/* Print.cpp - Base class that provides print() and println() Copyright (c) 2008 David A. Mellis. All right reserved. many modifications, by Paul Stoffregen This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA Modified 23 November 2006 by David A. Mellis */ #include #include #include #include #include #include "wiring.h" #include "Print.h" #if ARDUINO >= 100 #else void Print::write(const char *str) { write((const uint8_t *)str, strlen(str)); } #endif #if ARDUINO >= 100 size_t Print::write(const uint8_t *buffer, size_t size) { size_t count = 0; while (size--) count += write(*buffer++); return count; } #else void Print::write(const uint8_t *buffer, size_t size) { while (size--) write(*buffer++); } #endif #if ARDUINO >= 100 size_t Print::print(const String &s) { uint8_t buffer[33]; size_t count = 0; unsigned int index = 0; unsigned int len = s.length(); while (len > 0) { s.getBytes(buffer, sizeof(buffer), index); unsigned int nbytes = len; if (nbytes > sizeof(buffer)-1) nbytes = sizeof(buffer)-1; index += nbytes; len -= nbytes; count += write(buffer, nbytes); } return count; } #else void Print::print(const String &s) { unsigned int len = s.length(); for (unsigned int i=0; i < len; i++) { write(s[i]); } } #endif #if ARDUINO >= 100 size_t Print::print(const __FlashStringHelper *ifsh) { uint8_t buffer[32]; size_t count = 0; const char PROGMEM *p = (const char PROGMEM *)ifsh; unsigned int len = strlen_P(p); while (len > 0) { unsigned int nbytes = len; if (nbytes > sizeof(buffer)) nbytes = sizeof(buffer); memcpy_P(buffer, p, nbytes); p += nbytes; len -= nbytes; count += write(buffer, nbytes); } return count; } #else void Print::print(const __FlashStringHelper *ifsh) { const char PROGMEM *p = (const char PROGMEM *)ifsh; while (1) { unsigned char c = pgm_read_byte(p++); if (c == 0) return; write(c); } } #endif #if ARDUINO >= 100 size_t Print::print(long n) { uint8_t sign=0; if (n < 0) { sign = 1; n = -n; } return printNumber(n, sign, 10); } #else void Print::print(long n) { uint8_t sign=0; if (n < 0) { sign = 1; n = -n; } printNumber(n, sign, 10); } #endif #if ARDUINO >= 100 size_t Print::println(void) { uint8_t buf[2]={'\r', '\n'}; return write(buf, 2); } #else void Print::println(void) { uint8_t buf[2]={'\r', '\n'}; write(buf, 2); } #endif #if ARDUINO >= 100 static int printf_putchar(char c, FILE *fp) { ((class Print *)(fdev_get_udata(fp)))->write((uint8_t)c); return 0; } int Print::printf(const char *format, ...) { FILE f; va_list ap; fdev_setup_stream(&f, printf_putchar, NULL, _FDEV_SETUP_WRITE); fdev_set_udata(&f, this); va_start(ap, format); return vfprintf(&f, format, ap); } int Print::printf(const __FlashStringHelper *format, ...) { FILE f; va_list ap; fdev_setup_stream(&f, printf_putchar, NULL, _FDEV_SETUP_WRITE); fdev_set_udata(&f, this); va_start(ap, format); return vfprintf_P(&f, (const char *)format, ap); } #endif //#define USE_HACKER_DELIGHT_OPTIMIZATION #define USE_STIMMER_OPTIMIZATION //#define USE_BENCHMARK_CODE #ifdef USE_HACKER_DELIGHT_OPTIMIZATION // Adapted from Hacker's Delight (Henry Warren, ISBN 0321842685) www.hackersdelight.org // by Rob Tillaart, Tom Carpenter, "genom2" with input from others... // http://forum.arduino.cc/index.php?topic=167414.0 // #define divmod10_asm(in32, tmp32, mod8) \ asm volatile ( \ "mov %2, %A0 \n\t" /* mod = in */ \ "ori %A0, 1 \n\t" /* q = in | 1 */ \ "movw %A1, %A0 \n\t" /* x = q */ \ "movw %C1, %C0 \n\t" \ "lsr %D1 \n\t" /* x = x >> 2 */ \ "ror %C1 \n\t" \ "ror %B1 \n\t" \ "ror %A1 \n\t" \ "lsr %D1 \n\t" \ "ror %C1 \n\t" \ "ror %B1 \n\t" \ "ror %A1 \n\t" \ "sub %A0, %A1 \n\t" /* q = q - x */ \ "sbc %B0, %B1 \n\t" \ "sbc %C0, %C1 \n\t" \ "sbc %D0, %D1 \n\t" \ "movw %A1, %A0 \n\t" /* x = q */ \ "movw %C1, %C0 \n\t" \ "lsr %D1 \n\t" /* x = x >> 4 */ \ "ror %C1 \n\t" \ "ror %B1 \n\t" \ "ror %A1 \n\t" \ "lsr %D1 \n\t" \ "ror %C1 \n\t" \ "ror %B1 \n\t" \ "ror %A1 \n\t" \ "lsr %D1 \n\t" \ "ror %C1 \n\t" \ "ror %B1 \n\t" \ "ror %A1 \n\t" \ "lsr %D1 \n\t" \ "ror %C1 \n\t" \ "ror %B1 \n\t" \ "ror %A1 \n\t" \ "add %A1, %A0 \n\t" /* x = x + q */ \ "adc %B1, %B0 \n\t" \ "adc %C1, %C0 \n\t" \ "adc %D1, %D0 \n\t" \ "movw %A0, %A1 \n\t" /* q = x */ \ "movw %C0, %C1 \n\t" \ "add %A0, %B1 \n\t" /* q = q + (x >> 8) */ \ "adc %B0, %C1 \n\t" \ "adc %C0, %D1 \n\t" \ "adc %D0, r1 \n\t" \ "mov %A0, %B0 \n\t" /* q = q >> 8 */ \ "mov %B0, %C0 \n\t" \ "mov %C0, %D0 \n\t" \ "eor %D0, %D0 \n\t" \ "add %A0, %A1 \n\t" /* q = q + x */ \ "adc %B0, %B1 \n\t" \ "adc %C0, %C1 \n\t" \ "adc %D0, %D1 \n\t" \ "mov %A0, %B0 \n\t" /* q = q >> 8 */ \ "mov %B0, %C0 \n\t" \ "mov %C0, %D0 \n\t" \ "eor %D0, %D0 \n\t" \ "add %A0, %A1 \n\t" /* q = q + x */ \ "adc %B0, %B1 \n\t" \ "adc %C0, %C1 \n\t" \ "adc %D0, %D1 \n\t" \ "mov %A0, %B0 \n\t" /* q = q >> 8 */ \ "mov %B0, %C0 \n\t" \ "mov %C0, %D0 \n\t" \ "eor %D0, %D0 \n\t" \ "add %A0, %A1 \n\t" /* q = q + x */ \ "adc %B0, %B1 \n\t" \ "adc %C0, %C1 \n\t" \ "adc %D0, %D1 \n\t" \ "andi %A0, 0xF8 \n\t" /* q = q & ~0x7 */ \ "sub %2, %A0 \n\t" /* mod = mod - q */ \ "lsr %D0 \n\t" /* q = q >> 2 */ \ "ror %C0 \n\t" \ "ror %B0 \n\t" \ "ror %A0 \n\t" \ "lsr %D0 \n\t" \ "ror %C0 \n\t" \ "ror %B0 \n\t" \ "ror %A0 \n\t" \ "sub %2, %A0 \n\t" /* mod = mod - q */ \ "lsr %D0 \n\t" /* q = q >> 1 */ \ "ror %C0 \n\t" \ "ror %B0 \n\t" \ "ror %A0 \n\t" \ : "+d" (in32), "=r" (tmp32), "=r" (mod8) : : "r0" \ ) #endif // USE_HACKER_DELIGHT_OPTIMIZATION #ifdef USE_STIMMER_OPTIMIZATION // http://forum.arduino.cc/index.php?topic=167414.msg1293679#msg1293679 // http://forum.arduino.cc/index.php?topic=167414.msg1309482#msg1309482 // equivelant code: // mod8 = in32 % 10; // in32 = in32 / 10; // tmp8 = 10; #define divmod10_asm(in32, mod8, tmp8) \ asm volatile ( \ " ldi %2,51 \n\t" \ " mul %A0,%2 \n\t" \ " clr %A0 \n\t" \ " add r0,%2 \n\t" \ " adc %A0,r1 \n\t" \ " mov %1,r0 \n\t" \ " mul %B0,%2 \n\t" \ " clr %B0 \n\t" \ " add %A0,r0 \n\t" \ " adc %B0,r1 \n\t" \ " mul %C0,%2 \n\t" \ " clr %C0 \n\t" \ " add %B0,r0 \n\t" \ " adc %C0,r1 \n\t" \ " mul %D0,%2 \n\t" \ " clr %D0 \n\t" \ " add %C0,r0 \n\t" \ " adc %D0,r1 \n\t" \ " clr r1 \n\t" \ " add %1,%A0 \n\t" \ " adc %A0,%B0 \n\t" \ " adc %B0,%C0 \n\t" \ " adc %C0,%D0 \n\t" \ " adc %D0,r1 \n\t" \ " add %1,%B0 \n\t" \ " adc %A0,%C0 \n\t" \ " adc %B0,%D0 \n\t" \ " adc %C0,r1 \n\t" \ " adc %D0,r1 \n\t" \ " add %1,%D0 \n\t" \ " adc %A0,r1 \n\t" \ " adc %B0,r1 \n\t" \ " adc %C0,r1 \n\t" \ " adc %D0,r1 \n\t" \ " lsr %D0 \n\t" \ " ror %C0 \n\t" \ " ror %B0 \n\t" \ " ror %A0 \n\t" \ " ror %1 \n\t" \ " ldi %2,10 \n\t" \ " mul %1,%2 \n\t" \ " mov %1,r1 \n\t" \ " clr r1 \n\t" \ :"+r"(in32),"=d"(mod8),"=d"(tmp8) : : "r0") #endif // USE_STIMMER_OPTIMIZATION #ifdef USE_BENCHMARK_CODE uint32_t usec_print = 0; #endif #if ARDUINO >= 100 size_t Print::printNumberDec(unsigned long n, uint8_t sign) #else void Print::printNumberDec(unsigned long n, uint8_t sign) #endif { uint8_t digit, buf[11], *p; #if defined(USE_HACKER_DELIGHT_OPTIMIZATION) uint32_t tmp32; #elif defined(USE_STIMMER_OPTIMIZATION) uint8_t tmp8; #endif #ifdef USE_BENCHMARK_CODE uint32_t usec = micros(); #endif p = buf + (sizeof(buf)-1); do { #if defined(USE_HACKER_DELIGHT_OPTIMIZATION) divmod10_asm(n, tmp32, digit); #elif defined(USE_STIMMER_OPTIMIZATION) divmod10_asm(n, digit, tmp8); #else tmp32 = n; n = n / 10; digit = tmp32 - n * 10; #endif *--p = digit + '0'; } while (n); if (sign) *--p = '-'; #ifdef USE_BENCHMARK_CODE usec_print += micros() - usec; #endif #if ARDUINO >= 100 return write(p, sizeof(buf)-1 - (p - buf)); #else write(p, sizeof(buf)-1 - (p - buf)); #endif } #if ARDUINO >= 100 size_t Print::printNumberHex(unsigned long n) #else void Print::printNumberHex(unsigned long n) #endif { uint8_t digit, buf[8], *p; p = buf + (sizeof(buf)-1); do { digit = n & 15; *--p = (digit < 10) ? '0' + digit : 'A' + digit - 10; n >>= 4; } while (n); #if ARDUINO >= 100 return write(p, sizeof(buf)-1 - (p - buf)); #else write(p, sizeof(buf)-1 - (p - buf)); #endif } #if ARDUINO >= 100 size_t Print::printNumberBin(unsigned long n) #else void Print::printNumberBin(unsigned long n) #endif { uint8_t buf[32], *p; p = buf + (sizeof(buf)-1); do { *--p = '0' + ((uint8_t)n & 1); n >>= 1; } while (n); #if ARDUINO >= 100 return write(p, sizeof(buf)-1 - (p - buf)); #else write(p, sizeof(buf)-1 - (p - buf)); #endif } #if ARDUINO >= 100 size_t Print::printNumberAny(unsigned long n, uint8_t base) #else void Print::printNumberAny(unsigned long n, uint8_t base) #endif { uint8_t digit, buf[21], *p; uint32_t tmp; //uint32_t usec; //usec = micros(); p = buf + (sizeof(buf)-1); do { tmp = n; n = n / base; digit = tmp - n * base; *--p = (digit < 10) ? '0' + digit : 'A' + digit - 10; } while (n); //usec_print += micros() - usec; #if ARDUINO >= 100 return write(p, sizeof(buf)-1 - (p - buf)); #else write(p, sizeof(buf)-1 - (p - buf)); #endif } #if ARDUINO >= 100 size_t Print::printFloat(double number, uint8_t digits) #else void Print::printFloat(double number, uint8_t digits) #endif { uint8_t sign=0; #if ARDUINO >= 100 size_t count=0; #endif // Handle negative numbers if (number < 0.0) { sign = 1; number = -number; } // Round correctly so that print(1.999, 2) prints as "2.00" double rounding = 0.5; for (uint8_t i=0; i= 100 count += printNumber(int_part, sign, 10); #else printNumber(int_part, sign, 10); #endif // Print the decimal point, but only if there are digits beyond if (digits > 0) { uint8_t n, buf[8], count=1; buf[0] = '.'; // Extract digits from the remainder one at a time if (digits > sizeof(buf) - 1) digits = sizeof(buf) - 1; while (digits-- > 0) { remainder *= 10.0; n = (uint8_t)(remainder); buf[count++] = '0' + n; remainder -= n; } #if ARDUINO >= 100 count += write(buf, count); #else write(buf, count); #endif } #if ARDUINO >= 100 return count; #endif }