYPE' or 'METHOD_TYPE' for the
- function.
-
- 'DECL_INITIAL'
- A function that has a definition in the current translation unit
- will have a non-'NULL' 'DECL_INITIAL'. However, back ends should
- not make use of the particular value given by 'DECL_INITIAL'.
-
- It should contain a tree of 'BLOCK' nodes that mirrors the scopes
- that variables are bound in the function. Each block contains a
- list of decls declared in a basic block, a pointer to a chain of
- blocks at the next lower scope level, then a pointer to the next
- block at the same level and a backpointer to the parent 'BLOCK' or
- 'FUNCTION_DECL'. So given a function as follows:
-
- void foo()
- {
- int a;
- {
- int b;
- }
- int c;
- }
-
- you would get the following:
-
- tree foo = FUNCTION_DECL;
- tree decl_a = VAR_DECL;
- tree decl_b = VAR_DECL;
- tree decl_c = VAR_DECL;
- tree block_a = BLOCK;
- tree block_b = BLOCK;
- tree block_c = BLOCK;
- BLOCK_VARS(block_a) = decl_a;
- BLOCK_SUBBLOCKS(block_a) = block_b;
- BLOCK_CHAIN(block_a) = block_c;
- BLOCK_SUPERCONTEXT(block_a) = foo;
- BLOCK_VARS(block_b) = decl_b;
- BLOCK_SUPERCONTEXT(block_b) = block_a;
- BLOCK_VARS(block_c) = decl_c;
- BLOCK_SUPERCONTEXT(block_c) = foo;
- DECL_INITIAL(foo) = block_a;
-
-
- File: gccint.info, Node: Function Properties, Prev: Function Basics, Up: Functions
-
- 11.8.2 Function Properties
- --------------------------
-
- To determine the scope of a function, you can use the 'DECL_CONTEXT'
- macro. This macro will return the class (either a 'RECORD_TYPE' or a
- 'UNION_TYPE') or namespace (a 'NAMESPACE_DECL') of which the function is
- a member. For a virtual function, this macro returns the class in which
- the function was actually defined, not the base class in which the
- virtual declaration occurred.
-
- In C, the 'DECL_CONTEXT' for a function maybe another function. This
- representation indicates that the GNU nested function extension is in
- use. For details on the semantics of nested functions, see the GCC
- Manual. The nested function can refer to local variables in its
- containing function. Such references are not explicitly marked in the
- tree structure; back ends must look at the 'DECL_CONTEXT' for the
- referenced 'VAR_DECL'. If the 'DECL_CONTEXT' for the referenced
- 'VAR_DECL' is not the same as the function currently being processed,
- and neither 'DECL_EXTERNAL' nor 'TREE_STATIC' hold, then the reference
- is to a local variable in a containing function, and the back end must
- take appropriate action.
-
- 'DECL_EXTERNAL'
- This predicate holds if the function is undefined.
-
- 'TREE_PUBLIC'
- This predicate holds if the function has external linkage.
-
- 'TREE_STATIC'
- This predicate holds if the function has been defined.
-
- 'TREE_THIS_VOLATILE'
- This predicate holds if the function does not return normally.
-
- 'TREE_READONLY'
- This predicate holds if the function can only read its arguments.
-
- 'DECL_PURE_P'
- This predicate holds if the function can only read its arguments,
- but may also read global memory.
-
- 'DECL_VIRTUAL_P'
- This predicate holds if the function is virtual.
-
- 'DECL_ARTIFICIAL'
- This macro holds if the function was implicitly generated by the
- compiler, rather than explicitly declared. In addition to
- implicitly generated class member functions, this macro holds for
- the special functions created to implement static initialization
- and destruction, to compute run-time type information, and so
- forth.
-
- 'DECL_FUNCTION_SPECIFIC_TARGET'
- This macro returns a tree node that holds the target options that
- are to be used to compile this particular function or 'NULL_TREE'
- if the function is to be compiled with the target options specified
- on the command line.
-
- 'DECL_FUNCTION_SPECIFIC_OPTIMIZATION'
- This macro returns a tree node that holds the optimization options
- that are to be used to compile this particular function or
- 'NULL_TREE' if the function is to be compiled with the optimization
- options specified on the command line.
-
-
- File: gccint.info, Node: Language-dependent trees, Next: C and C++ Trees, Prev: Functions, Up: GENERIC
-
- 11.9 Language-dependent trees
- =============================
-
- Front ends may wish to keep some state associated with various GENERIC
- trees while parsing. To support this, trees provide a set of flags that
- may be used by the front end. They are accessed using
- 'TREE_LANG_FLAG_n' where 'n' is currently 0 through 6.
-
- If necessary, a front end can use some language-dependent tree codes in
- its GENERIC representation, so long as it provides a hook for converting
- them to GIMPLE and doesn't expect them to work with any (hypothetical)
- optimizers that run before the conversion to GIMPLE. The intermediate
- representation used while parsing C and C++ looks very little like
- GENERIC, but the C and C++ gimplifier hooks are perfectly happy to take
- it as input and spit out GIMPLE.
-
-
- File: gccint.info, Node: C and C++ Trees, Prev: Language-dependent trees, Up: GENERIC
-
- 11.10 C and C++ Trees
- =====================
-
- This section documents the internal representation used by GCC to
- represent C and C++ source programs. When presented with a C or C++
- source program, GCC parses the program, performs semantic analysis
- (including the generation of error messages), and then produces the
- internal representation described here. This representation contains a
- complete representation for the entire translation unit provided as
- input to the front end. This representation is then typically processed
- by a code-generator in order to produce machine code, but could also be
- used in the creation of source browsers, intelligent editors, automatic
- documentation generators, interpreters, and any other programs needing
- the ability to process C or C++ code.
-
- This section explains the internal representation. In particular, it
- documents the internal representation for C and C++ source constructs,
- and the macros, functions, and variables that can be used to access
- these constructs. The C++ representation is largely a superset of the
- representation used in the C front end. There is only one construct
- used in C that does not appear in the C++ front end and that is the GNU
- "nested function" extension. Many of the macros documented here do not
- apply in C because the corresponding language constructs do not appear
- in C.
-
- The C and C++ front ends generate a mix of GENERIC trees and ones
- specific to C and C++. These language-specific trees are higher-level
- constructs than the ones in GENERIC to make the parser's job easier.
- This section describes those trees that aren't part of GENERIC as well
- as aspects of GENERIC trees that are treated in a language-specific
- manner.
-
- If you are developing a "back end", be it is a code-generator or some
- other tool, that uses this representation, you may occasionally find
- that you need to ask questions not easily answered by the functions and
- macros available here. If that situation occurs, it is quite likely
- that GCC already supports the functionality you desire, but that the
- interface is simply not documented here. In that case, you should ask
- the GCC maintainers (via mail to <gcc@gcc.gnu.org>) about documenting
- the functionality you require. Similarly, if you find yourself writing
- functions that do not deal directly with your back end, but instead
- might be useful to other people using the GCC front end, you should
- submit your patches for inclusion in GCC.
-
- * Menu:
-
- * Types for C++:: Fundamental and aggregate types.
- * Namespaces:: Namespaces.
- * Classes:: Classes.
- * Functions for C++:: Overloading and accessors for C++.
- * Statements for C++:: Statements specific to C and C++.
- * C++ Expressions:: From 'typeid' to 'throw'.
-
-
- File: gccint.info, Node: Types for C++, Next: Namespaces, Up: C and C++ Trees
-
- 11.10.1 Types for C++
- ---------------------
-
- In C++, an array type is not qualified; rather the type of the array
- elements is qualified. This situation is reflected in the intermediate
- representation. The macros described here will always examine the
- qualification of the underlying element type when applied to an array
- type. (If the element type is itself an array, then the recursion
- continues until a non-array type is found, and the qualification of this
- type is examined.) So, for example, 'CP_TYPE_CONST_P' will hold of the
- type 'const int ()[7]', denoting an array of seven 'int's.
-
- The following functions and macros deal with cv-qualification of types:
- 'cp_type_quals'
- This function returns the set of type qualifiers applied to this
- type. This value is 'TYPE_UNQUALIFIED' if no qualifiers have been
- applied. The 'TYPE_QUAL_CONST' bit is set if the type is
- 'const'-qualified. The 'TYPE_QUAL_VOLATILE' bit is set if the type
- is 'volatile'-qualified. The 'TYPE_QUAL_RESTRICT' bit is set if
- the type is 'restrict'-qualified.
-
- 'CP_TYPE_CONST_P'
- This macro holds if the type is 'const'-qualified.
-
- 'CP_TYPE_VOLATILE_P'
- This macro holds if the type is 'volatile'-qualified.
-
- 'CP_TYPE_RESTRICT_P'
- This macro holds if the type is 'restrict'-qualified.
-
- 'CP_TYPE_CONST_NON_VOLATILE_P'
- This predicate holds for a type that is 'const'-qualified, but
- _not_ 'volatile'-qualified; other cv-qualifiers are ignored as
- well: only the 'const'-ness is tested.
-
- A few other macros and functions are usable with all types:
- 'TYPE_SIZE'
- The number of bits required to represent the type, represented as
- an 'INTEGER_CST'. For an incomplete type, 'TYPE_SIZE' will be
- 'NULL_TREE'.
-
- 'TYPE_ALIGN'
- The alignment of the type, in bits, represented as an 'int'.
-
- 'TYPE_NAME'
- This macro returns a declaration (in the form of a 'TYPE_DECL') for
- the type. (Note this macro does _not_ return an 'IDENTIFIER_NODE',
- as you might expect, given its name!) You can look at the
- 'DECL_NAME' of the 'TYPE_DECL' to obtain the actual name of the
- type. The 'TYPE_NAME' will be 'NULL_TREE' for a type that is not a
- built-in type, the result of a typedef, or a named class type.
-
- 'CP_INTEGRAL_TYPE'
- This predicate holds if the type is an integral type. Notice that
- in C++, enumerations are _not_ integral types.
-
- 'ARITHMETIC_TYPE_P'
- This predicate holds if the type is an integral type (in the C++
- sense) or a floating point type.
-
- 'CLASS_TYPE_P'
- This predicate holds for a class-type.
-
- 'TYPE_BUILT_IN'
- This predicate holds for a built-in type.
-
- 'TYPE_PTRDATAMEM_P'
- This predicate holds if the type is a pointer to data member.
-
- 'TYPE_PTR_P'
- This predicate holds if the type is a pointer type, and the pointee
- is not a data member.
-
- 'TYPE_PTRFN_P'
- This predicate holds for a pointer to function type.
-
- 'TYPE_PTROB_P'
- This predicate holds for a pointer to object type. Note however
- that it does not hold for the generic pointer to object type 'void
- *'. You may use 'TYPE_PTROBV_P' to test for a pointer to object
- type as well as 'void *'.
-
- The table below describes types specific to C and C++ as well as
- language-dependent info about GENERIC types.
-
- 'POINTER_TYPE'
- Used to represent pointer types, and pointer to data member types.
- If 'TREE_TYPE' is a pointer to data member type, then
- 'TYPE_PTRDATAMEM_P' will hold. For a pointer to data member type
- of the form 'T X::*', 'TYPE_PTRMEM_CLASS_TYPE' will be the type
- 'X', while 'TYPE_PTRMEM_POINTED_TO_TYPE' will be the type 'T'.
-
- 'RECORD_TYPE'
- Used to represent 'struct' and 'class' types in C and C++. If
- 'TYPE_PTRMEMFUNC_P' holds, then this type is a pointer-to-member
- type. In that case, the 'TYPE_PTRMEMFUNC_FN_TYPE' is a
- 'POINTER_TYPE' pointing to a 'METHOD_TYPE'. The 'METHOD_TYPE' is
- the type of a function pointed to by the pointer-to-member
- function. If 'TYPE_PTRMEMFUNC_P' does not hold, this type is a
- class type. For more information, *note Classes::.
-
- 'UNKNOWN_TYPE'
- This node is used to represent a type the knowledge of which is
- insufficient for a sound processing.
-
- 'TYPENAME_TYPE'
- Used to represent a construct of the form 'typename T::A'. The
- 'TYPE_CONTEXT' is 'T'; the 'TYPE_NAME' is an 'IDENTIFIER_NODE' for
- 'A'. If the type is specified via a template-id, then
- 'TYPENAME_TYPE_FULLNAME' yields a 'TEMPLATE_ID_EXPR'. The
- 'TREE_TYPE' is non-'NULL' if the node is implicitly generated in
- support for the implicit typename extension; in which case the
- 'TREE_TYPE' is a type node for the base-class.
-
- 'TYPEOF_TYPE'
- Used to represent the '__typeof__' extension. The 'TYPE_FIELDS' is
- the expression the type of which is being represented.
-
-
- File: gccint.info, Node: Namespaces, Next: Classes, Prev: Types for C++, Up: C and C++ Trees
-
- 11.10.2 Namespaces
- ------------------
-
- The root of the entire intermediate representation is the variable
- 'global_namespace'. This is the namespace specified with '::' in C++
- source code. All other namespaces, types, variables, functions, and so
- forth can be found starting with this namespace.
-
- However, except for the fact that it is distinguished as the root of
- the representation, the global namespace is no different from any other
- namespace. Thus, in what follows, we describe namespaces generally,
- rather than the global namespace in particular.
-
- A namespace is represented by a 'NAMESPACE_DECL' node.
-
- The following macros and functions can be used on a 'NAMESPACE_DECL':
-
- 'DECL_NAME'
- This macro is used to obtain the 'IDENTIFIER_NODE' corresponding to
- the unqualified name of the name of the namespace (*note
- Identifiers::). The name of the global namespace is '::', even
- though in C++ the global namespace is unnamed. However, you should
- use comparison with 'global_namespace', rather than 'DECL_NAME' to
- determine whether or not a namespace is the global one. An unnamed
- namespace will have a 'DECL_NAME' equal to
- 'anonymous_namespace_name'. Within a single translation unit, all
- unnamed namespaces will have the same name.
-
- 'DECL_CONTEXT'
- This macro returns the enclosing namespace. The 'DECL_CONTEXT' for
- the 'global_namespace' is 'NULL_TREE'.
-
- 'DECL_NAMESPACE_ALIAS'
- If this declaration is for a namespace alias, then
- 'DECL_NAMESPACE_ALIAS' is the namespace for which this one is an
- alias.
-
- Do not attempt to use 'cp_namespace_decls' for a namespace which is
- an alias. Instead, follow 'DECL_NAMESPACE_ALIAS' links until you
- reach an ordinary, non-alias, namespace, and call
- 'cp_namespace_decls' there.
-
- 'DECL_NAMESPACE_STD_P'
- This predicate holds if the namespace is the special '::std'
- namespace.
-
- 'cp_namespace_decls'
- This function will return the declarations contained in the
- namespace, including types, overloaded functions, other namespaces,
- and so forth. If there are no declarations, this function will
- return 'NULL_TREE'. The declarations are connected through their
- 'TREE_CHAIN' fields.
-
- Although most entries on this list will be declarations,
- 'TREE_LIST' nodes may also appear. In this case, the 'TREE_VALUE'
- will be an 'OVERLOAD'. The value of the 'TREE_PURPOSE' is
- unspecified; back ends should ignore this value. As with the other
- kinds of declarations returned by 'cp_namespace_decls', the
- 'TREE_CHAIN' will point to the next declaration in this list.
-
- For more information on the kinds of declarations that can occur on
- this list, *Note Declarations::. Some declarations will not appear
- on this list. In particular, no 'FIELD_DECL', 'LABEL_DECL', or
- 'PARM_DECL' nodes will appear here.
-
- This function cannot be used with namespaces that have
- 'DECL_NAMESPACE_ALIAS' set.
-
-
- File: gccint.info, Node: Classes, Next: Functions for C++, Prev: Namespaces, Up: C and C++ Trees
-
- 11.10.3 Classes
- ---------------
-
- Besides namespaces, the other high-level scoping construct in C++ is the
- class. (Throughout this manual the term "class" is used to mean the
- types referred to in the ANSI/ISO C++ Standard as classes; these include
- types defined with the 'class', 'struct', and 'union' keywords.)
-
- A class type is represented by either a 'RECORD_TYPE' or a
- 'UNION_TYPE'. A class declared with the 'union' tag is represented by a
- 'UNION_TYPE', while classes declared with either the 'struct' or the
- 'class' tag are represented by 'RECORD_TYPE's. You can use the
- 'CLASSTYPE_DECLARED_CLASS' macro to discern whether or not a particular
- type is a 'class' as opposed to a 'struct'. This macro will be true
- only for classes declared with the 'class' tag.
-
- Almost all members are available on the 'TYPE_FIELDS' list. Given one
- member, the next can be found by following the 'TREE_CHAIN'. You should
- not depend in any way on the order in which fields appear on this list.
- All nodes on this list will be 'DECL' nodes. A 'FIELD_DECL' is used to
- represent a non-static data member, a 'VAR_DECL' is used to represent a
- static data member, and a 'TYPE_DECL' is used to represent a type. Note
- that the 'CONST_DECL' for an enumeration constant will appear on this
- list, if the enumeration type was declared in the class. (Of course,
- the 'TYPE_DECL' for the enumeration type will appear here as well.)
- There are no entries for base classes on this list. In particular,
- there is no 'FIELD_DECL' for the "base-class portion" of an object. If
- a function member is overloaded, each of the overloaded functions
- appears; no 'OVERLOAD' nodes appear on the 'TYPE_FIELDS' list.
- Implicitly declared functions (including default constructors, copy
- constructors, assignment operators, and destructors) will appear on this
- list as well.
-
- The 'TYPE_VFIELD' is a compiler-generated field used to point to
- virtual function tables. It may or may not appear on the 'TYPE_FIELDS'
- list. However, back ends should handle the 'TYPE_VFIELD' just like all
- the entries on the 'TYPE_FIELDS' list.
-
- Every class has an associated "binfo", which can be obtained with
- 'TYPE_BINFO'. Binfos are used to represent base-classes. The binfo
- given by 'TYPE_BINFO' is the degenerate case, whereby every class is
- considered to be its own base-class. The base binfos for a particular
- binfo are held in a vector, whose length is obtained with
- 'BINFO_N_BASE_BINFOS'. The base binfos themselves are obtained with
- 'BINFO_BASE_BINFO' and 'BINFO_BASE_ITERATE'. To add a new binfo, use
- 'BINFO_BASE_APPEND'. The vector of base binfos can be obtained with
- 'BINFO_BASE_BINFOS', but normally you do not need to use that. The
- class type associated with a binfo is given by 'BINFO_TYPE'. It is not
- always the case that 'BINFO_TYPE (TYPE_BINFO (x))', because of typedefs
- and qualified types. Neither is it the case that 'TYPE_BINFO
- (BINFO_TYPE (y))' is the same binfo as 'y'. The reason is that if 'y'
- is a binfo representing a base-class 'B' of a derived class 'D', then
- 'BINFO_TYPE (y)' will be 'B', and 'TYPE_BINFO (BINFO_TYPE (y))' will be
- 'B' as its own base-class, rather than as a base-class of 'D'.
-
- The access to a base type can be found with 'BINFO_BASE_ACCESS'. This
- will produce 'access_public_node', 'access_private_node' or
- 'access_protected_node'. If bases are always public,
- 'BINFO_BASE_ACCESSES' may be 'NULL'.
-
- 'BINFO_VIRTUAL_P' is used to specify whether the binfo is inherited
- virtually or not. The other flags, 'BINFO_FLAG_0' to 'BINFO_FLAG_6',
- can be used for language specific use.
-
- The following macros can be used on a tree node representing a
- class-type.
-
- 'LOCAL_CLASS_P'
- This predicate holds if the class is local class _i.e._ declared
- inside a function body.
-
- 'TYPE_POLYMORPHIC_P'
- This predicate holds if the class has at least one virtual function
- (declared or inherited).
-
- 'TYPE_HAS_DEFAULT_CONSTRUCTOR'
- This predicate holds whenever its argument represents a class-type
- with default constructor.
-
- 'CLASSTYPE_HAS_MUTABLE'
- 'TYPE_HAS_MUTABLE_P'
- These predicates hold for a class-type having a mutable data
- member.
-
- 'CLASSTYPE_NON_POD_P'
- This predicate holds only for class-types that are not PODs.
-
- 'TYPE_HAS_NEW_OPERATOR'
- This predicate holds for a class-type that defines 'operator new'.
-
- 'TYPE_HAS_ARRAY_NEW_OPERATOR'
- This predicate holds for a class-type for which 'operator new[]' is
- defined.
-
- 'TYPE_OVERLOADS_CALL_EXPR'
- This predicate holds for class-type for which the function call
- 'operator()' is overloaded.
-
- 'TYPE_OVERLOADS_ARRAY_REF'
- This predicate holds for a class-type that overloads 'operator[]'
-
- 'TYPE_OVERLOADS_ARROW'
- This predicate holds for a class-type for which 'operator->' is
- overloaded.
-
-
- File: gccint.info, Node: Functions for C++, Next: Statements for C++, Prev: Classes, Up: C and C++ Trees
-
- 11.10.4 Functions for C++
- -------------------------
-
- A function is represented by a 'FUNCTION_DECL' node. A set of
- overloaded functions is sometimes represented by an 'OVERLOAD' node.
-
- An 'OVERLOAD' node is not a declaration, so none of the 'DECL_' macros
- should be used on an 'OVERLOAD'. An 'OVERLOAD' node is similar to a
- 'TREE_LIST'. Use 'OVL_CURRENT' to get the function associated with an
- 'OVERLOAD' node; use 'OVL_NEXT' to get the next 'OVERLOAD' node in the
- list of overloaded functions. The macros 'OVL_CURRENT' and 'OVL_NEXT'
- are actually polymorphic; you can use them to work with 'FUNCTION_DECL'
- nodes as well as with overloads. In the case of a 'FUNCTION_DECL',
- 'OVL_CURRENT' will always return the function itself, and 'OVL_NEXT'
- will always be 'NULL_TREE'.
-
- To determine the scope of a function, you can use the 'DECL_CONTEXT'
- macro. This macro will return the class (either a 'RECORD_TYPE' or a
- 'UNION_TYPE') or namespace (a 'NAMESPACE_DECL') of which the function is
- a member. For a virtual function, this macro returns the class in which
- the function was actually defined, not the base class in which the
- virtual declaration occurred.
-
- If a friend function is defined in a class scope, the
- 'DECL_FRIEND_CONTEXT' macro can be used to determine the class in which
- it was defined. For example, in
- class C { friend void f() {} };
- the 'DECL_CONTEXT' for 'f' will be the 'global_namespace', but the
- 'DECL_FRIEND_CONTEXT' will be the 'RECORD_TYPE' for 'C'.
-
- The following macros and functions can be used on a 'FUNCTION_DECL':
- 'DECL_MAIN_P'
- This predicate holds for a function that is the program entry point
- '::code'.
-
- 'DECL_LOCAL_FUNCTION_P'
- This predicate holds if the function was declared at block scope,
- even though it has a global scope.
-
- 'DECL_ANTICIPATED'
- This predicate holds if the function is a built-in function but its
- prototype is not yet explicitly declared.
-
- 'DECL_EXTERN_C_FUNCTION_P'
- This predicate holds if the function is declared as an ''extern
- "C"'' function.
-
- 'DECL_LINKONCE_P'
- This macro holds if multiple copies of this function may be emitted
- in various translation units. It is the responsibility of the
- linker to merge the various copies. Template instantiations are
- the most common example of functions for which 'DECL_LINKONCE_P'
- holds; G++ instantiates needed templates in all translation units
- which require them, and then relies on the linker to remove
- duplicate instantiations.
-
- FIXME: This macro is not yet implemented.
-
- 'DECL_FUNCTION_MEMBER_P'
- This macro holds if the function is a member of a class, rather
- than a member of a namespace.
-
- 'DECL_STATIC_FUNCTION_P'
- This predicate holds if the function a static member function.
-
- 'DECL_NONSTATIC_MEMBER_FUNCTION_P'
- This macro holds for a non-static member function.
-
- 'DECL_CONST_MEMFUNC_P'
- This predicate holds for a 'const'-member function.
-
- 'DECL_VOLATILE_MEMFUNC_P'
- This predicate holds for a 'volatile'-member function.
-
- 'DECL_CONSTRUCTOR_P'
- This macro holds if the function is a constructor.
-
- 'DECL_NONCONVERTING_P'
- This predicate holds if the constructor is a non-converting
- constructor.
-
- 'DECL_COMPLETE_CONSTRUCTOR_P'
- This predicate holds for a function which is a constructor for an
- object of a complete type.
-
- 'DECL_BASE_CONSTRUCTOR_P'
- This predicate holds for a function which is a constructor for a
- base class sub-object.
-
- 'DECL_COPY_CONSTRUCTOR_P'
- This predicate holds for a function which is a copy-constructor.
-
- 'DECL_DESTRUCTOR_P'
- This macro holds if the function is a destructor.
-
- 'DECL_COMPLETE_DESTRUCTOR_P'
- This predicate holds if the function is the destructor for an
- object a complete type.
-
- 'DECL_OVERLOADED_OPERATOR_P'
- This macro holds if the function is an overloaded operator.
-
- 'DECL_CONV_FN_P'
- This macro holds if the function is a type-conversion operator.
-
- 'DECL_GLOBAL_CTOR_P'
- This predicate holds if the function is a file-scope initialization
- function.
-
- 'DECL_GLOBAL_DTOR_P'
- This predicate holds if the function is a file-scope finalization
- function.
-
- 'DECL_THUNK_P'
- This predicate holds if the function is a thunk.
-
- These functions represent stub code that adjusts the 'this' pointer
- and then jumps to another function. When the jumped-to function
- returns, control is transferred directly to the caller, without
- returning to the thunk. The first parameter to the thunk is always
- the 'this' pointer; the thunk should add 'THUNK_DELTA' to this
- value. (The 'THUNK_DELTA' is an 'int', not an 'INTEGER_CST'.)
-
- Then, if 'THUNK_VCALL_OFFSET' (an 'INTEGER_CST') is nonzero the
- adjusted 'this' pointer must be adjusted again. The complete
- calculation is given by the following pseudo-code:
-
- this += THUNK_DELTA
- if (THUNK_VCALL_OFFSET)
- this += (*((ptrdiff_t **) this))[THUNK_VCALL_OFFSET]
-
- Finally, the thunk should jump to the location given by
- 'DECL_INITIAL'; this will always be an expression for the address
- of a function.
-
- 'DECL_NON_THUNK_FUNCTION_P'
- This predicate holds if the function is _not_ a thunk function.
-
- 'GLOBAL_INIT_PRIORITY'
- If either 'DECL_GLOBAL_CTOR_P' or 'DECL_GLOBAL_DTOR_P' holds, then
- this gives the initialization priority for the function. The
- linker will arrange that all functions for which
- 'DECL_GLOBAL_CTOR_P' holds are run in increasing order of priority
- before 'main' is called. When the program exits, all functions for
- which 'DECL_GLOBAL_DTOR_P' holds are run in the reverse order.
-
- 'TYPE_RAISES_EXCEPTIONS'
- This macro returns the list of exceptions that a (member-)function
- can raise. The returned list, if non 'NULL', is comprised of nodes
- whose 'TREE_VALUE' represents a type.
-
- 'TYPE_NOTHROW_P'
- This predicate holds when the exception-specification of its
- arguments is of the form ''()''.
-
- 'DECL_ARRAY_DELETE_OPERATOR_P'
- This predicate holds if the function an overloaded 'operator
- delete[]'.
-
-
- File: gccint.info, Node: Statements for C++, Next: C++ Expressions, Prev: Functions for C++, Up: C and C++ Trees
-
- 11.10.5 Statements for C++
- --------------------------
-
- A function that has a definition in the current translation unit will
- have a non-'NULL' 'DECL_INITIAL'. However, back ends should not make
- use of the particular value given by 'DECL_INITIAL'.
-
- The 'DECL_SAVED_TREE' macro will give the complete body of the
- function.
-
- 11.10.5.1 Statements
- ....................
-
- There are tree nodes corresponding to all of the source-level statement
- constructs, used within the C and C++ frontends. These are enumerated
- here, together with a list of the various macros that can be used to
- obtain information about them. There are a few macros that can be used
- with all statements:
-
- 'STMT_IS_FULL_EXPR_P'
- In C++, statements normally constitute "full expressions";
- temporaries created during a statement are destroyed when the
- statement is complete. However, G++ sometimes represents
- expressions by statements; these statements will not have
- 'STMT_IS_FULL_EXPR_P' set. Temporaries created during such
- statements should be destroyed when the innermost enclosing
- statement with 'STMT_IS_FULL_EXPR_P' set is exited.
-
- Here is the list of the various statement nodes, and the macros used to
- access them. This documentation describes the use of these nodes in
- non-template functions (including instantiations of template functions).
- In template functions, the same nodes are used, but sometimes in
- slightly different ways.
-
- Many of the statements have substatements. For example, a 'while' loop
- will have a body, which is itself a statement. If the substatement is
- 'NULL_TREE', it is considered equivalent to a statement consisting of a
- single ';', i.e., an expression statement in which the expression has
- been omitted. A substatement may in fact be a list of statements,
- connected via their 'TREE_CHAIN's. So, you should always process the
- statement tree by looping over substatements, like this:
- void process_stmt (stmt)
- tree stmt;
- {
- while (stmt)
- {
- switch (TREE_CODE (stmt))
- {
- case IF_STMT:
- process_stmt (THEN_CLAUSE (stmt));
- /* More processing here. */
- break;
-
- ...
- }
-
- stmt = TREE_CHAIN (stmt);
- }
- }
- In other words, while the 'then' clause of an 'if' statement in C++ can
- be only one statement (although that one statement may be a compound
- statement), the intermediate representation will sometimes use several
- statements chained together.
-
- 'BREAK_STMT'
-
- Used to represent a 'break' statement. There are no additional
- fields.
-
- 'CLEANUP_STMT'
-
- Used to represent an action that should take place upon exit from
- the enclosing scope. Typically, these actions are calls to
- destructors for local objects, but back ends cannot rely on this
- fact. If these nodes are in fact representing such destructors,
- 'CLEANUP_DECL' will be the 'VAR_DECL' destroyed. Otherwise,
- 'CLEANUP_DECL' will be 'NULL_TREE'. In any case, the
- 'CLEANUP_EXPR' is the expression to execute. The cleanups executed
- on exit from a scope should be run in the reverse order of the
- order in which the associated 'CLEANUP_STMT's were encountered.
-
- 'CONTINUE_STMT'
-
- Used to represent a 'continue' statement. There are no additional
- fields.
-
- 'CTOR_STMT'
-
- Used to mark the beginning (if 'CTOR_BEGIN_P' holds) or end (if
- 'CTOR_END_P' holds of the main body of a constructor. See also
- 'SUBOBJECT' for more information on how to use these nodes.
-
- 'DO_STMT'
-
- Used to represent a 'do' loop. The body of the loop is given by
- 'DO_BODY' while the termination condition for the loop is given by
- 'DO_COND'. The condition for a 'do'-statement is always an
- expression.
-
- 'EMPTY_CLASS_EXPR'
-
- Used to represent a temporary object of a class with no data whose
- address is never taken. (All such objects are interchangeable.)
- The 'TREE_TYPE' represents the type of the object.
-
- 'EXPR_STMT'
-
- Used to represent an expression statement. Use 'EXPR_STMT_EXPR' to
- obtain the expression.
-
- 'FOR_STMT'
-
- Used to represent a 'for' statement. The 'FOR_INIT_STMT' is the
- initialization statement for the loop. The 'FOR_COND' is the
- termination condition. The 'FOR_EXPR' is the expression executed
- right before the 'FOR_COND' on each loop iteration; often, this
- expression increments a counter. The body of the loop is given by
- 'FOR_BODY'. Note that 'FOR_INIT_STMT' and 'FOR_BODY' return
- statements, while 'FOR_COND' and 'FOR_EXPR' return expressions.
-
- 'HANDLER'
-
- Used to represent a C++ 'catch' block. The 'HANDLER_TYPE' is the
- type of exception that will be caught by this handler; it is equal
- (by pointer equality) to 'NULL' if this handler is for all types.
- 'HANDLER_PARMS' is the 'DECL_STMT' for the catch parameter, and
- 'HANDLER_BODY' is the code for the block itself.
-
- 'IF_STMT'
-
- Used to represent an 'if' statement. The 'IF_COND' is the
- expression.
-
- If the condition is a 'TREE_LIST', then the 'TREE_PURPOSE' is a
- statement (usually a 'DECL_STMT'). Each time the condition is
- evaluated, the statement should be executed. Then, the
- 'TREE_VALUE' should be used as the conditional expression itself.
- This representation is used to handle C++ code like this:
-
- C++ distinguishes between this and 'COND_EXPR' for handling
- templates.
-
- if (int i = 7) ...
-
- where there is a new local variable (or variables) declared within
- the condition.
-
- The 'THEN_CLAUSE' represents the statement given by the 'then'
- condition, while the 'ELSE_CLAUSE' represents the statement given
- by the 'else' condition.
-
- 'SUBOBJECT'
-
- In a constructor, these nodes are used to mark the point at which a
- subobject of 'this' is fully constructed. If, after this point, an
- exception is thrown before a 'CTOR_STMT' with 'CTOR_END_P' set is
- encountered, the 'SUBOBJECT_CLEANUP' must be executed. The
- cleanups must be executed in the reverse order in which they
- appear.
-
- 'SWITCH_STMT'
-
- Used to represent a 'switch' statement. The 'SWITCH_STMT_COND' is
- the expression on which the switch is occurring. See the
- documentation for an 'IF_STMT' for more information on the
- representation used for the condition. The 'SWITCH_STMT_BODY' is
- the body of the switch statement. The 'SWITCH_STMT_TYPE' is the
- original type of switch expression as given in the source, before
- any compiler conversions.
-
- 'TRY_BLOCK'
- Used to represent a 'try' block. The body of the try block is
- given by 'TRY_STMTS'. Each of the catch blocks is a 'HANDLER'
- node. The first handler is given by 'TRY_HANDLERS'. Subsequent
- handlers are obtained by following the 'TREE_CHAIN' link from one
- handler to the next. The body of the handler is given by
- 'HANDLER_BODY'.
-
- If 'CLEANUP_P' holds of the 'TRY_BLOCK', then the 'TRY_HANDLERS'
- will not be a 'HANDLER' node. Instead, it will be an expression
- that should be executed if an exception is thrown in the try block.
- It must rethrow the exception after executing that code. And, if
- an exception is thrown while the expression is executing,
- 'terminate' must be called.
-
- 'USING_STMT'
- Used to represent a 'using' directive. The namespace is given by
- 'USING_STMT_NAMESPACE', which will be a NAMESPACE_DECL. This node
- is needed inside template functions, to implement using directives
- during instantiation.
-
- 'WHILE_STMT'
-
- Used to represent a 'while' loop. The 'WHILE_COND' is the
- termination condition for the loop. See the documentation for an
- 'IF_STMT' for more information on the representation used for the
- condition.
-
- The 'WHILE_BODY' is the body of the loop.
-
-
- File: gccint.info, Node: C++ Expressions, Prev: Statements for C++, Up: C and C++ Trees
-
- 11.10.6 C++ Expressions
- -----------------------
-
- This section describes expressions specific to the C and C++ front ends.
-
- 'TYPEID_EXPR'
-
- Used to represent a 'typeid' expression.
-
- 'NEW_EXPR'
- 'VEC_NEW_EXPR'
-
- Used to represent a call to 'new' and 'new[]' respectively.
-
- 'DELETE_EXPR'
- 'VEC_DELETE_EXPR'
-
- Used to represent a call to 'delete' and 'delete[]' respectively.
-
- 'MEMBER_REF'
-
- Represents a reference to a member of a class.
-
- 'THROW_EXPR'
-
- Represents an instance of 'throw' in the program. Operand 0, which
- is the expression to throw, may be 'NULL_TREE'.
-
- 'AGGR_INIT_EXPR'
- An 'AGGR_INIT_EXPR' represents the initialization as the return
- value of a function call, or as the result of a constructor. An
- 'AGGR_INIT_EXPR' will only appear as a full-expression, or as the
- second operand of a 'TARGET_EXPR'. 'AGGR_INIT_EXPR's have a
- representation similar to that of 'CALL_EXPR's. You can use the
- 'AGGR_INIT_EXPR_FN' and 'AGGR_INIT_EXPR_ARG' macros to access the
- function to call and the arguments to pass.
-
- If 'AGGR_INIT_VIA_CTOR_P' holds of the 'AGGR_INIT_EXPR', then the
- initialization is via a constructor call. The address of the
- 'AGGR_INIT_EXPR_SLOT' operand, which is always a 'VAR_DECL', is
- taken, and this value replaces the first argument in the argument
- list.
-
- In either case, the expression is void.
-
-
- File: gccint.info, Node: GIMPLE, Next: Tree SSA, Prev: GENERIC, Up: Top
-
- 12 GIMPLE
- *********
-
- GIMPLE is a three-address representation derived from GENERIC by
- breaking down GENERIC expressions into tuples of no more than 3 operands
- (with some exceptions like function calls). GIMPLE was heavily
- influenced by the SIMPLE IL used by the McCAT compiler project at McGill
- University, though we have made some different choices. For one thing,
- SIMPLE doesn't support 'goto'.
-
- Temporaries are introduced to hold intermediate values needed to
- compute complex expressions. Additionally, all the control structures
- used in GENERIC are lowered into conditional jumps, lexical scopes are
- removed and exception regions are converted into an on the side
- exception region tree.
-
- The compiler pass which converts GENERIC into GIMPLE is referred to as
- the 'gimplifier'. The gimplifier works recursively, generating GIMPLE
- tuples out of the original GENERIC expressions.
-
- One of the early implementation strategies used for the GIMPLE
- representation was to use the same internal data structures used by
- front ends to represent parse trees. This simplified implementation
- because we could leverage existing functionality and interfaces.
- However, GIMPLE is a much more restrictive representation than abstract
- syntax trees (AST), therefore it does not require the full structural
- complexity provided by the main tree data structure.
-
- The GENERIC representation of a function is stored in the
- 'DECL_SAVED_TREE' field of the associated 'FUNCTION_DECL' tree node. It
- is converted to GIMPLE by a call to 'gimplify_function_tree'.
-
- If a front end wants to include language-specific tree codes in the
- tree representation which it provides to the back end, it must provide a
- definition of 'LANG_HOOKS_GIMPLIFY_EXPR' which knows how to convert the
- front end trees to GIMPLE. Usually such a hook will involve much of the
- same code for expanding front end trees to RTL. This function can
- return fully lowered GIMPLE, or it can return GENERIC trees and let the
- main gimplifier lower them the rest of the way; this is often simpler.
- GIMPLE that is not fully lowered is known as "High GIMPLE" and consists
- of the IL before the pass 'pass_lower_cf'. High GIMPLE contains some
- container statements like lexical scopes (represented by 'GIMPLE_BIND')
- and nested expressions (e.g., 'GIMPLE_TRY'), while "Low GIMPLE" exposes
- all of the implicit jumps for control and exception expressions directly
- in the IL and EH region trees.
-
- The C and C++ front ends currently convert directly from front end
- trees to GIMPLE, and hand that off to the back end rather than first
- converting to GENERIC. Their gimplifier hooks know about all the
- '_STMT' nodes and how to convert them to GENERIC forms. There was some
- work done on a genericization pass which would run first, but the
- existence of 'STMT_EXPR' meant that in order to convert all of the C
- statements into GENERIC equivalents would involve walking the entire
- tree anyway, so it was simpler to lower all the way. This might change
- in the future if someone writes an optimization pass which would work
- better with higher-level trees, but currently the optimizers all expect
- GIMPLE.
-
- You can request to dump a C-like representation of the GIMPLE form with
- the flag '-fdump-tree-gimple'.
-
- * Menu:
-
- * Tuple representation::
- * Class hierarchy of GIMPLE statements::
- * GIMPLE instruction set::
- * GIMPLE Exception Handling::
- * Temporaries::
- * Operands::
- * Manipulating GIMPLE statements::
- * Tuple specific accessors::
- * GIMPLE sequences::
- * Sequence iterators::
- * Adding a new GIMPLE statement code::
- * Statement and operand traversals::
-
-
- File: gccint.info, Node: Tuple representation, Next: Class hierarchy of GIMPLE statements, Up: GIMPLE
-
- 12.1 Tuple representation
- =========================
-
- GIMPLE instructions are tuples of variable size divided in two groups: a
- header describing the instruction and its locations, and a variable
- length body with all the operands. Tuples are organized into a
- hierarchy with 3 main classes of tuples.
-
- 12.1.1 'gimple' (gsbase)
- ------------------------
-
- This is the root of the hierarchy, it holds basic information needed by
- most GIMPLE statements. There are some fields that may not be relevant
- to every GIMPLE statement, but those were moved into the base structure
- to take advantage of holes left by other fields (thus making the
- structure more compact). The structure takes 4 words (32 bytes) on 64
- bit hosts:
-
- Field Size (bits)
- 'code' 8
- 'subcode' 16
- 'no_warning' 1
- 'visited' 1
- 'nontemporal_move' 1
- 'plf' 2
- 'modified' 1
- 'has_volatile_ops' 1
- 'references_memory_p' 1
- 'uid' 32
- 'location' 32
- 'num_ops' 32
- 'bb' 64
- 'block' 63
- Total size 32 bytes
-
- * 'code' Main identifier for a GIMPLE instruction.
-
- * 'subcode' Used to distinguish different variants of the same basic
- instruction or provide flags applicable to a given code. The
- 'subcode' flags field has different uses depending on the code of
- the instruction, but mostly it distinguishes instructions of the
- same family. The most prominent use of this field is in
- assignments, where subcode indicates the operation done on the RHS
- of the assignment. For example, a = b + c is encoded as
- 'GIMPLE_ASSIGN <PLUS_EXPR, a, b, c>'.
-
- * 'no_warning' Bitflag to indicate whether a warning has already been
- issued on this statement.
-
- * 'visited' General purpose "visited" marker. Set and cleared by
- each pass when needed.
-
- * 'nontemporal_move' Bitflag used in assignments that represent
- non-temporal moves. Although this bitflag is only used in
- assignments, it was moved into the base to take advantage of the
- bit holes left by the previous fields.
-
- * 'plf' Pass Local Flags. This 2-bit mask can be used as general
- purpose markers by any pass. Passes are responsible for clearing
- and setting these two flags accordingly.
-
- * 'modified' Bitflag to indicate whether the statement has been
- modified. Used mainly by the operand scanner to determine when to
- re-scan a statement for operands.
-
- * 'has_volatile_ops' Bitflag to indicate whether this statement
- contains operands that have been marked volatile.
-
- * 'references_memory_p' Bitflag to indicate whether this statement
- contains memory references (i.e., its operands are either global
- variables, or pointer dereferences or anything that must reside in
- memory).
-
- * 'uid' This is an unsigned integer used by passes that want to
- assign IDs to every statement. These IDs must be assigned and used
- by each pass.
-
- * 'location' This is a 'location_t' identifier to specify source code
- location for this statement. It is inherited from the front end.
-
- * 'num_ops' Number of operands that this statement has. This
- specifies the size of the operand vector embedded in the tuple.
- Only used in some tuples, but it is declared in the base tuple to
- take advantage of the 32-bit hole left by the previous fields.
-
- * 'bb' Basic block holding the instruction.
-
- * 'block' Lexical block holding this statement. Also used for debug
- information generation.
-
- 12.1.2 'gimple_statement_with_ops'
- ----------------------------------
-
- This tuple is actually split in two: 'gimple_statement_with_ops_base'
- and 'gimple_statement_with_ops'. This is needed to accommodate the way
- the operand vector is allocated. The operand vector is defined to be an
- array of 1 element. So, to allocate a dynamic number of operands, the
- memory allocator ('gimple_alloc') simply allocates enough memory to hold
- the structure itself plus 'N - 1' operands which run "off the end" of
- the structure. For example, to allocate space for a tuple with 3
- operands, 'gimple_alloc' reserves 'sizeof (struct
- gimple_statement_with_ops) + 2 * sizeof (tree)' bytes.
-
- On the other hand, several fields in this tuple need to be shared with
- the 'gimple_statement_with_memory_ops' tuple. So, these common fields
- are placed in 'gimple_statement_with_ops_base' which is then inherited
- from the other two tuples.
-
- 'gsbase' 256
- 'def_ops' 64
- 'use_ops' 64
- 'op' 'num_ops' * 64
- Total 48 + 8 * 'num_ops' bytes
- size
-
- * 'gsbase' Inherited from 'struct gimple'.
-
- * 'def_ops' Array of pointers into the operand array indicating all
- the slots that contain a variable written-to by the statement.
- This array is also used for immediate use chaining. Note that it
- would be possible to not rely on this array, but the changes
- required to implement this are pretty invasive.
-
- * 'use_ops' Similar to 'def_ops' but for variables read by the
- statement.
-
- * 'op' Array of trees with 'num_ops' slots.
-
- 12.1.3 'gimple_statement_with_memory_ops'
- -----------------------------------------
-
- This tuple is essentially identical to 'gimple_statement_with_ops',
- except that it contains 4 additional fields to hold vectors related
- memory stores and loads. Similar to the previous case, the structure is
- split in two to accommodate for the operand vector
- ('gimple_statement_with_memory_ops_base' and
- 'gimple_statement_with_memory_ops').
-
- Field Size (bits)
- 'gsbase' 256
- 'def_ops' 64
- 'use_ops' 64
- 'vdef_ops' 64
- 'vuse_ops' 64
- 'stores' 64
- 'loads' 64
- 'op' 'num_ops' * 64
- Total size 80 + 8 * 'num_ops' bytes
-
- * 'vdef_ops' Similar to 'def_ops' but for 'VDEF' operators. There is
- one entry per memory symbol written by this statement. This is
- used to maintain the memory SSA use-def and def-def chains.
-
- * 'vuse_ops' Similar to 'use_ops' but for 'VUSE' operators. There is
- one entry per memory symbol loaded by this statement. This is used
- to maintain the memory SSA use-def chains.
-
- * 'stores' Bitset with all the UIDs for the symbols written-to by the
- statement. This is different than 'vdef_ops' in that all the
- affected symbols are mentioned in this set. If memory partitioning
- is enabled, the 'vdef_ops' vector will refer to memory partitions.
- Furthermore, no SSA information is stored in this set.
-
- * 'loads' Similar to 'stores', but for memory loads. (Note that
- there is some amount of redundancy here, it should be possible to
- reduce memory utilization further by removing these sets).
-
- All the other tuples are defined in terms of these three basic ones.
- Each tuple will add some fields.
-
-
- File: gccint.info, Node: Class hierarchy of GIMPLE statements, Next: GIMPLE instruction set, Prev: Tuple representation, Up: GIMPLE
-
- 12.2 Class hierarchy of GIMPLE statements
- =========================================
-
- The following diagram shows the C++ inheritance hierarchy of statement
- kinds, along with their relationships to 'GSS_' values (layouts) and
- 'GIMPLE_' values (codes):
-
- gimple
- | layout: GSS_BASE
- | used for 4 codes: GIMPLE_ERROR_MARK
- | GIMPLE_NOP
- | GIMPLE_OMP_SECTIONS_SWITCH
- | GIMPLE_PREDICT
- |
- + gimple_statement_with_ops_base
- | | (no GSS layout)
- | |
- | + gimple_statement_with_ops
- | | | layout: GSS_WITH_OPS
- | | |
- | | + gcond
- | | | code: GIMPLE_COND
- | | |
- | | + gdebug
- | | | code: GIMPLE_DEBUG
- | | |
- | | + ggoto
- | | | code: GIMPLE_GOTO
- | | |
- | | + glabel
- | | | code: GIMPLE_LABEL
- | | |
- | | + gswitch
- | | code: GIMPLE_SWITCH
- | |
- | + gimple_statement_with_memory_ops_base
- | | layout: GSS_WITH_MEM_OPS_BASE
- | |
- | + gimple_statement_with_memory_ops
- | | | layout: GSS_WITH_MEM_OPS
- | | |
- | | + gassign
- | | | code GIMPLE_ASSIGN
- | | |
- | | + greturn
- | | code GIMPLE_RETURN
- | |
- | + gcall
- | | layout: GSS_CALL, code: GIMPLE_CALL
- | |
- | + gasm
- | | layout: GSS_ASM, code: GIMPLE_ASM
- | |
- | + gtransaction
- | layout: GSS_TRANSACTION, code: GIMPLE_TRANSACTION
- |
- + gimple_statement_omp
- | | layout: GSS_OMP. Used for code GIMPLE_OMP_SECTION
- | |
- | + gomp_critical
- | | layout: GSS_OMP_CRITICAL, code: GIMPLE_OMP_CRITICAL
- | |
- | + gomp_for
- | | layout: GSS_OMP_FOR, code: GIMPLE_OMP_FOR
- | |
- | + gomp_parallel_layout
- | | | layout: GSS_OMP_PARALLEL_LAYOUT
- | | |
- | | + gimple_statement_omp_taskreg
- | | | |
- | | | + gomp_parallel
- | | | | code: GIMPLE_OMP_PARALLEL
- | | | |
- | | | + gomp_task
- | | | code: GIMPLE_OMP_TASK
- | | |
- | | + gimple_statement_omp_target
- | | code: GIMPLE_OMP_TARGET
- | |
- | + gomp_sections
- | | layout: GSS_OMP_SECTIONS, code: GIMPLE_OMP_SECTIONS
- | |
- | + gimple_statement_omp_single_layout
- | | layout: GSS_OMP_SINGLE_LAYOUT
- | |
- | + gomp_single
- | | code: GIMPLE_OMP_SINGLE
- | |
- | + gomp_teams
- | code: GIMPLE_OMP_TEAMS
- |
- + gbind
- | layout: GSS_BIND, code: GIMPLE_BIND
- |
- + gcatch
- | layout: GSS_CATCH, code: GIMPLE_CATCH
- |
- + geh_filter
- | layout: GSS_EH_FILTER, code: GIMPLE_EH_FILTER
- |
- + geh_else
- | layout: GSS_EH_ELSE, code: GIMPLE_EH_ELSE
- |
- + geh_mnt
- | layout: GSS_EH_MNT, code: GIMPLE_EH_MUST_NOT_THROW
- |
- + gphi
- | layout: GSS_PHI, code: GIMPLE_PHI
- |
- + gimple_statement_eh_ctrl
- | | layout: GSS_EH_CTRL
- | |
- | + gresx
- | | code: GIMPLE_RESX
- | |
- | + geh_dispatch
- | code: GIMPLE_EH_DISPATCH
- |
- + gtry
- | layout: GSS_TRY, code: GIMPLE_TRY
- |
- + gimple_statement_wce
- | layout: GSS_WCE, code: GIMPLE_WITH_CLEANUP_EXPR
- |
- + gomp_continue
- | layout: GSS_OMP_CONTINUE, code: GIMPLE_OMP_CONTINUE
- |
- + gomp_atomic_load
- | layout: GSS_OMP_ATOMIC_LOAD, code: GIMPLE_OMP_ATOMIC_LOAD
- |
- + gimple_statement_omp_atomic_store_layout
- | layout: GSS_OMP_ATOMIC_STORE_LAYOUT,
- | code: GIMPLE_OMP_ATOMIC_STORE
- |
- + gomp_atomic_store
- | code: GIMPLE_OMP_ATOMIC_STORE
- |
- + gomp_return
- code: GIMPLE_OMP_RETURN
-
-
- File: gccint.info, Node: GIMPLE instruction set, Next: GIMPLE Exception Handling, Prev: Class hierarchy of GIMPLE statements, Up: GIMPLE
-
- 12.3 GIMPLE instruction set
- ===========================
-
- The following table briefly describes the GIMPLE instruction set.
-
- Instruction High GIMPLE Low GIMPLE
- 'GIMPLE_ASM' x x
- 'GIMPLE_ASSIGN' x x
- 'GIMPLE_BIND' x
- 'GIMPLE_CALL' x x
- 'GIMPLE_CATCH' x
- 'GIMPLE_COND' x x
- 'GIMPLE_DEBUG' x x
- 'GIMPLE_EH_FILTER' x
- 'GIMPLE_GOTO' x x
- 'GIMPLE_LABEL' x x
- 'GIMPLE_NOP' x x
- 'GIMPLE_OMP_ATOMIC_LOAD' x x
- 'GIMPLE_OMP_ATOMIC_STORE' x x
- 'GIMPLE_OMP_CONTINUE' x x
- 'GIMPLE_OMP_CRITICAL' x x
- 'GIMPLE_OMP_FOR' x x
- 'GIMPLE_OMP_MASTER' x x
- 'GIMPLE_OMP_ORDERED' x x
- 'GIMPLE_OMP_PARALLEL' x x
- 'GIMPLE_OMP_RETURN' x x
- 'GIMPLE_OMP_SECTION' x x
- 'GIMPLE_OMP_SECTIONS' x x
- 'GIMPLE_OMP_SECTIONS_SWITCH' x x
- 'GIMPLE_OMP_SINGLE' x x
- 'GIMPLE_PHI' x
- 'GIMPLE_RESX' x
- 'GIMPLE_RETURN' x x
- 'GIMPLE_SWITCH' x x
- 'GIMPLE_TRY' x
-
-
- File: gccint.info, Node: GIMPLE Exception Handling, Next: Temporaries, Prev: GIMPLE instruction set, Up: GIMPLE
-
- 12.4 Exception Handling
- =======================
-
- Other exception handling constructs are represented using
- 'GIMPLE_TRY_CATCH'. 'GIMPLE_TRY_CATCH' has two operands. The first
- operand is a sequence of statements to execute. If executing these
- statements does not throw an exception, then the second operand is
- ignored. Otherwise, if an exception is thrown, then the second operand
- of the 'GIMPLE_TRY_CATCH' is checked. The second operand may have the
- following forms:
-
- 1. A sequence of statements to execute. When an exception occurs,
- these statements are executed, and then the exception is rethrown.
-
- 2. A sequence of 'GIMPLE_CATCH' statements. Each 'GIMPLE_CATCH' has a
- list of applicable exception types and handler code. If the thrown
- exception matches one of the caught types, the associated handler
- code is executed. If the handler code falls off the bottom,
- execution continues after the original 'GIMPLE_TRY_CATCH'.
-
- 3. A 'GIMPLE_EH_FILTER' statement. This has a list of permitted
- exception types, and code to handle a match failure. If the thrown
- exception does not match one of the allowed types, the associated
- match failure code is executed. If the thrown exception does
- match, it continues unwinding the stack looking for the next
- handler.
-
- Currently throwing an exception is not directly represented in GIMPLE,
- since it is implemented by calling a function. At some point in the
- future we will want to add some way to express that the call will throw
- an exception of a known type.
-
- Just before running the optimizers, the compiler lowers the high-level
- EH constructs above into a set of 'goto's, magic labels, and EH regions.
- Continuing to unwind at the end of a cleanup is represented with a
- 'GIMPLE_RESX'.
-
-
- File: gccint.info, Node: Temporaries, Next: Operands, Prev: GIMPLE Exception Handling, Up: GIMPLE
-
- 12.5 Temporaries
- ================
-
- When gimplification encounters a subexpression that is too complex, it
- creates a new temporary variable to hold the value of the subexpression,
- and adds a new statement to initialize it before the current statement.
- These special temporaries are known as 'expression temporaries', and are
- allocated using 'get_formal_tmp_var'. The compiler tries to always
- evaluate identical expressions into the same temporary, to simplify
- elimination of redundant calculations.
-
- We can only use expression temporaries when we know that it will not be
- reevaluated before its value is used, and that it will not be otherwise
- modified(1). Other temporaries can be allocated using
- 'get_initialized_tmp_var' or 'create_tmp_var'.
-
- Currently, an expression like 'a = b + 5' is not reduced any further.
- We tried converting it to something like
- T1 = b + 5;
- a = T1;
- but this bloated the representation for minimal benefit. However, a
- variable which must live in memory cannot appear in an expression; its
- value is explicitly loaded into a temporary first. Similarly, storing
- the value of an expression to a memory variable goes through a
- temporary.
-
- ---------- Footnotes ----------
-
- (1) These restrictions are derived from those in Morgan 4.8.
-
-
- File: gccint.info, Node: Operands, Next: Manipulating GIMPLE statements, Prev: Temporaries, Up: GIMPLE
-
- 12.6 Operands
- =============
-
- In general, expressions in GIMPLE consist of an operation and the
- appropriate number of simple operands; these operands must either be a
- GIMPLE rvalue ('is_gimple_val'), i.e. a constant or a register variable.
- More complex operands are factored out into temporaries, so that
- a = b + c + d
- becomes
- T1 = b + c;
- a = T1 + d;
-
- The same rule holds for arguments to a 'GIMPLE_CALL'.
-
- The target of an assignment is usually a variable, but can also be a
- 'MEM_REF' or a compound lvalue as described below.
-
- * Menu:
-
- * Compound Expressions::
- * Compound Lvalues::
- * Conditional Expressions::
- * Logical Operators::
-
-
- File: gccint.info, Node: Compound Expressions, Next: Compound Lvalues, Up: Operands
-
- 12.6.1 Compound Expressions
- ---------------------------
-
- The left-hand side of a C comma expression is simply moved into a
- separate statement.
-
-
- File: gccint.info, Node: Compound Lvalues, Next: Conditional Expressions, Prev: Compound Expressions, Up: Operands
-
- 12.6.2 Compound Lvalues
- -----------------------
-
- Currently compound lvalues involving array and structure field
- references are not broken down; an expression like 'a.b[2] = 42' is not
- reduced any further (though complex array subscripts are). This
- restriction is a workaround for limitations in later optimizers; if we
- were to convert this to
-
- T1 = &a.b;
- T1[2] = 42;
-
- alias analysis would not remember that the reference to 'T1[2]' came by
- way of 'a.b', so it would think that the assignment could alias another
- member of 'a'; this broke 'struct-alias-1.c'. Future optimizer
- improvements may make this limitation unnecessary.
-
-
- File: gccint.info, Node: Conditional Expressions, Next: Logical Operators, Prev: Compound Lvalues, Up: Operands
-
- 12.6.3 Conditional Expressions
- ------------------------------
-
- A C '?:' expression is converted into an 'if' statement with each branch
- assigning to the same temporary. So,
-
- a = b ? c : d;
- becomes
- if (b == 1)
- T1 = c;
- else
- T1 = d;
- a = T1;
-
- The GIMPLE level if-conversion pass re-introduces '?:' expression, if
- appropriate. It is used to vectorize loops with conditions using vector
- conditional operations.
-
- Note that in GIMPLE, 'if' statements are represented using
- 'GIMPLE_COND', as described below.
-
-
- File: gccint.info, Node: Logical Operators, Prev: Conditional Expressions, Up: Operands
-
- 12.6.4 Logical Operators
- ------------------------
-
- Except when they appear in the condition operand of a 'GIMPLE_COND',
- logical 'and' and 'or' operators are simplified as follows: 'a = b && c'
- becomes
-
- T1 = (bool)b;
- if (T1 == true)
- T1 = (bool)c;
- a = T1;
-
- Note that 'T1' in this example cannot be an expression temporary,
- because it has two different assignments.
-
- 12.6.5 Manipulating operands
- ----------------------------
-
- All gimple operands are of type 'tree'. But only certain types of trees
- are allowed to be used as operand tuples. Basic validation is
- controlled by the function 'get_gimple_rhs_class', which given a tree
- code, returns an 'enum' with the following values of type 'enum
- gimple_rhs_class'
-
- * 'GIMPLE_INVALID_RHS' The tree cannot be used as a GIMPLE operand.
-
- * 'GIMPLE_TERNARY_RHS' The tree is a valid GIMPLE ternary operation.
-
- * 'GIMPLE_BINARY_RHS' The tree is a valid GIMPLE binary operation.
-
- * 'GIMPLE_UNARY_RHS' The tree is a valid GIMPLE unary operation.
-
- * 'GIMPLE_SINGLE_RHS' The tree is a single object, that cannot be
- split into simpler operands (for instance, 'SSA_NAME', 'VAR_DECL',
- 'COMPONENT_REF', etc).
-
- This operand class also acts as an escape hatch for tree nodes that
- may be flattened out into the operand vector, but would need more
- than two slots on the RHS. For instance, a 'COND_EXPR' expression
- of the form '(a op b) ? x : y' could be flattened out on the
- operand vector using 4 slots, but it would also require additional
- processing to distinguish 'c = a op b' from 'c = a op b ? x : y'.
- Something similar occurs with 'ASSERT_EXPR'. In time, these
- special case tree expressions should be flattened into the operand
- vector.
-
- For tree nodes in the categories 'GIMPLE_TERNARY_RHS',
- 'GIMPLE_BINARY_RHS' and 'GIMPLE_UNARY_RHS', they cannot be stored inside
- tuples directly. They first need to be flattened and separated into
- individual components. For instance, given the GENERIC expression
-
- a = b + c
-
- its tree representation is:
-
- MODIFY_EXPR <VAR_DECL <a>, PLUS_EXPR <VAR_DECL <b>, VAR_DECL <c>>>
-
- In this case, the GIMPLE form for this statement is logically identical
- to its GENERIC form but in GIMPLE, the 'PLUS_EXPR' on the RHS of the
- assignment is not represented as a tree, instead the two operands are
- taken out of the 'PLUS_EXPR' sub-tree and flattened into the GIMPLE
- tuple as follows:
-
- GIMPLE_ASSIGN <PLUS_EXPR, VAR_DECL <a>, VAR_DECL <b>, VAR_DECL <c>>
-
- 12.6.6 Operand vector allocation
- --------------------------------
-
- The operand vector is stored at the bottom of the three tuple structures
- that accept operands. This means, that depending on the code of a given
- statement, its operand vector will be at different offsets from the base
- of the structure. To access tuple operands use the following accessors
-
- -- GIMPLE function: unsigned gimple_num_ops (gimple g)
- Returns the number of operands in statement G.
-
- -- GIMPLE function: tree gimple_op (gimple g, unsigned i)
- Returns operand 'I' from statement 'G'.
-
- -- GIMPLE function: tree * gimple_ops (gimple g)
- Returns a pointer into the operand vector for statement 'G'. This
- is computed using an internal table called 'gimple_ops_offset_'[].
- This table is indexed by the gimple code of 'G'.
-
- When the compiler is built, this table is filled-in using the sizes
- of the structures used by each statement code defined in
- gimple.def. Since the operand vector is at the bottom of the
- structure, for a gimple code 'C' the offset is computed as sizeof
- (struct-of 'C') - sizeof (tree).
-
- This mechanism adds one memory indirection to every access when
- using 'gimple_op'(), if this becomes a bottleneck, a pass can
- choose to memoize the result from 'gimple_ops'() and use that to
- access the operands.
-
- 12.6.7 Operand validation
- -------------------------
-
- When adding a new operand to a gimple statement, the operand will be
- validated according to what each tuple accepts in its operand vector.
- These predicates are called by the 'gimple_NAME_set_...()'. Each tuple
- will use one of the following predicates (Note, this list is not
- exhaustive):
-
- -- GIMPLE function: bool is_gimple_val (tree t)
- Returns true if t is a "GIMPLE value", which are all the
- non-addressable stack variables (variables for which
- 'is_gimple_reg' returns true) and constants (expressions for which
- 'is_gimple_min_invariant' returns true).
-
- -- GIMPLE function: bool is_gimple_addressable (tree t)
- Returns true if t is a symbol or memory reference whose address can
- be taken.
-
- -- GIMPLE function: bool is_gimple_asm_val (tree t)
- Similar to 'is_gimple_val' but it also accepts hard registers.
-
- -- GIMPLE function: bool is_gimple_call_addr (tree t)
- Return true if t is a valid expression to use as the function
- called by a 'GIMPLE_CALL'.
-
- -- GIMPLE function: bool is_gimple_mem_ref_addr (tree t)
- Return true if t is a valid expression to use as first operand of a
- 'MEM_REF' expression.
-
- -- GIMPLE function: bool is_gimple_constant (tree t)
- Return true if t is a valid gimple constant.
-
- -- GIMPLE function: bool is_gimple_min_invariant (tree t)
- Return true if t is a valid minimal invariant. This is different
- from constants, in that the specific value of t may not be known at
- compile time, but it is known that it doesn't change (e.g., the
- address of a function local variable).
-
- -- GIMPLE function: bool is_gimple_ip_invariant (tree t)
- Return true if t is an interprocedural invariant. This means that
- t is a valid invariant in all functions (e.g. it can be an address
- of a global variable but not of a local one).
-
- -- GIMPLE function: bool is_gimple_ip_invariant_address (tree t)
- Return true if t is an 'ADDR_EXPR' that does not change once the
- program is running (and which is valid in all functions).
-
- 12.6.8 Statement validation
- ---------------------------
-
- -- GIMPLE function: bool is_gimple_assign (gimple g)
- Return true if the code of g is 'GIMPLE_ASSIGN'.
-
- -- GIMPLE function: bool is_gimple_call (gimple g)
- Return true if the code of g is 'GIMPLE_CALL'.
-
- -- GIMPLE function: bool is_gimple_debug (gimple g)
- Return true if the code of g is 'GIMPLE_DEBUG'.
-
- -- GIMPLE function: bool gimple_assign_cast_p (const_gimple g)
- Return true if g is a 'GIMPLE_ASSIGN' that performs a type cast
- operation.
-
- -- GIMPLE function: bool gimple_debug_bind_p (gimple g)
- Return true if g is a 'GIMPLE_DEBUG' that binds the value of an
- expression to a variable.
-
- -- GIMPLE function: bool is_gimple_omp (gimple g)
- Return true if g is any of the OpenMP codes.
-
- -- GIMPLE function: gimple_debug_begin_stmt_p (gimple g)
- Return true if g is a 'GIMPLE_DEBUG' that marks the beginning of a
- source statement.
-
- -- GIMPLE function: gimple_debug_inline_entry_p (gimple g)
- Return true if g is a 'GIMPLE_DEBUG' that marks the entry point of
- an inlined function.
-
- -- GIMPLE function: gimple_debug_nonbind_marker_p (gimple g)
- Return true if g is a 'GIMPLE_DEBUG' that marks a program location,
- without any variable binding.
-
-
- File: gccint.info, Node: Manipulating GIMPLE statements, Next: Tuple specific accessors, Prev: Operands, Up: GIMPLE
-
- 12.7 Manipulating GIMPLE statements
- ===================================
-
- This section documents all the functions available to handle each of the
- GIMPLE instructions.
-
- 12.7.1 Common accessors
- -----------------------
-
- The following are common accessors for gimple statements.
-
- -- GIMPLE function: enum gimple_code gimple_code (gimple g)
- Return the code for statement 'G'.
-
- -- GIMPLE function: basic_block gimple_bb (gimple g)
- Return the basic block to which statement 'G' belongs to.
-
- -- GIMPLE function: tree gimple_block (gimple g)
- Return the lexical scope block holding statement 'G'.
-
- -- GIMPLE function: tree gimple_expr_type (gimple stmt)
- Return the type of the main expression computed by 'STMT'. Return
- 'void_type_node' if 'STMT' computes nothing. This will only return
- something meaningful for 'GIMPLE_ASSIGN', 'GIMPLE_COND' and
- 'GIMPLE_CALL'. For all other tuple codes, it will return
- 'void_type_node'.
-
- -- GIMPLE function: enum tree_code gimple_expr_code (gimple stmt)
- Return the tree code for the expression computed by 'STMT'. This
- is only meaningful for 'GIMPLE_CALL', 'GIMPLE_ASSIGN' and
- 'GIMPLE_COND'. If 'STMT' is 'GIMPLE_CALL', it will return
- 'CALL_EXPR'. For 'GIMPLE_COND', it returns the code of the
- comparison predicate. For 'GIMPLE_ASSIGN' it returns the code of
- the operation performed by the 'RHS' of the assignment.
-
- -- GIMPLE function: void gimple_set_block (gimple g, tree block)
- Set the lexical scope block of 'G' to 'BLOCK'.
-
- -- GIMPLE function: location_t gimple_locus (gimple g)
- Return locus information for statement 'G'.
-
- -- GIMPLE function: void gimple_set_locus (gimple g, location_t locus)
- Set locus information for statement 'G'.
-
- -- GIMPLE function: bool gimple_locus_empty_p (gimple g)
- Return true if 'G' does not have locus information.
-
- -- GIMPLE function: bool gimple_no_warning_p (gimple stmt)
- Return true if no warnings should be emitted for statement 'STMT'.
-
- -- GIMPLE function: void gimple_set_visited (gimple stmt, bool
- visited_p)
- Set the visited status on statement 'STMT' to 'VISITED_P'.
-
- -- GIMPLE function: bool gimple_visited_p (gimple stmt)
- Return the visited status on statement 'STMT'.
-
- -- GIMPLE function: void gimple_set_plf (gimple stmt, enum plf_mask
- plf, bool val_p)
- Set pass local flag 'PLF' on statement 'STMT' to 'VAL_P'.
-
- -- GIMPLE function: unsigned int gimple_plf (gimple stmt, enum plf_mask
- plf)
- Return the value of pass local flag 'PLF' on statement 'STMT'.
-
- -- GIMPLE function: bool gimple_has_ops (gimple g)
- Return true if statement 'G' has register or memory operands.
-
- -- GIMPLE function: bool gimple_has_mem_ops (gimple g)
- Return true if statement 'G' has memory operands.
-
- -- GIMPLE function: unsigned gimple_num_ops (gimple g)
- Return the number of operands for statement 'G'.
-
- -- GIMPLE function: tree * gimple_ops (gimple g)
- Return the array of operands for statement 'G'.
-
- -- GIMPLE function: tree gimple_op (gimple g, unsigned i)
- Return operand 'I' for statement 'G'.
-
- -- GIMPLE function: tree * gimple_op_ptr (gimple g, unsigned i)
- Return a pointer to operand 'I' for statement 'G'.
-
- -- GIMPLE function: void gimple_set_op (gimple g, unsigned i, tree op)
- Set operand 'I' of statement 'G' to 'OP'.
-
- -- GIMPLE function: bitmap gimple_addresses_taken (gimple stmt)
- Return the set of symbols that have had their address taken by
- 'STMT'.
-
- -- GIMPLE function: struct def_optype_d * gimple_def_ops (gimple g)
- Return the set of 'DEF' operands for statement 'G'.
-
- -- GIMPLE function: void gimple_set_def_ops (gimple g, struct
- def_optype_d *def)
- Set 'DEF' to be the set of 'DEF' operands for statement 'G'.
-
- -- GIMPLE function: struct use_optype_d * gimple_use_ops (gimple g)
- Return the set of 'USE' operands for statement 'G'.
-
- -- GIMPLE function: void gimple_set_use_ops (gimple g, struct
- use_optype_d *use)
- Set 'USE' to be the set of 'USE' operands for statement 'G'.
-
- -- GIMPLE function: struct voptype_d * gimple_vuse_ops (gimple g)
- Return the set of 'VUSE' operands for statement 'G'.
-
- -- GIMPLE function: void gimple_set_vuse_ops (gimple g, struct
- voptype_d *ops)
- Set 'OPS' to be the set of 'VUSE' operands for statement 'G'.
-
- -- GIMPLE function: struct voptype_d * gimple_vdef_ops (gimple g)
- Return the set of 'VDEF' operands for statement 'G'.
-
- -- GIMPLE function: void gimple_set_vdef_ops (gimple g, struct
- voptype_d *ops)
- Set 'OPS' to be the set of 'VDEF' operands for statement 'G'.
-
- -- GIMPLE function: bitmap gimple_loaded_syms (gimple g)
- Return the set of symbols loaded by statement 'G'. Each element of
- the set is the 'DECL_UID' of the corresponding symbol.
-
- -- GIMPLE function: bitmap gimple_stored_syms (gimple g)
- Return the set of symbols stored by statement 'G'. Each element of
- the set is the 'DECL_UID' of the corresponding symbol.
-
- -- GIMPLE function: bool gimple_modified_p (gimple g)
- Return true if statement 'G' has operands and the modified field
- has been set.
-
- -- GIMPLE function: bool gimple_has_volatile_ops (gimple stmt)
- Return true if statement 'STMT' contains volatile operands.
-
- -- GIMPLE function: void gimple_set_has_volatile_ops (gimple stmt, bool
- volatilep)
- Return true if statement 'STMT' contains volatile operands.
-
- -- GIMPLE function: void update_stmt (gimple s)
- Mark statement 'S' as modified, and update it.
-
- -- GIMPLE function: void update_stmt_if_modified (gimple s)
- Update statement 'S' if it has been marked modified.
-
- -- GIMPLE function: gimple gimple_copy (gimple stmt)
- Return a deep copy of statement 'STMT'.
-
-
- File: gccint.info, Node: Tuple specific accessors, Next: GIMPLE sequences, Prev: Manipulating GIMPLE statements, Up: GIMPLE
-
- 12.8 Tuple specific accessors
- =============================
-
- * Menu:
-
- * GIMPLE_ASM::
- * GIMPLE_ASSIGN::
- * GIMPLE_BIND::
- * GIMPLE_CALL::
- * GIMPLE_CATCH::
- * GIMPLE_COND::
- * GIMPLE_DEBUG::
- * GIMPLE_EH_FILTER::
- * GIMPLE_LABEL::
- * GIMPLE_GOTO::
- * GIMPLE_NOP::
- * GIMPLE_OMP_ATOMIC_LOAD::
- * GIMPLE_OMP_ATOMIC_STORE::
- * GIMPLE_OMP_CONTINUE::
- * GIMPLE_OMP_CRITICAL::
- * GIMPLE_OMP_FOR::
- * GIMPLE_OMP_MASTER::
- * GIMPLE_OMP_ORDERED::
- * GIMPLE_OMP_PARALLEL::
- * GIMPLE_OMP_RETURN::
- * GIMPLE_OMP_SECTION::
- * GIMPLE_OMP_SECTIONS::
- * GIMPLE_OMP_SINGLE::
- * GIMPLE_PHI::
- * GIMPLE_RESX::
- * GIMPLE_RETURN::
- * GIMPLE_SWITCH::
- * GIMPLE_TRY::
- * GIMPLE_WITH_CLEANUP_EXPR::
-
-
- File: gccint.info, Node: GIMPLE_ASM, Next: GIMPLE_ASSIGN, Up: Tuple specific accessors
-
- 12.8.1 'GIMPLE_ASM'
- -------------------
-
- -- GIMPLE function: gasm *gimple_build_asm_vec ( const char *string,
- vec<tree, va_gc> *inputs, vec<tree, va_gc> *outputs, vec<tree,
- va_gc> *clobbers, vec<tree, va_gc> *labels)
- Build a 'GIMPLE_ASM' statement. This statement is used for
- building in-line assembly constructs. 'STRING' is the assembly
- code. 'INPUTS', 'OUTPUTS', 'CLOBBERS' and 'LABELS' are the inputs,
- outputs, clobbered registers and labels.
-
- -- GIMPLE function: unsigned gimple_asm_ninputs (const gasm *g)
- Return the number of input operands for 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: unsigned gimple_asm_noutputs (const gasm *g)
- Return the number of output operands for 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: unsigned gimple_asm_nclobbers (const gasm *g)
- Return the number of clobber operands for 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: tree gimple_asm_input_op (const gasm *g, unsigned
- index)
- Return input operand 'INDEX' of 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: void gimple_asm_set_input_op (gasm *g, unsigned
- index, tree in_op)
- Set 'IN_OP' to be input operand 'INDEX' in 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: tree gimple_asm_output_op (const gasm *g, unsigned
- index)
- Return output operand 'INDEX' of 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: void gimple_asm_set_output_op (gasm *g, unsigned
- index, tree out_op)
- Set 'OUT_OP' to be output operand 'INDEX' in 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: tree gimple_asm_clobber_op (const gasm *g, unsigned
- index)
- Return clobber operand 'INDEX' of 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: void gimple_asm_set_clobber_op (gasm *g, unsigned
- index, tree clobber_op)
- Set 'CLOBBER_OP' to be clobber operand 'INDEX' in 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: const char * gimple_asm_string (const gasm *g)
- Return the string representing the assembly instruction in
- 'GIMPLE_ASM' 'G'.
-
- -- GIMPLE function: bool gimple_asm_volatile_p (const gasm *g)
- Return true if 'G' is an asm statement marked volatile.
-
- -- GIMPLE function: void gimple_asm_set_volatile (gasm *g, bool
- volatile_p)
- Mark asm statement 'G' as volatile or non-volatile based on
- 'VOLATILE_P'.
-
-
- File: gccint.info, Node: GIMPLE_ASSIGN, Next: GIMPLE_BIND, Prev: GIMPLE_ASM, Up: Tuple specific accessors
-
- 12.8.2 'GIMPLE_ASSIGN'
- ----------------------
-
- -- GIMPLE function: gassign *gimple_build_assign (tree lhs, tree rhs)
- Build a 'GIMPLE_ASSIGN' statement. The left-hand side is an lvalue
- passed in lhs. The right-hand side can be either a unary or binary
- tree expression. The expression tree rhs will be flattened and its
- operands assigned to the corresponding operand slots in the new
- statement. This function is useful when you already have a tree
- expression that you want to convert into a tuple. However, try to
- avoid building expression trees for the sole purpose of calling
- this function. If you already have the operands in separate trees,
- it is better to use 'gimple_build_assign' with 'enum tree_code'
- argument and separate arguments for each operand.
-
- -- GIMPLE function: gassign *gimple_build_assign (tree lhs, enum
- tree_code subcode, tree op1, tree op2, tree op3)
- This function is similar to two operand 'gimple_build_assign', but
- is used to build a 'GIMPLE_ASSIGN' statement when the operands of
- the right-hand side of the assignment are already split into
- different operands.
-
- The left-hand side is an lvalue passed in lhs. Subcode is the
- 'tree_code' for the right-hand side of the assignment. Op1, op2
- and op3 are the operands.
-
- -- GIMPLE function: gassign *gimple_build_assign (tree lhs, enum
- tree_code subcode, tree op1, tree op2)
- Like the above 5 operand 'gimple_build_assign', but with the last
- argument 'NULL' - this overload should not be used for
- 'GIMPLE_TERNARY_RHS' assignments.
-
- -- GIMPLE function: gassign *gimple_build_assign (tree lhs, enum
- tree_code subcode, tree op1)
- Like the above 4 operand 'gimple_build_assign', but with the last
- argument 'NULL' - this overload should be used only for
- 'GIMPLE_UNARY_RHS' and 'GIMPLE_SINGLE_RHS' assignments.
-
- -- GIMPLE function: gimple gimplify_assign (tree dst, tree src,
- gimple_seq *seq_p)
- Build a new 'GIMPLE_ASSIGN' tuple and append it to the end of
- '*SEQ_P'.
-
- 'DST'/'SRC' are the destination and source respectively. You can pass
- ungimplified trees in 'DST' or 'SRC', in which case they will be
- converted to a gimple operand if necessary.
-
- This function returns the newly created 'GIMPLE_ASSIGN' tuple.
-
- -- GIMPLE function: enum tree_code gimple_assign_rhs_code (gimple g)
- Return the code of the expression computed on the 'RHS' of
- assignment statement 'G'.
-
- -- GIMPLE function: enum gimple_rhs_class gimple_assign_rhs_class
- (gimple g)
- Return the gimple rhs class of the code for the expression computed
- on the rhs of assignment statement 'G'. This will never return
- 'GIMPLE_INVALID_RHS'.
-
- -- GIMPLE function: tree gimple_assign_lhs (gimple g)
- Return the 'LHS' of assignment statement 'G'.
-
- -- GIMPLE function: tree * gimple_assign_lhs_ptr (gimple g)
- Return a pointer to the 'LHS' of assignment statement 'G'.
-
- -- GIMPLE function: tree gimple_assign_rhs1 (gimple g)
- Return the first operand on the 'RHS' of assignment statement 'G'.
-
- -- GIMPLE function: tree * gimple_assign_rhs1_ptr (gimple g)
- Return the address of the first operand on the 'RHS' of assignment
- statement 'G'.
-
- -- GIMPLE function: tree gimple_assign_rhs2 (gimple g)
- Return the second operand on the 'RHS' of assignment statement 'G'.
-
- -- GIMPLE function: tree * gimple_assign_rhs2_ptr (gimple g)
- Return the address of the second operand on the 'RHS' of assignment
- statement 'G'.
-
- -- GIMPLE function: tree gimple_assign_rhs3 (gimple g)
- Return the third operand on the 'RHS' of assignment statement 'G'.
-
- -- GIMPLE function: tree * gimple_assign_rhs3_ptr (gimple g)
- Return the address of the third operand on the 'RHS' of assignment
- statement 'G'.
-
- -- GIMPLE function: void gimple_assign_set_lhs (gimple g, tree lhs)
- Set 'LHS' to be the 'LHS' operand of assignment statement 'G'.
-
- -- GIMPLE function: void gimple_assign_set_rhs1 (gimple g, tree rhs)
- Set 'RHS' to be the first operand on the 'RHS' of assignment
- statement 'G'.
-
- -- GIMPLE function: void gimple_assign_set_rhs2 (gimple g, tree rhs)
- Set 'RHS' to be the second operand on the 'RHS' of assignment
- statement 'G'.
-
- -- GIMPLE function: void gimple_assign_set_rhs3 (gimple g, tree rhs)
- Set 'RHS' to be the third operand on the 'RHS' of assignment
- statement 'G'.
-
- -- GIMPLE function: bool gimple_assign_cast_p (const_gimple s)
- Return true if 'S' is a type-cast assignment.
-
-
- File: gccint.info, Node: GIMPLE_BIND, Next: GIMPLE_CALL, Prev: GIMPLE_ASSIGN, Up: Tuple specific accessors
-
- 12.8.3 'GIMPLE_BIND'
- --------------------
-
- -- GIMPLE function: gbind *gimple_build_bind (tree vars, gimple_seq
- body)
- Build a 'GIMPLE_BIND' statement with a list of variables in 'VARS'
- and a body of statements in sequence 'BODY'.
-
- -- GIMPLE function: tree gimple_bind_vars (const gbind *g)
- Return the variables declared in the 'GIMPLE_BIND' statement 'G'.
-
- -- GIMPLE function: void gimple_bind_set_vars (gbind *g, tree vars)
- Set 'VARS' to be the set of variables declared in the 'GIMPLE_BIND'
- statement 'G'.
-
- -- GIMPLE function: void gimple_bind_append_vars (gbind *g, tree vars)
- Append 'VARS' to the set of variables declared in the 'GIMPLE_BIND'
- statement 'G'.
-
- -- GIMPLE function: gimple_seq gimple_bind_body (gbind *g)
- Return the GIMPLE sequence contained in the 'GIMPLE_BIND' statement
- 'G'.
-
- -- GIMPLE function: void gimple_bind_set_body (gbind *g, gimple_seq
- seq)
- Set 'SEQ' to be sequence contained in the 'GIMPLE_BIND' statement
- 'G'.
-
- -- GIMPLE function: void gimple_bind_add_stmt (gbind *gs, gimple stmt)
- Append a statement to the end of a 'GIMPLE_BIND''s body.
-
- -- GIMPLE function: void gimple_bind_add_seq (gbind *gs, gimple_seq
- seq)
- Append a sequence of statements to the end of a 'GIMPLE_BIND''s
- body.
-
- -- GIMPLE function: tree gimple_bind_block (const gbind *g)
- Return the 'TREE_BLOCK' node associated with 'GIMPLE_BIND'
- statement 'G'. This is analogous to the 'BIND_EXPR_BLOCK' field in
- trees.
-
- -- GIMPLE function: void gimple_bind_set_block (gbind *g, tree block)
- Set 'BLOCK' to be the 'TREE_BLOCK' node associated with
- 'GIMPLE_BIND' statement 'G'.
-
-
- File: gccint.info, Node: GIMPLE_CALL, Next: GIMPLE_CATCH, Prev: GIMPLE_BIND, Up: Tuple specific accessors
-
- 12.8.4 'GIMPLE_CALL'
- --------------------
-
- -- GIMPLE function: gcall *gimple_build_call (tree fn, unsigned nargs,
- ...)
- Build a 'GIMPLE_CALL' statement to function 'FN'. The argument
- 'FN' must be either a 'FUNCTION_DECL' or a gimple call address as
- determined by 'is_gimple_call_addr'. 'NARGS' are the number of
- arguments. The rest of the arguments follow the argument 'NARGS',
- and must be trees that are valid as rvalues in gimple (i.e., each
- operand is validated with 'is_gimple_operand').
-
- -- GIMPLE function: gcall *gimple_build_call_from_tree (tree call_expr,
- tree fnptrtype)
- Build a 'GIMPLE_CALL' from a 'CALL_EXPR' node. The arguments and
- the function are taken from the expression directly. The type of
- the 'GIMPLE_CALL' is set from the second parameter passed by a
- caller. This routine assumes that 'call_expr' is already in GIMPLE
- form. That is, its operands are GIMPLE values and the function
- call needs no further simplification. All the call flags in
- 'call_expr' are copied over to the new 'GIMPLE_CALL'.
-
- -- GIMPLE function: gcall *gimple_build_call_vec (tree fn, 'vec<tree>'
- args)
- Identical to 'gimple_build_call' but the arguments are stored in a
- 'vec<tree>'.
-
- -- GIMPLE function: tree gimple_call_lhs (gimple g)
- Return the 'LHS' of call statement 'G'.
-
- -- GIMPLE function: tree * gimple_call_lhs_ptr (gimple g)
- Return a pointer to the 'LHS' of call statement 'G'.
-
- -- GIMPLE function: void gimple_call_set_lhs (gimple g, tree lhs)
- Set 'LHS' to be the 'LHS' operand of call statement 'G'.
-
- -- GIMPLE function: tree gimple_call_fn (gimple g)
- Return the tree node representing the function called by call
- statement 'G'.
-
- -- GIMPLE function: void gimple_call_set_fn (gcall *g, tree fn)
- Set 'FN' to be the function called by call statement 'G'. This has
- to be a gimple value specifying the address of the called function.
-
- -- GIMPLE function: tree gimple_call_fndecl (gimple g)
- If a given 'GIMPLE_CALL''s callee is a 'FUNCTION_DECL', return it.
- Otherwise return 'NULL'. This function is analogous to
- 'get_callee_fndecl' in 'GENERIC'.
-
- -- GIMPLE function: tree gimple_call_set_fndecl (gimple g, tree fndecl)
- Set the called function to 'FNDECL'.
-
- -- GIMPLE function: tree gimple_call_return_type (const gcall *g)
- Return the type returned by call statement 'G'.
-
- -- GIMPLE function: tree gimple_call_chain (gimple g)
- Return the static chain for call statement 'G'.
-
- -- GIMPLE function: void gimple_call_set_chain (gcall *g, tree chain)
- Set 'CHAIN' to be the static chain for call statement 'G'.
-
- -- GIMPLE function: unsigned gimple_call_num_args (gimple g)
- Return the number of arguments used by call statement 'G'.
-
- -- GIMPLE function: tree gimple_call_arg (gimple g, unsigned index)
- Return the argument at position 'INDEX' for call statement 'G'.
- The first argument is 0.
-
- -- GIMPLE function: tree * gimple_call_arg_ptr (gimple g, unsigned
- index)
- Return a pointer to the argument at position 'INDEX' for call
- statement 'G'.
-
- -- GIMPLE function: void gimple_call_set_arg (gimple g, unsigned index,
- tree arg)
- Set 'ARG' to be the argument at position 'INDEX' for call statement
- 'G'.
-
- -- GIMPLE function: void gimple_call_set_tail (gcall *s)
- Mark call statement 'S' as being a tail call (i.e., a call just
- before the exit of a function). These calls are candidate for tail
- call optimization.
-
- -- GIMPLE function: bool gimple_call_tail_p (gcall *s)
- Return true if 'GIMPLE_CALL' 'S' is marked as a tail call.
-
- -- GIMPLE function: bool gimple_call_noreturn_p (gimple s)
- Return true if 'S' is a noreturn call.
-
- -- GIMPLE function: gimple gimple_call_copy_skip_args (gcall *stmt,
- bitmap args_to_skip)
- Build a 'GIMPLE_CALL' identical to 'STMT' but skipping the
- arguments in the positions marked by the set 'ARGS_TO_SKIP'.
-
-
- File: gccint.info, Node: GIMPLE_CATCH, Next: GIMPLE_COND, Prev: GIMPLE_CALL, Up: Tuple specific accessors
-
- 12.8.5 'GIMPLE_CATCH'
- ---------------------
-
- -- GIMPLE function: gcatch *gimple_build_catch (tree types, gimple_seq
- handler)
- Build a 'GIMPLE_CATCH' statement. 'TYPES' are the tree types this
- catch handles. 'HANDLER' is a sequence of statements with the code
- for the handler.
-
- -- GIMPLE function: tree gimple_catch_types (const gcatch *g)
- Return the types handled by 'GIMPLE_CATCH' statement 'G'.
-
- -- GIMPLE function: tree * gimple_catch_types_ptr (gcatch *g)
- Return a pointer to the types handled by 'GIMPLE_CATCH' statement
- 'G'.
-
- -- GIMPLE function: gimple_seq gimple_catch_handler (gcatch *g)
- Return the GIMPLE sequence representing the body of the handler of
- 'GIMPLE_CATCH' statement 'G'.
-
- -- GIMPLE function: void gimple_catch_set_types (gcatch *g, tree t)
- Set 'T' to be the set of types handled by 'GIMPLE_CATCH' 'G'.
-
- -- GIMPLE function: void gimple_catch_set_handler (gcatch *g,
- gimple_seq handler)
- Set 'HANDLER' to be the body of 'GIMPLE_CATCH' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_COND, Next: GIMPLE_DEBUG, Prev: GIMPLE_CATCH, Up: Tuple specific accessors
-
- 12.8.6 'GIMPLE_COND'
- --------------------
-
- -- GIMPLE function: gcond *gimple_build_cond ( enum tree_code
- pred_code, tree lhs, tree rhs, tree t_label, tree f_label)
- Build a 'GIMPLE_COND' statement. 'A' 'GIMPLE_COND' statement
- compares 'LHS' and 'RHS' and if the condition in 'PRED_CODE' is
- true, jump to the label in 't_label', otherwise jump to the label
- in 'f_label'. 'PRED_CODE' are relational operator tree codes like
- 'EQ_EXPR', 'LT_EXPR', 'LE_EXPR', 'NE_EXPR', etc.
-
- -- GIMPLE function: gcond *gimple_build_cond_from_tree (tree cond, tree
- t_label, tree f_label)
- Build a 'GIMPLE_COND' statement from the conditional expression
- tree 'COND'. 'T_LABEL' and 'F_LABEL' are as in
- 'gimple_build_cond'.
-
- -- GIMPLE function: enum tree_code gimple_cond_code (gimple g)
- Return the code of the predicate computed by conditional statement
- 'G'.
-
- -- GIMPLE function: void gimple_cond_set_code (gcond *g, enum tree_code
- code)
- Set 'CODE' to be the predicate code for the conditional statement
- 'G'.
-
- -- GIMPLE function: tree gimple_cond_lhs (gimple g)
- Return the 'LHS' of the predicate computed by conditional statement
- 'G'.
-
- -- GIMPLE function: void gimple_cond_set_lhs (gcond *g, tree lhs)
- Set 'LHS' to be the 'LHS' operand of the predicate computed by
- conditional statement 'G'.
-
- -- GIMPLE function: tree gimple_cond_rhs (gimple g)
- Return the 'RHS' operand of the predicate computed by conditional
- 'G'.
-
- -- GIMPLE function: void gimple_cond_set_rhs (gcond *g, tree rhs)
- Set 'RHS' to be the 'RHS' operand of the predicate computed by
- conditional statement 'G'.
-
- -- GIMPLE function: tree gimple_cond_true_label (const gcond *g)
- Return the label used by conditional statement 'G' when its
- predicate evaluates to true.
-
- -- GIMPLE function: void gimple_cond_set_true_label (gcond *g, tree
- label)
- Set 'LABEL' to be the label used by conditional statement 'G' when
- its predicate evaluates to true.
-
- -- GIMPLE function: void gimple_cond_set_false_label (gcond *g, tree
- label)
- Set 'LABEL' to be the label used by conditional statement 'G' when
- its predicate evaluates to false.
-
- -- GIMPLE function: tree gimple_cond_false_label (const gcond *g)
- Return the label used by conditional statement 'G' when its
- predicate evaluates to false.
-
- -- GIMPLE function: void gimple_cond_make_false (gcond *g)
- Set the conditional 'COND_STMT' to be of the form 'if (1 == 0)'.
-
- -- GIMPLE function: void gimple_cond_make_true (gcond *g)
- Set the conditional 'COND_STMT' to be of the form 'if (1 == 1)'.
-
-
- File: gccint.info, Node: GIMPLE_DEBUG, Next: GIMPLE_EH_FILTER, Prev: GIMPLE_COND, Up: Tuple specific accessors
-
- 12.8.7 'GIMPLE_DEBUG'
- ---------------------
-
- -- GIMPLE function: gdebug *gimple_build_debug_bind (tree var, tree
- value, gimple stmt)
- Build a 'GIMPLE_DEBUG' statement with 'GIMPLE_DEBUG_BIND'
- 'subcode'. The effect of this statement is to tell debug
- information generation machinery that the value of user variable
- 'var' is given by 'value' at that point, and to remain with that
- value until 'var' runs out of scope, a dynamically-subsequent debug
- bind statement overrides the binding, or conflicting values reach a
- control flow merge point. Even if components of the 'value'
- expression change afterwards, the variable is supposed to retain
- the same value, though not necessarily the same location.
-
- It is expected that 'var' be most often a tree for automatic user
- variables ('VAR_DECL' or 'PARM_DECL') that satisfy the requirements
- for gimple registers, but it may also be a tree for a scalarized
- component of a user variable ('ARRAY_REF', 'COMPONENT_REF'), or a
- debug temporary ('DEBUG_EXPR_DECL').
-
- As for 'value', it can be an arbitrary tree expression, but it is
- recommended that it be in a suitable form for a gimple assignment
- 'RHS'. It is not expected that user variables that could appear as
- 'var' ever appear in 'value', because in the latter we'd have their
- 'SSA_NAME's instead, but even if they were not in SSA form, user
- variables appearing in 'value' are to be regarded as part of the
- executable code space, whereas those in 'var' are to be regarded as
- part of the source code space. There is no way to refer to the
- value bound to a user variable within a 'value' expression.
-
- If 'value' is 'GIMPLE_DEBUG_BIND_NOVALUE', debug information
- generation machinery is informed that the variable 'var' is
- unbound, i.e., that its value is indeterminate, which sometimes
- means it is really unavailable, and other times that the compiler
- could not keep track of it.
-
- Block and location information for the newly-created stmt are taken
- from 'stmt', if given.
-
- -- GIMPLE function: tree gimple_debug_bind_get_var (gimple stmt)
- Return the user variable VAR that is bound at 'stmt'.
-
- -- GIMPLE function: tree gimple_debug_bind_get_value (gimple stmt)
- Return the value expression that is bound to a user variable at
- 'stmt'.
-
- -- GIMPLE function: tree * gimple_debug_bind_get_value_ptr (gimple
- stmt)
- Return a pointer to the value expression that is bound to a user
- variable at 'stmt'.
-
- -- GIMPLE function: void gimple_debug_bind_set_var (gimple stmt, tree
- var)
- Modify the user variable bound at 'stmt' to VAR.
-
- -- GIMPLE function: void gimple_debug_bind_set_value (gimple stmt, tree
- var)
- Modify the value bound to the user variable bound at 'stmt' to
- VALUE.
-
- -- GIMPLE function: void gimple_debug_bind_reset_value (gimple stmt)
- Modify the value bound to the user variable bound at 'stmt' so that
- the variable becomes unbound.
-
- -- GIMPLE function: bool gimple_debug_bind_has_value_p (gimple stmt)
- Return 'TRUE' if 'stmt' binds a user variable to a value, and
- 'FALSE' if it unbinds the variable.
-
- -- GIMPLE function: gimple gimple_build_debug_begin_stmt (tree block,
- location_t location)
- Build a 'GIMPLE_DEBUG' statement with 'GIMPLE_DEBUG_BEGIN_STMT'
- 'subcode'. The effect of this statement is to tell debug
- information generation machinery that the user statement at the
- given 'location' and 'block' starts at the point at which the
- statement is inserted. The intent is that side effects (e.g.
- variable bindings) of all prior user statements are observable, and
- that none of the side effects of subsequent user statements are.
-
- -- GIMPLE function: gimple gimple_build_debug_inline_entry (tree block,
- location_t location)
- Build a 'GIMPLE_DEBUG' statement with 'GIMPLE_DEBUG_INLINE_ENTRY'
- 'subcode'. The effect of this statement is to tell debug
- information generation machinery that a function call at 'location'
- underwent inline substitution, that 'block' is the enclosing
- lexical block created for the substitution, and that at the point
- of the program in which the stmt is inserted, all parameters for
- the inlined function are bound to the respective arguments, and
- none of the side effects of its stmts are observable.
-
-
- File: gccint.info, Node: GIMPLE_EH_FILTER, Next: GIMPLE_LABEL, Prev: GIMPLE_DEBUG, Up: Tuple specific accessors
-
- 12.8.8 'GIMPLE_EH_FILTER'
- -------------------------
-
- -- GIMPLE function: geh_filter *gimple_build_eh_filter (tree types,
- gimple_seq failure)
- Build a 'GIMPLE_EH_FILTER' statement. 'TYPES' are the filter's
- types. 'FAILURE' is a sequence with the filter's failure action.
-
- -- GIMPLE function: tree gimple_eh_filter_types (gimple g)
- Return the types handled by 'GIMPLE_EH_FILTER' statement 'G'.
-
- -- GIMPLE function: tree * gimple_eh_filter_types_ptr (gimple g)
- Return a pointer to the types handled by 'GIMPLE_EH_FILTER'
- statement 'G'.
-
- -- GIMPLE function: gimple_seq gimple_eh_filter_failure (gimple g)
- Return the sequence of statement to execute when 'GIMPLE_EH_FILTER'
- statement fails.
-
- -- GIMPLE function: void gimple_eh_filter_set_types (geh_filter *g,
- tree types)
- Set 'TYPES' to be the set of types handled by 'GIMPLE_EH_FILTER'
- 'G'.
-
- -- GIMPLE function: void gimple_eh_filter_set_failure (geh_filter *g,
- gimple_seq failure)
- Set 'FAILURE' to be the sequence of statements to execute on
- failure for 'GIMPLE_EH_FILTER' 'G'.
-
- -- GIMPLE function: tree gimple_eh_must_not_throw_fndecl ( geh_mnt
- *eh_mnt_stmt)
- Get the function decl to be called by the MUST_NOT_THROW region.
-
- -- GIMPLE function: void gimple_eh_must_not_throw_set_fndecl ( geh_mnt
- *eh_mnt_stmt, tree decl)
- Set the function decl to be called by GS to DECL.
-
-
- File: gccint.info, Node: GIMPLE_LABEL, Next: GIMPLE_GOTO, Prev: GIMPLE_EH_FILTER, Up: Tuple specific accessors
-
- 12.8.9 'GIMPLE_LABEL'
- ---------------------
-
- -- GIMPLE function: glabel *gimple_build_label (tree label)
- Build a 'GIMPLE_LABEL' statement with corresponding to the tree
- label, 'LABEL'.
-
- -- GIMPLE function: tree gimple_label_label (const glabel *g)
- Return the 'LABEL_DECL' node used by 'GIMPLE_LABEL' statement 'G'.
-
- -- GIMPLE function: void gimple_label_set_label (glabel *g, tree label)
- Set 'LABEL' to be the 'LABEL_DECL' node used by 'GIMPLE_LABEL'
- statement 'G'.
-
-
- File: gccint.info, Node: GIMPLE_GOTO, Next: GIMPLE_NOP, Prev: GIMPLE_LABEL, Up: Tuple specific accessors
-
- 12.8.10 'GIMPLE_GOTO'
- ---------------------
-
- -- GIMPLE function: ggoto *gimple_build_goto (tree dest)
- Build a 'GIMPLE_GOTO' statement to label 'DEST'.
-
- -- GIMPLE function: tree gimple_goto_dest (gimple g)
- Return the destination of the unconditional jump 'G'.
-
- -- GIMPLE function: void gimple_goto_set_dest (ggoto *g, tree dest)
- Set 'DEST' to be the destination of the unconditional jump 'G'.
-
-
- File: gccint.info, Node: GIMPLE_NOP, Next: GIMPLE_OMP_ATOMIC_LOAD, Prev: GIMPLE_GOTO, Up: Tuple specific accessors
-
- 12.8.11 'GIMPLE_NOP'
- --------------------
-
- -- GIMPLE function: gimple gimple_build_nop (void)
- Build a 'GIMPLE_NOP' statement.
-
- -- GIMPLE function: bool gimple_nop_p (gimple g)
- Returns 'TRUE' if statement 'G' is a 'GIMPLE_NOP'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_ATOMIC_LOAD, Next: GIMPLE_OMP_ATOMIC_STORE, Prev: GIMPLE_NOP, Up: Tuple specific accessors
-
- 12.8.12 'GIMPLE_OMP_ATOMIC_LOAD'
- --------------------------------
-
- -- GIMPLE function: gomp_atomic_load *gimple_build_omp_atomic_load (
- tree lhs, tree rhs)
- Build a 'GIMPLE_OMP_ATOMIC_LOAD' statement. 'LHS' is the left-hand
- side of the assignment. 'RHS' is the right-hand side of the
- assignment.
-
- -- GIMPLE function: void gimple_omp_atomic_load_set_lhs (
- gomp_atomic_load *g, tree lhs)
- Set the 'LHS' of an atomic load.
-
- -- GIMPLE function: tree gimple_omp_atomic_load_lhs ( const
- gomp_atomic_load *g)
- Get the 'LHS' of an atomic load.
-
- -- GIMPLE function: void gimple_omp_atomic_load_set_rhs (
- gomp_atomic_load *g, tree rhs)
- Set the 'RHS' of an atomic set.
-
- -- GIMPLE function: tree gimple_omp_atomic_load_rhs ( const
- gomp_atomic_load *g)
- Get the 'RHS' of an atomic set.
-
-
- File: gccint.info, Node: GIMPLE_OMP_ATOMIC_STORE, Next: GIMPLE_OMP_CONTINUE, Prev: GIMPLE_OMP_ATOMIC_LOAD, Up: Tuple specific accessors
-
- 12.8.13 'GIMPLE_OMP_ATOMIC_STORE'
- ---------------------------------
-
- -- GIMPLE function: gomp_atomic_store *gimple_build_omp_atomic_store (
- tree val)
- Build a 'GIMPLE_OMP_ATOMIC_STORE' statement. 'VAL' is the value to
- be stored.
-
- -- GIMPLE function: void gimple_omp_atomic_store_set_val (
- gomp_atomic_store *g, tree val)
- Set the value being stored in an atomic store.
-
- -- GIMPLE function: tree gimple_omp_atomic_store_val ( const
- gomp_atomic_store *g)
- Return the value being stored in an atomic store.
-
-
- File: gccint.info, Node: GIMPLE_OMP_CONTINUE, Next: GIMPLE_OMP_CRITICAL, Prev: GIMPLE_OMP_ATOMIC_STORE, Up: Tuple specific accessors
-
- 12.8.14 'GIMPLE_OMP_CONTINUE'
- -----------------------------
-
- -- GIMPLE function: gomp_continue *gimple_build_omp_continue ( tree
- control_def, tree control_use)
- Build a 'GIMPLE_OMP_CONTINUE' statement. 'CONTROL_DEF' is the
- definition of the control variable. 'CONTROL_USE' is the use of
- the control variable.
-
- -- GIMPLE function: tree gimple_omp_continue_control_def ( const
- gomp_continue *s)
- Return the definition of the control variable on a
- 'GIMPLE_OMP_CONTINUE' in 'S'.
-
- -- GIMPLE function: tree gimple_omp_continue_control_def_ptr (
- gomp_continue *s)
- Same as above, but return the pointer.
-
- -- GIMPLE function: tree gimple_omp_continue_set_control_def (
- gomp_continue *s)
- Set the control variable definition for a 'GIMPLE_OMP_CONTINUE'
- statement in 'S'.
-
- -- GIMPLE function: tree gimple_omp_continue_control_use ( const
- gomp_continue *s)
- Return the use of the control variable on a 'GIMPLE_OMP_CONTINUE'
- in 'S'.
-
- -- GIMPLE function: tree gimple_omp_continue_control_use_ptr (
- gomp_continue *s)
- Same as above, but return the pointer.
-
- -- GIMPLE function: tree gimple_omp_continue_set_control_use (
- gomp_continue *s)
- Set the control variable use for a 'GIMPLE_OMP_CONTINUE' statement
- in 'S'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_CRITICAL, Next: GIMPLE_OMP_FOR, Prev: GIMPLE_OMP_CONTINUE, Up: Tuple specific accessors
-
- 12.8.15 'GIMPLE_OMP_CRITICAL'
- -----------------------------
-
- -- GIMPLE function: gomp_critical *gimple_build_omp_critical (
- gimple_seq body, tree name)
- Build a 'GIMPLE_OMP_CRITICAL' statement. 'BODY' is the sequence of
- statements for which only one thread can execute. 'NAME' is an
- optional identifier for this critical block.
-
- -- GIMPLE function: tree gimple_omp_critical_name ( const gomp_critical
- *g)
- Return the name associated with 'OMP_CRITICAL' statement 'G'.
-
- -- GIMPLE function: tree * gimple_omp_critical_name_ptr ( gomp_critical
- *g)
- Return a pointer to the name associated with 'OMP' critical
- statement 'G'.
-
- -- GIMPLE function: void gimple_omp_critical_set_name ( gomp_critical
- *g, tree name)
- Set 'NAME' to be the name associated with 'OMP' critical statement
- 'G'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_FOR, Next: GIMPLE_OMP_MASTER, Prev: GIMPLE_OMP_CRITICAL, Up: Tuple specific accessors
-
- 12.8.16 'GIMPLE_OMP_FOR'
- ------------------------
-
- -- GIMPLE function: gomp_for *gimple_build_omp_for (gimple_seq body,
- tree clauses, tree index, tree initial, tree final, tree incr,
- gimple_seq pre_body, enum tree_code omp_for_cond)
- Build a 'GIMPLE_OMP_FOR' statement. 'BODY' is sequence of
- statements inside the for loop. 'CLAUSES', are any of the loop
- construct's clauses. 'PRE_BODY' is the sequence of statements that
- are loop invariant. 'INDEX' is the index variable. 'INITIAL' is
- the initial value of 'INDEX'. 'FINAL' is final value of 'INDEX'.
- OMP_FOR_COND is the predicate used to compare 'INDEX' and 'FINAL'.
- 'INCR' is the increment expression.
-
- -- GIMPLE function: tree gimple_omp_for_clauses (gimple g)
- Return the clauses associated with 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_for_clauses_ptr (gimple g)
- Return a pointer to the 'OMP_FOR' 'G'.
-
- -- GIMPLE function: void gimple_omp_for_set_clauses (gimple g, tree
- clauses)
- Set 'CLAUSES' to be the list of clauses associated with 'OMP_FOR'
- 'G'.
-
- -- GIMPLE function: tree gimple_omp_for_index (gimple g)
- Return the index variable for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_for_index_ptr (gimple g)
- Return a pointer to the index variable for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: void gimple_omp_for_set_index (gimple g, tree
- index)
- Set 'INDEX' to be the index variable for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree gimple_omp_for_initial (gimple g)
- Return the initial value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_for_initial_ptr (gimple g)
- Return a pointer to the initial value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: void gimple_omp_for_set_initial (gimple g, tree
- initial)
- Set 'INITIAL' to be the initial value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree gimple_omp_for_final (gimple g)
- Return the final value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_for_final_ptr (gimple g)
- turn a pointer to the final value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: void gimple_omp_for_set_final (gimple g, tree
- final)
- Set 'FINAL' to be the final value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree gimple_omp_for_incr (gimple g)
- Return the increment value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_for_incr_ptr (gimple g)
- Return a pointer to the increment value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: void gimple_omp_for_set_incr (gimple g, tree incr)
- Set 'INCR' to be the increment value for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: gimple_seq gimple_omp_for_pre_body (gimple g)
- Return the sequence of statements to execute before the 'OMP_FOR'
- statement 'G' starts.
-
- -- GIMPLE function: void gimple_omp_for_set_pre_body (gimple g,
- gimple_seq pre_body)
- Set 'PRE_BODY' to be the sequence of statements to execute before
- the 'OMP_FOR' statement 'G' starts.
-
- -- GIMPLE function: void gimple_omp_for_set_cond (gimple g, enum
- tree_code cond)
- Set 'COND' to be the condition code for 'OMP_FOR' 'G'.
-
- -- GIMPLE function: enum tree_code gimple_omp_for_cond (gimple g)
- Return the condition code associated with 'OMP_FOR' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_MASTER, Next: GIMPLE_OMP_ORDERED, Prev: GIMPLE_OMP_FOR, Up: Tuple specific accessors
-
- 12.8.17 'GIMPLE_OMP_MASTER'
- ---------------------------
-
- -- GIMPLE function: gimple gimple_build_omp_master (gimple_seq body)
- Build a 'GIMPLE_OMP_MASTER' statement. 'BODY' is the sequence of
- statements to be executed by just the master.
-
-
- File: gccint.info, Node: GIMPLE_OMP_ORDERED, Next: GIMPLE_OMP_PARALLEL, Prev: GIMPLE_OMP_MASTER, Up: Tuple specific accessors
-
- 12.8.18 'GIMPLE_OMP_ORDERED'
- ----------------------------
-
- -- GIMPLE function: gimple gimple_build_omp_ordered (gimple_seq body)
- Build a 'GIMPLE_OMP_ORDERED' statement.
-
- 'BODY' is the sequence of statements inside a loop that will executed
- in sequence.
-
-
- File: gccint.info, Node: GIMPLE_OMP_PARALLEL, Next: GIMPLE_OMP_RETURN, Prev: GIMPLE_OMP_ORDERED, Up: Tuple specific accessors
-
- 12.8.19 'GIMPLE_OMP_PARALLEL'
- -----------------------------
-
- -- GIMPLE function: gomp_parallel *gimple_build_omp_parallel
- (gimple_seq body, tree clauses, tree child_fn, tree data_arg)
- Build a 'GIMPLE_OMP_PARALLEL' statement.
-
- 'BODY' is sequence of statements which are executed in parallel.
- 'CLAUSES', are the 'OMP' parallel construct's clauses. 'CHILD_FN' is
- the function created for the parallel threads to execute. 'DATA_ARG'
- are the shared data argument(s).
-
- -- GIMPLE function: bool gimple_omp_parallel_combined_p (gimple g)
- Return true if 'OMP' parallel statement 'G' has the
- 'GF_OMP_PARALLEL_COMBINED' flag set.
-
- -- GIMPLE function: void gimple_omp_parallel_set_combined_p (gimple g)
- Set the 'GF_OMP_PARALLEL_COMBINED' field in 'OMP' parallel
- statement 'G'.
-
- -- GIMPLE function: gimple_seq gimple_omp_body (gimple g)
- Return the body for the 'OMP' statement 'G'.
-
- -- GIMPLE function: void gimple_omp_set_body (gimple g, gimple_seq
- body)
- Set 'BODY' to be the body for the 'OMP' statement 'G'.
-
- -- GIMPLE function: tree gimple_omp_parallel_clauses (gimple g)
- Return the clauses associated with 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_parallel_clauses_ptr (
- gomp_parallel *g)
- Return a pointer to the clauses associated with 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: void gimple_omp_parallel_set_clauses (
- gomp_parallel *g, tree clauses)
- Set 'CLAUSES' to be the list of clauses associated with
- 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: tree gimple_omp_parallel_child_fn ( const
- gomp_parallel *g)
- Return the child function used to hold the body of 'OMP_PARALLEL'
- 'G'.
-
- -- GIMPLE function: tree * gimple_omp_parallel_child_fn_ptr (
- gomp_parallel *g)
- Return a pointer to the child function used to hold the body of
- 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: void gimple_omp_parallel_set_child_fn (
- gomp_parallel *g, tree child_fn)
- Set 'CHILD_FN' to be the child function for 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: tree gimple_omp_parallel_data_arg ( const
- gomp_parallel *g)
- Return the artificial argument used to send variables and values
- from the parent to the children threads in 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_parallel_data_arg_ptr (
- gomp_parallel *g)
- Return a pointer to the data argument for 'OMP_PARALLEL' 'G'.
-
- -- GIMPLE function: void gimple_omp_parallel_set_data_arg (
- gomp_parallel *g, tree data_arg)
- Set 'DATA_ARG' to be the data argument for 'OMP_PARALLEL' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_RETURN, Next: GIMPLE_OMP_SECTION, Prev: GIMPLE_OMP_PARALLEL, Up: Tuple specific accessors
-
- 12.8.20 'GIMPLE_OMP_RETURN'
- ---------------------------
-
- -- GIMPLE function: gimple gimple_build_omp_return (bool wait_p)
- Build a 'GIMPLE_OMP_RETURN' statement. 'WAIT_P' is true if this is
- a non-waiting return.
-
- -- GIMPLE function: void gimple_omp_return_set_nowait (gimple s)
- Set the nowait flag on 'GIMPLE_OMP_RETURN' statement 'S'.
-
- -- GIMPLE function: bool gimple_omp_return_nowait_p (gimple g)
- Return true if 'OMP' return statement 'G' has the
- 'GF_OMP_RETURN_NOWAIT' flag set.
-
-
- File: gccint.info, Node: GIMPLE_OMP_SECTION, Next: GIMPLE_OMP_SECTIONS, Prev: GIMPLE_OMP_RETURN, Up: Tuple specific accessors
-
- 12.8.21 'GIMPLE_OMP_SECTION'
- ----------------------------
-
- -- GIMPLE function: gimple gimple_build_omp_section (gimple_seq body)
- Build a 'GIMPLE_OMP_SECTION' statement for a sections statement.
-
- 'BODY' is the sequence of statements in the section.
-
- -- GIMPLE function: bool gimple_omp_section_last_p (gimple g)
- Return true if 'OMP' section statement 'G' has the
- 'GF_OMP_SECTION_LAST' flag set.
-
- -- GIMPLE function: void gimple_omp_section_set_last (gimple g)
- Set the 'GF_OMP_SECTION_LAST' flag on 'G'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_SECTIONS, Next: GIMPLE_OMP_SINGLE, Prev: GIMPLE_OMP_SECTION, Up: Tuple specific accessors
-
- 12.8.22 'GIMPLE_OMP_SECTIONS'
- -----------------------------
-
- -- GIMPLE function: gomp_sections *gimple_build_omp_sections (
- gimple_seq body, tree clauses)
- Build a 'GIMPLE_OMP_SECTIONS' statement. 'BODY' is a sequence of
- section statements. 'CLAUSES' are any of the 'OMP' sections
- construct's clauses: private, firstprivate, lastprivate, reduction,
- and nowait.
-
- -- GIMPLE function: gimple gimple_build_omp_sections_switch (void)
- Build a 'GIMPLE_OMP_SECTIONS_SWITCH' statement.
-
- -- GIMPLE function: tree gimple_omp_sections_control (gimple g)
- Return the control variable associated with the
- 'GIMPLE_OMP_SECTIONS' in 'G'.
-
- -- GIMPLE function: tree * gimple_omp_sections_control_ptr (gimple g)
- Return a pointer to the clauses associated with the
- 'GIMPLE_OMP_SECTIONS' in 'G'.
-
- -- GIMPLE function: void gimple_omp_sections_set_control (gimple g,
- tree control)
- Set 'CONTROL' to be the set of clauses associated with the
- 'GIMPLE_OMP_SECTIONS' in 'G'.
-
- -- GIMPLE function: tree gimple_omp_sections_clauses (gimple g)
- Return the clauses associated with 'OMP_SECTIONS' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_sections_clauses_ptr (gimple g)
- Return a pointer to the clauses associated with 'OMP_SECTIONS' 'G'.
-
- -- GIMPLE function: void gimple_omp_sections_set_clauses (gimple g,
- tree clauses)
- Set 'CLAUSES' to be the set of clauses associated with
- 'OMP_SECTIONS' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_OMP_SINGLE, Next: GIMPLE_PHI, Prev: GIMPLE_OMP_SECTIONS, Up: Tuple specific accessors
-
- 12.8.23 'GIMPLE_OMP_SINGLE'
- ---------------------------
-
- -- GIMPLE function: gomp_single *gimple_build_omp_single ( gimple_seq
- body, tree clauses)
- Build a 'GIMPLE_OMP_SINGLE' statement. 'BODY' is the sequence of
- statements that will be executed once. 'CLAUSES' are any of the
- 'OMP' single construct's clauses: private, firstprivate,
- copyprivate, nowait.
-
- -- GIMPLE function: tree gimple_omp_single_clauses (gimple g)
- Return the clauses associated with 'OMP_SINGLE' 'G'.
-
- -- GIMPLE function: tree * gimple_omp_single_clauses_ptr (gimple g)
- Return a pointer to the clauses associated with 'OMP_SINGLE' 'G'.
-
- -- GIMPLE function: void gimple_omp_single_set_clauses ( gomp_single
- *g, tree clauses)
- Set 'CLAUSES' to be the clauses associated with 'OMP_SINGLE' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_PHI, Next: GIMPLE_RESX, Prev: GIMPLE_OMP_SINGLE, Up: Tuple specific accessors
-
- 12.8.24 'GIMPLE_PHI'
- --------------------
-
- -- GIMPLE function: unsigned gimple_phi_capacity (gimple g)
- Return the maximum number of arguments supported by 'GIMPLE_PHI'
- 'G'.
-
- -- GIMPLE function: unsigned gimple_phi_num_args (gimple g)
- Return the number of arguments in 'GIMPLE_PHI' 'G'. This must
- always be exactly the number of incoming edges for the basic block
- holding 'G'.
-
- -- GIMPLE function: tree gimple_phi_result (gimple g)
- Return the 'SSA' name created by 'GIMPLE_PHI' 'G'.
-
- -- GIMPLE function: tree * gimple_phi_result_ptr (gimple g)
- Return a pointer to the 'SSA' name created by 'GIMPLE_PHI' 'G'.
-
- -- GIMPLE function: void gimple_phi_set_result (gphi *g, tree result)
- Set 'RESULT' to be the 'SSA' name created by 'GIMPLE_PHI' 'G'.
-
- -- GIMPLE function: struct phi_arg_d * gimple_phi_arg (gimple g, index)
- Return the 'PHI' argument corresponding to incoming edge 'INDEX'
- for 'GIMPLE_PHI' 'G'.
-
- -- GIMPLE function: void gimple_phi_set_arg (gphi *g, index, struct
- phi_arg_d * phiarg)
- Set 'PHIARG' to be the argument corresponding to incoming edge
- 'INDEX' for 'GIMPLE_PHI' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_RESX, Next: GIMPLE_RETURN, Prev: GIMPLE_PHI, Up: Tuple specific accessors
-
- 12.8.25 'GIMPLE_RESX'
- ---------------------
-
- -- GIMPLE function: gresx *gimple_build_resx (int region)
- Build a 'GIMPLE_RESX' statement which is a statement. This
- statement is a placeholder for _Unwind_Resume before we know if a
- function call or a branch is needed. 'REGION' is the exception
- region from which control is flowing.
-
- -- GIMPLE function: int gimple_resx_region (const gresx *g)
- Return the region number for 'GIMPLE_RESX' 'G'.
-
- -- GIMPLE function: void gimple_resx_set_region (gresx *g, int region)
- Set 'REGION' to be the region number for 'GIMPLE_RESX' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_RETURN, Next: GIMPLE_SWITCH, Prev: GIMPLE_RESX, Up: Tuple specific accessors
-
- 12.8.26 'GIMPLE_RETURN'
- -----------------------
-
- -- GIMPLE function: greturn *gimple_build_return (tree retval)
- Build a 'GIMPLE_RETURN' statement whose return value is retval.
-
- -- GIMPLE function: tree gimple_return_retval (const greturn *g)
- Return the return value for 'GIMPLE_RETURN' 'G'.
-
- -- GIMPLE function: void gimple_return_set_retval (greturn *g, tree
- retval)
- Set 'RETVAL' to be the return value for 'GIMPLE_RETURN' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_SWITCH, Next: GIMPLE_TRY, Prev: GIMPLE_RETURN, Up: Tuple specific accessors
-
- 12.8.27 'GIMPLE_SWITCH'
- -----------------------
-
- -- GIMPLE function: gswitch *gimple_build_switch (tree index, tree
- default_label, 'vec'<tree> *args)
- Build a 'GIMPLE_SWITCH' statement. 'INDEX' is the index variable
- to switch on, and 'DEFAULT_LABEL' represents the default label.
- 'ARGS' is a vector of 'CASE_LABEL_EXPR' trees that contain the
- non-default case labels. Each label is a tree of code
- 'CASE_LABEL_EXPR'.
-
- -- GIMPLE function: unsigned gimple_switch_num_labels ( const gswitch
- *g)
- Return the number of labels associated with the switch statement
- 'G'.
-
- -- GIMPLE function: void gimple_switch_set_num_labels (gswitch *g,
- unsigned nlabels)
- Set 'NLABELS' to be the number of labels for the switch statement
- 'G'.
-
- -- GIMPLE function: tree gimple_switch_index (const gswitch *g)
- Return the index variable used by the switch statement 'G'.
-
- -- GIMPLE function: void gimple_switch_set_index (gswitch *g, tree
- index)
- Set 'INDEX' to be the index variable for switch statement 'G'.
-
- -- GIMPLE function: tree gimple_switch_label (const gswitch *g,
- unsigned index)
- Return the label numbered 'INDEX'. The default label is 0,
- followed by any labels in a switch statement.
-
- -- GIMPLE function: void gimple_switch_set_label (gswitch *g, unsigned
- index, tree label)
- Set the label number 'INDEX' to 'LABEL'. 0 is always the default
- label.
-
- -- GIMPLE function: tree gimple_switch_default_label ( const gswitch
- *g)
- Return the default label for a switch statement.
-
- -- GIMPLE function: void gimple_switch_set_default_label (gswitch *g,
- tree label)
- Set the default label for a switch statement.
-
-
- File: gccint.info, Node: GIMPLE_TRY, Next: GIMPLE_WITH_CLEANUP_EXPR, Prev: GIMPLE_SWITCH, Up: Tuple specific accessors
-
- 12.8.28 'GIMPLE_TRY'
- --------------------
-
- -- GIMPLE function: gtry *gimple_build_try (gimple_seq eval, gimple_seq
- cleanup, unsigned int kind)
- Build a 'GIMPLE_TRY' statement. 'EVAL' is a sequence with the
- expression to evaluate. 'CLEANUP' is a sequence of statements to
- run at clean-up time. 'KIND' is the enumeration value
- 'GIMPLE_TRY_CATCH' if this statement denotes a try/catch construct
- or 'GIMPLE_TRY_FINALLY' if this statement denotes a try/finally
- construct.
-
- -- GIMPLE function: enum gimple_try_flags gimple_try_kind (gimple g)
- Return the kind of try block represented by 'GIMPLE_TRY' 'G'. This
- is either 'GIMPLE_TRY_CATCH' or 'GIMPLE_TRY_FINALLY'.
-
- -- GIMPLE function: bool gimple_try_catch_is_cleanup (gimple g)
- Return the 'GIMPLE_TRY_CATCH_IS_CLEANUP' flag.
-
- -- GIMPLE function: gimple_seq gimple_try_eval (gimple g)
- Return the sequence of statements used as the body for 'GIMPLE_TRY'
- 'G'.
-
- -- GIMPLE function: gimple_seq gimple_try_cleanup (gimple g)
- Return the sequence of statements used as the cleanup body for
- 'GIMPLE_TRY' 'G'.
-
- -- GIMPLE function: void gimple_try_set_catch_is_cleanup (gimple g,
- bool catch_is_cleanup)
- Set the 'GIMPLE_TRY_CATCH_IS_CLEANUP' flag.
-
- -- GIMPLE function: void gimple_try_set_eval (gtry *g, gimple_seq eval)
- Set 'EVAL' to be the sequence of statements to use as the body for
- 'GIMPLE_TRY' 'G'.
-
- -- GIMPLE function: void gimple_try_set_cleanup (gtry *g, gimple_seq
- cleanup)
- Set 'CLEANUP' to be the sequence of statements to use as the
- cleanup body for 'GIMPLE_TRY' 'G'.
-
-
- File: gccint.info, Node: GIMPLE_WITH_CLEANUP_EXPR, Prev: GIMPLE_TRY, Up: Tuple specific accessors
-
- 12.8.29 'GIMPLE_WITH_CLEANUP_EXPR'
- ----------------------------------
-
- -- GIMPLE function: gimple gimple_build_wce (gimple_seq cleanup)
- Build a 'GIMPLE_WITH_CLEANUP_EXPR' statement. 'CLEANUP' is the
- clean-up expression.
-
- -- GIMPLE function: gimple_seq gimple_wce_cleanup (gimple g)
- Return the cleanup sequence for cleanup statement 'G'.
-
- -- GIMPLE function: void gimple_wce_set_cleanup (gimple g, gimple_seq
- cleanup)
- Set 'CLEANUP' to be the cleanup sequence for 'G'.
-
- -- GIMPLE function: bool gimple_wce_cleanup_eh_only (gimple g)
- Return the 'CLEANUP_EH_ONLY' flag for a 'WCE' tuple.
-
- -- GIMPLE function: void gimple_wce_set_cleanup_eh_only (gimple g, bool
- eh_only_p)
- Set the 'CLEANUP_EH_ONLY' flag for a 'WCE' tuple.
-
-
- File: gccint.info, Node: GIMPLE sequences, Next: Sequence iterators, Prev: Tuple specific accessors, Up: GIMPLE
-
- 12.9 GIMPLE sequences
- =====================
-
- GIMPLE sequences are the tuple equivalent of 'STATEMENT_LIST''s used in
- 'GENERIC'. They are used to chain statements together, and when used in
- conjunction with sequence iterators, provide a framework for iterating
- through statements.
-
- GIMPLE sequences are of type struct 'gimple_sequence', but are more
- commonly passed by reference to functions dealing with sequences. The
- type for a sequence pointer is 'gimple_seq' which is the same as struct
- 'gimple_sequence' *. When declaring a local sequence, you can define a
- local variable of type struct 'gimple_sequence'. When declaring a
- sequence allocated on the garbage collected heap, use the function
- 'gimple_seq_alloc' documented below.
-
- There are convenience functions for iterating through sequences in the
- section entitled Sequence Iterators.
-
- Below is a list of functions to manipulate and query sequences.
-
- -- GIMPLE function: void gimple_seq_add_stmt (gimple_seq *seq, gimple
- g)
- Link a gimple statement to the end of the sequence *'SEQ' if 'G' is
- not 'NULL'. If *'SEQ' is 'NULL', allocate a sequence before
- linking.
-
- -- GIMPLE function: void gimple_seq_add_seq (gimple_seq *dest,
- gimple_seq src)
- Append sequence 'SRC' to the end of sequence *'DEST' if 'SRC' is
- not 'NULL'. If *'DEST' is 'NULL', allocate a new sequence before
- appending.
-
- -- GIMPLE function: gimple_seq gimple_seq_deep_copy (gimple_seq src)
- Perform a deep copy of sequence 'SRC' and return the result.
-
- -- GIMPLE function: gimple_seq gimple_seq_reverse (gimple_seq seq)
- Reverse the order of the statements in the sequence 'SEQ'. Return
- 'SEQ'.
-
- -- GIMPLE function: gimple gimple_seq_first (gimple_seq s)
- Return the first statement in sequence 'S'.
-
- -- GIMPLE function: gimple gimple_seq_last (gimple_seq s)
- Return the last statement in sequence 'S'.
-
- -- GIMPLE function: void gimple_seq_set_last (gimple_seq s, gimple
- last)
- Set the last statement in sequence 'S' to the statement in 'LAST'.
-
- -- GIMPLE function: void gimple_seq_set_first (gimple_seq s, gimple
- first)
- Set the first statement in sequence 'S' to the statement in
- 'FIRST'.
-
- -- GIMPLE function: void gimple_seq_init (gimple_seq s)
- Initialize sequence 'S' to an empty sequence.
-
- -- GIMPLE function: gimple_seq gimple_seq_alloc (void)
- Allocate a new sequence in the garbage collected store and return
- it.
-
- -- GIMPLE function: void gimple_seq_copy (gimple_seq dest, gimple_seq
- src)
- Copy the sequence 'SRC' into the sequence 'DEST'.
-
- -- GIMPLE function: bool gimple_seq_empty_p (gimple_seq s)
- Return true if the sequence 'S' is empty.
-
- -- GIMPLE function: gimple_seq bb_seq (basic_block bb)
- Returns the sequence of statements in 'BB'.
-
- -- GIMPLE function: void set_bb_seq (basic_block bb, gimple_seq seq)
- Sets the sequence of statements in 'BB' to 'SEQ'.
-
- -- GIMPLE function: bool gimple_seq_singleton_p (gimple_seq seq)
- Determine whether 'SEQ' contains exactly one statement.
-
-
- File: gccint.info, Node: Sequence iterators, Next: Adding a new GIMPLE statement code, Prev: GIMPLE sequences, Up: GIMPLE
-
- 12.10 Sequence iterators
- ========================
-
- Sequence iterators are convenience constructs for iterating through
- statements in a sequence. Given a sequence 'SEQ', here is a typical use
- of gimple sequence iterators:
-
- gimple_stmt_iterator gsi;
-
- for (gsi = gsi_start (seq); !gsi_end_p (gsi); gsi_next (&gsi))
- {
- gimple g = gsi_stmt (gsi);
- /* Do something with gimple statement G. */
- }
-
- Backward iterations are possible:
-
- for (gsi = gsi_last (seq); !gsi_end_p (gsi); gsi_prev (&gsi))
-
- Forward and backward iterations on basic blocks are possible with
- 'gsi_start_bb' and 'gsi_last_bb'.
-
- In the documentation below we sometimes refer to enum
- 'gsi_iterator_update'. The valid options for this enumeration are:
-
- * 'GSI_NEW_STMT' Only valid when a single statement is added. Move
- the iterator to it.
-
- * 'GSI_SAME_STMT' Leave the iterator at the same statement.
-
- * 'GSI_CONTINUE_LINKING' Move iterator to whatever position is
- suitable for linking other statements in the same direction.
-
- Below is a list of the functions used to manipulate and use statement
- iterators.
-
- -- GIMPLE function: gimple_stmt_iterator gsi_start (gimple_seq seq)
- Return a new iterator pointing to the sequence 'SEQ''s first
- statement. If 'SEQ' is empty, the iterator's basic block is
- 'NULL'. Use 'gsi_start_bb' instead when the iterator needs to
- always have the correct basic block set.
-
- -- GIMPLE function: gimple_stmt_iterator gsi_start_bb (basic_block bb)
- Return a new iterator pointing to the first statement in basic
- block 'BB'.
-
- -- GIMPLE function: gimple_stmt_iterator gsi_last (gimple_seq seq)
- Return a new iterator initially pointing to the last statement of
- sequence 'SEQ'. If 'SEQ' is empty, the iterator's basic block is
- 'NULL'. Use 'gsi_last_bb' instead when the iterator needs to
- always have the correct basic block set.
-
- -- GIMPLE function: gimple_stmt_iterator gsi_last_bb (basic_block bb)
- Return a new iterator pointing to the last statement in basic block
- 'BB'.
-
- -- GIMPLE function: bool gsi_end_p (gimple_stmt_iterator i)
- Return 'TRUE' if at the end of 'I'.
-
- -- GIMPLE function: bool gsi_one_before_end_p (gimple_stmt_iterator i)
- Return 'TRUE' if we're one statement before the end of 'I'.
-
- -- GIMPLE function: void gsi_next (gimple_stmt_iterator *i)
- Advance the iterator to the next gimple statement.
-
- -- GIMPLE function: void gsi_prev (gimple_stmt_iterator *i)
- Advance the iterator to the previous gimple statement.
-
- -- GIMPLE function: gimple gsi_stmt (gimple_stmt_iterator i)
- Return the current stmt.
-
- -- GIMPLE function: gimple_stmt_iterator gsi_after_labels (basic_block
- bb)
- Return a block statement iterator that points to the first
- non-label statement in block 'BB'.
-
- -- GIMPLE function: gimple * gsi_stmt_ptr (gimple_stmt_iterator *i)
- Return a pointer to the current stmt.
-
- -- GIMPLE function: basic_block gsi_bb (gimple_stmt_iterator i)
- Return the basic block associated with this iterator.
-
- -- GIMPLE function: gimple_seq gsi_seq (gimple_stmt_iterator i)
- Return the sequence associated with this iterator.
-
- -- GIMPLE function: void gsi_remove (gimple_stmt_iterator *i, bool
- remove_eh_info)
- Remove the current stmt from the sequence. The iterator is updated
- to point to the next statement. When 'REMOVE_EH_INFO' is true we
- remove the statement pointed to by iterator 'I' from the 'EH'
- tables. Otherwise we do not modify the 'EH' tables. Generally,
- 'REMOVE_EH_INFO' should be true when the statement is going to be
- removed from the 'IL' and not reinserted elsewhere.
-
- -- GIMPLE function: void gsi_link_seq_before (gimple_stmt_iterator *i,
- gimple_seq seq, enum gsi_iterator_update mode)
- Links the sequence of statements 'SEQ' before the statement pointed
- by iterator 'I'. 'MODE' indicates what to do with the iterator
- after insertion (see 'enum gsi_iterator_update' above).
-
- -- GIMPLE function: void gsi_link_before (gimple_stmt_iterator *i,
- gimple g, enum gsi_iterator_update mode)
- Links statement 'G' before the statement pointed-to by iterator
- 'I'. Updates iterator 'I' according to 'MODE'.
-
- -- GIMPLE function: void gsi_link_seq_after (gimple_stmt_iterator *i,
- gimple_seq seq, enum gsi_iterator_update mode)
- Links sequence 'SEQ' after the statement pointed-to by iterator
- 'I'. 'MODE' is as in 'gsi_insert_after'.
-
- -- GIMPLE function: void gsi_link_after (gimple_stmt_iterator *i,
- gimple g, enum gsi_iterator_update mode)
- Links statement 'G' after the statement pointed-to by iterator 'I'.
- 'MODE' is as in 'gsi_insert_after'.
-
- -- GIMPLE function: gimple_seq gsi_split_seq_after
- (gimple_stmt_iterator i)
- Move all statements in the sequence after 'I' to a new sequence.
- Return this new sequence.
-
- -- GIMPLE function: gimple_seq gsi_split_seq_before
- (gimple_stmt_iterator *i)
- Move all statements in the sequence before 'I' to a new sequence.
- Return this new sequence.
-
- -- GIMPLE function: void gsi_replace (gimple_stmt_iterator *i, gimple
- stmt, bool update_eh_info)
- Replace the statement pointed-to by 'I' to 'STMT'. If
- 'UPDATE_EH_INFO' is true, the exception handling information of the
- original statement is moved to the new statement.
-
- -- GIMPLE function: void gsi_insert_before (gimple_stmt_iterator *i,
- gimple stmt, enum gsi_iterator_update mode)
- Insert statement 'STMT' before the statement pointed-to by iterator
- 'I', update 'STMT''s basic block and scan it for new operands.
- 'MODE' specifies how to update iterator 'I' after insertion (see
- enum 'gsi_iterator_update').
-
- -- GIMPLE function: void gsi_insert_seq_before (gimple_stmt_iterator
- *i, gimple_seq seq, enum gsi_iterator_update mode)
- Like 'gsi_insert_before', but for all the statements in 'SEQ'.
-
- -- GIMPLE function: void gsi_insert_after (gimple_stmt_iterator *i,
- gimple stmt, enum gsi_iterator_update mode)
- Insert statement 'STMT' after the statement pointed-to by iterator
- 'I', update 'STMT''s basic block and scan it for new operands.
- 'MODE' specifies how to update iterator 'I' after insertion (see
- enum 'gsi_iterator_update').
-
- -- GIMPLE function: void gsi_insert_seq_after (gimple_stmt_iterator *i,
- gimple_seq seq, enum gsi_iterator_update mode)
- Like 'gsi_insert_after', but for all the statements in 'SEQ'.
-
- -- GIMPLE function: gimple_stmt_iterator gsi_for_stmt (gimple stmt)
- Finds iterator for 'STMT'.
-
- -- GIMPLE function: void gsi_move_after (gimple_stmt_iterator *from,
- gimple_stmt_iterator *to)
- Move the statement at 'FROM' so it comes right after the statement
- at 'TO'.
-
- -- GIMPLE function: void gsi_move_before (gimple_stmt_iterator *from,
- gimple_stmt_iterator *to)
- Move the statement at 'FROM' so it comes right before the statement
- at 'TO'.
-
- -- GIMPLE function: void gsi_move_to_bb_end (gimple_stmt_iterator
- *from, basic_block bb)
- Move the statement at 'FROM' to the end of basic block 'BB'.
-
- -- GIMPLE function: void gsi_insert_on_edge (edge e, gimple stmt)
- Add 'STMT' to the pending list of edge 'E'. No actual insertion is
- made until a call to 'gsi_commit_edge_inserts'() is made.
-
- -- GIMPLE function: void gsi_insert_seq_on_edge (edge e, gimple_seq
- seq)
- Add the sequence of statements in 'SEQ' to the pending list of edge
- 'E'. No actual insertion is made until a call to
- 'gsi_commit_edge_inserts'() is made.
-
- -- GIMPLE function: basic_block gsi_insert_on_edge_immediate (edge e,
- gimple stmt)
- Similar to 'gsi_insert_on_edge'+'gsi_commit_edge_inserts'. If a
- new block has to be created, it is returned.
-
- -- GIMPLE function: void gsi_commit_one_edge_insert (edge e,
- basic_block *new_bb)
- Commit insertions pending at edge 'E'. If a new block is created,
- set 'NEW_BB' to this block, otherwise set it to 'NULL'.
-
- -- GIMPLE function: void gsi_commit_edge_inserts (void)
- This routine will commit all pending edge insertions, creating any
- new basic blocks which are necessary.
-
-
- File: gccint.info, Node: Adding a new GIMPLE statement code, Next: Statement and operand traversals, Prev: Sequence iterators, Up: GIMPLE
-
- 12.11 Adding a new GIMPLE statement code
- ========================================
-
- The first step in adding a new GIMPLE statement code, is modifying the
- file 'gimple.def', which contains all the GIMPLE codes. Then you must
- add a corresponding gimple subclass located in 'gimple.h'. This in
- turn, will require you to add a corresponding 'GTY' tag in
- 'gsstruct.def', and code to handle this tag in 'gss_for_code' which is
- located in 'gimple.c'.
-
- In order for the garbage collector to know the size of the structure
- you created in 'gimple.h', you need to add a case to handle your new
- GIMPLE statement in 'gimple_size' which is located in 'gimple.c'.
-
- You will probably want to create a function to build the new gimple
- statement in 'gimple.c'. The function should be called
- 'gimple_build_NEW-TUPLE-NAME', and should return the new tuple as a
- pointer to the appropriate gimple subclass.
-
- If your new statement requires accessors for any members or operands it
- may have, put simple inline accessors in 'gimple.h' and any non-trivial
- accessors in 'gimple.c' with a corresponding prototype in 'gimple.h'.
-
- You should add the new statement subclass to the class hierarchy
- diagram in 'gimple.texi'.
-
-
- File: gccint.info, Node: Statement and operand traversals, Prev: Adding a new GIMPLE statement code, Up: GIMPLE
-
- 12.12 Statement and operand traversals
- ======================================
-
- There are two functions available for walking statements and sequences:
- 'walk_gimple_stmt' and 'walk_gimple_seq', accordingly, and a third
- function for walking the operands in a statement: 'walk_gimple_op'.
-
- -- GIMPLE function: tree walk_gimple_stmt (gimple_stmt_iterator *gsi,
- walk_stmt_fn callback_stmt, walk_tree_fn callback_op, struct
- walk_stmt_info *wi)
- This function is used to walk the current statement in 'GSI',
- optionally using traversal state stored in 'WI'. If 'WI' is
- 'NULL', no state is kept during the traversal.
-
- The callback 'CALLBACK_STMT' is called. If 'CALLBACK_STMT' returns
- true, it means that the callback function has handled all the
- operands of the statement and it is not necessary to walk its
- operands.
-
- If 'CALLBACK_STMT' is 'NULL' or it returns false, 'CALLBACK_OP' is
- called on each operand of the statement via 'walk_gimple_op'. If
- 'walk_gimple_op' returns non-'NULL' for any operand, the remaining
- operands are not scanned.
-
- The return value is that returned by the last call to
- 'walk_gimple_op', or 'NULL_TREE' if no 'CALLBACK_OP' is specified.
-
- -- GIMPLE function: tree walk_gimple_op (gimple stmt, walk_tree_fn
- callback_op, struct walk_stmt_info *wi)
- Use this function to walk the operands of statement 'STMT'. Every
- operand is walked via 'walk_tree' with optional state information
- in 'WI'.
-
- 'CALLBACK_OP' is called on each operand of 'STMT' via 'walk_tree'.
- Additional parameters to 'walk_tree' must be stored in 'WI'. For
- each operand 'OP', 'walk_tree' is called as:
-
- walk_tree (&OP, CALLBACK_OP, WI, PSET)
-
- If 'CALLBACK_OP' returns non-'NULL' for an operand, the remaining
- operands are not scanned. The return value is that returned by the
- last call to 'walk_tree', or 'NULL_TREE' if no 'CALLBACK_OP' is
- specified.
-
- -- GIMPLE function: tree walk_gimple_seq (gimple_seq seq, walk_stmt_fn
- callback_stmt, walk_tree_fn callback_op, struct walk_stmt_info
- *wi)
- This function walks all the statements in the sequence 'SEQ'
- calling 'walk_gimple_stmt' on each one. 'WI' is as in
- 'walk_gimple_stmt'. If 'walk_gimple_stmt' returns non-'NULL', the
- walk is stopped and the value returned. Otherwise, all the
- statements are walked and 'NULL_TREE' returned.
-
-
- File: gccint.info, Node: Tree SSA, Next: RTL, Prev: GIMPLE, Up: Top
-
- 13 Analysis and Optimization of GIMPLE tuples
- *********************************************
-
- GCC uses three main intermediate languages to represent the program
- during compilation: GENERIC, GIMPLE and RTL. GENERIC is a
- language-independent representation generated by each front end. It is
- used to serve as an interface between the parser and optimizer. GENERIC
- is a common representation that is able to represent programs written in
- all the languages supported by GCC.
-
- GIMPLE and RTL are used to optimize the program. GIMPLE is used for
- target and language independent optimizations (e.g., inlining, constant
- propagation, tail call elimination, redundancy elimination, etc). Much
- like GENERIC, GIMPLE is a language independent, tree based
- representation. However, it differs from GENERIC in that the GIMPLE
- grammar is more restrictive: expressions contain no more than 3 operands
- (except function calls), it has no control flow structures and
- expressions with side effects are only allowed on the right hand side of
- assignments. See the chapter describing GENERIC and GIMPLE for more
- details.
-
- This chapter describes the data structures and functions used in the
- GIMPLE optimizers (also known as "tree optimizers" or "middle end"). In
- particular, it focuses on all the macros, data structures, functions and
- programming constructs needed to implement optimization passes for
- GIMPLE.
-
- * Menu:
-
- * Annotations:: Attributes for variables.
- * SSA Operands:: SSA names referenced by GIMPLE statements.
- * SSA:: Static Single Assignment representation.
- * Alias analysis:: Representing aliased loads and stores.
- * Memory model:: Memory model used by the middle-end.
-
-
- File: gccint.info, Node: Annotations, Next: SSA Operands, Up: Tree SSA
-
- 13.1 Annotations
- ================
-
- The optimizers need to associate attributes with variables during the
- optimization process. For instance, we need to know whether a variable
- has aliases. All these attributes are stored in data structures called
- annotations which are then linked to the field 'ann' in 'struct
- tree_common'.
-
-
- File: gccint.info, Node: SSA Operands, Next: SSA, Prev: Annotations, Up: Tree SSA
-
- 13.2 SSA Operands
- =================
-
- Almost every GIMPLE statement will contain a reference to a variable or
- memory location. Since statements come in different shapes and sizes,
- their operands are going to be located at various spots inside the
- statement's tree. To facilitate access to the statement's operands,
- they are organized into lists associated inside each statement's
- annotation. Each element in an operand list is a pointer to a
- 'VAR_DECL', 'PARM_DECL' or 'SSA_NAME' tree node. This provides a very
- convenient way of examining and replacing operands.
-
- Data flow analysis and optimization is done on all tree nodes
- representing variables. Any node for which 'SSA_VAR_P' returns nonzero
- is considered when scanning statement operands. However, not all
- 'SSA_VAR_P' variables are processed in the same way. For the purposes
- of optimization, we need to distinguish between references to local
- scalar variables and references to globals, statics, structures, arrays,
- aliased variables, etc. The reason is simple, the compiler can gather
- complete data flow information for a local scalar. On the other hand, a
- global variable may be modified by a function call, it may not be
- possible to keep track of all the elements of an array or the fields of
- a structure, etc.
-
- The operand scanner gathers two kinds of operands: "real" and
- "virtual". An operand for which 'is_gimple_reg' returns true is
- considered real, otherwise it is a virtual operand. We also distinguish
- between uses and definitions. An operand is used if its value is loaded
- by the statement (e.g., the operand at the RHS of an assignment). If
- the statement assigns a new value to the operand, the operand is
- considered a definition (e.g., the operand at the LHS of an assignment).
-
- Virtual and real operands also have very different data flow
- properties. Real operands are unambiguous references to the full object
- that they represent. For instance, given
-
- {
- int a, b;
- a = b
- }
-
- Since 'a' and 'b' are non-aliased locals, the statement 'a = b' will
- have one real definition and one real use because variable 'a' is
- completely modified with the contents of variable 'b'. Real definition
- are also known as "killing definitions". Similarly, the use of 'b'
- reads all its bits.
-
- In contrast, virtual operands are used with variables that can have a
- partial or ambiguous reference. This includes structures, arrays,
- globals, and aliased variables. In these cases, we have two types of
- definitions. For globals, structures, and arrays, we can determine from
- a statement whether a variable of these types has a killing definition.
- If the variable does, then the statement is marked as having a "must
- definition" of that variable. However, if a statement is only defining
- a part of the variable (i.e. a field in a structure), or if we know that
- a statement might define the variable but we cannot say for sure, then
- we mark that statement as having a "may definition". For instance,
- given
-
- {
- int a, b, *p;
-
- if (...)
- p = &a;
- else
- p = &b;
- *p = 5;
- return *p;
- }
-
- The assignment '*p = 5' may be a definition of 'a' or 'b'. If we
- cannot determine statically where 'p' is pointing to at the time of the
- store operation, we create virtual definitions to mark that statement as
- a potential definition site for 'a' and 'b'. Memory loads are similarly
- marked with virtual use operands. Virtual operands are shown in tree
- dumps right before the statement that contains them. To request a tree
- dump with virtual operands, use the '-vops' option to '-fdump-tree':
-
- {
- int a, b, *p;
-
- if (...)
- p = &a;
- else
- p = &b;
- # a = VDEF <a>
- # b = VDEF <b>
- *p = 5;
-
- # VUSE <a>
- # VUSE <b>
- return *p;
- }
-
- Notice that 'VDEF' operands have two copies of the referenced variable.
- This indicates that this is not a killing definition of that variable.
- In this case we refer to it as a "may definition" or "aliased store".
- The presence of the second copy of the variable in the 'VDEF' operand
- will become important when the function is converted into SSA form.
- This will be used to link all the non-killing definitions to prevent
- optimizations from making incorrect assumptions about them.
-
- Operands are updated as soon as the statement is finished via a call to
- 'update_stmt'. If statement elements are changed via 'SET_USE' or
- 'SET_DEF', then no further action is required (i.e., those macros take
- care of updating the statement). If changes are made by manipulating
- the statement's tree directly, then a call must be made to 'update_stmt'
- when complete. Calling one of the 'bsi_insert' routines or
- 'bsi_replace' performs an implicit call to 'update_stmt'.
-
- 13.2.1 Operand Iterators And Access Routines
- --------------------------------------------
-
- Operands are collected by 'tree-ssa-operands.c'. They are stored inside
- each statement's annotation and can be accessed through either the
- operand iterators or an access routine.
-
- The following access routines are available for examining operands:
-
- 1. 'SINGLE_SSA_{USE,DEF,TREE}_OPERAND': These accessors will return
- NULL unless there is exactly one operand matching the specified
- flags. If there is exactly one operand, the operand is returned as
- either a 'tree', 'def_operand_p', or 'use_operand_p'.
-
- tree t = SINGLE_SSA_TREE_OPERAND (stmt, flags);
- use_operand_p u = SINGLE_SSA_USE_OPERAND (stmt, SSA_ALL_VIRTUAL_USES);
- def_operand_p d = SINGLE_SSA_DEF_OPERAND (stmt, SSA_OP_ALL_DEFS);
-
- 2. 'ZERO_SSA_OPERANDS': This macro returns true if there are no
- operands matching the specified flags.
-
- if (ZERO_SSA_OPERANDS (stmt, SSA_OP_ALL_VIRTUALS))
- return;
-
- 3. 'NUM_SSA_OPERANDS': This macro Returns the number of operands
- matching 'flags'. This actually executes a loop to perform the
- count, so only use this if it is really needed.
-
- int count = NUM_SSA_OPERANDS (stmt, flags)
-
- If you wish to iterate over some or all operands, use the
- 'FOR_EACH_SSA_{USE,DEF,TREE}_OPERAND' iterator. For example, to print
- all the operands for a statement:
-
- void
- print_ops (tree stmt)
- {
- ssa_op_iter;
- tree var;
-
- FOR_EACH_SSA_TREE_OPERAND (var, stmt, iter, SSA_OP_ALL_OPERANDS)
- print_generic_expr (stderr, var, TDF_SLIM);
- }
-
- How to choose the appropriate iterator:
-
- 1. Determine whether you are need to see the operand pointers, or just
- the trees, and choose the appropriate macro:
-
- Need Macro:
- ---- -------
- use_operand_p FOR_EACH_SSA_USE_OPERAND
- def_operand_p FOR_EACH_SSA_DEF_OPERAND
- tree FOR_EACH_SSA_TREE_OPERAND
-
- 2. You need to declare a variable of the type you are interested in,
- and an ssa_op_iter structure which serves as the loop controlling
- variable.
-
- 3. Determine which operands you wish to use, and specify the flags of
- those you are interested in. They are documented in
- 'tree-ssa-operands.h':
-
- #define SSA_OP_USE 0x01 /* Real USE operands. */
- #define SSA_OP_DEF 0x02 /* Real DEF operands. */
- #define SSA_OP_VUSE 0x04 /* VUSE operands. */
- #define SSA_OP_VDEF 0x08 /* VDEF operands. */
-
- /* These are commonly grouped operand flags. */
- #define SSA_OP_VIRTUAL_USES (SSA_OP_VUSE)
- #define SSA_OP_VIRTUAL_DEFS (SSA_OP_VDEF)
- #define SSA_OP_ALL_VIRTUALS (SSA_OP_VIRTUAL_USES | SSA_OP_VIRTUAL_DEFS)
- #define SSA_OP_ALL_USES (SSA_OP_VIRTUAL_USES | SSA_OP_USE)
- #define SSA_OP_ALL_DEFS (SSA_OP_VIRTUAL_DEFS | SSA_OP_DEF)
- #define SSA_OP_ALL_OPERANDS (SSA_OP_ALL_USES | SSA_OP_ALL_DEFS)
-
- So if you want to look at the use pointers for all the 'USE' and 'VUSE'
- operands, you would do something like:
-
- use_operand_p use_p;
- ssa_op_iter iter;
-
- FOR_EACH_SSA_USE_OPERAND (use_p, stmt, iter, (SSA_OP_USE | SSA_OP_VUSE))
- {
- process_use_ptr (use_p);
- }
-
- The 'TREE' macro is basically the same as the 'USE' and 'DEF' macros,
- only with the use or def dereferenced via 'USE_FROM_PTR (use_p)' and
- 'DEF_FROM_PTR (def_p)'. Since we aren't using operand pointers, use and
- defs flags can be mixed.
-
- tree var;
- ssa_op_iter iter;
-
- FOR_EACH_SSA_TREE_OPERAND (var, stmt, iter, SSA_OP_VUSE)
- {
- print_generic_expr (stderr, var, TDF_SLIM);
- }
-
- 'VDEF's are broken into two flags, one for the 'DEF' portion
- ('SSA_OP_VDEF') and one for the USE portion ('SSA_OP_VUSE').
-
- There are many examples in the code, in addition to the documentation
- in 'tree-ssa-operands.h' and 'ssa-iterators.h'.
-
- There are also a couple of variants on the stmt iterators regarding PHI
- nodes.
-
- 'FOR_EACH_PHI_ARG' Works exactly like 'FOR_EACH_SSA_USE_OPERAND',
- except it works over 'PHI' arguments instead of statement operands.
-
- /* Look at every virtual PHI use. */
- FOR_EACH_PHI_ARG (use_p, phi_stmt, iter, SSA_OP_VIRTUAL_USES)
- {
- my_code;
- }
-
- /* Look at every real PHI use. */
- FOR_EACH_PHI_ARG (use_p, phi_stmt, iter, SSA_OP_USES)
- my_code;
-
- /* Look at every PHI use. */
- FOR_EACH_PHI_ARG (use_p, phi_stmt, iter, SSA_OP_ALL_USES)
- my_code;
-
- 'FOR_EACH_PHI_OR_STMT_{USE,DEF}' works exactly like
- 'FOR_EACH_SSA_{USE,DEF}_OPERAND', except it will function on either a
- statement or a 'PHI' node. These should be used when it is appropriate
- but they are not quite as efficient as the individual 'FOR_EACH_PHI' and
- 'FOR_EACH_SSA' routines.
-
- FOR_EACH_PHI_OR_STMT_USE (use_operand_p, stmt, iter, flags)
- {
- my_code;
- }
-
- FOR_EACH_PHI_OR_STMT_DEF (def_operand_p, phi, iter, flags)
- {
- my_code;
- }
-
- 13.2.2 Immediate Uses
- ---------------------
-
- Immediate use information is now always available. Using the immediate
- use iterators, you may examine every use of any 'SSA_NAME'. For
- instance, to change each use of 'ssa_var' to 'ssa_var2' and call
- fold_stmt on each stmt after that is done:
-
- use_operand_p imm_use_p;
- imm_use_iterator iterator;
- tree ssa_var, stmt;
-
-
- FOR_EACH_IMM_USE_STMT (stmt, iterator, ssa_var)
- {
- FOR_EACH_IMM_USE_ON_STMT (imm_use_p, iterator)
- SET_USE (imm_use_p, ssa_var_2);
- fold_stmt (stmt);
- }
-
- There are 2 iterators which can be used. 'FOR_EACH_IMM_USE_FAST' is
- used when the immediate uses are not changed, i.e., you are looking at
- the uses, but not setting them.
-
- If they do get changed, then care must be taken that things are not
- changed under the iterators, so use the 'FOR_EACH_IMM_USE_STMT' and
- 'FOR_EACH_IMM_USE_ON_STMT' iterators. They attempt to preserve the
- sanity of the use list by moving all the uses for a statement into a
- controlled position, and then iterating over those uses. Then the
- optimization can manipulate the stmt when all the uses have been
- processed. This is a little slower than the FAST version since it adds
- a placeholder element and must sort through the list a bit for each
- statement. This placeholder element must be also be removed if the loop
- is terminated early. The macro 'BREAK_FROM_IMM_USE_STMT' is provided to
- do this :
-
- FOR_EACH_IMM_USE_STMT (stmt, iterator, ssa_var)
- {
- if (stmt == last_stmt)
- BREAK_FROM_IMM_USE_STMT (iterator);
-
- FOR_EACH_IMM_USE_ON_STMT (imm_use_p, iterator)
- SET_USE (imm_use_p, ssa_var_2);
- fold_stmt (stmt);
- }
-
- There are checks in 'verify_ssa' which verify that the immediate use
- list is up to date, as well as checking that an optimization didn't
- break from the loop without using this macro. It is safe to simply
- 'break'; from a 'FOR_EACH_IMM_USE_FAST' traverse.
-
- Some useful functions and macros:
- 1. 'has_zero_uses (ssa_var)' : Returns true if there are no uses of
- 'ssa_var'.
- 2. 'has_single_use (ssa_var)' : Returns true if there is only a single
- use of 'ssa_var'.
- 3. 'single_imm_use (ssa_var, use_operand_p *ptr, tree *stmt)' :
- Returns true if there is only a single use of 'ssa_var', and also
- returns the use pointer and statement it occurs in, in the second
- and third parameters.
- 4. 'num_imm_uses (ssa_var)' : Returns the number of immediate uses of
- 'ssa_var'. It is better not to use this if possible since it
- simply utilizes a loop to count the uses.
- 5. 'PHI_ARG_INDEX_FROM_USE (use_p)' : Given a use within a 'PHI' node,
- return the index number for the use. An assert is triggered if the
- use isn't located in a 'PHI' node.
- 6. 'USE_STMT (use_p)' : Return the statement a use occurs in.
-
- Note that uses are not put into an immediate use list until their
- statement is actually inserted into the instruction stream via a 'bsi_*'
- routine.
-
- It is also still possible to utilize lazy updating of statements, but
- this should be used only when absolutely required. Both alias analysis
- and the dominator optimizations currently do this.
-
- When lazy updating is being used, the immediate use information is out
- of date and cannot be used reliably. Lazy updating is achieved by
- simply marking statements modified via calls to 'gimple_set_modified'
- instead of 'update_stmt'. When lazy updating is no longer required, all
- the modified statements must have 'update_stmt' called in order to bring
- them up to date. This must be done before the optimization is finished,
- or 'verify_ssa' will trigger an abort.
-
- This is done with a simple loop over the instruction stream:
- block_stmt_iterator bsi;
- basic_block bb;
- FOR_EACH_BB (bb)
- {
- for (bsi = bsi_start (bb); !bsi_end_p (bsi); bsi_next (&bsi))
- update_stmt_if_modified (bsi_stmt (bsi));
- }
-
-
- File: gccint.info, Node: SSA, Next: Alias analysis, Prev: SSA Operands, Up: Tree SSA
-
- 13.3 Static Single Assignment
- =============================
-
- Most of the tree optimizers rely on the data flow information provided
- by the Static Single Assignment (SSA) form. We implement the SSA form
- as described in 'R. Cytron, J. Ferrante, B. Rosen, M. Wegman, and K.
- Zadeck. Efficiently Computing Static Single Assignment Form and the
- Control Dependence Graph. ACM Transactions on Programming Languages and
- Systems, 13(4):451-490, October 1991'.
-
- The SSA form is based on the premise that program variables are
- assigned in exactly one location in the program. Multiple assignments
- to the same variable create new versions of that variable. Naturally,
- actual programs are seldom in SSA form initially because variables tend
- to be assigned multiple times. The compiler modifies the program
- representation so that every time a variable is assigned in the code, a
- new version of the variable is created. Different versions of the same
- variable are distinguished by subscripting the variable name with its
- version number. Variables used in the right-hand side of expressions
- are renamed so that their version number matches that of the most recent
- assignment.
-
- We represent variable versions using 'SSA_NAME' nodes. The renaming
- process in 'tree-ssa.c' wraps every real and virtual operand with an
- 'SSA_NAME' node which contains the version number and the statement that
- created the 'SSA_NAME'. Only definitions and virtual definitions may
- create new 'SSA_NAME' nodes.
-
- Sometimes, flow of control makes it impossible to determine the most
- recent version of a variable. In these cases, the compiler inserts an
- artificial definition for that variable called "PHI function" or "PHI
- node". This new definition merges all the incoming versions of the
- variable to create a new name for it. For instance,
-
- if (...)
- a_1 = 5;
- else if (...)
- a_2 = 2;
- else
- a_3 = 13;
-
- # a_4 = PHI <a_1, a_2, a_3>
- return a_4;
-
- Since it is not possible to determine which of the three branches will
- be taken at runtime, we don't know which of 'a_1', 'a_2' or 'a_3' to use
- at the return statement. So, the SSA renamer creates a new version
- 'a_4' which is assigned the result of "merging" 'a_1', 'a_2' and 'a_3'.
- Hence, PHI nodes mean "one of these operands. I don't know which".
-
- The following functions can be used to examine PHI nodes
-
- -- Function: gimple_phi_result (PHI)
- Returns the 'SSA_NAME' created by PHI node PHI (i.e., PHI's LHS).
-
- -- Function: gimple_phi_num_args (PHI)
- Returns the number of arguments in PHI. This number is exactly the
- number of incoming edges to the basic block holding PHI.
-
- -- Function: gimple_phi_arg (PHI, I)
- Returns Ith argument of PHI.
-
- -- Function: gimple_phi_arg_edge (PHI, I)
- Returns the incoming edge for the Ith argument of PHI.
-
- -- Function: gimple_phi_arg_def (PHI, I)
- Returns the 'SSA_NAME' for the Ith argument of PHI.
-
- 13.3.1 Preserving the SSA form
- ------------------------------
-
- Some optimization passes make changes to the function that invalidate
- the SSA property. This can happen when a pass has added new symbols or
- changed the program so that variables that were previously aliased
- aren't anymore. Whenever something like this happens, the affected
- symbols must be renamed into SSA form again. Transformations that emit
- new code or replicate existing statements will also need to update the
- SSA form.
-
- Since GCC implements two different SSA forms for register and virtual
- variables, keeping the SSA form up to date depends on whether you are
- updating register or virtual names. In both cases, the general idea
- behind incremental SSA updates is similar: when new SSA names are
- created, they typically are meant to replace other existing names in the
- program.
-
- For instance, given the following code:
-
- 1 L0:
- 2 x_1 = PHI (0, x_5)
- 3 if (x_1 < 10)
- 4 if (x_1 > 7)
- 5 y_2 = 0
- 6 else
- 7 y_3 = x_1 + x_7
- 8 endif
- 9 x_5 = x_1 + 1
- 10 goto L0;
- 11 endif
-
- Suppose that we insert new names 'x_10' and 'x_11' (lines '4' and '8').
-
- 1 L0:
- 2 x_1 = PHI (0, x_5)
- 3 if (x_1 < 10)
- 4 x_10 = ...
- 5 if (x_1 > 7)
- 6 y_2 = 0
- 7 else
- 8 x_11 = ...
- 9 y_3 = x_1 + x_7
- 10 endif
- 11 x_5 = x_1 + 1
- 12 goto L0;
- 13 endif
-
- We want to replace all the uses of 'x_1' with the new definitions of
- 'x_10' and 'x_11'. Note that the only uses that should be replaced are
- those at lines '5', '9' and '11'. Also, the use of 'x_7' at line '9'
- should _not_ be replaced (this is why we cannot just mark symbol 'x' for
- renaming).
-
- Additionally, we may need to insert a PHI node at line '11' because
- that is a merge point for 'x_10' and 'x_11'. So the use of 'x_1' at
- line '11' will be replaced with the new PHI node. The insertion of PHI
- nodes is optional. They are not strictly necessary to preserve the SSA
- form, and depending on what the caller inserted, they may not even be
- useful for the optimizers.
-
- Updating the SSA form is a two step process. First, the pass has to
- identify which names need to be updated and/or which symbols need to be
- renamed into SSA form for the first time. When new names are introduced
- to replace existing names in the program, the mapping between the old
- and the new names are registered by calling 'register_new_name_mapping'
- (note that if your pass creates new code by duplicating basic blocks,
- the call to 'tree_duplicate_bb' will set up the necessary mappings
- automatically).
-
- After the replacement mappings have been registered and new symbols
- marked for renaming, a call to 'update_ssa' makes the registered
- changes. This can be done with an explicit call or by creating 'TODO'
- flags in the 'tree_opt_pass' structure for your pass. There are several
- 'TODO' flags that control the behavior of 'update_ssa':
-
- * 'TODO_update_ssa'. Update the SSA form inserting PHI nodes for
- newly exposed symbols and virtual names marked for updating. When
- updating real names, only insert PHI nodes for a real name 'O_j' in
- blocks reached by all the new and old definitions for 'O_j'. If
- the iterated dominance frontier for 'O_j' is not pruned, we may end
- up inserting PHI nodes in blocks that have one or more edges with
- no incoming definition for 'O_j'. This would lead to uninitialized
- warnings for 'O_j''s symbol.
-
- * 'TODO_update_ssa_no_phi'. Update the SSA form without inserting
- any new PHI nodes at all. This is used by passes that have either
- inserted all the PHI nodes themselves or passes that need only to
- patch use-def and def-def chains for virtuals (e.g., DCE).
-
- * 'TODO_update_ssa_full_phi'. Insert PHI nodes everywhere they are
- needed. No pruning of the IDF is done. This is used by passes
- that need the PHI nodes for 'O_j' even if it means that some
- arguments will come from the default definition of 'O_j''s symbol
- (e.g., 'pass_linear_transform').
-
- WARNING: If you need to use this flag, chances are that your pass
- may be doing something wrong. Inserting PHI nodes for an old name
- where not all edges carry a new replacement may lead to silent
- codegen errors or spurious uninitialized warnings.
-
- * 'TODO_update_ssa_only_virtuals'. Passes that update the SSA form
- on their own may want to delegate the updating of virtual names to
- the generic updater. Since FUD chains are easier to maintain, this
- simplifies the work they need to do. NOTE: If this flag is used,
- any OLD->NEW mappings for real names are explicitly destroyed and
- only the symbols marked for renaming are processed.
-
- 13.3.2 Examining 'SSA_NAME' nodes
- ---------------------------------
-
- The following macros can be used to examine 'SSA_NAME' nodes
-
- -- Macro: SSA_NAME_DEF_STMT (VAR)
- Returns the statement S that creates the 'SSA_NAME' VAR. If S is
- an empty statement (i.e., 'IS_EMPTY_STMT (S)' returns 'true'), it
- means that the first reference to this variable is a USE or a VUSE.
-
- -- Macro: SSA_NAME_VERSION (VAR)
- Returns the version number of the 'SSA_NAME' object VAR.
-
- 13.3.3 Walking the dominator tree
- ---------------------------------
-
- -- Tree SSA function: void walk_dominator_tree (WALK_DATA, BB)
-
- This function walks the dominator tree for the current CFG calling
- a set of callback functions defined in STRUCT DOM_WALK_DATA in
- 'domwalk.h'. The call back functions you need to define give you
- hooks to execute custom code at various points during traversal:
-
- 1. Once to initialize any local data needed while processing BB
- and its children. This local data is pushed into an internal
- stack which is automatically pushed and popped as the walker
- traverses the dominator tree.
-
- 2. Once before traversing all the statements in the BB.
-
- 3. Once for every statement inside BB.
-
- 4. Once after traversing all the statements and before recursing
- into BB's dominator children.
-
- 5. It then recurses into all the dominator children of BB.
-
- 6. After recursing into all the dominator children of BB it can,
- optionally, traverse every statement in BB again (i.e.,
- repeating steps 2 and 3).
-
- 7. Once after walking the statements in BB and BB's dominator
- children. At this stage, the block local data stack is
- popped.
-
-
- File: gccint.info, Node: Alias analysis, Next: Memory model, Prev: SSA, Up: Tree SSA
-
- 13.4 Alias analysis
- ===================
-
- Alias analysis in GIMPLE SSA form consists of two pieces. First the
- virtual SSA web ties conflicting memory accesses and provides a SSA
- use-def chain and SSA immediate-use chains for walking possibly
- dependent memory accesses. Second an alias-oracle can be queried to
- disambiguate explicit and implicit memory references.
-
- 1. Memory SSA form.
-
- All statements that may use memory have exactly one accompanied use
- of a virtual SSA name that represents the state of memory at the
- given point in the IL.
-
- All statements that may define memory have exactly one accompanied
- definition of a virtual SSA name using the previous state of memory
- and defining the new state of memory after the given point in the
- IL.
-
- int i;
- int foo (void)
- {
- # .MEM_3 = VDEF <.MEM_2(D)>
- i = 1;
- # VUSE <.MEM_3>
- return i;
- }
-
- The virtual SSA names in this case are '.MEM_2(D)' and '.MEM_3'.
- The store to the global variable 'i' defines '.MEM_3' invalidating
- '.MEM_2(D)'. The load from 'i' uses that new state '.MEM_3'.
-
- The virtual SSA web serves as constraints to SSA optimizers
- preventing illegitimate code-motion and optimization. It also
- provides a way to walk related memory statements.
-
- 2. Points-to and escape analysis.
-
- Points-to analysis builds a set of constraints from the GIMPLE SSA
- IL representing all pointer operations and facts we do or do not
- know about pointers. Solving this set of constraints yields a
- conservatively correct solution for each pointer variable in the
- program (though we are only interested in SSA name pointers) as to
- what it may possibly point to.
-
- This points-to solution for a given SSA name pointer is stored in
- the 'pt_solution' sub-structure of the 'SSA_NAME_PTR_INFO' record.
- The following accessor functions are available:
-
- * 'pt_solution_includes'
- * 'pt_solutions_intersect'
-
- Points-to analysis also computes the solution for two special set
- of pointers, 'ESCAPED' and 'CALLUSED'. Those represent all memory
- that has escaped the scope of analysis or that is used by pure or
- nested const calls.
-
- 3. Type-based alias analysis
-
- Type-based alias analysis is frontend dependent though generic
- support is provided by the middle-end in 'alias.c'. TBAA code is
- used by both tree optimizers and RTL optimizers.
-
- Every language that wishes to perform language-specific alias
- analysis should define a function that computes, given a 'tree'
- node, an alias set for the node. Nodes in different alias sets are
- not allowed to alias. For an example, see the C front-end function
- 'c_get_alias_set'.
-
- 4. Tree alias-oracle
-
- The tree alias-oracle provides means to disambiguate two memory
- references and memory references against statements. The following
- queries are available:
-
- * 'refs_may_alias_p'
- * 'ref_maybe_used_by_stmt_p'
- * 'stmt_may_clobber_ref_p'
-
- In addition to those two kind of statement walkers are available
- walking statements related to a reference ref.
- 'walk_non_aliased_vuses' walks over dominating memory defining
- statements and calls back if the statement does not clobber ref
- providing the non-aliased VUSE. The walk stops at the first
- clobbering statement or if asked to. 'walk_aliased_vdefs' walks
- over dominating memory defining statements and calls back on each
- statement clobbering ref providing its aliasing VDEF. The walk
- stops if asked to.
-
-
- File: gccint.info, Node: Memory model, Prev: Alias analysis, Up: Tree SSA
-
- 13.5 Memory model
- =================
-
- The memory model used by the middle-end models that of the C/C++
- languages. The middle-end has the notion of an effective type of a
- memory region which is used for type-based alias analysis.
-
- The following is a refinement of ISO C99 6.5/6, clarifying the block
- copy case to follow common sense and extending the concept of a dynamic
- effective type to objects with a declared type as required for C++.
-
- The effective type of an object for an access to its stored value is
- the declared type of the object or the effective type determined by
- a previous store to it. If a value is stored into an object through
- an lvalue having a type that is not a character type, then the
- type of the lvalue becomes the effective type of the object for that
- access and for subsequent accesses that do not modify the stored value.
- If a value is copied into an object using memcpy or memmove,
- or is copied as an array of character type, then the effective type
- of the modified object for that access and for subsequent accesses that
- do not modify the value is undetermined. For all other accesses to an
- object, the effective type of the object is simply the type of the
- lvalue used for the access.
-
-
- File: gccint.info, Node: RTL, Next: Control Flow, Prev: Tree SSA, Up: Top
-
- 14 RTL Representation
- *********************
-
- The last part of the compiler work is done on a low-level intermediate
- representation called Register Transfer Language. In this language, the
- instructions to be output are described, pretty much one by one, in an
- algebraic form that describes what the instruction does.
-
- RTL is inspired by Lisp lists. It has both an internal form, made up
- of structures that point at other structures, and a textual form that is
- used in the machine description and in printed debugging dumps. The
- textual form uses nested parentheses to indicate the pointers in the
- internal form.
-
- * Menu:
-
- * RTL Objects:: Expressions vs vectors vs strings vs integers.
- * RTL Classes:: Categories of RTL expression objects, and their structure.
- * Accessors:: Macros to access expression operands or vector elts.
- * Special Accessors:: Macros to access specific annotations on RTL.
- * Flags:: Other flags in an RTL expression.
- * Machine Modes:: Describing the size and format of a datum.
- * Constants:: Expressions with constant values.
- * Regs and Memory:: Expressions representing register contents or memory.
- * Arithmetic:: Expressions representing arithmetic on other expressions.
- * Comparisons:: Expressions representing comparison of expressions.
- * Bit-Fields:: Expressions representing bit-fields in memory or reg.
- * Vector Operations:: Expressions involving vector datatypes.
- * Conversions:: Extending, truncating, floating or fixing.
- * RTL Declarations:: Declaring volatility, constancy, etc.
- * Side Effects:: Expressions for storing in registers, etc.
- * Incdec:: Embedded side-effects for autoincrement addressing.
- * Assembler:: Representing 'asm' with operands.
- * Debug Information:: Expressions representing debugging information.
- * Insns:: Expression types for entire insns.
- * Calls:: RTL representation of function call insns.
- * Sharing:: Some expressions are unique; others *must* be copied.
- * Reading RTL:: Reading textual RTL from a file.
-
-
- File: gccint.info, Node: RTL Objects, Next: RTL Classes, Up: RTL
-
- 14.1 RTL Object Types
- =====================
-
- RTL uses five kinds of objects: expressions, integers, wide integers,
- strings and vectors. Expressions are the most important ones. An RTL
- expression ("RTX", for short) is a C structure, but it is usually
- referred to with a pointer; a type that is given the typedef name 'rtx'.
-
- An integer is simply an 'int'; their written form uses decimal digits.
- A wide integer is an integral object whose type is 'HOST_WIDE_INT';
- their written form uses decimal digits.
-
- A string is a sequence of characters. In core it is represented as a
- 'char *' in usual C fashion, and it is written in C syntax as well.
- However, strings in RTL may never be null. If you write an empty string
- in a machine description, it is represented in core as a null pointer
- rather than as a pointer to a null character. In certain contexts,
- these null pointers instead of strings are valid. Within RTL code,
- strings are most commonly found inside 'symbol_ref' expressions, but
- they appear in other contexts in the RTL expressions that make up
- machine descriptions.
-
- In a machine description, strings are normally written with double
- quotes, as you would in C. However, strings in machine descriptions may
- extend over many lines, which is invalid C, and adjacent string
- constants are not concatenated as they are in C. Any string constant
- may be surrounded with a single set of parentheses. Sometimes this
- makes the machine description easier to read.
-
- There is also a special syntax for strings, which can be useful when C
- code is embedded in a machine description. Wherever a string can
- appear, it is also valid to write a C-style brace block. The entire
- brace block, including the outermost pair of braces, is considered to be
- the string constant. Double quote characters inside the braces are not
- special. Therefore, if you write string constants in the C code, you
- need not escape each quote character with a backslash.
-
- A vector contains an arbitrary number of pointers to expressions. The
- number of elements in the vector is explicitly present in the vector.
- The written form of a vector consists of square brackets ('[...]')
- surrounding the elements, in sequence and with whitespace separating
- them. Vectors of length zero are not created; null pointers are used
- instead.
-
- Expressions are classified by "expression codes" (also called RTX
- codes). The expression code is a name defined in 'rtl.def', which is
- also (in uppercase) a C enumeration constant. The possible expression
- codes and their meanings are machine-independent. The code of an RTX
- can be extracted with the macro 'GET_CODE (X)' and altered with
- 'PUT_CODE (X, NEWCODE)'.
-
- The expression code determines how many operands the expression
- contains, and what kinds of objects they are. In RTL, unlike Lisp, you
- cannot tell by looking at an operand what kind of object it is.
- Instead, you must know from its context--from the expression code of the
- containing expression. For example, in an expression of code 'subreg',
- the first operand is to be regarded as an expression and the second
- operand as a polynomial integer. In an expression of code 'plus', there
- are two operands, both of which are to be regarded as expressions. In a
- 'symbol_ref' expression, there is one operand, which is to be regarded
- as a string.
-
- Expressions are written as parentheses containing the name of the
- expression type, its flags and machine mode if any, and then the
- operands of the expression (separated by spaces).
-
- Expression code names in the 'md' file are written in lowercase, but
- when they appear in C code they are written in uppercase. In this
- manual, they are shown as follows: 'const_int'.
-
- In a few contexts a null pointer is valid where an expression is
- normally wanted. The written form of this is '(nil)'.
-
-
- File: gccint.info, Node: RTL Classes, Next: Accessors, Prev: RTL Objects, Up: RTL
-
- 14.2 RTL Classes and Formats
- ============================
-
- The various expression codes are divided into several "classes", which
- are represented by single characters. You can determine the class of an
- RTX code with the macro 'GET_RTX_CLASS (CODE)'. Currently, 'rtl.def'
- defines these classes:
-
- 'RTX_OBJ'
- An RTX code that represents an actual object, such as a register
- ('REG') or a memory location ('MEM', 'SYMBOL_REF'). 'LO_SUM') is
- also included; instead, 'SUBREG' and 'STRICT_LOW_PART' are not in
- this class, but in class 'RTX_EXTRA'.
-
- 'RTX_CONST_OBJ'
- An RTX code that represents a constant object. 'HIGH' is also
- included in this class.
-
- 'RTX_COMPARE'
- An RTX code for a non-symmetric comparison, such as 'GEU' or 'LT'.
-
- 'RTX_COMM_COMPARE'
- An RTX code for a symmetric (commutative) comparison, such as 'EQ'
- or 'ORDERED'.
-
- 'RTX_UNARY'
- An RTX code for a unary arithmetic operation, such as 'NEG', 'NOT',
- or 'ABS'. This category also includes value extension (sign or
- zero) and conversions between integer and floating point.
-
- 'RTX_COMM_ARITH'
- An RTX code for a commutative binary operation, such as 'PLUS' or
- 'AND'. 'NE' and 'EQ' are comparisons, so they have class
- 'RTX_COMM_COMPARE'.
-
- 'RTX_BIN_ARITH'
- An RTX code for a non-commutative binary operation, such as
- 'MINUS', 'DIV', or 'ASHIFTRT'.
-
- 'RTX_BITFIELD_OPS'
- An RTX code for a bit-field operation. Currently only
- 'ZERO_EXTRACT' and 'SIGN_EXTRACT'. These have three inputs and are
- lvalues (so they can be used for insertion as well). *Note
- Bit-Fields::.
-
- 'RTX_TERNARY'
- An RTX code for other three input operations. Currently only
- 'IF_THEN_ELSE', 'VEC_MERGE', 'SIGN_EXTRACT', 'ZERO_EXTRACT', and
- 'FMA'.
-
- 'RTX_INSN'
- An RTX code for an entire instruction: 'INSN', 'JUMP_INSN', and
- 'CALL_INSN'. *Note Insns::.
-
- 'RTX_MATCH'
- An RTX code for something that matches in insns, such as
- 'MATCH_DUP'. These only occur in machine descriptions.
-
- 'RTX_AUTOINC'
- An RTX code for an auto-increment addressing mode, such as
- 'POST_INC'. 'XEXP (X, 0)' gives the auto-modified register.
-
- 'RTX_EXTRA'
- All other RTX codes. This category includes the remaining codes
- used only in machine descriptions ('DEFINE_*', etc.). It also
- includes all the codes describing side effects ('SET', 'USE',
- 'CLOBBER', etc.) and the non-insns that may appear on an insn
- chain, such as 'NOTE', 'BARRIER', and 'CODE_LABEL'. 'SUBREG' is
- also part of this class.
-
- For each expression code, 'rtl.def' specifies the number of contained
- objects and their kinds using a sequence of characters called the
- "format" of the expression code. For example, the format of 'subreg' is
- 'ep'.
-
- These are the most commonly used format characters:
-
- 'e'
- An expression (actually a pointer to an expression).
-
- 'i'
- An integer.
-
- 'w'
- A wide integer.
-
- 's'
- A string.
-
- 'E'
- A vector of expressions.
-
- A few other format characters are used occasionally:
-
- 'u'
- 'u' is equivalent to 'e' except that it is printed differently in
- debugging dumps. It is used for pointers to insns.
-
- 'n'
- 'n' is equivalent to 'i' except that it is printed differently in
- debugging dumps. It is used for the line number or code number of
- a 'note' insn.
-
- 'S'
- 'S' indicates a string which is optional. In the RTL objects in
- core, 'S' is equivalent to 's', but when the object is read, from
- an 'md' file, the string value of this operand may be omitted. An
- omitted string is taken to be the null string.
-
- 'V'
- 'V' indicates a vector which is optional. In the RTL objects in
- core, 'V' is equivalent to 'E', but when the object is read from an
- 'md' file, the vector value of this operand may be omitted. An
- omitted vector is effectively the same as a vector of no elements.
-
- 'B'
- 'B' indicates a pointer to basic block structure.
-
- 'p'
- A polynomial integer. At present this is used only for
- 'SUBREG_BYTE'.
-
- '0'
- '0' means a slot whose contents do not fit any normal category.
- '0' slots are not printed at all in dumps, and are often used in
- special ways by small parts of the compiler.
-
- There are macros to get the number of operands and the format of an
- expression code:
-
- 'GET_RTX_LENGTH (CODE)'
- Number of operands of an RTX of code CODE.
-
- 'GET_RTX_FORMAT (CODE)'
- The format of an RTX of code CODE, as a C string.
-
- Some classes of RTX codes always have the same format. For example, it
- is safe to assume that all comparison operations have format 'ee'.
-
- 'RTX_UNARY'
- All codes of this class have format 'e'.
-
- 'RTX_BIN_ARITH'
- 'RTX_COMM_ARITH'
- 'RTX_COMM_COMPARE'
- 'RTX_COMPARE'
- All codes of these classes have format 'ee'.
-
- 'RTX_BITFIELD_OPS'
- 'RTX_TERNARY'
- All codes of these classes have format 'eee'.
-
- 'RTX_INSN'
- All codes of this class have formats that begin with 'iuueiee'.
- *Note Insns::. Note that not all RTL objects linked onto an insn
- chain are of class 'RTX_INSN'.
-
- 'RTX_CONST_OBJ'
- 'RTX_OBJ'
- 'RTX_MATCH'
- 'RTX_EXTRA'
- You can make no assumptions about the format of these codes.
-
-
- File: gccint.info, Node: Accessors, Next: Special Accessors, Prev: RTL Classes, Up: RTL
-
- 14.3 Access to Operands
- =======================
-
- Operands of expressions are accessed using the macros 'XEXP', 'XINT',
- 'XWINT' and 'XSTR'. Each of these macros takes two arguments: an
- expression-pointer (RTX) and an operand number (counting from zero).
- Thus,
-
- XEXP (X, 2)
-
- accesses operand 2 of expression X, as an expression.
-
- XINT (X, 2)
-
- accesses the same operand as an integer. 'XSTR', used in the same
- fashion, would access it as a string.
-
- Any operand can be accessed as an integer, as an expression or as a
- string. You must choose the correct method of access for the kind of
- value actually stored in the operand. You would do this based on the
- expression code of the containing expression. That is also how you
- would know how many operands there are.
-
- For example, if X is an 'int_list' expression, you know that it has two
- operands which can be correctly accessed as 'XINT (X, 0)' and 'XEXP (X,
- 1)'. Incorrect accesses like 'XEXP (X, 0)' and 'XINT (X, 1)' would
- compile, but would trigger an internal compiler error when rtl checking
- is enabled. Nothing stops you from writing 'XEXP (X, 28)' either, but
- this will access memory past the end of the expression with
- unpredictable results.
-
- Access to operands which are vectors is more complicated. You can use
- the macro 'XVEC' to get the vector-pointer itself, or the macros
- 'XVECEXP' and 'XVECLEN' to access the elements and length of a vector.
-
- 'XVEC (EXP, IDX)'
- Access the vector-pointer which is operand number IDX in EXP.
-
- 'XVECLEN (EXP, IDX)'
- Access the length (number of elements) in the vector which is in
- operand number IDX in EXP. This value is an 'int'.
-
- 'XVECEXP (EXP, IDX, ELTNUM)'
- Access element number ELTNUM in the vector which is in operand
- number IDX in EXP. This value is an RTX.
-
- It is up to you to make sure that ELTNUM is not negative and is
- less than 'XVECLEN (EXP, IDX)'.
-
- All the macros defined in this section expand into lvalues and
- therefore can be used to assign the operands, lengths and vector
- elements as well as to access them.
-
-
- File: gccint.info, Node: Special Accessors, Next: Flags, Prev: Accessors, Up: RTL
-
- 14.4 Access to Special Operands
- ===============================
-
- Some RTL nodes have special annotations associated with them.
-
- 'MEM'
- 'MEM_ALIAS_SET (X)'
- If 0, X is not in any alias set, and may alias anything.
- Otherwise, X can only alias 'MEM's in a conflicting alias set.
- This value is set in a language-dependent manner in the
- front-end, and should not be altered in the back-end. In some
- front-ends, these numbers may correspond in some way to types,
- or other language-level entities, but they need not, and the
- back-end makes no such assumptions. These set numbers are
- tested with 'alias_sets_conflict_p'.
-
- 'MEM_EXPR (X)'
- If this register is known to hold the value of some user-level
- declaration, this is that tree node. It may also be a
- 'COMPONENT_REF', in which case this is some field reference,
- and 'TREE_OPERAND (X, 0)' contains the declaration, or another
- 'COMPONENT_REF', or null if there is no compile-time object
- associated with the reference.
-
- 'MEM_OFFSET_KNOWN_P (X)'
- True if the offset of the memory reference from 'MEM_EXPR' is
- known. 'MEM_OFFSET (X)' provides the offset if so.
-
- 'MEM_OFFSET (X)'
- The offset from the start of 'MEM_EXPR'. The value is only
- valid if 'MEM_OFFSET_KNOWN_P (X)' is true.
-
- 'MEM_SIZE_KNOWN_P (X)'
- True if the size of the memory reference is known. 'MEM_SIZE
- (X)' provides its size if so.
-
- 'MEM_SIZE (X)'
- The size in bytes of the memory reference. This is mostly
- relevant for 'BLKmode' references as otherwise the size is
- implied by the mode. The value is only valid if
- 'MEM_SIZE_KNOWN_P (X)' is true.
-
- 'MEM_ALIGN (X)'
- The known alignment in bits of the memory reference.
-
- 'MEM_ADDR_SPACE (X)'
- The address space of the memory reference. This will commonly
- be zero for the generic address space.
-
- 'REG'
- 'ORIGINAL_REGNO (X)'
- This field holds the number the register "originally" had; for
- a pseudo register turned into a hard reg this will hold the
- old pseudo register number.
-
- 'REG_EXPR (X)'
- If this register is known to hold the value of some user-level
- declaration, this is that tree node.
-
- 'REG_OFFSET (X)'
- If this register is known to hold the value of some user-level
- declaration, this is the offset into that logical storage.
-
- 'SYMBOL_REF'
- 'SYMBOL_REF_DECL (X)'
- If the 'symbol_ref' X was created for a 'VAR_DECL' or a
- 'FUNCTION_DECL', that tree is recorded here. If this value is
- null, then X was created by back end code generation routines,
- and there is no associated front end symbol table entry.
-
- 'SYMBOL_REF_DECL' may also point to a tree of class ''c'',
- that is, some sort of constant. In this case, the
- 'symbol_ref' is an entry in the per-file constant pool; again,
- there is no associated front end symbol table entry.
-
- 'SYMBOL_REF_CONSTANT (X)'
- If 'CONSTANT_POOL_ADDRESS_P (X)' is true, this is the constant
- pool entry for X. It is null otherwise.
-
- 'SYMBOL_REF_DATA (X)'
- A field of opaque type used to store 'SYMBOL_REF_DECL' or
- 'SYMBOL_REF_CONSTANT'.
-
- 'SYMBOL_REF_FLAGS (X)'
- In a 'symbol_ref', this is used to communicate various
- predicates about the symbol. Some of these are common enough
- to be computed by common code, some are specific to the
- target. The common bits are:
-
- 'SYMBOL_FLAG_FUNCTION'
- Set if the symbol refers to a function.
-
- 'SYMBOL_FLAG_LOCAL'
- Set if the symbol is local to this "module". See
- 'TARGET_BINDS_LOCAL_P'.
-
- 'SYMBOL_FLAG_EXTERNAL'
- Set if this symbol is not defined in this translation
- unit. Note that this is not the inverse of
- 'SYMBOL_FLAG_LOCAL'.
-
- 'SYMBOL_FLAG_SMALL'
- Set if the symbol is located in the small data section.
- See 'TARGET_IN_SMALL_DATA_P'.
-
- 'SYMBOL_REF_TLS_MODEL (X)'
- This is a multi-bit field accessor that returns the
- 'tls_model' to be used for a thread-local storage symbol.
- It returns zero for non-thread-local symbols.
-
- 'SYMBOL_FLAG_HAS_BLOCK_INFO'
- Set if the symbol has 'SYMBOL_REF_BLOCK' and
- 'SYMBOL_REF_BLOCK_OFFSET' fields.
-
- 'SYMBOL_FLAG_ANCHOR'
- Set if the symbol is used as a section anchor. "Section
- anchors" are symbols that have a known position within an
- 'object_block' and that can be used to access nearby
- members of that block. They are used to implement
- '-fsection-anchors'.
-
- If this flag is set, then 'SYMBOL_FLAG_HAS_BLOCK_INFO'
- will be too.
-
- Bits beginning with 'SYMBOL_FLAG_MACH_DEP' are available for
- the target's use.
-
- 'SYMBOL_REF_BLOCK (X)'
- If 'SYMBOL_REF_HAS_BLOCK_INFO_P (X)', this is the 'object_block'
- structure to which the symbol belongs, or 'NULL' if it has not been
- assigned a block.
-
- 'SYMBOL_REF_BLOCK_OFFSET (X)'
- If 'SYMBOL_REF_HAS_BLOCK_INFO_P (X)', this is the offset of X from
- the first object in 'SYMBOL_REF_BLOCK (X)'. The value is negative
- if X has not yet been assigned to a block, or it has not been given
- an offset within that block.
-
-
- File: gccint.info, Node: Flags, Next: Machine Modes, Prev: Special Accessors, Up: RTL
-
- 14.5 Flags in an RTL Expression
- ===============================
-
- RTL expressions contain several flags (one-bit bit-fields) that are used
- in certain types of expression. Most often they are accessed with the
- following macros, which expand into lvalues.
-
- 'CROSSING_JUMP_P (X)'
- Nonzero in a 'jump_insn' if it crosses between hot and cold
- sections, which could potentially be very far apart in the
- executable. The presence of this flag indicates to other
- optimizations that this branching instruction should not be
- "collapsed" into a simpler branching construct. It is used when
- the optimization to partition basic blocks into hot and cold
- sections is turned on.
-
- 'CONSTANT_POOL_ADDRESS_P (X)'
- Nonzero in a 'symbol_ref' if it refers to part of the current
- function's constant pool. For most targets these addresses are in
- a '.rodata' section entirely separate from the function, but for
- some targets the addresses are close to the beginning of the
- function. In either case GCC assumes these addresses can be
- addressed directly, perhaps with the help of base registers.
- Stored in the 'unchanging' field and printed as '/u'.
-
- 'INSN_ANNULLED_BRANCH_P (X)'
- In a 'jump_insn', 'call_insn', or 'insn' indicates that the branch
- is an annulling one. See the discussion under 'sequence' below.
- Stored in the 'unchanging' field and printed as '/u'.
-
- 'INSN_DELETED_P (X)'
- In an 'insn', 'call_insn', 'jump_insn', 'code_label',
- 'jump_table_data', 'barrier', or 'note', nonzero if the insn has
- been deleted. Stored in the 'volatil' field and printed as '/v'.
-
- 'INSN_FROM_TARGET_P (X)'
- In an 'insn' or 'jump_insn' or 'call_insn' in a delay slot of a
- branch, indicates that the insn is from the target of the branch.
- If the branch insn has 'INSN_ANNULLED_BRANCH_P' set, this insn will
- only be executed if the branch is taken. For annulled branches
- with 'INSN_FROM_TARGET_P' clear, the insn will be executed only if
- the branch is not taken. When 'INSN_ANNULLED_BRANCH_P' is not set,
- this insn will always be executed. Stored in the 'in_struct' field
- and printed as '/s'.
-
- 'LABEL_PRESERVE_P (X)'
- In a 'code_label' or 'note', indicates that the label is referenced
- by code or data not visible to the RTL of a given function. Labels
- referenced by a non-local goto will have this bit set. Stored in
- the 'in_struct' field and printed as '/s'.
-
- 'LABEL_REF_NONLOCAL_P (X)'
- In 'label_ref' and 'reg_label' expressions, nonzero if this is a
- reference to a non-local label. Stored in the 'volatil' field and
- printed as '/v'.
-
- 'MEM_KEEP_ALIAS_SET_P (X)'
- In 'mem' expressions, 1 if we should keep the alias set for this
- mem unchanged when we access a component. Set to 1, for example,
- when we are already in a non-addressable component of an aggregate.
- Stored in the 'jump' field and printed as '/j'.
-
- 'MEM_VOLATILE_P (X)'
- In 'mem', 'asm_operands', and 'asm_input' expressions, nonzero for
- volatile memory references. Stored in the 'volatil' field and
- printed as '/v'.
-
- 'MEM_NOTRAP_P (X)'
- In 'mem', nonzero for memory references that will not trap. Stored
- in the 'call' field and printed as '/c'.
-
- 'MEM_POINTER (X)'
- Nonzero in a 'mem' if the memory reference holds a pointer. Stored
- in the 'frame_related' field and printed as '/f'.
-
- 'MEM_READONLY_P (X)'
- Nonzero in a 'mem', if the memory is statically allocated and
- read-only.
-
- Read-only in this context means never modified during the lifetime
- of the program, not necessarily in ROM or in write-disabled pages.
- A common example of the later is a shared library's global offset
- table. This table is initialized by the runtime loader, so the
- memory is technically writable, but after control is transferred
- from the runtime loader to the application, this memory will never
- be subsequently modified.
-
- Stored in the 'unchanging' field and printed as '/u'.
-
- 'PREFETCH_SCHEDULE_BARRIER_P (X)'
- In a 'prefetch', indicates that the prefetch is a scheduling
- barrier. No other INSNs will be moved over it. Stored in the
- 'volatil' field and printed as '/v'.
-
- 'REG_FUNCTION_VALUE_P (X)'
- Nonzero in a 'reg' if it is the place in which this function's
- value is going to be returned. (This happens only in a hard
- register.) Stored in the 'return_val' field and printed as '/i'.
-
- 'REG_POINTER (X)'
- Nonzero in a 'reg' if the register holds a pointer. Stored in the
- 'frame_related' field and printed as '/f'.
-
- 'REG_USERVAR_P (X)'
- In a 'reg', nonzero if it corresponds to a variable present in the
- user's source code. Zero for temporaries generated internally by
- the compiler. Stored in the 'volatil' field and printed as '/v'.
-
- The same hard register may be used also for collecting the values
- of functions called by this one, but 'REG_FUNCTION_VALUE_P' is zero
- in this kind of use.
-
- 'RTL_CONST_CALL_P (X)'
- In a 'call_insn' indicates that the insn represents a call to a
- const function. Stored in the 'unchanging' field and printed as
- '/u'.
-
- 'RTL_PURE_CALL_P (X)'
- In a 'call_insn' indicates that the insn represents a call to a
- pure function. Stored in the 'return_val' field and printed as
- '/i'.
-
- 'RTL_CONST_OR_PURE_CALL_P (X)'
- In a 'call_insn', true if 'RTL_CONST_CALL_P' or 'RTL_PURE_CALL_P'
- is true.
-
- 'RTL_LOOPING_CONST_OR_PURE_CALL_P (X)'
- In a 'call_insn' indicates that the insn represents a possibly
- infinite looping call to a const or pure function. Stored in the
- 'call' field and printed as '/c'. Only true if one of
- 'RTL_CONST_CALL_P' or 'RTL_PURE_CALL_P' is true.
-
- 'RTX_FRAME_RELATED_P (X)'
- Nonzero in an 'insn', 'call_insn', 'jump_insn', 'barrier', or 'set'
- which is part of a function prologue and sets the stack pointer,
- sets the frame pointer, or saves a register. This flag should also
- be set on an instruction that sets up a temporary register to use
- in place of the frame pointer. Stored in the 'frame_related' field
- and printed as '/f'.
-
- In particular, on RISC targets where there are limits on the sizes
- of immediate constants, it is sometimes impossible to reach the
- register save area directly from the stack pointer. In that case,
- a temporary register is used that is near enough to the register
- save area, and the Canonical Frame Address, i.e., DWARF2's logical
- frame pointer, register must (temporarily) be changed to be this
- temporary register. So, the instruction that sets this temporary
- register must be marked as 'RTX_FRAME_RELATED_P'.
-
- If the marked instruction is overly complex (defined in terms of
- what 'dwarf2out_frame_debug_expr' can handle), you will also have
- to create a 'REG_FRAME_RELATED_EXPR' note and attach it to the
- instruction. This note should contain a simple expression of the
- computation performed by this instruction, i.e., one that
- 'dwarf2out_frame_debug_expr' can handle.
-
- This flag is required for exception handling support on targets
- with RTL prologues.
-
- 'SCHED_GROUP_P (X)'
- During instruction scheduling, in an 'insn', 'call_insn',
- 'jump_insn' or 'jump_table_data', indicates that the previous insn
- must be scheduled together with this insn. This is used to ensure
- that certain groups of instructions will not be split up by the
- instruction scheduling pass, for example, 'use' insns before a
- 'call_insn' may not be separated from the 'call_insn'. Stored in
- the 'in_struct' field and printed as '/s'.
-
- 'SET_IS_RETURN_P (X)'
- For a 'set', nonzero if it is for a return. Stored in the 'jump'
- field and printed as '/j'.
-
- 'SIBLING_CALL_P (X)'
- For a 'call_insn', nonzero if the insn is a sibling call. Stored
- in the 'jump' field and printed as '/j'.
-
- 'STRING_POOL_ADDRESS_P (X)'
- For a 'symbol_ref' expression, nonzero if it addresses this
- function's string constant pool. Stored in the 'frame_related'
- field and printed as '/f'.
-
- 'SUBREG_PROMOTED_UNSIGNED_P (X)'
- Returns a value greater then zero for a 'subreg' that has
- 'SUBREG_PROMOTED_VAR_P' nonzero if the object being referenced is
- kept zero-extended, zero if it is kept sign-extended, and less then
- zero if it is extended some other way via the 'ptr_extend'
- instruction. Stored in the 'unchanging' field and 'volatil' field,
- printed as '/u' and '/v'. This macro may only be used to get the
- value it may not be used to change the value. Use
- 'SUBREG_PROMOTED_UNSIGNED_SET' to change the value.
-
- 'SUBREG_PROMOTED_UNSIGNED_SET (X)'
- Set the 'unchanging' and 'volatil' fields in a 'subreg' to reflect
- zero, sign, or other extension. If 'volatil' is zero, then
- 'unchanging' as nonzero means zero extension and as zero means sign
- extension. If 'volatil' is nonzero then some other type of
- extension was done via the 'ptr_extend' instruction.
-
- 'SUBREG_PROMOTED_VAR_P (X)'
- Nonzero in a 'subreg' if it was made when accessing an object that
- was promoted to a wider mode in accord with the 'PROMOTED_MODE'
- machine description macro (*note Storage Layout::). In this case,
- the mode of the 'subreg' is the declared mode of the object and the
- mode of 'SUBREG_REG' is the mode of the register that holds the
- object. Promoted variables are always either sign- or
- zero-extended to the wider mode on every assignment. Stored in the
- 'in_struct' field and printed as '/s'.
-
- 'SYMBOL_REF_USED (X)'
- In a 'symbol_ref', indicates that X has been used. This is
- normally only used to ensure that X is only declared external once.
- Stored in the 'used' field.
-
- 'SYMBOL_REF_WEAK (X)'
- In a 'symbol_ref', indicates that X has been declared weak. Stored
- in the 'return_val' field and printed as '/i'.
-
- 'SYMBOL_REF_FLAG (X)'
- In a 'symbol_ref', this is used as a flag for machine-specific
- purposes. Stored in the 'volatil' field and printed as '/v'.
-
- Most uses of 'SYMBOL_REF_FLAG' are historic and may be subsumed by
- 'SYMBOL_REF_FLAGS'. Certainly use of 'SYMBOL_REF_FLAGS' is
- mandatory if the target requires more than one bit of storage.
-
- These are the fields to which the above macros refer:
-
- 'call'
- In a 'mem', 1 means that the memory reference will not trap.
-
- In a 'call', 1 means that this pure or const call may possibly
- infinite loop.
-
- In an RTL dump, this flag is represented as '/c'.
-
- 'frame_related'
- In an 'insn' or 'set' expression, 1 means that it is part of a
- function prologue and sets the stack pointer, sets the frame
- pointer, saves a register, or sets up a temporary register to use
- in place of the frame pointer.
-
- In 'reg' expressions, 1 means that the register holds a pointer.
-
- In 'mem' expressions, 1 means that the memory reference holds a
- pointer.
-
- In 'symbol_ref' expressions, 1 means that the reference addresses
- this function's string constant pool.
-
- In an RTL dump, this flag is represented as '/f'.
-
- 'in_struct'
- In 'reg' expressions, it is 1 if the register has its entire life
- contained within the test expression of some loop.
-
- In 'subreg' expressions, 1 means that the 'subreg' is accessing an
- object that has had its mode promoted from a wider mode.
-
- In 'label_ref' expressions, 1 means that the referenced label is
- outside the innermost loop containing the insn in which the
- 'label_ref' was found.
-
- In 'code_label' expressions, it is 1 if the label may never be
- deleted. This is used for labels which are the target of non-local
- gotos. Such a label that would have been deleted is replaced with
- a 'note' of type 'NOTE_INSN_DELETED_LABEL'.
-
- In an 'insn' during dead-code elimination, 1 means that the insn is
- dead code.
-
- In an 'insn' or 'jump_insn' during reorg for an insn in the delay
- slot of a branch, 1 means that this insn is from the target of the
- branch.
-
- In an 'insn' during instruction scheduling, 1 means that this insn
- must be scheduled as part of a group together with the previous
- insn.
-
- In an RTL dump, this flag is represented as '/s'.
-
- 'return_val'
- In 'reg' expressions, 1 means the register contains the value to be
- returned by the current function. On machines that pass parameters
- in registers, the same register number may be used for parameters
- as well, but this flag is not set on such uses.
-
- In 'symbol_ref' expressions, 1 means the referenced symbol is weak.
-
- In 'call' expressions, 1 means the call is pure.
-
- In an RTL dump, this flag is represented as '/i'.
-
- 'jump'
- In a 'mem' expression, 1 means we should keep the alias set for
- this mem unchanged when we access a component.
-
- In a 'set', 1 means it is for a return.
-
- In a 'call_insn', 1 means it is a sibling call.
-
- In a 'jump_insn', 1 means it is a crossing jump.
-
- In an RTL dump, this flag is represented as '/j'.
-
- 'unchanging'
- In 'reg' and 'mem' expressions, 1 means that the value of the
- expression never changes.
-
- In 'subreg' expressions, it is 1 if the 'subreg' references an
- unsigned object whose mode has been promoted to a wider mode.
-
- In an 'insn' or 'jump_insn' in the delay slot of a branch
- instruction, 1 means an annulling branch should be used.
-
- In a 'symbol_ref' expression, 1 means that this symbol addresses
- something in the per-function constant pool.
-
- In a 'call_insn' 1 means that this instruction is a call to a const
- function.
-
- In an RTL dump, this flag is represented as '/u'.
-
- 'used'
- This flag is used directly (without an access macro) at the end of
- RTL generation for a function, to count the number of times an
- expression appears in insns. Expressions that appear more than
- once are copied, according to the rules for shared structure (*note
- Sharing::).
-
- For a 'reg', it is used directly (without an access macro) by the
- leaf register renumbering code to ensure that each register is only
- renumbered once.
-
- In a 'symbol_ref', it indicates that an external declaration for
- the symbol has already been written.
-
- 'volatil'
- In a 'mem', 'asm_operands', or 'asm_input' expression, it is 1 if
- the memory reference is volatile. Volatile memory references may
- not be deleted, reordered or combined.
-
- In a 'symbol_ref' expression, it is used for machine-specific
- purposes.
-
- In a 'reg' expression, it is 1 if the value is a user-level
- variable. 0 indicates an internal compiler temporary.
-
- In an 'insn', 1 means the insn has been deleted.
-
- In 'label_ref' and 'reg_label' expressions, 1 means a reference to
- a non-local label.
-
- In 'prefetch' expressions, 1 means that the containing insn is a
- scheduling barrier.
-
- In an RTL dump, this flag is represented as '/v'.
-
-
- File: gccint.info, Node: Machine Modes, Next: Constants, Prev: Flags, Up: RTL
-
- 14.6 Machine Modes
- ==================
-
- A machine mode describes a size of data object and the representation
- used for it. In the C code, machine modes are represented by an
- enumeration type, 'machine_mode', defined in 'machmode.def'. Each RTL
- expression has room for a machine mode and so do certain kinds of tree
- expressions (declarations and types, to be precise).
-
- In debugging dumps and machine descriptions, the machine mode of an RTL
- expression is written after the expression code with a colon to separate
- them. The letters 'mode' which appear at the end of each machine mode
- name are omitted. For example, '(reg:SI 38)' is a 'reg' expression with
- machine mode 'SImode'. If the mode is 'VOIDmode', it is not written at
- all.
-
- Here is a table of machine modes. The term "byte" below refers to an
- object of 'BITS_PER_UNIT' bits (*note Storage Layout::).
-
- 'BImode'
- "Bit" mode represents a single bit, for predicate registers.
-
- 'QImode'
- "Quarter-Integer" mode represents a single byte treated as an
- integer.
-
- 'HImode'
- "Half-Integer" mode represents a two-byte integer.
-
- 'PSImode'
- "Partial Single Integer" mode represents an integer which occupies
- four bytes but which doesn't really use all four. On some
- machines, this is the right mode to use for pointers.
-
- 'SImode'
- "Single Integer" mode represents a four-byte integer.
-
- 'PDImode'
- "Partial Double Integer" mode represents an integer which occupies
- eight bytes but which doesn't really use all eight. On some
- machines, this is the right mode to use for certain pointers.
-
- 'DImode'
- "Double Integer" mode represents an eight-byte integer.
-
- 'TImode'
- "Tetra Integer" (?) mode represents a sixteen-byte integer.
-
- 'OImode'
- "Octa Integer" (?) mode represents a thirty-two-byte integer.
-
- 'XImode'
- "Hexadeca Integer" (?) mode represents a sixty-four-byte integer.
-
- 'QFmode'
- "Quarter-Floating" mode represents a quarter-precision (single
- byte) floating point number.
-
- 'HFmode'
- "Half-Floating" mode represents a half-precision (two byte)
- floating point number.
-
- 'TQFmode'
- "Three-Quarter-Floating" (?) mode represents a
- three-quarter-precision (three byte) floating point number.
-
- 'SFmode'
- "Single Floating" mode represents a four byte floating point
- number. In the common case, of a processor with IEEE arithmetic
- and 8-bit bytes, this is a single-precision IEEE floating point
- number; it can also be used for double-precision (on processors
- with 16-bit bytes) and single-precision VAX and IBM types.
-
- 'DFmode'
- "Double Floating" mode represents an eight byte floating point
- number. In the common case, of a processor with IEEE arithmetic
- and 8-bit bytes, this is a double-precision IEEE floating point
- number.
-
- 'XFmode'
- "Extended Floating" mode represents an IEEE extended floating point
- number. This mode only has 80 meaningful bits (ten bytes). Some
- processors require such numbers to be padded to twelve bytes,
- others to sixteen; this mode is used for either.
-
- 'SDmode'
- "Single Decimal Floating" mode represents a four byte decimal
- floating point number (as distinct from conventional binary
- floating point).
-
- 'DDmode'
- "Double Decimal Floating" mode represents an eight byte decimal
- floating point number.
-
- 'TDmode'
- "Tetra Decimal Floating" mode represents a sixteen byte decimal
- floating point number all 128 of whose bits are meaningful.
-
- 'TFmode'
- "Tetra Floating" mode represents a sixteen byte floating point
- number all 128 of whose bits are meaningful. One common use is the
- IEEE quad-precision format.
-
- 'QQmode'
- "Quarter-Fractional" mode represents a single byte treated as a
- signed fractional number. The default format is "s.7".
-
- 'HQmode'
- "Half-Fractional" mode represents a two-byte signed fractional
- number. The default format is "s.15".
-
- 'SQmode'
- "Single Fractional" mode represents a four-byte signed fractional
- number. The default format is "s.31".
-
- 'DQmode'
- "Double Fractional" mode represents an eight-byte signed fractional
- number. The default format is "s.63".
-
- 'TQmode'
- "Tetra Fractional" mode represents a sixteen-byte signed fractional
- number. The default format is "s.127".
-
- 'UQQmode'
- "Unsigned Quarter-Fractional" mode represents a single byte treated
- as an unsigned fractional number. The default format is ".8".
-
- 'UHQmode'
- "Unsigned Half-Fractional" mode represents a two-byte unsigned
- fractional number. The default format is ".16".
-
- 'USQmode'
- "Unsigned Single Fractional" mode represents a four-byte unsigned
- fractional number. The default format is ".32".
-
- 'UDQmode'
- "Unsigned Double Fractional" mode represents an eight-byte unsigned
- fractional number. The default format is ".64".
-
- 'UTQmode'
- "Unsigned Tetra Fractional" mode represents a sixteen-byte unsigned
- fractional number. The default format is ".128".
-
- 'HAmode'
- "Half-Accumulator" mode represents a two-byte signed accumulator.
- The default format is "s8.7".
-
- 'SAmode'
- "Single Accumulator" mode represents a four-byte signed
- accumulator. The default format is "s16.15".
-
- 'DAmode'
- "Double Accumulator" mode represents an eight-byte signed
- accumulator. The default format is "s32.31".
-
- 'TAmode'
- "Tetra Accumulator" mode represents a sixteen-byte signed
- accumulator. The default format is "s64.63".
-
- 'UHAmode'
- "Unsigned Half-Accumulator" mode represents a two-byte unsigned
- accumulator. The default format is "8.8".
-
- 'USAmode'
- "Unsigned Single Accumulator" mode represents a four-byte unsigned
- accumulator. The default format is "16.16".
-
- 'UDAmode'
- "Unsigned Double Accumulator" mode represents an eight-byte
- unsigned accumulator. The default format is "32.32".
-
- 'UTAmode'
- "Unsigned Tetra Accumulator" mode represents a sixteen-byte
- unsigned accumulator. The default format is "64.64".
-
- 'CCmode'
- "Condition Code" mode represents the value of a condition code,
- which is a machine-specific set of bits used to represent the
- result of a comparison operation. Other machine-specific modes may
- also be used for the condition code. These modes are not used on
- machines that use 'cc0' (*note Condition Code::).
-
- 'BLKmode'
- "Block" mode represents values that are aggregates to which none of
- the other modes apply. In RTL, only memory references can have
- this mode, and only if they appear in string-move or vector
- instructions. On machines which have no such instructions,
- 'BLKmode' will not appear in RTL.
-
- 'VOIDmode'
- Void mode means the absence of a mode or an unspecified mode. For
- example, RTL expressions of code 'const_int' have mode 'VOIDmode'
- because they can be taken to have whatever mode the context
- requires. In debugging dumps of RTL, 'VOIDmode' is expressed by
- the absence of any mode.
-
- 'QCmode, HCmode, SCmode, DCmode, XCmode, TCmode'
- These modes stand for a complex number represented as a pair of
- floating point values. The floating point values are in 'QFmode',
- 'HFmode', 'SFmode', 'DFmode', 'XFmode', and 'TFmode', respectively.
-
- 'CQImode, CHImode, CSImode, CDImode, CTImode, COImode, CPSImode'
- These modes stand for a complex number represented as a pair of
- integer values. The integer values are in 'QImode', 'HImode',
- 'SImode', 'DImode', 'TImode', 'OImode', and 'PSImode',
- respectively.
-
- 'BND32mode BND64mode'
- These modes stand for bounds for pointer of 32 and 64 bit size
- respectively. Mode size is double pointer mode size.
-
- The machine description defines 'Pmode' as a C macro which expands into
- the machine mode used for addresses. Normally this is the mode whose
- size is 'BITS_PER_WORD', 'SImode' on 32-bit machines.
-
- The only modes which a machine description must support are 'QImode',
- and the modes corresponding to 'BITS_PER_WORD', 'FLOAT_TYPE_SIZE' and
- 'DOUBLE_TYPE_SIZE'. The compiler will attempt to use 'DImode' for
- 8-byte structures and unions, but this can be prevented by overriding
- the definition of 'MAX_FIXED_MODE_SIZE'. Alternatively, you can have
- the compiler use 'TImode' for 16-byte structures and unions. Likewise,
- you can arrange for the C type 'short int' to avoid using 'HImode'.
-
- Very few explicit references to machine modes remain in the compiler
- and these few references will soon be removed. Instead, the machine
- modes are divided into mode classes. These are represented by the
- enumeration type 'enum mode_class' defined in 'machmode.h'. The
- possible mode classes are:
-
- 'MODE_INT'
- Integer modes. By default these are 'BImode', 'QImode', 'HImode',
- 'SImode', 'DImode', 'TImode', and 'OImode'.
-
- 'MODE_PARTIAL_INT'
- The "partial integer" modes, 'PQImode', 'PHImode', 'PSImode' and
- 'PDImode'.
-
- 'MODE_FLOAT'
- Floating point modes. By default these are 'QFmode', 'HFmode',
- 'TQFmode', 'SFmode', 'DFmode', 'XFmode' and 'TFmode'.
-
- 'MODE_DECIMAL_FLOAT'
- Decimal floating point modes. By default these are 'SDmode',
- 'DDmode' and 'TDmode'.
-
- 'MODE_FRACT'
- Signed fractional modes. By default these are 'QQmode', 'HQmode',
- 'SQmode', 'DQmode' and 'TQmode'.
-
- 'MODE_UFRACT'
- Unsigned fractional modes. By default these are 'UQQmode',
- 'UHQmode', 'USQmode', 'UDQmode' and 'UTQmode'.
-
- 'MODE_ACCUM'
- Signed accumulator modes. By default these are 'HAmode', 'SAmode',
- 'DAmode' and 'TAmode'.
-
- 'MODE_UACCUM'
- Unsigned accumulator modes. By default these are 'UHAmode',
- 'USAmode', 'UDAmode' and 'UTAmode'.
-
- 'MODE_COMPLEX_INT'
- Complex integer modes. (These are not currently implemented).
-
- 'MODE_COMPLEX_FLOAT'
- Complex floating point modes. By default these are 'QCmode',
- 'HCmode', 'SCmode', 'DCmode', 'XCmode', and 'TCmode'.
-
- 'MODE_CC'
- Modes representing condition code values. These are 'CCmode' plus
- any 'CC_MODE' modes listed in the 'MACHINE-modes.def'. *Note Jump
- Patterns::, also see *note Condition Code::.
-
- 'MODE_POINTER_BOUNDS'
- Pointer bounds modes. Used to represent values of pointer bounds
- type. Operations in these modes may be executed as NOPs depending
- on hardware features and environment setup.
-
- 'MODE_RANDOM'
- This is a catchall mode class for modes which don't fit into the
- above classes. Currently 'VOIDmode' and 'BLKmode' are in
- 'MODE_RANDOM'.
-
- 'machmode.h' also defines various wrapper classes that combine a
- 'machine_mode' with a static assertion that a particular condition
- holds. The classes are:
-
- 'scalar_int_mode'
- A mode that has class 'MODE_INT' or 'MODE_PARTIAL_INT'.
-
- 'scalar_float_mode'
- A mode that has class 'MODE_FLOAT' or 'MODE_DECIMAL_FLOAT'.
-
- 'scalar_mode'
- A mode that holds a single numerical value. In practice this means
- that the mode is a 'scalar_int_mode', is a 'scalar_float_mode', or
- has class 'MODE_FRACT', 'MODE_UFRACT', 'MODE_ACCUM', 'MODE_UACCUM'
- or 'MODE_POINTER_BOUNDS'.
-
- 'complex_mode'
- A mode that has class 'MODE_COMPLEX_INT' or 'MODE_COMPLEX_FLOAT'.
-
- 'fixed_size_mode'
- A mode whose size is known at compile time.
-
- Named modes use the most constrained of the available wrapper classes,
- if one exists, otherwise they use 'machine_mode'. For example, 'QImode'
- is a 'scalar_int_mode', 'SFmode' is a 'scalar_float_mode' and 'BLKmode'
- is a plain 'machine_mode'. It is possible to refer to any mode as a raw
- 'machine_mode' by adding the 'E_' prefix, where 'E' stands for
- "enumeration". For example, the raw 'machine_mode' names of the modes
- just mentioned are 'E_QImode', 'E_SFmode' and 'E_BLKmode' respectively.
-
- The wrapper classes implicitly convert to 'machine_mode' and to any
- wrapper class that represents a more general condition; for example
- 'scalar_int_mode' and 'scalar_float_mode' both convert to 'scalar_mode'
- and all three convert to 'fixed_size_mode'. The classes act like
- 'machine_mode's that accept only certain named modes.
-
- 'machmode.h' also defines a template class 'opt_mode<T>' that holds a
- 'T' or nothing, where 'T' can be either 'machine_mode' or one of the
- wrapper classes above. The main operations on an 'opt_mode<T>' X are as
- follows:
-
- 'X.exists ()'
- Return true if X holds a mode rather than nothing.
-
- 'X.exists (&Y)'
- Return true if X holds a mode rather than nothing, storing the mode
- in Y if so. Y must be assignment-compatible with T.
-
- 'X.require ()'
- Assert that X holds a mode rather than nothing and return that
- mode.
-
- 'X = Y'
- Set X to Y, where Y is a T or implicitly converts to a T.
-
- The default constructor sets an 'opt_mode<T>' to nothing. There is
- also a constructor that takes an initial value of type T.
-
- It is possible to use the 'is-a.h' accessors on a 'machine_mode' or
- machine mode wrapper X:
-
- 'is_a <T> (X)'
- Return true if X meets the conditions for wrapper class T.
-
- 'is_a <T> (X, &Y)'
- Return true if X meets the conditions for wrapper class T, storing
- it in Y if so. Y must be assignment-compatible with T.
-
- 'as_a <T> (X)'
- Assert that X meets the conditions for wrapper class T and return
- it as a T.
-
- 'dyn_cast <T> (X)'
- Return an 'opt_mode<T>' that holds X if X meets the conditions for
- wrapper class T and that holds nothing otherwise.
-
- The purpose of these wrapper classes is to give stronger static type
- checking. For example, if a function takes a 'scalar_int_mode', a
- caller that has a general 'machine_mode' must either check or assert
- that the code is indeed a scalar integer first, using one of the
- functions above.
-
- The wrapper classes are normal C++ classes, with user-defined
- constructors. Sometimes it is useful to have a POD version of the same
- type, particularly if the type appears in a 'union'. The template class
- 'pod_mode<T>' provides a POD version of wrapper class T. It is
- assignment-compatible with T and implicitly converts to both
- 'machine_mode' and T.
-
- Here are some C macros that relate to machine modes:
-
- 'GET_MODE (X)'
- Returns the machine mode of the RTX X.
-
- 'PUT_MODE (X, NEWMODE)'
- Alters the machine mode of the RTX X to be NEWMODE.
-
- 'NUM_MACHINE_MODES'
- Stands for the number of machine modes available on the target
- machine. This is one greater than the largest numeric value of any
- machine mode.
-
- 'GET_MODE_NAME (M)'
- Returns the name of mode M as a string.
-
- 'GET_MODE_CLASS (M)'
- Returns the mode class of mode M.
-
- 'GET_MODE_WIDER_MODE (M)'
- Returns the next wider natural mode. For example, the expression
- 'GET_MODE_WIDER_MODE (QImode)' returns 'HImode'.
-
- 'GET_MODE_SIZE (M)'
- Returns the size in bytes of a datum of mode M.
-
- 'GET_MODE_BITSIZE (M)'
- Returns the size in bits of a datum of mode M.
-
- 'GET_MODE_IBIT (M)'
- Returns the number of integral bits of a datum of fixed-point mode
- M.
-
- 'GET_MODE_FBIT (M)'
- Returns the number of fractional bits of a datum of fixed-point
- mode M.
-
- 'GET_MODE_MASK (M)'
- Returns a bitmask containing 1 for all bits in a word that fit
- within mode M. This macro can only be used for modes whose bitsize
- is less than or equal to 'HOST_BITS_PER_INT'.
-
- 'GET_MODE_ALIGNMENT (M)'
- Return the required alignment, in bits, for an object of mode M.
-
- 'GET_MODE_UNIT_SIZE (M)'
- Returns the size in bytes of the subunits of a datum of mode M.
- This is the same as 'GET_MODE_SIZE' except in the case of complex
- modes. For them, the unit size is the size of the real or
- imaginary part.
-
- 'GET_MODE_NUNITS (M)'
- Returns the number of units contained in a mode, i.e.,
- 'GET_MODE_SIZE' divided by 'GET_MODE_UNIT_SIZE'.
-
- 'GET_CLASS_NARROWEST_MODE (C)'
- Returns the narrowest mode in mode class C.
-
- The following 3 variables are defined on every target. They can be
- used to allocate buffers that are guaranteed to be large enough to hold
- any value that can be represented on the target. The first two can be
- overridden by defining them in the target's mode.def file, however, the
- value must be a constant that can determined very early in the
- compilation process. The third symbol cannot be overridden.
-
- 'BITS_PER_UNIT'
- The number of bits in an addressable storage unit (byte). If you
- do not define this, the default is 8.
-
- 'MAX_BITSIZE_MODE_ANY_INT'
- The maximum bitsize of any mode that is used in integer math. This
- should be overridden by the target if it uses large integers as
- containers for larger vectors but otherwise never uses the contents
- to compute integer values.
-
- 'MAX_BITSIZE_MODE_ANY_MODE'
- The bitsize of the largest mode on the target. The default value
- is the largest mode size given in the mode definition file, which
- is always correct for targets whose modes have a fixed size.
- Targets that might increase the size of a mode beyond this default
- should define 'MAX_BITSIZE_MODE_ANY_MODE' to the actual upper limit
- in 'MACHINE-modes.def'.
-
- The global variables 'byte_mode' and 'word_mode' contain modes whose
- classes are 'MODE_INT' and whose bitsizes are either 'BITS_PER_UNIT' or
- 'BITS_PER_WORD', respectively. On 32-bit machines, these are 'QImode'
- and 'SImode', respectively.
-
-
- File: gccint.info, Node: Constants, Next: Regs and Memory, Prev: Machine Modes, Up: RTL
-
- 14.7 Constant Expression Types
- ==============================
-
- The simplest RTL expressions are those that represent constant values.
-
- '(const_int I)'
- This type of expression represents the integer value I. I is
- customarily accessed with the macro 'INTVAL' as in 'INTVAL (EXP)',
- which is equivalent to 'XWINT (EXP, 0)'.
-
- Constants generated for modes with fewer bits than in
- 'HOST_WIDE_INT' must be sign extended to full width (e.g., with
- 'gen_int_mode'). For constants for modes with more bits than in
- 'HOST_WIDE_INT' the implied high order bits of that constant are
- copies of the top bit. Note however that values are neither
- inherently signed nor inherently unsigned; where necessary,
- signedness is determined by the rtl operation instead.
-
- There is only one expression object for the integer value zero; it
- is the value of the variable 'const0_rtx'. Likewise, the only
- expression for integer value one is found in 'const1_rtx', the only
- expression for integer value two is found in 'const2_rtx', and the
- only expression for integer value negative one is found in
- 'constm1_rtx'. Any attempt to create an expression of code
- 'const_int' and value zero, one, two or negative one will return
- 'const0_rtx', 'const1_rtx', 'const2_rtx' or 'constm1_rtx' as
- appropriate.
-
- Similarly, there is only one object for the integer whose value is
- 'STORE_FLAG_VALUE'. It is found in 'const_true_rtx'. If
- 'STORE_FLAG_VALUE' is one, 'const_true_rtx' and 'const1_rtx' will
- point to the same object. If 'STORE_FLAG_VALUE' is -1,
- 'const_true_rtx' and 'constm1_rtx' will point to the same object.
-
- '(const_double:M I0 I1 ...)'
- This represents either a floating-point constant of mode M or (on
- older ports that do not define 'TARGET_SUPPORTS_WIDE_INT') an
- integer constant too large to fit into 'HOST_BITS_PER_WIDE_INT'
- bits but small enough to fit within twice that number of bits. In
- the latter case, M will be 'VOIDmode'. For integral values
- constants for modes with more bits than twice the number in
- 'HOST_WIDE_INT' the implied high order bits of that constant are
- copies of the top bit of 'CONST_DOUBLE_HIGH'. Note however that
- integral values are neither inherently signed nor inherently
- unsigned; where necessary, signedness is determined by the rtl
- operation instead.
-
- On more modern ports, 'CONST_DOUBLE' only represents floating point
- values. New ports define 'TARGET_SUPPORTS_WIDE_INT' to make this
- designation.
-
- If M is 'VOIDmode', the bits of the value are stored in I0 and I1.
- I0 is customarily accessed with the macro 'CONST_DOUBLE_LOW' and I1
- with 'CONST_DOUBLE_HIGH'.
-
- If the constant is floating point (regardless of its precision),
- then the number of integers used to store the value depends on the
- size of 'REAL_VALUE_TYPE' (*note Floating Point::). The integers
- represent a floating point number, but not precisely in the target
- machine's or host machine's floating point format. To convert them
- to the precise bit pattern used by the target machine, use the
- macro 'REAL_VALUE_TO_TARGET_DOUBLE' and friends (*note Data
- Output::).
-
- '(const_wide_int:M NUNITS ELT0 ...)'
- This contains an array of 'HOST_WIDE_INT's that is large enough to
- hold any constant that can be represented on the target. This form
- of rtl is only used on targets that define
- 'TARGET_SUPPORTS_WIDE_INT' to be nonzero and then 'CONST_DOUBLE's
- are only used to hold floating-point values. If the target leaves
- 'TARGET_SUPPORTS_WIDE_INT' defined as 0, 'CONST_WIDE_INT's are not
- used and 'CONST_DOUBLE's are as they were before.
-
- The values are stored in a compressed format. The higher-order 0s
- or -1s are not represented if they are just the logical sign
- extension of the number that is represented.
-
- 'CONST_WIDE_INT_VEC (CODE)'
- Returns the entire array of 'HOST_WIDE_INT's that are used to store
- the value. This macro should be rarely used.
-
- 'CONST_WIDE_INT_NUNITS (CODE)'
- The number of 'HOST_WIDE_INT's used to represent the number. Note
- that this generally is smaller than the number of 'HOST_WIDE_INT's
- implied by the mode size.
-
- 'CONST_WIDE_INT_ELT (CODE,I)'
- Returns the 'i'th element of the array. Element 0 is contains the
- low order bits of the constant.
-
- '(const_fixed:M ...)'
- Represents a fixed-point constant of mode M. The operand is a data
- structure of type 'struct fixed_value' and is accessed with the
- macro 'CONST_FIXED_VALUE'. The high part of data is accessed with
- 'CONST_FIXED_VALUE_HIGH'; the low part is accessed with
- 'CONST_FIXED_VALUE_LOW'.
-
- '(const_poly_int:M [C0 C1 ...])'
- Represents a 'poly_int'-style polynomial integer with coefficients
- C0, C1, .... The coefficients are 'wide_int'-based integers rather
- than rtxes. 'CONST_POLY_INT_COEFFS' gives the values of individual
- coefficients (which is mostly only useful in low-level routines)
- and 'const_poly_int_value' gives the full 'poly_int' value.
-
- '(const_vector:M [X0 X1 ...])'
- Represents a vector constant. The values in square brackets are
- elements of the vector, which are always 'const_int',
- 'const_wide_int', 'const_double' or 'const_fixed' expressions.
-
- Each vector constant V is treated as a specific instance of an
- arbitrary-length sequence that itself contains
- 'CONST_VECTOR_NPATTERNS (V)' interleaved patterns. Each pattern
- has the form:
-
- { BASE0, BASE1, BASE1 + STEP, BASE1 + STEP * 2, ... }
-
- The first three elements in each pattern are enough to determine
- the values of the other elements. However, if all STEPs are zero,
- only the first two elements are needed. If in addition each BASE1
- is equal to the corresponding BASE0, only the first element in each
- pattern is needed. The number of determining elements per pattern
- is given by 'CONST_VECTOR_NELTS_PER_PATTERN (V)'.
-
- For example, the constant:
-
- { 0, 1, 2, 6, 3, 8, 4, 10, 5, 12, 6, 14, 7, 16, 8, 18 }
-
- is interpreted as an interleaving of the sequences:
-
- { 0, 2, 3, 4, 5, 6, 7, 8 }
- { 1, 6, 8, 10, 12, 14, 16, 18 }
-
- where the sequences are represented by the following patterns:
-
- BASE0 == 0, BASE1 == 2, STEP == 1
- BASE0 == 1, BASE1 == 6, STEP == 2
-
- In this case:
-
- CONST_VECTOR_NPATTERNS (V) == 2
- CONST_VECTOR_NELTS_PER_PATTERN (V) == 3
-
- Thus the first 6 elements ('{ 0, 1, 2, 6, 3, 8 }') are enough to
- determine the whole sequence; we refer to them as the "encoded"
- elements. They are the only elements present in the square
- brackets for variable-length 'const_vector's (i.e. for
- 'const_vector's whose mode M has a variable number of elements).
- However, as a convenience to code that needs to handle both
- 'const_vector's and 'parallel's, all elements are present in the
- square brackets for fixed-length 'const_vector's; the encoding
- scheme simply reduces the amount of work involved in processing
- constants that follow a regular pattern.
-
- Sometimes this scheme can create two possible encodings of the same
- vector. For example { 0, 1 } could be seen as two patterns with
- one element each or one pattern with two elements (BASE0 and
- BASE1). The canonical encoding is always the one with the fewest
- patterns or (if both encodings have the same number of petterns)
- the one with the fewest encoded elements.
-
- 'const_vector_encoding_nelts (V)' gives the total number of encoded
- elements in V, which is 6 in the example above.
- 'CONST_VECTOR_ENCODED_ELT (V, I)' accesses the value of encoded
- element I.
-
- 'CONST_VECTOR_DUPLICATE_P (V)' is true if V simply contains
- repeated instances of 'CONST_VECTOR_NPATTERNS (V)' values. This is
- a shorthand for testing 'CONST_VECTOR_NELTS_PER_PATTERN (V) == 1'.
-
- 'CONST_VECTOR_STEPPED_P (V)' is true if at least one pattern in V
- has a nonzero step. This is a shorthand for testing
- 'CONST_VECTOR_NELTS_PER_PATTERN (V) == 3'.
-
- 'CONST_VECTOR_NUNITS (V)' gives the total number of elements in V;
- it is a shorthand for getting the number of units in 'GET_MODE
- (V)'.
-
- The utility function 'const_vector_elt' gives the value of an
- arbitrary element as an 'rtx'. 'const_vector_int_elt' gives the
- same value as a 'wide_int'.
-
- '(const_string STR)'
- Represents a constant string with value STR. Currently this is
- used only for insn attributes (*note Insn Attributes::) since
- constant strings in C are placed in memory.
-
- '(symbol_ref:MODE SYMBOL)'
- Represents the value of an assembler label for data. SYMBOL is a
- string that describes the name of the assembler label. If it
- starts with a '*', the label is the rest of SYMBOL not including
- the '*'. Otherwise, the label is SYMBOL, usually prefixed with
- '_'.
-
- The 'symbol_ref' contains a mode, which is usually 'Pmode'.
- Usually that is the only mode for which a symbol is directly valid.
-
- '(label_ref:MODE LABEL)'
- Represents the value of an assembler label for code. It contains
- one operand, an expression, which must be a 'code_label' or a
- 'note' of type 'NOTE_INSN_DELETED_LABEL' that appears in the
- instruction sequence to identify the place where the label should
- go.
-
- The reason for using a distinct expression type for code label
- references is so that jump optimization can distinguish them.
-
- The 'label_ref' contains a mode, which is usually 'Pmode'. Usually
- that is the only mode for which a label is directly valid.
-
- '(const:M EXP)'
- Represents a constant that is the result of an assembly-time
- arithmetic computation. The operand, EXP, contains only
- 'const_int', 'symbol_ref', 'label_ref' or 'unspec' expressions,
- combined with 'plus' and 'minus'. Any such 'unspec's are
- target-specific and typically represent some form of relocation
- operator. M should be a valid address mode.
-
- '(high:M EXP)'
- Represents the high-order bits of EXP. The number of bits is
- machine-dependent and is normally the number of bits specified in
- an instruction that initializes the high order bits of a register.
- It is used with 'lo_sum' to represent the typical two-instruction
- sequence used in RISC machines to reference large immediate values
- and/or link-time constants such as global memory addresses. In the
- latter case, M is 'Pmode' and EXP is usually a constant expression
- involving 'symbol_ref'.
-
- The macro 'CONST0_RTX (MODE)' refers to an expression with value 0 in
- mode MODE. If mode MODE is of mode class 'MODE_INT', it returns
- 'const0_rtx'. If mode MODE is of mode class 'MODE_FLOAT', it returns a
- 'CONST_DOUBLE' expression in mode MODE. Otherwise, it returns a
- 'CONST_VECTOR' expression in mode MODE. Similarly, the macro
- 'CONST1_RTX (MODE)' refers to an expression with value 1 in mode MODE
- and similarly for 'CONST2_RTX'. The 'CONST1_RTX' and 'CONST2_RTX'
- macros are undefined for vector modes.
-
-
- File: gccint.info, Node: Regs and Memory, Next: Arithmetic, Prev: Constants, Up: RTL
-
- 14.8 Registers and Memory
- =========================
-
- Here are the RTL expression types for describing access to machine
- registers and to main memory.
-
- '(reg:M N)'
- For small values of the integer N (those that are less than
- 'FIRST_PSEUDO_REGISTER'), this stands for a reference to machine
- register number N: a "hard register". For larger values of N, it
- stands for a temporary value or "pseudo register". The compiler's
- strategy is to generate code assuming an unlimited number of such
- pseudo registers, and later convert them into hard registers or
- into memory references.
-
- M is the machine mode of the reference. It is necessary because
- machines can generally refer to each register in more than one
- mode. For example, a register may contain a full word but there
- may be instructions to refer to it as a half word or as a single
- byte, as well as instructions to refer to it as a floating point
- number of various precisions.
-
- Even for a register that the machine can access in only one mode,
- the mode must always be specified.
-
- The symbol 'FIRST_PSEUDO_REGISTER' is defined by the machine
- description, since the number of hard registers on the machine is
- an invariant characteristic of the machine. Note, however, that
- not all of the machine registers must be general registers. All
- the machine registers that can be used for storage of data are
- given hard register numbers, even those that can be used only in
- certain instructions or can hold only certain types of data.
-
- A hard register may be accessed in various modes throughout one
- function, but each pseudo register is given a natural mode and is
- accessed only in that mode. When it is necessary to describe an
- access to a pseudo register using a nonnatural mode, a 'subreg'
- expression is used.
-
- A 'reg' expression with a machine mode that specifies more than one
- word of data may actually stand for several consecutive registers.
- If in addition the register number specifies a hardware register,
- then it actually represents several consecutive hardware registers
- starting with the specified one.
-
- Each pseudo register number used in a function's RTL code is
- represented by a unique 'reg' expression.
-
- Some pseudo register numbers, those within the range of
- 'FIRST_VIRTUAL_REGISTER' to 'LAST_VIRTUAL_REGISTER' only appear
- during the RTL generation phase and are eliminated before the
- optimization phases. These represent locations in the stack frame
- that cannot be determined until RTL generation for the function has
- been completed. The following virtual register numbers are
- defined:
-
- 'VIRTUAL_INCOMING_ARGS_REGNUM'
- This points to the first word of the incoming arguments passed
- on the stack. Normally these arguments are placed there by
- the caller, but the callee may have pushed some arguments that
- were previously passed in registers.
-
- When RTL generation is complete, this virtual register is
- replaced by the sum of the register given by
- 'ARG_POINTER_REGNUM' and the value of 'FIRST_PARM_OFFSET'.
-
- 'VIRTUAL_STACK_VARS_REGNUM'
- If 'FRAME_GROWS_DOWNWARD' is defined to a nonzero value, this
- points to immediately above the first variable on the stack.
- Otherwise, it points to the first variable on the stack.
-
- 'VIRTUAL_STACK_VARS_REGNUM' is replaced with the sum of the
- register given by 'FRAME_POINTER_REGNUM' and the value
- 'TARGET_STARTING_FRAME_OFFSET'.
-
- 'VIRTUAL_STACK_DYNAMIC_REGNUM'
- This points to the location of dynamically allocated memory on
- the stack immediately after the stack pointer has been
- adjusted by the amount of memory desired.
-
- This virtual register is replaced by the sum of the register
- given by 'STACK_POINTER_REGNUM' and the value
- 'STACK_DYNAMIC_OFFSET'.
-
- 'VIRTUAL_OUTGOING_ARGS_REGNUM'
- This points to the location in the stack at which outgoing
- arguments should be written when the stack is pre-pushed
- (arguments pushed using push insns should always use
- 'STACK_POINTER_REGNUM').
-
- This virtual register is replaced by the sum of the register
- given by 'STACK_POINTER_REGNUM' and the value
- 'STACK_POINTER_OFFSET'.
-
- '(subreg:M1 REG:M2 BYTENUM)'
-
- 'subreg' expressions are used to refer to a register in a machine
- mode other than its natural one, or to refer to one register of a
- multi-part 'reg' that actually refers to several registers.
-
- Each pseudo register has a natural mode. If it is necessary to
- operate on it in a different mode, the register must be enclosed in
- a 'subreg'.
-
- There are currently three supported types for the first operand of
- a 'subreg':
- * pseudo registers This is the most common case. Most 'subreg's
- have pseudo 'reg's as their first operand.
-
- * mem 'subreg's of 'mem' were common in earlier versions of GCC
- and are still supported. During the reload pass these are
- replaced by plain 'mem's. On machines that do not do
- instruction scheduling, use of 'subreg's of 'mem' are still
- used, but this is no longer recommended. Such 'subreg's are
- considered to be 'register_operand's rather than
- 'memory_operand's before and during reload. Because of this,
- the scheduling passes cannot properly schedule instructions
- with 'subreg's of 'mem', so for machines that do scheduling,
- 'subreg's of 'mem' should never be used. To support this, the
- combine and recog passes have explicit code to inhibit the
- creation of 'subreg's of 'mem' when 'INSN_SCHEDULING' is
- defined.
-
- The use of 'subreg's of 'mem' after the reload pass is an area
- that is not well understood and should be avoided. There is
- still some code in the compiler to support this, but this code
- has possibly rotted. This use of 'subreg's is discouraged and
- will most likely not be supported in the future.
-
- * hard registers It is seldom necessary to wrap hard registers
- in 'subreg's; such registers would normally reduce to a single
- 'reg' rtx. This use of 'subreg's is discouraged and may not
- be supported in the future.
-
- 'subreg's of 'subreg's are not supported. Using
- 'simplify_gen_subreg' is the recommended way to avoid this problem.
-
- 'subreg's come in two distinct flavors, each having its own usage
- and rules:
-
- Paradoxical subregs
- When M1 is strictly wider than M2, the 'subreg' expression is
- called "paradoxical". The canonical test for this class of
- 'subreg' is:
-
- paradoxical_subreg_p (M1, M2)
-
- Paradoxical 'subreg's can be used as both lvalues and rvalues.
- When used as an lvalue, the low-order bits of the source value
- are stored in REG and the high-order bits are discarded. When
- used as an rvalue, the low-order bits of the 'subreg' are
- taken from REG while the high-order bits may or may not be
- defined.
-
- The high-order bits of rvalues are defined in the following
- circumstances:
-
- * 'subreg's of 'mem' When M2 is smaller than a word, the
- macro 'LOAD_EXTEND_OP', can control how the high-order
- bits are defined.
-
- * 'subreg' of 'reg's The upper bits are defined when
- 'SUBREG_PROMOTED_VAR_P' is true.
- 'SUBREG_PROMOTED_UNSIGNED_P' describes what the upper
- bits hold. Such subregs usually represent local
- variables, register variables and parameter pseudo
- variables that have been promoted to a wider mode.
-
- BYTENUM is always zero for a paradoxical 'subreg', even on
- big-endian targets.
-
- For example, the paradoxical 'subreg':
-
- (set (subreg:SI (reg:HI X) 0) Y)
-
- stores the lower 2 bytes of Y in X and discards the upper 2
- bytes. A subsequent:
-
- (set Z (subreg:SI (reg:HI X) 0))
-
- would set the lower two bytes of Z to Y and set the upper two
- bytes to an unknown value assuming 'SUBREG_PROMOTED_VAR_P' is
- false.
-
- Normal subregs
- When M1 is at least as narrow as M2 the 'subreg' expression is
- called "normal".
-
- Normal 'subreg's restrict consideration to certain bits of
- REG. For this purpose, REG is divided into
- individually-addressable blocks in which each block has:
-
- REGMODE_NATURAL_SIZE (M2)
-
- bytes. Usually the value is 'UNITS_PER_WORD'; that is, most
- targets usually treat each word of a register as being
- independently addressable.
-
- There are two types of normal 'subreg'. If M1 is known to be
- no bigger than a block, the 'subreg' refers to the
- least-significant part (or "lowpart") of one block of REG. If
- M1 is known to be larger than a block, the 'subreg' refers to
- two or more complete blocks.
-
- When used as an lvalue, 'subreg' is a block-based accessor.
- Storing to a 'subreg' modifies all the blocks of REG that
- overlap the 'subreg', but it leaves the other blocks of REG
- alone.
-
- When storing to a normal 'subreg' that is smaller than a
- block, the other bits of the referenced block are usually left
- in an undefined state. This laxity makes it easier to
- generate efficient code for such instructions. To represent
- an instruction that preserves all the bits outside of those in
- the 'subreg', use 'strict_low_part' or 'zero_extract' around
- the 'subreg'.
-
- BYTENUM must identify the offset of the first byte of the
- 'subreg' from the start of REG, assuming that REG is laid out
- in memory order. The memory order of bytes is defined by two
- target macros, 'WORDS_BIG_ENDIAN' and 'BYTES_BIG_ENDIAN':
-
- * 'WORDS_BIG_ENDIAN', if set to 1, says that byte number
- zero is part of the most significant word; otherwise, it
- is part of the least significant word.
-
- * 'BYTES_BIG_ENDIAN', if set to 1, says that byte number
- zero is the most significant byte within a word;
- otherwise, it is the least significant byte within a
- word.
-
- On a few targets, 'FLOAT_WORDS_BIG_ENDIAN' disagrees with
- 'WORDS_BIG_ENDIAN'. However, most parts of the compiler treat
- floating point values as if they had the same endianness as
- integer values. This works because they handle them solely as
- a collection of integer values, with no particular numerical
- value. Only real.c and the runtime libraries care about
- 'FLOAT_WORDS_BIG_ENDIAN'.
-
- Thus,
-
- (subreg:HI (reg:SI X) 2)
-
- on a 'BYTES_BIG_ENDIAN', 'UNITS_PER_WORD == 4' target is the
- same as
-
- (subreg:HI (reg:SI X) 0)
-
- on a little-endian, 'UNITS_PER_WORD == 4' target. Both
- 'subreg's access the lower two bytes of register X.
-
- Note that the byte offset is a polynomial integer; it may not
- be a compile-time constant on targets with variable-sized
- modes. However, the restrictions above mean that there are
- only a certain set of acceptable offsets for a given
- combination of M1 and M2. The compiler can always tell which
- blocks a valid subreg occupies, and whether the subreg is a
- lowpart of a block.
-
- A 'MODE_PARTIAL_INT' mode behaves as if it were as wide as the
- corresponding 'MODE_INT' mode, except that it has an unknown number
- of undefined bits. For example:
-
- (subreg:PSI (reg:SI 0) 0)
-
- accesses the whole of '(reg:SI 0)', but the exact relationship
- between the 'PSImode' value and the 'SImode' value is not defined.
- If we assume 'REGMODE_NATURAL_SIZE (DImode) <= 4', then the
- following two 'subreg's:
-
- (subreg:PSI (reg:DI 0) 0)
- (subreg:PSI (reg:DI 0) 4)
-
- represent independent 4-byte accesses to the two halves of '(reg:DI
- 0)'. Both 'subreg's have an unknown number of undefined bits.
-
- If 'REGMODE_NATURAL_SIZE (PSImode) <= 2' then these two 'subreg's:
-
- (subreg:HI (reg:PSI 0) 0)
- (subreg:HI (reg:PSI 0) 2)
-
- represent independent 2-byte accesses that together span the whole
- of '(reg:PSI 0)'. Storing to the first 'subreg' does not affect
- the value of the second, and vice versa. '(reg:PSI 0)' has an
- unknown number of undefined bits, so the assignment:
-
- (set (subreg:HI (reg:PSI 0) 0) (reg:HI 4))
-
- does not guarantee that '(subreg:HI (reg:PSI 0) 0)' has the value
- '(reg:HI 4)'.
-
- The rules above apply to both pseudo REGs and hard REGs. If the
- semantics are not correct for particular combinations of M1, M2 and
- hard REG, the target-specific code must ensure that those
- combinations are never used. For example:
-
- TARGET_CAN_CHANGE_MODE_CLASS (M2, M1, CLASS)
-
- must be false for every class CLASS that includes REG.
-
- GCC must be able to determine at compile time whether a subreg is
- paradoxical, whether it occupies a whole number of blocks, or
- whether it is a lowpart of a block. This means that certain
- combinations of variable-sized mode are not permitted. For
- example, if M2 holds N 'SI' values, where N is greater than zero,
- it is not possible to form a 'DI' 'subreg' of it; such a 'subreg'
- would be paradoxical when N is 1 but not when N is greater than 1.
-
- The first operand of a 'subreg' expression is customarily accessed
- with the 'SUBREG_REG' macro and the second operand is customarily
- accessed with the 'SUBREG_BYTE' macro.
-
- It has been several years since a platform in which
- 'BYTES_BIG_ENDIAN' not equal to 'WORDS_BIG_ENDIAN' has been tested.
- Anyone wishing to support such a platform in the future may be
- confronted with code rot.
-
- '(scratch:M)'
- This represents a scratch register that will be required for the
- execution of a single instruction and not used subsequently. It is
- converted into a 'reg' by either the local register allocator or
- the reload pass.
-
- 'scratch' is usually present inside a 'clobber' operation (*note
- Side Effects::).
-
- '(cc0)'
- This refers to the machine's condition code register. It has no
- operands and may not have a machine mode. There are two ways to
- use it:
-
- * To stand for a complete set of condition code flags. This is
- best on most machines, where each comparison sets the entire
- series of flags.
-
- With this technique, '(cc0)' may be validly used in only two
- contexts: as the destination of an assignment (in test and
- compare instructions) and in comparison operators comparing
- against zero ('const_int' with value zero; that is to say,
- 'const0_rtx').
-
- * To stand for a single flag that is the result of a single
- condition. This is useful on machines that have only a single
- flag bit, and in which comparison instructions must specify
- the condition to test.
-
- With this technique, '(cc0)' may be validly used in only two
- contexts: as the destination of an assignment (in test and
- compare instructions) where the source is a comparison
- operator, and as the first operand of 'if_then_else' (in a
- conditional branch).
-
- There is only one expression object of code 'cc0'; it is the value
- of the variable 'cc0_rtx'. Any attempt to create an expression of
- code 'cc0' will return 'cc0_rtx'.
-
- Instructions can set the condition code implicitly. On many
- machines, nearly all instructions set the condition code based on
- the value that they compute or store. It is not necessary to
- record these actions explicitly in the RTL because the machine
- description includes a prescription for recognizing the
- instructions that do so (by means of the macro 'NOTICE_UPDATE_CC').
- *Note Condition Code::. Only instructions whose sole purpose is to
- set the condition code, and instructions that use the condition
- code, need mention '(cc0)'.
-
- On some machines, the condition code register is given a register
- number and a 'reg' is used instead of '(cc0)'. This is usually the
- preferable approach if only a small subset of instructions modify
- the condition code. Other machines store condition codes in
- general registers; in such cases a pseudo register should be used.
-
- Some machines, such as the SPARC and RS/6000, have two sets of
- arithmetic instructions, one that sets and one that does not set
- the condition code. This is best handled by normally generating
- the instruction that does not set the condition code, and making a
- pattern that both performs the arithmetic and sets the condition
- code register (which would not be '(cc0)' in this case). For
- examples, search for 'addcc' and 'andcc' in 'sparc.md'.
-
- '(pc)'
- This represents the machine's program counter. It has no operands
- and may not have a machine mode. '(pc)' may be validly used only
- in certain specific contexts in jump instructions.
-
- There is only one expression object of code 'pc'; it is the value
- of the variable 'pc_rtx'. Any attempt to create an expression of
- code 'pc' will return 'pc_rtx'.
-
- All instructions that do not jump alter the program counter
- implicitly by incrementing it, but there is no need to mention this
- in the RTL.
-
- '(mem:M ADDR ALIAS)'
- This RTX represents a reference to main memory at an address
- represented by the expression ADDR. M specifies how large a unit
- of memory is accessed. ALIAS specifies an alias set for the
- reference. In general two items are in different alias sets if
- they cannot reference the same memory address.
-
- The construct '(mem:BLK (scratch))' is considered to alias all
- other memories. Thus it may be used as a memory barrier in
- epilogue stack deallocation patterns.
-
- '(concatM RTX RTX)'
- This RTX represents the concatenation of two other RTXs. This is
- used for complex values. It should only appear in the RTL attached
- to declarations and during RTL generation. It should not appear in
- the ordinary insn chain.
-
- '(concatnM [RTX ...])'
- This RTX represents the concatenation of all the RTX to make a
- single value. Like 'concat', this should only appear in
- declarations, and not in the insn chain.
-
-
- File: gccint.info, Node: Arithmetic, Next: Comparisons, Prev: Regs and Memory, Up: RTL
-
- 14.9 RTL Expressions for Arithmetic
- ===================================
-
- Unless otherwise specified, all the operands of arithmetic expressions
- must be valid for mode M. An operand is valid for mode M if it has mode
- M, or if it is a 'const_int' or 'const_double' and M is a mode of class
- 'MODE_INT'.
-
- For commutative binary operations, constants should be placed in the
- second operand.
-
- '(plus:M X Y)'
- '(ss_plus:M X Y)'
- '(us_plus:M X Y)'
-
- These three expressions all represent the sum of the values
- represented by X and Y carried out in machine mode M. They differ
- in their behavior on overflow of integer modes. 'plus' wraps round
- modulo the width of M; 'ss_plus' saturates at the maximum signed
- value representable in M; 'us_plus' saturates at the maximum
- unsigned value.
-
- '(lo_sum:M X Y)'
-
- This expression represents the sum of X and the low-order bits of
- Y. It is used with 'high' (*note Constants::) to represent the
- typical two-instruction sequence used in RISC machines to reference
- large immediate values and/or link-time constants such as global
- memory addresses. In the latter case, M is 'Pmode' and Y is
- usually a constant expression involving 'symbol_ref'.
-
- The number of low order bits is machine-dependent but is normally
- the number of bits in mode M minus the number of bits set by
- 'high'.
-
- '(minus:M X Y)'
- '(ss_minus:M X Y)'
- '(us_minus:M X Y)'
-
- These three expressions represent the result of subtracting Y from
- X, carried out in mode M. Behavior on overflow is the same as for
- the three variants of 'plus' (see above).
-
- '(compare:M X Y)'
- Represents the result of subtracting Y from X for purposes of
- comparison. The result is computed without overflow, as if with
- infinite precision.
-
- Of course, machines cannot really subtract with infinite precision.
- However, they can pretend to do so when only the sign of the result
- will be used, which is the case when the result is stored in the
- condition code. And that is the _only_ way this kind of expression
- may validly be used: as a value to be stored in the condition
- codes, either '(cc0)' or a register. *Note Comparisons::.
-
- The mode M is not related to the modes of X and Y, but instead is
- the mode of the condition code value. If '(cc0)' is used, it is
- 'VOIDmode'. Otherwise it is some mode in class 'MODE_CC', often
- 'CCmode'. *Note Condition Code::. If M is 'VOIDmode' or 'CCmode',
- the operation returns sufficient information (in an unspecified
- format) so that any comparison operator can be applied to the
- result of the 'COMPARE' operation. For other modes in class
- 'MODE_CC', the operation only returns a subset of this information.
-
- Normally, X and Y must have the same mode. Otherwise, 'compare' is
- valid only if the mode of X is in class 'MODE_INT' and Y is a
- 'const_int' or 'const_double' with mode 'VOIDmode'. The mode of X
- determines what mode the comparison is to be done in; thus it must
- not be 'VOIDmode'.
-
- If one of the operands is a constant, it should be placed in the
- second operand and the comparison code adjusted as appropriate.
-
- A 'compare' specifying two 'VOIDmode' constants is not valid since
- there is no way to know in what mode the comparison is to be
- performed; the comparison must either be folded during the
- compilation or the first operand must be loaded into a register
- while its mode is still known.
-
- '(neg:M X)'
- '(ss_neg:M X)'
- '(us_neg:M X)'
- These two expressions represent the negation (subtraction from
- zero) of the value represented by X, carried out in mode M. They
- differ in the behavior on overflow of integer modes. In the case
- of 'neg', the negation of the operand may be a number not
- representable in mode M, in which case it is truncated to M.
- 'ss_neg' and 'us_neg' ensure that an out-of-bounds result saturates
- to the maximum or minimum signed or unsigned value.
-
- '(mult:M X Y)'
- '(ss_mult:M X Y)'
- '(us_mult:M X Y)'
- Represents the signed product of the values represented by X and Y
- carried out in machine mode M. 'ss_mult' and 'us_mult' ensure that
- an out-of-bounds result saturates to the maximum or minimum signed
- or unsigned value.
-
- Some machines support a multiplication that generates a product
- wider than the operands. Write the pattern for this as
-
- (mult:M (sign_extend:M X) (sign_extend:M Y))
-
- where M is wider than the modes of X and Y, which need not be the
- same.
-
- For unsigned widening multiplication, use the same idiom, but with
- 'zero_extend' instead of 'sign_extend'.
-
- '(fma:M X Y Z)'
- Represents the 'fma', 'fmaf', and 'fmal' builtin functions, which
- compute 'X * Y + Z' without doing an intermediate rounding step.
-
- '(div:M X Y)'
- '(ss_div:M X Y)'
- Represents the quotient in signed division of X by Y, carried out
- in machine mode M. If M is a floating point mode, it represents
- the exact quotient; otherwise, the integerized quotient. 'ss_div'
- ensures that an out-of-bounds result saturates to the maximum or
- minimum signed value.
-
- Some machines have division instructions in which the operands and
- quotient widths are not all the same; you should represent such
- instructions using 'truncate' and 'sign_extend' as in,
-
- (truncate:M1 (div:M2 X (sign_extend:M2 Y)))
-
- '(udiv:M X Y)'
- '(us_div:M X Y)'
- Like 'div' but represents unsigned division. 'us_div' ensures that
- an out-of-bounds result saturates to the maximum or minimum
- unsigned value.
-
- '(mod:M X Y)'
- '(umod:M X Y)'
- Like 'div' and 'udiv' but represent the remainder instead of the
- quotient.
-
- '(smin:M X Y)'
- '(smax:M X Y)'
- Represents the smaller (for 'smin') or larger (for 'smax') of X and
- Y, interpreted as signed values in mode M. When used with floating
- point, if both operands are zeros, or if either operand is 'NaN',
- then it is unspecified which of the two operands is returned as the
- result.
-
- '(umin:M X Y)'
- '(umax:M X Y)'
- Like 'smin' and 'smax', but the values are interpreted as unsigned
- integers.
-
- '(not:M X)'
- Represents the bitwise complement of the value represented by X,
- carried out in mode M, which must be a fixed-point machine mode.
-
- '(and:M X Y)'
- Represents the bitwise logical-and of the values represented by X
- and Y, carried out in machine mode M, which must be a fixed-point
- machine mode.
-
- '(ior:M X Y)'
- Represents the bitwise inclusive-or of the values represented by X
- and Y, carried out in machine mode M, which must be a fixed-point
- mode.
-
- '(xor:M X Y)'
- Represents the bitwise exclusive-or of the values represented by X
- and Y, carried out in machine mode M, which must be a fixed-point
- mode.
-
- '(ashift:M X C)'
- '(ss_ashift:M X C)'
- '(us_ashift:M X C)'
- These three expressions represent the result of arithmetically
- shifting X left by C places. They differ in their behavior on
- overflow of integer modes. An 'ashift' operation is a plain shift
- with no special behavior in case of a change in the sign bit;
- 'ss_ashift' and 'us_ashift' saturates to the minimum or maximum
- representable value if any of the bits shifted out differs from the
- final sign bit.
-
- X have mode M, a fixed-point machine mode. C be a fixed-point mode
- or be a constant with mode 'VOIDmode'; which mode is determined by
- the mode called for in the machine description entry for the
- left-shift instruction. For example, on the VAX, the mode of C is
- 'QImode' regardless of M.
-
- '(lshiftrt:M X C)'
- '(ashiftrt:M X C)'
- Like 'ashift' but for right shift. Unlike the case for left shift,
- these two operations are distinct.
-
- '(rotate:M X C)'
- '(rotatert:M X C)'
- Similar but represent left and right rotate. If C is a constant,
- use 'rotate'.
-
- '(abs:M X)'
- '(ss_abs:M X)'
- Represents the absolute value of X, computed in mode M. 'ss_abs'
- ensures that an out-of-bounds result saturates to the maximum
- signed value.
-
- '(sqrt:M X)'
- Represents the square root of X, computed in mode M. Most often M
- will be a floating point mode.
-
- '(ffs:M X)'
- Represents one plus the index of the least significant 1-bit in X,
- represented as an integer of mode M. (The value is zero if X is
- zero.) The mode of X must be M or 'VOIDmode'.
-
- '(clrsb:M X)'
- Represents the number of redundant leading sign bits in X,
- represented as an integer of mode M, starting at the most
- significant bit position. This is one less than the number of
- leading sign bits (either 0 or 1), with no special cases. The mode
- of X must be M or 'VOIDmode'.
-
- '(clz:M X)'
- Represents the number of leading 0-bits in X, represented as an
- integer of mode M, starting at the most significant bit position.
- If X is zero, the value is determined by
- 'CLZ_DEFINED_VALUE_AT_ZERO' (*note Misc::). Note that this is one
- of the few expressions that is not invariant under widening. The
- mode of X must be M or 'VOIDmode'.
-
- '(ctz:M X)'
- Represents the number of trailing 0-bits in X, represented as an
- integer of mode M, starting at the least significant bit position.
- If X is zero, the value is determined by
- 'CTZ_DEFINED_VALUE_AT_ZERO' (*note Misc::). Except for this case,
- 'ctz(x)' is equivalent to 'ffs(X) - 1'. The mode of X must be M or
- 'VOIDmode'.
-
- '(popcount:M X)'
- Represents the number of 1-bits in X, represented as an integer of
- mode M. The mode of X must be M or 'VOIDmode'.
-
- '(parity:M X)'
- Represents the number of 1-bits modulo 2 in X, represented as an
- integer of mode M. The mode of X must be M or 'VOIDmode'.
-
- '(bswap:M X)'
- Represents the value X with the order of bytes reversed, carried
- out in mode M, which must be a fixed-point machine mode. The mode
- of X must be M or 'VOIDmode'.
-
-
- File: gccint.info, Node: Comparisons, Next: Bit-Fields, Prev: Arithmetic, Up: RTL
-
- 14.10 Comparison Operations
- ===========================
-
- Comparison operators test a relation on two operands and are considered
- to represent a machine-dependent nonzero value described by, but not
- necessarily equal to, 'STORE_FLAG_VALUE' (*note Misc::) if the relation
- holds, or zero if it does not, for comparison operators whose results
- have a 'MODE_INT' mode, 'FLOAT_STORE_FLAG_VALUE' (*note Misc::) if the
- relation holds, or zero if it does not, for comparison operators that
- return floating-point values, and a vector of either
- 'VECTOR_STORE_FLAG_VALUE' (*note Misc::) if the relation holds, or of
- zeros if it does not, for comparison operators that return vector
- results. The mode of the comparison operation is independent of the
- mode of the data being compared. If the comparison operation is being
- tested (e.g., the first operand of an 'if_then_else'), the mode must be
- 'VOIDmode'.
-
- There are two ways that comparison operations may be used. The
- comparison operators may be used to compare the condition codes '(cc0)'
- against zero, as in '(eq (cc0) (const_int 0))'. Such a construct
- actually refers to the result of the preceding instruction in which the
- condition codes were set. The instruction setting the condition code
- must be adjacent to the instruction using the condition code; only
- 'note' insns may separate them.
-
- Alternatively, a comparison operation may directly compare two data
- objects. The mode of the comparison is determined by the operands; they
- must both be valid for a common machine mode. A comparison with both
- operands constant would be invalid as the machine mode could not be
- deduced from it, but such a comparison should never exist in RTL due to
- constant folding.
-
- In the example above, if '(cc0)' were last set to '(compare X Y)', the
- comparison operation is identical to '(eq X Y)'. Usually only one style
- of comparisons is supported on a particular machine, but the combine
- pass will try to merge the operations to produce the 'eq' shown in case
- it exists in the context of the particular insn involved.
-
- Inequality comparisons come in two flavors, signed and unsigned. Thus,
- there are distinct expression codes 'gt' and 'gtu' for signed and
- unsigned greater-than. These can produce different results for the same
- pair of integer values: for example, 1 is signed greater-than -1 but not
- unsigned greater-than, because -1 when regarded as unsigned is actually
- '0xffffffff' which is greater than 1.
-
- The signed comparisons are also used for floating point values.
- Floating point comparisons are distinguished by the machine modes of the
- operands.
-
- '(eq:M X Y)'
- 'STORE_FLAG_VALUE' if the values represented by X and Y are equal,
- otherwise 0.
-
- '(ne:M X Y)'
- 'STORE_FLAG_VALUE' if the values represented by X and Y are not
- equal, otherwise 0.
-
- '(gt:M X Y)'
- 'STORE_FLAG_VALUE' if the X is greater than Y. If they are
- fixed-point, the comparison is done in a signed sense.
-
- '(gtu:M X Y)'
- Like 'gt' but does unsigned comparison, on fixed-point numbers
- only.
-
- '(lt:M X Y)'
- '(ltu:M X Y)'
- Like 'gt' and 'gtu' but test for "less than".
-
- '(ge:M X Y)'
- '(geu:M X Y)'
- Like 'gt' and 'gtu' but test for "greater than or equal".
-
- '(le:M X Y)'
- '(leu:M X Y)'
- Like 'gt' and 'gtu' but test for "less than or equal".
-
- '(if_then_else COND THEN ELSE)'
- This is not a comparison operation but is listed here because it is
- always used in conjunction with a comparison operation. To be
- precise, COND is a comparison expression. This expression
- represents a choice, according to COND, between the value
- represented by THEN and the one represented by ELSE.
-
- On most machines, 'if_then_else' expressions are valid only to
- express conditional jumps.
-
- '(cond [TEST1 VALUE1 TEST2 VALUE2 ...] DEFAULT)'
- Similar to 'if_then_else', but more general. Each of TEST1, TEST2,
- ... is performed in turn. The result of this expression is the
- VALUE corresponding to the first nonzero test, or DEFAULT if none
- of the tests are nonzero expressions.
-
- This is currently not valid for instruction patterns and is
- supported only for insn attributes. *Note Insn Attributes::.
-
-
- File: gccint.info, Node: Bit-Fields, Next: Vector Operations, Prev: Comparisons, Up: RTL
-
- 14.11 Bit-Fields
- ================
-
- Special expression codes exist to represent bit-field instructions.
-
- '(sign_extract:M LOC SIZE POS)'
- This represents a reference to a sign-extended bit-field contained
- or starting in LOC (a memory or register reference). The bit-field
- is SIZE bits wide and starts at bit POS. The compilation option
- 'BITS_BIG_ENDIAN' says which end of the memory unit POS counts
- from.
-
- If LOC is in memory, its mode must be a single-byte integer mode.
- If LOC is in a register, the mode to use is specified by the
- operand of the 'insv' or 'extv' pattern (*note Standard Names::)
- and is usually a full-word integer mode, which is the default if
- none is specified.
-
- The mode of POS is machine-specific and is also specified in the
- 'insv' or 'extv' pattern.
-
- The mode M is the same as the mode that would be used for LOC if it
- were a register.
-
- A 'sign_extract' cannot appear as an lvalue, or part thereof, in
- RTL.
-
- '(zero_extract:M LOC SIZE POS)'
- Like 'sign_extract' but refers to an unsigned or zero-extended
- bit-field. The same sequence of bits are extracted, but they are
- filled to an entire word with zeros instead of by sign-extension.
-
- Unlike 'sign_extract', this type of expressions can be lvalues in
- RTL; they may appear on the left side of an assignment, indicating
- insertion of a value into the specified bit-field.
-
-
- File: gccint.info, Node: Vector Operations, Next: Conversions, Prev: Bit-Fields, Up: RTL
-
- 14.12 Vector Operations
- =======================
-
- All normal RTL expressions can be used with vector modes; they are
- interpreted as operating on each part of the vector independently.
- Additionally, there are a few new expressions to describe specific
- vector operations.
-
- '(vec_merge:M VEC1 VEC2 ITEMS)'
- This describes a merge operation between two vectors. The result
- is a vector of mode M; its elements are selected from either VEC1
- or VEC2. Which elements are selected is described by ITEMS, which
- is a bit mask represented by a 'const_int'; a zero bit indicates
- the corresponding element in the result vector is taken from VEC2
- while a set bit indicates it is taken from VEC1.
-
- '(vec_select:M VEC1 SELECTION)'
- This describes an operation that selects parts of a vector. VEC1
- is the source vector, and SELECTION is a 'parallel' that contains a
- 'const_int' (or another expression, if the selection can be made at
- runtime) for each of the subparts of the result vector, giving the
- number of the source subpart that should be stored into it. The
- result mode M is either the submode for a single element of VEC1
- (if only one subpart is selected), or another vector mode with that
- element submode (if multiple subparts are selected).
-
- '(vec_concat:M X1 X2)'
- Describes a vector concat operation. The result is a concatenation
- of the vectors or scalars X1 and X2; its length is the sum of the
- lengths of the two inputs.
-
- '(vec_duplicate:M X)'
- This operation converts a scalar into a vector or a small vector
- into a larger one by duplicating the input values. The output
- vector mode must have the same submodes as the input vector mode or
- the scalar modes, and the number of output parts must be an integer
- multiple of the number of input parts.
-
- '(vec_series:M BASE STEP)'
- This operation creates a vector in which element I is equal to
- 'BASE + I*STEP'. M must be a vector integer mode.
-
-
- File: gccint.info, Node: Conversions, Next: RTL Declarations, Prev: Vector Operations, Up: RTL
-
- 14.13 Conversions
- =================
-
- All conversions between machine modes must be represented by explicit
- conversion operations. For example, an expression which is the sum of a
- byte and a full word cannot be written as '(plus:SI (reg:QI 34) (reg:SI
- 80))' because the 'plus' operation requires two operands of the same
- machine mode. Therefore, the byte-sized operand is enclosed in a
- conversion operation, as in
-
- (plus:SI (sign_extend:SI (reg:QI 34)) (reg:SI 80))
-
- The conversion operation is not a mere placeholder, because there may
- be more than one way of converting from a given starting mode to the
- desired final mode. The conversion operation code says how to do it.
-
- For all conversion operations, X must not be 'VOIDmode' because the
- mode in which to do the conversion would not be known. The conversion
- must either be done at compile-time or X must be placed into a register.
-
- '(sign_extend:M X)'
- Represents the result of sign-extending the value X to machine mode
- M. M must be a fixed-point mode and X a fixed-point value of a
- mode narrower than M.
-
- '(zero_extend:M X)'
- Represents the result of zero-extending the value X to machine mode
- M. M must be a fixed-point mode and X a fixed-point value of a
- mode narrower than M.
-
- '(float_extend:M X)'
- Represents the result of extending the value X to machine mode M.
- M must be a floating point mode and X a floating point value of a
- mode narrower than M.
-
- '(truncate:M X)'
- Represents the result of truncating the value X to machine mode M.
- M must be a fixed-point mode and X a fixed-point value of a mode
- wider than M.
-
- '(ss_truncate:M X)'
- Represents the result of truncating the value X to machine mode M,
- using signed saturation in the case of overflow. Both M and the
- mode of X must be fixed-point modes.
-
- '(us_truncate:M X)'
- Represents the result of truncating the value X to machine mode M,
- using unsigned saturation in the case of overflow. Both M and the
- mode of X must be fixed-point modes.
-
- '(float_truncate:M X)'
- Represents the result of truncating the value X to machine mode M.
- M must be a floating point mode and X a floating point value of a
- mode wider than M.
-
- '(float:M X)'
- Represents the result of converting fixed point value X, regarded
- as signed, to floating point mode M.
-
- '(unsigned_float:M X)'
- Represents the result of converting fixed point value X, regarded
- as unsigned, to floating point mode M.
-
- '(fix:M X)'
- When M is a floating-point mode, represents the result of
- converting floating point value X (valid for mode M) to an integer,
- still represented in floating point mode M, by rounding towards
- zero.
-
- When M is a fixed-point mode, represents the result of converting
- floating point value X to mode M, regarded as signed. How rounding
- is done is not specified, so this operation may be used validly in
- compiling C code only for integer-valued operands.
-
- '(unsigned_fix:M X)'
- Represents the result of converting floating point value X to fixed
- point mode M, regarded as unsigned. How rounding is done is not
- specified.
-
- '(fract_convert:M X)'
- Represents the result of converting fixed-point value X to
- fixed-point mode M, signed integer value X to fixed-point mode M,
- floating-point value X to fixed-point mode M, fixed-point value X
- to integer mode M regarded as signed, or fixed-point value X to
- floating-point mode M. When overflows or underflows happen, the
- results are undefined.
-
- '(sat_fract:M X)'
- Represents the result of converting fixed-point value X to
- fixed-point mode M, signed integer value X to fixed-point mode M,
- or floating-point value X to fixed-point mode M. When overflows or
- underflows happen, the results are saturated to the maximum or the
- minimum.
-
- '(unsigned_fract_convert:M X)'
- Represents the result of converting fixed-point value X to integer
- mode M regarded as unsigned, or unsigned integer value X to
- fixed-point mode M. When overflows or underflows happen, the
- results are undefined.
-
- '(unsigned_sat_fract:M X)'
- Represents the result of converting unsigned integer value X to
- fixed-point mode M. When overflows or underflows happen, the
- results are saturated to the maximum or the minimum.
-
-
- File: gccint.info, Node: RTL Declarations, Next: Side Effects, Prev: Conversions, Up: RTL
-
- 14.14 Declarations
- ==================
-
- Declaration expression codes do not represent arithmetic operations but
- rather state assertions about their operands.
-
- '(strict_low_part (subreg:M (reg:N R) 0))'
- This expression code is used in only one context: as the
- destination operand of a 'set' expression. In addition, the
- operand of this expression must be a non-paradoxical 'subreg'
- expression.
-
- The presence of 'strict_low_part' says that the part of the
- register which is meaningful in mode N, but is not part of mode M,
- is not to be altered. Normally, an assignment to such a subreg is
- allowed to have undefined effects on the rest of the register when
- M is smaller than 'REGMODE_NATURAL_SIZE (N)'.
-
-
- File: gccint.info, Node: Side Effects, Next: Incdec, Prev: RTL Declarations, Up: RTL
-
- 14.15 Side Effect Expressions
- =============================
-
- The expression codes described so far represent values, not actions.
- But machine instructions never produce values; they are meaningful only
- for their side effects on the state of the machine. Special expression
- codes are used to represent side effects.
-
- The body of an instruction is always one of these side effect codes;
- the codes described above, which represent values, appear only as the
- operands of these.
-
- '(set LVAL X)'
- Represents the action of storing the value of X into the place
- represented by LVAL. LVAL must be an expression representing a
- place that can be stored in: 'reg' (or 'subreg', 'strict_low_part'
- or 'zero_extract'), 'mem', 'pc', 'parallel', or 'cc0'.
-
- If LVAL is a 'reg', 'subreg' or 'mem', it has a machine mode; then
- X must be valid for that mode.
-
- If LVAL is a 'reg' whose machine mode is less than the full width
- of the register, then it means that the part of the register
- specified by the machine mode is given the specified value and the
- rest of the register receives an undefined value. Likewise, if
- LVAL is a 'subreg' whose machine mode is narrower than the mode of
- the register, the rest of the register can be changed in an
- undefined way.
-
- If LVAL is a 'strict_low_part' of a subreg, then the part of the
- register specified by the machine mode of the 'subreg' is given the
- value X and the rest of the register is not changed.
-
- If LVAL is a 'zero_extract', then the referenced part of the
- bit-field (a memory or register reference) specified by the
- 'zero_extract' is given the value X and the rest of the bit-field
- is not changed. Note that 'sign_extract' cannot appear in LVAL.
-
- If LVAL is '(cc0)', it has no machine mode, and X may be either a
- 'compare' expression or a value that may have any mode. The latter
- case represents a "test" instruction. The expression '(set (cc0)
- (reg:M N))' is equivalent to '(set (cc0) (compare (reg:M N)
- (const_int 0)))'. Use the former expression to save space during
- the compilation.
-
- If LVAL is a 'parallel', it is used to represent the case of a
- function returning a structure in multiple registers. Each element
- of the 'parallel' is an 'expr_list' whose first operand is a 'reg'
- and whose second operand is a 'const_int' representing the offset
- (in bytes) into the structure at which the data in that register
- corresponds. The first element may be null to indicate that the
- structure is also passed partly in memory.
-
- If LVAL is '(pc)', we have a jump instruction, and the
- possibilities for X are very limited. It may be a 'label_ref'
- expression (unconditional jump). It may be an 'if_then_else'
- (conditional jump), in which case either the second or the third
- operand must be '(pc)' (for the case which does not jump) and the
- other of the two must be a 'label_ref' (for the case which does
- jump). X may also be a 'mem' or '(plus:SI (pc) Y)', where Y may be
- a 'reg' or a 'mem'; these unusual patterns are used to represent
- jumps through branch tables.
-
- If LVAL is neither '(cc0)' nor '(pc)', the mode of LVAL must not be
- 'VOIDmode' and the mode of X must be valid for the mode of LVAL.
-
- LVAL is customarily accessed with the 'SET_DEST' macro and X with
- the 'SET_SRC' macro.
-
- '(return)'
- As the sole expression in a pattern, represents a return from the
- current function, on machines where this can be done with one
- instruction, such as VAXen. On machines where a multi-instruction
- "epilogue" must be executed in order to return from the function,
- returning is done by jumping to a label which precedes the
- epilogue, and the 'return' expression code is never used.
-
- Inside an 'if_then_else' expression, represents the value to be
- placed in 'pc' to return to the caller.
-
- Note that an insn pattern of '(return)' is logically equivalent to
- '(set (pc) (return))', but the latter form is never used.
-
- '(simple_return)'
- Like '(return)', but truly represents only a function return, while
- '(return)' may represent an insn that also performs other functions
- of the function epilogue. Like '(return)', this may also occur in
- conditional jumps.
-
- '(call FUNCTION NARGS)'
- Represents a function call. FUNCTION is a 'mem' expression whose
- address is the address of the function to be called. NARGS is an
- expression which can be used for two purposes: on some machines it
- represents the number of bytes of stack argument; on others, it
- represents the number of argument registers.
-
- Each machine has a standard machine mode which FUNCTION must have.
- The machine description defines macro 'FUNCTION_MODE' to expand
- into the requisite mode name. The purpose of this mode is to
- specify what kind of addressing is allowed, on machines where the
- allowed kinds of addressing depend on the machine mode being
- addressed.
-
- '(clobber X)'
- Represents the storing or possible storing of an unpredictable,
- undescribed value into X, which must be a 'reg', 'scratch',
- 'parallel' or 'mem' expression.
-
- One place this is used is in string instructions that store
- standard values into particular hard registers. It may not be
- worth the trouble to describe the values that are stored, but it is
- essential to inform the compiler that the registers will be
- altered, lest it attempt to keep data in them across the string
- instruction.
-
- If X is '(mem:BLK (const_int 0))' or '(mem:BLK (scratch))', it
- means that all memory locations must be presumed clobbered. If X
- is a 'parallel', it has the same meaning as a 'parallel' in a 'set'
- expression.
-
- Note that the machine description classifies certain hard registers
- as "call-clobbered". All function call instructions are assumed by
- default to clobber these registers, so there is no need to use
- 'clobber' expressions to indicate this fact. Also, each function
- call is assumed to have the potential to alter any memory location,
- unless the function is declared 'const'.
-
- If the last group of expressions in a 'parallel' are each a
- 'clobber' expression whose arguments are 'reg' or 'match_scratch'
- (*note RTL Template::) expressions, the combiner phase can add the
- appropriate 'clobber' expressions to an insn it has constructed
- when doing so will cause a pattern to be matched.
-
- This feature can be used, for example, on a machine that whose
- multiply and add instructions don't use an MQ register but which
- has an add-accumulate instruction that does clobber the MQ
- register. Similarly, a combined instruction might require a
- temporary register while the constituent instructions might not.
-
- When a 'clobber' expression for a register appears inside a
- 'parallel' with other side effects, the register allocator
- guarantees that the register is unoccupied both before and after
- that insn if it is a hard register clobber. For pseudo-register
- clobber, the register allocator and the reload pass do not assign
- the same hard register to the clobber and the input operands if
- there is an insn alternative containing the '&' constraint (*note
- Modifiers::) for the clobber and the hard register is in register
- classes of the clobber in the alternative. You can clobber either
- a specific hard register, a pseudo register, or a 'scratch'
- expression; in the latter two cases, GCC will allocate a hard
- register that is available there for use as a temporary.
-
- For instructions that require a temporary register, you should use
- 'scratch' instead of a pseudo-register because this will allow the
- combiner phase to add the 'clobber' when required. You do this by
- coding ('clobber' ('match_scratch' ...)). If you do clobber a
- pseudo register, use one which appears nowhere else--generate a new
- one each time. Otherwise, you may confuse CSE.
-
- There is one other known use for clobbering a pseudo register in a
- 'parallel': when one of the input operands of the insn is also
- clobbered by the insn. In this case, using the same pseudo
- register in the clobber and elsewhere in the insn produces the
- expected results.
-
- '(use X)'
- Represents the use of the value of X. It indicates that the value
- in X at this point in the program is needed, even though it may not
- be apparent why this is so. Therefore, the compiler will not
- attempt to delete previous instructions whose only effect is to
- store a value in X. X must be a 'reg' expression.
-
- In some situations, it may be tempting to add a 'use' of a register
- in a 'parallel' to describe a situation where the value of a
- special register will modify the behavior of the instruction. A
- hypothetical example might be a pattern for an addition that can
- either wrap around or use saturating addition depending on the
- value of a special control register:
-
- (parallel [(set (reg:SI 2) (unspec:SI [(reg:SI 3)
- (reg:SI 4)] 0))
- (use (reg:SI 1))])
-
-
- This will not work, several of the optimizers only look at
- expressions locally; it is very likely that if you have multiple
- insns with identical inputs to the 'unspec', they will be optimized
- away even if register 1 changes in between.
-
- This means that 'use' can _only_ be used to describe that the
- register is live. You should think twice before adding 'use'
- statements, more often you will want to use 'unspec' instead. The
- 'use' RTX is most commonly useful to describe that a fixed register
- is implicitly used in an insn. It is also safe to use in patterns
- where the compiler knows for other reasons that the result of the
- whole pattern is variable, such as 'cpymemM' or 'call' patterns.
-
- During the reload phase, an insn that has a 'use' as pattern can
- carry a reg_equal note. These 'use' insns will be deleted before
- the reload phase exits.
-
- During the delayed branch scheduling phase, X may be an insn. This
- indicates that X previously was located at this place in the code
- and its data dependencies need to be taken into account. These
- 'use' insns will be deleted before the delayed branch scheduling
- phase exits.
-
- '(parallel [X0 X1 ...])'
- Represents several side effects performed in parallel. The square
- brackets stand for a vector; the operand of 'parallel' is a vector
- of expressions. X0, X1 and so on are individual side effect
- expressions--expressions of code 'set', 'call', 'return',
- 'simple_return', 'clobber' or 'use'.
-
- "In parallel" means that first all the values used in the
- individual side-effects are computed, and second all the actual
- side-effects are performed. For example,
-
- (parallel [(set (reg:SI 1) (mem:SI (reg:SI 1)))
- (set (mem:SI (reg:SI 1)) (reg:SI 1))])
-
- says unambiguously that the values of hard register 1 and the
- memory location addressed by it are interchanged. In both places
- where '(reg:SI 1)' appears as a memory address it refers to the
- value in register 1 _before_ the execution of the insn.
-
- It follows that it is _incorrect_ to use 'parallel' and expect the
- result of one 'set' to be available for the next one. For example,
- people sometimes attempt to represent a jump-if-zero instruction
- this way:
-
- (parallel [(set (cc0) (reg:SI 34))
- (set (pc) (if_then_else
- (eq (cc0) (const_int 0))
- (label_ref ...)
- (pc)))])
-
- But this is incorrect, because it says that the jump condition
- depends on the condition code value _before_ this instruction, not
- on the new value that is set by this instruction.
-
- Peephole optimization, which takes place together with final
- assembly code output, can produce insns whose patterns consist of a
- 'parallel' whose elements are the operands needed to output the
- resulting assembler code--often 'reg', 'mem' or constant
- expressions. This would not be well-formed RTL at any other stage
- in compilation, but it is OK then because no further optimization
- remains to be done. However, the definition of the macro
- 'NOTICE_UPDATE_CC', if any, must deal with such insns if you define
- any peephole optimizations.
-
- '(cond_exec [COND EXPR])'
- Represents a conditionally executed expression. The EXPR is
- executed only if the COND is nonzero. The COND expression must not
- have side-effects, but the EXPR may very well have side-effects.
-
- '(sequence [INSNS ...])'
- Represents a sequence of insns. If a 'sequence' appears in the
- chain of insns, then each of the INSNS that appears in the sequence
- must be suitable for appearing in the chain of insns, i.e. must
- satisfy the 'INSN_P' predicate.
-
- After delay-slot scheduling is completed, an insn and all the insns
- that reside in its delay slots are grouped together into a
- 'sequence'. The insn requiring the delay slot is the first insn in
- the vector; subsequent insns are to be placed in the delay slot.
-
- 'INSN_ANNULLED_BRANCH_P' is set on an insn in a delay slot to
- indicate that a branch insn should be used that will conditionally
- annul the effect of the insns in the delay slots. In such a case,
- 'INSN_FROM_TARGET_P' indicates that the insn is from the target of
- the branch and should be executed only if the branch is taken;
- otherwise the insn should be executed only if the branch is not
- taken. *Note Delay Slots::.
-
- Some back ends also use 'sequence' objects for purposes other than
- delay-slot groups. This is not supported in the common parts of
- the compiler, which treat such sequences as delay-slot groups.
-
- DWARF2 Call Frame Address (CFA) adjustments are sometimes also
- expressed using 'sequence' objects as the value of a
- 'RTX_FRAME_RELATED_P' note. This only happens if the CFA
- adjustments cannot be easily derived from the pattern of the
- instruction to which the note is attached. In such cases, the
- value of the note is used instead of best-guesing the semantics of
- the instruction. The back end can attach notes containing a
- 'sequence' of 'set' patterns that express the effect of the parent
- instruction.
-
- These expression codes appear in place of a side effect, as the body of
- an insn, though strictly speaking they do not always describe side
- effects as such:
-
- '(asm_input S)'
- Represents literal assembler code as described by the string S.
-
- '(unspec [OPERANDS ...] INDEX)'
- '(unspec_volatile [OPERANDS ...] INDEX)'
- Represents a machine-specific operation on OPERANDS. INDEX selects
- between multiple machine-specific operations. 'unspec_volatile' is
- used for volatile operations and operations that may trap; 'unspec'
- is used for other operations.
-
- These codes may appear inside a 'pattern' of an insn, inside a
- 'parallel', or inside an expression.
-
- '(addr_vec:M [LR0 LR1 ...])'
- Represents a table of jump addresses. The vector elements LR0,
- etc., are 'label_ref' expressions. The mode M specifies how much
- space is given to each address; normally M would be 'Pmode'.
-
- '(addr_diff_vec:M BASE [LR0 LR1 ...] MIN MAX FLAGS)'
- Represents a table of jump addresses expressed as offsets from
- BASE. The vector elements LR0, etc., are 'label_ref' expressions
- and so is BASE. The mode M specifies how much space is given to
- each address-difference. MIN and MAX are set up by branch
- shortening and hold a label with a minimum and a maximum address,
- respectively. FLAGS indicates the relative position of BASE, MIN
- and MAX to the containing insn and of MIN and MAX to BASE. See
- rtl.def for details.
-
- '(prefetch:M ADDR RW LOCALITY)'
- Represents prefetch of memory at address ADDR. Operand RW is 1 if
- the prefetch is for data to be written, 0 otherwise; targets that
- do not support write prefetches should treat this as a normal
- prefetch. Operand LOCALITY specifies the amount of temporal
- locality; 0 if there is none or 1, 2, or 3 for increasing levels of
- temporal locality; targets that do not support locality hints
- should ignore this.
-
- This insn is used to minimize cache-miss latency by moving data
- into a cache before it is accessed. It should use only
- non-faulting data prefetch instructions.
-
-
- File: gccint.info, Node: Incdec, Next: Assembler, Prev: Side Effects, Up: RTL
-
- 14.16 Embedded Side-Effects on Addresses
- ========================================
-
- Six special side-effect expression codes appear as memory addresses.
-
- '(pre_dec:M X)'
- Represents the side effect of decrementing X by a standard amount
- and represents also the value that X has after being decremented.
- X must be a 'reg' or 'mem', but most machines allow only a 'reg'.
- M must be the machine mode for pointers on the machine in use. The
- amount X is decremented by is the length in bytes of the machine
- mode of the containing memory reference of which this expression
- serves as the address. Here is an example of its use:
-
- (mem:DF (pre_dec:SI (reg:SI 39)))
-
- This says to decrement pseudo register 39 by the length of a
- 'DFmode' value and use the result to address a 'DFmode' value.
-
- '(pre_inc:M X)'
- Similar, but specifies incrementing X instead of decrementing it.
-
- '(post_dec:M X)'
- Represents the same side effect as 'pre_dec' but a different value.
- The value represented here is the value X has before being
- decremented.
-
- '(post_inc:M X)'
- Similar, but specifies incrementing X instead of decrementing it.
-
- '(post_modify:M X Y)'
-
- Represents the side effect of setting X to Y and represents X
- before X is modified. X must be a 'reg' or 'mem', but most
- machines allow only a 'reg'. M must be the machine mode for
- pointers on the machine in use.
-
- The expression Y must be one of three forms: '(plus:M X Z)',
- '(minus:M X Z)', or '(plus:M X I)', where Z is an index register
- and I is a constant.
-
- Here is an example of its use:
-
- (mem:SF (post_modify:SI (reg:SI 42) (plus (reg:SI 42)
- (reg:SI 48))))
-
- This says to modify pseudo register 42 by adding the contents of
- pseudo register 48 to it, after the use of what ever 42 points to.
-
- '(pre_modify:M X EXPR)'
- Similar except side effects happen before the use.
-
- These embedded side effect expressions must be used with care.
- Instruction patterns may not use them. Until the 'flow' pass of the
- compiler, they may occur only to represent pushes onto the stack. The
- 'flow' pass finds cases where registers are incremented or decremented
- in one instruction and used as an address shortly before or after; these
- cases are then transformed to use pre- or post-increment or -decrement.
-
- If a register used as the operand of these expressions is used in
- another address in an insn, the original value of the register is used.
- Uses of the register outside of an address are not permitted within the
- same insn as a use in an embedded side effect expression because such
- insns behave differently on different machines and hence must be treated
- as ambiguous and disallowed.
-
- An instruction that can be represented with an embedded side effect
- could also be represented using 'parallel' containing an additional
- 'set' to describe how the address register is altered. This is not done
- because machines that allow these operations at all typically allow them
- wherever a memory address is called for. Describing them as additional
- parallel stores would require doubling the number of entries in the
- machine description.
-
-
- File: gccint.info, Node: Assembler, Next: Debug Information, Prev: Incdec, Up: RTL
-
- 14.17 Assembler Instructions as Expressions
- ===========================================
-
- The RTX code 'asm_operands' represents a value produced by a
- user-specified assembler instruction. It is used to represent an 'asm'
- statement with arguments. An 'asm' statement with a single output
- operand, like this:
-
- asm ("foo %1,%2,%0" : "=a" (outputvar) : "g" (x + y), "di" (*z));
-
- is represented using a single 'asm_operands' RTX which represents the
- value that is stored in 'outputvar':
-
- (set RTX-FOR-OUTPUTVAR
- (asm_operands "foo %1,%2,%0" "a" 0
- [RTX-FOR-ADDITION-RESULT RTX-FOR-*Z]
- [(asm_input:M1 "g")
- (asm_input:M2 "di")]))
-
- Here the operands of the 'asm_operands' RTX are the assembler template
- string, the output-operand's constraint, the index-number of the output
- operand among the output operands specified, a vector of input operand
- RTX's, and a vector of input-operand modes and constraints. The mode M1
- is the mode of the sum 'x+y'; M2 is that of '*z'.
-
- When an 'asm' statement has multiple output values, its insn has
- several such 'set' RTX's inside of a 'parallel'. Each 'set' contains an
- 'asm_operands'; all of these share the same assembler template and
- vectors, but each contains the constraint for the respective output
- operand. They are also distinguished by the output-operand index
- number, which is 0, 1, ... for successive output operands.
-
-
- File: gccint.info, Node: Debug Information, Next: Insns, Prev: Assembler, Up: RTL
-
- 14.18 Variable Location Debug Information in RTL
- ================================================
-
- Variable tracking relies on 'MEM_EXPR' and 'REG_EXPR' annotations to
- determine what user variables memory and register references refer to.
-
- Variable tracking at assignments uses these notes only when they refer
- to variables that live at fixed locations (e.g., addressable variables,
- global non-automatic variables). For variables whose location may vary,
- it relies on the following types of notes.
-
- '(var_location:MODE VAR EXP STAT)'
- Binds variable 'var', a tree, to value EXP, an RTL expression. It
- appears only in 'NOTE_INSN_VAR_LOCATION' and 'DEBUG_INSN's, with
- slightly different meanings. MODE, if present, represents the mode
- of EXP, which is useful if it is a modeless expression. STAT is
- only meaningful in notes, indicating whether the variable is known
- to be initialized or uninitialized.
-
- '(debug_expr:MODE DECL)'
- Stands for the value bound to the 'DEBUG_EXPR_DECL' DECL, that
- points back to it, within value expressions in 'VAR_LOCATION'
- nodes.
-
- '(debug_implicit_ptr:MODE DECL)'
- Stands for the location of a DECL that is no longer addressable.
-
- '(entry_value:MODE DECL)'
- Stands for the value a DECL had at the entry point of the
- containing function.
-
- '(debug_parameter_ref:MODE DECL)'
- Refers to a parameter that was completely optimized out.
-
- '(debug_marker:MODE)'
- Marks a program location. With 'VOIDmode', it stands for the
- beginning of a statement, a recommended inspection point logically
- after all prior side effects, and before any subsequent side
- effects. With 'BLKmode', it indicates an inline entry point: the
- lexical block encoded in the 'INSN_LOCATION' is the enclosing block
- that encloses the inlined function.
-
-
- File: gccint.info, Node: Insns, Next: Calls, Prev: Debug Information, Up: RTL
-
- 14.19 Insns
- ===========
-
- The RTL representation of the code for a function is a doubly-linked
- chain of objects called "insns". Insns are expressions with special
- codes that are used for no other purpose. Some insns are actual
- instructions; others represent dispatch tables for 'switch' statements;
- others represent labels to jump to or various sorts of declarative
- information.
-
- In addition to its own specific data, each insn must have a unique
- id-number that distinguishes it from all other insns in the current
- function (after delayed branch scheduling, copies of an insn with the
- same id-number may be present in multiple places in a function, but
- these copies will always be identical and will only appear inside a
- 'sequence'), and chain pointers to the preceding and following insns.
- These three fields occupy the same position in every insn, independent
- of the expression code of the insn. They could be accessed with 'XEXP'
- and 'XINT', but instead three special macros are always used:
-
- 'INSN_UID (I)'
- Accesses the unique id of insn I.
-
- 'PREV_INSN (I)'
- Accesses the chain pointer to the insn preceding I. If I is the
- first insn, this is a null pointer.
-
- 'NEXT_INSN (I)'
- Accesses the chain pointer to the insn following I. If I is the
- last insn, this is a null pointer.
-
- The first insn in the chain is obtained by calling 'get_insns'; the
- last insn is the result of calling 'get_last_insn'. Within the chain
- delimited by these insns, the 'NEXT_INSN' and 'PREV_INSN' pointers must
- always correspond: if INSN is not the first insn,
-
- NEXT_INSN (PREV_INSN (INSN)) == INSN
-
- is always true and if INSN is not the last insn,
-
- PREV_INSN (NEXT_INSN (INSN)) == INSN
-
- is always true.
-
- After delay slot scheduling, some of the insns in the chain might be
- 'sequence' expressions, which contain a vector of insns. The value of
- 'NEXT_INSN' in all but the last of these insns is the next insn in the
- vector; the value of 'NEXT_INSN' of the last insn in the vector is the
- same as the value of 'NEXT_INSN' for the 'sequence' in which it is
- contained. Similar rules apply for 'PREV_INSN'.
-
- This means that the above invariants are not necessarily true for insns
- inside 'sequence' expressions. Specifically, if INSN is the first insn
- in a 'sequence', 'NEXT_INSN (PREV_INSN (INSN))' is the insn containing
- the 'sequence' expression, as is the value of 'PREV_INSN (NEXT_INSN
- (INSN))' if INSN is the last insn in the 'sequence' expression. You can
- use these expressions to find the containing 'sequence' expression.
-
- Every insn has one of the following expression codes:
-
- 'insn'
- The expression code 'insn' is used for instructions that do not
- jump and do not do function calls. 'sequence' expressions are
- always contained in insns with code 'insn' even if one of those
- insns should jump or do function calls.
-
- Insns with code 'insn' have four additional fields beyond the three
- mandatory ones listed above. These four are described in a table
- below.
-
- 'jump_insn'
- The expression code 'jump_insn' is used for instructions that may
- jump (or, more generally, may contain 'label_ref' expressions to
- which 'pc' can be set in that instruction). If there is an
- instruction to return from the current function, it is recorded as
- a 'jump_insn'.
-
- 'jump_insn' insns have the same extra fields as 'insn' insns,
- accessed in the same way and in addition contain a field
- 'JUMP_LABEL' which is defined once jump optimization has completed.
-
- For simple conditional and unconditional jumps, this field contains
- the 'code_label' to which this insn will (possibly conditionally)
- branch. In a more complex jump, 'JUMP_LABEL' records one of the
- labels that the insn refers to; other jump target labels are
- recorded as 'REG_LABEL_TARGET' notes. The exception is 'addr_vec'
- and 'addr_diff_vec', where 'JUMP_LABEL' is 'NULL_RTX' and the only
- way to find the labels is to scan the entire body of the insn.
-
- Return insns count as jumps, but their 'JUMP_LABEL' is 'RETURN' or
- 'SIMPLE_RETURN'.
-
- 'call_insn'
- The expression code 'call_insn' is used for instructions that may
- do function calls. It is important to distinguish these
- instructions because they imply that certain registers and memory
- locations may be altered unpredictably.
-
- 'call_insn' insns have the same extra fields as 'insn' insns,
- accessed in the same way and in addition contain a field
- 'CALL_INSN_FUNCTION_USAGE', which contains a list (chain of
- 'expr_list' expressions) containing 'use', 'clobber' and sometimes
- 'set' expressions that denote hard registers and 'mem's used or
- clobbered by the called function.
-
- A 'mem' generally points to a stack slot in which arguments passed
- to the libcall by reference (*note TARGET_PASS_BY_REFERENCE:
- Register Arguments.) are stored. If the argument is caller-copied
- (*note TARGET_CALLEE_COPIES: Register Arguments.), the stack slot
- will be mentioned in 'clobber' and 'use' entries; if it's
- callee-copied, only a 'use' will appear, and the 'mem' may point to
- addresses that are not stack slots.
-
- Registers occurring inside a 'clobber' in this list augment
- registers specified in 'CALL_USED_REGISTERS' (*note Register
- Basics::).
-
- If the list contains a 'set' involving two registers, it indicates
- that the function returns one of its arguments. Such a 'set' may
- look like a no-op if the same register holds the argument and the
- return value.
-
- 'code_label'
- A 'code_label' insn represents a label that a jump insn can jump
- to. It contains two special fields of data in addition to the
- three standard ones. 'CODE_LABEL_NUMBER' is used to hold the
- "label number", a number that identifies this label uniquely among
- all the labels in the compilation (not just in the current
- function). Ultimately, the label is represented in the assembler
- output as an assembler label, usually of the form 'LN' where N is
- the label number.
-
- When a 'code_label' appears in an RTL expression, it normally
- appears within a 'label_ref' which represents the address of the
- label, as a number.
-
- Besides as a 'code_label', a label can also be represented as a
- 'note' of type 'NOTE_INSN_DELETED_LABEL'.
-
- The field 'LABEL_NUSES' is only defined once the jump optimization
- phase is completed. It contains the number of times this label is
- referenced in the current function.
-
- The field 'LABEL_KIND' differentiates four different types of
- labels: 'LABEL_NORMAL', 'LABEL_STATIC_ENTRY', 'LABEL_GLOBAL_ENTRY',
- and 'LABEL_WEAK_ENTRY'. The only labels that do not have type
- 'LABEL_NORMAL' are "alternate entry points" to the current
- function. These may be static (visible only in the containing
- translation unit), global (exposed to all translation units), or
- weak (global, but can be overridden by another symbol with the same
- name).
-
- Much of the compiler treats all four kinds of label identically.
- Some of it needs to know whether or not a label is an alternate
- entry point; for this purpose, the macro 'LABEL_ALT_ENTRY_P' is
- provided. It is equivalent to testing whether 'LABEL_KIND (label)
- == LABEL_NORMAL'. The only place that cares about the distinction
- between static, global, and weak alternate entry points, besides
- the front-end code that creates them, is the function
- 'output_alternate_entry_point', in 'final.c'.
-
- To set the kind of a label, use the 'SET_LABEL_KIND' macro.
-
- 'jump_table_data'
- A 'jump_table_data' insn is a placeholder for the jump-table data
- of a 'casesi' or 'tablejump' insn. They are placed after a
- 'tablejump_p' insn. A 'jump_table_data' insn is not part o a basic
- blockm but it is associated with the basic block that ends with the
- 'tablejump_p' insn. The 'PATTERN' of a 'jump_table_data' is always
- either an 'addr_vec' or an 'addr_diff_vec', and a 'jump_table_data'
- insn is always preceded by a 'code_label'. The 'tablejump_p' insn
- refers to that 'code_label' via its 'JUMP_LABEL'.
-
- 'barrier'
- Barriers are placed in the instruction stream when control cannot
- flow past them. They are placed after unconditional jump
- instructions to indicate that the jumps are unconditional and after
- calls to 'volatile' functions, which do not return (e.g., 'exit').
- They contain no information beyond the three standard fields.
-
- 'note'
- 'note' insns are used to represent additional debugging and
- declarative information. They contain two nonstandard fields, an
- integer which is accessed with the macro 'NOTE_LINE_NUMBER' and a
- string accessed with 'NOTE_SOURCE_FILE'.
-
- If 'NOTE_LINE_NUMBER' is positive, the note represents the position
- of a source line and 'NOTE_SOURCE_FILE' is the source file name
- that the line came from. These notes control generation of line
- number data in the assembler output.
-
- Otherwise, 'NOTE_LINE_NUMBER' is not really a line number but a
- code with one of the following values (and 'NOTE_SOURCE_FILE' must
- contain a null pointer):
-
- 'NOTE_INSN_DELETED'
- Such a note is completely ignorable. Some passes of the
- compiler delete insns by altering them into notes of this
- kind.
-
- 'NOTE_INSN_DELETED_LABEL'
- This marks what used to be a 'code_label', but was not used
- for other purposes than taking its address and was transformed
- to mark that no code jumps to it.
-
- 'NOTE_INSN_BLOCK_BEG'
- 'NOTE_INSN_BLOCK_END'
- These types of notes indicate the position of the beginning
- and end of a level of scoping of variable names. They control
- the output of debugging information.
-
- 'NOTE_INSN_EH_REGION_BEG'
- 'NOTE_INSN_EH_REGION_END'
- These types of notes indicate the position of the beginning
- and end of a level of scoping for exception handling.
- 'NOTE_EH_HANDLER' identifies which region is associated with
- these notes.
-
- 'NOTE_INSN_FUNCTION_BEG'
- Appears at the start of the function body, after the function
- prologue.
-
- 'NOTE_INSN_VAR_LOCATION'
- This note is used to generate variable location debugging
- information. It indicates that the user variable in its
- 'VAR_LOCATION' operand is at the location given in the RTL
- expression, or holds a value that can be computed by
- evaluating the RTL expression from that static point in the
- program up to the next such note for the same user variable.
-
- 'NOTE_INSN_BEGIN_STMT'
- This note is used to generate 'is_stmt' markers in line number
- debuggign information. It indicates the beginning of a user
- statement.
-
- 'NOTE_INSN_INLINE_ENTRY'
- This note is used to generate 'entry_pc' for inlined
- subroutines in debugging information. It indicates an
- inspection point at which all arguments for the inlined
- function have been bound, and before its first statement.
-
- These codes are printed symbolically when they appear in debugging
- dumps.
-
- 'debug_insn'
- The expression code 'debug_insn' is used for pseudo-instructions
- that hold debugging information for variable tracking at
- assignments (see '-fvar-tracking-assignments' option). They are
- the RTL representation of 'GIMPLE_DEBUG' statements (*note
- GIMPLE_DEBUG::), with a 'VAR_LOCATION' operand that binds a user
- variable tree to an RTL representation of the 'value' in the
- corresponding statement. A 'DEBUG_EXPR' in it stands for the value
- bound to the corresponding 'DEBUG_EXPR_DECL'.
-
- 'GIMPLE_DEBUG_BEGIN_STMT' and 'GIMPLE_DEBUG_INLINE_ENTRY' are
- expanded to RTL as a 'DEBUG_INSN' with a 'DEBUG_MARKER' 'PATTERN';
- the difference is the RTL mode: the former's 'DEBUG_MARKER' is
- 'VOIDmode', whereas the latter is 'BLKmode'; information about the
- inlined function can be taken from the lexical block encoded in the
- 'INSN_LOCATION'. These 'DEBUG_INSN's, that do not carry
- 'VAR_LOCATION' information, just 'DEBUG_MARKER's, can be detected
- by testing 'DEBUG_MARKER_INSN_P', whereas those that do can be
- recognized as 'DEBUG_BIND_INSN_P'.
-
- Throughout optimization passes, 'DEBUG_INSN's are not reordered
- with respect to each other, particularly during scheduling.
- Binding information is kept in pseudo-instruction form, so that,
- unlike notes, it gets the same treatment and adjustments that
- regular instructions would. It is the variable tracking pass that
- turns these pseudo-instructions into 'NOTE_INSN_VAR_LOCATION',
- 'NOTE_INSN_BEGIN_STMT' and 'NOTE_INSN_INLINE_ENTRY' notes,
- analyzing control flow, value equivalences and changes to registers
- and memory referenced in value expressions, propagating the values
- of debug temporaries and determining expressions that can be used
- to compute the value of each user variable at as many points
- (ranges, actually) in the program as possible.
-
- Unlike 'NOTE_INSN_VAR_LOCATION', the value expression in an
- 'INSN_VAR_LOCATION' denotes a value at that specific point in the
- program, rather than an expression that can be evaluated at any
- later point before an overriding 'VAR_LOCATION' is encountered.
- E.g., if a user variable is bound to a 'REG' and then a subsequent
- insn modifies the 'REG', the note location would keep mapping the
- user variable to the register across the insn, whereas the insn
- location would keep the variable bound to the value, so that the
- variable tracking pass would emit another location note for the
- variable at the point in which the register is modified.
-
- The machine mode of an insn is normally 'VOIDmode', but some phases use
- the mode for various purposes.
-
- The common subexpression elimination pass sets the mode of an insn to
- 'QImode' when it is the first insn in a block that has already been
- processed.
-
- The second Haifa scheduling pass, for targets that can multiple issue,
- sets the mode of an insn to 'TImode' when it is believed that the
- instruction begins an issue group. That is, when the instruction cannot
- issue simultaneously with the previous. This may be relied on by later
- passes, in particular machine-dependent reorg.
-
- Here is a table of the extra fields of 'insn', 'jump_insn' and
- 'call_insn' insns:
-
- 'PATTERN (I)'
- An expression for the side effect performed by this insn. This
- must be one of the following codes: 'set', 'call', 'use',
- 'clobber', 'return', 'simple_return', 'asm_input', 'asm_output',
- 'addr_vec', 'addr_diff_vec', 'trap_if', 'unspec',
- 'unspec_volatile', 'parallel', 'cond_exec', or 'sequence'. If it
- is a 'parallel', each element of the 'parallel' must be one these
- codes, except that 'parallel' expressions cannot be nested and
- 'addr_vec' and 'addr_diff_vec' are not permitted inside a
- 'parallel' expression.
-
- 'INSN_CODE (I)'
- An integer that says which pattern in the machine description
- matches this insn, or -1 if the matching has not yet been
- attempted.
-
- Such matching is never attempted and this field remains -1 on an
- insn whose pattern consists of a single 'use', 'clobber',
- 'asm_input', 'addr_vec' or 'addr_diff_vec' expression.
-
- Matching is also never attempted on insns that result from an 'asm'
- statement. These contain at least one 'asm_operands' expression.
- The function 'asm_noperands' returns a non-negative value for such
- insns.
-
- In the debugging output, this field is printed as a number followed
- by a symbolic representation that locates the pattern in the 'md'
- file as some small positive or negative offset from a named
- pattern.
-
- 'LOG_LINKS (I)'
- A list (chain of 'insn_list' expressions) giving information about
- dependencies between instructions within a basic block. Neither a
- jump nor a label may come between the related insns. These are
- only used by the schedulers and by combine. This is a deprecated
- data structure. Def-use and use-def chains are now preferred.
-
- 'REG_NOTES (I)'
- A list (chain of 'expr_list', 'insn_list' and 'int_list'
- expressions) giving miscellaneous information about the insn. It
- is often information pertaining to the registers used in this insn.
-
- The 'LOG_LINKS' field of an insn is a chain of 'insn_list' expressions.
- Each of these has two operands: the first is an insn, and the second is
- another 'insn_list' expression (the next one in the chain). The last
- 'insn_list' in the chain has a null pointer as second operand. The
- significant thing about the chain is which insns appear in it (as first
- operands of 'insn_list' expressions). Their order is not significant.
-
- This list is originally set up by the flow analysis pass; it is a null
- pointer until then. Flow only adds links for those data dependencies
- which can be used for instruction combination. For each insn, the flow
- analysis pass adds a link to insns which store into registers values
- that are used for the first time in this insn.
-
- The 'REG_NOTES' field of an insn is a chain similar to the 'LOG_LINKS'
- field but it includes 'expr_list' and 'int_list' expressions in addition
- to 'insn_list' expressions. There are several kinds of register notes,
- which are distinguished by the machine mode, which in a register note is
- really understood as being an 'enum reg_note'. The first operand OP of
- the note is data whose meaning depends on the kind of note.
-
- The macro 'REG_NOTE_KIND (X)' returns the kind of register note. Its
- counterpart, the macro 'PUT_REG_NOTE_KIND (X, NEWKIND)' sets the
- register note type of X to be NEWKIND.
-
- Register notes are of three classes: They may say something about an
- input to an insn, they may say something about an output of an insn, or
- they may create a linkage between two insns. There are also a set of
- values that are only used in 'LOG_LINKS'.
-
- These register notes annotate inputs to an insn:
-
- 'REG_DEAD'
- The value in OP dies in this insn; that is to say, altering the
- value immediately after this insn would not affect the future
- behavior of the program.
-
- It does not follow that the register OP has no useful value after
- this insn since OP is not necessarily modified by this insn.
- Rather, no subsequent instruction uses the contents of OP.
-
- 'REG_UNUSED'
- The register OP being set by this insn will not be used in a
- subsequent insn. This differs from a 'REG_DEAD' note, which
- indicates that the value in an input will not be used subsequently.
- These two notes are independent; both may be present for the same
- register.
-
- 'REG_INC'
- The register OP is incremented (or decremented; at this level there
- is no distinction) by an embedded side effect inside this insn.
- This means it appears in a 'post_inc', 'pre_inc', 'post_dec' or
- 'pre_dec' expression.
-
- 'REG_NONNEG'
- The register OP is known to have a nonnegative value when this insn
- is reached. This is used by special looping instructions that
- terminate when the register goes negative.
-
- The 'REG_NONNEG' note is added only to 'doloop_end' insns, if its
- pattern uses a 'ge' condition.
-
- 'REG_LABEL_OPERAND'
- This insn uses OP, a 'code_label' or a 'note' of type
- 'NOTE_INSN_DELETED_LABEL', but is not a 'jump_insn', or it is a
- 'jump_insn' that refers to the operand as an ordinary operand. The
- label may still eventually be a jump target, but if so in an
- indirect jump in a subsequent insn. The presence of this note
- allows jump optimization to be aware that OP is, in fact, being
- used, and flow optimization to build an accurate flow graph.
-
- 'REG_LABEL_TARGET'
- This insn is a 'jump_insn' but not an 'addr_vec' or
- 'addr_diff_vec'. It uses OP, a 'code_label' as a direct or
- indirect jump target. Its purpose is similar to that of
- 'REG_LABEL_OPERAND'. This note is only present if the insn has
- multiple targets; the last label in the insn (in the highest
- numbered insn-field) goes into the 'JUMP_LABEL' field and does not
- have a 'REG_LABEL_TARGET' note. *Note JUMP_LABEL: Insns.
-
- 'REG_SETJMP'
- Appears attached to each 'CALL_INSN' to 'setjmp' or a related
- function.
-
- The following notes describe attributes of outputs of an insn:
-
- 'REG_EQUIV'
- 'REG_EQUAL'
- This note is only valid on an insn that sets only one register and
- indicates that that register will be equal to OP at run time; the
- scope of this equivalence differs between the two types of notes.
- The value which the insn explicitly copies into the register may
- look different from OP, but they will be equal at run time. If the
- output of the single 'set' is a 'strict_low_part' or 'zero_extract'
- expression, the note refers to the register that is contained in
- its first operand.
-
- For 'REG_EQUIV', the register is equivalent to OP throughout the
- entire function, and could validly be replaced in all its
- occurrences by OP. ("Validly" here refers to the data flow of the
- program; simple replacement may make some insns invalid.) For
- example, when a constant is loaded into a register that is never
- assigned any other value, this kind of note is used.
-
- When a parameter is copied into a pseudo-register at entry to a
- function, a note of this kind records that the register is
- equivalent to the stack slot where the parameter was passed.
- Although in this case the register may be set by other insns, it is
- still valid to replace the register by the stack slot throughout
- the function.
-
- A 'REG_EQUIV' note is also used on an instruction which copies a
- register parameter into a pseudo-register at entry to a function,
- if there is a stack slot where that parameter could be stored.
- Although other insns may set the pseudo-register, it is valid for
- the compiler to replace the pseudo-register by stack slot
- throughout the function, provided the compiler ensures that the
- stack slot is properly initialized by making the replacement in the
- initial copy instruction as well. This is used on machines for
- which the calling convention allocates stack space for register
- parameters. See 'REG_PARM_STACK_SPACE' in *note Stack Arguments::.
-
- In the case of 'REG_EQUAL', the register that is set by this insn
- will be equal to OP at run time at the end of this insn but not
- necessarily elsewhere in the function. In this case, OP is
- typically an arithmetic expression. For example, when a sequence
- of insns such as a library call is used to perform an arithmetic
- operation, this kind of note is attached to the insn that produces
- or copies the final value.
-
- These two notes are used in different ways by the compiler passes.
- 'REG_EQUAL' is used by passes prior to register allocation (such as
- common subexpression elimination and loop optimization) to tell
- them how to think of that value. 'REG_EQUIV' notes are used by
- register allocation to indicate that there is an available
- substitute expression (either a constant or a 'mem' expression for
- the location of a parameter on the stack) that may be used in place
- of a register if insufficient registers are available.
-
- Except for stack homes for parameters, which are indicated by a
- 'REG_EQUIV' note and are not useful to the early optimization
- passes and pseudo registers that are equivalent to a memory
- location throughout their entire life, which is not detected until
- later in the compilation, all equivalences are initially indicated
- by an attached 'REG_EQUAL' note. In the early stages of register
- allocation, a 'REG_EQUAL' note is changed into a 'REG_EQUIV' note
- if OP is a constant and the insn represents the only set of its
- destination register.
-
- Thus, compiler passes prior to register allocation need only check
- for 'REG_EQUAL' notes and passes subsequent to register allocation
- need only check for 'REG_EQUIV' notes.
-
- These notes describe linkages between insns. They occur in pairs: one
- insn has one of a pair of notes that points to a second insn, which has
- the inverse note pointing back to the first insn.
-
- 'REG_CC_SETTER'
- 'REG_CC_USER'
- On machines that use 'cc0', the insns which set and use 'cc0' set
- and use 'cc0' are adjacent. However, when branch delay slot
- filling is done, this may no longer be true. In this case a
- 'REG_CC_USER' note will be placed on the insn setting 'cc0' to
- point to the insn using 'cc0' and a 'REG_CC_SETTER' note will be
- placed on the insn using 'cc0' to point to the insn setting 'cc0'.
-
- These values are only used in the 'LOG_LINKS' field, and indicate the
- type of dependency that each link represents. Links which indicate a
- data dependence (a read after write dependence) do not use any code,
- they simply have mode 'VOIDmode', and are printed without any
- descriptive text.
-
- 'REG_DEP_TRUE'
- This indicates a true dependence (a read after write dependence).
-
- 'REG_DEP_OUTPUT'
- This indicates an output dependence (a write after write
- dependence).
-
- 'REG_DEP_ANTI'
- This indicates an anti dependence (a write after read dependence).
-
- These notes describe information gathered from gcov profile data. They
- are stored in the 'REG_NOTES' field of an insn.
-
- 'REG_BR_PROB'
- This is used to specify the ratio of branches to non-branches of a
- branch insn according to the profile data. The note is represented
- as an 'int_list' expression whose integer value is an encoding of
- 'profile_probability' type. 'profile_probability' provide member
- function 'from_reg_br_prob_note' and 'to_reg_br_prob_note' to
- extract and store the probability into the RTL encoding.
-
- 'REG_BR_PRED'
- These notes are found in JUMP insns after delayed branch scheduling
- has taken place. They indicate both the direction and the
- likelihood of the JUMP. The format is a bitmask of ATTR_FLAG_*
- values.
-
- 'REG_FRAME_RELATED_EXPR'
- This is used on an RTX_FRAME_RELATED_P insn wherein the attached
- expression is used in place of the actual insn pattern. This is
- done in cases where the pattern is either complex or misleading.
-
- The note 'REG_CALL_NOCF_CHECK' is used in conjunction with the
- '-fcf-protection=branch' option. The note is set if a 'nocf_check'
- attribute is specified for a function type or a pointer to function
- type. The note is stored in the 'REG_NOTES' field of an insn.
-
- 'REG_CALL_NOCF_CHECK'
- Users have control through the 'nocf_check' attribute to identify
- which calls to a function should be skipped from control-flow
- instrumentation when the option '-fcf-protection=branch' is
- specified. The compiler puts a 'REG_CALL_NOCF_CHECK' note on each
- 'CALL_INSN' instruction that has a function type marked with a
- 'nocf_check' attribute.
-
- For convenience, the machine mode in an 'insn_list' or 'expr_list' is
- printed using these symbolic codes in debugging dumps.
-
- The only difference between the expression codes 'insn_list' and
- 'expr_list' is that the first operand of an 'insn_list' is assumed to be
- an insn and is printed in debugging dumps as the insn's unique id; the
- first operand of an 'expr_list' is printed in the ordinary way as an
- expression.
-
-
- File: gccint.info, Node: Calls, Next: Sharing, Prev: Insns, Up: RTL
-
- 14.20 RTL Representation of Function-Call Insns
- ===============================================
-
- Insns that call subroutines have the RTL expression code 'call_insn'.
- These insns must satisfy special rules, and their bodies must use a
- special RTL expression code, 'call'.
-
- A 'call' expression has two operands, as follows:
-
- (call (mem:FM ADDR) NBYTES)
-
- Here NBYTES is an operand that represents the number of bytes of
- argument data being passed to the subroutine, FM is a machine mode
- (which must equal as the definition of the 'FUNCTION_MODE' macro in the
- machine description) and ADDR represents the address of the subroutine.
-
- For a subroutine that returns no value, the 'call' expression as shown
- above is the entire body of the insn, except that the insn might also
- contain 'use' or 'clobber' expressions.
-
- For a subroutine that returns a value whose mode is not 'BLKmode', the
- value is returned in a hard register. If this register's number is R,
- then the body of the call insn looks like this:
-
- (set (reg:M R)
- (call (mem:FM ADDR) NBYTES))
-
- This RTL expression makes it clear (to the optimizer passes) that the
- appropriate register receives a useful value in this insn.
-
- When a subroutine returns a 'BLKmode' value, it is handled by passing
- to the subroutine the address of a place to store the value. So the
- call insn itself does not "return" any value, and it has the same RTL
- form as a call that returns nothing.
-
- On some machines, the call instruction itself clobbers some register,
- for example to contain the return address. 'call_insn' insns on these
- machines should have a body which is a 'parallel' that contains both the
- 'call' expression and 'clobber' expressions that indicate which
- registers are destroyed. Similarly, if the call instruction requires
- some register other than the stack pointer that is not explicitly
- mentioned in its RTL, a 'use' subexpression should mention that
- register.
-
- Functions that are called are assumed to modify all registers listed in
- the configuration macro 'CALL_USED_REGISTERS' (*note Register Basics::)
- and, with the exception of 'const' functions and library calls, to
- modify all of memory.
-
- Insns containing just 'use' expressions directly precede the
- 'call_insn' insn to indicate which registers contain inputs to the
- function. Similarly, if registers other than those in
- 'CALL_USED_REGISTERS' are clobbered by the called function, insns
- containing a single 'clobber' follow immediately after the call to
- indicate which registers.
-
-
- File: gccint.info, Node: Sharing, Next: Reading RTL, Prev: Calls, Up: RTL
-
- 14.21 Structure Sharing Assumptions
- ===================================
-
- The compiler assumes that certain kinds of RTL expressions are unique;
- there do not exist two distinct objects representing the same value. In
- other cases, it makes an opposite assumption: that no RTL expression
- object of a certain kind appears in more than one place in the
- containing structure.
-
- These assumptions refer to a single function; except for the RTL
- objects that describe global variables and external functions, and a few
- standard objects such as small integer constants, no RTL objects are
- common to two functions.
-
- * Each pseudo-register has only a single 'reg' object to represent
- it, and therefore only a single machine mode.
-
- * For any symbolic label, there is only one 'symbol_ref' object
- referring to it.
-
- * All 'const_int' expressions with equal values are shared.
-
- * All 'const_poly_int' expressions with equal modes and values are
- shared.
-
- * There is only one 'pc' expression.
-
- * There is only one 'cc0' expression.
-
- * There is only one 'const_double' expression with value 0 for each
- floating point mode. Likewise for values 1 and 2.
-
- * There is only one 'const_vector' expression with value 0 for each
- vector mode, be it an integer or a double constant vector.
-
- * No 'label_ref' or 'scratch' appears in more than one place in the
- RTL structure; in other words, it is safe to do a tree-walk of all
- the insns in the function and assume that each time a 'label_ref'
- or 'scratch' is seen it is distinct from all others that are seen.
-
- * Only one 'mem' object is normally created for each static variable
- or stack slot, so these objects are frequently shared in all the
- places they appear. However, separate but equal objects for these
- variables are occasionally made.
-
- * When a single 'asm' statement has multiple output operands, a
- distinct 'asm_operands' expression is made for each output operand.
- However, these all share the vector which contains the sequence of
- input operands. This sharing is used later on to test whether two
- 'asm_operands' expressions come from the same statement, so all
- optimizations must carefully preserve the sharing if they copy the
- vector at all.
-
- * No RTL object appears in more than one place in the RTL structure
- except as described above. Many passes of the compiler rely on
- this by assuming that they can modify RTL objects in place without
- unwanted side-effects on other insns.
-
- * During initial RTL generation, shared structure is freely
- introduced. After all the RTL for a function has been generated,
- all shared structure is copied by 'unshare_all_rtl' in
- 'emit-rtl.c', after which the above rules are guaranteed to be
- followed.
-
- * During the combiner pass, shared structure within an insn can exist
- temporarily. However, the shared structure is copied before the
- combiner is finished with the insn. This is done by calling
- 'copy_rtx_if_shared', which is a subroutine of 'unshare_all_rtl'.
-
-
- File: gccint.info, Node: Reading RTL, Prev: Sharing, Up: RTL
-
- 14.22 Reading RTL
- =================
-
- To read an RTL object from a file, call 'read_rtx'. It takes one
- argument, a stdio stream, and returns a single RTL object. This routine
- is defined in 'read-rtl.c'. It is not available in the compiler itself,
- only the various programs that generate the compiler back end from the
- machine description.
-
- People frequently have the idea of using RTL stored as text in a file
- as an interface between a language front end and the bulk of GCC. This
- idea is not feasible.
-
- GCC was designed to use RTL internally only. Correct RTL for a given
- program is very dependent on the particular target machine. And the RTL
- does not contain all the information about the program.
-
- The proper way to interface GCC to a new language front end is with the
- "tree" data structure, described in the files 'tree.h' and 'tree.def'.
- The documentation for this structure (*note GENERIC::) is incomplete.
-
-
- File: gccint.info, Node: Control Flow, Next: Loop Analysis and Representation, Prev: RTL, Up: Top
-
- 15 Control Flow Graph
- *********************
-
- A control flow graph (CFG) is a data structure built on top of the
- intermediate code representation (the RTL or 'GIMPLE' instruction
- stream) abstracting the control flow behavior of a function that is
- being compiled. The CFG is a directed graph where the vertices
- represent basic blocks and edges represent possible transfer of control
- flow from one basic block to another. The data structures used to
- represent the control flow graph are defined in 'basic-block.h'.
-
- In GCC, the representation of control flow is maintained throughout the
- compilation process, from constructing the CFG early in 'pass_build_cfg'
- to 'pass_free_cfg' (see 'passes.def'). The CFG takes various different
- modes and may undergo extensive manipulations, but the graph is always
- valid between its construction and its release. This way, transfer of
- information such as data flow, a measured profile, or the loop tree, can
- be propagated through the passes pipeline, and even from 'GIMPLE' to
- 'RTL'.
-
- Often the CFG may be better viewed as integral part of instruction
- chain, than structure built on the top of it. Updating the compiler's
- intermediate representation for instructions cannot be easily done
- without proper maintenance of the CFG simultaneously.
-
- * Menu:
-
- * Basic Blocks:: The definition and representation of basic blocks.
- * Edges:: Types of edges and their representation.
- * Profile information:: Representation of frequencies and probabilities.
- * Maintaining the CFG:: Keeping the control flow graph and up to date.
- * Liveness information:: Using and maintaining liveness information.
-
-
- File: gccint.info, Node: Basic Blocks, Next: Edges, Up: Control Flow
-
- 15.1 Basic Blocks
- =================
-
- A basic block is a straight-line sequence of code with only one entry
- point and only one exit. In GCC, basic blocks are represented using the
- 'basic_block' data type.
-
- Special basic blocks represent possible entry and exit points of a
- function. These blocks are called 'ENTRY_BLOCK_PTR' and
- 'EXIT_BLOCK_PTR'. These blocks do not contain any code.
-
- The 'BASIC_BLOCK' array contains all basic blocks in an unspecified
- order. Each 'basic_block' structure has a field that holds a unique
- integer identifier 'index' that is the index of the block in the
- 'BASIC_BLOCK' array. The total number of basic blocks in the function
- is 'n_basic_blocks'. Both the basic block indices and the total number
- of basic blocks may vary during the compilation process, as passes
- reorder, create, duplicate, and destroy basic blocks. The index for any
- block should never be greater than 'last_basic_block'. The indices 0
- and 1 are special codes reserved for 'ENTRY_BLOCK' and 'EXIT_BLOCK', the
- indices of 'ENTRY_BLOCK_PTR' and 'EXIT_BLOCK_PTR'.
-
- Two pointer members of the 'basic_block' structure are the pointers
- 'next_bb' and 'prev_bb'. These are used to keep doubly linked chain of
- basic blocks in the same order as the underlying instruction stream.
- The chain of basic blocks is updated transparently by the provided API
- for manipulating the CFG. The macro 'FOR_EACH_BB' can be used to visit
- all the basic blocks in lexicographical order, except 'ENTRY_BLOCK' and
- 'EXIT_BLOCK'. The macro 'FOR_ALL_BB' also visits all basic blocks in
- lexicographical order, including 'ENTRY_BLOCK' and 'EXIT_BLOCK'.
-
- The functions 'post_order_compute' and 'inverted_post_order_compute'
- can be used to compute topological orders of the CFG. The orders are
- stored as vectors of basic block indices. The 'BASIC_BLOCK' array can
- be used to iterate each basic block by index. Dominator traversals are
- also possible using 'walk_dominator_tree'. Given two basic blocks A and
- B, block A dominates block B if A is _always_ executed before B.
-
- Each 'basic_block' also contains pointers to the first instruction (the
- "head") and the last instruction (the "tail") or "end" of the
- instruction stream contained in a basic block. In fact, since the
- 'basic_block' data type is used to represent blocks in both major
- intermediate representations of GCC ('GIMPLE' and RTL), there are
- pointers to the head and end of a basic block for both representations,
- stored in intermediate representation specific data in the 'il' field of
- 'struct basic_block_def'.
-
- For RTL, these pointers are 'BB_HEAD' and 'BB_END'.
-
- In the RTL representation of a function, the instruction stream
- contains not only the "real" instructions, but also "notes" or "insn
- notes" (to distinguish them from "reg notes"). Any function that moves
- or duplicates the basic blocks needs to take care of updating of these
- notes. Many of these notes expect that the instruction stream consists
- of linear regions, so updating can sometimes be tedious. All types of
- insn notes are defined in 'insn-notes.def'.
-
- In the RTL function representation, the instructions contained in a
- basic block always follow a 'NOTE_INSN_BASIC_BLOCK', but zero or more
- 'CODE_LABEL' nodes can precede the block note. A basic block ends with
- a control flow instruction or with the last instruction before the next
- 'CODE_LABEL' or 'NOTE_INSN_BASIC_BLOCK'. By definition, a 'CODE_LABEL'
- cannot appear in the middle of the instruction stream of a basic block.
-
- In addition to notes, the jump table vectors are also represented as
- "pseudo-instructions" inside the insn stream. These vectors never
- appear in the basic block and should always be placed just after the
- table jump instructions referencing them. After removing the table-jump
- it is often difficult to eliminate the code computing the address and
- referencing the vector, so cleaning up these vectors is postponed until
- after liveness analysis. Thus the jump table vectors may appear in the
- insn stream unreferenced and without any purpose. Before any edge is
- made "fall-thru", the existence of such construct in the way needs to be
- checked by calling 'can_fallthru' function.
-
- For the 'GIMPLE' representation, the PHI nodes and statements contained
- in a basic block are in a 'gimple_seq' pointed to by the basic block
- intermediate language specific pointers. Abstract containers and
- iterators are used to access the PHI nodes and statements in a basic
- blocks. These iterators are called "GIMPLE statement iterators" (GSIs).
- Grep for '^gsi' in the various 'gimple-*' and 'tree-*' files. There is
- a 'gimple_stmt_iterator' type for iterating over all kinds of statement,
- and a 'gphi_iterator' subclass for iterating over PHI nodes. The
- following snippet will pretty-print all PHI nodes the statements of the
- current function in the GIMPLE representation.
-
- basic_block bb;
-
- FOR_EACH_BB (bb)
- {
- gphi_iterator pi;
- gimple_stmt_iterator si;
-
- for (pi = gsi_start_phis (bb); !gsi_end_p (pi); gsi_next (&pi))
- {
- gphi *phi = pi.phi ();
- print_gimple_stmt (dump_file, phi, 0, TDF_SLIM);
- }
- for (si = gsi_start_bb (bb); !gsi_end_p (si); gsi_next (&si))
- {
- gimple stmt = gsi_stmt (si);
- print_gimple_stmt (dump_file, stmt, 0, TDF_SLIM);
- }
- }
-
-
- File: gccint.info, Node: Edges, Next: Profile information, Prev: Basic Blocks, Up: Control Flow
-
- 15.2 Edges
- ==========
-
- Edges represent possible control flow transfers from the end of some
- basic block A to the head of another basic block B. We say that A is a
- predecessor of B, and B is a successor of A. Edges are represented in
- GCC with the 'edge' data type. Each 'edge' acts as a link between two
- basic blocks: The 'src' member of an edge points to the predecessor
- basic block of the 'dest' basic block. The members 'preds' and 'succs'
- of the 'basic_block' data type point to type-safe vectors of edges to
- the predecessors and successors of the block.
-
- When walking the edges in an edge vector, "edge iterators" should be
- used. Edge iterators are constructed using the 'edge_iterator' data
- structure and several methods are available to operate on them:
-
- 'ei_start'
- This function initializes an 'edge_iterator' that points to the
- first edge in a vector of edges.
-
- 'ei_last'
- This function initializes an 'edge_iterator' that points to the
- last edge in a vector of edges.
-
- 'ei_end_p'
- This predicate is 'true' if an 'edge_iterator' represents the last
- edge in an edge vector.
-
- 'ei_one_before_end_p'
- This predicate is 'true' if an 'edge_iterator' represents the
- second last edge in an edge vector.
-
- 'ei_next'
- This function takes a pointer to an 'edge_iterator' and makes it
- point to the next edge in the sequence.
-
- 'ei_prev'
- This function takes a pointer to an 'edge_iterator' and makes it
- point to the previous edge in the sequence.
-
- 'ei_edge'
- This function returns the 'edge' currently pointed to by an
- 'edge_iterator'.
-
- 'ei_safe_safe'
- This function returns the 'edge' currently pointed to by an
- 'edge_iterator', but returns 'NULL' if the iterator is pointing at
- the end of the sequence. This function has been provided for
- existing code makes the assumption that a 'NULL' edge indicates the
- end of the sequence.
-
- The convenience macro 'FOR_EACH_EDGE' can be used to visit all of the
- edges in a sequence of predecessor or successor edges. It must not be
- used when an element might be removed during the traversal, otherwise
- elements will be missed. Here is an example of how to use the macro:
-
- edge e;
- edge_iterator ei;
-
- FOR_EACH_EDGE (e, ei, bb->succs)
- {
- if (e->flags & EDGE_FALLTHRU)
- break;
- }
-
- There are various reasons why control flow may transfer from one block
- to another. One possibility is that some instruction, for example a
- 'CODE_LABEL', in a linearized instruction stream just always starts a
- new basic block. In this case a "fall-thru" edge links the basic block
- to the first following basic block. But there are several other reasons
- why edges may be created. The 'flags' field of the 'edge' data type is
- used to store information about the type of edge we are dealing with.
- Each edge is of one of the following types:
-
- _jump_
- No type flags are set for edges corresponding to jump instructions.
- These edges are used for unconditional or conditional jumps and in
- RTL also for table jumps. They are the easiest to manipulate as
- they may be freely redirected when the flow graph is not in SSA
- form.
-
- _fall-thru_
- Fall-thru edges are present in case where the basic block may
- continue execution to the following one without branching. These
- edges have the 'EDGE_FALLTHRU' flag set. Unlike other types of
- edges, these edges must come into the basic block immediately
- following in the instruction stream. The function
- 'force_nonfallthru' is available to insert an unconditional jump in
- the case that redirection is needed. Note that this may require
- creation of a new basic block.
-
- _exception handling_
- Exception handling edges represent possible control transfers from
- a trapping instruction to an exception handler. The definition of
- "trapping" varies. In C++, only function calls can throw, but for
- Ada exceptions like division by zero or segmentation fault are
- defined and thus each instruction possibly throwing this kind of
- exception needs to be handled as control flow instruction.
- Exception edges have the 'EDGE_ABNORMAL' and 'EDGE_EH' flags set.
-
- When updating the instruction stream it is easy to change possibly
- trapping instruction to non-trapping, by simply removing the
- exception edge. The opposite conversion is difficult, but should
- not happen anyway. The edges can be eliminated via
- 'purge_dead_edges' call.
-
- In the RTL representation, the destination of an exception edge is
- specified by 'REG_EH_REGION' note attached to the insn. In case of
- a trapping call the 'EDGE_ABNORMAL_CALL' flag is set too. In the
- 'GIMPLE' representation, this extra flag is not set.
-
- In the RTL representation, the predicate 'may_trap_p' may be used
- to check whether instruction still may trap or not. For the tree
- representation, the 'tree_could_trap_p' predicate is available, but
- this predicate only checks for possible memory traps, as in
- dereferencing an invalid pointer location.
-
- _sibling calls_
- Sibling calls or tail calls terminate the function in a
- non-standard way and thus an edge to the exit must be present.
- 'EDGE_SIBCALL' and 'EDGE_ABNORMAL' are set in such case. These
- edges only exist in the RTL representation.
-
- _computed jumps_
- Computed jumps contain edges to all labels in the function
- referenced from the code. All those edges have 'EDGE_ABNORMAL'
- flag set. The edges used to represent computed jumps often cause
- compile time performance problems, since functions consisting of
- many taken labels and many computed jumps may have _very_ dense
- flow graphs, so these edges need to be handled with special care.
- During the earlier stages of the compilation process, GCC tries to
- avoid such dense flow graphs by factoring computed jumps. For
- example, given the following series of jumps,
-
- goto *x;
- [ ... ]
-
- goto *x;
- [ ... ]
-
- goto *x;
- [ ... ]
-
- factoring the computed jumps results in the following code sequence
- which has a much simpler flow graph:
-
- goto y;
- [ ... ]
-
- goto y;
- [ ... ]
-
- goto y;
- [ ... ]
-
- y:
- goto *x;
-
- However, the classic problem with this transformation is that it
- has a runtime cost in there resulting code: An extra jump.
- Therefore, the computed jumps are un-factored in the later passes
- of the compiler (in the pass called
- 'pass_duplicate_computed_gotos'). Be aware of that when you work
- on passes in that area. There have been numerous examples already
- where the compile time for code with unfactored computed jumps
- caused some serious headaches.
-
- _nonlocal goto handlers_
- GCC allows nested functions to return into caller using a 'goto' to
- a label passed to as an argument to the callee. The labels passed
- to nested functions contain special code to cleanup after function
- call. Such sections of code are referred to as "nonlocal goto
- receivers". If a function contains such nonlocal goto receivers,
- an edge from the call to the label is created with the
- 'EDGE_ABNORMAL' and 'EDGE_ABNORMAL_CALL' flags set.
-
- _function entry points_
- By definition, execution of function starts at basic block 0, so
- there is always an edge from the 'ENTRY_BLOCK_PTR' to basic block
- 0. There is no 'GIMPLE' representation for alternate entry points
- at this moment. In RTL, alternate entry points are specified by
- 'CODE_LABEL' with 'LABEL_ALTERNATE_NAME' defined. This feature is
- currently used for multiple entry point prologues and is limited to
- post-reload passes only. This can be used by back-ends to emit
- alternate prologues for functions called from different contexts.
- In future full support for multiple entry functions defined by
- Fortran 90 needs to be implemented.
-
- _function exits_
- In the pre-reload representation a function terminates after the
- last instruction in the insn chain and no explicit return
- instructions are used. This corresponds to the fall-thru edge into
- exit block. After reload, optimal RTL epilogues are used that use
- explicit (conditional) return instructions that are represented by
- edges with no flags set.
-
-
- File: gccint.info, Node: Profile information, Next: Maintaining the CFG, Prev: Edges, Up: Control Flow
-
- 15.3 Profile information
- ========================
-
- In many cases a compiler must make a choice whether to trade speed in
- one part of code for speed in another, or to trade code size for code
- speed. In such cases it is useful to know information about how often
- some given block will be executed. That is the purpose for maintaining
- profile within the flow graph. GCC can handle profile information
- obtained through "profile feedback", but it can also estimate branch
- probabilities based on statics and heuristics.
-
- The feedback based profile is produced by compiling the program with
- instrumentation, executing it on a train run and reading the numbers of
- executions of basic blocks and edges back to the compiler while
- re-compiling the program to produce the final executable. This method
- provides very accurate information about where a program spends most of
- its time on the train run. Whether it matches the average run of course
- depends on the choice of train data set, but several studies have shown
- that the behavior of a program usually changes just marginally over
- different data sets.
-
- When profile feedback is not available, the compiler may be asked to
- attempt to predict the behavior of each branch in the program using a
- set of heuristics (see 'predict.def' for details) and compute estimated
- frequencies of each basic block by propagating the probabilities over
- the graph.
-
- Each 'basic_block' contains two integer fields to represent profile
- information: 'frequency' and 'count'. The 'frequency' is an estimation
- how often is basic block executed within a function. It is represented
- as an integer scaled in the range from 0 to 'BB_FREQ_BASE'. The most
- frequently executed basic block in function is initially set to
- 'BB_FREQ_BASE' and the rest of frequencies are scaled accordingly.
- During optimization, the frequency of the most frequent basic block can
- both decrease (for instance by loop unrolling) or grow (for instance by
- cross-jumping optimization), so scaling sometimes has to be performed
- multiple times.
-
- The 'count' contains hard-counted numbers of execution measured during
- training runs and is nonzero only when profile feedback is available.
- This value is represented as the host's widest integer (typically a 64
- bit integer) of the special type 'gcov_type'.
-
- Most optimization passes can use only the frequency information of a
- basic block, but a few passes may want to know hard execution counts.
- The frequencies should always match the counts after scaling, however
- during updating of the profile information numerical error may
- accumulate into quite large errors.
-
- Each edge also contains a branch probability field: an integer in the
- range from 0 to 'REG_BR_PROB_BASE'. It represents probability of
- passing control from the end of the 'src' basic block to the 'dest'
- basic block, i.e. the probability that control will flow along this
- edge. The 'EDGE_FREQUENCY' macro is available to compute how frequently
- a given edge is taken. There is a 'count' field for each edge as well,
- representing same information as for a basic block.
-
- The basic block frequencies are not represented in the instruction
- stream, but in the RTL representation the edge frequencies are
- represented for conditional jumps (via the 'REG_BR_PROB' macro) since
- they are used when instructions are output to the assembly file and the
- flow graph is no longer maintained.
-
- The probability that control flow arrives via a given edge to its
- destination basic block is called "reverse probability" and is not
- directly represented, but it may be easily computed from frequencies of
- basic blocks.
-
- Updating profile information is a delicate task that can unfortunately
- not be easily integrated with the CFG manipulation API. Many of the
- functions and hooks to modify the CFG, such as
- 'redirect_edge_and_branch', do not have enough information to easily
- update the profile, so updating it is in the majority of cases left up
- to the caller. It is difficult to uncover bugs in the profile updating
- code, because they manifest themselves only by producing worse code, and
- checking profile consistency is not possible because of numeric error
- accumulation. Hence special attention needs to be given to this issue
- in each pass that modifies the CFG.
-
- It is important to point out that 'REG_BR_PROB_BASE' and 'BB_FREQ_BASE'
- are both set low enough to be possible to compute second power of any
- frequency or probability in the flow graph, it is not possible to even
- square the 'count' field, as modern CPUs are fast enough to execute
- $2^32$ operations quickly.
-
-
- File: gccint.info, Node: Maintaining the CFG, Next: Liveness information, Prev: Profile information, Up: Control Flow
-
- 15.4 Maintaining the CFG
- ========================
-
- An important task of each compiler pass is to keep both the control flow
- graph and all profile information up-to-date. Reconstruction of the
- control flow graph after each pass is not an option, since it may be
- very expensive and lost profile information cannot be reconstructed at
- all.
-
- GCC has two major intermediate representations, and both use the
- 'basic_block' and 'edge' data types to represent control flow. Both
- representations share as much of the CFG maintenance code as possible.
- For each representation, a set of "hooks" is defined so that each
- representation can provide its own implementation of CFG manipulation
- routines when necessary. These hooks are defined in 'cfghooks.h'.
- There are hooks for almost all common CFG manipulations, including block
- splitting and merging, edge redirection and creating and deleting basic
- blocks. These hooks should provide everything you need to maintain and
- manipulate the CFG in both the RTL and 'GIMPLE' representation.
-
- At the moment, the basic block boundaries are maintained transparently
- when modifying instructions, so there rarely is a need to move them
- manually (such as in case someone wants to output instruction outside
- basic block explicitly).
-
- In the RTL representation, each instruction has a 'BLOCK_FOR_INSN'
- value that represents pointer to the basic block that contains the
- instruction. In the 'GIMPLE' representation, the function 'gimple_bb'
- returns a pointer to the basic block containing the queried statement.
-
- When changes need to be applied to a function in its 'GIMPLE'
- representation, "GIMPLE statement iterators" should be used. These
- iterators provide an integrated abstraction of the flow graph and the
- instruction stream. Block statement iterators are constructed using the
- 'gimple_stmt_iterator' data structure and several modifiers are
- available, including the following:
-
- 'gsi_start'
- This function initializes a 'gimple_stmt_iterator' that points to
- the first non-empty statement in a basic block.
-
- 'gsi_last'
- This function initializes a 'gimple_stmt_iterator' that points to
- the last statement in a basic block.
-
- 'gsi_end_p'
- This predicate is 'true' if a 'gimple_stmt_iterator' represents the
- end of a basic block.
-
- 'gsi_next'
- This function takes a 'gimple_stmt_iterator' and makes it point to
- its successor.
-
- 'gsi_prev'
- This function takes a 'gimple_stmt_iterator' and makes it point to
- its predecessor.
-
- 'gsi_insert_after'
- This function inserts a statement after the 'gimple_stmt_iterator'
- passed in. The final parameter determines whether the statement
- iterator is updated to point to the newly inserted statement, or
- left pointing to the original statement.
-
- 'gsi_insert_before'
- This function inserts a statement before the 'gimple_stmt_iterator'
- passed in. The final parameter determines whether the statement
- iterator is updated to point to the newly inserted statement, or
- left pointing to the original statement.
-
- 'gsi_remove'
- This function removes the 'gimple_stmt_iterator' passed in and
- rechains the remaining statements in a basic block, if any.
-
- In the RTL representation, the macros 'BB_HEAD' and 'BB_END' may be
- used to get the head and end 'rtx' of a basic block. No abstract
- iterators are defined for traversing the insn chain, but you can just
- use 'NEXT_INSN' and 'PREV_INSN' instead. *Note Insns::.
-
- Usually a code manipulating pass simplifies the instruction stream and
- the flow of control, possibly eliminating some edges. This may for
- example happen when a conditional jump is replaced with an unconditional
- jump. Updating of edges is not transparent and each optimization pass
- is required to do so manually. However only few cases occur in
- practice. The pass may call 'purge_dead_edges' on a given basic block
- to remove superfluous edges, if any.
-
- Another common scenario is redirection of branch instructions, but this
- is best modeled as redirection of edges in the control flow graph and
- thus use of 'redirect_edge_and_branch' is preferred over more low level
- functions, such as 'redirect_jump' that operate on RTL chain only. The
- CFG hooks defined in 'cfghooks.h' should provide the complete API
- required for manipulating and maintaining the CFG.
-
- It is also possible that a pass has to insert control flow instruction
- into the middle of a basic block, thus creating an entry point in the
- middle of the basic block, which is impossible by definition: The block
- must be split to make sure it only has one entry point, i.e. the head of
- the basic block. The CFG hook 'split_block' may be used when an
- instruction in the middle of a basic block has to become the target of a
- jump or branch instruction.
-
- For a global optimizer, a common operation is to split edges in the
- flow graph and insert instructions on them. In the RTL representation,
- this can be easily done using the 'insert_insn_on_edge' function that
- emits an instruction "on the edge", caching it for a later
- 'commit_edge_insertions' call that will take care of moving the inserted
- instructions off the edge into the instruction stream contained in a
- basic block. This includes the creation of new basic blocks where
- needed. In the 'GIMPLE' representation, the equivalent functions are
- 'gsi_insert_on_edge' which inserts a block statement iterator on an
- edge, and 'gsi_commit_edge_inserts' which flushes the instruction to
- actual instruction stream.
-
- While debugging the optimization pass, the 'verify_flow_info' function
- may be useful to find bugs in the control flow graph updating code.
-
-
- File: gccint.info, Node: Liveness information, Prev: Maintaining the CFG, Up: Control Flow
-
- 15.5 Liveness information
- =========================
-
- Liveness information is useful to determine whether some register is
- "live" at given point of program, i.e. that it contains a value that may
- be used at a later point in the program. This information is used, for
- instance, during register allocation, as the pseudo registers only need
- to be assigned to a unique hard register or to a stack slot if they are
- live. The hard registers and stack slots may be freely reused for other
- values when a register is dead.
-
- Liveness information is available in the back end starting with
- 'pass_df_initialize' and ending with 'pass_df_finish'. Three flavors of
- live analysis are available: With 'LR', it is possible to determine at
- any point 'P' in the function if the register may be used on some path
- from 'P' to the end of the function. With 'UR', it is possible to
- determine if there is a path from the beginning of the function to 'P'
- that defines the variable. 'LIVE' is the intersection of the 'LR' and
- 'UR' and a variable is live at 'P' if there is both an assignment that
- reaches it from the beginning of the function and a use that can be
- reached on some path from 'P' to the end of the function.
-
- In general 'LIVE' is the most useful of the three. The macros
- 'DF_[LR,UR,LIVE]_[IN,OUT]' can be used to access this information. The
- macros take a basic block number and return a bitmap that is indexed by
- the register number. This information is only guaranteed to be up to
- date after calls are made to 'df_analyze'. See the file 'df-core.c' for
- details on using the dataflow.
-
- The liveness information is stored partly in the RTL instruction stream
- and partly in the flow graph. Local information is stored in the
- instruction stream: Each instruction may contain 'REG_DEAD' notes
- representing that the value of a given register is no longer needed, or
- 'REG_UNUSED' notes representing that the value computed by the
- instruction is never used. The second is useful for instructions
- computing multiple values at once.
-
-
- File: gccint.info, Node: Loop Analysis and Representation, Next: Machine Desc, Prev: Control Flow, Up: Top
-
- 16 Analysis and Representation of Loops
- ***************************************
-
- GCC provides extensive infrastructure for work with natural loops, i.e.,
- strongly connected components of CFG with only one entry block. This
- chapter describes representation of loops in GCC, both on GIMPLE and in
- RTL, as well as the interfaces to loop-related analyses (induction
- variable analysis and number of iterations analysis).
-
- * Menu:
-
- * Loop representation:: Representation and analysis of loops.
- * Loop querying:: Getting information about loops.
- * Loop manipulation:: Loop manipulation functions.
- * LCSSA:: Loop-closed SSA form.
- * Scalar evolutions:: Induction variables on GIMPLE.
- * loop-iv:: Induction variables on RTL.
- * Number of iterations:: Number of iterations analysis.
- * Dependency analysis:: Data dependency analysis.
-
-
- File: gccint.info, Node: Loop representation, Next: Loop querying, Up: Loop Analysis and Representation
-
- 16.1 Loop representation
- ========================
-
- This chapter describes the representation of loops in GCC, and functions
- that can be used to build, modify and analyze this representation. Most
- of the interfaces and data structures are declared in 'cfgloop.h'. Loop
- structures are analyzed and this information disposed or updated at the
- discretion of individual passes. Still most of the generic CFG
- manipulation routines are aware of loop structures and try to keep them
- up-to-date. By this means an increasing part of the compilation
- pipeline is setup to maintain loop structure across passes to allow
- attaching meta information to individual loops for consumption by later
- passes.
-
- In general, a natural loop has one entry block (header) and possibly
- several back edges (latches) leading to the header from the inside of
- the loop. Loops with several latches may appear if several loops share
- a single header, or if there is a branching in the middle of the loop.
- The representation of loops in GCC however allows only loops with a
- single latch. During loop analysis, headers of such loops are split and
- forwarder blocks are created in order to disambiguate their structures.
- Heuristic based on profile information and structure of the induction
- variables in the loops is used to determine whether the latches
- correspond to sub-loops or to control flow in a single loop. This means
- that the analysis sometimes changes the CFG, and if you run it in the
- middle of an optimization pass, you must be able to deal with the new
- blocks. You may avoid CFG changes by passing
- 'LOOPS_MAY_HAVE_MULTIPLE_LATCHES' flag to the loop discovery, note
- however that most other loop manipulation functions will not work
- correctly for loops with multiple latch edges (the functions that only
- query membership of blocks to loops and subloop relationships, or
- enumerate and test loop exits, can be expected to work).
-
- Body of the loop is the set of blocks that are dominated by its header,
- and reachable from its latch against the direction of edges in CFG. The
- loops are organized in a containment hierarchy (tree) such that all the
- loops immediately contained inside loop L are the children of L in the
- tree. This tree is represented by the 'struct loops' structure. The
- root of this tree is a fake loop that contains all blocks in the
- function. Each of the loops is represented in a 'struct loop'
- structure. Each loop is assigned an index ('num' field of the 'struct
- loop' structure), and the pointer to the loop is stored in the
- corresponding field of the 'larray' vector in the loops structure. The
- indices do not have to be continuous, there may be empty ('NULL')
- entries in the 'larray' created by deleting loops. Also, there is no
- guarantee on the relative order of a loop and its subloops in the
- numbering. The index of a loop never changes.
-
- The entries of the 'larray' field should not be accessed directly. The
- function 'get_loop' returns the loop description for a loop with the
- given index. 'number_of_loops' function returns number of loops in the
- function. To traverse all loops, use 'FOR_EACH_LOOP' macro. The
- 'flags' argument of the macro is used to determine the direction of
- traversal and the set of loops visited. Each loop is guaranteed to be
- visited exactly once, regardless of the changes to the loop tree, and
- the loops may be removed during the traversal. The newly created loops
- are never traversed, if they need to be visited, this must be done
- separately after their creation.
-
- Each basic block contains the reference to the innermost loop it
- belongs to ('loop_father'). For this reason, it is only possible to
- have one 'struct loops' structure initialized at the same time for each
- CFG. The global variable 'current_loops' contains the 'struct loops'
- structure. Many of the loop manipulation functions assume that
- dominance information is up-to-date.
-
- The loops are analyzed through 'loop_optimizer_init' function. The
- argument of this function is a set of flags represented in an integer
- bitmask. These flags specify what other properties of the loop
- structures should be calculated/enforced and preserved later:
-
- * 'LOOPS_MAY_HAVE_MULTIPLE_LATCHES': If this flag is set, no changes
- to CFG will be performed in the loop analysis, in particular, loops
- with multiple latch edges will not be disambiguated. If a loop has
- multiple latches, its latch block is set to NULL. Most of the loop
- manipulation functions will not work for loops in this shape. No
- other flags that require CFG changes can be passed to
- loop_optimizer_init.
- * 'LOOPS_HAVE_PREHEADERS': Forwarder blocks are created in such a way
- that each loop has only one entry edge, and additionally, the
- source block of this entry edge has only one successor. This
- creates a natural place where the code can be moved out of the
- loop, and ensures that the entry edge of the loop leads from its
- immediate super-loop.
- * 'LOOPS_HAVE_SIMPLE_LATCHES': Forwarder blocks are created to force
- the latch block of each loop to have only one successor. This
- ensures that the latch of the loop does not belong to any of its
- sub-loops, and makes manipulation with the loops significantly
- easier. Most of the loop manipulation functions assume that the
- loops are in this shape. Note that with this flag, the "normal"
- loop without any control flow inside and with one exit consists of
- two basic blocks.
- * 'LOOPS_HAVE_MARKED_IRREDUCIBLE_REGIONS': Basic blocks and edges in
- the strongly connected components that are not natural loops (have
- more than one entry block) are marked with 'BB_IRREDUCIBLE_LOOP'
- and 'EDGE_IRREDUCIBLE_LOOP' flags. The flag is not set for blocks
- and edges that belong to natural loops that are in such an
- irreducible region (but it is set for the entry and exit edges of
- such a loop, if they lead to/from this region).
- * 'LOOPS_HAVE_RECORDED_EXITS': The lists of exits are recorded and
- updated for each loop. This makes some functions (e.g.,
- 'get_loop_exit_edges') more efficient. Some functions (e.g.,
- 'single_exit') can be used only if the lists of exits are recorded.
-
- These properties may also be computed/enforced later, using functions
- 'create_preheaders', 'force_single_succ_latches',
- 'mark_irreducible_loops' and 'record_loop_exits'. The properties can be
- queried using 'loops_state_satisfies_p'.
-
- The memory occupied by the loops structures should be freed with
- 'loop_optimizer_finalize' function. When loop structures are setup to
- be preserved across passes this function reduces the information to be
- kept up-to-date to a minimum (only 'LOOPS_MAY_HAVE_MULTIPLE_LATCHES'
- set).
-
- The CFG manipulation functions in general do not update loop
- structures. Specialized versions that additionally do so are provided
- for the most common tasks. On GIMPLE, 'cleanup_tree_cfg_loop' function
- can be used to cleanup CFG while updating the loops structures if
- 'current_loops' is set.
-
- At the moment loop structure is preserved from the start of GIMPLE loop
- optimizations until the end of RTL loop optimizations. During this time
- a loop can be tracked by its 'struct loop' and number.
-
-
- File: gccint.info, Node: Loop querying, Next: Loop manipulation, Prev: Loop representation, Up: Loop Analysis and Representation
-
- 16.2 Loop querying
- ==================
-
- The functions to query the information about loops are declared in
- 'cfgloop.h'. Some of the information can be taken directly from the
- structures. 'loop_father' field of each basic block contains the
- innermost loop to that the block belongs. The most useful fields of
- loop structure (that are kept up-to-date at all times) are:
-
- * 'header', 'latch': Header and latch basic blocks of the loop.
- * 'num_nodes': Number of basic blocks in the loop (including the
- basic blocks of the sub-loops).
- * 'outer', 'inner', 'next': The super-loop, the first sub-loop, and
- the sibling of the loop in the loops tree.
-
- There are other fields in the loop structures, many of them used only
- by some of the passes, or not updated during CFG changes; in general,
- they should not be accessed directly.
-
- The most important functions to query loop structures are:
-
- * 'loop_depth': The depth of the loop in the loops tree, i.e., the
- number of super-loops of the loop.
- * 'flow_loops_dump': Dumps the information about loops to a file.
- * 'verify_loop_structure': Checks consistency of the loop structures.
- * 'loop_latch_edge': Returns the latch edge of a loop.
- * 'loop_preheader_edge': If loops have preheaders, returns the
- preheader edge of a loop.
- * 'flow_loop_nested_p': Tests whether loop is a sub-loop of another
- loop.
- * 'flow_bb_inside_loop_p': Tests whether a basic block belongs to a
- loop (including its sub-loops).
- * 'find_common_loop': Finds the common super-loop of two loops.
- * 'superloop_at_depth': Returns the super-loop of a loop with the
- given depth.
- * 'tree_num_loop_insns', 'num_loop_insns': Estimates the number of
- insns in the loop, on GIMPLE and on RTL.
- * 'loop_exit_edge_p': Tests whether edge is an exit from a loop.
- * 'mark_loop_exit_edges': Marks all exit edges of all loops with
- 'EDGE_LOOP_EXIT' flag.
- * 'get_loop_body', 'get_loop_body_in_dom_order',
- 'get_loop_body_in_bfs_order': Enumerates the basic blocks in the
- loop in depth-first search order in reversed CFG, ordered by
- dominance relation, and breath-first search order, respectively.
- * 'single_exit': Returns the single exit edge of the loop, or 'NULL'
- if the loop has more than one exit. You can only use this function
- if LOOPS_HAVE_MARKED_SINGLE_EXITS property is used.
- * 'get_loop_exit_edges': Enumerates the exit edges of a loop.
- * 'just_once_each_iteration_p': Returns true if the basic block is
- executed exactly once during each iteration of a loop (that is, it
- does not belong to a sub-loop, and it dominates the latch of the
- loop).
-
-
- File: gccint.info, Node: Loop manipulation, Next: LCSSA, Prev: Loop querying, Up: Loop Analysis and Representation
-
- 16.3 Loop manipulation
- ======================
-
- The loops tree can be manipulated using the following functions:
-
- * 'flow_loop_tree_node_add': Adds a node to the tree.
- * 'flow_loop_tree_node_remove': Removes a node from the tree.
- * 'add_bb_to_loop': Adds a basic block to a loop.
- * 'remove_bb_from_loops': Removes a basic block from loops.
-
- Most low-level CFG functions update loops automatically. The following
- functions handle some more complicated cases of CFG manipulations:
-
- * 'remove_path': Removes an edge and all blocks it dominates.
- * 'split_loop_exit_edge': Splits exit edge of the loop, ensuring that
- PHI node arguments remain in the loop (this ensures that
- loop-closed SSA form is preserved). Only useful on GIMPLE.
-
- Finally, there are some higher-level loop transformations implemented.
- While some of them are written so that they should work on non-innermost
- loops, they are mostly untested in that case, and at the moment, they
- are only reliable for the innermost loops:
-
- * 'create_iv': Creates a new induction variable. Only works on
- GIMPLE. 'standard_iv_increment_position' can be used to find a
- suitable place for the iv increment.
- * 'duplicate_loop_to_header_edge',
- 'tree_duplicate_loop_to_header_edge': These functions (on RTL and
- on GIMPLE) duplicate the body of the loop prescribed number of
- times on one of the edges entering loop header, thus performing
- either loop unrolling or loop peeling. 'can_duplicate_loop_p'
- ('can_unroll_loop_p' on GIMPLE) must be true for the duplicated
- loop.
- * 'loop_version': This function creates a copy of a loop, and a
- branch before them that selects one of them depending on the
- prescribed condition. This is useful for optimizations that need
- to verify some assumptions in runtime (one of the copies of the
- loop is usually left unchanged, while the other one is transformed
- in some way).
- * 'tree_unroll_loop': Unrolls the loop, including peeling the extra
- iterations to make the number of iterations divisible by unroll
- factor, updating the exit condition, and removing the exits that
- now cannot be taken. Works only on GIMPLE.
-
-
- File: gccint.info, Node: LCSSA, Next: Scalar evolutions, Prev: Loop manipulation, Up: Loop Analysis and Representation
-
- 16.4 Loop-closed SSA form
- =========================
-
- Throughout the loop optimizations on tree level, one extra condition is
- enforced on the SSA form: No SSA name is used outside of the loop in
- that it is defined. The SSA form satisfying this condition is called
- "loop-closed SSA form" - LCSSA. To enforce LCSSA, PHI nodes must be
- created at the exits of the loops for the SSA names that are used
- outside of them. Only the real operands (not virtual SSA names) are
- held in LCSSA, in order to save memory.
-
- There are various benefits of LCSSA:
-
- * Many optimizations (value range analysis, final value replacement)
- are interested in the values that are defined in the loop and used
- outside of it, i.e., exactly those for that we create new PHI
- nodes.
- * In induction variable analysis, it is not necessary to specify the
- loop in that the analysis should be performed - the scalar
- evolution analysis always returns the results with respect to the
- loop in that the SSA name is defined.
- * It makes updating of SSA form during loop transformations simpler.
- Without LCSSA, operations like loop unrolling may force creation of
- PHI nodes arbitrarily far from the loop, while in LCSSA, the SSA
- form can be updated locally. However, since we only keep real
- operands in LCSSA, we cannot use this advantage (we could have
- local updating of real operands, but it is not much more efficient
- than to use generic SSA form updating for it as well; the amount of
- changes to SSA is the same).
-
- However, it also means LCSSA must be updated. This is usually
- straightforward, unless you create a new value in loop and use it
- outside, or unless you manipulate loop exit edges (functions are
- provided to make these manipulations simple).
- 'rewrite_into_loop_closed_ssa' is used to rewrite SSA form to LCSSA, and
- 'verify_loop_closed_ssa' to check that the invariant of LCSSA is
- preserved.
-
-
- File: gccint.info, Node: Scalar evolutions, Next: loop-iv, Prev: LCSSA, Up: Loop Analysis and Representation
-
- 16.5 Scalar evolutions
- ======================
-
- Scalar evolutions (SCEV) are used to represent results of induction
- variable analysis on GIMPLE. They enable us to represent variables with
- complicated behavior in a simple and consistent way (we only use it to
- express values of polynomial induction variables, but it is possible to
- extend it). The interfaces to SCEV analysis are declared in
- 'tree-scalar-evolution.h'. To use scalar evolutions analysis,
- 'scev_initialize' must be used. To stop using SCEV, 'scev_finalize'
- should be used. SCEV analysis caches results in order to save time and
- memory. This cache however is made invalid by most of the loop
- transformations, including removal of code. If such a transformation is
- performed, 'scev_reset' must be called to clean the caches.
-
- Given an SSA name, its behavior in loops can be analyzed using the
- 'analyze_scalar_evolution' function. The returned SCEV however does not
- have to be fully analyzed and it may contain references to other SSA
- names defined in the loop. To resolve these (potentially recursive)
- references, 'instantiate_parameters' or 'resolve_mixers' functions must
- be used. 'instantiate_parameters' is useful when you use the results of
- SCEV only for some analysis, and when you work with whole nest of loops
- at once. It will try replacing all SSA names by their SCEV in all
- loops, including the super-loops of the current loop, thus providing a
- complete information about the behavior of the variable in the loop
- nest. 'resolve_mixers' is useful if you work with only one loop at a
- time, and if you possibly need to create code based on the value of the
- induction variable. It will only resolve the SSA names defined in the
- current loop, leaving the SSA names defined outside unchanged, even if
- their evolution in the outer loops is known.
-
- The SCEV is a normal tree expression, except for the fact that it may
- contain several special tree nodes. One of them is 'SCEV_NOT_KNOWN',
- used for SSA names whose value cannot be expressed. The other one is
- 'POLYNOMIAL_CHREC'. Polynomial chrec has three arguments - base, step
- and loop (both base and step may contain further polynomial chrecs).
- Type of the expression and of base and step must be the same. A
- variable has evolution 'POLYNOMIAL_CHREC(base, step, loop)' if it is (in
- the specified loop) equivalent to 'x_1' in the following example
-
- while (...)
- {
- x_1 = phi (base, x_2);
- x_2 = x_1 + step;
- }
-
- Note that this includes the language restrictions on the operations.
- For example, if we compile C code and 'x' has signed type, then the
- overflow in addition would cause undefined behavior, and we may assume
- that this does not happen. Hence, the value with this SCEV cannot
- overflow (which restricts the number of iterations of such a loop).
-
- In many cases, one wants to restrict the attention just to affine
- induction variables. In this case, the extra expressive power of SCEV
- is not useful, and may complicate the optimizations. In this case,
- 'simple_iv' function may be used to analyze a value - the result is a
- loop-invariant base and step.
-
-
- File: gccint.info, Node: loop-iv, Next: Number of iterations, Prev: Scalar evolutions, Up: Loop Analysis and Representation
-
- 16.6 IV analysis on RTL
- =======================
-
- The induction variable on RTL is simple and only allows analysis of
- affine induction variables, and only in one loop at once. The interface
- is declared in 'cfgloop.h'. Before analyzing induction variables in a
- loop L, 'iv_analysis_loop_init' function must be called on L. After the
- analysis (possibly calling 'iv_analysis_loop_init' for several loops) is
- finished, 'iv_analysis_done' should be called. The following functions
- can be used to access the results of the analysis:
-
- * 'iv_analyze': Analyzes a single register used in the given insn.
- If no use of the register in this insn is found, the following
- insns are scanned, so that this function can be called on the insn
- returned by get_condition.
- * 'iv_analyze_result': Analyzes result of the assignment in the given
- insn.
- * 'iv_analyze_expr': Analyzes a more complicated expression. All its
- operands are analyzed by 'iv_analyze', and hence they must be used
- in the specified insn or one of the following insns.
-
- The description of the induction variable is provided in 'struct
- rtx_iv'. In order to handle subregs, the representation is a bit
- complicated; if the value of the 'extend' field is not 'UNKNOWN', the
- value of the induction variable in the i-th iteration is
-
- delta + mult * extend_{extend_mode} (subreg_{mode} (base + i * step)),
-
- with the following exception: if 'first_special' is true, then the
- value in the first iteration (when 'i' is zero) is 'delta + mult *
- base'. However, if 'extend' is equal to 'UNKNOWN', then 'first_special'
- must be false, 'delta' 0, 'mult' 1 and the value in the i-th iteration
- is
-
- subreg_{mode} (base + i * step)
-
- The function 'get_iv_value' can be used to perform these calculations.
-
-
- File: gccint.info, Node: Number of iterations, Next: Dependency analysis, Prev: loop-iv, Up: Loop Analysis and Representation
-
- 16.7 Number of iterations analysis
- ==================================
-
- Both on GIMPLE and on RTL, there are functions available to determine
- the number of iterations of a loop, with a similar interface. The
- number of iterations of a loop in GCC is defined as the number of
- executions of the loop latch. In many cases, it is not possible to
- determine the number of iterations unconditionally - the determined
- number is correct only if some assumptions are satisfied. The analysis
- tries to verify these conditions using the information contained in the
- program; if it fails, the conditions are returned together with the
- result. The following information and conditions are provided by the
- analysis:
-
- * 'assumptions': If this condition is false, the rest of the
- information is invalid.
- * 'noloop_assumptions' on RTL, 'may_be_zero' on GIMPLE: If this
- condition is true, the loop exits in the first iteration.
- * 'infinite': If this condition is true, the loop is infinite. This
- condition is only available on RTL. On GIMPLE, conditions for
- finiteness of the loop are included in 'assumptions'.
- * 'niter_expr' on RTL, 'niter' on GIMPLE: The expression that gives
- number of iterations. The number of iterations is defined as the
- number of executions of the loop latch.
-
- Both on GIMPLE and on RTL, it necessary for the induction variable
- analysis framework to be initialized (SCEV on GIMPLE, loop-iv on RTL).
- On GIMPLE, the results are stored to 'struct tree_niter_desc' structure.
- Number of iterations before the loop is exited through a given exit can
- be determined using 'number_of_iterations_exit' function. On RTL, the
- results are returned in 'struct niter_desc' structure. The
- corresponding function is named 'check_simple_exit'. There are also
- functions that pass through all the exits of a loop and try to find one
- with easy to determine number of iterations - 'find_loop_niter' on
- GIMPLE and 'find_simple_exit' on RTL. Finally, there are functions that
- provide the same information, but additionally cache it, so that
- repeated calls to number of iterations are not so costly -
- 'number_of_latch_executions' on GIMPLE and 'get_simple_loop_desc' on
- RTL.
-
- Note that some of these functions may behave slightly differently than
- others - some of them return only the expression for the number of
- iterations, and fail if there are some assumptions. The function
- 'number_of_latch_executions' works only for single-exit loops. The
- function 'number_of_cond_exit_executions' can be used to determine
- number of executions of the exit condition of a single-exit loop (i.e.,
- the 'number_of_latch_executions' increased by one).
-
- On GIMPLE, below constraint flags affect semantics of some APIs of
- number of iterations analyzer:
-
- * 'LOOP_C_INFINITE': If this constraint flag is set, the loop is
- known to be infinite. APIs like 'number_of_iterations_exit' can
- return false directly without doing any analysis.
- * 'LOOP_C_FINITE': If this constraint flag is set, the loop is known
- to be finite, in other words, loop's number of iterations can be
- computed with 'assumptions' be true.
-
- Generally, the constraint flags are set/cleared by consumers which are
- loop optimizers. It's also the consumers' responsibility to set/clear
- constraints correctly. Failing to do that might result in hard to track
- down bugs in scev/niter consumers. One typical use case is vectorizer:
- it drives number of iterations analyzer by setting 'LOOP_C_FINITE' and
- vectorizes possibly infinite loop by versioning loop with analysis
- result. In return, constraints set by consumers can also help number of
- iterations analyzer in following optimizers. For example, 'niter' of a
- loop versioned under 'assumptions' is valid unconditionally.
-
- Other constraints may be added in the future, for example, a constraint
- indicating that loops' latch must roll thus 'may_be_zero' would be false
- unconditionally.
-
-
- File: gccint.info, Node: Dependency analysis, Prev: Number of iterations, Up: Loop Analysis and Representation
-
- 16.8 Data Dependency Analysis
- =============================
-
- The code for the data dependence analysis can be found in
- 'tree-data-ref.c' and its interface and data structures are described in
- 'tree-data-ref.h'. The function that computes the data dependences for
- all the array and pointer references for a given loop is
- 'compute_data_dependences_for_loop'. This function is currently used by
- the linear loop transform and the vectorization passes. Before calling
- this function, one has to allocate two vectors: a first vector will
- contain the set of data references that are contained in the analyzed
- loop body, and the second vector will contain the dependence relations
- between the data references. Thus if the vector of data references is
- of size 'n', the vector containing the dependence relations will contain
- 'n*n' elements. However if the analyzed loop contains side effects,
- such as calls that potentially can interfere with the data references in
- the current analyzed loop, the analysis stops while scanning the loop
- body for data references, and inserts a single 'chrec_dont_know' in the
- dependence relation array.
-
- The data references are discovered in a particular order during the
- scanning of the loop body: the loop body is analyzed in execution order,
- and the data references of each statement are pushed at the end of the
- data reference array. Two data references syntactically occur in the
- program in the same order as in the array of data references. This
- syntactic order is important in some classical data dependence tests,
- and mapping this order to the elements of this array avoids costly
- queries to the loop body representation.
-
- Three types of data references are currently handled: ARRAY_REF,
- INDIRECT_REF and COMPONENT_REF. The data structure for the data
- reference is 'data_reference', where 'data_reference_p' is a name of a
- pointer to the data reference structure. The structure contains the
- following elements:
-
- * 'base_object_info': Provides information about the base object of
- the data reference and its access functions. These access
- functions represent the evolution of the data reference in the loop
- relative to its base, in keeping with the classical meaning of the
- data reference access function for the support of arrays. For
- example, for a reference 'a.b[i][j]', the base object is 'a.b' and
- the access functions, one for each array subscript, are: '{i_init,
- + i_step}_1, {j_init, +, j_step}_2'.
-
- * 'first_location_in_loop': Provides information about the first
- location accessed by the data reference in the loop and about the
- access function used to represent evolution relative to this
- location. This data is used to support pointers, and is not used
- for arrays (for which we have base objects). Pointer accesses are
- represented as a one-dimensional access that starts from the first
- location accessed in the loop. For example:
-
- for1 i
- for2 j
- *((int *)p + i + j) = a[i][j];
-
- The access function of the pointer access is '{0, + 4B}_for2'
- relative to 'p + i'. The access functions of the array are
- '{i_init, + i_step}_for1' and '{j_init, +, j_step}_for2' relative
- to 'a'.
-
- Usually, the object the pointer refers to is either unknown, or we
- cannot prove that the access is confined to the boundaries of a
- certain object.
-
- Two data references can be compared only if at least one of these
- two representations has all its fields filled for both data
- references.
-
- The current strategy for data dependence tests is as follows: If
- both 'a' and 'b' are represented as arrays, compare 'a.base_object'
- and 'b.base_object'; if they are equal, apply dependence tests (use
- access functions based on base_objects). Else if both 'a' and 'b'
- are represented as pointers, compare 'a.first_location' and
- 'b.first_location'; if they are equal, apply dependence tests (use
- access functions based on first location). However, if 'a' and 'b'
- are represented differently, only try to prove that the bases are
- definitely different.
-
- * Aliasing information.
- * Alignment information.
-
- The structure describing the relation between two data references is
- 'data_dependence_relation' and the shorter name for a pointer to such a
- structure is 'ddr_p'. This structure contains:
-
- * a pointer to each data reference,
- * a tree node 'are_dependent' that is set to 'chrec_known' if the
- analysis has proved that there is no dependence between these two
- data references, 'chrec_dont_know' if the analysis was not able to
- determine any useful result and potentially there could exist a
- dependence between these data references, and 'are_dependent' is
- set to 'NULL_TREE' if there exist a dependence relation between the
- data references, and the description of this dependence relation is
- given in the 'subscripts', 'dir_vects', and 'dist_vects' arrays,
- * a boolean that determines whether the dependence relation can be
- represented by a classical distance vector,
- * an array 'subscripts' that contains a description of each subscript
- of the data references. Given two array accesses a subscript is
- the tuple composed of the access functions for a given dimension.
- For example, given 'A[f1][f2][f3]' and 'B[g1][g2][g3]', there are
- three subscripts: '(f1, g1), (f2, g2), (f3, g3)'.
- * two arrays 'dir_vects' and 'dist_vects' that contain classical
- representations of the data dependences under the form of direction
- and distance dependence vectors,
- * an array of loops 'loop_nest' that contains the loops to which the
- distance and direction vectors refer to.
-
- Several functions for pretty printing the information extracted by the
- data dependence analysis are available: 'dump_ddrs' prints with a
- maximum verbosity the details of a data dependence relations array,
- 'dump_dist_dir_vectors' prints only the classical distance and direction
- vectors for a data dependence relations array, and
- 'dump_data_references' prints the details of the data references
- contained in a data reference array.
-
-
- File: gccint.info, Node: Machine Desc, Next: Target Macros, Prev: Loop Analysis and Representation, Up: Top
-
- 17 Machine Descriptions
- ***********************
-
- A machine description has two parts: a file of instruction patterns
- ('.md' file) and a C header file of macro definitions.
-
- The '.md' file for a target machine contains a pattern for each
- instruction that the target machine supports (or at least each
- instruction that is worth telling the compiler about). It may also
- contain comments. A semicolon causes the rest of the line to be a
- comment, unless the semicolon is inside a quoted string.
-
- See the next chapter for information on the C header file.
-
- * Menu:
-
- * Overview:: How the machine description is used.
- * Patterns:: How to write instruction patterns.
- * Example:: An explained example of a 'define_insn' pattern.
- * RTL Template:: The RTL template defines what insns match a pattern.
- * Output Template:: The output template says how to make assembler code
- from such an insn.
- * Output Statement:: For more generality, write C code to output
- the assembler code.
- * Predicates:: Controlling what kinds of operands can be used
- for an insn.
- * Constraints:: Fine-tuning operand selection.
- * Standard Names:: Names mark patterns to use for code generation.
- * Pattern Ordering:: When the order of patterns makes a difference.
- * Dependent Patterns:: Having one pattern may make you need another.
- * Jump Patterns:: Special considerations for patterns for jump insns.
- * Looping Patterns:: How to define patterns for special looping insns.
- * Insn Canonicalizations::Canonicalization of Instructions
- * Expander Definitions::Generating a sequence of several RTL insns
- for a standard operation.
- * Insn Splitting:: Splitting Instructions into Multiple Instructions.
- * Including Patterns:: Including Patterns in Machine Descriptions.
- * Peephole Definitions::Defining machine-specific peephole optimizations.
- * Insn Attributes:: Specifying the value of attributes for generated insns.
- * Conditional Execution::Generating 'define_insn' patterns for
- predication.
- * Define Subst:: Generating 'define_insn' and 'define_expand'
- patterns from other patterns.
- * Constant Definitions::Defining symbolic constants that can be used in the
- md file.
- * Iterators:: Using iterators to generate patterns from a template.
-
-
- File: gccint.info, Node: Overview, Next: Patterns, Up: Machine Desc
-
- 17.1 Overview of How the Machine Description is Used
- ====================================================
-
- There are three main conversions that happen in the compiler:
-
- 1. The front end reads the source code and builds a parse tree.
-
- 2. The parse tree is used to generate an RTL insn list based on named
- instruction patterns.
-
- 3. The insn list is matched against the RTL templates to produce
- assembler code.
-
- For the generate pass, only the names of the insns matter, from either
- a named 'define_insn' or a 'define_expand'. The compiler will choose
- the pattern with the right name and apply the operands according to the
- documentation later in this chapter, without regard for the RTL template
- or operand constraints. Note that the names the compiler looks for are
- hard-coded in the compiler--it will ignore unnamed patterns and patterns
- with names it doesn't know about, but if you don't provide a named
- pattern it needs, it will abort.
-
- If a 'define_insn' is used, the template given is inserted into the
- insn list. If a 'define_expand' is used, one of three things happens,
- based on the condition logic. The condition logic may manually create
- new insns for the insn list, say via 'emit_insn()', and invoke 'DONE'.
- For certain named patterns, it may invoke 'FAIL' to tell the compiler to
- use an alternate way of performing that task. If it invokes neither
- 'DONE' nor 'FAIL', the template given in the pattern is inserted, as if
- the 'define_expand' were a 'define_insn'.
-
- Once the insn list is generated, various optimization passes convert,
- replace, and rearrange the insns in the insn list. This is where the
- 'define_split' and 'define_peephole' patterns get used, for example.
-
- Finally, the insn list's RTL is matched up with the RTL templates in
- the 'define_insn' patterns, and those patterns are used to emit the
- final assembly code. For this purpose, each named 'define_insn' acts
- like it's unnamed, since the names are ignored.
-
-
- File: gccint.info, Node: Patterns, Next: Example, Prev: Overview, Up: Machine Desc
-
- 17.2 Everything about Instruction Patterns
- ==========================================
-
- A 'define_insn' expression is used to define instruction patterns to
- which insns may be matched. A 'define_insn' expression contains an
- incomplete RTL expression, with pieces to be filled in later, operand
- constraints that restrict how the pieces can be filled in, and an output
- template or C code to generate the assembler output.
-
- A 'define_insn' is an RTL expression containing four or five operands:
-
- 1. An optional name N. When a name is present, the compiler
- automically generates a C++ function 'gen_N' that takes the
- operands of the instruction as arguments and returns the
- instruction's rtx pattern. The compiler also assigns the
- instruction a unique code 'CODE_FOR_N', with all such codes
- belonging to an enum called 'insn_code'.
-
- These names serve one of two purposes. The first is to indicate
- that the instruction performs a certain standard job for the
- RTL-generation pass of the compiler, such as a move, an addition,
- or a conditional jump. The second is to help the target generate
- certain target-specific operations, such as when implementing
- target-specific intrinsic functions.
-
- It is better to prefix target-specific names with the name of the
- target, to avoid any clash with current or future standard names.
-
- The absence of a name is indicated by writing an empty string where
- the name should go. Nameless instruction patterns are never used
- for generating RTL code, but they may permit several simpler insns
- to be combined later on.
-
- For the purpose of debugging the compiler, you may also specify a
- name beginning with the '*' character. Such a name is used only
- for identifying the instruction in RTL dumps; it is equivalent to
- having a nameless pattern for all other purposes. Names beginning
- with the '*' character are not required to be unique.
-
- The name may also have the form '@N'. This has the same effect as
- a name 'N', but in addition tells the compiler to generate further
- helper functions; see *note Parameterized Names:: for details.
-
- 2. The "RTL template": This is a vector of incomplete RTL expressions
- which describe the semantics of the instruction (*note RTL
- Template::). It is incomplete because it may contain
- 'match_operand', 'match_operator', and 'match_dup' expressions that
- stand for operands of the instruction.
-
- If the vector has multiple elements, the RTL template is treated as
- a 'parallel' expression.
-
- 3. The condition: This is a string which contains a C expression.
- When the compiler attempts to match RTL against a pattern, the
- condition is evaluated. If the condition evaluates to 'true', the
- match is permitted. The condition may be an empty string, which is
- treated as always 'true'.
-
- For a named pattern, the condition may not depend on the data in
- the insn being matched, but only the target-machine-type flags.
- The compiler needs to test these conditions during initialization
- in order to learn exactly which named instructions are available in
- a particular run.
-
- For nameless patterns, the condition is applied only when matching
- an individual insn, and only after the insn has matched the
- pattern's recognition template. The insn's operands may be found
- in the vector 'operands'.
-
- An instruction condition cannot become more restrictive as
- compilation progresses. If the condition accepts a particular RTL
- instruction at one stage of compilation, it must continue to accept
- that instruction until the final pass. For example,
- '!reload_completed' and 'can_create_pseudo_p ()' are both invalid
- instruction conditions, because they are true during the earlier
- RTL passes and false during the later ones. For the same reason,
- if a condition accepts an instruction before register allocation,
- it cannot later try to control register allocation by excluding
- certain register or value combinations.
-
- Although a condition cannot become more restrictive as compilation
- progresses, the condition for a nameless pattern _can_ become more
- permissive. For example, a nameless instruction can require
- 'reload_completed' to be true, in which case it only matches after
- register allocation.
-
- 4. The "output template" or "output statement": This is either a
- string, or a fragment of C code which returns a string.
-
- When simple substitution isn't general enough, you can specify a
- piece of C code to compute the output. *Note Output Statement::.
-
- 5. The "insn attributes": This is an optional vector containing the
- values of attributes for insns matching this pattern (*note Insn
- Attributes::).
-
-
- File: gccint.info, Node: Example, Next: RTL Template, Prev: Patterns, Up: Machine Desc
-
- 17.3 Example of 'define_insn'
- =============================
-
- Here is an example of an instruction pattern, taken from the machine
- description for the 68000/68020.
-
- (define_insn "tstsi"
- [(set (cc0)
- (match_operand:SI 0 "general_operand" "rm"))]
- ""
- "*
- {
- if (TARGET_68020 || ! ADDRESS_REG_P (operands[0]))
- return \"tstl %0\";
- return \"cmpl #0,%0\";
- }")
-
- This can also be written using braced strings:
-
- (define_insn "tstsi"
- [(set (cc0)
- (match_operand:SI 0 "general_operand" "rm"))]
- ""
- {
- if (TARGET_68020 || ! ADDRESS_REG_P (operands[0]))
- return "tstl %0";
- return "cmpl #0,%0";
- })
-
- This describes an instruction which sets the condition codes based on
- the value of a general operand. It has no condition, so any insn with
- an RTL description of the form shown may be matched to this pattern.
- The name 'tstsi' means "test a 'SImode' value" and tells the RTL
- generation pass that, when it is necessary to test such a value, an insn
- to do so can be constructed using this pattern.
-
- The output control string is a piece of C code which chooses which
- output template to return based on the kind of operand and the specific
- type of CPU for which code is being generated.
-
- '"rm"' is an operand constraint. Its meaning is explained below.
-
-
- File: gccint.info, Node: RTL Template, Next: Output Template, Prev: Example, Up: Machine Desc
-
- 17.4 RTL Template
- =================
-
- The RTL template is used to define which insns match the particular
- pattern and how to find their operands. For named patterns, the RTL
- template also says how to construct an insn from specified operands.
-
- Construction involves substituting specified operands into a copy of
- the template. Matching involves determining the values that serve as
- the operands in the insn being matched. Both of these activities are
- controlled by special expression types that direct matching and
- substitution of the operands.
-
- '(match_operand:M N PREDICATE CONSTRAINT)'
- This expression is a placeholder for operand number N of the insn.
- When constructing an insn, operand number N will be substituted at
- this point. When matching an insn, whatever appears at this
- position in the insn will be taken as operand number N; but it must
- satisfy PREDICATE or this instruction pattern will not match at
- all.
-
- Operand numbers must be chosen consecutively counting from zero in
- each instruction pattern. There may be only one 'match_operand'
- expression in the pattern for each operand number. Usually
- operands are numbered in the order of appearance in 'match_operand'
- expressions. In the case of a 'define_expand', any operand numbers
- used only in 'match_dup' expressions have higher values than all
- other operand numbers.
-
- PREDICATE is a string that is the name of a function that accepts
- two arguments, an expression and a machine mode. *Note
- Predicates::. During matching, the function will be called with
- the putative operand as the expression and M as the mode argument
- (if M is not specified, 'VOIDmode' will be used, which normally
- causes PREDICATE to accept any mode). If it returns zero, this
- instruction pattern fails to match. PREDICATE may be an empty
- string; then it means no test is to be done on the operand, so
- anything which occurs in this position is valid.
-
- Most of the time, PREDICATE will reject modes other than M--but not
- always. For example, the predicate 'address_operand' uses M as the
- mode of memory ref that the address should be valid for. Many
- predicates accept 'const_int' nodes even though their mode is
- 'VOIDmode'.
-
- CONSTRAINT controls reloading and the choice of the best register
- class to use for a value, as explained later (*note Constraints::).
- If the constraint would be an empty string, it can be omitted.
-
- People are often unclear on the difference between the constraint
- and the predicate. The predicate helps decide whether a given insn
- matches the pattern. The constraint plays no role in this
- decision; instead, it controls various decisions in the case of an
- insn which does match.
-
- '(match_scratch:M N CONSTRAINT)'
- This expression is also a placeholder for operand number N and
- indicates that operand must be a 'scratch' or 'reg' expression.
-
- When matching patterns, this is equivalent to
-
- (match_operand:M N "scratch_operand" CONSTRAINT)
-
- but, when generating RTL, it produces a ('scratch':M) expression.
-
- If the last few expressions in a 'parallel' are 'clobber'
- expressions whose operands are either a hard register or
- 'match_scratch', the combiner can add or delete them when
- necessary. *Note Side Effects::.
-
- '(match_dup N)'
- This expression is also a placeholder for operand number N. It is
- used when the operand needs to appear more than once in the insn.
-
- In construction, 'match_dup' acts just like 'match_operand': the
- operand is substituted into the insn being constructed. But in
- matching, 'match_dup' behaves differently. It assumes that operand
- number N has already been determined by a 'match_operand' appearing
- earlier in the recognition template, and it matches only an
- identical-looking expression.
-
- Note that 'match_dup' should not be used to tell the compiler that
- a particular register is being used for two operands (example:
- 'add' that adds one register to another; the second register is
- both an input operand and the output operand). Use a matching
- constraint (*note Simple Constraints::) for those. 'match_dup' is
- for the cases where one operand is used in two places in the
- template, such as an instruction that computes both a quotient and
- a remainder, where the opcode takes two input operands but the RTL
- template has to refer to each of those twice; once for the quotient
- pattern and once for the remainder pattern.
-
- '(match_operator:M N PREDICATE [OPERANDS...])'
- This pattern is a kind of placeholder for a variable RTL expression
- code.
-
- When constructing an insn, it stands for an RTL expression whose
- expression code is taken from that of operand N, and whose operands
- are constructed from the patterns OPERANDS.
-
- When matching an expression, it matches an expression if the
- function PREDICATE returns nonzero on that expression _and_ the
- patterns OPERANDS match the operands of the expression.
-
- Suppose that the function 'commutative_operator' is defined as
- follows, to match any expression whose operator is one of the
- commutative arithmetic operators of RTL and whose mode is MODE:
-
- int
- commutative_integer_operator (x, mode)
- rtx x;
- machine_mode mode;
- {
- enum rtx_code code = GET_CODE (x);
- if (GET_MODE (x) != mode)
- return 0;
- return (GET_RTX_CLASS (code) == RTX_COMM_ARITH
- || code == EQ || code == NE);
- }
-
- Then the following pattern will match any RTL expression consisting
- of a commutative operator applied to two general operands:
-
- (match_operator:SI 3 "commutative_operator"
- [(match_operand:SI 1 "general_operand" "g")
- (match_operand:SI 2 "general_operand" "g")])
-
- Here the vector '[OPERANDS...]' contains two patterns because the
- expressions to be matched all contain two operands.
-
- When this pattern does match, the two operands of the commutative
- operator are recorded as operands 1 and 2 of the insn. (This is
- done by the two instances of 'match_operand'.) Operand 3 of the
- insn will be the entire commutative expression: use 'GET_CODE
- (operands[3])' to see which commutative operator was used.
-
- The machine mode M of 'match_operator' works like that of
- 'match_operand': it is passed as the second argument to the
- predicate function, and that function is solely responsible for
- deciding whether the expression to be matched "has" that mode.
-
- When constructing an insn, argument 3 of the gen-function will
- specify the operation (i.e. the expression code) for the expression
- to be made. It should be an RTL expression, whose expression code
- is copied into a new expression whose operands are arguments 1 and
- 2 of the gen-function. The subexpressions of argument 3 are not
- used; only its expression code matters.
-
- When 'match_operator' is used in a pattern for matching an insn, it
- usually best if the operand number of the 'match_operator' is
- higher than that of the actual operands of the insn. This improves
- register allocation because the register allocator often looks at
- operands 1 and 2 of insns to see if it can do register tying.
-
- There is no way to specify constraints in 'match_operator'. The
- operand of the insn which corresponds to the 'match_operator' never
- has any constraints because it is never reloaded as a whole.
- However, if parts of its OPERANDS are matched by 'match_operand'
- patterns, those parts may have constraints of their own.
-
- '(match_op_dup:M N[OPERANDS...])'
- Like 'match_dup', except that it applies to operators instead of
- operands. When constructing an insn, operand number N will be
- substituted at this point. But in matching, 'match_op_dup' behaves
- differently. It assumes that operand number N has already been
- determined by a 'match_operator' appearing earlier in the
- recognition template, and it matches only an identical-looking
- expression.
-
- '(match_parallel N PREDICATE [SUBPAT...])'
- This pattern is a placeholder for an insn that consists of a
- 'parallel' expression with a variable number of elements. This
- expression should only appear at the top level of an insn pattern.
-
- When constructing an insn, operand number N will be substituted at
- this point. When matching an insn, it matches if the body of the
- insn is a 'parallel' expression with at least as many elements as
- the vector of SUBPAT expressions in the 'match_parallel', if each
- SUBPAT matches the corresponding element of the 'parallel', _and_
- the function PREDICATE returns nonzero on the 'parallel' that is
- the body of the insn. It is the responsibility of the predicate to
- validate elements of the 'parallel' beyond those listed in the
- 'match_parallel'.
-
- A typical use of 'match_parallel' is to match load and store
- multiple expressions, which can contain a variable number of
- elements in a 'parallel'. For example,
-
- (define_insn ""
- [(match_parallel 0 "load_multiple_operation"
- [(set (match_operand:SI 1 "gpc_reg_operand" "=r")
- (match_operand:SI 2 "memory_operand" "m"))
- (use (reg:SI 179))
- (clobber (reg:SI 179))])]
- ""
- "loadm 0,0,%1,%2")
-
- This example comes from 'a29k.md'. The function
- 'load_multiple_operation' is defined in 'a29k.c' and checks that
- subsequent elements in the 'parallel' are the same as the 'set' in
- the pattern, except that they are referencing subsequent registers
- and memory locations.
-
- An insn that matches this pattern might look like:
-
- (parallel
- [(set (reg:SI 20) (mem:SI (reg:SI 100)))
- (use (reg:SI 179))
- (clobber (reg:SI 179))
- (set (reg:SI 21)
- (mem:SI (plus:SI (reg:SI 100)
- (const_int 4))))
- (set (reg:SI 22)
- (mem:SI (plus:SI (reg:SI 100)
- (const_int 8))))])
-
- '(match_par_dup N [SUBPAT...])'
- Like 'match_op_dup', but for 'match_parallel' instead of
- 'match_operator'.
-
-
- File: gccint.info, Node: Output Template, Next: Output Statement, Prev: RTL Template, Up: Machine Desc
-
- 17.5 Output Templates and Operand Substitution
- ==============================================
-
- The "output template" is a string which specifies how to output the
- assembler code for an instruction pattern. Most of the template is a
- fixed string which is output literally. The character '%' is used to
- specify where to substitute an operand; it can also be used to identify
- places where different variants of the assembler require different
- syntax.
-
- In the simplest case, a '%' followed by a digit N says to output
- operand N at that point in the string.
-
- '%' followed by a letter and a digit says to output an operand in an
- alternate fashion. Four letters have standard, built-in meanings
- described below. The machine description macro 'PRINT_OPERAND' can
- define additional letters with nonstandard meanings.
-
- '%cDIGIT' can be used to substitute an operand that is a constant value
- without the syntax that normally indicates an immediate operand.
-
- '%nDIGIT' is like '%cDIGIT' except that the value of the constant is
- negated before printing.
-
- '%aDIGIT' can be used to substitute an operand as if it were a memory
- reference, with the actual operand treated as the address. This may be
- useful when outputting a "load address" instruction, because often the
- assembler syntax for such an instruction requires you to write the
- operand as if it were a memory reference.
-
- '%lDIGIT' is used to substitute a 'label_ref' into a jump instruction.
-
- '%=' outputs a number which is unique to each instruction in the entire
- compilation. This is useful for making local labels to be referred to
- more than once in a single template that generates multiple assembler
- instructions.
-
- '%' followed by a punctuation character specifies a substitution that
- does not use an operand. Only one case is standard: '%%' outputs a '%'
- into the assembler code. Other nonstandard cases can be defined in the
- 'PRINT_OPERAND' macro. You must also define which punctuation
- characters are valid with the 'PRINT_OPERAND_PUNCT_VALID_P' macro.
-
- The template may generate multiple assembler instructions. Write the
- text for the instructions, with '\;' between them.
-
- When the RTL contains two operands which are required by constraint to
- match each other, the output template must refer only to the
- lower-numbered operand. Matching operands are not always identical, and
- the rest of the compiler arranges to put the proper RTL expression for
- printing into the lower-numbered operand.
-
- One use of nonstandard letters or punctuation following '%' is to
- distinguish between different assembler languages for the same machine;
- for example, Motorola syntax versus MIT syntax for the 68000. Motorola
- syntax requires periods in most opcode names, while MIT syntax does not.
- For example, the opcode 'movel' in MIT syntax is 'move.l' in Motorola
- syntax. The same file of patterns is used for both kinds of output
- syntax, but the character sequence '%.' is used in each place where
- Motorola syntax wants a period. The 'PRINT_OPERAND' macro for Motorola
- syntax defines the sequence to output a period; the macro for MIT syntax
- defines it to do nothing.
-
- As a special case, a template consisting of the single character '#'
- instructs the compiler to first split the insn, and then output the
- resulting instructions separately. This helps eliminate redundancy in
- the output templates. If you have a 'define_insn' that needs to emit
- multiple assembler instructions, and there is a matching 'define_split'
- already defined, then you can simply use '#' as the output template
- instead of writing an output template that emits the multiple assembler
- instructions.
-
- Note that '#' only has an effect while generating assembly code; it
- does not affect whether a split occurs earlier. An associated
- 'define_split' must exist and it must be suitable for use after register
- allocation.
-
- If the macro 'ASSEMBLER_DIALECT' is defined, you can use construct of
- the form '{option0|option1|option2}' in the templates. These describe
- multiple variants of assembler language syntax. *Note Instruction
- Output::.
-
-
- File: gccint.info, Node: Output Statement, Next: Predicates, Prev: Output Template, Up: Machine Desc
-
- 17.6 C Statements for Assembler Output
- ======================================
-
- Often a single fixed template string cannot produce correct and
- efficient assembler code for all the cases that are recognized by a
- single instruction pattern. For example, the opcodes may depend on the
- kinds of operands; or some unfortunate combinations of operands may
- require extra machine instructions.
-
- If the output control string starts with a '@', then it is actually a
- series of templates, each on a separate line. (Blank lines and leading
- spaces and tabs are ignored.) The templates correspond to the pattern's
- constraint alternatives (*note Multi-Alternative::). For example, if a
- target machine has a two-address add instruction 'addr' to add into a
- register and another 'addm' to add a register to memory, you might write
- this pattern:
-
- (define_insn "addsi3"
- [(set (match_operand:SI 0 "general_operand" "=r,m")
- (plus:SI (match_operand:SI 1 "general_operand" "0,0")
- (match_operand:SI 2 "general_operand" "g,r")))]
- ""
- "@
- addr %2,%0
- addm %2,%0")
-
- If the output control string starts with a '*', then it is not an
- output template but rather a piece of C program that should compute a
- template. It should execute a 'return' statement to return the
- template-string you want. Most such templates use C string literals,
- which require doublequote characters to delimit them. To include these
- doublequote characters in the string, prefix each one with '\'.
-
- If the output control string is written as a brace block instead of a
- double-quoted string, it is automatically assumed to be C code. In that
- case, it is not necessary to put in a leading asterisk, or to escape the
- doublequotes surrounding C string literals.
-
- The operands may be found in the array 'operands', whose C data type is
- 'rtx []'.
-
- It is very common to select different ways of generating assembler code
- based on whether an immediate operand is within a certain range. Be
- careful when doing this, because the result of 'INTVAL' is an integer on
- the host machine. If the host machine has more bits in an 'int' than
- the target machine has in the mode in which the constant will be used,
- then some of the bits you get from 'INTVAL' will be superfluous. For
- proper results, you must carefully disregard the values of those bits.
-
- It is possible to output an assembler instruction and then go on to
- output or compute more of them, using the subroutine 'output_asm_insn'.
- This receives two arguments: a template-string and a vector of operands.
- The vector may be 'operands', or it may be another array of 'rtx' that
- you declare locally and initialize yourself.
-
- When an insn pattern has multiple alternatives in its constraints,
- often the appearance of the assembler code is determined mostly by which
- alternative was matched. When this is so, the C code can test the
- variable 'which_alternative', which is the ordinal number of the
- alternative that was actually satisfied (0 for the first, 1 for the
- second alternative, etc.).
-
- For example, suppose there are two opcodes for storing zero, 'clrreg'
- for registers and 'clrmem' for memory locations. Here is how a pattern
- could use 'which_alternative' to choose between them:
-
- (define_insn ""
- [(set (match_operand:SI 0 "general_operand" "=r,m")
- (const_int 0))]
- ""
- {
- return (which_alternative == 0
- ? "clrreg %0" : "clrmem %0");
- })
-
- The example above, where the assembler code to generate was _solely_
- determined by the alternative, could also have been specified as
- follows, having the output control string start with a '@':
-
- (define_insn ""
- [(set (match_operand:SI 0 "general_operand" "=r,m")
- (const_int 0))]
- ""
- "@
- clrreg %0
- clrmem %0")
-
- If you just need a little bit of C code in one (or a few) alternatives,
- you can use '*' inside of a '@' multi-alternative template:
-
- (define_insn ""
- [(set (match_operand:SI 0 "general_operand" "=r,<,m")
- (const_int 0))]
- ""
- "@
- clrreg %0
- * return stack_mem_p (operands[0]) ? \"push 0\" : \"clrmem %0\";
- clrmem %0")
-
-
- File: gccint.info, Node: Predicates, Next: Constraints, Prev: Output Statement, Up: Machine Desc
-
- 17.7 Predicates
- ===============
-
- A predicate determines whether a 'match_operand' or 'match_operator'
- expression matches, and therefore whether the surrounding instruction
- pattern will be used for that combination of operands. GCC has a number
- of machine-independent predicates, and you can define machine-specific
- predicates as needed. By convention, predicates used with
- 'match_operand' have names that end in '_operand', and those used with
- 'match_operator' have names that end in '_operator'.
-
- All predicates are boolean functions (in the mathematical sense) of two
- arguments: the RTL expression that is being considered at that position
- in the instruction pattern, and the machine mode that the
- 'match_operand' or 'match_operator' specifies. In this section, the
- first argument is called OP and the second argument MODE. Predicates
- can be called from C as ordinary two-argument functions; this can be
- useful in output templates or other machine-specific code.
-
- Operand predicates can allow operands that are not actually acceptable
- to the hardware, as long as the constraints give reload the ability to
- fix them up (*note Constraints::). However, GCC will usually generate
- better code if the predicates specify the requirements of the machine
- instructions as closely as possible. Reload cannot fix up operands that
- must be constants ("immediate operands"); you must use a predicate that
- allows only constants, or else enforce the requirement in the extra
- condition.
-
- Most predicates handle their MODE argument in a uniform manner. If
- MODE is 'VOIDmode' (unspecified), then OP can have any mode. If MODE is
- anything else, then OP must have the same mode, unless OP is a
- 'CONST_INT' or integer 'CONST_DOUBLE'. These RTL expressions always
- have 'VOIDmode', so it would be counterproductive to check that their
- mode matches. Instead, predicates that accept 'CONST_INT' and/or
- integer 'CONST_DOUBLE' check that the value stored in the constant will
- fit in the requested mode.
-
- Predicates with this behavior are called "normal". 'genrecog' can
- optimize the instruction recognizer based on knowledge of how normal
- predicates treat modes. It can also diagnose certain kinds of common
- errors in the use of normal predicates; for instance, it is almost
- always an error to use a normal predicate without specifying a mode.
-
- Predicates that do something different with their MODE argument are
- called "special". The generic predicates 'address_operand' and
- 'pmode_register_operand' are special predicates. 'genrecog' does not do
- any optimizations or diagnosis when special predicates are used.
-
- * Menu:
-
- * Machine-Independent Predicates:: Predicates available to all back ends.
- * Defining Predicates:: How to write machine-specific predicate
- functions.
-
-
- File: gccint.info, Node: Machine-Independent Predicates, Next: Defining Predicates, Up: Predicates
-
- 17.7.1 Machine-Independent Predicates
- -------------------------------------
-
- These are the generic predicates available to all back ends. They are
- defined in 'recog.c'. The first category of predicates allow only
- constant, or "immediate", operands.
-
- -- Function: immediate_operand
- This predicate allows any sort of constant that fits in MODE. It
- is an appropriate choice for instructions that take operands that
- must be constant.
-
- -- Function: const_int_operand
- This predicate allows any 'CONST_INT' expression that fits in MODE.
- It is an appropriate choice for an immediate operand that does not
- allow a symbol or label.
-
- -- Function: const_double_operand
- This predicate accepts any 'CONST_DOUBLE' expression that has
- exactly MODE. If MODE is 'VOIDmode', it will also accept
- 'CONST_INT'. It is intended for immediate floating point
- constants.
-
- The second category of predicates allow only some kind of machine
- register.
-
- -- Function: register_operand
- This predicate allows any 'REG' or 'SUBREG' expression that is
- valid for MODE. It is often suitable for arithmetic instruction
- operands on a RISC machine.
-
- -- Function: pmode_register_operand
- This is a slight variant on 'register_operand' which works around a
- limitation in the machine-description reader.
-
- (match_operand N "pmode_register_operand" CONSTRAINT)
-
- means exactly what
-
- (match_operand:P N "register_operand" CONSTRAINT)
-
- would mean, if the machine-description reader accepted ':P' mode
- suffixes. Unfortunately, it cannot, because 'Pmode' is an alias
- for some other mode, and might vary with machine-specific options.
- *Note Misc::.
-
- -- Function: scratch_operand
- This predicate allows hard registers and 'SCRATCH' expressions, but
- not pseudo-registers. It is used internally by 'match_scratch'; it
- should not be used directly.
-
- The third category of predicates allow only some kind of memory
- reference.
-
- -- Function: memory_operand
- This predicate allows any valid reference to a quantity of mode
- MODE in memory, as determined by the weak form of
- 'GO_IF_LEGITIMATE_ADDRESS' (*note Addressing Modes::).
-
- -- Function: address_operand
- This predicate is a little unusual; it allows any operand that is a
- valid expression for the _address_ of a quantity of mode MODE,
- again determined by the weak form of 'GO_IF_LEGITIMATE_ADDRESS'.
- To first order, if '(mem:MODE (EXP))' is acceptable to
- 'memory_operand', then EXP is acceptable to 'address_operand'.
- Note that EXP does not necessarily have the mode MODE.
-
- -- Function: indirect_operand
- This is a stricter form of 'memory_operand' which allows only
- memory references with a 'general_operand' as the address
- expression. New uses of this predicate are discouraged, because
- 'general_operand' is very permissive, so it's hard to tell what an
- 'indirect_operand' does or does not allow. If a target has
- different requirements for memory operands for different
- instructions, it is better to define target-specific predicates
- which enforce the hardware's requirements explicitly.
-
- -- Function: push_operand
- This predicate allows a memory reference suitable for pushing a
- value onto the stack. This will be a 'MEM' which refers to
- 'stack_pointer_rtx', with a side effect in its address expression
- (*note Incdec::); which one is determined by the 'STACK_PUSH_CODE'
- macro (*note Frame Layout::).
-
- -- Function: pop_operand
- This predicate allows a memory reference suitable for popping a
- value off the stack. Again, this will be a 'MEM' referring to
- 'stack_pointer_rtx', with a side effect in its address expression.
- However, this time 'STACK_POP_CODE' is expected.
-
- The fourth category of predicates allow some combination of the above
- operands.
-
- -- Function: nonmemory_operand
- This predicate allows any immediate or register operand valid for
- MODE.
-
- -- Function: nonimmediate_operand
- This predicate allows any register or memory operand valid for
- MODE.
-
- -- Function: general_operand
- This predicate allows any immediate, register, or memory operand
- valid for MODE.
-
- Finally, there are two generic operator predicates.
-
- -- Function: comparison_operator
- This predicate matches any expression which performs an arithmetic
- comparison in MODE; that is, 'COMPARISON_P' is true for the
- expression code.
-
- -- Function: ordered_comparison_operator
- This predicate matches any expression which performs an arithmetic
- comparison in MODE and whose expression code is valid for integer
- modes; that is, the expression code will be one of 'eq', 'ne',
- 'lt', 'ltu', 'le', 'leu', 'gt', 'gtu', 'ge', 'geu'.
-
-
- File: gccint.info, Node: Defining Predicates, Prev: Machine-Independent Predicates, Up: Predicates
-
- 17.7.2 Defining Machine-Specific Predicates
- -------------------------------------------
-
- Many machines have requirements for their operands that cannot be
- expressed precisely using the generic predicates. You can define
- additional predicates using 'define_predicate' and
- 'define_special_predicate' expressions. These expressions have three
- operands:
-
- * The name of the predicate, as it will be referred to in
- 'match_operand' or 'match_operator' expressions.
-
- * An RTL expression which evaluates to true if the predicate allows
- the operand OP, false if it does not. This expression can only use
- the following RTL codes:
-
- 'MATCH_OPERAND'
- When written inside a predicate expression, a 'MATCH_OPERAND'
- expression evaluates to true if the predicate it names would
- allow OP. The operand number and constraint are ignored. Due
- to limitations in 'genrecog', you can only refer to generic
- predicates and predicates that have already been defined.
-
- 'MATCH_CODE'
- This expression evaluates to true if OP or a specified
- subexpression of OP has one of a given list of RTX codes.
-
- The first operand of this expression is a string constant
- containing a comma-separated list of RTX code names (in lower
- case). These are the codes for which the 'MATCH_CODE' will be
- true.
-
- The second operand is a string constant which indicates what
- subexpression of OP to examine. If it is absent or the empty
- string, OP itself is examined. Otherwise, the string constant
- must be a sequence of digits and/or lowercase letters. Each
- character indicates a subexpression to extract from the
- current expression; for the first character this is OP, for
- the second and subsequent characters it is the result of the
- previous character. A digit N extracts 'XEXP (E, N)'; a
- letter L extracts 'XVECEXP (E, 0, N)' where N is the
- alphabetic ordinal of L (0 for 'a', 1 for 'b', and so on).
- The 'MATCH_CODE' then examines the RTX code of the
- subexpression extracted by the complete string. It is not
- possible to extract components of an 'rtvec' that is not at
- position 0 within its RTX object.
-
- 'MATCH_TEST'
- This expression has one operand, a string constant containing
- a C expression. The predicate's arguments, OP and MODE, are
- available with those names in the C expression. The
- 'MATCH_TEST' evaluates to true if the C expression evaluates
- to a nonzero value. 'MATCH_TEST' expressions must not have
- side effects.
-
- 'AND'
- 'IOR'
- 'NOT'
- 'IF_THEN_ELSE'
- The basic 'MATCH_' expressions can be combined using these
- logical operators, which have the semantics of the C operators
- '&&', '||', '!', and '? :' respectively. As in Common Lisp,
- you may give an 'AND' or 'IOR' expression an arbitrary number
- of arguments; this has exactly the same effect as writing a
- chain of two-argument 'AND' or 'IOR' expressions.
-
- * An optional block of C code, which should execute 'return true' if
- the predicate is found to match and 'return false' if it does not.
- It must not have any side effects. The predicate arguments, OP and
- MODE, are available with those names.
-
- If a code block is present in a predicate definition, then the RTL
- expression must evaluate to true _and_ the code block must execute
- 'return true' for the predicate to allow the operand. The RTL
- expression is evaluated first; do not re-check anything in the code
- block that was checked in the RTL expression.
-
- The program 'genrecog' scans 'define_predicate' and
- 'define_special_predicate' expressions to determine which RTX codes are
- possibly allowed. You should always make this explicit in the RTL
- predicate expression, using 'MATCH_OPERAND' and 'MATCH_CODE'.
-
- Here is an example of a simple predicate definition, from the IA64
- machine description:
-
- ;; True if OP is a 'SYMBOL_REF' which refers to the sdata section.
- (define_predicate "small_addr_symbolic_operand"
- (and (match_code "symbol_ref")
- (match_test "SYMBOL_REF_SMALL_ADDR_P (op)")))
-
- And here is another, showing the use of the C block.
-
- ;; True if OP is a register operand that is (or could be) a GR reg.
- (define_predicate "gr_register_operand"
- (match_operand 0 "register_operand")
- {
- unsigned int regno;
- if (GET_CODE (op) == SUBREG)
- op = SUBREG_REG (op);
-
- regno = REGNO (op);
- return (regno >= FIRST_PSEUDO_REGISTER || GENERAL_REGNO_P (regno));
- })
-
- Predicates written with 'define_predicate' automatically include a test
- that MODE is 'VOIDmode', or OP has the same mode as MODE, or OP is a
- 'CONST_INT' or 'CONST_DOUBLE'. They do _not_ check specifically for
- integer 'CONST_DOUBLE', nor do they test that the value of either kind
- of constant fits in the requested mode. This is because target-specific
- predicates that take constants usually have to do more stringent value
- checks anyway. If you need the exact same treatment of 'CONST_INT' or
- 'CONST_DOUBLE' that the generic predicates provide, use a
- 'MATCH_OPERAND' subexpression to call 'const_int_operand',
- 'const_double_operand', or 'immediate_operand'.
-
- Predicates written with 'define_special_predicate' do not get any
- automatic mode checks, and are treated as having special mode handling
- by 'genrecog'.
-
- The program 'genpreds' is responsible for generating code to test
- predicates. It also writes a header file containing function
- declarations for all machine-specific predicates. It is not necessary
- to declare these predicates in 'CPU-protos.h'.
-
-
- File: gccint.info, Node: Constraints, Next: Standard Names, Prev: Predicates, Up: Machine Desc
-
- 17.8 Operand Constraints
- ========================
-
- Each 'match_operand' in an instruction pattern can specify constraints
- for the operands allowed. The constraints allow you to fine-tune
- matching within the set of operands allowed by the predicate.
-
- Constraints can say whether an operand may be in a register, and which
- kinds of register; whether the operand can be a memory reference, and
- which kinds of address; whether the operand may be an immediate
- constant, and which possible values it may have. Constraints can also
- require two operands to match. Side-effects aren't allowed in operands
- of inline 'asm', unless '<' or '>' constraints are used, because there
- is no guarantee that the side effects will happen exactly once in an
- instruction that can update the addressing register.
-
- * Menu:
-
- * Simple Constraints:: Basic use of constraints.
- * Multi-Alternative:: When an insn has two alternative constraint-patterns.
- * Class Preferences:: Constraints guide which hard register to put things in.
- * Modifiers:: More precise control over effects of constraints.
- * Machine Constraints:: Existing constraints for some particular machines.
- * Disable Insn Alternatives:: Disable insn alternatives using attributes.
- * Define Constraints:: How to define machine-specific constraints.
- * C Constraint Interface:: How to test constraints from C code.
-
-
- File: gccint.info, Node: Simple Constraints, Next: Multi-Alternative, Up: Constraints
-
- 17.8.1 Simple Constraints
- -------------------------
-
- The simplest kind of constraint is a string full of letters, each of
- which describes one kind of operand that is permitted. Here are the
- letters that are allowed:
-
- whitespace
- Whitespace characters are ignored and can be inserted at any
- position except the first. This enables each alternative for
- different operands to be visually aligned in the machine
- description even if they have different number of constraints and
- modifiers.
-
- 'm'
- A memory operand is allowed, with any kind of address that the
- machine supports in general. Note that the letter used for the
- general memory constraint can be re-defined by a back end using the
- 'TARGET_MEM_CONSTRAINT' macro.
-
- 'o'
- A memory operand is allowed, but only if the address is
- "offsettable". This means that adding a small integer (actually,
- the width in bytes of the operand, as determined by its machine
- mode) may be added to the address and the result is also a valid
- memory address.
-
- For example, an address which is constant is offsettable; so is an
- address that is the sum of a register and a constant (as long as a
- slightly larger constant is also within the range of
- address-offsets supported by the machine); but an autoincrement or
- autodecrement address is not offsettable. More complicated
- indirect/indexed addresses may or may not be offsettable depending
- on the other addressing modes that the machine supports.
-
- Note that in an output operand which can be matched by another
- operand, the constraint letter 'o' is valid only when accompanied
- by both '<' (if the target machine has predecrement addressing) and
- '>' (if the target machine has preincrement addressing).
-
- 'V'
- A memory operand that is not offsettable. In other words, anything
- that would fit the 'm' constraint but not the 'o' constraint.
-
- '<'
- A memory operand with autodecrement addressing (either predecrement
- or postdecrement) is allowed. In inline 'asm' this constraint is
- only allowed if the operand is used exactly once in an instruction
- that can handle the side effects. Not using an operand with '<' in
- constraint string in the inline 'asm' pattern at all or using it in
- multiple instructions isn't valid, because the side effects
- wouldn't be performed or would be performed more than once.
- Furthermore, on some targets the operand with '<' in constraint
- string must be accompanied by special instruction suffixes like
- '%U0' instruction suffix on PowerPC or '%P0' on IA-64.
-
- '>'
- A memory operand with autoincrement addressing (either preincrement
- or postincrement) is allowed. In inline 'asm' the same
- restrictions as for '<' apply.
-
- 'r'
- A register operand is allowed provided that it is in a general
- register.
-
- 'i'
- An immediate integer operand (one with constant value) is allowed.
- This includes symbolic constants whose values will be known only at
- assembly time or later.
-
- 'n'
- An immediate integer operand with a known numeric value is allowed.
- Many systems cannot support assembly-time constants for operands
- less than a word wide. Constraints for these operands should use
- 'n' rather than 'i'.
-
- 'I', 'J', 'K', ... 'P'
- Other letters in the range 'I' through 'P' may be defined in a
- machine-dependent fashion to permit immediate integer operands with
- explicit integer values in specified ranges. For example, on the
- 68000, 'I' is defined to stand for the range of values 1 to 8.
- This is the range permitted as a shift count in the shift
- instructions.
-
- 'E'
- An immediate floating operand (expression code 'const_double') is
- allowed, but only if the target floating point format is the same
- as that of the host machine (on which the compiler is running).
-
- 'F'
- An immediate floating operand (expression code 'const_double' or
- 'const_vector') is allowed.
-
- 'G', 'H'
- 'G' and 'H' may be defined in a machine-dependent fashion to permit
- immediate floating operands in particular ranges of values.
-
- 's'
- An immediate integer operand whose value is not an explicit integer
- is allowed.
-
- This might appear strange; if an insn allows a constant operand
- with a value not known at compile time, it certainly must allow any
- known value. So why use 's' instead of 'i'? Sometimes it allows
- better code to be generated.
-
- For example, on the 68000 in a fullword instruction it is possible
- to use an immediate operand; but if the immediate value is between
- -128 and 127, better code results from loading the value into a
- register and using the register. This is because the load into the
- register can be done with a 'moveq' instruction. We arrange for
- this to happen by defining the letter 'K' to mean "any integer
- outside the range -128 to 127", and then specifying 'Ks' in the
- operand constraints.
-
- 'g'
- Any register, memory or immediate integer operand is allowed,
- except for registers that are not general registers.
-
- 'X'
- Any operand whatsoever is allowed, even if it does not satisfy
- 'general_operand'. This is normally used in the constraint of a
- 'match_scratch' when certain alternatives will not actually require
- a scratch register.
-
- '0', '1', '2', ... '9'
- An operand that matches the specified operand number is allowed.
- If a digit is used together with letters within the same
- alternative, the digit should come last.
-
- This number is allowed to be more than a single digit. If multiple
- digits are encountered consecutively, they are interpreted as a
- single decimal integer. There is scant chance for ambiguity, since
- to-date it has never been desirable that '10' be interpreted as
- matching either operand 1 _or_ operand 0. Should this be desired,
- one can use multiple alternatives instead.
-
- This is called a "matching constraint" and what it really means is
- that the assembler has only a single operand that fills two roles
- considered separate in the RTL insn. For example, an add insn has
- two input operands and one output operand in the RTL, but on most
- CISC machines an add instruction really has only two operands, one
- of them an input-output operand:
-
- addl #35,r12
-
- Matching constraints are used in these circumstances. More
- precisely, the two operands that match must include one input-only
- operand and one output-only operand. Moreover, the digit must be a
- smaller number than the number of the operand that uses it in the
- constraint.
-
- For operands to match in a particular case usually means that they
- are identical-looking RTL expressions. But in a few special cases
- specific kinds of dissimilarity are allowed. For example, '*x' as
- an input operand will match '*x++' as an output operand. For
- proper results in such cases, the output template should always use
- the output-operand's number when printing the operand.
-
- 'p'
- An operand that is a valid memory address is allowed. This is for
- "load address" and "push address" instructions.
-
- 'p' in the constraint must be accompanied by 'address_operand' as
- the predicate in the 'match_operand'. This predicate interprets
- the mode specified in the 'match_operand' as the mode of the memory
- reference for which the address would be valid.
-
- OTHER-LETTERS
- Other letters can be defined in machine-dependent fashion to stand
- for particular classes of registers or other arbitrary operand
- types. 'd', 'a' and 'f' are defined on the 68000/68020 to stand
- for data, address and floating point registers.
-
- In order to have valid assembler code, each operand must satisfy its
- constraint. But a failure to do so does not prevent the pattern from
- applying to an insn. Instead, it directs the compiler to modify the
- code so that the constraint will be satisfied. Usually this is done by
- copying an operand into a register.
-
- Contrast, therefore, the two instruction patterns that follow:
-
- (define_insn ""
- [(set (match_operand:SI 0 "general_operand" "=r")
- (plus:SI (match_dup 0)
- (match_operand:SI 1 "general_operand" "r")))]
- ""
- "...")
-
- which has two operands, one of which must appear in two places, and
-
- (define_insn ""
- [(set (match_operand:SI 0 "general_operand" "=r")
- (plus:SI (match_operand:SI 1 "general_operand" "0")
- (match_operand:SI 2 "general_operand" "r")))]
- ""
- "...")
-
- which has three operands, two of which are required by a constraint to
- be identical. If we are considering an insn of the form
-
- (insn N PREV NEXT
- (set (reg:SI 3)
- (plus:SI (reg:SI 6) (reg:SI 109)))
- ...)
-
- the first pattern would not apply at all, because this insn does not
- contain two identical subexpressions in the right place. The pattern
- would say, "That does not look like an add instruction; try other
- patterns". The second pattern would say, "Yes, that's an add
- instruction, but there is something wrong with it". It would direct the
- reload pass of the compiler to generate additional insns to make the
- constraint true. The results might look like this:
-
- (insn N2 PREV N
- (set (reg:SI 3) (reg:SI 6))
- ...)
-
- (insn N N2 NEXT
- (set (reg:SI 3)
- (plus:SI (reg:SI 3) (reg:SI 109)))
- ...)
-
- It is up to you to make sure that each operand, in each pattern, has
- constraints that can handle any RTL expression that could be present for
- that operand. (When multiple alternatives are in use, each pattern
- must, for each possible combination of operand expressions, have at
- least one alternative which can handle that combination of operands.)
- The constraints don't need to _allow_ any possible operand--when this is
- the case, they do not constrain--but they must at least point the way to
- reloading any possible operand so that it will fit.
-
- * If the constraint accepts whatever operands the predicate permits,
- there is no problem: reloading is never necessary for this operand.
-
- For example, an operand whose constraints permit everything except
- registers is safe provided its predicate rejects registers.
-
- An operand whose predicate accepts only constant values is safe
- provided its constraints include the letter 'i'. If any possible
- constant value is accepted, then nothing less than 'i' will do; if
- the predicate is more selective, then the constraints may also be
- more selective.
-
- * Any operand expression can be reloaded by copying it into a
- register. So if an operand's constraints allow some kind of
- register, it is certain to be safe. It need not permit all classes
- of registers; the compiler knows how to copy a register into
- another register of the proper class in order to make an
- instruction valid.
-
- * A nonoffsettable memory reference can be reloaded by copying the
- address into a register. So if the constraint uses the letter 'o',
- all memory references are taken care of.
-
- * A constant operand can be reloaded by allocating space in memory to
- hold it as preinitialized data. Then the memory reference can be
- used in place of the constant. So if the constraint uses the
- letters 'o' or 'm', constant operands are not a problem.
-
- * If the constraint permits a constant and a pseudo register used in
- an insn was not allocated to a hard register and is equivalent to a
- constant, the register will be replaced with the constant. If the
- predicate does not permit a constant and the insn is re-recognized
- for some reason, the compiler will crash. Thus the predicate must
- always recognize any objects allowed by the constraint.
-
- If the operand's predicate can recognize registers, but the constraint
- does not permit them, it can make the compiler crash. When this operand
- happens to be a register, the reload pass will be stymied, because it
- does not know how to copy a register temporarily into memory.
-
- If the predicate accepts a unary operator, the constraint applies to
- the operand. For example, the MIPS processor at ISA level 3 supports an
- instruction which adds two registers in 'SImode' to produce a 'DImode'
- result, but only if the registers are correctly sign extended. This
- predicate for the input operands accepts a 'sign_extend' of an 'SImode'
- register. Write the constraint to indicate the type of register that is
- required for the operand of the 'sign_extend'.
-
-
- File: gccint.info, Node: Multi-Alternative, Next: Class Preferences, Prev: Simple Constraints, Up: Constraints
-
- 17.8.2 Multiple Alternative Constraints
- ---------------------------------------
-
- Sometimes a single instruction has multiple alternative sets of possible
- operands. For example, on the 68000, a logical-or instruction can
- combine register or an immediate value into memory, or it can combine
- any kind of operand into a register; but it cannot combine one memory
- location into another.
-
- These constraints are represented as multiple alternatives. An
- alternative can be described by a series of letters for each operand.
- The overall constraint for an operand is made from the letters for this
- operand from the first alternative, a comma, the letters for this
- operand from the second alternative, a comma, and so on until the last
- alternative. All operands for a single instruction must have the same
- number of alternatives. Here is how it is done for fullword logical-or
- on the 68000:
-
- (define_insn "iorsi3"
- [(set (match_operand:SI 0 "general_operand" "=m,d")
- (ior:SI (match_operand:SI 1 "general_operand" "%0,0")
- (match_operand:SI 2 "general_operand" "dKs,dmKs")))]
- ...)
-
- The first alternative has 'm' (memory) for operand 0, '0' for operand 1
- (meaning it must match operand 0), and 'dKs' for operand 2. The second
- alternative has 'd' (data register) for operand 0, '0' for operand 1,
- and 'dmKs' for operand 2. The '=' and '%' in the constraints apply to
- all the alternatives; their meaning is explained in the next section
- (*note Class Preferences::).
-
- If all the operands fit any one alternative, the instruction is valid.
- Otherwise, for each alternative, the compiler counts how many
- instructions must be added to copy the operands so that that alternative
- applies. The alternative requiring the least copying is chosen. If two
- alternatives need the same amount of copying, the one that comes first
- is chosen. These choices can be altered with the '?' and '!'
- characters:
-
- '?'
- Disparage slightly the alternative that the '?' appears in, as a
- choice when no alternative applies exactly. The compiler regards
- this alternative as one unit more costly for each '?' that appears
- in it.
-
- '!'
- Disparage severely the alternative that the '!' appears in. This
- alternative can still be used if it fits without reloading, but if
- reloading is needed, some other alternative will be used.
-
- '^'
- This constraint is analogous to '?' but it disparages slightly the
- alternative only if the operand with the '^' needs a reload.
-
- '$'
- This constraint is analogous to '!' but it disparages severely the
- alternative only if the operand with the '$' needs a reload.
-
- When an insn pattern has multiple alternatives in its constraints,
- often the appearance of the assembler code is determined mostly by which
- alternative was matched. When this is so, the C code for writing the
- assembler code can use the variable 'which_alternative', which is the
- ordinal number of the alternative that was actually satisfied (0 for the
- first, 1 for the second alternative, etc.). *Note Output Statement::.
-
-
- File: gccint.info, Node: Class Preferences, Next: Modifiers, Prev: Multi-Alternative, Up: Constraints
-
- 17.8.3 Register Class Preferences
- ---------------------------------
-
- The operand constraints have another function: they enable the compiler
- to decide which kind of hardware register a pseudo register is best
- allocated to. The compiler examines the constraints that apply to the
- insns that use the pseudo register, looking for the machine-dependent
- letters such as 'd' and 'a' that specify classes of registers. The
- pseudo register is put in whichever class gets the most "votes". The
- constraint letters 'g' and 'r' also vote: they vote in favor of a
- general register. The machine description says which registers are
- considered general.
-
- Of course, on some machines all registers are equivalent, and no
- register classes are defined. Then none of this complexity is relevant.
-
-
- File: gccint.info, Node: Modifiers, Next: Machine Constraints, Prev: Class Preferences, Up: Constraints
-
- 17.8.4 Constraint Modifier Characters
- -------------------------------------
-
- Here are constraint modifier characters.
-
- '='
- Means that this operand is written to by this instruction: the
- previous value is discarded and replaced by new data.
-
- '+'
- Means that this operand is both read and written by the
- instruction.
-
- When the compiler fixes up the operands to satisfy the constraints,
- it needs to know which operands are read by the instruction and
- which are written by it. '=' identifies an operand which is only
- written; '+' identifies an operand that is both read and written;
- all other operands are assumed to only be read.
-
- If you specify '=' or '+' in a constraint, you put it in the first
- character of the constraint string.
-
- '&'
- Means (in a particular alternative) that this operand is an
- "earlyclobber" operand, which is written before the instruction is
- finished using the input operands. Therefore, this operand may not
- lie in a register that is read by the instruction or as part of any
- memory address.
-
- '&' applies only to the alternative in which it is written. In
- constraints with multiple alternatives, sometimes one alternative
- requires '&' while others do not. See, for example, the 'movdf'
- insn of the 68000.
-
- A operand which is read by the instruction can be tied to an
- earlyclobber operand if its only use as an input occurs before the
- early result is written. Adding alternatives of this form often
- allows GCC to produce better code when only some of the read
- operands can be affected by the earlyclobber. See, for example,
- the 'mulsi3' insn of the ARM.
-
- Furthermore, if the "earlyclobber" operand is also a read/write
- operand, then that operand is written only after it's used.
-
- '&' does not obviate the need to write '=' or '+'. As
- "earlyclobber" operands are always written, a read-only
- "earlyclobber" operand is ill-formed and will be rejected by the
- compiler.
-
- '%'
- Declares the instruction to be commutative for this operand and the
- following operand. This means that the compiler may interchange
- the two operands if that is the cheapest way to make all operands
- fit the constraints. '%' applies to all alternatives and must
- appear as the first character in the constraint. Only read-only
- operands can use '%'.
-
- This is often used in patterns for addition instructions that
- really have only two operands: the result must go in one of the
- arguments. Here for example, is how the 68000 halfword-add
- instruction is defined:
-
- (define_insn "addhi3"
- [(set (match_operand:HI 0 "general_operand" "=m,r")
- (plus:HI (match_operand:HI 1 "general_operand" "%0,0")
- (match_operand:HI 2 "general_operand" "di,g")))]
- ...)
- GCC can only handle one commutative pair in an asm; if you use
- more, the compiler may fail. Note that you need not use the
- modifier if the two alternatives are strictly identical; this would
- only waste time in the reload pass. The modifier is not
- operational after register allocation, so the result of
- 'define_peephole2' and 'define_split's performed after reload
- cannot rely on '%' to make the intended insn match.
-
- '#'
- Says that all following characters, up to the next comma, are to be
- ignored as a constraint. They are significant only for choosing
- register preferences.
-
- '*'
- Says that the following character should be ignored when choosing
- register preferences. '*' has no effect on the meaning of the
- constraint as a constraint, and no effect on reloading. For LRA
- '*' additionally disparages slightly the alternative if the
- following character matches the operand.
-
- Here is an example: the 68000 has an instruction to sign-extend a
- halfword in a data register, and can also sign-extend a value by
- copying it into an address register. While either kind of register
- is acceptable, the constraints on an address-register destination
- are less strict, so it is best if register allocation makes an
- address register its goal. Therefore, '*' is used so that the 'd'
- constraint letter (for data register) is ignored when computing
- register preferences.
-
- (define_insn "extendhisi2"
- [(set (match_operand:SI 0 "general_operand" "=*d,a")
- (sign_extend:SI
- (match_operand:HI 1 "general_operand" "0,g")))]
- ...)
-
-
- File: gccint.info, Node: Machine Constraints, Next: Disable Insn Alternatives, Prev: Modifiers, Up: Constraints
-
- 17.8.5 Constraints for Particular Machines
- ------------------------------------------
-
- Whenever possible, you should use the general-purpose constraint letters
- in 'asm' arguments, since they will convey meaning more readily to
- people reading your code. Failing that, use the constraint letters that
- usually have very similar meanings across architectures. The most
- commonly used constraints are 'm' and 'r' (for memory and
- general-purpose registers respectively; *note Simple Constraints::), and
- 'I', usually the letter indicating the most common immediate-constant
- format.
-
- Each architecture defines additional constraints. These constraints
- are used by the compiler itself for instruction generation, as well as
- for 'asm' statements; therefore, some of the constraints are not
- particularly useful for 'asm'. Here is a summary of some of the
- machine-dependent constraints available on some particular machines; it
- includes both constraints that are useful for 'asm' and constraints that
- aren't. The compiler source file mentioned in the table heading for
- each architecture is the definitive reference for the meanings of that
- architecture's constraints.
-
- _AArch64 family--'config/aarch64/constraints.md'_
- 'k'
- The stack pointer register ('SP')
-
- 'w'
- Floating point register, Advanced SIMD vector register or SVE
- vector register
-
- 'x'
- Like 'w', but restricted to registers 0 to 15 inclusive.
-
- 'y'
- Like 'w', but restricted to registers 0 to 7 inclusive.
-
- 'Upl'
- One of the low eight SVE predicate registers ('P0' to 'P7')
-
- 'Upa'
- Any of the SVE predicate registers ('P0' to 'P15')
-
- 'I'
- Integer constant that is valid as an immediate operand in an
- 'ADD' instruction
-
- 'J'
- Integer constant that is valid as an immediate operand in a
- 'SUB' instruction (once negated)
-
- 'K'
- Integer constant that can be used with a 32-bit logical
- instruction
-
- 'L'
- Integer constant that can be used with a 64-bit logical
- instruction
-
- 'M'
- Integer constant that is valid as an immediate operand in a
- 32-bit 'MOV' pseudo instruction. The 'MOV' may be assembled
- to one of several different machine instructions depending on
- the value
-
- 'N'
- Integer constant that is valid as an immediate operand in a
- 64-bit 'MOV' pseudo instruction
-
- 'S'
- An absolute symbolic address or a label reference
-
- 'Y'
- Floating point constant zero
-
- 'Z'
- Integer constant zero
-
- 'Ush'
- The high part (bits 12 and upwards) of the pc-relative address
- of a symbol within 4GB of the instruction
-
- 'Q'
- A memory address which uses a single base register with no
- offset
-
- 'Ump'
- A memory address suitable for a load/store pair instruction in
- SI, DI, SF and DF modes
-
- _AMD GCN --'config/gcn/constraints.md'_
- 'I'
- Immediate integer in the range -16 to 64
-
- 'J'
- Immediate 16-bit signed integer
-
- 'Kf'
- Immediate constant -1
-
- 'L'
- Immediate 15-bit unsigned integer
-
- 'A'
- Immediate constant that can be inlined in an instruction
- encoding: integer -16..64, or float 0.0, +/-0.5, +/-1.0,
- +/-2.0, +/-4.0, 1.0/(2.0*PI)
-
- 'B'
- Immediate 32-bit signed integer that can be attached to an
- instruction encoding
-
- 'C'
- Immediate 32-bit integer in range -16..4294967295 (i.e.
- 32-bit unsigned integer or 'A' constraint)
-
- 'DA'
- Immediate 64-bit constant that can be split into two 'A'
- constants
-
- 'DB'
- Immediate 64-bit constant that can be split into two 'B'
- constants
-
- 'U'
- Any 'unspec'
-
- 'Y'
- Any 'symbol_ref' or 'label_ref'
-
- 'v'
- VGPR register
-
- 'Sg'
- SGPR register
-
- 'SD'
- SGPR registers valid for instruction destinations, including
- VCC, M0 and EXEC
-
- 'SS'
- SGPR registers valid for instruction sources, including VCC,
- M0, EXEC and SCC
-
- 'Sm'
- SGPR registers valid as a source for scalar memory
- instructions (excludes M0 and EXEC)
-
- 'Sv'
- SGPR registers valid as a source or destination for vector
- instructions (excludes EXEC)
-
- 'ca'
- All condition registers: SCC, VCCZ, EXECZ
-
- 'cs'
- Scalar condition register: SCC
-
- 'cV'
- Vector condition register: VCC, VCC_LO, VCC_HI
-
- 'e'
- EXEC register (EXEC_LO and EXEC_HI)
-
- 'RB'
- Memory operand with address space suitable for 'buffer_*'
- instructions
-
- 'RF'
- Memory operand with address space suitable for 'flat_*'
- instructions
-
- 'RS'
- Memory operand with address space suitable for 's_*'
- instructions
-
- 'RL'
- Memory operand with address space suitable for 'ds_*' LDS
- instructions
-
- 'RG'
- Memory operand with address space suitable for 'ds_*' GDS
- instructions
-
- 'RD'
- Memory operand with address space suitable for any 'ds_*'
- instructions
-
- 'RM'
- Memory operand with address space suitable for 'global_*'
- instructions
-
- _ARC --'config/arc/constraints.md'_
- 'q'
- Registers usable in ARCompact 16-bit instructions: 'r0'-'r3',
- 'r12'-'r15'. This constraint can only match when the '-mq'
- option is in effect.
-
- 'e'
- Registers usable as base-regs of memory addresses in ARCompact
- 16-bit memory instructions: 'r0'-'r3', 'r12'-'r15', 'sp'.
- This constraint can only match when the '-mq' option is in
- effect.
- 'D'
- ARC FPX (dpfp) 64-bit registers. 'D0', 'D1'.
-
- 'I'
- A signed 12-bit integer constant.
-
- 'Cal'
- constant for arithmetic/logical operations. This might be any
- constant that can be put into a long immediate by the assmbler
- or linker without involving a PIC relocation.
-
- 'K'
- A 3-bit unsigned integer constant.
-
- 'L'
- A 6-bit unsigned integer constant.
-
- 'CnL'
- One's complement of a 6-bit unsigned integer constant.
-
- 'CmL'
- Two's complement of a 6-bit unsigned integer constant.
-
- 'M'
- A 5-bit unsigned integer constant.
-
- 'O'
- A 7-bit unsigned integer constant.
-
- 'P'
- A 8-bit unsigned integer constant.
-
- 'H'
- Any const_double value.
-
- _ARM family--'config/arm/constraints.md'_
-
- 'h'
- In Thumb state, the core registers 'r8'-'r15'.
-
- 'k'
- The stack pointer register.
-
- 'l'
- In Thumb State the core registers 'r0'-'r7'. In ARM state
- this is an alias for the 'r' constraint.
-
- 't'
- VFP floating-point registers 's0'-'s31'. Used for 32 bit
- values.
-
- 'w'
- VFP floating-point registers 'd0'-'d31' and the appropriate
- subset 'd0'-'d15' based on command line options. Used for 64
- bit values only. Not valid for Thumb1.
-
- 'y'
- The iWMMX co-processor registers.
-
- 'z'
- The iWMMX GR registers.
-
- 'G'
- The floating-point constant 0.0
-
- 'I'
- Integer that is valid as an immediate operand in a data
- processing instruction. That is, an integer in the range 0 to
- 255 rotated by a multiple of 2
-
- 'J'
- Integer in the range -4095 to 4095
-
- 'K'
- Integer that satisfies constraint 'I' when inverted (ones
- complement)
-
- 'L'
- Integer that satisfies constraint 'I' when negated (twos
- complement)
-
- 'M'
- Integer in the range 0 to 32
-
- 'Q'
- A memory reference where the exact address is in a single
- register (''m'' is preferable for 'asm' statements)
-
- 'R'
- An item in the constant pool
-
- 'S'
- A symbol in the text segment of the current file
-
- 'Uv'
- A memory reference suitable for VFP load/store insns
- (reg+constant offset)
-
- 'Uy'
- A memory reference suitable for iWMMXt load/store
- instructions.
-
- 'Uq'
- A memory reference suitable for the ARMv4 ldrsb instruction.
-
- _AVR family--'config/avr/constraints.md'_
- 'l'
- Registers from r0 to r15
-
- 'a'
- Registers from r16 to r23
-
- 'd'
- Registers from r16 to r31
-
- 'w'
- Registers from r24 to r31. These registers can be used in
- 'adiw' command
-
- 'e'
- Pointer register (r26-r31)
-
- 'b'
- Base pointer register (r28-r31)
-
- 'q'
- Stack pointer register (SPH:SPL)
-
- 't'
- Temporary register r0
-
- 'x'
- Register pair X (r27:r26)
-
- 'y'
- Register pair Y (r29:r28)
-
- 'z'
- Register pair Z (r31:r30)
-
- 'I'
- Constant greater than -1, less than 64
-
- 'J'
- Constant greater than -64, less than 1
-
- 'K'
- Constant integer 2
-
- 'L'
- Constant integer 0
-
- 'M'
- Constant that fits in 8 bits
-
- 'N'
- Constant integer -1
-
- 'O'
- Constant integer 8, 16, or 24
-
- 'P'
- Constant integer 1
-
- 'G'
- A floating point constant 0.0
-
- 'Q'
- A memory address based on Y or Z pointer with displacement.
-
- _Blackfin family--'config/bfin/constraints.md'_
- 'a'
- P register
-
- 'd'
- D register
-
- 'z'
- A call clobbered P register.
-
- 'qN'
- A single register. If N is in the range 0 to 7, the
- corresponding D register. If it is 'A', then the register P0.
-
- 'D'
- Even-numbered D register
-
- 'W'
- Odd-numbered D register
-
- 'e'
- Accumulator register.
-
- 'A'
- Even-numbered accumulator register.
-
- 'B'
- Odd-numbered accumulator register.
-
- 'b'
- I register
-
- 'v'
- B register
-
- 'f'
- M register
-
- 'c'
- Registers used for circular buffering, i.e. I, B, or L
- registers.
-
- 'C'
- The CC register.
-
- 't'
- LT0 or LT1.
-
- 'k'
- LC0 or LC1.
-
- 'u'
- LB0 or LB1.
-
- 'x'
- Any D, P, B, M, I or L register.
-
- 'y'
- Additional registers typically used only in prologues and
- epilogues: RETS, RETN, RETI, RETX, RETE, ASTAT, SEQSTAT and
- USP.
-
- 'w'
- Any register except accumulators or CC.
-
- 'Ksh'
- Signed 16 bit integer (in the range -32768 to 32767)
-
- 'Kuh'
- Unsigned 16 bit integer (in the range 0 to 65535)
-
- 'Ks7'
- Signed 7 bit integer (in the range -64 to 63)
-
- 'Ku7'
- Unsigned 7 bit integer (in the range 0 to 127)
-
- 'Ku5'
- Unsigned 5 bit integer (in the range 0 to 31)
-
- 'Ks4'
- Signed 4 bit integer (in the range -8 to 7)
-
- 'Ks3'
- Signed 3 bit integer (in the range -3 to 4)
-
- 'Ku3'
- Unsigned 3 bit integer (in the range 0 to 7)
-
- 'PN'
- Constant N, where N is a single-digit constant in the range 0
- to 4.
-
- 'PA'
- An integer equal to one of the MACFLAG_XXX constants that is
- suitable for use with either accumulator.
-
- 'PB'
- An integer equal to one of the MACFLAG_XXX constants that is
- suitable for use only with accumulator A1.
-
- 'M1'
- Constant 255.
-
- 'M2'
- Constant 65535.
-
- 'J'
- An integer constant with exactly a single bit set.
-
- 'L'
- An integer constant with all bits set except exactly one.
-
- 'H'
-
- 'Q'
- Any SYMBOL_REF.
-
- _CR16 Architecture--'config/cr16/cr16.h'_
-
- 'b'
- Registers from r0 to r14 (registers without stack pointer)
-
- 't'
- Register from r0 to r11 (all 16-bit registers)
-
- 'p'
- Register from r12 to r15 (all 32-bit registers)
-
- 'I'
- Signed constant that fits in 4 bits
-
- 'J'
- Signed constant that fits in 5 bits
-
- 'K'
- Signed constant that fits in 6 bits
-
- 'L'
- Unsigned constant that fits in 4 bits
-
- 'M'
- Signed constant that fits in 32 bits
-
- 'N'
- Check for 64 bits wide constants for add/sub instructions
-
- 'G'
- Floating point constant that is legal for store immediate
-
- _C-SKY--'config/csky/constraints.md'_
-
- 'a'
- The mini registers r0 - r7.
-
- 'b'
- The low registers r0 - r15.
-
- 'c'
- C register.
-
- 'y'
- HI and LO registers.
-
- 'l'
- LO register.
-
- 'h'
- HI register.
-
- 'v'
- Vector registers.
-
- 'z'
- Stack pointer register (SP).
-
- The C-SKY back end supports a large set of additional constraints
- that are only useful for instruction selection or splitting rather
- than inline asm, such as constraints representing constant integer
- ranges accepted by particular instruction encodings. Refer to the
- source code for details.
-
- _Epiphany--'config/epiphany/constraints.md'_
- 'U16'
- An unsigned 16-bit constant.
-
- 'K'
- An unsigned 5-bit constant.
-
- 'L'
- A signed 11-bit constant.
-
- 'Cm1'
- A signed 11-bit constant added to -1. Can only match when the
- '-m1reg-REG' option is active.
-
- 'Cl1'
- Left-shift of -1, i.e., a bit mask with a block of leading
- ones, the rest being a block of trailing zeroes. Can only
- match when the '-m1reg-REG' option is active.
-
- 'Cr1'
- Right-shift of -1, i.e., a bit mask with a trailing block of
- ones, the rest being zeroes. Or to put it another way, one
- less than a power of two. Can only match when the
- '-m1reg-REG' option is active.
-
- 'Cal'
- Constant for arithmetic/logical operations. This is like 'i',
- except that for position independent code, no symbols /
- expressions needing relocations are allowed.
-
- 'Csy'
- Symbolic constant for call/jump instruction.
-
- 'Rcs'
- The register class usable in short insns. This is a register
- class constraint, and can thus drive register allocation.
- This constraint won't match unless '-mprefer-short-insn-regs'
- is in effect.
-
- 'Rsc'
- The the register class of registers that can be used to hold a
- sibcall call address. I.e., a caller-saved register.
-
- 'Rct'
- Core control register class.
-
- 'Rgs'
- The register group usable in short insns. This constraint
- does not use a register class, so that it only passively
- matches suitable registers, and doesn't drive register
- allocation.
-
- 'Car'
- Constant suitable for the addsi3_r pattern. This is a valid
- offset For byte, halfword, or word addressing.
-
- 'Rra'
- Matches the return address if it can be replaced with the link
- register.
-
- 'Rcc'
- Matches the integer condition code register.
-
- 'Sra'
- Matches the return address if it is in a stack slot.
-
- 'Cfm'
- Matches control register values to switch fp mode, which are
- encapsulated in 'UNSPEC_FP_MODE'.
-
- _FRV--'config/frv/frv.h'_
- 'a'
- Register in the class 'ACC_REGS' ('acc0' to 'acc7').
-
- 'b'
- Register in the class 'EVEN_ACC_REGS' ('acc0' to 'acc7').
-
- 'c'
- Register in the class 'CC_REGS' ('fcc0' to 'fcc3' and 'icc0'
- to 'icc3').
-
- 'd'
- Register in the class 'GPR_REGS' ('gr0' to 'gr63').
-
- 'e'
- Register in the class 'EVEN_REGS' ('gr0' to 'gr63'). Odd
- registers are excluded not in the class but through the use of
- a machine mode larger than 4 bytes.
-
- 'f'
- Register in the class 'FPR_REGS' ('fr0' to 'fr63').
-
- 'h'
- Register in the class 'FEVEN_REGS' ('fr0' to 'fr63'). Odd
- registers are excluded not in the class but through the use of
- a machine mode larger than 4 bytes.
-
- 'l'
- Register in the class 'LR_REG' (the 'lr' register).
-
- 'q'
- Register in the class 'QUAD_REGS' ('gr2' to 'gr63'). Register
- numbers not divisible by 4 are excluded not in the class but
- through the use of a machine mode larger than 8 bytes.
-
- 't'
- Register in the class 'ICC_REGS' ('icc0' to 'icc3').
-
- 'u'
- Register in the class 'FCC_REGS' ('fcc0' to 'fcc3').
-
- 'v'
- Register in the class 'ICR_REGS' ('cc4' to 'cc7').
-
- 'w'
- Register in the class 'FCR_REGS' ('cc0' to 'cc3').
-
- 'x'
- Register in the class 'QUAD_FPR_REGS' ('fr0' to 'fr63').
- Register numbers not divisible by 4 are excluded not in the
- class but through the use of a machine mode larger than 8
- bytes.
-
- 'z'
- Register in the class 'SPR_REGS' ('lcr' and 'lr').
-
- 'A'
- Register in the class 'QUAD_ACC_REGS' ('acc0' to 'acc7').
-
- 'B'
- Register in the class 'ACCG_REGS' ('accg0' to 'accg7').
-
- 'C'
- Register in the class 'CR_REGS' ('cc0' to 'cc7').
-
- 'G'
- Floating point constant zero
-
- 'I'
- 6-bit signed integer constant
-
- 'J'
- 10-bit signed integer constant
-
- 'L'
- 16-bit signed integer constant
-
- 'M'
- 16-bit unsigned integer constant
-
- 'N'
- 12-bit signed integer constant that is negative--i.e. in the
- range of -2048 to -1
-
- 'O'
- Constant zero
-
- 'P'
- 12-bit signed integer constant that is greater than zero--i.e.
- in the range of 1 to 2047.
-
- _FT32--'config/ft32/constraints.md'_
- 'A'
- An absolute address
-
- 'B'
- An offset address
-
- 'W'
- A register indirect memory operand
-
- 'e'
- An offset address.
-
- 'f'
- An offset address.
-
- 'O'
- The constant zero or one
-
- 'I'
- A 16-bit signed constant (-32768 ... 32767)
-
- 'w'
- A bitfield mask suitable for bext or bins
-
- 'x'
- An inverted bitfield mask suitable for bext or bins
-
- 'L'
- A 16-bit unsigned constant, multiple of 4 (0 ... 65532)
-
- 'S'
- A 20-bit signed constant (-524288 ... 524287)
-
- 'b'
- A constant for a bitfield width (1 ... 16)
-
- 'KA'
- A 10-bit signed constant (-512 ... 511)
-
- _Hewlett-Packard PA-RISC--'config/pa/pa.h'_
- 'a'
- General register 1
-
- 'f'
- Floating point register
-
- 'q'
- Shift amount register
-
- 'x'
- Floating point register (deprecated)
-
- 'y'
- Upper floating point register (32-bit), floating point
- register (64-bit)
-
- 'Z'
- Any register
-
- 'I'
- Signed 11-bit integer constant
-
- 'J'
- Signed 14-bit integer constant
-
- 'K'
- Integer constant that can be deposited with a 'zdepi'
- instruction
-
- 'L'
- Signed 5-bit integer constant
-
- 'M'
- Integer constant 0
-
- 'N'
- Integer constant that can be loaded with a 'ldil' instruction
-
- 'O'
- Integer constant whose value plus one is a power of 2
-
- 'P'
- Integer constant that can be used for 'and' operations in
- 'depi' and 'extru' instructions
-
- 'S'
- Integer constant 31
-
- 'U'
- Integer constant 63
-
- 'G'
- Floating-point constant 0.0
-
- 'A'
- A 'lo_sum' data-linkage-table memory operand
-
- 'Q'
- A memory operand that can be used as the destination operand
- of an integer store instruction
-
- 'R'
- A scaled or unscaled indexed memory operand
-
- 'T'
- A memory operand for floating-point loads and stores
-
- 'W'
- A register indirect memory operand
-
- _Intel IA-64--'config/ia64/ia64.h'_
- 'a'
- General register 'r0' to 'r3' for 'addl' instruction
-
- 'b'
- Branch register
-
- 'c'
- Predicate register ('c' as in "conditional")
-
- 'd'
- Application register residing in M-unit
-
- 'e'
- Application register residing in I-unit
-
- 'f'
- Floating-point register
-
- 'm'
- Memory operand. If used together with '<' or '>', the operand
- can have postincrement and postdecrement which require
- printing with '%Pn' on IA-64.
-
- 'G'
- Floating-point constant 0.0 or 1.0
-
- 'I'
- 14-bit signed integer constant
-
- 'J'
- 22-bit signed integer constant
-
- 'K'
- 8-bit signed integer constant for logical instructions
-
- 'L'
- 8-bit adjusted signed integer constant for compare pseudo-ops
-
- 'M'
- 6-bit unsigned integer constant for shift counts
-
- 'N'
- 9-bit signed integer constant for load and store
- postincrements
-
- 'O'
- The constant zero
-
- 'P'
- 0 or -1 for 'dep' instruction
-
- 'Q'
- Non-volatile memory for floating-point loads and stores
-
- 'R'
- Integer constant in the range 1 to 4 for 'shladd' instruction
-
- 'S'
- Memory operand except postincrement and postdecrement. This
- is now roughly the same as 'm' when not used together with '<'
- or '>'.
-
- _M32C--'config/m32c/m32c.c'_
- 'Rsp'
- 'Rfb'
- 'Rsb'
- '$sp', '$fb', '$sb'.
-
- 'Rcr'
- Any control register, when they're 16 bits wide (nothing if
- control registers are 24 bits wide)
-
- 'Rcl'
- Any control register, when they're 24 bits wide.
-
- 'R0w'
- 'R1w'
- 'R2w'
- 'R3w'
- $r0, $r1, $r2, $r3.
-
- 'R02'
- $r0 or $r2, or $r2r0 for 32 bit values.
-
- 'R13'
- $r1 or $r3, or $r3r1 for 32 bit values.
-
- 'Rdi'
- A register that can hold a 64 bit value.
-
- 'Rhl'
- $r0 or $r1 (registers with addressable high/low bytes)
-
- 'R23'
- $r2 or $r3
-
- 'Raa'
- Address registers
-
- 'Raw'
- Address registers when they're 16 bits wide.
-
- 'Ral'
- Address registers when they're 24 bits wide.
-
- 'Rqi'
- Registers that can hold QI values.
-
- 'Rad'
- Registers that can be used with displacements ($a0, $a1, $sb).
-
- 'Rsi'
- Registers that can hold 32 bit values.
-
- 'Rhi'
- Registers that can hold 16 bit values.
-
- 'Rhc'
- Registers chat can hold 16 bit values, including all control
- registers.
-
- 'Rra'
- $r0 through R1, plus $a0 and $a1.
-
- 'Rfl'
- The flags register.
-
- 'Rmm'
- The memory-based pseudo-registers $mem0 through $mem15.
-
- 'Rpi'
- Registers that can hold pointers (16 bit registers for r8c,
- m16c; 24 bit registers for m32cm, m32c).
-
- 'Rpa'
- Matches multiple registers in a PARALLEL to form a larger
- register. Used to match function return values.
-
- 'Is3'
- -8 ... 7
-
- 'IS1'
- -128 ... 127
-
- 'IS2'
- -32768 ... 32767
-
- 'IU2'
- 0 ... 65535
-
- 'In4'
- -8 ... -1 or 1 ... 8
-
- 'In5'
- -16 ... -1 or 1 ... 16
-
- 'In6'
- -32 ... -1 or 1 ... 32
-
- 'IM2'
- -65536 ... -1
-
- 'Ilb'
- An 8 bit value with exactly one bit set.
-
- 'Ilw'
- A 16 bit value with exactly one bit set.
-
- 'Sd'
- The common src/dest memory addressing modes.
-
- 'Sa'
- Memory addressed using $a0 or $a1.
-
- 'Si'
- Memory addressed with immediate addresses.
-
- 'Ss'
- Memory addressed using the stack pointer ($sp).
-
- 'Sf'
- Memory addressed using the frame base register ($fb).
-
- 'Ss'
- Memory addressed using the small base register ($sb).
-
- 'S1'
- $r1h
-
- _MicroBlaze--'config/microblaze/constraints.md'_
- 'd'
- A general register ('r0' to 'r31').
-
- 'z'
- A status register ('rmsr', '$fcc1' to '$fcc7').
-
- _MIPS--'config/mips/constraints.md'_
- 'd'
- A general-purpose register. This is equivalent to 'r' unless
- generating MIPS16 code, in which case the MIPS16 register set
- is used.
-
- 'f'
- A floating-point register (if available).
-
- 'h'
- Formerly the 'hi' register. This constraint is no longer
- supported.
-
- 'l'
- The 'lo' register. Use this register to store values that are
- no bigger than a word.
-
- 'x'
- The concatenated 'hi' and 'lo' registers. Use this register
- to store doubleword values.
-
- 'c'
- A register suitable for use in an indirect jump. This will
- always be '$25' for '-mabicalls'.
-
- 'v'
- Register '$3'. Do not use this constraint in new code; it is
- retained only for compatibility with glibc.
-
- 'y'
- Equivalent to 'r'; retained for backwards compatibility.
-
- 'z'
- A floating-point condition code register.
-
- 'I'
- A signed 16-bit constant (for arithmetic instructions).
-
- 'J'
- Integer zero.
-
- 'K'
- An unsigned 16-bit constant (for logic instructions).
-
- 'L'
- A signed 32-bit constant in which the lower 16 bits are zero.
- Such constants can be loaded using 'lui'.
-
- 'M'
- A constant that cannot be loaded using 'lui', 'addiu' or
- 'ori'.
-
- 'N'
- A constant in the range -65535 to -1 (inclusive).
-
- 'O'
- A signed 15-bit constant.
-
- 'P'
- A constant in the range 1 to 65535 (inclusive).
-
- 'G'
- Floating-point zero.
-
- 'R'
- An address that can be used in a non-macro load or store.
-
- 'ZC'
- A memory operand whose address is formed by a base register
- and offset that is suitable for use in instructions with the
- same addressing mode as 'll' and 'sc'.
-
- 'ZD'
- An address suitable for a 'prefetch' instruction, or for any
- other instruction with the same addressing mode as 'prefetch'.
-
- _Motorola 680x0--'config/m68k/constraints.md'_
- 'a'
- Address register
-
- 'd'
- Data register
-
- 'f'
- 68881 floating-point register, if available
-
- 'I'
- Integer in the range 1 to 8
-
- 'J'
- 16-bit signed number
-
- 'K'
- Signed number whose magnitude is greater than 0x80
-
- 'L'
- Integer in the range -8 to -1
-
- 'M'
- Signed number whose magnitude is greater than 0x100
-
- 'N'
- Range 24 to 31, rotatert:SI 8 to 1 expressed as rotate
-
- 'O'
- 16 (for rotate using swap)
-
- 'P'
- Range 8 to 15, rotatert:HI 8 to 1 expressed as rotate
-
- 'R'
- Numbers that mov3q can handle
-
- 'G'
- Floating point constant that is not a 68881 constant
-
- 'S'
- Operands that satisfy 'm' when -mpcrel is in effect
-
- 'T'
- Operands that satisfy 's' when -mpcrel is not in effect
-
- 'Q'
- Address register indirect addressing mode
-
- 'U'
- Register offset addressing
-
- 'W'
- const_call_operand
-
- 'Cs'
- symbol_ref or const
-
- 'Ci'
- const_int
-
- 'C0'
- const_int 0
-
- 'Cj'
- Range of signed numbers that don't fit in 16 bits
-
- 'Cmvq'
- Integers valid for mvq
-
- 'Capsw'
- Integers valid for a moveq followed by a swap
-
- 'Cmvz'
- Integers valid for mvz
-
- 'Cmvs'
- Integers valid for mvs
-
- 'Ap'
- push_operand
-
- 'Ac'
- Non-register operands allowed in clr
-
- _Moxie--'config/moxie/constraints.md'_
- 'A'
- An absolute address
-
- 'B'
- An offset address
-
- 'W'
- A register indirect memory operand
-
- 'I'
- A constant in the range of 0 to 255.
-
- 'N'
- A constant in the range of 0 to -255.
-
- _MSP430-'config/msp430/constraints.md'_
-
- 'R12'
- Register R12.
-
- 'R13'
- Register R13.
-
- 'K'
- Integer constant 1.
-
- 'L'
- Integer constant -1^20..1^19.
-
- 'M'
- Integer constant 1-4.
-
- 'Ya'
- Memory references which do not require an extended MOVX
- instruction.
-
- 'Yl'
- Memory reference, labels only.
-
- 'Ys'
- Memory reference, stack only.
-
- _NDS32--'config/nds32/constraints.md'_
- 'w'
- LOW register class $r0 to $r7 constraint for V3/V3M ISA.
- 'l'
- LOW register class $r0 to $r7.
- 'd'
- MIDDLE register class $r0 to $r11, $r16 to $r19.
- 'h'
- HIGH register class $r12 to $r14, $r20 to $r31.
- 't'
- Temporary assist register $ta (i.e. $r15).
- 'k'
- Stack register $sp.
- 'Iu03'
- Unsigned immediate 3-bit value.
- 'In03'
- Negative immediate 3-bit value in the range of -7-0.
- 'Iu04'
- Unsigned immediate 4-bit value.
- 'Is05'
- Signed immediate 5-bit value.
- 'Iu05'
- Unsigned immediate 5-bit value.
- 'In05'
- Negative immediate 5-bit value in the range of -31-0.
- 'Ip05'
- Unsigned immediate 5-bit value for movpi45 instruction with
- range 16-47.
- 'Iu06'
- Unsigned immediate 6-bit value constraint for addri36.sp
- instruction.
- 'Iu08'
- Unsigned immediate 8-bit value.
- 'Iu09'
- Unsigned immediate 9-bit value.
- 'Is10'
- Signed immediate 10-bit value.
- 'Is11'
- Signed immediate 11-bit value.
- 'Is15'
- Signed immediate 15-bit value.
- 'Iu15'
- Unsigned immediate 15-bit value.
- 'Ic15'
- A constant which is not in the range of imm15u but ok for bclr
- instruction.
- 'Ie15'
- A constant which is not in the range of imm15u but ok for bset
- instruction.
- 'It15'
- A constant which is not in the range of imm15u but ok for btgl
- instruction.
- 'Ii15'
- A constant whose compliment value is in the range of imm15u
- and ok for bitci instruction.
- 'Is16'
- Signed immediate 16-bit value.
- 'Is17'
- Signed immediate 17-bit value.
- 'Is19'
- Signed immediate 19-bit value.
- 'Is20'
- Signed immediate 20-bit value.
- 'Ihig'
- The immediate value that can be simply set high 20-bit.
- 'Izeb'
- The immediate value 0xff.
- 'Izeh'
- The immediate value 0xffff.
- 'Ixls'
- The immediate value 0x01.
- 'Ix11'
- The immediate value 0x7ff.
- 'Ibms'
- The immediate value with power of 2.
- 'Ifex'
- The immediate value with power of 2 minus 1.
- 'U33'
- Memory constraint for 333 format.
- 'U45'
- Memory constraint for 45 format.
- 'U37'
- Memory constraint for 37 format.
-
- _Nios II family--'config/nios2/constraints.md'_
-
- 'I'
- Integer that is valid as an immediate operand in an
- instruction taking a signed 16-bit number. Range -32768 to
- 32767.
-
- 'J'
- Integer that is valid as an immediate operand in an
- instruction taking an unsigned 16-bit number. Range 0 to
- 65535.
-
- 'K'
- Integer that is valid as an immediate operand in an
- instruction taking only the upper 16-bits of a 32-bit number.
- Range 32-bit numbers with the lower 16-bits being 0.
-
- 'L'
- Integer that is valid as an immediate operand for a shift
- instruction. Range 0 to 31.
-
- 'M'
- Integer that is valid as an immediate operand for only the
- value 0. Can be used in conjunction with the format modifier
- 'z' to use 'r0' instead of '0' in the assembly output.
-
- 'N'
- Integer that is valid as an immediate operand for a custom
- instruction opcode. Range 0 to 255.
-
- 'P'
- An immediate operand for R2 andchi/andci instructions.
-
- 'S'
- Matches immediates which are addresses in the small data
- section and therefore can be added to 'gp' as a 16-bit
- immediate to re-create their 32-bit value.
-
- 'U'
- Matches constants suitable as an operand for the rdprs and
- cache instructions.
-
- 'v'
- A memory operand suitable for Nios II R2 load/store exclusive
- instructions.
-
- 'w'
- A memory operand suitable for load/store IO and cache
- instructions.
-
- 'T'
- A 'const' wrapped 'UNSPEC' expression, representing a
- supported PIC or TLS relocation.
-
- _OpenRISC--'config/or1k/constraints.md'_
- 'I'
- Integer that is valid as an immediate operand in an
- instruction taking a signed 16-bit number. Range -32768 to
- 32767.
-
- 'K'
- Integer that is valid as an immediate operand in an
- instruction taking an unsigned 16-bit number. Range 0 to
- 65535.
-
- 'M'
- Signed 16-bit constant shifted left 16 bits. (Used with
- 'l.movhi')
-
- 'O'
- Zero
-
- 'c'
- Register usable for sibcalls.
-
- _PDP-11--'config/pdp11/constraints.md'_
- 'a'
- Floating point registers AC0 through AC3. These can be loaded
- from/to memory with a single instruction.
-
- 'd'
- Odd numbered general registers (R1, R3, R5). These are used
- for 16-bit multiply operations.
-
- 'D'
- A memory reference that is encoded within the opcode, but not
- auto-increment or auto-decrement.
-
- 'f'
- Any of the floating point registers (AC0 through AC5).
-
- 'G'
- Floating point constant 0.
-
- 'h'
- Floating point registers AC4 and AC5. These cannot be loaded
- from/to memory with a single instruction.
-
- 'I'
- An integer constant that fits in 16 bits.
-
- 'J'
- An integer constant whose low order 16 bits are zero.
-
- 'K'
- An integer constant that does not meet the constraints for
- codes 'I' or 'J'.
-
- 'L'
- The integer constant 1.
-
- 'M'
- The integer constant -1.
-
- 'N'
- The integer constant 0.
-
- 'O'
- Integer constants 0 through 3; shifts by these amounts are
- handled as multiple single-bit shifts rather than a single
- variable-length shift.
-
- 'Q'
- A memory reference which requires an additional word (address
- or offset) after the opcode.
-
- 'R'
- A memory reference that is encoded within the opcode.
-
- _PowerPC and IBM RS6000--'config/rs6000/constraints.md'_
- 'r'
- A general purpose register (GPR), 'r0'...'r31'.
-
- 'b'
- A base register. Like 'r', but 'r0' is not allowed, so
- 'r1'...'r31'.
-
- 'f'
- A floating point register (FPR), 'f0'...'f31'.
-
- 'd'
- A floating point register. This is the same as 'f' nowadays;
- historically 'f' was for single-precision and 'd' was for
- double-precision floating point.
-
- 'v'
- An Altivec vector register (VR), 'v0'...'v31'.
-
- 'wa'
- A VSX register (VSR), 'vs0'...'vs63'. This is either an FPR
- ('vs0'...'vs31' are 'f0'...'f31') or a VR ('vs32'...'vs63' are
- 'v0'...'v31').
-
- When using 'wa', you should use the '%x' output modifier, so
- that the correct register number is printed. For example:
-
- asm ("xvadddp %x0,%x1,%x2"
- : "=wa" (v1)
- : "wa" (v2), "wa" (v3));
-
- You should not use '%x' for 'v' operands:
-
- asm ("xsaddqp %0,%1,%2"
- : "=v" (v1)
- : "v" (v2), "v" (v3));
-
- 'h'
- A special register ('vrsave', 'ctr', or 'lr').
-
- 'c'
- The count register, 'ctr'.
-
- 'l'
- The link register, 'lr'.
-
- 'x'
- Condition register field 0, 'cr0'.
-
- 'y'
- Any condition register field, 'cr0'...'cr7'.
-
- 'z'
- The carry bit, 'XER[CA]'.
-
- 'we'
- Like 'wa', if '-mpower9-vector' and '-m64' are used;
- otherwise, 'NO_REGS'.
-
- 'wn'
- No register ('NO_REGS').
-
- 'wr'
- Like 'r', if '-mpowerpc64' is used; otherwise, 'NO_REGS'.
-
- 'wx'
- Like 'd', if '-mpowerpc-gfxopt' is used; otherwise, 'NO_REGS'.
-
- 'wA'
- Like 'b', if '-mpowerpc64' is used; otherwise, 'NO_REGS'.
-
- 'wB'
- Signed 5-bit constant integer that can be loaded into an
- Altivec register.
-
- 'wD'
- Int constant that is the element number of the 64-bit scalar
- in a vector.
-
- 'wE'
- Vector constant that can be loaded with the XXSPLTIB
- instruction.
-
- 'wF'
- Memory operand suitable for power8 GPR load fusion.
-
- 'wL'
- Int constant that is the element number mfvsrld accesses in a
- vector.
-
- 'wM'
- Match vector constant with all 1's if the XXLORC instruction
- is available.
-
- 'wO'
- Memory operand suitable for the ISA 3.0 vector d-form
- instructions.
-
- 'wQ'
- Memory operand suitable for the load/store quad instructions.
-
- 'wS'
- Vector constant that can be loaded with XXSPLTIB & sign
- extension.
-
- 'wY'
- A memory operand for a DS-form instruction.
-
- 'wZ'
- An indexed or indirect memory operand, ignoring the bottom 4
- bits.
-
- 'I'
- A signed 16-bit constant.
-
- 'J'
- An unsigned 16-bit constant shifted left 16 bits (use 'L'
- instead for 'SImode' constants).
-
- 'K'
- An unsigned 16-bit constant.
-
- 'L'
- A signed 16-bit constant shifted left 16 bits.
-
- 'M'
- An integer constant greater than 31.
-
- 'N'
- An exact power of 2.
-
- 'O'
- The integer constant zero.
-
- 'P'
- A constant whose negation is a signed 16-bit constant.
-
- 'eI'
- A signed 34-bit integer constant if prefixed instructions are
- supported.
-
- 'G'
- A floating point constant that can be loaded into a register
- with one instruction per word.
-
- 'H'
- A floating point constant that can be loaded into a register
- using three instructions.
-
- 'm'
- A memory operand. Normally, 'm' does not allow addresses that
- update the base register. If the '<' or '>' constraint is
- also used, they are allowed and therefore on PowerPC targets
- in that case it is only safe to use 'm<>' in an 'asm'
- statement if that 'asm' statement accesses the operand exactly
- once. The 'asm' statement must also use '%U<OPNO>' as a
- placeholder for the "update" flag in the corresponding load or
- store instruction. For example:
-
- asm ("st%U0 %1,%0" : "=m<>" (mem) : "r" (val));
-
- is correct but:
-
- asm ("st %1,%0" : "=m<>" (mem) : "r" (val));
-
- is not.
-
- 'es'
- A "stable" memory operand; that is, one which does not include
- any automodification of the base register. This used to be
- useful when 'm' allowed automodification of the base register,
- but as those are now only allowed when '<' or '>' is used,
- 'es' is basically the same as 'm' without '<' and '>'.
-
- 'Q'
- A memory operand addressed by just a base register.
-
- 'Y'
- A memory operand for a DQ-form instruction.
-
- 'Z'
- A memory operand accessed with indexed or indirect addressing.
-
- 'R'
- An AIX TOC entry.
-
- 'a'
- An indexed or indirect address.
-
- 'U'
- A V.4 small data reference.
-
- 'W'
- A vector constant that does not require memory.
-
- 'j'
- The zero vector constant.
-
- _PRU--'config/pru/constraints.md'_
- 'I'
- An unsigned 8-bit integer constant.
-
- 'J'
- An unsigned 16-bit integer constant.
-
- 'L'
- An unsigned 5-bit integer constant (for shift counts).
-
- 'T'
- A text segment (program memory) constant label.
-
- 'Z'
- Integer constant zero.
-
- _RL78--'config/rl78/constraints.md'_
-
- 'Int3'
- An integer constant in the range 1 ... 7.
- 'Int8'
- An integer constant in the range 0 ... 255.
- 'J'
- An integer constant in the range -255 ... 0
- 'K'
- The integer constant 1.
- 'L'
- The integer constant -1.
- 'M'
- The integer constant 0.
- 'N'
- The integer constant 2.
- 'O'
- The integer constant -2.
- 'P'
- An integer constant in the range 1 ... 15.
- 'Qbi'
- The built-in compare types-eq, ne, gtu, ltu, geu, and leu.
- 'Qsc'
- The synthetic compare types-gt, lt, ge, and le.
- 'Wab'
- A memory reference with an absolute address.
- 'Wbc'
- A memory reference using 'BC' as a base register, with an
- optional offset.
- 'Wca'
- A memory reference using 'AX', 'BC', 'DE', or 'HL' for the
- address, for calls.
- 'Wcv'
- A memory reference using any 16-bit register pair for the
- address, for calls.
- 'Wd2'
- A memory reference using 'DE' as a base register, with an
- optional offset.
- 'Wde'
- A memory reference using 'DE' as a base register, without any
- offset.
- 'Wfr'
- Any memory reference to an address in the far address space.
- 'Wh1'
- A memory reference using 'HL' as a base register, with an
- optional one-byte offset.
- 'Whb'
- A memory reference using 'HL' as a base register, with 'B' or
- 'C' as the index register.
- 'Whl'
- A memory reference using 'HL' as a base register, without any
- offset.
- 'Ws1'
- A memory reference using 'SP' as a base register, with an
- optional one-byte offset.
- 'Y'
- Any memory reference to an address in the near address space.
- 'A'
- The 'AX' register.
- 'B'
- The 'BC' register.
- 'D'
- The 'DE' register.
- 'R'
- 'A' through 'L' registers.
- 'S'
- The 'SP' register.
- 'T'
- The 'HL' register.
- 'Z08W'
- The 16-bit 'R8' register.
- 'Z10W'
- The 16-bit 'R10' register.
- 'Zint'
- The registers reserved for interrupts ('R24' to 'R31').
- 'a'
- The 'A' register.
- 'b'
- The 'B' register.
- 'c'
- The 'C' register.
- 'd'
- The 'D' register.
- 'e'
- The 'E' register.
- 'h'
- The 'H' register.
- 'l'
- The 'L' register.
- 'v'
- The virtual registers.
- 'w'
- The 'PSW' register.
- 'x'
- The 'X' register.
-
- _RISC-V--'config/riscv/constraints.md'_
-
- 'f'
- A floating-point register (if available).
-
- 'I'
- An I-type 12-bit signed immediate.
-
- 'J'
- Integer zero.
-
- 'K'
- A 5-bit unsigned immediate for CSR access instructions.
-
- 'A'
- An address that is held in a general-purpose register.
-
- _RX--'config/rx/constraints.md'_
- 'Q'
- An address which does not involve register indirect addressing
- or pre/post increment/decrement addressing.
-
- 'Symbol'
- A symbol reference.
-
- 'Int08'
- A constant in the range -256 to 255, inclusive.
-
- 'Sint08'
- A constant in the range -128 to 127, inclusive.
-
- 'Sint16'
- A constant in the range -32768 to 32767, inclusive.
-
- 'Sint24'
- A constant in the range -8388608 to 8388607, inclusive.
-
- 'Uint04'
- A constant in the range 0 to 15, inclusive.
-
- _S/390 and zSeries--'config/s390/s390.h'_
- 'a'
- Address register (general purpose register except r0)
-
- 'c'
- Condition code register
-
- 'd'
- Data register (arbitrary general purpose register)
-
- 'f'
- Floating-point register
-
- 'I'
- Unsigned 8-bit constant (0-255)
-
- 'J'
- Unsigned 12-bit constant (0-4095)
-
- 'K'
- Signed 16-bit constant (-32768-32767)
-
- 'L'
- Value appropriate as displacement.
- '(0..4095)'
- for short displacement
- '(-524288..524287)'
- for long displacement
-
- 'M'
- Constant integer with a value of 0x7fffffff.
-
- 'N'
- Multiple letter constraint followed by 4 parameter letters.
- '0..9:'
- number of the part counting from most to least
- significant
- 'H,Q:'
- mode of the part
- 'D,S,H:'
- mode of the containing operand
- '0,F:'
- value of the other parts (F--all bits set)
- The constraint matches if the specified part of a constant has
- a value different from its other parts.
-
- 'Q'
- Memory reference without index register and with short
- displacement.
-
- 'R'
- Memory reference with index register and short displacement.
-
- 'S'
- Memory reference without index register but with long
- displacement.
-
- 'T'
- Memory reference with index register and long displacement.
-
- 'U'
- Pointer with short displacement.
-
- 'W'
- Pointer with long displacement.
-
- 'Y'
- Shift count operand.
-
- _SPARC--'config/sparc/sparc.h'_
- 'f'
- Floating-point register on the SPARC-V8 architecture and lower
- floating-point register on the SPARC-V9 architecture.
-
- 'e'
- Floating-point register. It is equivalent to 'f' on the
- SPARC-V8 architecture and contains both lower and upper
- floating-point registers on the SPARC-V9 architecture.
-
- 'c'
- Floating-point condition code register.
-
- 'd'
- Lower floating-point register. It is only valid on the
- SPARC-V9 architecture when the Visual Instruction Set is
- available.
-
- 'b'
- Floating-point register. It is only valid on the SPARC-V9
- architecture when the Visual Instruction Set is available.
-
- 'h'
- 64-bit global or out register for the SPARC-V8+ architecture.
-
- 'C'
- The constant all-ones, for floating-point.
-
- 'A'
- Signed 5-bit constant
-
- 'D'
- A vector constant
-
- 'I'
- Signed 13-bit constant
-
- 'J'
- Zero
-
- 'K'
- 32-bit constant with the low 12 bits clear (a constant that
- can be loaded with the 'sethi' instruction)
-
- 'L'
- A constant in the range supported by 'movcc' instructions
- (11-bit signed immediate)
-
- 'M'
- A constant in the range supported by 'movrcc' instructions
- (10-bit signed immediate)
-
- 'N'
- Same as 'K', except that it verifies that bits that are not in
- the lower 32-bit range are all zero. Must be used instead of
- 'K' for modes wider than 'SImode'
-
- 'O'
- The constant 4096
-
- 'G'
- Floating-point zero
-
- 'H'
- Signed 13-bit constant, sign-extended to 32 or 64 bits
-
- 'P'
- The constant -1
-
- 'Q'
- Floating-point constant whose integral representation can be
- moved into an integer register using a single sethi
- instruction
-
- 'R'
- Floating-point constant whose integral representation can be
- moved into an integer register using a single mov instruction
-
- 'S'
- Floating-point constant whose integral representation can be
- moved into an integer register using a high/lo_sum instruction
- sequence
-
- 'T'
- Memory address aligned to an 8-byte boundary
-
- 'U'
- Even register
-
- 'W'
- Memory address for 'e' constraint registers
-
- 'w'
- Memory address with only a base register
-
- 'Y'
- Vector zero
-
- _TI C6X family--'config/c6x/constraints.md'_
- 'a'
- Register file A (A0-A31).
-
- 'b'
- Register file B (B0-B31).
-
- 'A'
- Predicate registers in register file A (A0-A2 on C64X and
- higher, A1 and A2 otherwise).
-
- 'B'
- Predicate registers in register file B (B0-B2).
-
- 'C'
- A call-used register in register file B (B0-B9, B16-B31).
-
- 'Da'
- Register file A, excluding predicate registers (A3-A31, plus
- A0 if not C64X or higher).
-
- 'Db'
- Register file B, excluding predicate registers (B3-B31).
-
- 'Iu4'
- Integer constant in the range 0 ... 15.
-
- 'Iu5'
- Integer constant in the range 0 ... 31.
-
- 'In5'
- Integer constant in the range -31 ... 0.
-
- 'Is5'
- Integer constant in the range -16 ... 15.
-
- 'I5x'
- Integer constant that can be the operand of an ADDA or a SUBA
- insn.
-
- 'IuB'
- Integer constant in the range 0 ... 65535.
-
- 'IsB'
- Integer constant in the range -32768 ... 32767.
-
- 'IsC'
- Integer constant in the range -2^{20} ... 2^{20} - 1.
-
- 'Jc'
- Integer constant that is a valid mask for the clr instruction.
-
- 'Js'
- Integer constant that is a valid mask for the set instruction.
-
- 'Q'
- Memory location with A base register.
-
- 'R'
- Memory location with B base register.
-
- 'S0'
- On C64x+ targets, a GP-relative small data reference.
-
- 'S1'
- Any kind of 'SYMBOL_REF', for use in a call address.
-
- 'Si'
- Any kind of immediate operand, unless it matches the S0
- constraint.
-
- 'T'
- Memory location with B base register, but not using a long
- offset.
-
- 'W'
- A memory operand with an address that cannot be used in an
- unaligned access.
-
- 'Z'
- Register B14 (aka DP).
-
- _TILE-Gx--'config/tilegx/constraints.md'_
- 'R00'
- 'R01'
- 'R02'
- 'R03'
- 'R04'
- 'R05'
- 'R06'
- 'R07'
- 'R08'
- 'R09'
- 'R10'
- Each of these represents a register constraint for an
- individual register, from r0 to r10.
-
- 'I'
- Signed 8-bit integer constant.
-
- 'J'
- Signed 16-bit integer constant.
-
- 'K'
- Unsigned 16-bit integer constant.
-
- 'L'
- Integer constant that fits in one signed byte when incremented
- by one (-129 ... 126).
-
- 'm'
- Memory operand. If used together with '<' or '>', the operand
- can have postincrement which requires printing with '%In' and
- '%in' on TILE-Gx. For example:
-
- asm ("st_add %I0,%1,%i0" : "=m<>" (*mem) : "r" (val));
-
- 'M'
- A bit mask suitable for the BFINS instruction.
-
- 'N'
- Integer constant that is a byte tiled out eight times.
-
- 'O'
- The integer zero constant.
-
- 'P'
- Integer constant that is a sign-extended byte tiled out as
- four shorts.
-
- 'Q'
- Integer constant that fits in one signed byte when incremented
- (-129 ... 126), but excluding -1.
-
- 'S'
- Integer constant that has all 1 bits consecutive and starting
- at bit 0.
-
- 'T'
- A 16-bit fragment of a got, tls, or pc-relative reference.
-
- 'U'
- Memory operand except postincrement. This is roughly the same
- as 'm' when not used together with '<' or '>'.
-
- 'W'
- An 8-element vector constant with identical elements.
-
- 'Y'
- A 4-element vector constant with identical elements.
-
- 'Z0'
- The integer constant 0xffffffff.
-
- 'Z1'
- The integer constant 0xffffffff00000000.
-
- _TILEPro--'config/tilepro/constraints.md'_
- 'R00'
- 'R01'
- 'R02'
- 'R03'
- 'R04'
- 'R05'
- 'R06'
- 'R07'
- 'R08'
- 'R09'
- 'R10'
- Each of these represents a register constraint for an
- individual register, from r0 to r10.
-
- 'I'
- Signed 8-bit integer constant.
-
- 'J'
- Signed 16-bit integer constant.
-
- 'K'
- Nonzero integer constant with low 16 bits zero.
-
- 'L'
- Integer constant that fits in one signed byte when incremented
- by one (-129 ... 126).
-
- 'm'
- Memory operand. If used together with '<' or '>', the operand
- can have postincrement which requires printing with '%In' and
- '%in' on TILEPro. For example:
-
- asm ("swadd %I0,%1,%i0" : "=m<>" (mem) : "r" (val));
-
- 'M'
- A bit mask suitable for the MM instruction.
-
- 'N'
- Integer constant that is a byte tiled out four times.
-
- 'O'
- The integer zero constant.
-
- 'P'
- Integer constant that is a sign-extended byte tiled out as two
- shorts.
-
- 'Q'
- Integer constant that fits in one signed byte when incremented
- (-129 ... 126), but excluding -1.
-
- 'T'
- A symbolic operand, or a 16-bit fragment of a got, tls, or
- pc-relative reference.
-
- 'U'
- Memory operand except postincrement. This is roughly the same
- as 'm' when not used together with '<' or '>'.
-
- 'W'
- A 4-element vector constant with identical elements.
-
- 'Y'
- A 2-element vector constant with identical elements.
-
- _Visium--'config/visium/constraints.md'_
- 'b'
- EAM register 'mdb'
-
- 'c'
- EAM register 'mdc'
-
- 'f'
- Floating point register
-
- 'k'
- Register for sibcall optimization
-
- 'l'
- General register, but not 'r29', 'r30' and 'r31'
-
- 't'
- Register 'r1'
-
- 'u'
- Register 'r2'
-
- 'v'
- Register 'r3'
-
- 'G'
- Floating-point constant 0.0
-
- 'J'
- Integer constant in the range 0 .. 65535 (16-bit immediate)
-
- 'K'
- Integer constant in the range 1 .. 31 (5-bit immediate)
-
- 'L'
- Integer constant in the range -65535 .. -1 (16-bit negative
- immediate)
-
- 'M'
- Integer constant -1
-
- 'O'
- Integer constant 0
-
- 'P'
- Integer constant 32
-
- _x86 family--'config/i386/constraints.md'_
- 'R'
- Legacy register--the eight integer registers available on all
- i386 processors ('a', 'b', 'c', 'd', 'si', 'di', 'bp', 'sp').
-
- 'q'
- Any register accessible as 'Rl'. In 32-bit mode, 'a', 'b',
- 'c', and 'd'; in 64-bit mode, any integer register.
-
- 'Q'
- Any register accessible as 'Rh': 'a', 'b', 'c', and 'd'.
-
- 'l'
- Any register that can be used as the index in a base+index
- memory access: that is, any general register except the stack
- pointer.
-
- 'a'
- The 'a' register.
-
- 'b'
- The 'b' register.
-
- 'c'
- The 'c' register.
-
- 'd'
- The 'd' register.
-
- 'S'
- The 'si' register.
-
- 'D'
- The 'di' register.
-
- 'A'
- The 'a' and 'd' registers. This class is used for
- instructions that return double word results in the 'ax:dx'
- register pair. Single word values will be allocated either in
- 'ax' or 'dx'. For example on i386 the following implements
- 'rdtsc':
-
- unsigned long long rdtsc (void)
- {
- unsigned long long tick;
- __asm__ __volatile__("rdtsc":"=A"(tick));
- return tick;
- }
-
- This is not correct on x86-64 as it would allocate tick in
- either 'ax' or 'dx'. You have to use the following variant
- instead:
-
- unsigned long long rdtsc (void)
- {
- unsigned int tickl, tickh;
- __asm__ __volatile__("rdtsc":"=a"(tickl),"=d"(tickh));
- return ((unsigned long long)tickh << 32)|tickl;
- }
-
- 'U'
- The call-clobbered integer registers.
-
- 'f'
- Any 80387 floating-point (stack) register.
-
- 't'
- Top of 80387 floating-point stack ('%st(0)').
-
- 'u'
- Second from top of 80387 floating-point stack ('%st(1)').
-
- 'Yk'
- Any mask register that can be used as a predicate, i.e.
- 'k1-k7'.
-
- 'k'
- Any mask register.
-
- 'y'
- Any MMX register.
-
- 'x'
- Any SSE register.
-
- 'v'
- Any EVEX encodable SSE register ('%xmm0-%xmm31').
-
- 'w'
- Any bound register.
-
- 'Yz'
- First SSE register ('%xmm0').
-
- 'Yi'
- Any SSE register, when SSE2 and inter-unit moves are enabled.
-
- 'Yj'
- Any SSE register, when SSE2 and inter-unit moves from vector
- registers are enabled.
-
- 'Ym'
- Any MMX register, when inter-unit moves are enabled.
-
- 'Yn'
- Any MMX register, when inter-unit moves from vector registers
- are enabled.
-
- 'Yp'
- Any integer register when 'TARGET_PARTIAL_REG_STALL' is
- disabled.
-
- 'Ya'
- Any integer register when zero extensions with 'AND' are
- disabled.
-
- 'Yb'
- Any register that can be used as the GOT base when calling
- '___tls_get_addr': that is, any general register except 'a'
- and 'sp' registers, for '-fno-plt' if linker supports it.
- Otherwise, 'b' register.
-
- 'Yf'
- Any x87 register when 80387 floating-point arithmetic is
- enabled.
-
- 'Yr'
- Lower SSE register when avoiding REX prefix and all SSE
- registers otherwise.
-
- 'Yv'
- For AVX512VL, any EVEX-encodable SSE register
- ('%xmm0-%xmm31'), otherwise any SSE register.
-
- 'Yh'
- Any EVEX-encodable SSE register, that has number factor of
- four.
-
- 'Bf'
- Flags register operand.
-
- 'Bg'
- GOT memory operand.
-
- 'Bm'
- Vector memory operand.
-
- 'Bc'
- Constant memory operand.
-
- 'Bn'
- Memory operand without REX prefix.
-
- 'Bs'
- Sibcall memory operand.
-
- 'Bw'
- Call memory operand.
-
- 'Bz'
- Constant call address operand.
-
- 'BC'
- SSE constant -1 operand.
-
- 'I'
- Integer constant in the range 0 ... 31, for 32-bit shifts.
-
- 'J'
- Integer constant in the range 0 ... 63, for 64-bit shifts.
-
- 'K'
- Signed 8-bit integer constant.
-
- 'L'
- '0xFF' or '0xFFFF', for andsi as a zero-extending move.
-
- 'M'
- 0, 1, 2, or 3 (shifts for the 'lea' instruction).
-
- 'N'
- Unsigned 8-bit integer constant (for 'in' and 'out'
- instructions).
-
- 'O'
- Integer constant in the range 0 ... 127, for 128-bit shifts.
-
- 'G'
- Standard 80387 floating point constant.
-
- 'C'
- SSE constant zero operand.
-
- 'e'
- 32-bit signed integer constant, or a symbolic reference known
- to fit that range (for immediate operands in sign-extending
- x86-64 instructions).
-
- 'We'
- 32-bit signed integer constant, or a symbolic reference known
- to fit that range (for sign-extending conversion operations
- that require non-'VOIDmode' immediate operands).
-
- 'Wz'
- 32-bit unsigned integer constant, or a symbolic reference
- known to fit that range (for zero-extending conversion
- operations that require non-'VOIDmode' immediate operands).
-
- 'Wd'
- 128-bit integer constant where both the high and low 64-bit
- word satisfy the 'e' constraint.
-
- 'Z'
- 32-bit unsigned integer constant, or a symbolic reference
- known to fit that range (for immediate operands in
- zero-extending x86-64 instructions).
-
- 'Tv'
- VSIB address operand.
-
- 'Ts'
- Address operand without segment register.
-
- _Xstormy16--'config/stormy16/stormy16.h'_
- 'a'
- Register r0.
-
- 'b'
- Register r1.
-
- 'c'
- Register r2.
-
- 'd'
- Register r8.
-
- 'e'
- Registers r0 through r7.
-
- 't'
- Registers r0 and r1.
-
- 'y'
- The carry register.
-
- 'z'
- Registers r8 and r9.
-
- 'I'
- A constant between 0 and 3 inclusive.
-
- 'J'
- A constant that has exactly one bit set.
-
- 'K'
- A constant that has exactly one bit clear.
-
- 'L'
- A constant between 0 and 255 inclusive.
-
- 'M'
- A constant between -255 and 0 inclusive.
-
- 'N'
- A constant between -3 and 0 inclusive.
-
- 'O'
- A constant between 1 and 4 inclusive.
-
- 'P'
- A constant between -4 and -1 inclusive.
-
- 'Q'
- A memory reference that is a stack push.
-
- 'R'
- A memory reference that is a stack pop.
-
- 'S'
- A memory reference that refers to a constant address of known
- value.
-
- 'T'
- The register indicated by Rx (not implemented yet).
-
- 'U'
- A constant that is not between 2 and 15 inclusive.
-
- 'Z'
- The constant 0.
-
- _Xtensa--'config/xtensa/constraints.md'_
- 'a'
- General-purpose 32-bit register
-
- 'b'
- One-bit boolean register
-
- 'A'
- MAC16 40-bit accumulator register
-
- 'I'
- Signed 12-bit integer constant, for use in MOVI instructions
-
- 'J'
- Signed 8-bit integer constant, for use in ADDI instructions
-
- 'K'
- Integer constant valid for BccI instructions
-
- 'L'
- Unsigned constant valid for BccUI instructions
-
-
- File: gccint.info, Node: Disable Insn Alternatives, Next: Define Constraints, Prev: Machine Constraints, Up: Constraints
-
- 17.8.6 Disable insn alternatives using the 'enabled' attribute
- --------------------------------------------------------------
-
- There are three insn attributes that may be used to selectively disable
- instruction alternatives:
-
- 'enabled'
- Says whether an alternative is available on the current subtarget.
-
- 'preferred_for_size'
- Says whether an enabled alternative should be used in code that is
- optimized for size.
-
- 'preferred_for_speed'
- Says whether an enabled alternative should be used in code that is
- optimized for speed.
-
- All these attributes should use '(const_int 1)' to allow an alternative
- or '(const_int 0)' to disallow it. The attributes must be a static
- property of the subtarget; they cannot for example depend on the current
- operands, on the current optimization level, on the location of the insn
- within the body of a loop, on whether register allocation has finished,
- or on the current compiler pass.
-
- The 'enabled' attribute is a correctness property. It tells GCC to act
- as though the disabled alternatives were never defined in the first
- place. This is useful when adding new instructions to an existing
- pattern in cases where the new instructions are only available for
- certain cpu architecture levels (typically mapped to the '-march='
- command-line option).
-
- In contrast, the 'preferred_for_size' and 'preferred_for_speed'
- attributes are strong optimization hints rather than correctness
- properties. 'preferred_for_size' tells GCC which alternatives to
- consider when adding or modifying an instruction that GCC wants to
- optimize for size. 'preferred_for_speed' does the same thing for speed.
- Note that things like code motion can lead to cases where code optimized
- for size uses alternatives that are not preferred for size, and
- similarly for speed.
-
- Although 'define_insn's can in principle specify the 'enabled'
- attribute directly, it is often clearer to have subsiduary attributes
- for each architectural feature of interest. The 'define_insn's can then
- use these subsiduary attributes to say which alternatives require which
- features. The example below does this for 'cpu_facility'.
-
- E.g. the following two patterns could easily be merged using the
- 'enabled' attribute:
-
-
- (define_insn "*movdi_old"
- [(set (match_operand:DI 0 "register_operand" "=d")
- (match_operand:DI 1 "register_operand" " d"))]
- "!TARGET_NEW"
- "lgr %0,%1")
-
- (define_insn "*movdi_new"
- [(set (match_operand:DI 0 "register_operand" "=d,f,d")
- (match_operand:DI 1 "register_operand" " d,d,f"))]
- "TARGET_NEW"
- "@
- lgr %0,%1
- ldgr %0,%1
- lgdr %0,%1")
-
-
- to:
-
-
- (define_insn "*movdi_combined"
- [(set (match_operand:DI 0 "register_operand" "=d,f,d")
- (match_operand:DI 1 "register_operand" " d,d,f"))]
- ""
- "@
- lgr %0,%1
- ldgr %0,%1
- lgdr %0,%1"
- [(set_attr "cpu_facility" "*,new,new")])
-
-
- with the 'enabled' attribute defined like this:
-
-
- (define_attr "cpu_facility" "standard,new" (const_string "standard"))
-
- (define_attr "enabled" ""
- (cond [(eq_attr "cpu_facility" "standard") (const_int 1)
- (and (eq_attr "cpu_facility" "new")
- (ne (symbol_ref "TARGET_NEW") (const_int 0)))
- (const_int 1)]
- (const_int 0)))
-
-
-
- File: gccint.info, Node: Define Constraints, Next: C Constraint Interface, Prev: Disable Insn Alternatives, Up: Constraints
-
- 17.8.7 Defining Machine-Specific Constraints
- --------------------------------------------
-
- Machine-specific constraints fall into two categories: register and
- non-register constraints. Within the latter category, constraints which
- allow subsets of all possible memory or address operands should be
- specially marked, to give 'reload' more information.
-
- Machine-specific constraints can be given names of arbitrary length,
- but they must be entirely composed of letters, digits, underscores
- ('_'), and angle brackets ('< >'). Like C identifiers, they must begin
- with a letter or underscore.
-
- In order to avoid ambiguity in operand constraint strings, no
- constraint can have a name that begins with any other constraint's name.
- For example, if 'x' is defined as a constraint name, 'xy' may not be,
- and vice versa. As a consequence of this rule, no constraint may begin
- with one of the generic constraint letters: 'E F V X g i m n o p r s'.
-
- Register constraints correspond directly to register classes. *Note
- Register Classes::. There is thus not much flexibility in their
- definitions.
-
- -- MD Expression: define_register_constraint name regclass docstring
- All three arguments are string constants. NAME is the name of the
- constraint, as it will appear in 'match_operand' expressions. If
- NAME is a multi-letter constraint its length shall be the same for
- all constraints starting with the same letter. REGCLASS can be
- either the name of the corresponding register class (*note Register
- Classes::), or a C expression which evaluates to the appropriate
- register class. If it is an expression, it must have no side
- effects, and it cannot look at the operand. The usual use of
- expressions is to map some register constraints to 'NO_REGS' when
- the register class is not available on a given subarchitecture.
-
- DOCSTRING is a sentence documenting the meaning of the constraint.
- Docstrings are explained further below.
-
- Non-register constraints are more like predicates: the constraint
- definition gives a boolean expression which indicates whether the
- constraint matches.
-
- -- MD Expression: define_constraint name docstring exp
- The NAME and DOCSTRING arguments are the same as for
- 'define_register_constraint', but note that the docstring comes
- immediately after the name for these expressions. EXP is an RTL
- expression, obeying the same rules as the RTL expressions in
- predicate definitions. *Note Defining Predicates::, for details.
- If it evaluates true, the constraint matches; if it evaluates
- false, it doesn't. Constraint expressions should indicate which
- RTL codes they might match, just like predicate expressions.
-
- 'match_test' C expressions have access to the following variables:
-
- OP
- The RTL object defining the operand.
- MODE
- The machine mode of OP.
- IVAL
- 'INTVAL (OP)', if OP is a 'const_int'.
- HVAL
- 'CONST_DOUBLE_HIGH (OP)', if OP is an integer 'const_double'.
- LVAL
- 'CONST_DOUBLE_LOW (OP)', if OP is an integer 'const_double'.
- RVAL
- 'CONST_DOUBLE_REAL_VALUE (OP)', if OP is a floating-point
- 'const_double'.
-
- The *VAL variables should only be used once another piece of the
- expression has verified that OP is the appropriate kind of RTL
- object.
-
- Most non-register constraints should be defined with
- 'define_constraint'. The remaining two definition expressions are only
- appropriate for constraints that should be handled specially by 'reload'
- if they fail to match.
-
- -- MD Expression: define_memory_constraint name docstring exp
- Use this expression for constraints that match a subset of all
- memory operands: that is, 'reload' can make them match by
- converting the operand to the form '(mem (reg X))', where X is a
- base register (from the register class specified by
- 'BASE_REG_CLASS', *note Register Classes::).
-
- For example, on the S/390, some instructions do not accept
- arbitrary memory references, but only those that do not make use of
- an index register. The constraint letter 'Q' is defined to
- represent a memory address of this type. If 'Q' is defined with
- 'define_memory_constraint', a 'Q' constraint can handle any memory
- operand, because 'reload' knows it can simply copy the memory
- address into a base register if required. This is analogous to the
- way an 'o' constraint can handle any memory operand.
-
- The syntax and semantics are otherwise identical to
- 'define_constraint'.
-
- -- MD Expression: define_special_memory_constraint name docstring exp
- Use this expression for constraints that match a subset of all
- memory operands: that is, 'reload' cannot make them match by
- reloading the address as it is described for
- 'define_memory_constraint' or such address reload is undesirable
- with the performance point of view.
-
- For example, 'define_special_memory_constraint' can be useful if
- specifically aligned memory is necessary or desirable for some insn
- operand.
-
- The syntax and semantics are otherwise identical to
- 'define_constraint'.
-
- -- MD Expression: define_address_constraint name docstring exp
- Use this expression for constraints that match a subset of all
- address operands: that is, 'reload' can make the constraint match
- by converting the operand to the form '(reg X)', again with X a
- base register.
-
- Constraints defined with 'define_address_constraint' can only be
- used with the 'address_operand' predicate, or machine-specific
- predicates that work the same way. They are treated analogously to
- the generic 'p' constraint.
-
- The syntax and semantics are otherwise identical to
- 'define_constraint'.
-
- For historical reasons, names beginning with the letters 'G H' are
- reserved for constraints that match only 'const_double's, and names
- beginning with the letters 'I J K L M N O P' are reserved for
- constraints that match only 'const_int's. This may change in the
- future. For the time being, constraints with these names must be
- written in a stylized form, so that 'genpreds' can tell you did it
- correctly:
-
- (define_constraint "[GHIJKLMNOP]..."
- "DOC..."
- (and (match_code "const_int") ; 'const_double' for G/H
- CONDITION...)) ; usually a 'match_test'
-
- It is fine to use names beginning with other letters for constraints
- that match 'const_double's or 'const_int's.
-
- Each docstring in a constraint definition should be one or more
- complete sentences, marked up in Texinfo format. _They are currently
- unused._ In the future they will be copied into the GCC manual, in
- *note Machine Constraints::, replacing the hand-maintained tables
- currently found in that section. Also, in the future the compiler may
- use this to give more helpful diagnostics when poor choice of 'asm'
- constraints causes a reload failure.
-
- If you put the pseudo-Texinfo directive '@internal' at the beginning of
- a docstring, then (in the future) it will appear only in the internals
- manual's version of the machine-specific constraint tables. Use this
- for constraints that should not appear in 'asm' statements.
-
-
- File: gccint.info, Node: C Constraint Interface, Prev: Define Constraints, Up: Constraints
-
- 17.8.8 Testing constraints from C
- ---------------------------------
-
- It is occasionally useful to test a constraint from C code rather than
- implicitly via the constraint string in a 'match_operand'. The
- generated file 'tm_p.h' declares a few interfaces for working with
- constraints. At present these are defined for all constraints except
- 'g' (which is equivalent to 'general_operand').
-
- Some valid constraint names are not valid C identifiers, so there is a
- mangling scheme for referring to them from C. Constraint names that do
- not contain angle brackets or underscores are left unchanged.
- Underscores are doubled, each '<' is replaced with '_l', and each '>'
- with '_g'. Here are some examples:
-
- *Original* *Mangled*
- x x
- P42x P42x
- P4_x P4__x
- P4>x P4_gx
- P4>> P4_g_g
- P4_g> P4__g_g
-
- Throughout this section, the variable C is either a constraint in the
- abstract sense, or a constant from 'enum constraint_num'; the variable M
- is a mangled constraint name (usually as part of a larger identifier).
-
- -- Enum: constraint_num
- For each constraint except 'g', there is a corresponding
- enumeration constant: 'CONSTRAINT_' plus the mangled name of the
- constraint. Functions that take an 'enum constraint_num' as an
- argument expect one of these constants.
-
- -- Function: inline bool satisfies_constraint_M (rtx EXP)
- For each non-register constraint M except 'g', there is one of
- these functions; it returns 'true' if EXP satisfies the constraint.
- These functions are only visible if 'rtl.h' was included before
- 'tm_p.h'.
-
- -- Function: bool constraint_satisfied_p (rtx EXP, enum constraint_num
- C)
- Like the 'satisfies_constraint_M' functions, but the constraint to
- test is given as an argument, C. If C specifies a register
- constraint, this function will always return 'false'.
-
- -- Function: enum reg_class reg_class_for_constraint (enum
- constraint_num C)
- Returns the register class associated with C. If C is not a
- register constraint, or those registers are not available for the
- currently selected subtarget, returns 'NO_REGS'.
-
- Here is an example use of 'satisfies_constraint_M'. In peephole
- optimizations (*note Peephole Definitions::), operand constraint strings
- are ignored, so if there are relevant constraints, they must be tested
- in the C condition. In the example, the optimization is applied if
- operand 2 does _not_ satisfy the 'K' constraint. (This is a simplified
- version of a peephole definition from the i386 machine description.)
-
- (define_peephole2
- [(match_scratch:SI 3 "r")
- (set (match_operand:SI 0 "register_operand" "")
- (mult:SI (match_operand:SI 1 "memory_operand" "")
- (match_operand:SI 2 "immediate_operand" "")))]
-
- "!satisfies_constraint_K (operands[2])"
-
- [(set (match_dup 3) (match_dup 1))
- (set (match_dup 0) (mult:SI (match_dup 3) (match_dup 2)))]
-
- "")
-
-
- File: gccint.info, Node: Standard Names, Next: Pattern Ordering, Prev: Constraints, Up: Machine Desc
-
- 17.9 Standard Pattern Names For Generation
- ==========================================
-
- Here is a table of the instruction names that are meaningful in the RTL
- generation pass of the compiler. Giving one of these names to an
- instruction pattern tells the RTL generation pass that it can use the
- pattern to accomplish a certain task.
-
- 'movM'
- Here M stands for a two-letter machine mode name, in lowercase.
- This instruction pattern moves data with that machine mode from
- operand 1 to operand 0. For example, 'movsi' moves full-word data.
-
- If operand 0 is a 'subreg' with mode M of a register whose own mode
- is wider than M, the effect of this instruction is to store the
- specified value in the part of the register that corresponds to
- mode M. Bits outside of M, but which are within the same target
- word as the 'subreg' are undefined. Bits which are outside the
- target word are left unchanged.
-
- This class of patterns is special in several ways. First of all,
- each of these names up to and including full word size _must_ be
- defined, because there is no other way to copy a datum from one
- place to another. If there are patterns accepting operands in
- larger modes, 'movM' must be defined for integer modes of those
- sizes.
-
- Second, these patterns are not used solely in the RTL generation
- pass. Even the reload pass can generate move insns to copy values
- from stack slots into temporary registers. When it does so, one of
- the operands is a hard register and the other is an operand that
- can need to be reloaded into a register.
-
- Therefore, when given such a pair of operands, the pattern must
- generate RTL which needs no reloading and needs no temporary
- registers--no registers other than the operands. For example, if
- you support the pattern with a 'define_expand', then in such a case
- the 'define_expand' mustn't call 'force_reg' or any other such
- function which might generate new pseudo registers.
-
- This requirement exists even for subword modes on a RISC machine
- where fetching those modes from memory normally requires several
- insns and some temporary registers.
-
- During reload a memory reference with an invalid address may be
- passed as an operand. Such an address will be replaced with a
- valid address later in the reload pass. In this case, nothing may
- be done with the address except to use it as it stands. If it is
- copied, it will not be replaced with a valid address. No attempt
- should be made to make such an address into a valid address and no
- routine (such as 'change_address') that will do so may be called.
- Note that 'general_operand' will fail when applied to such an
- address.
-
- The global variable 'reload_in_progress' (which must be explicitly
- declared if required) can be used to determine whether such special
- handling is required.
-
- The variety of operands that have reloads depends on the rest of
- the machine description, but typically on a RISC machine these can
- only be pseudo registers that did not get hard registers, while on
- other machines explicit memory references will get optional
- reloads.
-
- If a scratch register is required to move an object to or from
- memory, it can be allocated using 'gen_reg_rtx' prior to life
- analysis.
-
- If there are cases which need scratch registers during or after
- reload, you must provide an appropriate secondary_reload target
- hook.
-
- The macro 'can_create_pseudo_p' can be used to determine if it is
- unsafe to create new pseudo registers. If this variable is
- nonzero, then it is unsafe to call 'gen_reg_rtx' to allocate a new
- pseudo.
-
- The constraints on a 'movM' must permit moving any hard register to
- any other hard register provided that 'TARGET_HARD_REGNO_MODE_OK'
- permits mode M in both registers and 'TARGET_REGISTER_MOVE_COST'
- applied to their classes returns a value of 2.
-
- It is obligatory to support floating point 'movM' instructions into
- and out of any registers that can hold fixed point values, because
- unions and structures (which have modes 'SImode' or 'DImode') can
- be in those registers and they may have floating point members.
-
- There may also be a need to support fixed point 'movM' instructions
- in and out of floating point registers. Unfortunately, I have
- forgotten why this was so, and I don't know whether it is still
- true. If 'TARGET_HARD_REGNO_MODE_OK' rejects fixed point values in
- floating point registers, then the constraints of the fixed point
- 'movM' instructions must be designed to avoid ever trying to reload
- into a floating point register.
-
- 'reload_inM'
- 'reload_outM'
- These named patterns have been obsoleted by the target hook
- 'secondary_reload'.
-
- Like 'movM', but used when a scratch register is required to move
- between operand 0 and operand 1. Operand 2 describes the scratch
- register. See the discussion of the 'SECONDARY_RELOAD_CLASS' macro
- in *note Register Classes::.
-
- There are special restrictions on the form of the 'match_operand's
- used in these patterns. First, only the predicate for the reload
- operand is examined, i.e., 'reload_in' examines operand 1, but not
- the predicates for operand 0 or 2. Second, there may be only one
- alternative in the constraints. Third, only a single register
- class letter may be used for the constraint; subsequent constraint
- letters are ignored. As a special exception, an empty constraint
- string matches the 'ALL_REGS' register class. This may relieve
- ports of the burden of defining an 'ALL_REGS' constraint letter
- just for these patterns.
-
- 'movstrictM'
- Like 'movM' except that if operand 0 is a 'subreg' with mode M of a
- register whose natural mode is wider, the 'movstrictM' instruction
- is guaranteed not to alter any of the register except the part
- which belongs to mode M.
-
- 'movmisalignM'
- This variant of a move pattern is designed to load or store a value
- from a memory address that is not naturally aligned for its mode.
- For a store, the memory will be in operand 0; for a load, the
- memory will be in operand 1. The other operand is guaranteed not
- to be a memory, so that it's easy to tell whether this is a load or
- store.
-
- This pattern is used by the autovectorizer, and when expanding a
- 'MISALIGNED_INDIRECT_REF' expression.
-
- 'load_multiple'
- Load several consecutive memory locations into consecutive
- registers. Operand 0 is the first of the consecutive registers,
- operand 1 is the first memory location, and operand 2 is a
- constant: the number of consecutive registers.
-
- Define this only if the target machine really has such an
- instruction; do not define this if the most efficient way of
- loading consecutive registers from memory is to do them one at a
- time.
-
- On some machines, there are restrictions as to which consecutive
- registers can be stored into memory, such as particular starting or
- ending register numbers or only a range of valid counts. For those
- machines, use a 'define_expand' (*note Expander Definitions::) and
- make the pattern fail if the restrictions are not met.
-
- Write the generated insn as a 'parallel' with elements being a
- 'set' of one register from the appropriate memory location (you may
- also need 'use' or 'clobber' elements). Use a 'match_parallel'
- (*note RTL Template::) to recognize the insn. See 'rs6000.md' for
- examples of the use of this insn pattern.
-
- 'store_multiple'
- Similar to 'load_multiple', but store several consecutive registers
- into consecutive memory locations. Operand 0 is the first of the
- consecutive memory locations, operand 1 is the first register, and
- operand 2 is a constant: the number of consecutive registers.
-
- 'vec_load_lanesMN'
- Perform an interleaved load of several vectors from memory operand
- 1 into register operand 0. Both operands have mode M. The
- register operand is viewed as holding consecutive vectors of mode
- N, while the memory operand is a flat array that contains the same
- number of elements. The operation is equivalent to:
-
- int c = GET_MODE_SIZE (M) / GET_MODE_SIZE (N);
- for (j = 0; j < GET_MODE_NUNITS (N); j++)
- for (i = 0; i < c; i++)
- operand0[i][j] = operand1[j * c + i];
-
- For example, 'vec_load_lanestiv4hi' loads 8 16-bit values from
- memory into a register of mode 'TI'. The register contains two
- consecutive vectors of mode 'V4HI'.
-
- This pattern can only be used if:
- TARGET_ARRAY_MODE_SUPPORTED_P (N, C)
- is true. GCC assumes that, if a target supports this kind of
- instruction for some mode N, it also supports unaligned loads for
- vectors of mode N.
-
- This pattern is not allowed to 'FAIL'.
-
- 'vec_mask_load_lanesMN'
- Like 'vec_load_lanesMN', but takes an additional mask operand
- (operand 2) that specifies which elements of the destination
- vectors should be loaded. Other elements of the destination
- vectors are set to zero. The operation is equivalent to:
-
- int c = GET_MODE_SIZE (M) / GET_MODE_SIZE (N);
- for (j = 0; j < GET_MODE_NUNITS (N); j++)
- if (operand2[j])
- for (i = 0; i < c; i++)
- operand0[i][j] = operand1[j * c + i];
- else
- for (i = 0; i < c; i++)
- operand0[i][j] = 0;
-
- This pattern is not allowed to 'FAIL'.
-
- 'vec_store_lanesMN'
- Equivalent to 'vec_load_lanesMN', with the memory and register
- operands reversed. That is, the instruction is equivalent to:
-
- int c = GET_MODE_SIZE (M) / GET_MODE_SIZE (N);
- for (j = 0; j < GET_MODE_NUNITS (N); j++)
- for (i = 0; i < c; i++)
- operand0[j * c + i] = operand1[i][j];
-
- for a memory operand 0 and register operand 1.
-
- This pattern is not allowed to 'FAIL'.
-
- 'vec_mask_store_lanesMN'
- Like 'vec_store_lanesMN', but takes an additional mask operand
- (operand 2) that specifies which elements of the source vectors
- should be stored. The operation is equivalent to:
-
- int c = GET_MODE_SIZE (M) / GET_MODE_SIZE (N);
- for (j = 0; j < GET_MODE_NUNITS (N); j++)
- if (operand2[j])
- for (i = 0; i < c; i++)
- operand0[j * c + i] = operand1[i][j];
-
- This pattern is not allowed to 'FAIL'.
-
- 'gather_loadMN'
- Load several separate memory locations into a vector of mode M.
- Operand 1 is a scalar base address and operand 2 is a vector of
- mode N containing offsets from that base. Operand 0 is a
- destination vector with the same number of elements as N. For each
- element index I:
-
- * extend the offset element I to address width, using zero
- extension if operand 3 is 1 and sign extension if operand 3 is
- zero;
- * multiply the extended offset by operand 4;
- * add the result to the base; and
- * load the value at that address into element I of operand 0.
-
- The value of operand 3 does not matter if the offsets are already
- address width.
-
- 'mask_gather_loadMN'
- Like 'gather_loadMN', but takes an extra mask operand as operand 5.
- Bit I of the mask is set if element I of the result should be
- loaded from memory and clear if element I of the result should be
- set to zero.
-
- 'scatter_storeMN'
- Store a vector of mode M into several distinct memory locations.
- Operand 0 is a scalar base address and operand 1 is a vector of
- mode N containing offsets from that base. Operand 4 is the vector
- of values that should be stored, which has the same number of
- elements as N. For each element index I:
-
- * extend the offset element I to address width, using zero
- extension if operand 2 is 1 and sign extension if operand 2 is
- zero;
- * multiply the extended offset by operand 3;
- * add the result to the base; and
- * store element I of operand 4 to that address.
-
- The value of operand 2 does not matter if the offsets are already
- address width.
-
- 'mask_scatter_storeMN'
- Like 'scatter_storeMN', but takes an extra mask operand as operand
- 5. Bit I of the mask is set if element I of the result should be
- stored to memory.
-
- 'vec_setM'
- Set given field in the vector value. Operand 0 is the vector to
- modify, operand 1 is new value of field and operand 2 specify the
- field index.
-
- 'vec_extractMN'
- Extract given field from the vector value. Operand 1 is the
- vector, operand 2 specify field index and operand 0 place to store
- value into. The N mode is the mode of the field or vector of
- fields that should be extracted, should be either element mode of
- the vector mode M, or a vector mode with the same element mode and
- smaller number of elements. If N is a vector mode, the index is
- counted in units of that mode.
-
- 'vec_initMN'
- Initialize the vector to given values. Operand 0 is the vector to
- initialize and operand 1 is parallel containing values for
- individual fields. The N mode is the mode of the elements, should
- be either element mode of the vector mode M, or a vector mode with
- the same element mode and smaller number of elements.
-
- 'vec_duplicateM'
- Initialize vector output operand 0 so that each element has the
- value given by scalar input operand 1. The vector has mode M and
- the scalar has the mode appropriate for one element of M.
-
- This pattern only handles duplicates of non-constant inputs.
- Constant vectors go through the 'movM' pattern instead.
-
- This pattern is not allowed to 'FAIL'.
-
- 'vec_seriesM'
- Initialize vector output operand 0 so that element I is equal to
- operand 1 plus I times operand 2. In other words, create a linear
- series whose base value is operand 1 and whose step is operand 2.
-
- The vector output has mode M and the scalar inputs have the mode
- appropriate for one element of M. This pattern is not used for
- floating-point vectors, in order to avoid having to specify the
- rounding behavior for I > 1.
-
- This pattern is not allowed to 'FAIL'.
-
- 'while_ultMN'
- Set operand 0 to a mask that is true while incrementing operand 1
- gives a value that is less than operand 2. Operand 0 has mode N
- and operands 1 and 2 are scalar integers of mode M. The operation
- is equivalent to:
-
- operand0[0] = operand1 < operand2;
- for (i = 1; i < GET_MODE_NUNITS (N); i++)
- operand0[i] = operand0[i - 1] && (operand1 + i < operand2);
-
- 'check_raw_ptrsM'
- Check whether, given two pointers A and B and a length LEN, a write
- of LEN bytes at A followed by a read of LEN bytes at B can be split
- into interleaved byte accesses 'A[0], B[0], A[1], B[1], ...'
- without affecting the dependencies between the bytes. Set operand
- 0 to true if the split is possible and false otherwise.
-
- Operands 1, 2 and 3 provide the values of A, B and LEN
- respectively. Operand 4 is a constant integer that provides the
- known common alignment of A and B. All inputs have mode M.
-
- This split is possible if:
-
- A == B || A + LEN <= B || B + LEN <= A
-
- You should only define this pattern if the target has a way of
- accelerating the test without having to do the individual
- comparisons.
-
- 'check_war_ptrsM'
- Like 'check_raw_ptrsM', but with the read and write swapped round.
- The split is possible in this case if:
-
- B <= A || A + LEN <= B
-
- 'vec_cmpMN'
- Output a vector comparison. Operand 0 of mode N is the destination
- for predicate in operand 1 which is a signed vector comparison with
- operands of mode M in operands 2 and 3. Predicate is computed by
- element-wise evaluation of the vector comparison with a truth value
- of all-ones and a false value of all-zeros.
-
- 'vec_cmpuMN'
- Similar to 'vec_cmpMN' but perform unsigned vector comparison.
-
- 'vec_cmpeqMN'
- Similar to 'vec_cmpMN' but perform equality or non-equality vector
- comparison only. If 'vec_cmpMN' or 'vec_cmpuMN' instruction
- pattern is supported, it will be preferred over 'vec_cmpeqMN', so
- there is no need to define this instruction pattern if the others
- are supported.
-
- 'vcondMN'
- Output a conditional vector move. Operand 0 is the destination to
- receive a combination of operand 1 and operand 2, which are of mode
- M, dependent on the outcome of the predicate in operand 3 which is
- a signed vector comparison with operands of mode N in operands 4
- and 5. The modes M and N should have the same size. Operand 0
- will be set to the value OP1 & MSK | OP2 & ~MSK where MSK is
- computed by element-wise evaluation of the vector comparison with a
- truth value of all-ones and a false value of all-zeros.
-
- 'vconduMN'
- Similar to 'vcondMN' but performs unsigned vector comparison.
-
- 'vcondeqMN'
- Similar to 'vcondMN' but performs equality or non-equality vector
- comparison only. If 'vcondMN' or 'vconduMN' instruction pattern is
- supported, it will be preferred over 'vcondeqMN', so there is no
- need to define this instruction pattern if the others are
- supported.
-
- 'vcond_mask_MN'
- Similar to 'vcondMN' but operand 3 holds a pre-computed result of
- vector comparison.
-
- 'maskloadMN'
- Perform a masked load of vector from memory operand 1 of mode M
- into register operand 0. Mask is provided in register operand 2 of
- mode N.
-
- This pattern is not allowed to 'FAIL'.
-
- 'maskstoreMN'
- Perform a masked store of vector from register operand 1 of mode M
- into memory operand 0. Mask is provided in register operand 2 of
- mode N.
-
- This pattern is not allowed to 'FAIL'.
-
- 'vec_permM'
- Output a (variable) vector permutation. Operand 0 is the
- destination to receive elements from operand 1 and operand 2, which
- are of mode M. Operand 3 is the "selector". It is an integral
- mode vector of the same width and number of elements as mode M.
-
- The input elements are numbered from 0 in operand 1 through 2*N-1
- in operand 2. The elements of the selector must be computed modulo
- 2*N. Note that if 'rtx_equal_p(operand1, operand2)', this can be
- implemented with just operand 1 and selector elements modulo N.
-
- In order to make things easy for a number of targets, if there is
- no 'vec_perm' pattern for mode M, but there is for mode Q where Q
- is a vector of 'QImode' of the same width as M, the middle-end will
- lower the mode M 'VEC_PERM_EXPR' to mode Q.
-
- See also 'TARGET_VECTORIZER_VEC_PERM_CONST', which performs the
- analogous operation for constant selectors.
-
- 'pushM1'
- Output a push instruction. Operand 0 is value to push. Used only
- when 'PUSH_ROUNDING' is defined. For historical reason, this
- pattern may be missing and in such case an 'mov' expander is used
- instead, with a 'MEM' expression forming the push operation. The
- 'mov' expander method is deprecated.
-
- 'addM3'
- Add operand 2 and operand 1, storing the result in operand 0. All
- operands must have mode M. This can be used even on two-address
- machines, by means of constraints requiring operands 1 and 0 to be
- the same location.
-
- 'ssaddM3', 'usaddM3'
- 'subM3', 'sssubM3', 'ussubM3'
- 'mulM3', 'ssmulM3', 'usmulM3'
- 'divM3', 'ssdivM3'
- 'udivM3', 'usdivM3'
- 'modM3', 'umodM3'
- 'uminM3', 'umaxM3'
- 'andM3', 'iorM3', 'xorM3'
- Similar, for other arithmetic operations.
-
- 'addvM4'
- Like 'addM3' but takes a 'code_label' as operand 3 and emits code
- to jump to it if signed overflow occurs during the addition. This
- pattern is used to implement the built-in functions performing
- signed integer addition with overflow checking.
-
- 'subvM4', 'mulvM4'
- Similar, for other signed arithmetic operations.
-
- 'uaddvM4'
- Like 'addvM4' but for unsigned addition. That is to say, the
- operation is the same as signed addition but the jump is taken only
- on unsigned overflow.
-
- 'usubvM4', 'umulvM4'
- Similar, for other unsigned arithmetic operations.
-
- 'addptrM3'
- Like 'addM3' but is guaranteed to only be used for address
- calculations. The expanded code is not allowed to clobber the
- condition code. It only needs to be defined if 'addM3' sets the
- condition code. If adds used for address calculations and normal
- adds are not compatible it is required to expand a distinct pattern
- (e.g. using an unspec). The pattern is used by LRA to emit address
- calculations. 'addM3' is used if 'addptrM3' is not defined.
-
- 'fmaM4'
- Multiply operand 2 and operand 1, then add operand 3, storing the
- result in operand 0 without doing an intermediate rounding step.
- All operands must have mode M. This pattern is used to implement
- the 'fma', 'fmaf', and 'fmal' builtin functions from the ISO C99
- standard.
-
- 'fmsM4'
- Like 'fmaM4', except operand 3 subtracted from the product instead
- of added to the product. This is represented in the rtl as
-
- (fma:M OP1 OP2 (neg:M OP3))
-
- 'fnmaM4'
- Like 'fmaM4' except that the intermediate product is negated before
- being added to operand 3. This is represented in the rtl as
-
- (fma:M (neg:M OP1) OP2 OP3)
-
- 'fnmsM4'
- Like 'fmsM4' except that the intermediate product is negated before
- subtracting operand 3. This is represented in the rtl as
-
- (fma:M (neg:M OP1) OP2 (neg:M OP3))
-
- 'sminM3', 'smaxM3'
- Signed minimum and maximum operations. When used with floating
- point, if both operands are zeros, or if either operand is 'NaN',
- then it is unspecified which of the two operands is returned as the
- result.
-
- 'fminM3', 'fmaxM3'
- IEEE-conformant minimum and maximum operations. If one operand is
- a quiet 'NaN', then the other operand is returned. If both
- operands are quiet 'NaN', then a quiet 'NaN' is returned. In the
- case when gcc supports signaling 'NaN' (-fsignaling-nans) an
- invalid floating point exception is raised and a quiet 'NaN' is
- returned.
-
- All operands have mode M, which is a scalar or vector
- floating-point mode. These patterns are not allowed to 'FAIL'.
-
- 'reduc_smin_scal_M', 'reduc_smax_scal_M'
- Find the signed minimum/maximum of the elements of a vector. The
- vector is operand 1, and operand 0 is the scalar result, with mode
- equal to the mode of the elements of the input vector.
-
- 'reduc_umin_scal_M', 'reduc_umax_scal_M'
- Find the unsigned minimum/maximum of the elements of a vector. The
- vector is operand 1, and operand 0 is the scalar result, with mode
- equal to the mode of the elements of the input vector.
-
- 'reduc_plus_scal_M'
- Compute the sum of the elements of a vector. The vector is operand
- 1, and operand 0 is the scalar result, with mode equal to the mode
- of the elements of the input vector.
-
- 'reduc_and_scal_M'
- 'reduc_ior_scal_M'
- 'reduc_xor_scal_M'
- Compute the bitwise 'AND'/'IOR'/'XOR' reduction of the elements of
- a vector of mode M. Operand 1 is the vector input and operand 0 is
- the scalar result. The mode of the scalar result is the same as
- one element of M.
-
- 'extract_last_M'
- Find the last set bit in mask operand 1 and extract the associated
- element of vector operand 2. Store the result in scalar operand 0.
- Operand 2 has vector mode M while operand 0 has the mode
- appropriate for one element of M. Operand 1 has the usual mask
- mode for vectors of mode M; see 'TARGET_VECTORIZE_GET_MASK_MODE'.
-
- 'fold_extract_last_M'
- If any bits of mask operand 2 are set, find the last set bit,
- extract the associated element from vector operand 3, and store the
- result in operand 0. Store operand 1 in operand 0 otherwise.
- Operand 3 has mode M and operands 0 and 1 have the mode appropriate
- for one element of M. Operand 2 has the usual mask mode for
- vectors of mode M; see 'TARGET_VECTORIZE_GET_MASK_MODE'.
-
- 'fold_left_plus_M'
- Take scalar operand 1 and successively add each element from vector
- operand 2. Store the result in scalar operand 0. The vector has
- mode M and the scalars have the mode appropriate for one element of
- M. The operation is strictly in-order: there is no reassociation.
-
- 'mask_fold_left_plus_M'
- Like 'fold_left_plus_M', but takes an additional mask operand
- (operand 3) that specifies which elements of the source vector
- should be added.
-
- 'sdot_prodM'
- 'udot_prodM'
- Compute the sum of the products of two signed/unsigned elements.
- Operand 1 and operand 2 are of the same mode. Their product, which
- is of a wider mode, is computed and added to operand 3. Operand 3
- is of a mode equal or wider than the mode of the product. The
- result is placed in operand 0, which is of the same mode as operand
- 3.
-
- 'ssadM'
- 'usadM'
- Compute the sum of absolute differences of two signed/unsigned
- elements. Operand 1 and operand 2 are of the same mode. Their
- absolute difference, which is of a wider mode, is computed and
- added to operand 3. Operand 3 is of a mode equal or wider than the
- mode of the absolute difference. The result is placed in operand
- 0, which is of the same mode as operand 3.
-
- 'widen_ssumM3'
- 'widen_usumM3'
- Operands 0 and 2 are of the same mode, which is wider than the mode
- of operand 1. Add operand 1 to operand 2 and place the widened
- result in operand 0. (This is used express accumulation of
- elements into an accumulator of a wider mode.)
-
- 'smulhsM3'
- 'umulhsM3'
- Signed/unsigned multiply high with scale. This is equivalent to
- the C code:
- narrow op0, op1, op2;
- ...
- op0 = (narrow) (((wide) op1 * (wide) op2) >> (N / 2 - 1));
- where the sign of 'narrow' determines whether this is a signed or
- unsigned operation, and N is the size of 'wide' in bits.
-
- 'smulhrsM3'
- 'umulhrsM3'
- Signed/unsigned multiply high with round and scale. This is
- equivalent to the C code:
- narrow op0, op1, op2;
- ...
- op0 = (narrow) (((((wide) op1 * (wide) op2) >> (N / 2 - 2)) + 1) >> 1);
- where the sign of 'narrow' determines whether this is a signed or
- unsigned operation, and N is the size of 'wide' in bits.
-
- 'sdiv_pow2M3'
- 'sdiv_pow2M3'
- Signed division by power-of-2 immediate. Equivalent to:
- signed op0, op1;
- ...
- op0 = op1 / (1 << imm);
-
- 'vec_shl_insert_M'
- Shift the elements in vector input operand 1 left one element (i.e.
- away from element 0) and fill the vacated element 0 with the scalar
- in operand 2. Store the result in vector output operand 0.
- Operands 0 and 1 have mode M and operand 2 has the mode appropriate
- for one element of M.
-
- 'vec_shl_M'
- Whole vector left shift in bits, i.e. away from element 0. Operand
- 1 is a vector to be shifted. Operand 2 is an integer shift amount
- in bits. Operand 0 is where the resulting shifted vector is
- stored. The output and input vectors should have the same modes.
-
- 'vec_shr_M'
- Whole vector right shift in bits, i.e. towards element 0. Operand
- 1 is a vector to be shifted. Operand 2 is an integer shift amount
- in bits. Operand 0 is where the resulting shifted vector is
- stored. The output and input vectors should have the same modes.
-
- 'vec_pack_trunc_M'
- Narrow (demote) and merge the elements of two vectors. Operands 1
- and 2 are vectors of the same mode having N integral or floating
- point elements of size S. Operand 0 is the resulting vector in
- which 2*N elements of size S/2 are concatenated after narrowing
- them down using truncation.
-
- 'vec_pack_sbool_trunc_M'
- Narrow and merge the elements of two vectors. Operands 1 and 2 are
- vectors of the same type having N boolean elements. Operand 0 is
- the resulting vector in which 2*N elements are concatenated. The
- last operand (operand 3) is the number of elements in the output
- vector 2*N as a 'CONST_INT'. This instruction pattern is used when
- all the vector input and output operands have the same scalar mode
- M and thus using 'vec_pack_trunc_M' would be ambiguous.
-
- 'vec_pack_ssat_M', 'vec_pack_usat_M'
- Narrow (demote) and merge the elements of two vectors. Operands 1
- and 2 are vectors of the same mode having N integral elements of
- size S. Operand 0 is the resulting vector in which the elements of
- the two input vectors are concatenated after narrowing them down
- using signed/unsigned saturating arithmetic.
-
- 'vec_pack_sfix_trunc_M', 'vec_pack_ufix_trunc_M'
- Narrow, convert to signed/unsigned integral type and merge the
- elements of two vectors. Operands 1 and 2 are vectors of the same
- mode having N floating point elements of size S. Operand 0 is the
- resulting vector in which 2*N elements of size S/2 are
- concatenated.
-
- 'vec_packs_float_M', 'vec_packu_float_M'
- Narrow, convert to floating point type and merge the elements of
- two vectors. Operands 1 and 2 are vectors of the same mode having
- N signed/unsigned integral elements of size S. Operand 0 is the
- resulting vector in which 2*N elements of size S/2 are
- concatenated.
-
- 'vec_unpacks_hi_M', 'vec_unpacks_lo_M'
- Extract and widen (promote) the high/low part of a vector of signed
- integral or floating point elements. The input vector (operand 1)
- has N elements of size S. Widen (promote) the high/low elements of
- the vector using signed or floating point extension and place the
- resulting N/2 values of size 2*S in the output vector (operand 0).
-
- 'vec_unpacku_hi_M', 'vec_unpacku_lo_M'
- Extract and widen (promote) the high/low part of a vector of
- unsigned integral elements. The input vector (operand 1) has N
- elements of size S. Widen (promote) the high/low elements of the
- vector using zero extension and place the resulting N/2 values of
- size 2*S in the output vector (operand 0).
-
- 'vec_unpacks_sbool_hi_M', 'vec_unpacks_sbool_lo_M'
- Extract the high/low part of a vector of boolean elements that have
- scalar mode M. The input vector (operand 1) has N elements, the
- output vector (operand 0) has N/2 elements. The last operand
- (operand 2) is the number of elements of the input vector N as a
- 'CONST_INT'. These patterns are used if both the input and output
- vectors have the same scalar mode M and thus using
- 'vec_unpacks_hi_M' or 'vec_unpacks_lo_M' would be ambiguous.
-
- 'vec_unpacks_float_hi_M', 'vec_unpacks_float_lo_M'
- 'vec_unpacku_float_hi_M', 'vec_unpacku_float_lo_M'
- Extract, convert to floating point type and widen the high/low part
- of a vector of signed/unsigned integral elements. The input vector
- (operand 1) has N elements of size S. Convert the high/low
- elements of the vector using floating point conversion and place
- the resulting N/2 values of size 2*S in the output vector (operand
- 0).
-
- 'vec_unpack_sfix_trunc_hi_M',
- 'vec_unpack_sfix_trunc_lo_M'
- 'vec_unpack_ufix_trunc_hi_M'
- 'vec_unpack_ufix_trunc_lo_M'
- Extract, convert to signed/unsigned integer type and widen the
- high/low part of a vector of floating point elements. The input
- vector (operand 1) has N elements of size S. Convert the high/low
- elements of the vector to integers and place the resulting N/2
- values of size 2*S in the output vector (operand 0).
-
- 'vec_widen_umult_hi_M', 'vec_widen_umult_lo_M'
- 'vec_widen_smult_hi_M', 'vec_widen_smult_lo_M'
- 'vec_widen_umult_even_M', 'vec_widen_umult_odd_M'
- 'vec_widen_smult_even_M', 'vec_widen_smult_odd_M'
- Signed/Unsigned widening multiplication. The two inputs (operands
- 1 and 2) are vectors with N signed/unsigned elements of size S.
- Multiply the high/low or even/odd elements of the two vectors, and
- put the N/2 products of size 2*S in the output vector (operand 0).
- A target shouldn't implement even/odd pattern pair if it is less
- efficient than lo/hi one.
-
- 'vec_widen_ushiftl_hi_M', 'vec_widen_ushiftl_lo_M'
- 'vec_widen_sshiftl_hi_M', 'vec_widen_sshiftl_lo_M'
- Signed/Unsigned widening shift left. The first input (operand 1)
- is a vector with N signed/unsigned elements of size S. Operand 2
- is a constant. Shift the high/low elements of operand 1, and put
- the N/2 results of size 2*S in the output vector (operand 0).
-
- 'mulhisi3'
- Multiply operands 1 and 2, which have mode 'HImode', and store a
- 'SImode' product in operand 0.
-
- 'mulqihi3', 'mulsidi3'
- Similar widening-multiplication instructions of other widths.
-
- 'umulqihi3', 'umulhisi3', 'umulsidi3'
- Similar widening-multiplication instructions that do unsigned
- multiplication.
-
- 'usmulqihi3', 'usmulhisi3', 'usmulsidi3'
- Similar widening-multiplication instructions that interpret the
- first operand as unsigned and the second operand as signed, then do
- a signed multiplication.
-
- 'smulM3_highpart'
- Perform a signed multiplication of operands 1 and 2, which have
- mode M, and store the most significant half of the product in
- operand 0. The least significant half of the product is discarded.
-
- 'umulM3_highpart'
- Similar, but the multiplication is unsigned.
-
- 'maddMN4'
- Multiply operands 1 and 2, sign-extend them to mode N, add operand
- 3, and store the result in operand 0. Operands 1 and 2 have mode M
- and operands 0 and 3 have mode N. Both modes must be integer or
- fixed-point modes and N must be twice the size of M.
-
- In other words, 'maddMN4' is like 'mulMN3' except that it also adds
- operand 3.
-
- These instructions are not allowed to 'FAIL'.
-
- 'umaddMN4'
- Like 'maddMN4', but zero-extend the multiplication operands instead
- of sign-extending them.
-
- 'ssmaddMN4'
- Like 'maddMN4', but all involved operations must be
- signed-saturating.
-
- 'usmaddMN4'
- Like 'umaddMN4', but all involved operations must be
- unsigned-saturating.
-
- 'msubMN4'
- Multiply operands 1 and 2, sign-extend them to mode N, subtract the
- result from operand 3, and store the result in operand 0. Operands
- 1 and 2 have mode M and operands 0 and 3 have mode N. Both modes
- must be integer or fixed-point modes and N must be twice the size
- of M.
-
- In other words, 'msubMN4' is like 'mulMN3' except that it also
- subtracts the result from operand 3.
-
- These instructions are not allowed to 'FAIL'.
-
- 'umsubMN4'
- Like 'msubMN4', but zero-extend the multiplication operands instead
- of sign-extending them.
-
- 'ssmsubMN4'
- Like 'msubMN4', but all involved operations must be
- signed-saturating.
-
- 'usmsubMN4'
- Like 'umsubMN4', but all involved operations must be
- unsigned-saturating.
-
- 'divmodM4'
- Signed division that produces both a quotient and a remainder.
- Operand 1 is divided by operand 2 to produce a quotient stored in
- operand 0 and a remainder stored in operand 3.
-
- For machines with an instruction that produces both a quotient and
- a remainder, provide a pattern for 'divmodM4' but do not provide
- patterns for 'divM3' and 'modM3'. This allows optimization in the
- relatively common case when both the quotient and remainder are
- computed.
-
- If an instruction that just produces a quotient or just a remainder
- exists and is more efficient than the instruction that produces
- both, write the output routine of 'divmodM4' to call
- 'find_reg_note' and look for a 'REG_UNUSED' note on the quotient or
- remainder and generate the appropriate instruction.
-
- 'udivmodM4'
- Similar, but does unsigned division.
-
- 'ashlM3', 'ssashlM3', 'usashlM3'
- Arithmetic-shift operand 1 left by a number of bits specified by
- operand 2, and store the result in operand 0. Here M is the mode
- of operand 0 and operand 1; operand 2's mode is specified by the
- instruction pattern, and the compiler will convert the operand to
- that mode before generating the instruction. The shift or rotate
- expander or instruction pattern should explicitly specify the mode
- of the operand 2, it should never be 'VOIDmode'. The meaning of
- out-of-range shift counts can optionally be specified by
- 'TARGET_SHIFT_TRUNCATION_MASK'. *Note
- TARGET_SHIFT_TRUNCATION_MASK::. Operand 2 is always a scalar type.
-
- 'ashrM3', 'lshrM3', 'rotlM3', 'rotrM3'
- Other shift and rotate instructions, analogous to the 'ashlM3'
- instructions. Operand 2 is always a scalar type.
-
- 'vashlM3', 'vashrM3', 'vlshrM3', 'vrotlM3', 'vrotrM3'
- Vector shift and rotate instructions that take vectors as operand 2
- instead of a scalar type.
-
- 'avgM3_floor'
- 'uavgM3_floor'
- Signed and unsigned average instructions. These instructions add
- operands 1 and 2 without truncation, divide the result by 2, round
- towards -Inf, and store the result in operand 0. This is
- equivalent to the C code:
- narrow op0, op1, op2;
- ...
- op0 = (narrow) (((wide) op1 + (wide) op2) >> 1);
- where the sign of 'narrow' determines whether this is a signed or
- unsigned operation.
-
- 'avgM3_ceil'
- 'uavgM3_ceil'
- Like 'avgM3_floor' and 'uavgM3_floor', but round towards +Inf.
- This is equivalent to the C code:
- narrow op0, op1, op2;
- ...
- op0 = (narrow) (((wide) op1 + (wide) op2 + 1) >> 1);
-
- 'bswapM2'
- Reverse the order of bytes of operand 1 and store the result in
- operand 0.
-
- 'negM2', 'ssnegM2', 'usnegM2'
- Negate operand 1 and store the result in operand 0.
-
- 'negvM3'
- Like 'negM2' but takes a 'code_label' as operand 2 and emits code
- to jump to it if signed overflow occurs during the negation.
-
- 'absM2'
- Store the absolute value of operand 1 into operand 0.
-
- 'sqrtM2'
- Store the square root of operand 1 into operand 0. Both operands
- have mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'rsqrtM2'
- Store the reciprocal of the square root of operand 1 into operand
- 0. Both operands have mode M, which is a scalar or vector
- floating-point mode.
-
- On most architectures this pattern is only approximate, so either
- its C condition or the 'TARGET_OPTAB_SUPPORTED_P' hook should check
- for the appropriate math flags. (Using the C condition is more
- direct, but using 'TARGET_OPTAB_SUPPORTED_P' can be useful if a
- target-specific built-in also uses the 'rsqrtM2' pattern.)
-
- This pattern is not allowed to 'FAIL'.
-
- 'fmodM3'
- Store the remainder of dividing operand 1 by operand 2 into operand
- 0, rounded towards zero to an integer. All operands have mode M,
- which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'remainderM3'
- Store the remainder of dividing operand 1 by operand 2 into operand
- 0, rounded to the nearest integer. All operands have mode M, which
- is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'scalbM3'
- Raise 'FLT_RADIX' to the power of operand 2, multiply it by operand
- 1, and store the result in operand 0. All operands have mode M,
- which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'ldexpM3'
- Raise 2 to the power of operand 2, multiply it by operand 1, and
- store the result in operand 0. Operands 0 and 1 have mode M, which
- is a scalar or vector floating-point mode. Operand 2's mode has
- the same number of elements as M and each element is wide enough to
- store an 'int'. The integers are signed.
-
- This pattern is not allowed to 'FAIL'.
-
- 'cosM2'
- Store the cosine of operand 1 into operand 0. Both operands have
- mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'sinM2'
- Store the sine of operand 1 into operand 0. Both operands have
- mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'sincosM3'
- Store the cosine of operand 2 into operand 0 and the sine of
- operand 2 into operand 1. All operands have mode M, which is a
- scalar or vector floating-point mode.
-
- Targets that can calculate the sine and cosine simultaneously can
- implement this pattern as opposed to implementing individual
- 'sinM2' and 'cosM2' patterns. The 'sin' and 'cos' built-in
- functions will then be expanded to the 'sincosM3' pattern, with one
- of the output values left unused.
-
- 'tanM2'
- Store the tangent of operand 1 into operand 0. Both operands have
- mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'asinM2'
- Store the arc sine of operand 1 into operand 0. Both operands have
- mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'acosM2'
- Store the arc cosine of operand 1 into operand 0. Both operands
- have mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'atanM2'
- Store the arc tangent of operand 1 into operand 0. Both operands
- have mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'expM2'
- Raise e (the base of natural logarithms) to the power of operand 1
- and store the result in operand 0. Both operands have mode M,
- which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'expm1M2'
- Raise e (the base of natural logarithms) to the power of operand 1,
- subtract 1, and store the result in operand 0. Both operands have
- mode M, which is a scalar or vector floating-point mode.
-
- For inputs close to zero, the pattern is expected to be more
- accurate than a separate 'expM2' and 'subM3' would be.
-
- This pattern is not allowed to 'FAIL'.
-
- 'exp10M2'
- Raise 10 to the power of operand 1 and store the result in operand
- 0. Both operands have mode M, which is a scalar or vector
- floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'exp2M2'
- Raise 2 to the power of operand 1 and store the result in operand
- 0. Both operands have mode M, which is a scalar or vector
- floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'logM2'
- Store the natural logarithm of operand 1 into operand 0. Both
- operands have mode M, which is a scalar or vector floating-point
- mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'log1pM2'
- Add 1 to operand 1, compute the natural logarithm, and store the
- result in operand 0. Both operands have mode M, which is a scalar
- or vector floating-point mode.
-
- For inputs close to zero, the pattern is expected to be more
- accurate than a separate 'addM3' and 'logM2' would be.
-
- This pattern is not allowed to 'FAIL'.
-
- 'log10M2'
- Store the base-10 logarithm of operand 1 into operand 0. Both
- operands have mode M, which is a scalar or vector floating-point
- mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'log2M2'
- Store the base-2 logarithm of operand 1 into operand 0. Both
- operands have mode M, which is a scalar or vector floating-point
- mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'logbM2'
- Store the base-'FLT_RADIX' logarithm of operand 1 into operand 0.
- Both operands have mode M, which is a scalar or vector
- floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'significandM2'
- Store the significand of floating-point operand 1 in operand 0.
- Both operands have mode M, which is a scalar or vector
- floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'powM3'
- Store the value of operand 1 raised to the exponent operand 2 into
- operand 0. All operands have mode M, which is a scalar or vector
- floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'atan2M3'
- Store the arc tangent (inverse tangent) of operand 1 divided by
- operand 2 into operand 0, using the signs of both arguments to
- determine the quadrant of the result. All operands have mode M,
- which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'floorM2'
- Store the largest integral value not greater than operand 1 in
- operand 0. Both operands have mode M, which is a scalar or vector
- floating-point mode. If '-ffp-int-builtin-inexact' is in effect,
- the "inexact" exception may be raised for noninteger operands;
- otherwise, it may not.
-
- This pattern is not allowed to 'FAIL'.
-
- 'btruncM2'
- Round operand 1 to an integer, towards zero, and store the result
- in operand 0. Both operands have mode M, which is a scalar or
- vector floating-point mode. If '-ffp-int-builtin-inexact' is in
- effect, the "inexact" exception may be raised for noninteger
- operands; otherwise, it may not.
-
- This pattern is not allowed to 'FAIL'.
-
- 'roundM2'
- Round operand 1 to the nearest integer, rounding away from zero in
- the event of a tie, and store the result in operand 0. Both
- operands have mode M, which is a scalar or vector floating-point
- mode. If '-ffp-int-builtin-inexact' is in effect, the "inexact"
- exception may be raised for noninteger operands; otherwise, it may
- not.
-
- This pattern is not allowed to 'FAIL'.
-
- 'ceilM2'
- Store the smallest integral value not less than operand 1 in
- operand 0. Both operands have mode M, which is a scalar or vector
- floating-point mode. If '-ffp-int-builtin-inexact' is in effect,
- the "inexact" exception may be raised for noninteger operands;
- otherwise, it may not.
-
- This pattern is not allowed to 'FAIL'.
-
- 'nearbyintM2'
- Round operand 1 to an integer, using the current rounding mode, and
- store the result in operand 0. Do not raise an inexact condition
- when the result is different from the argument. Both operands have
- mode M, which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'rintM2'
- Round operand 1 to an integer, using the current rounding mode, and
- store the result in operand 0. Raise an inexact condition when the
- result is different from the argument. Both operands have mode M,
- which is a scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'lrintMN2'
- Convert operand 1 (valid for floating point mode M) to fixed point
- mode N as a signed number according to the current rounding mode
- and store in operand 0 (which has mode N).
-
- 'lroundMN2'
- Convert operand 1 (valid for floating point mode M) to fixed point
- mode N as a signed number rounding to nearest and away from zero
- and store in operand 0 (which has mode N).
-
- 'lfloorMN2'
- Convert operand 1 (valid for floating point mode M) to fixed point
- mode N as a signed number rounding down and store in operand 0
- (which has mode N).
-
- 'lceilMN2'
- Convert operand 1 (valid for floating point mode M) to fixed point
- mode N as a signed number rounding up and store in operand 0 (which
- has mode N).
-
- 'copysignM3'
- Store a value with the magnitude of operand 1 and the sign of
- operand 2 into operand 0. All operands have mode M, which is a
- scalar or vector floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'xorsignM3'
- Equivalent to 'op0 = op1 * copysign (1.0, op2)': store a value with
- the magnitude of operand 1 and the sign of operand 2 into operand
- 0. All operands have mode M, which is a scalar or vector
- floating-point mode.
-
- This pattern is not allowed to 'FAIL'.
-
- 'ffsM2'
- Store into operand 0 one plus the index of the least significant
- 1-bit of operand 1. If operand 1 is zero, store zero.
-
- M is either a scalar or vector integer mode. When it is a scalar,
- operand 1 has mode M but operand 0 can have whatever scalar integer
- mode is suitable for the target. The compiler will insert
- conversion instructions as necessary (typically to convert the
- result to the same width as 'int'). When M is a vector, both
- operands must have mode M.
-
- This pattern is not allowed to 'FAIL'.
-
- 'clrsbM2'
- Count leading redundant sign bits. Store into operand 0 the number
- of redundant sign bits in operand 1, starting at the most
- significant bit position. A redundant sign bit is defined as any
- sign bit after the first. As such, this count will be one less
- than the count of leading sign bits.
-
- M is either a scalar or vector integer mode. When it is a scalar,
- operand 1 has mode M but operand 0 can have whatever scalar integer
- mode is suitable for the target. The compiler will insert
- conversion instructions as necessary (typically to convert the
- result to the same width as 'int'). When M is a vector, both
- operands must have mode M.
-
- This pattern is not allowed to 'FAIL'.
-
- 'clzM2'
- Store into operand 0 the number of leading 0-bits in operand 1,
- starting at the most significant bit position. If operand 1 is 0,
- the 'CLZ_DEFINED_VALUE_AT_ZERO' (*note Misc::) macro defines if the
- result is undefined or has a useful value.
-
- M is either a scalar or vector integer mode. When it is a scalar,
- operand 1 has mode M but operand 0 can have whatever scalar integer
- mode is suitable for the target. The compiler will insert
- conversion instructions as necessary (typically to convert the
- result to the same width as 'int'). When M is a vector, both
- operands must have mode M.
-
- This pattern is not allowed to 'FAIL'.
-
- 'ctzM2'
- Store into operand 0 the number of trailing 0-bits in operand 1,
- starting at the least significant bit position. If operand 1 is 0,
- the 'CTZ_DEFINED_VALUE_AT_ZERO' (*note Misc::) macro defines if the
- result is undefined or has a useful value.
-
- M is either a scalar or vector integer mode. When it is a scalar,
- operand 1 has mode M but operand 0 can have whatever scalar integer
- mode is suitable for the target. The compiler will insert
- conversion instructions as necessary (typically to convert the
- result to the same width as 'int'). When M is a vector, both
- operands must have mode M.
-
- This pattern is not allowed to 'FAIL'.
-
- 'popcountM2'
- Store into operand 0 the number of 1-bits in operand 1.
-
- M is either a scalar or vector integer mode. When it is a scalar,
- operand 1 has mode M but operand 0 can have whatever scalar integer
- mode is suitable for the target. The compiler will insert
- conversion instructions as necessary (typically to convert the
- result to the same width as 'int'). When M is a vector, both
- operands must have mode M.
-
- This pattern is not allowed to 'FAIL'.
-
- 'parityM2'
- Store into operand 0 the parity of operand 1, i.e. the number of
- 1-bits in operand 1 modulo 2.
-
- M is either a scalar or vector integer mode. When it is a scalar,
- operand 1 has mode M but operand 0 can have whatever scalar integer
- mode is suitable for the target. The compiler will insert
- conversion instructions as necessary (typically to convert the
- result to the same width as 'int'). When M is a vector, both
- operands must have mode M.
-
- This pattern is not allowed to 'FAIL'.
-
- 'one_cmplM2'
- Store the bitwise-complement of operand 1 into operand 0.
-
- 'cpymemM'
- Block copy instruction. The destination and source blocks of
- memory are the first two operands, and both are 'mem:BLK's with an
- address in mode 'Pmode'.
-
- The number of bytes to copy is the third operand, in mode M.
- Usually, you specify 'Pmode' for M. However, if you can generate
- better code knowing the range of valid lengths is smaller than
- those representable in a full Pmode pointer, you should provide a
- pattern with a mode corresponding to the range of values you can
- handle efficiently (e.g., 'QImode' for values in the range 0-127;
- note we avoid numbers that appear negative) and also a pattern with
- 'Pmode'.
-
- The fourth operand is the known shared alignment of the source and
- destination, in the form of a 'const_int' rtx. Thus, if the
- compiler knows that both source and destination are word-aligned,
- it may provide the value 4 for this operand.
-
- Optional operands 5 and 6 specify expected alignment and size of
- block respectively. The expected alignment differs from alignment
- in operand 4 in a way that the blocks are not required to be
- aligned according to it in all cases. This expected alignment is
- also in bytes, just like operand 4. Expected size, when unknown,
- is set to '(const_int -1)'.
-
- Descriptions of multiple 'cpymemM' patterns can only be beneficial
- if the patterns for smaller modes have fewer restrictions on their
- first, second and fourth operands. Note that the mode M in
- 'cpymemM' does not impose any restriction on the mode of
- individually copied data units in the block.
-
- The 'cpymemM' patterns need not give special consideration to the
- possibility that the source and destination strings might overlap.
- These patterns are used to do inline expansion of
- '__builtin_memcpy'.
-
- 'movmemM'
- Block move instruction. The destination and source blocks of
- memory are the first two operands, and both are 'mem:BLK's with an
- address in mode 'Pmode'.
-
- The number of bytes to copy is the third operand, in mode M.
- Usually, you specify 'Pmode' for M. However, if you can generate
- better code knowing the range of valid lengths is smaller than
- those representable in a full Pmode pointer, you should provide a
- pattern with a mode corresponding to the range of values you can
- handle efficiently (e.g., 'QImode' for values in the range 0-127;
- note we avoid numbers that appear negative) and also a pattern with
- 'Pmode'.
-
- The fourth operand is the known shared alignment of the source and
- destination, in the form of a 'const_int' rtx. Thus, if the
- compiler knows that both source and destination are word-aligned,
- it may provide the value 4 for this operand.
-
- Optional operands 5 and 6 specify expected alignment and size of
- block respectively. The expected alignment differs from alignment
- in operand 4 in a way that the blocks are not required to be
- aligned according to it in all cases. This expected alignment is
- also in bytes, just like operand 4. Expected size, when unknown,
- is set to '(const_int -1)'.
-
- Descriptions of multiple 'movmemM' patterns can only be beneficial
- if the patterns for smaller modes have fewer restrictions on their
- first, second and fourth operands. Note that the mode M in
- 'movmemM' does not impose any restriction on the mode of
- individually copied data units in the block.
-
- The 'movmemM' patterns must correctly handle the case where the
- source and destination strings overlap. These patterns are used to
- do inline expansion of '__builtin_memmove'.
-
- 'movstr'
- String copy instruction, with 'stpcpy' semantics. Operand 0 is an
- output operand in mode 'Pmode'. The addresses of the destination
- and source strings are operands 1 and 2, and both are 'mem:BLK's
- with addresses in mode 'Pmode'. The execution of the expansion of
- this pattern should store in operand 0 the address in which the
- 'NUL' terminator was stored in the destination string.
-
- This pattern has also several optional operands that are same as in
- 'setmem'.
-
- 'setmemM'
- Block set instruction. The destination string is the first
- operand, given as a 'mem:BLK' whose address is in mode 'Pmode'.
- The number of bytes to set is the second operand, in mode M. The
- value to initialize the memory with is the third operand. Targets
- that only support the clearing of memory should reject any value
- that is not the constant 0. See 'cpymemM' for a discussion of the
- choice of mode.
-
- The fourth operand is the known alignment of the destination, in
- the form of a 'const_int' rtx. Thus, if the compiler knows that
- the destination is word-aligned, it may provide the value 4 for
- this operand.
-
- Optional operands 5 and 6 specify expected alignment and size of
- block respectively. The expected alignment differs from alignment
- in operand 4 in a way that the blocks are not required to be
- aligned according to it in all cases. This expected alignment is
- also in bytes, just like operand 4. Expected size, when unknown,
- is set to '(const_int -1)'. Operand 7 is the minimal size of the
- block and operand 8 is the maximal size of the block (NULL if it
- cannot be represented as CONST_INT). Operand 9 is the probable
- maximal size (i.e. we cannot rely on it for correctness, but it can
- be used for choosing proper code sequence for a given size).
-
- The use for multiple 'setmemM' is as for 'cpymemM'.
-
- 'cmpstrnM'
- String compare instruction, with five operands. Operand 0 is the
- output; it has mode M. The remaining four operands are like the
- operands of 'cpymemM'. The two memory blocks specified are
- compared byte by byte in lexicographic order starting at the
- beginning of each string. The instruction is not allowed to
- prefetch more than one byte at a time since either string may end
- in the first byte and reading past that may access an invalid page
- or segment and cause a fault. The comparison terminates early if
- the fetched bytes are different or if they are equal to zero. The
- effect of the instruction is to store a value in operand 0 whose
- sign indicates the result of the comparison.
-
- 'cmpstrM'
- String compare instruction, without known maximum length. Operand
- 0 is the output; it has mode M. The second and third operand are
- the blocks of memory to be compared; both are 'mem:BLK' with an
- address in mode 'Pmode'.
-
- The fourth operand is the known shared alignment of the source and
- destination, in the form of a 'const_int' rtx. Thus, if the
- compiler knows that both source and destination are word-aligned,
- it may provide the value 4 for this operand.
-
- The two memory blocks specified are compared byte by byte in
- lexicographic order starting at the beginning of each string. The
- instruction is not allowed to prefetch more than one byte at a time
- since either string may end in the first byte and reading past that
- may access an invalid page or segment and cause a fault. The
- comparison will terminate when the fetched bytes are different or
- if they are equal to zero. The effect of the instruction is to
- store a value in operand 0 whose sign indicates the result of the
- comparison.
-
- 'cmpmemM'
- Block compare instruction, with five operands like the operands of
- 'cmpstrM'. The two memory blocks specified are compared byte by
- byte in lexicographic order starting at the beginning of each
- block. Unlike 'cmpstrM' the instruction can prefetch any bytes in
- the two memory blocks. Also unlike 'cmpstrM' the comparison will
- not stop if both bytes are zero. The effect of the instruction is
- to store a value in operand 0 whose sign indicates the result of
- the comparison.
-
- 'strlenM'
- Compute the length of a string, with three operands. Operand 0 is
- the result (of mode M), operand 1 is a 'mem' referring to the first
- character of the string, operand 2 is the character to search for
- (normally zero), and operand 3 is a constant describing the known
- alignment of the beginning of the string.
-
- 'floatMN2'
- Convert signed integer operand 1 (valid for fixed point mode M) to
- floating point mode N and store in operand 0 (which has mode N).
-
- 'floatunsMN2'
- Convert unsigned integer operand 1 (valid for fixed point mode M)
- to floating point mode N and store in operand 0 (which has mode N).
-
- 'fixMN2'
- Convert operand 1 (valid for floating point mode M) to fixed point
- mode N as a signed number and store in operand 0 (which has mode
- N). This instruction's result is defined only when the value of
- operand 1 is an integer.
-
- If the machine description defines this pattern, it also needs to
- define the 'ftrunc' pattern.
-
- 'fixunsMN2'
- Convert operand 1 (valid for floating point mode M) to fixed point
- mode N as an unsigned number and store in operand 0 (which has mode
- N). This instruction's result is defined only when the value of
- operand 1 is an integer.
-
- 'ftruncM2'
- Convert operand 1 (valid for floating point mode M) to an integer
- value, still represented in floating point mode M, and store it in
- operand 0 (valid for floating point mode M).
-
- 'fix_truncMN2'
- Like 'fixMN2' but works for any floating point value of mode M by
- converting the value to an integer.
-
- 'fixuns_truncMN2'
- Like 'fixunsMN2' but works for any floating point value of mode M
- by converting the value to an integer.
-
- 'truncMN2'
- Truncate operand 1 (valid for mode M) to mode N and store in
- operand 0 (which has mode N). Both modes must be fixed point or
- both floating point.
-
- 'extendMN2'
- Sign-extend operand 1 (valid for mode M) to mode N and store in
- operand 0 (which has mode N). Both modes must be fixed point or
- both floating point.
-
- 'zero_extendMN2'
- Zero-extend operand 1 (valid for mode M) to mode N and store in
- operand 0 (which has mode N). Both modes must be fixed point.
-
- 'fractMN2'
- Convert operand 1 of mode M to mode N and store in operand 0 (which
- has mode N). Mode M and mode N could be fixed-point to
- fixed-point, signed integer to fixed-point, fixed-point to signed
- integer, floating-point to fixed-point, or fixed-point to
- floating-point. When overflows or underflows happen, the results
- are undefined.
-
- 'satfractMN2'
- Convert operand 1 of mode M to mode N and store in operand 0 (which
- has mode N). Mode M and mode N could be fixed-point to
- fixed-point, signed integer to fixed-point, or floating-point to
- fixed-point. When overflows or underflows happen, the instruction
- saturates the results to the maximum or the minimum.
-
- 'fractunsMN2'
- Convert operand 1 of mode M to mode N and store in operand 0 (which
- has mode N). Mode M and mode N could be unsigned integer to
- fixed-point, or fixed-point to unsigned integer. When overflows or
- underflows happen, the results are undefined.
-
- 'satfractunsMN2'
- Convert unsigned integer operand 1 of mode M to fixed-point mode N
- and store in operand 0 (which has mode N). When overflows or
- underflows happen, the instruction saturates the results to the
- maximum or the minimum.
-
- 'extvM'
- Extract a bit-field from register operand 1, sign-extend it, and
- store it in operand 0. Operand 2 specifies the width of the field
- in bits and operand 3 the starting bit, which counts from the most
- significant bit if 'BITS_BIG_ENDIAN' is true and from the least
- significant bit otherwise.
-
- Operands 0 and 1 both have mode M. Operands 2 and 3 have a
- target-specific mode.
-
- 'extvmisalignM'
- Extract a bit-field from memory operand 1, sign extend it, and
- store it in operand 0. Operand 2 specifies the width in bits and
- operand 3 the starting bit. The starting bit is always somewhere
- in the first byte of operand 1; it counts from the most significant
- bit if 'BITS_BIG_ENDIAN' is true and from the least significant bit
- otherwise.
-
- Operand 0 has mode M while operand 1 has 'BLK' mode. Operands 2
- and 3 have a target-specific mode.
-
- The instruction must not read beyond the last byte of the
- bit-field.
-
- 'extzvM'
- Like 'extvM' except that the bit-field value is zero-extended.
-
- 'extzvmisalignM'
- Like 'extvmisalignM' except that the bit-field value is
- zero-extended.
-
- 'insvM'
- Insert operand 3 into a bit-field of register operand 0. Operand 1
- specifies the width of the field in bits and operand 2 the starting
- bit, which counts from the most significant bit if
- 'BITS_BIG_ENDIAN' is true and from the least significant bit
- otherwise.
-
- Operands 0 and 3 both have mode M. Operands 1 and 2 have a
- target-specific mode.
-
- 'insvmisalignM'
- Insert operand 3 into a bit-field of memory operand 0. Operand 1
- specifies the width of the field in bits and operand 2 the starting
- bit. The starting bit is always somewhere in the first byte of
- operand 0; it counts from the most significant bit if
- 'BITS_BIG_ENDIAN' is true and from the least significant bit
- otherwise.
-
- Operand 3 has mode M while operand 0 has 'BLK' mode. Operands 1
- and 2 have a target-specific mode.
-
- The instruction must not read or write beyond the last byte of the
- bit-field.
-
- 'extv'
- Extract a bit-field from operand 1 (a register or memory operand),
- where operand 2 specifies the width in bits and operand 3 the
- starting bit, and store it in operand 0. Operand 0 must have mode
- 'word_mode'. Operand 1 may have mode 'byte_mode' or 'word_mode';
- often 'word_mode' is allowed only for registers. Operands 2 and 3
- must be valid for 'word_mode'.
-
- The RTL generation pass generates this instruction only with
- constants for operands 2 and 3 and the constant is never zero for
- operand 2.
-
- The bit-field value is sign-extended to a full word integer before
- it is stored in operand 0.
-
- This pattern is deprecated; please use 'extvM' and 'extvmisalignM'
- instead.
-
- 'extzv'
- Like 'extv' except that the bit-field value is zero-extended.
-
- This pattern is deprecated; please use 'extzvM' and
- 'extzvmisalignM' instead.
-
- 'insv'
- Store operand 3 (which must be valid for 'word_mode') into a
- bit-field in operand 0, where operand 1 specifies the width in bits
- and operand 2 the starting bit. Operand 0 may have mode
- 'byte_mode' or 'word_mode'; often 'word_mode' is allowed only for
- registers. Operands 1 and 2 must be valid for 'word_mode'.
-
- The RTL generation pass generates this instruction only with
- constants for operands 1 and 2 and the constant is never zero for
- operand 1.
-
- This pattern is deprecated; please use 'insvM' and 'insvmisalignM'
- instead.
-
- 'movMODEcc'
- Conditionally move operand 2 or operand 3 into operand 0 according
- to the comparison in operand 1. If the comparison is true, operand
- 2 is moved into operand 0, otherwise operand 3 is moved.
-
- The mode of the operands being compared need not be the same as the
- operands being moved. Some machines, sparc64 for example, have
- instructions that conditionally move an integer value based on the
- floating point condition codes and vice versa.
-
- If the machine does not have conditional move instructions, do not
- define these patterns.
-
- 'addMODEcc'
- Similar to 'movMODEcc' but for conditional addition. Conditionally
- move operand 2 or (operands 2 + operand 3) into operand 0 according
- to the comparison in operand 1. If the comparison is false,
- operand 2 is moved into operand 0, otherwise (operand 2 + operand
- 3) is moved.
-
- 'cond_addMODE'
- 'cond_subMODE'
- 'cond_mulMODE'
- 'cond_divMODE'
- 'cond_udivMODE'
- 'cond_modMODE'
- 'cond_umodMODE'
- 'cond_andMODE'
- 'cond_iorMODE'
- 'cond_xorMODE'
- 'cond_sminMODE'
- 'cond_smaxMODE'
- 'cond_uminMODE'
- 'cond_umaxMODE'
- When operand 1 is true, perform an operation on operands 2 and 3
- and store the result in operand 0, otherwise store operand 4 in
- operand 0. The operation works elementwise if the operands are
- vectors.
-
- The scalar case is equivalent to:
-
- op0 = op1 ? op2 OP op3 : op4;
-
- while the vector case is equivalent to:
-
- for (i = 0; i < GET_MODE_NUNITS (M); i++)
- op0[i] = op1[i] ? op2[i] OP op3[i] : op4[i];
-
- where, for example, OP is '+' for 'cond_addMODE'.
-
- When defined for floating-point modes, the contents of 'op3[i]' are
- not interpreted if 'op1[i]' is false, just like they would not be
- in a normal C '?:' condition.
-
- Operands 0, 2, 3 and 4 all have mode M. Operand 1 is a scalar
- integer if M is scalar, otherwise it has the mode returned by
- 'TARGET_VECTORIZE_GET_MASK_MODE'.
-
- 'cond_fmaMODE'
- 'cond_fmsMODE'
- 'cond_fnmaMODE'
- 'cond_fnmsMODE'
- Like 'cond_addM', except that the conditional operation takes 3
- operands rather than two. For example, the vector form of
- 'cond_fmaMODE' is equivalent to:
-
- for (i = 0; i < GET_MODE_NUNITS (M); i++)
- op0[i] = op1[i] ? fma (op2[i], op3[i], op4[i]) : op5[i];
-
- 'negMODEcc'
- Similar to 'movMODEcc' but for conditional negation. Conditionally
- move the negation of operand 2 or the unchanged operand 3 into
- operand 0 according to the comparison in operand 1. If the
- comparison is true, the negation of operand 2 is moved into operand
- 0, otherwise operand 3 is moved.
-
- 'notMODEcc'
- Similar to 'negMODEcc' but for conditional complement.
- Conditionally move the bitwise complement of operand 2 or the
- unchanged operand 3 into operand 0 according to the comparison in
- operand 1. If the comparison is true, the complement of operand 2
- is moved into operand 0, otherwise operand 3 is moved.
-
- 'cstoreMODE4'
- Store zero or nonzero in operand 0 according to whether a
- comparison is true. Operand 1 is a comparison operator. Operand 2
- and operand 3 are the first and second operand of the comparison,
- respectively. You specify the mode that operand 0 must have when
- you write the 'match_operand' expression. The compiler
- automatically sees which mode you have used and supplies an operand
- of that mode.
-
- The value stored for a true condition must have 1 as its low bit,
- or else must be negative. Otherwise the instruction is not
- suitable and you should omit it from the machine description. You
- describe to the compiler exactly which value is stored by defining
- the macro 'STORE_FLAG_VALUE' (*note Misc::). If a description
- cannot be found that can be used for all the possible comparison
- operators, you should pick one and use a 'define_expand' to map all
- results onto the one you chose.
-
- These operations may 'FAIL', but should do so only in relatively
- uncommon cases; if they would 'FAIL' for common cases involving
- integer comparisons, it is best to restrict the predicates to not
- allow these operands. Likewise if a given comparison operator will
- always fail, independent of the operands (for floating-point modes,
- the 'ordered_comparison_operator' predicate is often useful in this
- case).
-
- If this pattern is omitted, the compiler will generate a
- conditional branch--for example, it may copy a constant one to the
- target and branching around an assignment of zero to the target--or
- a libcall. If the predicate for operand 1 only rejects some
- operators, it will also try reordering the operands and/or
- inverting the result value (e.g. by an exclusive OR). These
- possibilities could be cheaper or equivalent to the instructions
- used for the 'cstoreMODE4' pattern followed by those required to
- convert a positive result from 'STORE_FLAG_VALUE' to 1; in this
- case, you can and should make operand 1's predicate reject some
- operators in the 'cstoreMODE4' pattern, or remove the pattern
- altogether from the machine description.
-
- 'cbranchMODE4'
- Conditional branch instruction combined with a compare instruction.
- Operand 0 is a comparison operator. Operand 1 and operand 2 are
- the first and second operands of the comparison, respectively.
- Operand 3 is the 'code_label' to jump to.
-
- 'jump'
- A jump inside a function; an unconditional branch. Operand 0 is
- the 'code_label' to jump to. This pattern name is mandatory on all
- machines.
-
- 'call'
- Subroutine call instruction returning no value. Operand 0 is the
- function to call; operand 1 is the number of bytes of arguments
- pushed as a 'const_int'; operand 2 is the number of registers used
- as operands.
-
- On most machines, operand 2 is not actually stored into the RTL
- pattern. It is supplied for the sake of some RISC machines which
- need to put this information into the assembler code; they can put
- it in the RTL instead of operand 1.
-
- Operand 0 should be a 'mem' RTX whose address is the address of the
- function. Note, however, that this address can be a 'symbol_ref'
- expression even if it would not be a legitimate memory address on
- the target machine. If it is also not a valid argument for a call
- instruction, the pattern for this operation should be a
- 'define_expand' (*note Expander Definitions::) that places the
- address into a register and uses that register in the call
- instruction.
-
- 'call_value'
- Subroutine call instruction returning a value. Operand 0 is the
- hard register in which the value is returned. There are three more
- operands, the same as the three operands of the 'call' instruction
- (but with numbers increased by one).
-
- Subroutines that return 'BLKmode' objects use the 'call' insn.
-
- 'call_pop', 'call_value_pop'
- Similar to 'call' and 'call_value', except used if defined and if
- 'RETURN_POPS_ARGS' is nonzero. They should emit a 'parallel' that
- contains both the function call and a 'set' to indicate the
- adjustment made to the frame pointer.
-
- For machines where 'RETURN_POPS_ARGS' can be nonzero, the use of
- these patterns increases the number of functions for which the
- frame pointer can be eliminated, if desired.
-
- 'untyped_call'
- Subroutine call instruction returning a value of any type. Operand
- 0 is the function to call; operand 1 is a memory location where the
- result of calling the function is to be stored; operand 2 is a
- 'parallel' expression where each element is a 'set' expression that
- indicates the saving of a function return value into the result
- block.
-
- This instruction pattern should be defined to support
- '__builtin_apply' on machines where special instructions are needed
- to call a subroutine with arbitrary arguments or to save the value
- returned. This instruction pattern is required on machines that
- have multiple registers that can hold a return value (i.e.
- 'FUNCTION_VALUE_REGNO_P' is true for more than one register).
-
- 'return'
- Subroutine return instruction. This instruction pattern name
- should be defined only if a single instruction can do all the work
- of returning from a function.
-
- Like the 'movM' patterns, this pattern is also used after the RTL
- generation phase. In this case it is to support machines where
- multiple instructions are usually needed to return from a function,
- but some class of functions only requires one instruction to
- implement a return. Normally, the applicable functions are those
- which do not need to save any registers or allocate stack space.
-
- It is valid for this pattern to expand to an instruction using
- 'simple_return' if no epilogue is required.
-
- 'simple_return'
- Subroutine return instruction. This instruction pattern name
- should be defined only if a single instruction can do all the work
- of returning from a function on a path where no epilogue is
- required. This pattern is very similar to the 'return' instruction
- pattern, but it is emitted only by the shrink-wrapping optimization
- on paths where the function prologue has not been executed, and a
- function return should occur without any of the effects of the
- epilogue. Additional uses may be introduced on paths where both
- the prologue and the epilogue have executed.
-
- For such machines, the condition specified in this pattern should
- only be true when 'reload_completed' is nonzero and the function's
- epilogue would only be a single instruction. For machines with
- register windows, the routine 'leaf_function_p' may be used to
- determine if a register window push is required.
-
- Machines that have conditional return instructions should define
- patterns such as
-
- (define_insn ""
- [(set (pc)
- (if_then_else (match_operator
- 0 "comparison_operator"
- [(cc0) (const_int 0)])
- (return)
- (pc)))]
- "CONDITION"
- "...")
-
- where CONDITION would normally be the same condition specified on
- the named 'return' pattern.
-
- 'untyped_return'
- Untyped subroutine return instruction. This instruction pattern
- should be defined to support '__builtin_return' on machines where
- special instructions are needed to return a value of any type.
-
- Operand 0 is a memory location where the result of calling a
- function with '__builtin_apply' is stored; operand 1 is a
- 'parallel' expression where each element is a 'set' expression that
- indicates the restoring of a function return value from the result
- block.
-
- 'nop'
- No-op instruction. This instruction pattern name should always be
- defined to output a no-op in assembler code. '(const_int 0)' will
- do as an RTL pattern.
-
- 'indirect_jump'
- An instruction to jump to an address which is operand zero. This
- pattern name is mandatory on all machines.
-
- 'casesi'
- Instruction to jump through a dispatch table, including bounds
- checking. This instruction takes five operands:
-
- 1. The index to dispatch on, which has mode 'SImode'.
-
- 2. The lower bound for indices in the table, an integer constant.
-
- 3. The total range of indices in the table--the largest index
- minus the smallest one (both inclusive).
-
- 4. A label that precedes the table itself.
-
- 5. A label to jump to if the index has a value outside the
- bounds.
-
- The table is an 'addr_vec' or 'addr_diff_vec' inside of a
- 'jump_table_data'. The number of elements in the table is one plus
- the difference between the upper bound and the lower bound.
-
- 'tablejump'
- Instruction to jump to a variable address. This is a low-level
- capability which can be used to implement a dispatch table when
- there is no 'casesi' pattern.
-
- This pattern requires two operands: the address or offset, and a
- label which should immediately precede the jump table. If the
- macro 'CASE_VECTOR_PC_RELATIVE' evaluates to a nonzero value then
- the first operand is an offset which counts from the address of the
- table; otherwise, it is an absolute address to jump to. In either
- case, the first operand has mode 'Pmode'.
-
- The 'tablejump' insn is always the last insn before the jump table
- it uses. Its assembler code normally has no need to use the second
- operand, but you should incorporate it in the RTL pattern so that
- the jump optimizer will not delete the table as unreachable code.
-
- 'doloop_end'
- Conditional branch instruction that decrements a register and jumps
- if the register is nonzero. Operand 0 is the register to decrement
- and test; operand 1 is the label to jump to if the register is
- nonzero. *Note Looping Patterns::.
-
- This optional instruction pattern should be defined for machines
- with low-overhead looping instructions as the loop optimizer will
- try to modify suitable loops to utilize it. The target hook
- 'TARGET_CAN_USE_DOLOOP_P' controls the conditions under which
- low-overhead loops can be used.
-
- 'doloop_begin'
- Companion instruction to 'doloop_end' required for machines that
- need to perform some initialization, such as loading a special
- counter register. Operand 1 is the associated 'doloop_end' pattern
- and operand 0 is the register that it decrements.
-
- If initialization insns do not always need to be emitted, use a
- 'define_expand' (*note Expander Definitions::) and make it fail.
-
- 'canonicalize_funcptr_for_compare'
- Canonicalize the function pointer in operand 1 and store the result
- into operand 0.
-
- Operand 0 is always a 'reg' and has mode 'Pmode'; operand 1 may be
- a 'reg', 'mem', 'symbol_ref', 'const_int', etc and also has mode
- 'Pmode'.
-
- Canonicalization of a function pointer usually involves computing
- the address of the function which would be called if the function
- pointer were used in an indirect call.
-
- Only define this pattern if function pointers on the target machine
- can have different values but still call the same function when
- used in an indirect call.
-
- 'save_stack_block'
- 'save_stack_function'
- 'save_stack_nonlocal'
- 'restore_stack_block'
- 'restore_stack_function'
- 'restore_stack_nonlocal'
- Most machines save and restore the stack pointer by copying it to
- or from an object of mode 'Pmode'. Do not define these patterns on
- such machines.
-
- Some machines require special handling for stack pointer saves and
- restores. On those machines, define the patterns corresponding to
- the non-standard cases by using a 'define_expand' (*note Expander
- Definitions::) that produces the required insns. The three types
- of saves and restores are:
-
- 1. 'save_stack_block' saves the stack pointer at the start of a
- block that allocates a variable-sized object, and
- 'restore_stack_block' restores the stack pointer when the
- block is exited.
-
- 2. 'save_stack_function' and 'restore_stack_function' do a
- similar job for the outermost block of a function and are used
- when the function allocates variable-sized objects or calls
- 'alloca'. Only the epilogue uses the restored stack pointer,
- allowing a simpler save or restore sequence on some machines.
-
- 3. 'save_stack_nonlocal' is used in functions that contain labels
- branched to by nested functions. It saves the stack pointer
- in such a way that the inner function can use
- 'restore_stack_nonlocal' to restore the stack pointer. The
- compiler generates code to restore the frame and argument
- pointer registers, but some machines require saving and
- restoring additional data such as register window information
- or stack backchains. Place insns in these patterns to save
- and restore any such required data.
-
- When saving the stack pointer, operand 0 is the save area and
- operand 1 is the stack pointer. The mode used to allocate the save
- area defaults to 'Pmode' but you can override that choice by
- defining the 'STACK_SAVEAREA_MODE' macro (*note Storage Layout::).
- You must specify an integral mode, or 'VOIDmode' if no save area is
- needed for a particular type of save (either because no save is
- needed or because a machine-specific save area can be used).
- Operand 0 is the stack pointer and operand 1 is the save area for
- restore operations. If 'save_stack_block' is defined, operand 0
- must not be 'VOIDmode' since these saves can be arbitrarily nested.
-
- A save area is a 'mem' that is at a constant offset from
- 'virtual_stack_vars_rtx' when the stack pointer is saved for use by
- nonlocal gotos and a 'reg' in the other two cases.
-
- 'allocate_stack'
- Subtract (or add if 'STACK_GROWS_DOWNWARD' is undefined) operand 1
- from the stack pointer to create space for dynamically allocated
- data.
-
- Store the resultant pointer to this space into operand 0. If you
- are allocating space from the main stack, do this by emitting a
- move insn to copy 'virtual_stack_dynamic_rtx' to operand 0. If you
- are allocating the space elsewhere, generate code to copy the
- location of the space to operand 0. In the latter case, you must
- ensure this space gets freed when the corresponding space on the
- main stack is free.
-
- Do not define this pattern if all that must be done is the
- subtraction. Some machines require other operations such as stack
- probes or maintaining the back chain. Define this pattern to emit
- those operations in addition to updating the stack pointer.
-
- 'check_stack'
- If stack checking (*note Stack Checking::) cannot be done on your
- system by probing the stack, define this pattern to perform the
- needed check and signal an error if the stack has overflowed. The
- single operand is the address in the stack farthest from the
- current stack pointer that you need to validate. Normally, on
- platforms where this pattern is needed, you would obtain the stack
- limit from a global or thread-specific variable or register.
-
- 'probe_stack_address'
- If stack checking (*note Stack Checking::) can be done on your
- system by probing the stack but without the need to actually access
- it, define this pattern and signal an error if the stack has
- overflowed. The single operand is the memory address in the stack
- that needs to be probed.
-
- 'probe_stack'
- If stack checking (*note Stack Checking::) can be done on your
- system by probing the stack but doing it with a "store zero"
- instruction is not valid or optimal, define this pattern to do the
- probing differently and signal an error if the stack has
- overflowed. The single operand is the memory reference in the
- stack that needs to be probed.
-
- 'nonlocal_goto'
- Emit code to generate a non-local goto, e.g., a jump from one
- function to a label in an outer function. This pattern has four
- arguments, each representing a value to be used in the jump. The
- first argument is to be loaded into the frame pointer, the second
- is the address to branch to (code to dispatch to the actual label),
- the third is the address of a location where the stack is saved,
- and the last is the address of the label, to be placed in the
- location for the incoming static chain.
-
- On most machines you need not define this pattern, since GCC will
- already generate the correct code, which is to load the frame
- pointer and static chain, restore the stack (using the
- 'restore_stack_nonlocal' pattern, if defined), and jump indirectly
- to the dispatcher. You need only define this pattern if this code
- will not work on your machine.
-
- 'nonlocal_goto_receiver'
- This pattern, if defined, contains code needed at the target of a
- nonlocal goto after the code already generated by GCC. You will
- not normally need to define this pattern. A typical reason why you
- might need this pattern is if some value, such as a pointer to a
- global table, must be restored when the frame pointer is restored.
- Note that a nonlocal goto only occurs within a unit-of-translation,
- so a global table pointer that is shared by all functions of a
- given module need not be restored. There are no arguments.
-
- 'exception_receiver'
- This pattern, if defined, contains code needed at the site of an
- exception handler that isn't needed at the site of a nonlocal goto.
- You will not normally need to define this pattern. A typical
- reason why you might need this pattern is if some value, such as a
- pointer to a global table, must be restored after control flow is
- branched to the handler of an exception. There are no arguments.
-
- 'builtin_setjmp_setup'
- This pattern, if defined, contains additional code needed to
- initialize the 'jmp_buf'. You will not normally need to define
- this pattern. A typical reason why you might need this pattern is
- if some value, such as a pointer to a global table, must be
- restored. Though it is preferred that the pointer value be
- recalculated if possible (given the address of a label for
- instance). The single argument is a pointer to the 'jmp_buf'.
- Note that the buffer is five words long and that the first three
- are normally used by the generic mechanism.
-
- 'builtin_setjmp_receiver'
- This pattern, if defined, contains code needed at the site of a
- built-in setjmp that isn't needed at the site of a nonlocal goto.
- You will not normally need to define this pattern. A typical
- reason why you might need this pattern is if some value, such as a
- pointer to a global table, must be restored. It takes one
- argument, which is the label to which builtin_longjmp transferred
- control; this pattern may be emitted at a small offset from that
- label.
-
- 'builtin_longjmp'
- This pattern, if defined, performs the entire action of the
- longjmp. You will not normally need to define this pattern unless
- you also define 'builtin_setjmp_setup'. The single argument is a
- pointer to the 'jmp_buf'.
-
- 'eh_return'
- This pattern, if defined, affects the way '__builtin_eh_return',
- and thence the call frame exception handling library routines, are
- built. It is intended to handle non-trivial actions needed along
- the abnormal return path.
-
- The address of the exception handler to which the function should
- return is passed as operand to this pattern. It will normally need
- to copied by the pattern to some special register or memory
- location. If the pattern needs to determine the location of the
- target call frame in order to do so, it may use
- 'EH_RETURN_STACKADJ_RTX', if defined; it will have already been
- assigned.
-
- If this pattern is not defined, the default action will be to
- simply copy the return address to 'EH_RETURN_HANDLER_RTX'. Either
- that macro or this pattern needs to be defined if call frame
- exception handling is to be used.
-
- 'prologue'
- This pattern, if defined, emits RTL for entry to a function. The
- function entry is responsible for setting up the stack frame,
- initializing the frame pointer register, saving callee saved
- registers, etc.
-
- Using a prologue pattern is generally preferred over defining
- 'TARGET_ASM_FUNCTION_PROLOGUE' to emit assembly code for the
- prologue.
-
- The 'prologue' pattern is particularly useful for targets which
- perform instruction scheduling.
-
- 'window_save'
- This pattern, if defined, emits RTL for a register window save. It
- should be defined if the target machine has register windows but
- the window events are decoupled from calls to subroutines. The
- canonical example is the SPARC architecture.
-
- 'epilogue'
- This pattern emits RTL for exit from a function. The function exit
- is responsible for deallocating the stack frame, restoring callee
- saved registers and emitting the return instruction.
-
- Using an epilogue pattern is generally preferred over defining
- 'TARGET_ASM_FUNCTION_EPILOGUE' to emit assembly code for the
- epilogue.
-
- The 'epilogue' pattern is particularly useful for targets which
- perform instruction scheduling or which have delay slots for their
- return instruction.
-
- 'sibcall_epilogue'
- This pattern, if defined, emits RTL for exit from a function
- without the final branch back to the calling function. This
- pattern will be emitted before any sibling call (aka tail call)
- sites.
-
- The 'sibcall_epilogue' pattern must not clobber any arguments used
- for parameter passing or any stack slots for arguments passed to
- the current function.
-
- 'trap'
- This pattern, if defined, signals an error, typically by causing
- some kind of signal to be raised.
-
- 'ctrapMM4'
- Conditional trap instruction. Operand 0 is a piece of RTL which
- performs a comparison, and operands 1 and 2 are the arms of the
- comparison. Operand 3 is the trap code, an integer.
-
- A typical 'ctrap' pattern looks like
-
- (define_insn "ctrapsi4"
- [(trap_if (match_operator 0 "trap_operator"
- [(match_operand 1 "register_operand")
- (match_operand 2 "immediate_operand")])
- (match_operand 3 "const_int_operand" "i"))]
- ""
- "...")
-
- 'prefetch'
- This pattern, if defined, emits code for a non-faulting data
- prefetch instruction. Operand 0 is the address of the memory to
- prefetch. Operand 1 is a constant 1 if the prefetch is preparing
- for a write to the memory address, or a constant 0 otherwise.
- Operand 2 is the expected degree of temporal locality of the data
- and is a value between 0 and 3, inclusive; 0 means that the data
- has no temporal locality, so it need not be left in the cache after
- the access; 3 means that the data has a high degree of temporal
- locality and should be left in all levels of cache possible; 1 and
- 2 mean, respectively, a low or moderate degree of temporal
- locality.
-
- Targets that do not support write prefetches or locality hints can
- ignore the values of operands 1 and 2.
-
- 'blockage'
- This pattern defines a pseudo insn that prevents the instruction
- scheduler and other passes from moving instructions and using
- register equivalences across the boundary defined by the blockage
- insn. This needs to be an UNSPEC_VOLATILE pattern or a volatile
- ASM.
-
- 'memory_blockage'
- This pattern, if defined, represents a compiler memory barrier, and
- will be placed at points across which RTL passes may not propagate
- memory accesses. This instruction needs to read and write volatile
- BLKmode memory. It does not need to generate any machine
- instruction. If this pattern is not defined, the compiler falls
- back to emitting an instruction corresponding to 'asm volatile (""
- ::: "memory")'.
-
- 'memory_barrier'
- If the target memory model is not fully synchronous, then this
- pattern should be defined to an instruction that orders both loads
- and stores before the instruction with respect to loads and stores
- after the instruction. This pattern has no operands.
-
- 'speculation_barrier'
- If the target can support speculative execution, then this pattern
- should be defined to an instruction that will block subsequent
- execution until any prior speculation conditions has been resolved.
- The pattern must also ensure that the compiler cannot move memory
- operations past the barrier, so it needs to be an UNSPEC_VOLATILE
- pattern. The pattern has no operands.
-
- If this pattern is not defined then the default expansion of
- '__builtin_speculation_safe_value' will emit a warning. You can
- suppress this warning by defining this pattern with a final
- condition of '0' (zero), which tells the compiler that a
- speculation barrier is not needed for this target.
-
- 'sync_compare_and_swapMODE'
- This pattern, if defined, emits code for an atomic compare-and-swap
- operation. Operand 1 is the memory on which the atomic operation
- is performed. Operand 2 is the "old" value to be compared against
- the current contents of the memory location. Operand 3 is the
- "new" value to store in the memory if the compare succeeds.
- Operand 0 is the result of the operation; it should contain the
- contents of the memory before the operation. If the compare
- succeeds, this should obviously be a copy of operand 2.
-
- This pattern must show that both operand 0 and operand 1 are
- modified.
-
- This pattern must issue any memory barrier instructions such that
- all memory operations before the atomic operation occur before the
- atomic operation and all memory operations after the atomic
- operation occur after the atomic operation.
-
- For targets where the success or failure of the compare-and-swap
- operation is available via the status flags, it is possible to
- avoid a separate compare operation and issue the subsequent branch
- or store-flag operation immediately after the compare-and-swap. To
- this end, GCC will look for a 'MODE_CC' set in the output of
- 'sync_compare_and_swapMODE'; if the machine description includes
- such a set, the target should also define special 'cbranchcc4'
- and/or 'cstorecc4' instructions. GCC will then be able to take the
- destination of the 'MODE_CC' set and pass it to the 'cbranchcc4' or
- 'cstorecc4' pattern as the first operand of the comparison (the
- second will be '(const_int 0)').
-
- For targets where the operating system may provide support for this
- operation via library calls, the 'sync_compare_and_swap_optab' may
- be initialized to a function with the same interface as the
- '__sync_val_compare_and_swap_N' built-in. If the entire set of
- __SYNC builtins are supported via library calls, the target can
- initialize all of the optabs at once with 'init_sync_libfuncs'.
- For the purposes of C++11 'std::atomic::is_lock_free', it is
- assumed that these library calls do _not_ use any kind of
- interruptable locking.
-
- 'sync_addMODE', 'sync_subMODE'
- 'sync_iorMODE', 'sync_andMODE'
- 'sync_xorMODE', 'sync_nandMODE'
- These patterns emit code for an atomic operation on memory.
- Operand 0 is the memory on which the atomic operation is performed.
- Operand 1 is the second operand to the binary operator.
-
- This pattern must issue any memory barrier instructions such that
- all memory operations before the atomic operation occur before the
- atomic operation and all memory operations after the atomic
- operation occur after the atomic operation.
-
- If these patterns are not defined, the operation will be
- constructed from a compare-and-swap operation, if defined.
-
- 'sync_old_addMODE', 'sync_old_subMODE'
- 'sync_old_iorMODE', 'sync_old_andMODE'
- 'sync_old_xorMODE', 'sync_old_nandMODE'
- These patterns emit code for an atomic operation on memory, and
- return the value that the memory contained before the operation.
- Operand 0 is the result value, operand 1 is the memory on which the
- atomic operation is performed, and operand 2 is the second operand
- to the binary operator.
-
- This pattern must issue any memory barrier instructions such that
- all memory operations before the atomic operation occur before the
- atomic operation and all memory operations after the atomic
- operation occur after the atomic operation.
-
- If these patterns are not defined, the operation will be
- constructed from a compare-and-swap operation, if defined.
-
- 'sync_new_addMODE', 'sync_new_subMODE'
- 'sync_new_iorMODE', 'sync_new_andMODE'
- 'sync_new_xorMODE', 'sync_new_nandMODE'
- These patterns are like their 'sync_old_OP' counterparts, except
- that they return the value that exists in the memory location after
- the operation, rather than before the operation.
-
- 'sync_lock_test_and_setMODE'
- This pattern takes two forms, based on the capabilities of the
- target. In either case, operand 0 is the result of the operand,
- operand 1 is the memory on which the atomic operation is performed,
- and operand 2 is the value to set in the lock.
-
- In the ideal case, this operation is an atomic exchange operation,
- in which the previous value in memory operand is copied into the
- result operand, and the value operand is stored in the memory
- operand.
-
- For less capable targets, any value operand that is not the
- constant 1 should be rejected with 'FAIL'. In this case the target
- may use an atomic test-and-set bit operation. The result operand
- should contain 1 if the bit was previously set and 0 if the bit was
- previously clear. The true contents of the memory operand are
- implementation defined.
-
- This pattern must issue any memory barrier instructions such that
- the pattern as a whole acts as an acquire barrier, that is all
- memory operations after the pattern do not occur until the lock is
- acquired.
-
- If this pattern is not defined, the operation will be constructed
- from a compare-and-swap operation, if defined.
-
- 'sync_lock_releaseMODE'
- This pattern, if defined, releases a lock set by
- 'sync_lock_test_and_setMODE'. Operand 0 is the memory that
- contains the lock; operand 1 is the value to store in the lock.
-
- If the target doesn't implement full semantics for
- 'sync_lock_test_and_setMODE', any value operand which is not the
- constant 0 should be rejected with 'FAIL', and the true contents of
- the memory operand are implementation defined.
-
- This pattern must issue any memory barrier instructions such that
- the pattern as a whole acts as a release barrier, that is the lock
- is released only after all previous memory operations have
- completed.
-
- If this pattern is not defined, then a 'memory_barrier' pattern
- will be emitted, followed by a store of the value to the memory
- operand.
-
- 'atomic_compare_and_swapMODE'
- This pattern, if defined, emits code for an atomic compare-and-swap
- operation with memory model semantics. Operand 2 is the memory on
- which the atomic operation is performed. Operand 0 is an output
- operand which is set to true or false based on whether the
- operation succeeded. Operand 1 is an output operand which is set
- to the contents of the memory before the operation was attempted.
- Operand 3 is the value that is expected to be in memory. Operand 4
- is the value to put in memory if the expected value is found there.
- Operand 5 is set to 1 if this compare and swap is to be treated as
- a weak operation. Operand 6 is the memory model to be used if the
- operation is a success. Operand 7 is the memory model to be used
- if the operation fails.
-
- If memory referred to in operand 2 contains the value in operand 3,
- then operand 4 is stored in memory pointed to by operand 2 and
- fencing based on the memory model in operand 6 is issued.
-
- If memory referred to in operand 2 does not contain the value in
- operand 3, then fencing based on the memory model in operand 7 is
- issued.
-
- If a target does not support weak compare-and-swap operations, or
- the port elects not to implement weak operations, the argument in
- operand 5 can be ignored. Note a strong implementation must be
- provided.
-
- If this pattern is not provided, the '__atomic_compare_exchange'
- built-in functions will utilize the legacy 'sync_compare_and_swap'
- pattern with an '__ATOMIC_SEQ_CST' memory model.
-
- 'atomic_loadMODE'
- This pattern implements an atomic load operation with memory model
- semantics. Operand 1 is the memory address being loaded from.
- Operand 0 is the result of the load. Operand 2 is the memory model
- to be used for the load operation.
-
- If not present, the '__atomic_load' built-in function will either
- resort to a normal load with memory barriers, or a compare-and-swap
- operation if a normal load would not be atomic.
-
- 'atomic_storeMODE'
- This pattern implements an atomic store operation with memory model
- semantics. Operand 0 is the memory address being stored to.
- Operand 1 is the value to be written. Operand 2 is the memory
- model to be used for the operation.
-
- If not present, the '__atomic_store' built-in function will attempt
- to perform a normal store and surround it with any required memory
- fences. If the store would not be atomic, then an
- '__atomic_exchange' is attempted with the result being ignored.
-
- 'atomic_exchangeMODE'
- This pattern implements an atomic exchange operation with memory
- model semantics. Operand 1 is the memory location the operation is
- performed on. Operand 0 is an output operand which is set to the
- original value contained in the memory pointed to by operand 1.
- Operand 2 is the value to be stored. Operand 3 is the memory model
- to be used.
-
- If this pattern is not present, the built-in function
- '__atomic_exchange' will attempt to preform the operation with a
- compare and swap loop.
-
- 'atomic_addMODE', 'atomic_subMODE'
- 'atomic_orMODE', 'atomic_andMODE'
- 'atomic_xorMODE', 'atomic_nandMODE'
- These patterns emit code for an atomic operation on memory with
- memory model semantics. Operand 0 is the memory on which the
- atomic operation is performed. Operand 1 is the second operand to
- the binary operator. Operand 2 is the memory model to be used by
- the operation.
-
- If these patterns are not defined, attempts will be made to use
- legacy 'sync' patterns, or equivalent patterns which return a
- result. If none of these are available a compare-and-swap loop
- will be used.
-
- 'atomic_fetch_addMODE', 'atomic_fetch_subMODE'
- 'atomic_fetch_orMODE', 'atomic_fetch_andMODE'
- 'atomic_fetch_xorMODE', 'atomic_fetch_nandMODE'
- These patterns emit code for an atomic operation on memory with
- memory model semantics, and return the original value. Operand 0
- is an output operand which contains the value of the memory
- location before the operation was performed. Operand 1 is the
- memory on which the atomic operation is performed. Operand 2 is
- the second operand to the binary operator. Operand 3 is the memory
- model to be used by the operation.
-
- If these patterns are not defined, attempts will be made to use
- legacy 'sync' patterns. If none of these are available a
- compare-and-swap loop will be used.
-
- 'atomic_add_fetchMODE', 'atomic_sub_fetchMODE'
- 'atomic_or_fetchMODE', 'atomic_and_fetchMODE'
- 'atomic_xor_fetchMODE', 'atomic_nand_fetchMODE'
- These patterns emit code for an atomic operation on memory with
- memory model semantics and return the result after the operation is
- performed. Operand 0 is an output operand which contains the value
- after the operation. Operand 1 is the memory on which the atomic
- operation is performed. Operand 2 is the second operand to the
- binary operator. Operand 3 is the memory model to be used by the
- operation.
-
- If these patterns are not defined, attempts will be made to use
- legacy 'sync' patterns, or equivalent patterns which return the
- result before the operation followed by the arithmetic operation
- required to produce the result. If none of these are available a
- compare-and-swap loop will be used.
-
- 'atomic_test_and_set'
- This pattern emits code for '__builtin_atomic_test_and_set'.
- Operand 0 is an output operand which is set to true if the previous
- previous contents of the byte was "set", and false otherwise.
- Operand 1 is the 'QImode' memory to be modified. Operand 2 is the
- memory model to be used.
-
- The specific value that defines "set" is implementation defined,
- and is normally based on what is performed by the native atomic
- test and set instruction.
-
- 'atomic_bit_test_and_setMODE'
- 'atomic_bit_test_and_complementMODE'
- 'atomic_bit_test_and_resetMODE'
- These patterns emit code for an atomic bitwise operation on memory
- with memory model semantics, and return the original value of the
- specified bit. Operand 0 is an output operand which contains the
- value of the specified bit from the memory location before the
- operation was performed. Operand 1 is the memory on which the
- atomic operation is performed. Operand 2 is the bit within the
- operand, starting with least significant bit. Operand 3 is the
- memory model to be used by the operation. Operand 4 is a flag - it
- is 'const1_rtx' if operand 0 should contain the original value of
- the specified bit in the least significant bit of the operand, and
- 'const0_rtx' if the bit should be in its original position in the
- operand. 'atomic_bit_test_and_setMODE' atomically sets the
- specified bit after remembering its original value,
- 'atomic_bit_test_and_complementMODE' inverts the specified bit and
- 'atomic_bit_test_and_resetMODE' clears the specified bit.
-
- If these patterns are not defined, attempts will be made to use
- 'atomic_fetch_orMODE', 'atomic_fetch_xorMODE' or
- 'atomic_fetch_andMODE' instruction patterns, or their 'sync'
- counterparts. If none of these are available a compare-and-swap
- loop will be used.
-
- 'mem_thread_fence'
- This pattern emits code required to implement a thread fence with
- memory model semantics. Operand 0 is the memory model to be used.
-
- For the '__ATOMIC_RELAXED' model no instructions need to be issued
- and this expansion is not invoked.
-
- The compiler always emits a compiler memory barrier regardless of
- what expanding this pattern produced.
-
- If this pattern is not defined, the compiler falls back to
- expanding the 'memory_barrier' pattern, then to emitting
- '__sync_synchronize' library call, and finally to just placing a
- compiler memory barrier.
-
- 'get_thread_pointerMODE'
- 'set_thread_pointerMODE'
- These patterns emit code that reads/sets the TLS thread pointer.
- Currently, these are only needed if the target needs to support the
- '__builtin_thread_pointer' and '__builtin_set_thread_pointer'
- builtins.
-
- The get/set patterns have a single output/input operand
- respectively, with MODE intended to be 'Pmode'.
-
- 'stack_protect_combined_set'
- This pattern, if defined, moves a 'ptr_mode' value from an address
- whose declaration RTX is given in operand 1 to the memory in
- operand 0 without leaving the value in a register afterward. If
- several instructions are needed by the target to perform the
- operation (eg. to load the address from a GOT entry then load the
- 'ptr_mode' value and finally store it), it is the backend's
- responsibility to ensure no intermediate result gets spilled. This
- is to avoid leaking the value some place that an attacker might use
- to rewrite the stack guard slot after having clobbered it.
-
- If this pattern is not defined, then the address declaration is
- expanded first in the standard way and a 'stack_protect_set'
- pattern is then generated to move the value from that address to
- the address in operand 0.
-
- 'stack_protect_set'
- This pattern, if defined, moves a 'ptr_mode' value from the valid
- memory location in operand 1 to the memory in operand 0 without
- leaving the value in a register afterward. This is to avoid
- leaking the value some place that an attacker might use to rewrite
- the stack guard slot after having clobbered it.
-
- Note: on targets where the addressing modes do not allow to load
- directly from stack guard address, the address is expanded in a
- standard way first which could cause some spills.
-
- If this pattern is not defined, then a plain move pattern is
- generated.
-
- 'stack_protect_combined_test'
- This pattern, if defined, compares a 'ptr_mode' value from an
- address whose declaration RTX is given in operand 1 with the memory
- in operand 0 without leaving the value in a register afterward and
- branches to operand 2 if the values were equal. If several
- instructions are needed by the target to perform the operation (eg.
- to load the address from a GOT entry then load the 'ptr_mode' value
- and finally store it), it is the backend's responsibility to ensure
- no intermediate result gets spilled. This is to avoid leaking the
- value some place that an attacker might use to rewrite the stack
- guard slot after having clobbered it.
-
- If this pattern is not defined, then the address declaration is
- expanded first in the standard way and a 'stack_protect_test'
- pattern is then generated to compare the value from that address to
- the value at the memory in operand 0.
-
- 'stack_protect_test'
- This pattern, if defined, compares a 'ptr_mode' value from the
- valid memory location in operand 1 with the memory in operand 0
- without leaving the value in a register afterward and branches to
- operand 2 if the values were equal.
-
- If this pattern is not defined, then a plain compare pattern and
- conditional branch pattern is used.
-
- 'clear_cache'
- This pattern, if defined, flushes the instruction cache for a
- region of memory. The region is bounded to by the Pmode pointers
- in operand 0 inclusive and operand 1 exclusive.
-
- If this pattern is not defined, a call to the library function
- '__clear_cache' is used.
-
-
- File: gccint.info, Node: Pattern Ordering, Next: Dependent Patterns, Prev: Standard Names, Up: Machine Desc
-
- 17.10 When the Order of Patterns Matters
- ========================================
-
- Sometimes an insn can match more than one instruction pattern. Then the
- pattern that appears first in the machine description is the one used.
- Therefore, more specific patterns (patterns that will match fewer
- things) and faster instructions (those that will produce better code
- when they do match) should usually go first in the description.
-
- In some cases the effect of ordering the patterns can be used to hide a
- pattern when it is not valid. For example, the 68000 has an instruction
- for converting a fullword to floating point and another for converting a
- byte to floating point. An instruction converting an integer to
- floating point could match either one. We put the pattern to convert
- the fullword first to make sure that one will be used rather than the
- other. (Otherwise a large integer might be generated as a single-byte
- immediate quantity, which would not work.) Instead of using this
- pattern ordering it would be possible to make the pattern for
- convert-a-byte smart enough to deal properly with any constant value.
-
-
- File: gccint.info, Node: Dependent Patterns, Next: Jump Patterns, Prev: Pattern Ordering, Up: Machine Desc
-
- 17.11 Interdependence of Patterns
- =================================
-
- In some cases machines support instructions identical except for the
- machine mode of one or more operands. For example, there may be
- "sign-extend halfword" and "sign-extend byte" instructions whose
- patterns are
-
- (set (match_operand:SI 0 ...)
- (extend:SI (match_operand:HI 1 ...)))
-
- (set (match_operand:SI 0 ...)
- (extend:SI (match_operand:QI 1 ...)))
-
- Constant integers do not specify a machine mode, so an instruction to
- extend a constant value could match either pattern. The pattern it
- actually will match is the one that appears first in the file. For
- correct results, this must be the one for the widest possible mode
- ('HImode', here). If the pattern matches the 'QImode' instruction, the
- results will be incorrect if the constant value does not actually fit
- that mode.
-
- Such instructions to extend constants are rarely generated because they
- are optimized away, but they do occasionally happen in nonoptimized
- compilations.
-
- If a constraint in a pattern allows a constant, the reload pass may
- replace a register with a constant permitted by the constraint in some
- cases. Similarly for memory references. Because of this substitution,
- you should not provide separate patterns for increment and decrement
- instructions. Instead, they should be generated from the same pattern
- that supports register-register add insns by examining the operands and
- generating the appropriate machine instruction.
-
-
- File: gccint.info, Node: Jump Patterns, Next: Looping Patterns, Prev: Dependent Patterns, Up: Machine Desc
-
- 17.12 Defining Jump Instruction Patterns
- ========================================
-
- GCC does not assume anything about how the machine realizes jumps. The
- machine description should define a single pattern, usually a
- 'define_expand', which expands to all the required insns.
-
- Usually, this would be a comparison insn to set the condition code and
- a separate branch insn testing the condition code and branching or not
- according to its value. For many machines, however, separating compares
- and branches is limiting, which is why the more flexible approach with
- one 'define_expand' is used in GCC. The machine description becomes
- clearer for architectures that have compare-and-branch instructions but
- no condition code. It also works better when different sets of
- comparison operators are supported by different kinds of conditional
- branches (e.g. integer vs. floating-point), or by conditional branches
- with respect to conditional stores.
-
- Two separate insns are always used if the machine description
- represents a condition code register using the legacy RTL expression
- '(cc0)', and on most machines that use a separate condition code
- register (*note Condition Code::). For machines that use '(cc0)', in
- fact, the set and use of the condition code must be separate and
- adjacent(1), thus allowing flags in 'cc_status' to be used (*note
- Condition Code::) and so that the comparison and branch insns could be
- located from each other by using the functions 'prev_cc0_setter' and
- 'next_cc0_user'.
-
- Even in this case having a single entry point for conditional branches
- is advantageous, because it handles equally well the case where a single
- comparison instruction records the results of both signed and unsigned
- comparison of the given operands (with the branch insns coming in
- distinct signed and unsigned flavors) as in the x86 or SPARC, and the
- case where there are distinct signed and unsigned compare instructions
- and only one set of conditional branch instructions as in the PowerPC.
-
- ---------- Footnotes ----------
-
- (1) 'note' insns can separate them, though.
-
-
- File: gccint.info, Node: Looping Patterns, Next: Insn Canonicalizations, Prev: Jump Patterns, Up: Machine Desc
-
- 17.13 Defining Looping Instruction Patterns
- ===========================================
-
- Some machines have special jump instructions that can be utilized to
- make loops more efficient. A common example is the 68000 'dbra'
- instruction which performs a decrement of a register and a branch if the
- result was greater than zero. Other machines, in particular digital
- signal processors (DSPs), have special block repeat instructions to
- provide low-overhead loop support. For example, the TI TMS320C3x/C4x
- DSPs have a block repeat instruction that loads special registers to
- mark the top and end of a loop and to count the number of loop
- iterations. This avoids the need for fetching and executing a
- 'dbra'-like instruction and avoids pipeline stalls associated with the
- jump.
-
- GCC has two special named patterns to support low overhead looping.
- They are 'doloop_begin' and 'doloop_end'. These are emitted by the loop
- optimizer for certain well-behaved loops with a finite number of loop
- iterations using information collected during strength reduction.
-
- The 'doloop_end' pattern describes the actual looping instruction (or
- the implicit looping operation) and the 'doloop_begin' pattern is an
- optional companion pattern that can be used for initialization needed
- for some low-overhead looping instructions.
-
- Note that some machines require the actual looping instruction to be
- emitted at the top of the loop (e.g., the TMS320C3x/C4x DSPs). Emitting
- the true RTL for a looping instruction at the top of the loop can cause
- problems with flow analysis. So instead, a dummy 'doloop' insn is
- emitted at the end of the loop. The machine dependent reorg pass checks
- for the presence of this 'doloop' insn and then searches back to the top
- of the loop, where it inserts the true looping insn (provided there are
- no instructions in the loop which would cause problems). Any additional
- labels can be emitted at this point. In addition, if the desired
- special iteration counter register was not allocated, this machine
- dependent reorg pass could emit a traditional compare and jump
- instruction pair.
-
- For the 'doloop_end' pattern, the loop optimizer allocates an
- additional pseudo register as an iteration counter. This pseudo
- register cannot be used within the loop (i.e., general induction
- variables cannot be derived from it), however, in many cases the loop
- induction variable may become redundant and removed by the flow pass.
-
- The 'doloop_end' pattern must have a specific structure to be handled
- correctly by GCC. The example below is taken (slightly simplified) from
- the PDP-11 target:
-
- (define_expand "doloop_end"
- [(parallel [(set (pc)
- (if_then_else
- (ne (match_operand:HI 0 "nonimmediate_operand" "+r,!m")
- (const_int 1))
- (label_ref (match_operand 1 "" ""))
- (pc)))
- (set (match_dup 0)
- (plus:HI (match_dup 0)
- (const_int -1)))])]
- ""
- "{
- if (GET_MODE (operands[0]) != HImode)
- FAIL;
- }")
-
- (define_insn "doloop_end_insn"
- [(set (pc)
- (if_then_else
- (ne (match_operand:HI 0 "nonimmediate_operand" "+r,!m")
- (const_int 1))
- (label_ref (match_operand 1 "" ""))
- (pc)))
- (set (match_dup 0)
- (plus:HI (match_dup 0)
- (const_int -1)))]
- ""
-
- {
- if (which_alternative == 0)
- return "sob %0,%l1";
-
- /* emulate sob */
- output_asm_insn ("dec %0", operands);
- return "bne %l1";
- })
-
- The first part of the pattern describes the branch condition. GCC
- supports three cases for the way the target machine handles the loop
- counter:
- * Loop terminates when the loop register decrements to zero. This is
- represented by a 'ne' comparison of the register (its old value)
- with constant 1 (as in the example above).
- * Loop terminates when the loop register decrements to -1. This is
- represented by a 'ne' comparison of the register with constant
- zero.
- * Loop terminates when the loop register decrements to a negative
- value. This is represented by a 'ge' comparison of the register
- with constant zero. For this case, GCC will attach a 'REG_NONNEG'
- note to the 'doloop_end' insn if it can determine that the register
- will be non-negative.
-
- Since the 'doloop_end' insn is a jump insn that also has an output, the
- reload pass does not handle the output operand. Therefore, the
- constraint must allow for that operand to be in memory rather than a
- register. In the example shown above, that is handled (in the
- 'doloop_end_insn' pattern) by using a loop instruction sequence that can
- handle memory operands when the memory alternative appears.
-
- GCC does not check the mode of the loop register operand when
- generating the 'doloop_end' pattern. If the pattern is only valid for
- some modes but not others, the pattern should be a 'define_expand'
- pattern that checks the operand mode in the preparation code, and issues
- 'FAIL' if an unsupported mode is found. The example above does this,
- since the machine instruction to be used only exists for 'HImode'.
-
- If the 'doloop_end' pattern is a 'define_expand', there must also be a
- 'define_insn' or 'define_insn_and_split' matching the generated pattern.
- Otherwise, the compiler will fail during loop optimization.
-
-
- File: gccint.info, Node: Insn Canonicalizations, Next: Expander Definitions, Prev: Looping Patterns, Up: Machine Desc
-
- 17.14 Canonicalization of Instructions
- ======================================
-
- There are often cases where multiple RTL expressions could represent an
- operation performed by a single machine instruction. This situation is
- most commonly encountered with logical, branch, and multiply-accumulate
- instructions. In such cases, the compiler attempts to convert these
- multiple RTL expressions into a single canonical form to reduce the
- number of insn patterns required.
-
- In addition to algebraic simplifications, following canonicalizations
- are performed:
-
- * For commutative and comparison operators, a constant is always made
- the second operand. If a machine only supports a constant as the
- second operand, only patterns that match a constant in the second
- operand need be supplied.
-
- * For associative operators, a sequence of operators will always
- chain to the left; for instance, only the left operand of an
- integer 'plus' can itself be a 'plus'. 'and', 'ior', 'xor',
- 'plus', 'mult', 'smin', 'smax', 'umin', and 'umax' are associative
- when applied to integers, and sometimes to floating-point.
-
- * For these operators, if only one operand is a 'neg', 'not', 'mult',
- 'plus', or 'minus' expression, it will be the first operand.
-
- * In combinations of 'neg', 'mult', 'plus', and 'minus', the 'neg'
- operations (if any) will be moved inside the operations as far as
- possible. For instance, '(neg (mult A B))' is canonicalized as
- '(mult (neg A) B)', but '(plus (mult (neg B) C) A)' is
- canonicalized as '(minus A (mult B C))'.
-
- * For the 'compare' operator, a constant is always the second operand
- if the first argument is a condition code register or '(cc0)'.
-
- * For instructions that inherently set a condition code register, the
- 'compare' operator is always written as the first RTL expression of
- the 'parallel' instruction pattern. For example,
-
- (define_insn ""
- [(set (reg:CCZ FLAGS_REG)
- (compare:CCZ
- (plus:SI
- (match_operand:SI 1 "register_operand" "%r")
- (match_operand:SI 2 "register_operand" "r"))
- (const_int 0)))
- (set (match_operand:SI 0 "register_operand" "=r")
- (plus:SI (match_dup 1) (match_dup 2)))]
- ""
- "addl %0, %1, %2")
-
- * An operand of 'neg', 'not', 'mult', 'plus', or 'minus' is made the
- first operand under the same conditions as above.
-
- * '(ltu (plus A B) B)' is converted to '(ltu (plus A B) A)'.
- Likewise with 'geu' instead of 'ltu'.
-
- * '(minus X (const_int N))' is converted to '(plus X (const_int
- -N))'.
-
- * Within address computations (i.e., inside 'mem'), a left shift is
- converted into the appropriate multiplication by a power of two.
-
- * De Morgan's Law is used to move bitwise negation inside a bitwise
- logical-and or logical-or operation. If this results in only one
- operand being a 'not' expression, it will be the first one.
-
- A machine that has an instruction that performs a bitwise
- logical-and of one operand with the bitwise negation of the other
- should specify the pattern for that instruction as
-
- (define_insn ""
- [(set (match_operand:M 0 ...)
- (and:M (not:M (match_operand:M 1 ...))
- (match_operand:M 2 ...)))]
- "..."
- "...")
-
- Similarly, a pattern for a "NAND" instruction should be written
-
- (define_insn ""
- [(set (match_operand:M 0 ...)
- (ior:M (not:M (match_operand:M 1 ...))
- (not:M (match_operand:M 2 ...))))]
- "..."
- "...")
-
- In both cases, it is not necessary to include patterns for the many
- logically equivalent RTL expressions.
-
- * The only possible RTL expressions involving both bitwise
- exclusive-or and bitwise negation are '(xor:M X Y)' and '(not:M
- (xor:M X Y))'.
-
- * The sum of three items, one of which is a constant, will only
- appear in the form
-
- (plus:M (plus:M X Y) CONSTANT)
-
- * Equality comparisons of a group of bits (usually a single bit) with
- zero will be written using 'zero_extract' rather than the
- equivalent 'and' or 'sign_extract' operations.
-
- * '(sign_extend:M1 (mult:M2 (sign_extend:M2 X) (sign_extend:M2 Y)))'
- is converted to '(mult:M1 (sign_extend:M1 X) (sign_extend:M1 Y))',
- and likewise for 'zero_extend'.
-
- * '(sign_extend:M1 (mult:M2 (ashiftrt:M2 X S) (sign_extend:M2 Y)))'
- is converted to '(mult:M1 (sign_extend:M1 (ashiftrt:M2 X S))
- (sign_extend:M1 Y))', and likewise for patterns using 'zero_extend'
- and 'lshiftrt'. If the second operand of 'mult' is also a shift,
- then that is extended also. This transformation is only applied
- when it can be proven that the original operation had sufficient
- precision to prevent overflow.
-
- Further canonicalization rules are defined in the function
- 'commutative_operand_precedence' in 'gcc/rtlanal.c'.
-
-
- File: gccint.info, Node: Expander Definitions, Next: Insn Splitting, Prev: Insn Canonicalizations, Up: Machine Desc
-
- 17.15 Defining RTL Sequences for Code Generation
- ================================================
-
- On some target machines, some standard pattern names for RTL generation
- cannot be handled with single insn, but a sequence of RTL insns can
- represent them. For these target machines, you can write a
- 'define_expand' to specify how to generate the sequence of RTL.
-
- A 'define_expand' is an RTL expression that looks almost like a
- 'define_insn'; but, unlike the latter, a 'define_expand' is used only
- for RTL generation and it can produce more than one RTL insn.
-
- A 'define_expand' RTX has four operands:
-
- * The name. Each 'define_expand' must have a name, since the only
- use for it is to refer to it by name.
-
- * The RTL template. This is a vector of RTL expressions representing
- a sequence of separate instructions. Unlike 'define_insn', there
- is no implicit surrounding 'PARALLEL'.
-
- * The condition, a string containing a C expression. This expression
- is used to express how the availability of this pattern depends on
- subclasses of target machine, selected by command-line options when
- GCC is run. This is just like the condition of a 'define_insn'
- that has a standard name. Therefore, the condition (if present)
- may not depend on the data in the insn being matched, but only the
- target-machine-type flags. The compiler needs to test these
- conditions during initialization in order to learn exactly which
- named instructions are available in a particular run.
-
- * The preparation statements, a string containing zero or more C
- statements which are to be executed before RTL code is generated
- from the RTL template.
-
- Usually these statements prepare temporary registers for use as
- internal operands in the RTL template, but they can also generate
- RTL insns directly by calling routines such as 'emit_insn', etc.
- Any such insns precede the ones that come from the RTL template.
-
- * Optionally, a vector containing the values of attributes. *Note
- Insn Attributes::.
-
- Every RTL insn emitted by a 'define_expand' must match some
- 'define_insn' in the machine description. Otherwise, the compiler will
- crash when trying to generate code for the insn or trying to optimize
- it.
-
- The RTL template, in addition to controlling generation of RTL insns,
- also describes the operands that need to be specified when this pattern
- is used. In particular, it gives a predicate for each operand.
-
- A true operand, which needs to be specified in order to generate RTL
- from the pattern, should be described with a 'match_operand' in its
- first occurrence in the RTL template. This enters information on the
- operand's predicate into the tables that record such things. GCC uses
- the information to preload the operand into a register if that is
- required for valid RTL code. If the operand is referred to more than
- once, subsequent references should use 'match_dup'.
-
- The RTL template may also refer to internal "operands" which are
- temporary registers or labels used only within the sequence made by the
- 'define_expand'. Internal operands are substituted into the RTL
- template with 'match_dup', never with 'match_operand'. The values of
- the internal operands are not passed in as arguments by the compiler
- when it requests use of this pattern. Instead, they are computed within
- the pattern, in the preparation statements. These statements compute
- the values and store them into the appropriate elements of 'operands' so
- that 'match_dup' can find them.
-
- There are two special macros defined for use in the preparation
- statements: 'DONE' and 'FAIL'. Use them with a following semicolon, as
- a statement.
-
- 'DONE'
- Use the 'DONE' macro to end RTL generation for the pattern. The
- only RTL insns resulting from the pattern on this occasion will be
- those already emitted by explicit calls to 'emit_insn' within the
- preparation statements; the RTL template will not be generated.
-
- 'FAIL'
- Make the pattern fail on this occasion. When a pattern fails, it
- means that the pattern was not truly available. The calling
- routines in the compiler will try other strategies for code
- generation using other patterns.
-
- Failure is currently supported only for binary (addition,
- multiplication, shifting, etc.) and bit-field ('extv', 'extzv',
- and 'insv') operations.
-
- If the preparation falls through (invokes neither 'DONE' nor 'FAIL'),
- then the 'define_expand' acts like a 'define_insn' in that the RTL
- template is used to generate the insn.
-
- The RTL template is not used for matching, only for generating the
- initial insn list. If the preparation statement always invokes 'DONE'
- or 'FAIL', the RTL template may be reduced to a simple list of operands,
- such as this example:
-
- (define_expand "addsi3"
- [(match_operand:SI 0 "register_operand" "")
- (match_operand:SI 1 "register_operand" "")
- (match_operand:SI 2 "register_operand" "")]
- ""
- "
- {
- handle_add (operands[0], operands[1], operands[2]);
- DONE;
- }")
-
- Here is an example, the definition of left-shift for the SPUR chip:
-
- (define_expand "ashlsi3"
- [(set (match_operand:SI 0 "register_operand" "")
- (ashift:SI
- (match_operand:SI 1 "register_operand" "")
- (match_operand:SI 2 "nonmemory_operand" "")))]
- ""
- "
-
- {
- if (GET_CODE (operands[2]) != CONST_INT
- || (unsigned) INTVAL (operands[2]) > 3)
- FAIL;
- }")
-
- This example uses 'define_expand' so that it can generate an RTL insn
- for shifting when the shift-count is in the supported range of 0 to 3
- but fail in other cases where machine insns aren't available. When it
- fails, the compiler tries another strategy using different patterns
- (such as, a library call).
-
- If the compiler were able to handle nontrivial condition-strings in
- patterns with names, then it would be possible to use a 'define_insn' in
- that case. Here is another case (zero-extension on the 68000) which
- makes more use of the power of 'define_expand':
-
- (define_expand "zero_extendhisi2"
- [(set (match_operand:SI 0 "general_operand" "")
- (const_int 0))
- (set (strict_low_part
- (subreg:HI
- (match_dup 0)
- 0))
- (match_operand:HI 1 "general_operand" ""))]
- ""
- "operands[1] = make_safe_from (operands[1], operands[0]);")
-
- Here two RTL insns are generated, one to clear the entire output operand
- and the other to copy the input operand into its low half. This
- sequence is incorrect if the input operand refers to [the old value of]
- the output operand, so the preparation statement makes sure this isn't
- so. The function 'make_safe_from' copies the 'operands[1]' into a
- temporary register if it refers to 'operands[0]'. It does this by
- emitting another RTL insn.
-
- Finally, a third example shows the use of an internal operand.
- Zero-extension on the SPUR chip is done by 'and'-ing the result against
- a halfword mask. But this mask cannot be represented by a 'const_int'
- because the constant value is too large to be legitimate on this
- machine. So it must be copied into a register with 'force_reg' and then
- the register used in the 'and'.
-
- (define_expand "zero_extendhisi2"
- [(set (match_operand:SI 0 "register_operand" "")
- (and:SI (subreg:SI
- (match_operand:HI 1 "register_operand" "")
- 0)
- (match_dup 2)))]
- ""
- "operands[2]
- = force_reg (SImode, GEN_INT (65535)); ")
-
- _Note:_ If the 'define_expand' is used to serve a standard binary or
- unary arithmetic operation or a bit-field operation, then the last insn
- it generates must not be a 'code_label', 'barrier' or 'note'. It must
- be an 'insn', 'jump_insn' or 'call_insn'. If you don't need a real insn
- at the end, emit an insn to copy the result of the operation into
- itself. Such an insn will generate no code, but it can avoid problems
- in the compiler.
-
-
- File: gccint.info, Node: Insn Splitting, Next: Including Patterns, Prev: Expander Definitions, Up: Machine Desc
-
- 17.16 Defining How to Split Instructions
- ========================================
-
- There are two cases where you should specify how to split a pattern into
- multiple insns. On machines that have instructions requiring delay
- slots (*note Delay Slots::) or that have instructions whose output is
- not available for multiple cycles (*note Processor pipeline
- description::), the compiler phases that optimize these cases need to be
- able to move insns into one-instruction delay slots. However, some
- insns may generate more than one machine instruction. These insns
- cannot be placed into a delay slot.
-
- Often you can rewrite the single insn as a list of individual insns,
- each corresponding to one machine instruction. The disadvantage of
- doing so is that it will cause the compilation to be slower and require
- more space. If the resulting insns are too complex, it may also
- suppress some optimizations. The compiler splits the insn if there is a
- reason to believe that it might improve instruction or delay slot
- scheduling.
-
- The insn combiner phase also splits putative insns. If three insns are
- merged into one insn with a complex expression that cannot be matched by
- some 'define_insn' pattern, the combiner phase attempts to split the
- complex pattern into two insns that are recognized. Usually it can
- break the complex pattern into two patterns by splitting out some
- subexpression. However, in some other cases, such as performing an
- addition of a large constant in two insns on a RISC machine, the way to
- split the addition into two insns is machine-dependent.
-
- The 'define_split' definition tells the compiler how to split a complex
- insn into several simpler insns. It looks like this:
-
- (define_split
- [INSN-PATTERN]
- "CONDITION"
- [NEW-INSN-PATTERN-1
- NEW-INSN-PATTERN-2
- ...]
- "PREPARATION-STATEMENTS")
-
- INSN-PATTERN is a pattern that needs to be split and CONDITION is the
- final condition to be tested, as in a 'define_insn'. When an insn
- matching INSN-PATTERN and satisfying CONDITION is found, it is replaced
- in the insn list with the insns given by NEW-INSN-PATTERN-1,
- NEW-INSN-PATTERN-2, etc.
-
- The PREPARATION-STATEMENTS are similar to those statements that are
- specified for 'define_expand' (*note Expander Definitions::) and are
- executed before the new RTL is generated to prepare for the generated
- code or emit some insns whose pattern is not fixed. Unlike those in
- 'define_expand', however, these statements must not generate any new
- pseudo-registers. Once reload has completed, they also must not
- allocate any space in the stack frame.
-
- There are two special macros defined for use in the preparation
- statements: 'DONE' and 'FAIL'. Use them with a following semicolon, as
- a statement.
-
- 'DONE'
- Use the 'DONE' macro to end RTL generation for the splitter. The
- only RTL insns generated as replacement for the matched input insn
- will be those already emitted by explicit calls to 'emit_insn'
- within the preparation statements; the replacement pattern is not
- used.
-
- 'FAIL'
- Make the 'define_split' fail on this occasion. When a
- 'define_split' fails, it means that the splitter was not truly
- available for the inputs it was given, and the input insn will not
- be split.
-
- If the preparation falls through (invokes neither 'DONE' nor 'FAIL'),
- then the 'define_split' uses the replacement template.
-
- Patterns are matched against INSN-PATTERN in two different
- circumstances. If an insn needs to be split for delay slot scheduling
- or insn scheduling, the insn is already known to be valid, which means
- that it must have been matched by some 'define_insn' and, if
- 'reload_completed' is nonzero, is known to satisfy the constraints of
- that 'define_insn'. In that case, the new insn patterns must also be
- insns that are matched by some 'define_insn' and, if 'reload_completed'
- is nonzero, must also satisfy the constraints of those definitions.
-
- As an example of this usage of 'define_split', consider the following
- example from 'a29k.md', which splits a 'sign_extend' from 'HImode' to
- 'SImode' into a pair of shift insns:
-
- (define_split
- [(set (match_operand:SI 0 "gen_reg_operand" "")
- (sign_extend:SI (match_operand:HI 1 "gen_reg_operand" "")))]
- ""
- [(set (match_dup 0)
- (ashift:SI (match_dup 1)
- (const_int 16)))
- (set (match_dup 0)
- (ashiftrt:SI (match_dup 0)
- (const_int 16)))]
- "
- { operands[1] = gen_lowpart (SImode, operands[1]); }")
-
- When the combiner phase tries to split an insn pattern, it is always
- the case that the pattern is _not_ matched by any 'define_insn'. The
- combiner pass first tries to split a single 'set' expression and then
- the same 'set' expression inside a 'parallel', but followed by a
- 'clobber' of a pseudo-reg to use as a scratch register. In these cases,
- the combiner expects exactly one or two new insn patterns to be
- generated. It will verify that these patterns match some 'define_insn'
- definitions, so you need not do this test in the 'define_split' (of
- course, there is no point in writing a 'define_split' that will never
- produce insns that match).
-
- Here is an example of this use of 'define_split', taken from
- 'rs6000.md':
-
- (define_split
- [(set (match_operand:SI 0 "gen_reg_operand" "")
- (plus:SI (match_operand:SI 1 "gen_reg_operand" "")
- (match_operand:SI 2 "non_add_cint_operand" "")))]
- ""
- [(set (match_dup 0) (plus:SI (match_dup 1) (match_dup 3)))
- (set (match_dup 0) (plus:SI (match_dup 0) (match_dup 4)))]
- "
- {
- int low = INTVAL (operands[2]) & 0xffff;
- int high = (unsigned) INTVAL (operands[2]) >> 16;
-
- if (low & 0x8000)
- high++, low |= 0xffff0000;
-
- operands[3] = GEN_INT (high << 16);
- operands[4] = GEN_INT (low);
- }")
-
- Here the predicate 'non_add_cint_operand' matches any 'const_int' that
- is _not_ a valid operand of a single add insn. The add with the smaller
- displacement is written so that it can be substituted into the address
- of a subsequent operation.
-
- An example that uses a scratch register, from the same file, generates
- an equality comparison of a register and a large constant:
-
- (define_split
- [(set (match_operand:CC 0 "cc_reg_operand" "")
- (compare:CC (match_operand:SI 1 "gen_reg_operand" "")
- (match_operand:SI 2 "non_short_cint_operand" "")))
- (clobber (match_operand:SI 3 "gen_reg_operand" ""))]
- "find_single_use (operands[0], insn, 0)
- && (GET_CODE (*find_single_use (operands[0], insn, 0)) == EQ
- || GET_CODE (*find_single_use (operands[0], insn, 0)) == NE)"
- [(set (match_dup 3) (xor:SI (match_dup 1) (match_dup 4)))
- (set (match_dup 0) (compare:CC (match_dup 3) (match_dup 5)))]
- "
- {
- /* Get the constant we are comparing against, C, and see what it
- looks like sign-extended to 16 bits. Then see what constant
- could be XOR'ed with C to get the sign-extended value. */
-
- int c = INTVAL (operands[2]);
- int sextc = (c << 16) >> 16;
- int xorv = c ^ sextc;
-
- operands[4] = GEN_INT (xorv);
- operands[5] = GEN_INT (sextc);
- }")
-
- To avoid confusion, don't write a single 'define_split' that accepts
- some insns that match some 'define_insn' as well as some insns that
- don't. Instead, write two separate 'define_split' definitions, one for
- the insns that are valid and one for the insns that are not valid.
-
- The splitter is allowed to split jump instructions into sequence of
- jumps or create new jumps in while splitting non-jump instructions. As
- the control flow graph and branch prediction information needs to be
- updated, several restriction apply.
-
- Splitting of jump instruction into sequence that over by another jump
- instruction is always valid, as compiler expect identical behavior of
- new jump. When new sequence contains multiple jump instructions or new
- labels, more assistance is needed. Splitter is required to create only
- unconditional jumps, or simple conditional jump instructions.
- Additionally it must attach a 'REG_BR_PROB' note to each conditional
- jump. A global variable 'split_branch_probability' holds the
- probability of the original branch in case it was a simple conditional
- jump, -1 otherwise. To simplify recomputing of edge frequencies, the
- new sequence is required to have only forward jumps to the newly created
- labels.
-
- For the common case where the pattern of a define_split exactly matches
- the pattern of a define_insn, use 'define_insn_and_split'. It looks
- like this:
-
- (define_insn_and_split
- [INSN-PATTERN]
- "CONDITION"
- "OUTPUT-TEMPLATE"
- "SPLIT-CONDITION"
- [NEW-INSN-PATTERN-1
- NEW-INSN-PATTERN-2
- ...]
- "PREPARATION-STATEMENTS"
- [INSN-ATTRIBUTES])
-
-
- INSN-PATTERN, CONDITION, OUTPUT-TEMPLATE, and INSN-ATTRIBUTES are used
- as in 'define_insn'. The NEW-INSN-PATTERN vector and the
- PREPARATION-STATEMENTS are used as in a 'define_split'. The
- SPLIT-CONDITION is also used as in 'define_split', with the additional
- behavior that if the condition starts with '&&', the condition used for
- the split will be the constructed as a logical "and" of the split
- condition with the insn condition. For example, from i386.md:
-
- (define_insn_and_split "zero_extendhisi2_and"
- [(set (match_operand:SI 0 "register_operand" "=r")
- (zero_extend:SI (match_operand:HI 1 "register_operand" "0")))
- (clobber (reg:CC 17))]
- "TARGET_ZERO_EXTEND_WITH_AND && !optimize_size"
- "#"
- "&& reload_completed"
- [(parallel [(set (match_dup 0)
- (and:SI (match_dup 0) (const_int 65535)))
- (clobber (reg:CC 17))])]
- ""
- [(set_attr "type" "alu1")])
-
-
- In this case, the actual split condition will be
- 'TARGET_ZERO_EXTEND_WITH_AND && !optimize_size && reload_completed'.
-
- The 'define_insn_and_split' construction provides exactly the same
- functionality as two separate 'define_insn' and 'define_split' patterns.
- It exists for compactness, and as a maintenance tool to prevent having
- to ensure the two patterns' templates match.
-
- It is sometimes useful to have a 'define_insn_and_split' that replaces
- specific operands of an instruction but leaves the rest of the
- instruction pattern unchanged. You can do this directly with a
- 'define_insn_and_split', but it requires a NEW-INSN-PATTERN-1 that
- repeats most of the original INSN-PATTERN. There is also the
- complication that an implicit 'parallel' in INSN-PATTERN must become an
- explicit 'parallel' in NEW-INSN-PATTERN-1, which is easy to overlook. A
- simpler alternative is to use 'define_insn_and_rewrite', which is a form
- of 'define_insn_and_split' that automatically generates
- NEW-INSN-PATTERN-1 by replacing each 'match_operand' in INSN-PATTERN
- with a corresponding 'match_dup', and each 'match_operator' in the
- pattern with a corresponding 'match_op_dup'. The arguments are
- otherwise identical to 'define_insn_and_split':
-
- (define_insn_and_rewrite
- [INSN-PATTERN]
- "CONDITION"
- "OUTPUT-TEMPLATE"
- "SPLIT-CONDITION"
- "PREPARATION-STATEMENTS"
- [INSN-ATTRIBUTES])
-
- The 'match_dup's and 'match_op_dup's in the new instruction pattern use
- any new operand values that the PREPARATION-STATEMENTS store in the
- 'operands' array, as for a normal 'define_insn_and_split'.
- PREPARATION-STATEMENTS can also emit additional instructions before the
- new instruction. They can even emit an entirely different sequence of
- instructions and use 'DONE' to avoid emitting a new form of the original
- instruction.
-
- The split in a 'define_insn_and_rewrite' is only intended to apply to
- existing instructions that match INSN-PATTERN. SPLIT-CONDITION must
- therefore start with '&&', so that the split condition applies on top of
- CONDITION.
-
- Here is an example from the AArch64 SVE port, in which operand 1 is
- known to be equivalent to an all-true constant and isn't used by the
- output template:
-
- (define_insn_and_rewrite "*while_ult<GPI:mode><PRED_ALL:mode>_cc"
- [(set (reg:CC CC_REGNUM)
- (compare:CC
- (unspec:SI [(match_operand:PRED_ALL 1)
- (unspec:PRED_ALL
- [(match_operand:GPI 2 "aarch64_reg_or_zero" "rZ")
- (match_operand:GPI 3 "aarch64_reg_or_zero" "rZ")]
- UNSPEC_WHILE_LO)]
- UNSPEC_PTEST_PTRUE)
- (const_int 0)))
- (set (match_operand:PRED_ALL 0 "register_operand" "=Upa")
- (unspec:PRED_ALL [(match_dup 2)
- (match_dup 3)]
- UNSPEC_WHILE_LO))]
- "TARGET_SVE"
- "whilelo\t%0.<PRED_ALL:Vetype>, %<w>2, %<w>3"
- ;; Force the compiler to drop the unused predicate operand, so that we
- ;; don't have an unnecessary PTRUE.
- "&& !CONSTANT_P (operands[1])"
- {
- operands[1] = CONSTM1_RTX (<MODE>mode);
- }
- )
-
- The splitter in this case simply replaces operand 1 with the constant
- value that it is known to have. The equivalent 'define_insn_and_split'
- would be:
-
- (define_insn_and_split "*while_ult<GPI:mode><PRED_ALL:mode>_cc"
- [(set (reg:CC CC_REGNUM)
- (compare:CC
- (unspec:SI [(match_operand:PRED_ALL 1)
- (unspec:PRED_ALL
- [(match_operand:GPI 2 "aarch64_reg_or_zero" "rZ")
- (match_operand:GPI 3 "aarch64_reg_or_zero" "rZ")]
- UNSPEC_WHILE_LO)]
- UNSPEC_PTEST_PTRUE)
- (const_int 0)))
- (set (match_operand:PRED_ALL 0 "register_operand" "=Upa")
- (unspec:PRED_ALL [(match_dup 2)
- (match_dup 3)]
- UNSPEC_WHILE_LO))]
- "TARGET_SVE"
- "whilelo\t%0.<PRED_ALL:Vetype>, %<w>2, %<w>3"
- ;; Force the compiler to drop the unused predicate operand, so that we
- ;; don't have an unnecessary PTRUE.
- "&& !CONSTANT_P (operands[1])"
- [(parallel
- [(set (reg:CC CC_REGNUM)
- (compare:CC
- (unspec:SI [(match_dup 1)
- (unspec:PRED_ALL [(match_dup 2)
- (match_dup 3)]
- UNSPEC_WHILE_LO)]
- UNSPEC_PTEST_PTRUE)
- (const_int 0)))
- (set (match_dup 0)
- (unspec:PRED_ALL [(match_dup 2)
- (match_dup 3)]
- UNSPEC_WHILE_LO))])]
- {
- operands[1] = CONSTM1_RTX (<MODE>mode);
- }
- )
-
-
- File: gccint.info, Node: Including Patterns, Next: Peephole Definitions, Prev: Insn Splitting, Up: Machine Desc
-
- 17.17 Including Patterns in Machine Descriptions.
- =================================================
-
- The 'include' pattern tells the compiler tools where to look for
- patterns that are in files other than in the file '.md'. This is used
- only at build time and there is no preprocessing allowed.
-
- It looks like:
-
-
- (include
- PATHNAME)
-
- For example:
-
-
- (include "filestuff")
-
-
- Where PATHNAME is a string that specifies the location of the file,
- specifies the include file to be in 'gcc/config/target/filestuff'. The
- directory 'gcc/config/target' is regarded as the default directory.
-
- Machine descriptions may be split up into smaller more manageable
- subsections and placed into subdirectories.
-
- By specifying:
-
-
- (include "BOGUS/filestuff")
-
-
- the include file is specified to be in
- 'gcc/config/TARGET/BOGUS/filestuff'.
-
- Specifying an absolute path for the include file such as;
-
- (include "/u2/BOGUS/filestuff")
-
- is permitted but is not encouraged.
-
- 17.17.1 RTL Generation Tool Options for Directory Search
- --------------------------------------------------------
-
- The '-IDIR' option specifies directories to search for machine
- descriptions. For example:
-
-
- genrecog -I/p1/abc/proc1 -I/p2/abcd/pro2 target.md
-
-
- Add the directory DIR to the head of the list of directories to be
- searched for header files. This can be used to override a system
- machine definition file, substituting your own version, since these
- directories are searched before the default machine description file
- directories. If you use more than one '-I' option, the directories are
- scanned in left-to-right order; the standard default directory come
- after.
-
-
- File: gccint.info, Node: Peephole Definitions, Next: Insn Attributes, Prev: Including Patterns, Up: Machine Desc
-
- 17.18 Machine-Specific Peephole Optimizers
- ==========================================
-
- In addition to instruction patterns the 'md' file may contain
- definitions of machine-specific peephole optimizations.
-
- The combiner does not notice certain peephole optimizations when the
- data flow in the program does not suggest that it should try them. For
- example, sometimes two consecutive insns related in purpose can be
- combined even though the second one does not appear to use a register
- computed in the first one. A machine-specific peephole optimizer can
- detect such opportunities.
-
- There are two forms of peephole definitions that may be used. The
- original 'define_peephole' is run at assembly output time to match insns
- and substitute assembly text. Use of 'define_peephole' is deprecated.
-
- A newer 'define_peephole2' matches insns and substitutes new insns.
- The 'peephole2' pass is run after register allocation but before
- scheduling, which may result in much better code for targets that do
- scheduling.
-
- * Menu:
-
- * define_peephole:: RTL to Text Peephole Optimizers
- * define_peephole2:: RTL to RTL Peephole Optimizers
-
-
- File: gccint.info, Node: define_peephole, Next: define_peephole2, Up: Peephole Definitions
-
- 17.18.1 RTL to Text Peephole Optimizers
- ---------------------------------------
-
- A definition looks like this:
-
- (define_peephole
- [INSN-PATTERN-1
- INSN-PATTERN-2
- ...]
- "CONDITION"
- "TEMPLATE"
- "OPTIONAL-INSN-ATTRIBUTES")
-
- The last string operand may be omitted if you are not using any
- machine-specific information in this machine description. If present,
- it must obey the same rules as in a 'define_insn'.
-
- In this skeleton, INSN-PATTERN-1 and so on are patterns to match
- consecutive insns. The optimization applies to a sequence of insns when
- INSN-PATTERN-1 matches the first one, INSN-PATTERN-2 matches the next,
- and so on.
-
- Each of the insns matched by a peephole must also match a
- 'define_insn'. Peepholes are checked only at the last stage just before
- code generation, and only optionally. Therefore, any insn which would
- match a peephole but no 'define_insn' will cause a crash in code
- generation in an unoptimized compilation, or at various optimization
- stages.
-
- The operands of the insns are matched with 'match_operands',
- 'match_operator', and 'match_dup', as usual. What is not usual is that
- the operand numbers apply to all the insn patterns in the definition.
- So, you can check for identical operands in two insns by using
- 'match_operand' in one insn and 'match_dup' in the other.
-
- The operand constraints used in 'match_operand' patterns do not have
- any direct effect on the applicability of the peephole, but they will be
- validated afterward, so make sure your constraints are general enough to
- apply whenever the peephole matches. If the peephole matches but the
- constraints are not satisfied, the compiler will crash.
-
- It is safe to omit constraints in all the operands of the peephole; or
- you can write constraints which serve as a double-check on the criteria
- previously tested.
-
- Once a sequence of insns matches the patterns, the CONDITION is
- checked. This is a C expression which makes the final decision whether
- to perform the optimization (we do so if the expression is nonzero). If
- CONDITION is omitted (in other words, the string is empty) then the
- optimization is applied to every sequence of insns that matches the
- patterns.
-
- The defined peephole optimizations are applied after register
- allocation is complete. Therefore, the peephole definition can check
- which operands have ended up in which kinds of registers, just by
- looking at the operands.
-
- The way to refer to the operands in CONDITION is to write 'operands[I]'
- for operand number I (as matched by '(match_operand I ...)'). Use the
- variable 'insn' to refer to the last of the insns being matched; use
- 'prev_active_insn' to find the preceding insns.
-
- When optimizing computations with intermediate results, you can use
- CONDITION to match only when the intermediate results are not used
- elsewhere. Use the C expression 'dead_or_set_p (INSN, OP)', where INSN
- is the insn in which you expect the value to be used for the last time
- (from the value of 'insn', together with use of 'prev_nonnote_insn'),
- and OP is the intermediate value (from 'operands[I]').
-
- Applying the optimization means replacing the sequence of insns with
- one new insn. The TEMPLATE controls ultimate output of assembler code
- for this combined insn. It works exactly like the template of a
- 'define_insn'. Operand numbers in this template are the same ones used
- in matching the original sequence of insns.
-
- The result of a defined peephole optimizer does not need to match any
- of the insn patterns in the machine description; it does not even have
- an opportunity to match them. The peephole optimizer definition itself
- serves as the insn pattern to control how the insn is output.
-
- Defined peephole optimizers are run as assembler code is being output,
- so the insns they produce are never combined or rearranged in any way.
-
- Here is an example, taken from the 68000 machine description:
-
- (define_peephole
- [(set (reg:SI 15) (plus:SI (reg:SI 15) (const_int 4)))
- (set (match_operand:DF 0 "register_operand" "=f")
- (match_operand:DF 1 "register_operand" "ad"))]
- "FP_REG_P (operands[0]) && ! FP_REG_P (operands[1])"
- {
- rtx xoperands[2];
- xoperands[1] = gen_rtx_REG (SImode, REGNO (operands[1]) + 1);
- #ifdef MOTOROLA
- output_asm_insn ("move.l %1,(sp)", xoperands);
- output_asm_insn ("move.l %1,-(sp)", operands);
- return "fmove.d (sp)+,%0";
- #else
- output_asm_insn ("movel %1,sp@", xoperands);
- output_asm_insn ("movel %1,sp@-", operands);
- return "fmoved sp@+,%0";
- #endif
- })
-
- The effect of this optimization is to change
-
- jbsr _foobar
- addql #4,sp
- movel d1,sp@-
- movel d0,sp@-
- fmoved sp@+,fp0
-
- into
-
- jbsr _foobar
- movel d1,sp@
- movel d0,sp@-
- fmoved sp@+,fp0
-
- INSN-PATTERN-1 and so on look _almost_ like the second operand of
- 'define_insn'. There is one important difference: the second operand of
- 'define_insn' consists of one or more RTX's enclosed in square brackets.
- Usually, there is only one: then the same action can be written as an
- element of a 'define_peephole'. But when there are multiple actions in
- a 'define_insn', they are implicitly enclosed in a 'parallel'. Then you
- must explicitly write the 'parallel', and the square brackets within it,
- in the 'define_peephole'. Thus, if an insn pattern looks like this,
-
- (define_insn "divmodsi4"
- [(set (match_operand:SI 0 "general_operand" "=d")
- (div:SI (match_operand:SI 1 "general_operand" "0")
- (match_operand:SI 2 "general_operand" "dmsK")))
- (set (match_operand:SI 3 "general_operand" "=d")
- (mod:SI (match_dup 1) (match_dup 2)))]
- "TARGET_68020"
- "divsl%.l %2,%3:%0")
-
- then the way to mention this insn in a peephole is as follows:
-
- (define_peephole
- [...
- (parallel
- [(set (match_operand:SI 0 "general_operand" "=d")
- (div:SI (match_operand:SI 1 "general_operand" "0")
- (match_operand:SI 2 "general_operand" "dmsK")))
- (set (match_operand:SI 3 "general_operand" "=d")
- (mod:SI (match_dup 1) (match_dup 2)))])
- ...]
- ...)
-
-
- File: gccint.info, Node: define_peephole2, Prev: define_peephole, Up: Peephole Definitions
-
- 17.18.2 RTL to RTL Peephole Optimizers
- --------------------------------------
-
- The 'define_peephole2' definition tells the compiler how to substitute
- one sequence of instructions for another sequence, what additional
- scratch registers may be needed and what their lifetimes must be.
-
- (define_peephole2
- [INSN-PATTERN-1
- INSN-PATTERN-2
- ...]
- "CONDITION"
- [NEW-INSN-PATTERN-1
- NEW-INSN-PATTERN-2
- ...]
- "PREPARATION-STATEMENTS")
-
- The definition is almost identical to 'define_split' (*note Insn
- Splitting::) except that the pattern to match is not a single
- instruction, but a sequence of instructions.
-
- It is possible to request additional scratch registers for use in the
- output template. If appropriate registers are not free, the pattern
- will simply not match.
-
- Scratch registers are requested with a 'match_scratch' pattern at the
- top level of the input pattern. The allocated register (initially) will
- be dead at the point requested within the original sequence. If the
- scratch is used at more than a single point, a 'match_dup' pattern at
- the top level of the input pattern marks the last position in the input
- sequence at which the register must be available.
-
- Here is an example from the IA-32 machine description:
-
- (define_peephole2
- [(match_scratch:SI 2 "r")
- (parallel [(set (match_operand:SI 0 "register_operand" "")
- (match_operator:SI 3 "arith_or_logical_operator"
- [(match_dup 0)
- (match_operand:SI 1 "memory_operand" "")]))
- (clobber (reg:CC 17))])]
- "! optimize_size && ! TARGET_READ_MODIFY"
- [(set (match_dup 2) (match_dup 1))
- (parallel [(set (match_dup 0)
- (match_op_dup 3 [(match_dup 0) (match_dup 2)]))
- (clobber (reg:CC 17))])]
- "")
-
- This pattern tries to split a load from its use in the hopes that we'll
- be able to schedule around the memory load latency. It allocates a
- single 'SImode' register of class 'GENERAL_REGS' ('"r"') that needs to
- be live only at the point just before the arithmetic.
-
- A real example requiring extended scratch lifetimes is harder to come
- by, so here's a silly made-up example:
-
- (define_peephole2
- [(match_scratch:SI 4 "r")
- (set (match_operand:SI 0 "" "") (match_operand:SI 1 "" ""))
- (set (match_operand:SI 2 "" "") (match_dup 1))
- (match_dup 4)
- (set (match_operand:SI 3 "" "") (match_dup 1))]
- "/* determine 1 does not overlap 0 and 2 */"
- [(set (match_dup 4) (match_dup 1))
- (set (match_dup 0) (match_dup 4))
- (set (match_dup 2) (match_dup 4))
- (set (match_dup 3) (match_dup 4))]
- "")
-
- There are two special macros defined for use in the preparation
- statements: 'DONE' and 'FAIL'. Use them with a following semicolon, as
- a statement.
-
- 'DONE'
- Use the 'DONE' macro to end RTL generation for the peephole. The
- only RTL insns generated as replacement for the matched input insn
- will be those already emitted by explicit calls to 'emit_insn'
- within the preparation statements; the replacement pattern is not
- used.
-
- 'FAIL'
- Make the 'define_peephole2' fail on this occasion. When a
- 'define_peephole2' fails, it means that the replacement was not
- truly available for the particular inputs it was given. In that
- case, GCC may still apply a later 'define_peephole2' that also
- matches the given insn pattern. (Note that this is different from
- 'define_split', where 'FAIL' prevents the input insn from being
- split at all.)
-
- If the preparation falls through (invokes neither 'DONE' nor 'FAIL'),
- then the 'define_peephole2' uses the replacement template.
-
- If we had not added the '(match_dup 4)' in the middle of the input
- sequence, it might have been the case that the register we chose at the
- beginning of the sequence is killed by the first or second 'set'.
-
-
- File: gccint.info, Node: Insn Attributes, Next: Conditional Execution, Prev: Peephole Definitions, Up: Machine Desc
-
- 17.19 Instruction Attributes
- ============================
-
- In addition to describing the instruction supported by the target
- machine, the 'md' file also defines a group of "attributes" and a set of
- values for each. Every generated insn is assigned a value for each
- attribute. One possible attribute would be the effect that the insn has
- on the machine's condition code. This attribute can then be used by
- 'NOTICE_UPDATE_CC' to track the condition codes.
-
- * Menu:
-
- * Defining Attributes:: Specifying attributes and their values.
- * Expressions:: Valid expressions for attribute values.
- * Tagging Insns:: Assigning attribute values to insns.
- * Attr Example:: An example of assigning attributes.
- * Insn Lengths:: Computing the length of insns.
- * Constant Attributes:: Defining attributes that are constant.
- * Mnemonic Attribute:: Obtain the instruction mnemonic as attribute value.
- * Delay Slots:: Defining delay slots required for a machine.
- * Processor pipeline description:: Specifying information for insn scheduling.
-
-
- File: gccint.info, Node: Defining Attributes, Next: Expressions, Up: Insn Attributes
-
- 17.19.1 Defining Attributes and their Values
- --------------------------------------------
-
- The 'define_attr' expression is used to define each attribute required
- by the target machine. It looks like:
-
- (define_attr NAME LIST-OF-VALUES DEFAULT)
-
- NAME is a string specifying the name of the attribute being defined.
- Some attributes are used in a special way by the rest of the compiler.
- The 'enabled' attribute can be used to conditionally enable or disable
- insn alternatives (*note Disable Insn Alternatives::). The 'predicable'
- attribute, together with a suitable 'define_cond_exec' (*note
- Conditional Execution::), can be used to automatically generate
- conditional variants of instruction patterns. The 'mnemonic' attribute
- can be used to check for the instruction mnemonic (*note Mnemonic
- Attribute::). The compiler internally uses the names 'ce_enabled' and
- 'nonce_enabled', so they should not be used elsewhere as alternative
- names.
-
- LIST-OF-VALUES is either a string that specifies a comma-separated list
- of values that can be assigned to the attribute, or a null string to
- indicate that the attribute takes numeric values.
-
- DEFAULT is an attribute expression that gives the value of this
- attribute for insns that match patterns whose definition does not
- include an explicit value for this attribute. *Note Attr Example::, for
- more information on the handling of defaults. *Note Constant
- Attributes::, for information on attributes that do not depend on any
- particular insn.
-
- For each defined attribute, a number of definitions are written to the
- 'insn-attr.h' file. For cases where an explicit set of values is
- specified for an attribute, the following are defined:
-
- * A '#define' is written for the symbol 'HAVE_ATTR_NAME'.
-
- * An enumerated class is defined for 'attr_NAME' with elements of the
- form 'UPPER-NAME_UPPER-VALUE' where the attribute name and value
- are first converted to uppercase.
-
- * A function 'get_attr_NAME' is defined that is passed an insn and
- returns the attribute value for that insn.
-
- For example, if the following is present in the 'md' file:
-
- (define_attr "type" "branch,fp,load,store,arith" ...)
-
- the following lines will be written to the file 'insn-attr.h'.
-
- #define HAVE_ATTR_type 1
- enum attr_type {TYPE_BRANCH, TYPE_FP, TYPE_LOAD,
- TYPE_STORE, TYPE_ARITH};
- extern enum attr_type get_attr_type ();
-
- If the attribute takes numeric values, no 'enum' type will be defined
- and the function to obtain the attribute's value will return 'int'.
-
- There are attributes which are tied to a specific meaning. These
- attributes are not free to use for other purposes:
-
- 'length'
- The 'length' attribute is used to calculate the length of emitted
- code chunks. This is especially important when verifying branch
- distances. *Note Insn Lengths::.
-
- 'enabled'
- The 'enabled' attribute can be defined to prevent certain
- alternatives of an insn definition from being used during code
- generation. *Note Disable Insn Alternatives::.
-
- 'mnemonic'
- The 'mnemonic' attribute can be defined to implement instruction
- specific checks in e.g. the pipeline description. *Note Mnemonic
- Attribute::.
-
- For each of these special attributes, the corresponding
- 'HAVE_ATTR_NAME' '#define' is also written when the attribute is not
- defined; in that case, it is defined as '0'.
-
- Another way of defining an attribute is to use:
-
- (define_enum_attr "ATTR" "ENUM" DEFAULT)
-
- This works in just the same way as 'define_attr', except that the list
- of values is taken from a separate enumeration called ENUM (*note
- define_enum::). This form allows you to use the same list of values for
- several attributes without having to repeat the list each time. For
- example:
-
- (define_enum "processor" [
- model_a
- model_b
- ...
- ])
- (define_enum_attr "arch" "processor"
- (const (symbol_ref "target_arch")))
- (define_enum_attr "tune" "processor"
- (const (symbol_ref "target_tune")))
-
- defines the same attributes as:
-
- (define_attr "arch" "model_a,model_b,..."
- (const (symbol_ref "target_arch")))
- (define_attr "tune" "model_a,model_b,..."
- (const (symbol_ref "target_tune")))
-
- but without duplicating the processor list. The second example defines
- two separate C enums ('attr_arch' and 'attr_tune') whereas the first
- defines a single C enum ('processor').
-
-
- File: gccint.info, Node: Expressions, Next: Tagging Insns, Prev: Defining Attributes, Up: Insn Attributes
-
- 17.19.2 Attribute Expressions
- -----------------------------
-
- RTL expressions used to define attributes use the codes described above
- plus a few specific to attribute definitions, to be discussed below.
- Attribute value expressions must have one of the following forms:
-
- '(const_int I)'
- The integer I specifies the value of a numeric attribute. I must
- be non-negative.
-
- The value of a numeric attribute can be specified either with a
- 'const_int', or as an integer represented as a string in
- 'const_string', 'eq_attr' (see below), 'attr', 'symbol_ref', simple
- arithmetic expressions, and 'set_attr' overrides on specific
- instructions (*note Tagging Insns::).
-
- '(const_string VALUE)'
- The string VALUE specifies a constant attribute value. If VALUE is
- specified as '"*"', it means that the default value of the
- attribute is to be used for the insn containing this expression.
- '"*"' obviously cannot be used in the DEFAULT expression of a
- 'define_attr'.
-
- If the attribute whose value is being specified is numeric, VALUE
- must be a string containing a non-negative integer (normally
- 'const_int' would be used in this case). Otherwise, it must
- contain one of the valid values for the attribute.
-
- '(if_then_else TEST TRUE-VALUE FALSE-VALUE)'
- TEST specifies an attribute test, whose format is defined below.
- The value of this expression is TRUE-VALUE if TEST is true,
- otherwise it is FALSE-VALUE.
-
- '(cond [TEST1 VALUE1 ...] DEFAULT)'
- The first operand of this expression is a vector containing an even
- number of expressions and consisting of pairs of TEST and VALUE
- expressions. The value of the 'cond' expression is that of the
- VALUE corresponding to the first true TEST expression. If none of
- the TEST expressions are true, the value of the 'cond' expression
- is that of the DEFAULT expression.
-
- TEST expressions can have one of the following forms:
-
- '(const_int I)'
- This test is true if I is nonzero and false otherwise.
-
- '(not TEST)'
- '(ior TEST1 TEST2)'
- '(and TEST1 TEST2)'
- These tests are true if the indicated logical function is true.
-
- '(match_operand:M N PRED CONSTRAINTS)'
- This test is true if operand N of the insn whose attribute value is
- being determined has mode M (this part of the test is ignored if M
- is 'VOIDmode') and the function specified by the string PRED
- returns a nonzero value when passed operand N and mode M (this part
- of the test is ignored if PRED is the null string).
-
- The CONSTRAINTS operand is ignored and should be the null string.
-
- '(match_test C-EXPR)'
- The test is true if C expression C-EXPR is true. In non-constant
- attributes, C-EXPR has access to the following variables:
-
- INSN
- The rtl instruction under test.
- WHICH_ALTERNATIVE
- The 'define_insn' alternative that INSN matches. *Note Output
- Statement::.
- OPERANDS
- An array of INSN's rtl operands.
-
- C-EXPR behaves like the condition in a C 'if' statement, so there
- is no need to explicitly convert the expression into a boolean 0 or
- 1 value. For example, the following two tests are equivalent:
-
- (match_test "x & 2")
- (match_test "(x & 2) != 0")
-
- '(le ARITH1 ARITH2)'
- '(leu ARITH1 ARITH2)'
- '(lt ARITH1 ARITH2)'
- '(ltu ARITH1 ARITH2)'
- '(gt ARITH1 ARITH2)'
- '(gtu ARITH1 ARITH2)'
- '(ge ARITH1 ARITH2)'
- '(geu ARITH1 ARITH2)'
- '(ne ARITH1 ARITH2)'
- '(eq ARITH1 ARITH2)'
- These tests are true if the indicated comparison of the two
- arithmetic expressions is true. Arithmetic expressions are formed
- with 'plus', 'minus', 'mult', 'div', 'mod', 'abs', 'neg', 'and',
- 'ior', 'xor', 'not', 'ashift', 'lshiftrt', and 'ashiftrt'
- expressions.
-
- 'const_int' and 'symbol_ref' are always valid terms (*note Insn
- Lengths::,for additional forms). 'symbol_ref' is a string denoting
- a C expression that yields an 'int' when evaluated by the
- 'get_attr_...' routine. It should normally be a global variable.
-
- '(eq_attr NAME VALUE)'
- NAME is a string specifying the name of an attribute.
-
- VALUE is a string that is either a valid value for attribute NAME,
- a comma-separated list of values, or '!' followed by a value or
- list. If VALUE does not begin with a '!', this test is true if the
- value of the NAME attribute of the current insn is in the list
- specified by VALUE. If VALUE begins with a '!', this test is true
- if the attribute's value is _not_ in the specified list.
-
- For example,
-
- (eq_attr "type" "load,store")
-
- is equivalent to
-
- (ior (eq_attr "type" "load") (eq_attr "type" "store"))
-
- If NAME specifies an attribute of 'alternative', it refers to the
- value of the compiler variable 'which_alternative' (*note Output
- Statement::) and the values must be small integers. For example,
-
- (eq_attr "alternative" "2,3")
-
- is equivalent to
-
- (ior (eq (symbol_ref "which_alternative") (const_int 2))
- (eq (symbol_ref "which_alternative") (const_int 3)))
-
- Note that, for most attributes, an 'eq_attr' test is simplified in
- cases where the value of the attribute being tested is known for
- all insns matching a particular pattern. This is by far the most
- common case.
-
- '(attr_flag NAME)'
- The value of an 'attr_flag' expression is true if the flag
- specified by NAME is true for the 'insn' currently being scheduled.
-
- NAME is a string specifying one of a fixed set of flags to test.
- Test the flags 'forward' and 'backward' to determine the direction
- of a conditional branch.
-
- This example describes a conditional branch delay slot which can be
- nullified for forward branches that are taken (annul-true) or for
- backward branches which are not taken (annul-false).
-
- (define_delay (eq_attr "type" "cbranch")
- [(eq_attr "in_branch_delay" "true")
- (and (eq_attr "in_branch_delay" "true")
- (attr_flag "forward"))
- (and (eq_attr "in_branch_delay" "true")
- (attr_flag "backward"))])
-
- The 'forward' and 'backward' flags are false if the current 'insn'
- being scheduled is not a conditional branch.
-
- 'attr_flag' is only used during delay slot scheduling and has no
- meaning to other passes of the compiler.
-
- '(attr NAME)'
- The value of another attribute is returned. This is most useful
- for numeric attributes, as 'eq_attr' and 'attr_flag' produce more
- efficient code for non-numeric attributes.
-
-
- File: gccint.info, Node: Tagging Insns, Next: Attr Example, Prev: Expressions, Up: Insn Attributes
-
- 17.19.3 Assigning Attribute Values to Insns
- -------------------------------------------
-
- The value assigned to an attribute of an insn is primarily determined by
- which pattern is matched by that insn (or which 'define_peephole'
- generated it). Every 'define_insn' and 'define_peephole' can have an
- optional last argument to specify the values of attributes for matching
- insns. The value of any attribute not specified in a particular insn is
- set to the default value for that attribute, as specified in its
- 'define_attr'. Extensive use of default values for attributes permits
- the specification of the values for only one or two attributes in the
- definition of most insn patterns, as seen in the example in the next
- section.
-
- The optional last argument of 'define_insn' and 'define_peephole' is a
- vector of expressions, each of which defines the value for a single
- attribute. The most general way of assigning an attribute's value is to
- use a 'set' expression whose first operand is an 'attr' expression
- giving the name of the attribute being set. The second operand of the
- 'set' is an attribute expression (*note Expressions::) giving the value
- of the attribute.
-
- When the attribute value depends on the 'alternative' attribute (i.e.,
- which is the applicable alternative in the constraint of the insn), the
- 'set_attr_alternative' expression can be used. It allows the
- specification of a vector of attribute expressions, one for each
- alternative.
-
- When the generality of arbitrary attribute expressions is not required,
- the simpler 'set_attr' expression can be used, which allows specifying a
- string giving either a single attribute value or a list of attribute
- values, one for each alternative.
-
- The form of each of the above specifications is shown below. In each
- case, NAME is a string specifying the attribute to be set.
-
- '(set_attr NAME VALUE-STRING)'
- VALUE-STRING is either a string giving the desired attribute value,
- or a string containing a comma-separated list giving the values for
- succeeding alternatives. The number of elements must match the
- number of alternatives in the constraint of the insn pattern.
-
- Note that it may be useful to specify '*' for some alternative, in
- which case the attribute will assume its default value for insns
- matching that alternative.
-
- '(set_attr_alternative NAME [VALUE1 VALUE2 ...])'
- Depending on the alternative of the insn, the value will be one of
- the specified values. This is a shorthand for using a 'cond' with
- tests on the 'alternative' attribute.
-
- '(set (attr NAME) VALUE)'
- The first operand of this 'set' must be the special RTL expression
- 'attr', whose sole operand is a string giving the name of the
- attribute being set. VALUE is the value of the attribute.
-
- The following shows three different ways of representing the same
- attribute value specification:
-
- (set_attr "type" "load,store,arith")
-
- (set_attr_alternative "type"
- [(const_string "load") (const_string "store")
- (const_string "arith")])
-
- (set (attr "type")
- (cond [(eq_attr "alternative" "1") (const_string "load")
- (eq_attr "alternative" "2") (const_string "store")]
- (const_string "arith")))
-
- The 'define_asm_attributes' expression provides a mechanism to specify
- the attributes assigned to insns produced from an 'asm' statement. It
- has the form:
-
- (define_asm_attributes [ATTR-SETS])
-
- where ATTR-SETS is specified the same as for both the 'define_insn' and
- the 'define_peephole' expressions.
-
- These values will typically be the "worst case" attribute values. For
- example, they might indicate that the condition code will be clobbered.
-
- A specification for a 'length' attribute is handled specially. The way
- to compute the length of an 'asm' insn is to multiply the length
- specified in the expression 'define_asm_attributes' by the number of
- machine instructions specified in the 'asm' statement, determined by
- counting the number of semicolons and newlines in the string.
- Therefore, the value of the 'length' attribute specified in a
- 'define_asm_attributes' should be the maximum possible length of a
- single machine instruction.
-
-
- File: gccint.info, Node: Attr Example, Next: Insn Lengths, Prev: Tagging Insns, Up: Insn Attributes
-
- 17.19.4 Example of Attribute Specifications
- -------------------------------------------
-
- The judicious use of defaulting is important in the efficient use of
- insn attributes. Typically, insns are divided into "types" and an
- attribute, customarily called 'type', is used to represent this value.
- This attribute is normally used only to define the default value for
- other attributes. An example will clarify this usage.
-
- Assume we have a RISC machine with a condition code and in which only
- full-word operations are performed in registers. Let us assume that we
- can divide all insns into loads, stores, (integer) arithmetic
- operations, floating point operations, and branches.
-
- Here we will concern ourselves with determining the effect of an insn
- on the condition code and will limit ourselves to the following possible
- effects: The condition code can be set unpredictably (clobbered), not be
- changed, be set to agree with the results of the operation, or only
- changed if the item previously set into the condition code has been
- modified.
-
- Here is part of a sample 'md' file for such a machine:
-
- (define_attr "type" "load,store,arith,fp,branch" (const_string "arith"))
-
- (define_attr "cc" "clobber,unchanged,set,change0"
- (cond [(eq_attr "type" "load")
- (const_string "change0")
- (eq_attr "type" "store,branch")
- (const_string "unchanged")
- (eq_attr "type" "arith")
- (if_then_else (match_operand:SI 0 "" "")
- (const_string "set")
- (const_string "clobber"))]
- (const_string "clobber")))
-
- (define_insn ""
- [(set (match_operand:SI 0 "general_operand" "=r,r,m")
- (match_operand:SI 1 "general_operand" "r,m,r"))]
- ""
- "@
- move %0,%1
- load %0,%1
- store %0,%1"
- [(set_attr "type" "arith,load,store")])
-
- Note that we assume in the above example that arithmetic operations
- performed on quantities smaller than a machine word clobber the
- condition code since they will set the condition code to a value
- corresponding to the full-word result.
-
-
- File: gccint.info, Node: Insn Lengths, Next: Constant Attributes, Prev: Attr Example, Up: Insn Attributes
-
- 17.19.5 Computing the Length of an Insn
- ---------------------------------------
-
- For many machines, multiple types of branch instructions are provided,
- each for different length branch displacements. In most cases, the
- assembler will choose the correct instruction to use. However, when the
- assembler cannot do so, GCC can when a special attribute, the 'length'
- attribute, is defined. This attribute must be defined to have numeric
- values by specifying a null string in its 'define_attr'.
-
- In the case of the 'length' attribute, two additional forms of
- arithmetic terms are allowed in test expressions:
-
- '(match_dup N)'
- This refers to the address of operand N of the current insn, which
- must be a 'label_ref'.
-
- '(pc)'
- For non-branch instructions and backward branch instructions, this
- refers to the address of the current insn. But for forward branch
- instructions, this refers to the address of the next insn, because
- the length of the current insn is to be computed.
-
- For normal insns, the length will be determined by value of the
- 'length' attribute. In the case of 'addr_vec' and 'addr_diff_vec' insn
- patterns, the length is computed as the number of vectors multiplied by
- the size of each vector.
-
- Lengths are measured in addressable storage units (bytes).
-
- Note that it is possible to call functions via the 'symbol_ref'
- mechanism to compute the length of an insn. However, if you use this
- mechanism you must provide dummy clauses to express the maximum length
- without using the function call. You can an example of this in the 'pa'
- machine description for the 'call_symref' pattern.
-
- The following macros can be used to refine the length computation:
-
- 'ADJUST_INSN_LENGTH (INSN, LENGTH)'
- If defined, modifies the length assigned to instruction INSN as a
- function of the context in which it is used. LENGTH is an lvalue
- that contains the initially computed length of the insn and should
- be updated with the correct length of the insn.
-
- This macro will normally not be required. A case in which it is
- required is the ROMP. On this machine, the size of an 'addr_vec'
- insn must be increased by two to compensate for the fact that
- alignment may be required.
-
- The routine that returns 'get_attr_length' (the value of the 'length'
- attribute) can be used by the output routine to determine the form of
- the branch instruction to be written, as the example below illustrates.
-
- As an example of the specification of variable-length branches,
- consider the IBM 360. If we adopt the convention that a register will
- be set to the starting address of a function, we can jump to labels
- within 4k of the start using a four-byte instruction. Otherwise, we
- need a six-byte sequence to load the address from memory and then branch
- to it.
-
- On such a machine, a pattern for a branch instruction might be
- specified as follows:
-
- (define_insn "jump"
- [(set (pc)
- (label_ref (match_operand 0 "" "")))]
- ""
- {
- return (get_attr_length (insn) == 4
- ? "b %l0" : "l r15,=a(%l0); br r15");
- }
- [(set (attr "length")
- (if_then_else (lt (match_dup 0) (const_int 4096))
- (const_int 4)
- (const_int 6)))])
-
-
- File: gccint.info, Node: Constant Attributes, Next: Mnemonic Attribute, Prev: Insn Lengths, Up: Insn Attributes
-
- 17.19.6 Constant Attributes
- ---------------------------
-
- A special form of 'define_attr', where the expression for the default
- value is a 'const' expression, indicates an attribute that is constant
- for a given run of the compiler. Constant attributes may be used to
- specify which variety of processor is used. For example,
-
- (define_attr "cpu" "m88100,m88110,m88000"
- (const
- (cond [(symbol_ref "TARGET_88100") (const_string "m88100")
- (symbol_ref "TARGET_88110") (const_string "m88110")]
- (const_string "m88000"))))
-
- (define_attr "memory" "fast,slow"
- (const
- (if_then_else (symbol_ref "TARGET_FAST_MEM")
- (const_string "fast")
- (const_string "slow"))))
-
- The routine generated for constant attributes has no parameters as it
- does not depend on any particular insn. RTL expressions used to define
- the value of a constant attribute may use the 'symbol_ref' form, but may
- not use either the 'match_operand' form or 'eq_attr' forms involving
- insn attributes.
-
-
- File: gccint.info, Node: Mnemonic Attribute, Next: Delay Slots, Prev: Constant Attributes, Up: Insn Attributes
-
- 17.19.7 Mnemonic Attribute
- --------------------------
-
- The 'mnemonic' attribute is a string type attribute holding the
- instruction mnemonic for an insn alternative. The attribute values will
- automatically be generated by the machine description parser if there is
- an attribute definition in the md file:
-
- (define_attr "mnemonic" "unknown" (const_string "unknown"))
-
- The default value can be freely chosen as long as it does not collide
- with any of the instruction mnemonics. This value will be used whenever
- the machine description parser is not able to determine the mnemonic
- string. This might be the case for output templates containing more
- than a single instruction as in '"mvcle\t%0,%1,0\;jo\t.-4"'.
-
- The 'mnemonic' attribute set is not generated automatically if the
- instruction string is generated via C code.
-
- An existing 'mnemonic' attribute set in an insn definition will not be
- overriden by the md file parser. That way it is possible to manually
- set the instruction mnemonics for the cases where the md file parser
- fails to determine it automatically.
-
- The 'mnemonic' attribute is useful for dealing with instruction
- specific properties in the pipeline description without defining
- additional insn attributes.
-
- (define_attr "ooo_expanded" ""
- (cond [(eq_attr "mnemonic" "dlr,dsgr,d,dsgf,stam,dsgfr,dlgr")
- (const_int 1)]
- (const_int 0)))
-
-
- File: gccint.info, Node: Delay Slots, Next: Processor pipeline description, Prev: Mnemonic Attribute, Up: Insn Attributes
-
- 17.19.8 Delay Slot Scheduling
- -----------------------------
-
- The insn attribute mechanism can be used to specify the requirements for
- delay slots, if any, on a target machine. An instruction is said to
- require a "delay slot" if some instructions that are physically after
- the instruction are executed as if they were located before it. Classic
- examples are branch and call instructions, which often execute the
- following instruction before the branch or call is performed.
-
- On some machines, conditional branch instructions can optionally
- "annul" instructions in the delay slot. This means that the instruction
- will not be executed for certain branch outcomes. Both instructions
- that annul if the branch is true and instructions that annul if the
- branch is false are supported.
-
- Delay slot scheduling differs from instruction scheduling in that
- determining whether an instruction needs a delay slot is dependent only
- on the type of instruction being generated, not on data flow between the
- instructions. See the next section for a discussion of data-dependent
- instruction scheduling.
-
- The requirement of an insn needing one or more delay slots is indicated
- via the 'define_delay' expression. It has the following form:
-
- (define_delay TEST
- [DELAY-1 ANNUL-TRUE-1 ANNUL-FALSE-1
- DELAY-2 ANNUL-TRUE-2 ANNUL-FALSE-2
- ...])
-
- TEST is an attribute test that indicates whether this 'define_delay'
- applies to a particular insn. If so, the number of required delay slots
- is determined by the length of the vector specified as the second
- argument. An insn placed in delay slot N must satisfy attribute test
- DELAY-N. ANNUL-TRUE-N is an attribute test that specifies which insns
- may be annulled if the branch is true. Similarly, ANNUL-FALSE-N
- specifies which insns in the delay slot may be annulled if the branch is
- false. If annulling is not supported for that delay slot, '(nil)'
- should be coded.
-
- For example, in the common case where branch and call insns require a
- single delay slot, which may contain any insn other than a branch or
- call, the following would be placed in the 'md' file:
-
- (define_delay (eq_attr "type" "branch,call")
- [(eq_attr "type" "!branch,call") (nil) (nil)])
-
- Multiple 'define_delay' expressions may be specified. In this case,
- each such expression specifies different delay slot requirements and
- there must be no insn for which tests in two 'define_delay' expressions
- are both true.
-
- For example, if we have a machine that requires one delay slot for
- branches but two for calls, no delay slot can contain a branch or call
- insn, and any valid insn in the delay slot for the branch can be
- annulled if the branch is true, we might represent this as follows:
-
- (define_delay (eq_attr "type" "branch")
- [(eq_attr "type" "!branch,call")
- (eq_attr "type" "!branch,call")
- (nil)])
-
- (define_delay (eq_attr "type" "call")
- [(eq_attr "type" "!branch,call") (nil) (nil)
- (eq_attr "type" "!branch,call") (nil) (nil)])
-
-
- File: gccint.info, Node: Processor pipeline description, Prev: Delay Slots, Up: Insn Attributes
-
- 17.19.9 Specifying processor pipeline description
- -------------------------------------------------
-
- To achieve better performance, most modern processors (super-pipelined,
- superscalar RISC, and VLIW processors) have many "functional units" on
- which several instructions can be executed simultaneously. An
- instruction starts execution if its issue conditions are satisfied. If
- not, the instruction is stalled until its conditions are satisfied.
- Such "interlock (pipeline) delay" causes interruption of the fetching of
- successor instructions (or demands nop instructions, e.g. for some MIPS
- processors).
-
- There are two major kinds of interlock delays in modern processors.
- The first one is a data dependence delay determining "instruction
- latency time". The instruction execution is not started until all
- source data have been evaluated by prior instructions (there are more
- complex cases when the instruction execution starts even when the data
- are not available but will be ready in given time after the instruction
- execution start). Taking the data dependence delays into account is
- simple. The data dependence (true, output, and anti-dependence) delay
- between two instructions is given by a constant. In most cases this
- approach is adequate. The second kind of interlock delays is a
- reservation delay. The reservation delay means that two instructions
- under execution will be in need of shared processors resources, i.e.
- buses, internal registers, and/or functional units, which are reserved
- for some time. Taking this kind of delay into account is complex
- especially for modern RISC processors.
-
- The task of exploiting more processor parallelism is solved by an
- instruction scheduler. For a better solution to this problem, the
- instruction scheduler has to have an adequate description of the
- processor parallelism (or "pipeline description"). GCC machine
- descriptions describe processor parallelism and functional unit
- reservations for groups of instructions with the aid of "regular
- expressions".
-
- The GCC instruction scheduler uses a "pipeline hazard recognizer" to
- figure out the possibility of the instruction issue by the processor on
- a given simulated processor cycle. The pipeline hazard recognizer is
- automatically generated from the processor pipeline description. The
- pipeline hazard recognizer generated from the machine description is
- based on a deterministic finite state automaton (DFA): the instruction
- issue is possible if there is a transition from one automaton state to
- another one. This algorithm is very fast, and furthermore, its speed is
- not dependent on processor complexity(1).
-
- The rest of this section describes the directives that constitute an
- automaton-based processor pipeline description. The order of these
- constructions within the machine description file is not important.
-
- The following optional construction describes names of automata
- generated and used for the pipeline hazards recognition. Sometimes the
- generated finite state automaton used by the pipeline hazard recognizer
- is large. If we use more than one automaton and bind functional units
- to the automata, the total size of the automata is usually less than the
- size of the single automaton. If there is no one such construction,
- only one finite state automaton is generated.
-
- (define_automaton AUTOMATA-NAMES)
-
- AUTOMATA-NAMES is a string giving names of the automata. The names are
- separated by commas. All the automata should have unique names. The
- automaton name is used in the constructions 'define_cpu_unit' and
- 'define_query_cpu_unit'.
-
- Each processor functional unit used in the description of instruction
- reservations should be described by the following construction.
-
- (define_cpu_unit UNIT-NAMES [AUTOMATON-NAME])
-
- UNIT-NAMES is a string giving the names of the functional units
- separated by commas. Don't use name 'nothing', it is reserved for other
- goals.
-
- AUTOMATON-NAME is a string giving the name of the automaton with which
- the unit is bound. The automaton should be described in construction
- 'define_automaton'. You should give "automaton-name", if there is a
- defined automaton.
-
- The assignment of units to automata are constrained by the uses of the
- units in insn reservations. The most important constraint is: if a unit
- reservation is present on a particular cycle of an alternative for an
- insn reservation, then some unit from the same automaton must be present
- on the same cycle for the other alternatives of the insn reservation.
- The rest of the constraints are mentioned in the description of the
- subsequent constructions.
-
- The following construction describes CPU functional units analogously
- to 'define_cpu_unit'. The reservation of such units can be queried for
- an automaton state. The instruction scheduler never queries reservation
- of functional units for given automaton state. So as a rule, you don't
- need this construction. This construction could be used for future code
- generation goals (e.g. to generate VLIW insn templates).
-
- (define_query_cpu_unit UNIT-NAMES [AUTOMATON-NAME])
-
- UNIT-NAMES is a string giving names of the functional units separated
- by commas.
-
- AUTOMATON-NAME is a string giving the name of the automaton with which
- the unit is bound.
-
- The following construction is the major one to describe pipeline
- characteristics of an instruction.
-
- (define_insn_reservation INSN-NAME DEFAULT_LATENCY
- CONDITION REGEXP)
-
- DEFAULT_LATENCY is a number giving latency time of the instruction.
- There is an important difference between the old description and the
- automaton based pipeline description. The latency time is used for all
- dependencies when we use the old description. In the automaton based
- pipeline description, the given latency time is only used for true
- dependencies. The cost of anti-dependencies is always zero and the cost
- of output dependencies is the difference between latency times of the
- producing and consuming insns (if the difference is negative, the cost
- is considered to be zero). You can always change the default costs for
- any description by using the target hook 'TARGET_SCHED_ADJUST_COST'
- (*note Scheduling::).
-
- INSN-NAME is a string giving the internal name of the insn. The
- internal names are used in constructions 'define_bypass' and in the
- automaton description file generated for debugging. The internal name
- has nothing in common with the names in 'define_insn'. It is a good
- practice to use insn classes described in the processor manual.
-
- CONDITION defines what RTL insns are described by this construction.
- You should remember that you will be in trouble if CONDITION for two or
- more different 'define_insn_reservation' constructions is TRUE for an
- insn. In this case what reservation will be used for the insn is not
- defined. Such cases are not checked during generation of the pipeline
- hazards recognizer because in general recognizing that two conditions
- may have the same value is quite difficult (especially if the conditions
- contain 'symbol_ref'). It is also not checked during the pipeline
- hazard recognizer work because it would slow down the recognizer
- considerably.
-
- REGEXP is a string describing the reservation of the cpu's functional
- units by the instruction. The reservations are described by a regular
- expression according to the following syntax:
-
- regexp = regexp "," oneof
- | oneof
-
- oneof = oneof "|" allof
- | allof
-
- allof = allof "+" repeat
- | repeat
-
- repeat = element "*" number
- | element
-
- element = cpu_function_unit_name
- | reservation_name
- | result_name
- | "nothing"
- | "(" regexp ")"
-
- * ',' is used for describing the start of the next cycle in the
- reservation.
-
- * '|' is used for describing a reservation described by the first
- regular expression *or* a reservation described by the second
- regular expression *or* etc.
-
- * '+' is used for describing a reservation described by the first
- regular expression *and* a reservation described by the second
- regular expression *and* etc.
-
- * '*' is used for convenience and simply means a sequence in which
- the regular expression are repeated NUMBER times with cycle
- advancing (see ',').
-
- * 'cpu_function_unit_name' denotes reservation of the named
- functional unit.
-
- * 'reservation_name' -- see description of construction
- 'define_reservation'.
-
- * 'nothing' denotes no unit reservations.
-
- Sometimes unit reservations for different insns contain common parts.
- In such case, you can simplify the pipeline description by describing
- the common part by the following construction
-
- (define_reservation RESERVATION-NAME REGEXP)
-
- RESERVATION-NAME is a string giving name of REGEXP. Functional unit
- names and reservation names are in the same name space. So the
- reservation names should be different from the functional unit names and
- cannot be the reserved name 'nothing'.
-
- The following construction is used to describe exceptions in the
- latency time for given instruction pair. This is so called bypasses.
-
- (define_bypass NUMBER OUT_INSN_NAMES IN_INSN_NAMES
- [GUARD])
-
- NUMBER defines when the result generated by the instructions given in
- string OUT_INSN_NAMES will be ready for the instructions given in string
- IN_INSN_NAMES. Each of these strings is a comma-separated list of
- filename-style globs and they refer to the names of
- 'define_insn_reservation's. For example:
- (define_bypass 1 "cpu1_load_*, cpu1_store_*" "cpu1_load_*")
- defines a bypass between instructions that start with 'cpu1_load_' or
- 'cpu1_store_' and those that start with 'cpu1_load_'.
-
- GUARD is an optional string giving the name of a C function which
- defines an additional guard for the bypass. The function will get the
- two insns as parameters. If the function returns zero the bypass will
- be ignored for this case. The additional guard is necessary to
- recognize complicated bypasses, e.g. when the consumer is only an
- address of insn 'store' (not a stored value).
-
- If there are more one bypass with the same output and input insns, the
- chosen bypass is the first bypass with a guard in description whose
- guard function returns nonzero. If there is no such bypass, then bypass
- without the guard function is chosen.
-
- The following five constructions are usually used to describe VLIW
- processors, or more precisely, to describe a placement of small
- instructions into VLIW instruction slots. They can be used for RISC
- processors, too.
-
- (exclusion_set UNIT-NAMES UNIT-NAMES)
- (presence_set UNIT-NAMES PATTERNS)
- (final_presence_set UNIT-NAMES PATTERNS)
- (absence_set UNIT-NAMES PATTERNS)
- (final_absence_set UNIT-NAMES PATTERNS)
-
- UNIT-NAMES is a string giving names of functional units separated by
- commas.
-
- PATTERNS is a string giving patterns of functional units separated by
- comma. Currently pattern is one unit or units separated by
- white-spaces.
-
- The first construction ('exclusion_set') means that each functional
- unit in the first string cannot be reserved simultaneously with a unit
- whose name is in the second string and vice versa. For example, the
- construction is useful for describing processors (e.g. some SPARC
- processors) with a fully pipelined floating point functional unit which
- can execute simultaneously only single floating point insns or only
- double floating point insns.
-
- The second construction ('presence_set') means that each functional
- unit in the first string cannot be reserved unless at least one of
- pattern of units whose names are in the second string is reserved. This
- is an asymmetric relation. For example, it is useful for description
- that VLIW 'slot1' is reserved after 'slot0' reservation. We could
- describe it by the following construction
-
- (presence_set "slot1" "slot0")
-
- Or 'slot1' is reserved only after 'slot0' and unit 'b0' reservation.
- In this case we could write
-
- (presence_set "slot1" "slot0 b0")
-
- The third construction ('final_presence_set') is analogous to
- 'presence_set'. The difference between them is when checking is done.
- When an instruction is issued in given automaton state reflecting all
- current and planned unit reservations, the automaton state is changed.
- The first state is a source state, the second one is a result state.
- Checking for 'presence_set' is done on the source state reservation,
- checking for 'final_presence_set' is done on the result reservation.
- This construction is useful to describe a reservation which is actually
- two subsequent reservations. For example, if we use
-
- (presence_set "slot1" "slot0")
-
- the following insn will be never issued (because 'slot1' requires
- 'slot0' which is absent in the source state).
-
- (define_reservation "insn_and_nop" "slot0 + slot1")
-
- but it can be issued if we use analogous 'final_presence_set'.
-
- The forth construction ('absence_set') means that each functional unit
- in the first string can be reserved only if each pattern of units whose
- names are in the second string is not reserved. This is an asymmetric
- relation (actually 'exclusion_set' is analogous to this one but it is
- symmetric). For example it might be useful in a VLIW description to say
- that 'slot0' cannot be reserved after either 'slot1' or 'slot2' have
- been reserved. This can be described as:
-
- (absence_set "slot0" "slot1, slot2")
-
- Or 'slot2' cannot be reserved if 'slot0' and unit 'b0' are reserved or
- 'slot1' and unit 'b1' are reserved. In this case we could write
-
- (absence_set "slot2" "slot0 b0, slot1 b1")
-
- All functional units mentioned in a set should belong to the same
- automaton.
-
- The last construction ('final_absence_set') is analogous to
- 'absence_set' but checking is done on the result (state) reservation.
- See comments for 'final_presence_set'.
-
- You can control the generator of the pipeline hazard recognizer with
- the following construction.
-
- (automata_option OPTIONS)
-
- OPTIONS is a string giving options which affect the generated code.
- Currently there are the following options:
-
- * "no-minimization" makes no minimization of the automaton. This is
- only worth to do when we are debugging the description and need to
- look more accurately at reservations of states.
-
- * "time" means printing time statistics about the generation of
- automata.
-
- * "stats" means printing statistics about the generated automata such
- as the number of DFA states, NDFA states and arcs.
-
- * "v" means a generation of the file describing the result automata.
- The file has suffix '.dfa' and can be used for the description
- verification and debugging.
-
- * "w" means a generation of warning instead of error for non-critical
- errors.
-
- * "no-comb-vect" prevents the automaton generator from generating two
- data structures and comparing them for space efficiency. Using a
- comb vector to represent transitions may be better, but it can be
- very expensive to construct. This option is useful if the build
- process spends an unacceptably long time in genautomata.
-
- * "ndfa" makes nondeterministic finite state automata. This affects
- the treatment of operator '|' in the regular expressions. The
- usual treatment of the operator is to try the first alternative
- and, if the reservation is not possible, the second alternative.
- The nondeterministic treatment means trying all alternatives, some
- of them may be rejected by reservations in the subsequent insns.
-
- * "collapse-ndfa" modifies the behavior of the generator when
- producing an automaton. An additional state transition to collapse
- a nondeterministic NDFA state to a deterministic DFA state is
- generated. It can be triggered by passing 'const0_rtx' to
- state_transition. In such an automaton, cycle advance transitions
- are available only for these collapsed states. This option is
- useful for ports that want to use the 'ndfa' option, but also want
- to use 'define_query_cpu_unit' to assign units to insns issued in a
- cycle.
-
- * "progress" means output of a progress bar showing how many states
- were generated so far for automaton being processed. This is
- useful during debugging a DFA description. If you see too many
- generated states, you could interrupt the generator of the pipeline
- hazard recognizer and try to figure out a reason for generation of
- the huge automaton.
-
- As an example, consider a superscalar RISC machine which can issue
- three insns (two integer insns and one floating point insn) on the cycle
- but can finish only two insns. To describe this, we define the
- following functional units.
-
- (define_cpu_unit "i0_pipeline, i1_pipeline, f_pipeline")
- (define_cpu_unit "port0, port1")
-
- All simple integer insns can be executed in any integer pipeline and
- their result is ready in two cycles. The simple integer insns are
- issued into the first pipeline unless it is reserved, otherwise they are
- issued into the second pipeline. Integer division and multiplication
- insns can be executed only in the second integer pipeline and their
- results are ready correspondingly in 9 and 4 cycles. The integer
- division is not pipelined, i.e. the subsequent integer division insn
- cannot be issued until the current division insn finished. Floating
- point insns are fully pipelined and their results are ready in 3 cycles.
- Where the result of a floating point insn is used by an integer insn, an
- additional delay of one cycle is incurred. To describe all of this we
- could specify
-
- (define_cpu_unit "div")
-
- (define_insn_reservation "simple" 2 (eq_attr "type" "int")
- "(i0_pipeline | i1_pipeline), (port0 | port1)")
-
- (define_insn_reservation "mult" 4 (eq_attr "type" "mult")
- "i1_pipeline, nothing*2, (port0 | port1)")
-
- (define_insn_reservation "div" 9 (eq_attr "type" "div")
- "i1_pipeline, div*7, div + (port0 | port1)")
-
- (define_insn_reservation "float" 3 (eq_attr "type" "float")
- "f_pipeline, nothing, (port0 | port1))
-
- (define_bypass 4 "float" "simple,mult,div")
-
- To simplify the description we could describe the following reservation
-
- (define_reservation "finish" "port0|port1")
-
- and use it in all 'define_insn_reservation' as in the following
- construction
-
- (define_insn_reservation "simple" 2 (eq_attr "type" "int")
- "(i0_pipeline | i1_pipeline), finish")
-
- ---------- Footnotes ----------
-
- (1) However, the size of the automaton depends on processor
- complexity. To limit this effect, machine descriptions can split
- orthogonal parts of the machine description among several automata: but
- then, since each of these must be stepped independently, this does cause
- a small decrease in the algorithm's performance.
-
-
- File: gccint.info, Node: Conditional Execution, Next: Define Subst, Prev: Insn Attributes, Up: Machine Desc
-
- 17.20 Conditional Execution
- ===========================
-
- A number of architectures provide for some form of conditional
- execution, or predication. The hallmark of this feature is the ability
- to nullify most of the instructions in the instruction set. When the
- instruction set is large and not entirely symmetric, it can be quite
- tedious to describe these forms directly in the '.md' file. An
- alternative is the 'define_cond_exec' template.
-
- (define_cond_exec
- [PREDICATE-PATTERN]
- "CONDITION"
- "OUTPUT-TEMPLATE"
- "OPTIONAL-INSN-ATTRIBUES")
-
- PREDICATE-PATTERN is the condition that must be true for the insn to be
- executed at runtime and should match a relational operator. One can use
- 'match_operator' to match several relational operators at once. Any
- 'match_operand' operands must have no more than one alternative.
-
- CONDITION is a C expression that must be true for the generated pattern
- to match.
-
- OUTPUT-TEMPLATE is a string similar to the 'define_insn' output
- template (*note Output Template::), except that the '*' and '@' special
- cases do not apply. This is only useful if the assembly text for the
- predicate is a simple prefix to the main insn. In order to handle the
- general case, there is a global variable 'current_insn_predicate' that
- will contain the entire predicate if the current insn is predicated, and
- will otherwise be 'NULL'.
-
- OPTIONAL-INSN-ATTRIBUTES is an optional vector of attributes that gets
- appended to the insn attributes of the produced cond_exec rtx. It can
- be used to add some distinguishing attribute to cond_exec rtxs produced
- that way. An example usage would be to use this attribute in
- conjunction with attributes on the main pattern to disable particular
- alternatives under certain conditions.
-
- When 'define_cond_exec' is used, an implicit reference to the
- 'predicable' instruction attribute is made. *Note Insn Attributes::.
- This attribute must be a boolean (i.e. have exactly two elements in its
- LIST-OF-VALUES), with the possible values being 'no' and 'yes'. The
- default and all uses in the insns must be a simple constant, not a
- complex expressions. It may, however, depend on the alternative, by
- using a comma-separated list of values. If that is the case, the port
- should also define an 'enabled' attribute (*note Disable Insn
- Alternatives::), which should also allow only 'no' and 'yes' as its
- values.
-
- For each 'define_insn' for which the 'predicable' attribute is true, a
- new 'define_insn' pattern will be generated that matches a predicated
- version of the instruction. For example,
-
- (define_insn "addsi"
- [(set (match_operand:SI 0 "register_operand" "r")
- (plus:SI (match_operand:SI 1 "register_operand" "r")
- (match_operand:SI 2 "register_operand" "r")))]
- "TEST1"
- "add %2,%1,%0")
-
- (define_cond_exec
- [(ne (match_operand:CC 0 "register_operand" "c")
- (const_int 0))]
- "TEST2"
- "(%0)")
-
- generates a new pattern
-
- (define_insn ""
- [(cond_exec
- (ne (match_operand:CC 3 "register_operand" "c") (const_int 0))
- (set (match_operand:SI 0 "register_operand" "r")
- (plus:SI (match_operand:SI 1 "register_operand" "r")
- (match_operand:SI 2 "register_operand" "r"))))]
- "(TEST2) && (TEST1)"
- "(%3) add %2,%1,%0")
-
-
- File: gccint.info, Node: Define Subst, Next: Constant Definitions, Prev: Conditional Execution, Up: Machine Desc
-
- 17.21 RTL Templates Transformations
- ===================================
-
- For some hardware architectures there are common cases when the RTL
- templates for the instructions can be derived from the other RTL
- templates using simple transformations. E.g., 'i386.md' contains an RTL
- template for the ordinary 'sub' instruction-- '*subsi_1', and for the
- 'sub' instruction with subsequent zero-extension--'*subsi_1_zext'. Such
- cases can be easily implemented by a single meta-template capable of
- generating a modified case based on the initial one:
-
- (define_subst "NAME"
- [INPUT-TEMPLATE]
- "CONDITION"
- [OUTPUT-TEMPLATE])
- INPUT-TEMPLATE is a pattern describing the source RTL template, which
- will be transformed.
-
- CONDITION is a C expression that is conjunct with the condition from
- the input-template to generate a condition to be used in the
- output-template.
-
- OUTPUT-TEMPLATE is a pattern that will be used in the resulting
- template.
-
- 'define_subst' mechanism is tightly coupled with the notion of the
- subst attribute (*note Subst Iterators::). The use of 'define_subst' is
- triggered by a reference to a subst attribute in the transforming RTL
- template. This reference initiates duplication of the source RTL
- template and substitution of the attributes with their values. The
- source RTL template is left unchanged, while the copy is transformed by
- 'define_subst'. This transformation can fail in the case when the
- source RTL template is not matched against the input-template of the
- 'define_subst'. In such case the copy is deleted.
-
- 'define_subst' can be used only in 'define_insn' and 'define_expand',
- it cannot be used in other expressions (e.g. in
- 'define_insn_and_split').
-
- * Menu:
-
- * Define Subst Example:: Example of 'define_subst' work.
- * Define Subst Pattern Matching:: Process of template comparison.
- * Define Subst Output Template:: Generation of output template.
-
-
- File: gccint.info, Node: Define Subst Example, Next: Define Subst Pattern Matching, Up: Define Subst
-
- 17.21.1 'define_subst' Example
- ------------------------------
-
- To illustrate how 'define_subst' works, let us examine a simple template
- transformation.
-
- Suppose there are two kinds of instructions: one that touches flags and
- the other that does not. The instructions of the second type could be
- generated with the following 'define_subst':
-
- (define_subst "add_clobber_subst"
- [(set (match_operand:SI 0 "" "")
- (match_operand:SI 1 "" ""))]
- ""
- [(set (match_dup 0)
- (match_dup 1))
- (clobber (reg:CC FLAGS_REG))])
-
- This 'define_subst' can be applied to any RTL pattern containing 'set'
- of mode SI and generates a copy with clobber when it is applied.
-
- Assume there is an RTL template for a 'max' instruction to be used in
- 'define_subst' mentioned above:
-
- (define_insn "maxsi"
- [(set (match_operand:SI 0 "register_operand" "=r")
- (max:SI
- (match_operand:SI 1 "register_operand" "r")
- (match_operand:SI 2 "register_operand" "r")))]
- ""
- "max\t{%2, %1, %0|%0, %1, %2}"
- [...])
-
- To mark the RTL template for 'define_subst' application,
- subst-attributes are used. They should be declared in advance:
-
- (define_subst_attr "add_clobber_name" "add_clobber_subst" "_noclobber" "_clobber")
-
- Here 'add_clobber_name' is the attribute name, 'add_clobber_subst' is
- the name of the corresponding 'define_subst', the third argument
- ('_noclobber') is the attribute value that would be substituted into the
- unchanged version of the source RTL template, and the last argument
- ('_clobber') is the value that would be substituted into the second,
- transformed, version of the RTL template.
-
- Once the subst-attribute has been defined, it should be used in RTL
- templates which need to be processed by the 'define_subst'. So, the
- original RTL template should be changed:
-
- (define_insn "maxsi<add_clobber_name>"
- [(set (match_operand:SI 0 "register_operand" "=r")
- (max:SI
- (match_operand:SI 1 "register_operand" "r")
- (match_operand:SI 2 "register_operand" "r")))]
- ""
- "max\t{%2, %1, %0|%0, %1, %2}"
- [...])
-
- The result of the 'define_subst' usage would look like the following:
-
- (define_insn "maxsi_noclobber"
- [(set (match_operand:SI 0 "register_operand" "=r")
- (max:SI
- (match_operand:SI 1 "register_operand" "r")
- (match_operand:SI 2 "register_operand" "r")))]
- ""
- "max\t{%2, %1, %0|%0, %1, %2}"
- [...])
- (define_insn "maxsi_clobber"
- [(set (match_operand:SI 0 "register_operand" "=r")
- (max:SI
- (match_operand:SI 1 "register_operand" "r")
- (match_operand:SI 2 "register_operand" "r")))
- (clobber (reg:CC FLAGS_REG))]
- ""
- "max\t{%2, %1, %0|%0, %1, %2}"
- [...])
-
-
- File: gccint.info, Node: Define Subst Pattern Matching, Next: Define Subst Output Template, Prev: Define Subst Example, Up: Define Subst
-
- 17.21.2 Pattern Matching in 'define_subst'
- ------------------------------------------
-
- All expressions, allowed in 'define_insn' or 'define_expand', are
- allowed in the input-template of 'define_subst', except 'match_par_dup',
- 'match_scratch', 'match_parallel'. The meanings of expressions in the
- input-template were changed:
-
- 'match_operand' matches any expression (possibly, a subtree in
- RTL-template), if modes of the 'match_operand' and this expression are
- the same, or mode of the 'match_operand' is 'VOIDmode', or this
- expression is 'match_dup', 'match_op_dup'. If the expression is
- 'match_operand' too, and predicate of 'match_operand' from the input
- pattern is not empty, then the predicates are compared. That can be
- used for more accurate filtering of accepted RTL-templates.
-
- 'match_operator' matches common operators (like 'plus', 'minus'),
- 'unspec', 'unspec_volatile' operators and 'match_operator's from the
- original pattern if the modes match and 'match_operator' from the input
- pattern has the same number of operands as the operator from the
- original pattern.
-
-
- File: gccint.info, Node: Define Subst Output Template, Prev: Define Subst Pattern Matching, Up: Define Subst
-
- 17.21.3 Generation of output template in 'define_subst'
- -------------------------------------------------------
-
- If all necessary checks for 'define_subst' application pass, a new
- RTL-pattern, based on the output-template, is created to replace the old
- template. Like in input-patterns, meanings of some RTL expressions are
- changed when they are used in output-patterns of a 'define_subst'.
- Thus, 'match_dup' is used for copying the whole expression from the
- original pattern, which matched corresponding 'match_operand' from the
- input pattern.
-
- 'match_dup N' is used in the output template to be replaced with the
- expression from the original pattern, which matched 'match_operand N'
- from the input pattern. As a consequence, 'match_dup' cannot be used to
- point to 'match_operand's from the output pattern, it should always
- refer to a 'match_operand' from the input pattern. If a 'match_dup N'
- occurs more than once in the output template, its first occurrence is
- replaced with the expression from the original pattern, and the
- subsequent expressions are replaced with 'match_dup N', i.e., a
- reference to the first expression.
-
- In the output template one can refer to the expressions from the
- original pattern and create new ones. For instance, some operands could
- be added by means of standard 'match_operand'.
-
- After replacing 'match_dup' with some RTL-subtree from the original
- pattern, it could happen that several 'match_operand's in the output
- pattern have the same indexes. It is unknown, how many and what indexes
- would be used in the expression which would replace 'match_dup', so such
- conflicts in indexes are inevitable. To overcome this issue,
- 'match_operands' and 'match_operators', which were introduced into the
- output pattern, are renumerated when all 'match_dup's are replaced.
-
- Number of alternatives in 'match_operand's introduced into the output
- template 'M' could differ from the number of alternatives in the
- original pattern 'N', so in the resultant pattern there would be 'N*M'
- alternatives. Thus, constraints from the original pattern would be
- duplicated 'N' times, constraints from the output pattern would be
- duplicated 'M' times, producing all possible combinations.
-
-
- File: gccint.info, Node: Constant Definitions, Next: Iterators, Prev: Define Subst, Up: Machine Desc
-
- 17.22 Constant Definitions
- ==========================
-
- Using literal constants inside instruction patterns reduces legibility
- and can be a maintenance problem.
-
- To overcome this problem, you may use the 'define_constants'
- expression. It contains a vector of name-value pairs. From that point
- on, wherever any of the names appears in the MD file, it is as if the
- corresponding value had been written instead. You may use
- 'define_constants' multiple times; each appearance adds more constants
- to the table. It is an error to redefine a constant with a different
- value.
-
- To come back to the a29k load multiple example, instead of
-
- (define_insn ""
- [(match_parallel 0 "load_multiple_operation"
- [(set (match_operand:SI 1 "gpc_reg_operand" "=r")
- (match_operand:SI 2 "memory_operand" "m"))
- (use (reg:SI 179))
- (clobber (reg:SI 179))])]
- ""
- "loadm 0,0,%1,%2")
-
- You could write:
-
- (define_constants [
- (R_BP 177)
- (R_FC 178)
- (R_CR 179)
- (R_Q 180)
- ])
-
- (define_insn ""
- [(match_parallel 0 "load_multiple_operation"
- [(set (match_operand:SI 1 "gpc_reg_operand" "=r")
- (match_operand:SI 2 "memory_operand" "m"))
- (use (reg:SI R_CR))
- (clobber (reg:SI R_CR))])]
- ""
- "loadm 0,0,%1,%2")
-
- The constants that are defined with a define_constant are also output
- in the insn-codes.h header file as #defines.
-
- You can also use the machine description file to define enumerations.
- Like the constants defined by 'define_constant', these enumerations are
- visible to both the machine description file and the main C code.
-
- The syntax is as follows:
-
- (define_c_enum "NAME" [
- VALUE0
- VALUE1
- ...
- VALUEN
- ])
-
- This definition causes the equivalent of the following C code to appear
- in 'insn-constants.h':
-
- enum NAME {
- VALUE0 = 0,
- VALUE1 = 1,
- ...
- VALUEN = N
- };
- #define NUM_CNAME_VALUES (N + 1)
-
- where CNAME is the capitalized form of NAME. It also makes each VALUEI
- available in the machine description file, just as if it had been
- declared with:
-
- (define_constants [(VALUEI I)])
-
- Each VALUEI is usually an upper-case identifier and usually begins with
- CNAME.
-
- You can split the enumeration definition into as many statements as you
- like. The above example is directly equivalent to:
-
- (define_c_enum "NAME" [VALUE0])
- (define_c_enum "NAME" [VALUE1])
- ...
- (define_c_enum "NAME" [VALUEN])
-
- Splitting the enumeration helps to improve the modularity of each
- individual '.md' file. For example, if a port defines its
- synchronization instructions in a separate 'sync.md' file, it is
- convenient to define all synchronization-specific enumeration values in
- 'sync.md' rather than in the main '.md' file.
-
- Some enumeration names have special significance to GCC:
-
- 'unspecv'
- If an enumeration called 'unspecv' is defined, GCC will use it when
- printing out 'unspec_volatile' expressions. For example:
-
- (define_c_enum "unspecv" [
- UNSPECV_BLOCKAGE
- ])
-
- causes GCC to print '(unspec_volatile ... 0)' as:
-
- (unspec_volatile ... UNSPECV_BLOCKAGE)
-
- 'unspec'
- If an enumeration called 'unspec' is defined, GCC will use it when
- printing out 'unspec' expressions. GCC will also use it when
- printing out 'unspec_volatile' expressions unless an 'unspecv'
- enumeration is also defined. You can therefore decide whether to
- keep separate enumerations for volatile and non-volatile
- expressions or whether to use the same enumeration for both.
-
- Another way of defining an enumeration is to use 'define_enum':
-
- (define_enum "NAME" [
- VALUE0
- VALUE1
- ...
- VALUEN
- ])
-
- This directive implies:
-
- (define_c_enum "NAME" [
- CNAME_CVALUE0
- CNAME_CVALUE1
- ...
- CNAME_CVALUEN
- ])
-
- where CVALUEI is the capitalized form of VALUEI. However, unlike
- 'define_c_enum', the enumerations defined by 'define_enum' can be used
- in attribute specifications (*note define_enum_attr::).
-
-
- File: gccint.info, Node: Iterators, Prev: Constant Definitions, Up: Machine Desc
-
- 17.23 Iterators
- ===============
-
- Ports often need to define similar patterns for more than one machine
- mode or for more than one rtx code. GCC provides some simple iterator
- facilities to make this process easier.
-
- * Menu:
-
- * Mode Iterators:: Generating variations of patterns for different modes.
- * Code Iterators:: Doing the same for codes.
- * Int Iterators:: Doing the same for integers.
- * Subst Iterators:: Generating variations of patterns for define_subst.
- * Parameterized Names:: Specifying iterator values in C++ code.
-
-
- File: gccint.info, Node: Mode Iterators, Next: Code Iterators, Up: Iterators
-
- 17.23.1 Mode Iterators
- ----------------------
-
- Ports often need to define similar patterns for two or more different
- modes. For example:
-
- * If a processor has hardware support for both single and double
- floating-point arithmetic, the 'SFmode' patterns tend to be very
- similar to the 'DFmode' ones.
-
- * If a port uses 'SImode' pointers in one configuration and 'DImode'
- pointers in another, it will usually have very similar 'SImode' and
- 'DImode' patterns for manipulating pointers.
-
- Mode iterators allow several patterns to be instantiated from one '.md'
- file template. They can be used with any type of rtx-based construct,
- such as a 'define_insn', 'define_split', or 'define_peephole2'.
-
- * Menu:
-
- * Defining Mode Iterators:: Defining a new mode iterator.
- * Substitutions:: Combining mode iterators with substitutions
- * Examples:: Examples
-
-
- File: gccint.info, Node: Defining Mode Iterators, Next: Substitutions, Up: Mode Iterators
-
- 17.23.1.1 Defining Mode Iterators
- .................................
-
- The syntax for defining a mode iterator is:
-
- (define_mode_iterator NAME [(MODE1 "COND1") ... (MODEN "CONDN")])
-
- This allows subsequent '.md' file constructs to use the mode suffix
- ':NAME'. Every construct that does so will be expanded N times, once
- with every use of ':NAME' replaced by ':MODE1', once with every use
- replaced by ':MODE2', and so on. In the expansion for a particular
- MODEI, every C condition will also require that CONDI be true.
-
- For example:
-
- (define_mode_iterator P [(SI "Pmode == SImode") (DI "Pmode == DImode")])
-
- defines a new mode suffix ':P'. Every construct that uses ':P' will be
- expanded twice, once with every ':P' replaced by ':SI' and once with
- every ':P' replaced by ':DI'. The ':SI' version will only apply if
- 'Pmode == SImode' and the ':DI' version will only apply if 'Pmode ==
- DImode'.
-
- As with other '.md' conditions, an empty string is treated as "always
- true". '(MODE "")' can also be abbreviated to 'MODE'. For example:
-
- (define_mode_iterator GPR [SI (DI "TARGET_64BIT")])
-
- means that the ':DI' expansion only applies if 'TARGET_64BIT' but that
- the ':SI' expansion has no such constraint.
-
- Iterators are applied in the order they are defined. This can be
- significant if two iterators are used in a construct that requires
- substitutions. *Note Substitutions::.
-
-
- File: gccint.info, Node: Substitutions, Next: Examples, Prev: Defining Mode Iterators, Up: Mode Iterators
-
- 17.23.1.2 Substitution in Mode Iterators
- ........................................
-
- If an '.md' file construct uses mode iterators, each version of the
- construct will often need slightly different strings or modes. For
- example:
-
- * When a 'define_expand' defines several 'addM3' patterns (*note
- Standard Names::), each expander will need to use the appropriate
- mode name for M.
-
- * When a 'define_insn' defines several instruction patterns, each
- instruction will often use a different assembler mnemonic.
-
- * When a 'define_insn' requires operands with different modes, using
- an iterator for one of the operand modes usually requires a
- specific mode for the other operand(s).
-
- GCC supports such variations through a system of "mode attributes".
- There are two standard attributes: 'mode', which is the name of the mode
- in lower case, and 'MODE', which is the same thing in upper case. You
- can define other attributes using:
-
- (define_mode_attr NAME [(MODE1 "VALUE1") ... (MODEN "VALUEN")])
-
- where NAME is the name of the attribute and VALUEI is the value
- associated with MODEI.
-
- When GCC replaces some :ITERATOR with :MODE, it will scan each string
- and mode in the pattern for sequences of the form '<ITERATOR:ATTR>',
- where ATTR is the name of a mode attribute. If the attribute is defined
- for MODE, the whole '<...>' sequence will be replaced by the appropriate
- attribute value.
-
- For example, suppose an '.md' file has:
-
- (define_mode_iterator P [(SI "Pmode == SImode") (DI "Pmode == DImode")])
- (define_mode_attr load [(SI "lw") (DI "ld")])
-
- If one of the patterns that uses ':P' contains the string
- '"<P:load>\t%0,%1"', the 'SI' version of that pattern will use
- '"lw\t%0,%1"' and the 'DI' version will use '"ld\t%0,%1"'.
-
- Here is an example of using an attribute for a mode:
-
- (define_mode_iterator LONG [SI DI])
- (define_mode_attr SHORT [(SI "HI") (DI "SI")])
- (define_insn ...
- (sign_extend:LONG (match_operand:<LONG:SHORT> ...)) ...)
-
- The 'ITERATOR:' prefix may be omitted, in which case the substitution
- will be attempted for every iterator expansion.
-
-
- File: gccint.info, Node: Examples, Prev: Substitutions, Up: Mode Iterators
-
- 17.23.1.3 Mode Iterator Examples
- ................................
-
- Here is an example from the MIPS port. It defines the following modes
- and attributes (among others):
-
- (define_mode_iterator GPR [SI (DI "TARGET_64BIT")])
- (define_mode_attr d [(SI "") (DI "d")])
-
- and uses the following template to define both 'subsi3' and 'subdi3':
-
- (define_insn "sub<mode>3"
- [(set (match_operand:GPR 0 "register_operand" "=d")
- (minus:GPR (match_operand:GPR 1 "register_operand" "d")
- (match_operand:GPR 2 "register_operand" "d")))]
- ""
- "<d>subu\t%0,%1,%2"
- [(set_attr "type" "arith")
- (set_attr "mode" "<MODE>")])
-
- This is exactly equivalent to:
-
- (define_insn "subsi3"
- [(set (match_operand:SI 0 "register_operand" "=d")
- (minus:SI (match_operand:SI 1 "register_operand" "d")
- (match_operand:SI 2 "register_operand" "d")))]
- ""
- "subu\t%0,%1,%2"
- [(set_attr "type" "arith")
- (set_attr "mode" "SI")])
-
- (define_insn "subdi3"
- [(set (match_operand:DI 0 "register_operand" "=d")
- (minus:DI (match_operand:DI 1 "register_operand" "d")
- (match_operand:DI 2 "register_operand" "d")))]
- ""
- "dsubu\t%0,%1,%2"
- [(set_attr "type" "arith")
- (set_attr "mode" "DI")])
-
-
- File: gccint.info, Node: Code Iterators, Next: Int Iterators, Prev: Mode Iterators, Up: Iterators
-
- 17.23.2 Code Iterators
- ----------------------
-
- Code iterators operate in a similar way to mode iterators. *Note Mode
- Iterators::.
-
- The construct:
-
- (define_code_iterator NAME [(CODE1 "COND1") ... (CODEN "CONDN")])
-
- defines a pseudo rtx code NAME that can be instantiated as CODEI if
- condition CONDI is true. Each CODEI must have the same rtx format.
- *Note RTL Classes::.
-
- As with mode iterators, each pattern that uses NAME will be expanded N
- times, once with all uses of NAME replaced by CODE1, once with all uses
- replaced by CODE2, and so on. *Note Defining Mode Iterators::.
-
- It is possible to define attributes for codes as well as for modes.
- There are two standard code attributes: 'code', the name of the code in
- lower case, and 'CODE', the name of the code in upper case. Other
- attributes are defined using:
-
- (define_code_attr NAME [(CODE1 "VALUE1") ... (CODEN "VALUEN")])
-
- Instruction patterns can use code attributes as rtx codes, which can be
- useful if two sets of codes act in tandem. For example, the following
- 'define_insn' defines two patterns, one calculating a signed absolute
- difference and another calculating an unsigned absolute difference:
-
- (define_code_iterator any_max [smax umax])
- (define_code_attr paired_min [(smax "smin") (umax "umin")])
- (define_insn ...
- [(set (match_operand:SI 0 ...)
- (minus:SI (any_max:SI (match_operand:SI 1 ...)
- (match_operand:SI 2 ...))
- (<paired_min>:SI (match_dup 1) (match_dup 2))))]
- ...)
-
- The signed version of the instruction uses 'smax' and 'smin' while the
- unsigned version uses 'umax' and 'umin'. There are no versions that
- pair 'smax' with 'umin' or 'umax' with 'smin'.
-
- Here's an example of code iterators in action, taken from the MIPS
- port:
-
- (define_code_iterator any_cond [unordered ordered unlt unge uneq ltgt unle ungt
- eq ne gt ge lt le gtu geu ltu leu])
-
- (define_expand "b<code>"
- [(set (pc)
- (if_then_else (any_cond:CC (cc0)
- (const_int 0))
- (label_ref (match_operand 0 ""))
- (pc)))]
- ""
- {
- gen_conditional_branch (operands, <CODE>);
- DONE;
- })
-
- This is equivalent to:
-
- (define_expand "bunordered"
- [(set (pc)
- (if_then_else (unordered:CC (cc0)
- (const_int 0))
- (label_ref (match_operand 0 ""))
- (pc)))]
- ""
- {
- gen_conditional_branch (operands, UNORDERED);
- DONE;
- })
-
- (define_expand "bordered"
- [(set (pc)
- (if_then_else (ordered:CC (cc0)
- (const_int 0))
- (label_ref (match_operand 0 ""))
- (pc)))]
- ""
- {
- gen_conditional_branch (operands, ORDERED);
- DONE;
- })
-
- ...
-
-
- File: gccint.info, Node: Int Iterators, Next: Subst Iterators, Prev: Code Iterators, Up: Iterators
-
- 17.23.3 Int Iterators
- ---------------------
-
- Int iterators operate in a similar way to code iterators. *Note Code
- Iterators::.
-
- The construct:
-
- (define_int_iterator NAME [(INT1 "COND1") ... (INTN "CONDN")])
-
- defines a pseudo integer constant NAME that can be instantiated as INTI
- if condition CONDI is true. Each INT must have the same rtx format.
- *Note RTL Classes::. Int iterators can appear in only those rtx fields
- that have 'i' as the specifier. This means that each INT has to be a
- constant defined using define_constant or define_c_enum.
-
- As with mode and code iterators, each pattern that uses NAME will be
- expanded N times, once with all uses of NAME replaced by INT1, once with
- all uses replaced by INT2, and so on. *Note Defining Mode Iterators::.
-
- It is possible to define attributes for ints as well as for codes and
- modes. Attributes are defined using:
-
- (define_int_attr NAME [(INT1 "VALUE1") ... (INTN "VALUEN")])
-
- Here's an example of int iterators in action, taken from the ARM port:
-
- (define_int_iterator QABSNEG [UNSPEC_VQABS UNSPEC_VQNEG])
-
- (define_int_attr absneg [(UNSPEC_VQABS "abs") (UNSPEC_VQNEG "neg")])
-
- (define_insn "neon_vq<absneg><mode>"
- [(set (match_operand:VDQIW 0 "s_register_operand" "=w")
- (unspec:VDQIW [(match_operand:VDQIW 1 "s_register_operand" "w")
- (match_operand:SI 2 "immediate_operand" "i")]
- QABSNEG))]
- "TARGET_NEON"
- "vq<absneg>.<V_s_elem>\t%<V_reg>0, %<V_reg>1"
- [(set_attr "type" "neon_vqneg_vqabs")]
- )
-
-
- This is equivalent to:
-
- (define_insn "neon_vqabs<mode>"
- [(set (match_operand:VDQIW 0 "s_register_operand" "=w")
- (unspec:VDQIW [(match_operand:VDQIW 1 "s_register_operand" "w")
- (match_operand:SI 2 "immediate_operand" "i")]
- UNSPEC_VQABS))]
- "TARGET_NEON"
- "vqabs.<V_s_elem>\t%<V_reg>0, %<V_reg>1"
- [(set_attr "type" "neon_vqneg_vqabs")]
- )
-
- (define_insn "neon_vqneg<mode>"
- [(set (match_operand:VDQIW 0 "s_register_operand" "=w")
- (unspec:VDQIW [(match_operand:VDQIW 1 "s_register_operand" "w")
- (match_operand:SI 2 "immediate_operand" "i")]
- UNSPEC_VQNEG))]
- "TARGET_NEON"
- "vqneg.<V_s_elem>\t%<V_reg>0, %<V_reg>1"
- [(set_attr "type" "neon_vqneg_vqabs")]
- )
-
-
-
- File: gccint.info, Node: Subst Iterators, Next: Parameterized Names, Prev: Int Iterators, Up: Iterators
-
- 17.23.4 Subst Iterators
- -----------------------
-
- Subst iterators are special type of iterators with the following
- restrictions: they could not be declared explicitly, they always have
- only two values, and they do not have explicit dedicated name.
- Subst-iterators are triggered only when corresponding subst-attribute is
- used in RTL-pattern.
-
- Subst iterators transform templates in the following way: the templates
- are duplicated, the subst-attributes in these templates are replaced
- with the corresponding values, and a new attribute is implicitly added
- to the given 'define_insn'/'define_expand'. The name of the added
- attribute matches the name of 'define_subst'. Such attributes are
- declared implicitly, and it is not allowed to have a 'define_attr' named
- as a 'define_subst'.
-
- Each subst iterator is linked to a 'define_subst'. It is declared
- implicitly by the first appearance of the corresponding
- 'define_subst_attr', and it is not allowed to define it explicitly.
-
- Declarations of subst-attributes have the following syntax:
-
- (define_subst_attr "NAME"
- "SUBST-NAME"
- "NO-SUBST-VALUE"
- "SUBST-APPLIED-VALUE")
-
- NAME is a string with which the given subst-attribute could be referred
- to.
-
- SUBST-NAME shows which 'define_subst' should be applied to an
- RTL-template if the given subst-attribute is present in the
- RTL-template.
-
- NO-SUBST-VALUE is a value with which subst-attribute would be replaced
- in the first copy of the original RTL-template.
-
- SUBST-APPLIED-VALUE is a value with which subst-attribute would be
- replaced in the second copy of the original RTL-template.
-
-
- File: gccint.info, Node: Parameterized Names, Prev: Subst Iterators, Up: Iterators
-
- 17.23.5 Parameterized Names
- ---------------------------
-
- Ports sometimes need to apply iterators using C++ code, in order to get
- the code or RTL pattern for a specific instruction. For example,
- suppose we have the 'neon_vq<absneg><mode>' pattern given above:
-
- (define_int_iterator QABSNEG [UNSPEC_VQABS UNSPEC_VQNEG])
-
- (define_int_attr absneg [(UNSPEC_VQABS "abs") (UNSPEC_VQNEG "neg")])
-
- (define_insn "neon_vq<absneg><mode>"
- [(set (match_operand:VDQIW 0 "s_register_operand" "=w")
- (unspec:VDQIW [(match_operand:VDQIW 1 "s_register_operand" "w")
- (match_operand:SI 2 "immediate_operand" "i")]
- QABSNEG))]
- ...
- )
-
- A port might need to generate this pattern for a variable 'QABSNEG'
- value and a variable 'VDQIW' mode. There are two ways of doing this.
- The first is to build the rtx for the pattern directly from C++ code;
- this is a valid technique and avoids any risk of combinatorial
- explosion. The second is to prefix the instruction name with the
- special character '@', which tells GCC to generate the four additional
- functions below. In each case, NAME is the name of the instruction
- without the leading '@' character, without the '<...>' placeholders, and
- with any underscore before a '<...>' placeholder removed if keeping it
- would lead to a double or trailing underscore.
-
- 'insn_code maybe_code_for_NAME (I1, I2, ...)'
- See whether replacing the first '<...>' placeholder with iterator
- value I1, the second with iterator value I2, and so on, gives a
- valid instruction. Return its code if so, otherwise return
- 'CODE_FOR_nothing'.
-
- 'insn_code code_for_NAME (I1, I2, ...)'
- Same, but abort the compiler if the requested instruction does not
- exist.
-
- 'rtx maybe_gen_NAME (I1, I2, ..., OP0, OP1, ...)'
- Check for a valid instruction in the same way as
- 'maybe_code_for_NAME'. If the instruction exists, generate an
- instance of it using the operand values given by OP0, OP1, and so
- on, otherwise return null.
-
- 'rtx gen_NAME (I1, I2, ..., OP0, OP1, ...)'
- Same, but abort the compiler if the requested instruction does not
- exist, or if the instruction generator invoked the 'FAIL' macro.
-
- For example, changing the pattern above to:
-
- (define_insn "@neon_vq<absneg><mode>"
- [(set (match_operand:VDQIW 0 "s_register_operand" "=w")
- (unspec:VDQIW [(match_operand:VDQIW 1 "s_register_operand" "w")
- (match_operand:SI 2 "immediate_operand" "i")]
- QABSNEG))]
- ...
- )
-
- would define the same patterns as before, but in addition would
- generate the four functions below:
-
- insn_code maybe_code_for_neon_vq (int, machine_mode);
- insn_code code_for_neon_vq (int, machine_mode);
- rtx maybe_gen_neon_vq (int, machine_mode, rtx, rtx, rtx);
- rtx gen_neon_vq (int, machine_mode, rtx, rtx, rtx);
-
- Calling 'code_for_neon_vq (UNSPEC_VQABS, V8QImode)' would then give
- 'CODE_FOR_neon_vqabsv8qi'.
-
- It is possible to have multiple '@' patterns with the same name and
- same types of iterator. For example:
-
- (define_insn "@some_arithmetic_op<mode>"
- [(set (match_operand:INTEGER_MODES 0 "register_operand") ...)]
- ...
- )
-
- (define_insn "@some_arithmetic_op<mode>"
- [(set (match_operand:FLOAT_MODES 0 "register_operand") ...)]
- ...
- )
-
- would produce a single set of functions that handles both
- 'INTEGER_MODES' and 'FLOAT_MODES'.
-
- It is also possible for these '@' patterns to have different numbers of
- operands from each other. For example, patterns with a binary rtl code
- might take three operands (one output and two inputs) while patterns
- with a ternary rtl code might take four operands (one output and three
- inputs). This combination would produce separate 'maybe_gen_NAME' and
- 'gen_NAME' functions for each operand count, but it would still produce
- a single 'maybe_code_for_NAME' and a single 'code_for_NAME'.
-
-
- File: gccint.info, Node: Target Macros, Next: Host Config, Prev: Machine Desc, Up: Top
-
- 18 Target Description Macros and Functions
- ******************************************
-
- In addition to the file 'MACHINE.md', a machine description includes a C
- header file conventionally given the name 'MACHINE.h' and a C source
- file named 'MACHINE.c'. The header file defines numerous macros that
- convey the information about the target machine that does not fit into
- the scheme of the '.md' file. The file 'tm.h' should be a link to
- 'MACHINE.h'. The header file 'config.h' includes 'tm.h' and most
- compiler source files include 'config.h'. The source file defines a
- variable 'targetm', which is a structure containing pointers to
- functions and data relating to the target machine. 'MACHINE.c' should
- also contain their definitions, if they are not defined elsewhere in
- GCC, and other functions called through the macros defined in the '.h'
- file.
-
- * Menu:
-
- * Target Structure:: The 'targetm' variable.
- * Driver:: Controlling how the driver runs the compilation passes.
- * Run-time Target:: Defining '-m' options like '-m68000' and '-m68020'.
- * Per-Function Data:: Defining data structures for per-function information.
- * Storage Layout:: Defining sizes and alignments of data.
- * Type Layout:: Defining sizes and properties of basic user data types.
- * Registers:: Naming and describing the hardware registers.
- * Register Classes:: Defining the classes of hardware registers.
- * Stack and Calling:: Defining which way the stack grows and by how much.
- * Varargs:: Defining the varargs macros.
- * Trampolines:: Code set up at run time to enter a nested function.
- * Library Calls:: Controlling how library routines are implicitly called.
- * Addressing Modes:: Defining addressing modes valid for memory operands.
- * Anchored Addresses:: Defining how '-fsection-anchors' should work.
- * Condition Code:: Defining how insns update the condition code.
- * Costs:: Defining relative costs of different operations.
- * Scheduling:: Adjusting the behavior of the instruction scheduler.
- * Sections:: Dividing storage into text, data, and other sections.
- * PIC:: Macros for position independent code.
- * Assembler Format:: Defining how to write insns and pseudo-ops to output.
- * Debugging Info:: Defining the format of debugging output.
- * Floating Point:: Handling floating point for cross-compilers.
- * Mode Switching:: Insertion of mode-switching instructions.
- * Target Attributes:: Defining target-specific uses of '__attribute__'.
- * Emulated TLS:: Emulated TLS support.
- * MIPS Coprocessors:: MIPS coprocessor support and how to customize it.
- * PCH Target:: Validity checking for precompiled headers.
- * C++ ABI:: Controlling C++ ABI changes.
- * D Language and ABI:: Controlling D ABI changes.
- * Named Address Spaces:: Adding support for named address spaces
- * Misc:: Everything else.
-
-
- File: gccint.info, Node: Target Structure, Next: Driver, Up: Target Macros
-
- 18.1 The Global 'targetm' Variable
- ==================================
-
- -- Variable: struct gcc_target targetm
- The target '.c' file must define the global 'targetm' variable
- which contains pointers to functions and data relating to the
- target machine. The variable is declared in 'target.h';
- 'target-def.h' defines the macro 'TARGET_INITIALIZER' which is used
- to initialize the variable, and macros for the default initializers
- for elements of the structure. The '.c' file should override those
- macros for which the default definition is inappropriate. For
- example:
- #include "target.h"
- #include "target-def.h"
-
- /* Initialize the GCC target structure. */
-
- #undef TARGET_COMP_TYPE_ATTRIBUTES
- #define TARGET_COMP_TYPE_ATTRIBUTES MACHINE_comp_type_attributes
-
- struct gcc_target targetm = TARGET_INITIALIZER;
-
- Where a macro should be defined in the '.c' file in this manner to form
- part of the 'targetm' structure, it is documented below as a "Target
- Hook" with a prototype. Many macros will change in future from being
- defined in the '.h' file to being part of the 'targetm' structure.
-
- Similarly, there is a 'targetcm' variable for hooks that are specific
- to front ends for C-family languages, documented as "C Target Hook".
- This is declared in 'c-family/c-target.h', the initializer
- 'TARGETCM_INITIALIZER' in 'c-family/c-target-def.h'. If targets
- initialize 'targetcm' themselves, they should set
- 'target_has_targetcm=yes' in 'config.gcc'; otherwise a default
- definition is used.
-
- Similarly, there is a 'targetm_common' variable for hooks that are
- shared between the compiler driver and the compilers proper, documented
- as "Common Target Hook". This is declared in 'common/common-target.h',
- the initializer 'TARGETM_COMMON_INITIALIZER' in
- 'common/common-target-def.h'. If targets initialize 'targetm_common'
- themselves, they should set 'target_has_targetm_common=yes' in
- 'config.gcc'; otherwise a default definition is used.
-
- Similarly, there is a 'targetdm' variable for hooks that are specific
- to the D language front end, documented as "D Target Hook". This is
- declared in 'd/d-target.h', the initializer 'TARGETDM_INITIALIZER' in
- 'd/d-target-def.h'. If targets initialize 'targetdm' themselves, they
- should set 'target_has_targetdm=yes' in 'config.gcc'; otherwise a
- default definition is used.
-
-
- File: gccint.info, Node: Driver, Next: Run-time Target, Prev: Target Structure, Up: Target Macros
-
- 18.2 Controlling the Compilation Driver, 'gcc'
- ==============================================
-
- You can control the compilation driver.
-
- -- Macro: DRIVER_SELF_SPECS
- A list of specs for the driver itself. It should be a suitable
- initializer for an array of strings, with no surrounding braces.
-
- The driver applies these specs to its own command line between
- loading default 'specs' files (but not command-line specified ones)
- and choosing the multilib directory or running any subcommands. It
- applies them in the order given, so each spec can depend on the
- options added by earlier ones. It is also possible to remove
- options using '%<OPTION' in the usual way.
-
- This macro can be useful when a port has several interdependent
- target options. It provides a way of standardizing the command
- line so that the other specs are easier to write.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: OPTION_DEFAULT_SPECS
- A list of specs used to support configure-time default options
- (i.e. '--with' options) in the driver. It should be a suitable
- initializer for an array of structures, each containing two
- strings, without the outermost pair of surrounding braces.
-
- The first item in the pair is the name of the default. This must
- match the code in 'config.gcc' for the target. The second item is
- a spec to apply if a default with this name was specified. The
- string '%(VALUE)' in the spec will be replaced by the value of the
- default everywhere it occurs.
-
- The driver will apply these specs to its own command line between
- loading default 'specs' files and processing 'DRIVER_SELF_SPECS',
- using the same mechanism as 'DRIVER_SELF_SPECS'.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: CPP_SPEC
- A C string constant that tells the GCC driver program options to
- pass to CPP. It can also specify how to translate options you give
- to GCC into options for GCC to pass to the CPP.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: CPLUSPLUS_CPP_SPEC
- This macro is just like 'CPP_SPEC', but is used for C++, rather
- than C. If you do not define this macro, then the value of
- 'CPP_SPEC' (if any) will be used instead.
-
- -- Macro: CC1_SPEC
- A C string constant that tells the GCC driver program options to
- pass to 'cc1', 'cc1plus', 'f771', and the other language front
- ends. It can also specify how to translate options you give to GCC
- into options for GCC to pass to front ends.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: CC1PLUS_SPEC
- A C string constant that tells the GCC driver program options to
- pass to 'cc1plus'. It can also specify how to translate options
- you give to GCC into options for GCC to pass to the 'cc1plus'.
-
- Do not define this macro if it does not need to do anything. Note
- that everything defined in CC1_SPEC is already passed to 'cc1plus'
- so there is no need to duplicate the contents of CC1_SPEC in
- CC1PLUS_SPEC.
-
- -- Macro: ASM_SPEC
- A C string constant that tells the GCC driver program options to
- pass to the assembler. It can also specify how to translate
- options you give to GCC into options for GCC to pass to the
- assembler. See the file 'sun3.h' for an example of this.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: ASM_FINAL_SPEC
- A C string constant that tells the GCC driver program how to run
- any programs which cleanup after the normal assembler. Normally,
- this is not needed. See the file 'mips.h' for an example of this.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: AS_NEEDS_DASH_FOR_PIPED_INPUT
- Define this macro, with no value, if the driver should give the
- assembler an argument consisting of a single dash, '-', to instruct
- it to read from its standard input (which will be a pipe connected
- to the output of the compiler proper). This argument is given
- after any '-o' option specifying the name of the output file.
-
- If you do not define this macro, the assembler is assumed to read
- its standard input if given no non-option arguments. If your
- assembler cannot read standard input at all, use a '%{pipe:%e}'
- construct; see 'mips.h' for instance.
-
- -- Macro: LINK_SPEC
- A C string constant that tells the GCC driver program options to
- pass to the linker. It can also specify how to translate options
- you give to GCC into options for GCC to pass to the linker.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: LIB_SPEC
- Another C string constant used much like 'LINK_SPEC'. The
- difference between the two is that 'LIB_SPEC' is used at the end of
- the command given to the linker.
-
- If this macro is not defined, a default is provided that loads the
- standard C library from the usual place. See 'gcc.c'.
-
- -- Macro: LIBGCC_SPEC
- Another C string constant that tells the GCC driver program how and
- when to place a reference to 'libgcc.a' into the linker command
- line. This constant is placed both before and after the value of
- 'LIB_SPEC'.
-
- If this macro is not defined, the GCC driver provides a default
- that passes the string '-lgcc' to the linker.
-
- -- Macro: REAL_LIBGCC_SPEC
- By default, if 'ENABLE_SHARED_LIBGCC' is defined, the 'LIBGCC_SPEC'
- is not directly used by the driver program but is instead modified
- to refer to different versions of 'libgcc.a' depending on the
- values of the command line flags '-static', '-shared',
- '-static-libgcc', and '-shared-libgcc'. On targets where these
- modifications are inappropriate, define 'REAL_LIBGCC_SPEC' instead.
- 'REAL_LIBGCC_SPEC' tells the driver how to place a reference to
- 'libgcc' on the link command line, but, unlike 'LIBGCC_SPEC', it is
- used unmodified.
-
- -- Macro: USE_LD_AS_NEEDED
- A macro that controls the modifications to 'LIBGCC_SPEC' mentioned
- in 'REAL_LIBGCC_SPEC'. If nonzero, a spec will be generated that
- uses '--as-needed' or equivalent options and the shared 'libgcc' in
- place of the static exception handler library, when linking without
- any of '-static', '-static-libgcc', or '-shared-libgcc'.
-
- -- Macro: LINK_EH_SPEC
- If defined, this C string constant is added to 'LINK_SPEC'. When
- 'USE_LD_AS_NEEDED' is zero or undefined, it also affects the
- modifications to 'LIBGCC_SPEC' mentioned in 'REAL_LIBGCC_SPEC'.
-
- -- Macro: STARTFILE_SPEC
- Another C string constant used much like 'LINK_SPEC'. The
- difference between the two is that 'STARTFILE_SPEC' is used at the
- very beginning of the command given to the linker.
-
- If this macro is not defined, a default is provided that loads the
- standard C startup file from the usual place. See 'gcc.c'.
-
- -- Macro: ENDFILE_SPEC
- Another C string constant used much like 'LINK_SPEC'. The
- difference between the two is that 'ENDFILE_SPEC' is used at the
- very end of the command given to the linker.
-
- Do not define this macro if it does not need to do anything.
-
- -- Macro: THREAD_MODEL_SPEC
- GCC '-v' will print the thread model GCC was configured to use.
- However, this doesn't work on platforms that are multilibbed on
- thread models, such as AIX 4.3. On such platforms, define
- 'THREAD_MODEL_SPEC' such that it evaluates to a string without
- blanks that names one of the recognized thread models. '%*', the
- default value of this macro, will expand to the value of
- 'thread_file' set in 'config.gcc'.
-
- -- Macro: SYSROOT_SUFFIX_SPEC
- Define this macro to add a suffix to the target sysroot when GCC is
- configured with a sysroot. This will cause GCC to search for
- usr/lib, et al, within sysroot+suffix.
-
- -- Macro: SYSROOT_HEADERS_SUFFIX_SPEC
- Define this macro to add a headers_suffix to the target sysroot
- when GCC is configured with a sysroot. This will cause GCC to pass
- the updated sysroot+headers_suffix to CPP, causing it to search for
- usr/include, et al, within sysroot+headers_suffix.
-
- -- Macro: EXTRA_SPECS
- Define this macro to provide additional specifications to put in
- the 'specs' file that can be used in various specifications like
- 'CC1_SPEC'.
-
- The definition should be an initializer for an array of structures,
- containing a string constant, that defines the specification name,
- and a string constant that provides the specification.
-
- Do not define this macro if it does not need to do anything.
-
- 'EXTRA_SPECS' is useful when an architecture contains several
- related targets, which have various '..._SPECS' which are similar
- to each other, and the maintainer would like one central place to
- keep these definitions.
-
- For example, the PowerPC System V.4 targets use 'EXTRA_SPECS' to
- define either '_CALL_SYSV' when the System V calling sequence is
- used or '_CALL_AIX' when the older AIX-based calling sequence is
- used.
-
- The 'config/rs6000/rs6000.h' target file defines:
-
- #define EXTRA_SPECS \
- { "cpp_sysv_default", CPP_SYSV_DEFAULT },
-
- #define CPP_SYS_DEFAULT ""
-
- The 'config/rs6000/sysv.h' target file defines:
- #undef CPP_SPEC
- #define CPP_SPEC \
- "%{posix: -D_POSIX_SOURCE } \
- %{mcall-sysv: -D_CALL_SYSV } \
- %{!mcall-sysv: %(cpp_sysv_default) } \
- %{msoft-float: -D_SOFT_FLOAT} %{mcpu=403: -D_SOFT_FLOAT}"
-
- #undef CPP_SYSV_DEFAULT
- #define CPP_SYSV_DEFAULT "-D_CALL_SYSV"
-
- while the 'config/rs6000/eabiaix.h' target file defines
- 'CPP_SYSV_DEFAULT' as:
-
- #undef CPP_SYSV_DEFAULT
- #define CPP_SYSV_DEFAULT "-D_CALL_AIX"
-
- -- Macro: LINK_LIBGCC_SPECIAL_1
- Define this macro if the driver program should find the library
- 'libgcc.a'. If you do not define this macro, the driver program
- will pass the argument '-lgcc' to tell the linker to do the search.
-
- -- Macro: LINK_GCC_C_SEQUENCE_SPEC
- The sequence in which libgcc and libc are specified to the linker.
- By default this is '%G %L %G'.
-
- -- Macro: POST_LINK_SPEC
- Define this macro to add additional steps to be executed after
- linker. The default value of this macro is empty string.
-
- -- Macro: LINK_COMMAND_SPEC
- A C string constant giving the complete command line need to
- execute the linker. When you do this, you will need to update your
- port each time a change is made to the link command line within
- 'gcc.c'. Therefore, define this macro only if you need to
- completely redefine the command line for invoking the linker and
- there is no other way to accomplish the effect you need.
- Overriding this macro may be avoidable by overriding
- 'LINK_GCC_C_SEQUENCE_SPEC' instead.
-
- -- Common Target Hook: bool TARGET_ALWAYS_STRIP_DOTDOT
- True if '..' components should always be removed from directory
- names computed relative to GCC's internal directories, false
- (default) if such components should be preserved and directory
- names containing them passed to other tools such as the linker.
-
- -- Macro: MULTILIB_DEFAULTS
- Define this macro as a C expression for the initializer of an array
- of string to tell the driver program which options are defaults for
- this target and thus do not need to be handled specially when using
- 'MULTILIB_OPTIONS'.
-
- Do not define this macro if 'MULTILIB_OPTIONS' is not defined in
- the target makefile fragment or if none of the options listed in
- 'MULTILIB_OPTIONS' are set by default. *Note Target Fragment::.
-
- -- Macro: RELATIVE_PREFIX_NOT_LINKDIR
- Define this macro to tell 'gcc' that it should only translate a
- '-B' prefix into a '-L' linker option if the prefix indicates an
- absolute file name.
-
- -- Macro: MD_EXEC_PREFIX
- If defined, this macro is an additional prefix to try after
- 'STANDARD_EXEC_PREFIX'. 'MD_EXEC_PREFIX' is not searched when the
- compiler is built as a cross compiler. If you define
- 'MD_EXEC_PREFIX', then be sure to add it to the list of directories
- used to find the assembler in 'configure.ac'.
-
- -- Macro: STANDARD_STARTFILE_PREFIX
- Define this macro as a C string constant if you wish to override
- the standard choice of 'libdir' as the default prefix to try when
- searching for startup files such as 'crt0.o'.
- 'STANDARD_STARTFILE_PREFIX' is not searched when the compiler is
- built as a cross compiler.
-
- -- Macro: STANDARD_STARTFILE_PREFIX_1
- Define this macro as a C string constant if you wish to override
- the standard choice of '/lib' as a prefix to try after the default
- prefix when searching for startup files such as 'crt0.o'.
- 'STANDARD_STARTFILE_PREFIX_1' is not searched when the compiler is
- built as a cross compiler.
-
- -- Macro: STANDARD_STARTFILE_PREFIX_2
- Define this macro as a C string constant if you wish to override
- the standard choice of '/lib' as yet another prefix to try after
- the default prefix when searching for startup files such as
- 'crt0.o'. 'STANDARD_STARTFILE_PREFIX_2' is not searched when the
- compiler is built as a cross compiler.
-
- -- Macro: MD_STARTFILE_PREFIX
- If defined, this macro supplies an additional prefix to try after
- the standard prefixes. 'MD_EXEC_PREFIX' is not searched when the
- compiler is built as a cross compiler.
-
- -- Macro: MD_STARTFILE_PREFIX_1
- If defined, this macro supplies yet another prefix to try after the
- standard prefixes. It is not searched when the compiler is built
- as a cross compiler.
-
- -- Macro: INIT_ENVIRONMENT
- Define this macro as a C string constant if you wish to set
- environment variables for programs called by the driver, such as
- the assembler and loader. The driver passes the value of this
- macro to 'putenv' to initialize the necessary environment
- variables.
-
- -- Macro: LOCAL_INCLUDE_DIR
- Define this macro as a C string constant if you wish to override
- the standard choice of '/usr/local/include' as the default prefix
- to try when searching for local header files. 'LOCAL_INCLUDE_DIR'
- comes before 'NATIVE_SYSTEM_HEADER_DIR' (set in 'config.gcc',
- normally '/usr/include') in the search order.
-
- Cross compilers do not search either '/usr/local/include' or its
- replacement.
-
- -- Macro: NATIVE_SYSTEM_HEADER_COMPONENT
- The "component" corresponding to 'NATIVE_SYSTEM_HEADER_DIR'. See
- 'INCLUDE_DEFAULTS', below, for the description of components. If
- you do not define this macro, no component is used.
-
- -- Macro: INCLUDE_DEFAULTS
- Define this macro if you wish to override the entire default search
- path for include files. For a native compiler, the default search
- path usually consists of 'GCC_INCLUDE_DIR', 'LOCAL_INCLUDE_DIR',
- 'GPLUSPLUS_INCLUDE_DIR', and 'NATIVE_SYSTEM_HEADER_DIR'. In
- addition, 'GPLUSPLUS_INCLUDE_DIR' and 'GCC_INCLUDE_DIR' are defined
- automatically by 'Makefile', and specify private search areas for
- GCC. The directory 'GPLUSPLUS_INCLUDE_DIR' is used only for C++
- programs.
-
- The definition should be an initializer for an array of structures.
- Each array element should have four elements: the directory name (a
- string constant), the component name (also a string constant), a
- flag for C++-only directories, and a flag showing that the includes
- in the directory don't need to be wrapped in 'extern 'C'' when
- compiling C++. Mark the end of the array with a null element.
-
- The component name denotes what GNU package the include file is
- part of, if any, in all uppercase letters. For example, it might
- be 'GCC' or 'BINUTILS'. If the package is part of a
- vendor-supplied operating system, code the component name as '0'.
-
- For example, here is the definition used for VAX/VMS:
-
- #define INCLUDE_DEFAULTS \
- { \
- { "GNU_GXX_INCLUDE:", "G++", 1, 1}, \
- { "GNU_CC_INCLUDE:", "GCC", 0, 0}, \
- { "SYS$SYSROOT:[SYSLIB.]", 0, 0, 0}, \
- { ".", 0, 0, 0}, \
- { 0, 0, 0, 0} \
- }
-
- Here is the order of prefixes tried for exec files:
-
- 1. Any prefixes specified by the user with '-B'.
-
- 2. The environment variable 'GCC_EXEC_PREFIX' or, if 'GCC_EXEC_PREFIX'
- is not set and the compiler has not been installed in the
- configure-time PREFIX, the location in which the compiler has
- actually been installed.
-
- 3. The directories specified by the environment variable
- 'COMPILER_PATH'.
-
- 4. The macro 'STANDARD_EXEC_PREFIX', if the compiler has been
- installed in the configured-time PREFIX.
-
- 5. The location '/usr/libexec/gcc/', but only if this is a native
- compiler.
-
- 6. The location '/usr/lib/gcc/', but only if this is a native
- compiler.
-
- 7. The macro 'MD_EXEC_PREFIX', if defined, but only if this is a
- native compiler.
-
- Here is the order of prefixes tried for startfiles:
-
- 1. Any prefixes specified by the user with '-B'.
-
- 2. The environment variable 'GCC_EXEC_PREFIX' or its automatically
- determined value based on the installed toolchain location.
-
- 3. The directories specified by the environment variable
- 'LIBRARY_PATH' (or port-specific name; native only, cross compilers
- do not use this).
-
- 4. The macro 'STANDARD_EXEC_PREFIX', but only if the toolchain is
- installed in the configured PREFIX or this is a native compiler.
-
- 5. The location '/usr/lib/gcc/', but only if this is a native
- compiler.
-
- 6. The macro 'MD_EXEC_PREFIX', if defined, but only if this is a
- native compiler.
-
- 7. The macro 'MD_STARTFILE_PREFIX', if defined, but only if this is a
- native compiler, or we have a target system root.
-
- 8. The macro 'MD_STARTFILE_PREFIX_1', if defined, but only if this is
- a native compiler, or we have a target system root.
-
- 9. The macro 'STANDARD_STARTFILE_PREFIX', with any sysroot
- modifications. If this path is relative it will be prefixed by
- 'GCC_EXEC_PREFIX' and the machine suffix or 'STANDARD_EXEC_PREFIX'
- and the machine suffix.
-
- 10. The macro 'STANDARD_STARTFILE_PREFIX_1', but only if this is a
- native compiler, or we have a target system root. The default for
- this macro is '/lib/'.
-
- 11. The macro 'STANDARD_STARTFILE_PREFIX_2', but only if this is a
- native compiler, or we have a target system root. The default for
- this macro is '/usr/lib/'.
-
-
- File: gccint.info, Node: Run-time Target, Next: Per-Function Data, Prev: Driver, Up: Target Macros
-
- 18.3 Run-time Target Specification
- ==================================
-
- Here are run-time target specifications.
-
- -- Macro: TARGET_CPU_CPP_BUILTINS ()
- This function-like macro expands to a block of code that defines
- built-in preprocessor macros and assertions for the target CPU,
- using the functions 'builtin_define', 'builtin_define_std' and
- 'builtin_assert'. When the front end calls this macro it provides
- a trailing semicolon, and since it has finished command line option
- processing your code can use those results freely.
-
- 'builtin_assert' takes a string in the form you pass to the
- command-line option '-A', such as 'cpu=mips', and creates the
- assertion. 'builtin_define' takes a string in the form accepted by
- option '-D' and unconditionally defines the macro.
-
- 'builtin_define_std' takes a string representing the name of an
- object-like macro. If it doesn't lie in the user's namespace,
- 'builtin_define_std' defines it unconditionally. Otherwise, it
- defines a version with two leading underscores, and another version
- with two leading and trailing underscores, and defines the original
- only if an ISO standard was not requested on the command line. For
- example, passing 'unix' defines '__unix', '__unix__' and possibly
- 'unix'; passing '_mips' defines '__mips', '__mips__' and possibly
- '_mips', and passing '_ABI64' defines only '_ABI64'.
-
- You can also test for the C dialect being compiled. The variable
- 'c_language' is set to one of 'clk_c', 'clk_cplusplus' or
- 'clk_objective_c'. Note that if we are preprocessing assembler,
- this variable will be 'clk_c' but the function-like macro
- 'preprocessing_asm_p()' will return true, so you might want to
- check for that first. If you need to check for strict ANSI, the
- variable 'flag_iso' can be used. The function-like macro
- 'preprocessing_trad_p()' can be used to check for traditional
- preprocessing.
-
- -- Macro: TARGET_OS_CPP_BUILTINS ()
- Similarly to 'TARGET_CPU_CPP_BUILTINS' but this macro is optional
- and is used for the target operating system instead.
-
- -- Macro: TARGET_OBJFMT_CPP_BUILTINS ()
- Similarly to 'TARGET_CPU_CPP_BUILTINS' but this macro is optional
- and is used for the target object format. 'elfos.h' uses this
- macro to define '__ELF__', so you probably do not need to define it
- yourself.
-
- -- Variable: extern int target_flags
- This variable is declared in 'options.h', which is included before
- any target-specific headers.
-
- -- Common Target Hook: int TARGET_DEFAULT_TARGET_FLAGS
- This variable specifies the initial value of 'target_flags'. Its
- default setting is 0.
-
- -- Common Target Hook: bool TARGET_HANDLE_OPTION (struct gcc_options
- *OPTS, struct gcc_options *OPTS_SET, const struct
- cl_decoded_option *DECODED, location_t LOC)
- This hook is called whenever the user specifies one of the
- target-specific options described by the '.opt' definition files
- (*note Options::). It has the opportunity to do some
- option-specific processing and should return true if the option is
- valid. The default definition does nothing but return true.
-
- DECODED specifies the option and its arguments. OPTS and OPTS_SET
- are the 'gcc_options' structures to be used for storing option
- state, and LOC is the location at which the option was passed
- ('UNKNOWN_LOCATION' except for options passed via attributes).
-
- -- C Target Hook: bool TARGET_HANDLE_C_OPTION (size_t CODE, const char
- *ARG, int VALUE)
- This target hook is called whenever the user specifies one of the
- target-specific C language family options described by the '.opt'
- definition files(*note Options::). It has the opportunity to do
- some option-specific processing and should return true if the
- option is valid. The arguments are like for
- 'TARGET_HANDLE_OPTION'. The default definition does nothing but
- return false.
-
- In general, you should use 'TARGET_HANDLE_OPTION' to handle
- options. However, if processing an option requires routines that
- are only available in the C (and related language) front ends, then
- you should use 'TARGET_HANDLE_C_OPTION' instead.
-
- -- C Target Hook: tree TARGET_OBJC_CONSTRUCT_STRING_OBJECT (tree
- STRING)
- Targets may provide a string object type that can be used within
- and between C, C++ and their respective Objective-C dialects. A
- string object might, for example, embed encoding and length
- information. These objects are considered opaque to the compiler
- and handled as references. An ideal implementation makes the
- composition of the string object match that of the Objective-C
- 'NSString' ('NXString' for GNUStep), allowing efficient
- interworking between C-only and Objective-C code. If a target
- implements string objects then this hook should return a reference
- to such an object constructed from the normal 'C' string
- representation provided in STRING. At present, the hook is used by
- Objective-C only, to obtain a common-format string object when the
- target provides one.
-
- -- C Target Hook: void TARGET_OBJC_DECLARE_UNRESOLVED_CLASS_REFERENCE
- (const char *CLASSNAME)
- Declare that Objective C class CLASSNAME is referenced by the
- current TU.
-
- -- C Target Hook: void TARGET_OBJC_DECLARE_CLASS_DEFINITION (const char
- *CLASSNAME)
- Declare that Objective C class CLASSNAME is defined by the current
- TU.
-
- -- C Target Hook: bool TARGET_STRING_OBJECT_REF_TYPE_P (const_tree
- STRINGREF)
- If a target implements string objects then this hook should return
- 'true' if STRINGREF is a valid reference to such an object.
-
- -- C Target Hook: void TARGET_CHECK_STRING_OBJECT_FORMAT_ARG (tree
- FORMAT_ARG, tree ARGS_LIST)
- If a target implements string objects then this hook should should
- provide a facility to check the function arguments in ARGS_LIST
- against the format specifiers in FORMAT_ARG where the type of
- FORMAT_ARG is one recognized as a valid string reference type.
-
- -- Target Hook: void TARGET_OVERRIDE_OPTIONS_AFTER_CHANGE (void)
- This target function is similar to the hook
- 'TARGET_OPTION_OVERRIDE' but is called when the optimize level is
- changed via an attribute or pragma or when it is reset at the end
- of the code affected by the attribute or pragma. It is not called
- at the beginning of compilation when 'TARGET_OPTION_OVERRIDE' is
- called so if you want to perform these actions then, you should
- have 'TARGET_OPTION_OVERRIDE' call
- 'TARGET_OVERRIDE_OPTIONS_AFTER_CHANGE'.
-
- -- Macro: C_COMMON_OVERRIDE_OPTIONS
- This is similar to the 'TARGET_OPTION_OVERRIDE' hook but is only
- used in the C language frontends (C, Objective-C, C++,
- Objective-C++) and so can be used to alter option flag variables
- which only exist in those frontends.
-
- -- Common Target Hook: const struct default_options *
- TARGET_OPTION_OPTIMIZATION_TABLE
- Some machines may desire to change what optimizations are performed
- for various optimization levels. This variable, if defined,
- describes options to enable at particular sets of optimization
- levels. These options are processed once just after the
- optimization level is determined and before the remainder of the
- command options have been parsed, so may be overridden by other
- options passed explicitly.
-
- This processing is run once at program startup and when the
- optimization options are changed via '#pragma GCC optimize' or by
- using the 'optimize' attribute.
-
- -- Common Target Hook: void TARGET_OPTION_INIT_STRUCT (struct
- gcc_options *OPTS)
- Set target-dependent initial values of fields in OPTS.
-
- -- Macro: SWITCHABLE_TARGET
- Some targets need to switch between substantially different
- subtargets during compilation. For example, the MIPS target has
- one subtarget for the traditional MIPS architecture and another for
- MIPS16. Source code can switch between these two subarchitectures
- using the 'mips16' and 'nomips16' attributes.
-
- Such subtargets can differ in things like the set of available
- registers, the set of available instructions, the costs of various
- operations, and so on. GCC caches a lot of this type of
- information in global variables, and recomputing them for each
- subtarget takes a significant amount of time. The compiler
- therefore provides a facility for maintaining several versions of
- the global variables and quickly switching between them; see
- 'target-globals.h' for details.
-
- Define this macro to 1 if your target needs this facility. The
- default is 0.
-
- -- Target Hook: bool TARGET_FLOAT_EXCEPTIONS_ROUNDING_SUPPORTED_P
- (void)
- Returns true if the target supports IEEE 754 floating-point
- exceptions and rounding modes, false otherwise. This is intended
- to relate to the 'float' and 'double' types, but not necessarily
- 'long double'. By default, returns true if the 'adddf3'
- instruction pattern is available and false otherwise, on the
- assumption that hardware floating point supports exceptions and
- rounding modes but software floating point does not.
-
-
- File: gccint.info, Node: Per-Function Data, Next: Storage Layout, Prev: Run-time Target, Up: Target Macros
-
- 18.4 Defining data structures for per-function information.
- ===========================================================
-
- If the target needs to store information on a per-function basis, GCC
- provides a macro and a couple of variables to allow this. Note, just
- using statics to store the information is a bad idea, since GCC supports
- nested functions, so you can be halfway through encoding one function
- when another one comes along.
-
- GCC defines a data structure called 'struct function' which contains
- all of the data specific to an individual function. This structure
- contains a field called 'machine' whose type is 'struct machine_function
- *', which can be used by targets to point to their own specific data.
-
- If a target needs per-function specific data it should define the type
- 'struct machine_function' and also the macro 'INIT_EXPANDERS'. This
- macro should be used to initialize the function pointer
- 'init_machine_status'. This pointer is explained below.
-
- One typical use of per-function, target specific data is to create an
- RTX to hold the register containing the function's return address. This
- RTX can then be used to implement the '__builtin_return_address'
- function, for level 0.
-
- Note--earlier implementations of GCC used a single data area to hold
- all of the per-function information. Thus when processing of a nested
- function began the old per-function data had to be pushed onto a stack,
- and when the processing was finished, it had to be popped off the stack.
- GCC used to provide function pointers called 'save_machine_status' and
- 'restore_machine_status' to handle the saving and restoring of the
- target specific information. Since the single data area approach is no
- longer used, these pointers are no longer supported.
-
- -- Macro: INIT_EXPANDERS
- Macro called to initialize any target specific information. This
- macro is called once per function, before generation of any RTL has
- begun. The intention of this macro is to allow the initialization
- of the function pointer 'init_machine_status'.
-
- -- Variable: void (*)(struct function *) init_machine_status
- If this function pointer is non-'NULL' it will be called once per
- function, before function compilation starts, in order to allow the
- target to perform any target specific initialization of the 'struct
- function' structure. It is intended that this would be used to
- initialize the 'machine' of that structure.
-
- 'struct machine_function' structures are expected to be freed by
- GC. Generally, any memory that they reference must be allocated by
- using GC allocation, including the structure itself.
-
-
- File: gccint.info, Node: Storage Layout, Next: Type Layout, Prev: Per-Function Data, Up: Target Macros
-
- 18.5 Storage Layout
- ===================
-
- Note that the definitions of the macros in this table which are sizes or
- alignments measured in bits do not need to be constant. They can be C
- expressions that refer to static variables, such as the 'target_flags'.
- *Note Run-time Target::.
-
- -- Macro: BITS_BIG_ENDIAN
- Define this macro to have the value 1 if the most significant bit
- in a byte has the lowest number; otherwise define it to have the
- value zero. This means that bit-field instructions count from the
- most significant bit. If the machine has no bit-field
- instructions, then this must still be defined, but it doesn't
- matter which value it is defined to. This macro need not be a
- constant.
-
- This macro does not affect the way structure fields are packed into
- bytes or words; that is controlled by 'BYTES_BIG_ENDIAN'.
-
- -- Macro: BYTES_BIG_ENDIAN
- Define this macro to have the value 1 if the most significant byte
- in a word has the lowest number. This macro need not be a
- constant.
-
- -- Macro: WORDS_BIG_ENDIAN
- Define this macro to have the value 1 if, in a multiword object,
- the most significant word has the lowest number. This applies to
- both memory locations and registers; see 'REG_WORDS_BIG_ENDIAN' if
- the order of words in memory is not the same as the order in
- registers. This macro need not be a constant.
-
- -- Macro: REG_WORDS_BIG_ENDIAN
- On some machines, the order of words in a multiword object differs
- between registers in memory. In such a situation, define this
- macro to describe the order of words in a register. The macro
- 'WORDS_BIG_ENDIAN' controls the order of words in memory.
-
- -- Macro: FLOAT_WORDS_BIG_ENDIAN
- Define this macro to have the value 1 if 'DFmode', 'XFmode' or
- 'TFmode' floating point numbers are stored in memory with the word
- containing the sign bit at the lowest address; otherwise define it
- to have the value 0. This macro need not be a constant.
-
- You need not define this macro if the ordering is the same as for
- multi-word integers.
-
- -- Macro: BITS_PER_WORD
- Number of bits in a word. If you do not define this macro, the
- default is 'BITS_PER_UNIT * UNITS_PER_WORD'.
-
- -- Macro: MAX_BITS_PER_WORD
- Maximum number of bits in a word. If this is undefined, the
- default is 'BITS_PER_WORD'. Otherwise, it is the constant value
- that is the largest value that 'BITS_PER_WORD' can have at
- run-time.
-
- -- Macro: UNITS_PER_WORD
- Number of storage units in a word; normally the size of a
- general-purpose register, a power of two from 1 or 8.
-
- -- Macro: MIN_UNITS_PER_WORD
- Minimum number of units in a word. If this is undefined, the
- default is 'UNITS_PER_WORD'. Otherwise, it is the constant value
- that is the smallest value that 'UNITS_PER_WORD' can have at
- run-time.
-
- -- Macro: POINTER_SIZE
- Width of a pointer, in bits. You must specify a value no wider
- than the width of 'Pmode'. If it is not equal to the width of
- 'Pmode', you must define 'POINTERS_EXTEND_UNSIGNED'. If you do not
- specify a value the default is 'BITS_PER_WORD'.
-
- -- Macro: POINTERS_EXTEND_UNSIGNED
- A C expression that determines how pointers should be extended from
- 'ptr_mode' to either 'Pmode' or 'word_mode'. It is greater than
- zero if pointers should be zero-extended, zero if they should be
- sign-extended, and negative if some other sort of conversion is
- needed. In the last case, the extension is done by the target's
- 'ptr_extend' instruction.
-
- You need not define this macro if the 'ptr_mode', 'Pmode' and
- 'word_mode' are all the same width.
-
- -- Macro: PROMOTE_MODE (M, UNSIGNEDP, TYPE)
- A macro to update M and UNSIGNEDP when an object whose type is TYPE
- and which has the specified mode and signedness is to be stored in
- a register. This macro is only called when TYPE is a scalar type.
-
- On most RISC machines, which only have operations that operate on a
- full register, define this macro to set M to 'word_mode' if M is an
- integer mode narrower than 'BITS_PER_WORD'. In most cases, only
- integer modes should be widened because wider-precision
- floating-point operations are usually more expensive than their
- narrower counterparts.
-
- For most machines, the macro definition does not change UNSIGNEDP.
- However, some machines, have instructions that preferentially
- handle either signed or unsigned quantities of certain modes. For
- example, on the DEC Alpha, 32-bit loads from memory and 32-bit add
- instructions sign-extend the result to 64 bits. On such machines,
- set UNSIGNEDP according to which kind of extension is more
- efficient.
-
- Do not define this macro if it would never modify M.
-
- -- Target Hook: enum flt_eval_method TARGET_C_EXCESS_PRECISION (enum
- excess_precision_type TYPE)
- Return a value, with the same meaning as the C99 macro
- 'FLT_EVAL_METHOD' that describes which excess precision should be
- applied. TYPE is either 'EXCESS_PRECISION_TYPE_IMPLICIT',
- 'EXCESS_PRECISION_TYPE_FAST', or 'EXCESS_PRECISION_TYPE_STANDARD'.
- For 'EXCESS_PRECISION_TYPE_IMPLICIT', the target should return
- which precision and range operations will be implictly evaluated in
- regardless of the excess precision explicitly added. For
- 'EXCESS_PRECISION_TYPE_STANDARD' and 'EXCESS_PRECISION_TYPE_FAST',
- the target should return the explicit excess precision that should
- be added depending on the value set for
- '-fexcess-precision=[standard|fast]'. Note that unpredictable
- explicit excess precision does not make sense, so a target should
- never return 'FLT_EVAL_METHOD_UNPREDICTABLE' when TYPE is
- 'EXCESS_PRECISION_TYPE_STANDARD' or 'EXCESS_PRECISION_TYPE_FAST'.
-
- -- Target Hook: machine_mode TARGET_PROMOTE_FUNCTION_MODE (const_tree
- TYPE, machine_mode MODE, int *PUNSIGNEDP, const_tree FUNTYPE,
- int FOR_RETURN)
- Like 'PROMOTE_MODE', but it is applied to outgoing function
- arguments or function return values. The target hook should return
- the new mode and possibly change '*PUNSIGNEDP' if the promotion
- should change signedness. This function is called only for scalar
- _or pointer_ types.
-
- FOR_RETURN allows to distinguish the promotion of arguments and
- return values. If it is '1', a return value is being promoted and
- 'TARGET_FUNCTION_VALUE' must perform the same promotions done here.
- If it is '2', the returned mode should be that of the register in
- which an incoming parameter is copied, or the outgoing result is
- computed; then the hook should return the same mode as
- 'promote_mode', though the signedness may be different.
-
- TYPE can be NULL when promoting function arguments of libcalls.
-
- The default is to not promote arguments and return values. You can
- also define the hook to
- 'default_promote_function_mode_always_promote' if you would like to
- apply the same rules given by 'PROMOTE_MODE'.
-
- -- Macro: PARM_BOUNDARY
- Normal alignment required for function parameters on the stack, in
- bits. All stack parameters receive at least this much alignment
- regardless of data type. On most machines, this is the same as the
- size of an integer.
-
- -- Macro: STACK_BOUNDARY
- Define this macro to the minimum alignment enforced by hardware for
- the stack pointer on this machine. The definition is a C
- expression for the desired alignment (measured in bits). This
- value is used as a default if 'PREFERRED_STACK_BOUNDARY' is not
- defined. On most machines, this should be the same as
- 'PARM_BOUNDARY'.
-
- -- Macro: PREFERRED_STACK_BOUNDARY
- Define this macro if you wish to preserve a certain alignment for
- the stack pointer, greater than what the hardware enforces. The
- definition is a C expression for the desired alignment (measured in
- bits). This macro must evaluate to a value equal to or larger than
- 'STACK_BOUNDARY'.
-
- -- Macro: INCOMING_STACK_BOUNDARY
- Define this macro if the incoming stack boundary may be different
- from 'PREFERRED_STACK_BOUNDARY'. This macro must evaluate to a
- value equal to or larger than 'STACK_BOUNDARY'.
-
- -- Macro: FUNCTION_BOUNDARY
- Alignment required for a function entry point, in bits.
-
- -- Macro: BIGGEST_ALIGNMENT
- Biggest alignment that any data type can require on this machine,
- in bits. Note that this is not the biggest alignment that is
- supported, just the biggest alignment that, when violated, may
- cause a fault.
-
- -- Target Hook: HOST_WIDE_INT TARGET_ABSOLUTE_BIGGEST_ALIGNMENT
- If defined, this target hook specifies the absolute biggest
- alignment that a type or variable can have on this machine,
- otherwise, 'BIGGEST_ALIGNMENT' is used.
-
- -- Macro: MALLOC_ABI_ALIGNMENT
- Alignment, in bits, a C conformant malloc implementation has to
- provide. If not defined, the default value is 'BITS_PER_WORD'.
-
- -- Macro: ATTRIBUTE_ALIGNED_VALUE
- Alignment used by the '__attribute__ ((aligned))' construct. If
- not defined, the default value is 'BIGGEST_ALIGNMENT'.
-
- -- Macro: MINIMUM_ATOMIC_ALIGNMENT
- If defined, the smallest alignment, in bits, that can be given to
- an object that can be referenced in one operation, without
- disturbing any nearby object. Normally, this is 'BITS_PER_UNIT',
- but may be larger on machines that don't have byte or half-word
- store operations.
-
- -- Macro: BIGGEST_FIELD_ALIGNMENT
- Biggest alignment that any structure or union field can require on
- this machine, in bits. If defined, this overrides
- 'BIGGEST_ALIGNMENT' for structure and union fields only, unless the
- field alignment has been set by the '__attribute__ ((aligned (N)))'
- construct.
-
- -- Macro: ADJUST_FIELD_ALIGN (FIELD, TYPE, COMPUTED)
- An expression for the alignment of a structure field FIELD of type
- TYPE if the alignment computed in the usual way (including applying
- of 'BIGGEST_ALIGNMENT' and 'BIGGEST_FIELD_ALIGNMENT' to the
- alignment) is COMPUTED. It overrides alignment only if the field
- alignment has not been set by the '__attribute__ ((aligned (N)))'
- construct. Note that FIELD may be 'NULL_TREE' in case we just
- query for the minimum alignment of a field of type TYPE in
- structure context.
-
- -- Macro: MAX_STACK_ALIGNMENT
- Biggest stack alignment guaranteed by the backend. Use this macro
- to specify the maximum alignment of a variable on stack.
-
- If not defined, the default value is 'STACK_BOUNDARY'.
-
- -- Macro: MAX_OFILE_ALIGNMENT
- Biggest alignment supported by the object file format of this
- machine. Use this macro to limit the alignment which can be
- specified using the '__attribute__ ((aligned (N)))' construct for
- functions and objects with static storage duration. The alignment
- of automatic objects may exceed the object file format maximum up
- to the maximum supported by GCC. If not defined, the default value
- is 'BIGGEST_ALIGNMENT'.
-
- On systems that use ELF, the default (in 'config/elfos.h') is the
- largest supported 32-bit ELF section alignment representable on a
- 32-bit host e.g. '(((uint64_t) 1 << 28) * 8)'. On 32-bit ELF the
- largest supported section alignment in bits is '(0x80000000 * 8)',
- but this is not representable on 32-bit hosts.
-
- -- Target Hook: HOST_WIDE_INT TARGET_STATIC_RTX_ALIGNMENT (machine_mode
- MODE)
- This hook returns the preferred alignment in bits for a
- statically-allocated rtx, such as a constant pool entry. MODE is
- the mode of the rtx. The default implementation returns
- 'GET_MODE_ALIGNMENT (MODE)'.
-
- -- Macro: DATA_ALIGNMENT (TYPE, BASIC-ALIGN)
- If defined, a C expression to compute the alignment for a variable
- in the static store. TYPE is the data type, and BASIC-ALIGN is the
- alignment that the object would ordinarily have. The value of this
- macro is used instead of that alignment to align the object.
-
- If this macro is not defined, then BASIC-ALIGN is used.
-
- One use of this macro is to increase alignment of medium-size data
- to make it all fit in fewer cache lines. Another is to cause
- character arrays to be word-aligned so that 'strcpy' calls that
- copy constants to character arrays can be done inline.
-
- -- Macro: DATA_ABI_ALIGNMENT (TYPE, BASIC-ALIGN)
- Similar to 'DATA_ALIGNMENT', but for the cases where the ABI
- mandates some alignment increase, instead of optimization only
- purposes. E.g. AMD x86-64 psABI says that variables with array
- type larger than 15 bytes must be aligned to 16 byte boundaries.
-
- If this macro is not defined, then BASIC-ALIGN is used.
-
- -- Target Hook: HOST_WIDE_INT TARGET_CONSTANT_ALIGNMENT (const_tree
- CONSTANT, HOST_WIDE_INT BASIC_ALIGN)
- This hook returns the alignment in bits of a constant that is being
- placed in memory. CONSTANT is the constant and BASIC_ALIGN is the
- alignment that the object would ordinarily have.
-
- The default definition just returns BASIC_ALIGN.
-
- The typical use of this hook is to increase alignment for string
- constants to be word aligned so that 'strcpy' calls that copy
- constants can be done inline. The function
- 'constant_alignment_word_strings' provides such a definition.
-
- -- Macro: LOCAL_ALIGNMENT (TYPE, BASIC-ALIGN)
- If defined, a C expression to compute the alignment for a variable
- in the local store. TYPE is the data type, and BASIC-ALIGN is the
- alignment that the object would ordinarily have. The value of this
- macro is used instead of that alignment to align the object.
-
- If this macro is not defined, then BASIC-ALIGN is used.
-
- One use of this macro is to increase alignment of medium-size data
- to make it all fit in fewer cache lines.
-
- If the value of this macro has a type, it should be an unsigned
- type.
-
- -- Target Hook: HOST_WIDE_INT TARGET_VECTOR_ALIGNMENT (const_tree TYPE)
- This hook can be used to define the alignment for a vector of type
- TYPE, in order to comply with a platform ABI. The default is to
- require natural alignment for vector types. The alignment returned
- by this hook must be a power-of-two multiple of the default
- alignment of the vector element type.
-
- -- Macro: STACK_SLOT_ALIGNMENT (TYPE, MODE, BASIC-ALIGN)
- If defined, a C expression to compute the alignment for stack slot.
- TYPE is the data type, MODE is the widest mode available, and
- BASIC-ALIGN is the alignment that the slot would ordinarily have.
- The value of this macro is used instead of that alignment to align
- the slot.
-
- If this macro is not defined, then BASIC-ALIGN is used when TYPE is
- 'NULL'. Otherwise, 'LOCAL_ALIGNMENT' will be used.
-
- This macro is to set alignment of stack slot to the maximum
- alignment of all possible modes which the slot may have.
-
- If the value of this macro has a type, it should be an unsigned
- type.
-
- -- Macro: LOCAL_DECL_ALIGNMENT (DECL)
- If defined, a C expression to compute the alignment for a local
- variable DECL.
-
- If this macro is not defined, then 'LOCAL_ALIGNMENT (TREE_TYPE
- (DECL), DECL_ALIGN (DECL))' is used.
-
- One use of this macro is to increase alignment of medium-size data
- to make it all fit in fewer cache lines.
-
- If the value of this macro has a type, it should be an unsigned
- type.
-
- -- Macro: MINIMUM_ALIGNMENT (EXP, MODE, ALIGN)
- If defined, a C expression to compute the minimum required
- alignment for dynamic stack realignment purposes for EXP (a type or
- decl), MODE, assuming normal alignment ALIGN.
-
- If this macro is not defined, then ALIGN will be used.
-
- -- Macro: EMPTY_FIELD_BOUNDARY
- Alignment in bits to be given to a structure bit-field that follows
- an empty field such as 'int : 0;'.
-
- If 'PCC_BITFIELD_TYPE_MATTERS' is true, it overrides this macro.
-
- -- Macro: STRUCTURE_SIZE_BOUNDARY
- Number of bits which any structure or union's size must be a
- multiple of. Each structure or union's size is rounded up to a
- multiple of this.
-
- If you do not define this macro, the default is the same as
- 'BITS_PER_UNIT'.
-
- -- Macro: STRICT_ALIGNMENT
- Define this macro to be the value 1 if instructions will fail to
- work if given data not on the nominal alignment. If instructions
- will merely go slower in that case, define this macro as 0.
-
- -- Macro: PCC_BITFIELD_TYPE_MATTERS
- Define this if you wish to imitate the way many other C compilers
- handle alignment of bit-fields and the structures that contain
- them.
-
- The behavior is that the type written for a named bit-field ('int',
- 'short', or other integer type) imposes an alignment for the entire
- structure, as if the structure really did contain an ordinary field
- of that type. In addition, the bit-field is placed within the
- structure so that it would fit within such a field, not crossing a
- boundary for it.
-
- Thus, on most machines, a named bit-field whose type is written as
- 'int' would not cross a four-byte boundary, and would force
- four-byte alignment for the whole structure. (The alignment used
- may not be four bytes; it is controlled by the other alignment
- parameters.)
-
- An unnamed bit-field will not affect the alignment of the
- containing structure.
-
- If the macro is defined, its definition should be a C expression; a
- nonzero value for the expression enables this behavior.
-
- Note that if this macro is not defined, or its value is zero, some
- bit-fields may cross more than one alignment boundary. The
- compiler can support such references if there are 'insv', 'extv',
- and 'extzv' insns that can directly reference memory.
-
- The other known way of making bit-fields work is to define
- 'STRUCTURE_SIZE_BOUNDARY' as large as 'BIGGEST_ALIGNMENT'. Then
- every structure can be accessed with fullwords.
-
- Unless the machine has bit-field instructions or you define
- 'STRUCTURE_SIZE_BOUNDARY' that way, you must define
- 'PCC_BITFIELD_TYPE_MATTERS' to have a nonzero value.
-
- If your aim is to make GCC use the same conventions for laying out
- bit-fields as are used by another compiler, here is how to
- investigate what the other compiler does. Compile and run this
- program:
-
- struct foo1
- {
- char x;
- char :0;
- char y;
- };
-
- struct foo2
- {
- char x;
- int :0;
- char y;
- };
-
- main ()
- {
- printf ("Size of foo1 is %d\n",
- sizeof (struct foo1));
- printf ("Size of foo2 is %d\n",
- sizeof (struct foo2));
- exit (0);
- }
-
- If this prints 2 and 5, then the compiler's behavior is what you
- would get from 'PCC_BITFIELD_TYPE_MATTERS'.
-
- -- Macro: BITFIELD_NBYTES_LIMITED
- Like 'PCC_BITFIELD_TYPE_MATTERS' except that its effect is limited
- to aligning a bit-field within the structure.
-
- -- Target Hook: bool TARGET_ALIGN_ANON_BITFIELD (void)
- When 'PCC_BITFIELD_TYPE_MATTERS' is true this hook will determine
- whether unnamed bitfields affect the alignment of the containing
- structure. The hook should return true if the structure should
- inherit the alignment requirements of an unnamed bitfield's type.
-
- -- Target Hook: bool TARGET_NARROW_VOLATILE_BITFIELD (void)
- This target hook should return 'true' if accesses to volatile
- bitfields should use the narrowest mode possible. It should return
- 'false' if these accesses should use the bitfield container type.
-
- The default is 'false'.
-
- -- Target Hook: bool TARGET_MEMBER_TYPE_FORCES_BLK (const_tree FIELD,
- machine_mode MODE)
- Return true if a structure, union or array containing FIELD should
- be accessed using 'BLKMODE'.
-
- If FIELD is the only field in the structure, MODE is its mode,
- otherwise MODE is VOIDmode. MODE is provided in the case where
- structures of one field would require the structure's mode to
- retain the field's mode.
-
- Normally, this is not needed.
-
- -- Macro: ROUND_TYPE_ALIGN (TYPE, COMPUTED, SPECIFIED)
- Define this macro as an expression for the alignment of a type
- (given by TYPE as a tree node) if the alignment computed in the
- usual way is COMPUTED and the alignment explicitly specified was
- SPECIFIED.
-
- The default is to use SPECIFIED if it is larger; otherwise, use the
- smaller of COMPUTED and 'BIGGEST_ALIGNMENT'
-
- -- Macro: MAX_FIXED_MODE_SIZE
- An integer expression for the size in bits of the largest integer
- machine mode that should actually be used. All integer machine
- modes of this size or smaller can be used for structures and unions
- with the appropriate sizes. If this macro is undefined,
- 'GET_MODE_BITSIZE (DImode)' is assumed.
-
- -- Macro: STACK_SAVEAREA_MODE (SAVE_LEVEL)
- If defined, an expression of type 'machine_mode' that specifies the
- mode of the save area operand of a 'save_stack_LEVEL' named pattern
- (*note Standard Names::). SAVE_LEVEL is one of 'SAVE_BLOCK',
- 'SAVE_FUNCTION', or 'SAVE_NONLOCAL' and selects which of the three
- named patterns is having its mode specified.
-
- You need not define this macro if it always returns 'Pmode'. You
- would most commonly define this macro if the 'save_stack_LEVEL'
- patterns need to support both a 32- and a 64-bit mode.
-
- -- Macro: STACK_SIZE_MODE
- If defined, an expression of type 'machine_mode' that specifies the
- mode of the size increment operand of an 'allocate_stack' named
- pattern (*note Standard Names::).
-
- You need not define this macro if it always returns 'word_mode'.
- You would most commonly define this macro if the 'allocate_stack'
- pattern needs to support both a 32- and a 64-bit mode.
-
- -- Target Hook: scalar_int_mode TARGET_LIBGCC_CMP_RETURN_MODE (void)
- This target hook should return the mode to be used for the return
- value of compare instructions expanded to libgcc calls. If not
- defined 'word_mode' is returned which is the right choice for a
- majority of targets.
-
- -- Target Hook: scalar_int_mode TARGET_LIBGCC_SHIFT_COUNT_MODE (void)
- This target hook should return the mode to be used for the shift
- count operand of shift instructions expanded to libgcc calls. If
- not defined 'word_mode' is returned which is the right choice for a
- majority of targets.
-
- -- Target Hook: scalar_int_mode TARGET_UNWIND_WORD_MODE (void)
- Return machine mode to be used for '_Unwind_Word' type. The
- default is to use 'word_mode'.
-
- -- Target Hook: bool TARGET_MS_BITFIELD_LAYOUT_P (const_tree
- RECORD_TYPE)
- This target hook returns 'true' if bit-fields in the given
- RECORD_TYPE are to be laid out following the rules of Microsoft
- Visual C/C++, namely: (i) a bit-field won't share the same storage
- unit with the previous bit-field if their underlying types have
- different sizes, and the bit-field will be aligned to the highest
- alignment of the underlying types of itself and of the previous
- bit-field; (ii) a zero-sized bit-field will affect the alignment of
- the whole enclosing structure, even if it is unnamed; except that
- (iii) a zero-sized bit-field will be disregarded unless it follows
- another bit-field of nonzero size. If this hook returns 'true',
- other macros that control bit-field layout are ignored.
-
- When a bit-field is inserted into a packed record, the whole size
- of the underlying type is used by one or more same-size adjacent
- bit-fields (that is, if its long:3, 32 bits is used in the record,
- and any additional adjacent long bit-fields are packed into the
- same chunk of 32 bits. However, if the size changes, a new field
- of that size is allocated). In an unpacked record, this is the
- same as using alignment, but not equivalent when packing.
-
- If both MS bit-fields and '__attribute__((packed))' are used, the
- latter will take precedence. If '__attribute__((packed))' is used
- on a single field when MS bit-fields are in use, it will take
- precedence for that field, but the alignment of the rest of the
- structure may affect its placement.
-
- -- Target Hook: bool TARGET_DECIMAL_FLOAT_SUPPORTED_P (void)
- Returns true if the target supports decimal floating point.
-
- -- Target Hook: bool TARGET_FIXED_POINT_SUPPORTED_P (void)
- Returns true if the target supports fixed-point arithmetic.
-
- -- Target Hook: void TARGET_EXPAND_TO_RTL_HOOK (void)
- This hook is called just before expansion into rtl, allowing the
- target to perform additional initializations or analysis before the
- expansion. For example, the rs6000 port uses it to allocate a
- scratch stack slot for use in copying SDmode values between memory
- and floating point registers whenever the function being expanded
- has any SDmode usage.
-
- -- Target Hook: void TARGET_INSTANTIATE_DECLS (void)
- This hook allows the backend to perform additional instantiations
- on rtl that are not actually in any insns yet, but will be later.
-
- -- Target Hook: const char * TARGET_MANGLE_TYPE (const_tree TYPE)
- If your target defines any fundamental types, or any types your
- target uses should be mangled differently from the default, define
- this hook to return the appropriate encoding for these types as
- part of a C++ mangled name. The TYPE argument is the tree
- structure representing the type to be mangled. The hook may be
- applied to trees which are not target-specific fundamental types;
- it should return 'NULL' for all such types, as well as arguments it
- does not recognize. If the return value is not 'NULL', it must
- point to a statically-allocated string constant.
-
- Target-specific fundamental types might be new fundamental types or
- qualified versions of ordinary fundamental types. Encode new
- fundamental types as 'u N NAME', where NAME is the name used for
- the type in source code, and N is the length of NAME in decimal.
- Encode qualified versions of ordinary types as 'U N NAME CODE',
- where NAME is the name used for the type qualifier in source code,
- N is the length of NAME as above, and CODE is the code used to
- represent the unqualified version of this type. (See
- 'write_builtin_type' in 'cp/mangle.c' for the list of codes.) In
- both cases the spaces are for clarity; do not include any spaces in
- your string.
-
- This hook is applied to types prior to typedef resolution. If the
- mangled name for a particular type depends only on that type's main
- variant, you can perform typedef resolution yourself using
- 'TYPE_MAIN_VARIANT' before mangling.
-
- The default version of this hook always returns 'NULL', which is
- appropriate for a target that does not define any new fundamental
- types.
-
-
- File: gccint.info, Node: Type Layout, Next: Registers, Prev: Storage Layout, Up: Target Macros
-
- 18.6 Layout of Source Language Data Types
- =========================================
-
- These macros define the sizes and other characteristics of the standard
- basic data types used in programs being compiled. Unlike the macros in
- the previous section, these apply to specific features of C and related
- languages, rather than to fundamental aspects of storage layout.
-
- -- Macro: INT_TYPE_SIZE
- A C expression for the size in bits of the type 'int' on the target
- machine. If you don't define this, the default is one word.
-
- -- Macro: SHORT_TYPE_SIZE
- A C expression for the size in bits of the type 'short' on the
- target machine. If you don't define this, the default is half a
- word. (If this would be less than one storage unit, it is rounded
- up to one unit.)
-
- -- Macro: LONG_TYPE_SIZE
- A C expression for the size in bits of the type 'long' on the
- target machine. If you don't define this, the default is one word.
-
- -- Macro: ADA_LONG_TYPE_SIZE
- On some machines, the size used for the Ada equivalent of the type
- 'long' by a native Ada compiler differs from that used by C. In
- that situation, define this macro to be a C expression to be used
- for the size of that type. If you don't define this, the default
- is the value of 'LONG_TYPE_SIZE'.
-
- -- Macro: LONG_LONG_TYPE_SIZE
- A C expression for the size in bits of the type 'long long' on the
- target machine. If you don't define this, the default is two
- words. If you want to support GNU Ada on your machine, the value
- of this macro must be at least 64.
-
- -- Macro: CHAR_TYPE_SIZE
- A C expression for the size in bits of the type 'char' on the
- target machine. If you don't define this, the default is
- 'BITS_PER_UNIT'.
-
- -- Macro: BOOL_TYPE_SIZE
- A C expression for the size in bits of the C++ type 'bool' and C99
- type '_Bool' on the target machine. If you don't define this, and
- you probably shouldn't, the default is 'CHAR_TYPE_SIZE'.
-
- -- Macro: FLOAT_TYPE_SIZE
- A C expression for the size in bits of the type 'float' on the
- target machine. If you don't define this, the default is one word.
-
- -- Macro: DOUBLE_TYPE_SIZE
- A C expression for the size in bits of the type 'double' on the
- target machine. If you don't define this, the default is two
- words.
-
- -- Macro: LONG_DOUBLE_TYPE_SIZE
- A C expression for the size in bits of the type 'long double' on
- the target machine. If you don't define this, the default is two
- words.
-
- -- Macro: SHORT_FRACT_TYPE_SIZE
- A C expression for the size in bits of the type 'short _Fract' on
- the target machine. If you don't define this, the default is
- 'BITS_PER_UNIT'.
-
- -- Macro: FRACT_TYPE_SIZE
- A C expression for the size in bits of the type '_Fract' on the
- target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 2'.
-
- -- Macro: LONG_FRACT_TYPE_SIZE
- A C expression for the size in bits of the type 'long _Fract' on
- the target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 4'.
-
- -- Macro: LONG_LONG_FRACT_TYPE_SIZE
- A C expression for the size in bits of the type 'long long _Fract'
- on the target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 8'.
-
- -- Macro: SHORT_ACCUM_TYPE_SIZE
- A C expression for the size in bits of the type 'short _Accum' on
- the target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 2'.
-
- -- Macro: ACCUM_TYPE_SIZE
- A C expression for the size in bits of the type '_Accum' on the
- target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 4'.
-
- -- Macro: LONG_ACCUM_TYPE_SIZE
- A C expression for the size in bits of the type 'long _Accum' on
- the target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 8'.
-
- -- Macro: LONG_LONG_ACCUM_TYPE_SIZE
- A C expression for the size in bits of the type 'long long _Accum'
- on the target machine. If you don't define this, the default is
- 'BITS_PER_UNIT * 16'.
-
- -- Macro: LIBGCC2_GNU_PREFIX
- This macro corresponds to the 'TARGET_LIBFUNC_GNU_PREFIX' target
- hook and should be defined if that hook is overriden to be true.
- It causes function names in libgcc to be changed to use a '__gnu_'
- prefix for their name rather than the default '__'. A port which
- uses this macro should also arrange to use 't-gnu-prefix' in the
- libgcc 'config.host'.
-
- -- Macro: WIDEST_HARDWARE_FP_SIZE
- A C expression for the size in bits of the widest floating-point
- format supported by the hardware. If you define this macro, you
- must specify a value less than or equal to the value of
- 'LONG_DOUBLE_TYPE_SIZE'. If you do not define this macro, the
- value of 'LONG_DOUBLE_TYPE_SIZE' is the default.
-
- -- Macro: DEFAULT_SIGNED_CHAR
- An expression whose value is 1 or 0, according to whether the type
- 'char' should be signed or unsigned by default. The user can
- always override this default with the options '-fsigned-char' and
- '-funsigned-char'.
-
- -- Target Hook: bool TARGET_DEFAULT_SHORT_ENUMS (void)
- This target hook should return true if the compiler should give an
- 'enum' type only as many bytes as it takes to represent the range
- of possible values of that type. It should return false if all
- 'enum' types should be allocated like 'int'.
-
- The default is to return false.
-
- -- Macro: SIZE_TYPE
- A C expression for a string describing the name of the data type to
- use for size values. The typedef name 'size_t' is defined using
- the contents of the string.
-
- The string can contain more than one keyword. If so, separate them
- with spaces, and write first any length keyword, then 'unsigned' if
- appropriate, and finally 'int'. The string must exactly match one
- of the data type names defined in the function
- 'c_common_nodes_and_builtins' in the file 'c-family/c-common.c'.
- You may not omit 'int' or change the order--that would cause the
- compiler to crash on startup.
-
- If you don't define this macro, the default is '"long unsigned
- int"'.
-
- -- Macro: SIZETYPE
- GCC defines internal types ('sizetype', 'ssizetype', 'bitsizetype'
- and 'sbitsizetype') for expressions dealing with size. This macro
- is a C expression for a string describing the name of the data type
- from which the precision of 'sizetype' is extracted.
-
- The string has the same restrictions as 'SIZE_TYPE' string.
-
- If you don't define this macro, the default is 'SIZE_TYPE'.
-
- -- Macro: PTRDIFF_TYPE
- A C expression for a string describing the name of the data type to
- use for the result of subtracting two pointers. The typedef name
- 'ptrdiff_t' is defined using the contents of the string. See
- 'SIZE_TYPE' above for more information.
-
- If you don't define this macro, the default is '"long int"'.
-
- -- Macro: WCHAR_TYPE
- A C expression for a string describing the name of the data type to
- use for wide characters. The typedef name 'wchar_t' is defined
- using the contents of the string. See 'SIZE_TYPE' above for more
- information.
-
- If you don't define this macro, the default is '"int"'.
-
- -- Macro: WCHAR_TYPE_SIZE
- A C expression for the size in bits of the data type for wide
- characters. This is used in 'cpp', which cannot make use of
- 'WCHAR_TYPE'.
-
- -- Macro: WINT_TYPE
- A C expression for a string describing the name of the data type to
- use for wide characters passed to 'printf' and returned from
- 'getwc'. The typedef name 'wint_t' is defined using the contents
- of the string. See 'SIZE_TYPE' above for more information.
-
- If you don't define this macro, the default is '"unsigned int"'.
-
- -- Macro: INTMAX_TYPE
- A C expression for a string describing the name of the data type
- that can represent any value of any standard or extended signed
- integer type. The typedef name 'intmax_t' is defined using the
- contents of the string. See 'SIZE_TYPE' above for more
- information.
-
- If you don't define this macro, the default is the first of
- '"int"', '"long int"', or '"long long int"' that has as much
- precision as 'long long int'.
-
- -- Macro: UINTMAX_TYPE
- A C expression for a string describing the name of the data type
- that can represent any value of any standard or extended unsigned
- integer type. The typedef name 'uintmax_t' is defined using the
- contents of the string. See 'SIZE_TYPE' above for more
- information.
-
- If you don't define this macro, the default is the first of
- '"unsigned int"', '"long unsigned int"', or '"long long unsigned
- int"' that has as much precision as 'long long unsigned int'.
-
- -- Macro: SIG_ATOMIC_TYPE
- -- Macro: INT8_TYPE
- -- Macro: INT16_TYPE
- -- Macro: INT32_TYPE
- -- Macro: INT64_TYPE
- -- Macro: UINT8_TYPE
- -- Macro: UINT16_TYPE
- -- Macro: UINT32_TYPE
- -- Macro: UINT64_TYPE
- -- Macro: INT_LEAST8_TYPE
- -- Macro: INT_LEAST16_TYPE
- -- Macro: INT_LEAST32_TYPE
- -- Macro: INT_LEAST64_TYPE
- -- Macro: UINT_LEAST8_TYPE
- -- Macro: UINT_LEAST16_TYPE
- -- Macro: UINT_LEAST32_TYPE
- -- Macro: UINT_LEAST64_TYPE
- -- Macro: INT_FAST8_TYPE
- -- Macro: INT_FAST16_TYPE
- -- Macro: INT_FAST32_TYPE
- -- Macro: INT_FAST64_TYPE
- -- Macro: UINT_FAST8_TYPE
- -- Macro: UINT_FAST16_TYPE
- -- Macro: UINT_FAST32_TYPE
- -- Macro: UINT_FAST64_TYPE
- -- Macro: INTPTR_TYPE
- -- Macro: UINTPTR_TYPE
- C expressions for the standard types 'sig_atomic_t', 'int8_t',
- 'int16_t', 'int32_t', 'int64_t', 'uint8_t', 'uint16_t', 'uint32_t',
- 'uint64_t', 'int_least8_t', 'int_least16_t', 'int_least32_t',
- 'int_least64_t', 'uint_least8_t', 'uint_least16_t',
- 'uint_least32_t', 'uint_least64_t', 'int_fast8_t', 'int_fast16_t',
- 'int_fast32_t', 'int_fast64_t', 'uint_fast8_t', 'uint_fast16_t',
- 'uint_fast32_t', 'uint_fast64_t', 'intptr_t', and 'uintptr_t'. See
- 'SIZE_TYPE' above for more information.
-
- If any of these macros evaluates to a null pointer, the
- corresponding type is not supported; if GCC is configured to
- provide '<stdint.h>' in such a case, the header provided may not
- conform to C99, depending on the type in question. The defaults
- for all of these macros are null pointers.
-
- -- Macro: TARGET_PTRMEMFUNC_VBIT_LOCATION
- The C++ compiler represents a pointer-to-member-function with a
- struct that looks like:
-
- struct {
- union {
- void (*fn)();
- ptrdiff_t vtable_index;
- };
- ptrdiff_t delta;
- };
-
- The C++ compiler must use one bit to indicate whether the function
- that will be called through a pointer-to-member-function is
- virtual. Normally, we assume that the low-order bit of a function
- pointer must always be zero. Then, by ensuring that the
- vtable_index is odd, we can distinguish which variant of the union
- is in use. But, on some platforms function pointers can be odd,
- and so this doesn't work. In that case, we use the low-order bit
- of the 'delta' field, and shift the remainder of the 'delta' field
- to the left.
-
- GCC will automatically make the right selection about where to
- store this bit using the 'FUNCTION_BOUNDARY' setting for your
- platform. However, some platforms such as ARM/Thumb have
- 'FUNCTION_BOUNDARY' set such that functions always start at even
- addresses, but the lowest bit of pointers to functions indicate
- whether the function at that address is in ARM or Thumb mode. If
- this is the case of your architecture, you should define this macro
- to 'ptrmemfunc_vbit_in_delta'.
-
- In general, you should not have to define this macro. On
- architectures in which function addresses are always even,
- according to 'FUNCTION_BOUNDARY', GCC will automatically define
- this macro to 'ptrmemfunc_vbit_in_pfn'.
-
- -- Macro: TARGET_VTABLE_USES_DESCRIPTORS
- Normally, the C++ compiler uses function pointers in vtables. This
- macro allows the target to change to use "function descriptors"
- instead. Function descriptors are found on targets for whom a
- function pointer is actually a small data structure. Normally the
- data structure consists of the actual code address plus a data
- pointer to which the function's data is relative.
-
- If vtables are used, the value of this macro should be the number
- of words that the function descriptor occupies.
-
- -- Macro: TARGET_VTABLE_ENTRY_ALIGN
- By default, the vtable entries are void pointers, the so the
- alignment is the same as pointer alignment. The value of this
- macro specifies the alignment of the vtable entry in bits. It
- should be defined only when special alignment is necessary. */
-
- -- Macro: TARGET_VTABLE_DATA_ENTRY_DISTANCE
- There are a few non-descriptor entries in the vtable at offsets
- below zero. If these entries must be padded (say, to preserve the
- alignment specified by 'TARGET_VTABLE_ENTRY_ALIGN'), set this to
- the number of words in each data entry.
-
-
- File: gccint.info, Node: Registers, Next: Register Classes, Prev: Type Layout, Up: Target Macros
-
- 18.7 Register Usage
- ===================
-
- This section explains how to describe what registers the target machine
- has, and how (in general) they can be used.
-
- The description of which registers a specific instruction can use is
- done with register classes; see *note Register Classes::. For
- information on using registers to access a stack frame, see *note Frame
- Registers::. For passing values in registers, see *note Register
- Arguments::. For returning values in registers, see *note Scalar
- Return::.
-
- * Menu:
-
- * Register Basics:: Number and kinds of registers.
- * Allocation Order:: Order in which registers are allocated.
- * Values in Registers:: What kinds of values each reg can hold.
- * Leaf Functions:: Renumbering registers for leaf functions.
- * Stack Registers:: Handling a register stack such as 80387.
-
-
- File: gccint.info, Node: Register Basics, Next: Allocation Order, Up: Registers
-
- 18.7.1 Basic Characteristics of Registers
- -----------------------------------------
-
- Registers have various characteristics.
-
- -- Macro: FIRST_PSEUDO_REGISTER
- Number of hardware registers known to the compiler. They receive
- numbers 0 through 'FIRST_PSEUDO_REGISTER-1'; thus, the first pseudo
- register's number really is assigned the number
- 'FIRST_PSEUDO_REGISTER'.
-
- -- Macro: FIXED_REGISTERS
- An initializer that says which registers are used for fixed
- purposes all throughout the compiled code and are therefore not
- available for general allocation. These would include the stack
- pointer, the frame pointer (except on machines where that can be
- used as a general register when no frame pointer is needed), the
- program counter on machines where that is considered one of the
- addressable registers, and any other numbered register with a
- standard use.
-
- This information is expressed as a sequence of numbers, separated
- by commas and surrounded by braces. The Nth number is 1 if
- register N is fixed, 0 otherwise.
-
- The table initialized from this macro, and the table initialized by
- the following one, may be overridden at run time either
- automatically, by the actions of the macro
- 'CONDITIONAL_REGISTER_USAGE', or by the user with the command
- options '-ffixed-REG', '-fcall-used-REG' and '-fcall-saved-REG'.
-
- -- Macro: CALL_USED_REGISTERS
- Like 'FIXED_REGISTERS' but has 1 for each register that is
- clobbered (in general) by function calls as well as for fixed
- registers. This macro therefore identifies the registers that are
- not available for general allocation of values that must live
- across function calls.
-
- If a register has 0 in 'CALL_USED_REGISTERS', the compiler
- automatically saves it on function entry and restores it on
- function exit, if the register is used within the function.
-
- Exactly one of 'CALL_USED_REGISTERS' and
- 'CALL_REALLY_USED_REGISTERS' must be defined. Modern ports should
- define 'CALL_REALLY_USED_REGISTERS'.
-
- -- Macro: CALL_REALLY_USED_REGISTERS
- Like 'CALL_USED_REGISTERS' except this macro doesn't require that
- the entire set of 'FIXED_REGISTERS' be included.
- ('CALL_USED_REGISTERS' must be a superset of 'FIXED_REGISTERS').
-
- Exactly one of 'CALL_USED_REGISTERS' and
- 'CALL_REALLY_USED_REGISTERS' must be defined. Modern ports should
- define 'CALL_REALLY_USED_REGISTERS'.
-
- -- Target Hook: const predefined_function_abi & TARGET_FNTYPE_ABI
- (const_tree TYPE)
- Return the ABI used by a function with type TYPE; see the
- definition of 'predefined_function_abi' for details of the ABI
- descriptor. Targets only need to define this hook if they support
- interoperability between several ABIs in the same translation unit.
-
- -- Target Hook: const predefined_function_abi & TARGET_INSN_CALLEE_ABI
- (const rtx_insn *INSN)
- This hook returns a description of the ABI used by the target of
- call instruction INSN; see the definition of
- 'predefined_function_abi' for details of the ABI descriptor. Only
- the global function 'insn_callee_abi' should call this hook
- directly.
-
- Targets only need to define this hook if they support
- interoperability between several ABIs in the same translation unit.
-
- -- Target Hook: bool TARGET_HARD_REGNO_CALL_PART_CLOBBERED (unsigned
- int ABI_ID, unsigned int REGNO, machine_mode MODE)
- ABIs usually specify that calls must preserve the full contents of
- a particular register, or that calls can alter any part of a
- particular register. This information is captured by the target
- macro 'CALL_REALLY_USED_REGISTERS'. However, some ABIs specify
- that calls must preserve certain bits of a particular register but
- can alter others. This hook should return true if this applies to
- at least one of the registers in '(reg:MODE REGNO)', and if as a
- result the call would alter part of the MODE value. For example,
- if a call preserves the low 32 bits of a 64-bit hard register REGNO
- but can clobber the upper 32 bits, this hook should return true for
- a 64-bit mode but false for a 32-bit mode.
-
- The value of ABI_ID comes from the 'predefined_function_abi'
- structure that describes the ABI of the call; see the definition of
- the structure for more details. If (as is usual) the target uses
- the same ABI for all functions in a translation unit, ABI_ID is
- always 0.
-
- The default implementation returns false, which is correct for
- targets that don't have partly call-clobbered registers.
-
- -- Target Hook: const char * TARGET_GET_MULTILIB_ABI_NAME (void)
- This hook returns name of multilib ABI name.
-
- -- Target Hook: void TARGET_CONDITIONAL_REGISTER_USAGE (void)
- This hook may conditionally modify five variables 'fixed_regs',
- 'call_used_regs', 'global_regs', 'reg_names', and
- 'reg_class_contents', to take into account any dependence of these
- register sets on target flags. The first three of these are of
- type 'char []' (interpreted as boolean vectors). 'global_regs' is
- a 'const char *[]', and 'reg_class_contents' is a 'HARD_REG_SET'.
- Before the macro is called, 'fixed_regs', 'call_used_regs',
- 'reg_class_contents', and 'reg_names' have been initialized from
- 'FIXED_REGISTERS', 'CALL_USED_REGISTERS', 'REG_CLASS_CONTENTS', and
- 'REGISTER_NAMES', respectively. 'global_regs' has been cleared,
- and any '-ffixed-REG', '-fcall-used-REG' and '-fcall-saved-REG'
- command options have been applied.
-
- If the usage of an entire class of registers depends on the target
- flags, you may indicate this to GCC by using this macro to modify
- 'fixed_regs' and 'call_used_regs' to 1 for each of the registers in
- the classes which should not be used by GCC. Also make
- 'define_register_constraint's return 'NO_REGS' for constraints that
- shouldn't be used.
-
- (However, if this class is not included in 'GENERAL_REGS' and all
- of the insn patterns whose constraints permit this class are
- controlled by target switches, then GCC will automatically avoid
- using these registers when the target switches are opposed to
- them.)
-
- -- Macro: INCOMING_REGNO (OUT)
- Define this macro if the target machine has register windows. This
- C expression returns the register number as seen by the called
- function corresponding to the register number OUT as seen by the
- calling function. Return OUT if register number OUT is not an
- outbound register.
-
- -- Macro: OUTGOING_REGNO (IN)
- Define this macro if the target machine has register windows. This
- C expression returns the register number as seen by the calling
- function corresponding to the register number IN as seen by the
- called function. Return IN if register number IN is not an inbound
- register.
-
- -- Macro: LOCAL_REGNO (REGNO)
- Define this macro if the target machine has register windows. This
- C expression returns true if the register is call-saved but is in
- the register window. Unlike most call-saved registers, such
- registers need not be explicitly restored on function exit or
- during non-local gotos.
-
- -- Macro: PC_REGNUM
- If the program counter has a register number, define this as that
- register number. Otherwise, do not define it.
-
-
- File: gccint.info, Node: Allocation Order, Next: Values in Registers, Prev: Register Basics, Up: Registers
-
- 18.7.2 Order of Allocation of Registers
- ---------------------------------------
-
- Registers are allocated in order.
-
- -- Macro: REG_ALLOC_ORDER
- If defined, an initializer for a vector of integers, containing the
- numbers of hard registers in the order in which GCC should prefer
- to use them (from most preferred to least).
-
- If this macro is not defined, registers are used lowest numbered
- first (all else being equal).
-
- One use of this macro is on machines where the highest numbered
- registers must always be saved and the save-multiple-registers
- instruction supports only sequences of consecutive registers. On
- such machines, define 'REG_ALLOC_ORDER' to be an initializer that
- lists the highest numbered allocable register first.
-
- -- Macro: ADJUST_REG_ALLOC_ORDER
- A C statement (sans semicolon) to choose the order in which to
- allocate hard registers for pseudo-registers local to a basic
- block.
-
- Store the desired register order in the array 'reg_alloc_order'.
- Element 0 should be the register to allocate first; element 1, the
- next register; and so on.
-
- The macro body should not assume anything about the contents of
- 'reg_alloc_order' before execution of the macro.
-
- On most machines, it is not necessary to define this macro.
-
- -- Macro: HONOR_REG_ALLOC_ORDER
- Normally, IRA tries to estimate the costs for saving a register in
- the prologue and restoring it in the epilogue. This discourages it
- from using call-saved registers. If a machine wants to ensure that
- IRA allocates registers in the order given by REG_ALLOC_ORDER even
- if some call-saved registers appear earlier than call-used ones,
- then define this macro as a C expression to nonzero. Default is 0.
-
- -- Macro: IRA_HARD_REGNO_ADD_COST_MULTIPLIER (REGNO)
- In some case register allocation order is not enough for the
- Integrated Register Allocator (IRA) to generate a good code. If
- this macro is defined, it should return a floating point value
- based on REGNO. The cost of using REGNO for a pseudo will be
- increased by approximately the pseudo's usage frequency times the
- value returned by this macro. Not defining this macro is
- equivalent to having it always return '0.0'.
-
- On most machines, it is not necessary to define this macro.
-
-
- File: gccint.info, Node: Values in Registers, Next: Leaf Functions, Prev: Allocation Order, Up: Registers
-
- 18.7.3 How Values Fit in Registers
- ----------------------------------
-
- This section discusses the macros that describe which kinds of values
- (specifically, which machine modes) each register can hold, and how many
- consecutive registers are needed for a given mode.
-
- -- Target Hook: unsigned int TARGET_HARD_REGNO_NREGS (unsigned int
- REGNO, machine_mode MODE)
- This hook returns the number of consecutive hard registers,
- starting at register number REGNO, required to hold a value of mode
- MODE. This hook must never return zero, even if a register cannot
- hold the requested mode - indicate that with
- 'TARGET_HARD_REGNO_MODE_OK' and/or 'TARGET_CAN_CHANGE_MODE_CLASS'
- instead.
-
- The default definition returns the number of words in MODE.
-
- -- Macro: HARD_REGNO_NREGS_HAS_PADDING (REGNO, MODE)
- A C expression that is nonzero if a value of mode MODE, stored in
- memory, ends with padding that causes it to take up more space than
- in registers starting at register number REGNO (as determined by
- multiplying GCC's notion of the size of the register when
- containing this mode by the number of registers returned by
- 'TARGET_HARD_REGNO_NREGS'). By default this is zero.
-
- For example, if a floating-point value is stored in three 32-bit
- registers but takes up 128 bits in memory, then this would be
- nonzero.
-
- This macros only needs to be defined if there are cases where
- 'subreg_get_info' would otherwise wrongly determine that a 'subreg'
- can be represented by an offset to the register number, when in
- fact such a 'subreg' would contain some of the padding not stored
- in registers and so not be representable.
-
- -- Macro: HARD_REGNO_NREGS_WITH_PADDING (REGNO, MODE)
- For values of REGNO and MODE for which
- 'HARD_REGNO_NREGS_HAS_PADDING' returns nonzero, a C expression
- returning the greater number of registers required to hold the
- value including any padding. In the example above, the value would
- be four.
-
- -- Macro: REGMODE_NATURAL_SIZE (MODE)
- Define this macro if the natural size of registers that hold values
- of mode MODE is not the word size. It is a C expression that
- should give the natural size in bytes for the specified mode. It
- is used by the register allocator to try to optimize its results.
- This happens for example on SPARC 64-bit where the natural size of
- floating-point registers is still 32-bit.
-
- -- Target Hook: bool TARGET_HARD_REGNO_MODE_OK (unsigned int REGNO,
- machine_mode MODE)
- This hook returns true if it is permissible to store a value of
- mode MODE in hard register number REGNO (or in several registers
- starting with that one). The default definition returns true
- unconditionally.
-
- You need not include code to check for the numbers of fixed
- registers, because the allocation mechanism considers them to be
- always occupied.
-
- On some machines, double-precision values must be kept in even/odd
- register pairs. You can implement that by defining this hook to
- reject odd register numbers for such modes.
-
- The minimum requirement for a mode to be OK in a register is that
- the 'movMODE' instruction pattern support moves between the
- register and other hard register in the same class and that moving
- a value into the register and back out not alter it.
-
- Since the same instruction used to move 'word_mode' will work for
- all narrower integer modes, it is not necessary on any machine for
- this hook to distinguish between these modes, provided you define
- patterns 'movhi', etc., to take advantage of this. This is useful
- because of the interaction between 'TARGET_HARD_REGNO_MODE_OK' and
- 'TARGET_MODES_TIEABLE_P'; it is very desirable for all integer
- modes to be tieable.
-
- Many machines have special registers for floating point arithmetic.
- Often people assume that floating point machine modes are allowed
- only in floating point registers. This is not true. Any registers
- that can hold integers can safely _hold_ a floating point machine
- mode, whether or not floating arithmetic can be done on it in those
- registers. Integer move instructions can be used to move the
- values.
-
- On some machines, though, the converse is true: fixed-point machine
- modes may not go in floating registers. This is true if the
- floating registers normalize any value stored in them, because
- storing a non-floating value there would garble it. In this case,
- 'TARGET_HARD_REGNO_MODE_OK' should reject fixed-point machine modes
- in floating registers. But if the floating registers do not
- automatically normalize, if you can store any bit pattern in one
- and retrieve it unchanged without a trap, then any machine mode may
- go in a floating register, so you can define this hook to say so.
-
- The primary significance of special floating registers is rather
- that they are the registers acceptable in floating point arithmetic
- instructions. However, this is of no concern to
- 'TARGET_HARD_REGNO_MODE_OK'. You handle it by writing the proper
- constraints for those instructions.
-
- On some machines, the floating registers are especially slow to
- access, so that it is better to store a value in a stack frame than
- in such a register if floating point arithmetic is not being done.
- As long as the floating registers are not in class 'GENERAL_REGS',
- they will not be used unless some pattern's constraint asks for
- one.
-
- -- Macro: HARD_REGNO_RENAME_OK (FROM, TO)
- A C expression that is nonzero if it is OK to rename a hard
- register FROM to another hard register TO.
-
- One common use of this macro is to prevent renaming of a register
- to another register that is not saved by a prologue in an interrupt
- handler.
-
- The default is always nonzero.
-
- -- Target Hook: bool TARGET_MODES_TIEABLE_P (machine_mode MODE1,
- machine_mode MODE2)
- This hook returns true if a value of mode MODE1 is accessible in
- mode MODE2 without copying.
-
- If 'TARGET_HARD_REGNO_MODE_OK (R, MODE1)' and
- 'TARGET_HARD_REGNO_MODE_OK (R, MODE2)' are always the same for any
- R, then 'TARGET_MODES_TIEABLE_P (MODE1, MODE2)' should be true. If
- they differ for any R, you should define this hook to return false
- unless some other mechanism ensures the accessibility of the value
- in a narrower mode.
-
- You should define this hook to return true in as many cases as
- possible since doing so will allow GCC to perform better register
- allocation. The default definition returns true unconditionally.
-
- -- Target Hook: bool TARGET_HARD_REGNO_SCRATCH_OK (unsigned int REGNO)
- This target hook should return 'true' if it is OK to use a hard
- register REGNO as scratch reg in peephole2.
-
- One common use of this macro is to prevent using of a register that
- is not saved by a prologue in an interrupt handler.
-
- The default version of this hook always returns 'true'.
-
- -- Macro: AVOID_CCMODE_COPIES
- Define this macro if the compiler should avoid copies to/from
- 'CCmode' registers. You should only define this macro if support
- for copying to/from 'CCmode' is incomplete.
-
-
- File: gccint.info, Node: Leaf Functions, Next: Stack Registers, Prev: Values in Registers, Up: Registers
-
- 18.7.4 Handling Leaf Functions
- ------------------------------
-
- On some machines, a leaf function (i.e., one which makes no calls) can
- run more efficiently if it does not make its own register window. Often
- this means it is required to receive its arguments in the registers
- where they are passed by the caller, instead of the registers where they
- would normally arrive.
-
- The special treatment for leaf functions generally applies only when
- other conditions are met; for example, often they may use only those
- registers for its own variables and temporaries. We use the term "leaf
- function" to mean a function that is suitable for this special handling,
- so that functions with no calls are not necessarily "leaf functions".
-
- GCC assigns register numbers before it knows whether the function is
- suitable for leaf function treatment. So it needs to renumber the
- registers in order to output a leaf function. The following macros
- accomplish this.
-
- -- Macro: LEAF_REGISTERS
- Name of a char vector, indexed by hard register number, which
- contains 1 for a register that is allowable in a candidate for leaf
- function treatment.
-
- If leaf function treatment involves renumbering the registers, then
- the registers marked here should be the ones before
- renumbering--those that GCC would ordinarily allocate. The
- registers which will actually be used in the assembler code, after
- renumbering, should not be marked with 1 in this vector.
-
- Define this macro only if the target machine offers a way to
- optimize the treatment of leaf functions.
-
- -- Macro: LEAF_REG_REMAP (REGNO)
- A C expression whose value is the register number to which REGNO
- should be renumbered, when a function is treated as a leaf
- function.
-
- If REGNO is a register number which should not appear in a leaf
- function before renumbering, then the expression should yield -1,
- which will cause the compiler to abort.
-
- Define this macro only if the target machine offers a way to
- optimize the treatment of leaf functions, and registers need to be
- renumbered to do this.
-
- 'TARGET_ASM_FUNCTION_PROLOGUE' and 'TARGET_ASM_FUNCTION_EPILOGUE' must
- usually treat leaf functions specially. They can test the C variable
- 'current_function_is_leaf' which is nonzero for leaf functions.
- 'current_function_is_leaf' is set prior to local register allocation and
- is valid for the remaining compiler passes. They can also test the C
- variable 'current_function_uses_only_leaf_regs' which is nonzero for
- leaf functions which only use leaf registers.
- 'current_function_uses_only_leaf_regs' is valid after all passes that
- modify the instructions have been run and is only useful if
- 'LEAF_REGISTERS' is defined.
-
-
- File: gccint.info, Node: Stack Registers, Prev: Leaf Functions, Up: Registers
-
- 18.7.5 Registers That Form a Stack
- ----------------------------------
-
- There are special features to handle computers where some of the
- "registers" form a stack. Stack registers are normally written by
- pushing onto the stack, and are numbered relative to the top of the
- stack.
-
- Currently, GCC can only handle one group of stack-like registers, and
- they must be consecutively numbered. Furthermore, the existing support
- for stack-like registers is specific to the 80387 floating point
- coprocessor. If you have a new architecture that uses stack-like
- registers, you will need to do substantial work on 'reg-stack.c' and
- write your machine description to cooperate with it, as well as defining
- these macros.
-
- -- Macro: STACK_REGS
- Define this if the machine has any stack-like registers.
-
- -- Macro: STACK_REG_COVER_CLASS
- This is a cover class containing the stack registers. Define this
- if the machine has any stack-like registers.
-
- -- Macro: FIRST_STACK_REG
- The number of the first stack-like register. This one is the top
- of the stack.
-
- -- Macro: LAST_STACK_REG
- The number of the last stack-like register. This one is the bottom
- of the stack.
-
-
- File: gccint.info, Node: Register Classes, Next: Stack and Calling, Prev: Registers, Up: Target Macros
-
- 18.8 Register Classes
- =====================
-
- On many machines, the numbered registers are not all equivalent. For
- example, certain registers may not be allowed for indexed addressing;
- certain registers may not be allowed in some instructions. These
- machine restrictions are described to the compiler using "register
- classes".
-
- You define a number of register classes, giving each one a name and
- saying which of the registers belong to it. Then you can specify
- register classes that are allowed as operands to particular instruction
- patterns.
-
- In general, each register will belong to several classes. In fact, one
- class must be named 'ALL_REGS' and contain all the registers. Another
- class must be named 'NO_REGS' and contain no registers. Often the union
- of two classes will be another class; however, this is not required.
-
- One of the classes must be named 'GENERAL_REGS'. There is nothing
- terribly special about the name, but the operand constraint letters 'r'
- and 'g' specify this class. If 'GENERAL_REGS' is the same as
- 'ALL_REGS', just define it as a macro which expands to 'ALL_REGS'.
-
- Order the classes so that if class X is contained in class Y then X has
- a lower class number than Y.
-
- The way classes other than 'GENERAL_REGS' are specified in operand
- constraints is through machine-dependent operand constraint letters.
- You can define such letters to correspond to various classes, then use
- them in operand constraints.
-
- You must define the narrowest register classes for allocatable
- registers, so that each class either has no subclasses, or that for some
- mode, the move cost between registers within the class is cheaper than
- moving a register in the class to or from memory (*note Costs::).
-
- You should define a class for the union of two classes whenever some
- instruction allows both classes. For example, if an instruction allows
- either a floating point (coprocessor) register or a general register for
- a certain operand, you should define a class 'FLOAT_OR_GENERAL_REGS'
- which includes both of them. Otherwise you will get suboptimal code, or
- even internal compiler errors when reload cannot find a register in the
- class computed via 'reg_class_subunion'.
-
- You must also specify certain redundant information about the register
- classes: for each class, which classes contain it and which ones are
- contained in it; for each pair of classes, the largest class contained
- in their union.
-
- When a value occupying several consecutive registers is expected in a
- certain class, all the registers used must belong to that class.
- Therefore, register classes cannot be used to enforce a requirement for
- a register pair to start with an even-numbered register. The way to
- specify this requirement is with 'TARGET_HARD_REGNO_MODE_OK'.
-
- Register classes used for input-operands of bitwise-and or shift
- instructions have a special requirement: each such class must have, for
- each fixed-point machine mode, a subclass whose registers can transfer
- that mode to or from memory. For example, on some machines, the
- operations for single-byte values ('QImode') are limited to certain
- registers. When this is so, each register class that is used in a
- bitwise-and or shift instruction must have a subclass consisting of
- registers from which single-byte values can be loaded or stored. This
- is so that 'PREFERRED_RELOAD_CLASS' can always have a possible value to
- return.
-
- -- Data type: enum reg_class
- An enumerated type that must be defined with all the register class
- names as enumerated values. 'NO_REGS' must be first. 'ALL_REGS'
- must be the last register class, followed by one more enumerated
- value, 'LIM_REG_CLASSES', which is not a register class but rather
- tells how many classes there are.
-
- Each register class has a number, which is the value of casting the
- class name to type 'int'. The number serves as an index in many of
- the tables described below.
-
- -- Macro: N_REG_CLASSES
- The number of distinct register classes, defined as follows:
-
- #define N_REG_CLASSES (int) LIM_REG_CLASSES
-
- -- Macro: REG_CLASS_NAMES
- An initializer containing the names of the register classes as C
- string constants. These names are used in writing some of the
- debugging dumps.
-
- -- Macro: REG_CLASS_CONTENTS
- An initializer containing the contents of the register classes, as
- integers which are bit masks. The Nth integer specifies the
- contents of class N. The way the integer MASK is interpreted is
- that register R is in the class if 'MASK & (1 << R)' is 1.
-
- When the machine has more than 32 registers, an integer does not
- suffice. Then the integers are replaced by sub-initializers,
- braced groupings containing several integers. Each sub-initializer
- must be suitable as an initializer for the type 'HARD_REG_SET'
- which is defined in 'hard-reg-set.h'. In this situation, the first
- integer in each sub-initializer corresponds to registers 0 through
- 31, the second integer to registers 32 through 63, and so on.
-
- -- Macro: REGNO_REG_CLASS (REGNO)
- A C expression whose value is a register class containing hard
- register REGNO. In general there is more than one such class;
- choose a class which is "minimal", meaning that no smaller class
- also contains the register.
-
- -- Macro: BASE_REG_CLASS
- A macro whose definition is the name of the class to which a valid
- base register must belong. A base register is one used in an
- address which is the register value plus a displacement.
-
- -- Macro: MODE_BASE_REG_CLASS (MODE)
- This is a variation of the 'BASE_REG_CLASS' macro which allows the
- selection of a base register in a mode dependent manner. If MODE
- is VOIDmode then it should return the same value as
- 'BASE_REG_CLASS'.
-
- -- Macro: MODE_BASE_REG_REG_CLASS (MODE)
- A C expression whose value is the register class to which a valid
- base register must belong in order to be used in a base plus index
- register address. You should define this macro if base plus index
- addresses have different requirements than other base register
- uses.
-
- -- Macro: MODE_CODE_BASE_REG_CLASS (MODE, ADDRESS_SPACE, OUTER_CODE,
- INDEX_CODE)
- A C expression whose value is the register class to which a valid
- base register for a memory reference in mode MODE to address space
- ADDRESS_SPACE must belong. OUTER_CODE and INDEX_CODE define the
- context in which the base register occurs. OUTER_CODE is the code
- of the immediately enclosing expression ('MEM' for the top level of
- an address, 'ADDRESS' for something that occurs in an
- 'address_operand'). INDEX_CODE is the code of the corresponding
- index expression if OUTER_CODE is 'PLUS'; 'SCRATCH' otherwise.
-
- -- Macro: INDEX_REG_CLASS
- A macro whose definition is the name of the class to which a valid
- index register must belong. An index register is one used in an
- address where its value is either multiplied by a scale factor or
- added to another register (as well as added to a displacement).
-
- -- Macro: REGNO_OK_FOR_BASE_P (NUM)
- A C expression which is nonzero if register number NUM is suitable
- for use as a base register in operand addresses.
-
- -- Macro: REGNO_MODE_OK_FOR_BASE_P (NUM, MODE)
- A C expression that is just like 'REGNO_OK_FOR_BASE_P', except that
- that expression may examine the mode of the memory reference in
- MODE. You should define this macro if the mode of the memory
- reference affects whether a register may be used as a base
- register. If you define this macro, the compiler will use it
- instead of 'REGNO_OK_FOR_BASE_P'. The mode may be 'VOIDmode' for
- addresses that appear outside a 'MEM', i.e., as an
- 'address_operand'.
-
- -- Macro: REGNO_MODE_OK_FOR_REG_BASE_P (NUM, MODE)
- A C expression which is nonzero if register number NUM is suitable
- for use as a base register in base plus index operand addresses,
- accessing memory in mode MODE. It may be either a suitable hard
- register or a pseudo register that has been allocated such a hard
- register. You should define this macro if base plus index
- addresses have different requirements than other base register
- uses.
-
- Use of this macro is deprecated; please use the more general
- 'REGNO_MODE_CODE_OK_FOR_BASE_P'.
-
- -- Macro: REGNO_MODE_CODE_OK_FOR_BASE_P (NUM, MODE, ADDRESS_SPACE,
- OUTER_CODE, INDEX_CODE)
- A C expression which is nonzero if register number NUM is suitable
- for use as a base register in operand addresses, accessing memory
- in mode MODE in address space ADDRESS_SPACE. This is similar to
- 'REGNO_MODE_OK_FOR_BASE_P', except that that expression may examine
- the context in which the register appears in the memory reference.
- OUTER_CODE is the code of the immediately enclosing expression
- ('MEM' if at the top level of the address, 'ADDRESS' for something
- that occurs in an 'address_operand'). INDEX_CODE is the code of
- the corresponding index expression if OUTER_CODE is 'PLUS';
- 'SCRATCH' otherwise. The mode may be 'VOIDmode' for addresses that
- appear outside a 'MEM', i.e., as an 'address_operand'.
-
- -- Macro: REGNO_OK_FOR_INDEX_P (NUM)
- A C expression which is nonzero if register number NUM is suitable
- for use as an index register in operand addresses. It may be
- either a suitable hard register or a pseudo register that has been
- allocated such a hard register.
-
- The difference between an index register and a base register is
- that the index register may be scaled. If an address involves the
- sum of two registers, neither one of them scaled, then either one
- may be labeled the "base" and the other the "index"; but whichever
- labeling is used must fit the machine's constraints of which
- registers may serve in each capacity. The compiler will try both
- labelings, looking for one that is valid, and will reload one or
- both registers only if neither labeling works.
-
- -- Target Hook: reg_class_t TARGET_PREFERRED_RENAME_CLASS (reg_class_t
- RCLASS)
- A target hook that places additional preference on the register
- class to use when it is necessary to rename a register in class
- RCLASS to another class, or perhaps NO_REGS, if no preferred
- register class is found or hook 'preferred_rename_class' is not
- implemented. Sometimes returning a more restrictive class makes
- better code. For example, on ARM, thumb-2 instructions using
- 'LO_REGS' may be smaller than instructions using 'GENERIC_REGS'.
- By returning 'LO_REGS' from 'preferred_rename_class', code size can
- be reduced.
-
- -- Target Hook: reg_class_t TARGET_PREFERRED_RELOAD_CLASS (rtx X,
- reg_class_t RCLASS)
- A target hook that places additional restrictions on the register
- class to use when it is necessary to copy value X into a register
- in class RCLASS. The value is a register class; perhaps RCLASS, or
- perhaps another, smaller class.
-
- The default version of this hook always returns value of 'rclass'
- argument.
-
- Sometimes returning a more restrictive class makes better code.
- For example, on the 68000, when X is an integer constant that is in
- range for a 'moveq' instruction, the value of this macro is always
- 'DATA_REGS' as long as RCLASS includes the data registers.
- Requiring a data register guarantees that a 'moveq' will be used.
-
- One case where 'TARGET_PREFERRED_RELOAD_CLASS' must not return
- RCLASS is if X is a legitimate constant which cannot be loaded into
- some register class. By returning 'NO_REGS' you can force X into a
- memory location. For example, rs6000 can load immediate values
- into general-purpose registers, but does not have an instruction
- for loading an immediate value into a floating-point register, so
- 'TARGET_PREFERRED_RELOAD_CLASS' returns 'NO_REGS' when X is a
- floating-point constant. If the constant can't be loaded into any
- kind of register, code generation will be better if
- 'TARGET_LEGITIMATE_CONSTANT_P' makes the constant illegitimate
- instead of using 'TARGET_PREFERRED_RELOAD_CLASS'.
-
- If an insn has pseudos in it after register allocation, reload will
- go through the alternatives and call repeatedly
- 'TARGET_PREFERRED_RELOAD_CLASS' to find the best one. Returning
- 'NO_REGS', in this case, makes reload add a '!' in front of the
- constraint: the x86 back-end uses this feature to discourage usage
- of 387 registers when math is done in the SSE registers (and vice
- versa).
-
- -- Macro: PREFERRED_RELOAD_CLASS (X, CLASS)
- A C expression that places additional restrictions on the register
- class to use when it is necessary to copy value X into a register
- in class CLASS. The value is a register class; perhaps CLASS, or
- perhaps another, smaller class. On many machines, the following
- definition is safe:
-
- #define PREFERRED_RELOAD_CLASS(X,CLASS) CLASS
-
- Sometimes returning a more restrictive class makes better code.
- For example, on the 68000, when X is an integer constant that is in
- range for a 'moveq' instruction, the value of this macro is always
- 'DATA_REGS' as long as CLASS includes the data registers.
- Requiring a data register guarantees that a 'moveq' will be used.
-
- One case where 'PREFERRED_RELOAD_CLASS' must not return CLASS is if
- X is a legitimate constant which cannot be loaded into some
- register class. By returning 'NO_REGS' you can force X into a
- memory location. For example, rs6000 can load immediate values
- into general-purpose registers, but does not have an instruction
- for loading an immediate value into a floating-point register, so
- 'PREFERRED_RELOAD_CLASS' returns 'NO_REGS' when X is a
- floating-point constant. If the constant cannot be loaded into any
- kind of register, code generation will be better if
- 'TARGET_LEGITIMATE_CONSTANT_P' makes the constant illegitimate
- instead of using 'TARGET_PREFERRED_RELOAD_CLASS'.
-
- If an insn has pseudos in it after register allocation, reload will
- go through the alternatives and call repeatedly
- 'PREFERRED_RELOAD_CLASS' to find the best one. Returning
- 'NO_REGS', in this case, makes reload add a '!' in front of the
- constraint: the x86 back-end uses this feature to discourage usage
- of 387 registers when math is done in the SSE registers (and vice
- versa).
-
- -- Target Hook: reg_class_t TARGET_PREFERRED_OUTPUT_RELOAD_CLASS (rtx
- X, reg_class_t RCLASS)
- Like 'TARGET_PREFERRED_RELOAD_CLASS', but for output reloads
- instead of input reloads.
-
- The default version of this hook always returns value of 'rclass'
- argument.
-
- You can also use 'TARGET_PREFERRED_OUTPUT_RELOAD_CLASS' to
- discourage reload from using some alternatives, like
- 'TARGET_PREFERRED_RELOAD_CLASS'.
-
- -- Macro: LIMIT_RELOAD_CLASS (MODE, CLASS)
- A C expression that places additional restrictions on the register
- class to use when it is necessary to be able to hold a value of
- mode MODE in a reload register for which class CLASS would
- ordinarily be used.
-
- Unlike 'PREFERRED_RELOAD_CLASS', this macro should be used when
- there are certain modes that simply cannot go in certain reload
- classes.
-
- The value is a register class; perhaps CLASS, or perhaps another,
- smaller class.
-
- Don't define this macro unless the target machine has limitations
- which require the macro to do something nontrivial.
-
- -- Target Hook: reg_class_t TARGET_SECONDARY_RELOAD (bool IN_P, rtx X,
- reg_class_t RELOAD_CLASS, machine_mode RELOAD_MODE,
- secondary_reload_info *SRI)
- Many machines have some registers that cannot be copied directly to
- or from memory or even from other types of registers. An example
- is the 'MQ' register, which on most machines, can only be copied to
- or from general registers, but not memory. Below, we shall be
- using the term 'intermediate register' when a move operation cannot
- be performed directly, but has to be done by copying the source
- into the intermediate register first, and then copying the
- intermediate register to the destination. An intermediate register
- always has the same mode as source and destination. Since it holds
- the actual value being copied, reload might apply optimizations to
- re-use an intermediate register and eliding the copy from the
- source when it can determine that the intermediate register still
- holds the required value.
-
- Another kind of secondary reload is required on some machines which
- allow copying all registers to and from memory, but require a
- scratch register for stores to some memory locations (e.g., those
- with symbolic address on the RT, and those with certain symbolic
- address on the SPARC when compiling PIC). Scratch registers need
- not have the same mode as the value being copied, and usually hold
- a different value than that being copied. Special patterns in the
- md file are needed to describe how the copy is performed with the
- help of the scratch register; these patterns also describe the
- number, register class(es) and mode(s) of the scratch register(s).
-
- In some cases, both an intermediate and a scratch register are
- required.
-
- For input reloads, this target hook is called with nonzero IN_P,
- and X is an rtx that needs to be copied to a register of class
- RELOAD_CLASS in RELOAD_MODE. For output reloads, this target hook
- is called with zero IN_P, and a register of class RELOAD_CLASS
- needs to be copied to rtx X in RELOAD_MODE.
-
- If copying a register of RELOAD_CLASS from/to X requires an
- intermediate register, the hook 'secondary_reload' should return
- the register class required for this intermediate register. If no
- intermediate register is required, it should return NO_REGS. If
- more than one intermediate register is required, describe the one
- that is closest in the copy chain to the reload register.
-
- If scratch registers are needed, you also have to describe how to
- perform the copy from/to the reload register to/from this closest
- intermediate register. Or if no intermediate register is required,
- but still a scratch register is needed, describe the copy from/to
- the reload register to/from the reload operand X.
-
- You do this by setting 'sri->icode' to the instruction code of a
- pattern in the md file which performs the move. Operands 0 and 1
- are the output and input of this copy, respectively. Operands from
- operand 2 onward are for scratch operands. These scratch operands
- must have a mode, and a single-register-class output constraint.
-
- When an intermediate register is used, the 'secondary_reload' hook
- will be called again to determine how to copy the intermediate
- register to/from the reload operand X, so your hook must also have
- code to handle the register class of the intermediate operand.
-
- X might be a pseudo-register or a 'subreg' of a pseudo-register,
- which could either be in a hard register or in memory. Use
- 'true_regnum' to find out; it will return -1 if the pseudo is in
- memory and the hard register number if it is in a register.
-
- Scratch operands in memory (constraint '"=m"' / '"=&m"') are
- currently not supported. For the time being, you will have to
- continue to use 'TARGET_SECONDARY_MEMORY_NEEDED' for that purpose.
-
- 'copy_cost' also uses this target hook to find out how values are
- copied. If you want it to include some extra cost for the need to
- allocate (a) scratch register(s), set 'sri->extra_cost' to the
- additional cost. Or if two dependent moves are supposed to have a
- lower cost than the sum of the individual moves due to expected
- fortuitous scheduling and/or special forwarding logic, you can set
- 'sri->extra_cost' to a negative amount.
-
- -- Macro: SECONDARY_RELOAD_CLASS (CLASS, MODE, X)
- -- Macro: SECONDARY_INPUT_RELOAD_CLASS (CLASS, MODE, X)
- -- Macro: SECONDARY_OUTPUT_RELOAD_CLASS (CLASS, MODE, X)
- These macros are obsolete, new ports should use the target hook
- 'TARGET_SECONDARY_RELOAD' instead.
-
- These are obsolete macros, replaced by the
- 'TARGET_SECONDARY_RELOAD' target hook. Older ports still define
- these macros to indicate to the reload phase that it may need to
- allocate at least one register for a reload in addition to the
- register to contain the data. Specifically, if copying X to a
- register CLASS in MODE requires an intermediate register, you were
- supposed to define 'SECONDARY_INPUT_RELOAD_CLASS' to return the
- largest register class all of whose registers can be used as
- intermediate registers or scratch registers.
-
- If copying a register CLASS in MODE to X requires an intermediate
- or scratch register, 'SECONDARY_OUTPUT_RELOAD_CLASS' was supposed
- to be defined be defined to return the largest register class
- required. If the requirements for input and output reloads were
- the same, the macro 'SECONDARY_RELOAD_CLASS' should have been used
- instead of defining both macros identically.
-
- The values returned by these macros are often 'GENERAL_REGS'.
- Return 'NO_REGS' if no spare register is needed; i.e., if X can be
- directly copied to or from a register of CLASS in MODE without
- requiring a scratch register. Do not define this macro if it would
- always return 'NO_REGS'.
-
- If a scratch register is required (either with or without an
- intermediate register), you were supposed to define patterns for
- 'reload_inM' or 'reload_outM', as required (*note Standard Names::.
- These patterns, which were normally implemented with a
- 'define_expand', should be similar to the 'movM' patterns, except
- that operand 2 is the scratch register.
-
- These patterns need constraints for the reload register and scratch
- register that contain a single register class. If the original
- reload register (whose class is CLASS) can meet the constraint
- given in the pattern, the value returned by these macros is used
- for the class of the scratch register. Otherwise, two additional
- reload registers are required. Their classes are obtained from the
- constraints in the insn pattern.
-
- X might be a pseudo-register or a 'subreg' of a pseudo-register,
- which could either be in a hard register or in memory. Use
- 'true_regnum' to find out; it will return -1 if the pseudo is in
- memory and the hard register number if it is in a register.
-
- These macros should not be used in the case where a particular
- class of registers can only be copied to memory and not to another
- class of registers. In that case, secondary reload registers are
- not needed and would not be helpful. Instead, a stack location
- must be used to perform the copy and the 'movM' pattern should use
- memory as an intermediate storage. This case often occurs between
- floating-point and general registers.
-
- -- Target Hook: bool TARGET_SECONDARY_MEMORY_NEEDED (machine_mode MODE,
- reg_class_t CLASS1, reg_class_t CLASS2)
- Certain machines have the property that some registers cannot be
- copied to some other registers without using memory. Define this
- hook on those machines to return true if objects of mode M in
- registers of CLASS1 can only be copied to registers of class CLASS2
- by storing a register of CLASS1 into memory and loading that memory
- location into a register of CLASS2. The default definition returns
- false for all inputs.
-
- -- Macro: SECONDARY_MEMORY_NEEDED_RTX (MODE)
- Normally when 'TARGET_SECONDARY_MEMORY_NEEDED' is defined, the
- compiler allocates a stack slot for a memory location needed for
- register copies. If this macro is defined, the compiler instead
- uses the memory location defined by this macro.
-
- Do not define this macro if you do not define
- 'TARGET_SECONDARY_MEMORY_NEEDED'.
-
- -- Target Hook: machine_mode TARGET_SECONDARY_MEMORY_NEEDED_MODE
- (machine_mode MODE)
- If 'TARGET_SECONDARY_MEMORY_NEEDED' tells the compiler to use
- memory when moving between two particular registers of mode MODE,
- this hook specifies the mode that the memory should have.
-
- The default depends on 'TARGET_LRA_P'. Without LRA, the default is
- to use a word-sized mode for integral modes that are smaller than a
- a word. This is right thing to do on most machines because it
- ensures that all bits of the register are copied and prevents
- accesses to the registers in a narrower mode, which some machines
- prohibit for floating-point registers.
-
- However, this default behavior is not correct on some machines,
- such as the DEC Alpha, that store short integers in floating-point
- registers differently than in integer registers. On those
- machines, the default widening will not work correctly and you must
- define this hook to suppress that widening in some cases. See the
- file 'alpha.c' for details.
-
- With LRA, the default is to use MODE unmodified.
-
- -- Target Hook: void TARGET_SELECT_EARLY_REMAT_MODES (sbitmap MODES)
- On some targets, certain modes cannot be held in registers around a
- standard ABI call and are relatively expensive to spill to the
- stack. The early rematerialization pass can help in such cases by
- aggressively recomputing values after calls, so that they don't
- need to be spilled.
-
- This hook returns the set of such modes by setting the associated
- bits in MODES. The default implementation selects no modes, which
- has the effect of disabling the early rematerialization pass.
-
- -- Target Hook: bool TARGET_CLASS_LIKELY_SPILLED_P (reg_class_t RCLASS)
- A target hook which returns 'true' if pseudos that have been
- assigned to registers of class RCLASS would likely be spilled
- because registers of RCLASS are needed for spill registers.
-
- The default version of this target hook returns 'true' if RCLASS
- has exactly one register and 'false' otherwise. On most machines,
- this default should be used. For generally register-starved
- machines, such as i386, or machines with right register
- constraints, such as SH, this hook can be used to avoid excessive
- spilling.
-
- This hook is also used by some of the global intra-procedural code
- transformations to throtle code motion, to avoid increasing
- register pressure.
-
- -- Target Hook: unsigned char TARGET_CLASS_MAX_NREGS (reg_class_t
- RCLASS, machine_mode MODE)
- A target hook returns the maximum number of consecutive registers
- of class RCLASS needed to hold a value of mode MODE.
-
- This is closely related to the macro 'TARGET_HARD_REGNO_NREGS'. In
- fact, the value returned by 'TARGET_CLASS_MAX_NREGS (RCLASS, MODE)'
- target hook should be the maximum value of 'TARGET_HARD_REGNO_NREGS
- (REGNO, MODE)' for all REGNO values in the class RCLASS.
-
- This target hook helps control the handling of multiple-word values
- in the reload pass.
-
- The default version of this target hook returns the size of MODE in
- words.
-
- -- Macro: CLASS_MAX_NREGS (CLASS, MODE)
- A C expression for the maximum number of consecutive registers of
- class CLASS needed to hold a value of mode MODE.
-
- This is closely related to the macro 'TARGET_HARD_REGNO_NREGS'. In
- fact, the value of the macro 'CLASS_MAX_NREGS (CLASS, MODE)' should
- be the maximum value of 'TARGET_HARD_REGNO_NREGS (REGNO, MODE)' for
- all REGNO values in the class CLASS.
-
- This macro helps control the handling of multiple-word values in
- the reload pass.
-
- -- Target Hook: bool TARGET_CAN_CHANGE_MODE_CLASS (machine_mode FROM,
- machine_mode TO, reg_class_t RCLASS)
- This hook returns true if it is possible to bitcast values held in
- registers of class RCLASS from mode FROM to mode TO and if doing so
- preserves the low-order bits that are common to both modes. The
- result is only meaningful if RCLASS has registers that can hold
- both 'from' and 'to'. The default implementation returns true.
-
- As an example of when such bitcasting is invalid, loading 32-bit
- integer or floating-point objects into floating-point registers on
- Alpha extends them to 64 bits. Therefore loading a 64-bit object
- and then storing it as a 32-bit object does not store the low-order
- 32 bits, as would be the case for a normal register. Therefore,
- 'alpha.h' defines 'TARGET_CAN_CHANGE_MODE_CLASS' to return:
-
- (GET_MODE_SIZE (from) == GET_MODE_SIZE (to)
- || !reg_classes_intersect_p (FLOAT_REGS, rclass))
-
- Even if storing from a register in mode TO would be valid, if both
- FROM and 'raw_reg_mode' for RCLASS are wider than 'word_mode', then
- we must prevent TO narrowing the mode. This happens when the
- middle-end assumes that it can load or store pieces of an N-word
- pseudo, and that the pseudo will eventually be allocated to N
- 'word_mode' hard registers. Failure to prevent this kind of mode
- change will result in the entire 'raw_reg_mode' being modified
- instead of the partial value that the middle-end intended.
-
- -- Target Hook: reg_class_t TARGET_IRA_CHANGE_PSEUDO_ALLOCNO_CLASS
- (int, REG_CLASS_T, REG_CLASS_T)
- A target hook which can change allocno class for given pseudo from
- allocno and best class calculated by IRA.
-
- The default version of this target hook always returns given class.
-
- -- Target Hook: bool TARGET_LRA_P (void)
- A target hook which returns true if we use LRA instead of reload
- pass. The default version of this target hook returns true. New
- ports should use LRA, and existing ports are encouraged to convert.
-
- -- Target Hook: int TARGET_REGISTER_PRIORITY (int)
- A target hook which returns the register priority number to which
- the register HARD_REGNO belongs to. The bigger the number, the
- more preferable the hard register usage (when all other conditions
- are the same). This hook can be used to prefer some hard register
- over others in LRA. For example, some x86-64 register usage needs
- additional prefix which makes instructions longer. The hook can
- return lower priority number for such registers make them less
- favorable and as result making the generated code smaller. The
- default version of this target hook returns always zero.
-
- -- Target Hook: bool TARGET_REGISTER_USAGE_LEVELING_P (void)
- A target hook which returns true if we need register usage
- leveling. That means if a few hard registers are equally good for
- the assignment, we choose the least used hard register. The
- register usage leveling may be profitable for some targets. Don't
- use the usage leveling for targets with conditional execution or
- targets with big register files as it hurts if-conversion and
- cross-jumping optimizations. The default version of this target
- hook returns always false.
-
- -- Target Hook: bool TARGET_DIFFERENT_ADDR_DISPLACEMENT_P (void)
- A target hook which returns true if an address with the same
- structure can have different maximal legitimate displacement. For
- example, the displacement can depend on memory mode or on operand
- combinations in the insn. The default version of this target hook
- returns always false.
-
- -- Target Hook: bool TARGET_CANNOT_SUBSTITUTE_MEM_EQUIV_P (rtx SUBST)
- A target hook which returns 'true' if SUBST can't substitute safely
- pseudos with equivalent memory values during register allocation.
- The default version of this target hook returns 'false'. On most
- machines, this default should be used. For generally machines with
- non orthogonal register usage for addressing, such as SH, this hook
- can be used to avoid excessive spilling.
-
- -- Target Hook: bool TARGET_LEGITIMIZE_ADDRESS_DISPLACEMENT (rtx
- *OFFSET1, rtx *OFFSET2, poly_int64 ORIG_OFFSET, machine_mode
- MODE)
- This hook tries to split address offset ORIG_OFFSET into two parts:
- one that should be added to the base address to create a local
- anchor point, and an additional offset that can be applied to the
- anchor to address a value of mode MODE. The idea is that the local
- anchor could be shared by other accesses to nearby locations.
-
- The hook returns true if it succeeds, storing the offset of the
- anchor from the base in OFFSET1 and the offset of the final address
- from the anchor in OFFSET2. The default implementation returns
- false.
-
- -- Target Hook: reg_class_t TARGET_SPILL_CLASS (reg_class_t,
- MACHINE_MODE)
- This hook defines a class of registers which could be used for
- spilling pseudos of the given mode and class, or 'NO_REGS' if only
- memory should be used. Not defining this hook is equivalent to
- returning 'NO_REGS' for all inputs.
-
- -- Target Hook: bool TARGET_ADDITIONAL_ALLOCNO_CLASS_P (reg_class_t)
- This hook should return 'true' if given class of registers should
- be an allocno class in any way. Usually RA uses only one register
- class from all classes containing the same register set. In some
- complicated cases, you need to have two or more such classes as
- allocno ones for RA correct work. Not defining this hook is
- equivalent to returning 'false' for all inputs.
-
- -- Target Hook: scalar_int_mode TARGET_CSTORE_MODE (enum insn_code
- ICODE)
- This hook defines the machine mode to use for the boolean result of
- conditional store patterns. The ICODE argument is the instruction
- code for the cstore being performed. Not definiting this hook is
- the same as accepting the mode encoded into operand 0 of the cstore
- expander patterns.
-
- -- Target Hook: int TARGET_COMPUTE_PRESSURE_CLASSES (enum reg_class
- *PRESSURE_CLASSES)
- A target hook which lets a backend compute the set of pressure
- classes to be used by those optimization passes which take register
- pressure into account, as opposed to letting IRA compute them. It
- returns the number of register classes stored in the array
- PRESSURE_CLASSES.
-
-
- File: gccint.info, Node: Stack and Calling, Next: Varargs, Prev: Register Classes, Up: Target Macros
-
- 18.9 Stack Layout and Calling Conventions
- =========================================
-
- This describes the stack layout and calling conventions.
-
- * Menu:
-
- * Frame Layout::
- * Exception Handling::
- * Stack Checking::
- * Frame Registers::
- * Elimination::
- * Stack Arguments::
- * Register Arguments::
- * Scalar Return::
- * Aggregate Return::
- * Caller Saves::
- * Function Entry::
- * Profiling::
- * Tail Calls::
- * Shrink-wrapping separate components::
- * Stack Smashing Protection::
- * Miscellaneous Register Hooks::
-
-
- File: gccint.info, Node: Frame Layout, Next: Exception Handling, Up: Stack and Calling
-
- 18.9.1 Basic Stack Layout
- -------------------------
-
- Here is the basic stack layout.
-
- -- Macro: STACK_GROWS_DOWNWARD
- Define this macro to be true if pushing a word onto the stack moves
- the stack pointer to a smaller address, and false otherwise.
-
- -- Macro: STACK_PUSH_CODE
- This macro defines the operation used when something is pushed on
- the stack. In RTL, a push operation will be '(set (mem
- (STACK_PUSH_CODE (reg sp))) ...)'
-
- The choices are 'PRE_DEC', 'POST_DEC', 'PRE_INC', and 'POST_INC'.
- Which of these is correct depends on the stack direction and on
- whether the stack pointer points to the last item on the stack or
- whether it points to the space for the next item on the stack.
-
- The default is 'PRE_DEC' when 'STACK_GROWS_DOWNWARD' is true, which
- is almost always right, and 'PRE_INC' otherwise, which is often
- wrong.
-
- -- Macro: FRAME_GROWS_DOWNWARD
- Define this macro to nonzero value if the addresses of local
- variable slots are at negative offsets from the frame pointer.
-
- -- Macro: ARGS_GROW_DOWNWARD
- Define this macro if successive arguments to a function occupy
- decreasing addresses on the stack.
-
- -- Target Hook: HOST_WIDE_INT TARGET_STARTING_FRAME_OFFSET (void)
- This hook returns the offset from the frame pointer to the first
- local variable slot to be allocated. If 'FRAME_GROWS_DOWNWARD', it
- is the offset to _end_ of the first slot allocated, otherwise it is
- the offset to _beginning_ of the first slot allocated. The default
- implementation returns 0.
-
- -- Macro: STACK_ALIGNMENT_NEEDED
- Define to zero to disable final alignment of the stack during
- reload. The nonzero default for this macro is suitable for most
- ports.
-
- On ports where 'TARGET_STARTING_FRAME_OFFSET' is nonzero or where
- there is a register save block following the local block that
- doesn't require alignment to 'STACK_BOUNDARY', it may be beneficial
- to disable stack alignment and do it in the backend.
-
- -- Macro: STACK_POINTER_OFFSET
- Offset from the stack pointer register to the first location at
- which outgoing arguments are placed. If not specified, the default
- value of zero is used. This is the proper value for most machines.
-
- If 'ARGS_GROW_DOWNWARD', this is the offset to the location above
- the first location at which outgoing arguments are placed.
-
- -- Macro: FIRST_PARM_OFFSET (FUNDECL)
- Offset from the argument pointer register to the first argument's
- address. On some machines it may depend on the data type of the
- function.
-
- If 'ARGS_GROW_DOWNWARD', this is the offset to the location above
- the first argument's address.
-
- -- Macro: STACK_DYNAMIC_OFFSET (FUNDECL)
- Offset from the stack pointer register to an item dynamically
- allocated on the stack, e.g., by 'alloca'.
-
- The default value for this macro is 'STACK_POINTER_OFFSET' plus the
- length of the outgoing arguments. The default is correct for most
- machines. See 'function.c' for details.
-
- -- Macro: INITIAL_FRAME_ADDRESS_RTX
- A C expression whose value is RTL representing the address of the
- initial stack frame. This address is passed to 'RETURN_ADDR_RTX'
- and 'DYNAMIC_CHAIN_ADDRESS'. If you don't define this macro, a
- reasonable default value will be used. Define this macro in order
- to make frame pointer elimination work in the presence of
- '__builtin_frame_address (count)' and '__builtin_return_address
- (count)' for 'count' not equal to zero.
-
- -- Macro: DYNAMIC_CHAIN_ADDRESS (FRAMEADDR)
- A C expression whose value is RTL representing the address in a
- stack frame where the pointer to the caller's frame is stored.
- Assume that FRAMEADDR is an RTL expression for the address of the
- stack frame itself.
-
- If you don't define this macro, the default is to return the value
- of FRAMEADDR--that is, the stack frame address is also the address
- of the stack word that points to the previous frame.
-
- -- Macro: SETUP_FRAME_ADDRESSES
- A C expression that produces the machine-specific code to setup the
- stack so that arbitrary frames can be accessed. For example, on
- the SPARC, we must flush all of the register windows to the stack
- before we can access arbitrary stack frames. You will seldom need
- to define this macro. The default is to do nothing.
-
- -- Target Hook: rtx TARGET_BUILTIN_SETJMP_FRAME_VALUE (void)
- This target hook should return an rtx that is used to store the
- address of the current frame into the built in 'setjmp' buffer.
- The default value, 'virtual_stack_vars_rtx', is correct for most
- machines. One reason you may need to define this target hook is if
- 'hard_frame_pointer_rtx' is the appropriate value on your machine.
-
- -- Macro: FRAME_ADDR_RTX (FRAMEADDR)
- A C expression whose value is RTL representing the value of the
- frame address for the current frame. FRAMEADDR is the frame
- pointer of the current frame. This is used for
- __builtin_frame_address. You need only define this macro if the
- frame address is not the same as the frame pointer. Most machines
- do not need to define it.
-
- -- Macro: RETURN_ADDR_RTX (COUNT, FRAMEADDR)
- A C expression whose value is RTL representing the value of the
- return address for the frame COUNT steps up from the current frame,
- after the prologue. FRAMEADDR is the frame pointer of the COUNT
- frame, or the frame pointer of the COUNT - 1 frame if
- 'RETURN_ADDR_IN_PREVIOUS_FRAME' is nonzero.
-
- The value of the expression must always be the correct address when
- COUNT is zero, but may be 'NULL_RTX' if there is no way to
- determine the return address of other frames.
-
- -- Macro: RETURN_ADDR_IN_PREVIOUS_FRAME
- Define this macro to nonzero value if the return address of a
- particular stack frame is accessed from the frame pointer of the
- previous stack frame. The zero default for this macro is suitable
- for most ports.
-
- -- Macro: INCOMING_RETURN_ADDR_RTX
- A C expression whose value is RTL representing the location of the
- incoming return address at the beginning of any function, before
- the prologue. This RTL is either a 'REG', indicating that the
- return value is saved in 'REG', or a 'MEM' representing a location
- in the stack.
-
- You only need to define this macro if you want to support call
- frame debugging information like that provided by DWARF 2.
-
- If this RTL is a 'REG', you should also define
- 'DWARF_FRAME_RETURN_COLUMN' to 'DWARF_FRAME_REGNUM (REGNO)'.
-
- -- Macro: DWARF_ALT_FRAME_RETURN_COLUMN
- A C expression whose value is an integer giving a DWARF 2 column
- number that may be used as an alternative return column. The
- column must not correspond to any gcc hard register (that is, it
- must not be in the range of 'DWARF_FRAME_REGNUM').
-
- This macro can be useful if 'DWARF_FRAME_RETURN_COLUMN' is set to a
- general register, but an alternative column needs to be used for
- signal frames. Some targets have also used different frame return
- columns over time.
-
- -- Macro: DWARF_ZERO_REG
- A C expression whose value is an integer giving a DWARF 2 register
- number that is considered to always have the value zero. This
- should only be defined if the target has an architected zero
- register, and someone decided it was a good idea to use that
- register number to terminate the stack backtrace. New ports should
- avoid this.
-
- -- Target Hook: void TARGET_DWARF_HANDLE_FRAME_UNSPEC (const char
- *LABEL, rtx PATTERN, int INDEX)
- This target hook allows the backend to emit frame-related insns
- that contain UNSPECs or UNSPEC_VOLATILEs. The DWARF 2 call frame
- debugging info engine will invoke it on insns of the form
- (set (reg) (unspec [...] UNSPEC_INDEX))
- and
- (set (reg) (unspec_volatile [...] UNSPECV_INDEX)).
- to let the backend emit the call frame instructions. LABEL is the
- CFI label attached to the insn, PATTERN is the pattern of the insn
- and INDEX is 'UNSPEC_INDEX' or 'UNSPECV_INDEX'.
-
- -- Target Hook: unsigned int TARGET_DWARF_POLY_INDETERMINATE_VALUE
- (unsigned int I, unsigned int *FACTOR, int *OFFSET)
- Express the value of 'poly_int' indeterminate I as a DWARF
- expression, with I counting from 1. Return the number of a DWARF
- register R and set '*FACTOR' and '*OFFSET' such that the value of
- the indeterminate is:
- value_of(R) / FACTOR - OFFSET
-
- A target only needs to define this hook if it sets
- 'NUM_POLY_INT_COEFFS' to a value greater than 1.
-
- -- Macro: INCOMING_FRAME_SP_OFFSET
- A C expression whose value is an integer giving the offset, in
- bytes, from the value of the stack pointer register to the top of
- the stack frame at the beginning of any function, before the
- prologue. The top of the frame is defined to be the value of the
- stack pointer in the previous frame, just before the call
- instruction.
-
- You only need to define this macro if you want to support call
- frame debugging information like that provided by DWARF 2.
-
- -- Macro: DEFAULT_INCOMING_FRAME_SP_OFFSET
- Like 'INCOMING_FRAME_SP_OFFSET', but must be the same for all
- functions of the same ABI, and when using GAS '.cfi_*' directives
- must also agree with the default CFI GAS emits. Define this macro
- only if 'INCOMING_FRAME_SP_OFFSET' can have different values
- between different functions of the same ABI or when
- 'INCOMING_FRAME_SP_OFFSET' does not agree with GAS default CFI.
-
- -- Macro: ARG_POINTER_CFA_OFFSET (FUNDECL)
- A C expression whose value is an integer giving the offset, in
- bytes, from the argument pointer to the canonical frame address
- (cfa). The final value should coincide with that calculated by
- 'INCOMING_FRAME_SP_OFFSET'. Which is unfortunately not usable
- during virtual register instantiation.
-
- The default value for this macro is 'FIRST_PARM_OFFSET (fundecl) +
- crtl->args.pretend_args_size', which is correct for most machines;
- in general, the arguments are found immediately before the stack
- frame. Note that this is not the case on some targets that save
- registers into the caller's frame, such as SPARC and rs6000, and so
- such targets need to define this macro.
-
- You only need to define this macro if the default is incorrect, and
- you want to support call frame debugging information like that
- provided by DWARF 2.
-
- -- Macro: FRAME_POINTER_CFA_OFFSET (FUNDECL)
- If defined, a C expression whose value is an integer giving the
- offset in bytes from the frame pointer to the canonical frame
- address (cfa). The final value should coincide with that
- calculated by 'INCOMING_FRAME_SP_OFFSET'.
-
- Normally the CFA is calculated as an offset from the argument
- pointer, via 'ARG_POINTER_CFA_OFFSET', but if the argument pointer
- is variable due to the ABI, this may not be possible. If this
- macro is defined, it implies that the virtual register
- instantiation should be based on the frame pointer instead of the
- argument pointer. Only one of 'FRAME_POINTER_CFA_OFFSET' and
- 'ARG_POINTER_CFA_OFFSET' should be defined.
-
- -- Macro: CFA_FRAME_BASE_OFFSET (FUNDECL)
- If defined, a C expression whose value is an integer giving the
- offset in bytes from the canonical frame address (cfa) to the frame
- base used in DWARF 2 debug information. The default is zero. A
- different value may reduce the size of debug information on some
- ports.
-
-
- File: gccint.info, Node: Exception Handling, Next: Stack Checking, Prev: Frame Layout, Up: Stack and Calling
-
- 18.9.2 Exception Handling Support
- ---------------------------------
-
- -- Macro: EH_RETURN_DATA_REGNO (N)
- A C expression whose value is the Nth register number used for data
- by exception handlers, or 'INVALID_REGNUM' if fewer than N
- registers are usable.
-
- The exception handling library routines communicate with the
- exception handlers via a set of agreed upon registers. Ideally
- these registers should be call-clobbered; it is possible to use
- call-saved registers, but may negatively impact code size. The
- target must support at least 2 data registers, but should define 4
- if there are enough free registers.
-
- You must define this macro if you want to support call frame
- exception handling like that provided by DWARF 2.
-
- -- Macro: EH_RETURN_STACKADJ_RTX
- A C expression whose value is RTL representing a location in which
- to store a stack adjustment to be applied before function return.
- This is used to unwind the stack to an exception handler's call
- frame. It will be assigned zero on code paths that return
- normally.
-
- Typically this is a call-clobbered hard register that is otherwise
- untouched by the epilogue, but could also be a stack slot.
-
- Do not define this macro if the stack pointer is saved and restored
- by the regular prolog and epilog code in the call frame itself; in
- this case, the exception handling library routines will update the
- stack location to be restored in place. Otherwise, you must define
- this macro if you want to support call frame exception handling
- like that provided by DWARF 2.
-
- -- Macro: EH_RETURN_HANDLER_RTX
- A C expression whose value is RTL representing a location in which
- to store the address of an exception handler to which we should
- return. It will not be assigned on code paths that return
- normally.
-
- Typically this is the location in the call frame at which the
- normal return address is stored. For targets that return by
- popping an address off the stack, this might be a memory address
- just below the _target_ call frame rather than inside the current
- call frame. If defined, 'EH_RETURN_STACKADJ_RTX' will have already
- been assigned, so it may be used to calculate the location of the
- target call frame.
-
- Some targets have more complex requirements than storing to an
- address calculable during initial code generation. In that case
- the 'eh_return' instruction pattern should be used instead.
-
- If you want to support call frame exception handling, you must
- define either this macro or the 'eh_return' instruction pattern.
-
- -- Macro: RETURN_ADDR_OFFSET
- If defined, an integer-valued C expression for which rtl will be
- generated to add it to the exception handler address before it is
- searched in the exception handling tables, and to subtract it again
- from the address before using it to return to the exception
- handler.
-
- -- Macro: ASM_PREFERRED_EH_DATA_FORMAT (CODE, GLOBAL)
- This macro chooses the encoding of pointers embedded in the
- exception handling sections. If at all possible, this should be
- defined such that the exception handling section will not require
- dynamic relocations, and so may be read-only.
-
- CODE is 0 for data, 1 for code labels, 2 for function pointers.
- GLOBAL is true if the symbol may be affected by dynamic
- relocations. The macro should return a combination of the
- 'DW_EH_PE_*' defines as found in 'dwarf2.h'.
-
- If this macro is not defined, pointers will not be encoded but
- represented directly.
-
- -- Macro: ASM_MAYBE_OUTPUT_ENCODED_ADDR_RTX (FILE, ENCODING, SIZE,
- ADDR, DONE)
- This macro allows the target to emit whatever special magic is
- required to represent the encoding chosen by
- 'ASM_PREFERRED_EH_DATA_FORMAT'. Generic code takes care of
- pc-relative and indirect encodings; this must be defined if the
- target uses text-relative or data-relative encodings.
-
- This is a C statement that branches to DONE if the format was
- handled. ENCODING is the format chosen, SIZE is the number of
- bytes that the format occupies, ADDR is the 'SYMBOL_REF' to be
- emitted.
-
- -- Macro: MD_FALLBACK_FRAME_STATE_FOR (CONTEXT, FS)
- This macro allows the target to add CPU and operating system
- specific code to the call-frame unwinder for use when there is no
- unwind data available. The most common reason to implement this
- macro is to unwind through signal frames.
-
- This macro is called from 'uw_frame_state_for' in 'unwind-dw2.c',
- 'unwind-dw2-xtensa.c' and 'unwind-ia64.c'. CONTEXT is an
- '_Unwind_Context'; FS is an '_Unwind_FrameState'. Examine
- 'context->ra' for the address of the code being executed and
- 'context->cfa' for the stack pointer value. If the frame can be
- decoded, the register save addresses should be updated in FS and
- the macro should evaluate to '_URC_NO_REASON'. If the frame cannot
- be decoded, the macro should evaluate to '_URC_END_OF_STACK'.
-
- For proper signal handling in Java this macro is accompanied by
- 'MAKE_THROW_FRAME', defined in 'libjava/include/*-signal.h'
- headers.
-
- -- Macro: MD_HANDLE_UNWABI (CONTEXT, FS)
- This macro allows the target to add operating system specific code
- to the call-frame unwinder to handle the IA-64 '.unwabi' unwinding
- directive, usually used for signal or interrupt frames.
-
- This macro is called from 'uw_update_context' in libgcc's
- 'unwind-ia64.c'. CONTEXT is an '_Unwind_Context'; FS is an
- '_Unwind_FrameState'. Examine 'fs->unwabi' for the abi and context
- in the '.unwabi' directive. If the '.unwabi' directive can be
- handled, the register save addresses should be updated in FS.
-
- -- Macro: TARGET_USES_WEAK_UNWIND_INFO
- A C expression that evaluates to true if the target requires unwind
- info to be given comdat linkage. Define it to be '1' if comdat
- linkage is necessary. The default is '0'.
-
-
- File: gccint.info, Node: Stack Checking, Next: Frame Registers, Prev: Exception Handling, Up: Stack and Calling
-
- 18.9.3 Specifying How Stack Checking is Done
- --------------------------------------------
-
- GCC will check that stack references are within the boundaries of the
- stack, if the option '-fstack-check' is specified, in one of three ways:
-
- 1. If the value of the 'STACK_CHECK_BUILTIN' macro is nonzero, GCC
- will assume that you have arranged for full stack checking to be
- done at appropriate places in the configuration files. GCC will
- not do other special processing.
-
- 2. If 'STACK_CHECK_BUILTIN' is zero and the value of the
- 'STACK_CHECK_STATIC_BUILTIN' macro is nonzero, GCC will assume that
- you have arranged for static stack checking (checking of the static
- stack frame of functions) to be done at appropriate places in the
- configuration files. GCC will only emit code to do dynamic stack
- checking (checking on dynamic stack allocations) using the third
- approach below.
-
- 3. If neither of the above are true, GCC will generate code to
- periodically "probe" the stack pointer using the values of the
- macros defined below.
-
- If neither STACK_CHECK_BUILTIN nor STACK_CHECK_STATIC_BUILTIN is
- defined, GCC will change its allocation strategy for large objects if
- the option '-fstack-check' is specified: they will always be allocated
- dynamically if their size exceeds 'STACK_CHECK_MAX_VAR_SIZE' bytes.
-
- -- Macro: STACK_CHECK_BUILTIN
- A nonzero value if stack checking is done by the configuration
- files in a machine-dependent manner. You should define this macro
- if stack checking is required by the ABI of your machine or if you
- would like to do stack checking in some more efficient way than the
- generic approach. The default value of this macro is zero.
-
- -- Macro: STACK_CHECK_STATIC_BUILTIN
- A nonzero value if static stack checking is done by the
- configuration files in a machine-dependent manner. You should
- define this macro if you would like to do static stack checking in
- some more efficient way than the generic approach. The default
- value of this macro is zero.
-
- -- Macro: STACK_CHECK_PROBE_INTERVAL_EXP
- An integer specifying the interval at which GCC must generate stack
- probe instructions, defined as 2 raised to this integer. You will
- normally define this macro so that the interval be no larger than
- the size of the "guard pages" at the end of a stack area. The
- default value of 12 (4096-byte interval) is suitable for most
- systems.
-
- -- Macro: STACK_CHECK_MOVING_SP
- An integer which is nonzero if GCC should move the stack pointer
- page by page when doing probes. This can be necessary on systems
- where the stack pointer contains the bottom address of the memory
- area accessible to the executing thread at any point in time. In
- this situation an alternate signal stack is required in order to be
- able to recover from a stack overflow. The default value of this
- macro is zero.
-
- -- Macro: STACK_CHECK_PROTECT
- The number of bytes of stack needed to recover from a stack
- overflow, for languages where such a recovery is supported. The
- default value of 4KB/8KB with the 'setjmp'/'longjmp'-based
- exception handling mechanism and 8KB/12KB with other exception
- handling mechanisms should be adequate for most architectures and
- operating systems.
-
- The following macros are relevant only if neither STACK_CHECK_BUILTIN
- nor STACK_CHECK_STATIC_BUILTIN is defined; you can omit them altogether
- in the opposite case.
-
- -- Macro: STACK_CHECK_MAX_FRAME_SIZE
- The maximum size of a stack frame, in bytes. GCC will generate
- probe instructions in non-leaf functions to ensure at least this
- many bytes of stack are available. If a stack frame is larger than
- this size, stack checking will not be reliable and GCC will issue a
- warning. The default is chosen so that GCC only generates one
- instruction on most systems. You should normally not change the
- default value of this macro.
-
- -- Macro: STACK_CHECK_FIXED_FRAME_SIZE
- GCC uses this value to generate the above warning message. It
- represents the amount of fixed frame used by a function, not
- including space for any callee-saved registers, temporaries and
- user variables. You need only specify an upper bound for this
- amount and will normally use the default of four words.
-
- -- Macro: STACK_CHECK_MAX_VAR_SIZE
- The maximum size, in bytes, of an object that GCC will place in the
- fixed area of the stack frame when the user specifies
- '-fstack-check'. GCC computed the default from the values of the
- above macros and you will normally not need to override that
- default.
-
- -- Target Hook: HOST_WIDE_INT
- TARGET_STACK_CLASH_PROTECTION_ALLOCA_PROBE_RANGE (void)
- Some targets have an ABI defined interval for which no probing
- needs to be done. When a probe does need to be done this same
- interval is used as the probe distance up when doing stack clash
- protection for alloca. On such targets this value can be set to
- override the default probing up interval. Define this variable to
- return nonzero if such a probe range is required or zero otherwise.
- Defining this hook also requires your functions which make use of
- alloca to have at least 8 byesof outgoing arguments. If this is
- not the case the stack will be corrupted. You need not define this
- macro if it would always have the value zero.
-
-
- File: gccint.info, Node: Frame Registers, Next: Elimination, Prev: Stack Checking, Up: Stack and Calling
-
- 18.9.4 Registers That Address the Stack Frame
- ---------------------------------------------
-
- This discusses registers that address the stack frame.
-
- -- Macro: STACK_POINTER_REGNUM
- The register number of the stack pointer register, which must also
- be a fixed register according to 'FIXED_REGISTERS'. On most
- machines, the hardware determines which register this is.
-
- -- Macro: FRAME_POINTER_REGNUM
- The register number of the frame pointer register, which is used to
- access automatic variables in the stack frame. On some machines,
- the hardware determines which register this is. On other machines,
- you can choose any register you wish for this purpose.
-
- -- Macro: HARD_FRAME_POINTER_REGNUM
- On some machines the offset between the frame pointer and starting
- offset of the automatic variables is not known until after register
- allocation has been done (for example, because the saved registers
- are between these two locations). On those machines, define
- 'FRAME_POINTER_REGNUM' the number of a special, fixed register to
- be used internally until the offset is known, and define
- 'HARD_FRAME_POINTER_REGNUM' to be the actual hard register number
- used for the frame pointer.
-
- You should define this macro only in the very rare circumstances
- when it is not possible to calculate the offset between the frame
- pointer and the automatic variables until after register allocation
- has been completed. When this macro is defined, you must also
- indicate in your definition of 'ELIMINABLE_REGS' how to eliminate
- 'FRAME_POINTER_REGNUM' into either 'HARD_FRAME_POINTER_REGNUM' or
- 'STACK_POINTER_REGNUM'.
-
- Do not define this macro if it would be the same as
- 'FRAME_POINTER_REGNUM'.
-
- -- Macro: ARG_POINTER_REGNUM
- The register number of the arg pointer register, which is used to
- access the function's argument list. On some machines, this is the
- same as the frame pointer register. On some machines, the hardware
- determines which register this is. On other machines, you can
- choose any register you wish for this purpose. If this is not the
- same register as the frame pointer register, then you must mark it
- as a fixed register according to 'FIXED_REGISTERS', or arrange to
- be able to eliminate it (*note Elimination::).
-
- -- Macro: HARD_FRAME_POINTER_IS_FRAME_POINTER
- Define this to a preprocessor constant that is nonzero if
- 'hard_frame_pointer_rtx' and 'frame_pointer_rtx' should be the
- same. The default definition is '(HARD_FRAME_POINTER_REGNUM ==
- FRAME_POINTER_REGNUM)'; you only need to define this macro if that
- definition is not suitable for use in preprocessor conditionals.
-
- -- Macro: HARD_FRAME_POINTER_IS_ARG_POINTER
- Define this to a preprocessor constant that is nonzero if
- 'hard_frame_pointer_rtx' and 'arg_pointer_rtx' should be the same.
- The default definition is '(HARD_FRAME_POINTER_REGNUM ==
- ARG_POINTER_REGNUM)'; you only need to define this macro if that
- definition is not suitable for use in preprocessor conditionals.
-
- -- Macro: RETURN_ADDRESS_POINTER_REGNUM
- The register number of the return address pointer register, which
- is used to access the current function's return address from the
- stack. On some machines, the return address is not at a fixed
- offset from the frame pointer or stack pointer or argument pointer.
- This register can be defined to point to the return address on the
- stack, and then be converted by 'ELIMINABLE_REGS' into either the
- frame pointer or stack pointer.
-
- Do not define this macro unless there is no other way to get the
- return address from the stack.
-
- -- Macro: STATIC_CHAIN_REGNUM
- -- Macro: STATIC_CHAIN_INCOMING_REGNUM
- Register numbers used for passing a function's static chain
- pointer. If register windows are used, the register number as seen
- by the called function is 'STATIC_CHAIN_INCOMING_REGNUM', while the
- register number as seen by the calling function is
- 'STATIC_CHAIN_REGNUM'. If these registers are the same,
- 'STATIC_CHAIN_INCOMING_REGNUM' need not be defined.
-
- The static chain register need not be a fixed register.
-
- If the static chain is passed in memory, these macros should not be
- defined; instead, the 'TARGET_STATIC_CHAIN' hook should be used.
-
- -- Target Hook: rtx TARGET_STATIC_CHAIN (const_tree FNDECL_OR_TYPE,
- bool INCOMING_P)
- This hook replaces the use of 'STATIC_CHAIN_REGNUM' et al for
- targets that may use different static chain locations for different
- nested functions. This may be required if the target has function
- attributes that affect the calling conventions of the function and
- those calling conventions use different static chain locations.
-
- The default version of this hook uses 'STATIC_CHAIN_REGNUM' et al.
-
- If the static chain is passed in memory, this hook should be used
- to provide rtx giving 'mem' expressions that denote where they are
- stored. Often the 'mem' expression as seen by the caller will be
- at an offset from the stack pointer and the 'mem' expression as
- seen by the callee will be at an offset from the frame pointer.
- The variables 'stack_pointer_rtx', 'frame_pointer_rtx', and
- 'arg_pointer_rtx' will have been initialized and should be used to
- refer to those items.
-
- -- Macro: DWARF_FRAME_REGISTERS
- This macro specifies the maximum number of hard registers that can
- be saved in a call frame. This is used to size data structures
- used in DWARF2 exception handling.
-
- Prior to GCC 3.0, this macro was needed in order to establish a
- stable exception handling ABI in the face of adding new hard
- registers for ISA extensions. In GCC 3.0 and later, the EH ABI is
- insulated from changes in the number of hard registers.
- Nevertheless, this macro can still be used to reduce the runtime
- memory requirements of the exception handling routines, which can
- be substantial if the ISA contains a lot of registers that are not
- call-saved.
-
- If this macro is not defined, it defaults to
- 'FIRST_PSEUDO_REGISTER'.
-
- -- Macro: PRE_GCC3_DWARF_FRAME_REGISTERS
-
- This macro is similar to 'DWARF_FRAME_REGISTERS', but is provided
- for backward compatibility in pre GCC 3.0 compiled code.
-
- If this macro is not defined, it defaults to
- 'DWARF_FRAME_REGISTERS'.
-
- -- Macro: DWARF_REG_TO_UNWIND_COLUMN (REGNO)
-
- Define this macro if the target's representation for dwarf
- registers is different than the internal representation for unwind
- column. Given a dwarf register, this macro should return the
- internal unwind column number to use instead.
-
- -- Macro: DWARF_FRAME_REGNUM (REGNO)
-
- Define this macro if the target's representation for dwarf
- registers used in .eh_frame or .debug_frame is different from that
- used in other debug info sections. Given a GCC hard register
- number, this macro should return the .eh_frame register number.
- The default is 'DBX_REGISTER_NUMBER (REGNO)'.
-
- -- Macro: DWARF2_FRAME_REG_OUT (REGNO, FOR_EH)
-
- Define this macro to map register numbers held in the call frame
- info that GCC has collected using 'DWARF_FRAME_REGNUM' to those
- that should be output in .debug_frame ('FOR_EH' is zero) and
- .eh_frame ('FOR_EH' is nonzero). The default is to return 'REGNO'.
-
- -- Macro: REG_VALUE_IN_UNWIND_CONTEXT
-
- Define this macro if the target stores register values as
- '_Unwind_Word' type in unwind context. It should be defined if
- target register size is larger than the size of 'void *'. The
- default is to store register values as 'void *' type.
-
- -- Macro: ASSUME_EXTENDED_UNWIND_CONTEXT
-
- Define this macro to be 1 if the target always uses extended unwind
- context with version, args_size and by_value fields. If it is
- undefined, it will be defined to 1 when
- 'REG_VALUE_IN_UNWIND_CONTEXT' is defined and 0 otherwise.
-
- -- Macro: DWARF_LAZY_REGISTER_VALUE (REGNO, VALUE)
- Define this macro if the target has pseudo DWARF registers whose
- values need to be computed lazily on demand by the unwinder (such
- as when referenced in a CFA expression). The macro returns true if
- REGNO is such a register and stores its value in '*VALUE' if so.
-
-
- File: gccint.info, Node: Elimination, Next: Stack Arguments, Prev: Frame Registers, Up: Stack and Calling
-
- 18.9.5 Eliminating Frame Pointer and Arg Pointer
- ------------------------------------------------
-
- This is about eliminating the frame pointer and arg pointer.
-
- -- Target Hook: bool TARGET_FRAME_POINTER_REQUIRED (void)
- This target hook should return 'true' if a function must have and
- use a frame pointer. This target hook is called in the reload
- pass. If its return value is 'true' the function will have a frame
- pointer.
-
- This target hook can in principle examine the current function and
- decide according to the facts, but on most machines the constant
- 'false' or the constant 'true' suffices. Use 'false' when the
- machine allows code to be generated with no frame pointer, and
- doing so saves some time or space. Use 'true' when there is no
- possible advantage to avoiding a frame pointer.
-
- In certain cases, the compiler does not know how to produce valid
- code without a frame pointer. The compiler recognizes those cases
- and automatically gives the function a frame pointer regardless of
- what 'targetm.frame_pointer_required' returns. You don't need to
- worry about them.
-
- In a function that does not require a frame pointer, the frame
- pointer register can be allocated for ordinary usage, unless you
- mark it as a fixed register. See 'FIXED_REGISTERS' for more
- information.
-
- Default return value is 'false'.
-
- -- Macro: ELIMINABLE_REGS
- This macro specifies a table of register pairs used to eliminate
- unneeded registers that point into the stack frame.
-
- The definition of this macro is a list of structure
- initializations, each of which specifies an original and
- replacement register.
-
- On some machines, the position of the argument pointer is not known
- until the compilation is completed. In such a case, a separate
- hard register must be used for the argument pointer. This register
- can be eliminated by replacing it with either the frame pointer or
- the argument pointer, depending on whether or not the frame pointer
- has been eliminated.
-
- In this case, you might specify:
- #define ELIMINABLE_REGS \
- {{ARG_POINTER_REGNUM, STACK_POINTER_REGNUM}, \
- {ARG_POINTER_REGNUM, FRAME_POINTER_REGNUM}, \
- {FRAME_POINTER_REGNUM, STACK_POINTER_REGNUM}}
-
- Note that the elimination of the argument pointer with the stack
- pointer is specified first since that is the preferred elimination.
-
- -- Target Hook: bool TARGET_CAN_ELIMINATE (const int FROM_REG, const
- int TO_REG)
- This target hook should return 'true' if the compiler is allowed to
- try to replace register number FROM_REG with register number
- TO_REG. This target hook will usually be 'true', since most of the
- cases preventing register elimination are things that the compiler
- already knows about.
-
- Default return value is 'true'.
-
- -- Macro: INITIAL_ELIMINATION_OFFSET (FROM-REG, TO-REG, OFFSET-VAR)
- This macro returns the initial difference between the specified
- pair of registers. The value would be computed from information
- such as the result of 'get_frame_size ()' and the tables of
- registers 'df_regs_ever_live_p' and 'call_used_regs'.
-
- -- Target Hook: void TARGET_COMPUTE_FRAME_LAYOUT (void)
- This target hook is called once each time the frame layout needs to
- be recalculated. The calculations can be cached by the target and
- can then be used by 'INITIAL_ELIMINATION_OFFSET' instead of
- re-computing the layout on every invocation of that hook. This is
- particularly useful for targets that have an expensive frame layout
- function. Implementing this callback is optional.
-
-
- File: gccint.info, Node: Stack Arguments, Next: Register Arguments, Prev: Elimination, Up: Stack and Calling
-
- 18.9.6 Passing Function Arguments on the Stack
- ----------------------------------------------
-
- The macros in this section control how arguments are passed on the
- stack. See the following section for other macros that control passing
- certain arguments in registers.
-
- -- Target Hook: bool TARGET_PROMOTE_PROTOTYPES (const_tree FNTYPE)
- This target hook returns 'true' if an argument declared in a
- prototype as an integral type smaller than 'int' should actually be
- passed as an 'int'. In addition to avoiding errors in certain
- cases of mismatch, it also makes for better code on certain
- machines. The default is to not promote prototypes.
-
- -- Macro: PUSH_ARGS
- A C expression. If nonzero, push insns will be used to pass
- outgoing arguments. If the target machine does not have a push
- instruction, set it to zero. That directs GCC to use an alternate
- strategy: to allocate the entire argument block and then store the
- arguments into it. When 'PUSH_ARGS' is nonzero, 'PUSH_ROUNDING'
- must be defined too.
-
- -- Macro: PUSH_ARGS_REVERSED
- A C expression. If nonzero, function arguments will be evaluated
- from last to first, rather than from first to last. If this macro
- is not defined, it defaults to 'PUSH_ARGS' on targets where the
- stack and args grow in opposite directions, and 0 otherwise.
-
- -- Macro: PUSH_ROUNDING (NPUSHED)
- A C expression that is the number of bytes actually pushed onto the
- stack when an instruction attempts to push NPUSHED bytes.
-
- On some machines, the definition
-
- #define PUSH_ROUNDING(BYTES) (BYTES)
-
- will suffice. But on other machines, instructions that appear to
- push one byte actually push two bytes in an attempt to maintain
- alignment. Then the definition should be
-
- #define PUSH_ROUNDING(BYTES) (((BYTES) + 1) & ~1)
-
- If the value of this macro has a type, it should be an unsigned
- type.
-
- -- Macro: ACCUMULATE_OUTGOING_ARGS
- A C expression. If nonzero, the maximum amount of space required
- for outgoing arguments will be computed and placed into
- 'crtl->outgoing_args_size'. No space will be pushed onto the stack
- for each call; instead, the function prologue should increase the
- stack frame size by this amount.
-
- Setting both 'PUSH_ARGS' and 'ACCUMULATE_OUTGOING_ARGS' is not
- proper.
-
- -- Macro: REG_PARM_STACK_SPACE (FNDECL)
- Define this macro if functions should assume that stack space has
- been allocated for arguments even when their values are passed in
- registers.
-
- The value of this macro is the size, in bytes, of the area reserved
- for arguments passed in registers for the function represented by
- FNDECL, which can be zero if GCC is calling a library function.
- The argument FNDECL can be the FUNCTION_DECL, or the type itself of
- the function.
-
- This space can be allocated by the caller, or be a part of the
- machine-dependent stack frame: 'OUTGOING_REG_PARM_STACK_SPACE' says
- which.
-
- -- Macro: INCOMING_REG_PARM_STACK_SPACE (FNDECL)
- Like 'REG_PARM_STACK_SPACE', but for incoming register arguments.
- Define this macro if space guaranteed when compiling a function
- body is different to space required when making a call, a situation
- that can arise with K&R style function definitions.
-
- -- Macro: OUTGOING_REG_PARM_STACK_SPACE (FNTYPE)
- Define this to a nonzero value if it is the responsibility of the
- caller to allocate the area reserved for arguments passed in
- registers when calling a function of FNTYPE. FNTYPE may be NULL if
- the function called is a library function.
-
- If 'ACCUMULATE_OUTGOING_ARGS' is defined, this macro controls
- whether the space for these arguments counts in the value of
- 'crtl->outgoing_args_size'.
-
- -- Macro: STACK_PARMS_IN_REG_PARM_AREA
- Define this macro if 'REG_PARM_STACK_SPACE' is defined, but the
- stack parameters don't skip the area specified by it.
-
- Normally, when a parameter is not passed in registers, it is placed
- on the stack beyond the 'REG_PARM_STACK_SPACE' area. Defining this
- macro suppresses this behavior and causes the parameter to be
- passed on the stack in its natural location.
-
- -- Target Hook: poly_int64 TARGET_RETURN_POPS_ARGS (tree FUNDECL, tree
- FUNTYPE, poly_int64 SIZE)
- This target hook returns the number of bytes of its own arguments
- that a function pops on returning, or 0 if the function pops no
- arguments and the caller must therefore pop them all after the
- function returns.
-
- FUNDECL is a C variable whose value is a tree node that describes
- the function in question. Normally it is a node of type
- 'FUNCTION_DECL' that describes the declaration of the function.
- From this you can obtain the 'DECL_ATTRIBUTES' of the function.
-
- FUNTYPE is a C variable whose value is a tree node that describes
- the function in question. Normally it is a node of type
- 'FUNCTION_TYPE' that describes the data type of the function. From
- this it is possible to obtain the data types of the value and
- arguments (if known).
-
- When a call to a library function is being considered, FUNDECL will
- contain an identifier node for the library function. Thus, if you
- need to distinguish among various library functions, you can do so
- by their names. Note that "library function" in this context means
- a function used to perform arithmetic, whose name is known
- specially in the compiler and was not mentioned in the C code being
- compiled.
-
- SIZE is the number of bytes of arguments passed on the stack. If a
- variable number of bytes is passed, it is zero, and argument
- popping will always be the responsibility of the calling function.
-
- On the VAX, all functions always pop their arguments, so the
- definition of this macro is SIZE. On the 68000, using the standard
- calling convention, no functions pop their arguments, so the value
- of the macro is always 0 in this case. But an alternative calling
- convention is available in which functions that take a fixed number
- of arguments pop them but other functions (such as 'printf') pop
- nothing (the caller pops all). When this convention is in use,
- FUNTYPE is examined to determine whether a function takes a fixed
- number of arguments.
-
- -- Macro: CALL_POPS_ARGS (CUM)
- A C expression that should indicate the number of bytes a call
- sequence pops off the stack. It is added to the value of
- 'RETURN_POPS_ARGS' when compiling a function call.
-
- CUM is the variable in which all arguments to the called function
- have been accumulated.
-
- On certain architectures, such as the SH5, a call trampoline is
- used that pops certain registers off the stack, depending on the
- arguments that have been passed to the function. Since this is a
- property of the call site, not of the called function,
- 'RETURN_POPS_ARGS' is not appropriate.
-
-
- File: gccint.info, Node: Register Arguments, Next: Scalar Return, Prev: Stack Arguments, Up: Stack and Calling
-
- 18.9.7 Passing Arguments in Registers
- -------------------------------------
-
- This section describes the macros which let you control how various
- types of arguments are passed in registers or how they are arranged in
- the stack.
-
- -- Target Hook: rtx TARGET_FUNCTION_ARG (cumulative_args_t CA, const
- function_arg_info &ARG)
- Return an RTX indicating whether function argument ARG is passed in
- a register and if so, which register. Argument CA summarizes all
- the previous arguments.
-
- The return value is usually either a 'reg' RTX for the hard
- register in which to pass the argument, or zero to pass the
- argument on the stack.
-
- The return value can be a 'const_int' which means argument is
- passed in a target specific slot with specified number. Target
- hooks should be used to store or load argument in such case. See
- 'TARGET_STORE_BOUNDS_FOR_ARG' and 'TARGET_LOAD_BOUNDS_FOR_ARG' for
- more information.
-
- The value of the expression can also be a 'parallel' RTX. This is
- used when an argument is passed in multiple locations. The mode of
- the 'parallel' should be the mode of the entire argument. The
- 'parallel' holds any number of 'expr_list' pairs; each one
- describes where part of the argument is passed. In each
- 'expr_list' the first operand must be a 'reg' RTX for the hard
- register in which to pass this part of the argument, and the mode
- of the register RTX indicates how large this part of the argument
- is. The second operand of the 'expr_list' is a 'const_int' which
- gives the offset in bytes into the entire argument of where this
- part starts. As a special exception the first 'expr_list' in the
- 'parallel' RTX may have a first operand of zero. This indicates
- that the entire argument is also stored on the stack.
-
- The last time this hook is called, it is called with 'MODE ==
- VOIDmode', and its result is passed to the 'call' or 'call_value'
- pattern as operands 2 and 3 respectively.
-
- The usual way to make the ISO library 'stdarg.h' work on a machine
- where some arguments are usually passed in registers, is to cause
- nameless arguments to be passed on the stack instead. This is done
- by making 'TARGET_FUNCTION_ARG' return 0 whenever NAMED is 'false'.
-
- You may use the hook 'targetm.calls.must_pass_in_stack' in the
- definition of this macro to determine if this argument is of a type
- that must be passed in the stack. If 'REG_PARM_STACK_SPACE' is not
- defined and 'TARGET_FUNCTION_ARG' returns nonzero for such an
- argument, the compiler will abort. If 'REG_PARM_STACK_SPACE' is
- defined, the argument will be computed in the stack and then loaded
- into a register.
-
- -- Target Hook: bool TARGET_MUST_PASS_IN_STACK (const function_arg_info
- &ARG)
- This target hook should return 'true' if we should not pass ARG
- solely in registers. The file 'expr.h' defines a definition that
- is usually appropriate, refer to 'expr.h' for additional
- documentation.
-
- -- Target Hook: rtx TARGET_FUNCTION_INCOMING_ARG (cumulative_args_t CA,
- const function_arg_info &ARG)
- Define this hook if the caller and callee on the target have
- different views of where arguments are passed. Also define this
- hook if there are functions that are never directly called, but are
- invoked by the hardware and which have nonstandard calling
- conventions.
-
- In this case 'TARGET_FUNCTION_ARG' computes the register in which
- the caller passes the value, and 'TARGET_FUNCTION_INCOMING_ARG'
- should be defined in a similar fashion to tell the function being
- called where the arguments will arrive.
-
- 'TARGET_FUNCTION_INCOMING_ARG' can also return arbitrary address
- computation using hard register, which can be forced into a
- register, so that it can be used to pass special arguments.
-
- If 'TARGET_FUNCTION_INCOMING_ARG' is not defined,
- 'TARGET_FUNCTION_ARG' serves both purposes.
-
- -- Target Hook: bool TARGET_USE_PSEUDO_PIC_REG (void)
- This hook should return 1 in case pseudo register should be created
- for pic_offset_table_rtx during function expand.
-
- -- Target Hook: void TARGET_INIT_PIC_REG (void)
- Perform a target dependent initialization of pic_offset_table_rtx.
- This hook is called at the start of register allocation.
-
- -- Target Hook: int TARGET_ARG_PARTIAL_BYTES (cumulative_args_t CUM,
- const function_arg_info &ARG)
- This target hook returns the number of bytes at the beginning of an
- argument that must be put in registers. The value must be zero for
- arguments that are passed entirely in registers or that are
- entirely pushed on the stack.
-
- On some machines, certain arguments must be passed partially in
- registers and partially in memory. On these machines, typically
- the first few words of arguments are passed in registers, and the
- rest on the stack. If a multi-word argument (a 'double' or a
- structure) crosses that boundary, its first few words must be
- passed in registers and the rest must be pushed. This macro tells
- the compiler when this occurs, and how many bytes should go in
- registers.
-
- 'TARGET_FUNCTION_ARG' for these arguments should return the first
- register to be used by the caller for this argument; likewise
- 'TARGET_FUNCTION_INCOMING_ARG', for the called function.
-
- -- Target Hook: bool TARGET_PASS_BY_REFERENCE (cumulative_args_t CUM,
- const function_arg_info &ARG)
- This target hook should return 'true' if argument ARG at the
- position indicated by CUM should be passed by reference. This
- predicate is queried after target independent reasons for being
- passed by reference, such as 'TREE_ADDRESSABLE (ARG.type)'.
-
- If the hook returns true, a copy of that argument is made in memory
- and a pointer to the argument is passed instead of the argument
- itself. The pointer is passed in whatever way is appropriate for
- passing a pointer to that type.
-
- -- Target Hook: bool TARGET_CALLEE_COPIES (cumulative_args_t CUM, const
- function_arg_info &ARG)
- The function argument described by the parameters to this hook is
- known to be passed by reference. The hook should return true if
- the function argument should be copied by the callee instead of
- copied by the caller.
-
- For any argument for which the hook returns true, if it can be
- determined that the argument is not modified, then a copy need not
- be generated.
-
- The default version of this hook always returns false.
-
- -- Macro: CUMULATIVE_ARGS
- A C type for declaring a variable that is used as the first
- argument of 'TARGET_FUNCTION_ARG' and other related values. For
- some target machines, the type 'int' suffices and can hold the
- number of bytes of argument so far.
-
- There is no need to record in 'CUMULATIVE_ARGS' anything about the
- arguments that have been passed on the stack. The compiler has
- other variables to keep track of that. For target machines on
- which all arguments are passed on the stack, there is no need to
- store anything in 'CUMULATIVE_ARGS'; however, the data structure
- must exist and should not be empty, so use 'int'.
-
- -- Macro: OVERRIDE_ABI_FORMAT (FNDECL)
- If defined, this macro is called before generating any code for a
- function, but after the CFUN descriptor for the function has been
- created. The back end may use this macro to update CFUN to reflect
- an ABI other than that which would normally be used by default. If
- the compiler is generating code for a compiler-generated function,
- FNDECL may be 'NULL'.
-
- -- Macro: INIT_CUMULATIVE_ARGS (CUM, FNTYPE, LIBNAME, FNDECL,
- N_NAMED_ARGS)
- A C statement (sans semicolon) for initializing the variable CUM
- for the state at the beginning of the argument list. The variable
- has type 'CUMULATIVE_ARGS'. The value of FNTYPE is the tree node
- for the data type of the function which will receive the args, or 0
- if the args are to a compiler support library function. For direct
- calls that are not libcalls, FNDECL contain the declaration node of
- the function. FNDECL is also set when 'INIT_CUMULATIVE_ARGS' is
- used to find arguments for the function being compiled.
- N_NAMED_ARGS is set to the number of named arguments, including a
- structure return address if it is passed as a parameter, when
- making a call. When processing incoming arguments, N_NAMED_ARGS is
- set to -1.
-
- When processing a call to a compiler support library function,
- LIBNAME identifies which one. It is a 'symbol_ref' rtx which
- contains the name of the function, as a string. LIBNAME is 0 when
- an ordinary C function call is being processed. Thus, each time
- this macro is called, either LIBNAME or FNTYPE is nonzero, but
- never both of them at once.
-
- -- Macro: INIT_CUMULATIVE_LIBCALL_ARGS (CUM, MODE, LIBNAME)
- Like 'INIT_CUMULATIVE_ARGS' but only used for outgoing libcalls, it
- gets a 'MODE' argument instead of FNTYPE, that would be 'NULL'.
- INDIRECT would always be zero, too. If this macro is not defined,
- 'INIT_CUMULATIVE_ARGS (cum, NULL_RTX, libname, 0)' is used instead.
-
- -- Macro: INIT_CUMULATIVE_INCOMING_ARGS (CUM, FNTYPE, LIBNAME)
- Like 'INIT_CUMULATIVE_ARGS' but overrides it for the purposes of
- finding the arguments for the function being compiled. If this
- macro is undefined, 'INIT_CUMULATIVE_ARGS' is used instead.
-
- The value passed for LIBNAME is always 0, since library routines
- with special calling conventions are never compiled with GCC. The
- argument LIBNAME exists for symmetry with 'INIT_CUMULATIVE_ARGS'.
-
- -- Target Hook: void TARGET_FUNCTION_ARG_ADVANCE (cumulative_args_t CA,
- const function_arg_info &ARG)
- This hook updates the summarizer variable pointed to by CA to
- advance past argument ARG in the argument list. Once this is done,
- the variable CUM is suitable for analyzing the _following_ argument
- with 'TARGET_FUNCTION_ARG', etc.
-
- This hook need not do anything if the argument in question was
- passed on the stack. The compiler knows how to track the amount of
- stack space used for arguments without any special help.
-
- -- Target Hook: HOST_WIDE_INT TARGET_FUNCTION_ARG_OFFSET (machine_mode
- MODE, const_tree TYPE)
- This hook returns the number of bytes to add to the offset of an
- argument of type TYPE and mode MODE when passed in memory. This is
- needed for the SPU, which passes 'char' and 'short' arguments in
- the preferred slot that is in the middle of the quad word instead
- of starting at the top. The default implementation returns 0.
-
- -- Target Hook: pad_direction TARGET_FUNCTION_ARG_PADDING (machine_mode
- MODE, const_tree TYPE)
- This hook determines whether, and in which direction, to pad out an
- argument of mode MODE and type TYPE. It returns 'PAD_UPWARD' to
- insert padding above the argument, 'PAD_DOWNWARD' to insert padding
- below the argument, or 'PAD_NONE' to inhibit padding.
-
- The _amount_ of padding is not controlled by this hook, but by
- 'TARGET_FUNCTION_ARG_ROUND_BOUNDARY'. It is always just enough to
- reach the next multiple of that boundary.
-
- This hook has a default definition that is right for most systems.
- For little-endian machines, the default is to pad upward. For
- big-endian machines, the default is to pad downward for an argument
- of constant size shorter than an 'int', and upward otherwise.
-
- -- Macro: PAD_VARARGS_DOWN
- If defined, a C expression which determines whether the default
- implementation of va_arg will attempt to pad down before reading
- the next argument, if that argument is smaller than its aligned
- space as controlled by 'PARM_BOUNDARY'. If this macro is not
- defined, all such arguments are padded down if 'BYTES_BIG_ENDIAN'
- is true.
-
- -- Macro: BLOCK_REG_PADDING (MODE, TYPE, FIRST)
- Specify padding for the last element of a block move between
- registers and memory. FIRST is nonzero if this is the only
- element. Defining this macro allows better control of register
- function parameters on big-endian machines, without using
- 'PARALLEL' rtl. In particular, 'MUST_PASS_IN_STACK' need not test
- padding and mode of types in registers, as there is no longer a
- "wrong" part of a register; For example, a three byte aggregate may
- be passed in the high part of a register if so required.
-
- -- Target Hook: unsigned int TARGET_FUNCTION_ARG_BOUNDARY (machine_mode
- MODE, const_tree TYPE)
- This hook returns the alignment boundary, in bits, of an argument
- with the specified mode and type. The default hook returns
- 'PARM_BOUNDARY' for all arguments.
-
- -- Target Hook: unsigned int TARGET_FUNCTION_ARG_ROUND_BOUNDARY
- (machine_mode MODE, const_tree TYPE)
- Normally, the size of an argument is rounded up to 'PARM_BOUNDARY',
- which is the default value for this hook. You can define this hook
- to return a different value if an argument size must be rounded to
- a larger value.
-
- -- Macro: FUNCTION_ARG_REGNO_P (REGNO)
- A C expression that is nonzero if REGNO is the number of a hard
- register in which function arguments are sometimes passed. This
- does _not_ include implicit arguments such as the static chain and
- the structure-value address. On many machines, no registers can be
- used for this purpose since all function arguments are pushed on
- the stack.
-
- -- Target Hook: bool TARGET_SPLIT_COMPLEX_ARG (const_tree TYPE)
- This hook should return true if parameter of type TYPE are passed
- as two scalar parameters. By default, GCC will attempt to pack
- complex arguments into the target's word size. Some ABIs require
- complex arguments to be split and treated as their individual
- components. For example, on AIX64, complex floats should be passed
- in a pair of floating point registers, even though a complex float
- would fit in one 64-bit floating point register.
-
- The default value of this hook is 'NULL', which is treated as
- always false.
-
- -- Target Hook: tree TARGET_BUILD_BUILTIN_VA_LIST (void)
- This hook returns a type node for 'va_list' for the target. The
- default version of the hook returns 'void*'.
-
- -- Target Hook: int TARGET_ENUM_VA_LIST_P (int IDX, const char **PNAME,
- tree *PTREE)
- This target hook is used in function 'c_common_nodes_and_builtins'
- to iterate through the target specific builtin types for va_list.
- The variable IDX is used as iterator. PNAME has to be a pointer to
- a 'const char *' and PTREE a pointer to a 'tree' typed variable.
- The arguments PNAME and PTREE are used to store the result of this
- macro and are set to the name of the va_list builtin type and its
- internal type. If the return value of this macro is zero, then
- there is no more element. Otherwise the IDX should be increased
- for the next call of this macro to iterate through all types.
-
- -- Target Hook: tree TARGET_FN_ABI_VA_LIST (tree FNDECL)
- This hook returns the va_list type of the calling convention
- specified by FNDECL. The default version of this hook returns
- 'va_list_type_node'.
-
- -- Target Hook: tree TARGET_CANONICAL_VA_LIST_TYPE (tree TYPE)
- This hook returns the va_list type of the calling convention
- specified by the type of TYPE. If TYPE is not a valid va_list
- type, it returns 'NULL_TREE'.
-
- -- Target Hook: tree TARGET_GIMPLIFY_VA_ARG_EXPR (tree VALIST, tree
- TYPE, gimple_seq *PRE_P, gimple_seq *POST_P)
- This hook performs target-specific gimplification of 'VA_ARG_EXPR'.
- The first two parameters correspond to the arguments to 'va_arg';
- the latter two are as in 'gimplify.c:gimplify_expr'.
-
- -- Target Hook: bool TARGET_VALID_POINTER_MODE (scalar_int_mode MODE)
- Define this to return nonzero if the port can handle pointers with
- machine mode MODE. The default version of this hook returns true
- for both 'ptr_mode' and 'Pmode'.
-
- -- Target Hook: bool TARGET_REF_MAY_ALIAS_ERRNO (ao_ref *REF)
- Define this to return nonzero if the memory reference REF may alias
- with the system C library errno location. The default version of
- this hook assumes the system C library errno location is either a
- declaration of type int or accessed by dereferencing a pointer to
- int.
-
- -- Target Hook: machine_mode TARGET_TRANSLATE_MODE_ATTRIBUTE
- (machine_mode MODE)
- Define this hook if during mode attribute processing, the port
- should translate machine_mode MODE to another mode. For example,
- rs6000's 'KFmode', when it is the same as 'TFmode'.
-
- The default version of the hook returns that mode that was passed
- in.
-
- -- Target Hook: bool TARGET_SCALAR_MODE_SUPPORTED_P (scalar_mode MODE)
- Define this to return nonzero if the port is prepared to handle
- insns involving scalar mode MODE. For a scalar mode to be
- considered supported, all the basic arithmetic and comparisons must
- work.
-
- The default version of this hook returns true for any mode required
- to handle the basic C types (as defined by the port). Included
- here are the double-word arithmetic supported by the code in
- 'optabs.c'.
-
- -- Target Hook: bool TARGET_VECTOR_MODE_SUPPORTED_P (machine_mode MODE)
- Define this to return nonzero if the port is prepared to handle
- insns involving vector mode MODE. At the very least, it must have
- move patterns for this mode.
-
- -- Target Hook: bool TARGET_COMPATIBLE_VECTOR_TYPES_P (const_tree
- TYPE1, const_tree TYPE2)
- Return true if there is no target-specific reason for treating
- vector types TYPE1 and TYPE2 as distinct types. The caller has
- already checked for target-independent reasons, meaning that the
- types are known to have the same mode, to have the same number of
- elements, and to have what the caller considers to be compatible
- element types.
-
- The main reason for defining this hook is to reject pairs of types
- that are handled differently by the target's calling convention.
- For example, when a new N-bit vector architecture is added to a
- target, the target may want to handle normal N-bit 'VECTOR_TYPE'
- arguments and return values in the same way as before, to maintain
- backwards compatibility. However, it may also provide new,
- architecture-specific 'VECTOR_TYPE's that are passed and returned
- in a more efficient way. It is then important to maintain a
- distinction between the "normal" 'VECTOR_TYPE's and the new
- architecture-specific ones.
-
- The default implementation returns true, which is correct for most
- targets.
-
- -- Target Hook: opt_machine_mode TARGET_ARRAY_MODE (machine_mode MODE,
- unsigned HOST_WIDE_INT NELEMS)
- Return the mode that GCC should use for an array that has NELEMS
- elements, with each element having mode MODE. Return no mode if
- the target has no special requirements. In the latter case, GCC
- looks for an integer mode of the appropriate size if available and
- uses BLKmode otherwise. Usually the search for the integer mode is
- limited to 'MAX_FIXED_MODE_SIZE', but the
- 'TARGET_ARRAY_MODE_SUPPORTED_P' hook allows a larger mode to be
- used in specific cases.
-
- The main use of this hook is to specify that an array of vectors
- should also have a vector mode. The default implementation returns
- no mode.
-
- -- Target Hook: bool TARGET_ARRAY_MODE_SUPPORTED_P (machine_mode MODE,
- unsigned HOST_WIDE_INT NELEMS)
- Return true if GCC should try to use a scalar mode to store an
- array of NELEMS elements, given that each element has mode MODE.
- Returning true here overrides the usual 'MAX_FIXED_MODE' limit and
- allows GCC to use any defined integer mode.
-
- One use of this hook is to support vector load and store operations
- that operate on several homogeneous vectors. For example, ARM NEON
- has operations like:
-
- int8x8x3_t vld3_s8 (const int8_t *)
-
- where the return type is defined as:
-
- typedef struct int8x8x3_t
- {
- int8x8_t val[3];
- } int8x8x3_t;
-
- If this hook allows 'val' to have a scalar mode, then 'int8x8x3_t'
- can have the same mode. GCC can then store 'int8x8x3_t's in
- registers rather than forcing them onto the stack.
-
- -- Target Hook: bool TARGET_LIBGCC_FLOATING_MODE_SUPPORTED_P
- (scalar_float_mode MODE)
- Define this to return nonzero if libgcc provides support for the
- floating-point mode MODE, which is known to pass
- 'TARGET_SCALAR_MODE_SUPPORTED_P'. The default version of this hook
- returns true for all of 'SFmode', 'DFmode', 'XFmode' and 'TFmode',
- if such modes exist.
-
- -- Target Hook: opt_scalar_float_mode TARGET_FLOATN_MODE (int N, bool
- EXTENDED)
- Define this to return the machine mode to use for the type
- '_FloatN', if EXTENDED is false, or the type '_FloatNx', if
- EXTENDED is true. If such a type is not supported, return
- 'opt_scalar_float_mode ()'. The default version of this hook
- returns 'SFmode' for '_Float32', 'DFmode' for '_Float64' and
- '_Float32x' and 'TFmode' for '_Float128', if those modes exist and
- satisfy the requirements for those types and pass
- 'TARGET_SCALAR_MODE_SUPPORTED_P' and
- 'TARGET_LIBGCC_FLOATING_MODE_SUPPORTED_P'; for '_Float64x', it
- returns the first of 'XFmode' and 'TFmode' that exists and
- satisfies the same requirements; for other types, it returns
- 'opt_scalar_float_mode ()'. The hook is only called for values of
- N and EXTENDED that are valid according to ISO/IEC TS 18661-3:2015;
- that is, N is one of 32, 64, 128, or, if EXTENDED is false, 16 or
- greater than 128 and a multiple of 32.
-
- -- Target Hook: bool TARGET_FLOATN_BUILTIN_P (int FUNC)
- Define this to return true if the '_FloatN' and '_FloatNx' built-in
- functions should implicitly enable the built-in function without
- the '__builtin_' prefix in addition to the normal built-in function
- with the '__builtin_' prefix. The default is to only enable
- built-in functions without the '__builtin_' prefix for the GNU C
- langauge. In strict ANSI/ISO mode, the built-in function without
- the '__builtin_' prefix is not enabled. The argument 'FUNC' is the
- 'enum built_in_function' id of the function to be enabled.
-
- -- Target Hook: bool TARGET_SMALL_REGISTER_CLASSES_FOR_MODE_P
- (machine_mode MODE)
- Define this to return nonzero for machine modes for which the port
- has small register classes. If this target hook returns nonzero
- for a given MODE, the compiler will try to minimize the lifetime of
- registers in MODE. The hook may be called with 'VOIDmode' as
- argument. In this case, the hook is expected to return nonzero if
- it returns nonzero for any mode.
-
- On some machines, it is risky to let hard registers live across
- arbitrary insns. Typically, these machines have instructions that
- require values to be in specific registers (like an accumulator),
- and reload will fail if the required hard register is used for
- another purpose across such an insn.
-
- Passes before reload do not know which hard registers will be used
- in an instruction, but the machine modes of the registers set or
- used in the instruction are already known. And for some machines,
- register classes are small for, say, integer registers but not for
- floating point registers. For example, the AMD x86-64 architecture
- requires specific registers for the legacy x86 integer
- instructions, but there are many SSE registers for floating point
- operations. On such targets, a good strategy may be to return
- nonzero from this hook for 'INTEGRAL_MODE_P' machine modes but zero
- for the SSE register classes.
-
- The default version of this hook returns false for any mode. It is
- always safe to redefine this hook to return with a nonzero value.
- But if you unnecessarily define it, you will reduce the amount of
- optimizations that can be performed in some cases. If you do not
- define this hook to return a nonzero value when it is required, the
- compiler will run out of spill registers and print a fatal error
- message.
-
-
- File: gccint.info, Node: Scalar Return, Next: Aggregate Return, Prev: Register Arguments, Up: Stack and Calling
-
- 18.9.8 How Scalar Function Values Are Returned
- ----------------------------------------------
-
- This section discusses the macros that control returning scalars as
- values--values that can fit in registers.
-
- -- Target Hook: rtx TARGET_FUNCTION_VALUE (const_tree RET_TYPE,
- const_tree FN_DECL_OR_TYPE, bool OUTGOING)
-
- Define this to return an RTX representing the place where a
- function returns or receives a value of data type RET_TYPE, a tree
- node representing a data type. FN_DECL_OR_TYPE is a tree node
- representing 'FUNCTION_DECL' or 'FUNCTION_TYPE' of a function being
- called. If OUTGOING is false, the hook should compute the register
- in which the caller will see the return value. Otherwise, the hook
- should return an RTX representing the place where a function
- returns a value.
-
- On many machines, only 'TYPE_MODE (RET_TYPE)' is relevant.
- (Actually, on most machines, scalar values are returned in the same
- place regardless of mode.) The value of the expression is usually
- a 'reg' RTX for the hard register where the return value is stored.
- The value can also be a 'parallel' RTX, if the return value is in
- multiple places. See 'TARGET_FUNCTION_ARG' for an explanation of
- the 'parallel' form. Note that the callee will populate every
- location specified in the 'parallel', but if the first element of
- the 'parallel' contains the whole return value, callers will use
- that element as the canonical location and ignore the others. The
- m68k port uses this type of 'parallel' to return pointers in both
- '%a0' (the canonical location) and '%d0'.
-
- If 'TARGET_PROMOTE_FUNCTION_RETURN' returns true, you must apply
- the same promotion rules specified in 'PROMOTE_MODE' if VALTYPE is
- a scalar type.
-
- If the precise function being called is known, FUNC is a tree node
- ('FUNCTION_DECL') for it; otherwise, FUNC is a null pointer. This
- makes it possible to use a different value-returning convention for
- specific functions when all their calls are known.
-
- Some target machines have "register windows" so that the register
- in which a function returns its value is not the same as the one in
- which the caller sees the value. For such machines, you should
- return different RTX depending on OUTGOING.
-
- 'TARGET_FUNCTION_VALUE' is not used for return values with
- aggregate data types, because these are returned in another way.
- See 'TARGET_STRUCT_VALUE_RTX' and related macros, below.
-
- -- Macro: FUNCTION_VALUE (VALTYPE, FUNC)
- This macro has been deprecated. Use 'TARGET_FUNCTION_VALUE' for a
- new target instead.
-
- -- Macro: LIBCALL_VALUE (MODE)
- A C expression to create an RTX representing the place where a
- library function returns a value of mode MODE.
-
- Note that "library function" in this context means a compiler
- support routine, used to perform arithmetic, whose name is known
- specially by the compiler and was not mentioned in the C code being
- compiled.
-
- -- Target Hook: rtx TARGET_LIBCALL_VALUE (machine_mode MODE, const_rtx
- FUN)
- Define this hook if the back-end needs to know the name of the
- libcall function in order to determine where the result should be
- returned.
-
- The mode of the result is given by MODE and the name of the called
- library function is given by FUN. The hook should return an RTX
- representing the place where the library function result will be
- returned.
-
- If this hook is not defined, then LIBCALL_VALUE will be used.
-
- -- Macro: FUNCTION_VALUE_REGNO_P (REGNO)
- A C expression that is nonzero if REGNO is the number of a hard
- register in which the values of called function may come back.
-
- A register whose use for returning values is limited to serving as
- the second of a pair (for a value of type 'double', say) need not
- be recognized by this macro. So for most machines, this definition
- suffices:
-
- #define FUNCTION_VALUE_REGNO_P(N) ((N) == 0)
-
- If the machine has register windows, so that the caller and the
- called function use different registers for the return value, this
- macro should recognize only the caller's register numbers.
-
- This macro has been deprecated. Use
- 'TARGET_FUNCTION_VALUE_REGNO_P' for a new target instead.
-
- -- Target Hook: bool TARGET_FUNCTION_VALUE_REGNO_P (const unsigned int
- REGNO)
- A target hook that return 'true' if REGNO is the number of a hard
- register in which the values of called function may come back.
-
- A register whose use for returning values is limited to serving as
- the second of a pair (for a value of type 'double', say) need not
- be recognized by this target hook.
-
- If the machine has register windows, so that the caller and the
- called function use different registers for the return value, this
- target hook should recognize only the caller's register numbers.
-
- If this hook is not defined, then FUNCTION_VALUE_REGNO_P will be
- used.
-
- -- Macro: APPLY_RESULT_SIZE
- Define this macro if 'untyped_call' and 'untyped_return' need more
- space than is implied by 'FUNCTION_VALUE_REGNO_P' for saving and
- restoring an arbitrary return value.
-
- -- Target Hook: bool TARGET_OMIT_STRUCT_RETURN_REG
- Normally, when a function returns a structure by memory, the
- address is passed as an invisible pointer argument, but the
- compiler also arranges to return the address from the function like
- it would a normal pointer return value. Define this to true if
- that behavior is undesirable on your target.
-
- -- Target Hook: bool TARGET_RETURN_IN_MSB (const_tree TYPE)
- This hook should return true if values of type TYPE are returned at
- the most significant end of a register (in other words, if they are
- padded at the least significant end). You can assume that TYPE is
- returned in a register; the caller is required to check this.
-
- Note that the register provided by 'TARGET_FUNCTION_VALUE' must be
- able to hold the complete return value. For example, if a 1-, 2-
- or 3-byte structure is returned at the most significant end of a
- 4-byte register, 'TARGET_FUNCTION_VALUE' should provide an 'SImode'
- rtx.
-
-
- File: gccint.info, Node: Aggregate Return, Next: Caller Saves, Prev: Scalar Return, Up: Stack and Calling
-
- 18.9.9 How Large Values Are Returned
- ------------------------------------
-
- When a function value's mode is 'BLKmode' (and in some other cases), the
- value is not returned according to 'TARGET_FUNCTION_VALUE' (*note Scalar
- Return::). Instead, the caller passes the address of a block of memory
- in which the value should be stored. This address is called the
- "structure value address".
-
- This section describes how to control returning structure values in
- memory.
-
- -- Target Hook: bool TARGET_RETURN_IN_MEMORY (const_tree TYPE,
- const_tree FNTYPE)
- This target hook should return a nonzero value to say to return the
- function value in memory, just as large structures are always
- returned. Here TYPE will be the data type of the value, and FNTYPE
- will be the type of the function doing the returning, or 'NULL' for
- libcalls.
-
- Note that values of mode 'BLKmode' must be explicitly handled by
- this function. Also, the option '-fpcc-struct-return' takes effect
- regardless of this macro. On most systems, it is possible to leave
- the hook undefined; this causes a default definition to be used,
- whose value is the constant 1 for 'BLKmode' values, and 0
- otherwise.
-
- Do not use this hook to indicate that structures and unions should
- always be returned in memory. You should instead use
- 'DEFAULT_PCC_STRUCT_RETURN' to indicate this.
-
- -- Macro: DEFAULT_PCC_STRUCT_RETURN
- Define this macro to be 1 if all structure and union return values
- must be in memory. Since this results in slower code, this should
- be defined only if needed for compatibility with other compilers or
- with an ABI. If you define this macro to be 0, then the
- conventions used for structure and union return values are decided
- by the 'TARGET_RETURN_IN_MEMORY' target hook.
-
- If not defined, this defaults to the value 1.
-
- -- Target Hook: rtx TARGET_STRUCT_VALUE_RTX (tree FNDECL, int INCOMING)
- This target hook should return the location of the structure value
- address (normally a 'mem' or 'reg'), or 0 if the address is passed
- as an "invisible" first argument. Note that FNDECL may be 'NULL',
- for libcalls. You do not need to define this target hook if the
- address is always passed as an "invisible" first argument.
-
- On some architectures the place where the structure value address
- is found by the called function is not the same place that the
- caller put it. This can be due to register windows, or it could be
- because the function prologue moves it to a different place.
- INCOMING is '1' or '2' when the location is needed in the context
- of the called function, and '0' in the context of the caller.
-
- If INCOMING is nonzero and the address is to be found on the stack,
- return a 'mem' which refers to the frame pointer. If INCOMING is
- '2', the result is being used to fetch the structure value address
- at the beginning of a function. If you need to emit adjusting
- code, you should do it at this point.
-
- -- Macro: PCC_STATIC_STRUCT_RETURN
- Define this macro if the usual system convention on the target
- machine for returning structures and unions is for the called
- function to return the address of a static variable containing the
- value.
-
- Do not define this if the usual system convention is for the caller
- to pass an address to the subroutine.
-
- This macro has effect in '-fpcc-struct-return' mode, but it does
- nothing when you use '-freg-struct-return' mode.
-
- -- Target Hook: fixed_size_mode TARGET_GET_RAW_RESULT_MODE (int REGNO)
- This target hook returns the mode to be used when accessing raw
- return registers in '__builtin_return'. Define this macro if the
- value in REG_RAW_MODE is not correct.
-
- -- Target Hook: fixed_size_mode TARGET_GET_RAW_ARG_MODE (int REGNO)
- This target hook returns the mode to be used when accessing raw
- argument registers in '__builtin_apply_args'. Define this macro if
- the value in REG_RAW_MODE is not correct.
-
- -- Target Hook: bool TARGET_EMPTY_RECORD_P (const_tree TYPE)
- This target hook returns true if the type is an empty record. The
- default is to return 'false'.
-
- -- Target Hook: void TARGET_WARN_PARAMETER_PASSING_ABI
- (cumulative_args_t CA, tree TYPE)
- This target hook warns about the change in empty class parameter
- passing ABI.
-
-
- File: gccint.info, Node: Caller Saves, Next: Function Entry, Prev: Aggregate Return, Up: Stack and Calling
-
- 18.9.10 Caller-Saves Register Allocation
- ----------------------------------------
-
- If you enable it, GCC can save registers around function calls. This
- makes it possible to use call-clobbered registers to hold variables that
- must live across calls.
-
- -- Macro: HARD_REGNO_CALLER_SAVE_MODE (REGNO, NREGS)
- A C expression specifying which mode is required for saving NREGS
- of a pseudo-register in call-clobbered hard register REGNO. If
- REGNO is unsuitable for caller save, 'VOIDmode' should be returned.
- For most machines this macro need not be defined since GCC will
- select the smallest suitable mode.
-
-
- File: gccint.info, Node: Function Entry, Next: Profiling, Prev: Caller Saves, Up: Stack and Calling
-
- 18.9.11 Function Entry and Exit
- -------------------------------
-
- This section describes the macros that output function entry
- ("prologue") and exit ("epilogue") code.
-
- -- Target Hook: void TARGET_ASM_PRINT_PATCHABLE_FUNCTION_ENTRY (FILE
- *FILE, unsigned HOST_WIDE_INT PATCH_AREA_SIZE, bool RECORD_P)
- Generate a patchable area at the function start, consisting of
- PATCH_AREA_SIZE NOP instructions. If the target supports named
- sections and if RECORD_P is true, insert a pointer to the current
- location in the table of patchable functions. The default
- implementation of the hook places the table of pointers in the
- special section named '__patchable_function_entries'.
-
- -- Target Hook: void TARGET_ASM_FUNCTION_PROLOGUE (FILE *FILE)
- If defined, a function that outputs the assembler code for entry to
- a function. The prologue is responsible for setting up the stack
- frame, initializing the frame pointer register, saving registers
- that must be saved, and allocating SIZE additional bytes of storage
- for the local variables. FILE is a stdio stream to which the
- assembler code should be output.
-
- The label for the beginning of the function need not be output by
- this macro. That has already been done when the macro is run.
-
- To determine which registers to save, the macro can refer to the
- array 'regs_ever_live': element R is nonzero if hard register R is
- used anywhere within the function. This implies the function
- prologue should save register R, provided it is not one of the
- call-used registers. ('TARGET_ASM_FUNCTION_EPILOGUE' must likewise
- use 'regs_ever_live'.)
-
- On machines that have "register windows", the function entry code
- does not save on the stack the registers that are in the windows,
- even if they are supposed to be preserved by function calls;
- instead it takes appropriate steps to "push" the register stack, if
- any non-call-used registers are used in the function.
-
- On machines where functions may or may not have frame-pointers, the
- function entry code must vary accordingly; it must set up the frame
- pointer if one is wanted, and not otherwise. To determine whether
- a frame pointer is in wanted, the macro can refer to the variable
- 'frame_pointer_needed'. The variable's value will be 1 at run time
- in a function that needs a frame pointer. *Note Elimination::.
-
- The function entry code is responsible for allocating any stack
- space required for the function. This stack space consists of the
- regions listed below. In most cases, these regions are allocated
- in the order listed, with the last listed region closest to the top
- of the stack (the lowest address if 'STACK_GROWS_DOWNWARD' is
- defined, and the highest address if it is not defined). You can
- use a different order for a machine if doing so is more convenient
- or required for compatibility reasons. Except in cases where
- required by standard or by a debugger, there is no reason why the
- stack layout used by GCC need agree with that used by other
- compilers for a machine.
-
- -- Target Hook: void TARGET_ASM_FUNCTION_END_PROLOGUE (FILE *FILE)
- If defined, a function that outputs assembler code at the end of a
- prologue. This should be used when the function prologue is being
- emitted as RTL, and you have some extra assembler that needs to be
- emitted. *Note prologue instruction pattern::.
-
- -- Target Hook: void TARGET_ASM_FUNCTION_BEGIN_EPILOGUE (FILE *FILE)
- If defined, a function that outputs assembler code at the start of
- an epilogue. This should be used when the function epilogue is
- being emitted as RTL, and you have some extra assembler that needs
- to be emitted. *Note epilogue instruction pattern::.
-
- -- Target Hook: void TARGET_ASM_FUNCTION_EPILOGUE (FILE *FILE)
- If defined, a function that outputs the assembler code for exit
- from a function. The epilogue is responsible for restoring the
- saved registers and stack pointer to their values when the function
- was called, and returning control to the caller. This macro takes
- the same argument as the macro 'TARGET_ASM_FUNCTION_PROLOGUE', and
- the registers to restore are determined from 'regs_ever_live' and
- 'CALL_USED_REGISTERS' in the same way.
-
- On some machines, there is a single instruction that does all the
- work of returning from the function. On these machines, give that
- instruction the name 'return' and do not define the macro
- 'TARGET_ASM_FUNCTION_EPILOGUE' at all.
-
- Do not define a pattern named 'return' if you want the
- 'TARGET_ASM_FUNCTION_EPILOGUE' to be used. If you want the target
- switches to control whether return instructions or epilogues are
- used, define a 'return' pattern with a validity condition that
- tests the target switches appropriately. If the 'return' pattern's
- validity condition is false, epilogues will be used.
-
- On machines where functions may or may not have frame-pointers, the
- function exit code must vary accordingly. Sometimes the code for
- these two cases is completely different. To determine whether a
- frame pointer is wanted, the macro can refer to the variable
- 'frame_pointer_needed'. The variable's value will be 1 when
- compiling a function that needs a frame pointer.
-
- Normally, 'TARGET_ASM_FUNCTION_PROLOGUE' and
- 'TARGET_ASM_FUNCTION_EPILOGUE' must treat leaf functions specially.
- The C variable 'current_function_is_leaf' is nonzero for such a
- function. *Note Leaf Functions::.
-
- On some machines, some functions pop their arguments on exit while
- others leave that for the caller to do. For example, the 68020
- when given '-mrtd' pops arguments in functions that take a fixed
- number of arguments.
-
- Your definition of the macro 'RETURN_POPS_ARGS' decides which
- functions pop their own arguments. 'TARGET_ASM_FUNCTION_EPILOGUE'
- needs to know what was decided. The number of bytes of the current
- function's arguments that this function should pop is available in
- 'crtl->args.pops_args'. *Note Scalar Return::.
-
- * A region of 'crtl->args.pretend_args_size' bytes of uninitialized
- space just underneath the first argument arriving on the stack.
- (This may not be at the very start of the allocated stack region if
- the calling sequence has pushed anything else since pushing the
- stack arguments. But usually, on such machines, nothing else has
- been pushed yet, because the function prologue itself does all the
- pushing.) This region is used on machines where an argument may be
- passed partly in registers and partly in memory, and, in some cases
- to support the features in '<stdarg.h>'.
-
- * An area of memory used to save certain registers used by the
- function. The size of this area, which may also include space for
- such things as the return address and pointers to previous stack
- frames, is machine-specific and usually depends on which registers
- have been used in the function. Machines with register windows
- often do not require a save area.
-
- * A region of at least SIZE bytes, possibly rounded up to an
- allocation boundary, to contain the local variables of the
- function. On some machines, this region and the save area may
- occur in the opposite order, with the save area closer to the top
- of the stack.
-
- * Optionally, when 'ACCUMULATE_OUTGOING_ARGS' is defined, a region of
- 'crtl->outgoing_args_size' bytes to be used for outgoing argument
- lists of the function. *Note Stack Arguments::.
-
- -- Macro: EXIT_IGNORE_STACK
- Define this macro as a C expression that is nonzero if the return
- instruction or the function epilogue ignores the value of the stack
- pointer; in other words, if it is safe to delete an instruction to
- adjust the stack pointer before a return from the function. The
- default is 0.
-
- Note that this macro's value is relevant only for functions for
- which frame pointers are maintained. It is never safe to delete a
- final stack adjustment in a function that has no frame pointer, and
- the compiler knows this regardless of 'EXIT_IGNORE_STACK'.
-
- -- Macro: EPILOGUE_USES (REGNO)
- Define this macro as a C expression that is nonzero for registers
- that are used by the epilogue or the 'return' pattern. The stack
- and frame pointer registers are already assumed to be used as
- needed.
-
- -- Macro: EH_USES (REGNO)
- Define this macro as a C expression that is nonzero for registers
- that are used by the exception handling mechanism, and so should be
- considered live on entry to an exception edge.
-
- -- Target Hook: void TARGET_ASM_OUTPUT_MI_THUNK (FILE *FILE, tree
- THUNK_FNDECL, HOST_WIDE_INT DELTA, HOST_WIDE_INT VCALL_OFFSET,
- tree FUNCTION)
- A function that outputs the assembler code for a thunk function,
- used to implement C++ virtual function calls with multiple
- inheritance. The thunk acts as a wrapper around a virtual
- function, adjusting the implicit object parameter before handing
- control off to the real function.
-
- First, emit code to add the integer DELTA to the location that
- contains the incoming first argument. Assume that this argument
- contains a pointer, and is the one used to pass the 'this' pointer
- in C++. This is the incoming argument _before_ the function
- prologue, e.g. '%o0' on a sparc. The addition must preserve the
- values of all other incoming arguments.
-
- Then, if VCALL_OFFSET is nonzero, an additional adjustment should
- be made after adding 'delta'. In particular, if P is the adjusted
- pointer, the following adjustment should be made:
-
- p += (*((ptrdiff_t **)p))[vcall_offset/sizeof(ptrdiff_t)]
-
- After the additions, emit code to jump to FUNCTION, which is a
- 'FUNCTION_DECL'. This is a direct pure jump, not a call, and does
- not touch the return address. Hence returning from FUNCTION will
- return to whoever called the current 'thunk'.
-
- The effect must be as if FUNCTION had been called directly with the
- adjusted first argument. This macro is responsible for emitting
- all of the code for a thunk function;
- 'TARGET_ASM_FUNCTION_PROLOGUE' and 'TARGET_ASM_FUNCTION_EPILOGUE'
- are not invoked.
-
- The THUNK_FNDECL is redundant. (DELTA and FUNCTION have already
- been extracted from it.) It might possibly be useful on some
- targets, but probably not.
-
- If you do not define this macro, the target-independent code in the
- C++ front end will generate a less efficient heavyweight thunk that
- calls FUNCTION instead of jumping to it. The generic approach does
- not support varargs.
-
- -- Target Hook: bool TARGET_ASM_CAN_OUTPUT_MI_THUNK (const_tree
- THUNK_FNDECL, HOST_WIDE_INT DELTA, HOST_WIDE_INT VCALL_OFFSET,
- const_tree FUNCTION)
- A function that returns true if TARGET_ASM_OUTPUT_MI_THUNK would be
- able to output the assembler code for the thunk function specified
- by the arguments it is passed, and false otherwise. In the latter
- case, the generic approach will be used by the C++ front end, with
- the limitations previously exposed.
-
-
- File: gccint.info, Node: Profiling, Next: Tail Calls, Prev: Function Entry, Up: Stack and Calling
-
- 18.9.12 Generating Code for Profiling
- -------------------------------------
-
- These macros will help you generate code for profiling.
-
- -- Macro: FUNCTION_PROFILER (FILE, LABELNO)
- A C statement or compound statement to output to FILE some
- assembler code to call the profiling subroutine 'mcount'.
-
- The details of how 'mcount' expects to be called are determined by
- your operating system environment, not by GCC. To figure them out,
- compile a small program for profiling using the system's installed
- C compiler and look at the assembler code that results.
-
- Older implementations of 'mcount' expect the address of a counter
- variable to be loaded into some register. The name of this
- variable is 'LP' followed by the number LABELNO, so you would
- generate the name using 'LP%d' in a 'fprintf'.
-
- -- Macro: PROFILE_HOOK
- A C statement or compound statement to output to FILE some assembly
- code to call the profiling subroutine 'mcount' even the target does
- not support profiling.
-
- -- Macro: NO_PROFILE_COUNTERS
- Define this macro to be an expression with a nonzero value if the
- 'mcount' subroutine on your system does not need a counter variable
- allocated for each function. This is true for almost all modern
- implementations. If you define this macro, you must not use the
- LABELNO argument to 'FUNCTION_PROFILER'.
-
- -- Macro: PROFILE_BEFORE_PROLOGUE
- Define this macro if the code for function profiling should come
- before the function prologue. Normally, the profiling code comes
- after.
-
- -- Target Hook: bool TARGET_KEEP_LEAF_WHEN_PROFILED (void)
- This target hook returns true if the target wants the leaf flag for
- the current function to stay true even if it calls mcount. This
- might make sense for targets using the leaf flag only to determine
- whether a stack frame needs to be generated or not and for which
- the call to mcount is generated before the function prologue.
-
-
- File: gccint.info, Node: Tail Calls, Next: Shrink-wrapping separate components, Prev: Profiling, Up: Stack and Calling
-
- 18.9.13 Permitting tail calls
- -----------------------------
-
- -- Target Hook: bool TARGET_FUNCTION_OK_FOR_SIBCALL (tree DECL, tree
- EXP)
- True if it is OK to do sibling call optimization for the specified
- call expression EXP. DECL will be the called function, or 'NULL'
- if this is an indirect call.
-
- It is not uncommon for limitations of calling conventions to
- prevent tail calls to functions outside the current unit of
- translation, or during PIC compilation. The hook is used to
- enforce these restrictions, as the 'sibcall' md pattern cannot
- fail, or fall over to a "normal" call. The criteria for successful
- sibling call optimization may vary greatly between different
- architectures.
-
- -- Target Hook: void TARGET_EXTRA_LIVE_ON_ENTRY (bitmap REGS)
- Add any hard registers to REGS that are live on entry to the
- function. This hook only needs to be defined to provide registers
- that cannot be found by examination of FUNCTION_ARG_REGNO_P, the
- callee saved registers, STATIC_CHAIN_INCOMING_REGNUM,
- STATIC_CHAIN_REGNUM, TARGET_STRUCT_VALUE_RTX, FRAME_POINTER_REGNUM,
- EH_USES, FRAME_POINTER_REGNUM, ARG_POINTER_REGNUM, and the
- PIC_OFFSET_TABLE_REGNUM.
-
- -- Target Hook: void TARGET_SET_UP_BY_PROLOGUE (struct
- hard_reg_set_container *)
- This hook should add additional registers that are computed by the
- prologue to the hard regset for shrink-wrapping optimization
- purposes.
-
- -- Target Hook: bool TARGET_WARN_FUNC_RETURN (tree)
- True if a function's return statements should be checked for
- matching the function's return type. This includes checking for
- falling off the end of a non-void function. Return false if no
- such check should be made.
-
-
- File: gccint.info, Node: Shrink-wrapping separate components, Next: Stack Smashing Protection, Prev: Tail Calls, Up: Stack and Calling
-
- 18.9.14 Shrink-wrapping separate components
- -------------------------------------------
-
- The prologue may perform a variety of target dependent tasks such as
- saving callee-saved registers, saving the return address, aligning the
- stack, creating a stack frame, initializing the PIC register, setting up
- the static chain, etc.
-
- On some targets some of these tasks may be independent of others and
- thus may be shrink-wrapped separately. These independent tasks are
- referred to as components and are handled generically by the target
- independent parts of GCC.
-
- Using the following hooks those prologue or epilogue components can be
- shrink-wrapped separately, so that the initialization (and possibly
- teardown) those components do is not done as frequently on execution
- paths where this would unnecessary.
-
- What exactly those components are is up to the target code; the generic
- code treats them abstractly, as a bit in an 'sbitmap'. These 'sbitmap's
- are allocated by the 'shrink_wrap.get_separate_components' and
- 'shrink_wrap.components_for_bb' hooks, and deallocated by the generic
- code.
-
- -- Target Hook: sbitmap TARGET_SHRINK_WRAP_GET_SEPARATE_COMPONENTS
- (void)
- This hook should return an 'sbitmap' with the bits set for those
- components that can be separately shrink-wrapped in the current
- function. Return 'NULL' if the current function should not get any
- separate shrink-wrapping. Don't define this hook if it would
- always return 'NULL'. If it is defined, the other hooks in this
- group have to be defined as well.
-
- -- Target Hook: sbitmap TARGET_SHRINK_WRAP_COMPONENTS_FOR_BB
- (basic_block)
- This hook should return an 'sbitmap' with the bits set for those
- components where either the prologue component has to be executed
- before the 'basic_block', or the epilogue component after it, or
- both.
-
- -- Target Hook: void TARGET_SHRINK_WRAP_DISQUALIFY_COMPONENTS (sbitmap
- COMPONENTS, edge E, sbitmap EDGE_COMPONENTS, bool IS_PROLOGUE)
- This hook should clear the bits in the COMPONENTS bitmap for those
- components in EDGE_COMPONENTS that the target cannot handle on edge
- E, where IS_PROLOGUE says if this is for a prologue or an epilogue
- instead.
-
- -- Target Hook: void TARGET_SHRINK_WRAP_EMIT_PROLOGUE_COMPONENTS
- (sbitmap)
- Emit prologue insns for the components indicated by the parameter.
-
- -- Target Hook: void TARGET_SHRINK_WRAP_EMIT_EPILOGUE_COMPONENTS
- (sbitmap)
- Emit epilogue insns for the components indicated by the parameter.
-
- -- Target Hook: void TARGET_SHRINK_WRAP_SET_HANDLED_COMPONENTS
- (sbitmap)
- Mark the components in the parameter as handled, so that the
- 'prologue' and 'epilogue' named patterns know to ignore those
- components. The target code should not hang on to the 'sbitmap',
- it will be deleted after this call.
-
-
- File: gccint.info, Node: Stack Smashing Protection, Next: Miscellaneous Register Hooks, Prev: Shrink-wrapping separate components, Up: Stack and Calling
-
- 18.9.15 Stack smashing protection
- ---------------------------------
-
- -- Target Hook: tree TARGET_STACK_PROTECT_GUARD (void)
- This hook returns a 'DECL' node for the external variable to use
- for the stack protection guard. This variable is initialized by
- the runtime to some random value and is used to initialize the
- guard value that is placed at the top of the local stack frame.
- The type of this variable must be 'ptr_type_node'.
-
- The default version of this hook creates a variable called
- '__stack_chk_guard', which is normally defined in 'libgcc2.c'.
-
- -- Target Hook: tree TARGET_STACK_PROTECT_FAIL (void)
- This hook returns a 'CALL_EXPR' that alerts the runtime that the
- stack protect guard variable has been modified. This expression
- should involve a call to a 'noreturn' function.
-
- The default version of this hook invokes a function called
- '__stack_chk_fail', taking no arguments. This function is normally
- defined in 'libgcc2.c'.
-
- -- Target Hook: bool TARGET_STACK_PROTECT_RUNTIME_ENABLED_P (void)
- Returns true if the target wants GCC's default stack protect
- runtime support, otherwise return false. The default
- implementation always returns true.
-
- -- Common Target Hook: bool TARGET_SUPPORTS_SPLIT_STACK (bool REPORT,
- struct gcc_options *OPTS)
- Whether this target supports splitting the stack when the options
- described in OPTS have been passed. This is called after options
- have been parsed, so the target may reject splitting the stack in
- some configurations. The default version of this hook returns
- false. If REPORT is true, this function may issue a warning or
- error; if REPORT is false, it must simply return a value
-
- -- Common Target Hook: vec<const char *> TARGET_GET_VALID_OPTION_VALUES
- (int OPTION_CODE, const char *PREFIX)
- The hook is used for options that have a non-trivial list of
- possible option values. OPTION_CODE is option code of opt_code
- enum type. PREFIX is used for bash completion and allows an
- implementation to return more specific completion based on the
- prefix. All string values should be allocated from heap memory and
- consumers should release them. The result will be pruned to cases
- with PREFIX if not NULL.
-
-
- File: gccint.info, Node: Miscellaneous Register Hooks, Prev: Stack Smashing Protection, Up: Stack and Calling
-
- 18.9.16 Miscellaneous register hooks
- ------------------------------------
-
- -- Target Hook: bool TARGET_CALL_FUSAGE_CONTAINS_NON_CALLEE_CLOBBERS
- Set to true if each call that binds to a local definition
- explicitly clobbers or sets all non-fixed registers modified by
- performing the call. That is, by the call pattern itself, or by
- code that might be inserted by the linker (e.g. stubs, veneers,
- branch islands), but not including those modifiable by the callee.
- The affected registers may be mentioned explicitly in the call
- pattern, or included as clobbers in CALL_INSN_FUNCTION_USAGE. The
- default version of this hook is set to false. The purpose of this
- hook is to enable the fipa-ra optimization.
-
-
- File: gccint.info, Node: Varargs, Next: Trampolines, Prev: Stack and Calling, Up: Target Macros
-
- 18.10 Implementing the Varargs Macros
- =====================================
-
- GCC comes with an implementation of '<varargs.h>' and '<stdarg.h>' that
- work without change on machines that pass arguments on the stack. Other
- machines require their own implementations of varargs, and the two
- machine independent header files must have conditionals to include it.
-
- ISO '<stdarg.h>' differs from traditional '<varargs.h>' mainly in the
- calling convention for 'va_start'. The traditional implementation takes
- just one argument, which is the variable in which to store the argument
- pointer. The ISO implementation of 'va_start' takes an additional
- second argument. The user is supposed to write the last named argument
- of the function here.
-
- However, 'va_start' should not use this argument. The way to find the
- end of the named arguments is with the built-in functions described
- below.
-
- -- Macro: __builtin_saveregs ()
- Use this built-in function to save the argument registers in memory
- so that the varargs mechanism can access them. Both ISO and
- traditional versions of 'va_start' must use '__builtin_saveregs',
- unless you use 'TARGET_SETUP_INCOMING_VARARGS' (see below) instead.
-
- On some machines, '__builtin_saveregs' is open-coded under the
- control of the target hook 'TARGET_EXPAND_BUILTIN_SAVEREGS'. On
- other machines, it calls a routine written in assembler language,
- found in 'libgcc2.c'.
-
- Code generated for the call to '__builtin_saveregs' appears at the
- beginning of the function, as opposed to where the call to
- '__builtin_saveregs' is written, regardless of what the code is.
- This is because the registers must be saved before the function
- starts to use them for its own purposes.
-
- -- Macro: __builtin_next_arg (LASTARG)
- This builtin returns the address of the first anonymous stack
- argument, as type 'void *'. If 'ARGS_GROW_DOWNWARD', it returns
- the address of the location above the first anonymous stack
- argument. Use it in 'va_start' to initialize the pointer for
- fetching arguments from the stack. Also use it in 'va_start' to
- verify that the second parameter LASTARG is the last named argument
- of the current function.
-
- -- Macro: __builtin_classify_type (OBJECT)
- Since each machine has its own conventions for which data types are
- passed in which kind of register, your implementation of 'va_arg'
- has to embody these conventions. The easiest way to categorize the
- specified data type is to use '__builtin_classify_type' together
- with 'sizeof' and '__alignof__'.
-
- '__builtin_classify_type' ignores the value of OBJECT, considering
- only its data type. It returns an integer describing what kind of
- type that is--integer, floating, pointer, structure, and so on.
-
- The file 'typeclass.h' defines an enumeration that you can use to
- interpret the values of '__builtin_classify_type'.
-
- These machine description macros help implement varargs:
-
- -- Target Hook: rtx TARGET_EXPAND_BUILTIN_SAVEREGS (void)
- If defined, this hook produces the machine-specific code for a call
- to '__builtin_saveregs'. This code will be moved to the very
- beginning of the function, before any parameter access are made.
- The return value of this function should be an RTX that contains
- the value to use as the return of '__builtin_saveregs'.
-
- -- Target Hook: void TARGET_SETUP_INCOMING_VARARGS (cumulative_args_t
- ARGS_SO_FAR, const function_arg_info &ARG, int
- *PRETEND_ARGS_SIZE, int SECOND_TIME)
- This target hook offers an alternative to using
- '__builtin_saveregs' and defining the hook
- 'TARGET_EXPAND_BUILTIN_SAVEREGS'. Use it to store the anonymous
- register arguments into the stack so that all the arguments appear
- to have been passed consecutively on the stack. Once this is done,
- you can use the standard implementation of varargs that works for
- machines that pass all their arguments on the stack.
-
- The argument ARGS_SO_FAR points to the 'CUMULATIVE_ARGS' data
- structure, containing the values that are obtained after processing
- the named arguments. The argument ARG describes the last of these
- named arguments.
-
- The target hook should do two things: first, push onto the stack
- all the argument registers _not_ used for the named arguments, and
- second, store the size of the data thus pushed into the
- 'int'-valued variable pointed to by PRETEND_ARGS_SIZE. The value
- that you store here will serve as additional offset for setting up
- the stack frame.
-
- Because you must generate code to push the anonymous arguments at
- compile time without knowing their data types,
- 'TARGET_SETUP_INCOMING_VARARGS' is only useful on machines that
- have just a single category of argument register and use it
- uniformly for all data types.
-
- If the argument SECOND_TIME is nonzero, it means that the arguments
- of the function are being analyzed for the second time. This
- happens for an inline function, which is not actually compiled
- until the end of the source file. The hook
- 'TARGET_SETUP_INCOMING_VARARGS' should not generate any
- instructions in this case.
-
- -- Target Hook: bool TARGET_STRICT_ARGUMENT_NAMING (cumulative_args_t
- CA)
- Define this hook to return 'true' if the location where a function
- argument is passed depends on whether or not it is a named
- argument.
-
- This hook controls how the NAMED argument to 'TARGET_FUNCTION_ARG'
- is set for varargs and stdarg functions. If this hook returns
- 'true', the NAMED argument is always true for named arguments, and
- false for unnamed arguments. If it returns 'false', but
- 'TARGET_PRETEND_OUTGOING_VARARGS_NAMED' returns 'true', then all
- arguments are treated as named. Otherwise, all named arguments
- except the last are treated as named.
-
- You need not define this hook if it always returns 'false'.
-
- -- Target Hook: void TARGET_CALL_ARGS (rtx, TREE)
- While generating RTL for a function call, this target hook is
- invoked once for each argument passed to the function, either a
- register returned by 'TARGET_FUNCTION_ARG' or a memory location.
- It is called just before the point where argument registers are
- stored. The type of the function to be called is also passed as
- the second argument; it is 'NULL_TREE' for libcalls. The
- 'TARGET_END_CALL_ARGS' hook is invoked just after the code to copy
- the return reg has been emitted. This functionality can be used to
- perform special setup of call argument registers if a target needs
- it. For functions without arguments, the hook is called once with
- 'pc_rtx' passed instead of an argument register. Most ports do not
- need to implement anything for this hook.
-
- -- Target Hook: void TARGET_END_CALL_ARGS (void)
- This target hook is invoked while generating RTL for a function
- call, just after the point where the return reg is copied into a
- pseudo. It signals that all the call argument and return registers
- for the just emitted call are now no longer in use. Most ports do
- not need to implement anything for this hook.
-
- -- Target Hook: bool TARGET_PRETEND_OUTGOING_VARARGS_NAMED
- (cumulative_args_t CA)
- If you need to conditionally change ABIs so that one works with
- 'TARGET_SETUP_INCOMING_VARARGS', but the other works like neither
- 'TARGET_SETUP_INCOMING_VARARGS' nor 'TARGET_STRICT_ARGUMENT_NAMING'
- was defined, then define this hook to return 'true' if
- 'TARGET_SETUP_INCOMING_VARARGS' is used, 'false' otherwise.
- Otherwise, you should not define this hook.
-
- -- Target Hook: rtx TARGET_LOAD_BOUNDS_FOR_ARG (rtx SLOT, rtx ARG, rtx
- SLOT_NO)
- This hook is used by expand pass to emit insn to load bounds of ARG
- passed in SLOT. Expand pass uses this hook in case bounds of ARG
- are not passed in register. If SLOT is a memory, then bounds are
- loaded as for regular pointer loaded from memory. If SLOT is not a
- memory then SLOT_NO is an integer constant holding number of the
- target dependent special slot which should be used to obtain
- bounds. Hook returns RTX holding loaded bounds.
-
- -- Target Hook: void TARGET_STORE_BOUNDS_FOR_ARG (rtx ARG, rtx SLOT,
- rtx BOUNDS, rtx SLOT_NO)
- This hook is used by expand pass to emit insns to store BOUNDS of
- ARG passed in SLOT. Expand pass uses this hook in case BOUNDS of
- ARG are not passed in register. If SLOT is a memory, then BOUNDS
- are stored as for regular pointer stored in memory. If SLOT is not
- a memory then SLOT_NO is an integer constant holding number of the
- target dependent special slot which should be used to store BOUNDS.
-
- -- Target Hook: rtx TARGET_LOAD_RETURNED_BOUNDS (rtx SLOT)
- This hook is used by expand pass to emit insn to load bounds
- returned by function call in SLOT. Hook returns RTX holding loaded
- bounds.
-
- -- Target Hook: void TARGET_STORE_RETURNED_BOUNDS (rtx SLOT, rtx
- BOUNDS)
- This hook is used by expand pass to emit insn to store BOUNDS
- returned by function call into SLOT.
-
-
- File: gccint.info, Node: Trampolines, Next: Library Calls, Prev: Varargs, Up: Target Macros
-
- 18.11 Support for Nested Functions
- ==================================
-
- Taking the address of a nested function requires special compiler
- handling to ensure that the static chain register is loaded when the
- function is invoked via an indirect call.
-
- GCC has traditionally supported nested functions by creating an
- executable "trampoline" at run time when the address of a nested
- function is taken. This is a small piece of code which normally resides
- on the stack, in the stack frame of the containing function. The
- trampoline loads the static chain register and then jumps to the real
- address of the nested function.
-
- The use of trampolines requires an executable stack, which is a
- security risk. To avoid this problem, GCC also supports another
- strategy: using descriptors for nested functions. Under this model,
- taking the address of a nested function results in a pointer to a
- non-executable function descriptor object. Initializing the static
- chain from the descriptor is handled at indirect call sites.
-
- On some targets, including HPPA and IA-64, function descriptors may be
- mandated by the ABI or be otherwise handled in a target-specific way by
- the back end in its code generation strategy for indirect calls. GCC
- also provides its own generic descriptor implementation to support the
- '-fno-trampolines' option. In this case runtime detection of function
- descriptors at indirect call sites relies on descriptor pointers being
- tagged with a bit that is never set in bare function addresses. Since
- GCC's generic function descriptors are not ABI-compliant, this option is
- typically used only on a per-language basis (notably by Ada) or when it
- can otherwise be applied to the whole program.
-
- Define the following hook if your backend either implements
- ABI-specified descriptor support, or can use GCC's generic descriptor
- implementation for nested functions.
-
- -- Target Hook: int TARGET_CUSTOM_FUNCTION_DESCRIPTORS
- If the target can use GCC's generic descriptor mechanism for nested
- functions, define this hook to a power of 2 representing an unused
- bit in function pointers which can be used to differentiate
- descriptors at run time. This value gives the number of bytes by
- which descriptor pointers are misaligned compared to function
- pointers. For example, on targets that require functions to be
- aligned to a 4-byte boundary, a value of either 1 or 2 is
- appropriate unless the architecture already reserves the bit for
- another purpose, such as on ARM.
-
- Define this hook to 0 if the target implements ABI support for
- function descriptors in its standard calling sequence, like for
- example HPPA or IA-64.
-
- Using descriptors for nested functions eliminates the need for
- trampolines that reside on the stack and require it to be made
- executable.
-
- The following macros tell GCC how to generate code to allocate and
- initialize an executable trampoline. You can also use this interface if
- your back end needs to create ABI-specified non-executable descriptors;
- in this case the "trampoline" created is the descriptor containing data
- only.
-
- The instructions in an executable trampoline must do two things: load a
- constant address into the static chain register, and jump to the real
- address of the nested function. On CISC machines such as the m68k, this
- requires two instructions, a move immediate and a jump. Then the two
- addresses exist in the trampoline as word-long immediate operands. On
- RISC machines, it is often necessary to load each address into a
- register in two parts. Then pieces of each address form separate
- immediate operands.
-
- The code generated to initialize the trampoline must store the variable
- parts--the static chain value and the function address--into the
- immediate operands of the instructions. On a CISC machine, this is
- simply a matter of copying each address to a memory reference at the
- proper offset from the start of the trampoline. On a RISC machine, it
- may be necessary to take out pieces of the address and store them
- separately.
-
- -- Target Hook: void TARGET_ASM_TRAMPOLINE_TEMPLATE (FILE *F)
- This hook is called by 'assemble_trampoline_template' to output, on
- the stream F, assembler code for a block of data that contains the
- constant parts of a trampoline. This code should not include a
- label--the label is taken care of automatically.
-
- If you do not define this hook, it means no template is needed for
- the target. Do not define this hook on systems where the block
- move code to copy the trampoline into place would be larger than
- the code to generate it on the spot.
-
- -- Macro: TRAMPOLINE_SECTION
- Return the section into which the trampoline template is to be
- placed (*note Sections::). The default value is
- 'readonly_data_section'.
-
- -- Macro: TRAMPOLINE_SIZE
- A C expression for the size in bytes of the trampoline, as an
- integer.
-
- -- Macro: TRAMPOLINE_ALIGNMENT
- Alignment required for trampolines, in bits.
-
- If you don't define this macro, the value of 'FUNCTION_ALIGNMENT'
- is used for aligning trampolines.
-
- -- Target Hook: void TARGET_TRAMPOLINE_INIT (rtx M_TRAMP, tree FNDECL,
- rtx STATIC_CHAIN)
- This hook is called to initialize a trampoline. M_TRAMP is an RTX
- for the memory block for the trampoline; FNDECL is the
- 'FUNCTION_DECL' for the nested function; STATIC_CHAIN is an RTX for
- the static chain value that should be passed to the function when
- it is called.
-
- If the target defines 'TARGET_ASM_TRAMPOLINE_TEMPLATE', then the
- first thing this hook should do is emit a block move into M_TRAMP
- from the memory block returned by 'assemble_trampoline_template'.
- Note that the block move need only cover the constant parts of the
- trampoline. If the target isolates the variable parts of the
- trampoline to the end, not all 'TRAMPOLINE_SIZE' bytes need be
- copied.
-
- If the target requires any other actions, such as flushing caches
- or enabling stack execution, these actions should be performed
- after initializing the trampoline proper.
-
- -- Target Hook: rtx TARGET_TRAMPOLINE_ADJUST_ADDRESS (rtx ADDR)
- This hook should perform any machine-specific adjustment in the
- address of the trampoline. Its argument contains the address of
- the memory block that was passed to 'TARGET_TRAMPOLINE_INIT'. In
- case the address to be used for a function call should be different
- from the address at which the template was stored, the different
- address should be returned; otherwise ADDR should be returned
- unchanged. If this hook is not defined, ADDR will be used for
- function calls.
-
- Implementing trampolines is difficult on many machines because they
- have separate instruction and data caches. Writing into a stack
- location fails to clear the memory in the instruction cache, so when the
- program jumps to that location, it executes the old contents.
-
- Here are two possible solutions. One is to clear the relevant parts of
- the instruction cache whenever a trampoline is set up. The other is to
- make all trampolines identical, by having them jump to a standard
- subroutine. The former technique makes trampoline execution faster; the
- latter makes initialization faster.
-
- To clear the instruction cache when a trampoline is initialized, define
- the following macro.
-
- -- Macro: CLEAR_INSN_CACHE (BEG, END)
- If defined, expands to a C expression clearing the _instruction
- cache_ in the specified interval. The definition of this macro
- would typically be a series of 'asm' statements. Both BEG and END
- are both pointer expressions.
-
- To use a standard subroutine, define the following macro. In addition,
- you must make sure that the instructions in a trampoline fill an entire
- cache line with identical instructions, or else ensure that the
- beginning of the trampoline code is always aligned at the same point in
- its cache line. Look in 'm68k.h' as a guide.
-
- -- Macro: TRANSFER_FROM_TRAMPOLINE
- Define this macro if trampolines need a special subroutine to do
- their work. The macro should expand to a series of 'asm'
- statements which will be compiled with GCC. They go in a library
- function named '__transfer_from_trampoline'.
-
- If you need to avoid executing the ordinary prologue code of a
- compiled C function when you jump to the subroutine, you can do so
- by placing a special label of your own in the assembler code. Use
- one 'asm' statement to generate an assembler label, and another to
- make the label global. Then trampolines can use that label to jump
- directly to your special assembler code.
-
-
- File: gccint.info, Node: Library Calls, Next: Addressing Modes, Prev: Trampolines, Up: Target Macros
-
- 18.12 Implicit Calls to Library Routines
- ========================================
-
- Here is an explanation of implicit calls to library routines.
-
- -- Macro: DECLARE_LIBRARY_RENAMES
- This macro, if defined, should expand to a piece of C code that
- will get expanded when compiling functions for libgcc.a. It can be
- used to provide alternate names for GCC's internal library
- functions if there are ABI-mandated names that the compiler should
- provide.
-
- -- Target Hook: void TARGET_INIT_LIBFUNCS (void)
- This hook should declare additional library routines or rename
- existing ones, using the functions 'set_optab_libfunc' and
- 'init_one_libfunc' defined in 'optabs.c'. 'init_optabs' calls this
- macro after initializing all the normal library routines.
-
- The default is to do nothing. Most ports don't need to define this
- hook.
-
- -- Target Hook: bool TARGET_LIBFUNC_GNU_PREFIX
- If false (the default), internal library routines start with two
- underscores. If set to true, these routines start with '__gnu_'
- instead. E.g., '__muldi3' changes to '__gnu_muldi3'. This
- currently only affects functions defined in 'libgcc2.c'. If this
- is set to true, the 'tm.h' file must also '#define
- LIBGCC2_GNU_PREFIX'.
-
- -- Macro: FLOAT_LIB_COMPARE_RETURNS_BOOL (MODE, COMPARISON)
- This macro should return 'true' if the library routine that
- implements the floating point comparison operator COMPARISON in
- mode MODE will return a boolean, and FALSE if it will return a
- tristate.
-
- GCC's own floating point libraries return tristates from the
- comparison operators, so the default returns false always. Most
- ports don't need to define this macro.
-
- -- Macro: TARGET_LIB_INT_CMP_BIASED
- This macro should evaluate to 'true' if the integer comparison
- functions (like '__cmpdi2') return 0 to indicate that the first
- operand is smaller than the second, 1 to indicate that they are
- equal, and 2 to indicate that the first operand is greater than the
- second. If this macro evaluates to 'false' the comparison
- functions return -1, 0, and 1 instead of 0, 1, and 2. If the
- target uses the routines in 'libgcc.a', you do not need to define
- this macro.
-
- -- Macro: TARGET_HAS_NO_HW_DIVIDE
- This macro should be defined if the target has no hardware divide
- instructions. If this macro is defined, GCC will use an algorithm
- which make use of simple logical and arithmetic operations for
- 64-bit division. If the macro is not defined, GCC will use an
- algorithm which make use of a 64-bit by 32-bit divide primitive.
-
- -- Macro: TARGET_EDOM
- The value of 'EDOM' on the target machine, as a C integer constant
- expression. If you don't define this macro, GCC does not attempt
- to deposit the value of 'EDOM' into 'errno' directly. Look in
- '/usr/include/errno.h' to find the value of 'EDOM' on your system.
-
- If you do not define 'TARGET_EDOM', then compiled code reports
- domain errors by calling the library function and letting it report
- the error. If mathematical functions on your system use 'matherr'
- when there is an error, then you should leave 'TARGET_EDOM'
- undefined so that 'matherr' is used normally.
-
- -- Macro: GEN_ERRNO_RTX
- Define this macro as a C expression to create an rtl expression
- that refers to the global "variable" 'errno'. (On certain systems,
- 'errno' may not actually be a variable.) If you don't define this
- macro, a reasonable default is used.
-
- -- Target Hook: bool TARGET_LIBC_HAS_FUNCTION (enum function_class
- FN_CLASS)
- This hook determines whether a function from a class of functions
- FN_CLASS is present in the target C library.
-
- -- Target Hook: bool TARGET_LIBC_HAS_FAST_FUNCTION (int FCODE)
- This hook determines whether a function from a class of functions
- '(enum function_class)'FCODE has a fast implementation.
-
- -- Macro: NEXT_OBJC_RUNTIME
- Set this macro to 1 to use the "NeXT" Objective-C message sending
- conventions by default. This calling convention involves passing
- the object, the selector and the method arguments all at once to
- the method-lookup library function. This is the usual setting when
- targeting Darwin/Mac OS X systems, which have the NeXT runtime
- installed.
-
- If the macro is set to 0, the "GNU" Objective-C message sending
- convention will be used by default. This convention passes just
- the object and the selector to the method-lookup function, which
- returns a pointer to the method.
-
- In either case, it remains possible to select code-generation for
- the alternate scheme, by means of compiler command line switches.
-
-
- File: gccint.info, Node: Addressing Modes, Next: Anchored Addresses, Prev: Library Calls, Up: Target Macros
-
- 18.13 Addressing Modes
- ======================
-
- This is about addressing modes.
-
- -- Macro: HAVE_PRE_INCREMENT
- -- Macro: HAVE_PRE_DECREMENT
- -- Macro: HAVE_POST_INCREMENT
- -- Macro: HAVE_POST_DECREMENT
- A C expression that is nonzero if the machine supports
- pre-increment, pre-decrement, post-increment, or post-decrement
- addressing respectively.
-
- -- Macro: HAVE_PRE_MODIFY_DISP
- -- Macro: HAVE_POST_MODIFY_DISP
- A C expression that is nonzero if the machine supports pre- or
- post-address side-effect generation involving constants other than
- the size of the memory operand.
-
- -- Macro: HAVE_PRE_MODIFY_REG
- -- Macro: HAVE_POST_MODIFY_REG
- A C expression that is nonzero if the machine supports pre- or
- post-address side-effect generation involving a register
- displacement.
-
- -- Macro: CONSTANT_ADDRESS_P (X)
- A C expression that is 1 if the RTX X is a constant which is a
- valid address. On most machines the default definition of
- '(CONSTANT_P (X) && GET_CODE (X) != CONST_DOUBLE)' is acceptable,
- but a few machines are more restrictive as to which constant
- addresses are supported.
-
- -- Macro: CONSTANT_P (X)
- 'CONSTANT_P', which is defined by target-independent code, accepts
- integer-values expressions whose values are not explicitly known,
- such as 'symbol_ref', 'label_ref', and 'high' expressions and
- 'const' arithmetic expressions, in addition to 'const_int' and
- 'const_double' expressions.
-
- -- Macro: MAX_REGS_PER_ADDRESS
- A number, the maximum number of registers that can appear in a
- valid memory address. Note that it is up to you to specify a value
- equal to the maximum number that 'TARGET_LEGITIMATE_ADDRESS_P'
- would ever accept.
-
- -- Target Hook: bool TARGET_LEGITIMATE_ADDRESS_P (machine_mode MODE,
- rtx X, bool STRICT)
- A function that returns whether X (an RTX) is a legitimate memory
- address on the target machine for a memory operand of mode MODE.
-
- Legitimate addresses are defined in two variants: a strict variant
- and a non-strict one. The STRICT parameter chooses which variant
- is desired by the caller.
-
- The strict variant is used in the reload pass. It must be defined
- so that any pseudo-register that has not been allocated a hard
- register is considered a memory reference. This is because in
- contexts where some kind of register is required, a pseudo-register
- with no hard register must be rejected. For non-hard registers,
- the strict variant should look up the 'reg_renumber' array; it
- should then proceed using the hard register number in the array, or
- treat the pseudo as a memory reference if the array holds '-1'.
-
- The non-strict variant is used in other passes. It must be defined
- to accept all pseudo-registers in every context where some kind of
- register is required.
-
- Normally, constant addresses which are the sum of a 'symbol_ref'
- and an integer are stored inside a 'const' RTX to mark them as
- constant. Therefore, there is no need to recognize such sums
- specifically as legitimate addresses. Normally you would simply
- recognize any 'const' as legitimate.
-
- Usually 'PRINT_OPERAND_ADDRESS' is not prepared to handle constant
- sums that are not marked with 'const'. It assumes that a naked
- 'plus' indicates indexing. If so, then you _must_ reject such
- naked constant sums as illegitimate addresses, so that none of them
- will be given to 'PRINT_OPERAND_ADDRESS'.
-
- On some machines, whether a symbolic address is legitimate depends
- on the section that the address refers to. On these machines,
- define the target hook 'TARGET_ENCODE_SECTION_INFO' to store the
- information into the 'symbol_ref', and then check for it here.
- When you see a 'const', you will have to look inside it to find the
- 'symbol_ref' in order to determine the section. *Note Assembler
- Format::.
-
- Some ports are still using a deprecated legacy substitute for this
- hook, the 'GO_IF_LEGITIMATE_ADDRESS' macro. This macro has this
- syntax:
-
- #define GO_IF_LEGITIMATE_ADDRESS (MODE, X, LABEL)
-
- and should 'goto LABEL' if the address X is a valid address on the
- target machine for a memory operand of mode MODE.
-
- Compiler source files that want to use the strict variant of this
- macro define the macro 'REG_OK_STRICT'. You should use an '#ifdef
- REG_OK_STRICT' conditional to define the strict variant in that
- case and the non-strict variant otherwise.
-
- Using the hook is usually simpler because it limits the number of
- files that are recompiled when changes are made.
-
- -- Macro: TARGET_MEM_CONSTRAINT
- A single character to be used instead of the default ''m''
- character for general memory addresses. This defines the
- constraint letter which matches the memory addresses accepted by
- 'TARGET_LEGITIMATE_ADDRESS_P'. Define this macro if you want to
- support new address formats in your back end without changing the
- semantics of the ''m'' constraint. This is necessary in order to
- preserve functionality of inline assembly constructs using the
- ''m'' constraint.
-
- -- Macro: FIND_BASE_TERM (X)
- A C expression to determine the base term of address X, or to
- provide a simplified version of X from which 'alias.c' can easily
- find the base term. This macro is used in only two places:
- 'find_base_value' and 'find_base_term' in 'alias.c'.
-
- It is always safe for this macro to not be defined. It exists so
- that alias analysis can understand machine-dependent addresses.
-
- The typical use of this macro is to handle addresses containing a
- label_ref or symbol_ref within an UNSPEC.
-
- -- Target Hook: rtx TARGET_LEGITIMIZE_ADDRESS (rtx X, rtx OLDX,
- machine_mode MODE)
- This hook is given an invalid memory address X for an operand of
- mode MODE and should try to return a valid memory address.
-
- X will always be the result of a call to 'break_out_memory_refs',
- and OLDX will be the operand that was given to that function to
- produce X.
-
- The code of the hook should not alter the substructure of X. If it
- transforms X into a more legitimate form, it should return the new
- X.
-
- It is not necessary for this hook to come up with a legitimate
- address, with the exception of native TLS addresses (*note Emulated
- TLS::). The compiler has standard ways of doing so in all cases.
- In fact, if the target supports only emulated TLS, it is safe to
- omit this hook or make it return X if it cannot find a valid way to
- legitimize the address. But often a machine-dependent strategy can
- generate better code.
-
- -- Macro: LEGITIMIZE_RELOAD_ADDRESS (X, MODE, OPNUM, TYPE, IND_LEVELS,
- WIN)
- A C compound statement that attempts to replace X, which is an
- address that needs reloading, with a valid memory address for an
- operand of mode MODE. WIN will be a C statement label elsewhere in
- the code. It is not necessary to define this macro, but it might
- be useful for performance reasons.
-
- For example, on the i386, it is sometimes possible to use a single
- reload register instead of two by reloading a sum of two pseudo
- registers into a register. On the other hand, for number of RISC
- processors offsets are limited so that often an intermediate
- address needs to be generated in order to address a stack slot. By
- defining 'LEGITIMIZE_RELOAD_ADDRESS' appropriately, the
- intermediate addresses generated for adjacent some stack slots can
- be made identical, and thus be shared.
-
- _Note_: This macro should be used with caution. It is necessary to
- know something of how reload works in order to effectively use
- this, and it is quite easy to produce macros that build in too much
- knowledge of reload internals.
-
- _Note_: This macro must be able to reload an address created by a
- previous invocation of this macro. If it fails to handle such
- addresses then the compiler may generate incorrect code or abort.
-
- The macro definition should use 'push_reload' to indicate parts
- that need reloading; OPNUM, TYPE and IND_LEVELS are usually
- suitable to be passed unaltered to 'push_reload'.
-
- The code generated by this macro must not alter the substructure of
- X. If it transforms X into a more legitimate form, it should
- assign X (which will always be a C variable) a new value. This
- also applies to parts that you change indirectly by calling
- 'push_reload'.
-
- The macro definition may use 'strict_memory_address_p' to test if
- the address has become legitimate.
-
- If you want to change only a part of X, one standard way of doing
- this is to use 'copy_rtx'. Note, however, that it unshares only a
- single level of rtl. Thus, if the part to be changed is not at the
- top level, you'll need to replace first the top level. It is not
- necessary for this macro to come up with a legitimate address; but
- often a machine-dependent strategy can generate better code.
-
- -- Target Hook: bool TARGET_MODE_DEPENDENT_ADDRESS_P (const_rtx ADDR,
- addr_space_t ADDRSPACE)
- This hook returns 'true' if memory address ADDR in address space
- ADDRSPACE can have different meanings depending on the machine mode
- of the memory reference it is used for or if the address is valid
- for some modes but not others.
-
- Autoincrement and autodecrement addresses typically have
- mode-dependent effects because the amount of the increment or
- decrement is the size of the operand being addressed. Some
- machines have other mode-dependent addresses. Many RISC machines
- have no mode-dependent addresses.
-
- You may assume that ADDR is a valid address for the machine.
-
- The default version of this hook returns 'false'.
-
- -- Target Hook: bool TARGET_LEGITIMATE_CONSTANT_P (machine_mode MODE,
- rtx X)
- This hook returns true if X is a legitimate constant for a
- MODE-mode immediate operand on the target machine. You can assume
- that X satisfies 'CONSTANT_P', so you need not check this.
-
- The default definition returns true.
-
- -- Target Hook: rtx TARGET_DELEGITIMIZE_ADDRESS (rtx X)
- This hook is used to undo the possibly obfuscating effects of the
- 'LEGITIMIZE_ADDRESS' and 'LEGITIMIZE_RELOAD_ADDRESS' target macros.
- Some backend implementations of these macros wrap symbol references
- inside an 'UNSPEC' rtx to represent PIC or similar addressing
- modes. This target hook allows GCC's optimizers to understand the
- semantics of these opaque 'UNSPEC's by converting them back into
- their original form.
-
- -- Target Hook: bool TARGET_CONST_NOT_OK_FOR_DEBUG_P (rtx X)
- This hook should return true if X should not be emitted into debug
- sections.
-
- -- Target Hook: bool TARGET_CANNOT_FORCE_CONST_MEM (machine_mode MODE,
- rtx X)
- This hook should return true if X is of a form that cannot (or
- should not) be spilled to the constant pool. MODE is the mode of
- X.
-
- The default version of this hook returns false.
-
- The primary reason to define this hook is to prevent reload from
- deciding that a non-legitimate constant would be better reloaded
- from the constant pool instead of spilling and reloading a register
- holding the constant. This restriction is often true of addresses
- of TLS symbols for various targets.
-
- -- Target Hook: bool TARGET_USE_BLOCKS_FOR_CONSTANT_P (machine_mode
- MODE, const_rtx X)
- This hook should return true if pool entries for constant X can be
- placed in an 'object_block' structure. MODE is the mode of X.
-
- The default version returns false for all constants.
-
- -- Target Hook: bool TARGET_USE_BLOCKS_FOR_DECL_P (const_tree DECL)
- This hook should return true if pool entries for DECL should be
- placed in an 'object_block' structure.
-
- The default version returns true for all decls.
-
- -- Target Hook: tree TARGET_BUILTIN_RECIPROCAL (tree FNDECL)
- This hook should return the DECL of a function that implements the
- reciprocal of the machine-specific builtin function FNDECL, or
- 'NULL_TREE' if such a function is not available.
-
- -- Target Hook: tree TARGET_VECTORIZE_BUILTIN_MASK_FOR_LOAD (void)
- This hook should return the DECL of a function F that given an
- address ADDR as an argument returns a mask M that can be used to
- extract from two vectors the relevant data that resides in ADDR in
- case ADDR is not properly aligned.
-
- The autovectorizer, when vectorizing a load operation from an
- address ADDR that may be unaligned, will generate two vector loads
- from the two aligned addresses around ADDR. It then generates a
- 'REALIGN_LOAD' operation to extract the relevant data from the two
- loaded vectors. The first two arguments to 'REALIGN_LOAD', V1 and
- V2, are the two vectors, each of size VS, and the third argument,
- OFF, defines how the data will be extracted from these two vectors:
- if OFF is 0, then the returned vector is V2; otherwise, the
- returned vector is composed from the last VS-OFF elements of V1
- concatenated to the first OFF elements of V2.
-
- If this hook is defined, the autovectorizer will generate a call to
- F (using the DECL tree that this hook returns) and will use the
- return value of F as the argument OFF to 'REALIGN_LOAD'.
- Therefore, the mask M returned by F should comply with the
- semantics expected by 'REALIGN_LOAD' described above. If this hook
- is not defined, then ADDR will be used as the argument OFF to
- 'REALIGN_LOAD', in which case the low log2(VS) - 1 bits of ADDR
- will be considered.
-
- -- Target Hook: int TARGET_VECTORIZE_BUILTIN_VECTORIZATION_COST (enum
- vect_cost_for_stmt TYPE_OF_COST, tree VECTYPE, int MISALIGN)
- Returns cost of different scalar or vector statements for
- vectorization cost model. For vector memory operations the cost
- may depend on type (VECTYPE) and misalignment value (MISALIGN).
-
- -- Target Hook: poly_uint64 TARGET_VECTORIZE_PREFERRED_VECTOR_ALIGNMENT
- (const_tree TYPE)
- This hook returns the preferred alignment in bits for accesses to
- vectors of type TYPE in vectorized code. This might be less than
- or greater than the ABI-defined value returned by
- 'TARGET_VECTOR_ALIGNMENT'. It can be equal to the alignment of a
- single element, in which case the vectorizer will not try to
- optimize for alignment.
-
- The default hook returns 'TYPE_ALIGN (TYPE)', which is correct for
- most targets.
-
- -- Target Hook: bool TARGET_VECTORIZE_VECTOR_ALIGNMENT_REACHABLE
- (const_tree TYPE, bool IS_PACKED)
- Return true if vector alignment is reachable (by peeling N
- iterations) for the given scalar type TYPE. IS_PACKED is false if
- the scalar access using TYPE is known to be naturally aligned.
-
- -- Target Hook: bool TARGET_VECTORIZE_VEC_PERM_CONST (machine_mode
- MODE, rtx OUTPUT, rtx IN0, rtx IN1, const vec_perm_indices
- &SEL)
- This hook is used to test whether the target can permute up to two
- vectors of mode MODE using the permutation vector 'sel', and also
- to emit such a permutation. In the former case IN0, IN1 and OUT
- are all null. In the latter case IN0 and IN1 are the source
- vectors and OUT is the destination vector; all three are registers
- of mode MODE. IN1 is the same as IN0 if SEL describes a
- permutation on one vector instead of two.
-
- Return true if the operation is possible, emitting instructions for
- it if rtxes are provided.
-
- If the hook returns false for a mode with multibyte elements, GCC
- will try the equivalent byte operation. If that also fails, it
- will try forcing the selector into a register and using the
- VEC_PERMMODE instruction pattern. There is no need for the hook to
- handle these two implementation approaches itself.
-
- -- Target Hook: tree TARGET_VECTORIZE_BUILTIN_VECTORIZED_FUNCTION
- (unsigned CODE, tree VEC_TYPE_OUT, tree VEC_TYPE_IN)
- This hook should return the decl of a function that implements the
- vectorized variant of the function with the 'combined_fn' code CODE
- or 'NULL_TREE' if such a function is not available. The return
- type of the vectorized function shall be of vector type
- VEC_TYPE_OUT and the argument types should be VEC_TYPE_IN.
-
- -- Target Hook: tree TARGET_VECTORIZE_BUILTIN_MD_VECTORIZED_FUNCTION
- (tree FNDECL, tree VEC_TYPE_OUT, tree VEC_TYPE_IN)
- This hook should return the decl of a function that implements the
- vectorized variant of target built-in function 'fndecl'. The
- return type of the vectorized function shall be of vector type
- VEC_TYPE_OUT and the argument types should be VEC_TYPE_IN.
-
- -- Target Hook: bool TARGET_VECTORIZE_SUPPORT_VECTOR_MISALIGNMENT
- (machine_mode MODE, const_tree TYPE, int MISALIGNMENT, bool
- IS_PACKED)
- This hook should return true if the target supports misaligned
- vector store/load of a specific factor denoted in the MISALIGNMENT
- parameter. The vector store/load should be of machine mode MODE
- and the elements in the vectors should be of type TYPE. IS_PACKED
- parameter is true if the memory access is defined in a packed
- struct.
-
- -- Target Hook: machine_mode TARGET_VECTORIZE_PREFERRED_SIMD_MODE
- (scalar_mode MODE)
- This hook should return the preferred mode for vectorizing scalar
- mode MODE. The default is equal to 'word_mode', because the
- vectorizer can do some transformations even in absence of
- specialized SIMD hardware.
-
- -- Target Hook: machine_mode TARGET_VECTORIZE_SPLIT_REDUCTION
- (machine_mode)
- This hook should return the preferred mode to split the final
- reduction step on MODE to. The reduction is then carried out
- reducing upper against lower halves of vectors recursively until
- the specified mode is reached. The default is MODE which means no
- splitting.
-
- -- Target Hook: unsigned int
- TARGET_VECTORIZE_AUTOVECTORIZE_VECTOR_MODES (vector_modes
- *MODES, bool ALL)
- If using the mode returned by
- 'TARGET_VECTORIZE_PREFERRED_SIMD_MODE' is not the only approach
- worth considering, this hook should add one mode to MODES for each
- useful alternative approach. These modes are then passed to
- 'TARGET_VECTORIZE_RELATED_MODE' to obtain the vector mode for a
- given element mode.
-
- The modes returned in MODES should use the smallest element mode
- possible for the vectorization approach that they represent,
- preferring integer modes over floating-poing modes in the event of
- a tie. The first mode should be the
- 'TARGET_VECTORIZE_PREFERRED_SIMD_MODE' for its element mode.
-
- If ALL is true, add suitable vector modes even when they are
- generally not expected to be worthwhile.
-
- The hook returns a bitmask of flags that control how the modes in
- MODES are used. The flags are:
- 'VECT_COMPARE_COSTS'
- Tells the loop vectorizer to try all the provided modes and
- pick the one with the lowest cost. By default the vectorizer
- will choose the first mode that works.
-
- The hook does not need to do anything if the vector returned by
- 'TARGET_VECTORIZE_PREFERRED_SIMD_MODE' is the only one relevant for
- autovectorization. The default implementation adds no modes and
- returns 0.
-
- -- Target Hook: opt_machine_mode TARGET_VECTORIZE_RELATED_MODE
- (machine_mode VECTOR_MODE, scalar_mode ELEMENT_MODE,
- poly_uint64 NUNITS)
- If a piece of code is using vector mode VECTOR_MODE and also wants
- to operate on elements of mode ELEMENT_MODE, return the vector mode
- it should use for those elements. If NUNITS is nonzero, ensure
- that the mode has exactly NUNITS elements, otherwise pick whichever
- vector size pairs the most naturally with VECTOR_MODE. Return an
- empty 'opt_machine_mode' if there is no supported vector mode with
- the required properties.
-
- There is no prescribed way of handling the case in which NUNITS is
- zero. One common choice is to pick a vector mode with the same
- size as VECTOR_MODE; this is the natural choice if the target has a
- fixed vector size. Another option is to choose a vector mode with
- the same number of elements as VECTOR_MODE; this is the natural
- choice if the target has a fixed number of elements.
- Alternatively, the hook might choose a middle ground, such as
- trying to keep the number of elements as similar as possible while
- applying maximum and minimum vector sizes.
-
- The default implementation uses 'mode_for_vector' to find the
- requested mode, returning a mode with the same size as VECTOR_MODE
- when NUNITS is zero. This is the correct behavior for most
- targets.
-
- -- Target Hook: opt_machine_mode TARGET_VECTORIZE_GET_MASK_MODE
- (machine_mode MODE)
- Return the mode to use for a vector mask that holds one boolean
- result for each element of vector mode MODE. The returned mask
- mode can be a vector of integers (class 'MODE_VECTOR_INT'), a
- vector of booleans (class 'MODE_VECTOR_BOOL') or a scalar integer
- (class 'MODE_INT'). Return an empty 'opt_machine_mode' if no such
- mask mode exists.
-
- The default implementation returns a 'MODE_VECTOR_INT' with the
- same size and number of elements as MODE, if such a mode exists.
-
- -- Target Hook: bool TARGET_VECTORIZE_EMPTY_MASK_IS_EXPENSIVE (unsigned
- IFN)
- This hook returns true if masked internal function IFN (really of
- type 'internal_fn') should be considered expensive when the mask is
- all zeros. GCC can then try to branch around the instruction
- instead.
-
- -- Target Hook: void * TARGET_VECTORIZE_INIT_COST (class loop
- *LOOP_INFO)
- This hook should initialize target-specific data structures in
- preparation for modeling the costs of vectorizing a loop or basic
- block. The default allocates three unsigned integers for
- accumulating costs for the prologue, body, and epilogue of the loop
- or basic block. If LOOP_INFO is non-NULL, it identifies the loop
- being vectorized; otherwise a single block is being vectorized.
-
- -- Target Hook: unsigned TARGET_VECTORIZE_ADD_STMT_COST (void *DATA,
- int COUNT, enum vect_cost_for_stmt KIND, class _stmt_vec_info
- *STMT_INFO, int MISALIGN, enum vect_cost_model_location WHERE)
- This hook should update the target-specific DATA in response to
- adding COUNT copies of the given KIND of statement to a loop or
- basic block. The default adds the builtin vectorizer cost for the
- copies of the statement to the accumulator specified by WHERE, (the
- prologue, body, or epilogue) and returns the amount added. The
- return value should be viewed as a tentative cost that may later be
- revised.
-
- -- Target Hook: void TARGET_VECTORIZE_FINISH_COST (void *DATA, unsigned
- *PROLOGUE_COST, unsigned *BODY_COST, unsigned *EPILOGUE_COST)
- This hook should complete calculations of the cost of vectorizing a
- loop or basic block based on DATA, and return the prologue, body,
- and epilogue costs as unsigned integers. The default returns the
- value of the three accumulators.
-
- -- Target Hook: void TARGET_VECTORIZE_DESTROY_COST_DATA (void *DATA)
- This hook should release DATA and any related data structures
- allocated by TARGET_VECTORIZE_INIT_COST. The default releases the
- accumulator.
-
- -- Target Hook: tree TARGET_VECTORIZE_BUILTIN_GATHER (const_tree
- MEM_VECTYPE, const_tree INDEX_TYPE, int SCALE)
- Target builtin that implements vector gather operation.
- MEM_VECTYPE is the vector type of the load and INDEX_TYPE is scalar
- type of the index, scaled by SCALE. The default is 'NULL_TREE'
- which means to not vectorize gather loads.
-
- -- Target Hook: tree TARGET_VECTORIZE_BUILTIN_SCATTER (const_tree
- VECTYPE, const_tree INDEX_TYPE, int SCALE)
- Target builtin that implements vector scatter operation. VECTYPE
- is the vector type of the store and INDEX_TYPE is scalar type of
- the index, scaled by SCALE. The default is 'NULL_TREE' which means
- to not vectorize scatter stores.
-
- -- Target Hook: int TARGET_SIMD_CLONE_COMPUTE_VECSIZE_AND_SIMDLEN
- (struct cgraph_node *, struct cgraph_simd_clone *, TREE, INT)
- This hook should set VECSIZE_MANGLE, VECSIZE_INT, VECSIZE_FLOAT
- fields in SIMD_CLONE structure pointed by CLONE_INFO argument and
- also SIMDLEN field if it was previously 0. The hook should return
- 0 if SIMD clones shouldn't be emitted, or number of VECSIZE_MANGLE
- variants that should be emitted.
-
- -- Target Hook: void TARGET_SIMD_CLONE_ADJUST (struct cgraph_node *)
- This hook should add implicit 'attribute(target("..."))' attribute
- to SIMD clone NODE if needed.
-
- -- Target Hook: int TARGET_SIMD_CLONE_USABLE (struct cgraph_node *)
- This hook should return -1 if SIMD clone NODE shouldn't be used in
- vectorized loops in current function, or non-negative number if it
- is usable. In that case, the smaller the number is, the more
- desirable it is to use it.
-
- -- Target Hook: int TARGET_SIMT_VF (void)
- Return number of threads in SIMT thread group on the target.
-
- -- Target Hook: int TARGET_OMP_DEVICE_KIND_ARCH_ISA (enum
- omp_device_kind_arch_isa TRAIT, const char *NAME)
- Return 1 if TRAIT NAME is present in the OpenMP context's device
- trait set, return 0 if not present in any OpenMP context in the
- whole translation unit, or -1 if not present in the current OpenMP
- context but might be present in another OpenMP context in the same
- TU.
-
- -- Target Hook: bool TARGET_GOACC_VALIDATE_DIMS (tree DECL, int *DIMS,
- int FN_LEVEL, unsigned USED)
- This hook should check the launch dimensions provided for an
- OpenACC compute region, or routine. Defaulted values are
- represented as -1 and non-constant values as 0. The FN_LEVEL is
- negative for the function corresponding to the compute region. For
- a routine it is the outermost level at which partitioned execution
- may be spawned. The hook should verify non-default values. If
- DECL is NULL, global defaults are being validated and unspecified
- defaults should be filled in. Diagnostics should be issued as
- appropriate. Return true, if changes have been made. You must
- override this hook to provide dimensions larger than 1.
-
- -- Target Hook: int TARGET_GOACC_DIM_LIMIT (int AXIS)
- This hook should return the maximum size of a particular dimension,
- or zero if unbounded.
-
- -- Target Hook: bool TARGET_GOACC_FORK_JOIN (gcall *CALL, const int
- *DIMS, bool IS_FORK)
- This hook can be used to convert IFN_GOACC_FORK and IFN_GOACC_JOIN
- function calls to target-specific gimple, or indicate whether they
- should be retained. It is executed during the oacc_device_lower
- pass. It should return true, if the call should be retained. It
- should return false, if it is to be deleted (either because
- target-specific gimple has been inserted before it, or there is no
- need for it). The default hook returns false, if there are no RTL
- expanders for them.
-
- -- Target Hook: void TARGET_GOACC_REDUCTION (gcall *CALL)
- This hook is used by the oacc_transform pass to expand calls to the
- GOACC_REDUCTION internal function, into a sequence of gimple
- instructions. CALL is gimple statement containing the call to the
- function. This hook removes statement CALL after the expanded
- sequence has been inserted. This hook is also responsible for
- allocating any storage for reductions when necessary.
-
- -- Target Hook: tree TARGET_PREFERRED_ELSE_VALUE (unsigned IFN, tree
- TYPE, unsigned NOPS, tree *OPS)
- This hook returns the target's preferred final argument for a call
- to conditional internal function IFN (really of type
- 'internal_fn'). TYPE specifies the return type of the function and
- OPS are the operands to the conditional operation, of which there
- are NOPS.
-
- For example, if IFN is 'IFN_COND_ADD', the hook returns a value of
- type TYPE that should be used when 'OPS[0]' and 'OPS[1]' are
- conditionally added together.
-
- This hook is only relevant if the target supports conditional
- patterns like 'cond_addM'. The default implementation returns a
- zero constant of type TYPE.
-
-
- File: gccint.info, Node: Anchored Addresses, Next: Condition Code, Prev: Addressing Modes, Up: Target Macros
-
- 18.14 Anchored Addresses
- ========================
-
- GCC usually addresses every static object as a separate entity. For
- example, if we have:
-
- static int a, b, c;
- int foo (void) { return a + b + c; }
-
- the code for 'foo' will usually calculate three separate symbolic
- addresses: those of 'a', 'b' and 'c'. On some targets, it would be
- better to calculate just one symbolic address and access the three
- variables relative to it. The equivalent pseudocode would be something
- like:
-
- int foo (void)
- {
- register int *xr = &x;
- return xr[&a - &x] + xr[&b - &x] + xr[&c - &x];
- }
-
- (which isn't valid C). We refer to shared addresses like 'x' as
- "section anchors". Their use is controlled by '-fsection-anchors'.
-
- The hooks below describe the target properties that GCC needs to know
- in order to make effective use of section anchors. It won't use section
- anchors at all unless either 'TARGET_MIN_ANCHOR_OFFSET' or
- 'TARGET_MAX_ANCHOR_OFFSET' is set to a nonzero value.
-
- -- Target Hook: HOST_WIDE_INT TARGET_MIN_ANCHOR_OFFSET
- The minimum offset that should be applied to a section anchor. On
- most targets, it should be the smallest offset that can be applied
- to a base register while still giving a legitimate address for
- every mode. The default value is 0.
-
- -- Target Hook: HOST_WIDE_INT TARGET_MAX_ANCHOR_OFFSET
- Like 'TARGET_MIN_ANCHOR_OFFSET', but the maximum (inclusive) offset
- that should be applied to section anchors. The default value is 0.
-
- -- Target Hook: void TARGET_ASM_OUTPUT_ANCHOR (rtx X)
- Write the assembly code to define section anchor X, which is a
- 'SYMBOL_REF' for which 'SYMBOL_REF_ANCHOR_P (X)' is true. The hook
- is called with the assembly output position set to the beginning of
- 'SYMBOL_REF_BLOCK (X)'.
-
- If 'ASM_OUTPUT_DEF' is available, the hook's default definition
- uses it to define the symbol as '. + SYMBOL_REF_BLOCK_OFFSET (X)'.
- If 'ASM_OUTPUT_DEF' is not available, the hook's default definition
- is 'NULL', which disables the use of section anchors altogether.
-
- -- Target Hook: bool TARGET_USE_ANCHORS_FOR_SYMBOL_P (const_rtx X)
- Return true if GCC should attempt to use anchors to access
- 'SYMBOL_REF' X. You can assume 'SYMBOL_REF_HAS_BLOCK_INFO_P (X)'
- and '!SYMBOL_REF_ANCHOR_P (X)'.
-
- The default version is correct for most targets, but you might need
- to intercept this hook to handle things like target-specific
- attributes or target-specific sections.
-
-
- File: gccint.info, Node: Condition Code, Next: Costs, Prev: Anchored Addresses, Up: Target Macros
-
- 18.15 Condition Code Status
- ===========================
-
- The macros in this section can be split in two families, according to
- the two ways of representing condition codes in GCC.
-
- The first representation is the so called '(cc0)' representation (*note
- Jump Patterns::), where all instructions can have an implicit clobber of
- the condition codes. The second is the condition code register
- representation, which provides better schedulability for architectures
- that do have a condition code register, but on which most instructions
- do not affect it. The latter category includes most RISC machines.
-
- The implicit clobbering poses a strong restriction on the placement of
- the definition and use of the condition code. In the past the
- definition and use were always adjacent. However, recent changes to
- support trapping arithmatic may result in the definition and user being
- in different blocks. Thus, there may be a 'NOTE_INSN_BASIC_BLOCK'
- between them. Additionally, the definition may be the source of
- exception handling edges.
-
- These restrictions can prevent important optimizations on some
- machines. For example, on the IBM RS/6000, there is a delay for taken
- branches unless the condition code register is set three instructions
- earlier than the conditional branch. The instruction scheduler cannot
- perform this optimization if it is not permitted to separate the
- definition and use of the condition code register.
-
- For this reason, it is possible and suggested to use a register to
- represent the condition code for new ports. If there is a specific
- condition code register in the machine, use a hard register. If the
- condition code or comparison result can be placed in any general
- register, or if there are multiple condition registers, use a pseudo
- register. Registers used to store the condition code value will usually
- have a mode that is in class 'MODE_CC'.
-
- Alternatively, you can use 'BImode' if the comparison operator is
- specified already in the compare instruction. In this case, you are not
- interested in most macros in this section.
-
- * Menu:
-
- * CC0 Condition Codes:: Old style representation of condition codes.
- * MODE_CC Condition Codes:: Modern representation of condition codes.
-
-
- File: gccint.info, Node: CC0 Condition Codes, Next: MODE_CC Condition Codes, Up: Condition Code
-
- 18.15.1 Representation of condition codes using '(cc0)'
- -------------------------------------------------------
-
- The file 'conditions.h' defines a variable 'cc_status' to describe how
- the condition code was computed (in case the interpretation of the
- condition code depends on the instruction that it was set by). This
- variable contains the RTL expressions on which the condition code is
- currently based, and several standard flags.
-
- Sometimes additional machine-specific flags must be defined in the
- machine description header file. It can also add additional
- machine-specific information by defining 'CC_STATUS_MDEP'.
-
- -- Macro: CC_STATUS_MDEP
- C code for a data type which is used for declaring the 'mdep'
- component of 'cc_status'. It defaults to 'int'.
-
- This macro is not used on machines that do not use 'cc0'.
-
- -- Macro: CC_STATUS_MDEP_INIT
- A C expression to initialize the 'mdep' field to "empty". The
- default definition does nothing, since most machines don't use the
- field anyway. If you want to use the field, you should probably
- define this macro to initialize it.
-
- This macro is not used on machines that do not use 'cc0'.
-
- -- Macro: NOTICE_UPDATE_CC (EXP, INSN)
- A C compound statement to set the components of 'cc_status'
- appropriately for an insn INSN whose body is EXP. It is this
- macro's responsibility to recognize insns that set the condition
- code as a byproduct of other activity as well as those that
- explicitly set '(cc0)'.
-
- This macro is not used on machines that do not use 'cc0'.
-
- If there are insns that do not set the condition code but do alter
- other machine registers, this macro must check to see whether they
- invalidate the expressions that the condition code is recorded as
- reflecting. For example, on the 68000, insns that store in address
- registers do not set the condition code, which means that usually
- 'NOTICE_UPDATE_CC' can leave 'cc_status' unaltered for such insns.
- But suppose that the previous insn set the condition code based on
- location 'a4@(102)' and the current insn stores a new value in
- 'a4'. Although the condition code is not changed by this, it will
- no longer be true that it reflects the contents of 'a4@(102)'.
- Therefore, 'NOTICE_UPDATE_CC' must alter 'cc_status' in this case
- to say that nothing is known about the condition code value.
-
- The definition of 'NOTICE_UPDATE_CC' must be prepared to deal with
- the results of peephole optimization: insns whose patterns are
- 'parallel' RTXs containing various 'reg', 'mem' or constants which
- are just the operands. The RTL structure of these insns is not
- sufficient to indicate what the insns actually do. What
- 'NOTICE_UPDATE_CC' should do when it sees one is just to run
- 'CC_STATUS_INIT'.
-
- A possible definition of 'NOTICE_UPDATE_CC' is to call a function
- that looks at an attribute (*note Insn Attributes::) named, for
- example, 'cc'. This avoids having detailed information about
- patterns in two places, the 'md' file and in 'NOTICE_UPDATE_CC'.
-
-
- File: gccint.info, Node: MODE_CC Condition Codes, Prev: CC0 Condition Codes, Up: Condition Code
-
- 18.15.2 Representation of condition codes using registers
- ---------------------------------------------------------
-
- -- Macro: SELECT_CC_MODE (OP, X, Y)
- On many machines, the condition code may be produced by other
- instructions than compares, for example the branch can use directly
- the condition code set by a subtract instruction. However, on some
- machines when the condition code is set this way some bits (such as
- the overflow bit) are not set in the same way as a test
- instruction, so that a different branch instruction must be used
- for some conditional branches. When this happens, use the machine
- mode of the condition code register to record different formats of
- the condition code register. Modes can also be used to record
- which compare instruction (e.g. a signed or an unsigned comparison)
- produced the condition codes.
-
- If other modes than 'CCmode' are required, add them to
- 'MACHINE-modes.def' and define 'SELECT_CC_MODE' to choose a mode
- given an operand of a compare. This is needed because the modes
- have to be chosen not only during RTL generation but also, for
- example, by instruction combination. The result of
- 'SELECT_CC_MODE' should be consistent with the mode used in the
- patterns; for example to support the case of the add on the SPARC
- discussed above, we have the pattern
-
- (define_insn ""
- [(set (reg:CCNZ 0)
- (compare:CCNZ
- (plus:SI (match_operand:SI 0 "register_operand" "%r")
- (match_operand:SI 1 "arith_operand" "rI"))
- (const_int 0)))]
- ""
- "...")
-
- together with a 'SELECT_CC_MODE' that returns 'CCNZmode' for
- comparisons whose argument is a 'plus':
-
- #define SELECT_CC_MODE(OP,X,Y) \
- (GET_MODE_CLASS (GET_MODE (X)) == MODE_FLOAT \
- ? ((OP == LT || OP == LE || OP == GT || OP == GE) \
- ? CCFPEmode : CCFPmode) \
- : ((GET_CODE (X) == PLUS || GET_CODE (X) == MINUS \
- || GET_CODE (X) == NEG || GET_CODE (x) == ASHIFT) \
- ? CCNZmode : CCmode))
-
- Another reason to use modes is to retain information on which
- operands were used by the comparison; see 'REVERSIBLE_CC_MODE'
- later in this section.
-
- You should define this macro if and only if you define extra CC
- modes in 'MACHINE-modes.def'.
-
- -- Target Hook: void TARGET_CANONICALIZE_COMPARISON (int *CODE, rtx
- *OP0, rtx *OP1, bool OP0_PRESERVE_VALUE)
- On some machines not all possible comparisons are defined, but you
- can convert an invalid comparison into a valid one. For example,
- the Alpha does not have a 'GT' comparison, but you can use an 'LT'
- comparison instead and swap the order of the operands.
-
- On such machines, implement this hook to do any required
- conversions. CODE is the initial comparison code and OP0 and OP1
- are the left and right operands of the comparison, respectively.
- If OP0_PRESERVE_VALUE is 'true' the implementation is not allowed
- to change the value of OP0 since the value might be used in RTXs
- which aren't comparisons. E.g. the implementation is not allowed
- to swap operands in that case.
-
- GCC will not assume that the comparison resulting from this macro
- is valid but will see if the resulting insn matches a pattern in
- the 'md' file.
-
- You need not to implement this hook if it would never change the
- comparison code or operands.
-
- -- Macro: REVERSIBLE_CC_MODE (MODE)
- A C expression whose value is one if it is always safe to reverse a
- comparison whose mode is MODE. If 'SELECT_CC_MODE' can ever return
- MODE for a floating-point inequality comparison, then
- 'REVERSIBLE_CC_MODE (MODE)' must be zero.
-
- You need not define this macro if it would always returns zero or
- if the floating-point format is anything other than
- 'IEEE_FLOAT_FORMAT'. For example, here is the definition used on
- the SPARC, where floating-point inequality comparisons are given
- either 'CCFPEmode' or 'CCFPmode':
-
- #define REVERSIBLE_CC_MODE(MODE) \
- ((MODE) != CCFPEmode && (MODE) != CCFPmode)
-
- -- Macro: REVERSE_CONDITION (CODE, MODE)
- A C expression whose value is reversed condition code of the CODE
- for comparison done in CC_MODE MODE. The macro is used only in
- case 'REVERSIBLE_CC_MODE (MODE)' is nonzero. Define this macro in
- case machine has some non-standard way how to reverse certain
- conditionals. For instance in case all floating point conditions
- are non-trapping, compiler may freely convert unordered compares to
- ordered ones. Then definition may look like:
-
- #define REVERSE_CONDITION(CODE, MODE) \
- ((MODE) != CCFPmode ? reverse_condition (CODE) \
- : reverse_condition_maybe_unordered (CODE))
-
- -- Target Hook: bool TARGET_FIXED_CONDITION_CODE_REGS (unsigned int
- *P1, unsigned int *P2)
- On targets which do not use '(cc0)', and which use a hard register
- rather than a pseudo-register to hold condition codes, the regular
- CSE passes are often not able to identify cases in which the hard
- register is set to a common value. Use this hook to enable a small
- pass which optimizes such cases. This hook should return true to
- enable this pass, and it should set the integers to which its
- arguments point to the hard register numbers used for condition
- codes. When there is only one such register, as is true on most
- systems, the integer pointed to by P2 should be set to
- 'INVALID_REGNUM'.
-
- The default version of this hook returns false.
-
- -- Target Hook: machine_mode TARGET_CC_MODES_COMPATIBLE (machine_mode
- M1, machine_mode M2)
- On targets which use multiple condition code modes in class
- 'MODE_CC', it is sometimes the case that a comparison can be
- validly done in more than one mode. On such a system, define this
- target hook to take two mode arguments and to return a mode in
- which both comparisons may be validly done. If there is no such
- mode, return 'VOIDmode'.
-
- The default version of this hook checks whether the modes are the
- same. If they are, it returns that mode. If they are different,
- it returns 'VOIDmode'.
-
- -- Target Hook: unsigned int TARGET_FLAGS_REGNUM
- If the target has a dedicated flags register, and it needs to use
- the post-reload comparison elimination pass, or the delay slot
- filler pass, then this value should be set appropriately.
-
-
- File: gccint.info, Node: Costs, Next: Scheduling, Prev: Condition Code, Up: Target Macros
-
- 18.16 Describing Relative Costs of Operations
- =============================================
-
- These macros let you describe the relative speed of various operations
- on the target machine.
-
- -- Macro: REGISTER_MOVE_COST (MODE, FROM, TO)
- A C expression for the cost of moving data of mode MODE from a
- register in class FROM to one in class TO. The classes are
- expressed using the enumeration values such as 'GENERAL_REGS'. A
- value of 2 is the default; other values are interpreted relative to
- that.
-
- It is not required that the cost always equal 2 when FROM is the
- same as TO; on some machines it is expensive to move between
- registers if they are not general registers.
-
- If reload sees an insn consisting of a single 'set' between two
- hard registers, and if 'REGISTER_MOVE_COST' applied to their
- classes returns a value of 2, reload does not check to ensure that
- the constraints of the insn are met. Setting a cost of other than
- 2 will allow reload to verify that the constraints are met. You
- should do this if the 'movM' pattern's constraints do not allow
- such copying.
-
- These macros are obsolete, new ports should use the target hook
- 'TARGET_REGISTER_MOVE_COST' instead.
-
- -- Target Hook: int TARGET_REGISTER_MOVE_COST (machine_mode MODE,
- reg_class_t FROM, reg_class_t TO)
- This target hook should return the cost of moving data of mode MODE
- from a register in class FROM to one in class TO. The classes are
- expressed using the enumeration values such as 'GENERAL_REGS'. A
- value of 2 is the default; other values are interpreted relative to
- that.
-
- It is not required that the cost always equal 2 when FROM is the
- same as TO; on some machines it is expensive to move between
- registers if they are not general registers.
-
- If reload sees an insn consisting of a single 'set' between two
- hard registers, and if 'TARGET_REGISTER_MOVE_COST' applied to their
- classes returns a value of 2, reload does not check to ensure that
- the constraints of the insn are met. Setting a cost of other than
- 2 will allow reload to verify that the constraints are met. You
- should do this if the 'movM' pattern's constraints do not allow
- such copying.
-
- The default version of this function returns 2.
-
- -- Macro: MEMORY_MOVE_COST (MODE, CLASS, IN)
- A C expression for the cost of moving data of mode MODE between a
- register of class CLASS and memory; IN is zero if the value is to
- be written to memory, nonzero if it is to be read in. This cost is
- relative to those in 'REGISTER_MOVE_COST'. If moving between
- registers and memory is more expensive than between two registers,
- you should define this macro to express the relative cost.
-
- If you do not define this macro, GCC uses a default cost of 4 plus
- the cost of copying via a secondary reload register, if one is
- needed. If your machine requires a secondary reload register to
- copy between memory and a register of CLASS but the reload
- mechanism is more complex than copying via an intermediate, define
- this macro to reflect the actual cost of the move.
-
- GCC defines the function 'memory_move_secondary_cost' if secondary
- reloads are needed. It computes the costs due to copying via a
- secondary register. If your machine copies from memory using a
- secondary register in the conventional way but the default base
- value of 4 is not correct for your machine, define this macro to
- add some other value to the result of that function. The arguments
- to that function are the same as to this macro.
-
- These macros are obsolete, new ports should use the target hook
- 'TARGET_MEMORY_MOVE_COST' instead.
-
- -- Target Hook: int TARGET_MEMORY_MOVE_COST (machine_mode MODE,
- reg_class_t RCLASS, bool IN)
- This target hook should return the cost of moving data of mode MODE
- between a register of class RCLASS and memory; IN is 'false' if the
- value is to be written to memory, 'true' if it is to be read in.
- This cost is relative to those in 'TARGET_REGISTER_MOVE_COST'. If
- moving between registers and memory is more expensive than between
- two registers, you should add this target hook to express the
- relative cost.
-
- If you do not add this target hook, GCC uses a default cost of 4
- plus the cost of copying via a secondary reload register, if one is
- needed. If your machine requires a secondary reload register to
- copy between memory and a register of RCLASS but the reload
- mechanism is more complex than copying via an intermediate, use
- this target hook to reflect the actual cost of the move.
-
- GCC defines the function 'memory_move_secondary_cost' if secondary
- reloads are needed. It computes the costs due to copying via a
- secondary register. If your machine copies from memory using a
- secondary register in the conventional way but the default base
- value of 4 is not correct for your machine, use this target hook to
- add some other value to the result of that function. The arguments
- to that function are the same as to this target hook.
-
- -- Macro: BRANCH_COST (SPEED_P, PREDICTABLE_P)
- A C expression for the cost of a branch instruction. A value of 1
- is the default; other values are interpreted relative to that.
- Parameter SPEED_P is true when the branch in question should be
- optimized for speed. When it is false, 'BRANCH_COST' should return
- a value optimal for code size rather than performance.
- PREDICTABLE_P is true for well-predicted branches. On many
- architectures the 'BRANCH_COST' can be reduced then.
-
- Here are additional macros which do not specify precise relative costs,
- but only that certain actions are more expensive than GCC would
- ordinarily expect.
-
- -- Macro: SLOW_BYTE_ACCESS
- Define this macro as a C expression which is nonzero if accessing
- less than a word of memory (i.e. a 'char' or a 'short') is no
- faster than accessing a word of memory, i.e., if such access
- require more than one instruction or if there is no difference in
- cost between byte and (aligned) word loads.
-
- When this macro is not defined, the compiler will access a field by
- finding the smallest containing object; when it is defined, a
- fullword load will be used if alignment permits. Unless bytes
- accesses are faster than word accesses, using word accesses is
- preferable since it may eliminate subsequent memory access if
- subsequent accesses occur to other fields in the same word of the
- structure, but to different bytes.
-
- -- Target Hook: bool TARGET_SLOW_UNALIGNED_ACCESS (machine_mode MODE,
- unsigned int ALIGN)
- This hook returns true if memory accesses described by the MODE and
- ALIGNMENT parameters have a cost many times greater than aligned
- accesses, for example if they are emulated in a trap handler. This
- hook is invoked only for unaligned accesses, i.e. when 'ALIGNMENT <
- GET_MODE_ALIGNMENT (MODE)'.
-
- When this hook returns true, the compiler will act as if
- 'STRICT_ALIGNMENT' were true when generating code for block moves.
- This can cause significantly more instructions to be produced.
- Therefore, do not make this hook return true if unaligned accesses
- only add a cycle or two to the time for a memory access.
-
- The hook must return true whenever 'STRICT_ALIGNMENT' is true. The
- default implementation returns 'STRICT_ALIGNMENT'.
-
- -- Macro: MOVE_RATIO (SPEED)
- The threshold of number of scalar memory-to-memory move insns,
- _below_ which a sequence of insns should be generated instead of a
- string move insn or a library call. Increasing the value will
- always make code faster, but eventually incurs high cost in
- increased code size.
-
- Note that on machines where the corresponding move insn is a
- 'define_expand' that emits a sequence of insns, this macro counts
- the number of such sequences.
-
- The parameter SPEED is true if the code is currently being
- optimized for speed rather than size.
-
- If you don't define this, a reasonable default is used.
-
- -- Target Hook: bool TARGET_USE_BY_PIECES_INFRASTRUCTURE_P (unsigned
- HOST_WIDE_INT SIZE, unsigned int ALIGNMENT, enum
- by_pieces_operation OP, bool SPEED_P)
- GCC will attempt several strategies when asked to copy between two
- areas of memory, or to set, clear or store to memory, for example
- when copying a 'struct'. The 'by_pieces' infrastructure implements
- such memory operations as a sequence of load, store or move insns.
- Alternate strategies are to expand the 'cpymem' or 'setmem' optabs,
- to emit a library call, or to emit unit-by-unit, loop-based
- operations.
-
- This target hook should return true if, for a memory operation with
- a given SIZE and ALIGNMENT, using the 'by_pieces' infrastructure is
- expected to result in better code generation. Both SIZE and
- ALIGNMENT are measured in terms of storage units.
-
- The parameter OP is one of: 'CLEAR_BY_PIECES', 'MOVE_BY_PIECES',
- 'SET_BY_PIECES', 'STORE_BY_PIECES' or 'COMPARE_BY_PIECES'. These
- describe the type of memory operation under consideration.
-
- The parameter SPEED_P is true if the code is currently being
- optimized for speed rather than size.
-
- Returning true for higher values of SIZE can improve code
- generation for speed if the target does not provide an
- implementation of the 'cpymem' or 'setmem' standard names, if the
- 'cpymem' or 'setmem' implementation would be more expensive than a
- sequence of insns, or if the overhead of a library call would
- dominate that of the body of the memory operation.
-
- Returning true for higher values of 'size' may also cause an
- increase in code size, for example where the number of insns
- emitted to perform a move would be greater than that of a library
- call.
-
- -- Target Hook: int TARGET_COMPARE_BY_PIECES_BRANCH_RATIO (machine_mode
- MODE)
- When expanding a block comparison in MODE, gcc can try to reduce
- the number of branches at the expense of more memory operations.
- This hook allows the target to override the default choice. It
- should return the factor by which branches should be reduced over
- the plain expansion with one comparison per MODE-sized piece. A
- port can also prevent a particular mode from being used for block
- comparisons by returning a negative number from this hook.
-
- -- Macro: MOVE_MAX_PIECES
- A C expression used by 'move_by_pieces' to determine the largest
- unit a load or store used to copy memory is. Defaults to
- 'MOVE_MAX'.
-
- -- Macro: STORE_MAX_PIECES
- A C expression used by 'store_by_pieces' to determine the largest
- unit a store used to memory is. Defaults to 'MOVE_MAX_PIECES', or
- two times the size of 'HOST_WIDE_INT', whichever is smaller.
-
- -- Macro: COMPARE_MAX_PIECES
- A C expression used by 'compare_by_pieces' to determine the largest
- unit a load or store used to compare memory is. Defaults to
- 'MOVE_MAX_PIECES'.
-
- -- Macro: CLEAR_RATIO (SPEED)
- The threshold of number of scalar move insns, _below_ which a
- sequence of insns should be generated to clear memory instead of a
- string clear insn or a library call. Increasing the value will
- always make code faster, but eventually incurs high cost in
- increased code size.
-
- The parameter SPEED is true if the code is currently being
- optimized for speed rather than size.
-
- If you don't define this, a reasonable default is used.
-
- -- Macro: SET_RATIO (SPEED)
- The threshold of number of scalar move insns, _below_ which a
- sequence of insns should be generated to set memory to a constant
- value, instead of a block set insn or a library call. Increasing
- the value will always make code faster, but eventually incurs high
- cost in increased code size.
-
- The parameter SPEED is true if the code is currently being
- optimized for speed rather than size.
-
- If you don't define this, it defaults to the value of 'MOVE_RATIO'.
-
- -- Macro: USE_LOAD_POST_INCREMENT (MODE)
- A C expression used to determine whether a load postincrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_POST_INCREMENT'.
-
- -- Macro: USE_LOAD_POST_DECREMENT (MODE)
- A C expression used to determine whether a load postdecrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_POST_DECREMENT'.
-
- -- Macro: USE_LOAD_PRE_INCREMENT (MODE)
- A C expression used to determine whether a load preincrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_PRE_INCREMENT'.
-
- -- Macro: USE_LOAD_PRE_DECREMENT (MODE)
- A C expression used to determine whether a load predecrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_PRE_DECREMENT'.
-
- -- Macro: USE_STORE_POST_INCREMENT (MODE)
- A C expression used to determine whether a store postincrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_POST_INCREMENT'.
-
- -- Macro: USE_STORE_POST_DECREMENT (MODE)
- A C expression used to determine whether a store postdecrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_POST_DECREMENT'.
-
- -- Macro: USE_STORE_PRE_INCREMENT (MODE)
- This macro is used to determine whether a store preincrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_PRE_INCREMENT'.
-
- -- Macro: USE_STORE_PRE_DECREMENT (MODE)
- This macro is used to determine whether a store predecrement is a
- good thing to use for a given mode. Defaults to the value of
- 'HAVE_PRE_DECREMENT'.
-
- -- Macro: NO_FUNCTION_CSE
- Define this macro to be true if it is as good or better to call a
- constant function address than to call an address kept in a
- register.
-
- -- Macro: LOGICAL_OP_NON_SHORT_CIRCUIT
- Define this macro if a non-short-circuit operation produced by
- 'fold_range_test ()' is optimal. This macro defaults to true if
- 'BRANCH_COST' is greater than or equal to the value 2.
-
- -- Target Hook: bool TARGET_OPTAB_SUPPORTED_P (int OP, machine_mode
- MODE1, machine_mode MODE2, optimization_type OPT_TYPE)
- Return true if the optimizers should use optab OP with modes MODE1
- and MODE2 for optimization type OPT_TYPE. The optab is known to
- have an associated '.md' instruction whose C condition is true.
- MODE2 is only meaningful for conversion optabs; for direct optabs
- it is a copy of MODE1.
-
- For example, when called with OP equal to 'rint_optab' and MODE1
- equal to 'DFmode', the hook should say whether the optimizers
- should use optab 'rintdf2'.
-
- The default hook returns true for all inputs.
-
- -- Target Hook: bool TARGET_RTX_COSTS (rtx X, machine_mode MODE, int
- OUTER_CODE, int OPNO, int *TOTAL, bool SPEED)
- This target hook describes the relative costs of RTL expressions.
-
- The cost may depend on the precise form of the expression, which is
- available for examination in X, and the fact that X appears as
- operand OPNO of an expression with rtx code OUTER_CODE. That is,
- the hook can assume that there is some rtx Y such that 'GET_CODE
- (Y) == OUTER_CODE' and such that either (a) 'XEXP (Y, OPNO) == X'
- or (b) 'XVEC (Y, OPNO)' contains X.
-
- MODE is X's machine mode, or for cases like 'const_int' that do not
- have a mode, the mode in which X is used.
-
- In implementing this hook, you can use the construct 'COSTS_N_INSNS
- (N)' to specify a cost equal to N fast instructions.
-
- On entry to the hook, '*TOTAL' contains a default estimate for the
- cost of the expression. The hook should modify this value as
- necessary. Traditionally, the default costs are 'COSTS_N_INSNS
- (5)' for multiplications, 'COSTS_N_INSNS (7)' for division and
- modulus operations, and 'COSTS_N_INSNS (1)' for all other
- operations.
-
- When optimizing for code size, i.e. when 'speed' is false, this
- target hook should be used to estimate the relative size cost of an
- expression, again relative to 'COSTS_N_INSNS'.
-
- The hook returns true when all subexpressions of X have been
- processed, and false when 'rtx_cost' should recurse.
-
- -- Target Hook: int TARGET_ADDRESS_COST (rtx ADDRESS, machine_mode
- MODE, addr_space_t AS, bool SPEED)
- This hook computes the cost of an addressing mode that contains
- ADDRESS. If not defined, the cost is computed from the ADDRESS
- expression and the 'TARGET_RTX_COST' hook.
-
- For most CISC machines, the default cost is a good approximation of
- the true cost of the addressing mode. However, on RISC machines,
- all instructions normally have the same length and execution time.
- Hence all addresses will have equal costs.
-
- In cases where more than one form of an address is known, the form
- with the lowest cost will be used. If multiple forms have the
- same, lowest, cost, the one that is the most complex will be used.
-
- For example, suppose an address that is equal to the sum of a
- register and a constant is used twice in the same basic block.
- When this macro is not defined, the address will be computed in a
- register and memory references will be indirect through that
- register. On machines where the cost of the addressing mode
- containing the sum is no higher than that of a simple indirect
- reference, this will produce an additional instruction and possibly
- require an additional register. Proper specification of this macro
- eliminates this overhead for such machines.
-
- This hook is never called with an invalid address.
-
- On machines where an address involving more than one register is as
- cheap as an address computation involving only one register,
- defining 'TARGET_ADDRESS_COST' to reflect this can cause two
- registers to be live over a region of code where only one would
- have been if 'TARGET_ADDRESS_COST' were not defined in that manner.
- This effect should be considered in the definition of this macro.
- Equivalent costs should probably only be given to addresses with
- different numbers of registers on machines with lots of registers.
-
- -- Target Hook: int TARGET_INSN_COST (rtx_insn *INSN, bool SPEED)
- This target hook describes the relative costs of RTL instructions.
-
- In implementing this hook, you can use the construct 'COSTS_N_INSNS
- (N)' to specify a cost equal to N fast instructions.
-
- When optimizing for code size, i.e. when 'speed' is false, this
- target hook should be used to estimate the relative size cost of an
- expression, again relative to 'COSTS_N_INSNS'.
-
- -- Target Hook: unsigned int TARGET_MAX_NOCE_IFCVT_SEQ_COST (edge E)
- This hook returns a value in the same units as 'TARGET_RTX_COSTS',
- giving the maximum acceptable cost for a sequence generated by the
- RTL if-conversion pass when conditional execution is not available.
- The RTL if-conversion pass attempts to convert conditional
- operations that would require a branch to a series of unconditional
- operations and 'movMODEcc' insns. This hook returns the maximum
- cost of the unconditional instructions and the 'movMODEcc' insns.
- RTL if-conversion is cancelled if the cost of the converted
- sequence is greater than the value returned by this hook.
-
- 'e' is the edge between the basic block containing the conditional
- branch to the basic block which would be executed if the condition
- were true.
-
- The default implementation of this hook uses the
- 'max-rtl-if-conversion-[un]predictable' parameters if they are set,
- and uses a multiple of 'BRANCH_COST' otherwise.
-
- -- Target Hook: bool TARGET_NOCE_CONVERSION_PROFITABLE_P (rtx_insn
- *SEQ, struct noce_if_info *IF_INFO)
- This hook returns true if the instruction sequence 'seq' is a good
- candidate as a replacement for the if-convertible sequence
- described in 'if_info'.
-
- -- Target Hook: bool TARGET_NO_SPECULATION_IN_DELAY_SLOTS_P (void)
- This predicate controls the use of the eager delay slot filler to
- disallow speculatively executed instructions being placed in delay
- slots. Targets such as certain MIPS architectures possess both
- branches with and without delay slots. As the eager delay slot
- filler can decrease performance, disabling it is beneficial when
- ordinary branches are available. Use of delay slot branches filled
- using the basic filler is often still desirable as the delay slot
- can hide a pipeline bubble.
-
- -- Target Hook: HOST_WIDE_INT TARGET_ESTIMATED_POLY_VALUE (poly_int64
- VAL)
- Return an estimate of the runtime value of VAL, for use in things
- like cost calculations or profiling frequencies. The default
- implementation returns the lowest possible value of VAL.
-
-
- File: gccint.info, Node: Scheduling, Next: Sections, Prev: Costs, Up: Target Macros
-
- 18.17 Adjusting the Instruction Scheduler
- =========================================
-
- The instruction scheduler may need a fair amount of machine-specific
- adjustment in order to produce good code. GCC provides several target
- hooks for this purpose. It is usually enough to define just a few of
- them: try the first ones in this list first.
-
- -- Target Hook: int TARGET_SCHED_ISSUE_RATE (void)
- This hook returns the maximum number of instructions that can ever
- issue at the same time on the target machine. The default is one.
- Although the insn scheduler can define itself the possibility of
- issue an insn on the same cycle, the value can serve as an
- additional constraint to issue insns on the same simulated
- processor cycle (see hooks 'TARGET_SCHED_REORDER' and
- 'TARGET_SCHED_REORDER2'). This value must be constant over the
- entire compilation. If you need it to vary depending on what the
- instructions are, you must use 'TARGET_SCHED_VARIABLE_ISSUE'.
-
- -- Target Hook: int TARGET_SCHED_VARIABLE_ISSUE (FILE *FILE, int
- VERBOSE, rtx_insn *INSN, int MORE)
- This hook is executed by the scheduler after it has scheduled an
- insn from the ready list. It should return the number of insns
- which can still be issued in the current cycle. The default is
- 'MORE - 1' for insns other than 'CLOBBER' and 'USE', which normally
- are not counted against the issue rate. You should define this
- hook if some insns take more machine resources than others, so that
- fewer insns can follow them in the same cycle. FILE is either a
- null pointer, or a stdio stream to write any debug output to.
- VERBOSE is the verbose level provided by '-fsched-verbose-N'. INSN
- is the instruction that was scheduled.
-
- -- Target Hook: int TARGET_SCHED_ADJUST_COST (rtx_insn *INSN, int
- DEP_TYPE1, rtx_insn *DEP_INSN, int COST, unsigned int DW)
- This function corrects the value of COST based on the relationship
- between INSN and DEP_INSN through a dependence of type dep_type,
- and strength DW. It should return the new value. The default is
- to make no adjustment to COST. This can be used for example to
- specify to the scheduler using the traditional pipeline description
- that an output- or anti-dependence does not incur the same cost as
- a data-dependence. If the scheduler using the automaton based
- pipeline description, the cost of anti-dependence is zero and the
- cost of output-dependence is maximum of one and the difference of
- latency times of the first and the second insns. If these values
- are not acceptable, you could use the hook to modify them too. See
- also *note Processor pipeline description::.
-
- -- Target Hook: int TARGET_SCHED_ADJUST_PRIORITY (rtx_insn *INSN, int
- PRIORITY)
- This hook adjusts the integer scheduling priority PRIORITY of INSN.
- It should return the new priority. Increase the priority to
- execute INSN earlier, reduce the priority to execute INSN later.
- Do not define this hook if you do not need to adjust the scheduling
- priorities of insns.
-
- -- Target Hook: int TARGET_SCHED_REORDER (FILE *FILE, int VERBOSE,
- rtx_insn **READY, int *N_READYP, int CLOCK)
- This hook is executed by the scheduler after it has scheduled the
- ready list, to allow the machine description to reorder it (for
- example to combine two small instructions together on 'VLIW'
- machines). FILE is either a null pointer, or a stdio stream to
- write any debug output to. VERBOSE is the verbose level provided
- by '-fsched-verbose-N'. READY is a pointer to the ready list of
- instructions that are ready to be scheduled. N_READYP is a pointer
- to the number of elements in the ready list. The scheduler reads
- the ready list in reverse order, starting with READY[*N_READYP - 1]
- and going to READY[0]. CLOCK is the timer tick of the scheduler.
- You may modify the ready list and the number of ready insns. The
- return value is the number of insns that can issue this cycle;
- normally this is just 'issue_rate'. See also
- 'TARGET_SCHED_REORDER2'.
-
- -- Target Hook: int TARGET_SCHED_REORDER2 (FILE *FILE, int VERBOSE,
- rtx_insn **READY, int *N_READYP, int CLOCK)
- Like 'TARGET_SCHED_REORDER', but called at a different time. That
- function is called whenever the scheduler starts a new cycle. This
- one is called once per iteration over a cycle, immediately after
- 'TARGET_SCHED_VARIABLE_ISSUE'; it can reorder the ready list and
- return the number of insns to be scheduled in the same cycle.
- Defining this hook can be useful if there are frequent situations
- where scheduling one insn causes other insns to become ready in the
- same cycle. These other insns can then be taken into account
- properly.
-
- -- Target Hook: bool TARGET_SCHED_MACRO_FUSION_P (void)
- This hook is used to check whether target platform supports macro
- fusion.
-
- -- Target Hook: bool TARGET_SCHED_MACRO_FUSION_PAIR_P (rtx_insn *PREV,
- rtx_insn *CURR)
- This hook is used to check whether two insns should be macro fused
- for a target microarchitecture. If this hook returns true for the
- given insn pair (PREV and CURR), the scheduler will put them into a
- sched group, and they will not be scheduled apart. The two insns
- will be either two SET insns or a compare and a conditional jump
- and this hook should validate any dependencies needed to fuse the
- two insns together.
-
- -- Target Hook: void TARGET_SCHED_DEPENDENCIES_EVALUATION_HOOK
- (rtx_insn *HEAD, rtx_insn *TAIL)
- This hook is called after evaluation forward dependencies of insns
- in chain given by two parameter values (HEAD and TAIL
- correspondingly) but before insns scheduling of the insn chain.
- For example, it can be used for better insn classification if it
- requires analysis of dependencies. This hook can use backward and
- forward dependencies of the insn scheduler because they are already
- calculated.
-
- -- Target Hook: void TARGET_SCHED_INIT (FILE *FILE, int VERBOSE, int
- MAX_READY)
- This hook is executed by the scheduler at the beginning of each
- block of instructions that are to be scheduled. FILE is either a
- null pointer, or a stdio stream to write any debug output to.
- VERBOSE is the verbose level provided by '-fsched-verbose-N'.
- MAX_READY is the maximum number of insns in the current scheduling
- region that can be live at the same time. This can be used to
- allocate scratch space if it is needed, e.g. by
- 'TARGET_SCHED_REORDER'.
-
- -- Target Hook: void TARGET_SCHED_FINISH (FILE *FILE, int VERBOSE)
- This hook is executed by the scheduler at the end of each block of
- instructions that are to be scheduled. It can be used to perform
- cleanup of any actions done by the other scheduling hooks. FILE is
- either a null pointer, or a stdio stream to write any debug output
- to. VERBOSE is the verbose level provided by '-fsched-verbose-N'.
-
- -- Target Hook: void TARGET_SCHED_INIT_GLOBAL (FILE *FILE, int VERBOSE,
- int OLD_MAX_UID)
- This hook is executed by the scheduler after function level
- initializations. FILE is either a null pointer, or a stdio stream
- to write any debug output to. VERBOSE is the verbose level
- provided by '-fsched-verbose-N'. OLD_MAX_UID is the maximum insn
- uid when scheduling begins.
-
- -- Target Hook: void TARGET_SCHED_FINISH_GLOBAL (FILE *FILE, int
- VERBOSE)
- This is the cleanup hook corresponding to
- 'TARGET_SCHED_INIT_GLOBAL'. FILE is either a null pointer, or a
- stdio stream to write any debug output to. VERBOSE is the verbose
- level provided by '-fsched-verbose-N'.
-
- -- Target Hook: rtx TARGET_SCHED_DFA_PRE_CYCLE_INSN (void)
- The hook returns an RTL insn. The automaton state used in the
- pipeline hazard recognizer is changed as if the insn were scheduled
- when the new simulated processor cycle starts. Usage of the hook
- may simplify the automaton pipeline description for some VLIW
- processors. If the hook is defined, it is used only for the
- automaton based pipeline description. The default is not to change
- the state when the new simulated processor cycle starts.
-
- -- Target Hook: void TARGET_SCHED_INIT_DFA_PRE_CYCLE_INSN (void)
- The hook can be used to initialize data used by the previous hook.
-
- -- Target Hook: rtx_insn * TARGET_SCHED_DFA_POST_CYCLE_INSN (void)
- The hook is analogous to 'TARGET_SCHED_DFA_PRE_CYCLE_INSN' but used
- to changed the state as if the insn were scheduled when the new
- simulated processor cycle finishes.
-
- -- Target Hook: void TARGET_SCHED_INIT_DFA_POST_CYCLE_INSN (void)
- The hook is analogous to 'TARGET_SCHED_INIT_DFA_PRE_CYCLE_INSN' but
- used to initialize data used by the previous hook.
-
- -- Target Hook: void TARGET_SCHED_DFA_PRE_ADVANCE_CYCLE (void)
- The hook to notify target that the current simulated cycle is about
- to finish. The hook is analogous to
- 'TARGET_SCHED_DFA_PRE_CYCLE_INSN' but used to change the state in
- more complicated situations - e.g., when advancing state on a
- single insn is not enough.
-
- -- Target Hook: void TARGET_SCHED_DFA_POST_ADVANCE_CYCLE (void)
- The hook to notify target that new simulated cycle has just
- started. The hook is analogous to
- 'TARGET_SCHED_DFA_POST_CYCLE_INSN' but used to change the state in
- more complicated situations - e.g., when advancing state on a
- single insn is not enough.
-
- -- Target Hook: int TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD
- (void)
- This hook controls better choosing an insn from the ready insn
- queue for the DFA-based insn scheduler. Usually the scheduler
- chooses the first insn from the queue. If the hook returns a
- positive value, an additional scheduler code tries all permutations
- of 'TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD ()' subsequent
- ready insns to choose an insn whose issue will result in maximal
- number of issued insns on the same cycle. For the VLIW processor,
- the code could actually solve the problem of packing simple insns
- into the VLIW insn. Of course, if the rules of VLIW packing are
- described in the automaton.
-
- This code also could be used for superscalar RISC processors. Let
- us consider a superscalar RISC processor with 3 pipelines. Some
- insns can be executed in pipelines A or B, some insns can be
- executed only in pipelines B or C, and one insn can be executed in
- pipeline B. The processor may issue the 1st insn into A and the
- 2nd one into B. In this case, the 3rd insn will wait for freeing B
- until the next cycle. If the scheduler issues the 3rd insn the
- first, the processor could issue all 3 insns per cycle.
-
- Actually this code demonstrates advantages of the automaton based
- pipeline hazard recognizer. We try quickly and easy many insn
- schedules to choose the best one.
-
- The default is no multipass scheduling.
-
- -- Target Hook: int
- TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD_GUARD
- (rtx_insn *INSN, int READY_INDEX)
-
- This hook controls what insns from the ready insn queue will be
- considered for the multipass insn scheduling. If the hook returns
- zero for INSN, the insn will be considered in multipass scheduling.
- Positive return values will remove INSN from consideration on the
- current round of multipass scheduling. Negative return values will
- remove INSN from consideration for given number of cycles.
- Backends should be careful about returning non-zero for highest
- priority instruction at position 0 in the ready list. READY_INDEX
- is passed to allow backends make correct judgements.
-
- The default is that any ready insns can be chosen to be issued.
-
- -- Target Hook: void TARGET_SCHED_FIRST_CYCLE_MULTIPASS_BEGIN (void
- *DATA, signed char *READY_TRY, int N_READY, bool
- FIRST_CYCLE_INSN_P)
- This hook prepares the target backend for a new round of multipass
- scheduling.
-
- -- Target Hook: void TARGET_SCHED_FIRST_CYCLE_MULTIPASS_ISSUE (void
- *DATA, signed char *READY_TRY, int N_READY, rtx_insn *INSN,
- const void *PREV_DATA)
- This hook is called when multipass scheduling evaluates instruction
- INSN.
-
- -- Target Hook: void TARGET_SCHED_FIRST_CYCLE_MULTIPASS_BACKTRACK
- (const void *DATA, signed char *READY_TRY, int N_READY)
- This is called when multipass scheduling backtracks from evaluation
- of an instruction.
-
- -- Target Hook: void TARGET_SCHED_FIRST_CYCLE_MULTIPASS_END (const void
- *DATA)
- This hook notifies the target about the result of the concluded
- current round of multipass scheduling.
-
- -- Target Hook: void TARGET_SCHED_FIRST_CYCLE_MULTIPASS_INIT (void
- *DATA)
- This hook initializes target-specific data used in multipass
- scheduling.
-
- -- Target Hook: void TARGET_SCHED_FIRST_CYCLE_MULTIPASS_FINI (void
- *DATA)
- This hook finalizes target-specific data used in multipass
- scheduling.
-
- -- Target Hook: int TARGET_SCHED_DFA_NEW_CYCLE (FILE *DUMP, int
- VERBOSE, rtx_insn *INSN, int LAST_CLOCK, int CLOCK, int
- *SORT_P)
- This hook is called by the insn scheduler before issuing INSN on
- cycle CLOCK. If the hook returns nonzero, INSN is not issued on
- this processor cycle. Instead, the processor cycle is advanced.
- If *SORT_P is zero, the insn ready queue is not sorted on the new
- cycle start as usually. DUMP and VERBOSE specify the file and
- verbosity level to use for debugging output. LAST_CLOCK and CLOCK
- are, respectively, the processor cycle on which the previous insn
- has been issued, and the current processor cycle.
-
- -- Target Hook: bool TARGET_SCHED_IS_COSTLY_DEPENDENCE (struct _dep
- *_DEP, int COST, int DISTANCE)
- This hook is used to define which dependences are considered costly
- by the target, so costly that it is not advisable to schedule the
- insns that are involved in the dependence too close to one another.
- The parameters to this hook are as follows: The first parameter
- _DEP is the dependence being evaluated. The second parameter COST
- is the cost of the dependence as estimated by the scheduler, and
- the third parameter DISTANCE is the distance in cycles between the
- two insns. The hook returns 'true' if considering the distance
- between the two insns the dependence between them is considered
- costly by the target, and 'false' otherwise.
-
- Defining this hook can be useful in multiple-issue out-of-order
- machines, where (a) it's practically hopeless to predict the actual
- data/resource delays, however: (b) there's a better chance to
- predict the actual grouping that will be formed, and (c) correctly
- emulating the grouping can be very important. In such targets one
- may want to allow issuing dependent insns closer to one
- another--i.e., closer than the dependence distance; however, not in
- cases of "costly dependences", which this hooks allows to define.
-
- -- Target Hook: void TARGET_SCHED_H_I_D_EXTENDED (void)
- This hook is called by the insn scheduler after emitting a new
- instruction to the instruction stream. The hook notifies a target
- backend to extend its per instruction data structures.
-
- -- Target Hook: void * TARGET_SCHED_ALLOC_SCHED_CONTEXT (void)
- Return a pointer to a store large enough to hold target scheduling
- context.
-
- -- Target Hook: void TARGET_SCHED_INIT_SCHED_CONTEXT (void *TC, bool
- CLEAN_P)
- Initialize store pointed to by TC to hold target scheduling
- context. It CLEAN_P is true then initialize TC as if scheduler is
- at the beginning of the block. Otherwise, copy the current context
- into TC.
-
- -- Target Hook: void TARGET_SCHED_SET_SCHED_CONTEXT (void *TC)
- Copy target scheduling context pointed to by TC to the current
- context.
-
- -- Target Hook: void TARGET_SCHED_CLEAR_SCHED_CONTEXT (void *TC)
- Deallocate internal data in target scheduling context pointed to by
- TC.
-
- -- Target Hook: void TARGET_SCHED_FREE_SCHED_CONTEXT (void *TC)
- Deallocate a store for target scheduling context pointed to by TC.
-
- -- Target Hook: int TARGET_SCHED_SPECULATE_INSN (rtx_insn *INSN,
- unsigned int DEP_STATUS, rtx *NEW_PAT)
- This hook is called by the insn scheduler when INSN has only
- speculative dependencies and therefore can be scheduled
- speculatively. The hook is used to check if the pattern of INSN
- has a speculative version and, in case of successful check, to
- generate that speculative pattern. The hook should return 1, if
- the instruction has a speculative form, or -1, if it doesn't.
- REQUEST describes the type of requested speculation. If the return
- value equals 1 then NEW_PAT is assigned the generated speculative
- pattern.
-
- -- Target Hook: bool TARGET_SCHED_NEEDS_BLOCK_P (unsigned int
- DEP_STATUS)
- This hook is called by the insn scheduler during generation of
- recovery code for INSN. It should return 'true', if the
- corresponding check instruction should branch to recovery code, or
- 'false' otherwise.
-
- -- Target Hook: rtx TARGET_SCHED_GEN_SPEC_CHECK (rtx_insn *INSN,
- rtx_insn *LABEL, unsigned int DS)
- This hook is called by the insn scheduler to generate a pattern for
- recovery check instruction. If MUTATE_P is zero, then INSN is a
- speculative instruction for which the check should be generated.
- LABEL is either a label of a basic block, where recovery code
- should be emitted, or a null pointer, when requested check doesn't
- branch to recovery code (a simple check). If MUTATE_P is nonzero,
- then a pattern for a branchy check corresponding to a simple check
- denoted by INSN should be generated. In this case LABEL can't be
- null.
-
- -- Target Hook: void TARGET_SCHED_SET_SCHED_FLAGS (struct spec_info_def
- *SPEC_INFO)
- This hook is used by the insn scheduler to find out what features
- should be enabled/used. The structure *SPEC_INFO should be filled
- in by the target. The structure describes speculation types that
- can be used in the scheduler.
-
- -- Target Hook: bool TARGET_SCHED_CAN_SPECULATE_INSN (rtx_insn *INSN)
- Some instructions should never be speculated by the schedulers,
- usually because the instruction is too expensive to get this wrong.
- Often such instructions have long latency, and often they are not
- fully modeled in the pipeline descriptions. This hook should
- return 'false' if INSN should not be speculated.
-
- -- Target Hook: int TARGET_SCHED_SMS_RES_MII (struct ddg *G)
- This hook is called by the swing modulo scheduler to calculate a
- resource-based lower bound which is based on the resources
- available in the machine and the resources required by each
- instruction. The target backend can use G to calculate such bound.
- A very simple lower bound will be used in case this hook is not
- implemented: the total number of instructions divided by the issue
- rate.
-
- -- Target Hook: bool TARGET_SCHED_DISPATCH (rtx_insn *INSN, int X)
- This hook is called by Haifa Scheduler. It returns true if
- dispatch scheduling is supported in hardware and the condition
- specified in the parameter is true.
-
- -- Target Hook: void TARGET_SCHED_DISPATCH_DO (rtx_insn *INSN, int X)
- This hook is called by Haifa Scheduler. It performs the operation
- specified in its second parameter.
-
- -- Target Hook: bool TARGET_SCHED_EXPOSED_PIPELINE
- True if the processor has an exposed pipeline, which means that not
- just the order of instructions is important for correctness when
- scheduling, but also the latencies of operations.
-
- -- Target Hook: int TARGET_SCHED_REASSOCIATION_WIDTH (unsigned int OPC,
- machine_mode MODE)
- This hook is called by tree reassociator to determine a level of
- parallelism required in output calculations chain.
-
- -- Target Hook: void TARGET_SCHED_FUSION_PRIORITY (rtx_insn *INSN, int
- MAX_PRI, int *FUSION_PRI, int *PRI)
- This hook is called by scheduling fusion pass. It calculates
- fusion priorities for each instruction passed in by parameter. The
- priorities are returned via pointer parameters.
-
- INSN is the instruction whose priorities need to be calculated.
- MAX_PRI is the maximum priority can be returned in any cases.
- FUSION_PRI is the pointer parameter through which INSN's fusion
- priority should be calculated and returned. PRI is the pointer
- parameter through which INSN's priority should be calculated and
- returned.
-
- Same FUSION_PRI should be returned for instructions which should be
- scheduled together. Different PRI should be returned for
- instructions with same FUSION_PRI. FUSION_PRI is the major sort
- key, PRI is the minor sort key. All instructions will be scheduled
- according to the two priorities. All priorities calculated should
- be between 0 (exclusive) and MAX_PRI (inclusive). To avoid false
- dependencies, FUSION_PRI of instructions which need to be scheduled
- together should be smaller than FUSION_PRI of irrelevant
- instructions.
-
- Given below example:
-
- ldr r10, [r1, 4]
- add r4, r4, r10
- ldr r15, [r2, 8]
- sub r5, r5, r15
- ldr r11, [r1, 0]
- add r4, r4, r11
- ldr r16, [r2, 12]
- sub r5, r5, r16
-
- On targets like ARM/AArch64, the two pairs of consecutive loads
- should be merged. Since peephole2 pass can't help in this case
- unless consecutive loads are actually next to each other in
- instruction flow. That's where this scheduling fusion pass works.
- This hook calculates priority for each instruction based on its
- fustion type, like:
-
- ldr r10, [r1, 4] ; fusion_pri=99, pri=96
- add r4, r4, r10 ; fusion_pri=100, pri=100
- ldr r15, [r2, 8] ; fusion_pri=98, pri=92
- sub r5, r5, r15 ; fusion_pri=100, pri=100
- ldr r11, [r1, 0] ; fusion_pri=99, pri=100
- add r4, r4, r11 ; fusion_pri=100, pri=100
- ldr r16, [r2, 12] ; fusion_pri=98, pri=88
- sub r5, r5, r16 ; fusion_pri=100, pri=100
-
- Scheduling fusion pass then sorts all ready to issue instructions
- according to the priorities. As a result, instructions of same
- fusion type will be pushed together in instruction flow, like:
-
- ldr r11, [r1, 0]
- ldr r10, [r1, 4]
- ldr r15, [r2, 8]
- ldr r16, [r2, 12]
- add r4, r4, r10
- sub r5, r5, r15
- add r4, r4, r11
- sub r5, r5, r16
-
- Now peephole2 pass can simply merge the two pairs of loads.
-
- Since scheduling fusion pass relies on peephole2 to do real fusion
- work, it is only enabled by default when peephole2 is in effect.
-
- This is firstly introduced on ARM/AArch64 targets, please refer to
- the hook implementation for how different fusion types are
- supported.
-
- -- Target Hook: void TARGET_EXPAND_DIVMOD_LIBFUNC (rtx LIBFUNC,
- machine_mode MODE, rtx OP0, rtx OP1, rtx *QUOT, rtx *REM)
- Define this hook for enabling divmod transform if the port does not
- have hardware divmod insn but defines target-specific divmod
- libfuncs.
-
-
- File: gccint.info, Node: Sections, Next: PIC, Prev: Scheduling, Up: Target Macros
-
- 18.18 Dividing the Output into Sections (Texts, Data, ...)
- ==========================================================
-
- An object file is divided into sections containing different types of
- data. In the most common case, there are three sections: the "text
- section", which holds instructions and read-only data; the "data
- section", which holds initialized writable data; and the "bss section",
- which holds uninitialized data. Some systems have other kinds of
- sections.
-
- 'varasm.c' provides several well-known sections, such as
- 'text_section', 'data_section' and 'bss_section'. The normal way of
- controlling a 'FOO_section' variable is to define the associated
- 'FOO_SECTION_ASM_OP' macro, as described below. The macros are only
- read once, when 'varasm.c' initializes itself, so their values must be
- run-time constants. They may however depend on command-line flags.
-
- _Note:_ Some run-time files, such 'crtstuff.c', also make use of the
- 'FOO_SECTION_ASM_OP' macros, and expect them to be string literals.
-
- Some assemblers require a different string to be written every time a
- section is selected. If your assembler falls into this category, you
- should define the 'TARGET_ASM_INIT_SECTIONS' hook and use
- 'get_unnamed_section' to set up the sections.
-
- You must always create a 'text_section', either by defining
- 'TEXT_SECTION_ASM_OP' or by initializing 'text_section' in
- 'TARGET_ASM_INIT_SECTIONS'. The same is true of 'data_section' and
- 'DATA_SECTION_ASM_OP'. If you do not create a distinct
- 'readonly_data_section', the default is to reuse 'text_section'.
-
- All the other 'varasm.c' sections are optional, and are null if the
- target does not provide them.
-
- -- Macro: TEXT_SECTION_ASM_OP
- A C expression whose value is a string, including spacing,
- containing the assembler operation that should precede instructions
- and read-only data. Normally '"\t.text"' is right.
-
- -- Macro: HOT_TEXT_SECTION_NAME
- If defined, a C string constant for the name of the section
- containing most frequently executed functions of the program. If
- not defined, GCC will provide a default definition if the target
- supports named sections.
-
- -- Macro: UNLIKELY_EXECUTED_TEXT_SECTION_NAME
- If defined, a C string constant for the name of the section
- containing unlikely executed functions in the program.
-
- -- Macro: DATA_SECTION_ASM_OP
- A C expression whose value is a string, including spacing,
- containing the assembler operation to identify the following data
- as writable initialized data. Normally '"\t.data"' is right.
-
- -- Macro: SDATA_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as initialized, writable small data.
-
- -- Macro: READONLY_DATA_SECTION_ASM_OP
- A C expression whose value is a string, including spacing,
- containing the assembler operation to identify the following data
- as read-only initialized data.
-
- -- Macro: BSS_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as uninitialized global data. If not defined, and
- 'ASM_OUTPUT_ALIGNED_BSS' not defined, uninitialized global data
- will be output in the data section if '-fno-common' is passed,
- otherwise 'ASM_OUTPUT_COMMON' will be used.
-
- -- Macro: SBSS_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as uninitialized, writable small data.
-
- -- Macro: TLS_COMMON_ASM_OP
- If defined, a C expression whose value is a string containing the
- assembler operation to identify the following data as thread-local
- common data. The default is '".tls_common"'.
-
- -- Macro: TLS_SECTION_ASM_FLAG
- If defined, a C expression whose value is a character constant
- containing the flag used to mark a section as a TLS section. The
- default is ''T''.
-
- -- Macro: INIT_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as initialization code. If not defined, GCC will
- assume such a section does not exist. This section has no
- corresponding 'init_section' variable; it is used entirely in
- runtime code.
-
- -- Macro: FINI_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as finalization code. If not defined, GCC will
- assume such a section does not exist. This section has no
- corresponding 'fini_section' variable; it is used entirely in
- runtime code.
-
- -- Macro: INIT_ARRAY_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as part of the '.init_array' (or equivalent)
- section. If not defined, GCC will assume such a section does not
- exist. Do not define both this macro and 'INIT_SECTION_ASM_OP'.
-
- -- Macro: FINI_ARRAY_SECTION_ASM_OP
- If defined, a C expression whose value is a string, including
- spacing, containing the assembler operation to identify the
- following data as part of the '.fini_array' (or equivalent)
- section. If not defined, GCC will assume such a section does not
- exist. Do not define both this macro and 'FINI_SECTION_ASM_OP'.
-
- -- Macro: MACH_DEP_SECTION_ASM_FLAG
- If defined, a C expression whose value is a character constant
- containing the flag used to mark a machine-dependent section. This
- corresponds to the 'SECTION_MACH_DEP' section flag.
-
- -- Macro: CRT_CALL_STATIC_FUNCTION (SECTION_OP, FUNCTION)
- If defined, an ASM statement that switches to a different section
- via SECTION_OP, calls FUNCTION, and switches back to the text
- section. This is used in 'crtstuff.c' if 'INIT_SECTION_ASM_OP' or
- 'FINI_SECTION_ASM_OP' to calls to initialization and finalization
- functions from the init and fini sections. By default, this macro
- uses a simple function call. Some ports need hand-crafted assembly
- code to avoid dependencies on registers initialized in the function
- prologue or to ensure that constant pools don't end up too far way
- in the text section.
-
- -- Macro: TARGET_LIBGCC_SDATA_SECTION
- If defined, a string which names the section into which small
- variables defined in crtstuff and libgcc should go. This is useful
- when the target has options for optimizing access to small data,
- and you want the crtstuff and libgcc routines to be conservative in
- what they expect of your application yet liberal in what your
- application expects. For example, for targets with a '.sdata'
- section (like MIPS), you could compile crtstuff with '-G 0' so that
- it doesn't require small data support from your application, but
- use this macro to put small data into '.sdata' so that your
- application can access these variables whether it uses small data
- or not.
-
- -- Macro: FORCE_CODE_SECTION_ALIGN
- If defined, an ASM statement that aligns a code section to some
- arbitrary boundary. This is used to force all fragments of the
- '.init' and '.fini' sections to have to same alignment and thus
- prevent the linker from having to add any padding.
-
- -- Macro: JUMP_TABLES_IN_TEXT_SECTION
- Define this macro to be an expression with a nonzero value if jump
- tables (for 'tablejump' insns) should be output in the text
- section, along with the assembler instructions. Otherwise, the
- readonly data section is used.
-
- This macro is irrelevant if there is no separate readonly data
- section.
-
- -- Target Hook: void TARGET_ASM_INIT_SECTIONS (void)
- Define this hook if you need to do something special to set up the
- 'varasm.c' sections, or if your target has some special sections of
- its own that you need to create.
-
- GCC calls this hook after processing the command line, but before
- writing any assembly code, and before calling any of the
- section-returning hooks described below.
-
- -- Target Hook: int TARGET_ASM_RELOC_RW_MASK (void)
- Return a mask describing how relocations should be treated when
- selecting sections. Bit 1 should be set if global relocations
- should be placed in a read-write section; bit 0 should be set if
- local relocations should be placed in a read-write section.
-
- The default version of this function returns 3 when '-fpic' is in
- effect, and 0 otherwise. The hook is typically redefined when the
- target cannot support (some kinds of) dynamic relocations in
- read-only sections even in executables.
-
- -- Target Hook: bool TARGET_ASM_GENERATE_PIC_ADDR_DIFF_VEC (void)
- Return true to generate ADDR_DIF_VEC table or false to generate
- ADDR_VEC table for jumps in case of -fPIC.
-
- The default version of this function returns true if flag_pic
- equals true and false otherwise
-
- -- Target Hook: section * TARGET_ASM_SELECT_SECTION (tree EXP, int
- RELOC, unsigned HOST_WIDE_INT ALIGN)
- Return the section into which EXP should be placed. You can assume
- that EXP is either a 'VAR_DECL' node or a constant of some sort.
- RELOC indicates whether the initial value of EXP requires link-time
- relocations. Bit 0 is set when variable contains local relocations
- only, while bit 1 is set for global relocations. ALIGN is the
- constant alignment in bits.
-
- The default version of this function takes care of putting
- read-only variables in 'readonly_data_section'.
-
- See also USE_SELECT_SECTION_FOR_FUNCTIONS.
-
- -- Macro: USE_SELECT_SECTION_FOR_FUNCTIONS
- Define this macro if you wish TARGET_ASM_SELECT_SECTION to be
- called for 'FUNCTION_DECL's as well as for variables and constants.
-
- In the case of a 'FUNCTION_DECL', RELOC will be zero if the
- function has been determined to be likely to be called, and nonzero
- if it is unlikely to be called.
-
- -- Target Hook: void TARGET_ASM_UNIQUE_SECTION (tree DECL, int RELOC)
- Build up a unique section name, expressed as a 'STRING_CST' node,
- and assign it to 'DECL_SECTION_NAME (DECL)'. As with
- 'TARGET_ASM_SELECT_SECTION', RELOC indicates whether the initial
- value of EXP requires link-time relocations.
-
- The default version of this function appends the symbol name to the
- ELF section name that would normally be used for the symbol. For
- example, the function 'foo' would be placed in '.text.foo'.
- Whatever the actual target object format, this is often good
- enough.
-
- -- Target Hook: section * TARGET_ASM_FUNCTION_RODATA_SECTION (tree
- DECL)
- Return the readonly data section associated with 'DECL_SECTION_NAME
- (DECL)'. The default version of this function selects
- '.gnu.linkonce.r.name' if the function's section is
- '.gnu.linkonce.t.name', '.rodata.name' if function is in
- '.text.name', and the normal readonly-data section otherwise.
-
- -- Target Hook: const char * TARGET_ASM_MERGEABLE_RODATA_PREFIX
- Usually, the compiler uses the prefix '".rodata"' to construct
- section names for mergeable constant data. Define this macro to
- override the string if a different section name should be used.
-
- -- Target Hook: section * TARGET_ASM_TM_CLONE_TABLE_SECTION (void)
- Return the section that should be used for transactional memory
- clone tables.
-
- -- Target Hook: section * TARGET_ASM_SELECT_RTX_SECTION (machine_mode
- MODE, rtx X, unsigned HOST_WIDE_INT ALIGN)
- Return the section into which a constant X, of mode MODE, should be
- placed. You can assume that X is some kind of constant in RTL.
- The argument MODE is redundant except in the case of a 'const_int'
- rtx. ALIGN is the constant alignment in bits.
-
- The default version of this function takes care of putting symbolic
- constants in 'flag_pic' mode in 'data_section' and everything else
- in 'readonly_data_section'.
-
- -- Target Hook: tree TARGET_MANGLE_DECL_ASSEMBLER_NAME (tree DECL, tree
- ID)
- Define this hook if you need to postprocess the assembler name
- generated by target-independent code. The ID provided to this hook
- will be the computed name (e.g., the macro 'DECL_NAME' of the DECL
- in C, or the mangled name of the DECL in C++). The return value of
- the hook is an 'IDENTIFIER_NODE' for the appropriate mangled name
- on your target system. The default implementation of this hook
- just returns the ID provided.
-
- -- Target Hook: void TARGET_ENCODE_SECTION_INFO (tree DECL, rtx RTL,
- int NEW_DECL_P)
- Define this hook if references to a symbol or a constant must be
- treated differently depending on something about the variable or
- function named by the symbol (such as what section it is in).
-
- The hook is executed immediately after rtl has been created for
- DECL, which may be a variable or function declaration or an entry
- in the constant pool. In either case, RTL is the rtl in question.
- Do _not_ use 'DECL_RTL (DECL)' in this hook; that field may not
- have been initialized yet.
-
- In the case of a constant, it is safe to assume that the rtl is a
- 'mem' whose address is a 'symbol_ref'. Most decls will also have
- this form, but that is not guaranteed. Global register variables,
- for instance, will have a 'reg' for their rtl. (Normally the right
- thing to do with such unusual rtl is leave it alone.)
-
- The NEW_DECL_P argument will be true if this is the first time that
- 'TARGET_ENCODE_SECTION_INFO' has been invoked on this decl. It
- will be false for subsequent invocations, which will happen for
- duplicate declarations. Whether or not anything must be done for
- the duplicate declaration depends on whether the hook examines
- 'DECL_ATTRIBUTES'. NEW_DECL_P is always true when the hook is
- called for a constant.
-
- The usual thing for this hook to do is to record flags in the
- 'symbol_ref', using 'SYMBOL_REF_FLAG' or 'SYMBOL_REF_FLAGS'.
- Historically, the name string was modified if it was necessary to
- encode more than one bit of information, but this practice is now
- discouraged; use 'SYMBOL_REF_FLAGS'.
-
- The default definition of this hook, 'default_encode_section_info'
- in 'varasm.c', sets a number of commonly-useful bits in
- 'SYMBOL_REF_FLAGS'. Check whether the default does what you need
- before overriding it.
-
- -- Target Hook: const char * TARGET_STRIP_NAME_ENCODING (const char
- *NAME)
- Decode NAME and return the real name part, sans the characters that
- 'TARGET_ENCODE_SECTION_INFO' may have added.
-
- -- Target Hook: bool TARGET_IN_SMALL_DATA_P (const_tree EXP)
- Returns true if EXP should be placed into a "small data" section.
- The default version of this hook always returns false.
-
- -- Target Hook: bool TARGET_HAVE_SRODATA_SECTION
- Contains the value true if the target places read-only "small data"
- into a separate section. The default value is false.
-
- -- Target Hook: bool TARGET_PROFILE_BEFORE_PROLOGUE (void)
- It returns true if target wants profile code emitted before
- prologue.
-
- The default version of this hook use the target macro
- 'PROFILE_BEFORE_PROLOGUE'.
-
- -- Target Hook: bool TARGET_BINDS_LOCAL_P (const_tree EXP)
- Returns true if EXP names an object for which name resolution rules
- must resolve to the current "module" (dynamic shared library or
- executable image).
-
- The default version of this hook implements the name resolution
- rules for ELF, which has a looser model of global name binding than
- other currently supported object file formats.
-
- -- Target Hook: bool TARGET_HAVE_TLS
- Contains the value true if the target supports thread-local
- storage. The default value is false.
-
-
- File: gccint.info, Node: PIC, Next: Assembler Format, Prev: Sections, Up: Target Macros
-
- 18.19 Position Independent Code
- ===============================
-
- This section describes macros that help implement generation of position
- independent code. Simply defining these macros is not enough to
- generate valid PIC; you must also add support to the hook
- 'TARGET_LEGITIMATE_ADDRESS_P' and to the macro 'PRINT_OPERAND_ADDRESS',
- as well as 'LEGITIMIZE_ADDRESS'. You must modify the definition of
- 'movsi' to do something appropriate when the source operand contains a
- symbolic address. You may also need to alter the handling of switch
- statements so that they use relative addresses.
-
- -- Macro: PIC_OFFSET_TABLE_REGNUM
- The register number of the register used to address a table of
- static data addresses in memory. In some cases this register is
- defined by a processor's "application binary interface" (ABI).
- When this macro is defined, RTL is generated for this register
- once, as with the stack pointer and frame pointer registers. If
- this macro is not defined, it is up to the machine-dependent files
- to allocate such a register (if necessary). Note that this
- register must be fixed when in use (e.g. when 'flag_pic' is true).
-
- -- Macro: PIC_OFFSET_TABLE_REG_CALL_CLOBBERED
- A C expression that is nonzero if the register defined by
- 'PIC_OFFSET_TABLE_REGNUM' is clobbered by calls. If not defined,
- the default is zero. Do not define this macro if
- 'PIC_OFFSET_TABLE_REGNUM' is not defined.
-
- -- Macro: LEGITIMATE_PIC_OPERAND_P (X)
- A C expression that is nonzero if X is a legitimate immediate
- operand on the target machine when generating position independent
- code. You can assume that X satisfies 'CONSTANT_P', so you need
- not check this. You can also assume FLAG_PIC is true, so you need
- not check it either. You need not define this macro if all
- constants (including 'SYMBOL_REF') can be immediate operands when
- generating position independent code.
-
-
- File: gccint.info, Node: Assembler Format, Next: Debugging Info, Prev: PIC, Up: Target Macros
-
- 18.20 Defining the Output Assembler Language
- ============================================
-
- This section describes macros whose principal purpose is to describe how
- to write instructions in assembler language--rather than what the
- instructions do.
-
- * Menu:
-
- * File Framework:: Structural information for the assembler file.
- * Data Output:: Output of constants (numbers, strings, addresses).
- * Uninitialized Data:: Output of uninitialized variables.
- * Label Output:: Output and generation of labels.
- * Initialization:: General principles of initialization
- and termination routines.
- * Macros for Initialization::
- Specific macros that control the handling of
- initialization and termination routines.
- * Instruction Output:: Output of actual instructions.
- * Dispatch Tables:: Output of jump tables.
- * Exception Region Output:: Output of exception region code.
- * Alignment Output:: Pseudo ops for alignment and skipping data.
-
-
- File: gccint.info, Node: File Framework, Next: Data Output, Up: Assembler Format
-
- 18.20.1 The Overall Framework of an Assembler File
- --------------------------------------------------
-
- This describes the overall framework of an assembly file.
-
- -- Target Hook: void TARGET_ASM_FILE_START (void)
- Output to 'asm_out_file' any text which the assembler expects to
- find at the beginning of a file. The default behavior is
- controlled by two flags, documented below. Unless your target's
- assembler is quite unusual, if you override the default, you should
- call 'default_file_start' at some point in your target hook. This
- lets other target files rely on these variables.
-
- -- Target Hook: bool TARGET_ASM_FILE_START_APP_OFF
- If this flag is true, the text of the macro 'ASM_APP_OFF' will be
- printed as the very first line in the assembly file, unless
- '-fverbose-asm' is in effect. (If that macro has been defined to
- the empty string, this variable has no effect.) With the normal
- definition of 'ASM_APP_OFF', the effect is to notify the GNU
- assembler that it need not bother stripping comments or extra
- whitespace from its input. This allows it to work a bit faster.
-
- The default is false. You should not set it to true unless you
- have verified that your port does not generate any extra whitespace
- or comments that will cause GAS to issue errors in NO_APP mode.
-
- -- Target Hook: bool TARGET_ASM_FILE_START_FILE_DIRECTIVE
- If this flag is true, 'output_file_directive' will be called for
- the primary source file, immediately after printing 'ASM_APP_OFF'
- (if that is enabled). Most ELF assemblers expect this to be done.
- The default is false.
-
- -- Target Hook: void TARGET_ASM_FILE_END (void)
- Output to 'asm_out_file' any text which the assembler expects to
- find at the end of a file. The default is to output nothing.
-
- -- Function: void file_end_indicate_exec_stack ()
- Some systems use a common convention, the '.note.GNU-stack' special
- section, to indicate whether or not an object file relies on the
- stack being executable. If your system uses this convention, you
- should define 'TARGET_ASM_FILE_END' to this function. If you need
- to do other things in that hook, have your hook function call this
- function.
-
- -- Target Hook: void TARGET_ASM_LTO_START (void)
- Output to 'asm_out_file' any text which the assembler expects to
- find at the start of an LTO section. The default is to output
- nothing.
-
- -- Target Hook: void TARGET_ASM_LTO_END (void)
- Output to 'asm_out_file' any text which the assembler expects to
- find at the end of an LTO section. The default is to output
- nothing.
-
- -- Target Hook: void TARGET_ASM_CODE_END (void)
- Output to 'asm_out_file' any text which is needed before emitting
- unwind info and debug info at the end of a file. Some targets emit
- here PIC setup thunks that cannot be emitted at the end of file,
- because they couldn't have unwind info then. The default is to
- output nothing.
-
- -- Macro: ASM_COMMENT_START
- A C string constant describing how to begin a comment in the target
- assembler language. The compiler assumes that the comment will end
- at the end of the line.
-
- -- Macro: ASM_APP_ON
- A C string constant for text to be output before each 'asm'
- statement or group of consecutive ones. Normally this is '"#APP"',
- which is a comment that has no effect on most assemblers but tells
- the GNU assembler that it must check the lines that follow for all
- valid assembler constructs.
-
- -- Macro: ASM_APP_OFF
- A C string constant for text to be output after each 'asm'
- statement or group of consecutive ones. Normally this is
- '"#NO_APP"', which tells the GNU assembler to resume making the
- time-saving assumptions that are valid for ordinary compiler
- output.
-
- -- Macro: ASM_OUTPUT_SOURCE_FILENAME (STREAM, NAME)
- A C statement to output COFF information or DWARF debugging
- information which indicates that filename NAME is the current
- source file to the stdio stream STREAM.
-
- This macro need not be defined if the standard form of output for
- the file format in use is appropriate.
-
- -- Target Hook: void TARGET_ASM_OUTPUT_SOURCE_FILENAME (FILE *FILE,
- const char *NAME)
- Output DWARF debugging information which indicates that filename
- NAME is the current source file to the stdio stream FILE.
-
- This target hook need not be defined if the standard form of output
- for the file format in use is appropriate.
-
- -- Target Hook: void TARGET_ASM_OUTPUT_IDENT (const char *NAME)
- Output a string based on NAME, suitable for the '#ident' directive,
- or the equivalent directive or pragma in non-C-family languages.
- If this hook is not defined, nothing is output for the '#ident'
- directive.
-
- -- Macro: OUTPUT_QUOTED_STRING (STREAM, STRING)
- A C statement to output the string STRING to the stdio stream
- STREAM. If you do not call the function 'output_quoted_string' in
- your config files, GCC will only call it to output filenames to the
- assembler source. So you can use it to canonicalize the format of
- the filename using this macro.
-
- -- Target Hook: void TARGET_ASM_NAMED_SECTION (const char *NAME,
- unsigned int FLAGS, tree DECL)
- Output assembly directives to switch to section NAME. The section
- should have attributes as specified by FLAGS, which is a bit mask
- of the 'SECTION_*' flags defined in 'output.h'. If DECL is
- non-NULL, it is the 'VAR_DECL' or 'FUNCTION_DECL' with which this
- section is associated.
-
- -- Target Hook: bool TARGET_ASM_ELF_FLAGS_NUMERIC (unsigned int FLAGS,
- unsigned int *NUM)
- This hook can be used to encode ELF section flags for which no
- letter code has been defined in the assembler. It is called by
- 'default_asm_named_section' whenever the section flags need to be
- emitted in the assembler output. If the hook returns true, then
- the numerical value for ELF section flags should be calculated from
- FLAGS and saved in *NUM; the value is printed out instead of the
- normal sequence of letter codes. If the hook is not defined, or if
- it returns false, then NUM is ignored and the traditional letter
- sequence is emitted.
-
- -- Target Hook: section * TARGET_ASM_FUNCTION_SECTION (tree DECL, enum
- node_frequency FREQ, bool STARTUP, bool EXIT)
- Return preferred text (sub)section for function DECL. Main purpose
- of this function is to separate cold, normal and hot functions.
- STARTUP is true when function is known to be used only at startup
- (from static constructors or it is 'main()'). EXIT is true when
- function is known to be used only at exit (from static
- destructors). Return NULL if function should go to default text
- section.
-
- -- Target Hook: void TARGET_ASM_FUNCTION_SWITCHED_TEXT_SECTIONS (FILE
- *FILE, tree DECL, bool NEW_IS_COLD)
- Used by the target to emit any assembler directives or additional
- labels needed when a function is partitioned between different
- sections. Output should be written to FILE. The function decl is
- available as DECL and the new section is 'cold' if NEW_IS_COLD is
- 'true'.
-
- -- Common Target Hook: bool TARGET_HAVE_NAMED_SECTIONS
- This flag is true if the target supports
- 'TARGET_ASM_NAMED_SECTION'. It must not be modified by
- command-line option processing.
-
- -- Target Hook: bool TARGET_HAVE_SWITCHABLE_BSS_SECTIONS
- This flag is true if we can create zeroed data by switching to a
- BSS section and then using 'ASM_OUTPUT_SKIP' to allocate the space.
- This is true on most ELF targets.
-
- -- Target Hook: unsigned int TARGET_SECTION_TYPE_FLAGS (tree DECL,
- const char *NAME, int RELOC)
- Choose a set of section attributes for use by
- 'TARGET_ASM_NAMED_SECTION' based on a variable or function decl, a
- section name, and whether or not the declaration's initializer may
- contain runtime relocations. DECL may be null, in which case
- read-write data should be assumed.
-
- The default version of this function handles choosing code vs data,
- read-only vs read-write data, and 'flag_pic'. You should only need
- to override this if your target has special flags that might be set
- via '__attribute__'.
-
- -- Target Hook: int TARGET_ASM_RECORD_GCC_SWITCHES (print_switch_type
- TYPE, const char *TEXT)
- Provides the target with the ability to record the gcc command line
- switches that have been passed to the compiler, and options that
- are enabled. The TYPE argument specifies what is being recorded.
- It can take the following values:
-
- 'SWITCH_TYPE_PASSED'
- TEXT is a command line switch that has been set by the user.
-
- 'SWITCH_TYPE_ENABLED'
- TEXT is an option which has been enabled. This might be as a
- direct result of a command line switch, or because it is
- enabled by default or because it has been enabled as a side
- effect of a different command line switch. For example, the
- '-O2' switch enables various different individual optimization
- passes.
-
- 'SWITCH_TYPE_DESCRIPTIVE'
- TEXT is either NULL or some descriptive text which should be
- ignored. If TEXT is NULL then it is being used to warn the
- target hook that either recording is starting or ending. The
- first time TYPE is SWITCH_TYPE_DESCRIPTIVE and TEXT is NULL,
- the warning is for start up and the second time the warning is
- for wind down. This feature is to allow the target hook to
- make any necessary preparations before it starts to record
- switches and to perform any necessary tidying up after it has
- finished recording switches.
-
- 'SWITCH_TYPE_LINE_START'
- This option can be ignored by this target hook.
-
- 'SWITCH_TYPE_LINE_END'
- This option can be ignored by this target hook.
-
- The hook's return value must be zero. Other return values may be
- supported in the future.
-
- By default this hook is set to NULL, but an example implementation
- is provided for ELF based targets. Called ELF_RECORD_GCC_SWITCHES,
- it records the switches as ASCII text inside a new, string
- mergeable section in the assembler output file. The name of the
- new section is provided by the
- 'TARGET_ASM_RECORD_GCC_SWITCHES_SECTION' target hook.
-
- -- Target Hook: const char * TARGET_ASM_RECORD_GCC_SWITCHES_SECTION
- This is the name of the section that will be created by the example
- ELF implementation of the 'TARGET_ASM_RECORD_GCC_SWITCHES' target
- hook.
-
-
- File: gccint.info, Node: Data Output, Next: Uninitialized Data, Prev: File Framework, Up: Assembler Format
-
- 18.20.2 Output of Data
- ----------------------
-
- -- Target Hook: const char * TARGET_ASM_BYTE_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_HI_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_PSI_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_SI_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_PDI_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_DI_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_PTI_OP
- -- Target Hook: const char * TARGET_ASM_ALIGNED_TI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_HI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_PSI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_SI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_PDI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_DI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_PTI_OP
- -- Target Hook: const char * TARGET_ASM_UNALIGNED_TI_OP
- These hooks specify assembly directives for creating certain kinds
- of integer object. The 'TARGET_ASM_BYTE_OP' directive creates a
- byte-sized object, the 'TARGET_ASM_ALIGNED_HI_OP' one creates an
- aligned two-byte object, and so on. Any of the hooks may be
- 'NULL', indicating that no suitable directive is available.
-
- The compiler will print these strings at the start of a new line,
- followed immediately by the object's initial value. In most cases,
- the string should contain a tab, a pseudo-op, and then another tab.
-
- -- Target Hook: bool TARGET_ASM_INTEGER (rtx X, unsigned int SIZE, int
- ALIGNED_P)
- The 'assemble_integer' function uses this hook to output an integer
- object. X is the object's value, SIZE is its size in bytes and
- ALIGNED_P indicates whether it is aligned. The function should
- return 'true' if it was able to output the object. If it returns
- false, 'assemble_integer' will try to split the object into smaller
- parts.
-
- The default implementation of this hook will use the
- 'TARGET_ASM_BYTE_OP' family of strings, returning 'false' when the
- relevant string is 'NULL'.
-
- -- Target Hook: void TARGET_ASM_DECL_END (void)
- Define this hook if the target assembler requires a special marker
- to terminate an initialized variable declaration.
-
- -- Target Hook: bool TARGET_ASM_OUTPUT_ADDR_CONST_EXTRA (FILE *FILE,
- rtx X)
- A target hook to recognize RTX patterns that 'output_addr_const'
- can't deal with, and output assembly code to FILE corresponding to
- the pattern X. This may be used to allow machine-dependent
- 'UNSPEC's to appear within constants.
-
- If target hook fails to recognize a pattern, it must return
- 'false', so that a standard error message is printed. If it prints
- an error message itself, by calling, for example,
- 'output_operand_lossage', it may just return 'true'.
-
- -- Macro: ASM_OUTPUT_ASCII (STREAM, PTR, LEN)
- A C statement to output to the stdio stream STREAM an assembler
- instruction to assemble a string constant containing the LEN bytes
- at PTR. PTR will be a C expression of type 'char *' and LEN a C
- expression of type 'int'.
-
- If the assembler has a '.ascii' pseudo-op as found in the Berkeley
- Unix assembler, do not define the macro 'ASM_OUTPUT_ASCII'.
-
- -- Macro: ASM_OUTPUT_FDESC (STREAM, DECL, N)
- A C statement to output word N of a function descriptor for DECL.
- This must be defined if 'TARGET_VTABLE_USES_DESCRIPTORS' is
- defined, and is otherwise unused.
-
- -- Macro: CONSTANT_POOL_BEFORE_FUNCTION
- You may define this macro as a C expression. You should define the
- expression to have a nonzero value if GCC should output the
- constant pool for a function before the code for the function, or a
- zero value if GCC should output the constant pool after the
- function. If you do not define this macro, the usual case, GCC
- will output the constant pool before the function.
-
- -- Macro: ASM_OUTPUT_POOL_PROLOGUE (FILE, FUNNAME, FUNDECL, SIZE)
- A C statement to output assembler commands to define the start of
- the constant pool for a function. FUNNAME is a string giving the
- name of the function. Should the return type of the function be
- required, it can be obtained via FUNDECL. SIZE is the size, in
- bytes, of the constant pool that will be written immediately after
- this call.
-
- If no constant-pool prefix is required, the usual case, this macro
- need not be defined.
-
- -- Macro: ASM_OUTPUT_SPECIAL_POOL_ENTRY (FILE, X, MODE, ALIGN, LABELNO,
- JUMPTO)
- A C statement (with or without semicolon) to output a constant in
- the constant pool, if it needs special treatment. (This macro need
- not do anything for RTL expressions that can be output normally.)
-
- The argument FILE is the standard I/O stream to output the
- assembler code on. X is the RTL expression for the constant to
- output, and MODE is the machine mode (in case X is a 'const_int').
- ALIGN is the required alignment for the value X; you should output
- an assembler directive to force this much alignment.
-
- The argument LABELNO is a number to use in an internal label for
- the address of this pool entry. The definition of this macro is
- responsible for outputting the label definition at the proper
- place. Here is how to do this:
-
- (*targetm.asm_out.internal_label) (FILE, "LC", LABELNO);
-
- When you output a pool entry specially, you should end with a
- 'goto' to the label JUMPTO. This will prevent the same pool entry
- from being output a second time in the usual manner.
-
- You need not define this macro if it would do nothing.
-
- -- Macro: ASM_OUTPUT_POOL_EPILOGUE (FILE FUNNAME FUNDECL SIZE)
- A C statement to output assembler commands to at the end of the
- constant pool for a function. FUNNAME is a string giving the name
- of the function. Should the return type of the function be
- required, you can obtain it via FUNDECL. SIZE is the size, in
- bytes, of the constant pool that GCC wrote immediately before this
- call.
-
- If no constant-pool epilogue is required, the usual case, you need
- not define this macro.
-
- -- Macro: IS_ASM_LOGICAL_LINE_SEPARATOR (C, STR)
- Define this macro as a C expression which is nonzero if C is used
- as a logical line separator by the assembler. STR points to the
- position in the string where C was found; this can be used if a
- line separator uses multiple characters.
-
- If you do not define this macro, the default is that only the
- character ';' is treated as a logical line separator.
-
- -- Target Hook: const char * TARGET_ASM_OPEN_PAREN
- -- Target Hook: const char * TARGET_ASM_CLOSE_PAREN
- These target hooks are C string constants, describing the syntax in
- the assembler for grouping arithmetic expressions. If not
- overridden, they default to normal parentheses, which is correct
- for most assemblers.
-
- These macros are provided by 'real.h' for writing the definitions of
- 'ASM_OUTPUT_DOUBLE' and the like:
-
- -- Macro: REAL_VALUE_TO_TARGET_SINGLE (X, L)
- -- Macro: REAL_VALUE_TO_TARGET_DOUBLE (X, L)
- -- Macro: REAL_VALUE_TO_TARGET_LONG_DOUBLE (X, L)
- -- Macro: REAL_VALUE_TO_TARGET_DECIMAL32 (X, L)
- -- Macro: REAL_VALUE_TO_TARGET_DECIMAL64 (X, L)
- -- Macro: REAL_VALUE_TO_TARGET_DECIMAL128 (X, L)
- These translate X, of type 'REAL_VALUE_TYPE', to the target's
- floating point representation, and store its bit pattern in the
- variable L. For 'REAL_VALUE_TO_TARGET_SINGLE' and
- 'REAL_VALUE_TO_TARGET_DECIMAL32', this variable should be a simple
- 'long int'. For the others, it should be an array of 'long int'.
- The number of elements in this array is determined by the size of
- the desired target floating point data type: 32 bits of it go in
- each 'long int' array element. Each array element holds 32 bits of
- the result, even if 'long int' is wider than 32 bits on the host
- machine.
-
- The array element values are designed so that you can print them
- out using 'fprintf' in the order they should appear in the target
- machine's memory.
-
-
- File: gccint.info, Node: Uninitialized Data, Next: Label Output, Prev: Data Output, Up: Assembler Format
-
- 18.20.3 Output of Uninitialized Variables
- -----------------------------------------
-
- Each of the macros in this section is used to do the whole job of
- outputting a single uninitialized variable.
-
- -- Macro: ASM_OUTPUT_COMMON (STREAM, NAME, SIZE, ROUNDED)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- the assembler definition of a common-label named NAME whose size is
- SIZE bytes. The variable ROUNDED is the size rounded up to
- whatever alignment the caller wants. It is possible that SIZE may
- be zero, for instance if a struct with no other member than a
- zero-length array is defined. In this case, the backend must
- output a symbol definition that allocates at least one byte, both
- so that the address of the resulting object does not compare equal
- to any other, and because some object formats cannot even express
- the concept of a zero-sized common symbol, as that is how they
- represent an ordinary undefined external.
-
- Use the expression 'assemble_name (STREAM, NAME)' to output the
- name itself; before and after that, output the additional assembler
- syntax for defining the name, and a newline.
-
- This macro controls how the assembler definitions of uninitialized
- common global variables are output.
-
- -- Macro: ASM_OUTPUT_ALIGNED_COMMON (STREAM, NAME, SIZE, ALIGNMENT)
- Like 'ASM_OUTPUT_COMMON' except takes the required alignment as a
- separate, explicit argument. If you define this macro, it is used
- in place of 'ASM_OUTPUT_COMMON', and gives you more flexibility in
- handling the required alignment of the variable. The alignment is
- specified as the number of bits.
-
- -- Macro: ASM_OUTPUT_ALIGNED_DECL_COMMON (STREAM, DECL, NAME, SIZE,
- ALIGNMENT)
- Like 'ASM_OUTPUT_ALIGNED_COMMON' except that DECL of the variable
- to be output, if there is one, or 'NULL_TREE' if there is no
- corresponding variable. If you define this macro, GCC will use it
- in place of both 'ASM_OUTPUT_COMMON' and
- 'ASM_OUTPUT_ALIGNED_COMMON'. Define this macro when you need to
- see the variable's decl in order to chose what to output.
-
- -- Macro: ASM_OUTPUT_ALIGNED_BSS (STREAM, DECL, NAME, SIZE, ALIGNMENT)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- the assembler definition of uninitialized global DECL named NAME
- whose size is SIZE bytes. The variable ALIGNMENT is the alignment
- specified as the number of bits.
-
- Try to use function 'asm_output_aligned_bss' defined in file
- 'varasm.c' when defining this macro. If unable, use the expression
- 'assemble_name (STREAM, NAME)' to output the name itself; before
- and after that, output the additional assembler syntax for defining
- the name, and a newline.
-
- There are two ways of handling global BSS. One is to define this
- macro. The other is to have 'TARGET_ASM_SELECT_SECTION' return a
- switchable BSS section (*note
- TARGET_HAVE_SWITCHABLE_BSS_SECTIONS::). You do not need to do
- both.
-
- Some languages do not have 'common' data, and require a non-common
- form of global BSS in order to handle uninitialized globals
- efficiently. C++ is one example of this. However, if the target
- does not support global BSS, the front end may choose to make
- globals common in order to save space in the object file.
-
- -- Macro: ASM_OUTPUT_LOCAL (STREAM, NAME, SIZE, ROUNDED)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- the assembler definition of a local-common-label named NAME whose
- size is SIZE bytes. The variable ROUNDED is the size rounded up to
- whatever alignment the caller wants.
-
- Use the expression 'assemble_name (STREAM, NAME)' to output the
- name itself; before and after that, output the additional assembler
- syntax for defining the name, and a newline.
-
- This macro controls how the assembler definitions of uninitialized
- static variables are output.
-
- -- Macro: ASM_OUTPUT_ALIGNED_LOCAL (STREAM, NAME, SIZE, ALIGNMENT)
- Like 'ASM_OUTPUT_LOCAL' except takes the required alignment as a
- separate, explicit argument. If you define this macro, it is used
- in place of 'ASM_OUTPUT_LOCAL', and gives you more flexibility in
- handling the required alignment of the variable. The alignment is
- specified as the number of bits.
-
- -- Macro: ASM_OUTPUT_ALIGNED_DECL_LOCAL (STREAM, DECL, NAME, SIZE,
- ALIGNMENT)
- Like 'ASM_OUTPUT_ALIGNED_LOCAL' except that DECL of the variable to
- be output, if there is one, or 'NULL_TREE' if there is no
- corresponding variable. If you define this macro, GCC will use it
- in place of both 'ASM_OUTPUT_LOCAL' and 'ASM_OUTPUT_ALIGNED_LOCAL'.
- Define this macro when you need to see the variable's decl in order
- to chose what to output.
-
-
- File: gccint.info, Node: Label Output, Next: Initialization, Prev: Uninitialized Data, Up: Assembler Format
-
- 18.20.4 Output and Generation of Labels
- ---------------------------------------
-
- This is about outputting labels.
-
- -- Macro: ASM_OUTPUT_LABEL (STREAM, NAME)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- the assembler definition of a label named NAME. Use the expression
- 'assemble_name (STREAM, NAME)' to output the name itself; before
- and after that, output the additional assembler syntax for defining
- the name, and a newline. A default definition of this macro is
- provided which is correct for most systems.
-
- -- Macro: ASM_OUTPUT_FUNCTION_LABEL (STREAM, NAME, DECL)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- the assembler definition of a label named NAME of a function. Use
- the expression 'assemble_name (STREAM, NAME)' to output the name
- itself; before and after that, output the additional assembler
- syntax for defining the name, and a newline. A default definition
- of this macro is provided which is correct for most systems.
-
- If this macro is not defined, then the function name is defined in
- the usual manner as a label (by means of 'ASM_OUTPUT_LABEL').
-
- -- Macro: ASM_OUTPUT_INTERNAL_LABEL (STREAM, NAME)
- Identical to 'ASM_OUTPUT_LABEL', except that NAME is known to refer
- to a compiler-generated label. The default definition uses
- 'assemble_name_raw', which is like 'assemble_name' except that it
- is more efficient.
-
- -- Macro: SIZE_ASM_OP
- A C string containing the appropriate assembler directive to
- specify the size of a symbol, without any arguments. On systems
- that use ELF, the default (in 'config/elfos.h') is '"\t.size\t"';
- on other systems, the default is not to define this macro.
-
- Define this macro only if it is correct to use the default
- definitions of 'ASM_OUTPUT_SIZE_DIRECTIVE' and
- 'ASM_OUTPUT_MEASURED_SIZE' for your system. If you need your own
- custom definitions of those macros, or if you do not need explicit
- symbol sizes at all, do not define this macro.
-
- -- Macro: ASM_OUTPUT_SIZE_DIRECTIVE (STREAM, NAME, SIZE)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- a directive telling the assembler that the size of the symbol NAME
- is SIZE. SIZE is a 'HOST_WIDE_INT'. If you define 'SIZE_ASM_OP',
- a default definition of this macro is provided.
-
- -- Macro: ASM_OUTPUT_MEASURED_SIZE (STREAM, NAME)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- a directive telling the assembler to calculate the size of the
- symbol NAME by subtracting its address from the current address.
-
- If you define 'SIZE_ASM_OP', a default definition of this macro is
- provided. The default assumes that the assembler recognizes a
- special '.' symbol as referring to the current address, and can
- calculate the difference between this and another symbol. If your
- assembler does not recognize '.' or cannot do calculations with it,
- you will need to redefine 'ASM_OUTPUT_MEASURED_SIZE' to use some
- other technique.
-
- -- Macro: NO_DOLLAR_IN_LABEL
- Define this macro if the assembler does not accept the character
- '$' in label names. By default constructors and destructors in G++
- have '$' in the identifiers. If this macro is defined, '.' is used
- instead.
-
- -- Macro: NO_DOT_IN_LABEL
- Define this macro if the assembler does not accept the character
- '.' in label names. By default constructors and destructors in G++
- have names that use '.'. If this macro is defined, these names are
- rewritten to avoid '.'.
-
- -- Macro: TYPE_ASM_OP
- A C string containing the appropriate assembler directive to
- specify the type of a symbol, without any arguments. On systems
- that use ELF, the default (in 'config/elfos.h') is '"\t.type\t"';
- on other systems, the default is not to define this macro.
-
- Define this macro only if it is correct to use the default
- definition of 'ASM_OUTPUT_TYPE_DIRECTIVE' for your system. If you
- need your own custom definition of this macro, or if you do not
- need explicit symbol types at all, do not define this macro.
-
- -- Macro: TYPE_OPERAND_FMT
- A C string which specifies (using 'printf' syntax) the format of
- the second operand to 'TYPE_ASM_OP'. On systems that use ELF, the
- default (in 'config/elfos.h') is '"@%s"'; on other systems, the
- default is not to define this macro.
-
- Define this macro only if it is correct to use the default
- definition of 'ASM_OUTPUT_TYPE_DIRECTIVE' for your system. If you
- need your own custom definition of this macro, or if you do not
- need explicit symbol types at all, do not define this macro.
-
- -- Macro: ASM_OUTPUT_TYPE_DIRECTIVE (STREAM, TYPE)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- a directive telling the assembler that the type of the symbol NAME
- is TYPE. TYPE is a C string; currently, that string is always
- either '"function"' or '"object"', but you should not count on
- this.
-
- If you define 'TYPE_ASM_OP' and 'TYPE_OPERAND_FMT', a default
- definition of this macro is provided.
-
- -- Macro: ASM_DECLARE_FUNCTION_NAME (STREAM, NAME, DECL)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for declaring the name NAME of a function which
- is being defined. This macro is responsible for outputting the
- label definition (perhaps using 'ASM_OUTPUT_FUNCTION_LABEL'). The
- argument DECL is the 'FUNCTION_DECL' tree node representing the
- function.
-
- If this macro is not defined, then the function name is defined in
- the usual manner as a label (by means of
- 'ASM_OUTPUT_FUNCTION_LABEL').
-
- You may wish to use 'ASM_OUTPUT_TYPE_DIRECTIVE' in the definition
- of this macro.
-
- -- Macro: ASM_DECLARE_FUNCTION_SIZE (STREAM, NAME, DECL)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for declaring the size of a function which is
- being defined. The argument NAME is the name of the function. The
- argument DECL is the 'FUNCTION_DECL' tree node representing the
- function.
-
- If this macro is not defined, then the function size is not
- defined.
-
- You may wish to use 'ASM_OUTPUT_MEASURED_SIZE' in the definition of
- this macro.
-
- -- Macro: ASM_DECLARE_COLD_FUNCTION_NAME (STREAM, NAME, DECL)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for declaring the name NAME of a cold function
- partition which is being defined. This macro is responsible for
- outputting the label definition (perhaps using
- 'ASM_OUTPUT_FUNCTION_LABEL'). The argument DECL is the
- 'FUNCTION_DECL' tree node representing the function.
-
- If this macro is not defined, then the cold partition name is
- defined in the usual manner as a label (by means of
- 'ASM_OUTPUT_LABEL').
-
- You may wish to use 'ASM_OUTPUT_TYPE_DIRECTIVE' in the definition
- of this macro.
-
- -- Macro: ASM_DECLARE_COLD_FUNCTION_SIZE (STREAM, NAME, DECL)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for declaring the size of a cold function
- partition which is being defined. The argument NAME is the name of
- the cold partition of the function. The argument DECL is the
- 'FUNCTION_DECL' tree node representing the function.
-
- If this macro is not defined, then the partition size is not
- defined.
-
- You may wish to use 'ASM_OUTPUT_MEASURED_SIZE' in the definition of
- this macro.
-
- -- Macro: ASM_DECLARE_OBJECT_NAME (STREAM, NAME, DECL)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for declaring the name NAME of an initialized
- variable which is being defined. This macro must output the label
- definition (perhaps using 'ASM_OUTPUT_LABEL'). The argument DECL
- is the 'VAR_DECL' tree node representing the variable.
-
- If this macro is not defined, then the variable name is defined in
- the usual manner as a label (by means of 'ASM_OUTPUT_LABEL').
-
- You may wish to use 'ASM_OUTPUT_TYPE_DIRECTIVE' and/or
- 'ASM_OUTPUT_SIZE_DIRECTIVE' in the definition of this macro.
-
- -- Target Hook: void TARGET_ASM_DECLARE_CONSTANT_NAME (FILE *FILE,
- const char *NAME, const_tree EXPR, HOST_WIDE_INT SIZE)
- A target hook to output to the stdio stream FILE any text necessary
- for declaring the name NAME of a constant which is being defined.
- This target hook is responsible for outputting the label definition
- (perhaps using 'assemble_label'). The argument EXP is the value of
- the constant, and SIZE is the size of the constant in bytes. The
- NAME will be an internal label.
-
- The default version of this target hook, define the NAME in the
- usual manner as a label (by means of 'assemble_label').
-
- You may wish to use 'ASM_OUTPUT_TYPE_DIRECTIVE' in this target
- hook.
-
- -- Macro: ASM_DECLARE_REGISTER_GLOBAL (STREAM, DECL, REGNO, NAME)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for claiming a register REGNO for a global
- variable DECL with name NAME.
-
- If you don't define this macro, that is equivalent to defining it
- to do nothing.
-
- -- Macro: ASM_FINISH_DECLARE_OBJECT (STREAM, DECL, TOPLEVEL, ATEND)
- A C statement (sans semicolon) to finish up declaring a variable
- name once the compiler has processed its initializer fully and thus
- has had a chance to determine the size of an array when controlled
- by an initializer. This is used on systems where it's necessary to
- declare something about the size of the object.
-
- If you don't define this macro, that is equivalent to defining it
- to do nothing.
-
- You may wish to use 'ASM_OUTPUT_SIZE_DIRECTIVE' and/or
- 'ASM_OUTPUT_MEASURED_SIZE' in the definition of this macro.
-
- -- Target Hook: void TARGET_ASM_GLOBALIZE_LABEL (FILE *STREAM, const
- char *NAME)
- This target hook is a function to output to the stdio stream STREAM
- some commands that will make the label NAME global; that is,
- available for reference from other files.
-
- The default implementation relies on a proper definition of
- 'GLOBAL_ASM_OP'.
-
- -- Target Hook: void TARGET_ASM_GLOBALIZE_DECL_NAME (FILE *STREAM, tree
- DECL)
- This target hook is a function to output to the stdio stream STREAM
- some commands that will make the name associated with DECL global;
- that is, available for reference from other files.
-
- The default implementation uses the TARGET_ASM_GLOBALIZE_LABEL
- target hook.
-
- -- Target Hook: void TARGET_ASM_ASSEMBLE_UNDEFINED_DECL (FILE *STREAM,
- const char *NAME, const_tree DECL)
- This target hook is a function to output to the stdio stream STREAM
- some commands that will declare the name associated with DECL which
- is not defined in the current translation unit. Most assemblers do
- not require anything to be output in this case.
-
- -- Macro: ASM_WEAKEN_LABEL (STREAM, NAME)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- some commands that will make the label NAME weak; that is,
- available for reference from other files but only used if no other
- definition is available. Use the expression 'assemble_name
- (STREAM, NAME)' to output the name itself; before and after that,
- output the additional assembler syntax for making that name weak,
- and a newline.
-
- If you don't define this macro or 'ASM_WEAKEN_DECL', GCC will not
- support weak symbols and you should not define the 'SUPPORTS_WEAK'
- macro.
-
- -- Macro: ASM_WEAKEN_DECL (STREAM, DECL, NAME, VALUE)
- Combines (and replaces) the function of 'ASM_WEAKEN_LABEL' and
- 'ASM_OUTPUT_WEAK_ALIAS', allowing access to the associated function
- or variable decl. If VALUE is not 'NULL', this C statement should
- output to the stdio stream STREAM assembler code which defines
- (equates) the weak symbol NAME to have the value VALUE. If VALUE
- is 'NULL', it should output commands to make NAME weak.
-
- -- Macro: ASM_OUTPUT_WEAKREF (STREAM, DECL, NAME, VALUE)
- Outputs a directive that enables NAME to be used to refer to symbol
- VALUE with weak-symbol semantics. 'decl' is the declaration of
- 'name'.
-
- -- Macro: SUPPORTS_WEAK
- A preprocessor constant expression which evaluates to true if the
- target supports weak symbols.
-
- If you don't define this macro, 'defaults.h' provides a default
- definition. If either 'ASM_WEAKEN_LABEL' or 'ASM_WEAKEN_DECL' is
- defined, the default definition is '1'; otherwise, it is '0'.
-
- -- Macro: TARGET_SUPPORTS_WEAK
- A C expression which evaluates to true if the target supports weak
- symbols.
-
- If you don't define this macro, 'defaults.h' provides a default
- definition. The default definition is '(SUPPORTS_WEAK)'. Define
- this macro if you want to control weak symbol support with a
- compiler flag such as '-melf'.
-
- -- Macro: MAKE_DECL_ONE_ONLY (DECL)
- A C statement (sans semicolon) to mark DECL to be emitted as a
- public symbol such that extra copies in multiple translation units
- will be discarded by the linker. Define this macro if your object
- file format provides support for this concept, such as the 'COMDAT'
- section flags in the Microsoft Windows PE/COFF format, and this
- support requires changes to DECL, such as putting it in a separate
- section.
-
- -- Macro: SUPPORTS_ONE_ONLY
- A C expression which evaluates to true if the target supports
- one-only semantics.
-
- If you don't define this macro, 'varasm.c' provides a default
- definition. If 'MAKE_DECL_ONE_ONLY' is defined, the default
- definition is '1'; otherwise, it is '0'. Define this macro if you
- want to control one-only symbol support with a compiler flag, or if
- setting the 'DECL_ONE_ONLY' flag is enough to mark a declaration to
- be emitted as one-only.
-
- -- Target Hook: void TARGET_ASM_ASSEMBLE_VISIBILITY (tree DECL, int
- VISIBILITY)
- This target hook is a function to output to ASM_OUT_FILE some
- commands that will make the symbol(s) associated with DECL have
- hidden, protected or internal visibility as specified by
- VISIBILITY.
-
- -- Macro: TARGET_WEAK_NOT_IN_ARCHIVE_TOC
- A C expression that evaluates to true if the target's linker
- expects that weak symbols do not appear in a static archive's table
- of contents. The default is '0'.
-
- Leaving weak symbols out of an archive's table of contents means
- that, if a symbol will only have a definition in one translation
- unit and will have undefined references from other translation
- units, that symbol should not be weak. Defining this macro to be
- nonzero will thus have the effect that certain symbols that would
- normally be weak (explicit template instantiations, and vtables for
- polymorphic classes with noninline key methods) will instead be
- nonweak.
-
- The C++ ABI requires this macro to be zero. Define this macro for
- targets where full C++ ABI compliance is impossible and where
- linker restrictions require weak symbols to be left out of a static
- archive's table of contents.
-
- -- Macro: ASM_OUTPUT_EXTERNAL (STREAM, DECL, NAME)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- any text necessary for declaring the name of an external symbol
- named NAME which is referenced in this compilation but not defined.
- The value of DECL is the tree node for the declaration.
-
- This macro need not be defined if it does not need to output
- anything. The GNU assembler and most Unix assemblers don't require
- anything.
-
- -- Target Hook: void TARGET_ASM_EXTERNAL_LIBCALL (rtx SYMREF)
- This target hook is a function to output to ASM_OUT_FILE an
- assembler pseudo-op to declare a library function name external.
- The name of the library function is given by SYMREF, which is a
- 'symbol_ref'.
-
- -- Target Hook: void TARGET_ASM_MARK_DECL_PRESERVED (const char
- *SYMBOL)
- This target hook is a function to output to ASM_OUT_FILE an
- assembler directive to annotate SYMBOL as used. The Darwin target
- uses the .no_dead_code_strip directive.
-
- -- Macro: ASM_OUTPUT_LABELREF (STREAM, NAME)
- A C statement (sans semicolon) to output to the stdio stream STREAM
- a reference in assembler syntax to a label named NAME. This should
- add '_' to the front of the name, if that is customary on your
- operating system, as it is in most Berkeley Unix systems. This
- macro is used in 'assemble_name'.
-
- -- Target Hook: tree TARGET_MANGLE_ASSEMBLER_NAME (const char *NAME)
- Given a symbol NAME, perform same mangling as 'varasm.c''s
- 'assemble_name', but in memory rather than to a file stream,
- returning result as an 'IDENTIFIER_NODE'. Required for correct LTO
- symtabs. The default implementation calls the
- 'TARGET_STRIP_NAME_ENCODING' hook and then prepends the
- 'USER_LABEL_PREFIX', if any.
-
- -- Macro: ASM_OUTPUT_SYMBOL_REF (STREAM, SYM)
- A C statement (sans semicolon) to output a reference to
- 'SYMBOL_REF' SYM. If not defined, 'assemble_name' will be used to
- output the name of the symbol. This macro may be used to modify
- the way a symbol is referenced depending on information encoded by
- 'TARGET_ENCODE_SECTION_INFO'.
-
- -- Macro: ASM_OUTPUT_LABEL_REF (STREAM, BUF)
- A C statement (sans semicolon) to output a reference to BUF, the
- result of 'ASM_GENERATE_INTERNAL_LABEL'. If not defined,
- 'assemble_name' will be used to output the name of the symbol.
- This macro is not used by 'output_asm_label', or the '%l' specifier
- that calls it; the intention is that this macro should be set when
- it is necessary to output a label differently when its address is
- being taken.
-
- -- Target Hook: void TARGET_ASM_INTERNAL_LABEL (FILE *STREAM, const
- char *PREFIX, unsigned long LABELNO)
- A function to output to the stdio stream STREAM a label whose name
- is made from the string PREFIX and the number LABELNO.
-
- It is absolutely essential that these labels be distinct from the
- labels used for user-level functions and variables. Otherwise,
- certain programs will have name conflicts with internal labels.
-
- It is desirable to exclude internal labels from the symbol table of
- the object file. Most assemblers have a naming convention for
- labels that should be excluded; on many systems, the letter 'L' at
- the beginning of a label has this effect. You should find out what
- convention your system uses, and follow it.
-
- The default version of this function utilizes
- 'ASM_GENERATE_INTERNAL_LABEL'.
-
- -- Macro: ASM_OUTPUT_DEBUG_LABEL (STREAM, PREFIX, NUM)
- A C statement to output to the stdio stream STREAM a debug info
- label whose name is made from the string PREFIX and the number NUM.
- This is useful for VLIW targets, where debug info labels may need
- to be treated differently than branch target labels. On some
- systems, branch target labels must be at the beginning of
- instruction bundles, but debug info labels can occur in the middle
- of instruction bundles.
-
- If this macro is not defined, then
- '(*targetm.asm_out.internal_label)' will be used.
-
- -- Macro: ASM_GENERATE_INTERNAL_LABEL (STRING, PREFIX, NUM)
- A C statement to store into the string STRING a label whose name is
- made from the string PREFIX and the number NUM.
-
- This string, when output subsequently by 'assemble_name', should
- produce the output that '(*targetm.asm_out.internal_label)' would
- produce with the same PREFIX and NUM.
-
- If the string begins with '*', then 'assemble_name' will output the
- rest of the string unchanged. It is often convenient for
- 'ASM_GENERATE_INTERNAL_LABEL' to use '*' in this way. If the
- string doesn't start with '*', then 'ASM_OUTPUT_LABELREF' gets to
- output the string, and may change it. (Of course,
- 'ASM_OUTPUT_LABELREF' is also part of your machine description, so
- you should know what it does on your machine.)
-
- -- Macro: ASM_FORMAT_PRIVATE_NAME (OUTVAR, NAME, NUMBER)
- A C expression to assign to OUTVAR (which is a variable of type
- 'char *') a newly allocated string made from the string NAME and
- the number NUMBER, with some suitable punctuation added. Use
- 'alloca' to get space for the string.
-
- The string will be used as an argument to 'ASM_OUTPUT_LABELREF' to
- produce an assembler label for an internal static variable whose
- name is NAME. Therefore, the string must be such as to result in
- valid assembler code. The argument NUMBER is different each time
- this macro is executed; it prevents conflicts between
- similarly-named internal static variables in different scopes.
-
- Ideally this string should not be a valid C identifier, to prevent
- any conflict with the user's own symbols. Most assemblers allow
- periods or percent signs in assembler symbols; putting at least one
- of these between the name and the number will suffice.
-
- If this macro is not defined, a default definition will be provided
- which is correct for most systems.
-
- -- Macro: ASM_OUTPUT_DEF (STREAM, NAME, VALUE)
- A C statement to output to the stdio stream STREAM assembler code
- which defines (equates) the symbol NAME to have the value VALUE.
-
- If 'SET_ASM_OP' is defined, a default definition is provided which
- is correct for most systems.
-
- -- Macro: ASM_OUTPUT_DEF_FROM_DECLS (STREAM, DECL_OF_NAME,
- DECL_OF_VALUE)
- A C statement to output to the stdio stream STREAM assembler code
- which defines (equates) the symbol whose tree node is DECL_OF_NAME
- to have the value of the tree node DECL_OF_VALUE. This macro will
- be used in preference to 'ASM_OUTPUT_DEF' if it is defined and if
- the tree nodes are available.
-
- If 'SET_ASM_OP' is defined, a default definition is provided which
- is correct for most systems.
-
- -- Macro: TARGET_DEFERRED_OUTPUT_DEFS (DECL_OF_NAME, DECL_OF_VALUE)
- A C statement that evaluates to true if the assembler code which
- defines (equates) the symbol whose tree node is DECL_OF_NAME to
- have the value of the tree node DECL_OF_VALUE should be emitted
- near the end of the current compilation unit. The default is to
- not defer output of defines. This macro affects defines output by
- 'ASM_OUTPUT_DEF' and 'ASM_OUTPUT_DEF_FROM_DECLS'.
-
- -- Macro: ASM_OUTPUT_WEAK_ALIAS (STREAM, NAME, VALUE)
- A C statement to output to the stdio stream STREAM assembler code
- which defines (equates) the weak symbol NAME to have the value
- VALUE. If VALUE is 'NULL', it defines NAME as an undefined weak
- symbol.
-
- Define this macro if the target only supports weak aliases; define
- 'ASM_OUTPUT_DEF' instead if possible.
-
- -- Macro: OBJC_GEN_METHOD_LABEL (BUF, IS_INST, CLASS_NAME, CAT_NAME,
- SEL_NAME)
- Define this macro to override the default assembler names used for
- Objective-C methods.
-
- The default name is a unique method number followed by the name of
- the class (e.g. '_1_Foo'). For methods in categories, the name of
- the category is also included in the assembler name (e.g.
- '_1_Foo_Bar').
-
- These names are safe on most systems, but make debugging difficult
- since the method's selector is not present in the name. Therefore,
- particular systems define other ways of computing names.
-
- BUF is an expression of type 'char *' which gives you a buffer in
- which to store the name; its length is as long as CLASS_NAME,
- CAT_NAME and SEL_NAME put together, plus 50 characters extra.
-
- The argument IS_INST specifies whether the method is an instance
- method or a class method; CLASS_NAME is the name of the class;
- CAT_NAME is the name of the category (or 'NULL' if the method is
- not in a category); and SEL_NAME is the name of the selector.
-
- On systems where the assembler can handle quoted names, you can use
- this macro to provide more human-readable names.
-
-
- File: gccint.info, Node: Initialization, Next: Macros for Initialization, Prev: Label Output, Up: Assembler Format
-
- 18.20.5 How Initialization Functions Are Handled
- ------------------------------------------------
-
- The compiled code for certain languages includes "constructors" (also
- called "initialization routines")--functions to initialize data in the
- program when the program is started. These functions need to be called
- before the program is "started"--that is to say, before 'main' is
- called.
-
- Compiling some languages generates "destructors" (also called
- "termination routines") that should be called when the program
- terminates.
-
- To make the initialization and termination functions work, the compiler
- must output something in the assembler code to cause those functions to
- be called at the appropriate time. When you port the compiler to a new
- system, you need to specify how to do this.
-
- There are two major ways that GCC currently supports the execution of
- initialization and termination functions. Each way has two variants.
- Much of the structure is common to all four variations.
-
- The linker must build two lists of these functions--a list of
- initialization functions, called '__CTOR_LIST__', and a list of
- termination functions, called '__DTOR_LIST__'.
-
- Each list always begins with an ignored function pointer (which may
- hold 0, -1, or a count of the function pointers after it, depending on
- the environment). This is followed by a series of zero or more function
- pointers to constructors (or destructors), followed by a function
- pointer containing zero.
-
- Depending on the operating system and its executable file format,
- either 'crtstuff.c' or 'libgcc2.c' traverses these lists at startup time
- and exit time. Constructors are called in reverse order of the list;
- destructors in forward order.
-
- The best way to handle static constructors works only for object file
- formats which provide arbitrarily-named sections. A section is set
- aside for a list of constructors, and another for a list of destructors.
- Traditionally these are called '.ctors' and '.dtors'. Each object file
- that defines an initialization function also puts a word in the
- constructor section to point to that function. The linker accumulates
- all these words into one contiguous '.ctors' section. Termination
- functions are handled similarly.
-
- This method will be chosen as the default by 'target-def.h' if
- 'TARGET_ASM_NAMED_SECTION' is defined. A target that does not support
- arbitrary sections, but does support special designated constructor and
- destructor sections may define 'CTORS_SECTION_ASM_OP' and
- 'DTORS_SECTION_ASM_OP' to achieve the same effect.
-
- When arbitrary sections are available, there are two variants,
- depending upon how the code in 'crtstuff.c' is called. On systems that
- support a ".init" section which is executed at program startup, parts of
- 'crtstuff.c' are compiled into that section. The program is linked by
- the 'gcc' driver like this:
-
- ld -o OUTPUT_FILE crti.o crtbegin.o ... -lgcc crtend.o crtn.o
-
- The prologue of a function ('__init') appears in the '.init' section of
- 'crti.o'; the epilogue appears in 'crtn.o'. Likewise for the function
- '__fini' in the ".fini" section. Normally these files are provided by
- the operating system or by the GNU C library, but are provided by GCC
- for a few targets.
-
- The objects 'crtbegin.o' and 'crtend.o' are (for most targets) compiled
- from 'crtstuff.c'. They contain, among other things, code fragments
- within the '.init' and '.fini' sections that branch to routines in the
- '.text' section. The linker will pull all parts of a section together,
- which results in a complete '__init' function that invokes the routines
- we need at startup.
-
- To use this variant, you must define the 'INIT_SECTION_ASM_OP' macro
- properly.
-
- If no init section is available, when GCC compiles any function called
- 'main' (or more accurately, any function designated as a program entry
- point by the language front end calling 'expand_main_function'), it
- inserts a procedure call to '__main' as the first executable code after
- the function prologue. The '__main' function is defined in 'libgcc2.c'
- and runs the global constructors.
-
- In file formats that don't support arbitrary sections, there are again
- two variants. In the simplest variant, the GNU linker (GNU 'ld') and an
- 'a.out' format must be used. In this case, 'TARGET_ASM_CONSTRUCTOR' is
- defined to produce a '.stabs' entry of type 'N_SETT', referencing the
- name '__CTOR_LIST__', and with the address of the void function
- containing the initialization code as its value. The GNU linker
- recognizes this as a request to add the value to a "set"; the values are
- accumulated, and are eventually placed in the executable as a vector in
- the format described above, with a leading (ignored) count and a
- trailing zero element. 'TARGET_ASM_DESTRUCTOR' is handled similarly.
- Since no init section is available, the absence of 'INIT_SECTION_ASM_OP'
- causes the compilation of 'main' to call '__main' as above, starting the
- initialization process.
-
- The last variant uses neither arbitrary sections nor the GNU linker.
- This is preferable when you want to do dynamic linking and when using
- file formats which the GNU linker does not support, such as 'ECOFF'. In
- this case, 'TARGET_HAVE_CTORS_DTORS' is false, initialization and
- termination functions are recognized simply by their names. This
- requires an extra program in the linkage step, called 'collect2'. This
- program pretends to be the linker, for use with GCC; it does its job by
- running the ordinary linker, but also arranges to include the vectors of
- initialization and termination functions. These functions are called
- via '__main' as described above. In order to use this method,
- 'use_collect2' must be defined in the target in 'config.gcc'.
-
- The following section describes the specific macros that control and
- customize the handling of initialization and termination functions.
-
-
- File: gccint.info, Node: Macros for Initialization, Next: Instruction Output, Prev: Initialization, Up: Assembler Format
-
- 18.20.6 Macros Controlling Initialization Routines
- --------------------------------------------------
-
- Here are the macros that control how the compiler handles initialization
- and termination functions:
-
- -- Macro: INIT_SECTION_ASM_OP
- If defined, a C string constant, including spacing, for the
- assembler operation to identify the following data as
- initialization code. If not defined, GCC will assume such a
- section does not exist. When you are using special sections for
- initialization and termination functions, this macro also controls
- how 'crtstuff.c' and 'libgcc2.c' arrange to run the initialization
- functions.
-
- -- Macro: HAS_INIT_SECTION
- If defined, 'main' will not call '__main' as described above. This
- macro should be defined for systems that control start-up code on a
- symbol-by-symbol basis, such as OSF/1, and should not be defined
- explicitly for systems that support 'INIT_SECTION_ASM_OP'.
-
- -- Macro: LD_INIT_SWITCH
- If defined, a C string constant for a switch that tells the linker
- that the following symbol is an initialization routine.
-
- -- Macro: LD_FINI_SWITCH
- If defined, a C string constant for a switch that tells the linker
- that the following symbol is a finalization routine.
-
- -- Macro: COLLECT_SHARED_INIT_FUNC (STREAM, FUNC)
- If defined, a C statement that will write a function that can be
- automatically called when a shared library is loaded. The function
- should call FUNC, which takes no arguments. If not defined, and
- the object format requires an explicit initialization function,
- then a function called '_GLOBAL__DI' will be generated.
-
- This function and the following one are used by collect2 when
- linking a shared library that needs constructors or destructors, or
- has DWARF2 exception tables embedded in the code.
-
- -- Macro: COLLECT_SHARED_FINI_FUNC (STREAM, FUNC)
- If defined, a C statement that will write a function that can be
- automatically called when a shared library is unloaded. The
- function should call FUNC, which takes no arguments. If not
- defined, and the object format requires an explicit finalization
- function, then a function called '_GLOBAL__DD' will be generated.
-
- -- Macro: INVOKE__main
- If defined, 'main' will call '__main' despite the presence of
- 'INIT_SECTION_ASM_OP'. This macro should be defined for systems
- where the init section is not actually run automatically, but is
- still useful for collecting the lists of constructors and
- destructors.
-
- -- Macro: SUPPORTS_INIT_PRIORITY
- If nonzero, the C++ 'init_priority' attribute is supported and the
- compiler should emit instructions to control the order of
- initialization of objects. If zero, the compiler will issue an
- error message upon encountering an 'init_priority' attribute.
-
- -- Target Hook: bool TARGET_HAVE_CTORS_DTORS
- This value is true if the target supports some "native" method of
- collecting constructors and destructors to be run at startup and
- exit. It is false if we must use 'collect2'.
-
- -- Target Hook: void TARGET_ASM_CONSTRUCTOR (rtx SYMBOL, int PRIORITY)
- If defined, a function that outputs assembler code to arrange to
- call the function referenced by SYMBOL at initialization time.
-
- Assume that SYMBOL is a 'SYMBOL_REF' for a function taking no
- arguments and with no return value. If the target supports
- initialization priorities, PRIORITY is a value between 0 and
- 'MAX_INIT_PRIORITY'; otherwise it must be 'DEFAULT_INIT_PRIORITY'.
-
- If this macro is not defined by the target, a suitable default will
- be chosen if (1) the target supports arbitrary section names, (2)
- the target defines 'CTORS_SECTION_ASM_OP', or (3) 'USE_COLLECT2' is
- not defined.
-
- -- Target Hook: void TARGET_ASM_DESTRUCTOR (rtx SYMBOL, int PRIORITY)
- This is like 'TARGET_ASM_CONSTRUCTOR' but used for termination
- functions rather than initialization functions.
-
- If 'TARGET_HAVE_CTORS_DTORS' is true, the initialization routine
- generated for the generated object file will have static linkage.
-
- If your system uses 'collect2' as the means of processing constructors,
- then that program normally uses 'nm' to scan an object file for
- constructor functions to be called.
-
- On certain kinds of systems, you can define this macro to make
- 'collect2' work faster (and, in some cases, make it work at all):
-
- -- Macro: OBJECT_FORMAT_COFF
- Define this macro if the system uses COFF (Common Object File
- Format) object files, so that 'collect2' can assume this format and
- scan object files directly for dynamic constructor/destructor
- functions.
-
- This macro is effective only in a native compiler; 'collect2' as
- part of a cross compiler always uses 'nm' for the target machine.
-
- -- Macro: REAL_NM_FILE_NAME
- Define this macro as a C string constant containing the file name
- to use to execute 'nm'. The default is to search the path normally
- for 'nm'.
-
- -- Macro: NM_FLAGS
- 'collect2' calls 'nm' to scan object files for static constructors
- and destructors and LTO info. By default, '-n' is passed. Define
- 'NM_FLAGS' to a C string constant if other options are needed to
- get the same output format as GNU 'nm -n' produces.
-
- If your system supports shared libraries and has a program to list the
- dynamic dependencies of a given library or executable, you can define
- these macros to enable support for running initialization and
- termination functions in shared libraries:
-
- -- Macro: LDD_SUFFIX
- Define this macro to a C string constant containing the name of the
- program which lists dynamic dependencies, like 'ldd' under SunOS 4.
-
- -- Macro: PARSE_LDD_OUTPUT (PTR)
- Define this macro to be C code that extracts filenames from the
- output of the program denoted by 'LDD_SUFFIX'. PTR is a variable
- of type 'char *' that points to the beginning of a line of output
- from 'LDD_SUFFIX'. If the line lists a dynamic dependency, the
- code must advance PTR to the beginning of the filename on that
- line. Otherwise, it must set PTR to 'NULL'.
-
- -- Macro: SHLIB_SUFFIX
- Define this macro to a C string constant containing the default
- shared library extension of the target (e.g., '".so"'). 'collect2'
- strips version information after this suffix when generating global
- constructor and destructor names. This define is only needed on
- targets that use 'collect2' to process constructors and
- destructors.
-
-
- File: gccint.info, Node: Instruction Output, Next: Dispatch Tables, Prev: Macros for Initialization, Up: Assembler Format
-
- 18.20.7 Output of Assembler Instructions
- ----------------------------------------
-
- This describes assembler instruction output.
-
- -- Macro: REGISTER_NAMES
- A C initializer containing the assembler's names for the machine
- registers, each one as a C string constant. This is what
- translates register numbers in the compiler into assembler
- language.
-
- -- Macro: ADDITIONAL_REGISTER_NAMES
- If defined, a C initializer for an array of structures containing a
- name and a register number. This macro defines additional names
- for hard registers, thus allowing the 'asm' option in declarations
- to refer to registers using alternate names.
-
- -- Macro: OVERLAPPING_REGISTER_NAMES
- If defined, a C initializer for an array of structures containing a
- name, a register number and a count of the number of consecutive
- machine registers the name overlaps. This macro defines additional
- names for hard registers, thus allowing the 'asm' option in
- declarations to refer to registers using alternate names. Unlike
- 'ADDITIONAL_REGISTER_NAMES', this macro should be used when the
- register name implies multiple underlying registers.
-
- This macro should be used when it is important that a clobber in an
- 'asm' statement clobbers all the underlying values implied by the
- register name. For example, on ARM, clobbering the
- double-precision VFP register "d0" implies clobbering both
- single-precision registers "s0" and "s1".
-
- -- Macro: ASM_OUTPUT_OPCODE (STREAM, PTR)
- Define this macro if you are using an unusual assembler that
- requires different names for the machine instructions.
-
- The definition is a C statement or statements which output an
- assembler instruction opcode to the stdio stream STREAM. The
- macro-operand PTR is a variable of type 'char *' which points to
- the opcode name in its "internal" form--the form that is written in
- the machine description. The definition should output the opcode
- name to STREAM, performing any translation you desire, and
- increment the variable PTR to point at the end of the opcode so
- that it will not be output twice.
-
- In fact, your macro definition may process less than the entire
- opcode name, or more than the opcode name; but if you want to
- process text that includes '%'-sequences to substitute operands,
- you must take care of the substitution yourself. Just be sure to
- increment PTR over whatever text should not be output normally.
-
- If you need to look at the operand values, they can be found as the
- elements of 'recog_data.operand'.
-
- If the macro definition does nothing, the instruction is output in
- the usual way.
-
- -- Macro: FINAL_PRESCAN_INSN (INSN, OPVEC, NOPERANDS)
- If defined, a C statement to be executed just prior to the output
- of assembler code for INSN, to modify the extracted operands so
- they will be output differently.
-
- Here the argument OPVEC is the vector containing the operands
- extracted from INSN, and NOPERANDS is the number of elements of the
- vector which contain meaningful data for this insn. The contents
- of this vector are what will be used to convert the insn template
- into assembler code, so you can change the assembler output by
- changing the contents of the vector.
-
- This macro is useful when various assembler syntaxes share a single
- file of instruction patterns; by defining this macro differently,
- you can cause a large class of instructions to be output
- differently (such as with rearranged operands). Naturally,
- variations in assembler syntax affecting individual insn patterns
- ought to be handled by writing conditional output routines in those
- patterns.
-
- If this macro is not defined, it is equivalent to a null statement.
-
- -- Target Hook: void TARGET_ASM_FINAL_POSTSCAN_INSN (FILE *FILE,
- rtx_insn *INSN, rtx *OPVEC, int NOPERANDS)
- If defined, this target hook is a function which is executed just
- after the output of assembler code for INSN, to change the mode of
- the assembler if necessary.
-
- Here the argument OPVEC is the vector containing the operands
- extracted from INSN, and NOPERANDS is the number of elements of the
- vector which contain meaningful data for this insn. The contents
- of this vector are what was used to convert the insn template into
- assembler code, so you can change the assembler mode by checking
- the contents of the vector.
-
- -- Macro: PRINT_OPERAND (STREAM, X, CODE)
- A C compound statement to output to stdio stream STREAM the
- assembler syntax for an instruction operand X. X is an RTL
- expression.
-
- CODE is a value that can be used to specify one of several ways of
- printing the operand. It is used when identical operands must be
- printed differently depending on the context. CODE comes from the
- '%' specification that was used to request printing of the operand.
- If the specification was just '%DIGIT' then CODE is 0; if the
- specification was '%LTR DIGIT' then CODE is the ASCII code for LTR.
-
- If X is a register, this macro should print the register's name.
- The names can be found in an array 'reg_names' whose type is 'char
- *[]'. 'reg_names' is initialized from 'REGISTER_NAMES'.
-
- When the machine description has a specification '%PUNCT' (a '%'
- followed by a punctuation character), this macro is called with a
- null pointer for X and the punctuation character for CODE.
-
- -- Macro: PRINT_OPERAND_PUNCT_VALID_P (CODE)
- A C expression which evaluates to true if CODE is a valid
- punctuation character for use in the 'PRINT_OPERAND' macro. If
- 'PRINT_OPERAND_PUNCT_VALID_P' is not defined, it means that no
- punctuation characters (except for the standard one, '%') are used
- in this way.
-
- -- Macro: PRINT_OPERAND_ADDRESS (STREAM, X)
- A C compound statement to output to stdio stream STREAM the
- assembler syntax for an instruction operand that is a memory
- reference whose address is X. X is an RTL expression.
-
- On some machines, the syntax for a symbolic address depends on the
- section that the address refers to. On these machines, define the
- hook 'TARGET_ENCODE_SECTION_INFO' to store the information into the
- 'symbol_ref', and then check for it here. *Note Assembler
- Format::.
-
- -- Macro: DBR_OUTPUT_SEQEND (FILE)
- A C statement, to be executed after all slot-filler instructions
- have been output. If necessary, call 'dbr_sequence_length' to
- determine the number of slots filled in a sequence (zero if not
- currently outputting a sequence), to decide how many no-ops to
- output, or whatever.
-
- Don't define this macro if it has nothing to do, but it is helpful
- in reading assembly output if the extent of the delay sequence is
- made explicit (e.g. with white space).
-
- Note that output routines for instructions with delay slots must be
- prepared to deal with not being output as part of a sequence (i.e. when
- the scheduling pass is not run, or when no slot fillers could be found.)
- The variable 'final_sequence' is null when not processing a sequence,
- otherwise it contains the 'sequence' rtx being output.
-
- -- Macro: REGISTER_PREFIX
- -- Macro: LOCAL_LABEL_PREFIX
- -- Macro: USER_LABEL_PREFIX
- -- Macro: IMMEDIATE_PREFIX
- If defined, C string expressions to be used for the '%R', '%L',
- '%U', and '%I' options of 'asm_fprintf' (see 'final.c'). These are
- useful when a single 'md' file must support multiple assembler
- formats. In that case, the various 'tm.h' files can define these
- macros differently.
-
- -- Macro: ASM_FPRINTF_EXTENSIONS (FILE, ARGPTR, FORMAT)
- If defined this macro should expand to a series of 'case'
- statements which will be parsed inside the 'switch' statement of
- the 'asm_fprintf' function. This allows targets to define extra
- printf formats which may useful when generating their assembler
- statements. Note that uppercase letters are reserved for future
- generic extensions to asm_fprintf, and so are not available to
- target specific code. The output file is given by the parameter
- FILE. The varargs input pointer is ARGPTR and the rest of the
- format string, starting the character after the one that is being
- switched upon, is pointed to by FORMAT.
-
- -- Macro: ASSEMBLER_DIALECT
- If your target supports multiple dialects of assembler language
- (such as different opcodes), define this macro as a C expression
- that gives the numeric index of the assembler language dialect to
- use, with zero as the first variant.
-
- If this macro is defined, you may use constructs of the form
- '{option0|option1|option2...}'
- in the output templates of patterns (*note Output Template::) or in
- the first argument of 'asm_fprintf'. This construct outputs
- 'option0', 'option1', 'option2', etc., if the value of
- 'ASSEMBLER_DIALECT' is zero, one, two, etc. Any special characters
- within these strings retain their usual meaning. If there are
- fewer alternatives within the braces than the value of
- 'ASSEMBLER_DIALECT', the construct outputs nothing. If it's needed
- to print curly braces or '|' character in assembler output
- directly, '%{', '%}' and '%|' can be used.
-
- If you do not define this macro, the characters '{', '|' and '}' do
- not have any special meaning when used in templates or operands to
- 'asm_fprintf'.
-
- Define the macros 'REGISTER_PREFIX', 'LOCAL_LABEL_PREFIX',
- 'USER_LABEL_PREFIX' and 'IMMEDIATE_PREFIX' if you can express the
- variations in assembler language syntax with that mechanism.
- Define 'ASSEMBLER_DIALECT' and use the '{option0|option1}' syntax
- if the syntax variant are larger and involve such things as
- different opcodes or operand order.
-
- -- Macro: ASM_OUTPUT_REG_PUSH (STREAM, REGNO)
- A C expression to output to STREAM some assembler code which will
- push hard register number REGNO onto the stack. The code need not
- be optimal, since this macro is used only when profiling.
-
- -- Macro: ASM_OUTPUT_REG_POP (STREAM, REGNO)
- A C expression to output to STREAM some assembler code which will
- pop hard register number REGNO off of the stack. The code need not
- be optimal, since this macro is used only when profiling.
-
-
- File: gccint.info, Node: Dispatch Tables, Next: Exception Region Output, Prev: Instruction Output, Up: Assembler Format
-
- 18.20.8 Output of Dispatch Tables
- ---------------------------------
-
- This concerns dispatch tables.
-
- -- Macro: ASM_OUTPUT_ADDR_DIFF_ELT (STREAM, BODY, VALUE, REL)
- A C statement to output to the stdio stream STREAM an assembler
- pseudo-instruction to generate a difference between two labels.
- VALUE and REL are the numbers of two internal labels. The
- definitions of these labels are output using
- '(*targetm.asm_out.internal_label)', and they must be printed in
- the same way here. For example,
-
- fprintf (STREAM, "\t.word L%d-L%d\n",
- VALUE, REL)
-
- You must provide this macro on machines where the addresses in a
- dispatch table are relative to the table's own address. If
- defined, GCC will also use this macro on all machines when
- producing PIC. BODY is the body of the 'ADDR_DIFF_VEC'; it is
- provided so that the mode and flags can be read.
-
- -- Macro: ASM_OUTPUT_ADDR_VEC_ELT (STREAM, VALUE)
- This macro should be provided on machines where the addresses in a
- dispatch table are absolute.
-
- The definition should be a C statement to output to the stdio
- stream STREAM an assembler pseudo-instruction to generate a
- reference to a label. VALUE is the number of an internal label
- whose definition is output using
- '(*targetm.asm_out.internal_label)'. For example,
-
- fprintf (STREAM, "\t.word L%d\n", VALUE)
-
- -- Macro: ASM_OUTPUT_CASE_LABEL (STREAM, PREFIX, NUM, TABLE)
- Define this if the label before a jump-table needs to be output
- specially. The first three arguments are the same as for
- '(*targetm.asm_out.internal_label)'; the fourth argument is the
- jump-table which follows (a 'jump_table_data' containing an
- 'addr_vec' or 'addr_diff_vec').
-
- This feature is used on system V to output a 'swbeg' statement for
- the table.
-
- If this macro is not defined, these labels are output with
- '(*targetm.asm_out.internal_label)'.
-
- -- Macro: ASM_OUTPUT_CASE_END (STREAM, NUM, TABLE)
- Define this if something special must be output at the end of a
- jump-table. The definition should be a C statement to be executed
- after the assembler code for the table is written. It should write
- the appropriate code to stdio stream STREAM. The argument TABLE is
- the jump-table insn, and NUM is the label-number of the preceding
- label.
-
- If this macro is not defined, nothing special is output at the end
- of the jump-table.
-
- -- Target Hook: void TARGET_ASM_POST_CFI_STARTPROC (FILE *, TREE)
- This target hook is used to emit assembly strings required by the
- target after the .cfi_startproc directive. The first argument is
- the file stream to write the strings to and the second argument is
- the function's declaration. The expected use is to add more .cfi_*
- directives.
-
- The default is to not output any assembly strings.
-
- -- Target Hook: void TARGET_ASM_EMIT_UNWIND_LABEL (FILE *STREAM, tree
- DECL, int FOR_EH, int EMPTY)
- This target hook emits a label at the beginning of each FDE. It
- should be defined on targets where FDEs need special labels, and it
- should write the appropriate label, for the FDE associated with the
- function declaration DECL, to the stdio stream STREAM. The third
- argument, FOR_EH, is a boolean: true if this is for an exception
- table. The fourth argument, EMPTY, is a boolean: true if this is a
- placeholder label for an omitted FDE.
-
- The default is that FDEs are not given nonlocal labels.
-
- -- Target Hook: void TARGET_ASM_EMIT_EXCEPT_TABLE_LABEL (FILE *STREAM)
- This target hook emits a label at the beginning of the exception
- table. It should be defined on targets where it is desirable for
- the table to be broken up according to function.
-
- The default is that no label is emitted.
-
- -- Target Hook: void TARGET_ASM_EMIT_EXCEPT_PERSONALITY (rtx
- PERSONALITY)
- If the target implements 'TARGET_ASM_UNWIND_EMIT', this hook may be
- used to emit a directive to install a personality hook into the
- unwind info. This hook should not be used if dwarf2 unwind info is
- used.
-
- -- Target Hook: void TARGET_ASM_UNWIND_EMIT (FILE *STREAM, rtx_insn
- *INSN)
- This target hook emits assembly directives required to unwind the
- given instruction. This is only used when
- 'TARGET_EXCEPT_UNWIND_INFO' returns 'UI_TARGET'.
-
- -- Target Hook: bool TARGET_ASM_UNWIND_EMIT_BEFORE_INSN
- True if the 'TARGET_ASM_UNWIND_EMIT' hook should be called before
- the assembly for INSN has been emitted, false if the hook should be
- called afterward.
-
-
- File: gccint.info, Node: Exception Region Output, Next: Alignment Output, Prev: Dispatch Tables, Up: Assembler Format
-
- 18.20.9 Assembler Commands for Exception Regions
- ------------------------------------------------
-
- This describes commands marking the start and the end of an exception
- region.
-
- -- Macro: EH_FRAME_SECTION_NAME
- If defined, a C string constant for the name of the section
- containing exception handling frame unwind information. If not
- defined, GCC will provide a default definition if the target
- supports named sections. 'crtstuff.c' uses this macro to switch to
- the appropriate section.
-
- You should define this symbol if your target supports DWARF 2 frame
- unwind information and the default definition does not work.
-
- -- Macro: EH_FRAME_THROUGH_COLLECT2
- If defined, DWARF 2 frame unwind information will identified by
- specially named labels. The collect2 process will locate these
- labels and generate code to register the frames.
-
- This might be necessary, for instance, if the system linker will
- not place the eh_frames in-between the sentinals from 'crtstuff.c',
- or if the system linker does garbage collection and sections cannot
- be marked as not to be collected.
-
- -- Macro: EH_TABLES_CAN_BE_READ_ONLY
- Define this macro to 1 if your target is such that no frame unwind
- information encoding used with non-PIC code will ever require a
- runtime relocation, but the linker may not support merging
- read-only and read-write sections into a single read-write section.
-
- -- Macro: MASK_RETURN_ADDR
- An rtx used to mask the return address found via 'RETURN_ADDR_RTX',
- so that it does not contain any extraneous set bits in it.
-
- -- Macro: DWARF2_UNWIND_INFO
- Define this macro to 0 if your target supports DWARF 2 frame unwind
- information, but it does not yet work with exception handling.
- Otherwise, if your target supports this information (if it defines
- 'INCOMING_RETURN_ADDR_RTX' and 'OBJECT_FORMAT_ELF'), GCC will
- provide a default definition of 1.
-
- -- Common Target Hook: enum unwind_info_type TARGET_EXCEPT_UNWIND_INFO
- (struct gcc_options *OPTS)
- This hook defines the mechanism that will be used for exception
- handling by the target. If the target has ABI specified unwind
- tables, the hook should return 'UI_TARGET'. If the target is to
- use the 'setjmp'/'longjmp'-based exception handling scheme, the
- hook should return 'UI_SJLJ'. If the target supports DWARF 2 frame
- unwind information, the hook should return 'UI_DWARF2'.
-
- A target may, if exceptions are disabled, choose to return
- 'UI_NONE'. This may end up simplifying other parts of
- target-specific code. The default implementation of this hook
- never returns 'UI_NONE'.
-
- Note that the value returned by this hook should be constant. It
- should not depend on anything except the command-line switches
- described by OPTS. In particular, the setting 'UI_SJLJ' must be
- fixed at compiler start-up as C pre-processor macros and builtin
- functions related to exception handling are set up depending on
- this setting.
-
- The default implementation of the hook first honors the
- '--enable-sjlj-exceptions' configure option, then
- 'DWARF2_UNWIND_INFO', and finally defaults to 'UI_SJLJ'. If
- 'DWARF2_UNWIND_INFO' depends on command-line options, the target
- must define this hook so that OPTS is used correctly.
-
- -- Common Target Hook: bool TARGET_UNWIND_TABLES_DEFAULT
- This variable should be set to 'true' if the target ABI requires
- unwinding tables even when exceptions are not used. It must not be
- modified by command-line option processing.
-
- -- Macro: DONT_USE_BUILTIN_SETJMP
- Define this macro to 1 if the 'setjmp'/'longjmp'-based scheme
- should use the 'setjmp'/'longjmp' functions from the C library
- instead of the '__builtin_setjmp'/'__builtin_longjmp' machinery.
-
- -- Macro: JMP_BUF_SIZE
- This macro has no effect unless 'DONT_USE_BUILTIN_SETJMP' is also
- defined. Define this macro if the default size of 'jmp_buf' buffer
- for the 'setjmp'/'longjmp'-based exception handling mechanism is
- not large enough, or if it is much too large. The default size is
- 'FIRST_PSEUDO_REGISTER * sizeof(void *)'.
-
- -- Macro: DWARF_CIE_DATA_ALIGNMENT
- This macro need only be defined if the target might save registers
- in the function prologue at an offset to the stack pointer that is
- not aligned to 'UNITS_PER_WORD'. The definition should be the
- negative minimum alignment if 'STACK_GROWS_DOWNWARD' is true, and
- the positive minimum alignment otherwise. *Note DWARF::. Only
- applicable if the target supports DWARF 2 frame unwind information.
-
- -- Target Hook: bool TARGET_TERMINATE_DW2_EH_FRAME_INFO
- Contains the value true if the target should add a zero word onto
- the end of a Dwarf-2 frame info section when used for exception
- handling. Default value is false if 'EH_FRAME_SECTION_NAME' is
- defined, and true otherwise.
-
- -- Target Hook: rtx TARGET_DWARF_REGISTER_SPAN (rtx REG)
- Given a register, this hook should return a parallel of registers
- to represent where to find the register pieces. Define this hook
- if the register and its mode are represented in Dwarf in
- non-contiguous locations, or if the register should be represented
- in more than one register in Dwarf. Otherwise, this hook should
- return 'NULL_RTX'. If not defined, the default is to return
- 'NULL_RTX'.
-
- -- Target Hook: machine_mode TARGET_DWARF_FRAME_REG_MODE (int REGNO)
- Given a register, this hook should return the mode which the
- corresponding Dwarf frame register should have. This is normally
- used to return a smaller mode than the raw mode to prevent call
- clobbered parts of a register altering the frame register size
-
- -- Target Hook: void TARGET_INIT_DWARF_REG_SIZES_EXTRA (tree ADDRESS)
- If some registers are represented in Dwarf-2 unwind information in
- multiple pieces, define this hook to fill in information about the
- sizes of those pieces in the table used by the unwinder at runtime.
- It will be called by 'expand_builtin_init_dwarf_reg_sizes' after
- filling in a single size corresponding to each hard register;
- ADDRESS is the address of the table.
-
- -- Target Hook: bool TARGET_ASM_TTYPE (rtx SYM)
- This hook is used to output a reference from a frame unwinding
- table to the type_info object identified by SYM. It should return
- 'true' if the reference was output. Returning 'false' will cause
- the reference to be output using the normal Dwarf2 routines.
-
- -- Target Hook: bool TARGET_ARM_EABI_UNWINDER
- This flag should be set to 'true' on targets that use an ARM EABI
- based unwinding library, and 'false' on other targets. This
- effects the format of unwinding tables, and how the unwinder in
- entered after running a cleanup. The default is 'false'.
-
-
- File: gccint.info, Node: Alignment Output, Prev: Exception Region Output, Up: Assembler Format
-
- 18.20.10 Assembler Commands for Alignment
- -----------------------------------------
-
- This describes commands for alignment.
-
- -- Macro: JUMP_ALIGN (LABEL)
- The alignment (log base 2) to put in front of LABEL, which is a
- common destination of jumps and has no fallthru incoming edge.
-
- This macro need not be defined if you don't want any special
- alignment to be done at such a time. Most machine descriptions do
- not currently define the macro.
-
- Unless it's necessary to inspect the LABEL parameter, it is better
- to set the variable ALIGN_JUMPS in the target's
- 'TARGET_OPTION_OVERRIDE'. Otherwise, you should try to honor the
- user's selection in ALIGN_JUMPS in a 'JUMP_ALIGN' implementation.
-
- -- Macro: LABEL_ALIGN_AFTER_BARRIER (LABEL)
- The alignment (log base 2) to put in front of LABEL, which follows
- a 'BARRIER'.
-
- This macro need not be defined if you don't want any special
- alignment to be done at such a time. Most machine descriptions do
- not currently define the macro.
-
- -- Macro: LOOP_ALIGN (LABEL)
- The alignment (log base 2) to put in front of LABEL that heads a
- frequently executed basic block (usually the header of a loop).
-
- This macro need not be defined if you don't want any special
- alignment to be done at such a time. Most machine descriptions do
- not currently define the macro.
-
- Unless it's necessary to inspect the LABEL parameter, it is better
- to set the variable 'align_loops' in the target's
- 'TARGET_OPTION_OVERRIDE'. Otherwise, you should try to honor the
- user's selection in 'align_loops' in a 'LOOP_ALIGN' implementation.
-
- -- Macro: LABEL_ALIGN (LABEL)
- The alignment (log base 2) to put in front of LABEL. If
- 'LABEL_ALIGN_AFTER_BARRIER' / 'LOOP_ALIGN' specify a different
- alignment, the maximum of the specified values is used.
-
- Unless it's necessary to inspect the LABEL parameter, it is better
- to set the variable 'align_labels' in the target's
- 'TARGET_OPTION_OVERRIDE'. Otherwise, you should try to honor the
- user's selection in 'align_labels' in a 'LABEL_ALIGN'
- implementation.
-
- -- Macro: ASM_OUTPUT_SKIP (STREAM, NBYTES)
- A C statement to output to the stdio stream STREAM an assembler
- instruction to advance the location counter by NBYTES bytes. Those
- bytes should be zero when loaded. NBYTES will be a C expression of
- type 'unsigned HOST_WIDE_INT'.
-
- -- Macro: ASM_NO_SKIP_IN_TEXT
- Define this macro if 'ASM_OUTPUT_SKIP' should not be used in the
- text section because it fails to put zeros in the bytes that are
- skipped. This is true on many Unix systems, where the pseudo-op to
- skip bytes produces no-op instructions rather than zeros when used
- in the text section.
-
- -- Macro: ASM_OUTPUT_ALIGN (STREAM, POWER)
- A C statement to output to the stdio stream STREAM an assembler
- command to advance the location counter to a multiple of 2 to the
- POWER bytes. POWER will be a C expression of type 'int'.
-
- -- Macro: ASM_OUTPUT_ALIGN_WITH_NOP (STREAM, POWER)
- Like 'ASM_OUTPUT_ALIGN', except that the "nop" instruction is used
- for padding, if necessary.
-
- -- Macro: ASM_OUTPUT_MAX_SKIP_ALIGN (STREAM, POWER, MAX_SKIP)
- A C statement to output to the stdio stream STREAM an assembler
- command to advance the location counter to a multiple of 2 to the
- POWER bytes, but only if MAX_SKIP or fewer bytes are needed to
- satisfy the alignment request. POWER and MAX_SKIP will be a C
- expression of type 'int'.
-
-
- File: gccint.info, Node: Debugging Info, Next: Floating Point, Prev: Assembler Format, Up: Target Macros
-
- 18.21 Controlling Debugging Information Format
- ==============================================
-
- This describes how to specify debugging information.
-
- * Menu:
-
- * All Debuggers:: Macros that affect all debugging formats uniformly.
- * DBX Options:: Macros enabling specific options in DBX format.
- * DBX Hooks:: Hook macros for varying DBX format.
- * File Names and DBX:: Macros controlling output of file names in DBX format.
- * DWARF:: Macros for DWARF format.
- * VMS Debug:: Macros for VMS debug format.
-
-
- File: gccint.info, Node: All Debuggers, Next: DBX Options, Up: Debugging Info
-
- 18.21.1 Macros Affecting All Debugging Formats
- ----------------------------------------------
-
- These macros affect all debugging formats.
-
- -- Macro: DBX_REGISTER_NUMBER (REGNO)
- A C expression that returns the DBX register number for the
- compiler register number REGNO. In the default macro provided, the
- value of this expression will be REGNO itself. But sometimes there
- are some registers that the compiler knows about and DBX does not,
- or vice versa. In such cases, some register may need to have one
- number in the compiler and another for DBX.
-
- If two registers have consecutive numbers inside GCC, and they can
- be used as a pair to hold a multiword value, then they _must_ have
- consecutive numbers after renumbering with 'DBX_REGISTER_NUMBER'.
- Otherwise, debuggers will be unable to access such a pair, because
- they expect register pairs to be consecutive in their own numbering
- scheme.
-
- If you find yourself defining 'DBX_REGISTER_NUMBER' in way that
- does not preserve register pairs, then what you must do instead is
- redefine the actual register numbering scheme.
-
- -- Macro: DEBUGGER_AUTO_OFFSET (X)
- A C expression that returns the integer offset value for an
- automatic variable having address X (an RTL expression). The
- default computation assumes that X is based on the frame-pointer
- and gives the offset from the frame-pointer. This is required for
- targets that produce debugging output for DBX and allow the
- frame-pointer to be eliminated when the '-g' option is used.
-
- -- Macro: DEBUGGER_ARG_OFFSET (OFFSET, X)
- A C expression that returns the integer offset value for an
- argument having address X (an RTL expression). The nominal offset
- is OFFSET.
-
- -- Macro: PREFERRED_DEBUGGING_TYPE
- A C expression that returns the type of debugging output GCC should
- produce when the user specifies just '-g'. Define this if you have
- arranged for GCC to support more than one format of debugging
- output. Currently, the allowable values are 'DBX_DEBUG',
- 'DWARF2_DEBUG', 'XCOFF_DEBUG', 'VMS_DEBUG', and
- 'VMS_AND_DWARF2_DEBUG'.
-
- When the user specifies '-ggdb', GCC normally also uses the value
- of this macro to select the debugging output format, but with two
- exceptions. If 'DWARF2_DEBUGGING_INFO' is defined, GCC uses the
- value 'DWARF2_DEBUG'. Otherwise, if 'DBX_DEBUGGING_INFO' is
- defined, GCC uses 'DBX_DEBUG'.
-
- The value of this macro only affects the default debugging output;
- the user can always get a specific type of output by using
- '-gstabs', '-gdwarf-2', '-gxcoff', or '-gvms'.
-
-
- File: gccint.info, Node: DBX Options, Next: DBX Hooks, Prev: All Debuggers, Up: Debugging Info
-
- 18.21.2 Specific Options for DBX Output
- ---------------------------------------
-
- These are specific options for DBX output.
-
- -- Macro: DBX_DEBUGGING_INFO
- Define this macro if GCC should produce debugging output for DBX in
- response to the '-g' option.
-
- -- Macro: XCOFF_DEBUGGING_INFO
- Define this macro if GCC should produce XCOFF format debugging
- output in response to the '-g' option. This is a variant of DBX
- format.
-
- -- Macro: DEFAULT_GDB_EXTENSIONS
- Define this macro to control whether GCC should by default generate
- GDB's extended version of DBX debugging information (assuming
- DBX-format debugging information is enabled at all). If you don't
- define the macro, the default is 1: always generate the extended
- information if there is any occasion to.
-
- -- Macro: DEBUG_SYMS_TEXT
- Define this macro if all '.stabs' commands should be output while
- in the text section.
-
- -- Macro: ASM_STABS_OP
- A C string constant, including spacing, naming the assembler pseudo
- op to use instead of '"\t.stabs\t"' to define an ordinary debugging
- symbol. If you don't define this macro, '"\t.stabs\t"' is used.
- This macro applies only to DBX debugging information format.
-
- -- Macro: ASM_STABD_OP
- A C string constant, including spacing, naming the assembler pseudo
- op to use instead of '"\t.stabd\t"' to define a debugging symbol
- whose value is the current location. If you don't define this
- macro, '"\t.stabd\t"' is used. This macro applies only to DBX
- debugging information format.
-
- -- Macro: ASM_STABN_OP
- A C string constant, including spacing, naming the assembler pseudo
- op to use instead of '"\t.stabn\t"' to define a debugging symbol
- with no name. If you don't define this macro, '"\t.stabn\t"' is
- used. This macro applies only to DBX debugging information format.
-
- -- Macro: DBX_NO_XREFS
- Define this macro if DBX on your system does not support the
- construct 'xsTAGNAME'. On some systems, this construct is used to
- describe a forward reference to a structure named TAGNAME. On
- other systems, this construct is not supported at all.
-
- -- Macro: DBX_CONTIN_LENGTH
- A symbol name in DBX-format debugging information is normally
- continued (split into two separate '.stabs' directives) when it
- exceeds a certain length (by default, 80 characters). On some
- operating systems, DBX requires this splitting; on others,
- splitting must not be done. You can inhibit splitting by defining
- this macro with the value zero. You can override the default
- splitting-length by defining this macro as an expression for the
- length you desire.
-
- -- Macro: DBX_CONTIN_CHAR
- Normally continuation is indicated by adding a '\' character to the
- end of a '.stabs' string when a continuation follows. To use a
- different character instead, define this macro as a character
- constant for the character you want to use. Do not define this
- macro if backslash is correct for your system.
-
- -- Macro: DBX_STATIC_STAB_DATA_SECTION
- Define this macro if it is necessary to go to the data section
- before outputting the '.stabs' pseudo-op for a non-global static
- variable.
-
- -- Macro: DBX_TYPE_DECL_STABS_CODE
- The value to use in the "code" field of the '.stabs' directive for
- a typedef. The default is 'N_LSYM'.
-
- -- Macro: DBX_STATIC_CONST_VAR_CODE
- The value to use in the "code" field of the '.stabs' directive for
- a static variable located in the text section. DBX format does not
- provide any "right" way to do this. The default is 'N_FUN'.
-
- -- Macro: DBX_REGPARM_STABS_CODE
- The value to use in the "code" field of the '.stabs' directive for
- a parameter passed in registers. DBX format does not provide any
- "right" way to do this. The default is 'N_RSYM'.
-
- -- Macro: DBX_REGPARM_STABS_LETTER
- The letter to use in DBX symbol data to identify a symbol as a
- parameter passed in registers. DBX format does not customarily
- provide any way to do this. The default is ''P''.
-
- -- Macro: DBX_FUNCTION_FIRST
- Define this macro if the DBX information for a function and its
- arguments should precede the assembler code for the function.
- Normally, in DBX format, the debugging information entirely follows
- the assembler code.
-
- -- Macro: DBX_BLOCKS_FUNCTION_RELATIVE
- Define this macro, with value 1, if the value of a symbol
- describing the scope of a block ('N_LBRAC' or 'N_RBRAC') should be
- relative to the start of the enclosing function. Normally, GCC
- uses an absolute address.
-
- -- Macro: DBX_LINES_FUNCTION_RELATIVE
- Define this macro, with value 1, if the value of a symbol
- indicating the current line number ('N_SLINE') should be relative
- to the start of the enclosing function. Normally, GCC uses an
- absolute address.
-
- -- Macro: DBX_USE_BINCL
- Define this macro if GCC should generate 'N_BINCL' and 'N_EINCL'
- stabs for included header files, as on Sun systems. This macro
- also directs GCC to output a type number as a pair of a file number
- and a type number within the file. Normally, GCC does not generate
- 'N_BINCL' or 'N_EINCL' stabs, and it outputs a single number for a
- type number.
-
-
- File: gccint.info, Node: DBX Hooks, Next: File Names and DBX, Prev: DBX Options, Up: Debugging Info
-
- 18.21.3 Open-Ended Hooks for DBX Format
- ---------------------------------------
-
- These are hooks for DBX format.
-
- -- Macro: DBX_OUTPUT_SOURCE_LINE (STREAM, LINE, COUNTER)
- A C statement to output DBX debugging information before code for
- line number LINE of the current source file to the stdio stream
- STREAM. COUNTER is the number of time the macro was invoked,
- including the current invocation; it is intended to generate unique
- labels in the assembly output.
-
- This macro should not be defined if the default output is correct,
- or if it can be made correct by defining
- 'DBX_LINES_FUNCTION_RELATIVE'.
-
- -- Macro: NO_DBX_FUNCTION_END
- Some stabs encapsulation formats (in particular ECOFF), cannot
- handle the '.stabs "",N_FUN,,0,0,Lscope-function-1' gdb dbx
- extension construct. On those machines, define this macro to turn
- this feature off without disturbing the rest of the gdb extensions.
-
- -- Macro: NO_DBX_BNSYM_ENSYM
- Some assemblers cannot handle the '.stabd BNSYM/ENSYM,0,0' gdb dbx
- extension construct. On those machines, define this macro to turn
- this feature off without disturbing the rest of the gdb extensions.
-
-
- File: gccint.info, Node: File Names and DBX, Next: DWARF, Prev: DBX Hooks, Up: Debugging Info
-
- 18.21.4 File Names in DBX Format
- --------------------------------
-
- This describes file names in DBX format.
-
- -- Macro: DBX_OUTPUT_MAIN_SOURCE_FILENAME (STREAM, NAME)
- A C statement to output DBX debugging information to the stdio
- stream STREAM, which indicates that file NAME is the main source
- file--the file specified as the input file for compilation. This
- macro is called only once, at the beginning of compilation.
-
- This macro need not be defined if the standard form of output for
- DBX debugging information is appropriate.
-
- It may be necessary to refer to a label equal to the beginning of
- the text section. You can use 'assemble_name (stream,
- ltext_label_name)' to do so. If you do this, you must also set the
- variable USED_LTEXT_LABEL_NAME to 'true'.
-
- -- Macro: NO_DBX_MAIN_SOURCE_DIRECTORY
- Define this macro, with value 1, if GCC should not emit an
- indication of the current directory for compilation and current
- source language at the beginning of the file.
-
- -- Macro: NO_DBX_GCC_MARKER
- Define this macro, with value 1, if GCC should not emit an
- indication that this object file was compiled by GCC. The default
- is to emit an 'N_OPT' stab at the beginning of every source file,
- with 'gcc2_compiled.' for the string and value 0.
-
- -- Macro: DBX_OUTPUT_MAIN_SOURCE_FILE_END (STREAM, NAME)
- A C statement to output DBX debugging information at the end of
- compilation of the main source file NAME. Output should be written
- to the stdio stream STREAM.
-
- If you don't define this macro, nothing special is output at the
- end of compilation, which is correct for most machines.
-
- -- Macro: DBX_OUTPUT_NULL_N_SO_AT_MAIN_SOURCE_FILE_END
- Define this macro _instead of_ defining
- 'DBX_OUTPUT_MAIN_SOURCE_FILE_END', if what needs to be output at
- the end of compilation is an 'N_SO' stab with an empty string,
- whose value is the highest absolute text address in the file.
-
-
- File: gccint.info, Node: DWARF, Next: VMS Debug, Prev: File Names and DBX, Up: Debugging Info
-
- 18.21.5 Macros for DWARF Output
- -------------------------------
-
- Here are macros for DWARF output.
-
- -- Macro: DWARF2_DEBUGGING_INFO
- Define this macro if GCC should produce dwarf version 2 format
- debugging output in response to the '-g' option.
-
- -- Target Hook: int TARGET_DWARF_CALLING_CONVENTION (const_tree
- FUNCTION)
- Define this to enable the dwarf attribute
- 'DW_AT_calling_convention' to be emitted for each function.
- Instead of an integer return the enum value for the 'DW_CC_'
- tag.
-
- To support optional call frame debugging information, you must also
- define 'INCOMING_RETURN_ADDR_RTX' and either set
- 'RTX_FRAME_RELATED_P' on the prologue insns if you use RTL for the
- prologue, or call 'dwarf2out_def_cfa' and 'dwarf2out_reg_save' as
- appropriate from 'TARGET_ASM_FUNCTION_PROLOGUE' if you don't.
-
- -- Macro: DWARF2_FRAME_INFO
- Define this macro to a nonzero value if GCC should always output
- Dwarf 2 frame information. If 'TARGET_EXCEPT_UNWIND_INFO' (*note
- Exception Region Output::) returns 'UI_DWARF2', and exceptions are
- enabled, GCC will output this information not matter how you define
- 'DWARF2_FRAME_INFO'.
-
- -- Target Hook: enum unwind_info_type TARGET_DEBUG_UNWIND_INFO (void)
- This hook defines the mechanism that will be used for describing
- frame unwind information to the debugger. Normally the hook will
- return 'UI_DWARF2' if DWARF 2 debug information is enabled, and
- return 'UI_NONE' otherwise.
-
- A target may return 'UI_DWARF2' even when DWARF 2 debug information
- is disabled in order to always output DWARF 2 frame information.
-
- A target may return 'UI_TARGET' if it has ABI specified unwind
- tables. This will suppress generation of the normal debug frame
- unwind information.
-
- -- Macro: DWARF2_ASM_LINE_DEBUG_INFO
- Define this macro to be a nonzero value if the assembler can
- generate Dwarf 2 line debug info sections. This will result in
- much more compact line number tables, and hence is desirable if it
- works.
-
- -- Macro: DWARF2_ASM_VIEW_DEBUG_INFO
- Define this macro to be a nonzero value if the assembler supports
- view assignment and verification in '.loc'. If it does not, but
- the user enables location views, the compiler may have to fallback
- to internal line number tables.
-
- -- Target Hook: int TARGET_RESET_LOCATION_VIEW (rtx_insn *)
- This hook, if defined, enables -ginternal-reset-location-views, and
- uses its result to override cases in which the estimated min insn
- length might be nonzero even when a PC advance (i.e., a view reset)
- cannot be taken for granted.
-
- If the hook is defined, it must return a positive value to indicate
- the insn definitely advances the PC, and so the view number can be
- safely assumed to be reset; a negative value to mean the insn
- definitely does not advance the PC, and os the view number must not
- be reset; or zero to decide based on the estimated insn length.
-
- If insn length is to be regarded as reliable, set the hook to
- 'hook_int_rtx_insn_0'.
-
- -- Target Hook: bool TARGET_WANT_DEBUG_PUB_SECTIONS
- True if the '.debug_pubtypes' and '.debug_pubnames' sections should
- be emitted. These sections are not used on most platforms, and in
- particular GDB does not use them.
-
- -- Target Hook: bool TARGET_DELAY_SCHED2
- True if sched2 is not to be run at its normal place. This usually
- means it will be run as part of machine-specific reorg.
-
- -- Target Hook: bool TARGET_DELAY_VARTRACK
- True if vartrack is not to be run at its normal place. This
- usually means it will be run as part of machine-specific reorg.
-
- -- Target Hook: bool TARGET_NO_REGISTER_ALLOCATION
- True if register allocation and the passes following it should not
- be run. Usually true only for virtual assembler targets.
-
- -- Macro: ASM_OUTPUT_DWARF_DELTA (STREAM, SIZE, LABEL1, LABEL2)
- A C statement to issue assembly directives that create a difference
- LAB1 minus LAB2, using an integer of the given SIZE.
-
- -- Macro: ASM_OUTPUT_DWARF_VMS_DELTA (STREAM, SIZE, LABEL1, LABEL2)
- A C statement to issue assembly directives that create a difference
- between the two given labels in system defined units, e.g.
- instruction slots on IA64 VMS, using an integer of the given size.
-
- -- Macro: ASM_OUTPUT_DWARF_OFFSET (STREAM, SIZE, LABEL, OFFSET,
- SECTION)
- A C statement to issue assembly directives that create a
- section-relative reference to the given LABEL plus OFFSET, using an
- integer of the given SIZE. The label is known to be defined in the
- given SECTION.
-
- -- Macro: ASM_OUTPUT_DWARF_PCREL (STREAM, SIZE, LABEL)
- A C statement to issue assembly directives that create a
- self-relative reference to the given LABEL, using an integer of the
- given SIZE.
-
- -- Macro: ASM_OUTPUT_DWARF_DATAREL (STREAM, SIZE, LABEL)
- A C statement to issue assembly directives that create a reference
- to the given LABEL relative to the dbase, using an integer of the
- given SIZE.
-
- -- Macro: ASM_OUTPUT_DWARF_TABLE_REF (LABEL)
- A C statement to issue assembly directives that create a reference
- to the DWARF table identifier LABEL from the current section. This
- is used on some systems to avoid garbage collecting a DWARF table
- which is referenced by a function.
-
- -- Target Hook: void TARGET_ASM_OUTPUT_DWARF_DTPREL (FILE *FILE, int
- SIZE, rtx X)
- If defined, this target hook is a function which outputs a
- DTP-relative reference to the given TLS symbol of the specified
- size.
-
-
- File: gccint.info, Node: VMS Debug, Prev: DWARF, Up: Debugging Info
-
- 18.21.6 Macros for VMS Debug Format
- -----------------------------------
-
- Here are macros for VMS debug format.
-
- -- Macro: VMS_DEBUGGING_INFO
- Define this macro if GCC should produce debugging output for VMS in
- response to the '-g' option. The default behavior for VMS is to
- generate minimal debug info for a traceback in the absence of '-g'
- unless explicitly overridden with '-g0'. This behavior is
- controlled by 'TARGET_OPTION_OPTIMIZATION' and
- 'TARGET_OPTION_OVERRIDE'.
-
-
- File: gccint.info, Node: Floating Point, Next: Mode Switching, Prev: Debugging Info, Up: Target Macros
-
- 18.22 Cross Compilation and Floating Point
- ==========================================
-
- While all modern machines use twos-complement representation for
- integers, there are a variety of representations for floating point
- numbers. This means that in a cross-compiler the representation of
- floating point numbers in the compiled program may be different from
- that used in the machine doing the compilation.
-
- Because different representation systems may offer different amounts of
- range and precision, all floating point constants must be represented in
- the target machine's format. Therefore, the cross compiler cannot
- safely use the host machine's floating point arithmetic; it must emulate
- the target's arithmetic. To ensure consistency, GCC always uses
- emulation to work with floating point values, even when the host and
- target floating point formats are identical.
-
- The following macros are provided by 'real.h' for the compiler to use.
- All parts of the compiler which generate or optimize floating-point
- calculations must use these macros. They may evaluate their operands
- more than once, so operands must not have side effects.
-
- -- Macro: REAL_VALUE_TYPE
- The C data type to be used to hold a floating point value in the
- target machine's format. Typically this is a 'struct' containing
- an array of 'HOST_WIDE_INT', but all code should treat it as an
- opaque quantity.
-
- -- Macro: HOST_WIDE_INT REAL_VALUE_FIX (REAL_VALUE_TYPE X)
- Truncates X to a signed integer, rounding toward zero.
-
- -- Macro: unsigned HOST_WIDE_INT REAL_VALUE_UNSIGNED_FIX
- (REAL_VALUE_TYPE X)
- Truncates X to an unsigned integer, rounding toward zero. If X is
- negative, returns zero.
-
- -- Macro: REAL_VALUE_TYPE REAL_VALUE_ATOF (const char *STRING,
- machine_mode MODE)
- Converts STRING into a floating point number in the target
- machine's representation for mode MODE. This routine can handle
- both decimal and hexadecimal floating point constants, using the
- syntax defined by the C language for both.
-
- -- Macro: int REAL_VALUE_NEGATIVE (REAL_VALUE_TYPE X)
- Returns 1 if X is negative (including negative zero), 0 otherwise.
-
- -- Macro: int REAL_VALUE_ISINF (REAL_VALUE_TYPE X)
- Determines whether X represents infinity (positive or negative).
-
- -- Macro: int REAL_VALUE_ISNAN (REAL_VALUE_TYPE X)
- Determines whether X represents a "NaN" (not-a-number).
-
- -- Macro: REAL_VALUE_TYPE REAL_VALUE_NEGATE (REAL_VALUE_TYPE X)
- Returns the negative of the floating point value X.
-
- -- Macro: REAL_VALUE_TYPE REAL_VALUE_ABS (REAL_VALUE_TYPE X)
- Returns the absolute value of X.
-
-
- File: gccint.info, Node: Mode Switching, Next: Target Attributes, Prev: Floating Point, Up: Target Macros
-
- 18.23 Mode Switching Instructions
- =================================
-
- The following macros control mode switching optimizations:
-
- -- Macro: OPTIMIZE_MODE_SWITCHING (ENTITY)
- Define this macro if the port needs extra instructions inserted for
- mode switching in an optimizing compilation.
-
- For an example, the SH4 can perform both single and double
- precision floating point operations, but to perform a single
- precision operation, the FPSCR PR bit has to be cleared, while for
- a double precision operation, this bit has to be set. Changing the
- PR bit requires a general purpose register as a scratch register,
- hence these FPSCR sets have to be inserted before reload, i.e. you
- cannot put this into instruction emitting or
- 'TARGET_MACHINE_DEPENDENT_REORG'.
-
- You can have multiple entities that are mode-switched, and select
- at run time which entities actually need it.
- 'OPTIMIZE_MODE_SWITCHING' should return nonzero for any ENTITY that
- needs mode-switching. If you define this macro, you also have to
- define 'NUM_MODES_FOR_MODE_SWITCHING', 'TARGET_MODE_NEEDED',
- 'TARGET_MODE_PRIORITY' and 'TARGET_MODE_EMIT'.
- 'TARGET_MODE_AFTER', 'TARGET_MODE_ENTRY', and 'TARGET_MODE_EXIT'
- are optional.
-
- -- Macro: NUM_MODES_FOR_MODE_SWITCHING
- If you define 'OPTIMIZE_MODE_SWITCHING', you have to define this as
- initializer for an array of integers. Each initializer element N
- refers to an entity that needs mode switching, and specifies the
- number of different modes that might need to be set for this
- entity. The position of the initializer in the
- initializer--starting counting at zero--determines the integer that
- is used to refer to the mode-switched entity in question. In
- macros that take mode arguments / yield a mode result, modes are
- represented as numbers 0 ... N - 1. N is used to specify that no
- mode switch is needed / supplied.
-
- -- Target Hook: void TARGET_MODE_EMIT (int ENTITY, int MODE, int
- PREV_MODE, HARD_REG_SET REGS_LIVE)
- Generate one or more insns to set ENTITY to MODE. HARD_REG_LIVE is
- the set of hard registers live at the point where the insn(s) are
- to be inserted. PREV_MOXDE indicates the mode to switch from.
- Sets of a lower numbered entity will be emitted before sets of a
- higher numbered entity to a mode of the same or lower priority.
-
- -- Target Hook: int TARGET_MODE_NEEDED (int ENTITY, rtx_insn *INSN)
- ENTITY is an integer specifying a mode-switched entity. If
- 'OPTIMIZE_MODE_SWITCHING' is defined, you must define this macro to
- return an integer value not larger than the corresponding element
- in 'NUM_MODES_FOR_MODE_SWITCHING', to denote the mode that ENTITY
- must be switched into prior to the execution of INSN.
-
- -- Target Hook: int TARGET_MODE_AFTER (int ENTITY, int MODE, rtx_insn
- *INSN)
- ENTITY is an integer specifying a mode-switched entity. If this
- macro is defined, it is evaluated for every INSN during mode
- switching. It determines the mode that an insn results in (if
- different from the incoming mode).
-
- -- Target Hook: int TARGET_MODE_ENTRY (int ENTITY)
- If this macro is defined, it is evaluated for every ENTITY that
- needs mode switching. It should evaluate to an integer, which is a
- mode that ENTITY is assumed to be switched to at function entry.
- If 'TARGET_MODE_ENTRY' is defined then 'TARGET_MODE_EXIT' must be
- defined.
-
- -- Target Hook: int TARGET_MODE_EXIT (int ENTITY)
- If this macro is defined, it is evaluated for every ENTITY that
- needs mode switching. It should evaluate to an integer, which is a
- mode that ENTITY is assumed to be switched to at function exit. If
- 'TARGET_MODE_EXIT' is defined then 'TARGET_MODE_ENTRY' must be
- defined.
-
- -- Target Hook: int TARGET_MODE_PRIORITY (int ENTITY, int N)
- This macro specifies the order in which modes for ENTITY are
- processed. 0 is the highest priority,
- 'NUM_MODES_FOR_MODE_SWITCHING[ENTITY] - 1' the lowest. The value
- of the macro should be an integer designating a mode for ENTITY.
- For any fixed ENTITY, 'mode_priority' (ENTITY, N) shall be a
- bijection in 0 ... 'num_modes_for_mode_switching[ENTITY] - 1'.
-
-
- File: gccint.info, Node: Target Attributes, Next: Emulated TLS, Prev: Mode Switching, Up: Target Macros
-
- 18.24 Defining target-specific uses of '__attribute__'
- ======================================================
-
- Target-specific attributes may be defined for functions, data and types.
- These are described using the following target hooks; they also need to
- be documented in 'extend.texi'.
-
- -- Target Hook: const struct attribute_spec * TARGET_ATTRIBUTE_TABLE
- If defined, this target hook points to an array of 'struct
- attribute_spec' (defined in 'tree-core.h') specifying the machine
- specific attributes for this target and some of the restrictions on
- the entities to which these attributes are applied and the
- arguments they take.
-
- -- Target Hook: bool TARGET_ATTRIBUTE_TAKES_IDENTIFIER_P (const_tree
- NAME)
- If defined, this target hook is a function which returns true if
- the machine-specific attribute named NAME expects an identifier
- given as its first argument to be passed on as a plain identifier,
- not subjected to name lookup. If this is not defined, the default
- is false for all machine-specific attributes.
-
- -- Target Hook: int TARGET_COMP_TYPE_ATTRIBUTES (const_tree TYPE1,
- const_tree TYPE2)
- If defined, this target hook is a function which returns zero if
- the attributes on TYPE1 and TYPE2 are incompatible, one if they are
- compatible, and two if they are nearly compatible (which causes a
- warning to be generated). If this is not defined, machine-specific
- attributes are supposed always to be compatible.
-
- -- Target Hook: void TARGET_SET_DEFAULT_TYPE_ATTRIBUTES (tree TYPE)
- If defined, this target hook is a function which assigns default
- attributes to the newly defined TYPE.
-
- -- Target Hook: tree TARGET_MERGE_TYPE_ATTRIBUTES (tree TYPE1, tree
- TYPE2)
- Define this target hook if the merging of type attributes needs
- special handling. If defined, the result is a list of the combined
- 'TYPE_ATTRIBUTES' of TYPE1 and TYPE2. It is assumed that
- 'comptypes' has already been called and returned 1. This function
- may call 'merge_attributes' to handle machine-independent merging.
-
- -- Target Hook: tree TARGET_MERGE_DECL_ATTRIBUTES (tree OLDDECL, tree
- NEWDECL)
- Define this target hook if the merging of decl attributes needs
- special handling. If defined, the result is a list of the combined
- 'DECL_ATTRIBUTES' of OLDDECL and NEWDECL. NEWDECL is a duplicate
- declaration of OLDDECL. Examples of when this is needed are when
- one attribute overrides another, or when an attribute is nullified
- by a subsequent definition. This function may call
- 'merge_attributes' to handle machine-independent merging.
-
- If the only target-specific handling you require is 'dllimport' for
- Microsoft Windows targets, you should define the macro
- 'TARGET_DLLIMPORT_DECL_ATTRIBUTES' to '1'. The compiler will then
- define a function called 'merge_dllimport_decl_attributes' which
- can then be defined as the expansion of
- 'TARGET_MERGE_DECL_ATTRIBUTES'. You can also add
- 'handle_dll_attribute' in the attribute table for your port to
- perform initial processing of the 'dllimport' and 'dllexport'
- attributes. This is done in 'i386/cygwin.h' and 'i386/i386.c', for
- example.
-
- -- Target Hook: bool TARGET_VALID_DLLIMPORT_ATTRIBUTE_P (const_tree
- DECL)
- DECL is a variable or function with '__attribute__((dllimport))'
- specified. Use this hook if the target needs to add extra
- validation checks to 'handle_dll_attribute'.
-
- -- Macro: TARGET_DECLSPEC
- Define this macro to a nonzero value if you want to treat
- '__declspec(X)' as equivalent to '__attribute((X))'. By default,
- this behavior is enabled only for targets that define
- 'TARGET_DLLIMPORT_DECL_ATTRIBUTES'. The current implementation of
- '__declspec' is via a built-in macro, but you should not rely on
- this implementation detail.
-
- -- Target Hook: void TARGET_INSERT_ATTRIBUTES (tree NODE, tree
- *ATTR_PTR)
- Define this target hook if you want to be able to add attributes to
- a decl when it is being created. This is normally useful for back
- ends which wish to implement a pragma by using the attributes which
- correspond to the pragma's effect. The NODE argument is the decl
- which is being created. The ATTR_PTR argument is a pointer to the
- attribute list for this decl. The list itself should not be
- modified, since it may be shared with other decls, but attributes
- may be chained on the head of the list and '*ATTR_PTR' modified to
- point to the new attributes, or a copy of the list may be made if
- further changes are needed.
-
- -- Target Hook: tree TARGET_HANDLE_GENERIC_ATTRIBUTE (tree *NODE, tree
- NAME, tree ARGS, int FLAGS, bool *NO_ADD_ATTRS)
- Define this target hook if you want to be able to perform
- additional target-specific processing of an attribute which is
- handled generically by a front end. The arguments are the same as
- those which are passed to attribute handlers. So far this only
- affects the NOINIT and SECTION attribute.
-
- -- Target Hook: bool TARGET_FUNCTION_ATTRIBUTE_INLINABLE_P (const_tree
- FNDECL)
- This target hook returns 'true' if it is OK to inline FNDECL into
- the current function, despite its having target-specific
- attributes, 'false' otherwise. By default, if a function has a
- target specific attribute attached to it, it will not be inlined.
-
- -- Target Hook: bool TARGET_OPTION_VALID_ATTRIBUTE_P (tree FNDECL, tree
- NAME, tree ARGS, int FLAGS)
- This hook is called to parse 'attribute(target("..."))', which
- allows setting target-specific options on individual functions.
- These function-specific options may differ from the options
- specified on the command line. The hook should return 'true' if
- the options are valid.
-
- The hook should set the 'DECL_FUNCTION_SPECIFIC_TARGET' field in
- the function declaration to hold a pointer to a target-specific
- 'struct cl_target_option' structure.
-
- -- Target Hook: void TARGET_OPTION_SAVE (struct cl_target_option *PTR,
- struct gcc_options *OPTS)
- This hook is called to save any additional target-specific
- information in the 'struct cl_target_option' structure for
- function-specific options from the 'struct gcc_options' structure.
- *Note Option file format::.
-
- -- Target Hook: void TARGET_OPTION_RESTORE (struct gcc_options *OPTS,
- struct cl_target_option *PTR)
- This hook is called to restore any additional target-specific
- information in the 'struct cl_target_option' structure for
- function-specific options to the 'struct gcc_options' structure.
-
- -- Target Hook: void TARGET_OPTION_POST_STREAM_IN (struct
- cl_target_option *PTR)
- This hook is called to update target-specific information in the
- 'struct cl_target_option' structure after it is streamed in from
- LTO bytecode.
-
- -- Target Hook: void TARGET_OPTION_PRINT (FILE *FILE, int INDENT,
- struct cl_target_option *PTR)
- This hook is called to print any additional target-specific
- information in the 'struct cl_target_option' structure for
- function-specific options.
-
- -- Target Hook: bool TARGET_OPTION_PRAGMA_PARSE (tree ARGS, tree
- POP_TARGET)
- This target hook parses the options for '#pragma GCC target', which
- sets the target-specific options for functions that occur later in
- the input stream. The options accepted should be the same as those
- handled by the 'TARGET_OPTION_VALID_ATTRIBUTE_P' hook.
-
- -- Target Hook: void TARGET_OPTION_OVERRIDE (void)
- Sometimes certain combinations of command options do not make sense
- on a particular target machine. You can override the hook
- 'TARGET_OPTION_OVERRIDE' to take account of this. This hooks is
- called once just after all the command options have been parsed.
-
- Don't use this hook to turn on various extra optimizations for
- '-O'. That is what 'TARGET_OPTION_OPTIMIZATION' is for.
-
- If you need to do something whenever the optimization level is
- changed via the optimize attribute or pragma, see
- 'TARGET_OVERRIDE_OPTIONS_AFTER_CHANGE'
-
- -- Target Hook: bool TARGET_OPTION_FUNCTION_VERSIONS (tree DECL1, tree
- DECL2)
- This target hook returns 'true' if DECL1 and DECL2 are versions of
- the same function. DECL1 and DECL2 are function versions if and
- only if they have the same function signature and different target
- specific attributes, that is, they are compiled for different
- target machines.
-
- -- Target Hook: bool TARGET_CAN_INLINE_P (tree CALLER, tree CALLEE)
- This target hook returns 'false' if the CALLER function cannot
- inline CALLEE, based on target specific information. By default,
- inlining is not allowed if the callee function has function
- specific target options and the caller does not use the same
- options.
-
- -- Target Hook: void TARGET_RELAYOUT_FUNCTION (tree FNDECL)
- This target hook fixes function FNDECL after attributes are
- processed. Default does nothing. On ARM, the default function's
- alignment is updated with the attribute target.
-
-
- File: gccint.info, Node: Emulated TLS, Next: MIPS Coprocessors, Prev: Target Attributes, Up: Target Macros
-
- 18.25 Emulating TLS
- ===================
-
- For targets whose psABI does not provide Thread Local Storage via
- specific relocations and instruction sequences, an emulation layer is
- used. A set of target hooks allows this emulation layer to be
- configured for the requirements of a particular target. For instance
- the psABI may in fact specify TLS support in terms of an emulation
- layer.
-
- The emulation layer works by creating a control object for every TLS
- object. To access the TLS object, a lookup function is provided which,
- when given the address of the control object, will return the address of
- the current thread's instance of the TLS object.
-
- -- Target Hook: const char * TARGET_EMUTLS_GET_ADDRESS
- Contains the name of the helper function that uses a TLS control
- object to locate a TLS instance. The default causes libgcc's
- emulated TLS helper function to be used.
-
- -- Target Hook: const char * TARGET_EMUTLS_REGISTER_COMMON
- Contains the name of the helper function that should be used at
- program startup to register TLS objects that are implicitly
- initialized to zero. If this is 'NULL', all TLS objects will have
- explicit initializers. The default causes libgcc's emulated TLS
- registration function to be used.
-
- -- Target Hook: const char * TARGET_EMUTLS_VAR_SECTION
- Contains the name of the section in which TLS control variables
- should be placed. The default of 'NULL' allows these to be placed
- in any section.
-
- -- Target Hook: const char * TARGET_EMUTLS_TMPL_SECTION
- Contains the name of the section in which TLS initializers should
- be placed. The default of 'NULL' allows these to be placed in any
- section.
-
- -- Target Hook: const char * TARGET_EMUTLS_VAR_PREFIX
- Contains the prefix to be prepended to TLS control variable names.
- The default of 'NULL' uses a target-specific prefix.
-
- -- Target Hook: const char * TARGET_EMUTLS_TMPL_PREFIX
- Contains the prefix to be prepended to TLS initializer objects.
- The default of 'NULL' uses a target-specific prefix.
-
- -- Target Hook: tree TARGET_EMUTLS_VAR_FIELDS (tree TYPE, tree *NAME)
- Specifies a function that generates the FIELD_DECLs for a TLS
- control object type. TYPE is the RECORD_TYPE the fields are for
- and NAME should be filled with the structure tag, if the default of
- '__emutls_object' is unsuitable. The default creates a type
- suitable for libgcc's emulated TLS function.
-
- -- Target Hook: tree TARGET_EMUTLS_VAR_INIT (tree VAR, tree DECL, tree
- TMPL_ADDR)
- Specifies a function that generates the CONSTRUCTOR to initialize a
- TLS control object. VAR is the TLS control object, DECL is the TLS
- object and TMPL_ADDR is the address of the initializer. The
- default initializes libgcc's emulated TLS control object.
-
- -- Target Hook: bool TARGET_EMUTLS_VAR_ALIGN_FIXED
- Specifies whether the alignment of TLS control variable objects is
- fixed and should not be increased as some backends may do to
- optimize single objects. The default is false.
-
- -- Target Hook: bool TARGET_EMUTLS_DEBUG_FORM_TLS_ADDRESS
- Specifies whether a DWARF 'DW_OP_form_tls_address' location
- descriptor may be used to describe emulated TLS control objects.
-
-
- File: gccint.info, Node: MIPS Coprocessors, Next: PCH Target, Prev: Emulated TLS, Up: Target Macros
-
- 18.26 Defining coprocessor specifics for MIPS targets.
- ======================================================
-
- The MIPS specification allows MIPS implementations to have as many as 4
- coprocessors, each with as many as 32 private registers. GCC supports
- accessing these registers and transferring values between the registers
- and memory using asm-ized variables. For example:
-
- register unsigned int cp0count asm ("c0r1");
- unsigned int d;
-
- d = cp0count + 3;
-
- ("c0r1" is the default name of register 1 in coprocessor 0; alternate
- names may be added as described below, or the default names may be
- overridden entirely in 'SUBTARGET_CONDITIONAL_REGISTER_USAGE'.)
-
- Coprocessor registers are assumed to be epilogue-used; sets to them
- will be preserved even if it does not appear that the register is used
- again later in the function.
-
- Another note: according to the MIPS spec, coprocessor 1 (if present) is
- the FPU. One accesses COP1 registers through standard mips
- floating-point support; they are not included in this mechanism.
-
-
- File: gccint.info, Node: PCH Target, Next: C++ ABI, Prev: MIPS Coprocessors, Up: Target Macros
-
- 18.27 Parameters for Precompiled Header Validity Checking
- =========================================================
-
- -- Target Hook: void * TARGET_GET_PCH_VALIDITY (size_t *SZ)
- This hook returns a pointer to the data needed by
- 'TARGET_PCH_VALID_P' and sets '*SZ' to the size of the data in
- bytes.
-
- -- Target Hook: const char * TARGET_PCH_VALID_P (const void *DATA,
- size_t SZ)
- This hook checks whether the options used to create a PCH file are
- compatible with the current settings. It returns 'NULL' if so and
- a suitable error message if not. Error messages will be presented
- to the user and must be localized using '_(MSG)'.
-
- DATA is the data that was returned by 'TARGET_GET_PCH_VALIDITY'
- when the PCH file was created and SZ is the size of that data in
- bytes. It's safe to assume that the data was created by the same
- version of the compiler, so no format checking is needed.
-
- The default definition of 'default_pch_valid_p' should be suitable
- for most targets.
-
- -- Target Hook: const char * TARGET_CHECK_PCH_TARGET_FLAGS (int
- PCH_FLAGS)
- If this hook is nonnull, the default implementation of
- 'TARGET_PCH_VALID_P' will use it to check for compatible values of
- 'target_flags'. PCH_FLAGS specifies the value that 'target_flags'
- had when the PCH file was created. The return value is the same as
- for 'TARGET_PCH_VALID_P'.
-
- -- Target Hook: void TARGET_PREPARE_PCH_SAVE (void)
- Called before writing out a PCH file. If the target has some
- garbage-collected data that needs to be in a particular state on
- PCH loads, it can use this hook to enforce that state. Very few
- targets need to do anything here.
-
-
- File: gccint.info, Node: C++ ABI, Next: D Language and ABI, Prev: PCH Target, Up: Target Macros
-
- 18.28 C++ ABI parameters
- ========================
-
- -- Target Hook: tree TARGET_CXX_GUARD_TYPE (void)
- Define this hook to override the integer type used for guard
- variables. These are used to implement one-time construction of
- static objects. The default is long_long_integer_type_node.
-
- -- Target Hook: bool TARGET_CXX_GUARD_MASK_BIT (void)
- This hook determines how guard variables are used. It should
- return 'false' (the default) if the first byte should be used. A
- return value of 'true' indicates that only the least significant
- bit should be used.
-
- -- Target Hook: tree TARGET_CXX_GET_COOKIE_SIZE (tree TYPE)
- This hook returns the size of the cookie to use when allocating an
- array whose elements have the indicated TYPE. Assumes that it is
- already known that a cookie is needed. The default is 'max(sizeof
- (size_t), alignof(type))', as defined in section 2.7 of the
- IA64/Generic C++ ABI.
-
- -- Target Hook: bool TARGET_CXX_COOKIE_HAS_SIZE (void)
- This hook should return 'true' if the element size should be stored
- in array cookies. The default is to return 'false'.
-
- -- Target Hook: int TARGET_CXX_IMPORT_EXPORT_CLASS (tree TYPE, int
- IMPORT_EXPORT)
- If defined by a backend this hook allows the decision made to
- export class TYPE to be overruled. Upon entry IMPORT_EXPORT will
- contain 1 if the class is going to be exported, -1 if it is going
- to be imported and 0 otherwise. This function should return the
- modified value and perform any other actions necessary to support
- the backend's targeted operating system.
-
- -- Target Hook: bool TARGET_CXX_CDTOR_RETURNS_THIS (void)
- This hook should return 'true' if constructors and destructors
- return the address of the object created/destroyed. The default is
- to return 'false'.
-
- -- Target Hook: bool TARGET_CXX_KEY_METHOD_MAY_BE_INLINE (void)
- This hook returns true if the key method for a class (i.e., the
- method which, if defined in the current translation unit, causes
- the virtual table to be emitted) may be an inline function. Under
- the standard Itanium C++ ABI the key method may be an inline
- function so long as the function is not declared inline in the
- class definition. Under some variants of the ABI, an inline
- function can never be the key method. The default is to return
- 'true'.
-
- -- Target Hook: void TARGET_CXX_DETERMINE_CLASS_DATA_VISIBILITY (tree
- DECL)
- DECL is a virtual table, virtual table table, typeinfo object, or
- other similar implicit class data object that will be emitted with
- external linkage in this translation unit. No ELF visibility has
- been explicitly specified. If the target needs to specify a
- visibility other than that of the containing class, use this hook
- to set 'DECL_VISIBILITY' and 'DECL_VISIBILITY_SPECIFIED'.
-
- -- Target Hook: bool TARGET_CXX_CLASS_DATA_ALWAYS_COMDAT (void)
- This hook returns true (the default) if virtual tables and other
- similar implicit class data objects are always COMDAT if they have
- external linkage. If this hook returns false, then class data for
- classes whose virtual table will be emitted in only one translation
- unit will not be COMDAT.
-
- -- Target Hook: bool TARGET_CXX_LIBRARY_RTTI_COMDAT (void)
- This hook returns true (the default) if the RTTI information for
- the basic types which is defined in the C++ runtime should always
- be COMDAT, false if it should not be COMDAT.
-
- -- Target Hook: bool TARGET_CXX_USE_AEABI_ATEXIT (void)
- This hook returns true if '__aeabi_atexit' (as defined by the ARM
- EABI) should be used to register static destructors when
- '-fuse-cxa-atexit' is in effect. The default is to return false to
- use '__cxa_atexit'.
-
- -- Target Hook: bool TARGET_CXX_USE_ATEXIT_FOR_CXA_ATEXIT (void)
- This hook returns true if the target 'atexit' function can be used
- in the same manner as '__cxa_atexit' to register C++ static
- destructors. This requires that 'atexit'-registered functions in
- shared libraries are run in the correct order when the libraries
- are unloaded. The default is to return false.
-
- -- Target Hook: void TARGET_CXX_ADJUST_CLASS_AT_DEFINITION (tree TYPE)
- TYPE is a C++ class (i.e., RECORD_TYPE or UNION_TYPE) that has just
- been defined. Use this hook to make adjustments to the class (eg,
- tweak visibility or perform any other required target
- modifications).
-
- -- Target Hook: tree TARGET_CXX_DECL_MANGLING_CONTEXT (const_tree DECL)
- Return target-specific mangling context of DECL or 'NULL_TREE'.
-
-
- File: gccint.info, Node: D Language and ABI, Next: Named Address Spaces, Prev: C++ ABI, Up: Target Macros
-
- 18.29 D ABI parameters
- ======================
-
- -- D Target Hook: void TARGET_D_CPU_VERSIONS (void)
- Declare all environmental version identifiers relating to the
- target CPU using the function 'builtin_version', which takes a
- string representing the name of the version. Version identifiers
- predefined by this hook apply to all modules that are being
- compiled and imported.
-
- -- D Target Hook: void TARGET_D_OS_VERSIONS (void)
- Similarly to 'TARGET_D_CPU_VERSIONS', but is used for versions
- relating to the target operating system.
-
- -- D Target Hook: unsigned TARGET_D_CRITSEC_SIZE (void)
- Returns the size of the data structure used by the target operating
- system for critical sections and monitors. For example, on
- Microsoft Windows this would return the 'sizeof(CRITICAL_SECTION)',
- while other platforms that implement pthreads would return
- 'sizeof(pthread_mutex_t)'.
-
-
- File: gccint.info, Node: Named Address Spaces, Next: Misc, Prev: D Language and ABI, Up: Target Macros
-
- 18.30 Adding support for named address spaces
- =============================================
-
- The draft technical report of the ISO/IEC JTC1 S22 WG14 N1275 standards
- committee, 'Programming Languages - C - Extensions to support embedded
- processors', specifies a syntax for embedded processors to specify
- alternate address spaces. You can configure a GCC port to support
- section 5.1 of the draft report to add support for address spaces other
- than the default address space. These address spaces are new keywords
- that are similar to the 'volatile' and 'const' type attributes.
-
- Pointers to named address spaces can have a different size than
- pointers to the generic address space.
-
- For example, the SPU port uses the '__ea' address space to refer to
- memory in the host processor, rather than memory local to the SPU
- processor. Access to memory in the '__ea' address space involves
- issuing DMA operations to move data between the host processor and the
- local processor memory address space. Pointers in the '__ea' address
- space are either 32 bits or 64 bits based on the '-mea32' or '-mea64'
- switches (native SPU pointers are always 32 bits).
-
- Internally, address spaces are represented as a small integer in the
- range 0 to 15 with address space 0 being reserved for the generic
- address space.
-
- To register a named address space qualifier keyword with the C front
- end, the target may call the 'c_register_addr_space' routine. For
- example, the SPU port uses the following to declare '__ea' as the
- keyword for named address space #1:
- #define ADDR_SPACE_EA 1
- c_register_addr_space ("__ea", ADDR_SPACE_EA);
-
- -- Target Hook: scalar_int_mode TARGET_ADDR_SPACE_POINTER_MODE
- (addr_space_t ADDRESS_SPACE)
- Define this to return the machine mode to use for pointers to
- ADDRESS_SPACE if the target supports named address spaces. The
- default version of this hook returns 'ptr_mode'.
-
- -- Target Hook: scalar_int_mode TARGET_ADDR_SPACE_ADDRESS_MODE
- (addr_space_t ADDRESS_SPACE)
- Define this to return the machine mode to use for addresses in
- ADDRESS_SPACE if the target supports named address spaces. The
- default version of this hook returns 'Pmode'.
-
- -- Target Hook: bool TARGET_ADDR_SPACE_VALID_POINTER_MODE
- (scalar_int_mode MODE, addr_space_t AS)
- Define this to return nonzero if the port can handle pointers with
- machine mode MODE to address space AS. This target hook is the
- same as the 'TARGET_VALID_POINTER_MODE' target hook, except that it
- includes explicit named address space support. The default version
- of this hook returns true for the modes returned by either the
- 'TARGET_ADDR_SPACE_POINTER_MODE' or
- 'TARGET_ADDR_SPACE_ADDRESS_MODE' target hooks for the given address
- space.
-
- -- Target Hook: bool TARGET_ADDR_SPACE_LEGITIMATE_ADDRESS_P
- (machine_mode MODE, rtx EXP, bool STRICT, addr_space_t AS)
- Define this to return true if EXP is a valid address for mode MODE
- in the named address space AS. The STRICT parameter says whether
- strict addressing is in effect after reload has finished. This
- target hook is the same as the 'TARGET_LEGITIMATE_ADDRESS_P' target
- hook, except that it includes explicit named address space support.
-
- -- Target Hook: rtx TARGET_ADDR_SPACE_LEGITIMIZE_ADDRESS (rtx X, rtx
- OLDX, machine_mode MODE, addr_space_t AS)
- Define this to modify an invalid address X to be a valid address
- with mode MODE in the named address space AS. This target hook is
- the same as the 'TARGET_LEGITIMIZE_ADDRESS' target hook, except
- that it includes explicit named address space support.
-
- -- Target Hook: bool TARGET_ADDR_SPACE_SUBSET_P (addr_space_t SUBSET,
- addr_space_t SUPERSET)
- Define this to return whether the SUBSET named address space is
- contained within the SUPERSET named address space. Pointers to a
- named address space that is a subset of another named address space
- will be converted automatically without a cast if used together in
- arithmetic operations. Pointers to a superset address space can be
- converted to pointers to a subset address space via explicit casts.
-
- -- Target Hook: bool TARGET_ADDR_SPACE_ZERO_ADDRESS_VALID (addr_space_t
- AS)
- Define this to modify the default handling of address 0 for the
- address space. Return true if 0 should be considered a valid
- address.
-
- -- Target Hook: rtx TARGET_ADDR_SPACE_CONVERT (rtx OP, tree FROM_TYPE,
- tree TO_TYPE)
- Define this to convert the pointer expression represented by the
- RTL OP with type FROM_TYPE that points to a named address space to
- a new pointer expression with type TO_TYPE that points to a
- different named address space. When this hook it called, it is
- guaranteed that one of the two address spaces is a subset of the
- other, as determined by the 'TARGET_ADDR_SPACE_SUBSET_P' target
- hook.
-
- -- Target Hook: int TARGET_ADDR_SPACE_DEBUG (addr_space_t AS)
- Define this to define how the address space is encoded in dwarf.
- The result is the value to be used with 'DW_AT_address_class'.
-
- -- Target Hook: void TARGET_ADDR_SPACE_DIAGNOSE_USAGE (addr_space_t AS,
- location_t LOC)
- Define this hook if the availability of an address space depends on
- command line options and some diagnostics should be printed when
- the address space is used. This hook is called during parsing and
- allows to emit a better diagnostic compared to the case where the
- address space was not registered with 'c_register_addr_space'. AS
- is the address space as registered with 'c_register_addr_space'.
- LOC is the location of the address space qualifier token. The
- default implementation does nothing.
-
-
- File: gccint.info, Node: Misc, Prev: Named Address Spaces, Up: Target Macros
-
- 18.31 Miscellaneous Parameters
- ==============================
-
- Here are several miscellaneous parameters.
-
- -- Macro: HAS_LONG_COND_BRANCH
- Define this boolean macro to indicate whether or not your
- architecture has conditional branches that can span all of memory.
- It is used in conjunction with an optimization that partitions hot
- and cold basic blocks into separate sections of the executable. If
- this macro is set to false, gcc will convert any conditional
- branches that attempt to cross between sections into unconditional
- branches or indirect jumps.
-
- -- Macro: HAS_LONG_UNCOND_BRANCH
- Define this boolean macro to indicate whether or not your
- architecture has unconditional branches that can span all of
- memory. It is used in conjunction with an optimization that
- partitions hot and cold basic blocks into separate sections of the
- executable. If this macro is set to false, gcc will convert any
- unconditional branches that attempt to cross between sections into
- indirect jumps.
-
- -- Macro: CASE_VECTOR_MODE
- An alias for a machine mode name. This is the machine mode that
- elements of a jump-table should have.
-
- -- Macro: CASE_VECTOR_SHORTEN_MODE (MIN_OFFSET, MAX_OFFSET, BODY)
- Optional: return the preferred mode for an 'addr_diff_vec' when the
- minimum and maximum offset are known. If you define this, it
- enables extra code in branch shortening to deal with
- 'addr_diff_vec'. To make this work, you also have to define
- 'INSN_ALIGN' and make the alignment for 'addr_diff_vec' explicit.
- The BODY argument is provided so that the offset_unsigned and scale
- flags can be updated.
-
- -- Macro: CASE_VECTOR_PC_RELATIVE
- Define this macro to be a C expression to indicate when jump-tables
- should contain relative addresses. You need not define this macro
- if jump-tables never contain relative addresses, or jump-tables
- should contain relative addresses only when '-fPIC' or '-fPIC' is
- in effect.
-
- -- Target Hook: unsigned int TARGET_CASE_VALUES_THRESHOLD (void)
- This function return the smallest number of different values for
- which it is best to use a jump-table instead of a tree of
- conditional branches. The default is four for machines with a
- 'casesi' instruction and five otherwise. This is best for most
- machines.
-
- -- Macro: WORD_REGISTER_OPERATIONS
- Define this macro to 1 if operations between registers with
- integral mode smaller than a word are always performed on the
- entire register. To be more explicit, if you start with a pair of
- 'word_mode' registers with known values and you do a subword, for
- example 'QImode', addition on the low part of the registers, then
- the compiler may consider that the result has a known value in
- 'word_mode' too if the macro is defined to 1. Most RISC machines
- have this property and most CISC machines do not.
-
- -- Target Hook: unsigned int TARGET_MIN_ARITHMETIC_PRECISION (void)
- On some RISC architectures with 64-bit registers, the processor
- also maintains 32-bit condition codes that make it possible to do
- real 32-bit arithmetic, although the operations are performed on
- the full registers.
-
- On such architectures, defining this hook to 32 tells the compiler
- to try using 32-bit arithmetical operations setting the condition
- codes instead of doing full 64-bit arithmetic.
-
- More generally, define this hook on RISC architectures if you want
- the compiler to try using arithmetical operations setting the
- condition codes with a precision lower than the word precision.
-
- You need not define this hook if 'WORD_REGISTER_OPERATIONS' is not
- defined to 1.
-
- -- Macro: LOAD_EXTEND_OP (MEM_MODE)
- Define this macro to be a C expression indicating when insns that
- read memory in MEM_MODE, an integral mode narrower than a word, set
- the bits outside of MEM_MODE to be either the sign-extension or the
- zero-extension of the data read. Return 'SIGN_EXTEND' for values
- of MEM_MODE for which the insn sign-extends, 'ZERO_EXTEND' for
- which it zero-extends, and 'UNKNOWN' for other modes.
-
- This macro is not called with MEM_MODE non-integral or with a width
- greater than or equal to 'BITS_PER_WORD', so you may return any
- value in this case. Do not define this macro if it would always
- return 'UNKNOWN'. On machines where this macro is defined, you
- will normally define it as the constant 'SIGN_EXTEND' or
- 'ZERO_EXTEND'.
-
- You may return a non-'UNKNOWN' value even if for some hard
- registers the sign extension is not performed, if for the
- 'REGNO_REG_CLASS' of these hard registers
- 'TARGET_CAN_CHANGE_MODE_CLASS' returns false when the FROM mode is
- MEM_MODE and the TO mode is any integral mode larger than this but
- not larger than 'word_mode'.
-
- You must return 'UNKNOWN' if for some hard registers that allow
- this mode, 'TARGET_CAN_CHANGE_MODE_CLASS' says that they cannot
- change to 'word_mode', but that they can change to another integral
- mode that is larger then MEM_MODE but still smaller than
- 'word_mode'.
-
- -- Macro: SHORT_IMMEDIATES_SIGN_EXTEND
- Define this macro to 1 if loading short immediate values into
- registers sign extends.
-
- -- Target Hook: unsigned int TARGET_MIN_DIVISIONS_FOR_RECIP_MUL
- (machine_mode MODE)
- When '-ffast-math' is in effect, GCC tries to optimize divisions by
- the same divisor, by turning them into multiplications by the
- reciprocal. This target hook specifies the minimum number of
- divisions that should be there for GCC to perform the optimization
- for a variable of mode MODE. The default implementation returns 3
- if the machine has an instruction for the division, and 2 if it
- does not.
-
- -- Macro: MOVE_MAX
- The maximum number of bytes that a single instruction can move
- quickly between memory and registers or between two memory
- locations.
-
- -- Macro: MAX_MOVE_MAX
- The maximum number of bytes that a single instruction can move
- quickly between memory and registers or between two memory
- locations. If this is undefined, the default is 'MOVE_MAX'.
- Otherwise, it is the constant value that is the largest value that
- 'MOVE_MAX' can have at run-time.
-
- -- Macro: SHIFT_COUNT_TRUNCATED
- A C expression that is nonzero if on this machine the number of
- bits actually used for the count of a shift operation is equal to
- the number of bits needed to represent the size of the object being
- shifted. When this macro is nonzero, the compiler will assume that
- it is safe to omit a sign-extend, zero-extend, and certain bitwise
- 'and' instructions that truncates the count of a shift operation.
- On machines that have instructions that act on bit-fields at
- variable positions, which may include 'bit test' instructions, a
- nonzero 'SHIFT_COUNT_TRUNCATED' also enables deletion of
- truncations of the values that serve as arguments to bit-field
- instructions.
-
- If both types of instructions truncate the count (for shifts) and
- position (for bit-field operations), or if no variable-position
- bit-field instructions exist, you should define this macro.
-
- However, on some machines, such as the 80386 and the 680x0,
- truncation only applies to shift operations and not the (real or
- pretended) bit-field operations. Define 'SHIFT_COUNT_TRUNCATED' to
- be zero on such machines. Instead, add patterns to the 'md' file
- that include the implied truncation of the shift instructions.
-
- You need not define this macro if it would always have the value of
- zero.
-
- -- Target Hook: unsigned HOST_WIDE_INT TARGET_SHIFT_TRUNCATION_MASK
- (machine_mode MODE)
- This function describes how the standard shift patterns for MODE
- deal with shifts by negative amounts or by more than the width of
- the mode. *Note shift patterns::.
-
- On many machines, the shift patterns will apply a mask M to the
- shift count, meaning that a fixed-width shift of X by Y is
- equivalent to an arbitrary-width shift of X by Y & M. If this is
- true for mode MODE, the function should return M, otherwise it
- should return 0. A return value of 0 indicates that no particular
- behavior is guaranteed.
-
- Note that, unlike 'SHIFT_COUNT_TRUNCATED', this function does _not_
- apply to general shift rtxes; it applies only to instructions that
- are generated by the named shift patterns.
-
- The default implementation of this function returns
- 'GET_MODE_BITSIZE (MODE) - 1' if 'SHIFT_COUNT_TRUNCATED' and 0
- otherwise. This definition is always safe, but if
- 'SHIFT_COUNT_TRUNCATED' is false, and some shift patterns
- nevertheless truncate the shift count, you may get better code by
- overriding it.
-
- -- Target Hook: bool TARGET_TRULY_NOOP_TRUNCATION (poly_uint64 OUTPREC,
- poly_uint64 INPREC)
- This hook returns true if it is safe to "convert" a value of INPREC
- bits to one of OUTPREC bits (where OUTPREC is smaller than INPREC)
- by merely operating on it as if it had only OUTPREC bits. The
- default returns true unconditionally, which is correct for most
- machines.
-
- If 'TARGET_MODES_TIEABLE_P' returns false for a pair of modes,
- suboptimal code can result if this hook returns true for the
- corresponding mode sizes. Making this hook return false in such
- cases may improve things.
-
- -- Target Hook: int TARGET_MODE_REP_EXTENDED (scalar_int_mode MODE,
- scalar_int_mode REP_MODE)
- The representation of an integral mode can be such that the values
- are always extended to a wider integral mode. Return 'SIGN_EXTEND'
- if values of MODE are represented in sign-extended form to
- REP_MODE. Return 'UNKNOWN' otherwise. (Currently, none of the
- targets use zero-extended representation this way so unlike
- 'LOAD_EXTEND_OP', 'TARGET_MODE_REP_EXTENDED' is expected to return
- either 'SIGN_EXTEND' or 'UNKNOWN'. Also no target extends MODE to
- REP_MODE so that REP_MODE is not the next widest integral mode and
- currently we take advantage of this fact.)
-
- Similarly to 'LOAD_EXTEND_OP' you may return a non-'UNKNOWN' value
- even if the extension is not performed on certain hard registers as
- long as for the 'REGNO_REG_CLASS' of these hard registers
- 'TARGET_CAN_CHANGE_MODE_CLASS' returns false.
-
- Note that 'TARGET_MODE_REP_EXTENDED' and 'LOAD_EXTEND_OP' describe
- two related properties. If you define 'TARGET_MODE_REP_EXTENDED
- (mode, word_mode)' you probably also want to define 'LOAD_EXTEND_OP
- (mode)' to return the same type of extension.
-
- In order to enforce the representation of 'mode',
- 'TARGET_TRULY_NOOP_TRUNCATION' should return false when truncating
- to 'mode'.
-
- -- Target Hook: bool TARGET_SETJMP_PRESERVES_NONVOLATILE_REGS_P (void)
- On some targets, it is assumed that the compiler will spill all
- pseudos that are live across a call to 'setjmp', while other
- targets treat 'setjmp' calls as normal function calls.
-
- This hook returns false if 'setjmp' calls do not preserve all
- non-volatile registers so that gcc that must spill all pseudos that
- are live across 'setjmp' calls. Define this to return true if the
- target does not need to spill all pseudos live across 'setjmp'
- calls. The default implementation conservatively assumes all
- pseudos must be spilled across 'setjmp' calls.
-
- -- Macro: STORE_FLAG_VALUE
- A C expression describing the value returned by a comparison
- operator with an integral mode and stored by a store-flag
- instruction ('cstoreMODE4') when the condition is true. This
- description must apply to _all_ the 'cstoreMODE4' patterns and all
- the comparison operators whose results have a 'MODE_INT' mode.
-
- A value of 1 or -1 means that the instruction implementing the
- comparison operator returns exactly 1 or -1 when the comparison is
- true and 0 when the comparison is false. Otherwise, the value
- indicates which bits of the result are guaranteed to be 1 when the
- comparison is true. This value is interpreted in the mode of the
- comparison operation, which is given by the mode of the first
- operand in the 'cstoreMODE4' pattern. Either the low bit or the
- sign bit of 'STORE_FLAG_VALUE' be on. Presently, only those bits
- are used by the compiler.
-
- If 'STORE_FLAG_VALUE' is neither 1 or -1, the compiler will
- generate code that depends only on the specified bits. It can also
- replace comparison operators with equivalent operations if they
- cause the required bits to be set, even if the remaining bits are
- undefined. For example, on a machine whose comparison operators
- return an 'SImode' value and where 'STORE_FLAG_VALUE' is defined as
- '0x80000000', saying that just the sign bit is relevant, the
- expression
-
- (ne:SI (and:SI X (const_int POWER-OF-2)) (const_int 0))
-
- can be converted to
-
- (ashift:SI X (const_int N))
-
- where N is the appropriate shift count to move the bit being tested
- into the sign bit.
-
- There is no way to describe a machine that always sets the
- low-order bit for a true value, but does not guarantee the value of
- any other bits, but we do not know of any machine that has such an
- instruction. If you are trying to port GCC to such a machine,
- include an instruction to perform a logical-and of the result with
- 1 in the pattern for the comparison operators and let us know at
- <gcc@gcc.gnu.org>.
-
- Often, a machine will have multiple instructions that obtain a
- value from a comparison (or the condition codes). Here are rules
- to guide the choice of value for 'STORE_FLAG_VALUE', and hence the
- instructions to be used:
-
- * Use the shortest sequence that yields a valid definition for
- 'STORE_FLAG_VALUE'. It is more efficient for the compiler to
- "normalize" the value (convert it to, e.g., 1 or 0) than for
- the comparison operators to do so because there may be
- opportunities to combine the normalization with other
- operations.
-
- * For equal-length sequences, use a value of 1 or -1, with -1
- being slightly preferred on machines with expensive jumps and
- 1 preferred on other machines.
-
- * As a second choice, choose a value of '0x80000001' if
- instructions exist that set both the sign and low-order bits
- but do not define the others.
-
- * Otherwise, use a value of '0x80000000'.
-
- Many machines can produce both the value chosen for
- 'STORE_FLAG_VALUE' and its negation in the same number of
- instructions. On those machines, you should also define a pattern
- for those cases, e.g., one matching
-
- (set A (neg:M (ne:M B C)))
-
- Some machines can also perform 'and' or 'plus' operations on
- condition code values with less instructions than the corresponding
- 'cstoreMODE4' insn followed by 'and' or 'plus'. On those machines,
- define the appropriate patterns. Use the names 'incscc' and
- 'decscc', respectively, for the patterns which perform 'plus' or
- 'minus' operations on condition code values. See 'rs6000.md' for
- some examples. The GNU Superoptimizer can be used to find such
- instruction sequences on other machines.
-
- If this macro is not defined, the default value, 1, is used. You
- need not define 'STORE_FLAG_VALUE' if the machine has no store-flag
- instructions, or if the value generated by these instructions is 1.
-
- -- Macro: FLOAT_STORE_FLAG_VALUE (MODE)
- A C expression that gives a nonzero 'REAL_VALUE_TYPE' value that is
- returned when comparison operators with floating-point results are
- true. Define this macro on machines that have comparison
- operations that return floating-point values. If there are no such
- operations, do not define this macro.
-
- -- Macro: VECTOR_STORE_FLAG_VALUE (MODE)
- A C expression that gives a rtx representing the nonzero true
- element for vector comparisons. The returned rtx should be valid
- for the inner mode of MODE which is guaranteed to be a vector mode.
- Define this macro on machines that have vector comparison
- operations that return a vector result. If there are no such
- operations, do not define this macro. Typically, this macro is
- defined as 'const1_rtx' or 'constm1_rtx'. This macro may return
- 'NULL_RTX' to prevent the compiler optimizing such vector
- comparison operations for the given mode.
-
- -- Macro: CLZ_DEFINED_VALUE_AT_ZERO (MODE, VALUE)
- -- Macro: CTZ_DEFINED_VALUE_AT_ZERO (MODE, VALUE)
- A C expression that indicates whether the architecture defines a
- value for 'clz' or 'ctz' with a zero operand. A result of '0'
- indicates the value is undefined. If the value is defined for only
- the RTL expression, the macro should evaluate to '1'; if the value
- applies also to the corresponding optab entry (which is normally
- the case if it expands directly into the corresponding RTL), then
- the macro should evaluate to '2'. In the cases where the value is
- defined, VALUE should be set to this value.
-
- If this macro is not defined, the value of 'clz' or 'ctz' at zero
- is assumed to be undefined.
-
- This macro must be defined if the target's expansion for 'ffs'
- relies on a particular value to get correct results. Otherwise it
- is not necessary, though it may be used to optimize some corner
- cases, and to provide a default expansion for the 'ffs' optab.
-
- Note that regardless of this macro the "definedness" of 'clz' and
- 'ctz' at zero do _not_ extend to the builtin functions visible to
- the user. Thus one may be free to adjust the value at will to
- match the target expansion of these operations without fear of
- breaking the API.
-
- -- Macro: Pmode
- An alias for the machine mode for pointers. On most machines,
- define this to be the integer mode corresponding to the width of a
- hardware pointer; 'SImode' on 32-bit machine or 'DImode' on 64-bit
- machines. On some machines you must define this to be one of the
- partial integer modes, such as 'PSImode'.
-
- The width of 'Pmode' must be at least as large as the value of
- 'POINTER_SIZE'. If it is not equal, you must define the macro
- 'POINTERS_EXTEND_UNSIGNED' to specify how pointers are extended to
- 'Pmode'.
-
- -- Macro: FUNCTION_MODE
- An alias for the machine mode used for memory references to
- functions being called, in 'call' RTL expressions. On most CISC
- machines, where an instruction can begin at any byte address, this
- should be 'QImode'. On most RISC machines, where all instructions
- have fixed size and alignment, this should be a mode with the same
- size and alignment as the machine instruction words - typically
- 'SImode' or 'HImode'.
-
- -- Macro: STDC_0_IN_SYSTEM_HEADERS
- In normal operation, the preprocessor expands '__STDC__' to the
- constant 1, to signify that GCC conforms to ISO Standard C. On
- some hosts, like Solaris, the system compiler uses a different
- convention, where '__STDC__' is normally 0, but is 1 if the user
- specifies strict conformance to the C Standard.
-
- Defining 'STDC_0_IN_SYSTEM_HEADERS' makes GNU CPP follows the host
- convention when processing system header files, but when processing
- user files '__STDC__' will always expand to 1.
-
- -- C Target Hook: const char * TARGET_C_PREINCLUDE (void)
- Define this hook to return the name of a header file to be included
- at the start of all compilations, as if it had been included with
- '#include <FILE>'. If this hook returns 'NULL', or is not defined,
- or the header is not found, or if the user specifies
- '-ffreestanding' or '-nostdinc', no header is included.
-
- This hook can be used together with a header provided by the system
- C library to implement ISO C requirements for certain macros to be
- predefined that describe properties of the whole implementation
- rather than just the compiler.
-
- -- C Target Hook: bool TARGET_CXX_IMPLICIT_EXTERN_C (const char*)
- Define this hook to add target-specific C++ implicit extern C
- functions. If this function returns true for the name of a
- file-scope function, that function implicitly gets extern "C"
- linkage rather than whatever language linkage the declaration would
- normally have. An example of such function is WinMain on Win32
- targets.
-
- -- Macro: SYSTEM_IMPLICIT_EXTERN_C
- Define this macro if the system header files do not support C++.
- This macro handles system header files by pretending that system
- header files are enclosed in 'extern "C" {...}'.
-
- -- Macro: REGISTER_TARGET_PRAGMAS ()
- Define this macro if you want to implement any target-specific
- pragmas. If defined, it is a C expression which makes a series of
- calls to 'c_register_pragma' or 'c_register_pragma_with_expansion'
- for each pragma. The macro may also do any setup required for the
- pragmas.
-
- The primary reason to define this macro is to provide compatibility
- with other compilers for the same target. In general, we
- discourage definition of target-specific pragmas for GCC.
-
- If the pragma can be implemented by attributes then you should
- consider defining the target hook 'TARGET_INSERT_ATTRIBUTES' as
- well.
-
- Preprocessor macros that appear on pragma lines are not expanded.
- All '#pragma' directives that do not match any registered pragma
- are silently ignored, unless the user specifies
- '-Wunknown-pragmas'.
-
- -- Function: void c_register_pragma (const char *SPACE, const char
- *NAME, void (*CALLBACK) (struct cpp_reader *))
- -- Function: void c_register_pragma_with_expansion (const char *SPACE,
- const char *NAME, void (*CALLBACK) (struct cpp_reader *))
-
- Each call to 'c_register_pragma' or
- 'c_register_pragma_with_expansion' establishes one pragma. The
- CALLBACK routine will be called when the preprocessor encounters a
- pragma of the form
-
- #pragma [SPACE] NAME ...
-
- SPACE is the case-sensitive namespace of the pragma, or 'NULL' to
- put the pragma in the global namespace. The callback routine
- receives PFILE as its first argument, which can be passed on to
- cpplib's functions if necessary. You can lex tokens after the NAME
- by calling 'pragma_lex'. Tokens that are not read by the callback
- will be silently ignored. The end of the line is indicated by a
- token of type 'CPP_EOF'. Macro expansion occurs on the arguments
- of pragmas registered with 'c_register_pragma_with_expansion' but
- not on the arguments of pragmas registered with
- 'c_register_pragma'.
-
- Note that the use of 'pragma_lex' is specific to the C and C++
- compilers. It will not work in the Java or Fortran compilers, or
- any other language compilers for that matter. Thus if 'pragma_lex'
- is going to be called from target-specific code, it must only be
- done so when building the C and C++ compilers. This can be done by
- defining the variables 'c_target_objs' and 'cxx_target_objs' in the
- target entry in the 'config.gcc' file. These variables should name
- the target-specific, language-specific object file which contains
- the code that uses 'pragma_lex'. Note it will also be necessary to
- add a rule to the makefile fragment pointed to by 'tmake_file' that
- shows how to build this object file.
-
- -- Macro: HANDLE_PRAGMA_PACK_WITH_EXPANSION
- Define this macro if macros should be expanded in the arguments of
- '#pragma pack'.
-
- -- Macro: TARGET_DEFAULT_PACK_STRUCT
- If your target requires a structure packing default other than 0
- (meaning the machine default), define this macro to the necessary
- value (in bytes). This must be a value that would also be valid to
- use with '#pragma pack()' (that is, a small power of two).
-
- -- Macro: DOLLARS_IN_IDENTIFIERS
- Define this macro to control use of the character '$' in identifier
- names for the C family of languages. 0 means '$' is not allowed by
- default; 1 means it is allowed. 1 is the default; there is no need
- to define this macro in that case.
-
- -- Macro: INSN_SETS_ARE_DELAYED (INSN)
- Define this macro as a C expression that is nonzero if it is safe
- for the delay slot scheduler to place instructions in the delay
- slot of INSN, even if they appear to use a resource set or
- clobbered in INSN. INSN is always a 'jump_insn' or an 'insn'; GCC
- knows that every 'call_insn' has this behavior. On machines where
- some 'insn' or 'jump_insn' is really a function call and hence has
- this behavior, you should define this macro.
-
- You need not define this macro if it would always return zero.
-
- -- Macro: INSN_REFERENCES_ARE_DELAYED (INSN)
- Define this macro as a C expression that is nonzero if it is safe
- for the delay slot scheduler to place instructions in the delay
- slot of INSN, even if they appear to set or clobber a resource
- referenced in INSN. INSN is always a 'jump_insn' or an 'insn'. On
- machines where some 'insn' or 'jump_insn' is really a function call
- and its operands are registers whose use is actually in the
- subroutine it calls, you should define this macro. Doing so allows
- the delay slot scheduler to move instructions which copy arguments
- into the argument registers into the delay slot of INSN.
-
- You need not define this macro if it would always return zero.
-
- -- Macro: MULTIPLE_SYMBOL_SPACES
- Define this macro as a C expression that is nonzero if, in some
- cases, global symbols from one translation unit may not be bound to
- undefined symbols in another translation unit without user
- intervention. For instance, under Microsoft Windows symbols must
- be explicitly imported from shared libraries (DLLs).
-
- You need not define this macro if it would always evaluate to zero.
-
- -- Target Hook: rtx_insn * TARGET_MD_ASM_ADJUST (vec<rtx>& OUTPUTS,
- vec<rtx>& INPUTS, vec<const char *>& CONSTRAINTS, vec<rtx>&
- CLOBBERS, HARD_REG_SET& CLOBBERED_REGS)
- This target hook may add "clobbers" to CLOBBERS and CLOBBERED_REGS
- for any hard regs the port wishes to automatically clobber for an
- asm. The OUTPUTS and INPUTS may be inspected to avoid clobbering a
- register that is already used by the asm.
-
- It may modify the OUTPUTS, INPUTS, and CONSTRAINTS as necessary for
- other pre-processing. In this case the return value is a sequence
- of insns to emit after the asm.
-
- -- Macro: MATH_LIBRARY
- Define this macro as a C string constant for the linker argument to
- link in the system math library, minus the initial '"-l"', or '""'
- if the target does not have a separate math library.
-
- You need only define this macro if the default of '"m"' is wrong.
-
- -- Macro: LIBRARY_PATH_ENV
- Define this macro as a C string constant for the environment
- variable that specifies where the linker should look for libraries.
-
- You need only define this macro if the default of '"LIBRARY_PATH"'
- is wrong.
-
- -- Macro: TARGET_POSIX_IO
- Define this macro if the target supports the following POSIX file
- functions, access, mkdir and file locking with fcntl / F_SETLKW.
- Defining 'TARGET_POSIX_IO' will enable the test coverage code to
- use file locking when exiting a program, which avoids race
- conditions if the program has forked. It will also create
- directories at run-time for cross-profiling.
-
- -- Macro: MAX_CONDITIONAL_EXECUTE
-
- A C expression for the maximum number of instructions to execute
- via conditional execution instructions instead of a branch. A
- value of 'BRANCH_COST'+1 is the default if the machine does not use
- cc0, and 1 if it does use cc0.
-
- -- Macro: IFCVT_MODIFY_TESTS (CE_INFO, TRUE_EXPR, FALSE_EXPR)
- Used if the target needs to perform machine-dependent modifications
- on the conditionals used for turning basic blocks into
- conditionally executed code. CE_INFO points to a data structure,
- 'struct ce_if_block', which contains information about the
- currently processed blocks. TRUE_EXPR and FALSE_EXPR are the tests
- that are used for converting the then-block and the else-block,
- respectively. Set either TRUE_EXPR or FALSE_EXPR to a null pointer
- if the tests cannot be converted.
-
- -- Macro: IFCVT_MODIFY_MULTIPLE_TESTS (CE_INFO, BB, TRUE_EXPR,
- FALSE_EXPR)
- Like 'IFCVT_MODIFY_TESTS', but used when converting more
- complicated if-statements into conditions combined by 'and' and
- 'or' operations. BB contains the basic block that contains the
- test that is currently being processed and about to be turned into
- a condition.
-
- -- Macro: IFCVT_MODIFY_INSN (CE_INFO, PATTERN, INSN)
- A C expression to modify the PATTERN of an INSN that is to be
- converted to conditional execution format. CE_INFO points to a
- data structure, 'struct ce_if_block', which contains information
- about the currently processed blocks.
-
- -- Macro: IFCVT_MODIFY_FINAL (CE_INFO)
- A C expression to perform any final machine dependent modifications
- in converting code to conditional execution. The involved basic
- blocks can be found in the 'struct ce_if_block' structure that is
- pointed to by CE_INFO.
-
- -- Macro: IFCVT_MODIFY_CANCEL (CE_INFO)
- A C expression to cancel any machine dependent modifications in
- converting code to conditional execution. The involved basic
- blocks can be found in the 'struct ce_if_block' structure that is
- pointed to by CE_INFO.
-
- -- Macro: IFCVT_MACHDEP_INIT (CE_INFO)
- A C expression to initialize any machine specific data for
- if-conversion of the if-block in the 'struct ce_if_block' structure
- that is pointed to by CE_INFO.
-
- -- Target Hook: void TARGET_MACHINE_DEPENDENT_REORG (void)
- If non-null, this hook performs a target-specific pass over the
- instruction stream. The compiler will run it at all optimization
- levels, just before the point at which it normally does
- delayed-branch scheduling.
-
- The exact purpose of the hook varies from target to target. Some
- use it to do transformations that are necessary for correctness,
- such as laying out in-function constant pools or avoiding hardware
- hazards. Others use it as an opportunity to do some
- machine-dependent optimizations.
-
- You need not implement the hook if it has nothing to do. The
- default definition is null.
-
- -- Target Hook: void TARGET_INIT_BUILTINS (void)
- Define this hook if you have any machine-specific built-in
- functions that need to be defined. It should be a function that
- performs the necessary setup.
-
- Machine specific built-in functions can be useful to expand special
- machine instructions that would otherwise not normally be generated
- because they have no equivalent in the source language (for
- example, SIMD vector instructions or prefetch instructions).
-
- To create a built-in function, call the function
- 'lang_hooks.builtin_function' which is defined by the language
- front end. You can use any type nodes set up by
- 'build_common_tree_nodes'; only language front ends that use those
- two functions will call 'TARGET_INIT_BUILTINS'.
-
- -- Target Hook: tree TARGET_BUILTIN_DECL (unsigned CODE, bool
- INITIALIZE_P)
- Define this hook if you have any machine-specific built-in
- functions that need to be defined. It should be a function that
- returns the builtin function declaration for the builtin function
- code CODE. If there is no such builtin and it cannot be
- initialized at this time if INITIALIZE_P is true the function
- should return 'NULL_TREE'. If CODE is out of range the function
- should return 'error_mark_node'.
-
- -- Target Hook: rtx TARGET_EXPAND_BUILTIN (tree EXP, rtx TARGET, rtx
- SUBTARGET, machine_mode MODE, int IGNORE)
-
- Expand a call to a machine specific built-in function that was set
- up by 'TARGET_INIT_BUILTINS'. EXP is the expression for the
- function call; the result should go to TARGET if that is
- convenient, and have mode MODE if that is convenient. SUBTARGET
- may be used as the target for computing one of EXP's operands.
- IGNORE is nonzero if the value is to be ignored. This function
- should return the result of the call to the built-in function.
-
- -- Target Hook: tree TARGET_RESOLVE_OVERLOADED_BUILTIN (unsigned int
- LOC, tree FNDECL, void *ARGLIST)
- Select a replacement for a machine specific built-in function that
- was set up by 'TARGET_INIT_BUILTINS'. This is done _before_
- regular type checking, and so allows the target to implement a
- crude form of function overloading. FNDECL is the declaration of
- the built-in function. ARGLIST is the list of arguments passed to
- the built-in function. The result is a complete expression that
- implements the operation, usually another 'CALL_EXPR'. ARGLIST
- really has type 'VEC(tree,gc)*'
-
- -- Target Hook: bool TARGET_CHECK_BUILTIN_CALL (location_t LOC,
- vec<location_t> ARG_LOC, tree FNDECL, tree ORIG_FNDECL,
- unsigned int NARGS, tree *ARGS)
- Perform semantic checking on a call to a machine-specific built-in
- function after its arguments have been constrained to the function
- signature. Return true if the call is valid, otherwise report an
- error and return false.
-
- This hook is called after 'TARGET_RESOLVE_OVERLOADED_BUILTIN'. The
- call was originally to built-in function ORIG_FNDECL, but after the
- optional 'TARGET_RESOLVE_OVERLOADED_BUILTIN' step is now to
- built-in function FNDECL. LOC is the location of the call and ARGS
- is an array of function arguments, of which there are NARGS.
- ARG_LOC specifies the location of each argument.
-
- -- Target Hook: tree TARGET_FOLD_BUILTIN (tree FNDECL, int N_ARGS, tree
- *ARGP, bool IGNORE)
- Fold a call to a machine specific built-in function that was set up
- by 'TARGET_INIT_BUILTINS'. FNDECL is the declaration of the
- built-in function. N_ARGS is the number of arguments passed to the
- function; the arguments themselves are pointed to by ARGP. The
- result is another tree, valid for both GIMPLE and GENERIC,
- containing a simplified expression for the call's result. If
- IGNORE is true the value will be ignored.
-
- -- Target Hook: bool TARGET_GIMPLE_FOLD_BUILTIN (gimple_stmt_iterator
- *GSI)
- Fold a call to a machine specific built-in function that was set up
- by 'TARGET_INIT_BUILTINS'. GSI points to the gimple statement
- holding the function call. Returns true if any change was made to
- the GIMPLE stream.
-
- -- Target Hook: int TARGET_COMPARE_VERSION_PRIORITY (tree DECL1, tree
- DECL2)
- This hook is used to compare the target attributes in two functions
- to determine which function's features get higher priority. This
- is used during function multi-versioning to figure out the order in
- which two versions must be dispatched. A function version with a
- higher priority is checked for dispatching earlier. DECL1 and
- DECL2 are the two function decls that will be compared.
-
- -- Target Hook: tree TARGET_GET_FUNCTION_VERSIONS_DISPATCHER (void
- *DECL)
- This hook is used to get the dispatcher function for a set of
- function versions. The dispatcher function is called to invoke the
- right function version at run-time. DECL is one version from a set
- of semantically identical versions.
-
- -- Target Hook: tree TARGET_GENERATE_VERSION_DISPATCHER_BODY (void
- *ARG)
- This hook is used to generate the dispatcher logic to invoke the
- right function version at run-time for a given set of function
- versions. ARG points to the callgraph node of the dispatcher
- function whose body must be generated.
-
- -- Target Hook: bool TARGET_PREDICT_DOLOOP_P (class loop *LOOP)
- Return true if we can predict it is possible to use a low-overhead
- loop for a particular loop. The parameter LOOP is a pointer to the
- loop. This target hook is required only when the target supports
- low-overhead loops, and will help ivopts to make some decisions.
- The default version of this hook returns false.
-
- -- Target Hook: bool TARGET_HAVE_COUNT_REG_DECR_P
- Return true if the target supports hardware count register for
- decrement and branch. The default value is false.
-
- -- Target Hook: int64_t TARGET_DOLOOP_COST_FOR_GENERIC
- One IV candidate dedicated for doloop is introduced in IVOPTs, we
- can calculate the computation cost of adopting it to any generic IV
- use by function get_computation_cost as before. But for targets
- which have hardware count register support for decrement and
- branch, it may have to move IV value from hardware count register
- to general purpose register while doloop IV candidate is used for
- generic IV uses. It probably takes expensive penalty. This hook
- allows target owners to define the cost for this especially for
- generic IV uses. The default value is zero.
-
- -- Target Hook: int64_t TARGET_DOLOOP_COST_FOR_ADDRESS
- One IV candidate dedicated for doloop is introduced in IVOPTs, we
- can calculate the computation cost of adopting it to any address IV
- use by function get_computation_cost as before. But for targets
- which have hardware count register support for decrement and
- branch, it may have to move IV value from hardware count register
- to general purpose register while doloop IV candidate is used for
- address IV uses. It probably takes expensive penalty. This hook
- allows target owners to define the cost for this escpecially for
- address IV uses. The default value is zero.
-
- -- Target Hook: bool TARGET_CAN_USE_DOLOOP_P (const widest_int
- &ITERATIONS, const widest_int &ITERATIONS_MAX, unsigned int
- LOOP_DEPTH, bool ENTERED_AT_TOP)
- Return true if it is possible to use low-overhead loops
- ('doloop_end' and 'doloop_begin') for a particular loop.
- ITERATIONS gives the exact number of iterations, or 0 if not known.
- ITERATIONS_MAX gives the maximum number of iterations, or 0 if not
- known. LOOP_DEPTH is the nesting depth of the loop, with 1 for
- innermost loops, 2 for loops that contain innermost loops, and so
- on. ENTERED_AT_TOP is true if the loop is only entered from the
- top.
-
- This hook is only used if 'doloop_end' is available. The default
- implementation returns true. You can use
- 'can_use_doloop_if_innermost' if the loop must be the innermost,
- and if there are no other restrictions.
-
- -- Target Hook: const char * TARGET_INVALID_WITHIN_DOLOOP (const
- rtx_insn *INSN)
-
- Take an instruction in INSN and return NULL if it is valid within a
- low-overhead loop, otherwise return a string explaining why doloop
- could not be applied.
-
- Many targets use special registers for low-overhead looping. For
- any instruction that clobbers these this function should return a
- string indicating the reason why the doloop could not be applied.
- By default, the RTL loop optimizer does not use a present doloop
- pattern for loops containing function calls or branch on table
- instructions.
-
- -- Target Hook: bool TARGET_LEGITIMATE_COMBINED_INSN (rtx_insn *INSN)
- Take an instruction in INSN and return 'false' if the instruction
- is not appropriate as a combination of two or more instructions.
- The default is to accept all instructions.
-
- -- Target Hook: bool TARGET_CAN_FOLLOW_JUMP (const rtx_insn *FOLLOWER,
- const rtx_insn *FOLLOWEE)
- FOLLOWER and FOLLOWEE are JUMP_INSN instructions; return true if
- FOLLOWER may be modified to follow FOLLOWEE; false, if it can't.
- For example, on some targets, certain kinds of branches can't be
- made to follow through a hot/cold partitioning.
-
- -- Target Hook: bool TARGET_COMMUTATIVE_P (const_rtx X, int OUTER_CODE)
- This target hook returns 'true' if X is considered to be
- commutative. Usually, this is just COMMUTATIVE_P (X), but the HP
- PA doesn't consider PLUS to be commutative inside a MEM.
- OUTER_CODE is the rtx code of the enclosing rtl, if known,
- otherwise it is UNKNOWN.
-
- -- Target Hook: rtx TARGET_ALLOCATE_INITIAL_VALUE (rtx HARD_REG)
-
- When the initial value of a hard register has been copied in a
- pseudo register, it is often not necessary to actually allocate
- another register to this pseudo register, because the original hard
- register or a stack slot it has been saved into can be used.
- 'TARGET_ALLOCATE_INITIAL_VALUE' is called at the start of register
- allocation once for each hard register that had its initial value
- copied by using 'get_func_hard_reg_initial_val' or
- 'get_hard_reg_initial_val'. Possible values are 'NULL_RTX', if you
- don't want to do any special allocation, a 'REG' rtx--that would
- typically be the hard register itself, if it is known not to be
- clobbered--or a 'MEM'. If you are returning a 'MEM', this is only
- a hint for the allocator; it might decide to use another register
- anyways. You may use 'current_function_is_leaf' or 'REG_N_SETS' in
- the hook to determine if the hard register in question will not be
- clobbered. The default value of this hook is 'NULL', which
- disables any special allocation.
-
- -- Target Hook: int TARGET_UNSPEC_MAY_TRAP_P (const_rtx X, unsigned
- FLAGS)
- This target hook returns nonzero if X, an 'unspec' or
- 'unspec_volatile' operation, might cause a trap. Targets can use
- this hook to enhance precision of analysis for 'unspec' and
- 'unspec_volatile' operations. You may call 'may_trap_p_1' to
- analyze inner elements of X in which case FLAGS should be passed
- along.
-
- -- Target Hook: void TARGET_SET_CURRENT_FUNCTION (tree DECL)
- The compiler invokes this hook whenever it changes its current
- function context ('cfun'). You can define this function if the
- back end needs to perform any initialization or reset actions on a
- per-function basis. For example, it may be used to implement
- function attributes that affect register usage or code generation
- patterns. The argument DECL is the declaration for the new
- function context, and may be null to indicate that the compiler has
- left a function context and is returning to processing at the top
- level. The default hook function does nothing.
-
- GCC sets 'cfun' to a dummy function context during initialization
- of some parts of the back end. The hook function is not invoked in
- this situation; you need not worry about the hook being invoked
- recursively, or when the back end is in a partially-initialized
- state. 'cfun' might be 'NULL' to indicate processing at top level,
- outside of any function scope.
-
- -- Macro: TARGET_OBJECT_SUFFIX
- Define this macro to be a C string representing the suffix for
- object files on your target machine. If you do not define this
- macro, GCC will use '.o' as the suffix for object files.
-
- -- Macro: TARGET_EXECUTABLE_SUFFIX
- Define this macro to be a C string representing the suffix to be
- automatically added to executable files on your target machine. If
- you do not define this macro, GCC will use the null string as the
- suffix for executable files.
-
- -- Macro: COLLECT_EXPORT_LIST
- If defined, 'collect2' will scan the individual object files
- specified on its command line and create an export list for the
- linker. Define this macro for systems like AIX, where the linker
- discards object files that are not referenced from 'main' and uses
- export lists.
-
- -- Target Hook: bool TARGET_CANNOT_MODIFY_JUMPS_P (void)
- This target hook returns 'true' past the point in which new jump
- instructions could be created. On machines that require a register
- for every jump such as the SHmedia ISA of SH5, this point would
- typically be reload, so this target hook should be defined to a
- function such as:
-
- static bool
- cannot_modify_jumps_past_reload_p ()
- {
- return (reload_completed || reload_in_progress);
- }
-
- -- Target Hook: bool TARGET_HAVE_CONDITIONAL_EXECUTION (void)
- This target hook returns true if the target supports conditional
- execution. This target hook is required only when the target has
- several different modes and they have different conditional
- execution capability, such as ARM.
-
- -- Target Hook: rtx TARGET_GEN_CCMP_FIRST (rtx_insn **PREP_SEQ,
- rtx_insn **GEN_SEQ, int CODE, tree OP0, tree OP1)
- This function prepares to emit a comparison insn for the first
- compare in a sequence of conditional comparisions. It returns an
- appropriate comparison with 'CC' for passing to 'gen_ccmp_next' or
- 'cbranch_optab'. The insns to prepare the compare are saved in
- PREP_SEQ and the compare insns are saved in GEN_SEQ. They will be
- emitted when all the compares in the conditional comparision are
- generated without error. CODE is the 'rtx_code' of the compare for
- OP0 and OP1.
-
- -- Target Hook: rtx TARGET_GEN_CCMP_NEXT (rtx_insn **PREP_SEQ, rtx_insn
- **GEN_SEQ, rtx PREV, int CMP_CODE, tree OP0, tree OP1, int
- BIT_CODE)
- This function prepares to emit a conditional comparison within a
- sequence of conditional comparisons. It returns an appropriate
- comparison with 'CC' for passing to 'gen_ccmp_next' or
- 'cbranch_optab'. The insns to prepare the compare are saved in
- PREP_SEQ and the compare insns are saved in GEN_SEQ. They will be
- emitted when all the compares in the conditional comparision are
- generated without error. The PREV expression is the result of a
- prior call to 'gen_ccmp_first' or 'gen_ccmp_next'. It may return
- 'NULL' if the combination of PREV and this comparison is not
- supported, otherwise the result must be appropriate for passing to
- 'gen_ccmp_next' or 'cbranch_optab'. CODE is the 'rtx_code' of the
- compare for OP0 and OP1. BIT_CODE is 'AND' or 'IOR', which is the
- op on the compares.
-
- -- Target Hook: unsigned TARGET_LOOP_UNROLL_ADJUST (unsigned NUNROLL,
- class loop *LOOP)
- This target hook returns a new value for the number of times LOOP
- should be unrolled. The parameter NUNROLL is the number of times
- the loop is to be unrolled. The parameter LOOP is a pointer to the
- loop, which is going to be checked for unrolling. This target hook
- is required only when the target has special constraints like
- maximum number of memory accesses.
-
- -- Macro: POWI_MAX_MULTS
- If defined, this macro is interpreted as a signed integer C
- expression that specifies the maximum number of floating point
- multiplications that should be emitted when expanding
- exponentiation by an integer constant inline. When this value is
- defined, exponentiation requiring more than this number of
- multiplications is implemented by calling the system library's
- 'pow', 'powf' or 'powl' routines. The default value places no
- upper bound on the multiplication count.
-
- -- Macro: void TARGET_EXTRA_INCLUDES (const char *SYSROOT, const char
- *IPREFIX, int STDINC)
- This target hook should register any extra include files for the
- target. The parameter STDINC indicates if normal include files are
- present. The parameter SYSROOT is the system root directory. The
- parameter IPREFIX is the prefix for the gcc directory.
-
- -- Macro: void TARGET_EXTRA_PRE_INCLUDES (const char *SYSROOT, const
- char *IPREFIX, int STDINC)
- This target hook should register any extra include files for the
- target before any standard headers. The parameter STDINC indicates
- if normal include files are present. The parameter SYSROOT is the
- system root directory. The parameter IPREFIX is the prefix for the
- gcc directory.
-
- -- Macro: void TARGET_OPTF (char *PATH)
- This target hook should register special include paths for the
- target. The parameter PATH is the include to register. On Darwin
- systems, this is used for Framework includes, which have semantics
- that are different from '-I'.
-
- -- Macro: bool TARGET_USE_LOCAL_THUNK_ALIAS_P (tree FNDECL)
- This target macro returns 'true' if it is safe to use a local alias
- for a virtual function FNDECL when constructing thunks, 'false'
- otherwise. By default, the macro returns 'true' for all functions,
- if a target supports aliases (i.e. defines 'ASM_OUTPUT_DEF'),
- 'false' otherwise,
-
- -- Macro: TARGET_FORMAT_TYPES
- If defined, this macro is the name of a global variable containing
- target-specific format checking information for the '-Wformat'
- option. The default is to have no target-specific format checks.
-
- -- Macro: TARGET_N_FORMAT_TYPES
- If defined, this macro is the number of entries in
- 'TARGET_FORMAT_TYPES'.
-
- -- Macro: TARGET_OVERRIDES_FORMAT_ATTRIBUTES
- If defined, this macro is the name of a global variable containing
- target-specific format overrides for the '-Wformat' option. The
- default is to have no target-specific format overrides. If
- defined, 'TARGET_FORMAT_TYPES' must be defined, too.
-
- -- Macro: TARGET_OVERRIDES_FORMAT_ATTRIBUTES_COUNT
- If defined, this macro specifies the number of entries in
- 'TARGET_OVERRIDES_FORMAT_ATTRIBUTES'.
-
- -- Macro: TARGET_OVERRIDES_FORMAT_INIT
- If defined, this macro specifies the optional initialization
- routine for target specific customizations of the system printf and
- scanf formatter settings.
-
- -- Target Hook: const char * TARGET_INVALID_ARG_FOR_UNPROTOTYPED_FN
- (const_tree TYPELIST, const_tree FUNCDECL, const_tree VAL)
- If defined, this macro returns the diagnostic message when it is
- illegal to pass argument VAL to function FUNCDECL with prototype
- TYPELIST.
-
- -- Target Hook: const char * TARGET_INVALID_CONVERSION (const_tree
- FROMTYPE, const_tree TOTYPE)
- If defined, this macro returns the diagnostic message when it is
- invalid to convert from FROMTYPE to TOTYPE, or 'NULL' if validity
- should be determined by the front end.
-
- -- Target Hook: const char * TARGET_INVALID_UNARY_OP (int OP,
- const_tree TYPE)
- If defined, this macro returns the diagnostic message when it is
- invalid to apply operation OP (where unary plus is denoted by
- 'CONVERT_EXPR') to an operand of type TYPE, or 'NULL' if validity
- should be determined by the front end.
-
- -- Target Hook: const char * TARGET_INVALID_BINARY_OP (int OP,
- const_tree TYPE1, const_tree TYPE2)
- If defined, this macro returns the diagnostic message when it is
- invalid to apply operation OP to operands of types TYPE1 and TYPE2,
- or 'NULL' if validity should be determined by the front end.
-
- -- Target Hook: tree TARGET_PROMOTED_TYPE (const_tree TYPE)
- If defined, this target hook returns the type to which values of
- TYPE should be promoted when they appear in expressions, analogous
- to the integer promotions, or 'NULL_TREE' to use the front end's
- normal promotion rules. This hook is useful when there are
- target-specific types with special promotion rules. This is
- currently used only by the C and C++ front ends.
-
- -- Target Hook: tree TARGET_CONVERT_TO_TYPE (tree TYPE, tree EXPR)
- If defined, this hook returns the result of converting EXPR to
- TYPE. It should return the converted expression, or 'NULL_TREE' to
- apply the front end's normal conversion rules. This hook is useful
- when there are target-specific types with special conversion rules.
- This is currently used only by the C and C++ front ends.
-
- -- Target Hook: bool TARGET_VERIFY_TYPE_CONTEXT (location_t LOC,
- type_context_kind CONTEXT, const_tree TYPE, bool SILENT_P)
- If defined, this hook returns false if there is a target-specific
- reason why type TYPE cannot be used in the source language context
- described by CONTEXT. When SILENT_P is false, the hook also
- reports an error against LOC for invalid uses of TYPE.
-
- Calls to this hook should be made through the global function
- 'verify_type_context', which makes the SILENT_P parameter default
- to false and also handles 'error_mark_node'.
-
- The default implementation always returns true.
-
- -- Macro: OBJC_JBLEN
- This macro determines the size of the objective C jump buffer for
- the NeXT runtime. By default, OBJC_JBLEN is defined to an
- innocuous value.
-
- -- Macro: LIBGCC2_UNWIND_ATTRIBUTE
- Define this macro if any target-specific attributes need to be
- attached to the functions in 'libgcc' that provide low-level
- support for call stack unwinding. It is used in declarations in
- 'unwind-generic.h' and the associated definitions of those
- functions.
-
- -- Target Hook: void TARGET_UPDATE_STACK_BOUNDARY (void)
- Define this macro to update the current function stack boundary if
- necessary.
-
- -- Target Hook: rtx TARGET_GET_DRAP_RTX (void)
- This hook should return an rtx for Dynamic Realign Argument Pointer
- (DRAP) if a different argument pointer register is needed to access
- the function's argument list due to stack realignment. Return
- 'NULL' if no DRAP is needed.
-
- -- Target Hook: bool TARGET_ALLOCATE_STACK_SLOTS_FOR_ARGS (void)
- When optimization is disabled, this hook indicates whether or not
- arguments should be allocated to stack slots. Normally, GCC
- allocates stacks slots for arguments when not optimizing in order
- to make debugging easier. However, when a function is declared
- with '__attribute__((naked))', there is no stack frame, and the
- compiler cannot safely move arguments from the registers in which
- they are passed to the stack. Therefore, this hook should return
- true in general, but false for naked functions. The default
- implementation always returns true.
-
- -- Target Hook: unsigned HOST_WIDE_INT TARGET_CONST_ANCHOR
- On some architectures it can take multiple instructions to
- synthesize a constant. If there is another constant already in a
- register that is close enough in value then it is preferable that
- the new constant is computed from this register using immediate
- addition or subtraction. We accomplish this through CSE. Besides
- the value of the constant we also add a lower and an upper constant
- anchor to the available expressions. These are then queried when
- encountering new constants. The anchors are computed by rounding
- the constant up and down to a multiple of the value of
- 'TARGET_CONST_ANCHOR'. 'TARGET_CONST_ANCHOR' should be the maximum
- positive value accepted by immediate-add plus one. We currently
- assume that the value of 'TARGET_CONST_ANCHOR' is a power of 2.
- For example, on MIPS, where add-immediate takes a 16-bit signed
- value, 'TARGET_CONST_ANCHOR' is set to '0x8000'. The default value
- is zero, which disables this optimization.
-
- -- Target Hook: unsigned HOST_WIDE_INT TARGET_ASAN_SHADOW_OFFSET (void)
- Return the offset bitwise ored into shifted address to get
- corresponding Address Sanitizer shadow memory address. NULL if
- Address Sanitizer is not supported by the target.
-
- -- Target Hook: unsigned HOST_WIDE_INT TARGET_MEMMODEL_CHECK (unsigned
- HOST_WIDE_INT VAL)
- Validate target specific memory model mask bits. When NULL no
- target specific memory model bits are allowed.
-
- -- Target Hook: unsigned char TARGET_ATOMIC_TEST_AND_SET_TRUEVAL
- This value should be set if the result written by
- 'atomic_test_and_set' is not exactly 1, i.e. the 'bool' 'true'.
-
- -- Target Hook: bool TARGET_HAS_IFUNC_P (void)
- It returns true if the target supports GNU indirect functions. The
- support includes the assembler, linker and dynamic linker. The
- default value of this hook is based on target's libc.
-
- -- Target Hook: unsigned int TARGET_ATOMIC_ALIGN_FOR_MODE (machine_mode
- MODE)
- If defined, this function returns an appropriate alignment in bits
- for an atomic object of machine_mode MODE. If 0 is returned then
- the default alignment for the specified mode is used.
-
- -- Target Hook: void TARGET_ATOMIC_ASSIGN_EXPAND_FENV (tree *HOLD, tree
- *CLEAR, tree *UPDATE)
- ISO C11 requires atomic compound assignments that may raise
- floating-point exceptions to raise exceptions corresponding to the
- arithmetic operation whose result was successfully stored in a
- compare-and-exchange sequence. This requires code equivalent to
- calls to 'feholdexcept', 'feclearexcept' and 'feupdateenv' to be
- generated at appropriate points in the compare-and-exchange
- sequence. This hook should set '*HOLD' to an expression equivalent
- to the call to 'feholdexcept', '*CLEAR' to an expression equivalent
- to the call to 'feclearexcept' and '*UPDATE' to an expression
- equivalent to the call to 'feupdateenv'. The three expressions are
- 'NULL_TREE' on entry to the hook and may be left as 'NULL_TREE' if
- no code is required in a particular place. The default
- implementation leaves all three expressions as 'NULL_TREE'. The
- '__atomic_feraiseexcept' function from 'libatomic' may be of use as
- part of the code generated in '*UPDATE'.
-
- -- Target Hook: void TARGET_RECORD_OFFLOAD_SYMBOL (tree)
- Used when offloaded functions are seen in the compilation unit and
- no named sections are available. It is called once for each symbol
- that must be recorded in the offload function and variable table.
-
- -- Target Hook: char * TARGET_OFFLOAD_OPTIONS (void)
- Used when writing out the list of options into an LTO file. It
- should translate any relevant target-specific options (such as the
- ABI in use) into one of the '-foffload' options that exist as a
- common interface to express such options. It should return a
- string containing these options, separated by spaces, which the
- caller will free.
-
- -- Macro: TARGET_SUPPORTS_WIDE_INT
-
- On older ports, large integers are stored in 'CONST_DOUBLE' rtl
- objects. Newer ports define 'TARGET_SUPPORTS_WIDE_INT' to be
- nonzero to indicate that large integers are stored in
- 'CONST_WIDE_INT' rtl objects. The 'CONST_WIDE_INT' allows very
- large integer constants to be represented. 'CONST_DOUBLE' is
- limited to twice the size of the host's 'HOST_WIDE_INT'
- representation.
-
- Converting a port mostly requires looking for the places where
- 'CONST_DOUBLE's are used with 'VOIDmode' and replacing that code
- with code that accesses 'CONST_WIDE_INT's. '"grep -i
- const_double"' at the port level gets you to 95% of the changes
- that need to be made. There are a few places that require a deeper
- look.
-
- * There is no equivalent to 'hval' and 'lval' for
- 'CONST_WIDE_INT's. This would be difficult to express in the
- md language since there are a variable number of elements.
-
- Most ports only check that 'hval' is either 0 or -1 to see if
- the value is small. As mentioned above, this will no longer
- be necessary since small constants are always 'CONST_INT'. Of
- course there are still a few exceptions, the alpha's
- constraint used by the zap instruction certainly requires
- careful examination by C code. However, all the current code
- does is pass the hval and lval to C code, so evolving the c
- code to look at the 'CONST_WIDE_INT' is not really a large
- change.
-
- * Because there is no standard template that ports use to
- materialize constants, there is likely to be some futzing that
- is unique to each port in this code.
-
- * The rtx costs may have to be adjusted to properly account for
- larger constants that are represented as 'CONST_WIDE_INT'.
-
- All and all it does not take long to convert ports that the
- maintainer is familiar with.
-
- -- Target Hook: bool TARGET_HAVE_SPECULATION_SAFE_VALUE (bool ACTIVE)
- This hook is used to determine the level of target support for
- '__builtin_speculation_safe_value'. If called with an argument of
- false, it returns true if the target has been modified to support
- this builtin. If called with an argument of true, it returns true
- if the target requires active mitigation execution might be
- speculative.
-
- The default implementation returns false if the target does not
- define a pattern named 'speculation_barrier'. Else it returns true
- for the first case and whether the pattern is enabled for the
- current compilation for the second case.
-
- For targets that have no processors that can execute instructions
- speculatively an alternative implemenation of this hook is
- available: simply redefine this hook to
- 'speculation_safe_value_not_needed' along with your other target
- hooks.
-
- -- Target Hook: rtx TARGET_SPECULATION_SAFE_VALUE (machine_mode MODE,
- rtx RESULT, rtx VAL, rtx FAILVAL)
- This target hook can be used to generate a target-specific code
- sequence that implements the '__builtin_speculation_safe_value'
- built-in function. The function must always return VAL in RESULT
- in mode MODE when the cpu is not executing speculatively, but must
- never return that when speculating until it is known that the
- speculation will not be unwound. The hook supports two primary
- mechanisms for implementing the requirements. The first is to emit
- a speculation barrier which forces the processor to wait until all
- prior speculative operations have been resolved; the second is to
- use a target-specific mechanism that can track the speculation
- state and to return FAILVAL if it can determine that speculation
- must be unwound at a later time.
-
- The default implementation simply copies VAL to RESULT and emits a
- 'speculation_barrier' instruction if that is defined.
-
- -- Target Hook: void TARGET_RUN_TARGET_SELFTESTS (void)
- If selftests are enabled, run any selftests for this target.
-
-
- File: gccint.info, Node: Host Config, Next: Fragments, Prev: Target Macros, Up: Top
-
- 19 Host Configuration
- *********************
-
- Most details about the machine and system on which the compiler is
- actually running are detected by the 'configure' script. Some things
- are impossible for 'configure' to detect; these are described in two
- ways, either by macros defined in a file named 'xm-MACHINE.h' or by hook
- functions in the file specified by the OUT_HOST_HOOK_OBJ variable in
- 'config.gcc'. (The intention is that very few hosts will need a header
- file but nearly every fully supported host will need to override some
- hooks.)
-
- If you need to define only a few macros, and they have simple
- definitions, consider using the 'xm_defines' variable in your
- 'config.gcc' entry instead of creating a host configuration header.
- *Note System Config::.
-
- * Menu:
-
- * Host Common:: Things every host probably needs implemented.
- * Filesystem:: Your host cannot have the letter 'a' in filenames?
- * Host Misc:: Rare configuration options for hosts.
-
-
- File: gccint.info, Node: Host Common, Next: Filesystem, Up: Host Config
-
- 19.1 Host Common
- ================
-
- Some things are just not portable, even between similar operating
- systems, and are too difficult for autoconf to detect. They get
- implemented using hook functions in the file specified by the
- HOST_HOOK_OBJ variable in 'config.gcc'.
-
- -- Host Hook: void HOST_HOOKS_EXTRA_SIGNALS (void)
- This host hook is used to set up handling for extra signals. The
- most common thing to do in this hook is to detect stack overflow.
-
- -- Host Hook: void * HOST_HOOKS_GT_PCH_GET_ADDRESS (size_t SIZE, int
- FD)
- This host hook returns the address of some space that is likely to
- be free in some subsequent invocation of the compiler. We intend
- to load the PCH data at this address such that the data need not be
- relocated. The area should be able to hold SIZE bytes. If the
- host uses 'mmap', FD is an open file descriptor that can be used
- for probing.
-
- -- Host Hook: int HOST_HOOKS_GT_PCH_USE_ADDRESS (void * ADDRESS, size_t
- SIZE, int FD, size_t OFFSET)
- This host hook is called when a PCH file is about to be loaded. We
- want to load SIZE bytes from FD at OFFSET into memory at ADDRESS.
- The given address will be the result of a previous invocation of
- 'HOST_HOOKS_GT_PCH_GET_ADDRESS'. Return -1 if we couldn't allocate
- SIZE bytes at ADDRESS. Return 0 if the memory is allocated but the
- data is not loaded. Return 1 if the hook has performed everything.
-
- If the implementation uses reserved address space, free any
- reserved space beyond SIZE, regardless of the return value. If no
- PCH will be loaded, this hook may be called with SIZE zero, in
- which case all reserved address space should be freed.
-
- Do not try to handle values of ADDRESS that could not have been
- returned by this executable; just return -1. Such values usually
- indicate an out-of-date PCH file (built by some other GCC
- executable), and such a PCH file won't work.
-
- -- Host Hook: size_t HOST_HOOKS_GT_PCH_ALLOC_GRANULARITY (void);
- This host hook returns the alignment required for allocating
- virtual memory. Usually this is the same as getpagesize, but on
- some hosts the alignment for reserving memory differs from the
- pagesize for committing memory.
-
-
- File: gccint.info, Node: Filesystem, Next: Host Misc, Prev: Host Common, Up: Host Config
-
- 19.2 Host Filesystem
- ====================
-
- GCC needs to know a number of things about the semantics of the host
- machine's filesystem. Filesystems with Unix and MS-DOS semantics are
- automatically detected. For other systems, you can define the following
- macros in 'xm-MACHINE.h'.
-
- 'HAVE_DOS_BASED_FILE_SYSTEM'
- This macro is automatically defined by 'system.h' if the host file
- system obeys the semantics defined by MS-DOS instead of Unix. DOS
- file systems are case insensitive, file specifications may begin
- with a drive letter, and both forward slash and backslash ('/' and
- '\') are directory separators.
-
- 'DIR_SEPARATOR'
- 'DIR_SEPARATOR_2'
- If defined, these macros expand to character constants specifying
- separators for directory names within a file specification.
- 'system.h' will automatically give them appropriate values on Unix
- and MS-DOS file systems. If your file system is neither of these,
- define one or both appropriately in 'xm-MACHINE.h'.
-
- However, operating systems like VMS, where constructing a pathname
- is more complicated than just stringing together directory names
- separated by a special character, should not define either of these
- macros.
-
- 'PATH_SEPARATOR'
- If defined, this macro should expand to a character constant
- specifying the separator for elements of search paths. The default
- value is a colon (':'). DOS-based systems usually, but not always,
- use semicolon (';').
-
- 'VMS'
- Define this macro if the host system is VMS.
-
- 'HOST_OBJECT_SUFFIX'
- Define this macro to be a C string representing the suffix for
- object files on your host machine. If you do not define this
- macro, GCC will use '.o' as the suffix for object files.
-
- 'HOST_EXECUTABLE_SUFFIX'
- Define this macro to be a C string representing the suffix for
- executable files on your host machine. If you do not define this
- macro, GCC will use the null string as the suffix for executable
- files.
-
- 'HOST_BIT_BUCKET'
- A pathname defined by the host operating system, which can be
- opened as a file and written to, but all the information written is
- discarded. This is commonly known as a "bit bucket" or "null
- device". If you do not define this macro, GCC will use '/dev/null'
- as the bit bucket. If the host does not support a bit bucket,
- define this macro to an invalid filename.
-
- 'UPDATE_PATH_HOST_CANONICALIZE (PATH)'
- If defined, a C statement (sans semicolon) that performs
- host-dependent canonicalization when a path used in a compilation
- driver or preprocessor is canonicalized. PATH is a malloc-ed path
- to be canonicalized. If the C statement does canonicalize PATH
- into a different buffer, the old path should be freed and the new
- buffer should have been allocated with malloc.
-
- 'DUMPFILE_FORMAT'
- Define this macro to be a C string representing the format to use
- for constructing the index part of debugging dump file names. The
- resultant string must fit in fifteen bytes. The full filename will
- be the concatenation of: the prefix of the assembler file name, the
- string resulting from applying this format to an index number, and
- a string unique to each dump file kind, e.g. 'rtl'.
-
- If you do not define this macro, GCC will use '.%02d.'. You should
- define this macro if using the default will create an invalid file
- name.
-
- 'DELETE_IF_ORDINARY'
- Define this macro to be a C statement (sans semicolon) that
- performs host-dependent removal of ordinary temp files in the
- compilation driver.
-
- If you do not define this macro, GCC will use the default version.
- You should define this macro if the default version does not
- reliably remove the temp file as, for example, on VMS which allows
- multiple versions of a file.
-
- 'HOST_LACKS_INODE_NUMBERS'
- Define this macro if the host filesystem does not report meaningful
- inode numbers in struct stat.
-
-
- File: gccint.info, Node: Host Misc, Prev: Filesystem, Up: Host Config
-
- 19.3 Host Misc
- ==============
-
- 'FATAL_EXIT_CODE'
- A C expression for the status code to be returned when the compiler
- exits after serious errors. The default is the system-provided
- macro 'EXIT_FAILURE', or '1' if the system doesn't define that
- macro. Define this macro only if these defaults are incorrect.
-
- 'SUCCESS_EXIT_CODE'
- A C expression for the status code to be returned when the compiler
- exits without serious errors. (Warnings are not serious errors.)
- The default is the system-provided macro 'EXIT_SUCCESS', or '0' if
- the system doesn't define that macro. Define this macro only if
- these defaults are incorrect.
-
- 'USE_C_ALLOCA'
- Define this macro if GCC should use the C implementation of
- 'alloca' provided by 'libiberty.a'. This only affects how some
- parts of the compiler itself allocate memory. It does not change
- code generation.
-
- When GCC is built with a compiler other than itself, the C 'alloca'
- is always used. This is because most other implementations have
- serious bugs. You should define this macro only on a system where
- no stack-based 'alloca' can possibly work. For instance, if a
- system has a small limit on the size of the stack, GCC's builtin
- 'alloca' will not work reliably.
-
- 'COLLECT2_HOST_INITIALIZATION'
- If defined, a C statement (sans semicolon) that performs
- host-dependent initialization when 'collect2' is being initialized.
-
- 'GCC_DRIVER_HOST_INITIALIZATION'
- If defined, a C statement (sans semicolon) that performs
- host-dependent initialization when a compilation driver is being
- initialized.
-
- 'HOST_LONG_LONG_FORMAT'
- If defined, the string used to indicate an argument of type 'long
- long' to functions like 'printf'. The default value is '"ll"'.
-
- 'HOST_LONG_FORMAT'
- If defined, the string used to indicate an argument of type 'long'
- to functions like 'printf'. The default value is '"l"'.
-
- 'HOST_PTR_PRINTF'
- If defined, the string used to indicate an argument of type 'void
- *' to functions like 'printf'. The default value is '"%p"'.
-
- In addition, if 'configure' generates an incorrect definition of any of
- the macros in 'auto-host.h', you can override that definition in a host
- configuration header. If you need to do this, first see if it is
- possible to fix 'configure'.
-
-
- File: gccint.info, Node: Fragments, Next: Collect2, Prev: Host Config, Up: Top
-
- 20 Makefile Fragments
- *********************
-
- When you configure GCC using the 'configure' script, it will construct
- the file 'Makefile' from the template file 'Makefile.in'. When it does
- this, it can incorporate makefile fragments from the 'config' directory.
- These are used to set Makefile parameters that are not amenable to being
- calculated by autoconf. The list of fragments to incorporate is set by
- 'config.gcc' (and occasionally 'config.build' and 'config.host'); *Note
- System Config::.
-
- Fragments are named either 't-TARGET' or 'x-HOST', depending on whether
- they are relevant to configuring GCC to produce code for a particular
- target, or to configuring GCC to run on a particular host. Here TARGET
- and HOST are mnemonics which usually have some relationship to the
- canonical system name, but no formal connection.
-
- If these files do not exist, it means nothing needs to be added for a
- given target or host. Most targets need a few 't-TARGET' fragments, but
- needing 'x-HOST' fragments is rare.
-
- * Menu:
-
- * Target Fragment:: Writing 't-TARGET' files.
- * Host Fragment:: Writing 'x-HOST' files.
-
-
- File: gccint.info, Node: Target Fragment, Next: Host Fragment, Up: Fragments
-
- 20.1 Target Makefile Fragments
- ==============================
-
- Target makefile fragments can set these Makefile variables.
-
- 'LIBGCC2_CFLAGS'
- Compiler flags to use when compiling 'libgcc2.c'.
-
- 'LIB2FUNCS_EXTRA'
- A list of source file names to be compiled or assembled and
- inserted into 'libgcc.a'.
-
- 'CRTSTUFF_T_CFLAGS'
- Special flags used when compiling 'crtstuff.c'. *Note
- Initialization::.
-
- 'CRTSTUFF_T_CFLAGS_S'
- Special flags used when compiling 'crtstuff.c' for shared linking.
- Used if you use 'crtbeginS.o' and 'crtendS.o' in 'EXTRA-PARTS'.
- *Note Initialization::.
-
- 'MULTILIB_OPTIONS'
- For some targets, invoking GCC in different ways produces objects
- that cannot be linked together. For example, for some targets GCC
- produces both big and little endian code. For these targets, you
- must arrange for multiple versions of 'libgcc.a' to be compiled,
- one for each set of incompatible options. When GCC invokes the
- linker, it arranges to link in the right version of 'libgcc.a',
- based on the command line options used.
-
- The 'MULTILIB_OPTIONS' macro lists the set of options for which
- special versions of 'libgcc.a' must be built. Write options that
- are mutually incompatible side by side, separated by a slash.
- Write options that may be used together separated by a space. The
- build procedure will build all combinations of compatible options.
-
- For example, if you set 'MULTILIB_OPTIONS' to 'm68000/m68020
- msoft-float', 'Makefile' will build special versions of 'libgcc.a'
- using the following sets of options: '-m68000', '-m68020',
- '-msoft-float', '-m68000 -msoft-float', and '-m68020 -msoft-float'.
-
- 'MULTILIB_DIRNAMES'
- If 'MULTILIB_OPTIONS' is used, this variable specifies the
- directory names that should be used to hold the various libraries.
- Write one element in 'MULTILIB_DIRNAMES' for each element in
- 'MULTILIB_OPTIONS'. If 'MULTILIB_DIRNAMES' is not used, the
- default value will be 'MULTILIB_OPTIONS', with all slashes treated
- as spaces.
-
- 'MULTILIB_DIRNAMES' describes the multilib directories using GCC
- conventions and is applied to directories that are part of the GCC
- installation. When multilib-enabled, the compiler will add a
- subdirectory of the form PREFIX/MULTILIB before each directory in
- the search path for libraries and crt files.
-
- For example, if 'MULTILIB_OPTIONS' is set to 'm68000/m68020
- msoft-float', then the default value of 'MULTILIB_DIRNAMES' is
- 'm68000 m68020 msoft-float'. You may specify a different value if
- you desire a different set of directory names.
-
- 'MULTILIB_MATCHES'
- Sometimes the same option may be written in two different ways. If
- an option is listed in 'MULTILIB_OPTIONS', GCC needs to know about
- any synonyms. In that case, set 'MULTILIB_MATCHES' to a list of
- items of the form 'option=option' to describe all relevant
- synonyms. For example, 'm68000=mc68000 m68020=mc68020'.
-
- 'MULTILIB_EXCEPTIONS'
- Sometimes when there are multiple sets of 'MULTILIB_OPTIONS' being
- specified, there are combinations that should not be built. In
- that case, set 'MULTILIB_EXCEPTIONS' to be all of the switch
- exceptions in shell case syntax that should not be built.
-
- For example the ARM processor cannot execute both hardware floating
- point instructions and the reduced size THUMB instructions at the
- same time, so there is no need to build libraries with both of
- these options enabled. Therefore 'MULTILIB_EXCEPTIONS' is set to:
- *mthumb/*mhard-float*
-
- 'MULTILIB_REQUIRED'
- Sometimes when there are only a few combinations are required, it
- would be a big effort to come up with a 'MULTILIB_EXCEPTIONS' list
- to cover all undesired ones. In such a case, just listing all the
- required combinations in 'MULTILIB_REQUIRED' would be more
- straightforward.
-
- The way to specify the entries in 'MULTILIB_REQUIRED' is same with
- the way used for 'MULTILIB_EXCEPTIONS', only this time what are
- required will be specified. Suppose there are multiple sets of
- 'MULTILIB_OPTIONS' and only two combinations are required, one for
- ARMv7-M and one for ARMv7-R with hard floating-point ABI and FPU,
- the 'MULTILIB_REQUIRED' can be set to:
- MULTILIB_REQUIRED = mthumb/march=armv7-m
- MULTILIB_REQUIRED += march=armv7-r/mfloat-abi=hard/mfpu=vfpv3-d16
-
- The 'MULTILIB_REQUIRED' can be used together with
- 'MULTILIB_EXCEPTIONS'. The option combinations generated from
- 'MULTILIB_OPTIONS' will be filtered by 'MULTILIB_EXCEPTIONS' and
- then by 'MULTILIB_REQUIRED'.
-
- 'MULTILIB_REUSE'
- Sometimes it is desirable to reuse one existing multilib for
- different sets of options. Such kind of reuse can minimize the
- number of multilib variants. And for some targets it is better to
- reuse an existing multilib than to fall back to default multilib
- when there is no corresponding multilib. This can be done by
- adding reuse rules to 'MULTILIB_REUSE'.
-
- A reuse rule is comprised of two parts connected by equality sign.
- The left part is the option set used to build multilib and the
- right part is the option set that will reuse this multilib. Both
- parts should only use options specified in 'MULTILIB_OPTIONS' and
- the equality signs found in options name should be replaced with
- periods. An explicit period in the rule can be escaped by
- preceding it with a backslash. The order of options in the left
- part matters and should be same with those specified in
- 'MULTILIB_REQUIRED' or aligned with the order in
- 'MULTILIB_OPTIONS'. There is no such limitation for options in the
- right part as we don't build multilib from them.
-
- 'MULTILIB_REUSE' is different from 'MULTILIB_MATCHES' in that it
- sets up relations between two option sets rather than two options.
- Here is an example to demo how we reuse libraries built in Thumb
- mode for applications built in ARM mode:
- MULTILIB_REUSE = mthumb/march.armv7-r=marm/march.armv7-r
-
- Before the advent of 'MULTILIB_REUSE', GCC select multilib by
- comparing command line options with options used to build multilib.
- The 'MULTILIB_REUSE' is complementary to that way. Only when the
- original comparison matches nothing it will work to see if it is OK
- to reuse some existing multilib.
-
- 'MULTILIB_EXTRA_OPTS'
- Sometimes it is desirable that when building multiple versions of
- 'libgcc.a' certain options should always be passed on to the
- compiler. In that case, set 'MULTILIB_EXTRA_OPTS' to be the list
- of options to be used for all builds. If you set this, you should
- probably set 'CRTSTUFF_T_CFLAGS' to a dash followed by it.
-
- 'MULTILIB_OSDIRNAMES'
- If 'MULTILIB_OPTIONS' is used, this variable specifies a list of
- subdirectory names, that are used to modify the search path
- depending on the chosen multilib. Unlike 'MULTILIB_DIRNAMES',
- 'MULTILIB_OSDIRNAMES' describes the multilib directories using
- operating systems conventions, and is applied to the directories
- such as 'lib' or those in the 'LIBRARY_PATH' environment variable.
- The format is either the same as of 'MULTILIB_DIRNAMES', or a set
- of mappings. When it is the same as 'MULTILIB_DIRNAMES', it
- describes the multilib directories using operating system
- conventions, rather than GCC conventions. When it is a set of
- mappings of the form GCCDIR=OSDIR, the left side gives the GCC
- convention and the right gives the equivalent OS defined location.
- If the OSDIR part begins with a '!', GCC will not search in the
- non-multilib directory and use exclusively the multilib directory.
- Otherwise, the compiler will examine the search path for libraries
- and crt files twice; the first time it will add MULTILIB to each
- directory in the search path, the second it will not.
-
- For configurations that support both multilib and multiarch,
- 'MULTILIB_OSDIRNAMES' also encodes the multiarch name, thus
- subsuming 'MULTIARCH_DIRNAME'. The multiarch name is appended to
- each directory name, separated by a colon (e.g.
- '../lib32:i386-linux-gnu').
-
- Each multiarch subdirectory will be searched before the
- corresponding OS multilib directory, for example
- '/lib/i386-linux-gnu' before '/lib/../lib32'. The multiarch name
- will also be used to modify the system header search path, as
- explained for 'MULTIARCH_DIRNAME'.
-
- 'MULTIARCH_DIRNAME'
- This variable specifies the multiarch name for configurations that
- are multiarch-enabled but not multilibbed configurations.
-
- The multiarch name is used to augment the search path for
- libraries, crt files and system header files with additional
- locations. The compiler will add a multiarch subdirectory of the
- form PREFIX/MULTIARCH before each directory in the library and crt
- search path. It will also add two directories
- 'LOCAL_INCLUDE_DIR'/MULTIARCH and
- 'NATIVE_SYSTEM_HEADER_DIR'/MULTIARCH) to the system header search
- path, respectively before 'LOCAL_INCLUDE_DIR' and
- 'NATIVE_SYSTEM_HEADER_DIR'.
-
- 'MULTIARCH_DIRNAME' is not used for configurations that support
- both multilib and multiarch. In that case, multiarch names are
- encoded in 'MULTILIB_OSDIRNAMES' instead.
-
- More documentation about multiarch can be found at
- <https://wiki.debian.org/Multiarch>.
-
- 'SPECS'
- Unfortunately, setting 'MULTILIB_EXTRA_OPTS' is not enough, since
- it does not affect the build of target libraries, at least not the
- build of the default multilib. One possible work-around is to use
- 'DRIVER_SELF_SPECS' to bring options from the 'specs' file as if
- they had been passed in the compiler driver command line. However,
- you don't want to be adding these options after the toolchain is
- installed, so you can instead tweak the 'specs' file that will be
- used during the toolchain build, while you still install the
- original, built-in 'specs'. The trick is to set 'SPECS' to some
- other filename (say 'specs.install'), that will then be created out
- of the built-in specs, and introduce a 'Makefile' rule to generate
- the 'specs' file that's going to be used at build time out of your
- 'specs.install'.
-
- 'T_CFLAGS'
- These are extra flags to pass to the C compiler. They are used
- both when building GCC, and when compiling things with the
- just-built GCC. This variable is deprecated and should not be
- used.
-
-
- File: gccint.info, Node: Host Fragment, Prev: Target Fragment, Up: Fragments
-
- 20.2 Host Makefile Fragments
- ============================
-
- The use of 'x-HOST' fragments is discouraged. You should only use it
- for makefile dependencies.
-
-
- File: gccint.info, Node: Collect2, Next: Header Dirs, Prev: Fragments, Up: Top
-
- 21 'collect2'
- *************
-
- GCC uses a utility called 'collect2' on nearly all systems to arrange to
- call various initialization functions at start time.
-
- The program 'collect2' works by linking the program once and looking
- through the linker output file for symbols with particular names
- indicating they are constructor functions. If it finds any, it creates
- a new temporary '.c' file containing a table of them, compiles it, and
- links the program a second time including that file.
-
- The actual calls to the constructors are carried out by a subroutine
- called '__main', which is called (automatically) at the beginning of the
- body of 'main' (provided 'main' was compiled with GNU CC). Calling
- '__main' is necessary, even when compiling C code, to allow linking C
- and C++ object code together. (If you use '-nostdlib', you get an
- unresolved reference to '__main', since it's defined in the standard GCC
- library. Include '-lgcc' at the end of your compiler command line to
- resolve this reference.)
-
- The program 'collect2' is installed as 'ld' in the directory where the
- passes of the compiler are installed. When 'collect2' needs to find the
- _real_ 'ld', it tries the following file names:
-
- * a hard coded linker file name, if GCC was configured with the
- '--with-ld' option.
-
- * 'real-ld' in the directories listed in the compiler's search
- directories.
-
- * 'real-ld' in the directories listed in the environment variable
- 'PATH'.
-
- * The file specified in the 'REAL_LD_FILE_NAME' configuration macro,
- if specified.
-
- * 'ld' in the compiler's search directories, except that 'collect2'
- will not execute itself recursively.
-
- * 'ld' in 'PATH'.
-
- "The compiler's search directories" means all the directories where
- 'gcc' searches for passes of the compiler. This includes directories
- that you specify with '-B'.
-
- Cross-compilers search a little differently:
-
- * 'real-ld' in the compiler's search directories.
-
- * 'TARGET-real-ld' in 'PATH'.
-
- * The file specified in the 'REAL_LD_FILE_NAME' configuration macro,
- if specified.
-
- * 'ld' in the compiler's search directories.
-
- * 'TARGET-ld' in 'PATH'.
-
- 'collect2' explicitly avoids running 'ld' using the file name under
- which 'collect2' itself was invoked. In fact, it remembers up a list of
- such names--in case one copy of 'collect2' finds another copy (or
- version) of 'collect2' installed as 'ld' in a second place in the search
- path.
-
- 'collect2' searches for the utilities 'nm' and 'strip' using the same
- algorithm as above for 'ld'.
-
-
- File: gccint.info, Node: Header Dirs, Next: Type Information, Prev: Collect2, Up: Top
-
- 22 Standard Header File Directories
- ***********************************
-
- 'GCC_INCLUDE_DIR' means the same thing for native and cross. It is
- where GCC stores its private include files, and also where GCC stores
- the fixed include files. A cross compiled GCC runs 'fixincludes' on the
- header files in '$(tooldir)/include'. (If the cross compilation header
- files need to be fixed, they must be installed before GCC is built. If
- the cross compilation header files are already suitable for GCC, nothing
- special need be done).
-
- 'GPLUSPLUS_INCLUDE_DIR' means the same thing for native and cross. It
- is where 'g++' looks first for header files. The C++ library installs
- only target independent header files in that directory.
-
- 'LOCAL_INCLUDE_DIR' is used only by native compilers. GCC doesn't
- install anything there. It is normally '/usr/local/include'. This is
- where local additions to a packaged system should place header files.
-
- 'CROSS_INCLUDE_DIR' is used only by cross compilers. GCC doesn't
- install anything there.
-
- 'TOOL_INCLUDE_DIR' is used for both native and cross compilers. It is
- the place for other packages to install header files that GCC will use.
- For a cross-compiler, this is the equivalent of '/usr/include'. When
- you build a cross-compiler, 'fixincludes' processes any header files in
- this directory.
-
-
- File: gccint.info, Node: Type Information, Next: Plugins, Prev: Header Dirs, Up: Top
-
- 23 Memory Management and Type Information
- *****************************************
-
- GCC uses some fairly sophisticated memory management techniques, which
- involve determining information about GCC's data structures from GCC's
- source code and using this information to perform garbage collection and
- implement precompiled headers.
-
- A full C++ parser would be too complicated for this task, so a limited
- subset of C++ is interpreted and special markers are used to determine
- what parts of the source to look at. All 'struct', 'union' and
- 'template' structure declarations that define data structures that are
- allocated under control of the garbage collector must be marked. All
- global variables that hold pointers to garbage-collected memory must
- also be marked. Finally, all global variables that need to be saved and
- restored by a precompiled header must be marked. (The precompiled
- header mechanism can only save static variables if they're scalar.
- Complex data structures must be allocated in garbage-collected memory to
- be saved in a precompiled header.)
-
- The full format of a marker is
- GTY (([OPTION] [(PARAM)], [OPTION] [(PARAM)] ...))
- but in most cases no options are needed. The outer double parentheses
- are still necessary, though: 'GTY(())'. Markers can appear:
-
- * In a structure definition, before the open brace;
- * In a global variable declaration, after the keyword 'static' or
- 'extern'; and
- * In a structure field definition, before the name of the field.
-
- Here are some examples of marking simple data structures and globals.
-
- struct GTY(()) TAG
- {
- FIELDS...
- };
-
- typedef struct GTY(()) TAG
- {
- FIELDS...
- } *TYPENAME;
-
- static GTY(()) struct TAG *LIST; /* points to GC memory */
- static GTY(()) int COUNTER; /* save counter in a PCH */
-
- The parser understands simple typedefs such as 'typedef struct TAG
- *NAME;' and 'typedef int NAME;'. These don't need to be marked.
-
- Since 'gengtype''s understanding of C++ is limited, there are several
- constructs and declarations that are not supported inside
- classes/structures marked for automatic GC code generation. The
- following C++ constructs produce a 'gengtype' error on
- structures/classes marked for automatic GC code generation:
-
- * Type definitions inside classes/structures are not supported.
- * Enumerations inside classes/structures are not supported.
-
- If you have a class or structure using any of the above constructs, you
- need to mark that class as 'GTY ((user))' and provide your own marking
- routines (see section *note User GC:: for details).
-
- It is always valid to include function definitions inside classes.
- Those are always ignored by 'gengtype', as it only cares about data
- members.
-
- * Menu:
-
- * GTY Options:: What goes inside a 'GTY(())'.
- * Inheritance and GTY:: Adding GTY to a class hierarchy.
- * User GC:: Adding user-provided GC marking routines.
- * GGC Roots:: Making global variables GGC roots.
- * Files:: How the generated files work.
- * Invoking the garbage collector:: How to invoke the garbage collector.
- * Troubleshooting:: When something does not work as expected.
-
-
- File: gccint.info, Node: GTY Options, Next: Inheritance and GTY, Up: Type Information
-
- 23.1 The Inside of a 'GTY(())'
- ==============================
-
- Sometimes the C code is not enough to fully describe the type structure.
- Extra information can be provided with 'GTY' options and additional
- markers. Some options take a parameter, which may be either a string or
- a type name, depending on the parameter. If an option takes no
- parameter, it is acceptable either to omit the parameter entirely, or to
- provide an empty string as a parameter. For example, 'GTY ((skip))' and
- 'GTY ((skip ("")))' are equivalent.
-
- When the parameter is a string, often it is a fragment of C code. Four
- special escapes may be used in these strings, to refer to pieces of the
- data structure being marked:
-
- '%h'
- The current structure.
- '%1'
- The structure that immediately contains the current structure.
- '%0'
- The outermost structure that contains the current structure.
- '%a'
- A partial expression of the form '[i1][i2]...' that indexes the
- array item currently being marked.
-
- For instance, suppose that you have a structure of the form
- struct A {
- ...
- };
- struct B {
- struct A foo[12];
- };
- and 'b' is a variable of type 'struct B'. When marking 'b.foo[11]',
- '%h' would expand to 'b.foo[11]', '%0' and '%1' would both expand to
- 'b', and '%a' would expand to '[11]'.
-
- As in ordinary C, adjacent strings will be concatenated; this is
- helpful when you have a complicated expression.
- GTY ((chain_next ("TREE_CODE (&%h.generic) == INTEGER_TYPE"
- " ? TYPE_NEXT_VARIANT (&%h.generic)"
- " : TREE_CHAIN (&%h.generic)")))
-
- The available options are:
-
- 'length ("EXPRESSION")'
-
- There are two places the type machinery will need to be explicitly
- told the length of an array of non-atomic objects. The first case
- is when a structure ends in a variable-length array, like this:
- struct GTY(()) rtvec_def {
- int num_elem; /* number of elements */
- rtx GTY ((length ("%h.num_elem"))) elem[1];
- };
-
- In this case, the 'length' option is used to override the specified
- array length (which should usually be '1'). The parameter of the
- option is a fragment of C code that calculates the length.
-
- The second case is when a structure or a global variable contains a
- pointer to an array, like this:
- struct gimple_omp_for_iter * GTY((length ("%h.collapse"))) iter;
- In this case, 'iter' has been allocated by writing something like
- x->iter = ggc_alloc_cleared_vec_gimple_omp_for_iter (collapse);
- and the 'collapse' provides the length of the field.
-
- This second use of 'length' also works on global variables, like:
- static GTY((length("reg_known_value_size"))) rtx *reg_known_value;
-
- Note that the 'length' option is only meant for use with arrays of
- non-atomic objects, that is, objects that contain pointers pointing
- to other GTY-managed objects. For other GC-allocated arrays and
- strings you should use 'atomic'.
-
- 'skip'
-
- If 'skip' is applied to a field, the type machinery will ignore it.
- This is somewhat dangerous; the only safe use is in a union when
- one field really isn't ever used.
-
- 'for_user'
-
- Use this to mark types that need to be marked by user gc routines,
- but are not refered to in a template argument. So if you have some
- user gc type T1 and a non user gc type T2 you can give T2 the
- for_user option so that the marking functions for T1 can call non
- mangled functions to mark T2.
-
- 'desc ("EXPRESSION")'
- 'tag ("CONSTANT")'
- 'default'
-
- The type machinery needs to be told which field of a 'union' is
- currently active. This is done by giving each field a constant
- 'tag' value, and then specifying a discriminator using 'desc'. The
- value of the expression given by 'desc' is compared against each
- 'tag' value, each of which should be different. If no 'tag' is
- matched, the field marked with 'default' is used if there is one,
- otherwise no field in the union will be marked.
-
- In the 'desc' option, the "current structure" is the union that it
- discriminates. Use '%1' to mean the structure containing it.
- There are no escapes available to the 'tag' option, since it is a
- constant.
-
- For example,
- struct GTY(()) tree_binding
- {
- struct tree_common common;
- union tree_binding_u {
- tree GTY ((tag ("0"))) scope;
- struct cp_binding_level * GTY ((tag ("1"))) level;
- } GTY ((desc ("BINDING_HAS_LEVEL_P ((tree)&%0)"))) xscope;
- tree value;
- };
-
- In this example, the value of BINDING_HAS_LEVEL_P when applied to a
- 'struct tree_binding *' is presumed to be 0 or 1. If 1, the type
- mechanism will treat the field 'level' as being present and if 0,
- will treat the field 'scope' as being present.
-
- The 'desc' and 'tag' options can also be used for inheritance to
- denote which subclass an instance is. See *note Inheritance and
- GTY:: for more information.
-
- 'cache'
-
- When the 'cache' option is applied to a global variable
- gt_clear_cache is called on that variable between the mark and
- sweep phases of garbage collection. The gt_clear_cache function is
- free to mark blocks as used, or to clear pointers in the variable.
-
- 'deletable'
-
- 'deletable', when applied to a global variable, indicates that when
- garbage collection runs, there's no need to mark anything pointed
- to by this variable, it can just be set to 'NULL' instead. This is
- used to keep a list of free structures around for re-use.
-
- 'maybe_undef'
-
- When applied to a field, 'maybe_undef' indicates that it's OK if
- the structure that this fields points to is never defined, so long
- as this field is always 'NULL'. This is used to avoid requiring
- backends to define certain optional structures. It doesn't work
- with language frontends.
-
- 'nested_ptr (TYPE, "TO EXPRESSION", "FROM EXPRESSION")'
-
- The type machinery expects all pointers to point to the start of an
- object. Sometimes for abstraction purposes it's convenient to have
- a pointer which points inside an object. So long as it's possible
- to convert the original object to and from the pointer, such
- pointers can still be used. TYPE is the type of the original
- object, the TO EXPRESSION returns the pointer given the original
- object, and the FROM EXPRESSION returns the original object given
- the pointer. The pointer will be available using the '%h' escape.
-
- 'chain_next ("EXPRESSION")'
- 'chain_prev ("EXPRESSION")'
- 'chain_circular ("EXPRESSION")'
-
- It's helpful for the type machinery to know if objects are often
- chained together in long lists; this lets it generate code that
- uses less stack space by iterating along the list instead of
- recursing down it. 'chain_next' is an expression for the next item
- in the list, 'chain_prev' is an expression for the previous item.
- For singly linked lists, use only 'chain_next'; for doubly linked
- lists, use both. The machinery requires that taking the next item
- of the previous item gives the original item. 'chain_circular' is
- similar to 'chain_next', but can be used for circular single linked
- lists.
-
- 'reorder ("FUNCTION NAME")'
-
- Some data structures depend on the relative ordering of pointers.
- If the precompiled header machinery needs to change that ordering,
- it will call the function referenced by the 'reorder' option,
- before changing the pointers in the object that's pointed to by the
- field the option applies to. The function must take four
- arguments, with the signature
- 'void *, void *, gt_pointer_operator, void *'. The first parameter
- is a pointer to the structure that contains the object being
- updated, or the object itself if there is no containing structure.
- The second parameter is a cookie that should be ignored. The third
- parameter is a routine that, given a pointer, will update it to its
- correct new value. The fourth parameter is a cookie that must be
- passed to the second parameter.
-
- PCH cannot handle data structures that depend on the absolute
- values of pointers. 'reorder' functions can be expensive. When
- possible, it is better to depend on properties of the data, like an
- ID number or the hash of a string instead.
-
- 'atomic'
-
- The 'atomic' option can only be used with pointers. It informs the
- GC machinery that the memory that the pointer points to does not
- contain any pointers, and hence it should be treated by the GC and
- PCH machinery as an "atomic" block of memory that does not need to
- be examined when scanning memory for pointers. In particular, the
- machinery will not scan that memory for pointers to mark them as
- reachable (when marking pointers for GC) or to relocate them (when
- writing a PCH file).
-
- The 'atomic' option differs from the 'skip' option. 'atomic' keeps
- the memory under Garbage Collection, but makes the GC ignore the
- contents of the memory. 'skip' is more drastic in that it causes
- the pointer and the memory to be completely ignored by the Garbage
- Collector. So, memory marked as 'atomic' is automatically freed
- when no longer reachable, while memory marked as 'skip' is not.
-
- The 'atomic' option must be used with great care, because all sorts
- of problem can occur if used incorrectly, that is, if the memory
- the pointer points to does actually contain a pointer.
-
- Here is an example of how to use it:
- struct GTY(()) my_struct {
- int number_of_elements;
- unsigned int * GTY ((atomic)) elements;
- };
- In this case, 'elements' is a pointer under GC, and the memory it
- points to needs to be allocated using the Garbage Collector, and
- will be freed automatically by the Garbage Collector when it is no
- longer referenced. But the memory that the pointer points to is an
- array of 'unsigned int' elements, and the GC must not try to scan
- it to find pointers to mark or relocate, which is why it is marked
- with the 'atomic' option.
-
- Note that, currently, global variables cannot be marked with
- 'atomic'; only fields of a struct can. This is a known limitation.
- It would be useful to be able to mark global pointers with 'atomic'
- to make the PCH machinery aware of them so that they are saved and
- restored correctly to PCH files.
-
- 'special ("NAME")'
-
- The 'special' option is used to mark types that have to be dealt
- with by special case machinery. The parameter is the name of the
- special case. See 'gengtype.c' for further details. Avoid adding
- new special cases unless there is no other alternative.
-
- 'user'
-
- The 'user' option indicates that the code to mark structure fields
- is completely handled by user-provided routines. See section *note
- User GC:: for details on what functions need to be provided.
-
-
- File: gccint.info, Node: Inheritance and GTY, Next: User GC, Prev: GTY Options, Up: Type Information
-
- 23.2 Support for inheritance
- ============================
-
- gengtype has some support for simple class hierarchies. You can use
- this to have gengtype autogenerate marking routines, provided:
-
- * There must be a concrete base class, with a discriminator
- expression that can be used to identify which subclass an instance
- is.
- * Only single inheritance is used.
- * None of the classes within the hierarchy are templates.
-
- If your class hierarchy does not fit in this pattern, you must use
- *note User GC:: instead.
-
- The base class and its discriminator must be identified using the
- "desc" option. Each concrete subclass must use the "tag" option to
- identify which value of the discriminator it corresponds to.
-
- Every class in the hierarchy must have a 'GTY(())' marker, as gengtype
- will only attempt to parse classes that have such a marker (1).
-
- class GTY((desc("%h.kind"), tag("0"))) example_base
- {
- public:
- int kind;
- tree a;
- };
-
- class GTY((tag("1"))) some_subclass : public example_base
- {
- public:
- tree b;
- };
-
- class GTY((tag("2"))) some_other_subclass : public example_base
- {
- public:
- tree c;
- };
-
- The generated marking routines for the above will contain a "switch" on
- "kind", visiting all appropriate fields. For example, if kind is 2, it
- will cast to "some_other_subclass" and visit fields a, b, and c.
-
- ---------- Footnotes ----------
-
- (1) Classes lacking such a marker will not be identified as being
- part of the hierarchy, and so the marking routines will not handle them,
- leading to a assertion failure within the marking routines due to an
- unknown tag value (assuming that assertions are enabled).
-
-
- File: gccint.info, Node: User GC, Next: GGC Roots, Prev: Inheritance and GTY, Up: Type Information
-
- 23.3 Support for user-provided GC marking routines
- ==================================================
-
- The garbage collector supports types for which no automatic marking code
- is generated. For these types, the user is required to provide three
- functions: one to act as a marker for garbage collection, and two
- functions to act as marker and pointer walker for pre-compiled headers.
-
- Given a structure 'struct GTY((user)) my_struct', the following
- functions should be defined to mark 'my_struct':
-
- void gt_ggc_mx (my_struct *p)
- {
- /* This marks field 'fld'. */
- gt_ggc_mx (p->fld);
- }
-
- void gt_pch_nx (my_struct *p)
- {
- /* This marks field 'fld'. */
- gt_pch_nx (tp->fld);
- }
-
- void gt_pch_nx (my_struct *p, gt_pointer_operator op, void *cookie)
- {
- /* For every field 'fld', call the given pointer operator. */
- op (&(tp->fld), cookie);
- }
-
- In general, each marker 'M' should call 'M' for every pointer field in
- the structure. Fields that are not allocated in GC or are not pointers
- must be ignored.
-
- For embedded lists (e.g., structures with a 'next' or 'prev' pointer),
- the marker must follow the chain and mark every element in it.
-
- Note that the rules for the pointer walker 'gt_pch_nx (my_struct *,
- gt_pointer_operator, void *)' are slightly different. In this case, the
- operation 'op' must be applied to the _address_ of every pointer field.
-
- 23.3.1 User-provided marking routines for template types
- --------------------------------------------------------
-
- When a template type 'TP' is marked with 'GTY', all instances of that
- type are considered user-provided types. This means that the individual
- instances of 'TP' do not need to be marked with 'GTY'. The user needs
- to provide template functions to mark all the fields of the type.
-
- The following code snippets represent all the functions that need to be
- provided. Note that type 'TP' may reference to more than one type. In
- these snippets, there is only one type 'T', but there could be more.
-
- template<typename T>
- void gt_ggc_mx (TP<T> *tp)
- {
- extern void gt_ggc_mx (T&);
-
- /* This marks field 'fld' of type 'T'. */
- gt_ggc_mx (tp->fld);
- }
-
- template<typename T>
- void gt_pch_nx (TP<T> *tp)
- {
- extern void gt_pch_nx (T&);
-
- /* This marks field 'fld' of type 'T'. */
- gt_pch_nx (tp->fld);
- }
-
- template<typename T>
- void gt_pch_nx (TP<T *> *tp, gt_pointer_operator op, void *cookie)
- {
- /* For every field 'fld' of 'tp' with type 'T *', call the given
- pointer operator. */
- op (&(tp->fld), cookie);
- }
-
- template<typename T>
- void gt_pch_nx (TP<T> *tp, gt_pointer_operator, void *cookie)
- {
- extern void gt_pch_nx (T *, gt_pointer_operator, void *);
-
- /* For every field 'fld' of 'tp' with type 'T', call the pointer
- walker for all the fields of T. */
- gt_pch_nx (&(tp->fld), op, cookie);
- }
-
- Support for user-defined types is currently limited. The following
- restrictions apply:
-
- 1. Type 'TP' and all the argument types 'T' must be marked with 'GTY'.
-
- 2. Type 'TP' can only have type names in its argument list.
-
- 3. The pointer walker functions are different for 'TP<T>' and 'TP<T
- *>'. In the case of 'TP<T>', references to 'T' must be handled by
- calling 'gt_pch_nx' (which will, in turn, walk all the pointers
- inside fields of 'T'). In the case of 'TP<T *>', references to 'T
- *' must be handled by calling the 'op' function on the address of
- the pointer (see the code snippets above).
-
-
- File: gccint.info, Node: GGC Roots, Next: Files, Prev: User GC, Up: Type Information
-
- 23.4 Marking Roots for the Garbage Collector
- ============================================
-
- In addition to keeping track of types, the type machinery also locates
- the global variables ("roots") that the garbage collector starts at.
- Roots must be declared using one of the following syntaxes:
-
- * 'extern GTY(([OPTIONS])) TYPE NAME;'
- * 'static GTY(([OPTIONS])) TYPE NAME;'
- The syntax
- * 'GTY(([OPTIONS])) TYPE NAME;'
- is _not_ accepted. There should be an 'extern' declaration of such a
- variable in a header somewhere--mark that, not the definition. Or, if
- the variable is only used in one file, make it 'static'.
-
-
- File: gccint.info, Node: Files, Next: Invoking the garbage collector, Prev: GGC Roots, Up: Type Information
-
- 23.5 Source Files Containing Type Information
- =============================================
-
- Whenever you add 'GTY' markers to a source file that previously had
- none, or create a new source file containing 'GTY' markers, there are
- three things you need to do:
-
- 1. You need to add the file to the list of source files the type
- machinery scans. There are four cases:
-
- a. For a back-end file, this is usually done automatically; if
- not, you should add it to 'target_gtfiles' in the appropriate
- port's entries in 'config.gcc'.
-
- b. For files shared by all front ends, add the filename to the
- 'GTFILES' variable in 'Makefile.in'.
-
- c. For files that are part of one front end, add the filename to
- the 'gtfiles' variable defined in the appropriate
- 'config-lang.in'. Headers should appear before non-headers in
- this list.
-
- d. For files that are part of some but not all front ends, add
- the filename to the 'gtfiles' variable of _all_ the front ends
- that use it.
-
- 2. If the file was a header file, you'll need to check that it's
- included in the right place to be visible to the generated files.
- For a back-end header file, this should be done automatically. For
- a front-end header file, it needs to be included by the same file
- that includes 'gtype-LANG.h'. For other header files, it needs to
- be included in 'gtype-desc.c', which is a generated file, so add it
- to 'ifiles' in 'open_base_file' in 'gengtype.c'.
-
- For source files that aren't header files, the machinery will
- generate a header file that should be included in the source file
- you just changed. The file will be called 'gt-PATH.h' where PATH
- is the pathname relative to the 'gcc' directory with slashes
- replaced by -, so for example the header file to be included in
- 'cp/parser.c' is called 'gt-cp-parser.c'. The generated header
- file should be included after everything else in the source file.
- Don't forget to mention this file as a dependency in the
- 'Makefile'!
-
- For language frontends, there is another file that needs to be included
- somewhere. It will be called 'gtype-LANG.h', where LANG is the name of
- the subdirectory the language is contained in.
-
- Plugins can add additional root tables. Run the 'gengtype' utility in
- plugin mode as 'gengtype -P pluginout.h SOURCE-DIR FILE-LIST PLUGIN*.C'
- with your plugin files PLUGIN*.C using 'GTY' to generate the PLUGINOUT.H
- file. The GCC build tree is needed to be present in that mode.
-
-
- File: gccint.info, Node: Invoking the garbage collector, Next: Troubleshooting, Prev: Files, Up: Type Information
-
- 23.6 How to invoke the garbage collector
- ========================================
-
- The GCC garbage collector GGC is only invoked explicitly. In contrast
- with many other garbage collectors, it is not implicitly invoked by
- allocation routines when a lot of memory has been consumed. So the only
- way to have GGC reclaim storage is to call the 'ggc_collect' function
- explicitly. This call is an expensive operation, as it may have to scan
- the entire heap. Beware that local variables (on the GCC call stack)
- are not followed by such an invocation (as many other garbage collectors
- do): you should reference all your data from static or external 'GTY'-ed
- variables, and it is advised to call 'ggc_collect' with a shallow call
- stack. The GGC is an exact mark and sweep garbage collector (so it does
- not scan the call stack for pointers). In practice GCC passes don't
- often call 'ggc_collect' themselves, because it is called by the pass
- manager between passes.
-
- At the time of the 'ggc_collect' call all pointers in the GC-marked
- structures must be valid or 'NULL'. In practice this means that there
- should not be uninitialized pointer fields in the structures even if
- your code never reads or writes those fields at a particular instance.
- One way to ensure this is to use cleared versions of allocators unless
- all the fields are initialized manually immediately after allocation.
-
-
- File: gccint.info, Node: Troubleshooting, Prev: Invoking the garbage collector, Up: Type Information
-
- 23.7 Troubleshooting the garbage collector
- ==========================================
-
- With the current garbage collector implementation, most issues should
- show up as GCC compilation errors. Some of the most commonly
- encountered issues are described below.
-
- * Gengtype does not produce allocators for a 'GTY'-marked type.
- Gengtype checks if there is at least one possible path from GC
- roots to at least one instance of each type before outputting
- allocators. If there is no such path, the 'GTY' markers will be
- ignored and no allocators will be output. Solve this by making
- sure that there exists at least one such path. If creating it is
- unfeasible or raises a "code smell", consider if you really must
- use GC for allocating such type.
-
- * Link-time errors about undefined 'gt_ggc_r_foo_bar' and
- similarly-named symbols. Check if your 'foo_bar' source file has
- '#include "gt-foo_bar.h"' as its very last line.
-
-
- File: gccint.info, Node: Plugins, Next: LTO, Prev: Type Information, Up: Top
-
- 24 Plugins
- **********
-
- GCC plugins are loadable modules that provide extra features to the
- compiler. Like GCC itself they can be distributed in source and binary
- forms.
-
- GCC plugins provide developers with a rich subset of the GCC API to
- allow them to extend GCC as they see fit. Whether it is writing an
- additional optimization pass, transforming code, or analyzing
- information, plugins can be quite useful.
-
- * Menu:
-
- * Plugins loading:: How can we load plugins.
- * Plugin API:: The APIs for plugins.
- * Plugins pass:: How a plugin interact with the pass manager.
- * Plugins GC:: How a plugin Interact with GCC Garbage Collector.
- * Plugins description:: Giving information about a plugin itself.
- * Plugins attr:: Registering custom attributes or pragmas.
- * Plugins recording:: Recording information about pass execution.
- * Plugins gate:: Controlling which passes are being run.
- * Plugins tracking:: Keeping track of available passes.
- * Plugins building:: How can we build a plugin.
-
-
- File: gccint.info, Node: Plugins loading, Next: Plugin API, Up: Plugins
-
- 24.1 Loading Plugins
- ====================
-
- Plugins are supported on platforms that support '-ldl -rdynamic' as well
- as Windows/MinGW. They are loaded by the compiler using 'dlopen' or
- equivalent and invoked at pre-determined locations in the compilation
- process.
-
- Plugins are loaded with
-
- '-fplugin=/path/to/NAME.EXT' '-fplugin-arg-NAME-KEY1[=VALUE1]'
-
- Where NAME is the plugin name and EXT is the platform-specific dynamic
- library extension. It should be 'dll' on Windows/MinGW, 'dylib' on
- Darwin/Mac OS X, and 'so' on all other platforms. The plugin arguments
- are parsed by GCC and passed to respective plugins as key-value pairs.
- Multiple plugins can be invoked by specifying multiple '-fplugin'
- arguments.
-
- A plugin can be simply given by its short name (no dots or slashes).
- When simply passing '-fplugin=NAME', the plugin is loaded from the
- 'plugin' directory, so '-fplugin=NAME' is the same as '-fplugin=`gcc
- -print-file-name=plugin`/NAME.EXT', using backquote shell syntax to
- query the 'plugin' directory.
-
-
- File: gccint.info, Node: Plugin API, Next: Plugins pass, Prev: Plugins loading, Up: Plugins
-
- 24.2 Plugin API
- ===============
-
- Plugins are activated by the compiler at specific events as defined in
- 'gcc-plugin.h'. For each event of interest, the plugin should call
- 'register_callback' specifying the name of the event and address of the
- callback function that will handle that event.
-
- The header 'gcc-plugin.h' must be the first gcc header to be included.
-
- 24.2.1 Plugin license check
- ---------------------------
-
- Every plugin should define the global symbol 'plugin_is_GPL_compatible'
- to assert that it has been licensed under a GPL-compatible license. If
- this symbol does not exist, the compiler will emit a fatal error and
- exit with the error message:
-
- fatal error: plugin NAME is not licensed under a GPL-compatible license
- NAME: undefined symbol: plugin_is_GPL_compatible
- compilation terminated
-
- The declared type of the symbol should be int, to match a forward
- declaration in 'gcc-plugin.h' that suppresses C++ mangling. It does not
- need to be in any allocated section, though. The compiler merely
- asserts that the symbol exists in the global scope. Something like this
- is enough:
-
- int plugin_is_GPL_compatible;
-
- 24.2.2 Plugin initialization
- ----------------------------
-
- Every plugin should export a function called 'plugin_init' that is
- called right after the plugin is loaded. This function is responsible
- for registering all the callbacks required by the plugin and do any
- other required initialization.
-
- This function is called from 'compile_file' right before invoking the
- parser. The arguments to 'plugin_init' are:
-
- * 'plugin_info': Plugin invocation information.
- * 'version': GCC version.
-
- The 'plugin_info' struct is defined as follows:
-
- struct plugin_name_args
- {
- char *base_name; /* Short name of the plugin
- (filename without .so suffix). */
- const char *full_name; /* Path to the plugin as specified with
- -fplugin=. */
- int argc; /* Number of arguments specified with
- -fplugin-arg-.... */
- struct plugin_argument *argv; /* Array of ARGC key-value pairs. */
- const char *version; /* Version string provided by plugin. */
- const char *help; /* Help string provided by plugin. */
- }
-
- If initialization fails, 'plugin_init' must return a non-zero value.
- Otherwise, it should return 0.
-
- The version of the GCC compiler loading the plugin is described by the
- following structure:
-
- struct plugin_gcc_version
- {
- const char *basever;
- const char *datestamp;
- const char *devphase;
- const char *revision;
- const char *configuration_arguments;
- };
-
- The function 'plugin_default_version_check' takes two pointers to such
- structure and compare them field by field. It can be used by the
- plugin's 'plugin_init' function.
-
- The version of GCC used to compile the plugin can be found in the
- symbol 'gcc_version' defined in the header 'plugin-version.h'. The
- recommended version check to perform looks like
-
- #include "plugin-version.h"
- ...
-
- int
- plugin_init (struct plugin_name_args *plugin_info,
- struct plugin_gcc_version *version)
- {
- if (!plugin_default_version_check (version, &gcc_version))
- return 1;
-
- }
-
- but you can also check the individual fields if you want a less strict
- check.
-
- 24.2.3 Plugin callbacks
- -----------------------
-
- Callback functions have the following prototype:
-
- /* The prototype for a plugin callback function.
- gcc_data - event-specific data provided by GCC
- user_data - plugin-specific data provided by the plug-in. */
- typedef void (*plugin_callback_func)(void *gcc_data, void *user_data);
-
- Callbacks can be invoked at the following pre-determined events:
-
- enum plugin_event
- {
- PLUGIN_START_PARSE_FUNCTION, /* Called before parsing the body of a function. */
- PLUGIN_FINISH_PARSE_FUNCTION, /* After finishing parsing a function. */
- PLUGIN_PASS_MANAGER_SETUP, /* To hook into pass manager. */
- PLUGIN_FINISH_TYPE, /* After finishing parsing a type. */
- PLUGIN_FINISH_DECL, /* After finishing parsing a declaration. */
- PLUGIN_FINISH_UNIT, /* Useful for summary processing. */
- PLUGIN_PRE_GENERICIZE, /* Allows to see low level AST in C and C++ frontends. */
- PLUGIN_FINISH, /* Called before GCC exits. */
- PLUGIN_INFO, /* Information about the plugin. */
- PLUGIN_GGC_START, /* Called at start of GCC Garbage Collection. */
- PLUGIN_GGC_MARKING, /* Extend the GGC marking. */
- PLUGIN_GGC_END, /* Called at end of GGC. */
- PLUGIN_REGISTER_GGC_ROOTS, /* Register an extra GGC root table. */
- PLUGIN_ATTRIBUTES, /* Called during attribute registration */
- PLUGIN_START_UNIT, /* Called before processing a translation unit. */
- PLUGIN_PRAGMAS, /* Called during pragma registration. */
- /* Called before first pass from all_passes. */
- PLUGIN_ALL_PASSES_START,
- /* Called after last pass from all_passes. */
- PLUGIN_ALL_PASSES_END,
- /* Called before first ipa pass. */
- PLUGIN_ALL_IPA_PASSES_START,
- /* Called after last ipa pass. */
- PLUGIN_ALL_IPA_PASSES_END,
- /* Allows to override pass gate decision for current_pass. */
- PLUGIN_OVERRIDE_GATE,
- /* Called before executing a pass. */
- PLUGIN_PASS_EXECUTION,
- /* Called before executing subpasses of a GIMPLE_PASS in
- execute_ipa_pass_list. */
- PLUGIN_EARLY_GIMPLE_PASSES_START,
- /* Called after executing subpasses of a GIMPLE_PASS in
- execute_ipa_pass_list. */
- PLUGIN_EARLY_GIMPLE_PASSES_END,
- /* Called when a pass is first instantiated. */
- PLUGIN_NEW_PASS,
- /* Called when a file is #include-d or given via the #line directive.
- This could happen many times. The event data is the included file path,
- as a const char* pointer. */
- PLUGIN_INCLUDE_FILE,
-
- PLUGIN_EVENT_FIRST_DYNAMIC /* Dummy event used for indexing callback
- array. */
- };
-
- In addition, plugins can also look up the enumerator of a named event,
- and / or generate new events dynamically, by calling the function
- 'get_named_event_id'.
-
- To register a callback, the plugin calls 'register_callback' with the
- arguments:
-
- * 'char *name': Plugin name.
- * 'int event': The event code.
- * 'plugin_callback_func callback': The function that handles 'event'.
- * 'void *user_data': Pointer to plugin-specific data.
-
- For the PLUGIN_PASS_MANAGER_SETUP, PLUGIN_INFO, and
- PLUGIN_REGISTER_GGC_ROOTS pseudo-events the 'callback' should be null,
- and the 'user_data' is specific.
-
- When the PLUGIN_PRAGMAS event is triggered (with a null pointer as data
- from GCC), plugins may register their own pragmas. Notice that pragmas
- are not available from 'lto1', so plugins used with '-flto' option to
- GCC during link-time optimization cannot use pragmas and do not even see
- functions like 'c_register_pragma' or 'pragma_lex'.
-
- The PLUGIN_INCLUDE_FILE event, with a 'const char*' file path as GCC
- data, is triggered for processing of '#include' or '#line' directives.
-
- The PLUGIN_FINISH event is the last time that plugins can call GCC
- functions, notably emit diagnostics with 'warning', 'error' etc.
-
-
- File: gccint.info, Node: Plugins pass, Next: Plugins GC, Prev: Plugin API, Up: Plugins
-
- 24.3 Interacting with the pass manager
- ======================================
-
- There needs to be a way to add/reorder/remove passes dynamically. This
- is useful for both analysis plugins (plugging in after a certain pass
- such as CFG or an IPA pass) and optimization plugins.
-
- Basic support for inserting new passes or replacing existing passes is
- provided. A plugin registers a new pass with GCC by calling
- 'register_callback' with the 'PLUGIN_PASS_MANAGER_SETUP' event and a
- pointer to a 'struct register_pass_info' object defined as follows
-
- enum pass_positioning_ops
- {
- PASS_POS_INSERT_AFTER, // Insert after the reference pass.
- PASS_POS_INSERT_BEFORE, // Insert before the reference pass.
- PASS_POS_REPLACE // Replace the reference pass.
- };
-
- struct register_pass_info
- {
- struct opt_pass *pass; /* New pass provided by the plugin. */
- const char *reference_pass_name; /* Name of the reference pass for hooking
- up the new pass. */
- int ref_pass_instance_number; /* Insert the pass at the specified
- instance number of the reference pass. */
- /* Do it for every instance if it is 0. */
- enum pass_positioning_ops pos_op; /* how to insert the new pass. */
- };
-
-
- /* Sample plugin code that registers a new pass. */
- int
- plugin_init (struct plugin_name_args *plugin_info,
- struct plugin_gcc_version *version)
- {
- struct register_pass_info pass_info;
-
- ...
-
- /* Code to fill in the pass_info object with new pass information. */
-
- ...
-
- /* Register the new pass. */
- register_callback (plugin_info->base_name, PLUGIN_PASS_MANAGER_SETUP, NULL, &pass_info);
-
- ...
- }
-
-
- File: gccint.info, Node: Plugins GC, Next: Plugins description, Prev: Plugins pass, Up: Plugins
-
- 24.4 Interacting with the GCC Garbage Collector
- ===============================================
-
- Some plugins may want to be informed when GGC (the GCC Garbage
- Collector) is running. They can register callbacks for the
- 'PLUGIN_GGC_START' and 'PLUGIN_GGC_END' events (for which the callback
- is called with a null 'gcc_data') to be notified of the start or end of
- the GCC garbage collection.
-
- Some plugins may need to have GGC mark additional data. This can be
- done by registering a callback (called with a null 'gcc_data') for the
- 'PLUGIN_GGC_MARKING' event. Such callbacks can call the 'ggc_set_mark'
- routine, preferably through the 'ggc_mark' macro (and conversely, these
- routines should usually not be used in plugins outside of the
- 'PLUGIN_GGC_MARKING' event). Plugins that wish to hold weak references
- to gc data may also use this event to drop weak references when the
- object is about to be collected. The 'ggc_marked_p' function can be
- used to tell if an object is marked, or is about to be collected. The
- 'gt_clear_cache' overloads which some types define may also be of use in
- managing weak references.
-
- Some plugins may need to add extra GGC root tables, e.g. to handle
- their own 'GTY'-ed data. This can be done with the
- 'PLUGIN_REGISTER_GGC_ROOTS' pseudo-event with a null callback and the
- extra root table (of type 'struct ggc_root_tab*') as 'user_data'.
- Running the 'gengtype -p SOURCE-DIR FILE-LIST PLUGIN*.C ...' utility
- generates these extra root tables.
-
- You should understand the details of memory management inside GCC
- before using 'PLUGIN_GGC_MARKING' or 'PLUGIN_REGISTER_GGC_ROOTS'.
-
-
- File: gccint.info, Node: Plugins description, Next: Plugins attr, Prev: Plugins GC, Up: Plugins
-
- 24.5 Giving information about a plugin
- ======================================
-
- A plugin should give some information to the user about itself. This
- uses the following structure:
-
- struct plugin_info
- {
- const char *version;
- const char *help;
- };
-
- Such a structure is passed as the 'user_data' by the plugin's init
- routine using 'register_callback' with the 'PLUGIN_INFO' pseudo-event
- and a null callback.
-
-
- File: gccint.info, Node: Plugins attr, Next: Plugins recording, Prev: Plugins description, Up: Plugins
-
- 24.6 Registering custom attributes or pragmas
- =============================================
-
- For analysis (or other) purposes it is useful to be able to add custom
- attributes or pragmas.
-
- The 'PLUGIN_ATTRIBUTES' callback is called during attribute
- registration. Use the 'register_attribute' function to register custom
- attributes.
-
- /* Attribute handler callback */
- static tree
- handle_user_attribute (tree *node, tree name, tree args,
- int flags, bool *no_add_attrs)
- {
- return NULL_TREE;
- }
-
- /* Attribute definition */
- static struct attribute_spec user_attr =
- { "user", 1, 1, false, false, false, false, handle_user_attribute, NULL };
-
- /* Plugin callback called during attribute registration.
- Registered with register_callback (plugin_name, PLUGIN_ATTRIBUTES, register_attributes, NULL)
- */
- static void
- register_attributes (void *event_data, void *data)
- {
- warning (0, G_("Callback to register attributes"));
- register_attribute (&user_attr);
- }
-
-
- The PLUGIN_PRAGMAS callback is called once during pragmas registration.
- Use the 'c_register_pragma', 'c_register_pragma_with_data',
- 'c_register_pragma_with_expansion',
- 'c_register_pragma_with_expansion_and_data' functions to register custom
- pragmas and their handlers (which often want to call 'pragma_lex') from
- 'c-family/c-pragma.h'.
-
- /* Plugin callback called during pragmas registration. Registered with
- register_callback (plugin_name, PLUGIN_PRAGMAS,
- register_my_pragma, NULL);
- */
- static void
- register_my_pragma (void *event_data, void *data)
- {
- warning (0, G_("Callback to register pragmas"));
- c_register_pragma ("GCCPLUGIN", "sayhello", handle_pragma_sayhello);
- }
-
- It is suggested to pass '"GCCPLUGIN"' (or a short name identifying your
- plugin) as the "space" argument of your pragma.
-
- Pragmas registered with 'c_register_pragma_with_expansion' or
- 'c_register_pragma_with_expansion_and_data' support preprocessor
- expansions. For example:
-
- #define NUMBER 10
- #pragma GCCPLUGIN foothreshold (NUMBER)
-
-
- File: gccint.info, Node: Plugins recording, Next: Plugins gate, Prev: Plugins attr, Up: Plugins
-
- 24.7 Recording information about pass execution
- ===============================================
-
- The event PLUGIN_PASS_EXECUTION passes the pointer to the executed pass
- (the same as current_pass) as 'gcc_data' to the callback. You can also
- inspect cfun to find out about which function this pass is executed for.
- Note that this event will only be invoked if the gate check (if
- applicable, modified by PLUGIN_OVERRIDE_GATE) succeeds. You can use
- other hooks, like 'PLUGIN_ALL_PASSES_START', 'PLUGIN_ALL_PASSES_END',
- 'PLUGIN_ALL_IPA_PASSES_START', 'PLUGIN_ALL_IPA_PASSES_END',
- 'PLUGIN_EARLY_GIMPLE_PASSES_START', and/or
- 'PLUGIN_EARLY_GIMPLE_PASSES_END' to manipulate global state in your
- plugin(s) in order to get context for the pass execution.
-
-
- File: gccint.info, Node: Plugins gate, Next: Plugins tracking, Prev: Plugins recording, Up: Plugins
-
- 24.8 Controlling which passes are being run
- ===========================================
-
- After the original gate function for a pass is called, its result - the
- gate status - is stored as an integer. Then the event
- 'PLUGIN_OVERRIDE_GATE' is invoked, with a pointer to the gate status in
- the 'gcc_data' parameter to the callback function. A nonzero value of
- the gate status means that the pass is to be executed. You can both
- read and write the gate status via the passed pointer.
-
-
- File: gccint.info, Node: Plugins tracking, Next: Plugins building, Prev: Plugins gate, Up: Plugins
-
- 24.9 Keeping track of available passes
- ======================================
-
- When your plugin is loaded, you can inspect the various pass lists to
- determine what passes are available. However, other plugins might add
- new passes. Also, future changes to GCC might cause generic passes to
- be added after plugin loading. When a pass is first added to one of the
- pass lists, the event 'PLUGIN_NEW_PASS' is invoked, with the callback
- parameter 'gcc_data' pointing to the new pass.
-
-
- File: gccint.info, Node: Plugins building, Prev: Plugins tracking, Up: Plugins
-
- 24.10 Building GCC plugins
- ==========================
-
- If plugins are enabled, GCC installs the headers needed to build a
- plugin (somewhere in the installation tree, e.g. under '/usr/local').
- In particular a 'plugin/include' directory is installed, containing all
- the header files needed to build plugins.
-
- On most systems, you can query this 'plugin' directory by invoking 'gcc
- -print-file-name=plugin' (replace if needed 'gcc' with the appropriate
- program path).
-
- Inside plugins, this 'plugin' directory name can be queried by calling
- 'default_plugin_dir_name ()'.
-
- Plugins may know, when they are compiled, the GCC version for which
- 'plugin-version.h' is provided. The constant macros
- 'GCCPLUGIN_VERSION_MAJOR', 'GCCPLUGIN_VERSION_MINOR',
- 'GCCPLUGIN_VERSION_PATCHLEVEL', 'GCCPLUGIN_VERSION' are integer numbers,
- so a plugin could ensure it is built for GCC 4.7 with
- #if GCCPLUGIN_VERSION != 4007
- #error this GCC plugin is for GCC 4.7
- #endif
-
- The following GNU Makefile excerpt shows how to build a simple plugin:
-
- HOST_GCC=g++
- TARGET_GCC=gcc
- PLUGIN_SOURCE_FILES= plugin1.c plugin2.cc
- GCCPLUGINS_DIR:= $(shell $(TARGET_GCC) -print-file-name=plugin)
- CXXFLAGS+= -I$(GCCPLUGINS_DIR)/include -fPIC -fno-rtti -O2
-
- plugin.so: $(PLUGIN_SOURCE_FILES)
- $(HOST_GCC) -shared $(CXXFLAGS) $^ -o $@
-
- A single source file plugin may be built with 'g++ -I`gcc
- -print-file-name=plugin`/include -fPIC -shared -fno-rtti -O2 plugin.c -o
- plugin.so', using backquote shell syntax to query the 'plugin'
- directory.
-
- Plugin support on Windows/MinGW has a number of limitations and
- additional requirements. When building a plugin on Windows we have to
- link an import library for the corresponding backend executable, for
- example, 'cc1.exe', 'cc1plus.exe', etc., in order to gain access to the
- symbols provided by GCC. This means that on Windows a plugin is
- language-specific, for example, for C, C++, etc. If you wish to use
- your plugin with multiple languages, then you will need to build
- multiple plugin libraries and either instruct your users on how to load
- the correct version or provide a compiler wrapper that does this
- automatically.
-
- Additionally, on Windows the plugin library has to export the
- 'plugin_is_GPL_compatible' and 'plugin_init' symbols. If you do not
- wish to modify the source code of your plugin, then you can use the
- '-Wl,--export-all-symbols' option or provide a suitable DEF file.
- Alternatively, you can export just these two symbols by decorating them
- with '__declspec(dllexport)', for example:
-
- #ifdef _WIN32
- __declspec(dllexport)
- #endif
- int plugin_is_GPL_compatible;
-
- #ifdef _WIN32
- __declspec(dllexport)
- #endif
- int plugin_init (plugin_name_args *, plugin_gcc_version *)
-
- The import libraries are installed into the 'plugin' directory and
- their names are derived by appending the '.a' extension to the backend
- executable names, for example, 'cc1.exe.a', 'cc1plus.exe.a', etc. The
- following command line shows how to build the single source file plugin
- on Windows to be used with the C++ compiler:
-
- g++ -I`gcc -print-file-name=plugin`/include -shared -Wl,--export-all-symbols \
- -o plugin.dll plugin.c `gcc -print-file-name=plugin`/cc1plus.exe.a
-
- When a plugin needs to use 'gengtype', be sure that both 'gengtype' and
- 'gtype.state' have the same version as the GCC for which the plugin is
- built.
-
-
- File: gccint.info, Node: LTO, Next: Match and Simplify, Prev: Plugins, Up: Top
-
- 25 Link Time Optimization
- *************************
-
- Link Time Optimization (LTO) gives GCC the capability of dumping its
- internal representation (GIMPLE) to disk, so that all the different
- compilation units that make up a single executable can be optimized as a
- single module. This expands the scope of inter-procedural optimizations
- to encompass the whole program (or, rather, everything that is visible
- at link time).
-
- * Menu:
-
- * LTO Overview:: Overview of LTO.
- * LTO object file layout:: LTO file sections in ELF.
- * IPA:: Using summary information in IPA passes.
- * WHOPR:: Whole program assumptions,
- linker plugin and symbol visibilities.
- * Internal flags:: Internal flags controlling 'lto1'.
-
-
- File: gccint.info, Node: LTO Overview, Next: LTO object file layout, Up: LTO
-
- 25.1 Design Overview
- ====================
-
- Link time optimization is implemented as a GCC front end for a bytecode
- representation of GIMPLE that is emitted in special sections of '.o'
- files. Currently, LTO support is enabled in most ELF-based systems, as
- well as darwin, cygwin and mingw systems.
-
- Since GIMPLE bytecode is saved alongside final object code, object
- files generated with LTO support are larger than regular object files.
- This "fat" object format makes it easy to integrate LTO into existing
- build systems, as one can, for instance, produce archives of the files.
- Additionally, one might be able to ship one set of fat objects which
- could be used both for development and the production of optimized
- builds. A, perhaps surprising, side effect of this feature is that any
- mistake in the toolchain leads to LTO information not being used (e.g.
- an older 'libtool' calling 'ld' directly). This is both an advantage,
- as the system is more robust, and a disadvantage, as the user is not
- informed that the optimization has been disabled.
-
- The current implementation only produces "fat" objects, effectively
- doubling compilation time and increasing file sizes up to 5x the
- original size. This hides the problem that some tools, such as 'ar' and
- 'nm', need to understand symbol tables of LTO sections. These tools
- were extended to use the plugin infrastructure, and with these problems
- solved, GCC will also support "slim" objects consisting of the
- intermediate code alone.
-
- At the highest level, LTO splits the compiler in two. The first half
- (the "writer") produces a streaming representation of all the internal
- data structures needed to optimize and generate code. This includes
- declarations, types, the callgraph and the GIMPLE representation of
- function bodies.
-
- When '-flto' is given during compilation of a source file, the pass
- manager executes all the passes in 'all_lto_gen_passes'. Currently,
- this phase is composed of two IPA passes:
-
- * 'pass_ipa_lto_gimple_out' This pass executes the function
- 'lto_output' in 'lto-streamer-out.c', which traverses the call
- graph encoding every reachable declaration, type and function.
- This generates a memory representation of all the file sections
- described below.
-
- * 'pass_ipa_lto_finish_out' This pass executes the function
- 'produce_asm_for_decls' in 'lto-streamer-out.c', which takes the
- memory image built in the previous pass and encodes it in the
- corresponding ELF file sections.
-
- The second half of LTO support is the "reader". This is implemented as
- the GCC front end 'lto1' in 'lto/lto.c'. When 'collect2' detects a link
- set of '.o'/'.a' files with LTO information and the '-flto' is enabled,
- it invokes 'lto1' which reads the set of files and aggregates them into
- a single translation unit for optimization. The main entry point for
- the reader is 'lto/lto.c':'lto_main'.
-
- 25.1.1 LTO modes of operation
- -----------------------------
-
- One of the main goals of the GCC link-time infrastructure was to allow
- effective compilation of large programs. For this reason GCC implements
- two link-time compilation modes.
-
- 1. _LTO mode_, in which the whole program is read into the compiler at
- link-time and optimized in a similar way as if it were a single
- source-level compilation unit.
-
- 2. _WHOPR or partitioned mode_, designed to utilize multiple CPUs
- and/or a distributed compilation environment to quickly link large
- applications. WHOPR stands for WHOle Program optimizeR (not to be
- confused with the semantics of '-fwhole-program'). It partitions
- the aggregated callgraph from many different '.o' files and
- distributes the compilation of the sub-graphs to different CPUs.
-
- Note that distributed compilation is not implemented yet, but since
- the parallelism is facilitated via generating a 'Makefile', it
- would be easy to implement.
-
- WHOPR splits LTO into three main stages:
- 1. Local generation (LGEN) This stage executes in parallel. Every
- file in the program is compiled into the intermediate language and
- packaged together with the local call-graph and summary
- information. This stage is the same for both the LTO and WHOPR
- compilation mode.
-
- 2. Whole Program Analysis (WPA) WPA is performed sequentially. The
- global call-graph is generated, and a global analysis procedure
- makes transformation decisions. The global call-graph is
- partitioned to facilitate parallel optimization during phase 3.
- The results of the WPA stage are stored into new object files which
- contain the partitions of program expressed in the intermediate
- language and the optimization decisions.
-
- 3. Local transformations (LTRANS) This stage executes in parallel.
- All the decisions made during phase 2 are implemented locally in
- each partitioned object file, and the final object code is
- generated. Optimizations which cannot be decided efficiently
- during the phase 2 may be performed on the local call-graph
- partitions.
-
- WHOPR can be seen as an extension of the usual LTO mode of compilation.
- In LTO, WPA and LTRANS are executed within a single execution of the
- compiler, after the whole program has been read into memory.
-
- When compiling in WHOPR mode, the callgraph is partitioned during the
- WPA stage. The whole program is split into a given number of partitions
- of roughly the same size. The compiler tries to minimize the number of
- references which cross partition boundaries. The main advantage of
- WHOPR is to allow the parallel execution of LTRANS stages, which are the
- most time-consuming part of the compilation process. Additionally, it
- avoids the need to load the whole program into memory.
-
-
- File: gccint.info, Node: LTO object file layout, Next: IPA, Prev: LTO Overview, Up: LTO
-
- 25.2 LTO file sections
- ======================
-
- LTO information is stored in several ELF sections inside object files.
- Data structures and enum codes for sections are defined in
- 'lto-streamer.h'.
-
- These sections are emitted from 'lto-streamer-out.c' and mapped in all
- at once from 'lto/lto.c':'lto_file_read'. The individual functions
- dealing with the reading/writing of each section are described below.
-
- * Command line options ('.gnu.lto_.opts')
-
- This section contains the command line options used to generate the
- object files. This is used at link time to determine the
- optimization level and other settings when they are not explicitly
- specified at the linker command line.
-
- Currently, GCC does not support combining LTO object files compiled
- with different set of the command line options into a single
- binary. At link time, the options given on the command line and
- the options saved on all the files in a link-time set are applied
- globally. No attempt is made at validating the combination of
- flags (other than the usual validation done by option processing).
- This is implemented in 'lto/lto.c':'lto_read_all_file_options'.
-
- * Symbol table ('.gnu.lto_.symtab')
-
- This table replaces the ELF symbol table for functions and
- variables represented in the LTO IL. Symbols used and exported by
- the optimized assembly code of "fat" objects might not match the
- ones used and exported by the intermediate code. This table is
- necessary because the intermediate code is less optimized and thus
- requires a separate symbol table.
-
- Additionally, the binary code in the "fat" object will lack a call
- to a function, since the call was optimized out at compilation time
- after the intermediate language was streamed out. In some special
- cases, the same optimization may not happen during link-time
- optimization. This would lead to an undefined symbol if only one
- symbol table was used.
-
- The symbol table is emitted in
- 'lto-streamer-out.c':'produce_symtab'.
-
- * Global declarations and types ('.gnu.lto_.decls')
-
- This section contains an intermediate language dump of all
- declarations and types required to represent the callgraph, static
- variables and top-level debug info.
-
- The contents of this section are emitted in
- 'lto-streamer-out.c':'produce_asm_for_decls'. Types and symbols
- are emitted in a topological order that preserves the sharing of
- pointers when the file is read back in
- ('lto.c':'read_cgraph_and_symbols').
-
- * The callgraph ('.gnu.lto_.cgraph')
-
- This section contains the basic data structure used by the GCC
- inter-procedural optimization infrastructure. This section stores
- an annotated multi-graph which represents the functions and call
- sites as well as the variables, aliases and top-level 'asm'
- statements.
-
- This section is emitted in 'lto-streamer-out.c':'output_cgraph' and
- read in 'lto-cgraph.c':'input_cgraph'.
-
- * IPA references ('.gnu.lto_.refs')
-
- This section contains references between function and static
- variables. It is emitted by 'lto-cgraph.c':'output_refs' and read
- by 'lto-cgraph.c':'input_refs'.
-
- * Function bodies ('.gnu.lto_.function_body.<name>')
-
- This section contains function bodies in the intermediate language
- representation. Every function body is in a separate section to
- allow copying of the section independently to different object
- files or reading the function on demand.
-
- Functions are emitted in 'lto-streamer-out.c':'output_function' and
- read in 'lto-streamer-in.c':'input_function'.
-
- * Static variable initializers ('.gnu.lto_.vars')
-
- This section contains all the symbols in the global variable pool.
- It is emitted by 'lto-cgraph.c':'output_varpool' and read in
- 'lto-cgraph.c':'input_cgraph'.
-
- * Summaries and optimization summaries used by IPA passes
- ('.gnu.lto_.<xxx>', where '<xxx>' is one of 'jmpfuncs', 'pureconst'
- or 'reference')
-
- These sections are used by IPA passes that need to emit summary
- information during LTO generation to be read and aggregated at link
- time. Each pass is responsible for implementing two pass manager
- hooks: one for writing the summary and another for reading it in.
- The format of these sections is entirely up to each individual
- pass. The only requirement is that the writer and reader hooks
- agree on the format.
-
-
- File: gccint.info, Node: IPA, Next: WHOPR, Prev: LTO object file layout, Up: LTO
-
- 25.3 Using summary information in IPA passes
- ============================================
-
- Programs are represented internally as a _callgraph_ (a multi-graph
- where nodes are functions and edges are call sites) and a _varpool_ (a
- list of static and external variables in the program).
-
- The inter-procedural optimization is organized as a sequence of
- individual passes, which operate on the callgraph and the varpool. To
- make the implementation of WHOPR possible, every inter-procedural
- optimization pass is split into several stages that are executed at
- different times during WHOPR compilation:
-
- * LGEN time
- 1. _Generate summary_ ('generate_summary' in 'struct
- ipa_opt_pass_d'). This stage analyzes every function body and
- variable initializer is examined and stores relevant
- information into a pass-specific data structure.
-
- 2. _Write summary_ ('write_summary' in 'struct ipa_opt_pass_d').
- This stage writes all the pass-specific information generated
- by 'generate_summary'. Summaries go into their own
- 'LTO_section_*' sections that have to be declared in
- 'lto-streamer.h':'enum lto_section_type'. A new section is
- created by calling 'create_output_block' and data can be
- written using the 'lto_output_*' routines.
-
- * WPA time
- 1. _Read summary_ ('read_summary' in 'struct ipa_opt_pass_d').
- This stage reads all the pass-specific information in exactly
- the same order that it was written by 'write_summary'.
-
- 2. _Execute_ ('execute' in 'struct opt_pass'). This performs
- inter-procedural propagation. This must be done without
- actual access to the individual function bodies or variable
- initializers. Typically, this results in a transitive closure
- operation over the summary information of all the nodes in the
- callgraph.
-
- 3. _Write optimization summary_ ('write_optimization_summary' in
- 'struct ipa_opt_pass_d'). This writes the result of the
- inter-procedural propagation into the object file. This can
- use the same data structures and helper routines used in
- 'write_summary'.
-
- * LTRANS time
- 1. _Read optimization summary_ ('read_optimization_summary' in
- 'struct ipa_opt_pass_d'). The counterpart to
- 'write_optimization_summary'. This reads the interprocedural
- optimization decisions in exactly the same format emitted by
- 'write_optimization_summary'.
-
- 2. _Transform_ ('function_transform' and 'variable_transform' in
- 'struct ipa_opt_pass_d'). The actual function bodies and
- variable initializers are updated based on the information
- passed down from the _Execute_ stage.
-
- The implementation of the inter-procedural passes are shared between
- LTO, WHOPR and classic non-LTO compilation.
-
- * During the traditional file-by-file mode every pass executes its
- own _Generate summary_, _Execute_, and _Transform_ stages within
- the single execution context of the compiler.
-
- * In LTO compilation mode, every pass uses _Generate summary_ and
- _Write summary_ stages at compilation time, while the _Read
- summary_, _Execute_, and _Transform_ stages are executed at link
- time.
-
- * In WHOPR mode all stages are used.
-
- To simplify development, the GCC pass manager differentiates between
- normal inter-procedural passes (*note Regular IPA passes::), small
- inter-procedural passes (*note Small IPA passes::) and late
- inter-procedural passes (*note Late IPA passes::). A small or late IPA
- pass ('SIMPLE_IPA_PASS') does everything at once and thus cannot be
- executed during WPA in WHOPR mode. It defines only the _Execute_ stage
- and during this stage it accesses and modifies the function bodies.
- Such passes are useful for optimization at LGEN or LTRANS time and are
- used, for example, to implement early optimization before writing object
- files. The simple inter-procedural passes can also be used for easier
- prototyping and development of a new inter-procedural pass.
-
- 25.3.1 Virtual clones
- ---------------------
-
- One of the main challenges of introducing the WHOPR compilation mode was
- addressing the interactions between optimization passes. In LTO
- compilation mode, the passes are executed in a sequence, each of which
- consists of analysis (or _Generate summary_), propagation (or _Execute_)
- and _Transform_ stages. Once the work of one pass is finished, the next
- pass sees the updated program representation and can execute. This
- makes the individual passes dependent on each other.
-
- In WHOPR mode all passes first execute their _Generate summary_ stage.
- Then summary writing marks the end of the LGEN stage. At WPA time, the
- summaries are read back into memory and all passes run the _Execute_
- stage. Optimization summaries are streamed and sent to LTRANS, where
- all the passes execute the _Transform_ stage.
-
- Most optimization passes split naturally into analysis, propagation and
- transformation stages. But some do not. The main problem arises when
- one pass performs changes and the following pass gets confused by seeing
- different callgraphs between the _Transform_ stage and the _Generate
- summary_ or _Execute_ stage. This means that the passes are required to
- communicate their decisions with each other.
-
- To facilitate this communication, the GCC callgraph infrastructure
- implements _virtual clones_, a method of representing the changes
- performed by the optimization passes in the callgraph without needing to
- update function bodies.
-
- A _virtual clone_ in the callgraph is a function that has no associated
- body, just a description of how to create its body based on a different
- function (which itself may be a virtual clone).
-
- The description of function modifications includes adjustments to the
- function's signature (which allows, for example, removing or adding
- function arguments), substitutions to perform on the function body, and,
- for inlined functions, a pointer to the function that it will be inlined
- into.
-
- It is also possible to redirect any edge of the callgraph from a
- function to its virtual clone. This implies updating of the call site
- to adjust for the new function signature.
-
- Most of the transformations performed by inter-procedural optimizations
- can be represented via virtual clones. For instance, a constant
- propagation pass can produce a virtual clone of the function which
- replaces one of its arguments by a constant. The inliner can represent
- its decisions by producing a clone of a function whose body will be
- later integrated into a given function.
-
- Using _virtual clones_, the program can be easily updated during the
- _Execute_ stage, solving most of pass interactions problems that would
- otherwise occur during _Transform_.
-
- Virtual clones are later materialized in the LTRANS stage and turned
- into real functions. Passes executed after the virtual clone were
- introduced also perform their _Transform_ stage on new functions, so for
- a pass there is no significant difference between operating on a real
- function or a virtual clone introduced before its _Execute_ stage.
-
- Optimization passes then work on virtual clones introduced before their
- _Execute_ stage as if they were real functions. The only difference is
- that clones are not visible during the _Generate Summary_ stage.
-
- To keep function summaries updated, the callgraph interface allows an
- optimizer to register a callback that is called every time a new clone
- is introduced as well as when the actual function or variable is
- generated or when a function or variable is removed. These hooks are
- registered in the _Generate summary_ stage and allow the pass to keep
- its information intact until the _Execute_ stage. The same hooks can
- also be registered during the _Execute_ stage to keep the optimization
- summaries updated for the _Transform_ stage.
-
- 25.3.2 IPA references
- ---------------------
-
- GCC represents IPA references in the callgraph. For a function or
- variable 'A', the _IPA reference_ is a list of all locations where the
- address of 'A' is taken and, when 'A' is a variable, a list of all
- direct stores and reads to/from 'A'. References represent an oriented
- multi-graph on the union of nodes of the callgraph and the varpool. See
- 'ipa-reference.c':'ipa_reference_write_optimization_summary' and
- 'ipa-reference.c':'ipa_reference_read_optimization_summary' for details.
-
- 25.3.3 Jump functions
- ---------------------
-
- Suppose that an optimization pass sees a function 'A' and it knows the
- values of (some of) its arguments. The _jump function_ describes the
- value of a parameter of a given function call in function 'A' based on
- this knowledge.
-
- Jump functions are used by several optimizations, such as the
- inter-procedural constant propagation pass and the devirtualization
- pass. The inliner also uses jump functions to perform inlining of
- callbacks.
-
-
- File: gccint.info, Node: WHOPR, Next: Internal flags, Prev: IPA, Up: LTO
-
- 25.4 Whole program assumptions, linker plugin and symbol visibilities
- =====================================================================
-
- Link-time optimization gives relatively minor benefits when used alone.
- The problem is that propagation of inter-procedural information does not
- work well across functions and variables that are called or referenced
- by other compilation units (such as from a dynamically linked library).
- We say that such functions and variables are _externally visible_.
-
- To make the situation even more difficult, many applications organize
- themselves as a set of shared libraries, and the default ELF visibility
- rules allow one to overwrite any externally visible symbol with a
- different symbol at runtime. This basically disables any optimizations
- across such functions and variables, because the compiler cannot be sure
- that the function body it is seeing is the same function body that will
- be used at runtime. Any function or variable not declared 'static' in
- the sources degrades the quality of inter-procedural optimization.
-
- To avoid this problem the compiler must assume that it sees the whole
- program when doing link-time optimization. Strictly speaking, the whole
- program is rarely visible even at link-time. Standard system libraries
- are usually linked dynamically or not provided with the link-time
- information. In GCC, the whole program option ('-fwhole-program')
- asserts that every function and variable defined in the current
- compilation unit is static, except for function 'main' (note: at link
- time, the current unit is the union of all objects compiled with LTO).
- Since some functions and variables need to be referenced externally, for
- example by another DSO or from an assembler file, GCC also provides the
- function and variable attribute 'externally_visible' which can be used
- to disable the effect of '-fwhole-program' on a specific symbol.
-
- The whole program mode assumptions are slightly more complex in C++,
- where inline functions in headers are put into _COMDAT_ sections.
- COMDAT function and variables can be defined by multiple object files
- and their bodies are unified at link-time and dynamic link-time. COMDAT
- functions are changed to local only when their address is not taken and
- thus un-sharing them with a library is not harmful. COMDAT variables
- always remain externally visible, however for readonly variables it is
- assumed that their initializers cannot be overwritten by a different
- value.
-
- GCC provides the function and variable attribute 'visibility' that can
- be used to specify the visibility of externally visible symbols (or
- alternatively an '-fdefault-visibility' command line option). ELF
- defines the 'default', 'protected', 'hidden' and 'internal'
- visibilities.
-
- The most commonly used is visibility is 'hidden'. It specifies that
- the symbol cannot be referenced from outside of the current shared
- library. Unfortunately, this information cannot be used directly by the
- link-time optimization in the compiler since the whole shared library
- also might contain non-LTO objects and those are not visible to the
- compiler.
-
- GCC solves this problem using linker plugins. A _linker plugin_ is an
- interface to the linker that allows an external program to claim the
- ownership of a given object file. The linker then performs the linking
- procedure by querying the plugin about the symbol table of the claimed
- objects and once the linking decisions are complete, the plugin is
- allowed to provide the final object file before the actual linking is
- made. The linker plugin obtains the symbol resolution information which
- specifies which symbols provided by the claimed objects are bound from
- the rest of a binary being linked.
-
- GCC is designed to be independent of the rest of the toolchain and aims
- to support linkers without plugin support. For this reason it does not
- use the linker plugin by default. Instead, the object files are
- examined by 'collect2' before being passed to the linker and objects
- found to have LTO sections are passed to 'lto1' first. This mode does
- not work for library archives. The decision on what object files from
- the archive are needed depends on the actual linking and thus GCC would
- have to implement the linker itself. The resolution information is
- missing too and thus GCC needs to make an educated guess based on
- '-fwhole-program'. Without the linker plugin GCC also assumes that
- symbols are declared 'hidden' and not referred by non-LTO code by
- default.
-
-
- File: gccint.info, Node: Internal flags, Prev: WHOPR, Up: LTO
-
- 25.5 Internal flags controlling 'lto1'
- ======================================
-
- The following flags are passed into 'lto1' and are not meant to be used
- directly from the command line.
-
- * -fwpa This option runs the serial part of the link-time optimizer
- performing the inter-procedural propagation (WPA mode). The
- compiler reads in summary information from all inputs and performs
- an analysis based on summary information only. It generates object
- files for subsequent runs of the link-time optimizer where
- individual object files are optimized using both summary
- information from the WPA mode and the actual function bodies. It
- then drives the LTRANS phase.
-
- * -fltrans This option runs the link-time optimizer in the
- local-transformation (LTRANS) mode, which reads in output from a
- previous run of the LTO in WPA mode. In the LTRANS mode, LTO
- optimizes an object and produces the final assembly.
-
- * -fltrans-output-list=FILE This option specifies a file to which the
- names of LTRANS output files are written. This option is only
- meaningful in conjunction with '-fwpa'.
-
- * -fresolution=FILE This option specifies the linker resolution file.
- This option is only meaningful in conjunction with '-fwpa' and as
- option to pass through to the LTO linker plugin.
-
-
- File: gccint.info, Node: Match and Simplify, Next: Static Analyzer, Prev: LTO, Up: Top
-
- 26 Match and Simplify
- *********************
-
- The GIMPLE and GENERIC pattern matching project match-and-simplify tries
- to address several issues.
-
- 1. unify expression simplifications currently spread and duplicated
- over separate files like fold-const.c, gimple-fold.c and builtins.c
- 2. allow for a cheap way to implement building and simplifying
- non-trivial GIMPLE expressions, avoiding the need to go through
- building and simplifying GENERIC via fold_buildN and then
- gimplifying via force_gimple_operand
-
- To address these the project introduces a simple domain specific
- language to write expression simplifications from which code targeting
- GIMPLE and GENERIC is auto-generated. The GENERIC variant follows the
- fold_buildN API while for the GIMPLE variant and to address 2) new APIs
- are introduced.
-
- * Menu:
-
- * GIMPLE API::
- * The Language::
-
-
- File: gccint.info, Node: GIMPLE API, Next: The Language, Up: Match and Simplify
-
- 26.1 GIMPLE API
- ===============
-
- -- GIMPLE function: tree gimple_simplify (enum tree_code, tree, tree,
- gimple_seq *, tree (*)(tree))
- -- GIMPLE function: tree gimple_simplify (enum tree_code, tree, tree,
- tree, gimple_seq *, tree (*)(tree))
- -- GIMPLE function: tree gimple_simplify (enum tree_code, tree, tree,
- tree, tree, gimple_seq *, tree (*)(tree))
- -- GIMPLE function: tree gimple_simplify (enum built_in_function, tree,
- tree, gimple_seq *, tree (*)(tree))
- -- GIMPLE function: tree gimple_simplify (enum built_in_function, tree,
- tree, tree, gimple_seq *, tree (*)(tree))
- -- GIMPLE function: tree gimple_simplify (enum built_in_function, tree,
- tree, tree, tree, gimple_seq *, tree (*)(tree))
- The main GIMPLE API entry to the expression simplifications
- mimicing that of the GENERIC fold_{unary,binary,ternary} functions.
-
- thus providing n-ary overloads for operation or function. The
- additional arguments are a gimple_seq where built statements are
- inserted on (if 'NULL' then simplifications requiring new statements are
- not performed) and a valueization hook that can be used to tie
- simplifications to a SSA lattice.
-
- In addition to those APIs 'fold_stmt' is overloaded with a valueization
- hook:
-
- -- bool: fold_stmt (gimple_stmt_iterator *, tree (*)(tree));
-
- Ontop of these a 'fold_buildN'-like API for GIMPLE is introduced:
-
- -- GIMPLE function: tree gimple_build (gimple_seq *, location_t, enum
- tree_code, tree, tree, tree (*valueize) (tree) = NULL);
- -- GIMPLE function: tree gimple_build (gimple_seq *, location_t, enum
- tree_code, tree, tree, tree, tree (*valueize) (tree) = NULL);
- -- GIMPLE function: tree gimple_build (gimple_seq *, location_t, enum
- tree_code, tree, tree, tree, tree, tree (*valueize) (tree) =
- NULL);
- -- GIMPLE function: tree gimple_build (gimple_seq *, location_t, enum
- built_in_function, tree, tree, tree (*valueize) (tree) =
- NULL);
- -- GIMPLE function: tree gimple_build (gimple_seq *, location_t, enum
- built_in_function, tree, tree, tree, tree (*valueize) (tree) =
- NULL);
- -- GIMPLE function: tree gimple_build (gimple_seq *, location_t, enum
- built_in_function, tree, tree, tree, tree, tree (*valueize)
- (tree) = NULL);
- -- GIMPLE function: tree gimple_convert (gimple_seq *, location_t,
- tree, tree);
-
- which is supposed to replace 'force_gimple_operand (fold_buildN (...),
- ...)' and calls to 'fold_convert'. Overloads without the 'location_t'
- argument exist. Built statements are inserted on the provided sequence
- and simplification is performed using the optional valueization hook.
-
-
- File: gccint.info, Node: The Language, Prev: GIMPLE API, Up: Match and Simplify
-
- 26.2 The Language
- =================
-
- The language to write expression simplifications in resembles other
- domain-specific languages GCC uses. Thus it is lispy. Lets start with
- an example from the match.pd file:
-
- (simplify
- (bit_and @0 integer_all_onesp)
- @0)
-
- This example contains all required parts of an expression
- simplification. A simplification is wrapped inside a '(simplify ...)'
- expression. That contains at least two operands - an expression that is
- matched with the GIMPLE or GENERIC IL and a replacement expression that
- is returned if the match was successful.
-
- Expressions have an operator ID, 'bit_and' in this case. Expressions
- can be lower-case tree codes with '_expr' stripped off or builtin
- function code names in all-caps, like 'BUILT_IN_SQRT'.
-
- '@n' denotes a so-called capture. It captures the operand and lets you
- refer to it in other places of the match-and-simplify. In the above
- example it is refered to in the replacement expression. Captures are
- '@' followed by a number or an identifier.
-
- (simplify
- (bit_xor @0 @0)
- { build_zero_cst (type); })
-
- In this example '@0' is mentioned twice which constrains the matched
- expression to have two equal operands. Usually matches are constraint
- to equal types. If operands may be constants and conversions are
- involved matching by value might be preferred in which case use '@@0' to
- denote a by value match and the specific operand you want to refer to in
- the result part. This example also introduces operands written in C
- code. These can be used in the expression replacements and are supposed
- to evaluate to a tree node which has to be a valid GIMPLE operand (so
- you cannot generate expressions in C code).
-
- (simplify
- (trunc_mod integer_zerop@0 @1)
- (if (!integer_zerop (@1))
- @0))
-
- Here '@0' captures the first operand of the trunc_mod expression which
- is also predicated with 'integer_zerop'. Expression operands may be
- either expressions, predicates or captures. Captures can be
- unconstrained or capture expresions or predicates.
-
- This example introduces an optional operand of simplify, the
- if-expression. This condition is evaluated after the expression matched
- in the IL and is required to evaluate to true to enable the replacement
- expression in the second operand position. The expression operand of
- the 'if' is a standard C expression which may contain references to
- captures. The 'if' has an optional third operand which may contain the
- replacement expression that is enabled when the condition evaluates to
- false.
-
- A 'if' expression can be used to specify a common condition for
- multiple simplify patterns, avoiding the need to repeat that multiple
- times:
-
- (if (!TYPE_SATURATING (type)
- && !FLOAT_TYPE_P (type) && !FIXED_POINT_TYPE_P (type))
- (simplify
- (minus (plus @0 @1) @0)
- @1)
- (simplify
- (minus (minus @0 @1) @0)
- (negate @1)))
-
- Note that 'if's in outer position do not have the optional else clause
- but instead have multiple then clauses.
-
- Ifs can be nested.
-
- There exists a 'switch' expression which can be used to chain
- conditions avoiding nesting 'if's too much:
-
- (simplify
- (simple_comparison @0 REAL_CST@1)
- (switch
- /* a CMP (-0) -> a CMP 0 */
- (if (REAL_VALUE_MINUS_ZERO (TREE_REAL_CST (@1)))
- (cmp @0 { build_real (TREE_TYPE (@1), dconst0); }))
- /* x != NaN is always true, other ops are always false. */
- (if (REAL_VALUE_ISNAN (TREE_REAL_CST (@1))
- && ! HONOR_SNANS (@1))
- { constant_boolean_node (cmp == NE_EXPR, type); })))
-
- Is equal to
-
- (simplify
- (simple_comparison @0 REAL_CST@1)
- (switch
- /* a CMP (-0) -> a CMP 0 */
- (if (REAL_VALUE_MINUS_ZERO (TREE_REAL_CST (@1)))
- (cmp @0 { build_real (TREE_TYPE (@1), dconst0); })
- /* x != NaN is always true, other ops are always false. */
- (if (REAL_VALUE_ISNAN (TREE_REAL_CST (@1))
- && ! HONOR_SNANS (@1))
- { constant_boolean_node (cmp == NE_EXPR, type); }))))
-
- which has the second 'if' in the else operand of the first. The
- 'switch' expression takes 'if' expressions as operands (which may not
- have else clauses) and as a last operand a replacement expression which
- should be enabled by default if no other condition evaluated to true.
-
- Captures can also be used for capturing results of sub-expressions.
-
- #if GIMPLE
- (simplify
- (pointer_plus (addr@2 @0) INTEGER_CST_P@1)
- (if (is_gimple_min_invariant (@2)))
- {
- poly_int64 off;
- tree base = get_addr_base_and_unit_offset (@0, &off);
- off += tree_to_uhwi (@1);
- /* Now with that we should be able to simply write
- (addr (mem_ref (addr @base) (plus @off @1))) */
- build1 (ADDR_EXPR, type,
- build2 (MEM_REF, TREE_TYPE (TREE_TYPE (@2)),
- build_fold_addr_expr (base),
- build_int_cst (ptr_type_node, off)));
- })
- #endif
-
- In the above example, '@2' captures the result of the expression '(addr
- @0)'. For outermost expression only its type can be captured, and the
- keyword 'type' is reserved for this purpose. The above example also
- gives a way to conditionalize patterns to only apply to 'GIMPLE' or
- 'GENERIC' by means of using the pre-defined preprocessor macros 'GIMPLE'
- and 'GENERIC' and using preprocessor directives.
-
- (simplify
- (bit_and:c integral_op_p@0 (bit_ior:c (bit_not @0) @1))
- (bit_and @1 @0))
-
- Here we introduce flags on match expressions. The flag used above,
- 'c', denotes that the expression should be also matched commutated.
- Thus the above match expression is really the following four match
- expressions:
-
- (bit_and integral_op_p@0 (bit_ior (bit_not @0) @1))
- (bit_and (bit_ior (bit_not @0) @1) integral_op_p@0)
- (bit_and integral_op_p@0 (bit_ior @1 (bit_not @0)))
- (bit_and (bit_ior @1 (bit_not @0)) integral_op_p@0)
-
- Usual canonicalizations you know from GENERIC expressions are applied
- before matching, so for example constant operands always come second in
- commutative expressions.
-
- The second supported flag is 's' which tells the code generator to fail
- the pattern if the expression marked with 's' does have more than one
- use and the simplification results in an expression with more than one
- operator. For example in
-
- (simplify
- (pointer_plus (pointer_plus:s @0 @1) @3)
- (pointer_plus @0 (plus @1 @3)))
-
- this avoids the association if '(pointer_plus @0 @1)' is used outside
- of the matched expression and thus it would stay live and not trivially
- removed by dead code elimination. Now consider '((x + 3) + -3)' with
- the temporary holding '(x + 3)' used elsewhere. This simplifies down to
- 'x' which is desirable and thus flagging with 's' does not prevent the
- transform. Now consider '((x + 3) + 1)' which simplifies to '(x + 4)'.
- Despite being flagged with 's' the simplification will be performed.
- The simplification of '((x + a) + 1)' to '(x + (a + 1))' will not
- performed in this case though.
-
- More features exist to avoid too much repetition.
-
- (for op (plus pointer_plus minus bit_ior bit_xor)
- (simplify
- (op @0 integer_zerop)
- @0))
-
- A 'for' expression can be used to repeat a pattern for each operator
- specified, substituting 'op'. 'for' can be nested and a 'for' can have
- multiple operators to iterate.
-
- (for opa (plus minus)
- opb (minus plus)
- (for opc (plus minus)
- (simplify...
-
- In this example the pattern will be repeated four times with 'opa, opb,
- opc' being 'plus, minus, plus'; 'plus, minus, minus'; 'minus, plus,
- plus'; 'minus, plus, minus'.
-
- To avoid repeating operator lists in 'for' you can name them via
-
- (define_operator_list pmm plus minus mult)
-
- and use them in 'for' operator lists where they get expanded.
-
- (for opa (pmm trunc_div)
- (simplify...
-
- So this example iterates over 'plus', 'minus', 'mult' and 'trunc_div'.
-
- Using operator lists can also remove the need to explicitely write a
- 'for'. All operator list uses that appear in a 'simplify' or 'match'
- pattern in operator positions will implicitely be added to a new 'for'.
- For example
-
- (define_operator_list SQRT BUILT_IN_SQRTF BUILT_IN_SQRT BUILT_IN_SQRTL)
- (define_operator_list POW BUILT_IN_POWF BUILT_IN_POW BUILT_IN_POWL)
- (simplify
- (SQRT (POW @0 @1))
- (POW (abs @0) (mult @1 { built_real (TREE_TYPE (@1), dconsthalf); })))
-
- is the same as
-
- (for SQRT (BUILT_IN_SQRTF BUILT_IN_SQRT BUILT_IN_SQRTL)
- POW (BUILT_IN_POWF BUILT_IN_POW BUILT_IN_POWL)
- (simplify
- (SQRT (POW @0 @1))
- (POW (abs @0) (mult @1 { built_real (TREE_TYPE (@1), dconsthalf); }))))
-
- 'for's and operator lists can include the special identifier 'null'
- that matches nothing and can never be generated. This can be used to
- pad an operator list so that it has a standard form, even if there isn't
- a suitable operator for every form.
-
- Another building block are 'with' expressions in the result expression
- which nest the generated code in a new C block followed by its argument:
-
- (simplify
- (convert (mult @0 @1))
- (with { tree utype = unsigned_type_for (type); }
- (convert (mult (convert:utype @0) (convert:utype @1)))))
-
- This allows code nested in the 'with' to refer to the declared
- variables. In the above case we use the feature to specify the type of
- a generated expression with the ':type' syntax where 'type' needs to be
- an identifier that refers to the desired type. Usually the types of the
- generated result expressions are determined from the context, but
- sometimes like in the above case it is required that you specify them
- explicitely.
-
- As intermediate conversions are often optional there is a way to avoid
- the need to repeat patterns both with and without such conversions.
- Namely you can mark a conversion as being optional with a '?':
-
- (simplify
- (eq (convert@0 @1) (convert? @2))
- (eq @1 (convert @2)))
-
- which will match both '(eq (convert @1) (convert @2))' and '(eq
- (convert @1) @2)'. The optional converts are supposed to be all either
- present or not, thus '(eq (convert? @1) (convert? @2))' will result in
- two patterns only. If you want to match all four combinations you have
- access to two additional conditional converts as in '(eq (convert1? @1)
- (convert2? @2))'.
-
- The support for '?' marking extends to all unary operations including
- predicates you declare yourself with 'match'.
-
- Predicates available from the GCC middle-end need to be made available
- explicitely via 'define_predicates':
-
- (define_predicates
- integer_onep integer_zerop integer_all_onesp)
-
- You can also define predicates using the pattern matching language and
- the 'match' form:
-
- (match negate_expr_p
- INTEGER_CST
- (if (TYPE_OVERFLOW_WRAPS (type)
- || may_negate_without_overflow_p (t))))
- (match negate_expr_p
- (negate @0))
-
- This shows that for 'match' expressions there is 't' available which
- captures the outermost expression (something not possible in the
- 'simplify' context). As you can see 'match' has an identifier as first
- operand which is how you refer to the predicate in patterns. Multiple
- 'match' for the same identifier add additional cases where the predicate
- matches.
-
- Predicates can also match an expression in which case you need to
- provide a template specifying the identifier and where to get its
- operands from:
-
- (match (logical_inverted_value @0)
- (eq @0 integer_zerop))
- (match (logical_inverted_value @0)
- (bit_not truth_valued_p@0))
-
- You can use the above predicate like
-
- (simplify
- (bit_and @0 (logical_inverted_value @0))
- { build_zero_cst (type); })
-
- Which will match a bitwise and of an operand with its logical inverted
- value.
-
-
- File: gccint.info, Node: Static Analyzer, Next: User Experience Guidelines, Prev: Match and Simplify, Up: Top
-
- 27 Static Analyzer
- ******************
-
- * Menu:
-
- * Analyzer Internals:: Analyzer Internals
- * Debugging the Analyzer:: Useful debugging tips
-
-
- File: gccint.info, Node: Analyzer Internals, Next: Debugging the Analyzer, Up: Static Analyzer
-
- 27.1 Analyzer Internals
- =======================
-
- 27.1.1 Overview
- ---------------
-
- The analyzer implementation works on the gimple-SSA representation. (I
- chose this in the hopes of making it easy to work with LTO to do
- whole-program analysis).
-
- The implementation is read-only: it doesn't attempt to change anything,
- just emit warnings.
-
- The gimple representation can be seen using '-fdump-ipa-analyzer'.
-
- First, we build a 'supergraph' which combines the callgraph and all of
- the CFGs into a single directed graph, with both interprocedural and
- intraprocedural edges. The nodes and edges in the supergraph are called
- "supernodes" and "superedges", and often referred to in code as 'snodes'
- and 'sedges'. Basic blocks in the CFGs are split at interprocedural
- calls, so there can be more than one supernode per basic block. Most
- statements will be in just one supernode, but a call statement can
- appear in two supernodes: at the end of one for the call, and again at
- the start of another for the return.
-
- The supergraph can be seen using '-fdump-analyzer-supergraph'.
-
- We then build an 'analysis_plan' which walks the callgraph to determine
- which calls might be suitable for being summarized (rather than fully
- explored) and thus in what order to explore the functions.
-
- Next is the heart of the analyzer: we use a worklist to explore state
- within the supergraph, building an "exploded graph". Nodes in the
- exploded graph correspond to <point, state> pairs, as in "Precise
- Interprocedural Dataflow Analysis via Graph Reachability" (Thomas Reps,
- Susan Horwitz and Mooly Sagiv).
-
- We reuse nodes for <point, state> pairs we've already seen, and avoid
- tracking state too closely, so that (hopefully) we rapidly converge on a
- final exploded graph, and terminate the analysis. We also bail out if
- the number of exploded <end-of-basic-block, state> nodes gets larger
- than a particular multiple of the total number of basic blocks (to
- ensure termination in the face of pathological state-explosion cases, or
- bugs). We also stop exploring a point once we hit a limit of states for
- that point.
-
- We can identify problems directly when processing a <point, state>
- instance. For example, if we're finding the successors of
-
- <point: before-stmt: "free (ptr);",
- state: {"ptr": freed}>
-
- then we can detect a double-free of "ptr". We can then emit a path to
- reach the problem by finding the simplest route through the graph.
-
- Program points in the analysis are much more fine-grained than in the
- CFG and supergraph, with points (and thus potentially exploded nodes)
- for various events, including before individual statements. By default
- the exploded graph merges multiple consecutive statements in a supernode
- into one exploded edge to minimize the size of the exploded graph. This
- can be suppressed via '-fanalyzer-fine-grained'. The fine-grained
- approach seems to make things simpler and more debuggable that other
- approaches I tried, in that each point is responsible for one thing.
-
- Program points in the analysis also have a "call string" identifying
- the stack of callsites below them, so that paths in the exploded graph
- correspond to interprocedurally valid paths: we always return to the
- correct call site, propagating state information accordingly. We avoid
- infinite recursion by stopping the analysis if a callsite appears more
- than 'analyzer-max-recursion-depth' in a callstring (defaulting to 2).
-
- 27.1.2 Graphs
- -------------
-
- Nodes and edges in the exploded graph are called "exploded nodes" and
- "exploded edges" and often referred to in the code as 'enodes' and
- 'eedges' (especially when distinguishing them from the 'snodes' and
- 'sedges' in the supergraph).
-
- Each graph numbers its nodes, giving unique identifiers - supernodes
- are referred to throughout dumps in the form 'SN': INDEX' and exploded
- nodes in the form 'EN: INDEX' (e.g. 'SN: 2' and 'EN:29').
-
- The supergraph can be seen using '-fdump-analyzer-supergraph-graph'.
-
- The exploded graph can be seen using '-fdump-analyzer-exploded-graph'
- and other dump options. Exploded nodes are color-coded in the .dot
- output based on state-machine states to make it easier to see state
- changes at a glance.
-
- 27.1.3 State Tracking
- ---------------------
-
- There's a tension between:
- * precision of analysis in the straight-line case, vs
- * exponential blow-up in the face of control flow.
-
- For example, in general, given this CFG:
-
- A
- / \
- B C
- \ /
- D
- / \
- E F
- \ /
- G
-
- we want to avoid differences in state-tracking in B and C from leading
- to blow-up. If we don't prevent state blowup, we end up with
- exponential growth of the exploded graph like this:
-
-
- 1:A
- / \
- / \
- / \
- 2:B 3:C
- | |
- 4:D 5:D (2 exploded nodes for D)
- / \ / \
- 6:E 7:F 8:E 9:F
- | | | |
- 10:G 11:G 12:G 13:G (4 exploded nodes for G)
-
-
- Similar issues arise with loops.
-
- To prevent this, we follow various approaches:
-
- a. state pruning: which tries to discard state that won't be relevant
- later on withing the function. This can be disabled via
- '-fno-analyzer-state-purge'.
-
- b. state merging. We can try to find the commonality between two
- program_state instances to make a third, simpler program_state. We
- have two strategies here:
-
- 1. the worklist keeps new nodes for the same program_point
- together, and tries to merge them before processing, and thus
- before they have successors. Hence, in the above, the two
- nodes for D (4 and 5) reach the front of the worklist
- together, and we create a node for D with the merger of the
- incoming states.
-
- 2. try merging with the state of existing enodes for the
- program_point (which may have already been explored). There
- will be duplication, but only one set of duplication;
- subsequent duplicates are more likely to hit the cache. In
- particular, (hopefully) all merger chains are finite, and so
- we guarantee termination. This is intended to help with
- loops: we ought to explore the first iteration, and then have
- a "subsequent iterations" exploration, which uses a state
- merged from that of the first, to be more abstract.
-
- We avoid merging pairs of states that have state-machine
- differences, as these are the kinds of differences that are likely
- to be most interesting. So, for example, given:
-
- if (condition)
- ptr = malloc (size);
- else
- ptr = local_buf;
-
- .... do things with 'ptr'
-
- if (condition)
- free (ptr);
-
- ...etc
-
- then we end up with an exploded graph that looks like this:
-
-
- if (condition)
- / T \ F
- --------- ----------
- / \
- ptr = malloc (size) ptr = local_buf
- | |
- copy of copy of
- "do things with 'ptr'" "do things with 'ptr'"
- with ptr: heap-allocated with ptr: stack-allocated
- | |
- if (condition) if (condition)
- | known to be T | known to be F
- free (ptr); |
- \ /
- -----------------------------
- | ('ptr' is pruned, so states can be merged)
- etc
-
-
- where some duplication has occurred, but only for the places where
- the the different paths are worth exploringly separately.
-
- Merging can be disabled via '-fno-analyzer-state-merge'.
-
- 27.1.4 Region Model
- -------------------
-
- Part of the state stored at a 'exploded_node' is a 'region_model'. This
- is an implementation of the region-based ternary model described in "A
- Memory Model for Static Analysis of C Programs"
- (http://lcs.ios.ac.cn/~xuzb/canalyze/memmodel.pdf) (Zhongxing Xu, Ted
- Kremenek, and Jian Zhang).
-
- A 'region_model' encapsulates a representation of the state of memory,
- with a tree of 'region' instances, along with their associated values.
- The representation is graph-like because values can be pointers to
- regions. It also stores a constraint_manager, capturing relationships
- between the values.
-
- Because each node in the 'exploded_graph' has a 'region_model', and
- each of the latter is graph-like, the 'exploded_graph' is in some ways a
- graph of graphs.
-
- Here's an example of printing a 'region_model', showing the ASCII-art
- used to visualize the region hierarchy (colorized when printing to
- stderr):
-
- (gdb) call debug (*this)
- r0: {kind: 'root', parent: null, sval: null}
- |-stack: r1: {kind: 'stack', parent: r0, sval: sv1}
- | |: sval: sv1: {poisoned: uninit}
- | |-frame for 'test': r2: {kind: 'frame', parent: r1, sval: null, map: {'ptr_3': r3}, function: 'test', depth: 0}
- | | `-'ptr_3': r3: {kind: 'map', parent: r2, sval: sv3, type: 'void *', map: {}}
- | | |: sval: sv3: {type: 'void *', unknown}
- | | |: type: 'void *'
- | `-frame for 'calls_malloc': r4: {kind: 'frame', parent: r1, sval: null, map: {'result_3': r7, '_4': r8, '<anonymous>': r5}, function: 'calls_malloc', depth: 1}
- | |-'<anonymous>': r5: {kind: 'map', parent: r4, sval: sv4, type: 'void *', map: {}}
- | | |: sval: sv4: {type: 'void *', &r6}
- | | |: type: 'void *'
- | |-'result_3': r7: {kind: 'map', parent: r4, sval: sv4, type: 'void *', map: {}}
- | | |: sval: sv4: {type: 'void *', &r6}
- | | |: type: 'void *'
- | `-'_4': r8: {kind: 'map', parent: r4, sval: sv4, type: 'void *', map: {}}
- | |: sval: sv4: {type: 'void *', &r6}
- | |: type: 'void *'
- `-heap: r9: {kind: 'heap', parent: r0, sval: sv2}
- |: sval: sv2: {poisoned: uninit}
- `-r6: {kind: 'symbolic', parent: r9, sval: null, map: {}}
- svalues:
- sv0: {type: 'size_t', '1024'}
- sv1: {poisoned: uninit}
- sv2: {poisoned: uninit}
- sv3: {type: 'void *', unknown}
- sv4: {type: 'void *', &r6}
- constraint manager:
- equiv classes:
- ec0: {sv0 == '1024'}
- ec1: {sv4}
- constraints:
-
- This is the state at the point of returning from 'calls_malloc' back to
- 'test' in the following:
-
- void *
- calls_malloc (void)
- {
- void *result = malloc (1024);
- return result;
- }
-
- void test (void)
- {
- void *ptr = calls_malloc ();
- /* etc. */
- }
-
- The "root" region ("r0") has a "stack" child ("r1"), with two children:
- a frame for 'test' ("r2"), and a frame for 'calls_malloc' ("r4"). These
- frame regions have child regions for storing their local variables. For
- example, the return region and that of various other regions within the
- "calls_malloc" frame all have value "sv4", a pointer to a heap-allocated
- region "r6". Within the parent frame, 'ptr_3' has value "sv3", an
- unknown 'void *'.
-
- 27.1.5 Analyzer Paths
- ---------------------
-
- We need to explain to the user what the problem is, and to persuade them
- that there really is a problem. Hence having a 'diagnostic_path' isn't
- just an incidental detail of the analyzer; it's required.
-
- Paths ought to be:
- * interprocedurally-valid
- * feasible
-
- Without state-merging, all paths in the exploded graph are feasible (in
- terms of constraints being satisified). With state-merging, paths in
- the exploded graph can be infeasible.
-
- We collate warnings and only emit them for the simplest path e.g. for
- a bug in a utility function, with lots of routes to calling it, we only
- emit the simplest path (which could be intraprocedural, if it can be
- reproduced without a caller). We apply a check that each duplicate
- warning's shortest path is feasible, rejecting any warnings for which
- the shortest path is infeasible (which could lead to false negatives).
-
- We use the shortest feasible 'exploded_path' through the
- 'exploded_graph' (a list of 'exploded_edge *') to build a
- 'diagnostic_path' (a list of events for the diagnostic subsystem) -
- specifically a 'checker_path'.
-
- Having built the 'checker_path', we prune it to try to eliminate events
- that aren't relevant, to minimize how much the user has to read.
-
- After pruning, we notify each event in the path of its ID and record
- the IDs of interesting events, allowing for events to refer to other
- events in their descriptions. The 'pending_diagnostic' class has
- various vfuncs to support emitting more precise descriptions, so that
- e.g.
-
- * a deref-of-unchecked-malloc diagnostic might use:
- returning possibly-NULL pointer to 'make_obj' from 'allocator'
- for a 'return_event' to make it clearer how the unchecked value
- moves from callee back to caller
- * a double-free diagnostic might use:
- second 'free' here; first 'free' was at (3)
- and a use-after-free might use
- use after 'free' here; memory was freed at (2)
-
- At this point we can emit the diagnostic.
-
- 27.1.6 Limitations
- ------------------
-
- * Only for C so far
- * The implementation of call summaries is currently very simplistic.
- * Lack of function pointer analysis
- * The constraint-handling code assumes reflexivity in some places
- (that values are equal to themselves), which is not the case for
- NaN. As a simple workaround, constraints on floating-point values
- are currently ignored.
- * The region model code creates lots of little mutable objects at
- each 'region_model' (and thus per 'exploded_node') rather than
- sharing immutable objects and having the mutable state in the
- 'program_state' or 'region_model'. The latter approach might be
- more efficient, and might avoid dealing with IDs rather than
- pointers (which requires us to impose an ordering to get meaningful
- equality).
- * The region model code doesn't yet support 'memcpy'. At the
- gimple-ssa level these have been optimized to statements like this:
- _10 = MEM <long unsigned int> [(char * {ref-all})&c]
- MEM <long unsigned int> [(char * {ref-all})&d] = _10;
- Perhaps they could be supported via a new 'compound_svalue' type.
- * There are various other limitations in the region model (grep for
- TODO/xfail in the testsuite).
- * The constraint_manager's implementation of transitivity is
- currently too expensive to enable by default and so must be
- manually enabled via '-fanalyzer-transitivity').
- * The checkers are currently hardcoded and don't allow for user
- extensibility (e.g. adding allocate/release pairs).
- * Although the analyzer's test suite has a proof-of-concept test case
- for LTO, LTO support hasn't had extensive testing. There are
- various lang-specific things in the analyzer that assume C rather
- than LTO. For example, SSA names are printed to the user in "raw"
- form, rather than printing the underlying variable name.
-
- Some ideas for other checkers
- * File-descriptor-based APIs
- * Linux kernel internal APIs
- * Signal handling
-
-
- File: gccint.info, Node: Debugging the Analyzer, Prev: Analyzer Internals, Up: Static Analyzer
-
- 27.2 Debugging the Analyzer
- ===========================
-
- 27.2.1 Special Functions for Debugging the Analyzer
- ---------------------------------------------------
-
- The analyzer recognizes various special functions by name, for use in
- debugging the analyzer. Declarations can be seen in the testsuite in
- 'analyzer-decls.h'. None of these functions are actually implemented.
-
- Add:
- __analyzer_break ();
- to the source being analyzed to trigger a breakpoint in the analyzer
- when that source is reached. By putting a series of these in the
- source, it's much easier to effectively step through the program state
- as it's analyzed.
-
- __analyzer_dump ();
-
- will dump the copious information about the analyzer's state each time
- it reaches the call in its traversal of the source.
-
- __analyzer_dump_path ();
-
- will emit a placeholder "note" diagnostic with a path to that call
- site, if the analyzer finds a feasible path to it.
-
- The builtin '__analyzer_dump_exploded_nodes' will emit a warning after
- analysis containing information on all of the exploded nodes at that
- program point:
-
- __analyzer_dump_exploded_nodes (0);
-
- will output the number of "processed" nodes, and the IDs of both
- "processed" and "merger" nodes, such as:
-
- warning: 2 processed enodes: [EN: 56, EN: 58] merger(s): [EN: 54-55, EN: 57, EN: 59]
-
- With a non-zero argument
-
- __analyzer_dump_exploded_nodes (1);
-
- it will also dump all of the states within the "processed" nodes.
-
- __analyzer_dump_region_model ();
- will dump the region_model's state to stderr.
-
- __analyzer_eval (expr);
- will emit a warning with text "TRUE", FALSE" or "UNKNOWN" based on the
- truthfulness of the argument. This is useful for writing DejaGnu tests.
-
- 27.2.2 Other Debugging Techniques
- ---------------------------------
-
- One approach when tracking down where a particular bogus state is
- introduced into the 'exploded_graph' is to add custom code to
- 'region_model::validate'.
-
- For example, this custom code (added to 'region_model::validate')
- breaks with an assertion failure when a variable called 'ptr' acquires a
- value that's unknown, using 'region_model::get_value_by_name' to locate
- the variable
-
- /* Find a variable matching "ptr". */
- svalue_id sid = get_value_by_name ("ptr");
- if (!sid.null_p ())
- {
- svalue *sval = get_svalue (sid);
- gcc_assert (sval->get_kind () != SK_UNKNOWN);
- }
-
- making it easier to investigate further in a debugger when this occurs.
-
-
- File: gccint.info, Node: User Experience Guidelines, Next: Funding, Prev: Static Analyzer, Up: Top
-
- 28 User Experience Guidelines
- *****************************
-
- To borrow a slogan from Elm
- (https://elm-lang.org/news/compilers-as-assistants),
-
- *Compilers should be assistants, not adversaries.* A compiler
- should not just detect bugs, it should then help you understand why
- there is a bug. It should not berate you in a robot voice, it
- should give you specific hints that help you write better code.
- Ultimately, a compiler should make programming faster and more fun!
- -- _Evan Czaplicki_
-
- This chapter provides guidelines on how to implement diagnostics and
- command-line options in ways that we hope achieve the above ideal.
-
- * Menu:
-
- * Guidelines for Diagnostics:: How to implement diagnostics.
- * Guidelines for Options:: Guidelines for command-line options.
-
-
- File: gccint.info, Node: Guidelines for Diagnostics, Next: Guidelines for Options, Up: User Experience Guidelines
-
- 28.1 Guidelines for Diagnostics
- ===============================
-
- 28.1.1 Talk in terms of the user's code
- ---------------------------------------
-
- Diagnostics should be worded in terms of the user's source code, and the
- source language, rather than GCC's own implementation details.
-
- 28.1.2 Diagnostics are actionable
- ---------------------------------
-
- A good diagnostic is "actionable": it should assist the user in taking
- action.
-
- Consider what an end user will want to do when encountering a
- diagnostic.
-
- Given an error, an end user will think: "How do I fix this?"
-
- Given a warning, an end user will think:
-
- * "Is this a real problem?"
- * "Do I care?"
- * if they decide it's genuine: "How do I fix this?"
-
- A good diagnostic provides pertinent information to allow the user to
- easily answer the above questions.
-
- 28.1.3 The user's attention is important
- ----------------------------------------
-
- A perfect compiler would issue a warning on every aspect of the user's
- source code that ought to be fixed, and issue no other warnings.
- Naturally, this ideal is impossible to achieve.
-
- Warnings should have a good "signal-to-noise ratio": we should have few
- "false positives" (falsely issuing a warning when no warning is
- warranted) and few "false negatives" (failing to issue a warning when
- one _is_ justified).
-
- Note that a false positive can mean, in practice, a warning that the
- user doesn't agree with. Ideally a diagnostic should contain enough
- information to allow the user to make an informed choice about whether
- they should care (and how to fix it), but a balance must be drawn
- against overloading the user with irrelevant data.
-
- 28.1.4 Precision of Wording
- ---------------------------
-
- Provide the user with details that allow them to identify what the
- problem is. For example, the vaguely-worded message:
-
- demo.c:1:1: warning: 'noinline' attribute ignored [-Wattributes]
- 1 | int foo __attribute__((noinline));
- | ^~~
-
- doesn't tell the user why the attribute was ignored, or what kind of
- entity the compiler thought the attribute was being applied to (the
- source location for the diagnostic is also poor; *note discussion of
- 'input_location': input_location_example.). A better message would be:
-
- demo.c:1:24: warning: attribute 'noinline' on variable 'foo' was
- ignored [-Wattributes]
- 1 | int foo __attribute__((noinline));
- | ~~~ ~~~~~~~~~~~~~~~^~~~~~~~~
- demo.c:1:24: note: attribute 'noinline' is only applicable to functions
-
- which spells out the missing information (and fixes the location
- information, as discussed below).
-
- The above example uses a note to avoid a combinatorial explosion of
- possible messages.
-
- 28.1.5 Try the diagnostic on real-world code
- --------------------------------------------
-
- It's worth testing a new warning on many instances of real-world code,
- written by different people, and seeing what it complains about, and
- what it doesn't complain about.
-
- This may suggest heuristics that silence common false positives.
-
- It may also suggest ways to improve the precision of the message.
-
- 28.1.6 Make mismatches clear
- ----------------------------
-
- Many diagnostics relate to a mismatch between two different places in
- the user's source code. Examples include:
- * a type mismatch, where the type at a usage site does not match the
- type at a declaration
-
- * the argument count at a call site does not match the parameter
- count at the declaration
-
- * something is erroneously duplicated (e.g. an error, due to breaking
- a uniqueness requirement, or a warning, if it's suggestive of a
- bug)
-
- * an "opened" syntactic construct (such as an open-parenthesis) is
- not closed
-
- In each case, the diagnostic should indicate *both* pertinent locations
- (so that the user can easily see the problem and how to fix it).
-
- The standard way to do this is with a note (via 'inform'). For
- example:
-
- auto_diagnostic_group d;
- if (warning_at (loc, OPT_Wduplicated_cond,
- "duplicated %<if%> condition"))
- inform (EXPR_LOCATION (t), "previously used here");
-
- which leads to:
-
- demo.c: In function 'test':
- demo.c:5:17: warning: duplicated 'if' condition [-Wduplicated-cond]
- 5 | else if (flag > 3)
- | ~~~~~^~~
- demo.c:3:12: note: previously used here
- 3 | if (flag > 3)
- | ~~~~~^~~
-
- The 'inform' call should be guarded by the return value from the
- 'warning_at' call so that the note isn't emitted when the warning is
- suppressed.
-
- For cases involving punctuation where the locations might be near each
- other, they can be conditionally consolidated via
- 'gcc_rich_location::add_location_if_nearby':
-
- auto_diagnostic_group d;
- gcc_rich_location richloc (primary_loc);
- bool added secondary = richloc.add_location_if_nearby (secondary_loc);
- error_at (&richloc, "main message");
- if (!added secondary)
- inform (secondary_loc, "message for secondary");
-
- This will emit either one diagnostic with two locations:
- demo.c:42:10: error: main message
- (foo)
- ~ ^
-
- or two diagnostics:
-
- demo.c:42:4: error: main message
- foo)
- ^
- demo.c:40:2: note: message for secondary
- (
- ^
-
- 28.1.7 Location Information
- ---------------------------
-
- GCC's 'location_t' type can support both ordinary locations, and
- locations relating to a macro expansion.
-
- As of GCC 6, ordinary locations changed from supporting just a point in
- the user's source code to supporting three points: the "caret" location,
- plus a start and a finish:
-
- a = foo && bar;
- ~~~~^~~~~~
- | | |
- | | finish
- | caret
- start
-
- Tokens coming out of libcpp have locations of the form 'caret ==
- start', such as for 'foo' here:
-
- a = foo && bar;
- ^~~
- | |
- | finish
- caret == start
-
- Compound expressions should be reported using the location of the
- expression as a whole, rather than just of one token within it.
-
- For example, in '-Wformat', rather than underlining just the first
- token of a bad argument:
-
- printf("hello %i %s", (long)0, "world");
- ~^ ~
- %li
-
- the whole of the expression should be underlined, so that the user can
- easily identify what is being referred to:
-
- printf("hello %i %s", (long)0, "world");
- ~^ ~~~~~~~
- %li
-
- Avoid using the 'input_location' global, and the diagnostic functions
- that implicitly use it--use 'error_at' and 'warning_at' rather than
- 'error' and 'warning', and provide the most appropriate 'location_t'
- value available at that phase of the compilation. It's possible to
- supply secondary 'location_t' values via 'rich_location'.
-
- For example, in the example of imprecise wording above, generating the
- diagnostic using 'warning':
-
- // BAD: implicitly uses input_location
- warning (OPT_Wattributes, "%qE attribute ignored", name);
-
- leads to:
-
- // BAD: uses input_location
- demo.c:1:1: warning: 'noinline' attribute ignored [-Wattributes]
- 1 | int foo __attribute__((noinline));
- | ^~~
-
- which thus happened to use the location of the 'int' token, rather than
- that of the attribute. Using 'warning_at' with the location of the
- attribute, providing the location of the declaration in question as a
- secondary location, and adding a note:
-
- auto_diagnostic_group d;
- gcc_rich_location richloc (attrib_loc);
- richloc.add_range (decl_loc);
- if (warning_at (OPT_Wattributes, &richloc,
- "attribute %qE on variable %qE was ignored", name))
- inform (attrib_loc, "attribute %qE is only applicable to functions");
-
- would lead to:
-
- // OK: use location of attribute, with a secondary location
- demo.c:1:24: warning: attribute 'noinline' on variable 'foo' was
- ignored [-Wattributes]
- 1 | int foo __attribute__((noinline));
- | ~~~ ~~~~~~~~~~~~~~~^~~~~~~~~
- demo.c:1:24: note: attribute 'noinline' is only applicable to functions
-
- 28.1.8 Coding Conventions
- -------------------------
-
- See the diagnostics section
- (https://gcc.gnu.org/codingconventions.html#Diagnostics) of the GCC
- coding conventions.
-
- In the C++ front end, when comparing two types in a message, use '%H'
- and '%I' rather than '%T', as this allows the diagnostics subsystem to
- highlight differences between template-based types. For example, rather
- than using '%qT':
-
- // BAD: a pair of %qT used in C++ front end for type comparison
- error_at (loc, "could not convert %qE from %qT to %qT", expr,
- TREE_TYPE (expr), type);
-
- which could lead to:
-
- error: could not convert 'map<int, double>()' from 'map<int,double>'
- to 'map<int,int>'
-
- using '%H' and '%I' (via '%qH' and '%qI'):
-
- // OK: compare types in C++ front end via %qH and %qI
- error_at (loc, "could not convert %qE from %qH to %qI", expr,
- TREE_TYPE (expr), type);
-
- allows the above output to be simplified to:
-
- error: could not convert 'map<int, double>()' from 'map<[...],double>'
- to 'map<[...],int>'
-
- where the 'double' and 'int' are colorized to highlight them.
-
- 28.1.9 Group logically-related diagnostics
- ------------------------------------------
-
- Use 'auto_diagnostic_group' when issuing multiple related diagnostics
- (seen in various examples on this page). This informs the diagnostic
- subsystem that all diagnostics issued within the lifetime of the
- 'auto_diagnostic_group' are related. For example,
- '-fdiagnostics-format=json' will treat the first diagnostic emitted
- within the group as a top-level diagnostic, and all subsequent
- diagnostics within the group as its children.
-
- 28.1.10 Quoting
- ---------------
-
- Text should be quoted by either using the 'q' modifier in a directive
- such as '%qE', or by enclosing the quoted text in a pair of '%<' and
- '%>' directives, and never by using explicit quote characters. The
- directives handle the appropriate quote characters for each language and
- apply the correct color or highlighting.
-
- The following elements should be quoted in GCC diagnostics:
-
- * Language keywords.
- * Tokens.
- * Boolean, numerical, character, and string constants that appear in
- the source code.
- * Identifiers, including function, macro, type, and variable names.
-
- Other elements such as numbers that do not refer to numeric constants
- that appear in the source code should not be quoted. For example, in
- the message:
-
- argument %d of %qE must be a pointer type
-
- since the argument number does not refer to a numerical constant in the
- source code it should not be quoted.
-
- 28.1.11 Spelling and Terminology
- --------------------------------
-
- See the terminology and markup
- (https://gcc.gnu.org/codingconventions.html#Spelling Spelling) section
- of the GCC coding conventions.
-
- 28.1.12 Fix-it hints
- --------------------
-
- GCC's diagnostic subsystem can emit "fix-it hints": small suggested
- edits to the user's source code.
-
- They are printed by default underneath the code in question. They can
- also be viewed via '-fdiagnostics-generate-patch' and
- '-fdiagnostics-parseable-fixits'. With the latter, an IDE ought to be
- able to offer to automatically apply the suggested fix.
-
- Fix-it hints contain code fragments, and thus they should not be marked
- for translation.
-
- Fix-it hints can be added to a diagnostic by using a 'rich_location'
- rather than a 'location_t' - the fix-it hints are added to the
- 'rich_location' using one of the various 'add_fixit' member functions of
- 'rich_location'. They are documented with 'rich_location' in
- 'libcpp/line-map.h'. It's easiest to use the 'gcc_rich_location'
- subclass of 'rich_location' found in 'gcc-rich-location.h', as this
- implicitly supplies the 'line_table' variable.
-
- For example:
-
- if (const char *suggestion = hint.suggestion ())
- {
- gcc_rich_location richloc (location);
- richloc.add_fixit_replace (suggestion);
- error_at (&richloc,
- "%qE does not name a type; did you mean %qs?",
- id, suggestion);
- }
-
- which can lead to:
-
- spellcheck-typenames.C:73:1: error: 'singed' does not name a type; did
- you mean 'signed'?
- 73 | singed char ch;
- | ^~~~~~
- | signed
-
- Non-trivial edits can be built up by adding multiple fix-it hints to
- one 'rich_location'. It's best to express the edits in terms of the
- locations of individual tokens. Various handy functions for adding
- fix-it hints for idiomatic C and C++ can be seen in
- 'gcc-rich-location.h'.
-
- 28.1.12.1 Fix-it hints should work
- ..................................
-
- When implementing a fix-it hint, please verify that the suggested edit
- leads to fixed, compilable code. (Unfortunately, this currently must be
- done by hand using '-fdiagnostics-generate-patch'. It would be good to
- have an automated way of verifying that fix-it hints actually fix the
- code).
-
- For example, a "gotcha" here is to forget to add a space when adding a
- missing reserved word. Consider a C++ fix-it hint that adds 'typename'
- in front of a template declaration. A naive way to implement this might
- be:
-
- gcc_rich_location richloc (loc);
- // BAD: insertion is missing a trailing space
- richloc.add_fixit_insert_before ("typename");
- error_at (&richloc, "need %<typename%> before %<%T::%E%> because "
- "%qT is a dependent scope",
- parser->scope, id, parser->scope);
-
- When applied to the code, this might lead to:
-
- T::type x;
-
- being "corrected" to:
-
- typenameT::type x;
-
- In this case, the correct thing to do is to add a trailing space after
- 'typename':
-
- gcc_rich_location richloc (loc);
- // OK: note that here we have a trailing space
- richloc.add_fixit_insert_before ("typename ");
- error_at (&richloc, "need %<typename%> before %<%T::%E%> because "
- "%qT is a dependent scope",
- parser->scope, id, parser->scope);
-
- leading to this corrected code:
-
- typename T::type x;
-
- 28.1.12.2 Express deletion in terms of deletion, not replacement
- ................................................................
-
- It's best to express deletion suggestions in terms of deletion fix-it
- hints, rather than replacement fix-it hints. For example, consider
- this:
-
- auto_diagnostic_group d;
- gcc_rich_location richloc (location_of (retval));
- tree name = DECL_NAME (arg);
- richloc.add_fixit_replace (IDENTIFIER_POINTER (name));
- warning_at (&richloc, OPT_Wredundant_move,
- "redundant move in return statement");
-
- which is intended to e.g. replace a 'std::move' with the underlying
- value:
-
- return std::move (retval);
- ~~~~~~~~~~^~~~~~~~
- retval
-
- where the change has been expressed as replacement, replacing with the
- name of the declaration. This works for simple cases, but consider this
- case:
-
- #ifdef SOME_CONFIG_FLAG
- # define CONFIGURY_GLOBAL global_a
- #else
- # define CONFIGURY_GLOBAL global_b
- #endif
-
- int fn ()
- {
- return std::move (CONFIGURY_GLOBAL /* some comment */);
- }
-
- The above implementation erroneously strips out the macro and the
- comment in the fix-it hint:
-
- return std::move (CONFIGURY_GLOBAL /* some comment */);
- ~~~~~~~~~~^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- global_a
-
- and thus this resulting code:
-
- return global_a;
-
- It's better to do deletions in terms of deletions; deleting the
- 'std::move (' and the trailing close-paren, leading to this:
-
- return std::move (CONFIGURY_GLOBAL /* some comment */);
- ~~~~~~~~~~^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- CONFIGURY_GLOBAL /* some comment */
-
- and thus this result:
-
- return CONFIGURY_GLOBAL /* some comment */;
-
- Unfortunately, the pertinent 'location_t' values are not always
- available.
-
- 28.1.12.3 Multiple suggestions
- ..............................
-
- In the rare cases where you need to suggest more than one mutually
- exclusive solution to a problem, this can be done by emitting multiple
- notes and calling 'rich_location::fixits_cannot_be_auto_applied' on each
- note's 'rich_location'. If this is called, then the fix-it hints in the
- 'rich_location' will be printed, but will not be added to generated
- patches.
-
-
- File: gccint.info, Node: Guidelines for Options, Prev: Guidelines for Diagnostics, Up: User Experience Guidelines
-
- 28.2 Guidelines for Options
- ===========================
-
-
- File: gccint.info, Node: Funding, Next: GNU Project, Prev: User Experience Guidelines, Up: Top
-
- Funding Free Software
- *********************
-
- If you want to have more free software a few years from now, it makes
- sense for you to help encourage people to contribute funds for its
- development. The most effective approach known is to encourage
- commercial redistributors to donate.
-
- Users of free software systems can boost the pace of development by
- encouraging for-a-fee distributors to donate part of their selling price
- to free software developers--the Free Software Foundation, and others.
-
- The way to convince distributors to do this is to demand it and expect
- it from them. So when you compare distributors, judge them partly by
- how much they give to free software development. Show distributors they
- must compete to be the one who gives the most.
-
- To make this approach work, you must insist on numbers that you can
- compare, such as, "We will donate ten dollars to the Frobnitz project
- for each disk sold." Don't be satisfied with a vague promise, such as
- "A portion of the profits are donated," since it doesn't give a basis
- for comparison.
-
- Even a precise fraction "of the profits from this disk" is not very
- meaningful, since creative accounting and unrelated business decisions
- can greatly alter what fraction of the sales price counts as profit. If
- the price you pay is $50, ten percent of the profit is probably less
- than a dollar; it might be a few cents, or nothing at all.
-
- Some redistributors do development work themselves. This is useful
- too; but to keep everyone honest, you need to inquire how much they do,
- and what kind. Some kinds of development make much more long-term
- difference than others. For example, maintaining a separate version of
- a program contributes very little; maintaining the standard version of a
- program for the whole community contributes much. Easy new ports
- contribute little, since someone else would surely do them; difficult
- ports such as adding a new CPU to the GNU Compiler Collection contribute
- more; major new features or packages contribute the most.
-
- By establishing the idea that supporting further development is "the
- proper thing to do" when distributing free software for a fee, we can
- assure a steady flow of resources into making more free software.
-
- Copyright (C) 1994 Free Software Foundation, Inc.
- Verbatim copying and redistribution of this section is permitted
- without royalty; alteration is not permitted.
-
-
- File: gccint.info, Node: GNU Project, Next: Copying, Prev: Funding, Up: Top
-
- The GNU Project and GNU/Linux
- *****************************
-
- The GNU Project was launched in 1984 to develop a complete Unix-like
- operating system which is free software: the GNU system. (GNU is a
- recursive acronym for "GNU's Not Unix"; it is pronounced "guh-NEW".)
- Variants of the GNU operating system, which use the kernel Linux, are
- now widely used; though these systems are often referred to as "Linux",
- they are more accurately called GNU/Linux systems.
-
- For more information, see:
- <http://www.gnu.org/>
- <http://www.gnu.org/gnu/linux-and-gnu.html>
-
-
- File: gccint.info, Node: Copying, Next: GNU Free Documentation License, Prev: GNU Project, Up: Top
-
- GNU General Public License
- **************************
-
- Version 3, 29 June 2007
-
- Copyright (C) 2007 Free Software Foundation, Inc. <http://fsf.org/>
-
- Everyone is permitted to copy and distribute verbatim copies of this
- license document, but changing it is not allowed.
-
- Preamble
- ========
-
- The GNU General Public License is a free, copyleft license for software
- and other kinds of works.
-
- The licenses for most software and other practical works are designed
- to take away your freedom to share and change the works. By contrast,
- the GNU General Public License is intended to guarantee your freedom to
- share and change all versions of a program-to make sure it remains free
- software for all its users. We, the Free Software Foundation, use the
- GNU General Public License for most of our software; it applies also to
- any other work released this way by its authors. You can apply it to
- your programs, too.
-
- When we speak of free software, we are referring to freedom, not price.
- Our General Public Licenses are designed to make sure that you have the
- freedom to distribute copies of free software (and charge for them if
- you wish), that you receive source code or can get it if you want it,
- that you can change the software or use pieces of it in new free
- programs, and that you know you can do these things.
-
- To protect your rights, we need to prevent others from denying you
- these rights or asking you to surrender the rights. Therefore, you have
- certain responsibilities if you distribute copies of the software, or if
- you modify it: responsibilities to respect the freedom of others.
-
- For example, if you distribute copies of such a program, whether gratis
- or for a fee, you must pass on to the recipients the same freedoms that
- you received. You must make sure that they, too, receive or can get the
- source code. And you must show them these terms so they know their
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- Developers that use the GNU GPL protect your rights with two steps: (1)
- assert copyright on the software, and (2) offer you this License giving
- you legal permission to copy, distribute and/or modify it.
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- For the developers' and authors' protection, the GPL clearly explains
- that there is no warranty for this free software. For both users' and
- authors' sake, the GPL requires that modified versions be marked as
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- Some devices are designed to deny users access to install or run
- modified versions of the software inside them, although the manufacturer
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- protecting users' freedom to change the software. The systematic
- pattern of such abuse occurs in the area of products for individuals to
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- Finally, every program is threatened constantly by software patents.
- States should not allow patents to restrict development and use of
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- avoid the special danger that patents applied to a free program could
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-
- The precise terms and conditions for copying, distribution and
- modification follow.
-
- TERMS AND CONDITIONS
- ====================
-
- 0. Definitions.
-
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- END OF TERMS AND CONDITIONS
- ===========================
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- How to Apply These Terms to Your New Programs
- =============================================
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- Copyright (C) YEAR NAME OF AUTHOR
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- This program is free software: you can redistribute it and/or modify
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- Also add information on how to contact you by electronic and paper
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- If the program does terminal interaction, make it output a short notice
- like this when it starts in an interactive mode:
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- PROGRAM Copyright (C) YEAR NAME OF AUTHOR
- This program comes with ABSOLUTELY NO WARRANTY; for details type 'show w'.
- This is free software, and you are welcome to redistribute it
- under certain conditions; type 'show c' for details.
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- The hypothetical commands 'show w' and 'show c' should show the
- appropriate parts of the General Public License. Of course, your
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- necessary. For more information on this, and how to apply and follow
- the GNU GPL, see <http://www.gnu.org/licenses/>.
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- The GNU General Public License does not permit incorporating your
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-
-
- File: gccint.info, Node: GNU Free Documentation License, Next: Contributors, Prev: Copying, Up: Top
-
- GNU Free Documentation License
- ******************************
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- Version 1.3, 3 November 2008
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- Copyright (C) 2000, 2001, 2002, 2007, 2008 Free Software Foundation, Inc.
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- 0. PREAMBLE
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-
- The Document may include Warranty Disclaimers next to the notice
- which states that this License applies to the Document. These
- Warranty Disclaimers are considered to be included by reference in
- this License, but only as regards disclaiming warranties: any other
- implication that these Warranty Disclaimers may have is void and
- has no effect on the meaning of this License.
-
- 2. VERBATIM COPYING
-
- You may copy and distribute the Document in any medium, either
- commercially or noncommercially, provided that this License, the
- copyright notices, and the license notice saying this License
- applies to the Document are reproduced in all copies, and that you
- add no other conditions whatsoever to those of this License. You
- may not use technical measures to obstruct or control the reading
- or further copying of the copies you make or distribute. However,
- you may accept compensation in exchange for copies. If you
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- conditions in section 3.
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- You may also lend copies, under the same conditions stated above,
- and you may publicly display copies.
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- 3. COPYING IN QUANTITY
-
- If you publish printed copies (or copies in media that commonly
- have printed covers) of the Document, numbering more than 100, and
- the Document's license notice requires Cover Texts, you must
- enclose the copies in covers that carry, clearly and legibly, all
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- Back-Cover Texts on the back cover. Both covers must also clearly
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- front cover must present the full title with all words of the title
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- long as they preserve the title of the Document and satisfy these
- conditions, can be treated as verbatim copying in other respects.
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- the Document well before redistributing any large number of copies,
- to give them a chance to provide you with an updated version of the
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- 4. MODIFICATIONS
-
- You may copy and distribute a Modified Version of the Document
- under the conditions of sections 2 and 3 above, provided that you
- release the Modified Version under precisely this License, with the
- Modified Version filling the role of the Document, thus licensing
- distribution and modification of the Modified Version to whoever
- possesses a copy of it. In addition, you must do these things in
- the Modified Version:
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- A. Use in the Title Page (and on the covers, if any) a title
- distinct from that of the Document, and from those of previous
- versions (which should, if there were any, be listed in the
- History section of the Document). You may use the same title
- as a previous version if the original publisher of that
- version gives permission.
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- entities responsible for authorship of the modifications in
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- principal authors of the Document (all of its principal
- authors, if it has fewer than five), unless they release you
- from this requirement.
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- Modified Version, as the publisher.
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- D. Preserve all the copyright notices of the Document.
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- E. Add an appropriate copyright notice for your modifications
- adjacent to the other copyright notices.
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- notice giving the public permission to use the Modified
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- the Addendum below.
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- Sections and required Cover Texts given in the Document's
- license notice.
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- H. Include an unaltered copy of this License.
-
- I. Preserve the section Entitled "History", Preserve its Title,
- and add to it an item stating at least the title, year, new
- authors, and publisher of the Modified Version as given on the
- Title Page. If there is no section Entitled "History" in the
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- publisher of the Document as given on its Title Page, then add
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- likewise the network locations given in the Document for
- previous versions it was based on. These may be placed in the
- "History" section. You may omit a network location for a work
- that was published at least four years before the Document
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- to gives permission.
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- K. For any section Entitled "Acknowledgements" or "Dedications",
- Preserve the Title of the section, and preserve in the section
- all the substance and tone of each of the contributor
- acknowledgements and/or dedications given therein.
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- in their text and in their titles. Section numbers or the
- equivalent are not considered part of the section titles.
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- M. Delete any section Entitled "Endorsements". Such a section
- may not be included in the Modified Version.
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- N. Do not retitle any existing section to be Entitled
- "Endorsements" or to conflict in title with any Invariant
- Section.
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- O. Preserve any Warranty Disclaimers.
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- If the Modified Version includes new front-matter sections or
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- some or all of these sections as invariant. To do this, add their
- titles to the list of Invariant Sections in the Modified Version's
- license notice. These titles must be distinct from any other
- section titles.
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- You may add a section Entitled "Endorsements", provided it contains
- nothing but endorsements of your Modified Version by various
- parties--for example, statements of peer review or that the text
- has been approved by an organization as the authoritative
- definition of a standard.
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- You may add a passage of up to five words as a Front-Cover Text,
- and a passage of up to 25 words as a Back-Cover Text, to the end of
- the list of Cover Texts in the Modified Version. Only one passage
- of Front-Cover Text and one of Back-Cover Text may be added by (or
- through arrangements made by) any one entity. If the Document
- already includes a cover text for the same cover, previously added
- by you or by arrangement made by the same entity you are acting on
- behalf of, you may not add another; but you may replace the old
- one, on explicit permission from the previous publisher that added
- the old one.
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- The author(s) and publisher(s) of the Document do not by this
- License give permission to use their names for publicity for or to
- assert or imply endorsement of any Modified Version.
-
- 5. COMBINING DOCUMENTS
-
- You may combine the Document with other documents released under
- this License, under the terms defined in section 4 above for
- modified versions, provided that you include in the combination all
- of the Invariant Sections of all of the original documents,
- unmodified, and list them all as Invariant Sections of your
- combined work in its license notice, and that you preserve all
- their Warranty Disclaimers.
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- The combined work need only contain one copy of this License, and
- multiple identical Invariant Sections may be replaced with a single
- copy. If there are multiple Invariant Sections with the same name
- but different contents, make the title of each such section unique
- by adding at the end of it, in parentheses, the name of the
- original author or publisher of that section if known, or else a
- unique number. Make the same adjustment to the section titles in
- the list of Invariant Sections in the license notice of the
- combined work.
-
- In the combination, you must combine any sections Entitled
- "History" in the various original documents, forming one section
- Entitled "History"; likewise combine any sections Entitled
- "Acknowledgements", and any sections Entitled "Dedications". You
- must delete all sections Entitled "Endorsements."
-
- 6. COLLECTIONS OF DOCUMENTS
-
- You may make a collection consisting of the Document and other
- documents released under this License, and replace the individual
- copies of this License in the various documents with a single copy
- that is included in the collection, provided that you follow the
- rules of this License for verbatim copying of each of the documents
- in all other respects.
-
- You may extract a single document from such a collection, and
- distribute it individually under this License, provided you insert
- a copy of this License into the extracted document, and follow this
- License in all other respects regarding verbatim copying of that
- document.
-
- 7. AGGREGATION WITH INDEPENDENT WORKS
-
- A compilation of the Document or its derivatives with other
- separate and independent documents or works, in or on a volume of a
- storage or distribution medium, is called an "aggregate" if the
- copyright resulting from the compilation is not used to limit the
- legal rights of the compilation's users beyond what the individual
- works permit. When the Document is included in an aggregate, this
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- are not themselves derivative works of the Document.
-
- If the Cover Text requirement of section 3 is applicable to these
- copies of the Document, then if the Document is less than one half
- of the entire aggregate, the Document's Cover Texts may be placed
- on covers that bracket the Document within the aggregate, or the
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- the whole aggregate.
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- 8. TRANSLATION
-
- Translation is considered a kind of modification, so you may
- distribute translations of the Document under the terms of section
- 4. Replacing Invariant Sections with translations requires special
- permission from their copyright holders, but you may include
- translations of some or all Invariant Sections in addition to the
- original versions of these Invariant Sections. You may include a
- translation of this License, and all the license notices in the
- Document, and any Warranty Disclaimers, provided that you also
- include the original English version of this License and the
- original versions of those notices and disclaimers. In case of a
- disagreement between the translation and the original version of
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- prevail.
-
- If a section in the Document is Entitled "Acknowledgements",
- "Dedications", or "History", the requirement (section 4) to
- Preserve its Title (section 1) will typically require changing the
- actual title.
-
- 9. TERMINATION
-
- You may not copy, modify, sublicense, or distribute the Document
- except as expressly provided under this License. Any attempt
- otherwise to copy, modify, sublicense, or distribute it is void,
- and will automatically terminate your rights under this License.
-
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- license from a particular copyright holder is reinstated (a)
- provisionally, unless and until the copyright holder explicitly and
- finally terminates your license, and (b) permanently, if the
- copyright holder fails to notify you of the violation by some
- reasonable means prior to 60 days after the cessation.
-
- Moreover, your license from a particular copyright holder is
- reinstated permanently if the copyright holder notifies you of the
- violation by some reasonable means, this is the first time you have
- received notice of violation of this License (for any work) from
- that copyright holder, and you cure the violation prior to 30 days
- after your receipt of the notice.
-
- Termination of your rights under this section does not terminate
- the licenses of parties who have received copies or rights from you
- under this License. If your rights have been terminated and not
- permanently reinstated, receipt of a copy of some or all of the
- same material does not give you any rights to use it.
-
- 10. FUTURE REVISIONS OF THIS LICENSE
-
- The Free Software Foundation may publish new, revised versions of
- the GNU Free Documentation License from time to time. Such new
- versions will be similar in spirit to the present version, but may
- differ in detail to address new problems or concerns. See
- <http://www.gnu.org/copyleft/>.
-
- Each version of the License is given a distinguishing version
- number. If the Document specifies that a particular numbered
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- have the option of following the terms and conditions either of
- that specified version or of any later version that has been
- published (not as a draft) by the Free Software Foundation. If the
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- choose any version ever published (not as a draft) by the Free
- Software Foundation. If the Document specifies that a proxy can
- decide which future versions of this License can be used, that
- proxy's public statement of acceptance of a version permanently
- authorizes you to choose that version for the Document.
-
- 11. RELICENSING
-
- "Massive Multiauthor Collaboration Site" (or "MMC Site") means any
- World Wide Web server that publishes copyrightable works and also
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- public wiki that anybody can edit is an example of such a server.
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- site means any set of copyrightable works thus published on the MMC
- site.
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- "CC-BY-SA" means the Creative Commons Attribution-Share Alike 3.0
- license published by Creative Commons Corporation, a not-for-profit
- corporation with a principal place of business in San Francisco,
- California, as well as future copyleft versions of that license
- published by that same organization.
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- "Incorporate" means to publish or republish a Document, in whole or
- in part, as part of another Document.
-
- An MMC is "eligible for relicensing" if it is licensed under this
- License, and if all works that were first published under this
- License somewhere other than this MMC, and subsequently
- incorporated in whole or in part into the MMC, (1) had no cover
- texts or invariant sections, and (2) were thus incorporated prior
- to November 1, 2008.
-
- The operator of an MMC Site may republish an MMC contained in the
- site under CC-BY-SA on the same site at any time before August 1,
- 2009, provided the MMC is eligible for relicensing.
-
- ADDENDUM: How to use this License for your documents
- ====================================================
-
- To use this License in a document you have written, include a copy of
- the License in the document and put the following copyright and license
- notices just after the title page:
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- Copyright (C) YEAR YOUR NAME.
- Permission is granted to copy, distribute and/or modify this document
- under the terms of the GNU Free Documentation License, Version 1.3
- or any later version published by the Free Software Foundation;
- with no Invariant Sections, no Front-Cover Texts, and no Back-Cover
- Texts. A copy of the license is included in the section entitled ``GNU
- Free Documentation License''.
-
- If you have Invariant Sections, Front-Cover Texts and Back-Cover Texts,
- replace the "with...Texts." line with this:
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- with the Invariant Sections being LIST THEIR TITLES, with
- the Front-Cover Texts being LIST, and with the Back-Cover Texts
- being LIST.
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- If you have Invariant Sections without Cover Texts, or some other
- combination of the three, merge those two alternatives to suit the
- situation.
-
- If your document contains nontrivial examples of program code, we
- recommend releasing these examples in parallel under your choice of free
- software license, such as the GNU General Public License, to permit
- their use in free software.
-
-
- File: gccint.info, Node: Contributors, Next: Option Index, Prev: GNU Free Documentation License, Up: Top
-
- Contributors to GCC
- *******************
-
- The GCC project would like to thank its many contributors. Without them
- the project would not have been nearly as successful as it has been.
- Any omissions in this list are accidental. Feel free to contact
- <law@redhat.com> or <gerald@pfeifer.com> if you have been left out or
- some of your contributions are not listed. Please keep this list in
- alphabetical order.
-
- * Analog Devices helped implement the support for complex data types
- and iterators.
-
- * John David Anglin for threading-related fixes and improvements to
- libstdc++-v3, and the HP-UX port.
-
- * James van Artsdalen wrote the code that makes efficient use of the
- Intel 80387 register stack.
-
- * Abramo and Roberto Bagnara for the SysV68 Motorola 3300 Delta
- Series port.
-
- * Alasdair Baird for various bug fixes.
-
- * Giovanni Bajo for analyzing lots of complicated C++ problem
- reports.
-
- * Peter Barada for his work to improve code generation for new
- ColdFire cores.
-
- * Gerald Baumgartner added the signature extension to the C++ front
- end.
-
- * Godmar Back for his Java improvements and encouragement.
-
- * Scott Bambrough for help porting the Java compiler.
-
- * Wolfgang Bangerth for processing tons of bug reports.
-
- * Jon Beniston for his Microsoft Windows port of Java and port to
- Lattice Mico32.
-
- * Daniel Berlin for better DWARF 2 support, faster/better
- optimizations, improved alias analysis, plus migrating GCC to
- Bugzilla.
-
- * Geoff Berry for his Java object serialization work and various
- patches.
-
- * David Binderman tests weekly snapshots of GCC trunk against Fedora
- Rawhide for several architectures.
-
- * Laurynas Biveinis for memory management work and DJGPP port fixes.
-
- * Uros Bizjak for the implementation of x87 math built-in functions
- and for various middle end and i386 back end improvements and bug
- fixes.
-
- * Eric Blake for helping to make GCJ and libgcj conform to the
- specifications.
-
- * Janne Blomqvist for contributions to GNU Fortran.
-
- * Hans-J. Boehm for his garbage collector, IA-64 libffi port, and
- other Java work.
-
- * Segher Boessenkool for helping maintain the PowerPC port and the
- instruction combiner plus various contributions to the middle end.
-
- * Neil Booth for work on cpplib, lang hooks, debug hooks and other
- miscellaneous clean-ups.
-
- * Steven Bosscher for integrating the GNU Fortran front end into GCC
- and for contributing to the tree-ssa branch.
-
- * Eric Botcazou for fixing middle- and backend bugs left and right.
-
- * Per Bothner for his direction via the steering committee and
- various improvements to the infrastructure for supporting new
- languages. Chill front end implementation. Initial
- implementations of cpplib, fix-header, config.guess, libio, and
- past C++ library (libg++) maintainer. Dreaming up, designing and
- implementing much of GCJ.
-
- * Devon Bowen helped port GCC to the Tahoe.
-
- * Don Bowman for mips-vxworks contributions.
-
- * James Bowman for the FT32 port.
-
- * Dave Brolley for work on cpplib and Chill.
-
- * Paul Brook for work on the ARM architecture and maintaining GNU
- Fortran.
-
- * Robert Brown implemented the support for Encore 32000 systems.
-
- * Christian Bruel for improvements to local store elimination.
-
- * Herman A.J. ten Brugge for various fixes.
-
- * Joerg Brunsmann for Java compiler hacking and help with the GCJ
- FAQ.
-
- * Joe Buck for his direction via the steering committee from its
- creation to 2013.
-
- * Iain Buclaw for the D frontend.
-
- * Craig Burley for leadership of the G77 Fortran effort.
-
- * Tobias Burnus for contributions to GNU Fortran.
-
- * Stephan Buys for contributing Doxygen notes for libstdc++.
-
- * Paolo Carlini for libstdc++ work: lots of efficiency improvements
- to the C++ strings, streambufs and formatted I/O, hard detective
- work on the frustrating localization issues, and keeping up with
- the problem reports.
-
- * John Carr for his alias work, SPARC hacking, infrastructure
- improvements, previous contributions to the steering committee,
- loop optimizations, etc.
-
- * Stephane Carrez for 68HC11 and 68HC12 ports.
-
- * Steve Chamberlain for support for the Renesas SH and H8 processors
- and the PicoJava processor, and for GCJ config fixes.
-
- * Glenn Chambers for help with the GCJ FAQ.
-
- * John-Marc Chandonia for various libgcj patches.
-
- * Denis Chertykov for contributing and maintaining the AVR port, the
- first GCC port for an 8-bit architecture.
-
- * Kito Cheng for his work on the RISC-V port, including bringing up
- the test suite and maintenance.
-
- * Scott Christley for his Objective-C contributions.
-
- * Eric Christopher for his Java porting help and clean-ups.
-
- * Branko Cibej for more warning contributions.
-
- * The GNU Classpath project for all of their merged runtime code.
-
- * Nick Clifton for arm, mcore, fr30, v850, m32r, msp430 rx work,
- '--help', and other random hacking.
-
- * Michael Cook for libstdc++ cleanup patches to reduce warnings.
-
- * R. Kelley Cook for making GCC buildable from a read-only directory
- as well as other miscellaneous build process and documentation
- clean-ups.
-
- * Ralf Corsepius for SH testing and minor bug fixing.
-
- * Franc,ois-Xavier Coudert for contributions to GNU Fortran.
-
- * Stan Cox for care and feeding of the x86 port and lots of behind
- the scenes hacking.
-
- * Alex Crain provided changes for the 3b1.
-
- * Ian Dall for major improvements to the NS32k port.
-
- * Paul Dale for his work to add uClinux platform support to the m68k
- backend.
-
- * Palmer Dabbelt for his work maintaining the RISC-V port.
-
- * Dario Dariol contributed the four varieties of sample programs that
- print a copy of their source.
-
- * Russell Davidson for fstream and stringstream fixes in libstdc++.
-
- * Bud Davis for work on the G77 and GNU Fortran compilers.
-
- * Mo DeJong for GCJ and libgcj bug fixes.
-
- * Jerry DeLisle for contributions to GNU Fortran.
-
- * DJ Delorie for the DJGPP port, build and libiberty maintenance,
- various bug fixes, and the M32C, MeP, MSP430, and RL78 ports.
-
- * Arnaud Desitter for helping to debug GNU Fortran.
-
- * Gabriel Dos Reis for contributions to G++, contributions and
- maintenance of GCC diagnostics infrastructure, libstdc++-v3,
- including 'valarray<>', 'complex<>', maintaining the numerics
- library (including that pesky '<limits>' :-) and keeping up-to-date
- anything to do with numbers.
-
- * Ulrich Drepper for his work on glibc, testing of GCC using glibc,
- ISO C99 support, CFG dumping support, etc., plus support of the C++
- runtime libraries including for all kinds of C interface issues,
- contributing and maintaining 'complex<>', sanity checking and
- disbursement, configuration architecture, libio maintenance, and
- early math work.
-
- * Franc,ois Dumont for his work on libstdc++-v3, especially
- maintaining and improving 'debug-mode' and associative and
- unordered containers.
-
- * Zdenek Dvorak for a new loop unroller and various fixes.
-
- * Michael Eager for his work on the Xilinx MicroBlaze port.
-
- * Richard Earnshaw for his ongoing work with the ARM.
-
- * David Edelsohn for his direction via the steering committee,
- ongoing work with the RS6000/PowerPC port, help cleaning up Haifa
- loop changes, doing the entire AIX port of libstdc++ with his bare
- hands, and for ensuring GCC properly keeps working on AIX.
-
- * Kevin Ediger for the floating point formatting of num_put::do_put
- in libstdc++.
-
- * Phil Edwards for libstdc++ work including configuration hackery,
- documentation maintainer, chief breaker of the web pages, the
- occasional iostream bug fix, and work on shared library symbol
- versioning.
-
- * Paul Eggert for random hacking all over GCC.
-
- * Mark Elbrecht for various DJGPP improvements, and for libstdc++
- configuration support for locales and fstream-related fixes.
-
- * Vadim Egorov for libstdc++ fixes in strings, streambufs, and
- iostreams.
-
- * Christian Ehrhardt for dealing with bug reports.
-
- * Ben Elliston for his work to move the Objective-C runtime into its
- own subdirectory and for his work on autoconf.
-
- * Revital Eres for work on the PowerPC 750CL port.
-
- * Marc Espie for OpenBSD support.
-
- * Doug Evans for much of the global optimization framework, arc,
- m32r, and SPARC work.
-
- * Christopher Faylor for his work on the Cygwin port and for caring
- and feeding the gcc.gnu.org box and saving its users tons of spam.
-
- * Fred Fish for BeOS support and Ada fixes.
-
- * Ivan Fontes Garcia for the Portuguese translation of the GCJ FAQ.
-
- * Peter Gerwinski for various bug fixes and the Pascal front end.
-
- * Kaveh R. Ghazi for his direction via the steering committee,
- amazing work to make '-W -Wall -W* -Werror' useful, and testing GCC
- on a plethora of platforms. Kaveh extends his gratitude to the
- CAIP Center at Rutgers University for providing him with computing
- resources to work on Free Software from the late 1980s to 2010.
-
- * John Gilmore for a donation to the FSF earmarked improving GNU
- Java.
-
- * Judy Goldberg for c++ contributions.
-
- * Torbjorn Granlund for various fixes and the c-torture testsuite,
- multiply- and divide-by-constant optimization, improved long long
- support, improved leaf function register allocation, and his
- direction via the steering committee.
-
- * Jonny Grant for improvements to 'collect2's' '--help'
- documentation.
-
- * Anthony Green for his '-Os' contributions, the moxie port, and Java
- front end work.
-
- * Stu Grossman for gdb hacking, allowing GCJ developers to debug Java
- code.
-
- * Michael K. Gschwind contributed the port to the PDP-11.
-
- * Richard Biener for his ongoing middle-end contributions and bug
- fixes and for release management.
-
- * Ron Guilmette implemented the 'protoize' and 'unprotoize' tools,
- the support for DWARF 1 symbolic debugging information, and much of
- the support for System V Release 4. He has also worked heavily on
- the Intel 386 and 860 support.
-
- * Sumanth Gundapaneni for contributing the CR16 port.
-
- * Mostafa Hagog for Swing Modulo Scheduling (SMS) and post reload
- GCSE.
-
- * Bruno Haible for improvements in the runtime overhead for EH, new
- warnings and assorted bug fixes.
-
- * Andrew Haley for his amazing Java compiler and library efforts.
-
- * Chris Hanson assisted in making GCC work on HP-UX for the 9000
- series 300.
-
- * Michael Hayes for various thankless work he's done trying to get
- the c30/c40 ports functional. Lots of loop and unroll improvements
- and fixes.
-
- * Dara Hazeghi for wading through myriads of target-specific bug
- reports.
-
- * Kate Hedstrom for staking the G77 folks with an initial testsuite.
-
- * Richard Henderson for his ongoing SPARC, alpha, ia32, and ia64
- work, loop opts, and generally fixing lots of old problems we've
- ignored for years, flow rewrite and lots of further stuff,
- including reviewing tons of patches.
-
- * Aldy Hernandez for working on the PowerPC port, SIMD support, and
- various fixes.
-
- * Nobuyuki Hikichi of Software Research Associates, Tokyo,
- contributed the support for the Sony NEWS machine.
-
- * Kazu Hirata for caring and feeding the Renesas H8/300 port and
- various fixes.
-
- * Katherine Holcomb for work on GNU Fortran.
-
- * Manfred Hollstein for his ongoing work to keep the m88k alive, lots
- of testing and bug fixing, particularly of GCC configury code.
-
- * Steve Holmgren for MachTen patches.
-
- * Mat Hostetter for work on the TILE-Gx and TILEPro ports.
-
- * Jan Hubicka for his x86 port improvements.
-
- * Falk Hueffner for working on C and optimization bug reports.
-
- * Bernardo Innocenti for his m68k work, including merging of ColdFire
- improvements and uClinux support.
-
- * Christian Iseli for various bug fixes.
-
- * Kamil Iskra for general m68k hacking.
-
- * Lee Iverson for random fixes and MIPS testing.
-
- * Balaji V. Iyer for Cilk+ development and merging.
-
- * Andreas Jaeger for testing and benchmarking of GCC and various bug
- fixes.
-
- * Martin Jambor for his work on inter-procedural optimizations, the
- switch conversion pass, and scalar replacement of aggregates.
-
- * Jakub Jelinek for his SPARC work and sibling call optimizations as
- well as lots of bug fixes and test cases, and for improving the
- Java build system.
-
- * Janis Johnson for ia64 testing and fixes, her quality improvement
- sidetracks, and web page maintenance.
-
- * Kean Johnston for SCO OpenServer support and various fixes.
-
- * Tim Josling for the sample language treelang based originally on
- Richard Kenner's "toy" language.
-
- * Nicolai Josuttis for additional libstdc++ documentation.
-
- * Klaus Kaempf for his ongoing work to make alpha-vms a viable
- target.
-
- * Steven G. Kargl for work on GNU Fortran.
-
- * David Kashtan of SRI adapted GCC to VMS.
-
- * Ryszard Kabatek for many, many libstdc++ bug fixes and
- optimizations of strings, especially member functions, and for
- auto_ptr fixes.
-
- * Geoffrey Keating for his ongoing work to make the PPC work for
- GNU/Linux and his automatic regression tester.
-
- * Brendan Kehoe for his ongoing work with G++ and for a lot of early
- work in just about every part of libstdc++.
-
- * Oliver M. Kellogg of Deutsche Aerospace contributed the port to the
- MIL-STD-1750A.
-
- * Richard Kenner of the New York University Ultracomputer Research
- Laboratory wrote the machine descriptions for the AMD 29000, the
- DEC Alpha, the IBM RT PC, and the IBM RS/6000 as well as the
- support for instruction attributes. He also made changes to better
- support RISC processors including changes to common subexpression
- elimination, strength reduction, function calling sequence
- handling, and condition code support, in addition to generalizing
- the code for frame pointer elimination and delay slot scheduling.
- Richard Kenner was also the head maintainer of GCC for several
- years.
-
- * Mumit Khan for various contributions to the Cygwin and Mingw32
- ports and maintaining binary releases for Microsoft Windows hosts,
- and for massive libstdc++ porting work to Cygwin/Mingw32.
-
- * Robin Kirkham for cpu32 support.
-
- * Mark Klein for PA improvements.
-
- * Thomas Koenig for various bug fixes.
-
- * Bruce Korb for the new and improved fixincludes code.
-
- * Benjamin Kosnik for his G++ work and for leading the libstdc++-v3
- effort.
-
- * Maxim Kuvyrkov for contributions to the instruction scheduler, the
- Android and m68k/Coldfire ports, and optimizations.
-
- * Charles LaBrec contributed the support for the Integrated Solutions
- 68020 system.
-
- * Asher Langton and Mike Kumbera for contributing Cray pointer
- support to GNU Fortran, and for other GNU Fortran improvements.
-
- * Jeff Law for his direction via the steering committee, coordinating
- the entire egcs project and GCC 2.95, rolling out snapshots and
- releases, handling merges from GCC2, reviewing tons of patches that
- might have fallen through the cracks else, and random but extensive
- hacking.
-
- * Walter Lee for work on the TILE-Gx and TILEPro ports.
-
- * Marc Lehmann for his direction via the steering committee and
- helping with analysis and improvements of x86 performance.
-
- * Victor Leikehman for work on GNU Fortran.
-
- * Ted Lemon wrote parts of the RTL reader and printer.
-
- * Kriang Lerdsuwanakij for C++ improvements including template as
- template parameter support, and many C++ fixes.
-
- * Warren Levy for tremendous work on libgcj (Java Runtime Library)
- and random work on the Java front end.
-
- * Alain Lichnewsky ported GCC to the MIPS CPU.
-
- * Oskar Liljeblad for hacking on AWT and his many Java bug reports
- and patches.
-
- * Robert Lipe for OpenServer support, new testsuites, testing, etc.
-
- * Chen Liqin for various S+core related fixes/improvement, and for
- maintaining the S+core port.
-
- * Martin Liska for his work on identical code folding, the
- sanitizers, HSA, general bug fixing and for running automated
- regression testing of GCC and reporting numerous bugs.
-
- * Weiwen Liu for testing and various bug fixes.
-
- * Manuel Lo'pez-Iba'n~ez for improving '-Wconversion' and many other
- diagnostics fixes and improvements.
-
- * Dave Love for his ongoing work with the Fortran front end and
- runtime libraries.
-
- * Martin von Lo"wis for internal consistency checking infrastructure,
- various C++ improvements including namespace support, and tons of
- assistance with libstdc++/compiler merges.
-
- * H.J. Lu for his previous contributions to the steering committee,
- many x86 bug reports, prototype patches, and keeping the GNU/Linux
- ports working.
-
- * Greg McGary for random fixes and (someday) bounded pointers.
-
- * Andrew MacLeod for his ongoing work in building a real EH system,
- various code generation improvements, work on the global optimizer,
- etc.
-
- * Vladimir Makarov for hacking some ugly i960 problems, PowerPC
- hacking improvements to compile-time performance, overall knowledge
- and direction in the area of instruction scheduling, design and
- implementation of the automaton based instruction scheduler and
- design and implementation of the integrated and local register
- allocators.
-
- * David Malcolm for his work on improving GCC diagnostics, JIT,
- self-tests and unit testing.
-
- * Bob Manson for his behind the scenes work on dejagnu.
-
- * John Marino for contributing the DragonFly BSD port.
-
- * Philip Martin for lots of libstdc++ string and vector iterator
- fixes and improvements, and string clean up and testsuites.
-
- * Michael Matz for his work on dominance tree discovery, the x86-64
- port, link-time optimization framework and general optimization
- improvements.
-
- * All of the Mauve project contributors for Java test code.
-
- * Bryce McKinlay for numerous GCJ and libgcj fixes and improvements.
-
- * Adam Megacz for his work on the Microsoft Windows port of GCJ.
-
- * Michael Meissner for LRS framework, ia32, m32r, v850, m88k, MIPS,
- powerpc, haifa, ECOFF debug support, and other assorted hacking.
-
- * Jason Merrill for his direction via the steering committee and
- leading the G++ effort.
-
- * Martin Michlmayr for testing GCC on several architectures using the
- entire Debian archive.
-
- * David Miller for his direction via the steering committee, lots of
- SPARC work, improvements in jump.c and interfacing with the Linux
- kernel developers.
-
- * Gary Miller ported GCC to Charles River Data Systems machines.
-
- * Alfred Minarik for libstdc++ string and ios bug fixes, and turning
- the entire libstdc++ testsuite namespace-compatible.
-
- * Mark Mitchell for his direction via the steering committee,
- mountains of C++ work, load/store hoisting out of loops, alias
- analysis improvements, ISO C 'restrict' support, and serving as
- release manager from 2000 to 2011.
-
- * Alan Modra for various GNU/Linux bits and testing.
-
- * Toon Moene for his direction via the steering committee, Fortran
- maintenance, and his ongoing work to make us make Fortran run fast.
-
- * Jason Molenda for major help in the care and feeding of all the
- services on the gcc.gnu.org (formerly egcs.cygnus.com)
- machine--mail, web services, ftp services, etc etc. Doing all this
- work on scrap paper and the backs of envelopes would have been...
- difficult.
-
- * Catherine Moore for fixing various ugly problems we have sent her
- way, including the haifa bug which was killing the Alpha & PowerPC
- Linux kernels.
-
- * Mike Moreton for his various Java patches.
-
- * David Mosberger-Tang for various Alpha improvements, and for the
- initial IA-64 port.
-
- * Stephen Moshier contributed the floating point emulator that
- assists in cross-compilation and permits support for floating point
- numbers wider than 64 bits and for ISO C99 support.
-
- * Bill Moyer for his behind the scenes work on various issues.
-
- * Philippe De Muyter for his work on the m68k port.
-
- * Joseph S. Myers for his work on the PDP-11 port, format checking
- and ISO C99 support, and continuous emphasis on (and contributions
- to) documentation.
-
- * Nathan Myers for his work on libstdc++-v3: architecture and
- authorship through the first three snapshots, including
- implementation of locale infrastructure, string, shadow C headers,
- and the initial project documentation (DESIGN, CHECKLIST, and so
- forth). Later, more work on MT-safe string and shadow headers.
-
- * Felix Natter for documentation on porting libstdc++.
-
- * Nathanael Nerode for cleaning up the configuration/build process.
-
- * NeXT, Inc. donated the front end that supports the Objective-C
- language.
-
- * Hans-Peter Nilsson for the CRIS and MMIX ports, improvements to the
- search engine setup, various documentation fixes and other small
- fixes.
-
- * Geoff Noer for his work on getting cygwin native builds working.
-
- * Vegard Nossum for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Diego Novillo for his work on Tree SSA, OpenMP, SPEC performance
- tracking web pages, GIMPLE tuples, and assorted fixes.
-
- * David O'Brien for the FreeBSD/alpha, FreeBSD/AMD x86-64,
- FreeBSD/ARM, FreeBSD/PowerPC, and FreeBSD/SPARC64 ports and related
- infrastructure improvements.
-
- * Alexandre Oliva for various build infrastructure improvements,
- scripts and amazing testing work, including keeping libtool issues
- sane and happy.
-
- * Stefan Olsson for work on mt_alloc.
-
- * Melissa O'Neill for various NeXT fixes.
-
- * Rainer Orth for random MIPS work, including improvements to GCC's
- o32 ABI support, improvements to dejagnu's MIPS support, Java
- configuration clean-ups and porting work, and maintaining the IRIX,
- Solaris 2, and Tru64 UNIX ports.
-
- * Steven Pemberton for his contribution of 'enquire' which allowed
- GCC to determine various properties of the floating point unit and
- generate 'float.h' in older versions of GCC.
-
- * Hartmut Penner for work on the s390 port.
-
- * Paul Petersen wrote the machine description for the Alliant FX/8.
-
- * Alexandre Petit-Bianco for implementing much of the Java compiler
- and continued Java maintainership.
-
- * Matthias Pfaller for major improvements to the NS32k port.
-
- * Gerald Pfeifer for his direction via the steering committee,
- pointing out lots of problems we need to solve, maintenance of the
- web pages, and taking care of documentation maintenance in general.
-
- * Marek Polacek for his work on the C front end, the sanitizers and
- general bug fixing.
-
- * Andrew Pinski for processing bug reports by the dozen.
-
- * Ovidiu Predescu for his work on the Objective-C front end and
- runtime libraries.
-
- * Jerry Quinn for major performance improvements in C++ formatted
- I/O.
-
- * Ken Raeburn for various improvements to checker, MIPS ports and
- various cleanups in the compiler.
-
- * Rolf W. Rasmussen for hacking on AWT.
-
- * David Reese of Sun Microsystems contributed to the Solaris on
- PowerPC port.
-
- * John Regehr for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Volker Reichelt for running automated regression testing of GCC and
- reporting numerous bugs and for keeping up with the problem
- reports.
-
- * Joern Rennecke for maintaining the sh port, loop, regmove & reload
- hacking and developing and maintaining the Epiphany port.
-
- * Loren J. Rittle for improvements to libstdc++-v3 including the
- FreeBSD port, threading fixes, thread-related configury changes,
- critical threading documentation, and solutions to really tricky
- I/O problems, as well as keeping GCC properly working on FreeBSD
- and continuous testing.
-
- * Craig Rodrigues for processing tons of bug reports.
-
- * Ola Ro"nnerup for work on mt_alloc.
-
- * Gavin Romig-Koch for lots of behind the scenes MIPS work.
-
- * David Ronis inspired and encouraged Craig to rewrite the G77
- documentation in texinfo format by contributing a first pass at a
- translation of the old 'g77-0.5.16/f/DOC' file.
-
- * Ken Rose for fixes to GCC's delay slot filling code.
-
- * Ira Rosen for her contributions to the auto-vectorizer.
-
- * Paul Rubin wrote most of the preprocessor.
-
- * Pe'tur Runo'lfsson for major performance improvements in C++
- formatted I/O and large file support in C++ filebuf.
-
- * Chip Salzenberg for libstdc++ patches and improvements to locales,
- traits, Makefiles, libio, libtool hackery, and "long long" support.
-
- * Juha Sarlin for improvements to the H8 code generator.
-
- * Greg Satz assisted in making GCC work on HP-UX for the 9000 series
- 300.
-
- * Roger Sayle for improvements to constant folding and GCC's RTL
- optimizers as well as for fixing numerous bugs.
-
- * Bradley Schatz for his work on the GCJ FAQ.
-
- * Peter Schauer wrote the code to allow debugging to work on the
- Alpha.
-
- * William Schelter did most of the work on the Intel 80386 support.
-
- * Tobias Schlu"ter for work on GNU Fortran.
-
- * Bernd Schmidt for various code generation improvements and major
- work in the reload pass, serving as release manager for GCC 2.95.3,
- and work on the Blackfin and C6X ports.
-
- * Peter Schmid for constant testing of libstdc++--especially
- application testing, going above and beyond what was requested for
- the release criteria--and libstdc++ header file tweaks.
-
- * Jason Schroeder for jcf-dump patches.
-
- * Andreas Schwab for his work on the m68k port.
-
- * Lars Segerlund for work on GNU Fortran.
-
- * Dodji Seketeli for numerous C++ bug fixes and debug info
- improvements.
-
- * Tim Shen for major work on '<regex>'.
-
- * Joel Sherrill for his direction via the steering committee, RTEMS
- contributions and RTEMS testing.
-
- * Nathan Sidwell for many C++ fixes/improvements.
-
- * Jeffrey Siegal for helping RMS with the original design of GCC,
- some code which handles the parse tree and RTL data structures,
- constant folding and help with the original VAX & m68k ports.
-
- * Kenny Simpson for prompting libstdc++ fixes due to defect reports
- from the LWG (thereby keeping GCC in line with updates from the
- ISO).
-
- * Franz Sirl for his ongoing work with making the PPC port stable for
- GNU/Linux.
-
- * Andrey Slepuhin for assorted AIX hacking.
-
- * Trevor Smigiel for contributing the SPU port.
-
- * Christopher Smith did the port for Convex machines.
-
- * Danny Smith for his major efforts on the Mingw (and Cygwin) ports.
- Retired from GCC maintainership August 2010, having mentored two
- new maintainers into the role.
-
- * Randy Smith finished the Sun FPA support.
-
- * Ed Smith-Rowland for his continuous work on libstdc++-v3, special
- functions, '<random>', and various improvements to C++11 features.
-
- * Scott Snyder for queue, iterator, istream, and string fixes and
- libstdc++ testsuite entries. Also for providing the patch to G77
- to add rudimentary support for 'INTEGER*1', 'INTEGER*2', and
- 'LOGICAL*1'.
-
- * Zdenek Sojka for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Arseny Solokha for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Jayant Sonar for contributing the CR16 port.
-
- * Brad Spencer for contributions to the GLIBCPP_FORCE_NEW technique.
-
- * Richard Stallman, for writing the original GCC and launching the
- GNU project.
-
- * Jan Stein of the Chalmers Computer Society provided support for
- Genix, as well as part of the 32000 machine description.
-
- * Gerhard Steinmetz for running automated regression testing of GCC
- and reporting numerous bugs.
-
- * Nigel Stephens for various mips16 related fixes/improvements.
-
- * Jonathan Stone wrote the machine description for the Pyramid
- computer.
-
- * Graham Stott for various infrastructure improvements.
-
- * John Stracke for his Java HTTP protocol fixes.
-
- * Mike Stump for his Elxsi port, G++ contributions over the years and
- more recently his vxworks contributions
-
- * Jeff Sturm for Java porting help, bug fixes, and encouragement.
-
- * Zhendong Su for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Chengnian Sun for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Shigeya Suzuki for this fixes for the bsdi platforms.
-
- * Ian Lance Taylor for the Go frontend, the initial mips16 and mips64
- support, general configury hacking, fixincludes, etc.
-
- * Holger Teutsch provided the support for the Clipper CPU.
-
- * Gary Thomas for his ongoing work to make the PPC work for
- GNU/Linux.
-
- * Paul Thomas for contributions to GNU Fortran.
-
- * Philipp Thomas for random bug fixes throughout the compiler
-
- * Jason Thorpe for thread support in libstdc++ on NetBSD.
-
- * Kresten Krab Thorup wrote the run time support for the Objective-C
- language and the fantastic Java bytecode interpreter.
-
- * Michael Tiemann for random bug fixes, the first instruction
- scheduler, initial C++ support, function integration, NS32k, SPARC
- and M88k machine description work, delay slot scheduling.
-
- * Andreas Tobler for his work porting libgcj to Darwin.
-
- * Teemu Torma for thread safe exception handling support.
-
- * Leonard Tower wrote parts of the parser, RTL generator, and RTL
- definitions, and of the VAX machine description.
-
- * Daniel Towner and Hariharan Sandanagobalane contributed and
- maintain the picoChip port.
-
- * Tom Tromey for internationalization support and for his many Java
- contributions and libgcj maintainership.
-
- * Lassi Tuura for improvements to config.guess to determine HP
- processor types.
-
- * Petter Urkedal for libstdc++ CXXFLAGS, math, and algorithms fixes.
-
- * Andy Vaught for the design and initial implementation of the GNU
- Fortran front end.
-
- * Brent Verner for work with the libstdc++ cshadow files and their
- associated configure steps.
-
- * Todd Vierling for contributions for NetBSD ports.
-
- * Andrew Waterman for contributing the RISC-V port, as well as
- maintaining it.
-
- * Jonathan Wakely for contributing libstdc++ Doxygen notes and XHTML
- guidance and maintaining libstdc++.
-
- * Dean Wakerley for converting the install documentation from HTML to
- texinfo in time for GCC 3.0.
-
- * Krister Walfridsson for random bug fixes.
-
- * Feng Wang for contributions to GNU Fortran.
-
- * Stephen M. Webb for time and effort on making libstdc++ shadow
- files work with the tricky Solaris 8+ headers, and for pushing the
- build-time header tree. Also, for starting and driving the
- '<regex>' effort.
-
- * John Wehle for various improvements for the x86 code generator,
- related infrastructure improvements to help x86 code generation,
- value range propagation and other work, WE32k port.
-
- * Ulrich Weigand for work on the s390 port.
-
- * Janus Weil for contributions to GNU Fortran.
-
- * Zack Weinberg for major work on cpplib and various other bug fixes.
-
- * Matt Welsh for help with Linux Threads support in GCJ.
-
- * Urban Widmark for help fixing java.io.
-
- * Mark Wielaard for new Java library code and his work integrating
- with Classpath.
-
- * Dale Wiles helped port GCC to the Tahoe.
-
- * Bob Wilson from Tensilica, Inc. for the Xtensa port.
-
- * Jim Wilson for his direction via the steering committee, tackling
- hard problems in various places that nobody else wanted to work on,
- strength reduction and other loop optimizations.
-
- * Paul Woegerer and Tal Agmon for the CRX port.
-
- * Carlo Wood for various fixes.
-
- * Tom Wood for work on the m88k port.
-
- * Chung-Ju Wu for his work on the Andes NDS32 port.
-
- * Canqun Yang for work on GNU Fortran.
-
- * Masanobu Yuhara of Fujitsu Laboratories implemented the machine
- description for the Tron architecture (specifically, the Gmicro).
-
- * Kevin Zachmann helped port GCC to the Tahoe.
-
- * Ayal Zaks for Swing Modulo Scheduling (SMS).
-
- * Qirun Zhang for running automated regression testing of GCC and
- reporting numerous bugs.
-
- * Xiaoqiang Zhang for work on GNU Fortran.
-
- * Gilles Zunino for help porting Java to Irix.
-
- The following people are recognized for their contributions to GNAT,
- the Ada front end of GCC:
- * Bernard Banner
-
- * Romain Berrendonner
-
- * Geert Bosch
-
- * Emmanuel Briot
-
- * Joel Brobecker
-
- * Ben Brosgol
-
- * Vincent Celier
-
- * Arnaud Charlet
-
- * Chien Chieng
-
- * Cyrille Comar
-
- * Cyrille Crozes
-
- * Robert Dewar
-
- * Gary Dismukes
-
- * Robert Duff
-
- * Ed Falis
-
- * Ramon Fernandez
-
- * Sam Figueroa
-
- * Vasiliy Fofanov
-
- * Michael Friess
-
- * Franco Gasperoni
-
- * Ted Giering
-
- * Matthew Gingell
-
- * Laurent Guerby
-
- * Jerome Guitton
-
- * Olivier Hainque
-
- * Jerome Hugues
-
- * Hristian Kirtchev
-
- * Jerome Lambourg
-
- * Bruno Leclerc
-
- * Albert Lee
-
- * Sean McNeil
-
- * Javier Miranda
-
- * Laurent Nana
-
- * Pascal Obry
-
- * Dong-Ik Oh
-
- * Laurent Pautet
-
- * Brett Porter
-
- * Thomas Quinot
-
- * Nicolas Roche
-
- * Pat Rogers
-
- * Jose Ruiz
-
- * Douglas Rupp
-
- * Sergey Rybin
-
- * Gail Schenker
-
- * Ed Schonberg
-
- * Nicolas Setton
-
- * Samuel Tardieu
-
- The following people are recognized for their contributions of new
- features, bug reports, testing and integration of classpath/libgcj for
- GCC version 4.1:
- * Lillian Angel for 'JTree' implementation and lots Free Swing
- additions and bug fixes.
-
- * Wolfgang Baer for 'GapContent' bug fixes.
-
- * Anthony Balkissoon for 'JList', Free Swing 1.5 updates and mouse
- event fixes, lots of Free Swing work including 'JTable' editing.
-
- * Stuart Ballard for RMI constant fixes.
-
- * Goffredo Baroncelli for 'HTTPURLConnection' fixes.
-
- * Gary Benson for 'MessageFormat' fixes.
-
- * Daniel Bonniot for 'Serialization' fixes.
-
- * Chris Burdess for lots of gnu.xml and http protocol fixes, 'StAX'
- and 'DOM xml:id' support.
-
- * Ka-Hing Cheung for 'TreePath' and 'TreeSelection' fixes.
-
- * Archie Cobbs for build fixes, VM interface updates,
- 'URLClassLoader' updates.
-
- * Kelley Cook for build fixes.
-
- * Martin Cordova for Suggestions for better 'SocketTimeoutException'.
-
- * David Daney for 'BitSet' bug fixes, 'HttpURLConnection' rewrite and
- improvements.
-
- * Thomas Fitzsimmons for lots of upgrades to the gtk+ AWT and Cairo
- 2D support. Lots of imageio framework additions, lots of AWT and
- Free Swing bug fixes.
-
- * Jeroen Frijters for 'ClassLoader' and nio cleanups, serialization
- fixes, better 'Proxy' support, bug fixes and IKVM integration.
-
- * Santiago Gala for 'AccessControlContext' fixes.
-
- * Nicolas Geoffray for 'VMClassLoader' and 'AccessController'
- improvements.
-
- * David Gilbert for 'basic' and 'metal' icon and plaf support and
- lots of documenting, Lots of Free Swing and metal theme additions.
- 'MetalIconFactory' implementation.
-
- * Anthony Green for 'MIDI' framework, 'ALSA' and 'DSSI' providers.
-
- * Andrew Haley for 'Serialization' and 'URLClassLoader' fixes, gcj
- build speedups.
-
- * Kim Ho for 'JFileChooser' implementation.
-
- * Andrew John Hughes for 'Locale' and net fixes, URI RFC2986 updates,
- 'Serialization' fixes, 'Properties' XML support and generic branch
- work, VMIntegration guide update.
-
- * Bastiaan Huisman for 'TimeZone' bug fixing.
-
- * Andreas Jaeger for mprec updates.
-
- * Paul Jenner for better '-Werror' support.
-
- * Ito Kazumitsu for 'NetworkInterface' implementation and updates.
-
- * Roman Kennke for 'BoxLayout', 'GrayFilter' and 'SplitPane', plus
- bug fixes all over. Lots of Free Swing work including styled text.
-
- * Simon Kitching for 'String' cleanups and optimization suggestions.
-
- * Michael Koch for configuration fixes, 'Locale' updates, bug and
- build fixes.
-
- * Guilhem Lavaux for configuration, thread and channel fixes and
- Kaffe integration. JCL native 'Pointer' updates. Logger bug
- fixes.
-
- * David Lichteblau for JCL support library global/local reference
- cleanups.
-
- * Aaron Luchko for JDWP updates and documentation fixes.
-
- * Ziga Mahkovec for 'Graphics2D' upgraded to Cairo 0.5 and new regex
- features.
-
- * Sven de Marothy for BMP imageio support, CSS and 'TextLayout'
- fixes. 'GtkImage' rewrite, 2D, awt, free swing and date/time fixes
- and implementing the Qt4 peers.
-
- * Casey Marshall for crypto algorithm fixes, 'FileChannel' lock,
- 'SystemLogger' and 'FileHandler' rotate implementations, NIO
- 'FileChannel.map' support, security and policy updates.
-
- * Bryce McKinlay for RMI work.
-
- * Audrius Meskauskas for lots of Free Corba, RMI and HTML work plus
- testing and documenting.
-
- * Kalle Olavi Niemitalo for build fixes.
-
- * Rainer Orth for build fixes.
-
- * Andrew Overholt for 'File' locking fixes.
-
- * Ingo Proetel for 'Image', 'Logger' and 'URLClassLoader' updates.
-
- * Olga Rodimina for 'MenuSelectionManager' implementation.
-
- * Jan Roehrich for 'BasicTreeUI' and 'JTree' fixes.
-
- * Julian Scheid for documentation updates and gjdoc support.
-
- * Christian Schlichtherle for zip fixes and cleanups.
-
- * Robert Schuster for documentation updates and beans fixes,
- 'TreeNode' enumerations and 'ActionCommand' and various fixes, XML
- and URL, AWT and Free Swing bug fixes.
-
- * Keith Seitz for lots of JDWP work.
-
- * Christian Thalinger for 64-bit cleanups, Configuration and VM
- interface fixes and 'CACAO' integration, 'fdlibm' updates.
-
- * Gael Thomas for 'VMClassLoader' boot packages support suggestions.
-
- * Andreas Tobler for Darwin and Solaris testing and fixing, 'Qt4'
- support for Darwin/OS X, 'Graphics2D' support, 'gtk+' updates.
-
- * Dalibor Topic for better 'DEBUG' support, build cleanups and Kaffe
- integration. 'Qt4' build infrastructure, 'SHA1PRNG' and
- 'GdkPixbugDecoder' updates.
-
- * Tom Tromey for Eclipse integration, generics work, lots of bug
- fixes and gcj integration including coordinating The Big Merge.
-
- * Mark Wielaard for bug fixes, packaging and release management,
- 'Clipboard' implementation, system call interrupts and network
- timeouts and 'GdkPixpufDecoder' fixes.
-
- In addition to the above, all of which also contributed time and energy
- in testing GCC, we would like to thank the following for their
- contributions to testing:
-
- * Michael Abd-El-Malek
-
- * Thomas Arend
-
- * Bonzo Armstrong
-
- * Steven Ashe
-
- * Chris Baldwin
-
- * David Billinghurst
-
- * Jim Blandy
-
- * Stephane Bortzmeyer
-
- * Horst von Brand
-
- * Frank Braun
-
- * Rodney Brown
-
- * Sidney Cadot
-
- * Bradford Castalia
-
- * Robert Clark
-
- * Jonathan Corbet
-
- * Ralph Doncaster
-
- * Richard Emberson
-
- * Levente Farkas
-
- * Graham Fawcett
-
- * Mark Fernyhough
-
- * Robert A. French
-
- * Jo"rgen Freyh
-
- * Mark K. Gardner
-
- * Charles-Antoine Gauthier
-
- * Yung Shing Gene
-
- * David Gilbert
-
- * Simon Gornall
-
- * Fred Gray
-
- * John Griffin
-
- * Patrik Hagglund
-
- * Phil Hargett
-
- * Amancio Hasty
-
- * Takafumi Hayashi
-
- * Bryan W. Headley
-
- * Kevin B. Hendricks
-
- * Joep Jansen
-
- * Christian Joensson
-
- * Michel Kern
-
- * David Kidd
-
- * Tobias Kuipers
-
- * Anand Krishnaswamy
-
- * A. O. V. Le Blanc
-
- * llewelly
-
- * Damon Love
-
- * Brad Lucier
-
- * Matthias Klose
-
- * Martin Knoblauch
-
- * Rick Lutowski
-
- * Jesse Macnish
-
- * Stefan Morrell
-
- * Anon A. Mous
-
- * Matthias Mueller
-
- * Pekka Nikander
-
- * Rick Niles
-
- * Jon Olson
-
- * Magnus Persson
-
- * Chris Pollard
-
- * Richard Polton
-
- * Derk Reefman
-
- * David Rees
-
- * Paul Reilly
-
- * Tom Reilly
-
- * Torsten Rueger
-
- * Danny Sadinoff
-
- * Marc Schifer
-
- * Erik Schnetter
-
- * Wayne K. Schroll
-
- * David Schuler
-
- * Vin Shelton
-
- * Tim Souder
-
- * Adam Sulmicki
-
- * Bill Thorson
-
- * George Talbot
-
- * Pedro A. M. Vazquez
-
- * Gregory Warnes
-
- * Ian Watson
-
- * David E. Young
-
- * And many others
-
- And finally we'd like to thank everyone who uses the compiler, provides
- feedback and generally reminds us why we're doing this work in the first
- place.
-
-
- File: gccint.info, Node: Option Index, Next: Concept Index, Prev: Contributors, Up: Top
-
- Option Index
- ************
-
- GCC's command line options are indexed here without any initial '-' or
- '--'. Where an option has both positive and negative forms (such as
- '-fOPTION' and '-fno-OPTION'), relevant entries in the manual are
- indexed under the most appropriate form; it may sometimes be useful to
- look up both forms.
-
- �[index�]
- * Menu:
-
- * fltrans: Internal flags. (line 18)
- * fltrans-output-list: Internal flags. (line 23)
- * fresolution: Internal flags. (line 27)
- * fwpa: Internal flags. (line 9)
- * msoft-float: Soft float library routines.
- (line 6)
-
-
- File: gccint.info, Node: Concept Index, Prev: Option Index, Up: Top
-
- Concept Index
- *************
-
- �[index�]
- * Menu:
-
- * ! in constraint: Multi-Alternative. (line 48)
- * # in constraint: Modifiers. (line 78)
- * # in template: Output Template. (line 66)
- * #pragma: Misc. (line 420)
- * $ in constraint: Multi-Alternative. (line 57)
- * % in constraint: Modifiers. (line 52)
- * % in GTY option: GTY Options. (line 18)
- * % in template: Output Template. (line 6)
- * & in constraint: Modifiers. (line 25)
- * (gimple: Logical Operators. (line 169)
- * (gimple <1>: Logical Operators. (line 173)
- * (gimple <2>: Logical Operators. (line 177)
- * (gimple_stmt_iterator: GIMPLE API. (line 30)
- * (nil): RTL Objects. (line 73)
- * * in constraint: Modifiers. (line 83)
- * * in template: Output Statement. (line 29)
- * *gimple_build_asm_vec: GIMPLE_ASM. (line 6)
- * *gimple_build_assign: GIMPLE_ASSIGN. (line 6)
- * *gimple_build_assign <1>: GIMPLE_ASSIGN. (line 18)
- * *gimple_build_assign <2>: GIMPLE_ASSIGN. (line 29)
- * *gimple_build_assign <3>: GIMPLE_ASSIGN. (line 35)
- * *gimple_build_bind: GIMPLE_BIND. (line 6)
- * *gimple_build_call: GIMPLE_CALL. (line 6)
- * *gimple_build_call_from_tree: GIMPLE_CALL. (line 15)
- * *gimple_build_call_vec: GIMPLE_CALL. (line 25)
- * *gimple_build_catch: GIMPLE_CATCH. (line 6)
- * *gimple_build_cond: GIMPLE_COND. (line 6)
- * *gimple_build_cond_from_tree: GIMPLE_COND. (line 14)
- * *gimple_build_debug_bind: GIMPLE_DEBUG. (line 6)
- * *gimple_build_eh_filter: GIMPLE_EH_FILTER. (line 6)
- * *gimple_build_goto: GIMPLE_GOTO. (line 6)
- * *gimple_build_label: GIMPLE_LABEL. (line 6)
- * *gimple_build_omp_atomic_load: GIMPLE_OMP_ATOMIC_LOAD.
- (line 6)
- * *gimple_build_omp_atomic_store: GIMPLE_OMP_ATOMIC_STORE.
- (line 6)
- * *gimple_build_omp_continue: GIMPLE_OMP_CONTINUE.
- (line 6)
- * *gimple_build_omp_critical: GIMPLE_OMP_CRITICAL.
- (line 6)
- * *gimple_build_omp_for: GIMPLE_OMP_FOR. (line 6)
- * *gimple_build_omp_parallel: GIMPLE_OMP_PARALLEL.
- (line 6)
- * *gimple_build_omp_sections: GIMPLE_OMP_SECTIONS.
- (line 6)
- * *gimple_build_omp_single: GIMPLE_OMP_SINGLE. (line 6)
- * *gimple_build_resx: GIMPLE_RESX. (line 6)
- * *gimple_build_return: GIMPLE_RETURN. (line 6)
- * *gimple_build_switch: GIMPLE_SWITCH. (line 6)
- * *gimple_build_try: GIMPLE_TRY. (line 6)
- * + in constraint: Modifiers. (line 12)
- * -fsection-anchors: Special Accessors. (line 117)
- * -fsection-anchors <1>: Anchored Addresses. (line 6)
- * /c in RTL dump: Flags. (line 230)
- * /f in RTL dump: Flags. (line 238)
- * /i in RTL dump: Flags. (line 283)
- * /j in RTL dump: Flags. (line 295)
- * /s in RTL dump: Flags. (line 254)
- * /u in RTL dump: Flags. (line 307)
- * /v in RTL dump: Flags. (line 339)
- * 0 in constraint: Simple Constraints. (line 128)
- * < in constraint: Simple Constraints. (line 47)
- * = in constraint: Modifiers. (line 8)
- * > in constraint: Simple Constraints. (line 59)
- * ? in constraint: Multi-Alternative. (line 42)
- * @ in instruction pattern names: Parameterized Names.
- (line 6)
- * \: Output Template. (line 46)
- * ^ in constraint: Multi-Alternative. (line 53)
- * __absvdi2: Integer library routines.
- (line 106)
- * __absvsi2: Integer library routines.
- (line 105)
- * __addda3: Fixed-point fractional library routines.
- (line 52)
- * __adddf3: Soft float library routines.
- (line 22)
- * __adddq3: Fixed-point fractional library routines.
- (line 39)
- * __addha3: Fixed-point fractional library routines.
- (line 49)
- * __addhq3: Fixed-point fractional library routines.
- (line 37)
- * __addqq3: Fixed-point fractional library routines.
- (line 35)
- * __addsa3: Fixed-point fractional library routines.
- (line 51)
- * __addsf3: Soft float library routines.
- (line 21)
- * __addsq3: Fixed-point fractional library routines.
- (line 38)
- * __addta3: Fixed-point fractional library routines.
- (line 53)
- * __addtf3: Soft float library routines.
- (line 23)
- * __adduda3: Fixed-point fractional library routines.
- (line 59)
- * __addudq3: Fixed-point fractional library routines.
- (line 47)
- * __adduha3: Fixed-point fractional library routines.
- (line 55)
- * __adduhq3: Fixed-point fractional library routines.
- (line 43)
- * __adduqq3: Fixed-point fractional library routines.
- (line 41)
- * __addusa3: Fixed-point fractional library routines.
- (line 57)
- * __addusq3: Fixed-point fractional library routines.
- (line 45)
- * __adduta3: Fixed-point fractional library routines.
- (line 61)
- * __addvdi3: Integer library routines.
- (line 110)
- * __addvsi3: Integer library routines.
- (line 109)
- * __addxf3: Soft float library routines.
- (line 25)
- * __ashlda3: Fixed-point fractional library routines.
- (line 358)
- * __ashldi3: Integer library routines.
- (line 13)
- * __ashldq3: Fixed-point fractional library routines.
- (line 346)
- * __ashlha3: Fixed-point fractional library routines.
- (line 356)
- * __ashlhq3: Fixed-point fractional library routines.
- (line 344)
- * __ashlqq3: Fixed-point fractional library routines.
- (line 343)
- * __ashlsa3: Fixed-point fractional library routines.
- (line 357)
- * __ashlsi3: Integer library routines.
- (line 12)
- * __ashlsq3: Fixed-point fractional library routines.
- (line 345)
- * __ashlta3: Fixed-point fractional library routines.
- (line 359)
- * __ashlti3: Integer library routines.
- (line 14)
- * __ashluda3: Fixed-point fractional library routines.
- (line 365)
- * __ashludq3: Fixed-point fractional library routines.
- (line 354)
- * __ashluha3: Fixed-point fractional library routines.
- (line 361)
- * __ashluhq3: Fixed-point fractional library routines.
- (line 350)
- * __ashluqq3: Fixed-point fractional library routines.
- (line 348)
- * __ashlusa3: Fixed-point fractional library routines.
- (line 363)
- * __ashlusq3: Fixed-point fractional library routines.
- (line 352)
- * __ashluta3: Fixed-point fractional library routines.
- (line 367)
- * __ashrda3: Fixed-point fractional library routines.
- (line 378)
- * __ashrdi3: Integer library routines.
- (line 18)
- * __ashrdq3: Fixed-point fractional library routines.
- (line 374)
- * __ashrha3: Fixed-point fractional library routines.
- (line 376)
- * __ashrhq3: Fixed-point fractional library routines.
- (line 372)
- * __ashrqq3: Fixed-point fractional library routines.
- (line 371)
- * __ashrsa3: Fixed-point fractional library routines.
- (line 377)
- * __ashrsi3: Integer library routines.
- (line 17)
- * __ashrsq3: Fixed-point fractional library routines.
- (line 373)
- * __ashrta3: Fixed-point fractional library routines.
- (line 379)
- * __ashrti3: Integer library routines.
- (line 19)
- * __bid_adddd3: Decimal float library routines.
- (line 23)
- * __bid_addsd3: Decimal float library routines.
- (line 19)
- * __bid_addtd3: Decimal float library routines.
- (line 27)
- * __bid_divdd3: Decimal float library routines.
- (line 66)
- * __bid_divsd3: Decimal float library routines.
- (line 62)
- * __bid_divtd3: Decimal float library routines.
- (line 70)
- * __bid_eqdd2: Decimal float library routines.
- (line 258)
- * __bid_eqsd2: Decimal float library routines.
- (line 256)
- * __bid_eqtd2: Decimal float library routines.
- (line 260)
- * __bid_extendddtd2: Decimal float library routines.
- (line 91)
- * __bid_extendddtf: Decimal float library routines.
- (line 139)
- * __bid_extendddxf: Decimal float library routines.
- (line 133)
- * __bid_extenddfdd: Decimal float library routines.
- (line 146)
- * __bid_extenddftd: Decimal float library routines.
- (line 106)
- * __bid_extendsddd2: Decimal float library routines.
- (line 87)
- * __bid_extendsddf: Decimal float library routines.
- (line 127)
- * __bid_extendsdtd2: Decimal float library routines.
- (line 89)
- * __bid_extendsdtf: Decimal float library routines.
- (line 137)
- * __bid_extendsdxf: Decimal float library routines.
- (line 131)
- * __bid_extendsfdd: Decimal float library routines.
- (line 102)
- * __bid_extendsfsd: Decimal float library routines.
- (line 144)
- * __bid_extendsftd: Decimal float library routines.
- (line 104)
- * __bid_extendtftd: Decimal float library routines.
- (line 148)
- * __bid_extendxftd: Decimal float library routines.
- (line 108)
- * __bid_fixdddi: Decimal float library routines.
- (line 169)
- * __bid_fixddsi: Decimal float library routines.
- (line 161)
- * __bid_fixsddi: Decimal float library routines.
- (line 167)
- * __bid_fixsdsi: Decimal float library routines.
- (line 159)
- * __bid_fixtddi: Decimal float library routines.
- (line 171)
- * __bid_fixtdsi: Decimal float library routines.
- (line 163)
- * __bid_fixunsdddi: Decimal float library routines.
- (line 186)
- * __bid_fixunsddsi: Decimal float library routines.
- (line 177)
- * __bid_fixunssddi: Decimal float library routines.
- (line 184)
- * __bid_fixunssdsi: Decimal float library routines.
- (line 175)
- * __bid_fixunstddi: Decimal float library routines.
- (line 188)
- * __bid_fixunstdsi: Decimal float library routines.
- (line 179)
- * __bid_floatdidd: Decimal float library routines.
- (line 204)
- * __bid_floatdisd: Decimal float library routines.
- (line 202)
- * __bid_floatditd: Decimal float library routines.
- (line 206)
- * __bid_floatsidd: Decimal float library routines.
- (line 195)
- * __bid_floatsisd: Decimal float library routines.
- (line 193)
- * __bid_floatsitd: Decimal float library routines.
- (line 197)
- * __bid_floatunsdidd: Decimal float library routines.
- (line 222)
- * __bid_floatunsdisd: Decimal float library routines.
- (line 220)
- * __bid_floatunsditd: Decimal float library routines.
- (line 224)
- * __bid_floatunssidd: Decimal float library routines.
- (line 213)
- * __bid_floatunssisd: Decimal float library routines.
- (line 211)
- * __bid_floatunssitd: Decimal float library routines.
- (line 215)
- * __bid_gedd2: Decimal float library routines.
- (line 276)
- * __bid_gesd2: Decimal float library routines.
- (line 274)
- * __bid_getd2: Decimal float library routines.
- (line 278)
- * __bid_gtdd2: Decimal float library routines.
- (line 303)
- * __bid_gtsd2: Decimal float library routines.
- (line 301)
- * __bid_gttd2: Decimal float library routines.
- (line 305)
- * __bid_ledd2: Decimal float library routines.
- (line 294)
- * __bid_lesd2: Decimal float library routines.
- (line 292)
- * __bid_letd2: Decimal float library routines.
- (line 296)
- * __bid_ltdd2: Decimal float library routines.
- (line 285)
- * __bid_ltsd2: Decimal float library routines.
- (line 283)
- * __bid_lttd2: Decimal float library routines.
- (line 287)
- * __bid_muldd3: Decimal float library routines.
- (line 52)
- * __bid_mulsd3: Decimal float library routines.
- (line 48)
- * __bid_multd3: Decimal float library routines.
- (line 56)
- * __bid_nedd2: Decimal float library routines.
- (line 267)
- * __bid_negdd2: Decimal float library routines.
- (line 77)
- * __bid_negsd2: Decimal float library routines.
- (line 75)
- * __bid_negtd2: Decimal float library routines.
- (line 79)
- * __bid_nesd2: Decimal float library routines.
- (line 265)
- * __bid_netd2: Decimal float library routines.
- (line 269)
- * __bid_subdd3: Decimal float library routines.
- (line 37)
- * __bid_subsd3: Decimal float library routines.
- (line 33)
- * __bid_subtd3: Decimal float library routines.
- (line 41)
- * __bid_truncdddf: Decimal float library routines.
- (line 152)
- * __bid_truncddsd2: Decimal float library routines.
- (line 93)
- * __bid_truncddsf: Decimal float library routines.
- (line 123)
- * __bid_truncdfsd: Decimal float library routines.
- (line 110)
- * __bid_truncsdsf: Decimal float library routines.
- (line 150)
- * __bid_trunctddd2: Decimal float library routines.
- (line 97)
- * __bid_trunctddf: Decimal float library routines.
- (line 129)
- * __bid_trunctdsd2: Decimal float library routines.
- (line 95)
- * __bid_trunctdsf: Decimal float library routines.
- (line 125)
- * __bid_trunctdtf: Decimal float library routines.
- (line 154)
- * __bid_trunctdxf: Decimal float library routines.
- (line 135)
- * __bid_trunctfdd: Decimal float library routines.
- (line 118)
- * __bid_trunctfsd: Decimal float library routines.
- (line 114)
- * __bid_truncxfdd: Decimal float library routines.
- (line 116)
- * __bid_truncxfsd: Decimal float library routines.
- (line 112)
- * __bid_unorddd2: Decimal float library routines.
- (line 234)
- * __bid_unordsd2: Decimal float library routines.
- (line 232)
- * __bid_unordtd2: Decimal float library routines.
- (line 236)
- * __bswapdi2: Integer library routines.
- (line 161)
- * __bswapsi2: Integer library routines.
- (line 160)
- * __builtin_classify_type: Varargs. (line 48)
- * __builtin_next_arg: Varargs. (line 39)
- * __builtin_saveregs: Varargs. (line 22)
- * __clear_cache: Miscellaneous routines.
- (line 9)
- * __clzdi2: Integer library routines.
- (line 130)
- * __clzsi2: Integer library routines.
- (line 129)
- * __clzti2: Integer library routines.
- (line 131)
- * __cmpda2: Fixed-point fractional library routines.
- (line 458)
- * __cmpdf2: Soft float library routines.
- (line 163)
- * __cmpdi2: Integer library routines.
- (line 86)
- * __cmpdq2: Fixed-point fractional library routines.
- (line 447)
- * __cmpha2: Fixed-point fractional library routines.
- (line 456)
- * __cmphq2: Fixed-point fractional library routines.
- (line 445)
- * __cmpqq2: Fixed-point fractional library routines.
- (line 444)
- * __cmpsa2: Fixed-point fractional library routines.
- (line 457)
- * __cmpsf2: Soft float library routines.
- (line 162)
- * __cmpsq2: Fixed-point fractional library routines.
- (line 446)
- * __cmpta2: Fixed-point fractional library routines.
- (line 459)
- * __cmptf2: Soft float library routines.
- (line 164)
- * __cmpti2: Integer library routines.
- (line 87)
- * __cmpuda2: Fixed-point fractional library routines.
- (line 464)
- * __cmpudq2: Fixed-point fractional library routines.
- (line 454)
- * __cmpuha2: Fixed-point fractional library routines.
- (line 461)
- * __cmpuhq2: Fixed-point fractional library routines.
- (line 451)
- * __cmpuqq2: Fixed-point fractional library routines.
- (line 449)
- * __cmpusa2: Fixed-point fractional library routines.
- (line 463)
- * __cmpusq2: Fixed-point fractional library routines.
- (line 452)
- * __cmputa2: Fixed-point fractional library routines.
- (line 466)
- * __CTOR_LIST__: Initialization. (line 25)
- * __ctzdi2: Integer library routines.
- (line 137)
- * __ctzsi2: Integer library routines.
- (line 136)
- * __ctzti2: Integer library routines.
- (line 138)
- * __divda3: Fixed-point fractional library routines.
- (line 234)
- * __divdc3: Soft float library routines.
- (line 250)
- * __divdf3: Soft float library routines.
- (line 47)
- * __divdi3: Integer library routines.
- (line 24)
- * __divdq3: Fixed-point fractional library routines.
- (line 229)
- * __divha3: Fixed-point fractional library routines.
- (line 231)
- * __divhq3: Fixed-point fractional library routines.
- (line 227)
- * __divqq3: Fixed-point fractional library routines.
- (line 225)
- * __divsa3: Fixed-point fractional library routines.
- (line 233)
- * __divsc3: Soft float library routines.
- (line 248)
- * __divsf3: Soft float library routines.
- (line 46)
- * __divsi3: Integer library routines.
- (line 23)
- * __divsq3: Fixed-point fractional library routines.
- (line 228)
- * __divta3: Fixed-point fractional library routines.
- (line 235)
- * __divtc3: Soft float library routines.
- (line 252)
- * __divtf3: Soft float library routines.
- (line 48)
- * __divti3: Integer library routines.
- (line 25)
- * __divxc3: Soft float library routines.
- (line 254)
- * __divxf3: Soft float library routines.
- (line 50)
- * __dpd_adddd3: Decimal float library routines.
- (line 21)
- * __dpd_addsd3: Decimal float library routines.
- (line 17)
- * __dpd_addtd3: Decimal float library routines.
- (line 25)
- * __dpd_divdd3: Decimal float library routines.
- (line 64)
- * __dpd_divsd3: Decimal float library routines.
- (line 60)
- * __dpd_divtd3: Decimal float library routines.
- (line 68)
- * __dpd_eqdd2: Decimal float library routines.
- (line 257)
- * __dpd_eqsd2: Decimal float library routines.
- (line 255)
- * __dpd_eqtd2: Decimal float library routines.
- (line 259)
- * __dpd_extendddtd2: Decimal float library routines.
- (line 90)
- * __dpd_extendddtf: Decimal float library routines.
- (line 138)
- * __dpd_extendddxf: Decimal float library routines.
- (line 132)
- * __dpd_extenddfdd: Decimal float library routines.
- (line 145)
- * __dpd_extenddftd: Decimal float library routines.
- (line 105)
- * __dpd_extendsddd2: Decimal float library routines.
- (line 86)
- * __dpd_extendsddf: Decimal float library routines.
- (line 126)
- * __dpd_extendsdtd2: Decimal float library routines.
- (line 88)
- * __dpd_extendsdtf: Decimal float library routines.
- (line 136)
- * __dpd_extendsdxf: Decimal float library routines.
- (line 130)
- * __dpd_extendsfdd: Decimal float library routines.
- (line 101)
- * __dpd_extendsfsd: Decimal float library routines.
- (line 143)
- * __dpd_extendsftd: Decimal float library routines.
- (line 103)
- * __dpd_extendtftd: Decimal float library routines.
- (line 147)
- * __dpd_extendxftd: Decimal float library routines.
- (line 107)
- * __dpd_fixdddi: Decimal float library routines.
- (line 168)
- * __dpd_fixddsi: Decimal float library routines.
- (line 160)
- * __dpd_fixsddi: Decimal float library routines.
- (line 166)
- * __dpd_fixsdsi: Decimal float library routines.
- (line 158)
- * __dpd_fixtddi: Decimal float library routines.
- (line 170)
- * __dpd_fixtdsi: Decimal float library routines.
- (line 162)
- * __dpd_fixunsdddi: Decimal float library routines.
- (line 185)
- * __dpd_fixunsddsi: Decimal float library routines.
- (line 176)
- * __dpd_fixunssddi: Decimal float library routines.
- (line 183)
- * __dpd_fixunssdsi: Decimal float library routines.
- (line 174)
- * __dpd_fixunstddi: Decimal float library routines.
- (line 187)
- * __dpd_fixunstdsi: Decimal float library routines.
- (line 178)
- * __dpd_floatdidd: Decimal float library routines.
- (line 203)
- * __dpd_floatdisd: Decimal float library routines.
- (line 201)
- * __dpd_floatditd: Decimal float library routines.
- (line 205)
- * __dpd_floatsidd: Decimal float library routines.
- (line 194)
- * __dpd_floatsisd: Decimal float library routines.
- (line 192)
- * __dpd_floatsitd: Decimal float library routines.
- (line 196)
- * __dpd_floatunsdidd: Decimal float library routines.
- (line 221)
- * __dpd_floatunsdisd: Decimal float library routines.
- (line 219)
- * __dpd_floatunsditd: Decimal float library routines.
- (line 223)
- * __dpd_floatunssidd: Decimal float library routines.
- (line 212)
- * __dpd_floatunssisd: Decimal float library routines.
- (line 210)
- * __dpd_floatunssitd: Decimal float library routines.
- (line 214)
- * __dpd_gedd2: Decimal float library routines.
- (line 275)
- * __dpd_gesd2: Decimal float library routines.
- (line 273)
- * __dpd_getd2: Decimal float library routines.
- (line 277)
- * __dpd_gtdd2: Decimal float library routines.
- (line 302)
- * __dpd_gtsd2: Decimal float library routines.
- (line 300)
- * __dpd_gttd2: Decimal float library routines.
- (line 304)
- * __dpd_ledd2: Decimal float library routines.
- (line 293)
- * __dpd_lesd2: Decimal float library routines.
- (line 291)
- * __dpd_letd2: Decimal float library routines.
- (line 295)
- * __dpd_ltdd2: Decimal float library routines.
- (line 284)
- * __dpd_ltsd2: Decimal float library routines.
- (line 282)
- * __dpd_lttd2: Decimal float library routines.
- (line 286)
- * __dpd_muldd3: Decimal float library routines.
- (line 50)
- * __dpd_mulsd3: Decimal float library routines.
- (line 46)
- * __dpd_multd3: Decimal float library routines.
- (line 54)
- * __dpd_nedd2: Decimal float library routines.
- (line 266)
- * __dpd_negdd2: Decimal float library routines.
- (line 76)
- * __dpd_negsd2: Decimal float library routines.
- (line 74)
- * __dpd_negtd2: Decimal float library routines.
- (line 78)
- * __dpd_nesd2: Decimal float library routines.
- (line 264)
- * __dpd_netd2: Decimal float library routines.
- (line 268)
- * __dpd_subdd3: Decimal float library routines.
- (line 35)
- * __dpd_subsd3: Decimal float library routines.
- (line 31)
- * __dpd_subtd3: Decimal float library routines.
- (line 39)
- * __dpd_truncdddf: Decimal float library routines.
- (line 151)
- * __dpd_truncddsd2: Decimal float library routines.
- (line 92)
- * __dpd_truncddsf: Decimal float library routines.
- (line 122)
- * __dpd_truncdfsd: Decimal float library routines.
- (line 109)
- * __dpd_truncsdsf: Decimal float library routines.
- (line 149)
- * __dpd_trunctddd2: Decimal float library routines.
- (line 96)
- * __dpd_trunctddf: Decimal float library routines.
- (line 128)
- * __dpd_trunctdsd2: Decimal float library routines.
- (line 94)
- * __dpd_trunctdsf: Decimal float library routines.
- (line 124)
- * __dpd_trunctdtf: Decimal float library routines.
- (line 153)
- * __dpd_trunctdxf: Decimal float library routines.
- (line 134)
- * __dpd_trunctfdd: Decimal float library routines.
- (line 117)
- * __dpd_trunctfsd: Decimal float library routines.
- (line 113)
- * __dpd_truncxfdd: Decimal float library routines.
- (line 115)
- * __dpd_truncxfsd: Decimal float library routines.
- (line 111)
- * __dpd_unorddd2: Decimal float library routines.
- (line 233)
- * __dpd_unordsd2: Decimal float library routines.
- (line 231)
- * __dpd_unordtd2: Decimal float library routines.
- (line 235)
- * __DTOR_LIST__: Initialization. (line 25)
- * __eqdf2: Soft float library routines.
- (line 193)
- * __eqsf2: Soft float library routines.
- (line 192)
- * __eqtf2: Soft float library routines.
- (line 194)
- * __extenddftf2: Soft float library routines.
- (line 67)
- * __extenddfxf2: Soft float library routines.
- (line 68)
- * __extendsfdf2: Soft float library routines.
- (line 64)
- * __extendsftf2: Soft float library routines.
- (line 65)
- * __extendsfxf2: Soft float library routines.
- (line 66)
- * __ffsdi2: Integer library routines.
- (line 143)
- * __ffsti2: Integer library routines.
- (line 144)
- * __fixdfdi: Soft float library routines.
- (line 87)
- * __fixdfsi: Soft float library routines.
- (line 80)
- * __fixdfti: Soft float library routines.
- (line 93)
- * __fixsfdi: Soft float library routines.
- (line 86)
- * __fixsfsi: Soft float library routines.
- (line 79)
- * __fixsfti: Soft float library routines.
- (line 92)
- * __fixtfdi: Soft float library routines.
- (line 88)
- * __fixtfsi: Soft float library routines.
- (line 81)
- * __fixtfti: Soft float library routines.
- (line 94)
- * __fixunsdfdi: Soft float library routines.
- (line 107)
- * __fixunsdfsi: Soft float library routines.
- (line 100)
- * __fixunsdfti: Soft float library routines.
- (line 114)
- * __fixunssfdi: Soft float library routines.
- (line 106)
- * __fixunssfsi: Soft float library routines.
- (line 99)
- * __fixunssfti: Soft float library routines.
- (line 113)
- * __fixunstfdi: Soft float library routines.
- (line 108)
- * __fixunstfsi: Soft float library routines.
- (line 101)
- * __fixunstfti: Soft float library routines.
- (line 115)
- * __fixunsxfdi: Soft float library routines.
- (line 109)
- * __fixunsxfsi: Soft float library routines.
- (line 102)
- * __fixunsxfti: Soft float library routines.
- (line 116)
- * __fixxfdi: Soft float library routines.
- (line 89)
- * __fixxfsi: Soft float library routines.
- (line 82)
- * __fixxfti: Soft float library routines.
- (line 95)
- * __floatdidf: Soft float library routines.
- (line 127)
- * __floatdisf: Soft float library routines.
- (line 126)
- * __floatditf: Soft float library routines.
- (line 128)
- * __floatdixf: Soft float library routines.
- (line 129)
- * __floatsidf: Soft float library routines.
- (line 121)
- * __floatsisf: Soft float library routines.
- (line 120)
- * __floatsitf: Soft float library routines.
- (line 122)
- * __floatsixf: Soft float library routines.
- (line 123)
- * __floattidf: Soft float library routines.
- (line 133)
- * __floattisf: Soft float library routines.
- (line 132)
- * __floattitf: Soft float library routines.
- (line 134)
- * __floattixf: Soft float library routines.
- (line 135)
- * __floatundidf: Soft float library routines.
- (line 145)
- * __floatundisf: Soft float library routines.
- (line 144)
- * __floatunditf: Soft float library routines.
- (line 146)
- * __floatundixf: Soft float library routines.
- (line 147)
- * __floatunsidf: Soft float library routines.
- (line 139)
- * __floatunsisf: Soft float library routines.
- (line 138)
- * __floatunsitf: Soft float library routines.
- (line 140)
- * __floatunsixf: Soft float library routines.
- (line 141)
- * __floatuntidf: Soft float library routines.
- (line 151)
- * __floatuntisf: Soft float library routines.
- (line 150)
- * __floatuntitf: Soft float library routines.
- (line 152)
- * __floatuntixf: Soft float library routines.
- (line 153)
- * __fractdadf: Fixed-point fractional library routines.
- (line 643)
- * __fractdadi: Fixed-point fractional library routines.
- (line 640)
- * __fractdadq: Fixed-point fractional library routines.
- (line 623)
- * __fractdaha2: Fixed-point fractional library routines.
- (line 624)
- * __fractdahi: Fixed-point fractional library routines.
- (line 638)
- * __fractdahq: Fixed-point fractional library routines.
- (line 621)
- * __fractdaqi: Fixed-point fractional library routines.
- (line 637)
- * __fractdaqq: Fixed-point fractional library routines.
- (line 620)
- * __fractdasa2: Fixed-point fractional library routines.
- (line 625)
- * __fractdasf: Fixed-point fractional library routines.
- (line 642)
- * __fractdasi: Fixed-point fractional library routines.
- (line 639)
- * __fractdasq: Fixed-point fractional library routines.
- (line 622)
- * __fractdata2: Fixed-point fractional library routines.
- (line 626)
- * __fractdati: Fixed-point fractional library routines.
- (line 641)
- * __fractdauda: Fixed-point fractional library routines.
- (line 634)
- * __fractdaudq: Fixed-point fractional library routines.
- (line 630)
- * __fractdauha: Fixed-point fractional library routines.
- (line 632)
- * __fractdauhq: Fixed-point fractional library routines.
- (line 628)
- * __fractdauqq: Fixed-point fractional library routines.
- (line 627)
- * __fractdausa: Fixed-point fractional library routines.
- (line 633)
- * __fractdausq: Fixed-point fractional library routines.
- (line 629)
- * __fractdauta: Fixed-point fractional library routines.
- (line 635)
- * __fractdfda: Fixed-point fractional library routines.
- (line 1032)
- * __fractdfdq: Fixed-point fractional library routines.
- (line 1029)
- * __fractdfha: Fixed-point fractional library routines.
- (line 1030)
- * __fractdfhq: Fixed-point fractional library routines.
- (line 1027)
- * __fractdfqq: Fixed-point fractional library routines.
- (line 1026)
- * __fractdfsa: Fixed-point fractional library routines.
- (line 1031)
- * __fractdfsq: Fixed-point fractional library routines.
- (line 1028)
- * __fractdfta: Fixed-point fractional library routines.
- (line 1033)
- * __fractdfuda: Fixed-point fractional library routines.
- (line 1040)
- * __fractdfudq: Fixed-point fractional library routines.
- (line 1037)
- * __fractdfuha: Fixed-point fractional library routines.
- (line 1038)
- * __fractdfuhq: Fixed-point fractional library routines.
- (line 1035)
- * __fractdfuqq: Fixed-point fractional library routines.
- (line 1034)
- * __fractdfusa: Fixed-point fractional library routines.
- (line 1039)
- * __fractdfusq: Fixed-point fractional library routines.
- (line 1036)
- * __fractdfuta: Fixed-point fractional library routines.
- (line 1041)
- * __fractdida: Fixed-point fractional library routines.
- (line 982)
- * __fractdidq: Fixed-point fractional library routines.
- (line 979)
- * __fractdiha: Fixed-point fractional library routines.
- (line 980)
- * __fractdihq: Fixed-point fractional library routines.
- (line 977)
- * __fractdiqq: Fixed-point fractional library routines.
- (line 976)
- * __fractdisa: Fixed-point fractional library routines.
- (line 981)
- * __fractdisq: Fixed-point fractional library routines.
- (line 978)
- * __fractdita: Fixed-point fractional library routines.
- (line 983)
- * __fractdiuda: Fixed-point fractional library routines.
- (line 990)
- * __fractdiudq: Fixed-point fractional library routines.
- (line 987)
- * __fractdiuha: Fixed-point fractional library routines.
- (line 988)
- * __fractdiuhq: Fixed-point fractional library routines.
- (line 985)
- * __fractdiuqq: Fixed-point fractional library routines.
- (line 984)
- * __fractdiusa: Fixed-point fractional library routines.
- (line 989)
- * __fractdiusq: Fixed-point fractional library routines.
- (line 986)
- * __fractdiuta: Fixed-point fractional library routines.
- (line 991)
- * __fractdqda: Fixed-point fractional library routines.
- (line 551)
- * __fractdqdf: Fixed-point fractional library routines.
- (line 573)
- * __fractdqdi: Fixed-point fractional library routines.
- (line 570)
- * __fractdqha: Fixed-point fractional library routines.
- (line 549)
- * __fractdqhi: Fixed-point fractional library routines.
- (line 568)
- * __fractdqhq2: Fixed-point fractional library routines.
- (line 547)
- * __fractdqqi: Fixed-point fractional library routines.
- (line 567)
- * __fractdqqq2: Fixed-point fractional library routines.
- (line 546)
- * __fractdqsa: Fixed-point fractional library routines.
- (line 550)
- * __fractdqsf: Fixed-point fractional library routines.
- (line 572)
- * __fractdqsi: Fixed-point fractional library routines.
- (line 569)
- * __fractdqsq2: Fixed-point fractional library routines.
- (line 548)
- * __fractdqta: Fixed-point fractional library routines.
- (line 552)
- * __fractdqti: Fixed-point fractional library routines.
- (line 571)
- * __fractdquda: Fixed-point fractional library routines.
- (line 563)
- * __fractdqudq: Fixed-point fractional library routines.
- (line 558)
- * __fractdquha: Fixed-point fractional library routines.
- (line 560)
- * __fractdquhq: Fixed-point fractional library routines.
- (line 555)
- * __fractdquqq: Fixed-point fractional library routines.
- (line 553)
- * __fractdqusa: Fixed-point fractional library routines.
- (line 562)
- * __fractdqusq: Fixed-point fractional library routines.
- (line 556)
- * __fractdquta: Fixed-point fractional library routines.
- (line 565)
- * __fracthada2: Fixed-point fractional library routines.
- (line 579)
- * __fracthadf: Fixed-point fractional library routines.
- (line 597)
- * __fracthadi: Fixed-point fractional library routines.
- (line 594)
- * __fracthadq: Fixed-point fractional library routines.
- (line 577)
- * __fracthahi: Fixed-point fractional library routines.
- (line 592)
- * __fracthahq: Fixed-point fractional library routines.
- (line 575)
- * __fracthaqi: Fixed-point fractional library routines.
- (line 591)
- * __fracthaqq: Fixed-point fractional library routines.
- (line 574)
- * __fracthasa2: Fixed-point fractional library routines.
- (line 578)
- * __fracthasf: Fixed-point fractional library routines.
- (line 596)
- * __fracthasi: Fixed-point fractional library routines.
- (line 593)
- * __fracthasq: Fixed-point fractional library routines.
- (line 576)
- * __fracthata2: Fixed-point fractional library routines.
- (line 580)
- * __fracthati: Fixed-point fractional library routines.
- (line 595)
- * __fracthauda: Fixed-point fractional library routines.
- (line 588)
- * __fracthaudq: Fixed-point fractional library routines.
- (line 584)
- * __fracthauha: Fixed-point fractional library routines.
- (line 586)
- * __fracthauhq: Fixed-point fractional library routines.
- (line 582)
- * __fracthauqq: Fixed-point fractional library routines.
- (line 581)
- * __fracthausa: Fixed-point fractional library routines.
- (line 587)
- * __fracthausq: Fixed-point fractional library routines.
- (line 583)
- * __fracthauta: Fixed-point fractional library routines.
- (line 589)
- * __fracthida: Fixed-point fractional library routines.
- (line 950)
- * __fracthidq: Fixed-point fractional library routines.
- (line 947)
- * __fracthiha: Fixed-point fractional library routines.
- (line 948)
- * __fracthihq: Fixed-point fractional library routines.
- (line 945)
- * __fracthiqq: Fixed-point fractional library routines.
- (line 944)
- * __fracthisa: Fixed-point fractional library routines.
- (line 949)
- * __fracthisq: Fixed-point fractional library routines.
- (line 946)
- * __fracthita: Fixed-point fractional library routines.
- (line 951)
- * __fracthiuda: Fixed-point fractional library routines.
- (line 958)
- * __fracthiudq: Fixed-point fractional library routines.
- (line 955)
- * __fracthiuha: Fixed-point fractional library routines.
- (line 956)
- * __fracthiuhq: Fixed-point fractional library routines.
- (line 953)
- * __fracthiuqq: Fixed-point fractional library routines.
- (line 952)
- * __fracthiusa: Fixed-point fractional library routines.
- (line 957)
- * __fracthiusq: Fixed-point fractional library routines.
- (line 954)
- * __fracthiuta: Fixed-point fractional library routines.
- (line 959)
- * __fracthqda: Fixed-point fractional library routines.
- (line 505)
- * __fracthqdf: Fixed-point fractional library routines.
- (line 521)
- * __fracthqdi: Fixed-point fractional library routines.
- (line 518)
- * __fracthqdq2: Fixed-point fractional library routines.
- (line 502)
- * __fracthqha: Fixed-point fractional library routines.
- (line 503)
- * __fracthqhi: Fixed-point fractional library routines.
- (line 516)
- * __fracthqqi: Fixed-point fractional library routines.
- (line 515)
- * __fracthqqq2: Fixed-point fractional library routines.
- (line 500)
- * __fracthqsa: Fixed-point fractional library routines.
- (line 504)
- * __fracthqsf: Fixed-point fractional library routines.
- (line 520)
- * __fracthqsi: Fixed-point fractional library routines.
- (line 517)
- * __fracthqsq2: Fixed-point fractional library routines.
- (line 501)
- * __fracthqta: Fixed-point fractional library routines.
- (line 506)
- * __fracthqti: Fixed-point fractional library routines.
- (line 519)
- * __fracthquda: Fixed-point fractional library routines.
- (line 513)
- * __fracthqudq: Fixed-point fractional library routines.
- (line 510)
- * __fracthquha: Fixed-point fractional library routines.
- (line 511)
- * __fracthquhq: Fixed-point fractional library routines.
- (line 508)
- * __fracthquqq: Fixed-point fractional library routines.
- (line 507)
- * __fracthqusa: Fixed-point fractional library routines.
- (line 512)
- * __fracthqusq: Fixed-point fractional library routines.
- (line 509)
- * __fracthquta: Fixed-point fractional library routines.
- (line 514)
- * __fractqida: Fixed-point fractional library routines.
- (line 932)
- * __fractqidq: Fixed-point fractional library routines.
- (line 929)
- * __fractqiha: Fixed-point fractional library routines.
- (line 930)
- * __fractqihq: Fixed-point fractional library routines.
- (line 927)
- * __fractqiqq: Fixed-point fractional library routines.
- (line 926)
- * __fractqisa: Fixed-point fractional library routines.
- (line 931)
- * __fractqisq: Fixed-point fractional library routines.
- (line 928)
- * __fractqita: Fixed-point fractional library routines.
- (line 933)
- * __fractqiuda: Fixed-point fractional library routines.
- (line 941)
- * __fractqiudq: Fixed-point fractional library routines.
- (line 937)
- * __fractqiuha: Fixed-point fractional library routines.
- (line 939)
- * __fractqiuhq: Fixed-point fractional library routines.
- (line 935)
- * __fractqiuqq: Fixed-point fractional library routines.
- (line 934)
- * __fractqiusa: Fixed-point fractional library routines.
- (line 940)
- * __fractqiusq: Fixed-point fractional library routines.
- (line 936)
- * __fractqiuta: Fixed-point fractional library routines.
- (line 942)
- * __fractqqda: Fixed-point fractional library routines.
- (line 481)
- * __fractqqdf: Fixed-point fractional library routines.
- (line 499)
- * __fractqqdi: Fixed-point fractional library routines.
- (line 496)
- * __fractqqdq2: Fixed-point fractional library routines.
- (line 478)
- * __fractqqha: Fixed-point fractional library routines.
- (line 479)
- * __fractqqhi: Fixed-point fractional library routines.
- (line 494)
- * __fractqqhq2: Fixed-point fractional library routines.
- (line 476)
- * __fractqqqi: Fixed-point fractional library routines.
- (line 493)
- * __fractqqsa: Fixed-point fractional library routines.
- (line 480)
- * __fractqqsf: Fixed-point fractional library routines.
- (line 498)
- * __fractqqsi: Fixed-point fractional library routines.
- (line 495)
- * __fractqqsq2: Fixed-point fractional library routines.
- (line 477)
- * __fractqqta: Fixed-point fractional library routines.
- (line 482)
- * __fractqqti: Fixed-point fractional library routines.
- (line 497)
- * __fractqquda: Fixed-point fractional library routines.
- (line 490)
- * __fractqqudq: Fixed-point fractional library routines.
- (line 486)
- * __fractqquha: Fixed-point fractional library routines.
- (line 488)
- * __fractqquhq: Fixed-point fractional library routines.
- (line 484)
- * __fractqquqq: Fixed-point fractional library routines.
- (line 483)
- * __fractqqusa: Fixed-point fractional library routines.
- (line 489)
- * __fractqqusq: Fixed-point fractional library routines.
- (line 485)
- * __fractqquta: Fixed-point fractional library routines.
- (line 491)
- * __fractsada2: Fixed-point fractional library routines.
- (line 603)
- * __fractsadf: Fixed-point fractional library routines.
- (line 619)
- * __fractsadi: Fixed-point fractional library routines.
- (line 616)
- * __fractsadq: Fixed-point fractional library routines.
- (line 601)
- * __fractsaha2: Fixed-point fractional library routines.
- (line 602)
- * __fractsahi: Fixed-point fractional library routines.
- (line 614)
- * __fractsahq: Fixed-point fractional library routines.
- (line 599)
- * __fractsaqi: Fixed-point fractional library routines.
- (line 613)
- * __fractsaqq: Fixed-point fractional library routines.
- (line 598)
- * __fractsasf: Fixed-point fractional library routines.
- (line 618)
- * __fractsasi: Fixed-point fractional library routines.
- (line 615)
- * __fractsasq: Fixed-point fractional library routines.
- (line 600)
- * __fractsata2: Fixed-point fractional library routines.
- (line 604)
- * __fractsati: Fixed-point fractional library routines.
- (line 617)
- * __fractsauda: Fixed-point fractional library routines.
- (line 611)
- * __fractsaudq: Fixed-point fractional library routines.
- (line 608)
- * __fractsauha: Fixed-point fractional library routines.
- (line 609)
- * __fractsauhq: Fixed-point fractional library routines.
- (line 606)
- * __fractsauqq: Fixed-point fractional library routines.
- (line 605)
- * __fractsausa: Fixed-point fractional library routines.
- (line 610)
- * __fractsausq: Fixed-point fractional library routines.
- (line 607)
- * __fractsauta: Fixed-point fractional library routines.
- (line 612)
- * __fractsfda: Fixed-point fractional library routines.
- (line 1016)
- * __fractsfdq: Fixed-point fractional library routines.
- (line 1013)
- * __fractsfha: Fixed-point fractional library routines.
- (line 1014)
- * __fractsfhq: Fixed-point fractional library routines.
- (line 1011)
- * __fractsfqq: Fixed-point fractional library routines.
- (line 1010)
- * __fractsfsa: Fixed-point fractional library routines.
- (line 1015)
- * __fractsfsq: Fixed-point fractional library routines.
- (line 1012)
- * __fractsfta: Fixed-point fractional library routines.
- (line 1017)
- * __fractsfuda: Fixed-point fractional library routines.
- (line 1024)
- * __fractsfudq: Fixed-point fractional library routines.
- (line 1021)
- * __fractsfuha: Fixed-point fractional library routines.
- (line 1022)
- * __fractsfuhq: Fixed-point fractional library routines.
- (line 1019)
- * __fractsfuqq: Fixed-point fractional library routines.
- (line 1018)
- * __fractsfusa: Fixed-point fractional library routines.
- (line 1023)
- * __fractsfusq: Fixed-point fractional library routines.
- (line 1020)
- * __fractsfuta: Fixed-point fractional library routines.
- (line 1025)
- * __fractsida: Fixed-point fractional library routines.
- (line 966)
- * __fractsidq: Fixed-point fractional library routines.
- (line 963)
- * __fractsiha: Fixed-point fractional library routines.
- (line 964)
- * __fractsihq: Fixed-point fractional library routines.
- (line 961)
- * __fractsiqq: Fixed-point fractional library routines.
- (line 960)
- * __fractsisa: Fixed-point fractional library routines.
- (line 965)
- * __fractsisq: Fixed-point fractional library routines.
- (line 962)
- * __fractsita: Fixed-point fractional library routines.
- (line 967)
- * __fractsiuda: Fixed-point fractional library routines.
- (line 974)
- * __fractsiudq: Fixed-point fractional library routines.
- (line 971)
- * __fractsiuha: Fixed-point fractional library routines.
- (line 972)
- * __fractsiuhq: Fixed-point fractional library routines.
- (line 969)
- * __fractsiuqq: Fixed-point fractional library routines.
- (line 968)
- * __fractsiusa: Fixed-point fractional library routines.
- (line 973)
- * __fractsiusq: Fixed-point fractional library routines.
- (line 970)
- * __fractsiuta: Fixed-point fractional library routines.
- (line 975)
- * __fractsqda: Fixed-point fractional library routines.
- (line 527)
- * __fractsqdf: Fixed-point fractional library routines.
- (line 545)
- * __fractsqdi: Fixed-point fractional library routines.
- (line 542)
- * __fractsqdq2: Fixed-point fractional library routines.
- (line 524)
- * __fractsqha: Fixed-point fractional library routines.
- (line 525)
- * __fractsqhi: Fixed-point fractional library routines.
- (line 540)
- * __fractsqhq2: Fixed-point fractional library routines.
- (line 523)
- * __fractsqqi: Fixed-point fractional library routines.
- (line 539)
- * __fractsqqq2: Fixed-point fractional library routines.
- (line 522)
- * __fractsqsa: Fixed-point fractional library routines.
- (line 526)
- * __fractsqsf: Fixed-point fractional library routines.
- (line 544)
- * __fractsqsi: Fixed-point fractional library routines.
- (line 541)
- * __fractsqta: Fixed-point fractional library routines.
- (line 528)
- * __fractsqti: Fixed-point fractional library routines.
- (line 543)
- * __fractsquda: Fixed-point fractional library routines.
- (line 536)
- * __fractsqudq: Fixed-point fractional library routines.
- (line 532)
- * __fractsquha: Fixed-point fractional library routines.
- (line 534)
- * __fractsquhq: Fixed-point fractional library routines.
- (line 530)
- * __fractsquqq: Fixed-point fractional library routines.
- (line 529)
- * __fractsqusa: Fixed-point fractional library routines.
- (line 535)
- * __fractsqusq: Fixed-point fractional library routines.
- (line 531)
- * __fractsquta: Fixed-point fractional library routines.
- (line 537)
- * __fracttada2: Fixed-point fractional library routines.
- (line 650)
- * __fracttadf: Fixed-point fractional library routines.
- (line 671)
- * __fracttadi: Fixed-point fractional library routines.
- (line 668)
- * __fracttadq: Fixed-point fractional library routines.
- (line 647)
- * __fracttaha2: Fixed-point fractional library routines.
- (line 648)
- * __fracttahi: Fixed-point fractional library routines.
- (line 666)
- * __fracttahq: Fixed-point fractional library routines.
- (line 645)
- * __fracttaqi: Fixed-point fractional library routines.
- (line 665)
- * __fracttaqq: Fixed-point fractional library routines.
- (line 644)
- * __fracttasa2: Fixed-point fractional library routines.
- (line 649)
- * __fracttasf: Fixed-point fractional library routines.
- (line 670)
- * __fracttasi: Fixed-point fractional library routines.
- (line 667)
- * __fracttasq: Fixed-point fractional library routines.
- (line 646)
- * __fracttati: Fixed-point fractional library routines.
- (line 669)
- * __fracttauda: Fixed-point fractional library routines.
- (line 661)
- * __fracttaudq: Fixed-point fractional library routines.
- (line 656)
- * __fracttauha: Fixed-point fractional library routines.
- (line 658)
- * __fracttauhq: Fixed-point fractional library routines.
- (line 653)
- * __fracttauqq: Fixed-point fractional library routines.
- (line 651)
- * __fracttausa: Fixed-point fractional library routines.
- (line 660)
- * __fracttausq: Fixed-point fractional library routines.
- (line 654)
- * __fracttauta: Fixed-point fractional library routines.
- (line 663)
- * __fracttida: Fixed-point fractional library routines.
- (line 998)
- * __fracttidq: Fixed-point fractional library routines.
- (line 995)
- * __fracttiha: Fixed-point fractional library routines.
- (line 996)
- * __fracttihq: Fixed-point fractional library routines.
- (line 993)
- * __fracttiqq: Fixed-point fractional library routines.
- (line 992)
- * __fracttisa: Fixed-point fractional library routines.
- (line 997)
- * __fracttisq: Fixed-point fractional library routines.
- (line 994)
- * __fracttita: Fixed-point fractional library routines.
- (line 999)
- * __fracttiuda: Fixed-point fractional library routines.
- (line 1007)
- * __fracttiudq: Fixed-point fractional library routines.
- (line 1003)
- * __fracttiuha: Fixed-point fractional library routines.
- (line 1005)
- * __fracttiuhq: Fixed-point fractional library routines.
- (line 1001)
- * __fracttiuqq: Fixed-point fractional library routines.
- (line 1000)
- * __fracttiusa: Fixed-point fractional library routines.
- (line 1006)
- * __fracttiusq: Fixed-point fractional library routines.
- (line 1002)
- * __fracttiuta: Fixed-point fractional library routines.
- (line 1008)
- * __fractudada: Fixed-point fractional library routines.
- (line 865)
- * __fractudadf: Fixed-point fractional library routines.
- (line 888)
- * __fractudadi: Fixed-point fractional library routines.
- (line 885)
- * __fractudadq: Fixed-point fractional library routines.
- (line 861)
- * __fractudaha: Fixed-point fractional library routines.
- (line 863)
- * __fractudahi: Fixed-point fractional library routines.
- (line 883)
- * __fractudahq: Fixed-point fractional library routines.
- (line 859)
- * __fractudaqi: Fixed-point fractional library routines.
- (line 882)
- * __fractudaqq: Fixed-point fractional library routines.
- (line 858)
- * __fractudasa: Fixed-point fractional library routines.
- (line 864)
- * __fractudasf: Fixed-point fractional library routines.
- (line 887)
- * __fractudasi: Fixed-point fractional library routines.
- (line 884)
- * __fractudasq: Fixed-point fractional library routines.
- (line 860)
- * __fractudata: Fixed-point fractional library routines.
- (line 866)
- * __fractudati: Fixed-point fractional library routines.
- (line 886)
- * __fractudaudq: Fixed-point fractional library routines.
- (line 874)
- * __fractudauha2: Fixed-point fractional library routines.
- (line 876)
- * __fractudauhq: Fixed-point fractional library routines.
- (line 870)
- * __fractudauqq: Fixed-point fractional library routines.
- (line 868)
- * __fractudausa2: Fixed-point fractional library routines.
- (line 878)
- * __fractudausq: Fixed-point fractional library routines.
- (line 872)
- * __fractudauta2: Fixed-point fractional library routines.
- (line 880)
- * __fractudqda: Fixed-point fractional library routines.
- (line 772)
- * __fractudqdf: Fixed-point fractional library routines.
- (line 798)
- * __fractudqdi: Fixed-point fractional library routines.
- (line 794)
- * __fractudqdq: Fixed-point fractional library routines.
- (line 767)
- * __fractudqha: Fixed-point fractional library routines.
- (line 769)
- * __fractudqhi: Fixed-point fractional library routines.
- (line 792)
- * __fractudqhq: Fixed-point fractional library routines.
- (line 764)
- * __fractudqqi: Fixed-point fractional library routines.
- (line 790)
- * __fractudqqq: Fixed-point fractional library routines.
- (line 762)
- * __fractudqsa: Fixed-point fractional library routines.
- (line 771)
- * __fractudqsf: Fixed-point fractional library routines.
- (line 797)
- * __fractudqsi: Fixed-point fractional library routines.
- (line 793)
- * __fractudqsq: Fixed-point fractional library routines.
- (line 765)
- * __fractudqta: Fixed-point fractional library routines.
- (line 774)
- * __fractudqti: Fixed-point fractional library routines.
- (line 795)
- * __fractudquda: Fixed-point fractional library routines.
- (line 786)
- * __fractudquha: Fixed-point fractional library routines.
- (line 782)
- * __fractudquhq2: Fixed-point fractional library routines.
- (line 778)
- * __fractudquqq2: Fixed-point fractional library routines.
- (line 776)
- * __fractudqusa: Fixed-point fractional library routines.
- (line 784)
- * __fractudqusq2: Fixed-point fractional library routines.
- (line 780)
- * __fractudquta: Fixed-point fractional library routines.
- (line 788)
- * __fractuhada: Fixed-point fractional library routines.
- (line 806)
- * __fractuhadf: Fixed-point fractional library routines.
- (line 829)
- * __fractuhadi: Fixed-point fractional library routines.
- (line 826)
- * __fractuhadq: Fixed-point fractional library routines.
- (line 802)
- * __fractuhaha: Fixed-point fractional library routines.
- (line 804)
- * __fractuhahi: Fixed-point fractional library routines.
- (line 824)
- * __fractuhahq: Fixed-point fractional library routines.
- (line 800)
- * __fractuhaqi: Fixed-point fractional library routines.
- (line 823)
- * __fractuhaqq: Fixed-point fractional library routines.
- (line 799)
- * __fractuhasa: Fixed-point fractional library routines.
- (line 805)
- * __fractuhasf: Fixed-point fractional library routines.
- (line 828)
- * __fractuhasi: Fixed-point fractional library routines.
- (line 825)
- * __fractuhasq: Fixed-point fractional library routines.
- (line 801)
- * __fractuhata: Fixed-point fractional library routines.
- (line 807)
- * __fractuhati: Fixed-point fractional library routines.
- (line 827)
- * __fractuhauda2: Fixed-point fractional library routines.
- (line 819)
- * __fractuhaudq: Fixed-point fractional library routines.
- (line 815)
- * __fractuhauhq: Fixed-point fractional library routines.
- (line 811)
- * __fractuhauqq: Fixed-point fractional library routines.
- (line 809)
- * __fractuhausa2: Fixed-point fractional library routines.
- (line 817)
- * __fractuhausq: Fixed-point fractional library routines.
- (line 813)
- * __fractuhauta2: Fixed-point fractional library routines.
- (line 821)
- * __fractuhqda: Fixed-point fractional library routines.
- (line 709)
- * __fractuhqdf: Fixed-point fractional library routines.
- (line 730)
- * __fractuhqdi: Fixed-point fractional library routines.
- (line 727)
- * __fractuhqdq: Fixed-point fractional library routines.
- (line 706)
- * __fractuhqha: Fixed-point fractional library routines.
- (line 707)
- * __fractuhqhi: Fixed-point fractional library routines.
- (line 725)
- * __fractuhqhq: Fixed-point fractional library routines.
- (line 704)
- * __fractuhqqi: Fixed-point fractional library routines.
- (line 724)
- * __fractuhqqq: Fixed-point fractional library routines.
- (line 703)
- * __fractuhqsa: Fixed-point fractional library routines.
- (line 708)
- * __fractuhqsf: Fixed-point fractional library routines.
- (line 729)
- * __fractuhqsi: Fixed-point fractional library routines.
- (line 726)
- * __fractuhqsq: Fixed-point fractional library routines.
- (line 705)
- * __fractuhqta: Fixed-point fractional library routines.
- (line 710)
- * __fractuhqti: Fixed-point fractional library routines.
- (line 728)
- * __fractuhquda: Fixed-point fractional library routines.
- (line 720)
- * __fractuhqudq2: Fixed-point fractional library routines.
- (line 715)
- * __fractuhquha: Fixed-point fractional library routines.
- (line 717)
- * __fractuhquqq2: Fixed-point fractional library routines.
- (line 711)
- * __fractuhqusa: Fixed-point fractional library routines.
- (line 719)
- * __fractuhqusq2: Fixed-point fractional library routines.
- (line 713)
- * __fractuhquta: Fixed-point fractional library routines.
- (line 722)
- * __fractunsdadi: Fixed-point fractional library routines.
- (line 1562)
- * __fractunsdahi: Fixed-point fractional library routines.
- (line 1560)
- * __fractunsdaqi: Fixed-point fractional library routines.
- (line 1559)
- * __fractunsdasi: Fixed-point fractional library routines.
- (line 1561)
- * __fractunsdati: Fixed-point fractional library routines.
- (line 1563)
- * __fractunsdida: Fixed-point fractional library routines.
- (line 1714)
- * __fractunsdidq: Fixed-point fractional library routines.
- (line 1711)
- * __fractunsdiha: Fixed-point fractional library routines.
- (line 1712)
- * __fractunsdihq: Fixed-point fractional library routines.
- (line 1709)
- * __fractunsdiqq: Fixed-point fractional library routines.
- (line 1708)
- * __fractunsdisa: Fixed-point fractional library routines.
- (line 1713)
- * __fractunsdisq: Fixed-point fractional library routines.
- (line 1710)
- * __fractunsdita: Fixed-point fractional library routines.
- (line 1715)
- * __fractunsdiuda: Fixed-point fractional library routines.
- (line 1726)
- * __fractunsdiudq: Fixed-point fractional library routines.
- (line 1721)
- * __fractunsdiuha: Fixed-point fractional library routines.
- (line 1723)
- * __fractunsdiuhq: Fixed-point fractional library routines.
- (line 1718)
- * __fractunsdiuqq: Fixed-point fractional library routines.
- (line 1716)
- * __fractunsdiusa: Fixed-point fractional library routines.
- (line 1725)
- * __fractunsdiusq: Fixed-point fractional library routines.
- (line 1719)
- * __fractunsdiuta: Fixed-point fractional library routines.
- (line 1728)
- * __fractunsdqdi: Fixed-point fractional library routines.
- (line 1546)
- * __fractunsdqhi: Fixed-point fractional library routines.
- (line 1544)
- * __fractunsdqqi: Fixed-point fractional library routines.
- (line 1543)
- * __fractunsdqsi: Fixed-point fractional library routines.
- (line 1545)
- * __fractunsdqti: Fixed-point fractional library routines.
- (line 1547)
- * __fractunshadi: Fixed-point fractional library routines.
- (line 1552)
- * __fractunshahi: Fixed-point fractional library routines.
- (line 1550)
- * __fractunshaqi: Fixed-point fractional library routines.
- (line 1549)
- * __fractunshasi: Fixed-point fractional library routines.
- (line 1551)
- * __fractunshati: Fixed-point fractional library routines.
- (line 1553)
- * __fractunshida: Fixed-point fractional library routines.
- (line 1670)
- * __fractunshidq: Fixed-point fractional library routines.
- (line 1667)
- * __fractunshiha: Fixed-point fractional library routines.
- (line 1668)
- * __fractunshihq: Fixed-point fractional library routines.
- (line 1665)
- * __fractunshiqq: Fixed-point fractional library routines.
- (line 1664)
- * __fractunshisa: Fixed-point fractional library routines.
- (line 1669)
- * __fractunshisq: Fixed-point fractional library routines.
- (line 1666)
- * __fractunshita: Fixed-point fractional library routines.
- (line 1671)
- * __fractunshiuda: Fixed-point fractional library routines.
- (line 1682)
- * __fractunshiudq: Fixed-point fractional library routines.
- (line 1677)
- * __fractunshiuha: Fixed-point fractional library routines.
- (line 1679)
- * __fractunshiuhq: Fixed-point fractional library routines.
- (line 1674)
- * __fractunshiuqq: Fixed-point fractional library routines.
- (line 1672)
- * __fractunshiusa: Fixed-point fractional library routines.
- (line 1681)
- * __fractunshiusq: Fixed-point fractional library routines.
- (line 1675)
- * __fractunshiuta: Fixed-point fractional library routines.
- (line 1684)
- * __fractunshqdi: Fixed-point fractional library routines.
- (line 1536)
- * __fractunshqhi: Fixed-point fractional library routines.
- (line 1534)
- * __fractunshqqi: Fixed-point fractional library routines.
- (line 1533)
- * __fractunshqsi: Fixed-point fractional library routines.
- (line 1535)
- * __fractunshqti: Fixed-point fractional library routines.
- (line 1537)
- * __fractunsqida: Fixed-point fractional library routines.
- (line 1648)
- * __fractunsqidq: Fixed-point fractional library routines.
- (line 1645)
- * __fractunsqiha: Fixed-point fractional library routines.
- (line 1646)
- * __fractunsqihq: Fixed-point fractional library routines.
- (line 1643)
- * __fractunsqiqq: Fixed-point fractional library routines.
- (line 1642)
- * __fractunsqisa: Fixed-point fractional library routines.
- (line 1647)
- * __fractunsqisq: Fixed-point fractional library routines.
- (line 1644)
- * __fractunsqita: Fixed-point fractional library routines.
- (line 1649)
- * __fractunsqiuda: Fixed-point fractional library routines.
- (line 1660)
- * __fractunsqiudq: Fixed-point fractional library routines.
- (line 1655)
- * __fractunsqiuha: Fixed-point fractional library routines.
- (line 1657)
- * __fractunsqiuhq: Fixed-point fractional library routines.
- (line 1652)
- * __fractunsqiuqq: Fixed-point fractional library routines.
- (line 1650)
- * __fractunsqiusa: Fixed-point fractional library routines.
- (line 1659)
- * __fractunsqiusq: Fixed-point fractional library routines.
- (line 1653)
- * __fractunsqiuta: Fixed-point fractional library routines.
- (line 1662)
- * __fractunsqqdi: Fixed-point fractional library routines.
- (line 1531)
- * __fractunsqqhi: Fixed-point fractional library routines.
- (line 1529)
- * __fractunsqqqi: Fixed-point fractional library routines.
- (line 1528)
- * __fractunsqqsi: Fixed-point fractional library routines.
- (line 1530)
- * __fractunsqqti: Fixed-point fractional library routines.
- (line 1532)
- * __fractunssadi: Fixed-point fractional library routines.
- (line 1557)
- * __fractunssahi: Fixed-point fractional library routines.
- (line 1555)
- * __fractunssaqi: Fixed-point fractional library routines.
- (line 1554)
- * __fractunssasi: Fixed-point fractional library routines.
- (line 1556)
- * __fractunssati: Fixed-point fractional library routines.
- (line 1558)
- * __fractunssida: Fixed-point fractional library routines.
- (line 1692)
- * __fractunssidq: Fixed-point fractional library routines.
- (line 1689)
- * __fractunssiha: Fixed-point fractional library routines.
- (line 1690)
- * __fractunssihq: Fixed-point fractional library routines.
- (line 1687)
- * __fractunssiqq: Fixed-point fractional library routines.
- (line 1686)
- * __fractunssisa: Fixed-point fractional library routines.
- (line 1691)
- * __fractunssisq: Fixed-point fractional library routines.
- (line 1688)
- * __fractunssita: Fixed-point fractional library routines.
- (line 1693)
- * __fractunssiuda: Fixed-point fractional library routines.
- (line 1704)
- * __fractunssiudq: Fixed-point fractional library routines.
- (line 1699)
- * __fractunssiuha: Fixed-point fractional library routines.
- (line 1701)
- * __fractunssiuhq: Fixed-point fractional library routines.
- (line 1696)
- * __fractunssiuqq: Fixed-point fractional library routines.
- (line 1694)
- * __fractunssiusa: Fixed-point fractional library routines.
- (line 1703)
- * __fractunssiusq: Fixed-point fractional library routines.
- (line 1697)
- * __fractunssiuta: Fixed-point fractional library routines.
- (line 1706)
- * __fractunssqdi: Fixed-point fractional library routines.
- (line 1541)
- * __fractunssqhi: Fixed-point fractional library routines.
- (line 1539)
- * __fractunssqqi: Fixed-point fractional library routines.
- (line 1538)
- * __fractunssqsi: Fixed-point fractional library routines.
- (line 1540)
- * __fractunssqti: Fixed-point fractional library routines.
- (line 1542)
- * __fractunstadi: Fixed-point fractional library routines.
- (line 1567)
- * __fractunstahi: Fixed-point fractional library routines.
- (line 1565)
- * __fractunstaqi: Fixed-point fractional library routines.
- (line 1564)
- * __fractunstasi: Fixed-point fractional library routines.
- (line 1566)
- * __fractunstati: Fixed-point fractional library routines.
- (line 1568)
- * __fractunstida: Fixed-point fractional library routines.
- (line 1737)
- * __fractunstidq: Fixed-point fractional library routines.
- (line 1733)
- * __fractunstiha: Fixed-point fractional library routines.
- (line 1735)
- * __fractunstihq: Fixed-point fractional library routines.
- (line 1731)
- * __fractunstiqq: Fixed-point fractional library routines.
- (line 1730)
- * __fractunstisa: Fixed-point fractional library routines.
- (line 1736)
- * __fractunstisq: Fixed-point fractional library routines.
- (line 1732)
- * __fractunstita: Fixed-point fractional library routines.
- (line 1738)
- * __fractunstiuda: Fixed-point fractional library routines.
- (line 1752)
- * __fractunstiudq: Fixed-point fractional library routines.
- (line 1746)
- * __fractunstiuha: Fixed-point fractional library routines.
- (line 1748)
- * __fractunstiuhq: Fixed-point fractional library routines.
- (line 1742)
- * __fractunstiuqq: Fixed-point fractional library routines.
- (line 1740)
- * __fractunstiusa: Fixed-point fractional library routines.
- (line 1750)
- * __fractunstiusq: Fixed-point fractional library routines.
- (line 1744)
- * __fractunstiuta: Fixed-point fractional library routines.
- (line 1754)
- * __fractunsudadi: Fixed-point fractional library routines.
- (line 1628)
- * __fractunsudahi: Fixed-point fractional library routines.
- (line 1624)
- * __fractunsudaqi: Fixed-point fractional library routines.
- (line 1622)
- * __fractunsudasi: Fixed-point fractional library routines.
- (line 1626)
- * __fractunsudati: Fixed-point fractional library routines.
- (line 1630)
- * __fractunsudqdi: Fixed-point fractional library routines.
- (line 1602)
- * __fractunsudqhi: Fixed-point fractional library routines.
- (line 1598)
- * __fractunsudqqi: Fixed-point fractional library routines.
- (line 1596)
- * __fractunsudqsi: Fixed-point fractional library routines.
- (line 1600)
- * __fractunsudqti: Fixed-point fractional library routines.
- (line 1604)
- * __fractunsuhadi: Fixed-point fractional library routines.
- (line 1612)
- * __fractunsuhahi: Fixed-point fractional library routines.
- (line 1608)
- * __fractunsuhaqi: Fixed-point fractional library routines.
- (line 1606)
- * __fractunsuhasi: Fixed-point fractional library routines.
- (line 1610)
- * __fractunsuhati: Fixed-point fractional library routines.
- (line 1614)
- * __fractunsuhqdi: Fixed-point fractional library routines.
- (line 1583)
- * __fractunsuhqhi: Fixed-point fractional library routines.
- (line 1581)
- * __fractunsuhqqi: Fixed-point fractional library routines.
- (line 1580)
- * __fractunsuhqsi: Fixed-point fractional library routines.
- (line 1582)
- * __fractunsuhqti: Fixed-point fractional library routines.
- (line 1584)
- * __fractunsuqqdi: Fixed-point fractional library routines.
- (line 1576)
- * __fractunsuqqhi: Fixed-point fractional library routines.
- (line 1572)
- * __fractunsuqqqi: Fixed-point fractional library routines.
- (line 1570)
- * __fractunsuqqsi: Fixed-point fractional library routines.
- (line 1574)
- * __fractunsuqqti: Fixed-point fractional library routines.
- (line 1578)
- * __fractunsusadi: Fixed-point fractional library routines.
- (line 1619)
- * __fractunsusahi: Fixed-point fractional library routines.
- (line 1617)
- * __fractunsusaqi: Fixed-point fractional library routines.
- (line 1616)
- * __fractunsusasi: Fixed-point fractional library routines.
- (line 1618)
- * __fractunsusati: Fixed-point fractional library routines.
- (line 1620)
- * __fractunsusqdi: Fixed-point fractional library routines.
- (line 1592)
- * __fractunsusqhi: Fixed-point fractional library routines.
- (line 1588)
- * __fractunsusqqi: Fixed-point fractional library routines.
- (line 1586)
- * __fractunsusqsi: Fixed-point fractional library routines.
- (line 1590)
- * __fractunsusqti: Fixed-point fractional library routines.
- (line 1594)
- * __fractunsutadi: Fixed-point fractional library routines.
- (line 1638)
- * __fractunsutahi: Fixed-point fractional library routines.
- (line 1634)
- * __fractunsutaqi: Fixed-point fractional library routines.
- (line 1632)
- * __fractunsutasi: Fixed-point fractional library routines.
- (line 1636)
- * __fractunsutati: Fixed-point fractional library routines.
- (line 1640)
- * __fractuqqda: Fixed-point fractional library routines.
- (line 679)
- * __fractuqqdf: Fixed-point fractional library routines.
- (line 702)
- * __fractuqqdi: Fixed-point fractional library routines.
- (line 699)
- * __fractuqqdq: Fixed-point fractional library routines.
- (line 675)
- * __fractuqqha: Fixed-point fractional library routines.
- (line 677)
- * __fractuqqhi: Fixed-point fractional library routines.
- (line 697)
- * __fractuqqhq: Fixed-point fractional library routines.
- (line 673)
- * __fractuqqqi: Fixed-point fractional library routines.
- (line 696)
- * __fractuqqqq: Fixed-point fractional library routines.
- (line 672)
- * __fractuqqsa: Fixed-point fractional library routines.
- (line 678)
- * __fractuqqsf: Fixed-point fractional library routines.
- (line 701)
- * __fractuqqsi: Fixed-point fractional library routines.
- (line 698)
- * __fractuqqsq: Fixed-point fractional library routines.
- (line 674)
- * __fractuqqta: Fixed-point fractional library routines.
- (line 680)
- * __fractuqqti: Fixed-point fractional library routines.
- (line 700)
- * __fractuqquda: Fixed-point fractional library routines.
- (line 692)
- * __fractuqqudq2: Fixed-point fractional library routines.
- (line 686)
- * __fractuqquha: Fixed-point fractional library routines.
- (line 688)
- * __fractuqquhq2: Fixed-point fractional library routines.
- (line 682)
- * __fractuqqusa: Fixed-point fractional library routines.
- (line 690)
- * __fractuqqusq2: Fixed-point fractional library routines.
- (line 684)
- * __fractuqquta: Fixed-point fractional library routines.
- (line 694)
- * __fractusada: Fixed-point fractional library routines.
- (line 836)
- * __fractusadf: Fixed-point fractional library routines.
- (line 857)
- * __fractusadi: Fixed-point fractional library routines.
- (line 854)
- * __fractusadq: Fixed-point fractional library routines.
- (line 833)
- * __fractusaha: Fixed-point fractional library routines.
- (line 834)
- * __fractusahi: Fixed-point fractional library routines.
- (line 852)
- * __fractusahq: Fixed-point fractional library routines.
- (line 831)
- * __fractusaqi: Fixed-point fractional library routines.
- (line 851)
- * __fractusaqq: Fixed-point fractional library routines.
- (line 830)
- * __fractusasa: Fixed-point fractional library routines.
- (line 835)
- * __fractusasf: Fixed-point fractional library routines.
- (line 856)
- * __fractusasi: Fixed-point fractional library routines.
- (line 853)
- * __fractusasq: Fixed-point fractional library routines.
- (line 832)
- * __fractusata: Fixed-point fractional library routines.
- (line 837)
- * __fractusati: Fixed-point fractional library routines.
- (line 855)
- * __fractusauda2: Fixed-point fractional library routines.
- (line 847)
- * __fractusaudq: Fixed-point fractional library routines.
- (line 843)
- * __fractusauha2: Fixed-point fractional library routines.
- (line 845)
- * __fractusauhq: Fixed-point fractional library routines.
- (line 840)
- * __fractusauqq: Fixed-point fractional library routines.
- (line 838)
- * __fractusausq: Fixed-point fractional library routines.
- (line 841)
- * __fractusauta2: Fixed-point fractional library routines.
- (line 849)
- * __fractusqda: Fixed-point fractional library routines.
- (line 738)
- * __fractusqdf: Fixed-point fractional library routines.
- (line 761)
- * __fractusqdi: Fixed-point fractional library routines.
- (line 758)
- * __fractusqdq: Fixed-point fractional library routines.
- (line 734)
- * __fractusqha: Fixed-point fractional library routines.
- (line 736)
- * __fractusqhi: Fixed-point fractional library routines.
- (line 756)
- * __fractusqhq: Fixed-point fractional library routines.
- (line 732)
- * __fractusqqi: Fixed-point fractional library routines.
- (line 755)
- * __fractusqqq: Fixed-point fractional library routines.
- (line 731)
- * __fractusqsa: Fixed-point fractional library routines.
- (line 737)
- * __fractusqsf: Fixed-point fractional library routines.
- (line 760)
- * __fractusqsi: Fixed-point fractional library routines.
- (line 757)
- * __fractusqsq: Fixed-point fractional library routines.
- (line 733)
- * __fractusqta: Fixed-point fractional library routines.
- (line 739)
- * __fractusqti: Fixed-point fractional library routines.
- (line 759)
- * __fractusquda: Fixed-point fractional library routines.
- (line 751)
- * __fractusqudq2: Fixed-point fractional library routines.
- (line 745)
- * __fractusquha: Fixed-point fractional library routines.
- (line 747)
- * __fractusquhq2: Fixed-point fractional library routines.
- (line 743)
- * __fractusquqq2: Fixed-point fractional library routines.
- (line 741)
- * __fractusqusa: Fixed-point fractional library routines.
- (line 749)
- * __fractusquta: Fixed-point fractional library routines.
- (line 753)
- * __fractutada: Fixed-point fractional library routines.
- (line 899)
- * __fractutadf: Fixed-point fractional library routines.
- (line 925)
- * __fractutadi: Fixed-point fractional library routines.
- (line 921)
- * __fractutadq: Fixed-point fractional library routines.
- (line 894)
- * __fractutaha: Fixed-point fractional library routines.
- (line 896)
- * __fractutahi: Fixed-point fractional library routines.
- (line 919)
- * __fractutahq: Fixed-point fractional library routines.
- (line 891)
- * __fractutaqi: Fixed-point fractional library routines.
- (line 917)
- * __fractutaqq: Fixed-point fractional library routines.
- (line 889)
- * __fractutasa: Fixed-point fractional library routines.
- (line 898)
- * __fractutasf: Fixed-point fractional library routines.
- (line 924)
- * __fractutasi: Fixed-point fractional library routines.
- (line 920)
- * __fractutasq: Fixed-point fractional library routines.
- (line 892)
- * __fractutata: Fixed-point fractional library routines.
- (line 901)
- * __fractutati: Fixed-point fractional library routines.
- (line 922)
- * __fractutauda2: Fixed-point fractional library routines.
- (line 915)
- * __fractutaudq: Fixed-point fractional library routines.
- (line 909)
- * __fractutauha2: Fixed-point fractional library routines.
- (line 911)
- * __fractutauhq: Fixed-point fractional library routines.
- (line 905)
- * __fractutauqq: Fixed-point fractional library routines.
- (line 903)
- * __fractutausa2: Fixed-point fractional library routines.
- (line 913)
- * __fractutausq: Fixed-point fractional library routines.
- (line 907)
- * __gedf2: Soft float library routines.
- (line 205)
- * __gesf2: Soft float library routines.
- (line 204)
- * __getf2: Soft float library routines.
- (line 206)
- * __gtdf2: Soft float library routines.
- (line 223)
- * __gtsf2: Soft float library routines.
- (line 222)
- * __gttf2: Soft float library routines.
- (line 224)
- * __ledf2: Soft float library routines.
- (line 217)
- * __lesf2: Soft float library routines.
- (line 216)
- * __letf2: Soft float library routines.
- (line 218)
- * __lshrdi3: Integer library routines.
- (line 30)
- * __lshrsi3: Integer library routines.
- (line 29)
- * __lshrti3: Integer library routines.
- (line 31)
- * __lshruda3: Fixed-point fractional library routines.
- (line 396)
- * __lshrudq3: Fixed-point fractional library routines.
- (line 390)
- * __lshruha3: Fixed-point fractional library routines.
- (line 392)
- * __lshruhq3: Fixed-point fractional library routines.
- (line 386)
- * __lshruqq3: Fixed-point fractional library routines.
- (line 384)
- * __lshrusa3: Fixed-point fractional library routines.
- (line 394)
- * __lshrusq3: Fixed-point fractional library routines.
- (line 388)
- * __lshruta3: Fixed-point fractional library routines.
- (line 398)
- * __ltdf2: Soft float library routines.
- (line 211)
- * __ltsf2: Soft float library routines.
- (line 210)
- * __lttf2: Soft float library routines.
- (line 212)
- * __main: Collect2. (line 15)
- * __moddi3: Integer library routines.
- (line 36)
- * __modsi3: Integer library routines.
- (line 35)
- * __modti3: Integer library routines.
- (line 37)
- * __morestack_current_segment: Miscellaneous routines.
- (line 45)
- * __morestack_initial_sp: Miscellaneous routines.
- (line 46)
- * __morestack_segments: Miscellaneous routines.
- (line 44)
- * __mulda3: Fixed-point fractional library routines.
- (line 178)
- * __muldc3: Soft float library routines.
- (line 239)
- * __muldf3: Soft float library routines.
- (line 39)
- * __muldi3: Integer library routines.
- (line 42)
- * __muldq3: Fixed-point fractional library routines.
- (line 165)
- * __mulha3: Fixed-point fractional library routines.
- (line 175)
- * __mulhq3: Fixed-point fractional library routines.
- (line 163)
- * __mulqq3: Fixed-point fractional library routines.
- (line 161)
- * __mulsa3: Fixed-point fractional library routines.
- (line 177)
- * __mulsc3: Soft float library routines.
- (line 237)
- * __mulsf3: Soft float library routines.
- (line 38)
- * __mulsi3: Integer library routines.
- (line 41)
- * __mulsq3: Fixed-point fractional library routines.
- (line 164)
- * __multa3: Fixed-point fractional library routines.
- (line 179)
- * __multc3: Soft float library routines.
- (line 241)
- * __multf3: Soft float library routines.
- (line 40)
- * __multi3: Integer library routines.
- (line 43)
- * __muluda3: Fixed-point fractional library routines.
- (line 185)
- * __muludq3: Fixed-point fractional library routines.
- (line 173)
- * __muluha3: Fixed-point fractional library routines.
- (line 181)
- * __muluhq3: Fixed-point fractional library routines.
- (line 169)
- * __muluqq3: Fixed-point fractional library routines.
- (line 167)
- * __mulusa3: Fixed-point fractional library routines.
- (line 183)
- * __mulusq3: Fixed-point fractional library routines.
- (line 171)
- * __muluta3: Fixed-point fractional library routines.
- (line 187)
- * __mulvdi3: Integer library routines.
- (line 114)
- * __mulvsi3: Integer library routines.
- (line 113)
- * __mulxc3: Soft float library routines.
- (line 243)
- * __mulxf3: Soft float library routines.
- (line 42)
- * __nedf2: Soft float library routines.
- (line 199)
- * __negda2: Fixed-point fractional library routines.
- (line 306)
- * __negdf2: Soft float library routines.
- (line 55)
- * __negdi2: Integer library routines.
- (line 46)
- * __negdq2: Fixed-point fractional library routines.
- (line 296)
- * __negha2: Fixed-point fractional library routines.
- (line 304)
- * __neghq2: Fixed-point fractional library routines.
- (line 294)
- * __negqq2: Fixed-point fractional library routines.
- (line 293)
- * __negsa2: Fixed-point fractional library routines.
- (line 305)
- * __negsf2: Soft float library routines.
- (line 54)
- * __negsq2: Fixed-point fractional library routines.
- (line 295)
- * __negta2: Fixed-point fractional library routines.
- (line 307)
- * __negtf2: Soft float library routines.
- (line 56)
- * __negti2: Integer library routines.
- (line 47)
- * __neguda2: Fixed-point fractional library routines.
- (line 311)
- * __negudq2: Fixed-point fractional library routines.
- (line 302)
- * __neguha2: Fixed-point fractional library routines.
- (line 308)
- * __neguhq2: Fixed-point fractional library routines.
- (line 299)
- * __neguqq2: Fixed-point fractional library routines.
- (line 297)
- * __negusa2: Fixed-point fractional library routines.
- (line 310)
- * __negusq2: Fixed-point fractional library routines.
- (line 300)
- * __neguta2: Fixed-point fractional library routines.
- (line 313)
- * __negvdi2: Integer library routines.
- (line 118)
- * __negvsi2: Integer library routines.
- (line 117)
- * __negxf2: Soft float library routines.
- (line 57)
- * __nesf2: Soft float library routines.
- (line 198)
- * __netf2: Soft float library routines.
- (line 200)
- * __paritydi2: Integer library routines.
- (line 150)
- * __paritysi2: Integer library routines.
- (line 149)
- * __parityti2: Integer library routines.
- (line 151)
- * __popcountdi2: Integer library routines.
- (line 156)
- * __popcountsi2: Integer library routines.
- (line 155)
- * __popcountti2: Integer library routines.
- (line 157)
- * __powidf2: Soft float library routines.
- (line 232)
- * __powisf2: Soft float library routines.
- (line 231)
- * __powitf2: Soft float library routines.
- (line 233)
- * __powixf2: Soft float library routines.
- (line 234)
- * __satfractdadq: Fixed-point fractional library routines.
- (line 1160)
- * __satfractdaha2: Fixed-point fractional library routines.
- (line 1161)
- * __satfractdahq: Fixed-point fractional library routines.
- (line 1158)
- * __satfractdaqq: Fixed-point fractional library routines.
- (line 1157)
- * __satfractdasa2: Fixed-point fractional library routines.
- (line 1162)
- * __satfractdasq: Fixed-point fractional library routines.
- (line 1159)
- * __satfractdata2: Fixed-point fractional library routines.
- (line 1163)
- * __satfractdauda: Fixed-point fractional library routines.
- (line 1173)
- * __satfractdaudq: Fixed-point fractional library routines.
- (line 1168)
- * __satfractdauha: Fixed-point fractional library routines.
- (line 1170)
- * __satfractdauhq: Fixed-point fractional library routines.
- (line 1166)
- * __satfractdauqq: Fixed-point fractional library routines.
- (line 1164)
- * __satfractdausa: Fixed-point fractional library routines.
- (line 1172)
- * __satfractdausq: Fixed-point fractional library routines.
- (line 1167)
- * __satfractdauta: Fixed-point fractional library routines.
- (line 1174)
- * __satfractdfda: Fixed-point fractional library routines.
- (line 1513)
- * __satfractdfdq: Fixed-point fractional library routines.
- (line 1510)
- * __satfractdfha: Fixed-point fractional library routines.
- (line 1511)
- * __satfractdfhq: Fixed-point fractional library routines.
- (line 1508)
- * __satfractdfqq: Fixed-point fractional library routines.
- (line 1507)
- * __satfractdfsa: Fixed-point fractional library routines.
- (line 1512)
- * __satfractdfsq: Fixed-point fractional library routines.
- (line 1509)
- * __satfractdfta: Fixed-point fractional library routines.
- (line 1514)
- * __satfractdfuda: Fixed-point fractional library routines.
- (line 1522)
- * __satfractdfudq: Fixed-point fractional library routines.
- (line 1518)
- * __satfractdfuha: Fixed-point fractional library routines.
- (line 1520)
- * __satfractdfuhq: Fixed-point fractional library routines.
- (line 1516)
- * __satfractdfuqq: Fixed-point fractional library routines.
- (line 1515)
- * __satfractdfusa: Fixed-point fractional library routines.
- (line 1521)
- * __satfractdfusq: Fixed-point fractional library routines.
- (line 1517)
- * __satfractdfuta: Fixed-point fractional library routines.
- (line 1523)
- * __satfractdida: Fixed-point fractional library routines.
- (line 1463)
- * __satfractdidq: Fixed-point fractional library routines.
- (line 1460)
- * __satfractdiha: Fixed-point fractional library routines.
- (line 1461)
- * __satfractdihq: Fixed-point fractional library routines.
- (line 1458)
- * __satfractdiqq: Fixed-point fractional library routines.
- (line 1457)
- * __satfractdisa: Fixed-point fractional library routines.
- (line 1462)
- * __satfractdisq: Fixed-point fractional library routines.
- (line 1459)
- * __satfractdita: Fixed-point fractional library routines.
- (line 1464)
- * __satfractdiuda: Fixed-point fractional library routines.
- (line 1471)
- * __satfractdiudq: Fixed-point fractional library routines.
- (line 1468)
- * __satfractdiuha: Fixed-point fractional library routines.
- (line 1469)
- * __satfractdiuhq: Fixed-point fractional library routines.
- (line 1466)
- * __satfractdiuqq: Fixed-point fractional library routines.
- (line 1465)
- * __satfractdiusa: Fixed-point fractional library routines.
- (line 1470)
- * __satfractdiusq: Fixed-point fractional library routines.
- (line 1467)
- * __satfractdiuta: Fixed-point fractional library routines.
- (line 1472)
- * __satfractdqda: Fixed-point fractional library routines.
- (line 1105)
- * __satfractdqha: Fixed-point fractional library routines.
- (line 1103)
- * __satfractdqhq2: Fixed-point fractional library routines.
- (line 1101)
- * __satfractdqqq2: Fixed-point fractional library routines.
- (line 1100)
- * __satfractdqsa: Fixed-point fractional library routines.
- (line 1104)
- * __satfractdqsq2: Fixed-point fractional library routines.
- (line 1102)
- * __satfractdqta: Fixed-point fractional library routines.
- (line 1106)
- * __satfractdquda: Fixed-point fractional library routines.
- (line 1117)
- * __satfractdqudq: Fixed-point fractional library routines.
- (line 1112)
- * __satfractdquha: Fixed-point fractional library routines.
- (line 1114)
- * __satfractdquhq: Fixed-point fractional library routines.
- (line 1109)
- * __satfractdquqq: Fixed-point fractional library routines.
- (line 1107)
- * __satfractdqusa: Fixed-point fractional library routines.
- (line 1116)
- * __satfractdqusq: Fixed-point fractional library routines.
- (line 1110)
- * __satfractdquta: Fixed-point fractional library routines.
- (line 1119)
- * __satfracthada2: Fixed-point fractional library routines.
- (line 1126)
- * __satfracthadq: Fixed-point fractional library routines.
- (line 1124)
- * __satfracthahq: Fixed-point fractional library routines.
- (line 1122)
- * __satfracthaqq: Fixed-point fractional library routines.
- (line 1121)
- * __satfracthasa2: Fixed-point fractional library routines.
- (line 1125)
- * __satfracthasq: Fixed-point fractional library routines.
- (line 1123)
- * __satfracthata2: Fixed-point fractional library routines.
- (line 1127)
- * __satfracthauda: Fixed-point fractional library routines.
- (line 1138)
- * __satfracthaudq: Fixed-point fractional library routines.
- (line 1133)
- * __satfracthauha: Fixed-point fractional library routines.
- (line 1135)
- * __satfracthauhq: Fixed-point fractional library routines.
- (line 1130)
- * __satfracthauqq: Fixed-point fractional library routines.
- (line 1128)
- * __satfracthausa: Fixed-point fractional library routines.
- (line 1137)
- * __satfracthausq: Fixed-point fractional library routines.
- (line 1131)
- * __satfracthauta: Fixed-point fractional library routines.
- (line 1140)
- * __satfracthida: Fixed-point fractional library routines.
- (line 1431)
- * __satfracthidq: Fixed-point fractional library routines.
- (line 1428)
- * __satfracthiha: Fixed-point fractional library routines.
- (line 1429)
- * __satfracthihq: Fixed-point fractional library routines.
- (line 1426)
- * __satfracthiqq: Fixed-point fractional library routines.
- (line 1425)
- * __satfracthisa: Fixed-point fractional library routines.
- (line 1430)
- * __satfracthisq: Fixed-point fractional library routines.
- (line 1427)
- * __satfracthita: Fixed-point fractional library routines.
- (line 1432)
- * __satfracthiuda: Fixed-point fractional library routines.
- (line 1439)
- * __satfracthiudq: Fixed-point fractional library routines.
- (line 1436)
- * __satfracthiuha: Fixed-point fractional library routines.
- (line 1437)
- * __satfracthiuhq: Fixed-point fractional library routines.
- (line 1434)
- * __satfracthiuqq: Fixed-point fractional library routines.
- (line 1433)
- * __satfracthiusa: Fixed-point fractional library routines.
- (line 1438)
- * __satfracthiusq: Fixed-point fractional library routines.
- (line 1435)
- * __satfracthiuta: Fixed-point fractional library routines.
- (line 1440)
- * __satfracthqda: Fixed-point fractional library routines.
- (line 1071)
- * __satfracthqdq2: Fixed-point fractional library routines.
- (line 1068)
- * __satfracthqha: Fixed-point fractional library routines.
- (line 1069)
- * __satfracthqqq2: Fixed-point fractional library routines.
- (line 1066)
- * __satfracthqsa: Fixed-point fractional library routines.
- (line 1070)
- * __satfracthqsq2: Fixed-point fractional library routines.
- (line 1067)
- * __satfracthqta: Fixed-point fractional library routines.
- (line 1072)
- * __satfracthquda: Fixed-point fractional library routines.
- (line 1079)
- * __satfracthqudq: Fixed-point fractional library routines.
- (line 1076)
- * __satfracthquha: Fixed-point fractional library routines.
- (line 1077)
- * __satfracthquhq: Fixed-point fractional library routines.
- (line 1074)
- * __satfracthquqq: Fixed-point fractional library routines.
- (line 1073)
- * __satfracthqusa: Fixed-point fractional library routines.
- (line 1078)
- * __satfracthqusq: Fixed-point fractional library routines.
- (line 1075)
- * __satfracthquta: Fixed-point fractional library routines.
- (line 1080)
- * __satfractqida: Fixed-point fractional library routines.
- (line 1409)
- * __satfractqidq: Fixed-point fractional library routines.
- (line 1406)
- * __satfractqiha: Fixed-point fractional library routines.
- (line 1407)
- * __satfractqihq: Fixed-point fractional library routines.
- (line 1404)
- * __satfractqiqq: Fixed-point fractional library routines.
- (line 1403)
- * __satfractqisa: Fixed-point fractional library routines.
- (line 1408)
- * __satfractqisq: Fixed-point fractional library routines.
- (line 1405)
- * __satfractqita: Fixed-point fractional library routines.
- (line 1410)
- * __satfractqiuda: Fixed-point fractional library routines.
- (line 1421)
- * __satfractqiudq: Fixed-point fractional library routines.
- (line 1416)
- * __satfractqiuha: Fixed-point fractional library routines.
- (line 1418)
- * __satfractqiuhq: Fixed-point fractional library routines.
- (line 1413)
- * __satfractqiuqq: Fixed-point fractional library routines.
- (line 1411)
- * __satfractqiusa: Fixed-point fractional library routines.
- (line 1420)
- * __satfractqiusq: Fixed-point fractional library routines.
- (line 1414)
- * __satfractqiuta: Fixed-point fractional library routines.
- (line 1423)
- * __satfractqqda: Fixed-point fractional library routines.
- (line 1050)
- * __satfractqqdq2: Fixed-point fractional library routines.
- (line 1047)
- * __satfractqqha: Fixed-point fractional library routines.
- (line 1048)
- * __satfractqqhq2: Fixed-point fractional library routines.
- (line 1045)
- * __satfractqqsa: Fixed-point fractional library routines.
- (line 1049)
- * __satfractqqsq2: Fixed-point fractional library routines.
- (line 1046)
- * __satfractqqta: Fixed-point fractional library routines.
- (line 1051)
- * __satfractqquda: Fixed-point fractional library routines.
- (line 1062)
- * __satfractqqudq: Fixed-point fractional library routines.
- (line 1057)
- * __satfractqquha: Fixed-point fractional library routines.
- (line 1059)
- * __satfractqquhq: Fixed-point fractional library routines.
- (line 1054)
- * __satfractqquqq: Fixed-point fractional library routines.
- (line 1052)
- * __satfractqqusa: Fixed-point fractional library routines.
- (line 1061)
- * __satfractqqusq: Fixed-point fractional library routines.
- (line 1055)
- * __satfractqquta: Fixed-point fractional library routines.
- (line 1064)
- * __satfractsada2: Fixed-point fractional library routines.
- (line 1147)
- * __satfractsadq: Fixed-point fractional library routines.
- (line 1145)
- * __satfractsaha2: Fixed-point fractional library routines.
- (line 1146)
- * __satfractsahq: Fixed-point fractional library routines.
- (line 1143)
- * __satfractsaqq: Fixed-point fractional library routines.
- (line 1142)
- * __satfractsasq: Fixed-point fractional library routines.
- (line 1144)
- * __satfractsata2: Fixed-point fractional library routines.
- (line 1148)
- * __satfractsauda: Fixed-point fractional library routines.
- (line 1155)
- * __satfractsaudq: Fixed-point fractional library routines.
- (line 1152)
- * __satfractsauha: Fixed-point fractional library routines.
- (line 1153)
- * __satfractsauhq: Fixed-point fractional library routines.
- (line 1150)
- * __satfractsauqq: Fixed-point fractional library routines.
- (line 1149)
- * __satfractsausa: Fixed-point fractional library routines.
- (line 1154)
- * __satfractsausq: Fixed-point fractional library routines.
- (line 1151)
- * __satfractsauta: Fixed-point fractional library routines.
- (line 1156)
- * __satfractsfda: Fixed-point fractional library routines.
- (line 1497)
- * __satfractsfdq: Fixed-point fractional library routines.
- (line 1494)
- * __satfractsfha: Fixed-point fractional library routines.
- (line 1495)
- * __satfractsfhq: Fixed-point fractional library routines.
- (line 1492)
- * __satfractsfqq: Fixed-point fractional library routines.
- (line 1491)
- * __satfractsfsa: Fixed-point fractional library routines.
- (line 1496)
- * __satfractsfsq: Fixed-point fractional library routines.
- (line 1493)
- * __satfractsfta: Fixed-point fractional library routines.
- (line 1498)
- * __satfractsfuda: Fixed-point fractional library routines.
- (line 1505)
- * __satfractsfudq: Fixed-point fractional library routines.
- (line 1502)
- * __satfractsfuha: Fixed-point fractional library routines.
- (line 1503)
- * __satfractsfuhq: Fixed-point fractional library routines.
- (line 1500)
- * __satfractsfuqq: Fixed-point fractional library routines.
- (line 1499)
- * __satfractsfusa: Fixed-point fractional library routines.
- (line 1504)
- * __satfractsfusq: Fixed-point fractional library routines.
- (line 1501)
- * __satfractsfuta: Fixed-point fractional library routines.
- (line 1506)
- * __satfractsida: Fixed-point fractional library routines.
- (line 1447)
- * __satfractsidq: Fixed-point fractional library routines.
- (line 1444)
- * __satfractsiha: Fixed-point fractional library routines.
- (line 1445)
- * __satfractsihq: Fixed-point fractional library routines.
- (line 1442)
- * __satfractsiqq: Fixed-point fractional library routines.
- (line 1441)
- * __satfractsisa: Fixed-point fractional library routines.
- (line 1446)
- * __satfractsisq: Fixed-point fractional library routines.
- (line 1443)
- * __satfractsita: Fixed-point fractional library routines.
- (line 1448)
- * __satfractsiuda: Fixed-point fractional library routines.
- (line 1455)
- * __satfractsiudq: Fixed-point fractional library routines.
- (line 1452)
- * __satfractsiuha: Fixed-point fractional library routines.
- (line 1453)
- * __satfractsiuhq: Fixed-point fractional library routines.
- (line 1450)
- * __satfractsiuqq: Fixed-point fractional library routines.
- (line 1449)
- * __satfractsiusa: Fixed-point fractional library routines.
- (line 1454)
- * __satfractsiusq: Fixed-point fractional library routines.
- (line 1451)
- * __satfractsiuta: Fixed-point fractional library routines.
- (line 1456)
- * __satfractsqda: Fixed-point fractional library routines.
- (line 1086)
- * __satfractsqdq2: Fixed-point fractional library routines.
- (line 1083)
- * __satfractsqha: Fixed-point fractional library routines.
- (line 1084)
- * __satfractsqhq2: Fixed-point fractional library routines.
- (line 1082)
- * __satfractsqqq2: Fixed-point fractional library routines.
- (line 1081)
- * __satfractsqsa: Fixed-point fractional library routines.
- (line 1085)
- * __satfractsqta: Fixed-point fractional library routines.
- (line 1087)
- * __satfractsquda: Fixed-point fractional library routines.
- (line 1097)
- * __satfractsqudq: Fixed-point fractional library routines.
- (line 1092)
- * __satfractsquha: Fixed-point fractional library routines.
- (line 1094)
- * __satfractsquhq: Fixed-point fractional library routines.
- (line 1090)
- * __satfractsquqq: Fixed-point fractional library routines.
- (line 1088)
- * __satfractsqusa: Fixed-point fractional library routines.
- (line 1096)
- * __satfractsqusq: Fixed-point fractional library routines.
- (line 1091)
- * __satfractsquta: Fixed-point fractional library routines.
- (line 1098)
- * __satfracttada2: Fixed-point fractional library routines.
- (line 1182)
- * __satfracttadq: Fixed-point fractional library routines.
- (line 1179)
- * __satfracttaha2: Fixed-point fractional library routines.
- (line 1180)
- * __satfracttahq: Fixed-point fractional library routines.
- (line 1177)
- * __satfracttaqq: Fixed-point fractional library routines.
- (line 1176)
- * __satfracttasa2: Fixed-point fractional library routines.
- (line 1181)
- * __satfracttasq: Fixed-point fractional library routines.
- (line 1178)
- * __satfracttauda: Fixed-point fractional library routines.
- (line 1193)
- * __satfracttaudq: Fixed-point fractional library routines.
- (line 1188)
- * __satfracttauha: Fixed-point fractional library routines.
- (line 1190)
- * __satfracttauhq: Fixed-point fractional library routines.
- (line 1185)
- * __satfracttauqq: Fixed-point fractional library routines.
- (line 1183)
- * __satfracttausa: Fixed-point fractional library routines.
- (line 1192)
- * __satfracttausq: Fixed-point fractional library routines.
- (line 1186)
- * __satfracttauta: Fixed-point fractional library routines.
- (line 1195)
- * __satfracttida: Fixed-point fractional library routines.
- (line 1479)
- * __satfracttidq: Fixed-point fractional library routines.
- (line 1476)
- * __satfracttiha: Fixed-point fractional library routines.
- (line 1477)
- * __satfracttihq: Fixed-point fractional library routines.
- (line 1474)
- * __satfracttiqq: Fixed-point fractional library routines.
- (line 1473)
- * __satfracttisa: Fixed-point fractional library routines.
- (line 1478)
- * __satfracttisq: Fixed-point fractional library routines.
- (line 1475)
- * __satfracttita: Fixed-point fractional library routines.
- (line 1480)
- * __satfracttiuda: Fixed-point fractional library routines.
- (line 1488)
- * __satfracttiudq: Fixed-point fractional library routines.
- (line 1484)
- * __satfracttiuha: Fixed-point fractional library routines.
- (line 1486)
- * __satfracttiuhq: Fixed-point fractional library routines.
- (line 1482)
- * __satfracttiuqq: Fixed-point fractional library routines.
- (line 1481)
- * __satfracttiusa: Fixed-point fractional library routines.
- (line 1487)
- * __satfracttiusq: Fixed-point fractional library routines.
- (line 1483)
- * __satfracttiuta: Fixed-point fractional library routines.
- (line 1489)
- * __satfractudada: Fixed-point fractional library routines.
- (line 1358)
- * __satfractudadq: Fixed-point fractional library routines.
- (line 1353)
- * __satfractudaha: Fixed-point fractional library routines.
- (line 1355)
- * __satfractudahq: Fixed-point fractional library routines.
- (line 1351)
- * __satfractudaqq: Fixed-point fractional library routines.
- (line 1349)
- * __satfractudasa: Fixed-point fractional library routines.
- (line 1357)
- * __satfractudasq: Fixed-point fractional library routines.
- (line 1352)
- * __satfractudata: Fixed-point fractional library routines.
- (line 1359)
- * __satfractudaudq: Fixed-point fractional library routines.
- (line 1367)
- * __satfractudauha2: Fixed-point fractional library routines.
- (line 1369)
- * __satfractudauhq: Fixed-point fractional library routines.
- (line 1363)
- * __satfractudauqq: Fixed-point fractional library routines.
- (line 1361)
- * __satfractudausa2: Fixed-point fractional library routines.
- (line 1371)
- * __satfractudausq: Fixed-point fractional library routines.
- (line 1365)
- * __satfractudauta2: Fixed-point fractional library routines.
- (line 1373)
- * __satfractudqda: Fixed-point fractional library routines.
- (line 1282)
- * __satfractudqdq: Fixed-point fractional library routines.
- (line 1277)
- * __satfractudqha: Fixed-point fractional library routines.
- (line 1279)
- * __satfractudqhq: Fixed-point fractional library routines.
- (line 1274)
- * __satfractudqqq: Fixed-point fractional library routines.
- (line 1272)
- * __satfractudqsa: Fixed-point fractional library routines.
- (line 1281)
- * __satfractudqsq: Fixed-point fractional library routines.
- (line 1275)
- * __satfractudqta: Fixed-point fractional library routines.
- (line 1284)
- * __satfractudquda: Fixed-point fractional library routines.
- (line 1296)
- * __satfractudquha: Fixed-point fractional library routines.
- (line 1292)
- * __satfractudquhq2: Fixed-point fractional library routines.
- (line 1288)
- * __satfractudquqq2: Fixed-point fractional library routines.
- (line 1286)
- * __satfractudqusa: Fixed-point fractional library routines.
- (line 1294)
- * __satfractudqusq2: Fixed-point fractional library routines.
- (line 1290)
- * __satfractudquta: Fixed-point fractional library routines.
- (line 1298)
- * __satfractuhada: Fixed-point fractional library routines.
- (line 1310)
- * __satfractuhadq: Fixed-point fractional library routines.
- (line 1305)
- * __satfractuhaha: Fixed-point fractional library routines.
- (line 1307)
- * __satfractuhahq: Fixed-point fractional library routines.
- (line 1302)
- * __satfractuhaqq: Fixed-point fractional library routines.
- (line 1300)
- * __satfractuhasa: Fixed-point fractional library routines.
- (line 1309)
- * __satfractuhasq: Fixed-point fractional library routines.
- (line 1303)
- * __satfractuhata: Fixed-point fractional library routines.
- (line 1312)
- * __satfractuhauda2: Fixed-point fractional library routines.
- (line 1324)
- * __satfractuhaudq: Fixed-point fractional library routines.
- (line 1320)
- * __satfractuhauhq: Fixed-point fractional library routines.
- (line 1316)
- * __satfractuhauqq: Fixed-point fractional library routines.
- (line 1314)
- * __satfractuhausa2: Fixed-point fractional library routines.
- (line 1322)
- * __satfractuhausq: Fixed-point fractional library routines.
- (line 1318)
- * __satfractuhauta2: Fixed-point fractional library routines.
- (line 1326)
- * __satfractuhqda: Fixed-point fractional library routines.
- (line 1231)
- * __satfractuhqdq: Fixed-point fractional library routines.
- (line 1228)
- * __satfractuhqha: Fixed-point fractional library routines.
- (line 1229)
- * __satfractuhqhq: Fixed-point fractional library routines.
- (line 1226)
- * __satfractuhqqq: Fixed-point fractional library routines.
- (line 1225)
- * __satfractuhqsa: Fixed-point fractional library routines.
- (line 1230)
- * __satfractuhqsq: Fixed-point fractional library routines.
- (line 1227)
- * __satfractuhqta: Fixed-point fractional library routines.
- (line 1232)
- * __satfractuhquda: Fixed-point fractional library routines.
- (line 1242)
- * __satfractuhqudq2: Fixed-point fractional library routines.
- (line 1237)
- * __satfractuhquha: Fixed-point fractional library routines.
- (line 1239)
- * __satfractuhquqq2: Fixed-point fractional library routines.
- (line 1233)
- * __satfractuhqusa: Fixed-point fractional library routines.
- (line 1241)
- * __satfractuhqusq2: Fixed-point fractional library routines.
- (line 1235)
- * __satfractuhquta: Fixed-point fractional library routines.
- (line 1244)
- * __satfractunsdida: Fixed-point fractional library routines.
- (line 1841)
- * __satfractunsdidq: Fixed-point fractional library routines.
- (line 1837)
- * __satfractunsdiha: Fixed-point fractional library routines.
- (line 1839)
- * __satfractunsdihq: Fixed-point fractional library routines.
- (line 1835)
- * __satfractunsdiqq: Fixed-point fractional library routines.
- (line 1834)
- * __satfractunsdisa: Fixed-point fractional library routines.
- (line 1840)
- * __satfractunsdisq: Fixed-point fractional library routines.
- (line 1836)
- * __satfractunsdita: Fixed-point fractional library routines.
- (line 1842)
- * __satfractunsdiuda: Fixed-point fractional library routines.
- (line 1856)
- * __satfractunsdiudq: Fixed-point fractional library routines.
- (line 1850)
- * __satfractunsdiuha: Fixed-point fractional library routines.
- (line 1852)
- * __satfractunsdiuhq: Fixed-point fractional library routines.
- (line 1846)
- * __satfractunsdiuqq: Fixed-point fractional library routines.
- (line 1844)
- * __satfractunsdiusa: Fixed-point fractional library routines.
- (line 1854)
- * __satfractunsdiusq: Fixed-point fractional library routines.
- (line 1848)
- * __satfractunsdiuta: Fixed-point fractional library routines.
- (line 1858)
- * __satfractunshida: Fixed-point fractional library routines.
- (line 1793)
- * __satfractunshidq: Fixed-point fractional library routines.
- (line 1789)
- * __satfractunshiha: Fixed-point fractional library routines.
- (line 1791)
- * __satfractunshihq: Fixed-point fractional library routines.
- (line 1787)
- * __satfractunshiqq: Fixed-point fractional library routines.
- (line 1786)
- * __satfractunshisa: Fixed-point fractional library routines.
- (line 1792)
- * __satfractunshisq: Fixed-point fractional library routines.
- (line 1788)
- * __satfractunshita: Fixed-point fractional library routines.
- (line 1794)
- * __satfractunshiuda: Fixed-point fractional library routines.
- (line 1808)
- * __satfractunshiudq: Fixed-point fractional library routines.
- (line 1802)
- * __satfractunshiuha: Fixed-point fractional library routines.
- (line 1804)
- * __satfractunshiuhq: Fixed-point fractional library routines.
- (line 1798)
- * __satfractunshiuqq: Fixed-point fractional library routines.
- (line 1796)
- * __satfractunshiusa: Fixed-point fractional library routines.
- (line 1806)
- * __satfractunshiusq: Fixed-point fractional library routines.
- (line 1800)
- * __satfractunshiuta: Fixed-point fractional library routines.
- (line 1810)
- * __satfractunsqida: Fixed-point fractional library routines.
- (line 1767)
- * __satfractunsqidq: Fixed-point fractional library routines.
- (line 1763)
- * __satfractunsqiha: Fixed-point fractional library routines.
- (line 1765)
- * __satfractunsqihq: Fixed-point fractional library routines.
- (line 1761)
- * __satfractunsqiqq: Fixed-point fractional library routines.
- (line 1760)
- * __satfractunsqisa: Fixed-point fractional library routines.
- (line 1766)
- * __satfractunsqisq: Fixed-point fractional library routines.
- (line 1762)
- * __satfractunsqita: Fixed-point fractional library routines.
- (line 1768)
- * __satfractunsqiuda: Fixed-point fractional library routines.
- (line 1782)
- * __satfractunsqiudq: Fixed-point fractional library routines.
- (line 1776)
- * __satfractunsqiuha: Fixed-point fractional library routines.
- (line 1778)
- * __satfractunsqiuhq: Fixed-point fractional library routines.
- (line 1772)
- * __satfractunsqiuqq: Fixed-point fractional library routines.
- (line 1770)
- * __satfractunsqiusa: Fixed-point fractional library routines.
- (line 1780)
- * __satfractunsqiusq: Fixed-point fractional library routines.
- (line 1774)
- * __satfractunsqiuta: Fixed-point fractional library routines.
- (line 1784)
- * __satfractunssida: Fixed-point fractional library routines.
- (line 1818)
- * __satfractunssidq: Fixed-point fractional library routines.
- (line 1815)
- * __satfractunssiha: Fixed-point fractional library routines.
- (line 1816)
- * __satfractunssihq: Fixed-point fractional library routines.
- (line 1813)
- * __satfractunssiqq: Fixed-point fractional library routines.
- (line 1812)
- * __satfractunssisa: Fixed-point fractional library routines.
- (line 1817)
- * __satfractunssisq: Fixed-point fractional library routines.
- (line 1814)
- * __satfractunssita: Fixed-point fractional library routines.
- (line 1819)
- * __satfractunssiuda: Fixed-point fractional library routines.
- (line 1830)
- * __satfractunssiudq: Fixed-point fractional library routines.
- (line 1825)
- * __satfractunssiuha: Fixed-point fractional library routines.
- (line 1827)
- * __satfractunssiuhq: Fixed-point fractional library routines.
- (line 1822)
- * __satfractunssiuqq: Fixed-point fractional library routines.
- (line 1820)
- * __satfractunssiusa: Fixed-point fractional library routines.
- (line 1829)
- * __satfractunssiusq: Fixed-point fractional library routines.
- (line 1823)
- * __satfractunssiuta: Fixed-point fractional library routines.
- (line 1832)
- * __satfractunstida: Fixed-point fractional library routines.
- (line 1870)
- * __satfractunstidq: Fixed-point fractional library routines.
- (line 1865)
- * __satfractunstiha: Fixed-point fractional library routines.
- (line 1867)
- * __satfractunstihq: Fixed-point fractional library routines.
- (line 1862)
- * __satfractunstiqq: Fixed-point fractional library routines.
- (line 1860)
- * __satfractunstisa: Fixed-point fractional library routines.
- (line 1869)
- * __satfractunstisq: Fixed-point fractional library routines.
- (line 1863)
- * __satfractunstita: Fixed-point fractional library routines.
- (line 1872)
- * __satfractunstiuda: Fixed-point fractional library routines.
- (line 1886)
- * __satfractunstiudq: Fixed-point fractional library routines.
- (line 1880)
- * __satfractunstiuha: Fixed-point fractional library routines.
- (line 1882)
- * __satfractunstiuhq: Fixed-point fractional library routines.
- (line 1876)
- * __satfractunstiuqq: Fixed-point fractional library routines.
- (line 1874)
- * __satfractunstiusa: Fixed-point fractional library routines.
- (line 1884)
- * __satfractunstiusq: Fixed-point fractional library routines.
- (line 1878)
- * __satfractunstiuta: Fixed-point fractional library routines.
- (line 1888)
- * __satfractuqqda: Fixed-point fractional library routines.
- (line 1207)
- * __satfractuqqdq: Fixed-point fractional library routines.
- (line 1202)
- * __satfractuqqha: Fixed-point fractional library routines.
- (line 1204)
- * __satfractuqqhq: Fixed-point fractional library routines.
- (line 1199)
- * __satfractuqqqq: Fixed-point fractional library routines.
- (line 1197)
- * __satfractuqqsa: Fixed-point fractional library routines.
- (line 1206)
- * __satfractuqqsq: Fixed-point fractional library routines.
- (line 1200)
- * __satfractuqqta: Fixed-point fractional library routines.
- (line 1209)
- * __satfractuqquda: Fixed-point fractional library routines.
- (line 1221)
- * __satfractuqqudq2: Fixed-point fractional library routines.
- (line 1215)
- * __satfractuqquha: Fixed-point fractional library routines.
- (line 1217)
- * __satfractuqquhq2: Fixed-point fractional library routines.
- (line 1211)
- * __satfractuqqusa: Fixed-point fractional library routines.
- (line 1219)
- * __satfractuqqusq2: Fixed-point fractional library routines.
- (line 1213)
- * __satfractuqquta: Fixed-point fractional library routines.
- (line 1223)
- * __satfractusada: Fixed-point fractional library routines.
- (line 1334)
- * __satfractusadq: Fixed-point fractional library routines.
- (line 1331)
- * __satfractusaha: Fixed-point fractional library routines.
- (line 1332)
- * __satfractusahq: Fixed-point fractional library routines.
- (line 1329)
- * __satfractusaqq: Fixed-point fractional library routines.
- (line 1328)
- * __satfractusasa: Fixed-point fractional library routines.
- (line 1333)
- * __satfractusasq: Fixed-point fractional library routines.
- (line 1330)
- * __satfractusata: Fixed-point fractional library routines.
- (line 1335)
- * __satfractusauda2: Fixed-point fractional library routines.
- (line 1345)
- * __satfractusaudq: Fixed-point fractional library routines.
- (line 1341)
- * __satfractusauha2: Fixed-point fractional library routines.
- (line 1343)
- * __satfractusauhq: Fixed-point fractional library routines.
- (line 1338)
- * __satfractusauqq: Fixed-point fractional library routines.
- (line 1336)
- * __satfractusausq: Fixed-point fractional library routines.
- (line 1339)
- * __satfractusauta2: Fixed-point fractional library routines.
- (line 1347)
- * __satfractusqda: Fixed-point fractional library routines.
- (line 1255)
- * __satfractusqdq: Fixed-point fractional library routines.
- (line 1250)
- * __satfractusqha: Fixed-point fractional library routines.
- (line 1252)
- * __satfractusqhq: Fixed-point fractional library routines.
- (line 1248)
- * __satfractusqqq: Fixed-point fractional library routines.
- (line 1246)
- * __satfractusqsa: Fixed-point fractional library routines.
- (line 1254)
- * __satfractusqsq: Fixed-point fractional library routines.
- (line 1249)
- * __satfractusqta: Fixed-point fractional library routines.
- (line 1256)
- * __satfractusquda: Fixed-point fractional library routines.
- (line 1268)
- * __satfractusqudq2: Fixed-point fractional library routines.
- (line 1262)
- * __satfractusquha: Fixed-point fractional library routines.
- (line 1264)
- * __satfractusquhq2: Fixed-point fractional library routines.
- (line 1260)
- * __satfractusquqq2: Fixed-point fractional library routines.
- (line 1258)
- * __satfractusqusa: Fixed-point fractional library routines.
- (line 1266)
- * __satfractusquta: Fixed-point fractional library routines.
- (line 1270)
- * __satfractutada: Fixed-point fractional library routines.
- (line 1385)
- * __satfractutadq: Fixed-point fractional library routines.
- (line 1380)
- * __satfractutaha: Fixed-point fractional library routines.
- (line 1382)
- * __satfractutahq: Fixed-point fractional library routines.
- (line 1377)
- * __satfractutaqq: Fixed-point fractional library routines.
- (line 1375)
- * __satfractutasa: Fixed-point fractional library routines.
- (line 1384)
- * __satfractutasq: Fixed-point fractional library routines.
- (line 1378)
- * __satfractutata: Fixed-point fractional library routines.
- (line 1387)
- * __satfractutauda2: Fixed-point fractional library routines.
- (line 1401)
- * __satfractutaudq: Fixed-point fractional library routines.
- (line 1395)
- * __satfractutauha2: Fixed-point fractional library routines.
- (line 1397)
- * __satfractutauhq: Fixed-point fractional library routines.
- (line 1391)
- * __satfractutauqq: Fixed-point fractional library routines.
- (line 1389)
- * __satfractutausa2: Fixed-point fractional library routines.
- (line 1399)
- * __satfractutausq: Fixed-point fractional library routines.
- (line 1393)
- * __splitstack_find: Miscellaneous routines.
- (line 15)
- * __ssaddda3: Fixed-point fractional library routines.
- (line 74)
- * __ssadddq3: Fixed-point fractional library routines.
- (line 69)
- * __ssaddha3: Fixed-point fractional library routines.
- (line 71)
- * __ssaddhq3: Fixed-point fractional library routines.
- (line 67)
- * __ssaddqq3: Fixed-point fractional library routines.
- (line 65)
- * __ssaddsa3: Fixed-point fractional library routines.
- (line 73)
- * __ssaddsq3: Fixed-point fractional library routines.
- (line 68)
- * __ssaddta3: Fixed-point fractional library routines.
- (line 75)
- * __ssashlda3: Fixed-point fractional library routines.
- (line 409)
- * __ssashldq3: Fixed-point fractional library routines.
- (line 405)
- * __ssashlha3: Fixed-point fractional library routines.
- (line 407)
- * __ssashlhq3: Fixed-point fractional library routines.
- (line 403)
- * __ssashlsa3: Fixed-point fractional library routines.
- (line 408)
- * __ssashlsq3: Fixed-point fractional library routines.
- (line 404)
- * __ssashlta3: Fixed-point fractional library routines.
- (line 410)
- * __ssdivda3: Fixed-point fractional library routines.
- (line 268)
- * __ssdivdq3: Fixed-point fractional library routines.
- (line 263)
- * __ssdivha3: Fixed-point fractional library routines.
- (line 265)
- * __ssdivhq3: Fixed-point fractional library routines.
- (line 261)
- * __ssdivqq3: Fixed-point fractional library routines.
- (line 259)
- * __ssdivsa3: Fixed-point fractional library routines.
- (line 267)
- * __ssdivsq3: Fixed-point fractional library routines.
- (line 262)
- * __ssdivta3: Fixed-point fractional library routines.
- (line 269)
- * __ssmulda3: Fixed-point fractional library routines.
- (line 200)
- * __ssmuldq3: Fixed-point fractional library routines.
- (line 195)
- * __ssmulha3: Fixed-point fractional library routines.
- (line 197)
- * __ssmulhq3: Fixed-point fractional library routines.
- (line 193)
- * __ssmulqq3: Fixed-point fractional library routines.
- (line 191)
- * __ssmulsa3: Fixed-point fractional library routines.
- (line 199)
- * __ssmulsq3: Fixed-point fractional library routines.
- (line 194)
- * __ssmulta3: Fixed-point fractional library routines.
- (line 201)
- * __ssnegda2: Fixed-point fractional library routines.
- (line 323)
- * __ssnegdq2: Fixed-point fractional library routines.
- (line 320)
- * __ssnegha2: Fixed-point fractional library routines.
- (line 321)
- * __ssneghq2: Fixed-point fractional library routines.
- (line 318)
- * __ssnegqq2: Fixed-point fractional library routines.
- (line 317)
- * __ssnegsa2: Fixed-point fractional library routines.
- (line 322)
- * __ssnegsq2: Fixed-point fractional library routines.
- (line 319)
- * __ssnegta2: Fixed-point fractional library routines.
- (line 324)
- * __sssubda3: Fixed-point fractional library routines.
- (line 136)
- * __sssubdq3: Fixed-point fractional library routines.
- (line 131)
- * __sssubha3: Fixed-point fractional library routines.
- (line 133)
- * __sssubhq3: Fixed-point fractional library routines.
- (line 129)
- * __sssubqq3: Fixed-point fractional library routines.
- (line 127)
- * __sssubsa3: Fixed-point fractional library routines.
- (line 135)
- * __sssubsq3: Fixed-point fractional library routines.
- (line 130)
- * __sssubta3: Fixed-point fractional library routines.
- (line 137)
- * __subda3: Fixed-point fractional library routines.
- (line 114)
- * __subdf3: Soft float library routines.
- (line 30)
- * __subdq3: Fixed-point fractional library routines.
- (line 101)
- * __subha3: Fixed-point fractional library routines.
- (line 111)
- * __subhq3: Fixed-point fractional library routines.
- (line 99)
- * __subqq3: Fixed-point fractional library routines.
- (line 97)
- * __subsa3: Fixed-point fractional library routines.
- (line 113)
- * __subsf3: Soft float library routines.
- (line 29)
- * __subsq3: Fixed-point fractional library routines.
- (line 100)
- * __subta3: Fixed-point fractional library routines.
- (line 115)
- * __subtf3: Soft float library routines.
- (line 31)
- * __subuda3: Fixed-point fractional library routines.
- (line 121)
- * __subudq3: Fixed-point fractional library routines.
- (line 109)
- * __subuha3: Fixed-point fractional library routines.
- (line 117)
- * __subuhq3: Fixed-point fractional library routines.
- (line 105)
- * __subuqq3: Fixed-point fractional library routines.
- (line 103)
- * __subusa3: Fixed-point fractional library routines.
- (line 119)
- * __subusq3: Fixed-point fractional library routines.
- (line 107)
- * __subuta3: Fixed-point fractional library routines.
- (line 123)
- * __subvdi3: Integer library routines.
- (line 122)
- * __subvsi3: Integer library routines.
- (line 121)
- * __subxf3: Soft float library routines.
- (line 33)
- * __truncdfsf2: Soft float library routines.
- (line 75)
- * __trunctfdf2: Soft float library routines.
- (line 72)
- * __trunctfsf2: Soft float library routines.
- (line 74)
- * __truncxfdf2: Soft float library routines.
- (line 71)
- * __truncxfsf2: Soft float library routines.
- (line 73)
- * __ucmpdi2: Integer library routines.
- (line 92)
- * __ucmpti2: Integer library routines.
- (line 93)
- * __udivdi3: Integer library routines.
- (line 52)
- * __udivmoddi4: Integer library routines.
- (line 59)
- * __udivmodti4: Integer library routines.
- (line 61)
- * __udivsi3: Integer library routines.
- (line 50)
- * __udivti3: Integer library routines.
- (line 54)
- * __udivuda3: Fixed-point fractional library routines.
- (line 252)
- * __udivudq3: Fixed-point fractional library routines.
- (line 246)
- * __udivuha3: Fixed-point fractional library routines.
- (line 248)
- * __udivuhq3: Fixed-point fractional library routines.
- (line 242)
- * __udivuqq3: Fixed-point fractional library routines.
- (line 240)
- * __udivusa3: Fixed-point fractional library routines.
- (line 250)
- * __udivusq3: Fixed-point fractional library routines.
- (line 244)
- * __udivuta3: Fixed-point fractional library routines.
- (line 254)
- * __umoddi3: Integer library routines.
- (line 69)
- * __umodsi3: Integer library routines.
- (line 67)
- * __umodti3: Integer library routines.
- (line 71)
- * __unorddf2: Soft float library routines.
- (line 172)
- * __unordsf2: Soft float library routines.
- (line 171)
- * __unordtf2: Soft float library routines.
- (line 173)
- * __usadduda3: Fixed-point fractional library routines.
- (line 91)
- * __usaddudq3: Fixed-point fractional library routines.
- (line 85)
- * __usadduha3: Fixed-point fractional library routines.
- (line 87)
- * __usadduhq3: Fixed-point fractional library routines.
- (line 81)
- * __usadduqq3: Fixed-point fractional library routines.
- (line 79)
- * __usaddusa3: Fixed-point fractional library routines.
- (line 89)
- * __usaddusq3: Fixed-point fractional library routines.
- (line 83)
- * __usadduta3: Fixed-point fractional library routines.
- (line 93)
- * __usashluda3: Fixed-point fractional library routines.
- (line 427)
- * __usashludq3: Fixed-point fractional library routines.
- (line 421)
- * __usashluha3: Fixed-point fractional library routines.
- (line 423)
- * __usashluhq3: Fixed-point fractional library routines.
- (line 417)
- * __usashluqq3: Fixed-point fractional library routines.
- (line 415)
- * __usashlusa3: Fixed-point fractional library routines.
- (line 425)
- * __usashlusq3: Fixed-point fractional library routines.
- (line 419)
- * __usashluta3: Fixed-point fractional library routines.
- (line 429)
- * __usdivuda3: Fixed-point fractional library routines.
- (line 286)
- * __usdivudq3: Fixed-point fractional library routines.
- (line 280)
- * __usdivuha3: Fixed-point fractional library routines.
- (line 282)
- * __usdivuhq3: Fixed-point fractional library routines.
- (line 276)
- * __usdivuqq3: Fixed-point fractional library routines.
- (line 274)
- * __usdivusa3: Fixed-point fractional library routines.
- (line 284)
- * __usdivusq3: Fixed-point fractional library routines.
- (line 278)
- * __usdivuta3: Fixed-point fractional library routines.
- (line 288)
- * __usmuluda3: Fixed-point fractional library routines.
- (line 218)
- * __usmuludq3: Fixed-point fractional library routines.
- (line 212)
- * __usmuluha3: Fixed-point fractional library routines.
- (line 214)
- * __usmuluhq3: Fixed-point fractional library routines.
- (line 208)
- * __usmuluqq3: Fixed-point fractional library routines.
- (line 206)
- * __usmulusa3: Fixed-point fractional library routines.
- (line 216)
- * __usmulusq3: Fixed-point fractional library routines.
- (line 210)
- * __usmuluta3: Fixed-point fractional library routines.
- (line 220)
- * __usneguda2: Fixed-point fractional library routines.
- (line 337)
- * __usnegudq2: Fixed-point fractional library routines.
- (line 332)
- * __usneguha2: Fixed-point fractional library routines.
- (line 334)
- * __usneguhq2: Fixed-point fractional library routines.
- (line 329)
- * __usneguqq2: Fixed-point fractional library routines.
- (line 327)
- * __usnegusa2: Fixed-point fractional library routines.
- (line 336)
- * __usnegusq2: Fixed-point fractional library routines.
- (line 330)
- * __usneguta2: Fixed-point fractional library routines.
- (line 339)
- * __ussubuda3: Fixed-point fractional library routines.
- (line 154)
- * __ussubudq3: Fixed-point fractional library routines.
- (line 148)
- * __ussubuha3: Fixed-point fractional library routines.
- (line 150)
- * __ussubuhq3: Fixed-point fractional library routines.
- (line 144)
- * __ussubuqq3: Fixed-point fractional library routines.
- (line 142)
- * __ussubusa3: Fixed-point fractional library routines.
- (line 152)
- * __ussubusq3: Fixed-point fractional library routines.
- (line 146)
- * __ussubuta3: Fixed-point fractional library routines.
- (line 156)
- * abort: Portability. (line 20)
- * abs: Arithmetic. (line 200)
- * abs and attributes: Expressions. (line 83)
- * absence_set: Processor pipeline description.
- (line 223)
- * absM2 instruction pattern: Standard Names. (line 879)
- * absolute value: Arithmetic. (line 200)
- * ABSU_EXPR: Unary and Binary Expressions.
- (line 6)
- * ABS_EXPR: Unary and Binary Expressions.
- (line 6)
- * access to operands: Accessors. (line 6)
- * access to special operands: Special Accessors. (line 6)
- * accessors: Accessors. (line 6)
- * ACCUMULATE_OUTGOING_ARGS: Stack Arguments. (line 48)
- * ACCUMULATE_OUTGOING_ARGS and stack frames: Function Entry. (line 140)
- * ACCUM_TYPE_SIZE: Type Layout. (line 87)
- * acosM2 instruction pattern: Standard Names. (line 966)
- * ADA_LONG_TYPE_SIZE: Type Layout. (line 25)
- * Adding a new GIMPLE statement code: Adding a new GIMPLE statement code.
- (line 6)
- * ADDITIONAL_REGISTER_NAMES: Instruction Output. (line 14)
- * addM3 instruction pattern: Standard Names. (line 436)
- * addMODEcc instruction pattern: Standard Names. (line 1589)
- * addptrM3 instruction pattern: Standard Names. (line 469)
- * address constraints: Simple Constraints. (line 162)
- * addressing modes: Addressing Modes. (line 6)
- * address_operand: Machine-Independent Predicates.
- (line 62)
- * address_operand <1>: Simple Constraints. (line 166)
- * addr_diff_vec: Side Effects. (line 314)
- * addr_diff_vec, length of: Insn Lengths. (line 26)
- * ADDR_EXPR: Storage References. (line 6)
- * addr_vec: Side Effects. (line 309)
- * addr_vec, length of: Insn Lengths. (line 26)
- * addvM4 instruction pattern: Standard Names. (line 452)
- * ADJUST_FIELD_ALIGN: Storage Layout. (line 212)
- * ADJUST_INSN_LENGTH: Insn Lengths. (line 41)
- * ADJUST_REG_ALLOC_ORDER: Allocation Order. (line 22)
- * aggregates as return values: Aggregate Return. (line 6)
- * alias: Alias analysis. (line 6)
- * allocate_stack instruction pattern: Standard Names. (line 1956)
- * ALL_REGS: Register Classes. (line 17)
- * alternate entry points: Insns. (line 146)
- * analyzer: Static Analyzer. (line 6)
- * analyzer, debugging: Debugging the Analyzer.
- (line 6)
- * analyzer, internals: Analyzer Internals. (line 6)
- * anchored addresses: Anchored Addresses. (line 6)
- * and: Arithmetic. (line 158)
- * and and attributes: Expressions. (line 50)
- * and, canonicalization of: Insn Canonicalizations.
- (line 67)
- * andM3 instruction pattern: Standard Names. (line 442)
- * ANNOTATE_EXPR: Unary and Binary Expressions.
- (line 6)
- * annotations: Annotations. (line 6)
- * APPLY_RESULT_SIZE: Scalar Return. (line 112)
- * ARGS_GROW_DOWNWARD: Frame Layout. (line 30)
- * argument passing: Interface. (line 36)
- * arguments in registers: Register Arguments. (line 6)
- * arguments on stack: Stack Arguments. (line 6)
- * ARG_POINTER_CFA_OFFSET: Frame Layout. (line 207)
- * ARG_POINTER_REGNUM: Frame Registers. (line 40)
- * ARG_POINTER_REGNUM and virtual registers: Regs and Memory. (line 65)
- * arg_pointer_rtx: Frame Registers. (line 104)
- * arithmetic library: Soft float library routines.
- (line 6)
- * arithmetic shift: Arithmetic. (line 173)
- * arithmetic shift with signed saturation: Arithmetic. (line 173)
- * arithmetic shift with unsigned saturation: Arithmetic. (line 173)
- * arithmetic, in RTL: Arithmetic. (line 6)
- * ARITHMETIC_TYPE_P: Types for C++. (line 59)
- * array: Types. (line 6)
- * ARRAY_RANGE_REF: Storage References. (line 6)
- * ARRAY_REF: Storage References. (line 6)
- * ARRAY_TYPE: Types. (line 6)
- * ashift: Arithmetic. (line 173)
- * ashift and attributes: Expressions. (line 83)
- * ashiftrt: Arithmetic. (line 190)
- * ashiftrt and attributes: Expressions. (line 83)
- * ashlM3 instruction pattern: Standard Names. (line 828)
- * ashrM3 instruction pattern: Standard Names. (line 840)
- * asinM2 instruction pattern: Standard Names. (line 960)
- * ASM_APP_OFF: File Framework. (line 76)
- * ASM_APP_ON: File Framework. (line 69)
- * ASM_COMMENT_START: File Framework. (line 64)
- * ASM_DECLARE_COLD_FUNCTION_NAME: Label Output. (line 136)
- * ASM_DECLARE_COLD_FUNCTION_SIZE: Label Output. (line 151)
- * ASM_DECLARE_FUNCTION_NAME: Label Output. (line 108)
- * ASM_DECLARE_FUNCTION_SIZE: Label Output. (line 123)
- * ASM_DECLARE_OBJECT_NAME: Label Output. (line 164)
- * ASM_DECLARE_REGISTER_GLOBAL: Label Output. (line 192)
- * ASM_FINAL_SPEC: Driver. (line 81)
- * ASM_FINISH_DECLARE_OBJECT: Label Output. (line 200)
- * ASM_FORMAT_PRIVATE_NAME: Label Output. (line 426)
- * asm_fprintf: Instruction Output. (line 150)
- * ASM_FPRINTF_EXTENSIONS: Instruction Output. (line 160)
- * ASM_GENERATE_INTERNAL_LABEL: Label Output. (line 410)
- * asm_input: Side Effects. (line 296)
- * asm_input and /v: Flags. (line 65)
- * ASM_MAYBE_OUTPUT_ENCODED_ADDR_RTX: Exception Handling. (line 80)
- * asm_noperands: Insns. (line 327)
- * ASM_NO_SKIP_IN_TEXT: Alignment Output. (line 59)
- * asm_operands and /v: Flags. (line 65)
- * asm_operands, RTL sharing: Sharing. (line 48)
- * asm_operands, usage: Assembler. (line 6)
- * ASM_OUTPUT_ADDR_DIFF_ELT: Dispatch Tables. (line 8)
- * ASM_OUTPUT_ADDR_VEC_ELT: Dispatch Tables. (line 25)
- * ASM_OUTPUT_ALIGN: Alignment Output. (line 66)
- * ASM_OUTPUT_ALIGNED_BSS: Uninitialized Data. (line 45)
- * ASM_OUTPUT_ALIGNED_COMMON: Uninitialized Data. (line 29)
- * ASM_OUTPUT_ALIGNED_DECL_COMMON: Uninitialized Data. (line 36)
- * ASM_OUTPUT_ALIGNED_DECL_LOCAL: Uninitialized Data. (line 89)
- * ASM_OUTPUT_ALIGNED_LOCAL: Uninitialized Data. (line 82)
- * ASM_OUTPUT_ALIGN_WITH_NOP: Alignment Output. (line 71)
- * ASM_OUTPUT_ASCII: Data Output. (line 60)
- * ASM_OUTPUT_CASE_END: Dispatch Tables. (line 50)
- * ASM_OUTPUT_CASE_LABEL: Dispatch Tables. (line 37)
- * ASM_OUTPUT_COMMON: Uninitialized Data. (line 9)
- * ASM_OUTPUT_DEBUG_LABEL: Label Output. (line 398)
- * ASM_OUTPUT_DEF: Label Output. (line 447)
- * ASM_OUTPUT_DEF_FROM_DECLS: Label Output. (line 454)
- * ASM_OUTPUT_DWARF_DATAREL: DWARF. (line 110)
- * ASM_OUTPUT_DWARF_DELTA: DWARF. (line 89)
- * ASM_OUTPUT_DWARF_OFFSET: DWARF. (line 98)
- * ASM_OUTPUT_DWARF_PCREL: DWARF. (line 105)
- * ASM_OUTPUT_DWARF_TABLE_REF: DWARF. (line 115)
- * ASM_OUTPUT_DWARF_VMS_DELTA: DWARF. (line 93)
- * ASM_OUTPUT_EXTERNAL: Label Output. (line 327)
- * ASM_OUTPUT_FDESC: Data Output. (line 69)
- * ASM_OUTPUT_FUNCTION_LABEL: Label Output. (line 16)
- * ASM_OUTPUT_INTERNAL_LABEL: Label Output. (line 27)
- * ASM_OUTPUT_LABEL: Label Output. (line 8)
- * ASM_OUTPUT_LABELREF: Label Output. (line 349)
- * ASM_OUTPUT_LABEL_REF: Label Output. (line 371)
- * ASM_OUTPUT_LOCAL: Uninitialized Data. (line 69)
- * ASM_OUTPUT_MAX_SKIP_ALIGN: Alignment Output. (line 75)
- * ASM_OUTPUT_MEASURED_SIZE: Label Output. (line 51)
- * ASM_OUTPUT_OPCODE: Instruction Output. (line 35)
- * ASM_OUTPUT_POOL_EPILOGUE: Data Output. (line 118)
- * ASM_OUTPUT_POOL_PROLOGUE: Data Output. (line 82)
- * ASM_OUTPUT_REG_POP: Instruction Output. (line 206)
- * ASM_OUTPUT_REG_PUSH: Instruction Output. (line 201)
- * ASM_OUTPUT_SIZE_DIRECTIVE: Label Output. (line 45)
- * ASM_OUTPUT_SKIP: Alignment Output. (line 53)
- * ASM_OUTPUT_SOURCE_FILENAME: File Framework. (line 83)
- * ASM_OUTPUT_SPECIAL_POOL_ENTRY: Data Output. (line 93)
- * ASM_OUTPUT_SYMBOL_REF: Label Output. (line 364)
- * ASM_OUTPUT_TYPE_DIRECTIVE: Label Output. (line 98)
- * ASM_OUTPUT_WEAKREF: Label Output. (line 259)
- * ASM_OUTPUT_WEAK_ALIAS: Label Output. (line 473)
- * ASM_PREFERRED_EH_DATA_FORMAT: Exception Handling. (line 66)
- * ASM_SPEC: Driver. (line 73)
- * ASM_STABD_OP: DBX Options. (line 34)
- * ASM_STABN_OP: DBX Options. (line 41)
- * ASM_STABS_OP: DBX Options. (line 28)
- * ASM_WEAKEN_DECL: Label Output. (line 251)
- * ASM_WEAKEN_LABEL: Label Output. (line 238)
- * assembler format: File Framework. (line 6)
- * assembler instructions in RTL: Assembler. (line 6)
- * ASSEMBLER_DIALECT: Instruction Output. (line 172)
- * assemble_name: Label Output. (line 8)
- * assemble_name_raw: Label Output. (line 27)
- * assigning attribute values to insns: Tagging Insns. (line 6)
- * ASSUME_EXTENDED_UNWIND_CONTEXT: Frame Registers. (line 163)
- * asterisk in template: Output Statement. (line 29)
- * AS_NEEDS_DASH_FOR_PIPED_INPUT: Driver. (line 88)
- * atan2M3 instruction pattern: Standard Names. (line 1061)
- * atanM2 instruction pattern: Standard Names. (line 972)
- * atomic: GTY Options. (line 197)
- * atomic_addMODE instruction pattern: Standard Names. (line 2380)
- * atomic_add_fetchMODE instruction pattern: Standard Names. (line 2409)
- * atomic_andMODE instruction pattern: Standard Names. (line 2380)
- * atomic_and_fetchMODE instruction pattern: Standard Names. (line 2409)
- * atomic_bit_test_and_complementMODE instruction pattern: Standard Names.
- (line 2437)
- * atomic_bit_test_and_resetMODE instruction pattern: Standard Names.
- (line 2437)
- * atomic_bit_test_and_setMODE instruction pattern: Standard Names.
- (line 2437)
- * atomic_compare_and_swapMODE instruction pattern: Standard Names.
- (line 2316)
- * atomic_exchangeMODE instruction pattern: Standard Names. (line 2368)
- * atomic_fetch_addMODE instruction pattern: Standard Names. (line 2394)
- * atomic_fetch_andMODE instruction pattern: Standard Names. (line 2394)
- * atomic_fetch_nandMODE instruction pattern: Standard Names. (line 2394)
- * atomic_fetch_orMODE instruction pattern: Standard Names. (line 2394)
- * atomic_fetch_subMODE instruction pattern: Standard Names. (line 2394)
- * atomic_fetch_xorMODE instruction pattern: Standard Names. (line 2394)
- * atomic_loadMODE instruction pattern: Standard Names. (line 2347)
- * atomic_nandMODE instruction pattern: Standard Names. (line 2380)
- * atomic_nand_fetchMODE instruction pattern: Standard Names. (line 2409)
- * atomic_orMODE instruction pattern: Standard Names. (line 2380)
- * atomic_or_fetchMODE instruction pattern: Standard Names. (line 2409)
- * atomic_storeMODE instruction pattern: Standard Names. (line 2357)
- * atomic_subMODE instruction pattern: Standard Names. (line 2380)
- * atomic_sub_fetchMODE instruction pattern: Standard Names. (line 2409)
- * atomic_test_and_set instruction pattern: Standard Names. (line 2426)
- * atomic_xorMODE instruction pattern: Standard Names. (line 2380)
- * atomic_xor_fetchMODE instruction pattern: Standard Names. (line 2409)
- * attr: Expressions. (line 163)
- * attr <1>: Tagging Insns. (line 54)
- * attribute expressions: Expressions. (line 6)
- * attribute specifications: Attr Example. (line 6)
- * attribute specifications example: Attr Example. (line 6)
- * attributes: Attributes. (line 6)
- * attributes, defining: Defining Attributes.
- (line 6)
- * attributes, target-specific: Target Attributes. (line 6)
- * ATTRIBUTE_ALIGNED_VALUE: Storage Layout. (line 194)
- * attr_flag: Expressions. (line 138)
- * autoincrement addressing, availability: Portability. (line 20)
- * autoincrement/decrement addressing: Simple Constraints. (line 30)
- * automata_option: Processor pipeline description.
- (line 304)
- * automaton based pipeline description: Processor pipeline description.
- (line 6)
- * automaton based pipeline description <1>: Processor pipeline description.
- (line 49)
- * automaton based scheduler: Processor pipeline description.
- (line 6)
- * avgM3_ceil instruction pattern: Standard Names. (line 860)
- * avgM3_floor instruction pattern: Standard Names. (line 848)
- * AVOID_CCMODE_COPIES: Values in Registers.
- (line 148)
- * backslash: Output Template. (line 46)
- * barrier: Insns. (line 176)
- * barrier and /f: Flags. (line 135)
- * barrier and /v: Flags. (line 33)
- * BASE_REG_CLASS: Register Classes. (line 111)
- * basic block: Basic Blocks. (line 6)
- * Basic Statements: Basic Statements. (line 6)
- * basic-block.h: Control Flow. (line 6)
- * basic_block: Basic Blocks. (line 6)
- * BASIC_BLOCK: Basic Blocks. (line 14)
- * BB_HEAD, BB_END: Maintaining the CFG.
- (line 76)
- * bb_seq: GIMPLE sequences. (line 72)
- * BIGGEST_ALIGNMENT: Storage Layout. (line 179)
- * BIGGEST_FIELD_ALIGNMENT: Storage Layout. (line 205)
- * BImode: Machine Modes. (line 22)
- * BIND_EXPR: Unary and Binary Expressions.
- (line 6)
- * BINFO_TYPE: Classes. (line 6)
- * bit-fields: Bit-Fields. (line 6)
- * BITFIELD_NBYTES_LIMITED: Storage Layout. (line 428)
- * BITS_BIG_ENDIAN: Storage Layout. (line 11)
- * BITS_BIG_ENDIAN, effect on sign_extract: Bit-Fields. (line 8)
- * BITS_PER_UNIT: Machine Modes. (line 440)
- * BITS_PER_WORD: Storage Layout. (line 50)
- * bitwise complement: Arithmetic. (line 154)
- * bitwise exclusive-or: Arithmetic. (line 168)
- * bitwise inclusive-or: Arithmetic. (line 163)
- * bitwise logical-and: Arithmetic. (line 158)
- * BIT_AND_EXPR: Unary and Binary Expressions.
- (line 6)
- * BIT_IOR_EXPR: Unary and Binary Expressions.
- (line 6)
- * BIT_NOT_EXPR: Unary and Binary Expressions.
- (line 6)
- * BIT_XOR_EXPR: Unary and Binary Expressions.
- (line 6)
- * BLKmode: Machine Modes. (line 185)
- * BLKmode, and function return values: Calls. (line 23)
- * blockage instruction pattern: Standard Names. (line 2156)
- * Blocks: Blocks. (line 6)
- * BLOCK_FOR_INSN, gimple_bb: Maintaining the CFG.
- (line 28)
- * BLOCK_REG_PADDING: Register Arguments. (line 238)
- * BND32mode: Machine Modes. (line 210)
- * BND64mode: Machine Modes. (line 210)
- * bool: Misc. (line 958)
- * BOOLEAN_TYPE: Types. (line 6)
- * BOOL_TYPE_SIZE: Type Layout. (line 43)
- * branch prediction: Profile information.
- (line 24)
- * BRANCH_COST: Costs. (line 104)
- * break_out_memory_refs: Addressing Modes. (line 134)
- * BREAK_STMT: Statements for C++. (line 6)
- * BSS_SECTION_ASM_OP: Sections. (line 67)
- * bswap: Arithmetic. (line 246)
- * bswapM2 instruction pattern: Standard Names. (line 868)
- * btruncM2 instruction pattern: Standard Names. (line 1078)
- * build0: Macros and Functions.
- (line 16)
- * build1: Macros and Functions.
- (line 17)
- * build2: Macros and Functions.
- (line 18)
- * build3: Macros and Functions.
- (line 19)
- * build4: Macros and Functions.
- (line 20)
- * build5: Macros and Functions.
- (line 21)
- * build6: Macros and Functions.
- (line 22)
- * builtin_longjmp instruction pattern: Standard Names. (line 2054)
- * builtin_setjmp_receiver instruction pattern: Standard Names.
- (line 2044)
- * builtin_setjmp_setup instruction pattern: Standard Names. (line 2033)
- * BYTES_BIG_ENDIAN: Storage Layout. (line 23)
- * BYTES_BIG_ENDIAN, effect on subreg: Regs and Memory. (line 229)
- * byte_mode: Machine Modes. (line 458)
- * C statements for assembler output: Output Statement. (line 6)
- * cache: GTY Options. (line 127)
- * call: Flags. (line 230)
- * call <1>: Side Effects. (line 92)
- * call instruction pattern: Standard Names. (line 1709)
- * call usage: Calls. (line 10)
- * call, in call_insn: Flags. (line 129)
- * call, in mem: Flags. (line 70)
- * call-clobbered register: Register Basics. (line 35)
- * call-clobbered register <1>: Register Basics. (line 50)
- * call-clobbered register <2>: Register Basics. (line 58)
- * call-clobbered register <3>: Register Basics. (line 76)
- * call-saved register: Register Basics. (line 35)
- * call-saved register <1>: Register Basics. (line 50)
- * call-saved register <2>: Register Basics. (line 58)
- * call-saved register <3>: Register Basics. (line 76)
- * call-used register: Register Basics. (line 35)
- * call-used register <1>: Register Basics. (line 50)
- * call-used register <2>: Register Basics. (line 58)
- * call-used register <3>: Register Basics. (line 76)
- * calling conventions: Stack and Calling. (line 6)
- * calling functions in RTL: Calls. (line 6)
- * CALL_EXPR: Unary and Binary Expressions.
- (line 6)
- * call_insn: Insns. (line 95)
- * call_insn and /c: Flags. (line 129)
- * call_insn and /f: Flags. (line 135)
- * call_insn and /i: Flags. (line 120)
- * call_insn and /j: Flags. (line 175)
- * call_insn and /s: Flags. (line 38)
- * call_insn and /s <1>: Flags. (line 162)
- * call_insn and /u: Flags. (line 28)
- * call_insn and /u <1>: Flags. (line 115)
- * call_insn and /u or /i: Flags. (line 125)
- * call_insn and /v: Flags. (line 33)
- * CALL_INSN_FUNCTION_USAGE: Insns. (line 101)
- * call_pop instruction pattern: Standard Names. (line 1737)
- * CALL_POPS_ARGS: Stack Arguments. (line 138)
- * CALL_REALLY_USED_REGISTERS: Register Basics. (line 49)
- * CALL_USED_REGISTERS: Register Basics. (line 34)
- * call_used_regs: Register Basics. (line 102)
- * call_value instruction pattern: Standard Names. (line 1729)
- * call_value_pop instruction pattern: Standard Names. (line 1737)
- * canadian: Configure Terms. (line 6)
- * canonicalization of instructions: Insn Canonicalizations.
- (line 6)
- * canonicalize_funcptr_for_compare instruction pattern: Standard Names.
- (line 1888)
- * can_create_pseudo_p: Standard Names. (line 75)
- * can_fallthru: Basic Blocks. (line 67)
- * caret: Multi-Alternative. (line 53)
- * caret <1>: Guidelines for Diagnostics.
- (line 159)
- * casesi instruction pattern: Standard Names. (line 1830)
- * CASE_VECTOR_MODE: Misc. (line 26)
- * CASE_VECTOR_PC_RELATIVE: Misc. (line 39)
- * CASE_VECTOR_SHORTEN_MODE: Misc. (line 30)
- * cbranchMODE4 instruction pattern: Standard Names. (line 1698)
- * cc0: Regs and Memory. (line 329)
- * cc0 <1>: CC0 Condition Codes.
- (line 6)
- * cc0, RTL sharing: Sharing. (line 30)
- * cc0_rtx: Regs and Memory. (line 355)
- * CC1PLUS_SPEC: Driver. (line 63)
- * CC1_SPEC: Driver. (line 55)
- * CCmode: Machine Modes. (line 178)
- * CCmode <1>: MODE_CC Condition Codes.
- (line 6)
- * cc_status: CC0 Condition Codes.
- (line 6)
- * CC_STATUS_MDEP: CC0 Condition Codes.
- (line 16)
- * CC_STATUS_MDEP_INIT: CC0 Condition Codes.
- (line 22)
- * CDImode: Machine Modes. (line 204)
- * ceilM2 instruction pattern: Standard Names. (line 1097)
- * CEIL_DIV_EXPR: Unary and Binary Expressions.
- (line 6)
- * CEIL_MOD_EXPR: Unary and Binary Expressions.
- (line 6)
- * CFA_FRAME_BASE_OFFSET: Frame Layout. (line 239)
- * CFG verification: Maintaining the CFG.
- (line 116)
- * CFG, Control Flow Graph: Control Flow. (line 6)
- * cfghooks.h: Maintaining the CFG.
- (line 6)
- * cgraph_finalize_function: Parsing pass. (line 51)
- * chain_circular: GTY Options. (line 160)
- * chain_next: GTY Options. (line 160)
- * chain_prev: GTY Options. (line 160)
- * change_address: Standard Names. (line 47)
- * CHAR_TYPE_SIZE: Type Layout. (line 38)
- * check_raw_ptrsM instruction pattern: Standard Names. (line 330)
- * check_stack instruction pattern: Standard Names. (line 1974)
- * check_war_ptrsM instruction pattern: Standard Names. (line 349)
- * CHImode: Machine Modes. (line 204)
- * class definitions, register: Register Classes. (line 6)
- * class preference constraints: Class Preferences. (line 6)
- * class, scope: Classes. (line 6)
- * classes of RTX codes: RTL Classes. (line 6)
- * CLASSTYPE_DECLARED_CLASS: Classes. (line 6)
- * CLASSTYPE_HAS_MUTABLE: Classes. (line 82)
- * CLASSTYPE_NON_POD_P: Classes. (line 87)
- * CLASS_MAX_NREGS: Register Classes. (line 531)
- * CLASS_TYPE_P: Types for C++. (line 63)
- * Cleanups: Cleanups. (line 6)
- * CLEANUP_DECL: Statements for C++. (line 6)
- * CLEANUP_EXPR: Statements for C++. (line 6)
- * CLEANUP_POINT_EXPR: Unary and Binary Expressions.
- (line 6)
- * CLEANUP_STMT: Statements for C++. (line 6)
- * clear_cache instruction pattern: Standard Names. (line 2543)
- * CLEAR_INSN_CACHE: Trampolines. (line 151)
- * CLEAR_RATIO: Costs. (line 225)
- * clobber: Side Effects. (line 106)
- * clrsb: Arithmetic. (line 215)
- * clrsbM2 instruction pattern: Standard Names. (line 1170)
- * clz: Arithmetic. (line 222)
- * clzM2 instruction pattern: Standard Names. (line 1186)
- * CLZ_DEFINED_VALUE_AT_ZERO: Misc. (line 338)
- * cmpmemM instruction pattern: Standard Names. (line 1389)
- * cmpstrM instruction pattern: Standard Names. (line 1368)
- * cmpstrnM instruction pattern: Standard Names. (line 1355)
- * code generation RTL sequences: Expander Definitions.
- (line 6)
- * code iterators in .md files: Code Iterators. (line 6)
- * codes, RTL expression: RTL Objects. (line 47)
- * code_label: Insns. (line 125)
- * CODE_LABEL: Basic Blocks. (line 50)
- * code_label and /i: Flags. (line 48)
- * code_label and /v: Flags. (line 33)
- * CODE_LABEL_NUMBER: Insns. (line 125)
- * COImode: Machine Modes. (line 204)
- * COLLECT2_HOST_INITIALIZATION: Host Misc. (line 32)
- * COLLECT_EXPORT_LIST: Misc. (line 864)
- * COLLECT_SHARED_FINI_FUNC: Macros for Initialization.
- (line 43)
- * COLLECT_SHARED_INIT_FUNC: Macros for Initialization.
- (line 32)
- * command-line options, guidelines for: Guidelines for Options.
- (line 6)
- * commit_edge_insertions: Maintaining the CFG.
- (line 104)
- * compare: Arithmetic. (line 46)
- * compare, canonicalization of: Insn Canonicalizations.
- (line 36)
- * COMPARE_MAX_PIECES: Costs. (line 220)
- * comparison_operator: Machine-Independent Predicates.
- (line 110)
- * compiler passes and files: Passes. (line 6)
- * complement, bitwise: Arithmetic. (line 154)
- * COMPLEX_CST: Constant expressions.
- (line 6)
- * COMPLEX_EXPR: Unary and Binary Expressions.
- (line 6)
- * complex_mode: Machine Modes. (line 302)
- * COMPLEX_TYPE: Types. (line 6)
- * COMPONENT_REF: Storage References. (line 6)
- * Compound Expressions: Compound Expressions.
- (line 6)
- * Compound Lvalues: Compound Lvalues. (line 6)
- * COMPOUND_EXPR: Unary and Binary Expressions.
- (line 6)
- * COMPOUND_LITERAL_EXPR: Unary and Binary Expressions.
- (line 6)
- * COMPOUND_LITERAL_EXPR_DECL: Unary and Binary Expressions.
- (line 392)
- * COMPOUND_LITERAL_EXPR_DECL_EXPR: Unary and Binary Expressions.
- (line 392)
- * computed jump: Edges. (line 127)
- * computing the length of an insn: Insn Lengths. (line 6)
- * concat: Regs and Memory. (line 407)
- * concatn: Regs and Memory. (line 413)
- * cond: Comparisons. (line 90)
- * cond and attributes: Expressions. (line 37)
- * condition code register: Regs and Memory. (line 329)
- * condition code status: Condition Code. (line 6)
- * condition codes: Comparisons. (line 20)
- * conditional execution: Conditional Execution.
- (line 6)
- * Conditional Expressions: Conditional Expressions.
- (line 6)
- * conditions, in patterns: Patterns. (line 55)
- * cond_addMODE instruction pattern: Standard Names. (line 1596)
- * cond_andMODE instruction pattern: Standard Names. (line 1596)
- * cond_divMODE instruction pattern: Standard Names. (line 1596)
- * cond_exec: Side Effects. (line 254)
- * COND_EXPR: Unary and Binary Expressions.
- (line 6)
- * cond_fmaMODE instruction pattern: Standard Names. (line 1634)
- * cond_fmsMODE instruction pattern: Standard Names. (line 1634)
- * cond_fnmaMODE instruction pattern: Standard Names. (line 1634)
- * cond_fnmsMODE instruction pattern: Standard Names. (line 1634)
- * cond_iorMODE instruction pattern: Standard Names. (line 1596)
- * cond_modMODE instruction pattern: Standard Names. (line 1596)
- * cond_mulMODE instruction pattern: Standard Names. (line 1596)
- * cond_smaxMODE instruction pattern: Standard Names. (line 1596)
- * cond_sminMODE instruction pattern: Standard Names. (line 1596)
- * cond_subMODE instruction pattern: Standard Names. (line 1596)
- * cond_udivMODE instruction pattern: Standard Names. (line 1596)
- * cond_umaxMODE instruction pattern: Standard Names. (line 1596)
- * cond_uminMODE instruction pattern: Standard Names. (line 1596)
- * cond_umodMODE instruction pattern: Standard Names. (line 1596)
- * cond_xorMODE instruction pattern: Standard Names. (line 1596)
- * configuration file: Filesystem. (line 6)
- * configuration file <1>: Host Misc. (line 6)
- * configure terms: Configure Terms. (line 6)
- * CONJ_EXPR: Unary and Binary Expressions.
- (line 6)
- * const: Constants. (line 212)
- * const0_rtx: Constants. (line 21)
- * CONST0_RTX: Constants. (line 230)
- * const1_rtx: Constants. (line 21)
- * CONST1_RTX: Constants. (line 230)
- * const2_rtx: Constants. (line 21)
- * CONST2_RTX: Constants. (line 230)
- * constant attributes: Constant Attributes.
- (line 6)
- * constant definitions: Constant Definitions.
- (line 6)
- * constants in constraints: Simple Constraints. (line 68)
- * CONSTANT_ADDRESS_P: Addressing Modes. (line 28)
- * CONSTANT_P: Addressing Modes. (line 35)
- * CONSTANT_POOL_ADDRESS_P: Flags. (line 19)
- * CONSTANT_POOL_BEFORE_FUNCTION: Data Output. (line 74)
- * constm1_rtx: Constants. (line 21)
- * constraint modifier characters: Modifiers. (line 6)
- * constraint, matching: Simple Constraints. (line 140)
- * constraints: Constraints. (line 6)
- * constraints, defining: Define Constraints. (line 6)
- * constraints, machine specific: Machine Constraints.
- (line 6)
- * constraints, testing: C Constraint Interface.
- (line 6)
- * constraint_num: C Constraint Interface.
- (line 30)
- * constraint_satisfied_p: C Constraint Interface.
- (line 42)
- * CONSTRUCTOR: Unary and Binary Expressions.
- (line 6)
- * constructors, automatic calls: Collect2. (line 15)
- * constructors, output of: Initialization. (line 6)
- * CONST_DECL: Declarations. (line 6)
- * const_double: Constants. (line 37)
- * const_double, RTL sharing: Sharing. (line 32)
- * CONST_DOUBLE_LOW: Constants. (line 54)
- * const_double_operand: Machine-Independent Predicates.
- (line 20)
- * const_fixed: Constants. (line 93)
- * const_int: Constants. (line 8)
- * const_int and attribute tests: Expressions. (line 47)
- * const_int and attributes: Expressions. (line 10)
- * const_int, RTL sharing: Sharing. (line 23)
- * const_int_operand: Machine-Independent Predicates.
- (line 15)
- * const_poly_int: Constants. (line 100)
- * const_poly_int, RTL sharing: Sharing. (line 25)
- * const_string: Constants. (line 184)
- * const_string and attributes: Expressions. (line 20)
- * const_true_rtx: Constants. (line 31)
- * const_vector: Constants. (line 107)
- * const_vector, RTL sharing: Sharing. (line 35)
- * CONST_WIDE_INT: Constants. (line 67)
- * CONST_WIDE_INT_ELT: Constants. (line 89)
- * CONST_WIDE_INT_NUNITS: Constants. (line 84)
- * CONST_WIDE_INT_VEC: Constants. (line 80)
- * container: Containers. (line 6)
- * CONTINUE_STMT: Statements for C++. (line 6)
- * contributors: Contributors. (line 6)
- * controlling register usage: Register Basics. (line 116)
- * controlling the compilation driver: Driver. (line 6)
- * conventions, run-time: Interface. (line 6)
- * conversions: Conversions. (line 6)
- * CONVERT_EXPR: Unary and Binary Expressions.
- (line 6)
- * copysignM3 instruction pattern: Standard Names. (line 1142)
- * copy_rtx: Addressing Modes. (line 189)
- * copy_rtx_if_shared: Sharing. (line 67)
- * cosM2 instruction pattern: Standard Names. (line 931)
- * costs of instructions: Costs. (line 6)
- * CPLUSPLUS_CPP_SPEC: Driver. (line 50)
- * CPP_SPEC: Driver. (line 43)
- * CPSImode: Machine Modes. (line 204)
- * cpymemM instruction pattern: Standard Names. (line 1244)
- * CP_INTEGRAL_TYPE: Types for C++. (line 55)
- * cp_namespace_decls: Namespaces. (line 49)
- * CP_TYPE_CONST_NON_VOLATILE_P: Types for C++. (line 33)
- * CP_TYPE_CONST_P: Types for C++. (line 24)
- * cp_type_quals: Types for C++. (line 6)
- * cp_type_quals <1>: Types for C++. (line 16)
- * CP_TYPE_RESTRICT_P: Types for C++. (line 30)
- * CP_TYPE_VOLATILE_P: Types for C++. (line 27)
- * CQImode: Machine Modes. (line 204)
- * cross compilation and floating point: Floating Point. (line 6)
- * CROSSING_JUMP_P: Flags. (line 10)
- * crtl->args.pops_args: Function Entry. (line 111)
- * crtl->args.pretend_args_size: Function Entry. (line 117)
- * crtl->outgoing_args_size: Stack Arguments. (line 48)
- * CRTSTUFF_T_CFLAGS: Target Fragment. (line 15)
- * CRTSTUFF_T_CFLAGS_S: Target Fragment. (line 19)
- * CRT_CALL_STATIC_FUNCTION: Sections. (line 125)
- * CSImode: Machine Modes. (line 204)
- * cstoreMODE4 instruction pattern: Standard Names. (line 1659)
- * CTImode: Machine Modes. (line 204)
- * ctrapMM4 instruction pattern: Standard Names. (line 2125)
- * ctz: Arithmetic. (line 230)
- * ctzM2 instruction pattern: Standard Names. (line 1201)
- * CTZ_DEFINED_VALUE_AT_ZERO: Misc. (line 339)
- * CUMULATIVE_ARGS: Register Arguments. (line 137)
- * current_function_is_leaf: Leaf Functions. (line 50)
- * current_function_uses_only_leaf_regs: Leaf Functions. (line 50)
- * current_insn_predicate: Conditional Execution.
- (line 27)
- * C_COMMON_OVERRIDE_OPTIONS: Run-time Target. (line 136)
- * c_register_pragma: Misc. (line 440)
- * c_register_pragma_with_expansion: Misc. (line 442)
- * DAmode: Machine Modes. (line 154)
- * data bypass: Processor pipeline description.
- (line 105)
- * data bypass <1>: Processor pipeline description.
- (line 196)
- * data dependence delays: Processor pipeline description.
- (line 6)
- * Data Dependency Analysis: Dependency analysis.
- (line 6)
- * data structures: Per-Function Data. (line 6)
- * DATA_ABI_ALIGNMENT: Storage Layout. (line 263)
- * DATA_ALIGNMENT: Storage Layout. (line 250)
- * DATA_SECTION_ASM_OP: Sections. (line 52)
- * DBR_OUTPUT_SEQEND: Instruction Output. (line 133)
- * dbr_sequence_length: Instruction Output. (line 133)
- * DBX_BLOCKS_FUNCTION_RELATIVE: DBX Options. (line 100)
- * DBX_CONTIN_CHAR: DBX Options. (line 63)
- * DBX_CONTIN_LENGTH: DBX Options. (line 53)
- * DBX_DEBUGGING_INFO: DBX Options. (line 8)
- * DBX_FUNCTION_FIRST: DBX Options. (line 94)
- * DBX_LINES_FUNCTION_RELATIVE: DBX Options. (line 106)
- * DBX_NO_XREFS: DBX Options. (line 47)
- * DBX_OUTPUT_MAIN_SOURCE_FILENAME: File Names and DBX. (line 8)
- * DBX_OUTPUT_MAIN_SOURCE_FILE_END: File Names and DBX. (line 33)
- * DBX_OUTPUT_NULL_N_SO_AT_MAIN_SOURCE_FILE_END: File Names and DBX.
- (line 41)
- * DBX_OUTPUT_SOURCE_LINE: DBX Hooks. (line 8)
- * DBX_REGISTER_NUMBER: All Debuggers. (line 8)
- * DBX_REGPARM_STABS_CODE: DBX Options. (line 84)
- * DBX_REGPARM_STABS_LETTER: DBX Options. (line 89)
- * DBX_STATIC_CONST_VAR_CODE: DBX Options. (line 79)
- * DBX_STATIC_STAB_DATA_SECTION: DBX Options. (line 70)
- * DBX_TYPE_DECL_STABS_CODE: DBX Options. (line 75)
- * DBX_USE_BINCL: DBX Options. (line 112)
- * DCmode: Machine Modes. (line 199)
- * DDmode: Machine Modes. (line 93)
- * De Morgan's law: Insn Canonicalizations.
- (line 67)
- * dead_or_set_p: define_peephole. (line 65)
- * DEBUGGER_ARG_OFFSET: All Debuggers. (line 35)
- * DEBUGGER_AUTO_OFFSET: All Debuggers. (line 27)
- * debug_expr: Debug Information. (line 22)
- * DEBUG_EXPR_DECL: Declarations. (line 6)
- * debug_implicit_ptr: Debug Information. (line 27)
- * debug_insn: Insns. (line 247)
- * debug_marker: Debug Information. (line 37)
- * debug_parameter_ref: Debug Information. (line 34)
- * DEBUG_SYMS_TEXT: DBX Options. (line 24)
- * decimal float library: Decimal float library routines.
- (line 6)
- * declaration: Declarations. (line 6)
- * declarations, RTL: RTL Declarations. (line 6)
- * DECLARE_LIBRARY_RENAMES: Library Calls. (line 8)
- * DECL_ALIGN: Declarations. (line 6)
- * DECL_ANTICIPATED: Functions for C++. (line 42)
- * DECL_ARGUMENTS: Function Basics. (line 36)
- * DECL_ARRAY_DELETE_OPERATOR_P: Functions for C++. (line 158)
- * DECL_ARTIFICIAL: Working with declarations.
- (line 24)
- * DECL_ARTIFICIAL <1>: Function Basics. (line 6)
- * DECL_ARTIFICIAL <2>: Function Properties.
- (line 47)
- * DECL_ASSEMBLER_NAME: Function Basics. (line 6)
- * DECL_ASSEMBLER_NAME <1>: Function Basics. (line 19)
- * DECL_ATTRIBUTES: Attributes. (line 21)
- * DECL_BASE_CONSTRUCTOR_P: Functions for C++. (line 88)
- * DECL_COMPLETE_CONSTRUCTOR_P: Functions for C++. (line 84)
- * DECL_COMPLETE_DESTRUCTOR_P: Functions for C++. (line 98)
- * DECL_CONSTRUCTOR_P: Functions for C++. (line 77)
- * DECL_CONST_MEMFUNC_P: Functions for C++. (line 71)
- * DECL_CONTEXT: Namespaces. (line 31)
- * DECL_CONV_FN_P: Functions for C++. (line 105)
- * DECL_COPY_CONSTRUCTOR_P: Functions for C++. (line 92)
- * DECL_DESTRUCTOR_P: Functions for C++. (line 95)
- * DECL_EXTERNAL: Declarations. (line 6)
- * DECL_EXTERNAL <1>: Function Properties.
- (line 25)
- * DECL_EXTERN_C_FUNCTION_P: Functions for C++. (line 46)
- * DECL_FUNCTION_MEMBER_P: Functions for C++. (line 61)
- * DECL_FUNCTION_SPECIFIC_OPTIMIZATION: Function Basics. (line 6)
- * DECL_FUNCTION_SPECIFIC_OPTIMIZATION <1>: Function Properties.
- (line 61)
- * DECL_FUNCTION_SPECIFIC_TARGET: Function Basics. (line 6)
- * DECL_FUNCTION_SPECIFIC_TARGET <1>: Function Properties.
- (line 55)
- * DECL_GLOBAL_CTOR_P: Functions for C++. (line 108)
- * DECL_GLOBAL_DTOR_P: Functions for C++. (line 112)
- * DECL_INITIAL: Declarations. (line 6)
- * DECL_INITIAL <1>: Function Basics. (line 51)
- * DECL_LINKONCE_P: Functions for C++. (line 50)
- * DECL_LOCAL_FUNCTION_P: Functions for C++. (line 38)
- * DECL_MAIN_P: Functions for C++. (line 34)
- * DECL_NAME: Working with declarations.
- (line 7)
- * DECL_NAME <1>: Function Basics. (line 6)
- * DECL_NAME <2>: Function Basics. (line 9)
- * DECL_NAME <3>: Namespaces. (line 20)
- * DECL_NAMESPACE_ALIAS: Namespaces. (line 35)
- * DECL_NAMESPACE_STD_P: Namespaces. (line 45)
- * DECL_NONCONVERTING_P: Functions for C++. (line 80)
- * DECL_NONSTATIC_MEMBER_FUNCTION_P: Functions for C++. (line 68)
- * DECL_NON_THUNK_FUNCTION_P: Functions for C++. (line 138)
- * DECL_OVERLOADED_OPERATOR_P: Functions for C++. (line 102)
- * DECL_PURE_P: Function Properties.
- (line 40)
- * DECL_RESULT: Function Basics. (line 41)
- * DECL_SAVED_TREE: Function Basics. (line 44)
- * DECL_SIZE: Declarations. (line 6)
- * DECL_STATIC_FUNCTION_P: Functions for C++. (line 65)
- * DECL_STMT: Statements for C++. (line 6)
- * DECL_STMT_DECL: Statements for C++. (line 6)
- * DECL_THUNK_P: Functions for C++. (line 116)
- * DECL_VIRTUAL_P: Function Properties.
- (line 44)
- * DECL_VOLATILE_MEMFUNC_P: Functions for C++. (line 74)
- * default: GTY Options. (line 90)
- * default_file_start: File Framework. (line 8)
- * DEFAULT_GDB_EXTENSIONS: DBX Options. (line 17)
- * DEFAULT_INCOMING_FRAME_SP_OFFSET: Frame Layout. (line 199)
- * DEFAULT_PCC_STRUCT_RETURN: Aggregate Return. (line 34)
- * DEFAULT_SIGNED_CHAR: Type Layout. (line 117)
- * define_address_constraint: Define Constraints. (line 113)
- * define_asm_attributes: Tagging Insns. (line 73)
- * define_attr: Defining Attributes.
- (line 6)
- * define_automaton: Processor pipeline description.
- (line 53)
- * define_bypass: Processor pipeline description.
- (line 196)
- * define_code_attr: Code Iterators. (line 6)
- * define_code_iterator: Code Iterators. (line 6)
- * define_cond_exec: Conditional Execution.
- (line 13)
- * define_constants: Constant Definitions.
- (line 6)
- * define_constraint: Define Constraints. (line 45)
- * define_cpu_unit: Processor pipeline description.
- (line 68)
- * define_c_enum: Constant Definitions.
- (line 49)
- * define_delay: Delay Slots. (line 25)
- * define_enum: Constant Definitions.
- (line 118)
- * define_enum_attr: Defining Attributes.
- (line 83)
- * define_enum_attr <1>: Constant Definitions.
- (line 136)
- * define_expand: Expander Definitions.
- (line 11)
- * define_insn: Patterns. (line 6)
- * define_insn example: Example. (line 6)
- * define_insn_and_rewrite: Insn Splitting. (line 236)
- * define_insn_and_split: Insn Splitting. (line 190)
- * define_insn_reservation: Processor pipeline description.
- (line 105)
- * define_int_attr: Int Iterators. (line 6)
- * define_int_iterator: Int Iterators. (line 6)
- * define_memory_constraint: Define Constraints. (line 80)
- * define_mode_attr: Substitutions. (line 6)
- * define_mode_iterator: Defining Mode Iterators.
- (line 6)
- * define_peephole: define_peephole. (line 6)
- * define_peephole2: define_peephole2. (line 6)
- * define_predicate: Defining Predicates.
- (line 6)
- * define_query_cpu_unit: Processor pipeline description.
- (line 90)
- * define_register_constraint: Define Constraints. (line 26)
- * define_reservation: Processor pipeline description.
- (line 185)
- * define_special_memory_constraint: Define Constraints. (line 99)
- * define_special_predicate: Defining Predicates.
- (line 6)
- * define_split: Insn Splitting. (line 32)
- * define_subst: Define Subst. (line 6)
- * define_subst <1>: Define Subst Example.
- (line 6)
- * define_subst <2>: Define Subst Pattern Matching.
- (line 6)
- * define_subst <3>: Define Subst Output Template.
- (line 6)
- * define_subst <4>: Define Subst. (line 14)
- * define_subst <5>: Subst Iterators. (line 6)
- * define_subst_attr: Subst Iterators. (line 6)
- * define_subst_attr <1>: Subst Iterators. (line 26)
- * defining attributes and their values: Defining Attributes.
- (line 6)
- * defining constraints: Define Constraints. (line 6)
- * defining jump instruction patterns: Jump Patterns. (line 6)
- * defining looping instruction patterns: Looping Patterns. (line 6)
- * defining peephole optimizers: Peephole Definitions.
- (line 6)
- * defining predicates: Defining Predicates.
- (line 6)
- * defining RTL sequences for code generation: Expander Definitions.
- (line 6)
- * delay slots, defining: Delay Slots. (line 6)
- * deletable: GTY Options. (line 134)
- * DELETE_IF_ORDINARY: Filesystem. (line 79)
- * Dependent Patterns: Dependent Patterns. (line 6)
- * desc: GTY Options. (line 90)
- * descriptors for nested functions: Trampolines. (line 6)
- * destructors, output of: Initialization. (line 6)
- * deterministic finite state automaton: Processor pipeline description.
- (line 6)
- * deterministic finite state automaton <1>: Processor pipeline description.
- (line 304)
- * DFmode: Machine Modes. (line 76)
- * diagnostics guidelines, fix-it hints: Guidelines for Diagnostics.
- (line 320)
- * diagnostics, actionable: Guidelines for Diagnostics.
- (line 15)
- * diagnostics, false positive: Guidelines for Diagnostics.
- (line 39)
- * diagnostics, guidelines for: Guidelines for Diagnostics.
- (line 5)
- * diagnostics, locations: Guidelines for Diagnostics.
- (line 159)
- * diagnostics, true positive: Guidelines for Diagnostics.
- (line 39)
- * digits in constraint: Simple Constraints. (line 128)
- * DImode: Machine Modes. (line 45)
- * directory options .md: Including Patterns. (line 47)
- * DIR_SEPARATOR: Filesystem. (line 18)
- * DIR_SEPARATOR_2: Filesystem. (line 19)
- * disabling certain registers: Register Basics. (line 116)
- * dispatch table: Dispatch Tables. (line 8)
- * div: Arithmetic. (line 116)
- * div and attributes: Expressions. (line 83)
- * division: Arithmetic. (line 116)
- * division <1>: Arithmetic. (line 130)
- * division <2>: Arithmetic. (line 136)
- * divM3 instruction pattern: Standard Names. (line 442)
- * divmodM4 instruction pattern: Standard Names. (line 808)
- * dollar sign: Multi-Alternative. (line 57)
- * DOLLARS_IN_IDENTIFIERS: Misc. (line 485)
- * doloop_begin instruction pattern: Standard Names. (line 1879)
- * doloop_end instruction pattern: Standard Names. (line 1867)
- * DONE: Expander Definitions.
- (line 77)
- * DONE <1>: Insn Splitting. (line 61)
- * DONE <2>: define_peephole2. (line 76)
- * DONT_USE_BUILTIN_SETJMP: Exception Region Output.
- (line 78)
- * DOUBLE_TYPE_SIZE: Type Layout. (line 52)
- * DO_BODY: Statements for C++. (line 6)
- * DO_COND: Statements for C++. (line 6)
- * DO_STMT: Statements for C++. (line 6)
- * DQmode: Machine Modes. (line 118)
- * driver: Driver. (line 6)
- * DRIVER_SELF_SPECS: Driver. (line 8)
- * dump examples: Dump examples. (line 6)
- * dump setup: Dump setup. (line 6)
- * dump types: Dump types. (line 6)
- * dump verbosity: Dump output verbosity.
- (line 6)
- * DUMPFILE_FORMAT: Filesystem. (line 67)
- * dump_basic_block: Dump types. (line 29)
- * dump_generic_expr: Dump types. (line 31)
- * dump_gimple_stmt: Dump types. (line 33)
- * dump_printf: Dump types. (line 6)
- * DWARF2_ASM_LINE_DEBUG_INFO: DWARF. (line 45)
- * DWARF2_ASM_VIEW_DEBUG_INFO: DWARF. (line 51)
- * DWARF2_DEBUGGING_INFO: DWARF. (line 8)
- * DWARF2_FRAME_INFO: DWARF. (line 25)
- * DWARF2_FRAME_REG_OUT: Frame Registers. (line 149)
- * DWARF2_UNWIND_INFO: Exception Region Output.
- (line 39)
- * DWARF_ALT_FRAME_RETURN_COLUMN: Frame Layout. (line 146)
- * DWARF_CIE_DATA_ALIGNMENT: Exception Region Output.
- (line 90)
- * DWARF_FRAME_REGISTERS: Frame Registers. (line 109)
- * DWARF_FRAME_REGNUM: Frame Registers. (line 141)
- * DWARF_LAZY_REGISTER_VALUE: Frame Registers. (line 170)
- * DWARF_REG_TO_UNWIND_COLUMN: Frame Registers. (line 134)
- * DWARF_ZERO_REG: Frame Layout. (line 157)
- * DYNAMIC_CHAIN_ADDRESS: Frame Layout. (line 84)
- * E in constraint: Simple Constraints. (line 87)
- * earlyclobber operand: Modifiers. (line 25)
- * edge: Edges. (line 6)
- * edge in the flow graph: Edges. (line 6)
- * edge iterators: Edges. (line 15)
- * edge splitting: Maintaining the CFG.
- (line 104)
- * EDGE_ABNORMAL: Edges. (line 127)
- * EDGE_ABNORMAL, EDGE_ABNORMAL_CALL: Edges. (line 171)
- * EDGE_ABNORMAL, EDGE_EH: Edges. (line 95)
- * EDGE_ABNORMAL, EDGE_SIBCALL: Edges. (line 121)
- * EDGE_FALLTHRU, force_nonfallthru: Edges. (line 85)
- * EDOM, implicit usage: Library Calls. (line 59)
- * EH_FRAME_SECTION_NAME: Exception Region Output.
- (line 9)
- * EH_FRAME_THROUGH_COLLECT2: Exception Region Output.
- (line 19)
- * eh_return instruction pattern: Standard Names. (line 2060)
- * EH_RETURN_DATA_REGNO: Exception Handling. (line 6)
- * EH_RETURN_HANDLER_RTX: Exception Handling. (line 38)
- * EH_RETURN_STACKADJ_RTX: Exception Handling. (line 21)
- * EH_TABLES_CAN_BE_READ_ONLY: Exception Region Output.
- (line 29)
- * EH_USES: Function Entry. (line 162)
- * ei_edge: Edges. (line 43)
- * ei_end_p: Edges. (line 27)
- * ei_last: Edges. (line 23)
- * ei_next: Edges. (line 35)
- * ei_one_before_end_p: Edges. (line 31)
- * ei_prev: Edges. (line 39)
- * ei_safe_safe: Edges. (line 47)
- * ei_start: Edges. (line 19)
- * ELIMINABLE_REGS: Elimination. (line 34)
- * ELSE_CLAUSE: Statements for C++. (line 6)
- * Embedded C: Fixed-point fractional library routines.
- (line 6)
- * Empty Statements: Empty Statements. (line 6)
- * EMPTY_CLASS_EXPR: Statements for C++. (line 6)
- * EMPTY_FIELD_BOUNDARY: Storage Layout. (line 341)
- * Emulated TLS: Emulated TLS. (line 6)
- * enabled: Disable Insn Alternatives.
- (line 6)
- * ENDFILE_SPEC: Driver. (line 155)
- * endianness: Portability. (line 20)
- * ENTRY_BLOCK_PTR, EXIT_BLOCK_PTR: Basic Blocks. (line 10)
- * entry_value: Debug Information. (line 30)
- * enum reg_class: Register Classes. (line 70)
- * ENUMERAL_TYPE: Types. (line 6)
- * enumerations: Constant Definitions.
- (line 49)
- * epilogue: Function Entry. (line 6)
- * epilogue instruction pattern: Standard Names. (line 2098)
- * EPILOGUE_USES: Function Entry. (line 156)
- * eq: Comparisons. (line 52)
- * eq and attributes: Expressions. (line 83)
- * equal: Comparisons. (line 52)
- * eq_attr: Expressions. (line 104)
- * EQ_EXPR: Unary and Binary Expressions.
- (line 6)
- * errno, implicit usage: Library Calls. (line 71)
- * EXACT_DIV_EXPR: Unary and Binary Expressions.
- (line 6)
- * examining SSA_NAMEs: SSA. (line 182)
- * exception handling: Edges. (line 95)
- * exception handling <1>: Exception Handling. (line 6)
- * exception_receiver instruction pattern: Standard Names. (line 2025)
- * exclamation point: Multi-Alternative. (line 48)
- * exclusion_set: Processor pipeline description.
- (line 223)
- * exclusive-or, bitwise: Arithmetic. (line 168)
- * EXIT_EXPR: Unary and Binary Expressions.
- (line 6)
- * EXIT_IGNORE_STACK: Function Entry. (line 144)
- * exp10M2 instruction pattern: Standard Names. (line 995)
- * exp2M2 instruction pattern: Standard Names. (line 1002)
- * expander definitions: Expander Definitions.
- (line 6)
- * expm1M2 instruction pattern: Standard Names. (line 985)
- * expM2 instruction pattern: Standard Names. (line 978)
- * expression: Expression trees. (line 6)
- * expression codes: RTL Objects. (line 47)
- * EXPR_FILENAME: Working with declarations.
- (line 14)
- * EXPR_LINENO: Working with declarations.
- (line 20)
- * expr_list: Insns. (line 568)
- * EXPR_STMT: Statements for C++. (line 6)
- * EXPR_STMT_EXPR: Statements for C++. (line 6)
- * extendMN2 instruction pattern: Standard Names. (line 1447)
- * extensible constraints: Simple Constraints. (line 171)
- * extract_last_M instruction pattern: Standard Names. (line 543)
- * EXTRA_SPECS: Driver. (line 182)
- * extv instruction pattern: Standard Names. (line 1538)
- * extvM instruction pattern: Standard Names. (line 1483)
- * extvmisalignM instruction pattern: Standard Names. (line 1493)
- * extzv instruction pattern: Standard Names. (line 1556)
- * extzvM instruction pattern: Standard Names. (line 1507)
- * extzvmisalignM instruction pattern: Standard Names. (line 1510)
- * F in constraint: Simple Constraints. (line 92)
- * FAIL: Expander Definitions.
- (line 83)
- * FAIL <1>: Insn Splitting. (line 68)
- * FAIL <2>: define_peephole2. (line 83)
- * fall-thru: Edges. (line 68)
- * false positive: Guidelines for Diagnostics.
- (line 39)
- * FATAL_EXIT_CODE: Host Misc. (line 6)
- * FDL, GNU Free Documentation License: GNU Free Documentation License.
- (line 6)
- * features, optional, in system conventions: Run-time Target.
- (line 59)
- * ffs: Arithmetic. (line 210)
- * ffsM2 instruction pattern: Standard Names. (line 1157)
- * FIELD_DECL: Declarations. (line 6)
- * files and passes of the compiler: Passes. (line 6)
- * files, generated: Files. (line 6)
- * file_end_indicate_exec_stack: File Framework. (line 39)
- * final_absence_set: Processor pipeline description.
- (line 223)
- * FINAL_PRESCAN_INSN: Instruction Output. (line 60)
- * final_presence_set: Processor pipeline description.
- (line 223)
- * final_sequence: Instruction Output. (line 144)
- * FIND_BASE_TERM: Addressing Modes. (line 117)
- * finite state automaton minimization: Processor pipeline description.
- (line 304)
- * FINI_ARRAY_SECTION_ASM_OP: Sections. (line 113)
- * FINI_SECTION_ASM_OP: Sections. (line 98)
- * FIRST_PARM_OFFSET: Frame Layout. (line 59)
- * FIRST_PARM_OFFSET and virtual registers: Regs and Memory. (line 65)
- * FIRST_PSEUDO_REGISTER: Register Basics. (line 8)
- * FIRST_STACK_REG: Stack Registers. (line 26)
- * FIRST_VIRTUAL_REGISTER: Regs and Memory. (line 51)
- * fix: Conversions. (line 66)
- * fix-it hints: Guidelines for Diagnostics.
- (line 320)
- * fixed register: Register Basics. (line 15)
- * fixed-point fractional library: Fixed-point fractional library routines.
- (line 6)
- * FIXED_CONVERT_EXPR: Unary and Binary Expressions.
- (line 6)
- * FIXED_CST: Constant expressions.
- (line 6)
- * FIXED_POINT_TYPE: Types. (line 6)
- * FIXED_REGISTERS: Register Basics. (line 14)
- * fixed_regs: Register Basics. (line 102)
- * fixed_size_mode: Machine Modes. (line 305)
- * fixMN2 instruction pattern: Standard Names. (line 1414)
- * fixunsMN2 instruction pattern: Standard Names. (line 1423)
- * fixuns_truncMN2 instruction pattern: Standard Names. (line 1438)
- * fix_truncMN2 instruction pattern: Standard Names. (line 1434)
- * FIX_TRUNC_EXPR: Unary and Binary Expressions.
- (line 6)
- * flags in RTL expression: Flags. (line 6)
- * float: Conversions. (line 58)
- * floating point and cross compilation: Floating Point. (line 6)
- * floatMN2 instruction pattern: Standard Names. (line 1406)
- * floatunsMN2 instruction pattern: Standard Names. (line 1410)
- * FLOAT_EXPR: Unary and Binary Expressions.
- (line 6)
- * float_extend: Conversions. (line 33)
- * FLOAT_LIB_COMPARE_RETURNS_BOOL: Library Calls. (line 32)
- * FLOAT_STORE_FLAG_VALUE: Misc. (line 320)
- * float_truncate: Conversions. (line 53)
- * FLOAT_TYPE_SIZE: Type Layout. (line 48)
- * FLOAT_WORDS_BIG_ENDIAN: Storage Layout. (line 41)
- * FLOAT_WORDS_BIG_ENDIAN, (lack of) effect on subreg: Regs and Memory.
- (line 234)
- * floorM2 instruction pattern: Standard Names. (line 1069)
- * FLOOR_DIV_EXPR: Unary and Binary Expressions.
- (line 6)
- * FLOOR_MOD_EXPR: Unary and Binary Expressions.
- (line 6)
- * flow-insensitive alias analysis: Alias analysis. (line 6)
- * flow-sensitive alias analysis: Alias analysis. (line 6)
- * fma: Arithmetic. (line 112)
- * fmaM4 instruction pattern: Standard Names. (line 478)
- * fmaxM3 instruction pattern: Standard Names. (line 509)
- * fminM3 instruction pattern: Standard Names. (line 509)
- * fmodM3 instruction pattern: Standard Names. (line 901)
- * fmsM4 instruction pattern: Standard Names. (line 485)
- * fnmaM4 instruction pattern: Standard Names. (line 491)
- * fnmsM4 instruction pattern: Standard Names. (line 497)
- * fold_extract_last_M instruction pattern: Standard Names. (line 550)
- * fold_left_plus_M instruction pattern: Standard Names. (line 558)
- * FORCE_CODE_SECTION_ALIGN: Sections. (line 149)
- * force_reg: Standard Names. (line 36)
- * FOR_BODY: Statements for C++. (line 6)
- * FOR_COND: Statements for C++. (line 6)
- * FOR_EXPR: Statements for C++. (line 6)
- * FOR_INIT_STMT: Statements for C++. (line 6)
- * FOR_STMT: Statements for C++. (line 6)
- * for_user: GTY Options. (line 82)
- * fractional types: Fixed-point fractional library routines.
- (line 6)
- * fractMN2 instruction pattern: Standard Names. (line 1456)
- * fractunsMN2 instruction pattern: Standard Names. (line 1471)
- * fract_convert: Conversions. (line 82)
- * FRACT_TYPE_SIZE: Type Layout. (line 67)
- * frame layout: Frame Layout. (line 6)
- * FRAME_ADDR_RTX: Frame Layout. (line 108)
- * FRAME_GROWS_DOWNWARD: Frame Layout. (line 26)
- * FRAME_GROWS_DOWNWARD and virtual registers: Regs and Memory.
- (line 69)
- * FRAME_POINTER_CFA_OFFSET: Frame Layout. (line 225)
- * frame_pointer_needed: Function Entry. (line 42)
- * FRAME_POINTER_REGNUM: Frame Registers. (line 13)
- * FRAME_POINTER_REGNUM and virtual registers: Regs and Memory.
- (line 74)
- * frame_pointer_rtx: Frame Registers. (line 104)
- * frame_related: Flags. (line 238)
- * frame_related, in insn, call_insn, jump_insn, barrier, and set: Flags.
- (line 135)
- * frame_related, in mem: Flags. (line 74)
- * frame_related, in reg: Flags. (line 102)
- * frame_related, in symbol_ref: Flags. (line 179)
- * frequency, count, BB_FREQ_BASE: Profile information.
- (line 30)
- * ftruncM2 instruction pattern: Standard Names. (line 1429)
- * function: Functions. (line 6)
- * function <1>: Functions for C++. (line 6)
- * function call conventions: Interface. (line 6)
- * function entry and exit: Function Entry. (line 6)
- * function entry point, alternate function entry point: Edges.
- (line 180)
- * function properties: Function Properties.
- (line 6)
- * function-call insns: Calls. (line 6)
- * functions, leaf: Leaf Functions. (line 6)
- * FUNCTION_ARG_REGNO_P: Register Arguments. (line 261)
- * FUNCTION_BOUNDARY: Storage Layout. (line 176)
- * FUNCTION_DECL: Functions. (line 6)
- * FUNCTION_DECL <1>: Functions for C++. (line 6)
- * FUNCTION_MODE: Misc. (line 375)
- * FUNCTION_PROFILER: Profiling. (line 8)
- * FUNCTION_TYPE: Types. (line 6)
- * FUNCTION_VALUE: Scalar Return. (line 52)
- * FUNCTION_VALUE_REGNO_P: Scalar Return. (line 78)
- * fundamental type: Types. (line 6)
- * G in constraint: Simple Constraints. (line 96)
- * g in constraint: Simple Constraints. (line 118)
- * garbage collector, invocation: Invoking the garbage collector.
- (line 6)
- * garbage collector, troubleshooting: Troubleshooting. (line 6)
- * gather_loadMN instruction pattern: Standard Names. (line 232)
- * GCC and portability: Portability. (line 6)
- * GCC_DRIVER_HOST_INITIALIZATION: Host Misc. (line 36)
- * gcov_type: Profile information.
- (line 41)
- * ge: Comparisons. (line 72)
- * ge and attributes: Expressions. (line 83)
- * gencodes: RTL passes. (line 18)
- * general_operand: Machine-Independent Predicates.
- (line 104)
- * GENERAL_REGS: Register Classes. (line 22)
- * generated files: Files. (line 6)
- * generating assembler output: Output Statement. (line 6)
- * generating insns: RTL Template. (line 6)
- * GENERIC: Parsing pass. (line 6)
- * GENERIC <1>: GENERIC. (line 6)
- * generic predicates: Machine-Independent Predicates.
- (line 6)
- * genflags: RTL passes. (line 18)
- * GEN_ERRNO_RTX: Library Calls. (line 71)
- * get_attr: Expressions. (line 99)
- * get_attr_length: Insn Lengths. (line 52)
- * GET_CLASS_NARROWEST_MODE: Machine Modes. (line 430)
- * GET_CODE: RTL Objects. (line 47)
- * get_insns: Insns. (line 34)
- * get_last_insn: Insns. (line 34)
- * GET_MODE: Machine Modes. (line 377)
- * GET_MODE_ALIGNMENT: Machine Modes. (line 417)
- * GET_MODE_BITSIZE: Machine Modes. (line 401)
- * GET_MODE_CLASS: Machine Modes. (line 391)
- * GET_MODE_FBIT: Machine Modes. (line 408)
- * GET_MODE_IBIT: Machine Modes. (line 404)
- * GET_MODE_MASK: Machine Modes. (line 412)
- * GET_MODE_NAME: Machine Modes. (line 388)
- * GET_MODE_NUNITS: Machine Modes. (line 426)
- * GET_MODE_SIZE: Machine Modes. (line 398)
- * GET_MODE_UNIT_SIZE: Machine Modes. (line 420)
- * GET_MODE_WIDER_MODE: Machine Modes. (line 394)
- * GET_RTX_CLASS: RTL Classes. (line 6)
- * GET_RTX_FORMAT: RTL Classes. (line 136)
- * GET_RTX_LENGTH: RTL Classes. (line 133)
- * get_thread_pointerMODE instruction pattern: Standard Names.
- (line 2477)
- * geu: Comparisons. (line 72)
- * geu and attributes: Expressions. (line 83)
- * GE_EXPR: Unary and Binary Expressions.
- (line 6)
- * GGC: Type Information. (line 6)
- * ggc_collect: Invoking the garbage collector.
- (line 6)
- * GIMPLE: Parsing pass. (line 13)
- * GIMPLE <1>: Gimplification pass.
- (line 6)
- * GIMPLE <2>: GIMPLE. (line 6)
- * gimple: Tuple representation.
- (line 14)
- * GIMPLE API: GIMPLE API. (line 6)
- * GIMPLE class hierarchy: Class hierarchy of GIMPLE statements.
- (line 6)
- * GIMPLE Exception Handling: GIMPLE Exception Handling.
- (line 6)
- * GIMPLE instruction set: GIMPLE instruction set.
- (line 6)
- * GIMPLE sequences: GIMPLE sequences. (line 6)
- * GIMPLE statement iterators: Basic Blocks. (line 78)
- * GIMPLE statement iterators <1>: Maintaining the CFG.
- (line 33)
- * gimple_addresses_taken: Manipulating GIMPLE statements.
- (line 89)
- * GIMPLE_ASM: GIMPLE_ASM. (line 6)
- * gimple_asm_clobber_op: GIMPLE_ASM. (line 39)
- * gimple_asm_input_op: GIMPLE_ASM. (line 23)
- * gimple_asm_nclobbers: GIMPLE_ASM. (line 20)
- * gimple_asm_ninputs: GIMPLE_ASM. (line 14)
- * gimple_asm_noutputs: GIMPLE_ASM. (line 17)
- * gimple_asm_output_op: GIMPLE_ASM. (line 31)
- * gimple_asm_set_clobber_op: GIMPLE_ASM. (line 43)
- * gimple_asm_set_input_op: GIMPLE_ASM. (line 27)
- * gimple_asm_set_output_op: GIMPLE_ASM. (line 35)
- * gimple_asm_set_volatile: GIMPLE_ASM. (line 54)
- * gimple_asm_string: GIMPLE_ASM. (line 47)
- * gimple_asm_volatile_p: GIMPLE_ASM. (line 51)
- * GIMPLE_ASSIGN: GIMPLE_ASSIGN. (line 6)
- * gimple_assign_cast_p: Logical Operators. (line 158)
- * gimple_assign_cast_p <1>: GIMPLE_ASSIGN. (line 104)
- * gimple_assign_lhs: GIMPLE_ASSIGN. (line 62)
- * gimple_assign_lhs_ptr: GIMPLE_ASSIGN. (line 65)
- * gimple_assign_rhs1: GIMPLE_ASSIGN. (line 68)
- * gimple_assign_rhs1_ptr: GIMPLE_ASSIGN. (line 71)
- * gimple_assign_rhs2: GIMPLE_ASSIGN. (line 75)
- * gimple_assign_rhs2_ptr: GIMPLE_ASSIGN. (line 78)
- * gimple_assign_rhs3: GIMPLE_ASSIGN. (line 82)
- * gimple_assign_rhs3_ptr: GIMPLE_ASSIGN. (line 85)
- * gimple_assign_rhs_class: GIMPLE_ASSIGN. (line 56)
- * gimple_assign_rhs_code: GIMPLE_ASSIGN. (line 52)
- * gimple_assign_set_lhs: GIMPLE_ASSIGN. (line 89)
- * gimple_assign_set_rhs1: GIMPLE_ASSIGN. (line 92)
- * gimple_assign_set_rhs2: GIMPLE_ASSIGN. (line 96)
- * gimple_assign_set_rhs3: GIMPLE_ASSIGN. (line 100)
- * gimple_bb: Manipulating GIMPLE statements.
- (line 17)
- * GIMPLE_BIND: GIMPLE_BIND. (line 6)
- * gimple_bind_add_seq: GIMPLE_BIND. (line 34)
- * gimple_bind_add_stmt: GIMPLE_BIND. (line 31)
- * gimple_bind_append_vars: GIMPLE_BIND. (line 18)
- * gimple_bind_block: GIMPLE_BIND. (line 39)
- * gimple_bind_body: GIMPLE_BIND. (line 22)
- * gimple_bind_set_block: GIMPLE_BIND. (line 44)
- * gimple_bind_set_body: GIMPLE_BIND. (line 26)
- * gimple_bind_set_vars: GIMPLE_BIND. (line 14)
- * gimple_bind_vars: GIMPLE_BIND. (line 11)
- * gimple_block: Manipulating GIMPLE statements.
- (line 20)
- * gimple_build: GIMPLE API. (line 34)
- * gimple_build <1>: GIMPLE API. (line 36)
- * gimple_build <2>: GIMPLE API. (line 38)
- * gimple_build <3>: GIMPLE API. (line 41)
- * gimple_build <4>: GIMPLE API. (line 44)
- * gimple_build <5>: GIMPLE API. (line 47)
- * gimple_build_debug_begin_stmt: GIMPLE_DEBUG. (line 72)
- * gimple_build_debug_inline_entry: GIMPLE_DEBUG. (line 82)
- * gimple_build_nop: GIMPLE_NOP. (line 6)
- * gimple_build_omp_master: GIMPLE_OMP_MASTER. (line 6)
- * gimple_build_omp_ordered: GIMPLE_OMP_ORDERED. (line 6)
- * gimple_build_omp_return: GIMPLE_OMP_RETURN. (line 6)
- * gimple_build_omp_section: GIMPLE_OMP_SECTION. (line 6)
- * gimple_build_omp_sections_switch: GIMPLE_OMP_SECTIONS.
- (line 13)
- * gimple_build_wce: GIMPLE_WITH_CLEANUP_EXPR.
- (line 6)
- * GIMPLE_CALL: GIMPLE_CALL. (line 6)
- * gimple_call_arg: GIMPLE_CALL. (line 67)
- * gimple_call_arg_ptr: GIMPLE_CALL. (line 71)
- * gimple_call_chain: GIMPLE_CALL. (line 58)
- * gimple_call_copy_skip_args: GIMPLE_CALL. (line 92)
- * gimple_call_fn: GIMPLE_CALL. (line 39)
- * gimple_call_fndecl: GIMPLE_CALL. (line 47)
- * gimple_call_lhs: GIMPLE_CALL. (line 30)
- * gimple_call_lhs_ptr: GIMPLE_CALL. (line 33)
- * gimple_call_noreturn_p: GIMPLE_CALL. (line 89)
- * gimple_call_num_args: GIMPLE_CALL. (line 64)
- * gimple_call_return_type: GIMPLE_CALL. (line 55)
- * gimple_call_set_arg: GIMPLE_CALL. (line 76)
- * gimple_call_set_chain: GIMPLE_CALL. (line 61)
- * gimple_call_set_fn: GIMPLE_CALL. (line 43)
- * gimple_call_set_fndecl: GIMPLE_CALL. (line 52)
- * gimple_call_set_lhs: GIMPLE_CALL. (line 36)
- * gimple_call_set_tail: GIMPLE_CALL. (line 81)
- * gimple_call_tail_p: GIMPLE_CALL. (line 86)
- * GIMPLE_CATCH: GIMPLE_CATCH. (line 6)
- * gimple_catch_handler: GIMPLE_CATCH. (line 19)
- * gimple_catch_set_handler: GIMPLE_CATCH. (line 26)
- * gimple_catch_set_types: GIMPLE_CATCH. (line 23)
- * gimple_catch_types: GIMPLE_CATCH. (line 12)
- * gimple_catch_types_ptr: GIMPLE_CATCH. (line 15)
- * gimple_code: Manipulating GIMPLE statements.
- (line 14)
- * GIMPLE_COND: GIMPLE_COND. (line 6)
- * gimple_cond_code: GIMPLE_COND. (line 20)
- * gimple_cond_false_label: GIMPLE_COND. (line 59)
- * gimple_cond_lhs: GIMPLE_COND. (line 29)
- * gimple_cond_make_false: GIMPLE_COND. (line 63)
- * gimple_cond_make_true: GIMPLE_COND. (line 66)
- * gimple_cond_rhs: GIMPLE_COND. (line 37)
- * gimple_cond_set_code: GIMPLE_COND. (line 24)
- * gimple_cond_set_false_label: GIMPLE_COND. (line 54)
- * gimple_cond_set_lhs: GIMPLE_COND. (line 33)
- * gimple_cond_set_rhs: GIMPLE_COND. (line 41)
- * gimple_cond_set_true_label: GIMPLE_COND. (line 49)
- * gimple_cond_true_label: GIMPLE_COND. (line 45)
- * gimple_convert: GIMPLE API. (line 50)
- * gimple_copy: Manipulating GIMPLE statements.
- (line 146)
- * GIMPLE_DEBUG: GIMPLE_DEBUG. (line 6)
- * GIMPLE_DEBUG_BEGIN_STMT: GIMPLE_DEBUG. (line 6)
- * GIMPLE_DEBUG_BIND: GIMPLE_DEBUG. (line 6)
- * gimple_debug_bind_get_value: GIMPLE_DEBUG. (line 46)
- * gimple_debug_bind_get_value_ptr: GIMPLE_DEBUG. (line 50)
- * gimple_debug_bind_get_var: GIMPLE_DEBUG. (line 43)
- * gimple_debug_bind_has_value_p: GIMPLE_DEBUG. (line 68)
- * gimple_debug_bind_p: Logical Operators. (line 162)
- * gimple_debug_bind_reset_value: GIMPLE_DEBUG. (line 64)
- * gimple_debug_bind_set_value: GIMPLE_DEBUG. (line 59)
- * gimple_debug_bind_set_var: GIMPLE_DEBUG. (line 55)
- * GIMPLE_DEBUG_INLINE_ENTRY: GIMPLE_DEBUG. (line 6)
- * gimple_def_ops: Manipulating GIMPLE statements.
- (line 93)
- * GIMPLE_EH_FILTER: GIMPLE_EH_FILTER. (line 6)
- * gimple_eh_filter_failure: GIMPLE_EH_FILTER. (line 18)
- * gimple_eh_filter_set_failure: GIMPLE_EH_FILTER. (line 27)
- * gimple_eh_filter_set_types: GIMPLE_EH_FILTER. (line 22)
- * gimple_eh_filter_types: GIMPLE_EH_FILTER. (line 11)
- * gimple_eh_filter_types_ptr: GIMPLE_EH_FILTER. (line 14)
- * gimple_eh_must_not_throw_fndecl: GIMPLE_EH_FILTER. (line 32)
- * gimple_eh_must_not_throw_set_fndecl: GIMPLE_EH_FILTER. (line 36)
- * gimple_expr_code: Manipulating GIMPLE statements.
- (line 30)
- * gimple_expr_type: Manipulating GIMPLE statements.
- (line 23)
- * GIMPLE_GOTO: GIMPLE_GOTO. (line 6)
- * gimple_goto_dest: GIMPLE_GOTO. (line 9)
- * gimple_goto_set_dest: GIMPLE_GOTO. (line 12)
- * gimple_has_mem_ops: Manipulating GIMPLE statements.
- (line 71)
- * gimple_has_ops: Manipulating GIMPLE statements.
- (line 68)
- * gimple_has_volatile_ops: Manipulating GIMPLE statements.
- (line 133)
- * GIMPLE_LABEL: GIMPLE_LABEL. (line 6)
- * gimple_label_label: GIMPLE_LABEL. (line 10)
- * gimple_label_set_label: GIMPLE_LABEL. (line 13)
- * gimple_loaded_syms: Manipulating GIMPLE statements.
- (line 121)
- * gimple_locus: Manipulating GIMPLE statements.
- (line 41)
- * gimple_locus_empty_p: Manipulating GIMPLE statements.
- (line 47)
- * gimple_modified_p: Manipulating GIMPLE statements.
- (line 129)
- * GIMPLE_NOP: GIMPLE_NOP. (line 6)
- * gimple_nop_p: GIMPLE_NOP. (line 9)
- * gimple_no_warning_p: Manipulating GIMPLE statements.
- (line 50)
- * gimple_num_ops: Logical Operators. (line 76)
- * gimple_num_ops <1>: Manipulating GIMPLE statements.
- (line 74)
- * GIMPLE_OMP_ATOMIC_LOAD: GIMPLE_OMP_ATOMIC_LOAD.
- (line 6)
- * gimple_omp_atomic_load_lhs: GIMPLE_OMP_ATOMIC_LOAD.
- (line 16)
- * gimple_omp_atomic_load_rhs: GIMPLE_OMP_ATOMIC_LOAD.
- (line 24)
- * gimple_omp_atomic_load_set_lhs: GIMPLE_OMP_ATOMIC_LOAD.
- (line 12)
- * gimple_omp_atomic_load_set_rhs: GIMPLE_OMP_ATOMIC_LOAD.
- (line 20)
- * GIMPLE_OMP_ATOMIC_STORE: GIMPLE_OMP_ATOMIC_STORE.
- (line 6)
- * gimple_omp_atomic_store_set_val: GIMPLE_OMP_ATOMIC_STORE.
- (line 11)
- * gimple_omp_atomic_store_val: GIMPLE_OMP_ATOMIC_STORE.
- (line 15)
- * gimple_omp_body: GIMPLE_OMP_PARALLEL.
- (line 23)
- * GIMPLE_OMP_CONTINUE: GIMPLE_OMP_CONTINUE.
- (line 6)
- * gimple_omp_continue_control_def: GIMPLE_OMP_CONTINUE.
- (line 12)
- * gimple_omp_continue_control_def_ptr: GIMPLE_OMP_CONTINUE.
- (line 17)
- * gimple_omp_continue_control_use: GIMPLE_OMP_CONTINUE.
- (line 26)
- * gimple_omp_continue_control_use_ptr: GIMPLE_OMP_CONTINUE.
- (line 31)
- * gimple_omp_continue_set_control_def: GIMPLE_OMP_CONTINUE.
- (line 21)
- * gimple_omp_continue_set_control_use: GIMPLE_OMP_CONTINUE.
- (line 35)
- * GIMPLE_OMP_CRITICAL: GIMPLE_OMP_CRITICAL.
- (line 6)
- * gimple_omp_critical_name: GIMPLE_OMP_CRITICAL.
- (line 12)
- * gimple_omp_critical_name_ptr: GIMPLE_OMP_CRITICAL.
- (line 16)
- * gimple_omp_critical_set_name: GIMPLE_OMP_CRITICAL.
- (line 21)
- * GIMPLE_OMP_FOR: GIMPLE_OMP_FOR. (line 6)
- * gimple_omp_for_clauses: GIMPLE_OMP_FOR. (line 17)
- * gimple_omp_for_clauses_ptr: GIMPLE_OMP_FOR. (line 20)
- * gimple_omp_for_cond: GIMPLE_OMP_FOR. (line 80)
- * gimple_omp_for_final: GIMPLE_OMP_FOR. (line 48)
- * gimple_omp_for_final_ptr: GIMPLE_OMP_FOR. (line 51)
- * gimple_omp_for_incr: GIMPLE_OMP_FOR. (line 58)
- * gimple_omp_for_incr_ptr: GIMPLE_OMP_FOR. (line 61)
- * gimple_omp_for_index: GIMPLE_OMP_FOR. (line 28)
- * gimple_omp_for_index_ptr: GIMPLE_OMP_FOR. (line 31)
- * gimple_omp_for_initial: GIMPLE_OMP_FOR. (line 38)
- * gimple_omp_for_initial_ptr: GIMPLE_OMP_FOR. (line 41)
- * gimple_omp_for_pre_body: GIMPLE_OMP_FOR. (line 67)
- * gimple_omp_for_set_clauses: GIMPLE_OMP_FOR. (line 23)
- * gimple_omp_for_set_cond: GIMPLE_OMP_FOR. (line 76)
- * gimple_omp_for_set_final: GIMPLE_OMP_FOR. (line 54)
- * gimple_omp_for_set_incr: GIMPLE_OMP_FOR. (line 64)
- * gimple_omp_for_set_index: GIMPLE_OMP_FOR. (line 34)
- * gimple_omp_for_set_initial: GIMPLE_OMP_FOR. (line 44)
- * gimple_omp_for_set_pre_body: GIMPLE_OMP_FOR. (line 71)
- * GIMPLE_OMP_MASTER: GIMPLE_OMP_MASTER. (line 6)
- * GIMPLE_OMP_ORDERED: GIMPLE_OMP_ORDERED. (line 6)
- * GIMPLE_OMP_PARALLEL: GIMPLE_OMP_PARALLEL.
- (line 6)
- * gimple_omp_parallel_child_fn: GIMPLE_OMP_PARALLEL.
- (line 42)
- * gimple_omp_parallel_child_fn_ptr: GIMPLE_OMP_PARALLEL.
- (line 47)
- * gimple_omp_parallel_clauses: GIMPLE_OMP_PARALLEL.
- (line 30)
- * gimple_omp_parallel_clauses_ptr: GIMPLE_OMP_PARALLEL.
- (line 33)
- * gimple_omp_parallel_combined_p: GIMPLE_OMP_PARALLEL.
- (line 15)
- * gimple_omp_parallel_data_arg: GIMPLE_OMP_PARALLEL.
- (line 56)
- * gimple_omp_parallel_data_arg_ptr: GIMPLE_OMP_PARALLEL.
- (line 61)
- * gimple_omp_parallel_set_child_fn: GIMPLE_OMP_PARALLEL.
- (line 52)
- * gimple_omp_parallel_set_clauses: GIMPLE_OMP_PARALLEL.
- (line 37)
- * gimple_omp_parallel_set_combined_p: GIMPLE_OMP_PARALLEL.
- (line 19)
- * gimple_omp_parallel_set_data_arg: GIMPLE_OMP_PARALLEL.
- (line 65)
- * GIMPLE_OMP_RETURN: GIMPLE_OMP_RETURN. (line 6)
- * gimple_omp_return_nowait_p: GIMPLE_OMP_RETURN. (line 13)
- * gimple_omp_return_set_nowait: GIMPLE_OMP_RETURN. (line 10)
- * GIMPLE_OMP_SECTION: GIMPLE_OMP_SECTION. (line 6)
- * GIMPLE_OMP_SECTIONS: GIMPLE_OMP_SECTIONS.
- (line 6)
- * gimple_omp_sections_clauses: GIMPLE_OMP_SECTIONS.
- (line 29)
- * gimple_omp_sections_clauses_ptr: GIMPLE_OMP_SECTIONS.
- (line 32)
- * gimple_omp_sections_control: GIMPLE_OMP_SECTIONS.
- (line 16)
- * gimple_omp_sections_control_ptr: GIMPLE_OMP_SECTIONS.
- (line 20)
- * gimple_omp_sections_set_clauses: GIMPLE_OMP_SECTIONS.
- (line 35)
- * gimple_omp_sections_set_control: GIMPLE_OMP_SECTIONS.
- (line 24)
- * gimple_omp_section_last_p: GIMPLE_OMP_SECTION. (line 11)
- * gimple_omp_section_set_last: GIMPLE_OMP_SECTION. (line 15)
- * gimple_omp_set_body: GIMPLE_OMP_PARALLEL.
- (line 26)
- * GIMPLE_OMP_SINGLE: GIMPLE_OMP_SINGLE. (line 6)
- * gimple_omp_single_clauses: GIMPLE_OMP_SINGLE. (line 13)
- * gimple_omp_single_clauses_ptr: GIMPLE_OMP_SINGLE. (line 16)
- * gimple_omp_single_set_clauses: GIMPLE_OMP_SINGLE. (line 19)
- * gimple_op: Logical Operators. (line 79)
- * gimple_op <1>: Manipulating GIMPLE statements.
- (line 80)
- * gimple_ops: Logical Operators. (line 82)
- * gimple_ops <1>: Manipulating GIMPLE statements.
- (line 77)
- * gimple_op_ptr: Manipulating GIMPLE statements.
- (line 83)
- * GIMPLE_PHI: GIMPLE_PHI. (line 6)
- * gimple_phi_arg: GIMPLE_PHI. (line 24)
- * gimple_phi_arg <1>: SSA. (line 62)
- * gimple_phi_arg_def: SSA. (line 68)
- * gimple_phi_arg_edge: SSA. (line 65)
- * gimple_phi_capacity: GIMPLE_PHI. (line 6)
- * gimple_phi_num_args: GIMPLE_PHI. (line 10)
- * gimple_phi_num_args <1>: SSA. (line 58)
- * gimple_phi_result: GIMPLE_PHI. (line 15)
- * gimple_phi_result <1>: SSA. (line 55)
- * gimple_phi_result_ptr: GIMPLE_PHI. (line 18)
- * gimple_phi_set_arg: GIMPLE_PHI. (line 28)
- * gimple_phi_set_result: GIMPLE_PHI. (line 21)
- * gimple_plf: Manipulating GIMPLE statements.
- (line 64)
- * GIMPLE_RESX: GIMPLE_RESX. (line 6)
- * gimple_resx_region: GIMPLE_RESX. (line 12)
- * gimple_resx_set_region: GIMPLE_RESX. (line 15)
- * GIMPLE_RETURN: GIMPLE_RETURN. (line 6)
- * gimple_return_retval: GIMPLE_RETURN. (line 9)
- * gimple_return_set_retval: GIMPLE_RETURN. (line 12)
- * gimple_seq_add_seq: GIMPLE sequences. (line 30)
- * gimple_seq_add_stmt: GIMPLE sequences. (line 24)
- * gimple_seq_alloc: GIMPLE sequences. (line 61)
- * gimple_seq_copy: GIMPLE sequences. (line 65)
- * gimple_seq_deep_copy: GIMPLE sequences. (line 36)
- * gimple_seq_empty_p: GIMPLE sequences. (line 69)
- * gimple_seq_first: GIMPLE sequences. (line 43)
- * gimple_seq_init: GIMPLE sequences. (line 58)
- * gimple_seq_last: GIMPLE sequences. (line 46)
- * gimple_seq_reverse: GIMPLE sequences. (line 39)
- * gimple_seq_set_first: GIMPLE sequences. (line 53)
- * gimple_seq_set_last: GIMPLE sequences. (line 49)
- * gimple_seq_singleton_p: GIMPLE sequences. (line 78)
- * gimple_set_block: Manipulating GIMPLE statements.
- (line 38)
- * gimple_set_def_ops: Manipulating GIMPLE statements.
- (line 96)
- * gimple_set_has_volatile_ops: Manipulating GIMPLE statements.
- (line 136)
- * gimple_set_locus: Manipulating GIMPLE statements.
- (line 44)
- * gimple_set_op: Manipulating GIMPLE statements.
- (line 86)
- * gimple_set_plf: Manipulating GIMPLE statements.
- (line 60)
- * gimple_set_use_ops: Manipulating GIMPLE statements.
- (line 103)
- * gimple_set_vdef_ops: Manipulating GIMPLE statements.
- (line 117)
- * gimple_set_visited: Manipulating GIMPLE statements.
- (line 53)
- * gimple_set_vuse_ops: Manipulating GIMPLE statements.
- (line 110)
- * gimple_simplify: GIMPLE API. (line 6)
- * gimple_simplify <1>: GIMPLE API. (line 8)
- * gimple_simplify <2>: GIMPLE API. (line 10)
- * gimple_simplify <3>: GIMPLE API. (line 12)
- * gimple_simplify <4>: GIMPLE API. (line 14)
- * gimple_simplify <5>: GIMPLE API. (line 16)
- * gimple_statement_with_ops: Tuple representation.
- (line 96)
- * gimple_stored_syms: Manipulating GIMPLE statements.
- (line 125)
- * GIMPLE_SWITCH: GIMPLE_SWITCH. (line 6)
- * gimple_switch_default_label: GIMPLE_SWITCH. (line 41)
- * gimple_switch_index: GIMPLE_SWITCH. (line 24)
- * gimple_switch_label: GIMPLE_SWITCH. (line 31)
- * gimple_switch_num_labels: GIMPLE_SWITCH. (line 14)
- * gimple_switch_set_default_label: GIMPLE_SWITCH. (line 45)
- * gimple_switch_set_index: GIMPLE_SWITCH. (line 27)
- * gimple_switch_set_label: GIMPLE_SWITCH. (line 36)
- * gimple_switch_set_num_labels: GIMPLE_SWITCH. (line 19)
- * GIMPLE_TRY: GIMPLE_TRY. (line 6)
- * gimple_try_catch_is_cleanup: GIMPLE_TRY. (line 19)
- * gimple_try_cleanup: GIMPLE_TRY. (line 26)
- * gimple_try_eval: GIMPLE_TRY. (line 22)
- * gimple_try_kind: GIMPLE_TRY. (line 15)
- * gimple_try_set_catch_is_cleanup: GIMPLE_TRY. (line 30)
- * gimple_try_set_cleanup: GIMPLE_TRY. (line 38)
- * gimple_try_set_eval: GIMPLE_TRY. (line 34)
- * gimple_use_ops: Manipulating GIMPLE statements.
- (line 100)
- * gimple_vdef_ops: Manipulating GIMPLE statements.
- (line 114)
- * gimple_visited_p: Manipulating GIMPLE statements.
- (line 57)
- * gimple_vuse_ops: Manipulating GIMPLE statements.
- (line 107)
- * gimple_wce_cleanup: GIMPLE_WITH_CLEANUP_EXPR.
- (line 10)
- * gimple_wce_cleanup_eh_only: GIMPLE_WITH_CLEANUP_EXPR.
- (line 17)
- * gimple_wce_set_cleanup: GIMPLE_WITH_CLEANUP_EXPR.
- (line 13)
- * gimple_wce_set_cleanup_eh_only: GIMPLE_WITH_CLEANUP_EXPR.
- (line 20)
- * GIMPLE_WITH_CLEANUP_EXPR: GIMPLE_WITH_CLEANUP_EXPR.
- (line 6)
- * gimplification: Parsing pass. (line 13)
- * gimplification <1>: Gimplification pass.
- (line 6)
- * gimplifier: Parsing pass. (line 13)
- * gimplify_assign: GIMPLE_ASSIGN. (line 41)
- * gimplify_expr: Gimplification pass.
- (line 18)
- * gimplify_function_tree: Gimplification pass.
- (line 18)
- * GLOBAL_INIT_PRIORITY: Functions for C++. (line 141)
- * global_regs: Register Basics. (line 102)
- * GO_IF_LEGITIMATE_ADDRESS: Addressing Modes. (line 90)
- * greater than: Comparisons. (line 60)
- * greater than <1>: Comparisons. (line 64)
- * greater than <2>: Comparisons. (line 72)
- * gsi_after_labels: Sequence iterators. (line 74)
- * gsi_bb: Sequence iterators. (line 82)
- * gsi_commit_edge_inserts: Sequence iterators. (line 193)
- * gsi_commit_edge_inserts <1>: Maintaining the CFG.
- (line 104)
- * gsi_commit_one_edge_insert: Sequence iterators. (line 188)
- * gsi_end_p: Sequence iterators. (line 59)
- * gsi_end_p <1>: Maintaining the CFG.
- (line 48)
- * gsi_for_stmt: Sequence iterators. (line 156)
- * gsi_insert_after: Sequence iterators. (line 145)
- * gsi_insert_after <1>: Maintaining the CFG.
- (line 60)
- * gsi_insert_before: Sequence iterators. (line 134)
- * gsi_insert_before <1>: Maintaining the CFG.
- (line 66)
- * gsi_insert_on_edge: Sequence iterators. (line 173)
- * gsi_insert_on_edge <1>: Maintaining the CFG.
- (line 104)
- * gsi_insert_on_edge_immediate: Sequence iterators. (line 183)
- * gsi_insert_seq_after: Sequence iterators. (line 152)
- * gsi_insert_seq_before: Sequence iterators. (line 141)
- * gsi_insert_seq_on_edge: Sequence iterators. (line 177)
- * gsi_last: Sequence iterators. (line 49)
- * gsi_last <1>: Maintaining the CFG.
- (line 44)
- * gsi_last_bb: Sequence iterators. (line 55)
- * gsi_link_after: Sequence iterators. (line 113)
- * gsi_link_before: Sequence iterators. (line 103)
- * gsi_link_seq_after: Sequence iterators. (line 108)
- * gsi_link_seq_before: Sequence iterators. (line 97)
- * gsi_move_after: Sequence iterators. (line 159)
- * gsi_move_before: Sequence iterators. (line 164)
- * gsi_move_to_bb_end: Sequence iterators. (line 169)
- * gsi_next: Sequence iterators. (line 65)
- * gsi_next <1>: Maintaining the CFG.
- (line 52)
- * gsi_one_before_end_p: Sequence iterators. (line 62)
- * gsi_prev: Sequence iterators. (line 68)
- * gsi_prev <1>: Maintaining the CFG.
- (line 56)
- * gsi_remove: Sequence iterators. (line 88)
- * gsi_remove <1>: Maintaining the CFG.
- (line 72)
- * gsi_replace: Sequence iterators. (line 128)
- * gsi_seq: Sequence iterators. (line 85)
- * gsi_split_seq_after: Sequence iterators. (line 118)
- * gsi_split_seq_before: Sequence iterators. (line 123)
- * gsi_start: Sequence iterators. (line 39)
- * gsi_start <1>: Maintaining the CFG.
- (line 40)
- * gsi_start_bb: Sequence iterators. (line 45)
- * gsi_stmt: Sequence iterators. (line 71)
- * gsi_stmt_ptr: Sequence iterators. (line 79)
- * gt: Comparisons. (line 60)
- * gt and attributes: Expressions. (line 83)
- * gtu: Comparisons. (line 64)
- * gtu and attributes: Expressions. (line 83)
- * GTY: Type Information. (line 6)
- * GT_EXPR: Unary and Binary Expressions.
- (line 6)
- * guidelines for diagnostics: Guidelines for Diagnostics.
- (line 6)
- * guidelines for options: Guidelines for Options.
- (line 6)
- * guidelines, user experience: User Experience Guidelines.
- (line 6)
- * H in constraint: Simple Constraints. (line 96)
- * HAmode: Machine Modes. (line 146)
- * HANDLER: Statements for C++. (line 6)
- * HANDLER_BODY: Statements for C++. (line 6)
- * HANDLER_PARMS: Statements for C++. (line 6)
- * HANDLE_PRAGMA_PACK_WITH_EXPANSION: Misc. (line 475)
- * hard registers: Regs and Memory. (line 9)
- * HARD_FRAME_POINTER_IS_ARG_POINTER: Frame Registers. (line 57)
- * HARD_FRAME_POINTER_IS_FRAME_POINTER: Frame Registers. (line 50)
- * HARD_FRAME_POINTER_REGNUM: Frame Registers. (line 19)
- * HARD_REGNO_CALLER_SAVE_MODE: Caller Saves. (line 10)
- * HARD_REGNO_NREGS_HAS_PADDING: Values in Registers.
- (line 21)
- * HARD_REGNO_NREGS_WITH_PADDING: Values in Registers.
- (line 39)
- * HARD_REGNO_RENAME_OK: Values in Registers.
- (line 113)
- * HAS_INIT_SECTION: Macros for Initialization.
- (line 18)
- * HAS_LONG_COND_BRANCH: Misc. (line 8)
- * HAS_LONG_UNCOND_BRANCH: Misc. (line 17)
- * HAVE_DOS_BASED_FILE_SYSTEM: Filesystem. (line 11)
- * HAVE_POST_DECREMENT: Addressing Modes. (line 11)
- * HAVE_POST_INCREMENT: Addressing Modes. (line 10)
- * HAVE_POST_MODIFY_DISP: Addressing Modes. (line 17)
- * HAVE_POST_MODIFY_REG: Addressing Modes. (line 23)
- * HAVE_PRE_DECREMENT: Addressing Modes. (line 9)
- * HAVE_PRE_INCREMENT: Addressing Modes. (line 8)
- * HAVE_PRE_MODIFY_DISP: Addressing Modes. (line 16)
- * HAVE_PRE_MODIFY_REG: Addressing Modes. (line 22)
- * HCmode: Machine Modes. (line 199)
- * HFmode: Machine Modes. (line 61)
- * high: Constants. (line 220)
- * HImode: Machine Modes. (line 29)
- * HImode, in insn: Insns. (line 291)
- * HONOR_REG_ALLOC_ORDER: Allocation Order. (line 36)
- * host configuration: Host Config. (line 6)
- * host functions: Host Common. (line 6)
- * host hooks: Host Common. (line 6)
- * host makefile fragment: Host Fragment. (line 6)
- * HOST_BIT_BUCKET: Filesystem. (line 51)
- * HOST_EXECUTABLE_SUFFIX: Filesystem. (line 45)
- * HOST_HOOKS_EXTRA_SIGNALS: Host Common. (line 11)
- * HOST_HOOKS_GT_PCH_ALLOC_GRANULARITY: Host Common. (line 43)
- * HOST_HOOKS_GT_PCH_GET_ADDRESS: Host Common. (line 15)
- * HOST_HOOKS_GT_PCH_USE_ADDRESS: Host Common. (line 24)
- * HOST_LACKS_INODE_NUMBERS: Filesystem. (line 89)
- * HOST_LONG_FORMAT: Host Misc. (line 45)
- * HOST_LONG_LONG_FORMAT: Host Misc. (line 41)
- * HOST_OBJECT_SUFFIX: Filesystem. (line 40)
- * HOST_PTR_PRINTF: Host Misc. (line 49)
- * HOT_TEXT_SECTION_NAME: Sections. (line 42)
- * HQmode: Machine Modes. (line 110)
- * i in constraint: Simple Constraints. (line 68)
- * I in constraint: Simple Constraints. (line 79)
- * identifier: Identifiers. (line 6)
- * IDENTIFIER_LENGTH: Identifiers. (line 22)
- * IDENTIFIER_NODE: Identifiers. (line 6)
- * IDENTIFIER_OPNAME_P: Identifiers. (line 27)
- * IDENTIFIER_POINTER: Identifiers. (line 17)
- * IDENTIFIER_TYPENAME_P: Identifiers. (line 33)
- * IEEE 754-2008: Decimal float library routines.
- (line 6)
- * IFCVT_MACHDEP_INIT: Misc. (line 601)
- * IFCVT_MODIFY_CANCEL: Misc. (line 595)
- * IFCVT_MODIFY_FINAL: Misc. (line 589)
- * IFCVT_MODIFY_INSN: Misc. (line 583)
- * IFCVT_MODIFY_MULTIPLE_TESTS: Misc. (line 575)
- * IFCVT_MODIFY_TESTS: Misc. (line 565)
- * IF_COND: Statements for C++. (line 6)
- * IF_STMT: Statements for C++. (line 6)
- * if_then_else: Comparisons. (line 80)
- * if_then_else and attributes: Expressions. (line 32)
- * if_then_else usage: Side Effects. (line 56)
- * IMAGPART_EXPR: Unary and Binary Expressions.
- (line 6)
- * Immediate Uses: SSA Operands. (line 258)
- * immediate_operand: Machine-Independent Predicates.
- (line 10)
- * IMMEDIATE_PREFIX: Instruction Output. (line 153)
- * include: Including Patterns. (line 6)
- * INCLUDE_DEFAULTS: Driver. (line 331)
- * inclusive-or, bitwise: Arithmetic. (line 163)
- * INCOMING_FRAME_SP_OFFSET: Frame Layout. (line 188)
- * INCOMING_REGNO: Register Basics. (line 129)
- * INCOMING_REG_PARM_STACK_SPACE: Stack Arguments. (line 73)
- * INCOMING_RETURN_ADDR_RTX: Frame Layout. (line 133)
- * INCOMING_STACK_BOUNDARY: Storage Layout. (line 171)
- * INDEX_REG_CLASS: Register Classes. (line 140)
- * indirect_jump instruction pattern: Standard Names. (line 1826)
- * indirect_operand: Machine-Independent Predicates.
- (line 70)
- * INDIRECT_REF: Storage References. (line 6)
- * initialization routines: Initialization. (line 6)
- * INITIAL_ELIMINATION_OFFSET: Elimination. (line 68)
- * INITIAL_FRAME_ADDRESS_RTX: Frame Layout. (line 75)
- * INIT_ARRAY_SECTION_ASM_OP: Sections. (line 106)
- * INIT_CUMULATIVE_ARGS: Register Arguments. (line 158)
- * INIT_CUMULATIVE_INCOMING_ARGS: Register Arguments. (line 186)
- * INIT_CUMULATIVE_LIBCALL_ARGS: Register Arguments. (line 180)
- * INIT_ENVIRONMENT: Driver. (line 309)
- * INIT_EXPANDERS: Per-Function Data. (line 36)
- * INIT_EXPR: Unary and Binary Expressions.
- (line 6)
- * init_machine_status: Per-Function Data. (line 42)
- * init_one_libfunc: Library Calls. (line 15)
- * INIT_SECTION_ASM_OP: Sections. (line 90)
- * INIT_SECTION_ASM_OP <1>: Macros for Initialization.
- (line 9)
- * inlining: Target Attributes. (line 103)
- * insert_insn_on_edge: Maintaining the CFG.
- (line 104)
- * insn: Insns. (line 63)
- * insn and /f: Flags. (line 135)
- * insn and /j: Flags. (line 171)
- * insn and /s: Flags. (line 38)
- * insn and /s <1>: Flags. (line 162)
- * insn and /u: Flags. (line 28)
- * insn and /v: Flags. (line 33)
- * insn attributes: Insn Attributes. (line 6)
- * insn canonicalization: Insn Canonicalizations.
- (line 6)
- * insn includes: Including Patterns. (line 6)
- * insn lengths, computing: Insn Lengths. (line 6)
- * insn notes, notes: Basic Blocks. (line 52)
- * insn splitting: Insn Splitting. (line 6)
- * insn-attr.h: Defining Attributes.
- (line 34)
- * insns: Insns. (line 6)
- * insns, generating: RTL Template. (line 6)
- * insns, recognizing: RTL Template. (line 6)
- * INSN_ANNULLED_BRANCH_P: Flags. (line 28)
- * INSN_CODE: Insns. (line 318)
- * INSN_DELETED_P: Flags. (line 33)
- * INSN_FROM_TARGET_P: Flags. (line 38)
- * insn_list: Insns. (line 568)
- * INSN_REFERENCES_ARE_DELAYED: Misc. (line 502)
- * INSN_SETS_ARE_DELAYED: Misc. (line 491)
- * INSN_UID: Insns. (line 23)
- * INSN_VAR_LOCATION: Insns. (line 247)
- * instruction attributes: Insn Attributes. (line 6)
- * instruction latency time: Processor pipeline description.
- (line 6)
- * instruction latency time <1>: Processor pipeline description.
- (line 105)
- * instruction latency time <2>: Processor pipeline description.
- (line 196)
- * instruction patterns: Patterns. (line 6)
- * instruction splitting: Insn Splitting. (line 6)
- * insv instruction pattern: Standard Names. (line 1562)
- * insvM instruction pattern: Standard Names. (line 1514)
- * insvmisalignM instruction pattern: Standard Names. (line 1524)
- * int iterators in .md files: Int Iterators. (line 6)
- * INT16_TYPE: Type Layout. (line 210)
- * INT32_TYPE: Type Layout. (line 211)
- * INT64_TYPE: Type Layout. (line 212)
- * INT8_TYPE: Type Layout. (line 209)
- * INTEGER_CST: Constant expressions.
- (line 6)
- * INTEGER_TYPE: Types. (line 6)
- * inter-procedural optimization passes: IPA passes. (line 6)
- * Interdependence of Patterns: Dependent Patterns. (line 6)
- * interfacing to GCC output: Interface. (line 6)
- * interlock delays: Processor pipeline description.
- (line 6)
- * intermediate representation lowering: Parsing pass. (line 13)
- * INTMAX_TYPE: Type Layout. (line 186)
- * INTPTR_TYPE: Type Layout. (line 233)
- * introduction: Top. (line 6)
- * INT_FAST16_TYPE: Type Layout. (line 226)
- * INT_FAST32_TYPE: Type Layout. (line 227)
- * INT_FAST64_TYPE: Type Layout. (line 228)
- * INT_FAST8_TYPE: Type Layout. (line 225)
- * INT_LEAST16_TYPE: Type Layout. (line 218)
- * INT_LEAST32_TYPE: Type Layout. (line 219)
- * INT_LEAST64_TYPE: Type Layout. (line 220)
- * INT_LEAST8_TYPE: Type Layout. (line 217)
- * INT_TYPE_SIZE: Type Layout. (line 11)
- * INVOKE__main: Macros for Initialization.
- (line 50)
- * in_struct: Flags. (line 254)
- * in_struct, in code_label and note: Flags. (line 48)
- * in_struct, in insn and jump_insn and call_insn: Flags. (line 38)
- * in_struct, in insn, call_insn, jump_insn and jump_table_data: Flags.
- (line 162)
- * in_struct, in subreg: Flags. (line 201)
- * ior: Arithmetic. (line 163)
- * ior and attributes: Expressions. (line 50)
- * ior, canonicalization of: Insn Canonicalizations.
- (line 67)
- * iorM3 instruction pattern: Standard Names. (line 442)
- * IPA passes: IPA passes. (line 6)
- * IRA_HARD_REGNO_ADD_COST_MULTIPLIER: Allocation Order. (line 44)
- * is_a: Machine Modes. (line 347)
- * IS_ASM_LOGICAL_LINE_SEPARATOR: Data Output. (line 129)
- * is_gimple_addressable: Logical Operators. (line 113)
- * is_gimple_asm_val: Logical Operators. (line 117)
- * is_gimple_assign: Logical Operators. (line 149)
- * is_gimple_call: Logical Operators. (line 152)
- * is_gimple_call_addr: Logical Operators. (line 120)
- * is_gimple_constant: Logical Operators. (line 128)
- * is_gimple_debug: Logical Operators. (line 155)
- * is_gimple_ip_invariant: Logical Operators. (line 137)
- * is_gimple_ip_invariant_address: Logical Operators. (line 142)
- * is_gimple_mem_ref_addr: Logical Operators. (line 124)
- * is_gimple_min_invariant: Logical Operators. (line 131)
- * is_gimple_omp: Logical Operators. (line 166)
- * is_gimple_val: Logical Operators. (line 107)
- * iterators in .md files: Iterators. (line 6)
- * IV analysis on GIMPLE: Scalar evolutions. (line 6)
- * IV analysis on RTL: loop-iv. (line 6)
- * JMP_BUF_SIZE: Exception Region Output.
- (line 83)
- * jump: Flags. (line 295)
- * jump instruction pattern: Standard Names. (line 1704)
- * jump instruction patterns: Jump Patterns. (line 6)
- * jump instructions and set: Side Effects. (line 56)
- * jump, in call_insn: Flags. (line 175)
- * jump, in insn: Flags. (line 171)
- * jump, in mem: Flags. (line 59)
- * Jumps: Jumps. (line 6)
- * JUMP_ALIGN: Alignment Output. (line 8)
- * jump_insn: Insns. (line 73)
- * jump_insn and /f: Flags. (line 135)
- * jump_insn and /j: Flags. (line 10)
- * jump_insn and /s: Flags. (line 38)
- * jump_insn and /s <1>: Flags. (line 162)
- * jump_insn and /u: Flags. (line 28)
- * jump_insn and /v: Flags. (line 33)
- * JUMP_LABEL: Insns. (line 80)
- * JUMP_TABLES_IN_TEXT_SECTION: Sections. (line 155)
- * jump_table_data: Insns. (line 166)
- * jump_table_data and /s: Flags. (line 162)
- * jump_table_data and /v: Flags. (line 33)
- * LABEL_ALIGN: Alignment Output. (line 42)
- * LABEL_ALIGN_AFTER_BARRIER: Alignment Output. (line 21)
- * LABEL_ALTERNATE_NAME: Edges. (line 180)
- * LABEL_ALT_ENTRY_P: Insns. (line 146)
- * LABEL_DECL: Declarations. (line 6)
- * LABEL_KIND: Insns. (line 146)
- * LABEL_NUSES: Insns. (line 142)
- * LABEL_PRESERVE_P: Flags. (line 48)
- * label_ref: Constants. (line 199)
- * label_ref and /v: Flags. (line 54)
- * label_ref, RTL sharing: Sharing. (line 38)
- * LABEL_REF_NONLOCAL_P: Flags. (line 54)
- * language-dependent trees: Language-dependent trees.
- (line 6)
- * language-independent intermediate representation: Parsing pass.
- (line 13)
- * lang_hooks.gimplify_expr: Gimplification pass.
- (line 18)
- * lang_hooks.parse_file: Parsing pass. (line 6)
- * large return values: Aggregate Return. (line 6)
- * LAST_STACK_REG: Stack Registers. (line 30)
- * LAST_VIRTUAL_REGISTER: Regs and Memory. (line 51)
- * late IPA passes: Late IPA passes. (line 6)
- * lceilMN2: Standard Names. (line 1137)
- * LCSSA: LCSSA. (line 6)
- * LDD_SUFFIX: Macros for Initialization.
- (line 121)
- * ldexpM3 instruction pattern: Standard Names. (line 922)
- * LD_FINI_SWITCH: Macros for Initialization.
- (line 28)
- * LD_INIT_SWITCH: Macros for Initialization.
- (line 24)
- * le: Comparisons. (line 76)
- * le and attributes: Expressions. (line 83)
- * leaf functions: Leaf Functions. (line 6)
- * leaf_function_p: Standard Names. (line 1788)
- * LEAF_REGISTERS: Leaf Functions. (line 23)
- * LEAF_REG_REMAP: Leaf Functions. (line 37)
- * left rotate: Arithmetic. (line 195)
- * left shift: Arithmetic. (line 173)
- * LEGITIMATE_PIC_OPERAND_P: PIC. (line 31)
- * LEGITIMIZE_RELOAD_ADDRESS: Addressing Modes. (line 150)
- * length: GTY Options. (line 47)
- * less than: Comparisons. (line 68)
- * less than or equal: Comparisons. (line 76)
- * leu: Comparisons. (line 76)
- * leu and attributes: Expressions. (line 83)
- * LE_EXPR: Unary and Binary Expressions.
- (line 6)
- * lfloorMN2: Standard Names. (line 1132)
- * LIB2FUNCS_EXTRA: Target Fragment. (line 11)
- * LIBCALL_VALUE: Scalar Return. (line 56)
- * libgcc.a: Library Calls. (line 6)
- * LIBGCC2_CFLAGS: Target Fragment. (line 8)
- * LIBGCC2_GNU_PREFIX: Type Layout. (line 102)
- * LIBGCC2_UNWIND_ATTRIBUTE: Misc. (line 1047)
- * LIBGCC_SPEC: Driver. (line 115)
- * library subroutine names: Library Calls. (line 6)
- * LIBRARY_PATH_ENV: Misc. (line 543)
- * LIB_SPEC: Driver. (line 107)
- * LIMIT_RELOAD_CLASS: Register Classes. (line 296)
- * LINK_COMMAND_SPEC: Driver. (line 240)
- * LINK_EH_SPEC: Driver. (line 142)
- * LINK_GCC_C_SEQUENCE_SPEC: Driver. (line 232)
- * LINK_LIBGCC_SPECIAL_1: Driver. (line 227)
- * LINK_SPEC: Driver. (line 100)
- * list: Containers. (line 6)
- * Liveness representation: Liveness information.
- (line 6)
- * load address instruction: Simple Constraints. (line 162)
- * LOAD_EXTEND_OP: Misc. (line 80)
- * load_multiple instruction pattern: Standard Names. (line 136)
- * Local Register Allocator (LRA): RTL passes. (line 187)
- * LOCAL_ALIGNMENT: Storage Layout. (line 284)
- * LOCAL_CLASS_P: Classes. (line 70)
- * LOCAL_DECL_ALIGNMENT: Storage Layout. (line 321)
- * LOCAL_INCLUDE_DIR: Driver. (line 316)
- * LOCAL_LABEL_PREFIX: Instruction Output. (line 151)
- * LOCAL_REGNO: Register Basics. (line 143)
- * location information: Guidelines for Diagnostics.
- (line 159)
- * log10M2 instruction pattern: Standard Names. (line 1026)
- * log1pM2 instruction pattern: Standard Names. (line 1016)
- * log2M2 instruction pattern: Standard Names. (line 1033)
- * logbM2 instruction pattern: Standard Names. (line 1040)
- * Logical Operators: Logical Operators. (line 6)
- * logical-and, bitwise: Arithmetic. (line 158)
- * LOGICAL_OP_NON_SHORT_CIRCUIT: Costs. (line 294)
- * logM2 instruction pattern: Standard Names. (line 1009)
- * LOG_LINKS: Insns. (line 337)
- * longjmp and automatic variables: Interface. (line 52)
- * LONG_ACCUM_TYPE_SIZE: Type Layout. (line 92)
- * LONG_DOUBLE_TYPE_SIZE: Type Layout. (line 57)
- * LONG_FRACT_TYPE_SIZE: Type Layout. (line 72)
- * LONG_LONG_ACCUM_TYPE_SIZE: Type Layout. (line 97)
- * LONG_LONG_FRACT_TYPE_SIZE: Type Layout. (line 77)
- * LONG_LONG_TYPE_SIZE: Type Layout. (line 32)
- * LONG_TYPE_SIZE: Type Layout. (line 21)
- * Loop analysis: Loop representation.
- (line 6)
- * Loop manipulation: Loop manipulation. (line 6)
- * Loop querying: Loop querying. (line 6)
- * Loop representation: Loop representation.
- (line 6)
- * Loop-closed SSA form: LCSSA. (line 6)
- * looping instruction patterns: Looping Patterns. (line 6)
- * LOOP_ALIGN: Alignment Output. (line 29)
- * LOOP_EXPR: Unary and Binary Expressions.
- (line 6)
- * lowering, language-dependent intermediate representation: Parsing pass.
- (line 13)
- * lo_sum: Arithmetic. (line 25)
- * lrintMN2: Standard Names. (line 1122)
- * lroundMN2: Standard Names. (line 1127)
- * lshiftrt: Arithmetic. (line 190)
- * lshiftrt and attributes: Expressions. (line 83)
- * LSHIFT_EXPR: Unary and Binary Expressions.
- (line 6)
- * lshrM3 instruction pattern: Standard Names. (line 840)
- * lt: Comparisons. (line 68)
- * lt and attributes: Expressions. (line 83)
- * LTGT_EXPR: Unary and Binary Expressions.
- (line 6)
- * lto: LTO. (line 6)
- * ltrans: LTO. (line 6)
- * ltu: Comparisons. (line 68)
- * LT_EXPR: Unary and Binary Expressions.
- (line 6)
- * m in constraint: Simple Constraints. (line 17)
- * machine attributes: Target Attributes. (line 6)
- * machine description macros: Target Macros. (line 6)
- * machine descriptions: Machine Desc. (line 6)
- * machine mode conversions: Conversions. (line 6)
- * machine mode wrapper classes: Machine Modes. (line 286)
- * machine modes: Machine Modes. (line 6)
- * machine specific constraints: Machine Constraints.
- (line 6)
- * machine-independent predicates: Machine-Independent Predicates.
- (line 6)
- * machine_mode: Machine Modes. (line 6)
- * MACH_DEP_SECTION_ASM_FLAG: Sections. (line 120)
- * macros, target description: Target Macros. (line 6)
- * maddMN4 instruction pattern: Standard Names. (line 761)
- * makefile fragment: Fragments. (line 6)
- * makefile targets: Makefile. (line 6)
- * MAKE_DECL_ONE_ONLY: Label Output. (line 281)
- * make_safe_from: Expander Definitions.
- (line 151)
- * MALLOC_ABI_ALIGNMENT: Storage Layout. (line 190)
- * Manipulating GIMPLE statements: Manipulating GIMPLE statements.
- (line 6)
- * marking roots: GGC Roots. (line 6)
- * maskloadMN instruction pattern: Standard Names. (line 396)
- * maskstoreMN instruction pattern: Standard Names. (line 403)
- * mask_fold_left_plus_M instruction pattern: Standard Names. (line 564)
- * mask_gather_loadMN instruction pattern: Standard Names. (line 249)
- * MASK_RETURN_ADDR: Exception Region Output.
- (line 35)
- * mask_scatter_storeMN instruction pattern: Standard Names. (line 272)
- * Match and Simplify: Match and Simplify. (line 6)
- * matching constraint: Simple Constraints. (line 140)
- * matching operands: Output Template. (line 49)
- * match_dup: RTL Template. (line 73)
- * match_dup <1>: define_peephole2. (line 28)
- * match_dup and attributes: Insn Lengths. (line 16)
- * match_operand: RTL Template. (line 16)
- * match_operand and attributes: Expressions. (line 55)
- * match_operator: RTL Template. (line 95)
- * match_op_dup: RTL Template. (line 163)
- * match_parallel: RTL Template. (line 172)
- * match_par_dup: RTL Template. (line 219)
- * match_scratch: RTL Template. (line 58)
- * match_scratch <1>: define_peephole2. (line 28)
- * match_test and attributes: Expressions. (line 64)
- * math library: Soft float library routines.
- (line 6)
- * math, in RTL: Arithmetic. (line 6)
- * matherr: Library Calls. (line 59)
- * MATH_LIBRARY: Misc. (line 536)
- * maxM3 instruction pattern: Standard Names. (line 503)
- * MAX_BITSIZE_MODE_ANY_INT: Machine Modes. (line 444)
- * MAX_BITSIZE_MODE_ANY_MODE: Machine Modes. (line 450)
- * MAX_BITS_PER_WORD: Storage Layout. (line 54)
- * MAX_CONDITIONAL_EXECUTE: Misc. (line 558)
- * MAX_FIXED_MODE_SIZE: Storage Layout. (line 466)
- * MAX_MOVE_MAX: Misc. (line 127)
- * MAX_OFILE_ALIGNMENT: Storage Layout. (line 228)
- * MAX_REGS_PER_ADDRESS: Addressing Modes. (line 42)
- * MAX_STACK_ALIGNMENT: Storage Layout. (line 222)
- * maybe_undef: GTY Options. (line 141)
- * may_trap_p, tree_could_trap_p: Edges. (line 114)
- * mcount: Profiling. (line 12)
- * MD_EXEC_PREFIX: Driver. (line 271)
- * MD_FALLBACK_FRAME_STATE_FOR: Exception Handling. (line 93)
- * MD_HANDLE_UNWABI: Exception Handling. (line 112)
- * MD_STARTFILE_PREFIX: Driver. (line 299)
- * MD_STARTFILE_PREFIX_1: Driver. (line 304)
- * mem: Regs and Memory. (line 396)
- * mem and /c: Flags. (line 70)
- * mem and /f: Flags. (line 74)
- * mem and /j: Flags. (line 59)
- * mem and /u: Flags. (line 78)
- * mem and /v: Flags. (line 65)
- * mem, RTL sharing: Sharing. (line 43)
- * memory model: Memory model. (line 6)
- * memory reference, nonoffsettable: Simple Constraints. (line 254)
- * memory references in constraints: Simple Constraints. (line 17)
- * memory_barrier instruction pattern: Standard Names. (line 2172)
- * memory_blockage instruction pattern: Standard Names. (line 2163)
- * MEMORY_MOVE_COST: Costs. (line 53)
- * memory_operand: Machine-Independent Predicates.
- (line 57)
- * MEM_ADDR_SPACE: Special Accessors. (line 48)
- * MEM_ALIAS_SET: Special Accessors. (line 9)
- * MEM_ALIGN: Special Accessors. (line 45)
- * MEM_EXPR: Special Accessors. (line 19)
- * MEM_KEEP_ALIAS_SET_P: Flags. (line 59)
- * MEM_NOTRAP_P: Flags. (line 70)
- * MEM_OFFSET: Special Accessors. (line 31)
- * MEM_OFFSET_KNOWN_P: Special Accessors. (line 27)
- * MEM_POINTER: Flags. (line 74)
- * MEM_READONLY_P: Flags. (line 78)
- * MEM_REF: Storage References. (line 6)
- * MEM_SIZE: Special Accessors. (line 39)
- * MEM_SIZE_KNOWN_P: Special Accessors. (line 35)
- * mem_thread_fence instruction pattern: Standard Names. (line 2462)
- * MEM_VOLATILE_P: Flags. (line 65)
- * METHOD_TYPE: Types. (line 6)
- * MINIMUM_ALIGNMENT: Storage Layout. (line 334)
- * MINIMUM_ATOMIC_ALIGNMENT: Storage Layout. (line 198)
- * minM3 instruction pattern: Standard Names. (line 503)
- * minus: Arithmetic. (line 38)
- * minus and attributes: Expressions. (line 83)
- * minus, canonicalization of: Insn Canonicalizations.
- (line 27)
- * MINUS_EXPR: Unary and Binary Expressions.
- (line 6)
- * MIN_UNITS_PER_WORD: Storage Layout. (line 64)
- * MIPS coprocessor-definition macros: MIPS Coprocessors. (line 6)
- * miscellaneous register hooks: Miscellaneous Register Hooks.
- (line 6)
- * mnemonic attribute: Mnemonic Attribute. (line 6)
- * mod: Arithmetic. (line 136)
- * mod and attributes: Expressions. (line 83)
- * mode classes: Machine Modes. (line 226)
- * mode iterators in .md files: Mode Iterators. (line 6)
- * mode switching: Mode Switching. (line 6)
- * MODE_ACCUM: Machine Modes. (line 256)
- * MODE_BASE_REG_CLASS: Register Classes. (line 116)
- * MODE_BASE_REG_REG_CLASS: Register Classes. (line 122)
- * MODE_CC: Machine Modes. (line 271)
- * MODE_CC <1>: MODE_CC Condition Codes.
- (line 6)
- * MODE_CODE_BASE_REG_CLASS: Register Classes. (line 129)
- * MODE_COMPLEX_FLOAT: Machine Modes. (line 267)
- * MODE_COMPLEX_INT: Machine Modes. (line 264)
- * MODE_DECIMAL_FLOAT: Machine Modes. (line 244)
- * MODE_FLOAT: Machine Modes. (line 240)
- * MODE_FRACT: Machine Modes. (line 248)
- * MODE_INT: Machine Modes. (line 232)
- * MODE_PARTIAL_INT: Machine Modes. (line 236)
- * MODE_POINTER_BOUNDS: Machine Modes. (line 276)
- * MODE_RANDOM: Machine Modes. (line 281)
- * MODE_UACCUM: Machine Modes. (line 260)
- * MODE_UFRACT: Machine Modes. (line 252)
- * modifiers in constraints: Modifiers. (line 6)
- * MODIFY_EXPR: Unary and Binary Expressions.
- (line 6)
- * modM3 instruction pattern: Standard Names. (line 442)
- * modulo scheduling: RTL passes. (line 123)
- * MOVE_MAX: Misc. (line 122)
- * MOVE_MAX_PIECES: Costs. (line 210)
- * MOVE_RATIO: Costs. (line 149)
- * movM instruction pattern: Standard Names. (line 11)
- * movmemM instruction pattern: Standard Names. (line 1281)
- * movmisalignM instruction pattern: Standard Names. (line 125)
- * movMODEcc instruction pattern: Standard Names. (line 1576)
- * movstr instruction pattern: Standard Names. (line 1317)
- * movstrictM instruction pattern: Standard Names. (line 119)
- * msubMN4 instruction pattern: Standard Names. (line 784)
- * mulhisi3 instruction pattern: Standard Names. (line 737)
- * mulM3 instruction pattern: Standard Names. (line 442)
- * mulqihi3 instruction pattern: Standard Names. (line 741)
- * mulsidi3 instruction pattern: Standard Names. (line 741)
- * mult: Arithmetic. (line 93)
- * mult and attributes: Expressions. (line 83)
- * mult, canonicalization of: Insn Canonicalizations.
- (line 27)
- * mult, canonicalization of <1>: Insn Canonicalizations.
- (line 107)
- * MULTIARCH_DIRNAME: Target Fragment. (line 173)
- * MULTILIB_DEFAULTS: Driver. (line 256)
- * MULTILIB_DIRNAMES: Target Fragment. (line 44)
- * MULTILIB_EXCEPTIONS: Target Fragment. (line 70)
- * MULTILIB_EXTRA_OPTS: Target Fragment. (line 135)
- * MULTILIB_MATCHES: Target Fragment. (line 63)
- * MULTILIB_OPTIONS: Target Fragment. (line 24)
- * MULTILIB_OSDIRNAMES: Target Fragment. (line 142)
- * MULTILIB_REQUIRED: Target Fragment. (line 82)
- * MULTILIB_REUSE: Target Fragment. (line 103)
- * multiple alternative constraints: Multi-Alternative. (line 6)
- * MULTIPLE_SYMBOL_SPACES: Misc. (line 515)
- * multiplication: Arithmetic. (line 93)
- * multiplication with signed saturation: Arithmetic. (line 93)
- * multiplication with unsigned saturation: Arithmetic. (line 93)
- * MULT_EXPR: Unary and Binary Expressions.
- (line 6)
- * MULT_HIGHPART_EXPR: Unary and Binary Expressions.
- (line 6)
- * mulvM4 instruction pattern: Standard Names. (line 458)
- * n in constraint: Simple Constraints. (line 73)
- * name: Identifiers. (line 6)
- * named address spaces: Named Address Spaces.
- (line 6)
- * named patterns and conditions: Patterns. (line 61)
- * names, pattern: Standard Names. (line 6)
- * namespace, scope: Namespaces. (line 6)
- * NAMESPACE_DECL: Declarations. (line 6)
- * NAMESPACE_DECL <1>: Namespaces. (line 6)
- * NATIVE_SYSTEM_HEADER_COMPONENT: Driver. (line 326)
- * ne: Comparisons. (line 56)
- * ne and attributes: Expressions. (line 83)
- * nearbyintM2 instruction pattern: Standard Names. (line 1106)
- * neg: Arithmetic. (line 82)
- * neg and attributes: Expressions. (line 83)
- * neg, canonicalization of: Insn Canonicalizations.
- (line 27)
- * NEGATE_EXPR: Unary and Binary Expressions.
- (line 6)
- * negation: Arithmetic. (line 82)
- * negation with signed saturation: Arithmetic. (line 82)
- * negation with unsigned saturation: Arithmetic. (line 82)
- * negM2 instruction pattern: Standard Names. (line 872)
- * negMODEcc instruction pattern: Standard Names. (line 1645)
- * negvM3 instruction pattern: Standard Names. (line 875)
- * nested functions, support for: Trampolines. (line 6)
- * nested_ptr: GTY Options. (line 149)
- * next_bb, prev_bb, FOR_EACH_BB, FOR_ALL_BB: Basic Blocks. (line 25)
- * NEXT_INSN: Insns. (line 30)
- * NEXT_OBJC_RUNTIME: Library Calls. (line 86)
- * NE_EXPR: Unary and Binary Expressions.
- (line 6)
- * nil: RTL Objects. (line 73)
- * NM_FLAGS: Macros for Initialization.
- (line 110)
- * nondeterministic finite state automaton: Processor pipeline description.
- (line 304)
- * nonimmediate_operand: Machine-Independent Predicates.
- (line 100)
- * nonlocal goto handler: Edges. (line 171)
- * nonlocal_goto instruction pattern: Standard Names. (line 1998)
- * nonlocal_goto_receiver instruction pattern: Standard Names.
- (line 2015)
- * nonmemory_operand: Machine-Independent Predicates.
- (line 96)
- * nonoffsettable memory reference: Simple Constraints. (line 254)
- * NON_LVALUE_EXPR: Unary and Binary Expressions.
- (line 6)
- * nop instruction pattern: Standard Names. (line 1821)
- * NOP_EXPR: Unary and Binary Expressions.
- (line 6)
- * normal predicates: Predicates. (line 31)
- * not: Arithmetic. (line 154)
- * not and attributes: Expressions. (line 50)
- * not equal: Comparisons. (line 56)
- * not, canonicalization of: Insn Canonicalizations.
- (line 27)
- * note: Insns. (line 183)
- * note and /i: Flags. (line 48)
- * note and /v: Flags. (line 33)
- * NOTE_INSN_BASIC_BLOCK: Basic Blocks. (line 50)
- * NOTE_INSN_BASIC_BLOCK <1>: Basic Blocks. (line 52)
- * NOTE_INSN_BEGIN_STMT: Insns. (line 233)
- * NOTE_INSN_BLOCK_BEG: Insns. (line 208)
- * NOTE_INSN_BLOCK_END: Insns. (line 208)
- * NOTE_INSN_DELETED: Insns. (line 198)
- * NOTE_INSN_DELETED_LABEL: Insns. (line 203)
- * NOTE_INSN_EH_REGION_BEG: Insns. (line 214)
- * NOTE_INSN_EH_REGION_END: Insns. (line 214)
- * NOTE_INSN_FUNCTION_BEG: Insns. (line 221)
- * NOTE_INSN_INLINE_ENTRY: Insns. (line 238)
- * NOTE_INSN_VAR_LOCATION: Insns. (line 225)
- * NOTE_LINE_NUMBER: Insns. (line 183)
- * NOTE_SOURCE_FILE: Insns. (line 183)
- * NOTE_VAR_LOCATION: Insns. (line 225)
- * NOTICE_UPDATE_CC: CC0 Condition Codes.
- (line 30)
- * notMODEcc instruction pattern: Standard Names. (line 1652)
- * NO_DBX_BNSYM_ENSYM: DBX Hooks. (line 25)
- * NO_DBX_FUNCTION_END: DBX Hooks. (line 19)
- * NO_DBX_GCC_MARKER: File Names and DBX. (line 27)
- * NO_DBX_MAIN_SOURCE_DIRECTORY: File Names and DBX. (line 22)
- * NO_DOLLAR_IN_LABEL: Label Output. (line 64)
- * NO_DOT_IN_LABEL: Label Output. (line 70)
- * NO_FUNCTION_CSE: Costs. (line 289)
- * NO_PROFILE_COUNTERS: Profiling. (line 27)
- * NO_REGS: Register Classes. (line 17)
- * Number of iterations analysis: Number of iterations.
- (line 6)
- * NUM_MACHINE_MODES: Machine Modes. (line 383)
- * NUM_MODES_FOR_MODE_SWITCHING: Mode Switching. (line 30)
- * NUM_POLY_INT_COEFFS: Overview of poly_int.
- (line 24)
- * N_REG_CLASSES: Register Classes. (line 81)
- * o in constraint: Simple Constraints. (line 23)
- * OACC_CACHE: OpenACC. (line 6)
- * OACC_DATA: OpenACC. (line 6)
- * OACC_DECLARE: OpenACC. (line 6)
- * OACC_ENTER_DATA: OpenACC. (line 6)
- * OACC_EXIT_DATA: OpenACC. (line 6)
- * OACC_HOST_DATA: OpenACC. (line 6)
- * OACC_KERNELS: OpenACC. (line 6)
- * OACC_LOOP: OpenACC. (line 6)
- * OACC_PARALLEL: OpenACC. (line 6)
- * OACC_SERIAL: OpenACC. (line 6)
- * OACC_UPDATE: OpenACC. (line 6)
- * OBJC_GEN_METHOD_LABEL: Label Output. (line 482)
- * OBJC_JBLEN: Misc. (line 1042)
- * OBJECT_FORMAT_COFF: Macros for Initialization.
- (line 96)
- * offsettable address: Simple Constraints. (line 23)
- * OFFSET_TYPE: Types. (line 6)
- * OImode: Machine Modes. (line 51)
- * OMP_ATOMIC: OpenMP. (line 6)
- * OMP_CLAUSE: OpenMP. (line 6)
- * OMP_CONTINUE: OpenMP. (line 6)
- * OMP_CRITICAL: OpenMP. (line 6)
- * OMP_FOR: OpenMP. (line 6)
- * OMP_MASTER: OpenMP. (line 6)
- * OMP_ORDERED: OpenMP. (line 6)
- * OMP_PARALLEL: OpenMP. (line 6)
- * OMP_RETURN: OpenMP. (line 6)
- * OMP_SECTION: OpenMP. (line 6)
- * OMP_SECTIONS: OpenMP. (line 6)
- * OMP_SINGLE: OpenMP. (line 6)
- * one_cmplM2 instruction pattern: Standard Names. (line 1241)
- * operand access: Accessors. (line 6)
- * Operand Access Routines: SSA Operands. (line 116)
- * operand constraints: Constraints. (line 6)
- * Operand Iterators: SSA Operands. (line 116)
- * operand predicates: Predicates. (line 6)
- * operand substitution: Output Template. (line 6)
- * Operands: Operands. (line 6)
- * operands: SSA Operands. (line 6)
- * operands <1>: Patterns. (line 67)
- * operator predicates: Predicates. (line 6)
- * optc-gen.awk: Options. (line 6)
- * OPTGROUP_ALL: Optimization groups.
- (line 28)
- * OPTGROUP_INLINE: Optimization groups.
- (line 15)
- * OPTGROUP_IPA: Optimization groups.
- (line 9)
- * OPTGROUP_LOOP: Optimization groups.
- (line 12)
- * OPTGROUP_OMP: Optimization groups.
- (line 18)
- * OPTGROUP_OTHER: Optimization groups.
- (line 24)
- * OPTGROUP_VEC: Optimization groups.
- (line 21)
- * optimization dumps: Optimization info. (line 6)
- * optimization groups: Optimization groups.
- (line 6)
- * optimization info file names: Dump files and streams.
- (line 6)
- * Optimization infrastructure for GIMPLE: Tree SSA. (line 6)
- * OPTIMIZE_MODE_SWITCHING: Mode Switching. (line 8)
- * option specification files: Options. (line 6)
- * optional hardware or system features: Run-time Target. (line 59)
- * options, directory search: Including Patterns. (line 47)
- * options, guidelines for: Guidelines for Options.
- (line 6)
- * OPTION_DEFAULT_SPECS: Driver. (line 25)
- * opt_mode: Machine Modes. (line 322)
- * order of register allocation: Allocation Order. (line 6)
- * ordered_comparison_operator: Machine-Independent Predicates.
- (line 115)
- * ORDERED_EXPR: Unary and Binary Expressions.
- (line 6)
- * Ordering of Patterns: Pattern Ordering. (line 6)
- * ORIGINAL_REGNO: Special Accessors. (line 53)
- * other register constraints: Simple Constraints. (line 171)
- * outgoing_args_size: Stack Arguments. (line 48)
- * OUTGOING_REGNO: Register Basics. (line 136)
- * OUTGOING_REG_PARM_STACK_SPACE: Stack Arguments. (line 79)
- * output of assembler code: File Framework. (line 6)
- * output statements: Output Statement. (line 6)
- * output templates: Output Template. (line 6)
- * output_asm_insn: Output Statement. (line 52)
- * OUTPUT_QUOTED_STRING: File Framework. (line 105)
- * OVERLAPPING_REGISTER_NAMES: Instruction Output. (line 20)
- * OVERLOAD: Functions for C++. (line 6)
- * OVERRIDE_ABI_FORMAT: Register Arguments. (line 150)
- * OVL_CURRENT: Functions for C++. (line 6)
- * OVL_NEXT: Functions for C++. (line 6)
- * p in constraint: Simple Constraints. (line 162)
- * PAD_VARARGS_DOWN: Register Arguments. (line 230)
- * parallel: Side Effects. (line 210)
- * parameters, c++ abi: C++ ABI. (line 6)
- * parameters, d abi: D Language and ABI. (line 6)
- * parameters, miscellaneous: Misc. (line 6)
- * parameters, precompiled headers: PCH Target. (line 6)
- * parity: Arithmetic. (line 242)
- * parityM2 instruction pattern: Standard Names. (line 1228)
- * PARM_BOUNDARY: Storage Layout. (line 150)
- * PARM_DECL: Declarations. (line 6)
- * PARSE_LDD_OUTPUT: Macros for Initialization.
- (line 125)
- * pass dumps: Passes. (line 6)
- * passes and files of the compiler: Passes. (line 6)
- * passing arguments: Interface. (line 36)
- * pass_duplicate_computed_gotos: Edges. (line 161)
- * PATH_SEPARATOR: Filesystem. (line 31)
- * PATTERN: Insns. (line 307)
- * pattern conditions: Patterns. (line 55)
- * pattern names: Standard Names. (line 6)
- * Pattern Ordering: Pattern Ordering. (line 6)
- * patterns: Patterns. (line 6)
- * pc: Regs and Memory. (line 383)
- * pc and attributes: Insn Lengths. (line 20)
- * pc, RTL sharing: Sharing. (line 28)
- * PCC_BITFIELD_TYPE_MATTERS: Storage Layout. (line 360)
- * PCC_STATIC_STRUCT_RETURN: Aggregate Return. (line 64)
- * PC_REGNUM: Register Basics. (line 150)
- * pc_rtx: Regs and Memory. (line 388)
- * PDImode: Machine Modes. (line 40)
- * peephole optimization, RTL representation: Side Effects. (line 244)
- * peephole optimizer definitions: Peephole Definitions.
- (line 6)
- * per-function data: Per-Function Data. (line 6)
- * percent sign: Output Template. (line 6)
- * PHI nodes: SSA. (line 31)
- * PIC: PIC. (line 6)
- * PIC_OFFSET_TABLE_REGNUM: PIC. (line 15)
- * PIC_OFFSET_TABLE_REG_CALL_CLOBBERED: PIC. (line 25)
- * pipeline hazard recognizer: Processor pipeline description.
- (line 6)
- * pipeline hazard recognizer <1>: Processor pipeline description.
- (line 53)
- * Plugins: Plugins. (line 6)
- * plus: Arithmetic. (line 14)
- * plus and attributes: Expressions. (line 83)
- * plus, canonicalization of: Insn Canonicalizations.
- (line 27)
- * PLUS_EXPR: Unary and Binary Expressions.
- (line 6)
- * Pmode: Misc. (line 363)
- * pmode_register_operand: Machine-Independent Predicates.
- (line 34)
- * pointer: Types. (line 6)
- * POINTERS_EXTEND_UNSIGNED: Storage Layout. (line 76)
- * POINTER_DIFF_EXPR: Unary and Binary Expressions.
- (line 6)
- * POINTER_PLUS_EXPR: Unary and Binary Expressions.
- (line 6)
- * POINTER_SIZE: Storage Layout. (line 70)
- * POINTER_TYPE: Types. (line 6)
- * polynomial integers: poly_int. (line 6)
- * poly_int: poly_int. (line 6)
- * poly_int, invariant range: Overview of poly_int.
- (line 31)
- * poly_int, main typedefs: Overview of poly_int.
- (line 46)
- * poly_int, runtime value: Overview of poly_int.
- (line 6)
- * poly_int, template parameters: Overview of poly_int.
- (line 24)
- * poly_int, use in target-independent code: Consequences of using poly_int.
- (line 32)
- * poly_int, use in target-specific code: Consequences of using poly_int.
- (line 40)
- * POLY_INT_CST: Constant expressions.
- (line 6)
- * popcount: Arithmetic. (line 238)
- * popcountM2 instruction pattern: Standard Names. (line 1216)
- * pops_args: Function Entry. (line 111)
- * pop_operand: Machine-Independent Predicates.
- (line 87)
- * portability: Portability. (line 6)
- * position independent code: PIC. (line 6)
- * POSTDECREMENT_EXPR: Unary and Binary Expressions.
- (line 6)
- * POSTINCREMENT_EXPR: Unary and Binary Expressions.
- (line 6)
- * post_dec: Incdec. (line 25)
- * post_inc: Incdec. (line 30)
- * POST_LINK_SPEC: Driver. (line 236)
- * post_modify: Incdec. (line 33)
- * post_order_compute, inverted_post_order_compute, walk_dominator_tree: Basic Blocks.
- (line 34)
- * POWI_MAX_MULTS: Misc. (line 927)
- * powM3 instruction pattern: Standard Names. (line 1054)
- * pragma: Misc. (line 420)
- * PREDECREMENT_EXPR: Unary and Binary Expressions.
- (line 6)
- * predefined macros: Run-time Target. (line 6)
- * predicates: Predicates. (line 6)
- * predicates and machine modes: Predicates. (line 31)
- * predication: Conditional Execution.
- (line 6)
- * predict.def: Profile information.
- (line 24)
- * PREFERRED_DEBUGGING_TYPE: All Debuggers. (line 40)
- * PREFERRED_RELOAD_CLASS: Register Classes. (line 249)
- * PREFERRED_STACK_BOUNDARY: Storage Layout. (line 164)
- * prefetch: Side Effects. (line 324)
- * prefetch and /v: Flags. (line 92)
- * prefetch instruction pattern: Standard Names. (line 2140)
- * PREFETCH_SCHEDULE_BARRIER_P: Flags. (line 92)
- * PREINCREMENT_EXPR: Unary and Binary Expressions.
- (line 6)
- * presence_set: Processor pipeline description.
- (line 223)
- * preserving SSA form: SSA. (line 74)
- * pretend_args_size: Function Entry. (line 117)
- * prev_active_insn: define_peephole. (line 60)
- * PREV_INSN: Insns. (line 26)
- * pre_dec: Incdec. (line 8)
- * PRE_GCC3_DWARF_FRAME_REGISTERS: Frame Registers. (line 126)
- * pre_inc: Incdec. (line 22)
- * pre_modify: Incdec. (line 52)
- * PRINT_OPERAND: Instruction Output. (line 95)
- * PRINT_OPERAND_ADDRESS: Instruction Output. (line 122)
- * PRINT_OPERAND_PUNCT_VALID_P: Instruction Output. (line 115)
- * probe_stack instruction pattern: Standard Names. (line 1990)
- * probe_stack_address instruction pattern: Standard Names. (line 1983)
- * processor functional units: Processor pipeline description.
- (line 6)
- * processor functional units <1>: Processor pipeline description.
- (line 68)
- * processor pipeline description: Processor pipeline description.
- (line 6)
- * product: Arithmetic. (line 93)
- * profile feedback: Profile information.
- (line 14)
- * profile representation: Profile information.
- (line 6)
- * PROFILE_BEFORE_PROLOGUE: Profiling. (line 34)
- * PROFILE_HOOK: Profiling. (line 22)
- * profiling, code generation: Profiling. (line 6)
- * program counter: Regs and Memory. (line 384)
- * prologue: Function Entry. (line 6)
- * prologue instruction pattern: Standard Names. (line 2079)
- * PROMOTE_MODE: Storage Layout. (line 87)
- * pseudo registers: Regs and Memory. (line 9)
- * PSImode: Machine Modes. (line 32)
- * PTRDIFF_TYPE: Type Layout. (line 157)
- * purge_dead_edges: Edges. (line 103)
- * purge_dead_edges <1>: Maintaining the CFG.
- (line 81)
- * push address instruction: Simple Constraints. (line 162)
- * pushM1 instruction pattern: Standard Names. (line 429)
- * PUSH_ARGS: Stack Arguments. (line 17)
- * PUSH_ARGS_REVERSED: Stack Arguments. (line 25)
- * push_operand: Machine-Independent Predicates.
- (line 80)
- * push_reload: Addressing Modes. (line 176)
- * PUSH_ROUNDING: Stack Arguments. (line 31)
- * PUT_CODE: RTL Objects. (line 47)
- * PUT_MODE: Machine Modes. (line 380)
- * PUT_REG_NOTE_KIND: Insns. (line 369)
- * QCmode: Machine Modes. (line 199)
- * QFmode: Machine Modes. (line 57)
- * QImode: Machine Modes. (line 25)
- * QImode, in insn: Insns. (line 291)
- * QQmode: Machine Modes. (line 106)
- * qualified type: Types. (line 6)
- * qualified type <1>: Types for C++. (line 6)
- * querying function unit reservations: Processor pipeline description.
- (line 90)
- * question mark: Multi-Alternative. (line 42)
- * quotient: Arithmetic. (line 116)
- * r in constraint: Simple Constraints. (line 64)
- * RDIV_EXPR: Unary and Binary Expressions.
- (line 6)
- * READONLY_DATA_SECTION_ASM_OP: Sections. (line 62)
- * real operands: SSA Operands. (line 6)
- * REALPART_EXPR: Unary and Binary Expressions.
- (line 6)
- * REAL_CST: Constant expressions.
- (line 6)
- * REAL_LIBGCC_SPEC: Driver. (line 124)
- * REAL_NM_FILE_NAME: Macros for Initialization.
- (line 105)
- * REAL_TYPE: Types. (line 6)
- * REAL_VALUE_ABS: Floating Point. (line 58)
- * REAL_VALUE_ATOF: Floating Point. (line 39)
- * REAL_VALUE_FIX: Floating Point. (line 31)
- * REAL_VALUE_ISINF: Floating Point. (line 49)
- * REAL_VALUE_ISNAN: Floating Point. (line 52)
- * REAL_VALUE_NEGATE: Floating Point. (line 55)
- * REAL_VALUE_NEGATIVE: Floating Point. (line 46)
- * REAL_VALUE_TO_TARGET_DECIMAL128: Data Output. (line 153)
- * REAL_VALUE_TO_TARGET_DECIMAL32: Data Output. (line 151)
- * REAL_VALUE_TO_TARGET_DECIMAL64: Data Output. (line 152)
- * REAL_VALUE_TO_TARGET_DOUBLE: Data Output. (line 149)
- * REAL_VALUE_TO_TARGET_LONG_DOUBLE: Data Output. (line 150)
- * REAL_VALUE_TO_TARGET_SINGLE: Data Output. (line 148)
- * REAL_VALUE_TYPE: Floating Point. (line 25)
- * REAL_VALUE_UNSIGNED_FIX: Floating Point. (line 34)
- * recognizing insns: RTL Template. (line 6)
- * recog_data.operand: Instruction Output. (line 54)
- * RECORD_TYPE: Types. (line 6)
- * RECORD_TYPE <1>: Classes. (line 6)
- * redirect_edge_and_branch: Profile information.
- (line 71)
- * redirect_edge_and_branch, redirect_jump: Maintaining the CFG.
- (line 89)
- * reduc_and_scal_M instruction pattern: Standard Names. (line 535)
- * reduc_ior_scal_M instruction pattern: Standard Names. (line 536)
- * reduc_plus_scal_M instruction pattern: Standard Names. (line 530)
- * reduc_smax_scal_M instruction pattern: Standard Names. (line 520)
- * reduc_smin_scal_M instruction pattern: Standard Names. (line 520)
- * reduc_umax_scal_M instruction pattern: Standard Names. (line 525)
- * reduc_umin_scal_M instruction pattern: Standard Names. (line 525)
- * reduc_xor_scal_M instruction pattern: Standard Names. (line 537)
- * reference: Types. (line 6)
- * REFERENCE_TYPE: Types. (line 6)
- * reg: Regs and Memory. (line 9)
- * reg and /f: Flags. (line 102)
- * reg and /i: Flags. (line 97)
- * reg and /v: Flags. (line 106)
- * reg, RTL sharing: Sharing. (line 17)
- * register allocation order: Allocation Order. (line 6)
- * register class definitions: Register Classes. (line 6)
- * register class preference constraints: Class Preferences. (line 6)
- * register pairs: Values in Registers.
- (line 65)
- * Register Transfer Language (RTL): RTL. (line 6)
- * register usage: Registers. (line 6)
- * registers arguments: Register Arguments. (line 6)
- * registers in constraints: Simple Constraints. (line 64)
- * REGISTER_MOVE_COST: Costs. (line 9)
- * REGISTER_NAMES: Instruction Output. (line 8)
- * register_operand: Machine-Independent Predicates.
- (line 29)
- * REGISTER_PREFIX: Instruction Output. (line 150)
- * REGISTER_TARGET_PRAGMAS: Misc. (line 420)
- * REGMODE_NATURAL_SIZE: Regs and Memory. (line 191)
- * REGMODE_NATURAL_SIZE <1>: Regs and Memory. (line 268)
- * REGMODE_NATURAL_SIZE <2>: Values in Registers.
- (line 46)
- * REGNO_MODE_CODE_OK_FOR_BASE_P: Register Classes. (line 172)
- * REGNO_MODE_OK_FOR_BASE_P: Register Classes. (line 150)
- * REGNO_MODE_OK_FOR_REG_BASE_P: Register Classes. (line 160)
- * REGNO_OK_FOR_BASE_P: Register Classes. (line 146)
- * REGNO_OK_FOR_INDEX_P: Register Classes. (line 186)
- * REGNO_REG_CLASS: Register Classes. (line 105)
- * regs_ever_live: Function Entry. (line 29)
- * regular expressions: Processor pipeline description.
- (line 6)
- * regular expressions <1>: Processor pipeline description.
- (line 105)
- * regular IPA passes: Regular IPA passes. (line 6)
- * REG_ALLOC_ORDER: Allocation Order. (line 8)
- * REG_BR_PRED: Insns. (line 541)
- * REG_BR_PROB: Insns. (line 533)
- * REG_BR_PROB_BASE, BB_FREQ_BASE, count: Profile information.
- (line 82)
- * REG_BR_PROB_BASE, EDGE_FREQUENCY: Profile information.
- (line 52)
- * REG_CALL_NOCF_CHECK: Insns. (line 557)
- * REG_CC_SETTER: Insns. (line 505)
- * REG_CC_USER: Insns. (line 505)
- * reg_class_contents: Register Basics. (line 102)
- * REG_CLASS_CONTENTS: Register Classes. (line 91)
- * reg_class_for_constraint: C Constraint Interface.
- (line 48)
- * REG_CLASS_NAMES: Register Classes. (line 86)
- * REG_DEAD: Insns. (line 380)
- * REG_DEAD, REG_UNUSED: Liveness information.
- (line 32)
- * REG_DEP_ANTI: Insns. (line 527)
- * REG_DEP_OUTPUT: Insns. (line 523)
- * REG_DEP_TRUE: Insns. (line 520)
- * REG_EH_REGION, EDGE_ABNORMAL_CALL: Edges. (line 109)
- * REG_EQUAL: Insns. (line 434)
- * REG_EQUIV: Insns. (line 434)
- * REG_EXPR: Special Accessors. (line 58)
- * REG_FRAME_RELATED_EXPR: Insns. (line 547)
- * REG_FUNCTION_VALUE_P: Flags. (line 97)
- * REG_INC: Insns. (line 396)
- * reg_label and /v: Flags. (line 54)
- * REG_LABEL_OPERAND: Insns. (line 410)
- * REG_LABEL_TARGET: Insns. (line 419)
- * reg_names: Register Basics. (line 102)
- * reg_names <1>: Instruction Output. (line 107)
- * REG_NONNEG: Insns. (line 402)
- * REG_NOTES: Insns. (line 344)
- * REG_NOTE_KIND: Insns. (line 369)
- * REG_OFFSET: Special Accessors. (line 62)
- * REG_OK_STRICT: Addressing Modes. (line 99)
- * REG_PARM_STACK_SPACE: Stack Arguments. (line 58)
- * REG_PARM_STACK_SPACE, and TARGET_FUNCTION_ARG: Register Arguments.
- (line 49)
- * REG_POINTER: Flags. (line 102)
- * REG_SETJMP: Insns. (line 428)
- * REG_UNUSED: Insns. (line 389)
- * REG_USERVAR_P: Flags. (line 106)
- * REG_VALUE_IN_UNWIND_CONTEXT: Frame Registers. (line 156)
- * REG_WORDS_BIG_ENDIAN: Storage Layout. (line 35)
- * relative costs: Costs. (line 6)
- * RELATIVE_PREFIX_NOT_LINKDIR: Driver. (line 266)
- * reloading: RTL passes. (line 170)
- * reload_completed: Standard Names. (line 1788)
- * reload_in instruction pattern: Standard Names. (line 98)
- * reload_in_progress: Standard Names. (line 57)
- * reload_out instruction pattern: Standard Names. (line 98)
- * remainder: Arithmetic. (line 136)
- * remainderM3 instruction pattern: Standard Names. (line 908)
- * reorder: GTY Options. (line 175)
- * representation of RTL: RTL. (line 6)
- * reservation delays: Processor pipeline description.
- (line 6)
- * restore_stack_block instruction pattern: Standard Names. (line 1904)
- * restore_stack_function instruction pattern: Standard Names.
- (line 1904)
- * restore_stack_nonlocal instruction pattern: Standard Names.
- (line 1904)
- * rest_of_decl_compilation: Parsing pass. (line 51)
- * rest_of_type_compilation: Parsing pass. (line 51)
- * RESULT_DECL: Declarations. (line 6)
- * return: Side Effects. (line 72)
- * return instruction pattern: Standard Names. (line 1762)
- * return values in registers: Scalar Return. (line 6)
- * returning aggregate values: Aggregate Return. (line 6)
- * returning structures and unions: Interface. (line 10)
- * RETURN_ADDRESS_POINTER_REGNUM: Frame Registers. (line 64)
- * RETURN_ADDR_IN_PREVIOUS_FRAME: Frame Layout. (line 127)
- * RETURN_ADDR_OFFSET: Exception Handling. (line 59)
- * RETURN_ADDR_RTX: Frame Layout. (line 116)
- * RETURN_EXPR: Statements for C++. (line 6)
- * RETURN_STMT: Statements for C++. (line 6)
- * return_val: Flags. (line 283)
- * return_val, in call_insn: Flags. (line 120)
- * return_val, in reg: Flags. (line 97)
- * return_val, in symbol_ref: Flags. (line 216)
- * reverse probability: Profile information.
- (line 66)
- * REVERSE_CONDITION: MODE_CC Condition Codes.
- (line 92)
- * REVERSIBLE_CC_MODE: MODE_CC Condition Codes.
- (line 77)
- * right rotate: Arithmetic. (line 195)
- * right shift: Arithmetic. (line 190)
- * rintM2 instruction pattern: Standard Names. (line 1114)
- * RISC: Processor pipeline description.
- (line 6)
- * RISC <1>: Processor pipeline description.
- (line 223)
- * roots, marking: GGC Roots. (line 6)
- * rotate: Arithmetic. (line 195)
- * rotate <1>: Arithmetic. (line 195)
- * rotatert: Arithmetic. (line 195)
- * rotlM3 instruction pattern: Standard Names. (line 840)
- * rotrM3 instruction pattern: Standard Names. (line 840)
- * roundM2 instruction pattern: Standard Names. (line 1087)
- * ROUND_DIV_EXPR: Unary and Binary Expressions.
- (line 6)
- * ROUND_MOD_EXPR: Unary and Binary Expressions.
- (line 6)
- * ROUND_TYPE_ALIGN: Storage Layout. (line 457)
- * RSHIFT_EXPR: Unary and Binary Expressions.
- (line 6)
- * rsqrtM2 instruction pattern: Standard Names. (line 888)
- * RTL addition: Arithmetic. (line 14)
- * RTL addition with signed saturation: Arithmetic. (line 14)
- * RTL addition with unsigned saturation: Arithmetic. (line 14)
- * RTL classes: RTL Classes. (line 6)
- * RTL comparison: Arithmetic. (line 46)
- * RTL comparison operations: Comparisons. (line 6)
- * RTL constant expression types: Constants. (line 6)
- * RTL constants: Constants. (line 6)
- * RTL declarations: RTL Declarations. (line 6)
- * RTL difference: Arithmetic. (line 38)
- * RTL expression: RTL Objects. (line 6)
- * RTL expressions for arithmetic: Arithmetic. (line 6)
- * RTL format: RTL Classes. (line 73)
- * RTL format characters: RTL Classes. (line 78)
- * RTL function-call insns: Calls. (line 6)
- * RTL insn template: RTL Template. (line 6)
- * RTL integers: RTL Objects. (line 6)
- * RTL memory expressions: Regs and Memory. (line 6)
- * RTL object types: RTL Objects. (line 6)
- * RTL postdecrement: Incdec. (line 6)
- * RTL postincrement: Incdec. (line 6)
- * RTL predecrement: Incdec. (line 6)
- * RTL preincrement: Incdec. (line 6)
- * RTL register expressions: Regs and Memory. (line 6)
- * RTL representation: RTL. (line 6)
- * RTL side effect expressions: Side Effects. (line 6)
- * RTL strings: RTL Objects. (line 6)
- * RTL structure sharing assumptions: Sharing. (line 6)
- * RTL subtraction: Arithmetic. (line 38)
- * RTL subtraction with signed saturation: Arithmetic. (line 38)
- * RTL subtraction with unsigned saturation: Arithmetic. (line 38)
- * RTL sum: Arithmetic. (line 14)
- * RTL vectors: RTL Objects. (line 6)
- * RTL_CONST_CALL_P: Flags. (line 115)
- * RTL_CONST_OR_PURE_CALL_P: Flags. (line 125)
- * RTL_LOOPING_CONST_OR_PURE_CALL_P: Flags. (line 129)
- * RTL_PURE_CALL_P: Flags. (line 120)
- * RTX (See RTL): RTL Objects. (line 6)
- * RTX codes, classes of: RTL Classes. (line 6)
- * RTX_FRAME_RELATED_P: Flags. (line 135)
- * run-time conventions: Interface. (line 6)
- * run-time target specification: Run-time Target. (line 6)
- * s in constraint: Simple Constraints. (line 100)
- * SAD_EXPR: Vectors. (line 6)
- * same_type_p: Types. (line 86)
- * SAmode: Machine Modes. (line 150)
- * satfractMN2 instruction pattern: Standard Names. (line 1464)
- * satfractunsMN2 instruction pattern: Standard Names. (line 1477)
- * satisfies_constraint_M: C Constraint Interface.
- (line 36)
- * sat_fract: Conversions. (line 90)
- * SAVE_EXPR: Unary and Binary Expressions.
- (line 6)
- * save_stack_block instruction pattern: Standard Names. (line 1904)
- * save_stack_function instruction pattern: Standard Names. (line 1904)
- * save_stack_nonlocal instruction pattern: Standard Names. (line 1904)
- * SBSS_SECTION_ASM_OP: Sections. (line 75)
- * Scalar evolutions: Scalar evolutions. (line 6)
- * scalars, returned as values: Scalar Return. (line 6)
- * scalar_float_mode: Machine Modes. (line 293)
- * scalar_int_mode: Machine Modes. (line 290)
- * scalar_mode: Machine Modes. (line 296)
- * scalbM3 instruction pattern: Standard Names. (line 915)
- * scatter_storeMN instruction pattern: Standard Names. (line 255)
- * SCHED_GROUP_P: Flags. (line 162)
- * SCmode: Machine Modes. (line 199)
- * scratch: Regs and Memory. (line 320)
- * scratch operands: Regs and Memory. (line 320)
- * scratch, RTL sharing: Sharing. (line 38)
- * scratch_operand: Machine-Independent Predicates.
- (line 49)
- * SDATA_SECTION_ASM_OP: Sections. (line 57)
- * sdiv_pow2M3 instruction pattern: Standard Names. (line 614)
- * sdiv_pow2M3 instruction pattern <1>: Standard Names. (line 615)
- * SDmode: Machine Modes. (line 88)
- * sdot_prodM instruction pattern: Standard Names. (line 569)
- * search options: Including Patterns. (line 47)
- * SECONDARY_INPUT_RELOAD_CLASS: Register Classes. (line 391)
- * SECONDARY_MEMORY_NEEDED_RTX: Register Classes. (line 457)
- * SECONDARY_OUTPUT_RELOAD_CLASS: Register Classes. (line 392)
- * SECONDARY_RELOAD_CLASS: Register Classes. (line 390)
- * SELECT_CC_MODE: MODE_CC Condition Codes.
- (line 6)
- * sequence: Side Effects. (line 259)
- * Sequence iterators: Sequence iterators. (line 6)
- * set: Side Effects. (line 15)
- * set and /f: Flags. (line 135)
- * setmemM instruction pattern: Standard Names. (line 1328)
- * SETUP_FRAME_ADDRESSES: Frame Layout. (line 94)
- * SET_ASM_OP: Label Output. (line 451)
- * SET_ASM_OP <1>: Label Output. (line 462)
- * set_attr: Tagging Insns. (line 31)
- * set_attr_alternative: Tagging Insns. (line 49)
- * set_bb_seq: GIMPLE sequences. (line 75)
- * SET_DEST: Side Effects. (line 69)
- * SET_IS_RETURN_P: Flags. (line 171)
- * SET_LABEL_KIND: Insns. (line 146)
- * set_optab_libfunc: Library Calls. (line 15)
- * SET_RATIO: Costs. (line 237)
- * SET_SRC: Side Effects. (line 69)
- * set_thread_pointerMODE instruction pattern: Standard Names.
- (line 2477)
- * SET_TYPE_STRUCTURAL_EQUALITY: Types. (line 6)
- * SET_TYPE_STRUCTURAL_EQUALITY <1>: Types. (line 81)
- * SFmode: Machine Modes. (line 69)
- * sharing of RTL components: Sharing. (line 6)
- * shift: Arithmetic. (line 173)
- * SHIFT_COUNT_TRUNCATED: Misc. (line 134)
- * SHLIB_SUFFIX: Macros for Initialization.
- (line 133)
- * SHORT_ACCUM_TYPE_SIZE: Type Layout. (line 82)
- * SHORT_FRACT_TYPE_SIZE: Type Layout. (line 62)
- * SHORT_IMMEDIATES_SIGN_EXTEND: Misc. (line 108)
- * SHORT_TYPE_SIZE: Type Layout. (line 15)
- * shrink-wrapping separate components: Shrink-wrapping separate components.
- (line 6)
- * sibcall_epilogue instruction pattern: Standard Names. (line 2111)
- * sibling call: Edges. (line 121)
- * SIBLING_CALL_P: Flags. (line 175)
- * signal-to-noise ratio (metaphorical usage for diagnostics): Guidelines for Diagnostics.
- (line 39)
- * signed division: Arithmetic. (line 116)
- * signed division with signed saturation: Arithmetic. (line 116)
- * signed maximum: Arithmetic. (line 141)
- * signed minimum: Arithmetic. (line 141)
- * significandM2 instruction pattern: Standard Names. (line 1047)
- * sign_extend: Conversions. (line 23)
- * sign_extract: Bit-Fields. (line 8)
- * sign_extract, canonicalization of: Insn Canonicalizations.
- (line 103)
- * SIG_ATOMIC_TYPE: Type Layout. (line 208)
- * SImode: Machine Modes. (line 37)
- * simple constraints: Simple Constraints. (line 6)
- * simple_return: Side Effects. (line 86)
- * simple_return instruction pattern: Standard Names. (line 1777)
- * sincosM3 instruction pattern: Standard Names. (line 943)
- * sinM2 instruction pattern: Standard Names. (line 937)
- * SIZETYPE: Type Layout. (line 147)
- * SIZE_ASM_OP: Label Output. (line 33)
- * SIZE_TYPE: Type Layout. (line 131)
- * skip: GTY Options. (line 76)
- * SLOW_BYTE_ACCESS: Costs. (line 117)
- * small IPA passes: Small IPA passes. (line 6)
- * smax: Arithmetic. (line 141)
- * smin: Arithmetic. (line 141)
- * sms, swing, software pipelining: RTL passes. (line 123)
- * smulhrsM3 instruction pattern: Standard Names. (line 604)
- * smulhsM3 instruction pattern: Standard Names. (line 594)
- * smulM3_highpart instruction pattern: Standard Names. (line 753)
- * soft float library: Soft float library routines.
- (line 6)
- * source code, location information: Guidelines for Diagnostics.
- (line 159)
- * special: GTY Options. (line 238)
- * special predicates: Predicates. (line 31)
- * SPECS: Target Fragment. (line 194)
- * speculation_barrier instruction pattern: Standard Names. (line 2178)
- * speed of instructions: Costs. (line 6)
- * splitting instructions: Insn Splitting. (line 6)
- * split_block: Maintaining the CFG.
- (line 96)
- * SQmode: Machine Modes. (line 114)
- * sqrt: Arithmetic. (line 206)
- * sqrtM2 instruction pattern: Standard Names. (line 882)
- * square root: Arithmetic. (line 206)
- * SSA: SSA. (line 6)
- * ssaddM3 instruction pattern: Standard Names. (line 442)
- * ssadM instruction pattern: Standard Names. (line 578)
- * ssashlM3 instruction pattern: Standard Names. (line 828)
- * SSA_NAME_DEF_STMT: SSA. (line 184)
- * SSA_NAME_VERSION: SSA. (line 189)
- * ssdivM3 instruction pattern: Standard Names. (line 442)
- * ssmaddMN4 instruction pattern: Standard Names. (line 776)
- * ssmsubMN4 instruction pattern: Standard Names. (line 800)
- * ssmulM3 instruction pattern: Standard Names. (line 442)
- * ssnegM2 instruction pattern: Standard Names. (line 872)
- * sssubM3 instruction pattern: Standard Names. (line 442)
- * ss_abs: Arithmetic. (line 200)
- * ss_ashift: Arithmetic. (line 173)
- * ss_div: Arithmetic. (line 116)
- * ss_minus: Arithmetic. (line 38)
- * ss_mult: Arithmetic. (line 93)
- * ss_neg: Arithmetic. (line 82)
- * ss_plus: Arithmetic. (line 14)
- * ss_truncate: Conversions. (line 43)
- * stack arguments: Stack Arguments. (line 6)
- * stack frame layout: Frame Layout. (line 6)
- * stack smashing protection: Stack Smashing Protection.
- (line 6)
- * STACK_ALIGNMENT_NEEDED: Frame Layout. (line 41)
- * STACK_BOUNDARY: Storage Layout. (line 156)
- * STACK_CHECK_BUILTIN: Stack Checking. (line 31)
- * STACK_CHECK_FIXED_FRAME_SIZE: Stack Checking. (line 83)
- * STACK_CHECK_MAX_FRAME_SIZE: Stack Checking. (line 74)
- * STACK_CHECK_MAX_VAR_SIZE: Stack Checking. (line 90)
- * STACK_CHECK_MOVING_SP: Stack Checking. (line 53)
- * STACK_CHECK_PROBE_INTERVAL_EXP: Stack Checking. (line 45)
- * STACK_CHECK_PROTECT: Stack Checking. (line 62)
- * STACK_CHECK_STATIC_BUILTIN: Stack Checking. (line 38)
- * STACK_DYNAMIC_OFFSET: Frame Layout. (line 67)
- * STACK_DYNAMIC_OFFSET and virtual registers: Regs and Memory.
- (line 83)
- * STACK_GROWS_DOWNWARD: Frame Layout. (line 8)
- * STACK_PARMS_IN_REG_PARM_AREA: Stack Arguments. (line 89)
- * STACK_POINTER_OFFSET: Frame Layout. (line 51)
- * STACK_POINTER_OFFSET and virtual registers: Regs and Memory.
- (line 93)
- * STACK_POINTER_REGNUM: Frame Registers. (line 8)
- * STACK_POINTER_REGNUM and virtual registers: Regs and Memory.
- (line 83)
- * stack_pointer_rtx: Frame Registers. (line 104)
- * stack_protect_combined_set instruction pattern: Standard Names.
- (line 2487)
- * stack_protect_combined_test instruction pattern: Standard Names.
- (line 2517)
- * stack_protect_set instruction pattern: Standard Names. (line 2503)
- * stack_protect_test instruction pattern: Standard Names. (line 2534)
- * STACK_PUSH_CODE: Frame Layout. (line 12)
- * STACK_REGS: Stack Registers. (line 19)
- * STACK_REG_COVER_CLASS: Stack Registers. (line 22)
- * STACK_SAVEAREA_MODE: Storage Layout. (line 473)
- * STACK_SIZE_MODE: Storage Layout. (line 484)
- * STACK_SLOT_ALIGNMENT: Storage Layout. (line 305)
- * standard pattern names: Standard Names. (line 6)
- * STANDARD_STARTFILE_PREFIX: Driver. (line 278)
- * STANDARD_STARTFILE_PREFIX_1: Driver. (line 285)
- * STANDARD_STARTFILE_PREFIX_2: Driver. (line 292)
- * STARTFILE_SPEC: Driver. (line 147)
- * Statement and operand traversals: Statement and operand traversals.
- (line 6)
- * Statement Sequences: Statement Sequences.
- (line 6)
- * Statements: Statements. (line 6)
- * statements: Function Properties.
- (line 6)
- * statements <1>: Statements for C++. (line 6)
- * static analysis: Static Analyzer. (line 6)
- * static analyzer: Static Analyzer. (line 6)
- * static analyzer, debugging: Debugging the Analyzer.
- (line 5)
- * static analyzer, internals: Analyzer Internals. (line 5)
- * Static profile estimation: Profile information.
- (line 24)
- * static single assignment: SSA. (line 6)
- * STATIC_CHAIN_INCOMING_REGNUM: Frame Registers. (line 77)
- * STATIC_CHAIN_REGNUM: Frame Registers. (line 76)
- * stdarg.h and register arguments: Register Arguments. (line 44)
- * STDC_0_IN_SYSTEM_HEADERS: Misc. (line 384)
- * STMT_EXPR: Unary and Binary Expressions.
- (line 6)
- * STMT_IS_FULL_EXPR_P: Statements for C++. (line 22)
- * storage layout: Storage Layout. (line 6)
- * STORE_FLAG_VALUE: Misc. (line 235)
- * STORE_MAX_PIECES: Costs. (line 215)
- * store_multiple instruction pattern: Standard Names. (line 159)
- * strcpy: Storage Layout. (line 258)
- * STRICT_ALIGNMENT: Storage Layout. (line 355)
- * strict_low_part: RTL Declarations. (line 9)
- * strict_memory_address_p: Addressing Modes. (line 186)
- * STRING_CST: Constant expressions.
- (line 6)
- * STRING_POOL_ADDRESS_P: Flags. (line 179)
- * strlenM instruction pattern: Standard Names. (line 1399)
- * structure value address: Aggregate Return. (line 6)
- * structures, returning: Interface. (line 10)
- * STRUCTURE_SIZE_BOUNDARY: Storage Layout. (line 347)
- * subM3 instruction pattern: Standard Names. (line 442)
- * SUBOBJECT: Statements for C++. (line 6)
- * SUBOBJECT_CLEANUP: Statements for C++. (line 6)
- * subreg: Regs and Memory. (line 97)
- * subreg and /s: Flags. (line 201)
- * subreg and /u: Flags. (line 194)
- * subreg and /u and /v: Flags. (line 184)
- * subreg, in strict_low_part: RTL Declarations. (line 9)
- * SUBREG_BYTE: Regs and Memory. (line 311)
- * SUBREG_PROMOTED_UNSIGNED_P: Flags. (line 184)
- * SUBREG_PROMOTED_UNSIGNED_SET: Flags. (line 194)
- * SUBREG_PROMOTED_VAR_P: Flags. (line 201)
- * SUBREG_REG: Regs and Memory. (line 311)
- * subst iterators in .md files: Subst Iterators. (line 6)
- * subvM4 instruction pattern: Standard Names. (line 458)
- * SUCCESS_EXIT_CODE: Host Misc. (line 12)
- * support for nested functions: Trampolines. (line 6)
- * SUPPORTS_INIT_PRIORITY: Macros for Initialization.
- (line 57)
- * SUPPORTS_ONE_ONLY: Label Output. (line 290)
- * SUPPORTS_WEAK: Label Output. (line 264)
- * SWITCHABLE_TARGET: Run-time Target. (line 160)
- * SWITCH_BODY: Statements for C++. (line 6)
- * SWITCH_COND: Statements for C++. (line 6)
- * SWITCH_STMT: Statements for C++. (line 6)
- * symbolic label: Sharing. (line 20)
- * SYMBOL_FLAG_ANCHOR: Special Accessors. (line 117)
- * SYMBOL_FLAG_EXTERNAL: Special Accessors. (line 99)
- * SYMBOL_FLAG_FUNCTION: Special Accessors. (line 92)
- * SYMBOL_FLAG_HAS_BLOCK_INFO: Special Accessors. (line 113)
- * SYMBOL_FLAG_LOCAL: Special Accessors. (line 95)
- * SYMBOL_FLAG_SMALL: Special Accessors. (line 104)
- * SYMBOL_FLAG_TLS_SHIFT: Special Accessors. (line 108)
- * symbol_ref: Constants. (line 189)
- * symbol_ref and /f: Flags. (line 179)
- * symbol_ref and /i: Flags. (line 216)
- * symbol_ref and /u: Flags. (line 19)
- * symbol_ref and /v: Flags. (line 220)
- * symbol_ref, RTL sharing: Sharing. (line 20)
- * SYMBOL_REF_ANCHOR_P: Special Accessors. (line 117)
- * SYMBOL_REF_BLOCK: Special Accessors. (line 130)
- * SYMBOL_REF_BLOCK_OFFSET: Special Accessors. (line 135)
- * SYMBOL_REF_CONSTANT: Special Accessors. (line 78)
- * SYMBOL_REF_DATA: Special Accessors. (line 82)
- * SYMBOL_REF_DECL: Special Accessors. (line 67)
- * SYMBOL_REF_EXTERNAL_P: Special Accessors. (line 99)
- * SYMBOL_REF_FLAG: Flags. (line 220)
- * SYMBOL_REF_FLAG, in TARGET_ENCODE_SECTION_INFO: Sections. (line 289)
- * SYMBOL_REF_FLAGS: Special Accessors. (line 86)
- * SYMBOL_REF_FUNCTION_P: Special Accessors. (line 92)
- * SYMBOL_REF_HAS_BLOCK_INFO_P: Special Accessors. (line 113)
- * SYMBOL_REF_LOCAL_P: Special Accessors. (line 95)
- * SYMBOL_REF_SMALL_P: Special Accessors. (line 104)
- * SYMBOL_REF_TLS_MODEL: Special Accessors. (line 108)
- * SYMBOL_REF_USED: Flags. (line 211)
- * SYMBOL_REF_WEAK: Flags. (line 216)
- * sync_addMODE instruction pattern: Standard Names. (line 2232)
- * sync_andMODE instruction pattern: Standard Names. (line 2232)
- * sync_compare_and_swapMODE instruction pattern: Standard Names.
- (line 2192)
- * sync_iorMODE instruction pattern: Standard Names. (line 2232)
- * sync_lock_releaseMODE instruction pattern: Standard Names. (line 2297)
- * sync_lock_test_and_setMODE instruction pattern: Standard Names.
- (line 2271)
- * sync_nandMODE instruction pattern: Standard Names. (line 2232)
- * sync_new_addMODE instruction pattern: Standard Names. (line 2264)
- * sync_new_andMODE instruction pattern: Standard Names. (line 2264)
- * sync_new_iorMODE instruction pattern: Standard Names. (line 2264)
- * sync_new_nandMODE instruction pattern: Standard Names. (line 2264)
- * sync_new_subMODE instruction pattern: Standard Names. (line 2264)
- * sync_new_xorMODE instruction pattern: Standard Names. (line 2264)
- * sync_old_addMODE instruction pattern: Standard Names. (line 2247)
- * sync_old_andMODE instruction pattern: Standard Names. (line 2247)
- * sync_old_iorMODE instruction pattern: Standard Names. (line 2247)
- * sync_old_nandMODE instruction pattern: Standard Names. (line 2247)
- * sync_old_subMODE instruction pattern: Standard Names. (line 2247)
- * sync_old_xorMODE instruction pattern: Standard Names. (line 2247)
- * sync_subMODE instruction pattern: Standard Names. (line 2232)
- * sync_xorMODE instruction pattern: Standard Names. (line 2232)
- * SYSROOT_HEADERS_SUFFIX_SPEC: Driver. (line 176)
- * SYSROOT_SUFFIX_SPEC: Driver. (line 171)
- * SYSTEM_IMPLICIT_EXTERN_C: Misc. (line 415)
- * t-TARGET: Target Fragment. (line 6)
- * table jump: Basic Blocks. (line 67)
- * tablejump instruction pattern: Standard Names. (line 1850)
- * tag: GTY Options. (line 90)
- * tagging insns: Tagging Insns. (line 6)
- * tail calls: Tail Calls. (line 6)
- * TAmode: Machine Modes. (line 158)
- * tanM2 instruction pattern: Standard Names. (line 954)
- * target attributes: Target Attributes. (line 6)
- * target description macros: Target Macros. (line 6)
- * target functions: Target Structure. (line 6)
- * target hooks: Target Structure. (line 6)
- * target makefile fragment: Target Fragment. (line 6)
- * target specifications: Run-time Target. (line 6)
- * targetm: Target Structure. (line 6)
- * targets, makefile: Makefile. (line 6)
- * TARGET_ABSOLUTE_BIGGEST_ALIGNMENT: Storage Layout. (line 185)
- * TARGET_ADDITIONAL_ALLOCNO_CLASS_P: Register Classes. (line 639)
- * TARGET_ADDRESS_COST: Costs. (line 344)
- * TARGET_ADDR_SPACE_ADDRESS_MODE: Named Address Spaces.
- (line 42)
- * TARGET_ADDR_SPACE_CONVERT: Named Address Spaces.
- (line 89)
- * TARGET_ADDR_SPACE_DEBUG: Named Address Spaces.
- (line 99)
- * TARGET_ADDR_SPACE_DIAGNOSE_USAGE: Named Address Spaces.
- (line 103)
- * TARGET_ADDR_SPACE_LEGITIMATE_ADDRESS_P: Named Address Spaces.
- (line 59)
- * TARGET_ADDR_SPACE_LEGITIMIZE_ADDRESS: Named Address Spaces.
- (line 67)
- * TARGET_ADDR_SPACE_POINTER_MODE: Named Address Spaces.
- (line 36)
- * TARGET_ADDR_SPACE_SUBSET_P: Named Address Spaces.
- (line 74)
- * TARGET_ADDR_SPACE_VALID_POINTER_MODE: Named Address Spaces.
- (line 48)
- * TARGET_ADDR_SPACE_ZERO_ADDRESS_VALID: Named Address Spaces.
- (line 83)
- * TARGET_ALIGN_ANON_BITFIELD: Storage Layout. (line 432)
- * TARGET_ALLOCATE_INITIAL_VALUE: Misc. (line 807)
- * TARGET_ALLOCATE_STACK_SLOTS_FOR_ARGS: Misc. (line 1064)
- * TARGET_ALWAYS_STRIP_DOTDOT: Driver. (line 250)
- * TARGET_ARG_PARTIAL_BYTES: Register Arguments. (line 92)
- * TARGET_ARM_EABI_UNWINDER: Exception Region Output.
- (line 133)
- * TARGET_ARRAY_MODE: Register Arguments. (line 373)
- * TARGET_ARRAY_MODE_SUPPORTED_P: Register Arguments. (line 388)
- * TARGET_ASAN_SHADOW_OFFSET: Misc. (line 1092)
- * TARGET_ASM_ALIGNED_DI_OP: Data Output. (line 11)
- * TARGET_ASM_ALIGNED_HI_OP: Data Output. (line 7)
- * TARGET_ASM_ALIGNED_PDI_OP: Data Output. (line 10)
- * TARGET_ASM_ALIGNED_PSI_OP: Data Output. (line 8)
- * TARGET_ASM_ALIGNED_PTI_OP: Data Output. (line 12)
- * TARGET_ASM_ALIGNED_SI_OP: Data Output. (line 9)
- * TARGET_ASM_ALIGNED_TI_OP: Data Output. (line 13)
- * TARGET_ASM_ASSEMBLE_UNDEFINED_DECL: Label Output. (line 231)
- * TARGET_ASM_ASSEMBLE_VISIBILITY: Label Output. (line 301)
- * TARGET_ASM_BYTE_OP: Data Output. (line 6)
- * TARGET_ASM_CAN_OUTPUT_MI_THUNK: Function Entry. (line 209)
- * TARGET_ASM_CLOSE_PAREN: Data Output. (line 139)
- * TARGET_ASM_CODE_END: File Framework. (line 57)
- * TARGET_ASM_CONSTRUCTOR: Macros for Initialization.
- (line 68)
- * TARGET_ASM_DECLARE_CONSTANT_NAME: Label Output. (line 177)
- * TARGET_ASM_DECL_END: Data Output. (line 44)
- * TARGET_ASM_DESTRUCTOR: Macros for Initialization.
- (line 82)
- * TARGET_ASM_ELF_FLAGS_NUMERIC: File Framework. (line 120)
- * TARGET_ASM_EMIT_EXCEPT_PERSONALITY: Dispatch Tables. (line 89)
- * TARGET_ASM_EMIT_EXCEPT_TABLE_LABEL: Dispatch Tables. (line 82)
- * TARGET_ASM_EMIT_UNWIND_LABEL: Dispatch Tables. (line 70)
- * TARGET_ASM_EXTERNAL_LIBCALL: Label Output. (line 337)
- * TARGET_ASM_FILE_END: File Framework. (line 35)
- * TARGET_ASM_FILE_START: File Framework. (line 8)
- * TARGET_ASM_FILE_START_APP_OFF: File Framework. (line 16)
- * TARGET_ASM_FILE_START_FILE_DIRECTIVE: File Framework. (line 29)
- * TARGET_ASM_FINAL_POSTSCAN_INSN: Instruction Output. (line 82)
- * TARGET_ASM_FUNCTION_BEGIN_EPILOGUE: Function Entry. (line 67)
- * TARGET_ASM_FUNCTION_END_PROLOGUE: Function Entry. (line 61)
- * TARGET_ASM_FUNCTION_EPILOGUE: Function Entry. (line 73)
- * TARGET_ASM_FUNCTION_PROLOGUE: Function Entry. (line 18)
- * TARGET_ASM_FUNCTION_RODATA_SECTION: Sections. (line 225)
- * TARGET_ASM_FUNCTION_SECTION: File Framework. (line 132)
- * TARGET_ASM_FUNCTION_SWITCHED_TEXT_SECTIONS: File Framework.
- (line 142)
- * TARGET_ASM_GENERATE_PIC_ADDR_DIFF_VEC: Sections. (line 184)
- * TARGET_ASM_GLOBALIZE_DECL_NAME: Label Output. (line 222)
- * TARGET_ASM_GLOBALIZE_LABEL: Label Output. (line 213)
- * TARGET_ASM_INIT_SECTIONS: Sections. (line 164)
- * TARGET_ASM_INTEGER: Data Output. (line 31)
- * TARGET_ASM_INTERNAL_LABEL: Label Output. (line 380)
- * TARGET_ASM_LTO_END: File Framework. (line 52)
- * TARGET_ASM_LTO_START: File Framework. (line 47)
- * TARGET_ASM_MARK_DECL_PRESERVED: Label Output. (line 343)
- * TARGET_ASM_MERGEABLE_RODATA_PREFIX: Sections. (line 233)
- * TARGET_ASM_NAMED_SECTION: File Framework. (line 112)
- * TARGET_ASM_OPEN_PAREN: Data Output. (line 138)
- * TARGET_ASM_OUTPUT_ADDR_CONST_EXTRA: Data Output. (line 48)
- * TARGET_ASM_OUTPUT_ANCHOR: Anchored Addresses. (line 42)
- * TARGET_ASM_OUTPUT_DWARF_DTPREL: DWARF. (line 121)
- * TARGET_ASM_OUTPUT_IDENT: File Framework. (line 99)
- * TARGET_ASM_OUTPUT_MI_THUNK: Function Entry. (line 167)
- * TARGET_ASM_OUTPUT_SOURCE_FILENAME: File Framework. (line 91)
- * TARGET_ASM_POST_CFI_STARTPROC: Dispatch Tables. (line 61)
- * TARGET_ASM_PRINT_PATCHABLE_FUNCTION_ENTRY: Function Entry. (line 9)
- * TARGET_ASM_RECORD_GCC_SWITCHES: File Framework. (line 173)
- * TARGET_ASM_RECORD_GCC_SWITCHES_SECTION: File Framework. (line 218)
- * TARGET_ASM_RELOC_RW_MASK: Sections. (line 173)
- * TARGET_ASM_SELECT_RTX_SECTION: Sections. (line 242)
- * TARGET_ASM_SELECT_SECTION: Sections. (line 191)
- * TARGET_ASM_TM_CLONE_TABLE_SECTION: Sections. (line 238)
- * TARGET_ASM_TRAMPOLINE_TEMPLATE: Trampolines. (line 81)
- * TARGET_ASM_TTYPE: Exception Region Output.
- (line 127)
- * TARGET_ASM_UNALIGNED_DI_OP: Data Output. (line 18)
- * TARGET_ASM_UNALIGNED_HI_OP: Data Output. (line 14)
- * TARGET_ASM_UNALIGNED_PDI_OP: Data Output. (line 17)
- * TARGET_ASM_UNALIGNED_PSI_OP: Data Output. (line 15)
- * TARGET_ASM_UNALIGNED_PTI_OP: Data Output. (line 19)
- * TARGET_ASM_UNALIGNED_SI_OP: Data Output. (line 16)
- * TARGET_ASM_UNALIGNED_TI_OP: Data Output. (line 20)
- * TARGET_ASM_UNIQUE_SECTION: Sections. (line 213)
- * TARGET_ASM_UNWIND_EMIT: Dispatch Tables. (line 96)
- * TARGET_ASM_UNWIND_EMIT_BEFORE_INSN: Dispatch Tables. (line 102)
- * TARGET_ATOMIC_ALIGN_FOR_MODE: Misc. (line 1111)
- * TARGET_ATOMIC_ASSIGN_EXPAND_FENV: Misc. (line 1117)
- * TARGET_ATOMIC_TEST_AND_SET_TRUEVAL: Misc. (line 1102)
- * TARGET_ATTRIBUTE_TABLE: Target Attributes. (line 10)
- * TARGET_ATTRIBUTE_TAKES_IDENTIFIER_P: Target Attributes. (line 17)
- * TARGET_BINDS_LOCAL_P: Sections. (line 320)
- * TARGET_BUILD_BUILTIN_VA_LIST: Register Arguments. (line 281)
- * TARGET_BUILTIN_DECL: Misc. (line 637)
- * TARGET_BUILTIN_RECIPROCAL: Addressing Modes. (line 261)
- * TARGET_BUILTIN_SETJMP_FRAME_VALUE: Frame Layout. (line 101)
- * TARGET_CALLEE_COPIES: Register Arguments. (line 124)
- * TARGET_CALL_ARGS: Varargs. (line 123)
- * TARGET_CALL_FUSAGE_CONTAINS_NON_CALLEE_CLOBBERS: Miscellaneous Register Hooks.
- (line 6)
- * TARGET_CANNOT_FORCE_CONST_MEM: Addressing Modes. (line 234)
- * TARGET_CANNOT_MODIFY_JUMPS_P: Misc. (line 871)
- * TARGET_CANNOT_SUBSTITUTE_MEM_EQUIV_P: Register Classes. (line 610)
- * TARGET_CANONICALIZE_COMPARISON: MODE_CC Condition Codes.
- (line 55)
- * TARGET_CANONICAL_VA_LIST_TYPE: Register Arguments. (line 302)
- * TARGET_CAN_CHANGE_MODE_CLASS: Register Classes. (line 543)
- * TARGET_CAN_CHANGE_MODE_CLASS and subreg semantics: Regs and Memory.
- (line 294)
- * TARGET_CAN_ELIMINATE: Elimination. (line 58)
- * TARGET_CAN_FOLLOW_JUMP: Misc. (line 793)
- * TARGET_CAN_INLINE_P: Target Attributes. (line 173)
- * TARGET_CAN_USE_DOLOOP_P: Misc. (line 757)
- * TARGET_CASE_VALUES_THRESHOLD: Misc. (line 46)
- * TARGET_CC_MODES_COMPATIBLE: MODE_CC Condition Codes.
- (line 120)
- * TARGET_CHECK_BUILTIN_CALL: Misc. (line 669)
- * TARGET_CHECK_PCH_TARGET_FLAGS: PCH Target. (line 26)
- * TARGET_CHECK_STRING_OBJECT_FORMAT_ARG: Run-time Target. (line 119)
- * TARGET_CLASS_LIKELY_SPILLED_P: Register Classes. (line 499)
- * TARGET_CLASS_MAX_NREGS: Register Classes. (line 515)
- * TARGET_COMMUTATIVE_P: Misc. (line 800)
- * TARGET_COMPARE_BY_PIECES_BRANCH_RATIO: Costs. (line 200)
- * TARGET_COMPARE_VERSION_PRIORITY: Misc. (line 701)
- * TARGET_COMPATIBLE_VECTOR_TYPES_P: Register Arguments. (line 350)
- * TARGET_COMPUTE_FRAME_LAYOUT: Elimination. (line 74)
- * TARGET_COMPUTE_PRESSURE_CLASSES: Register Classes. (line 655)
- * TARGET_COMP_TYPE_ATTRIBUTES: Target Attributes. (line 25)
- * TARGET_CONDITIONAL_REGISTER_USAGE: Register Basics. (line 102)
- * TARGET_CONSTANT_ALIGNMENT: Storage Layout. (line 271)
- * TARGET_CONST_ANCHOR: Misc. (line 1075)
- * TARGET_CONST_NOT_OK_FOR_DEBUG_P: Addressing Modes. (line 230)
- * TARGET_CONVERT_TO_TYPE: Misc. (line 1022)
- * TARGET_CPU_CPP_BUILTINS: Run-time Target. (line 8)
- * TARGET_CSTORE_MODE: Register Classes. (line 647)
- * TARGET_CUSTOM_FUNCTION_DESCRIPTORS: Trampolines. (line 39)
- * TARGET_CXX_ADJUST_CLASS_AT_DEFINITION: C++ ABI. (line 86)
- * TARGET_CXX_CDTOR_RETURNS_THIS: C++ ABI. (line 37)
- * TARGET_CXX_CLASS_DATA_ALWAYS_COMDAT: C++ ABI. (line 61)
- * TARGET_CXX_COOKIE_HAS_SIZE: C++ ABI. (line 24)
- * TARGET_CXX_DECL_MANGLING_CONTEXT: C++ ABI. (line 92)
- * TARGET_CXX_DETERMINE_CLASS_DATA_VISIBILITY: C++ ABI. (line 52)
- * TARGET_CXX_GET_COOKIE_SIZE: C++ ABI. (line 17)
- * TARGET_CXX_GUARD_MASK_BIT: C++ ABI. (line 11)
- * TARGET_CXX_GUARD_TYPE: C++ ABI. (line 6)
- * TARGET_CXX_IMPLICIT_EXTERN_C: Misc. (line 407)
- * TARGET_CXX_IMPORT_EXPORT_CLASS: C++ ABI. (line 28)
- * TARGET_CXX_KEY_METHOD_MAY_BE_INLINE: C++ ABI. (line 42)
- * TARGET_CXX_LIBRARY_RTTI_COMDAT: C++ ABI. (line 68)
- * TARGET_CXX_USE_AEABI_ATEXIT: C++ ABI. (line 73)
- * TARGET_CXX_USE_ATEXIT_FOR_CXA_ATEXIT: C++ ABI. (line 79)
- * TARGET_C_EXCESS_PRECISION: Storage Layout. (line 109)
- * TARGET_C_PREINCLUDE: Misc. (line 395)
- * TARGET_DEBUG_UNWIND_INFO: DWARF. (line 32)
- * TARGET_DECIMAL_FLOAT_SUPPORTED_P: Storage Layout. (line 537)
- * TARGET_DECLSPEC: Target Attributes. (line 72)
- * TARGET_DEFAULT_PACK_STRUCT: Misc. (line 479)
- * TARGET_DEFAULT_SHORT_ENUMS: Type Layout. (line 123)
- * TARGET_DEFAULT_TARGET_FLAGS: Run-time Target. (line 55)
- * TARGET_DEFERRED_OUTPUT_DEFS: Label Output. (line 465)
- * TARGET_DELAY_SCHED2: DWARF. (line 77)
- * TARGET_DELAY_VARTRACK: DWARF. (line 81)
- * TARGET_DELEGITIMIZE_ADDRESS: Addressing Modes. (line 221)
- * TARGET_DIFFERENT_ADDR_DISPLACEMENT_P: Register Classes. (line 603)
- * TARGET_DLLIMPORT_DECL_ATTRIBUTES: Target Attributes. (line 55)
- * TARGET_DOLOOP_COST_FOR_ADDRESS: Misc. (line 746)
- * TARGET_DOLOOP_COST_FOR_GENERIC: Misc. (line 735)
- * TARGET_DWARF_CALLING_CONVENTION: DWARF. (line 12)
- * TARGET_DWARF_FRAME_REG_MODE: Exception Region Output.
- (line 113)
- * TARGET_DWARF_HANDLE_FRAME_UNSPEC: Frame Layout. (line 165)
- * TARGET_DWARF_POLY_INDETERMINATE_VALUE: Frame Layout. (line 177)
- * TARGET_DWARF_REGISTER_SPAN: Exception Region Output.
- (line 104)
- * TARGET_D_CPU_VERSIONS: D Language and ABI. (line 6)
- * TARGET_D_CRITSEC_SIZE: D Language and ABI. (line 17)
- * TARGET_D_OS_VERSIONS: D Language and ABI. (line 13)
- * TARGET_EDOM: Library Calls. (line 59)
- * TARGET_EMPTY_RECORD_P: Aggregate Return. (line 86)
- * TARGET_EMUTLS_DEBUG_FORM_TLS_ADDRESS: Emulated TLS. (line 67)
- * TARGET_EMUTLS_GET_ADDRESS: Emulated TLS. (line 18)
- * TARGET_EMUTLS_REGISTER_COMMON: Emulated TLS. (line 23)
- * TARGET_EMUTLS_TMPL_PREFIX: Emulated TLS. (line 44)
- * TARGET_EMUTLS_TMPL_SECTION: Emulated TLS. (line 35)
- * TARGET_EMUTLS_VAR_ALIGN_FIXED: Emulated TLS. (line 62)
- * TARGET_EMUTLS_VAR_FIELDS: Emulated TLS. (line 48)
- * TARGET_EMUTLS_VAR_INIT: Emulated TLS. (line 55)
- * TARGET_EMUTLS_VAR_PREFIX: Emulated TLS. (line 40)
- * TARGET_EMUTLS_VAR_SECTION: Emulated TLS. (line 30)
- * TARGET_ENCODE_SECTION_INFO: Sections. (line 263)
- * TARGET_ENCODE_SECTION_INFO and address validation: Addressing Modes.
- (line 82)
- * TARGET_ENCODE_SECTION_INFO usage: Instruction Output. (line 127)
- * TARGET_END_CALL_ARGS: Varargs. (line 137)
- * TARGET_ENUM_VA_LIST_P: Register Arguments. (line 285)
- * TARGET_ESTIMATED_POLY_VALUE: Costs. (line 425)
- * TARGET_EXCEPT_UNWIND_INFO: Exception Region Output.
- (line 46)
- * TARGET_EXECUTABLE_SUFFIX: Misc. (line 858)
- * TARGET_EXPAND_BUILTIN: Misc. (line 647)
- * TARGET_EXPAND_BUILTIN_SAVEREGS: Varargs. (line 64)
- * TARGET_EXPAND_DIVMOD_LIBFUNC: Scheduling. (line 461)
- * TARGET_EXPAND_TO_RTL_HOOK: Storage Layout. (line 543)
- * TARGET_EXPR: Unary and Binary Expressions.
- (line 6)
- * TARGET_EXTRA_INCLUDES: Misc. (line 937)
- * TARGET_EXTRA_LIVE_ON_ENTRY: Tail Calls. (line 20)
- * TARGET_EXTRA_PRE_INCLUDES: Misc. (line 944)
- * TARGET_FIXED_CONDITION_CODE_REGS: MODE_CC Condition Codes.
- (line 105)
- * TARGET_FIXED_POINT_SUPPORTED_P: Storage Layout. (line 540)
- * target_flags: Run-time Target. (line 51)
- * TARGET_FLAGS_REGNUM: MODE_CC Condition Codes.
- (line 133)
- * TARGET_FLOATN_BUILTIN_P: Register Arguments. (line 438)
- * TARGET_FLOATN_MODE: Register Arguments. (line 420)
- * TARGET_FLOAT_EXCEPTIONS_ROUNDING_SUPPORTED_P: Run-time Target.
- (line 179)
- * TARGET_FNTYPE_ABI: Register Basics. (line 58)
- * TARGET_FN_ABI_VA_LIST: Register Arguments. (line 297)
- * TARGET_FOLD_BUILTIN: Misc. (line 684)
- * TARGET_FORMAT_TYPES: Misc. (line 965)
- * TARGET_FRAME_POINTER_REQUIRED: Elimination. (line 8)
- * TARGET_FUNCTION_ARG: Register Arguments. (line 10)
- * TARGET_FUNCTION_ARG_ADVANCE: Register Arguments. (line 195)
- * TARGET_FUNCTION_ARG_BOUNDARY: Register Arguments. (line 248)
- * TARGET_FUNCTION_ARG_OFFSET: Register Arguments. (line 206)
- * TARGET_FUNCTION_ARG_PADDING: Register Arguments. (line 214)
- * TARGET_FUNCTION_ARG_ROUND_BOUNDARY: Register Arguments. (line 254)
- * TARGET_FUNCTION_ATTRIBUTE_INLINABLE_P: Target Attributes. (line 101)
- * TARGET_FUNCTION_INCOMING_ARG: Register Arguments. (line 64)
- * TARGET_FUNCTION_OK_FOR_SIBCALL: Tail Calls. (line 6)
- * TARGET_FUNCTION_VALUE: Scalar Return. (line 9)
- * TARGET_FUNCTION_VALUE_REGNO_P: Scalar Return. (line 96)
- * TARGET_GENERATE_VERSION_DISPATCHER_BODY: Misc. (line 717)
- * TARGET_GEN_CCMP_FIRST: Misc. (line 890)
- * TARGET_GEN_CCMP_NEXT: Misc. (line 901)
- * TARGET_GET_DRAP_RTX: Misc. (line 1058)
- * TARGET_GET_FUNCTION_VERSIONS_DISPATCHER: Misc. (line 710)
- * TARGET_GET_MULTILIB_ABI_NAME: Register Basics. (line 99)
- * TARGET_GET_PCH_VALIDITY: PCH Target. (line 6)
- * TARGET_GET_RAW_ARG_MODE: Aggregate Return. (line 81)
- * TARGET_GET_RAW_RESULT_MODE: Aggregate Return. (line 76)
- * TARGET_GET_VALID_OPTION_VALUES: Stack Smashing Protection.
- (line 39)
- * TARGET_GIMPLE_FOLD_BUILTIN: Misc. (line 694)
- * TARGET_GIMPLIFY_VA_ARG_EXPR: Register Arguments. (line 307)
- * TARGET_GOACC_DIM_LIMIT: Addressing Modes. (line 540)
- * TARGET_GOACC_FORK_JOIN: Addressing Modes. (line 544)
- * TARGET_GOACC_REDUCTION: Addressing Modes. (line 555)
- * TARGET_GOACC_VALIDATE_DIMS: Addressing Modes. (line 527)
- * TARGET_HANDLE_C_OPTION: Run-time Target. (line 73)
- * TARGET_HANDLE_GENERIC_ATTRIBUTE: Target Attributes. (line 93)
- * TARGET_HANDLE_OPTION: Run-time Target. (line 59)
- * TARGET_HARD_REGNO_CALL_PART_CLOBBERED: Register Basics. (line 76)
- * TARGET_HARD_REGNO_MODE_OK: Values in Registers.
- (line 54)
- * TARGET_HARD_REGNO_NREGS: Values in Registers.
- (line 10)
- * TARGET_HARD_REGNO_SCRATCH_OK: Values in Registers.
- (line 139)
- * TARGET_HAS_IFUNC_P: Misc. (line 1106)
- * TARGET_HAS_NO_HW_DIVIDE: Library Calls. (line 52)
- * TARGET_HAVE_CONDITIONAL_EXECUTION: Misc. (line 884)
- * TARGET_HAVE_COUNT_REG_DECR_P: Misc. (line 731)
- * TARGET_HAVE_CTORS_DTORS: Macros for Initialization.
- (line 63)
- * TARGET_HAVE_NAMED_SECTIONS: File Framework. (line 150)
- * TARGET_HAVE_SPECULATION_SAFE_VALUE: Misc. (line 1189)
- * TARGET_HAVE_SRODATA_SECTION: Sections. (line 309)
- * TARGET_HAVE_SWITCHABLE_BSS_SECTIONS: File Framework. (line 155)
- * TARGET_HAVE_TLS: Sections. (line 329)
- * TARGET_INIT_BUILTINS: Misc. (line 621)
- * TARGET_INIT_DWARF_REG_SIZES_EXTRA: Exception Region Output.
- (line 119)
- * TARGET_INIT_LIBFUNCS: Library Calls. (line 15)
- * TARGET_INIT_PIC_REG: Register Arguments. (line 88)
- * TARGET_INSERT_ATTRIBUTES: Target Attributes. (line 80)
- * TARGET_INSN_CALLEE_ABI: Register Basics. (line 65)
- * TARGET_INSN_COST: Costs. (line 380)
- * TARGET_INSTANTIATE_DECLS: Storage Layout. (line 551)
- * TARGET_INVALID_ARG_FOR_UNPROTOTYPED_FN: Misc. (line 989)
- * TARGET_INVALID_BINARY_OP: Misc. (line 1008)
- * TARGET_INVALID_CONVERSION: Misc. (line 995)
- * TARGET_INVALID_UNARY_OP: Misc. (line 1001)
- * TARGET_INVALID_WITHIN_DOLOOP: Misc. (line 774)
- * TARGET_IN_SMALL_DATA_P: Sections. (line 305)
- * TARGET_IRA_CHANGE_PSEUDO_ALLOCNO_CLASS: Register Classes. (line 570)
- * TARGET_KEEP_LEAF_WHEN_PROFILED: Profiling. (line 39)
- * TARGET_LEGITIMATE_ADDRESS_P: Addressing Modes. (line 48)
- * TARGET_LEGITIMATE_COMBINED_INSN: Misc. (line 788)
- * TARGET_LEGITIMATE_CONSTANT_P: Addressing Modes. (line 213)
- * TARGET_LEGITIMIZE_ADDRESS: Addressing Modes. (line 129)
- * TARGET_LEGITIMIZE_ADDRESS_DISPLACEMENT: Register Classes. (line 618)
- * TARGET_LIBCALL_VALUE: Scalar Return. (line 65)
- * TARGET_LIBC_HAS_FAST_FUNCTION: Library Calls. (line 82)
- * TARGET_LIBC_HAS_FUNCTION: Library Calls. (line 77)
- * TARGET_LIBFUNC_GNU_PREFIX: Library Calls. (line 24)
- * TARGET_LIBGCC_CMP_RETURN_MODE: Storage Layout. (line 493)
- * TARGET_LIBGCC_FLOATING_MODE_SUPPORTED_P: Register Arguments.
- (line 412)
- * TARGET_LIBGCC_SDATA_SECTION: Sections. (line 136)
- * TARGET_LIBGCC_SHIFT_COUNT_MODE: Storage Layout. (line 499)
- * TARGET_LIB_INT_CMP_BIASED: Library Calls. (line 42)
- * TARGET_LOAD_BOUNDS_FOR_ARG: Varargs. (line 153)
- * TARGET_LOAD_RETURNED_BOUNDS: Varargs. (line 172)
- * TARGET_LOOP_UNROLL_ADJUST: Misc. (line 918)
- * TARGET_LRA_P: Register Classes. (line 577)
- * TARGET_MACHINE_DEPENDENT_REORG: Misc. (line 606)
- * TARGET_MANGLE_ASSEMBLER_NAME: Label Output. (line 356)
- * TARGET_MANGLE_DECL_ASSEMBLER_NAME: Sections. (line 253)
- * TARGET_MANGLE_TYPE: Storage Layout. (line 555)
- * TARGET_MAX_ANCHOR_OFFSET: Anchored Addresses. (line 38)
- * TARGET_MAX_NOCE_IFCVT_SEQ_COST: Costs. (line 390)
- * TARGET_MD_ASM_ADJUST: Misc. (line 524)
- * TARGET_MEMBER_TYPE_FORCES_BLK: Storage Layout. (line 445)
- * TARGET_MEMMODEL_CHECK: Misc. (line 1097)
- * TARGET_MEMORY_MOVE_COST: Costs. (line 79)
- * TARGET_MEM_CONSTRAINT: Addressing Modes. (line 107)
- * TARGET_MEM_REF: Storage References. (line 6)
- * TARGET_MERGE_DECL_ATTRIBUTES: Target Attributes. (line 45)
- * TARGET_MERGE_TYPE_ATTRIBUTES: Target Attributes. (line 37)
- * TARGET_MIN_ANCHOR_OFFSET: Anchored Addresses. (line 32)
- * TARGET_MIN_ARITHMETIC_PRECISION: Misc. (line 63)
- * TARGET_MIN_DIVISIONS_FOR_RECIP_MUL: Misc. (line 112)
- * TARGET_MODES_TIEABLE_P: Values in Registers.
- (line 123)
- * TARGET_MODE_AFTER: Mode Switching. (line 57)
- * TARGET_MODE_DEPENDENT_ADDRESS_P: Addressing Modes. (line 196)
- * TARGET_MODE_EMIT: Mode Switching. (line 42)
- * TARGET_MODE_ENTRY: Mode Switching. (line 64)
- * TARGET_MODE_EXIT: Mode Switching. (line 71)
- * TARGET_MODE_NEEDED: Mode Switching. (line 50)
- * TARGET_MODE_PRIORITY: Mode Switching. (line 78)
- * TARGET_MODE_REP_EXTENDED: Misc. (line 197)
- * TARGET_MS_BITFIELD_LAYOUT_P: Storage Layout. (line 509)
- * TARGET_MUST_PASS_IN_STACK: Register Arguments. (line 57)
- * TARGET_MUST_PASS_IN_STACK, and TARGET_FUNCTION_ARG: Register Arguments.
- (line 49)
- * TARGET_NARROW_VOLATILE_BITFIELD: Storage Layout. (line 438)
- * TARGET_NOCE_CONVERSION_PROFITABLE_P: Costs. (line 409)
- * TARGET_NO_REGISTER_ALLOCATION: DWARF. (line 85)
- * TARGET_NO_SPECULATION_IN_DELAY_SLOTS_P: Costs. (line 415)
- * TARGET_N_FORMAT_TYPES: Misc. (line 970)
- * TARGET_OBJC_CONSTRUCT_STRING_OBJECT: Run-time Target. (line 88)
- * TARGET_OBJC_DECLARE_CLASS_DEFINITION: Run-time Target. (line 109)
- * TARGET_OBJC_DECLARE_UNRESOLVED_CLASS_REFERENCE: Run-time Target.
- (line 104)
- * TARGET_OBJECT_SUFFIX: Misc. (line 853)
- * TARGET_OBJFMT_CPP_BUILTINS: Run-time Target. (line 45)
- * TARGET_OFFLOAD_OPTIONS: Misc. (line 1140)
- * TARGET_OMIT_STRUCT_RETURN_REG: Scalar Return. (line 117)
- * TARGET_OMP_DEVICE_KIND_ARCH_ISA: Addressing Modes. (line 519)
- * TARGET_OPTAB_SUPPORTED_P: Costs. (line 299)
- * TARGET_OPTF: Misc. (line 952)
- * TARGET_OPTION_FUNCTION_VERSIONS: Target Attributes. (line 165)
- * TARGET_OPTION_INIT_STRUCT: Run-time Target. (line 156)
- * TARGET_OPTION_OPTIMIZATION_TABLE: Run-time Target. (line 142)
- * TARGET_OPTION_OVERRIDE: Target Attributes. (line 152)
- * TARGET_OPTION_POST_STREAM_IN: Target Attributes. (line 133)
- * TARGET_OPTION_PRAGMA_PARSE: Target Attributes. (line 145)
- * TARGET_OPTION_PRINT: Target Attributes. (line 139)
- * TARGET_OPTION_RESTORE: Target Attributes. (line 127)
- * TARGET_OPTION_SAVE: Target Attributes. (line 120)
- * TARGET_OPTION_VALID_ATTRIBUTE_P: Target Attributes. (line 108)
- * TARGET_OS_CPP_BUILTINS: Run-time Target. (line 41)
- * TARGET_OVERRIDES_FORMAT_ATTRIBUTES: Misc. (line 974)
- * TARGET_OVERRIDES_FORMAT_ATTRIBUTES_COUNT: Misc. (line 980)
- * TARGET_OVERRIDES_FORMAT_INIT: Misc. (line 984)
- * TARGET_OVERRIDE_OPTIONS_AFTER_CHANGE: Run-time Target. (line 126)
- * TARGET_PASS_BY_REFERENCE: Register Arguments. (line 112)
- * TARGET_PCH_VALID_P: PCH Target. (line 11)
- * TARGET_POSIX_IO: Misc. (line 550)
- * TARGET_PREDICT_DOLOOP_P: Misc. (line 724)
- * TARGET_PREFERRED_ELSE_VALUE: Addressing Modes. (line 563)
- * TARGET_PREFERRED_OUTPUT_RELOAD_CLASS: Register Classes. (line 284)
- * TARGET_PREFERRED_RELOAD_CLASS: Register Classes. (line 213)
- * TARGET_PREFERRED_RENAME_CLASS: Register Classes. (line 201)
- * TARGET_PREPARE_PCH_SAVE: PCH Target. (line 34)
- * TARGET_PRETEND_OUTGOING_VARARGS_NAMED: Varargs. (line 144)
- * TARGET_PROFILE_BEFORE_PROLOGUE: Sections. (line 313)
- * TARGET_PROMOTED_TYPE: Misc. (line 1014)
- * TARGET_PROMOTE_FUNCTION_MODE: Storage Layout. (line 126)
- * TARGET_PROMOTE_PROTOTYPES: Stack Arguments. (line 10)
- * TARGET_PTRMEMFUNC_VBIT_LOCATION: Type Layout. (line 250)
- * TARGET_RECORD_OFFLOAD_SYMBOL: Misc. (line 1135)
- * TARGET_REF_MAY_ALIAS_ERRNO: Register Arguments. (line 318)
- * TARGET_REGISTER_MOVE_COST: Costs. (line 31)
- * TARGET_REGISTER_PRIORITY: Register Classes. (line 582)
- * TARGET_REGISTER_USAGE_LEVELING_P: Register Classes. (line 593)
- * TARGET_RELAYOUT_FUNCTION: Target Attributes. (line 180)
- * TARGET_RESET_LOCATION_VIEW: DWARF. (line 57)
- * TARGET_RESOLVE_OVERLOADED_BUILTIN: Misc. (line 658)
- * TARGET_RETURN_IN_MEMORY: Aggregate Return. (line 15)
- * TARGET_RETURN_IN_MSB: Scalar Return. (line 124)
- * TARGET_RETURN_POPS_ARGS: Stack Arguments. (line 98)
- * TARGET_RTX_COSTS: Costs. (line 313)
- * TARGET_RUN_TARGET_SELFTESTS: Misc. (line 1226)
- * TARGET_SCALAR_MODE_SUPPORTED_P: Register Arguments. (line 334)
- * TARGET_SCHED_ADJUST_COST: Scheduling. (line 35)
- * TARGET_SCHED_ADJUST_PRIORITY: Scheduling. (line 50)
- * TARGET_SCHED_ALLOC_SCHED_CONTEXT: Scheduling. (line 294)
- * TARGET_SCHED_CAN_SPECULATE_INSN: Scheduling. (line 354)
- * TARGET_SCHED_CLEAR_SCHED_CONTEXT: Scheduling. (line 309)
- * TARGET_SCHED_DEPENDENCIES_EVALUATION_HOOK: Scheduling. (line 101)
- * TARGET_SCHED_DFA_NEW_CYCLE: Scheduling. (line 255)
- * TARGET_SCHED_DFA_POST_ADVANCE_CYCLE: Scheduling. (line 172)
- * TARGET_SCHED_DFA_POST_CYCLE_INSN: Scheduling. (line 156)
- * TARGET_SCHED_DFA_PRE_ADVANCE_CYCLE: Scheduling. (line 165)
- * TARGET_SCHED_DFA_PRE_CYCLE_INSN: Scheduling. (line 144)
- * TARGET_SCHED_DISPATCH: Scheduling. (line 370)
- * TARGET_SCHED_DISPATCH_DO: Scheduling. (line 375)
- * TARGET_SCHED_EXPOSED_PIPELINE: Scheduling. (line 379)
- * TARGET_SCHED_FINISH: Scheduling. (line 122)
- * TARGET_SCHED_FINISH_GLOBAL: Scheduling. (line 137)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_BACKTRACK: Scheduling. (line 235)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_BEGIN: Scheduling. (line 223)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD: Scheduling.
- (line 179)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_DFA_LOOKAHEAD_GUARD: Scheduling.
- (line 207)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_END: Scheduling. (line 240)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_FINI: Scheduling. (line 250)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_INIT: Scheduling. (line 245)
- * TARGET_SCHED_FIRST_CYCLE_MULTIPASS_ISSUE: Scheduling. (line 229)
- * TARGET_SCHED_FREE_SCHED_CONTEXT: Scheduling. (line 313)
- * TARGET_SCHED_FUSION_PRIORITY: Scheduling. (line 389)
- * TARGET_SCHED_GEN_SPEC_CHECK: Scheduling. (line 335)
- * TARGET_SCHED_H_I_D_EXTENDED: Scheduling. (line 289)
- * TARGET_SCHED_INIT: Scheduling. (line 111)
- * TARGET_SCHED_INIT_DFA_POST_CYCLE_INSN: Scheduling. (line 161)
- * TARGET_SCHED_INIT_DFA_PRE_CYCLE_INSN: Scheduling. (line 153)
- * TARGET_SCHED_INIT_GLOBAL: Scheduling. (line 129)
- * TARGET_SCHED_INIT_SCHED_CONTEXT: Scheduling. (line 298)
- * TARGET_SCHED_ISSUE_RATE: Scheduling. (line 11)
- * TARGET_SCHED_IS_COSTLY_DEPENDENCE: Scheduling. (line 267)
- * TARGET_SCHED_MACRO_FUSION_P: Scheduling. (line 87)
- * TARGET_SCHED_MACRO_FUSION_PAIR_P: Scheduling. (line 91)
- * TARGET_SCHED_NEEDS_BLOCK_P: Scheduling. (line 328)
- * TARGET_SCHED_REASSOCIATION_WIDTH: Scheduling. (line 384)
- * TARGET_SCHED_REORDER: Scheduling. (line 58)
- * TARGET_SCHED_REORDER2: Scheduling. (line 75)
- * TARGET_SCHED_SET_SCHED_CONTEXT: Scheduling. (line 305)
- * TARGET_SCHED_SET_SCHED_FLAGS: Scheduling. (line 347)
- * TARGET_SCHED_SMS_RES_MII: Scheduling. (line 361)
- * TARGET_SCHED_SPECULATE_INSN: Scheduling. (line 316)
- * TARGET_SCHED_VARIABLE_ISSUE: Scheduling. (line 22)
- * TARGET_SECONDARY_MEMORY_NEEDED: Register Classes. (line 447)
- * TARGET_SECONDARY_MEMORY_NEEDED_MODE: Register Classes. (line 466)
- * TARGET_SECONDARY_RELOAD: Register Classes. (line 312)
- * TARGET_SECTION_TYPE_FLAGS: File Framework. (line 160)
- * TARGET_SELECT_EARLY_REMAT_MODES: Register Classes. (line 488)
- * TARGET_SETJMP_PRESERVES_NONVOLATILE_REGS_P: Misc. (line 223)
- * TARGET_SETUP_INCOMING_VARARGS: Varargs. (line 71)
- * TARGET_SET_CURRENT_FUNCTION: Misc. (line 835)
- * TARGET_SET_DEFAULT_TYPE_ATTRIBUTES: Target Attributes. (line 33)
- * TARGET_SET_UP_BY_PROLOGUE: Tail Calls. (line 29)
- * TARGET_SHIFT_TRUNCATION_MASK: Misc. (line 160)
- * TARGET_SHRINK_WRAP_COMPONENTS_FOR_BB: Shrink-wrapping separate components.
- (line 36)
- * TARGET_SHRINK_WRAP_DISQUALIFY_COMPONENTS: Shrink-wrapping separate components.
- (line 43)
- * TARGET_SHRINK_WRAP_EMIT_EPILOGUE_COMPONENTS: Shrink-wrapping separate components.
- (line 54)
- * TARGET_SHRINK_WRAP_EMIT_PROLOGUE_COMPONENTS: Shrink-wrapping separate components.
- (line 50)
- * TARGET_SHRINK_WRAP_GET_SEPARATE_COMPONENTS: Shrink-wrapping separate components.
- (line 27)
- * TARGET_SHRINK_WRAP_SET_HANDLED_COMPONENTS: Shrink-wrapping separate components.
- (line 58)
- * TARGET_SIMD_CLONE_ADJUST: Addressing Modes. (line 506)
- * TARGET_SIMD_CLONE_COMPUTE_VECSIZE_AND_SIMDLEN: Addressing Modes.
- (line 498)
- * TARGET_SIMD_CLONE_USABLE: Addressing Modes. (line 510)
- * TARGET_SIMT_VF: Addressing Modes. (line 516)
- * TARGET_SLOW_UNALIGNED_ACCESS: Costs. (line 132)
- * TARGET_SMALL_REGISTER_CLASSES_FOR_MODE_P: Register Arguments.
- (line 448)
- * TARGET_SPECULATION_SAFE_VALUE: Misc. (line 1208)
- * TARGET_SPILL_CLASS: Register Classes. (line 632)
- * TARGET_SPLIT_COMPLEX_ARG: Register Arguments. (line 269)
- * TARGET_STACK_CLASH_PROTECTION_ALLOCA_PROBE_RANGE: Stack Checking.
- (line 97)
- * TARGET_STACK_PROTECT_FAIL: Stack Smashing Protection.
- (line 16)
- * TARGET_STACK_PROTECT_GUARD: Stack Smashing Protection.
- (line 6)
- * TARGET_STACK_PROTECT_RUNTIME_ENABLED_P: Stack Smashing Protection.
- (line 25)
- * TARGET_STARTING_FRAME_OFFSET: Frame Layout. (line 34)
- * TARGET_STARTING_FRAME_OFFSET and virtual registers: Regs and Memory.
- (line 74)
- * TARGET_STATIC_CHAIN: Frame Registers. (line 90)
- * TARGET_STATIC_RTX_ALIGNMENT: Storage Layout. (line 243)
- * TARGET_STORE_BOUNDS_FOR_ARG: Varargs. (line 163)
- * TARGET_STORE_RETURNED_BOUNDS: Varargs. (line 177)
- * TARGET_STRICT_ARGUMENT_NAMING: Varargs. (line 107)
- * TARGET_STRING_OBJECT_REF_TYPE_P: Run-time Target. (line 114)
- * TARGET_STRIP_NAME_ENCODING: Sections. (line 300)
- * TARGET_STRUCT_VALUE_RTX: Aggregate Return. (line 44)
- * TARGET_SUPPORTS_SPLIT_STACK: Stack Smashing Protection.
- (line 30)
- * TARGET_SUPPORTS_WEAK: Label Output. (line 272)
- * TARGET_SUPPORTS_WIDE_INT: Misc. (line 1148)
- * TARGET_TERMINATE_DW2_EH_FRAME_INFO: Exception Region Output.
- (line 98)
- * TARGET_TRAMPOLINE_ADJUST_ADDRESS: Trampolines. (line 127)
- * TARGET_TRAMPOLINE_INIT: Trampolines. (line 107)
- * TARGET_TRANSLATE_MODE_ATTRIBUTE: Register Arguments. (line 325)
- * TARGET_TRULY_NOOP_TRUNCATION: Misc. (line 184)
- * TARGET_UNSPEC_MAY_TRAP_P: Misc. (line 826)
- * TARGET_UNWIND_TABLES_DEFAULT: Exception Region Output.
- (line 73)
- * TARGET_UNWIND_WORD_MODE: Storage Layout. (line 505)
- * TARGET_UPDATE_STACK_BOUNDARY: Misc. (line 1054)
- * TARGET_USES_WEAK_UNWIND_INFO: Exception Handling. (line 123)
- * TARGET_USE_ANCHORS_FOR_SYMBOL_P: Anchored Addresses. (line 53)
- * TARGET_USE_BLOCKS_FOR_CONSTANT_P: Addressing Modes. (line 248)
- * TARGET_USE_BLOCKS_FOR_DECL_P: Addressing Modes. (line 255)
- * TARGET_USE_BY_PIECES_INFRASTRUCTURE_P: Costs. (line 165)
- * TARGET_USE_PSEUDO_PIC_REG: Register Arguments. (line 84)
- * TARGET_VALID_DLLIMPORT_ATTRIBUTE_P: Target Attributes. (line 66)
- * TARGET_VALID_POINTER_MODE: Register Arguments. (line 313)
- * TARGET_VECTORIZE_ADD_STMT_COST: Addressing Modes. (line 461)
- * TARGET_VECTORIZE_AUTOVECTORIZE_VECTOR_MODES: Addressing Modes.
- (line 376)
- * TARGET_VECTORIZE_BUILTIN_GATHER: Addressing Modes. (line 484)
- * TARGET_VECTORIZE_BUILTIN_MASK_FOR_LOAD: Addressing Modes. (line 266)
- * TARGET_VECTORIZE_BUILTIN_MD_VECTORIZED_FUNCTION: Addressing Modes.
- (line 344)
- * TARGET_VECTORIZE_BUILTIN_SCATTER: Addressing Modes. (line 491)
- * TARGET_VECTORIZE_BUILTIN_VECTORIZATION_COST: Addressing Modes.
- (line 292)
- * TARGET_VECTORIZE_BUILTIN_VECTORIZED_FUNCTION: Addressing Modes.
- (line 336)
- * TARGET_VECTORIZE_DESTROY_COST_DATA: Addressing Modes. (line 479)
- * TARGET_VECTORIZE_EMPTY_MASK_IS_EXPENSIVE: Addressing Modes.
- (line 445)
- * TARGET_VECTORIZE_FINISH_COST: Addressing Modes. (line 472)
- * TARGET_VECTORIZE_GET_MASK_MODE: Addressing Modes. (line 433)
- * TARGET_VECTORIZE_INIT_COST: Addressing Modes. (line 452)
- * TARGET_VECTORIZE_PREFERRED_SIMD_MODE: Addressing Modes. (line 361)
- * TARGET_VECTORIZE_PREFERRED_VECTOR_ALIGNMENT: Addressing Modes.
- (line 298)
- * TARGET_VECTORIZE_RELATED_MODE: Addressing Modes. (line 407)
- * TARGET_VECTORIZE_SPLIT_REDUCTION: Addressing Modes. (line 368)
- * TARGET_VECTORIZE_SUPPORT_VECTOR_MISALIGNMENT: Addressing Modes.
- (line 351)
- * TARGET_VECTORIZE_VECTOR_ALIGNMENT_REACHABLE: Addressing Modes.
- (line 310)
- * TARGET_VECTORIZE_VEC_PERM_CONST: Addressing Modes. (line 316)
- * TARGET_VECTOR_ALIGNMENT: Storage Layout. (line 298)
- * TARGET_VECTOR_MODE_SUPPORTED_P: Register Arguments. (line 345)
- * TARGET_VERIFY_TYPE_CONTEXT: Misc. (line 1029)
- * TARGET_VTABLE_DATA_ENTRY_DISTANCE: Type Layout. (line 303)
- * TARGET_VTABLE_ENTRY_ALIGN: Type Layout. (line 297)
- * TARGET_VTABLE_USES_DESCRIPTORS: Type Layout. (line 286)
- * TARGET_WANT_DEBUG_PUB_SECTIONS: DWARF. (line 72)
- * TARGET_WARN_FUNC_RETURN: Tail Calls. (line 35)
- * TARGET_WARN_PARAMETER_PASSING_ABI: Aggregate Return. (line 90)
- * TARGET_WEAK_NOT_IN_ARCHIVE_TOC: Label Output. (line 308)
- * TCmode: Machine Modes. (line 199)
- * TDmode: Machine Modes. (line 97)
- * TEMPLATE_DECL: Declarations. (line 6)
- * Temporaries: Temporaries. (line 6)
- * termination routines: Initialization. (line 6)
- * testing constraints: C Constraint Interface.
- (line 6)
- * TEXT_SECTION_ASM_OP: Sections. (line 37)
- * TFmode: Machine Modes. (line 101)
- * The Language: The Language. (line 6)
- * THEN_CLAUSE: Statements for C++. (line 6)
- * THREAD_MODEL_SPEC: Driver. (line 162)
- * THROW_EXPR: Unary and Binary Expressions.
- (line 6)
- * THUNK_DECL: Declarations. (line 6)
- * THUNK_DELTA: Declarations. (line 6)
- * TImode: Machine Modes. (line 48)
- * TImode, in insn: Insns. (line 291)
- * TLS_COMMON_ASM_OP: Sections. (line 80)
- * TLS_SECTION_ASM_FLAG: Sections. (line 85)
- * tm.h macros: Target Macros. (line 6)
- * TQFmode: Machine Modes. (line 65)
- * TQmode: Machine Modes. (line 122)
- * trampolines for nested functions: Trampolines. (line 6)
- * TRAMPOLINE_ALIGNMENT: Trampolines. (line 101)
- * TRAMPOLINE_SECTION: Trampolines. (line 92)
- * TRAMPOLINE_SIZE: Trampolines. (line 97)
- * TRANSFER_FROM_TRAMPOLINE: Trampolines. (line 163)
- * trap instruction pattern: Standard Names. (line 2121)
- * tree: Tree overview. (line 6)
- * tree <1>: Macros and Functions.
- (line 6)
- * Tree SSA: Tree SSA. (line 6)
- * TREE_CHAIN: Macros and Functions.
- (line 6)
- * TREE_CODE: Tree overview. (line 6)
- * tree_fits_shwi_p: Constant expressions.
- (line 6)
- * tree_fits_uhwi_p: Constant expressions.
- (line 6)
- * TREE_INT_CST_ELT: Constant expressions.
- (line 6)
- * tree_int_cst_equal: Constant expressions.
- (line 6)
- * TREE_INT_CST_LOW: Constant expressions.
- (line 6)
- * tree_int_cst_lt: Constant expressions.
- (line 6)
- * TREE_INT_CST_NUNITS: Constant expressions.
- (line 6)
- * TREE_LIST: Containers. (line 6)
- * TREE_OPERAND: Expression trees. (line 6)
- * TREE_PUBLIC: Function Basics. (line 6)
- * TREE_PUBLIC <1>: Function Properties.
- (line 28)
- * TREE_PURPOSE: Containers. (line 6)
- * TREE_READONLY: Function Properties.
- (line 37)
- * tree_size: Macros and Functions.
- (line 13)
- * TREE_STATIC: Function Properties.
- (line 31)
- * TREE_STRING_LENGTH: Constant expressions.
- (line 6)
- * TREE_STRING_POINTER: Constant expressions.
- (line 6)
- * TREE_THIS_VOLATILE: Function Properties.
- (line 34)
- * tree_to_shwi: Constant expressions.
- (line 6)
- * tree_to_uhwi: Constant expressions.
- (line 6)
- * TREE_TYPE: Macros and Functions.
- (line 6)
- * TREE_TYPE <1>: Types. (line 6)
- * TREE_TYPE <2>: Working with declarations.
- (line 11)
- * TREE_TYPE <3>: Expression trees. (line 6)
- * TREE_TYPE <4>: Expression trees. (line 17)
- * TREE_TYPE <5>: Function Basics. (line 47)
- * TREE_TYPE <6>: Types for C++. (line 6)
- * TREE_VALUE: Containers. (line 6)
- * TREE_VEC: Containers. (line 6)
- * TREE_VEC_ELT: Containers. (line 6)
- * TREE_VEC_LENGTH: Containers. (line 6)
- * true positive: Guidelines for Diagnostics.
- (line 39)
- * truncate: Conversions. (line 38)
- * truncMN2 instruction pattern: Standard Names. (line 1442)
- * TRUNC_DIV_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUNC_MOD_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUTH_ANDIF_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUTH_AND_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUTH_NOT_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUTH_ORIF_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUTH_OR_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRUTH_XOR_EXPR: Unary and Binary Expressions.
- (line 6)
- * TRY_BLOCK: Statements for C++. (line 6)
- * TRY_HANDLERS: Statements for C++. (line 6)
- * TRY_STMTS: Statements for C++. (line 6)
- * Tuple specific accessors: Tuple specific accessors.
- (line 6)
- * tuples: Tuple representation.
- (line 6)
- * type: Types. (line 6)
- * type declaration: Declarations. (line 6)
- * TYPENAME_TYPE: Types for C++. (line 6)
- * TYPENAME_TYPE_FULLNAME: Types. (line 6)
- * TYPENAME_TYPE_FULLNAME <1>: Types for C++. (line 6)
- * TYPEOF_TYPE: Types for C++. (line 6)
- * TYPE_ALIGN: Types. (line 6)
- * TYPE_ALIGN <1>: Types. (line 30)
- * TYPE_ALIGN <2>: Types for C++. (line 6)
- * TYPE_ALIGN <3>: Types for C++. (line 44)
- * TYPE_ARG_TYPES: Types. (line 6)
- * TYPE_ARG_TYPES <1>: Types for C++. (line 6)
- * TYPE_ASM_OP: Label Output. (line 76)
- * TYPE_ATTRIBUTES: Attributes. (line 24)
- * TYPE_BINFO: Classes. (line 6)
- * TYPE_BUILT_IN: Types for C++. (line 66)
- * TYPE_CANONICAL: Types. (line 6)
- * TYPE_CANONICAL <1>: Types. (line 41)
- * TYPE_CONTEXT: Types. (line 6)
- * TYPE_CONTEXT <1>: Types for C++. (line 6)
- * TYPE_DECL: Declarations. (line 6)
- * TYPE_FIELDS: Types. (line 6)
- * TYPE_FIELDS <1>: Types for C++. (line 6)
- * TYPE_FIELDS <2>: Classes. (line 6)
- * TYPE_HAS_ARRAY_NEW_OPERATOR: Classes. (line 93)
- * TYPE_HAS_DEFAULT_CONSTRUCTOR: Classes. (line 78)
- * TYPE_HAS_MUTABLE_P: Classes. (line 83)
- * TYPE_HAS_NEW_OPERATOR: Classes. (line 90)
- * TYPE_MAIN_VARIANT: Types. (line 6)
- * TYPE_MAIN_VARIANT <1>: Types. (line 19)
- * TYPE_MAIN_VARIANT <2>: Types for C++. (line 6)
- * TYPE_MAX_VALUE: Types. (line 6)
- * TYPE_METHOD_BASETYPE: Types. (line 6)
- * TYPE_METHOD_BASETYPE <1>: Types for C++. (line 6)
- * TYPE_MIN_VALUE: Types. (line 6)
- * TYPE_NAME: Types. (line 6)
- * TYPE_NAME <1>: Types. (line 33)
- * TYPE_NAME <2>: Types for C++. (line 6)
- * TYPE_NAME <3>: Types for C++. (line 47)
- * TYPE_NOTHROW_P: Functions for C++. (line 154)
- * TYPE_OFFSET_BASETYPE: Types. (line 6)
- * TYPE_OFFSET_BASETYPE <1>: Types for C++. (line 6)
- * TYPE_OPERAND_FMT: Label Output. (line 87)
- * TYPE_OVERLOADS_ARRAY_REF: Classes. (line 101)
- * TYPE_OVERLOADS_ARROW: Classes. (line 104)
- * TYPE_OVERLOADS_CALL_EXPR: Classes. (line 97)
- * TYPE_POLYMORPHIC_P: Classes. (line 74)
- * TYPE_PRECISION: Types. (line 6)
- * TYPE_PRECISION <1>: Types for C++. (line 6)
- * TYPE_PTRDATAMEM_P: Types for C++. (line 6)
- * TYPE_PTRDATAMEM_P <1>: Types for C++. (line 69)
- * TYPE_PTRFN_P: Types for C++. (line 76)
- * TYPE_PTROBV_P: Types for C++. (line 6)
- * TYPE_PTROB_P: Types for C++. (line 79)
- * TYPE_PTR_P: Types for C++. (line 72)
- * TYPE_QUAL_CONST: Types. (line 6)
- * TYPE_QUAL_CONST <1>: Types for C++. (line 6)
- * TYPE_QUAL_RESTRICT: Types. (line 6)
- * TYPE_QUAL_RESTRICT <1>: Types for C++. (line 6)
- * TYPE_QUAL_VOLATILE: Types. (line 6)
- * TYPE_QUAL_VOLATILE <1>: Types for C++. (line 6)
- * TYPE_RAISES_EXCEPTIONS: Functions for C++. (line 149)
- * TYPE_SIZE: Types. (line 6)
- * TYPE_SIZE <1>: Types. (line 25)
- * TYPE_SIZE <2>: Types for C++. (line 6)
- * TYPE_SIZE <3>: Types for C++. (line 39)
- * TYPE_STRUCTURAL_EQUALITY_P: Types. (line 6)
- * TYPE_STRUCTURAL_EQUALITY_P <1>: Types. (line 77)
- * TYPE_UNQUALIFIED: Types. (line 6)
- * TYPE_UNQUALIFIED <1>: Types for C++. (line 6)
- * TYPE_VFIELD: Classes. (line 6)
- * uaddvM4 instruction pattern: Standard Names. (line 461)
- * uavgM3_ceil instruction pattern: Standard Names. (line 860)
- * uavgM3_floor instruction pattern: Standard Names. (line 848)
- * UDAmode: Machine Modes. (line 170)
- * udiv: Arithmetic. (line 130)
- * udivM3 instruction pattern: Standard Names. (line 442)
- * udivmodM4 instruction pattern: Standard Names. (line 825)
- * udot_prodM instruction pattern: Standard Names. (line 570)
- * UDQmode: Machine Modes. (line 138)
- * UHAmode: Machine Modes. (line 162)
- * UHQmode: Machine Modes. (line 130)
- * UINT16_TYPE: Type Layout. (line 214)
- * UINT32_TYPE: Type Layout. (line 215)
- * UINT64_TYPE: Type Layout. (line 216)
- * UINT8_TYPE: Type Layout. (line 213)
- * UINTMAX_TYPE: Type Layout. (line 197)
- * UINTPTR_TYPE: Type Layout. (line 234)
- * UINT_FAST16_TYPE: Type Layout. (line 230)
- * UINT_FAST32_TYPE: Type Layout. (line 231)
- * UINT_FAST64_TYPE: Type Layout. (line 232)
- * UINT_FAST8_TYPE: Type Layout. (line 229)
- * UINT_LEAST16_TYPE: Type Layout. (line 222)
- * UINT_LEAST32_TYPE: Type Layout. (line 223)
- * UINT_LEAST64_TYPE: Type Layout. (line 224)
- * UINT_LEAST8_TYPE: Type Layout. (line 221)
- * umaddMN4 instruction pattern: Standard Names. (line 772)
- * umax: Arithmetic. (line 149)
- * umaxM3 instruction pattern: Standard Names. (line 442)
- * umin: Arithmetic. (line 149)
- * uminM3 instruction pattern: Standard Names. (line 442)
- * umod: Arithmetic. (line 136)
- * umodM3 instruction pattern: Standard Names. (line 442)
- * umsubMN4 instruction pattern: Standard Names. (line 796)
- * umulhisi3 instruction pattern: Standard Names. (line 744)
- * umulhrsM3 instruction pattern: Standard Names. (line 605)
- * umulhsM3 instruction pattern: Standard Names. (line 595)
- * umulM3_highpart instruction pattern: Standard Names. (line 758)
- * umulqihi3 instruction pattern: Standard Names. (line 744)
- * umulsidi3 instruction pattern: Standard Names. (line 744)
- * umulvM4 instruction pattern: Standard Names. (line 466)
- * unchanging: Flags. (line 307)
- * unchanging, in call_insn: Flags. (line 115)
- * unchanging, in jump_insn, call_insn and insn: Flags. (line 28)
- * unchanging, in mem: Flags. (line 78)
- * unchanging, in subreg: Flags. (line 184)
- * unchanging, in subreg <1>: Flags. (line 194)
- * unchanging, in symbol_ref: Flags. (line 19)
- * UNEQ_EXPR: Unary and Binary Expressions.
- (line 6)
- * UNGE_EXPR: Unary and Binary Expressions.
- (line 6)
- * UNGT_EXPR: Unary and Binary Expressions.
- (line 6)
- * unions, returning: Interface. (line 10)
- * UNION_TYPE: Types. (line 6)
- * UNION_TYPE <1>: Classes. (line 6)
- * UNITS_PER_WORD: Storage Layout. (line 60)
- * UNKNOWN_TYPE: Types. (line 6)
- * UNKNOWN_TYPE <1>: Types for C++. (line 6)
- * UNLE_EXPR: Unary and Binary Expressions.
- (line 6)
- * UNLIKELY_EXECUTED_TEXT_SECTION_NAME: Sections. (line 48)
- * UNLT_EXPR: Unary and Binary Expressions.
- (line 6)
- * UNORDERED_EXPR: Unary and Binary Expressions.
- (line 6)
- * unshare_all_rtl: Sharing. (line 61)
- * unsigned division: Arithmetic. (line 130)
- * unsigned division with unsigned saturation: Arithmetic. (line 130)
- * unsigned greater than: Comparisons. (line 64)
- * unsigned greater than <1>: Comparisons. (line 72)
- * unsigned less than: Comparisons. (line 68)
- * unsigned less than <1>: Comparisons. (line 76)
- * unsigned minimum and maximum: Arithmetic. (line 149)
- * unsigned_fix: Conversions. (line 77)
- * unsigned_float: Conversions. (line 62)
- * unsigned_fract_convert: Conversions. (line 97)
- * unsigned_sat_fract: Conversions. (line 103)
- * unspec: Side Effects. (line 299)
- * unspec <1>: Constant Definitions.
- (line 111)
- * unspec_volatile: Side Effects. (line 299)
- * unspec_volatile <1>: Constant Definitions.
- (line 99)
- * untyped_call instruction pattern: Standard Names. (line 1747)
- * untyped_return instruction pattern: Standard Names. (line 1810)
- * UPDATE_PATH_HOST_CANONICALIZE (PATH): Filesystem. (line 59)
- * update_ssa: SSA. (line 74)
- * update_stmt: Manipulating GIMPLE statements.
- (line 140)
- * update_stmt <1>: SSA Operands. (line 6)
- * update_stmt_if_modified: Manipulating GIMPLE statements.
- (line 143)
- * UQQmode: Machine Modes. (line 126)
- * usaddM3 instruction pattern: Standard Names. (line 442)
- * usadM instruction pattern: Standard Names. (line 579)
- * USAmode: Machine Modes. (line 166)
- * usashlM3 instruction pattern: Standard Names. (line 828)
- * usdivM3 instruction pattern: Standard Names. (line 442)
- * use: Side Effects. (line 168)
- * used: Flags. (line 325)
- * used, in symbol_ref: Flags. (line 211)
- * user: GTY Options. (line 245)
- * user experience guidelines: User Experience Guidelines.
- (line 6)
- * user gc: User GC. (line 6)
- * USER_LABEL_PREFIX: Instruction Output. (line 152)
- * USE_C_ALLOCA: Host Misc. (line 19)
- * USE_LD_AS_NEEDED: Driver. (line 135)
- * USE_LOAD_POST_DECREMENT: Costs. (line 254)
- * USE_LOAD_POST_INCREMENT: Costs. (line 249)
- * USE_LOAD_PRE_DECREMENT: Costs. (line 264)
- * USE_LOAD_PRE_INCREMENT: Costs. (line 259)
- * USE_SELECT_SECTION_FOR_FUNCTIONS: Sections. (line 205)
- * USE_STORE_POST_DECREMENT: Costs. (line 274)
- * USE_STORE_POST_INCREMENT: Costs. (line 269)
- * USE_STORE_PRE_DECREMENT: Costs. (line 284)
- * USE_STORE_PRE_INCREMENT: Costs. (line 279)
- * USING_STMT: Statements for C++. (line 6)
- * usmaddMN4 instruction pattern: Standard Names. (line 780)
- * usmsubMN4 instruction pattern: Standard Names. (line 804)
- * usmulhisi3 instruction pattern: Standard Names. (line 748)
- * usmulM3 instruction pattern: Standard Names. (line 442)
- * usmulqihi3 instruction pattern: Standard Names. (line 748)
- * usmulsidi3 instruction pattern: Standard Names. (line 748)
- * usnegM2 instruction pattern: Standard Names. (line 872)
- * USQmode: Machine Modes. (line 134)
- * ussubM3 instruction pattern: Standard Names. (line 442)
- * usubvM4 instruction pattern: Standard Names. (line 466)
- * us_ashift: Arithmetic. (line 173)
- * us_minus: Arithmetic. (line 38)
- * us_mult: Arithmetic. (line 93)
- * us_neg: Arithmetic. (line 82)
- * us_plus: Arithmetic. (line 14)
- * us_truncate: Conversions. (line 48)
- * UTAmode: Machine Modes. (line 174)
- * UTQmode: Machine Modes. (line 142)
- * V in constraint: Simple Constraints. (line 43)
- * values, returned by functions: Scalar Return. (line 6)
- * varargs implementation: Varargs. (line 6)
- * variable: Declarations. (line 6)
- * Variable Location Debug Information in RTL: Debug Information.
- (line 6)
- * VAR_DECL: Declarations. (line 6)
- * var_location: Debug Information. (line 14)
- * vashlM3 instruction pattern: Standard Names. (line 844)
- * vashrM3 instruction pattern: Standard Names. (line 844)
- * VA_ARG_EXPR: Unary and Binary Expressions.
- (line 6)
- * vcondeqMN instruction pattern: Standard Names. (line 385)
- * vcondMN instruction pattern: Standard Names. (line 372)
- * vconduMN instruction pattern: Standard Names. (line 382)
- * vcond_mask_MN instruction pattern: Standard Names. (line 392)
- * vector: Containers. (line 6)
- * vector operations: Vector Operations. (line 6)
- * VECTOR_CST: Constant expressions.
- (line 6)
- * VECTOR_STORE_FLAG_VALUE: Misc. (line 327)
- * vec_cmpeqMN instruction pattern: Standard Names. (line 365)
- * vec_cmpMN instruction pattern: Standard Names. (line 355)
- * vec_cmpuMN instruction pattern: Standard Names. (line 362)
- * vec_concat: Vector Operations. (line 29)
- * VEC_COND_EXPR: Vectors. (line 6)
- * vec_duplicate: Vector Operations. (line 34)
- * vec_duplicateM instruction pattern: Standard Names. (line 298)
- * VEC_DUPLICATE_EXPR: Vectors. (line 6)
- * vec_extractMN instruction pattern: Standard Names. (line 282)
- * vec_initMN instruction pattern: Standard Names. (line 291)
- * vec_load_lanesMN instruction pattern: Standard Names. (line 165)
- * VEC_LSHIFT_EXPR: Vectors. (line 6)
- * vec_mask_load_lanesMN instruction pattern: Standard Names. (line 189)
- * vec_mask_store_lanesMN instruction pattern: Standard Names.
- (line 219)
- * vec_merge: Vector Operations. (line 11)
- * vec_packs_float_M instruction pattern: Standard Names. (line 670)
- * vec_packu_float_M instruction pattern: Standard Names. (line 670)
- * VEC_PACK_FIX_TRUNC_EXPR: Vectors. (line 6)
- * VEC_PACK_FLOAT_EXPR: Vectors. (line 6)
- * VEC_PACK_SAT_EXPR: Vectors. (line 6)
- * vec_pack_sbool_trunc_M instruction pattern: Standard Names.
- (line 647)
- * vec_pack_sfix_trunc_M instruction pattern: Standard Names. (line 663)
- * vec_pack_ssat_M instruction pattern: Standard Names. (line 656)
- * VEC_PACK_TRUNC_EXPR: Vectors. (line 6)
- * vec_pack_trunc_M instruction pattern: Standard Names. (line 640)
- * vec_pack_ufix_trunc_M instruction pattern: Standard Names. (line 663)
- * vec_pack_usat_M instruction pattern: Standard Names. (line 656)
- * vec_permM instruction pattern: Standard Names. (line 410)
- * vec_permM instruction pattern <1>: Addressing Modes. (line 330)
- * VEC_RSHIFT_EXPR: Vectors. (line 6)
- * vec_select: Vector Operations. (line 19)
- * vec_series: Vector Operations. (line 41)
- * vec_seriesM instruction pattern: Standard Names. (line 308)
- * VEC_SERIES_EXPR: Vectors. (line 6)
- * vec_setM instruction pattern: Standard Names. (line 277)
- * vec_shl_insert_M instruction pattern: Standard Names. (line 621)
- * vec_shl_M instruction pattern: Standard Names. (line 628)
- * vec_shr_M instruction pattern: Standard Names. (line 634)
- * vec_store_lanesMN instruction pattern: Standard Names. (line 206)
- * vec_unpacks_float_hi_M instruction pattern: Standard Names.
- (line 700)
- * vec_unpacks_float_lo_M instruction pattern: Standard Names.
- (line 700)
- * vec_unpacks_hi_M instruction pattern: Standard Names. (line 677)
- * vec_unpacks_lo_M instruction pattern: Standard Names. (line 677)
- * vec_unpacks_sbool_hi_M instruction pattern: Standard Names.
- (line 691)
- * vec_unpacks_sbool_lo_M instruction pattern: Standard Names.
- (line 691)
- * vec_unpacku_float_hi_M instruction pattern: Standard Names.
- (line 700)
- * vec_unpacku_float_lo_M instruction pattern: Standard Names.
- (line 700)
- * vec_unpacku_hi_M instruction pattern: Standard Names. (line 684)
- * vec_unpacku_lo_M instruction pattern: Standard Names. (line 684)
- * VEC_UNPACK_FIX_TRUNC_HI_EXPR: Vectors. (line 6)
- * VEC_UNPACK_FIX_TRUNC_LO_EXPR: Vectors. (line 6)
- * VEC_UNPACK_FLOAT_HI_EXPR: Vectors. (line 6)
- * VEC_UNPACK_FLOAT_LO_EXPR: Vectors. (line 6)
- * VEC_UNPACK_HI_EXPR: Vectors. (line 6)
- * VEC_UNPACK_LO_EXPR: Vectors. (line 6)
- * vec_unpack_sfix_trunc_hi_M instruction pattern: Standard Names.
- (line 709)
- * vec_unpack_sfix_trunc_lo_M instruction pattern: Standard Names.
- (line 709)
- * vec_unpack_ufix_trunc_hi_M instruction pattern: Standard Names.
- (line 709)
- * vec_unpack_ufix_trunc_lo_M instruction pattern: Standard Names.
- (line 709)
- * VEC_WIDEN_MULT_HI_EXPR: Vectors. (line 6)
- * VEC_WIDEN_MULT_LO_EXPR: Vectors. (line 6)
- * vec_widen_smult_even_M instruction pattern: Standard Names.
- (line 719)
- * vec_widen_smult_hi_M instruction pattern: Standard Names. (line 719)
- * vec_widen_smult_lo_M instruction pattern: Standard Names. (line 719)
- * vec_widen_smult_odd_M instruction pattern: Standard Names. (line 719)
- * vec_widen_sshiftl_hi_M instruction pattern: Standard Names.
- (line 730)
- * vec_widen_sshiftl_lo_M instruction pattern: Standard Names.
- (line 730)
- * vec_widen_umult_even_M instruction pattern: Standard Names.
- (line 719)
- * vec_widen_umult_hi_M instruction pattern: Standard Names. (line 719)
- * vec_widen_umult_lo_M instruction pattern: Standard Names. (line 719)
- * vec_widen_umult_odd_M instruction pattern: Standard Names. (line 719)
- * vec_widen_ushiftl_hi_M instruction pattern: Standard Names.
- (line 730)
- * vec_widen_ushiftl_lo_M instruction pattern: Standard Names.
- (line 730)
- * verify_flow_info: Maintaining the CFG.
- (line 116)
- * virtual operands: SSA Operands. (line 6)
- * VIRTUAL_INCOMING_ARGS_REGNUM: Regs and Memory. (line 59)
- * VIRTUAL_OUTGOING_ARGS_REGNUM: Regs and Memory. (line 87)
- * VIRTUAL_STACK_DYNAMIC_REGNUM: Regs and Memory. (line 78)
- * VIRTUAL_STACK_VARS_REGNUM: Regs and Memory. (line 69)
- * VLIW: Processor pipeline description.
- (line 6)
- * VLIW <1>: Processor pipeline description.
- (line 223)
- * vlshrM3 instruction pattern: Standard Names. (line 844)
- * VMS: Filesystem. (line 37)
- * VMS_DEBUGGING_INFO: VMS Debug. (line 8)
- * VOIDmode: Machine Modes. (line 192)
- * VOID_TYPE: Types. (line 6)
- * volatil: Flags. (line 339)
- * volatil, in insn, call_insn, jump_insn, code_label, jump_table_data, barrier, and note: Flags.
- (line 33)
- * volatil, in label_ref and reg_label: Flags. (line 54)
- * volatil, in mem, asm_operands, and asm_input: Flags. (line 65)
- * volatil, in reg: Flags. (line 106)
- * volatil, in subreg: Flags. (line 184)
- * volatil, in subreg <1>: Flags. (line 194)
- * volatil, in symbol_ref: Flags. (line 220)
- * volatile memory references: Flags. (line 340)
- * volatile, in prefetch: Flags. (line 92)
- * voting between constraint alternatives: Class Preferences. (line 6)
- * vrotlM3 instruction pattern: Standard Names. (line 844)
- * vrotrM3 instruction pattern: Standard Names. (line 844)
- * walk_dominator_tree: SSA. (line 195)
- * walk_gimple_op: Statement and operand traversals.
- (line 30)
- * walk_gimple_seq: Statement and operand traversals.
- (line 47)
- * walk_gimple_stmt: Statement and operand traversals.
- (line 10)
- * WCHAR_TYPE: Type Layout. (line 165)
- * WCHAR_TYPE_SIZE: Type Layout. (line 173)
- * which_alternative: Output Statement. (line 58)
- * WHILE_BODY: Statements for C++. (line 6)
- * WHILE_COND: Statements for C++. (line 6)
- * WHILE_STMT: Statements for C++. (line 6)
- * while_ultMN instruction pattern: Standard Names. (line 320)
- * whopr: LTO. (line 6)
- * widen_ssumM3 instruction pattern: Standard Names. (line 587)
- * widen_usumM3 instruction pattern: Standard Names. (line 588)
- * WIDEST_HARDWARE_FP_SIZE: Type Layout. (line 110)
- * window_save instruction pattern: Standard Names. (line 2092)
- * WINT_TYPE: Type Layout. (line 178)
- * WORDS_BIG_ENDIAN: Storage Layout. (line 28)
- * WORDS_BIG_ENDIAN, effect on subreg: Regs and Memory. (line 225)
- * word_mode: Machine Modes. (line 458)
- * WORD_REGISTER_OPERATIONS: Misc. (line 53)
- * wpa: LTO. (line 6)
- * X in constraint: Simple Constraints. (line 122)
- * x-HOST: Host Fragment. (line 6)
- * XCmode: Machine Modes. (line 199)
- * XCOFF_DEBUGGING_INFO: DBX Options. (line 12)
- * XEXP: Accessors. (line 6)
- * XFmode: Machine Modes. (line 82)
- * XImode: Machine Modes. (line 54)
- * XINT: Accessors. (line 6)
- * xm-MACHINE.h: Filesystem. (line 6)
- * xm-MACHINE.h <1>: Host Misc. (line 6)
- * xor: Arithmetic. (line 168)
- * xor, canonicalization of: Insn Canonicalizations.
- (line 94)
- * xorM3 instruction pattern: Standard Names. (line 442)
- * xorsignM3 instruction pattern: Standard Names. (line 1149)
- * XSTR: Accessors. (line 6)
- * XVEC: Accessors. (line 38)
- * XVECEXP: Accessors. (line 45)
- * XVECLEN: Accessors. (line 41)
- * XWINT: Accessors. (line 6)
- * zero_extend: Conversions. (line 28)
- * zero_extendMN2 instruction pattern: Standard Names. (line 1452)
- * zero_extract: Bit-Fields. (line 30)
- * zero_extract, canonicalization of: Insn Canonicalizations.
- (line 103)
-
-
-
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- Node: LCSSA882721
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- Node: User GC1908557
- Node: GGC Roots1912296
- Node: Files1913009
- Node: Invoking the garbage collector1915716
- Node: Troubleshooting1917221
- Node: Plugins1918296
- Node: Plugins loading1919425
- Node: Plugin API1920524
- Node: Plugins pass1928250
- Node: Plugins GC1930221
- Node: Plugins description1931938
- Node: Plugins attr1932474
- Node: Plugins recording1934754
- Node: Plugins gate1935604
- Node: Plugins tracking1936195
- Node: Plugins building1936783
- Node: LTO1940284
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- Node: IPA1951613
- Node: WHOPR1960663
- Node: Internal flags1965223
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- Node: GIMPLE API1967596
- Node: The Language1970391
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- Node: User Experience Guidelines2000886
- Node: Guidelines for Diagnostics2001822
- Ref: input_location_example2008883
- Node: Guidelines for Options2018566
- Node: Funding2018743
- Node: GNU Project2021250
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- Node: GNU Free Documentation License2059410
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- Node: Option Index2125507
- Node: Concept Index2126384
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