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toolchain-gcc-arm-embedded/arm-none-eabi/include/sys/time.h

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  1. /* time.h -- An implementation of the standard Unix <sys/time.h> file.

  2.    Written by Geoffrey Noer <noer@cygnus.com>

  3.    Public domain; no rights reserved. */

  4. 

  5. /*-

  6.  * SPDX-License-Identifier: BSD-3-Clause

  7.  *

  8.  * Copyright (c) 1982, 1986, 1993

  9.  *	The Regents of the University of California.  All rights reserved.

  10.  *

  11.  * Redistribution and use in source and binary forms, with or without

  12.  * modification, are permitted provided that the following conditions

  13.  * are met:

  14.  * 1. Redistributions of source code must retain the above copyright

  15.  *    notice, this list of conditions and the following disclaimer.

  16.  * 2. Redistributions in binary form must reproduce the above copyright

  17.  *    notice, this list of conditions and the following disclaimer in the

  18.  *    documentation and/or other materials provided with the distribution.

  19.  * 3. Neither the name of the University nor the names of its contributors

  20.  *    may be used to endorse or promote products derived from this software

  21.  *    without specific prior written permission.

  22.  *

  23.  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND

  24.  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE

  25.  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE

  26.  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE

  27.  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL

  28.  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS

  29.  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)

  30.  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT

  31.  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY

  32.  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF

  33.  * SUCH DAMAGE.

  34.  *

  35.  *	@(#)time.h	8.5 (Berkeley) 5/4/95

  36.  * $FreeBSD: head/sys/sys/time.h 346176 2019-04-13 04:46:35Z imp $

  37.  */

  38. 

  39. #ifndef _SYS_TIME_H_

  40. #define	_SYS_TIME_H_

  41. 

  42. #include <_ansi.h>

  43. #include <sys/cdefs.h>

  44. #include <sys/_timeval.h>

  45. #include <sys/types.h>

  46. #include <sys/timespec.h>

  47. 

  48. #if __BSD_VISIBLE || __POSIX_VISIBLE >= 200112 || __XSI_VISIBLE

  49. #include <sys/select.h>

  50. #endif

  51. 

  52. struct timezone {

  53. 	int	tz_minuteswest;	/* minutes west of Greenwich */

  54. 	int	tz_dsttime;	/* type of dst correction */

  55. };

  56. #define	DST_NONE	0	/* not on dst */

  57. #define	DST_USA		1	/* USA style dst */

  58. #define	DST_AUST	2	/* Australian style dst */

  59. #define	DST_WET		3	/* Western European dst */

  60. #define	DST_MET		4	/* Middle European dst */

  61. #define	DST_EET		5	/* Eastern European dst */

  62. #define	DST_CAN		6	/* Canada */

  63. 

  64. #if __BSD_VISIBLE

  65. struct bintime {

  66. 	time_t	sec;

  67. 	uint64_t frac;

  68. };

  69. 

  70. static __inline void

  71. bintime_addx(struct bintime *_bt, uint64_t _x)

  72. {

  73. 	uint64_t _u;

  74. 

  75. 	_u = _bt->frac;

  76. 	_bt->frac += _x;

  77. 	if (_u > _bt->frac)

  78. 		_bt->sec++;

  79. }

  80. 

  81. static __inline void

  82. bintime_add(struct bintime *_bt, const struct bintime *_bt2)

  83. {

  84. 	uint64_t _u;

  85. 

  86. 	_u = _bt->frac;

  87. 	_bt->frac += _bt2->frac;

  88. 	if (_u > _bt->frac)

  89. 		_bt->sec++;

  90. 	_bt->sec += _bt2->sec;

  91. }

  92. 

  93. static __inline void

  94. bintime_sub(struct bintime *_bt, const struct bintime *_bt2)

  95. {

  96. 	uint64_t _u;

  97. 

  98. 	_u = _bt->frac;

  99. 	_bt->frac -= _bt2->frac;

  100. 	if (_u < _bt->frac)

  101. 		_bt->sec--;

  102. 	_bt->sec -= _bt2->sec;

  103. }

  104. 

  105. static __inline void

  106. bintime_mul(struct bintime *_bt, u_int _x)

  107. {

  108. 	uint64_t _p1, _p2;

  109. 

  110. 	_p1 = (_bt->frac & 0xffffffffull) * _x;

  111. 	_p2 = (_bt->frac >> 32) * _x + (_p1 >> 32);

  112. 	_bt->sec *= _x;

  113. 	_bt->sec += (_p2 >> 32);

  114. 	_bt->frac = (_p2 << 32) | (_p1 & 0xffffffffull);

  115. }

  116. 

  117. static __inline void

  118. bintime_shift(struct bintime *_bt, int _exp)

  119. {

  120. 

  121. 	if (_exp > 0) {

  122. 		_bt->sec <<= _exp;

  123. 		_bt->sec |= _bt->frac >> (64 - _exp);

  124. 		_bt->frac <<= _exp;

  125. 	} else if (_exp < 0) {

  126. 		_bt->frac >>= -_exp;

  127. 		_bt->frac |= (uint64_t)_bt->sec << (64 + _exp);

  128. 		_bt->sec >>= -_exp;

  129. 	}

  130. }

  131. 

  132. #define	bintime_clear(a)	((a)->sec = (a)->frac = 0)

  133. #define	bintime_isset(a)	((a)->sec || (a)->frac)

  134. #define	bintime_cmp(a, b, cmp)						\

  135. 	(((a)->sec == (b)->sec) ?					\

  136. 	    ((a)->frac cmp (b)->frac) :					\

  137. 	    ((a)->sec cmp (b)->sec))

  138. 

  139. #define	SBT_1S	((sbintime_t)1 << 32)

  140. #define	SBT_1M	(SBT_1S * 60)

  141. #define	SBT_1MS	(SBT_1S / 1000)

  142. #define	SBT_1US	(SBT_1S / 1000000)

  143. #define	SBT_1NS	(SBT_1S / 1000000000) /* beware rounding, see nstosbt() */

  144. #define	SBT_MAX	0x7fffffffffffffffLL

  145. 

  146. static __inline int

  147. sbintime_getsec(sbintime_t _sbt)

  148. {

  149. 

  150. 	return (_sbt >> 32);

  151. }

  152. 

  153. static __inline sbintime_t

  154. bttosbt(const struct bintime _bt)

  155. {

  156. 

  157. 	return (((sbintime_t)_bt.sec << 32) + (_bt.frac >> 32));

  158. }

  159. 

  160. static __inline struct bintime

  161. sbttobt(sbintime_t _sbt)

  162. {

  163. 	struct bintime _bt;

  164. 

  165. 	_bt.sec = _sbt >> 32;

  166. 	_bt.frac = _sbt << 32;

  167. 	return (_bt);

  168. }

  169. 

  170. /*

  171.  * Decimal<->sbt conversions.  Multiplying or dividing by SBT_1NS results in

  172.  * large roundoff errors which sbttons() and nstosbt() avoid.  Millisecond and

  173.  * microsecond functions are also provided for completeness.

  174.  *

  175.  * These functions return the smallest sbt larger or equal to the

  176.  * number of seconds requested so that sbttoX(Xtosbt(y)) == y.  Unlike

  177.  * top of second computations below, which require that we tick at the

  178.  * top of second, these need to be rounded up so we do whatever for at

  179.  * least as long as requested.

  180.  *

  181.  * The naive computation we'd do is this

  182.  *	((unit * 2^64 / SIFACTOR) + 2^32-1) >> 32

  183.  * However, that overflows. Instead, we compute

  184.  *	((unit * 2^63 / SIFACTOR) + 2^31-1) >> 32

  185.  * and use pre-computed constants that are the ceil of the 2^63 / SIFACTOR

  186.  * term to ensure we are using exactly the right constant. We use the lesser

  187.  * evil of ull rather than a uint64_t cast to ensure we have well defined

  188.  * right shift semantics. With these changes, we get all the ns, us and ms

  189.  * conversions back and forth right.

  190.  */

  191. static __inline int64_t

  192. sbttons(sbintime_t _sbt)

  193. {

  194. 	uint64_t ns;

  195. 

  196. 	ns = _sbt;

  197. 	if (ns >= SBT_1S)

  198. 		ns = (ns >> 32) * 1000000000;

  199. 	else

  200. 		ns = 0;

  201. 

  202. 	return (ns + (1000000000 * (_sbt & 0xffffffffu) >> 32));

  203. }

  204. 

  205. static __inline sbintime_t

  206. nstosbt(int64_t _ns)

  207. {

  208. 	sbintime_t sb = 0;

  209. 

  210. 	if (_ns >= SBT_1S) {

  211. 		sb = (_ns / 1000000000) * SBT_1S;

  212. 		_ns = _ns % 1000000000;

  213. 	}

  214. 	/* 9223372037 = ceil(2^63 / 1000000000) */

  215. 	sb += ((_ns * 9223372037ull) + 0x7fffffff) >> 31;

  216. 	return (sb);

  217. }

  218. 

  219. static __inline int64_t

  220. sbttous(sbintime_t _sbt)

  221. {

  222. 

  223. 	return ((1000000 * _sbt) >> 32);

  224. }

  225. 

  226. static __inline sbintime_t

  227. ustosbt(int64_t _us)

  228. {

  229. 	sbintime_t sb = 0;

  230. 

  231. 	if (_us >= SBT_1S) {

  232. 		sb = (_us / 1000000) * SBT_1S;

  233. 		_us = _us % 1000000;

  234. 	}

  235. 	/* 9223372036855 = ceil(2^63 / 1000000) */

  236. 	sb += ((_us * 9223372036855ull) + 0x7fffffff) >> 31;

  237. 	return (sb);

  238. }

  239. 

  240. static __inline int64_t

  241. sbttoms(sbintime_t _sbt)

  242. {

  243. 

  244. 	return ((1000 * _sbt) >> 32);

  245. }

  246. 

  247. static __inline sbintime_t

  248. mstosbt(int64_t _ms)

  249. {

  250. 	sbintime_t sb = 0;

  251. 

  252. 	if (_ms >= SBT_1S) {

  253. 		sb = (_ms / 1000) * SBT_1S;

  254. 		_ms = _ms % 1000;

  255. 	}

  256. 	/* 9223372036854776 = ceil(2^63 / 1000) */

  257. 	sb += ((_ms * 9223372036854776ull) + 0x7fffffff) >> 31;

  258. 	return (sb);

  259. }

  260. 

  261. /*-

  262.  * Background information:

  263.  *

  264.  * When converting between timestamps on parallel timescales of differing

  265.  * resolutions it is historical and scientific practice to round down rather

  266.  * than doing 4/5 rounding.

  267.  *

  268.  *   The date changes at midnight, not at noon.

  269.  *

  270.  *   Even at 15:59:59.999999999 it's not four'o'clock.

  271.  *

  272.  *   time_second ticks after N.999999999 not after N.4999999999

  273.  */

  274. 

  275. static __inline void

  276. bintime2timespec(const struct bintime *_bt, struct timespec *_ts)

  277. {

  278. 

  279. 	_ts->tv_sec = _bt->sec;

  280. 	_ts->tv_nsec = ((uint64_t)1000000000 *

  281. 	    (uint32_t)(_bt->frac >> 32)) >> 32;

  282. }

  283. 

  284. static __inline void

  285. timespec2bintime(const struct timespec *_ts, struct bintime *_bt)

  286. {

  287. 

  288. 	_bt->sec = _ts->tv_sec;

  289. 	/* 18446744073 = int(2^64 / 1000000000) */

  290. 	_bt->frac = _ts->tv_nsec * (uint64_t)18446744073LL;

  291. }

  292. 

  293. static __inline void

  294. bintime2timeval(const struct bintime *_bt, struct timeval *_tv)

  295. {

  296. 

  297. 	_tv->tv_sec = _bt->sec;

  298. 	_tv->tv_usec = ((uint64_t)1000000 * (uint32_t)(_bt->frac >> 32)) >> 32;

  299. }

  300. 

  301. static __inline void

  302. timeval2bintime(const struct timeval *_tv, struct bintime *_bt)

  303. {

  304. 

  305. 	_bt->sec = _tv->tv_sec;

  306. 	/* 18446744073709 = int(2^64 / 1000000) */

  307. 	_bt->frac = _tv->tv_usec * (uint64_t)18446744073709LL;

  308. }

  309. 

  310. static __inline struct timespec

  311. sbttots(sbintime_t _sbt)

  312. {

  313. 	struct timespec _ts;

  314. 

  315. 	_ts.tv_sec = _sbt >> 32;

  316. 	_ts.tv_nsec = sbttons((uint32_t)_sbt);

  317. 	return (_ts);

  318. }

  319. 

  320. static __inline sbintime_t

  321. tstosbt(struct timespec _ts)

  322. {

  323. 

  324. 	return (((sbintime_t)_ts.tv_sec << 32) + nstosbt(_ts.tv_nsec));

  325. }

  326. 

  327. static __inline struct timeval

  328. sbttotv(sbintime_t _sbt)

  329. {

  330. 	struct timeval _tv;

  331. 

  332. 	_tv.tv_sec = _sbt >> 32;

  333. 	_tv.tv_usec = sbttous((uint32_t)_sbt);

  334. 	return (_tv);

  335. }

  336. 

  337. static __inline sbintime_t

  338. tvtosbt(struct timeval _tv)

  339. {

  340. 

  341. 	return (((sbintime_t)_tv.tv_sec << 32) + ustosbt(_tv.tv_usec));

  342. }

  343. 

  344. /* Operations on timespecs */

  345. #define	timespecclear(tvp)	((tvp)->tv_sec = (tvp)->tv_nsec = 0)

  346. #define	timespecisset(tvp)	((tvp)->tv_sec || (tvp)->tv_nsec)

  347. #define	timespeccmp(tvp, uvp, cmp)					\

  348. 	(((tvp)->tv_sec == (uvp)->tv_sec) ?				\

  349. 	    ((tvp)->tv_nsec cmp (uvp)->tv_nsec) :			\

  350. 	    ((tvp)->tv_sec cmp (uvp)->tv_sec))

  351. 

  352. #define	timespecadd(tsp, usp, vsp)					\

  353. 	do {								\

  354. 		(vsp)->tv_sec = (tsp)->tv_sec + (usp)->tv_sec;		\

  355. 		(vsp)->tv_nsec = (tsp)->tv_nsec + (usp)->tv_nsec;	\

  356. 		if ((vsp)->tv_nsec >= 1000000000L) {			\

  357. 			(vsp)->tv_sec++;				\

  358. 			(vsp)->tv_nsec -= 1000000000L;			\

  359. 		}							\

  360. 	} while (0)

  361. #define	timespecsub(tsp, usp, vsp)					\

  362. 	do {								\

  363. 		(vsp)->tv_sec = (tsp)->tv_sec - (usp)->tv_sec;		\

  364. 		(vsp)->tv_nsec = (tsp)->tv_nsec - (usp)->tv_nsec;	\

  365. 		if ((vsp)->tv_nsec < 0) {				\

  366. 			(vsp)->tv_sec--;				\

  367. 			(vsp)->tv_nsec += 1000000000L;			\

  368. 		}							\

  369. 	} while (0)

  370. 

  371. #ifndef _KERNEL			/* NetBSD/OpenBSD compatible interfaces */

  372. 

  373. #define	timerclear(tvp)		((tvp)->tv_sec = (tvp)->tv_usec = 0)

  374. #define	timerisset(tvp)		((tvp)->tv_sec || (tvp)->tv_usec)

  375. #define	timercmp(tvp, uvp, cmp)					\

  376. 	(((tvp)->tv_sec == (uvp)->tv_sec) ?				\

  377. 	    ((tvp)->tv_usec cmp (uvp)->tv_usec) :			\

  378. 	    ((tvp)->tv_sec cmp (uvp)->tv_sec))

  379. #define	timeradd(tvp, uvp, vvp)						\

  380. 	do {								\

  381. 		(vvp)->tv_sec = (tvp)->tv_sec + (uvp)->tv_sec;		\

  382. 		(vvp)->tv_usec = (tvp)->tv_usec + (uvp)->tv_usec;	\

  383. 		if ((vvp)->tv_usec >= 1000000) {			\

  384. 			(vvp)->tv_sec++;				\

  385. 			(vvp)->tv_usec -= 1000000;			\

  386. 		}							\

  387. 	} while (0)

  388. #define	timersub(tvp, uvp, vvp)						\

  389. 	do {								\

  390. 		(vvp)->tv_sec = (tvp)->tv_sec - (uvp)->tv_sec;		\

  391. 		(vvp)->tv_usec = (tvp)->tv_usec - (uvp)->tv_usec;	\

  392. 		if ((vvp)->tv_usec < 0) {				\

  393. 			(vvp)->tv_sec--;				\

  394. 			(vvp)->tv_usec += 1000000;			\

  395. 		}							\

  396. 	} while (0)

  397. #endif

  398. #endif /* __BSD_VISIBLE */

  399. 

  400. /*

  401.  * Names of the interval timers, and structure

  402.  * defining a timer setting.

  403.  */

  404. #define	ITIMER_REAL	0

  405. #define	ITIMER_VIRTUAL	1

  406. #define	ITIMER_PROF	2

  407. 

  408. struct itimerval {

  409. 	struct	timeval it_interval;	/* timer interval */

  410. 	struct	timeval it_value;	/* current value */

  411. };

  412. 

  413. #ifndef _KERNEL

  414. #include <time.h>

  415. 

  416. __BEGIN_DECLS

  417. int utimes (const char *__path, const struct timeval *__tvp);

  418. 

  419. #if __BSD_VISIBLE

  420. int adjtime (const struct timeval *, struct timeval *);

  421. int futimes (int, const struct timeval *);

  422. int lutimes (const char *, const struct timeval *);

  423. int settimeofday (const struct timeval *, const struct timezone *);

  424. #endif

  425. 

  426. #if __MISC_VISIBLE || __XSI_VISIBLE

  427. int getitimer (int __which, struct itimerval *__value);

  428. int setitimer (int __which, const struct itimerval *__restrict __value,

  429. 					struct itimerval *__restrict __ovalue);

  430. #endif

  431. 

  432. int gettimeofday (struct timeval *__restrict __p,

  433. 			  void *__restrict __tz);

  434. 

  435. #if __GNU_VISIBLE

  436. int futimesat (int, const char *, const struct timeval [2]);

  437. #endif

  438. 

  439. #ifdef _COMPILING_NEWLIB

  440. int _gettimeofday (struct timeval *__p, void *__tz);

  441. #endif

  442. 

  443. __END_DECLS

  444. 

  445. #endif /* !_KERNEL */

  446. #include <machine/_time.h>

  447. 

  448. #endif /* !_SYS_TIME_H_ */