1 /*- 2 * SPDX-License-Identifier: BSD-3-Clause 3 * 4 * Copyright (c) 1982, 1986, 1993 5 * The Regents of the University of California. All rights reserved. 6 * 7 * Redistribution and use in source and binary forms, with or without 8 * modification, are permitted provided that the following conditions 9 * are met: 10 * 1. Redistributions of source code must retain the above copyright 11 * notice, this list of conditions and the following disclaimer. 12 * 2. Redistributions in binary form must reproduce the above copyright 13 * notice, this list of conditions and the following disclaimer in the 14 * documentation and/or other materials provided with the distribution. 15 * 3. Neither the name of the University nor the names of its contributors 16 * may be used to endorse or promote products derived from this software 17 * without specific prior written permission. 18 * 19 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 20 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 21 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 22 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 23 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 24 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 25 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 26 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 27 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 28 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 29 * SUCH DAMAGE. 30 * 31 * @(#)time.h 8.5 (Berkeley) 5/4/95 32 * $FreeBSD$ 33 */ 34 35 #ifndef _SYS_TIME_H_ 36 #define _SYS_TIME_H_ 37 38 #include <sys/_timeval.h> 39 #include <sys/types.h> 40 #include <sys/timespec.h> 41 #include <sys/_clock_id.h> 42 43 struct timezone { 44 int tz_minuteswest; /* minutes west of Greenwich */ 45 int tz_dsttime; /* type of dst correction */ 46 }; 47 #define DST_NONE 0 /* not on dst */ 48 #define DST_USA 1 /* USA style dst */ 49 #define DST_AUST 2 /* Australian style dst */ 50 #define DST_WET 3 /* Western European dst */ 51 #define DST_MET 4 /* Middle European dst */ 52 #define DST_EET 5 /* Eastern European dst */ 53 #define DST_CAN 6 /* Canada */ 54 55 #if __BSD_VISIBLE 56 struct bintime { 57 time_t sec; 58 uint64_t frac; 59 }; 60 61 static __inline void 62 bintime_addx(struct bintime *_bt, uint64_t _x) 63 { 64 uint64_t _u; 65 66 _u = _bt->frac; 67 _bt->frac += _x; 68 if (_u > _bt->frac) 69 _bt->sec++; 70 } 71 72 static __inline void 73 bintime_add(struct bintime *_bt, const struct bintime *_bt2) 74 { 75 uint64_t _u; 76 77 _u = _bt->frac; 78 _bt->frac += _bt2->frac; 79 if (_u > _bt->frac) 80 _bt->sec++; 81 _bt->sec += _bt2->sec; 82 } 83 84 static __inline void 85 bintime_sub(struct bintime *_bt, const struct bintime *_bt2) 86 { 87 uint64_t _u; 88 89 _u = _bt->frac; 90 _bt->frac -= _bt2->frac; 91 if (_u < _bt->frac) 92 _bt->sec--; 93 _bt->sec -= _bt2->sec; 94 } 95 96 static __inline void 97 bintime_mul(struct bintime *_bt, u_int _x) 98 { 99 uint64_t _p1, _p2; 100 101 _p1 = (_bt->frac & 0xffffffffull) * _x; 102 _p2 = (_bt->frac >> 32) * _x + (_p1 >> 32); 103 _bt->sec *= _x; 104 _bt->sec += (_p2 >> 32); 105 _bt->frac = (_p2 << 32) | (_p1 & 0xffffffffull); 106 } 107 108 static __inline void 109 bintime_shift(struct bintime *_bt, int _exp) 110 { 111 112 if (_exp > 0) { 113 _bt->sec <<= _exp; 114 _bt->sec |= _bt->frac >> (64 - _exp); 115 _bt->frac <<= _exp; 116 } else if (_exp < 0) { 117 _bt->frac >>= -_exp; 118 _bt->frac |= (uint64_t)_bt->sec << (64 + _exp); 119 _bt->sec >>= -_exp; 120 } 121 } 122 123 #define bintime_clear(a) ((a)->sec = (a)->frac = 0) 124 #define bintime_isset(a) ((a)->sec || (a)->frac) 125 #define bintime_cmp(a, b, cmp) \ 126 (((a)->sec == (b)->sec) ? \ 127 ((a)->frac cmp (b)->frac) : \ 128 ((a)->sec cmp (b)->sec)) 129 130 #define SBT_1S ((sbintime_t)1 << 32) 131 #define SBT_1M (SBT_1S * 60) 132 #define SBT_1MS (SBT_1S / 1000) 133 #define SBT_1US (SBT_1S / 1000000) 134 #define SBT_1NS (SBT_1S / 1000000000) /* beware rounding, see nstosbt() */ 135 #define SBT_MAX 0x7fffffffffffffffLL 136 137 static __inline int 138 sbintime_getsec(sbintime_t _sbt) 139 { 140 141 return (_sbt >> 32); 142 } 143 144 static __inline sbintime_t 145 bttosbt(const struct bintime _bt) 146 { 147 148 return (((sbintime_t)_bt.sec << 32) + (_bt.frac >> 32)); 149 } 150 151 static __inline struct bintime 152 sbttobt(sbintime_t _sbt) 153 { 154 struct bintime _bt; 155 156 _bt.sec = _sbt >> 32; 157 _bt.frac = _sbt << 32; 158 return (_bt); 159 } 160 161 /* 162 * Scaling functions for signed and unsigned 64-bit time using any 163 * 32-bit fraction: 164 */ 165 166 static __inline int64_t 167 __stime64_scale32_ceil(int64_t x, int32_t factor, int32_t divisor) 168 { 169 const int64_t rem = x % divisor; 170 171 return (x / divisor * factor + (rem * factor + divisor - 1) / divisor); 172 } 173 174 static __inline int64_t 175 __stime64_scale32_floor(int64_t x, int32_t factor, int32_t divisor) 176 { 177 const int64_t rem = x % divisor; 178 179 return (x / divisor * factor + (rem * factor) / divisor); 180 } 181 182 static __inline uint64_t 183 __utime64_scale32_ceil(uint64_t x, uint32_t factor, uint32_t divisor) 184 { 185 const uint64_t rem = x % divisor; 186 187 return (x / divisor * factor + (rem * factor + divisor - 1) / divisor); 188 } 189 190 static __inline uint64_t 191 __utime64_scale32_floor(uint64_t x, uint32_t factor, uint32_t divisor) 192 { 193 const uint64_t rem = x % divisor; 194 195 return (x / divisor * factor + (rem * factor) / divisor); 196 } 197 198 /* 199 * This function finds the common divisor between the two arguments, 200 * in powers of two. Use a macro, so the compiler will output a 201 * warning if the value overflows! 202 * 203 * Detailed description: 204 * 205 * Create a variable with 1's at the positions of the leading 0's 206 * starting at the least significant bit, producing 0 if none (e.g., 207 * 01011000 -> 0000 0111). Then these two variables are bitwise AND'ed 208 * together, to produce the greatest common power of two minus one. In 209 * the end add one to flip the value to the actual power of two (e.g., 210 * 0000 0111 + 1 -> 0000 1000). 211 */ 212 #define __common_powers_of_two(a, b) \ 213 ((~(a) & ((a) - 1) & ~(b) & ((b) - 1)) + 1) 214 215 /* 216 * Scaling functions for signed and unsigned 64-bit time assuming 217 * reducable 64-bit fractions to 32-bit fractions: 218 */ 219 220 static __inline int64_t 221 __stime64_scale64_ceil(int64_t x, int64_t factor, int64_t divisor) 222 { 223 const int64_t gcd = __common_powers_of_two(factor, divisor); 224 225 return (__stime64_scale32_ceil(x, factor / gcd, divisor / gcd)); 226 } 227 228 static __inline int64_t 229 __stime64_scale64_floor(int64_t x, int64_t factor, int64_t divisor) 230 { 231 const int64_t gcd = __common_powers_of_two(factor, divisor); 232 233 return (__stime64_scale32_floor(x, factor / gcd, divisor / gcd)); 234 } 235 236 static __inline uint64_t 237 __utime64_scale64_ceil(uint64_t x, uint64_t factor, uint64_t divisor) 238 { 239 const uint64_t gcd = __common_powers_of_two(factor, divisor); 240 241 return (__utime64_scale32_ceil(x, factor / gcd, divisor / gcd)); 242 } 243 244 static __inline uint64_t 245 __utime64_scale64_floor(uint64_t x, uint64_t factor, uint64_t divisor) 246 { 247 const uint64_t gcd = __common_powers_of_two(factor, divisor); 248 249 return (__utime64_scale32_floor(x, factor / gcd, divisor / gcd)); 250 } 251 252 /* 253 * Decimal<->sbt conversions. Multiplying or dividing by SBT_1NS 254 * results in large roundoff errors which sbttons() and nstosbt() 255 * avoid. Millisecond and microsecond functions are also provided for 256 * completeness. 257 * 258 * When converting from sbt to another unit, the result is always 259 * rounded down. When converting back to sbt the result is always 260 * rounded up. This gives the property that sbttoX(Xtosbt(y)) == y . 261 * 262 * The conversion functions can also handle negative values. 263 */ 264 #define SBT_DECLARE_CONVERSION_PAIR(name, units_per_second) \ 265 static __inline int64_t \ 266 sbtto##name(sbintime_t sbt) \ 267 { \ 268 return (__stime64_scale64_floor(sbt, units_per_second, SBT_1S)); \ 269 } \ 270 static __inline sbintime_t \ 271 name##tosbt(int64_t name) \ 272 { \ 273 return (__stime64_scale64_ceil(name, SBT_1S, units_per_second)); \ 274 } 275 276 SBT_DECLARE_CONVERSION_PAIR(ns, 1000000000) 277 SBT_DECLARE_CONVERSION_PAIR(us, 1000000) 278 SBT_DECLARE_CONVERSION_PAIR(ms, 1000) 279 280 /*- 281 * Background information: 282 * 283 * When converting between timestamps on parallel timescales of differing 284 * resolutions it is historical and scientific practice to round down rather 285 * than doing 4/5 rounding. 286 * 287 * The date changes at midnight, not at noon. 288 * 289 * Even at 15:59:59.999999999 it's not four'o'clock. 290 * 291 * time_second ticks after N.999999999 not after N.4999999999 292 */ 293 294 static __inline void 295 bintime2timespec(const struct bintime *_bt, struct timespec *_ts) 296 { 297 298 _ts->tv_sec = _bt->sec; 299 _ts->tv_nsec = __utime64_scale64_floor( 300 _bt->frac, 1000000000, 1ULL << 32) >> 32; 301 } 302 303 static __inline uint64_t 304 bintime2ns(const struct bintime *_bt) 305 { 306 uint64_t ret; 307 308 ret = (uint64_t)(_bt->sec) * (uint64_t)1000000000; 309 ret += __utime64_scale64_floor( 310 _bt->frac, 1000000000, 1ULL << 32) >> 32; 311 return (ret); 312 } 313 314 static __inline void 315 timespec2bintime(const struct timespec *_ts, struct bintime *_bt) 316 { 317 318 _bt->sec = _ts->tv_sec; 319 _bt->frac = __utime64_scale64_floor( 320 (uint64_t)_ts->tv_nsec << 32, 1ULL << 32, 1000000000); 321 } 322 323 static __inline void 324 bintime2timeval(const struct bintime *_bt, struct timeval *_tv) 325 { 326 327 _tv->tv_sec = _bt->sec; 328 _tv->tv_usec = __utime64_scale64_floor( 329 _bt->frac, 1000000, 1ULL << 32) >> 32; 330 } 331 332 static __inline void 333 timeval2bintime(const struct timeval *_tv, struct bintime *_bt) 334 { 335 336 _bt->sec = _tv->tv_sec; 337 _bt->frac = __utime64_scale64_floor( 338 (uint64_t)_tv->tv_usec << 32, 1ULL << 32, 1000000); 339 } 340 341 static __inline struct timespec 342 sbttots(sbintime_t _sbt) 343 { 344 struct timespec _ts; 345 346 _ts.tv_sec = _sbt >> 32; 347 _ts.tv_nsec = sbttons((uint32_t)_sbt); 348 return (_ts); 349 } 350 351 static __inline sbintime_t 352 tstosbt(struct timespec _ts) 353 { 354 355 return (((sbintime_t)_ts.tv_sec << 32) + nstosbt(_ts.tv_nsec)); 356 } 357 358 static __inline struct timeval 359 sbttotv(sbintime_t _sbt) 360 { 361 struct timeval _tv; 362 363 _tv.tv_sec = _sbt >> 32; 364 _tv.tv_usec = sbttous((uint32_t)_sbt); 365 return (_tv); 366 } 367 368 static __inline sbintime_t 369 tvtosbt(struct timeval _tv) 370 { 371 372 return (((sbintime_t)_tv.tv_sec << 32) + ustosbt(_tv.tv_usec)); 373 } 374 #endif /* __BSD_VISIBLE */ 375 376 #ifdef _KERNEL 377 /* 378 * Simple macros to convert ticks to milliseconds 379 * or microseconds and vice-versa. The answer 380 * will always be at least 1. Note the return 381 * value is a uint32_t however we step up the 382 * operations to 64 bit to avoid any overflow/underflow 383 * problems. 384 */ 385 #define TICKS_2_MSEC(t) max(1, (uint32_t)(hz == 1000) ? \ 386 (t) : (((uint64_t)(t) * (uint64_t)1000)/(uint64_t)hz)) 387 #define TICKS_2_USEC(t) max(1, (uint32_t)(hz == 1000) ? \ 388 ((t) * 1000) : (((uint64_t)(t) * (uint64_t)1000000)/(uint64_t)hz)) 389 #define MSEC_2_TICKS(m) max(1, (uint32_t)((hz == 1000) ? \ 390 (m) : ((uint64_t)(m) * (uint64_t)hz)/(uint64_t)1000)) 391 #define USEC_2_TICKS(u) max(1, (uint32_t)((hz == 1000) ? \ 392 ((u) / 1000) : ((uint64_t)(u) * (uint64_t)hz)/(uint64_t)1000000)) 393 394 #endif 395 /* Operations on timespecs */ 396 #define timespecclear(tvp) ((tvp)->tv_sec = (tvp)->tv_nsec = 0) 397 #define timespecisset(tvp) ((tvp)->tv_sec || (tvp)->tv_nsec) 398 #define timespeccmp(tvp, uvp, cmp) \ 399 (((tvp)->tv_sec == (uvp)->tv_sec) ? \ 400 ((tvp)->tv_nsec cmp (uvp)->tv_nsec) : \ 401 ((tvp)->tv_sec cmp (uvp)->tv_sec)) 402 403 #define timespecadd(tsp, usp, vsp) \ 404 do { \ 405 (vsp)->tv_sec = (tsp)->tv_sec + (usp)->tv_sec; \ 406 (vsp)->tv_nsec = (tsp)->tv_nsec + (usp)->tv_nsec; \ 407 if ((vsp)->tv_nsec >= 1000000000L) { \ 408 (vsp)->tv_sec++; \ 409 (vsp)->tv_nsec -= 1000000000L; \ 410 } \ 411 } while (0) 412 #define timespecsub(tsp, usp, vsp) \ 413 do { \ 414 (vsp)->tv_sec = (tsp)->tv_sec - (usp)->tv_sec; \ 415 (vsp)->tv_nsec = (tsp)->tv_nsec - (usp)->tv_nsec; \ 416 if ((vsp)->tv_nsec < 0) { \ 417 (vsp)->tv_sec--; \ 418 (vsp)->tv_nsec += 1000000000L; \ 419 } \ 420 } while (0) 421 #define timespecvalid_interval(tsp) ((tsp)->tv_sec >= 0 && \ 422 (tsp)->tv_nsec >= 0 && (tsp)->tv_nsec < 1000000000L) 423 424 #ifdef _KERNEL 425 426 /* Operations on timevals. */ 427 428 #define timevalclear(tvp) ((tvp)->tv_sec = (tvp)->tv_usec = 0) 429 #define timevalisset(tvp) ((tvp)->tv_sec || (tvp)->tv_usec) 430 #define timevalcmp(tvp, uvp, cmp) \ 431 (((tvp)->tv_sec == (uvp)->tv_sec) ? \ 432 ((tvp)->tv_usec cmp (uvp)->tv_usec) : \ 433 ((tvp)->tv_sec cmp (uvp)->tv_sec)) 434 435 /* timevaladd and timevalsub are not inlined */ 436 437 #endif /* _KERNEL */ 438 439 #ifndef _KERNEL /* NetBSD/OpenBSD compatible interfaces */ 440 441 #define timerclear(tvp) ((tvp)->tv_sec = (tvp)->tv_usec = 0) 442 #define timerisset(tvp) ((tvp)->tv_sec || (tvp)->tv_usec) 443 #define timercmp(tvp, uvp, cmp) \ 444 (((tvp)->tv_sec == (uvp)->tv_sec) ? \ 445 ((tvp)->tv_usec cmp (uvp)->tv_usec) : \ 446 ((tvp)->tv_sec cmp (uvp)->tv_sec)) 447 #define timeradd(tvp, uvp, vvp) \ 448 do { \ 449 (vvp)->tv_sec = (tvp)->tv_sec + (uvp)->tv_sec; \ 450 (vvp)->tv_usec = (tvp)->tv_usec + (uvp)->tv_usec; \ 451 if ((vvp)->tv_usec >= 1000000) { \ 452 (vvp)->tv_sec++; \ 453 (vvp)->tv_usec -= 1000000; \ 454 } \ 455 } while (0) 456 #define timersub(tvp, uvp, vvp) \ 457 do { \ 458 (vvp)->tv_sec = (tvp)->tv_sec - (uvp)->tv_sec; \ 459 (vvp)->tv_usec = (tvp)->tv_usec - (uvp)->tv_usec; \ 460 if ((vvp)->tv_usec < 0) { \ 461 (vvp)->tv_sec--; \ 462 (vvp)->tv_usec += 1000000; \ 463 } \ 464 } while (0) 465 #endif 466 467 /* 468 * Names of the interval timers, and structure 469 * defining a timer setting. 470 */ 471 #define ITIMER_REAL 0 472 #define ITIMER_VIRTUAL 1 473 #define ITIMER_PROF 2 474 475 struct itimerval { 476 struct timeval it_interval; /* timer interval */ 477 struct timeval it_value; /* current value */ 478 }; 479 480 /* 481 * Getkerninfo clock information structure 482 */ 483 struct clockinfo { 484 int hz; /* clock frequency */ 485 int tick; /* micro-seconds per hz tick */ 486 int spare; 487 int stathz; /* statistics clock frequency */ 488 int profhz; /* profiling clock frequency */ 489 }; 490 491 #if __BSD_VISIBLE 492 #define CPUCLOCK_WHICH_PID 0 493 #define CPUCLOCK_WHICH_TID 1 494 #endif 495 496 #if defined(_KERNEL) || defined(_STANDALONE) 497 498 /* 499 * Kernel to clock driver interface. 500 */ 501 void inittodr(time_t base); 502 void resettodr(void); 503 504 extern volatile time_t time_second; 505 extern volatile time_t time_uptime; 506 extern struct bintime tc_tick_bt; 507 extern sbintime_t tc_tick_sbt; 508 extern time_t tick_seconds_max; 509 extern struct bintime tick_bt; 510 extern sbintime_t tick_sbt; 511 extern int tc_precexp; 512 extern int tc_timepercentage; 513 extern struct bintime bt_timethreshold; 514 extern struct bintime bt_tickthreshold; 515 extern sbintime_t sbt_timethreshold; 516 extern sbintime_t sbt_tickthreshold; 517 518 extern volatile int rtc_generation; 519 520 /* 521 * Functions for looking at our clock: [get]{bin,nano,micro}[up]time() 522 * 523 * Functions without the "get" prefix returns the best timestamp 524 * we can produce in the given format. 525 * 526 * "bin" == struct bintime == seconds + 64 bit fraction of seconds. 527 * "nano" == struct timespec == seconds + nanoseconds. 528 * "micro" == struct timeval == seconds + microseconds. 529 * 530 * Functions containing "up" returns time relative to boot and 531 * should be used for calculating time intervals. 532 * 533 * Functions without "up" returns UTC time. 534 * 535 * Functions with the "get" prefix returns a less precise result 536 * much faster than the functions without "get" prefix and should 537 * be used where a precision of 1/hz seconds is acceptable or where 538 * performance is priority. (NB: "precision", _not_ "resolution" !) 539 */ 540 541 void binuptime(struct bintime *bt); 542 void nanouptime(struct timespec *tsp); 543 void microuptime(struct timeval *tvp); 544 545 static __inline sbintime_t 546 sbinuptime(void) 547 { 548 struct bintime _bt; 549 550 binuptime(&_bt); 551 return (bttosbt(_bt)); 552 } 553 554 void bintime(struct bintime *bt); 555 void nanotime(struct timespec *tsp); 556 void microtime(struct timeval *tvp); 557 558 void getbinuptime(struct bintime *bt); 559 void getnanouptime(struct timespec *tsp); 560 void getmicrouptime(struct timeval *tvp); 561 562 static __inline sbintime_t 563 getsbinuptime(void) 564 { 565 struct bintime _bt; 566 567 getbinuptime(&_bt); 568 return (bttosbt(_bt)); 569 } 570 571 void getbintime(struct bintime *bt); 572 void getnanotime(struct timespec *tsp); 573 void getmicrotime(struct timeval *tvp); 574 575 void getboottime(struct timeval *boottime); 576 void getboottimebin(struct bintime *boottimebin); 577 578 /* Other functions */ 579 int itimerdecr(struct itimerval *itp, int usec); 580 int itimerfix(struct timeval *tv); 581 int ppsratecheck(struct timeval *, int *, int); 582 int ratecheck(struct timeval *, const struct timeval *); 583 void timevaladd(struct timeval *t1, const struct timeval *t2); 584 void timevalsub(struct timeval *t1, const struct timeval *t2); 585 int tvtohz(struct timeval *tv); 586 587 /* 588 * The following HZ limits allow the tvtohz() function 589 * to only use integer computations. 590 */ 591 #define HZ_MAXIMUM (INT_MAX / (1000000 >> 6)) /* 137kHz */ 592 #define HZ_MINIMUM 8 /* hz */ 593 594 #define TC_DEFAULTPERC 5 595 596 #define BT2FREQ(bt) \ 597 (((uint64_t)0x8000000000000000 + ((bt)->frac >> 2)) / \ 598 ((bt)->frac >> 1)) 599 600 #define SBT2FREQ(sbt) ((SBT_1S + ((sbt) >> 1)) / (sbt)) 601 602 #define FREQ2BT(freq, bt) \ 603 { \ 604 (bt)->sec = 0; \ 605 (bt)->frac = ((uint64_t)0x8000000000000000 / (freq)) << 1; \ 606 } 607 608 #define TIMESEL(sbt, sbt2) \ 609 (((sbt2) >= sbt_timethreshold) ? \ 610 ((*(sbt) = getsbinuptime()), 1) : ((*(sbt) = sbinuptime()), 0)) 611 612 #else /* !_KERNEL && !_STANDALONE */ 613 #include <time.h> 614 615 #include <sys/cdefs.h> 616 #include <sys/select.h> 617 618 __BEGIN_DECLS 619 int setitimer(int, const struct itimerval *, struct itimerval *); 620 int utimes(const char *, const struct timeval *); 621 622 #if __BSD_VISIBLE 623 int adjtime(const struct timeval *, struct timeval *); 624 int clock_getcpuclockid2(id_t, int, clockid_t *); 625 int futimes(int, const struct timeval *); 626 int futimesat(int, const char *, const struct timeval [2]); 627 int lutimes(const char *, const struct timeval *); 628 int settimeofday(const struct timeval *, const struct timezone *); 629 #endif 630 631 #if __XSI_VISIBLE 632 int getitimer(int, struct itimerval *); 633 int gettimeofday(struct timeval *, struct timezone *); 634 #endif 635 636 __END_DECLS 637 638 #endif /* !_KERNEL */ 639 640 #endif /* !_SYS_TIME_H_ */ 641