samba-tool: Enable comparison of DNS naming contexts in ldapcmp
[Samba.git] / lib / util / time.c
blob7216ea6e08bf06b911100abed6bd158afa7fea97
1 /*
2 Unix SMB/CIFS implementation.
3 time handling functions
5 Copyright (C) Andrew Tridgell 1992-2004
6 Copyright (C) Stefan (metze) Metzmacher 2002
7 Copyright (C) Jeremy Allison 2007
8 Copyright (C) Andrew Bartlett 2011
10 This program is free software; you can redistribute it and/or modify
11 it under the terms of the GNU General Public License as published by
12 the Free Software Foundation; either version 3 of the License, or
13 (at your option) any later version.
15 This program is distributed in the hope that it will be useful,
16 but WITHOUT ANY WARRANTY; without even the implied warranty of
17 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18 GNU General Public License for more details.
20 You should have received a copy of the GNU General Public License
21 along with this program. If not, see <http://www.gnu.org/licenses/>.
24 #include "includes.h"
25 #include "system/time.h"
27 /**
28 * @file
29 * @brief time handling functions
32 #if (SIZEOF_LONG == 8)
33 #define TIME_FIXUP_CONSTANT_INT 11644473600L
34 #elif (SIZEOF_LONG_LONG == 8)
35 #define TIME_FIXUP_CONSTANT_INT 11644473600LL
36 #endif
40 /**
41 External access to time_t_min and time_t_max.
42 **/
43 _PUBLIC_ time_t get_time_t_max(void)
45 return TIME_T_MAX;
48 /**
49 a gettimeofday wrapper
50 **/
51 _PUBLIC_ void GetTimeOfDay(struct timeval *tval)
53 #ifdef HAVE_GETTIMEOFDAY_TZ
54 gettimeofday(tval,NULL);
55 #else
56 gettimeofday(tval);
57 #endif
60 /**
61 a wrapper to preferably get the monotonic time
62 **/
63 _PUBLIC_ void clock_gettime_mono(struct timespec *tp)
65 if (clock_gettime(CUSTOM_CLOCK_MONOTONIC,tp) != 0) {
66 clock_gettime(CLOCK_REALTIME,tp);
70 /**
71 a wrapper to preferably get the monotonic time in seconds
72 as this is only second resolution we can use the cached
73 (and much faster) COARSE clock variant
74 **/
75 _PUBLIC_ time_t time_mono(time_t *t)
77 struct timespec tp;
78 int rc = -1;
79 #ifdef CLOCK_MONOTONIC_COARSE
80 rc = clock_gettime(CLOCK_MONOTONIC_COARSE,&tp);
81 #endif
82 if (rc != 0) {
83 clock_gettime_mono(&tp);
85 if (t != NULL) {
86 *t = tp.tv_sec;
88 return tp.tv_sec;
92 #define TIME_FIXUP_CONSTANT 11644473600LL
94 time_t convert_timespec_to_time_t(struct timespec ts)
96 /* Ensure tv_nsec is less than 1sec. */
97 while (ts.tv_nsec > 1000000000) {
98 ts.tv_sec += 1;
99 ts.tv_nsec -= 1000000000;
102 /* 1 ns == 1,000,000,000 - one thousand millionths of a second.
103 increment if it's greater than 500 millionth of a second. */
105 if (ts.tv_nsec > 500000000) {
106 return ts.tv_sec + 1;
108 return ts.tv_sec;
111 struct timespec convert_time_t_to_timespec(time_t t)
113 struct timespec ts;
114 ts.tv_sec = t;
115 ts.tv_nsec = 0;
116 return ts;
122 Interpret an 8 byte "filetime" structure to a time_t
123 It's originally in "100ns units since jan 1st 1601"
125 An 8 byte value of 0xffffffffffffffff will be returned as a timespec of
127 tv_sec = 0
128 tv_nsec = 0;
130 Returns GMT.
132 time_t nt_time_to_unix(NTTIME nt)
134 return convert_timespec_to_time_t(nt_time_to_unix_timespec(&nt));
139 put a 8 byte filetime from a time_t
140 This takes GMT as input
142 _PUBLIC_ void unix_to_nt_time(NTTIME *nt, time_t t)
144 uint64_t t2;
146 if (t == (time_t)-1) {
147 *nt = (NTTIME)-1LL;
148 return;
151 if (t == TIME_T_MAX) {
152 *nt = 0x7fffffffffffffffLL;
153 return;
156 if (t == 0) {
157 *nt = 0;
158 return;
161 t2 = t;
162 t2 += TIME_FIXUP_CONSTANT_INT;
163 t2 *= 1000*1000*10;
165 *nt = t2;
170 check if it's a null unix time
172 _PUBLIC_ bool null_time(time_t t)
174 return t == 0 ||
175 t == (time_t)0xFFFFFFFF ||
176 t == (time_t)-1;
181 check if it's a null NTTIME
183 _PUBLIC_ bool null_nttime(NTTIME t)
185 return t == 0 || t == (NTTIME)-1;
188 /*******************************************************************
189 create a 16 bit dos packed date
190 ********************************************************************/
191 static uint16_t make_dos_date1(struct tm *t)
193 uint16_t ret=0;
194 ret = (((unsigned int)(t->tm_mon+1)) >> 3) | ((t->tm_year-80) << 1);
195 ret = ((ret&0xFF)<<8) | (t->tm_mday | (((t->tm_mon+1) & 0x7) << 5));
196 return ret;
199 /*******************************************************************
200 create a 16 bit dos packed time
201 ********************************************************************/
202 static uint16_t make_dos_time1(struct tm *t)
204 uint16_t ret=0;
205 ret = ((((unsigned int)t->tm_min >> 3)&0x7) | (((unsigned int)t->tm_hour) << 3));
206 ret = ((ret&0xFF)<<8) | ((t->tm_sec/2) | ((t->tm_min & 0x7) << 5));
207 return ret;
210 /*******************************************************************
211 create a 32 bit dos packed date/time from some parameters
212 This takes a GMT time and returns a packed localtime structure
213 ********************************************************************/
214 static uint32_t make_dos_date(time_t unixdate, int zone_offset)
216 struct tm *t;
217 uint32_t ret=0;
219 if (unixdate == 0) {
220 return 0;
223 unixdate -= zone_offset;
225 t = gmtime(&unixdate);
226 if (!t) {
227 return 0xFFFFFFFF;
230 ret = make_dos_date1(t);
231 ret = ((ret&0xFFFF)<<16) | make_dos_time1(t);
233 return ret;
237 put a dos date into a buffer (time/date format)
238 This takes GMT time and puts local time in the buffer
240 _PUBLIC_ void push_dos_date(uint8_t *buf, int offset, time_t unixdate, int zone_offset)
242 uint32_t x = make_dos_date(unixdate, zone_offset);
243 SIVAL(buf,offset,x);
247 put a dos date into a buffer (date/time format)
248 This takes GMT time and puts local time in the buffer
250 _PUBLIC_ void push_dos_date2(uint8_t *buf,int offset,time_t unixdate, int zone_offset)
252 uint32_t x;
253 x = make_dos_date(unixdate, zone_offset);
254 x = ((x&0xFFFF)<<16) | ((x&0xFFFF0000)>>16);
255 SIVAL(buf,offset,x);
259 put a dos 32 bit "unix like" date into a buffer. This routine takes
260 GMT and converts it to LOCAL time before putting it (most SMBs assume
261 localtime for this sort of date)
263 _PUBLIC_ void push_dos_date3(uint8_t *buf,int offset,time_t unixdate, int zone_offset)
265 if (!null_time(unixdate)) {
266 unixdate -= zone_offset;
268 SIVAL(buf,offset,unixdate);
271 /*******************************************************************
272 interpret a 32 bit dos packed date/time to some parameters
273 ********************************************************************/
274 void interpret_dos_date(uint32_t date,int *year,int *month,int *day,int *hour,int *minute,int *second)
276 uint32_t p0,p1,p2,p3;
278 p0=date&0xFF; p1=((date&0xFF00)>>8)&0xFF;
279 p2=((date&0xFF0000)>>16)&0xFF; p3=((date&0xFF000000)>>24)&0xFF;
281 *second = 2*(p0 & 0x1F);
282 *minute = ((p0>>5)&0xFF) + ((p1&0x7)<<3);
283 *hour = (p1>>3)&0xFF;
284 *day = (p2&0x1F);
285 *month = ((p2>>5)&0xFF) + ((p3&0x1)<<3) - 1;
286 *year = ((p3>>1)&0xFF) + 80;
290 create a unix date (int GMT) from a dos date (which is actually in
291 localtime)
293 _PUBLIC_ time_t pull_dos_date(const uint8_t *date_ptr, int zone_offset)
295 uint32_t dos_date=0;
296 struct tm t;
297 time_t ret;
299 dos_date = IVAL(date_ptr,0);
301 if (dos_date == 0) return (time_t)0;
303 interpret_dos_date(dos_date,&t.tm_year,&t.tm_mon,
304 &t.tm_mday,&t.tm_hour,&t.tm_min,&t.tm_sec);
305 t.tm_isdst = -1;
307 ret = timegm(&t);
309 ret += zone_offset;
311 return ret;
315 like make_unix_date() but the words are reversed
317 _PUBLIC_ time_t pull_dos_date2(const uint8_t *date_ptr, int zone_offset)
319 uint32_t x,x2;
321 x = IVAL(date_ptr,0);
322 x2 = ((x&0xFFFF)<<16) | ((x&0xFFFF0000)>>16);
323 SIVAL(&x,0,x2);
325 return pull_dos_date((const uint8_t *)&x, zone_offset);
329 create a unix GMT date from a dos date in 32 bit "unix like" format
330 these generally arrive as localtimes, with corresponding DST
332 _PUBLIC_ time_t pull_dos_date3(const uint8_t *date_ptr, int zone_offset)
334 time_t t = (time_t)IVAL(date_ptr,0);
335 if (!null_time(t)) {
336 t += zone_offset;
338 return t;
342 /****************************************************************************
343 Return the date and time as a string
344 ****************************************************************************/
346 char *timeval_string(TALLOC_CTX *ctx, const struct timeval *tp, bool hires)
348 time_t t;
349 struct tm *tm;
351 t = (time_t)tp->tv_sec;
352 tm = localtime(&t);
353 if (!tm) {
354 if (hires) {
355 return talloc_asprintf(ctx,
356 "%ld.%06ld seconds since the Epoch",
357 (long)tp->tv_sec,
358 (long)tp->tv_usec);
359 } else {
360 return talloc_asprintf(ctx,
361 "%ld seconds since the Epoch",
362 (long)t);
364 } else {
365 #ifdef HAVE_STRFTIME
366 char TimeBuf[60];
367 if (hires) {
368 strftime(TimeBuf,sizeof(TimeBuf)-1,"%Y/%m/%d %H:%M:%S",tm);
369 return talloc_asprintf(ctx,
370 "%s.%06ld", TimeBuf,
371 (long)tp->tv_usec);
372 } else {
373 strftime(TimeBuf,sizeof(TimeBuf)-1,"%Y/%m/%d %H:%M:%S",tm);
374 return talloc_strdup(ctx, TimeBuf);
376 #else
377 if (hires) {
378 const char *asct = asctime(tm);
379 return talloc_asprintf(ctx, "%s.%06ld",
380 asct ? asct : "unknown",
381 (long)tp->tv_usec);
382 } else {
383 const char *asct = asctime(tm);
384 return talloc_asprintf(ctx, asct ? asct : "unknown");
386 #endif
390 char *current_timestring(TALLOC_CTX *ctx, bool hires)
392 struct timeval tv;
394 GetTimeOfDay(&tv);
395 return timeval_string(ctx, &tv, hires);
400 return a HTTP/1.0 time string
402 _PUBLIC_ char *http_timestring(TALLOC_CTX *mem_ctx, time_t t)
404 char *buf;
405 char tempTime[60];
406 struct tm *tm = localtime(&t);
408 if (t == TIME_T_MAX) {
409 return talloc_strdup(mem_ctx, "never");
412 if (!tm) {
413 return talloc_asprintf(mem_ctx,"%ld seconds since the Epoch",(long)t);
416 #ifndef HAVE_STRFTIME
417 buf = talloc_strdup(mem_ctx, asctime(tm));
418 if (buf[strlen(buf)-1] == '\n') {
419 buf[strlen(buf)-1] = 0;
421 #else
422 strftime(tempTime, sizeof(tempTime)-1, "%a, %d %b %Y %H:%M:%S %Z", tm);
423 buf = talloc_strdup(mem_ctx, tempTime);
424 #endif /* !HAVE_STRFTIME */
426 return buf;
430 Return the date and time as a string
432 _PUBLIC_ char *timestring(TALLOC_CTX *mem_ctx, time_t t)
434 char *TimeBuf;
435 char tempTime[80];
436 struct tm *tm;
438 tm = localtime(&t);
439 if (!tm) {
440 return talloc_asprintf(mem_ctx,
441 "%ld seconds since the Epoch",
442 (long)t);
445 #ifdef HAVE_STRFTIME
446 /* Some versions of gcc complain about using some special format
447 * specifiers. This is a bug in gcc, not a bug in this code. See a
448 * recent strftime() manual page for details. */
449 strftime(tempTime,sizeof(tempTime)-1,"%a %b %e %X %Y %Z",tm);
450 TimeBuf = talloc_strdup(mem_ctx, tempTime);
451 #else
452 TimeBuf = talloc_strdup(mem_ctx, asctime(tm));
453 #endif
455 return TimeBuf;
459 return a talloced string representing a NTTIME for human consumption
461 _PUBLIC_ const char *nt_time_string(TALLOC_CTX *mem_ctx, NTTIME nt)
463 time_t t;
464 if (nt == 0) {
465 return "NTTIME(0)";
467 t = nt_time_to_unix(nt);
468 return timestring(mem_ctx, t);
473 put a NTTIME into a packet
475 _PUBLIC_ void push_nttime(uint8_t *base, uint16_t offset, NTTIME t)
477 SBVAL(base, offset, t);
481 pull a NTTIME from a packet
483 _PUBLIC_ NTTIME pull_nttime(uint8_t *base, uint16_t offset)
485 NTTIME ret = BVAL(base, offset);
486 return ret;
490 return (tv1 - tv2) in microseconds
492 _PUBLIC_ int64_t usec_time_diff(const struct timeval *tv1, const struct timeval *tv2)
494 int64_t sec_diff = tv1->tv_sec - tv2->tv_sec;
495 return (sec_diff * 1000000) + (int64_t)(tv1->tv_usec - tv2->tv_usec);
499 return (tp1 - tp2) in microseconds
501 _PUBLIC_ int64_t nsec_time_diff(const struct timespec *tp1, const struct timespec *tp2)
503 int64_t sec_diff = tp1->tv_sec - tp2->tv_sec;
504 return (sec_diff * 1000000000) + (int64_t)(tp1->tv_nsec - tp2->tv_nsec);
509 return a zero timeval
511 _PUBLIC_ struct timeval timeval_zero(void)
513 struct timeval tv;
514 tv.tv_sec = 0;
515 tv.tv_usec = 0;
516 return tv;
520 return true if a timeval is zero
522 _PUBLIC_ bool timeval_is_zero(const struct timeval *tv)
524 return tv->tv_sec == 0 && tv->tv_usec == 0;
528 return a timeval for the current time
530 _PUBLIC_ struct timeval timeval_current(void)
532 struct timeval tv;
533 GetTimeOfDay(&tv);
534 return tv;
538 return a timeval struct with the given elements
540 _PUBLIC_ struct timeval timeval_set(uint32_t secs, uint32_t usecs)
542 struct timeval tv;
543 tv.tv_sec = secs;
544 tv.tv_usec = usecs;
545 return tv;
550 return a timeval ofs microseconds after tv
552 _PUBLIC_ struct timeval timeval_add(const struct timeval *tv,
553 uint32_t secs, uint32_t usecs)
555 struct timeval tv2 = *tv;
556 const unsigned int million = 1000000;
557 tv2.tv_sec += secs;
558 tv2.tv_usec += usecs;
559 tv2.tv_sec += tv2.tv_usec / million;
560 tv2.tv_usec = tv2.tv_usec % million;
561 return tv2;
565 return the sum of two timeval structures
567 struct timeval timeval_sum(const struct timeval *tv1,
568 const struct timeval *tv2)
570 return timeval_add(tv1, tv2->tv_sec, tv2->tv_usec);
574 return a timeval secs/usecs into the future
576 _PUBLIC_ struct timeval timeval_current_ofs(uint32_t secs, uint32_t usecs)
578 struct timeval tv = timeval_current();
579 return timeval_add(&tv, secs, usecs);
583 return a timeval milliseconds into the future
585 _PUBLIC_ struct timeval timeval_current_ofs_msec(uint32_t msecs)
587 struct timeval tv = timeval_current();
588 return timeval_add(&tv, msecs / 1000, (msecs % 1000) * 1000);
592 return a timeval microseconds into the future
594 _PUBLIC_ struct timeval timeval_current_ofs_usec(uint32_t usecs)
596 struct timeval tv = timeval_current();
597 return timeval_add(&tv, usecs / 1000000, usecs % 1000000);
601 compare two timeval structures.
602 Return -1 if tv1 < tv2
603 Return 0 if tv1 == tv2
604 Return 1 if tv1 > tv2
606 _PUBLIC_ int timeval_compare(const struct timeval *tv1, const struct timeval *tv2)
608 if (tv1->tv_sec > tv2->tv_sec) return 1;
609 if (tv1->tv_sec < tv2->tv_sec) return -1;
610 if (tv1->tv_usec > tv2->tv_usec) return 1;
611 if (tv1->tv_usec < tv2->tv_usec) return -1;
612 return 0;
616 return true if a timer is in the past
618 _PUBLIC_ bool timeval_expired(const struct timeval *tv)
620 struct timeval tv2 = timeval_current();
621 if (tv2.tv_sec > tv->tv_sec) return true;
622 if (tv2.tv_sec < tv->tv_sec) return false;
623 return (tv2.tv_usec >= tv->tv_usec);
627 return the number of seconds elapsed between two times
629 _PUBLIC_ double timeval_elapsed2(const struct timeval *tv1, const struct timeval *tv2)
631 return (tv2->tv_sec - tv1->tv_sec) +
632 (tv2->tv_usec - tv1->tv_usec)*1.0e-6;
636 return the number of seconds elapsed since a given time
638 _PUBLIC_ double timeval_elapsed(const struct timeval *tv)
640 struct timeval tv2 = timeval_current();
641 return timeval_elapsed2(tv, &tv2);
645 return the lesser of two timevals
647 _PUBLIC_ struct timeval timeval_min(const struct timeval *tv1,
648 const struct timeval *tv2)
650 if (tv1->tv_sec < tv2->tv_sec) return *tv1;
651 if (tv1->tv_sec > tv2->tv_sec) return *tv2;
652 if (tv1->tv_usec < tv2->tv_usec) return *tv1;
653 return *tv2;
657 return the greater of two timevals
659 _PUBLIC_ struct timeval timeval_max(const struct timeval *tv1,
660 const struct timeval *tv2)
662 if (tv1->tv_sec > tv2->tv_sec) return *tv1;
663 if (tv1->tv_sec < tv2->tv_sec) return *tv2;
664 if (tv1->tv_usec > tv2->tv_usec) return *tv1;
665 return *tv2;
669 return the difference between two timevals as a timeval
670 if tv1 comes after tv2, then return a zero timeval
671 (this is *tv2 - *tv1)
673 _PUBLIC_ struct timeval timeval_until(const struct timeval *tv1,
674 const struct timeval *tv2)
676 struct timeval t;
677 if (timeval_compare(tv1, tv2) >= 0) {
678 return timeval_zero();
680 t.tv_sec = tv2->tv_sec - tv1->tv_sec;
681 if (tv1->tv_usec > tv2->tv_usec) {
682 t.tv_sec--;
683 t.tv_usec = 1000000 - (tv1->tv_usec - tv2->tv_usec);
684 } else {
685 t.tv_usec = tv2->tv_usec - tv1->tv_usec;
687 return t;
692 convert a timeval to a NTTIME
694 _PUBLIC_ NTTIME timeval_to_nttime(const struct timeval *tv)
696 return 10*(tv->tv_usec +
697 ((TIME_FIXUP_CONSTANT + (uint64_t)tv->tv_sec) * 1000000));
701 convert a NTTIME to a timeval
703 _PUBLIC_ void nttime_to_timeval(struct timeval *tv, NTTIME t)
705 if (tv == NULL) return;
707 t += 10/2;
708 t /= 10;
709 t -= TIME_FIXUP_CONSTANT*1000*1000;
711 tv->tv_sec = t / 1000000;
713 if (TIME_T_MIN > tv->tv_sec || tv->tv_sec > TIME_T_MAX) {
714 tv->tv_sec = 0;
715 tv->tv_usec = 0;
716 return;
719 tv->tv_usec = t - tv->tv_sec*1000000;
722 /*******************************************************************
723 yield the difference between *A and *B, in seconds, ignoring leap seconds
724 ********************************************************************/
725 static int tm_diff(struct tm *a, struct tm *b)
727 int ay = a->tm_year + (1900 - 1);
728 int by = b->tm_year + (1900 - 1);
729 int intervening_leap_days =
730 (ay/4 - by/4) - (ay/100 - by/100) + (ay/400 - by/400);
731 int years = ay - by;
732 int days = 365*years + intervening_leap_days + (a->tm_yday - b->tm_yday);
733 int hours = 24*days + (a->tm_hour - b->tm_hour);
734 int minutes = 60*hours + (a->tm_min - b->tm_min);
735 int seconds = 60*minutes + (a->tm_sec - b->tm_sec);
737 return seconds;
742 return the UTC offset in seconds west of UTC, or 0 if it cannot be determined
744 _PUBLIC_ int get_time_zone(time_t t)
746 struct tm *tm = gmtime(&t);
747 struct tm tm_utc;
748 if (!tm)
749 return 0;
750 tm_utc = *tm;
751 tm = localtime(&t);
752 if (!tm)
753 return 0;
754 return tm_diff(&tm_utc,tm);
757 struct timespec nt_time_to_unix_timespec(NTTIME *nt)
759 int64_t d;
760 struct timespec ret;
762 if (*nt == 0 || *nt == (int64_t)-1) {
763 ret.tv_sec = 0;
764 ret.tv_nsec = 0;
765 return ret;
768 d = (int64_t)*nt;
769 /* d is now in 100ns units, since jan 1st 1601".
770 Save off the ns fraction. */
773 * Take the last seven decimal digits and multiply by 100.
774 * to convert from 100ns units to 1ns units.
776 ret.tv_nsec = (long) ((d % (1000 * 1000 * 10)) * 100);
778 /* Convert to seconds */
779 d /= 1000*1000*10;
781 /* Now adjust by 369 years to make the secs since 1970 */
782 d -= TIME_FIXUP_CONSTANT_INT;
784 if (d <= (int64_t)TIME_T_MIN) {
785 ret.tv_sec = TIME_T_MIN;
786 ret.tv_nsec = 0;
787 return ret;
790 if (d >= (int64_t)TIME_T_MAX) {
791 ret.tv_sec = TIME_T_MAX;
792 ret.tv_nsec = 0;
793 return ret;
796 ret.tv_sec = (time_t)d;
797 return ret;
802 check if 2 NTTIMEs are equal.
804 bool nt_time_equal(NTTIME *t1, NTTIME *t2)
806 return *t1 == *t2;
810 Check if it's a null timespec.
813 bool null_timespec(struct timespec ts)
815 return ts.tv_sec == 0 ||
816 ts.tv_sec == (time_t)0xFFFFFFFF ||
817 ts.tv_sec == (time_t)-1;
820 /****************************************************************************
821 Convert a normalized timeval to a timespec.
822 ****************************************************************************/
824 struct timespec convert_timeval_to_timespec(const struct timeval tv)
826 struct timespec ts;
827 ts.tv_sec = tv.tv_sec;
828 ts.tv_nsec = tv.tv_usec * 1000;
829 return ts;
832 /****************************************************************************
833 Convert a normalized timespec to a timeval.
834 ****************************************************************************/
836 struct timeval convert_timespec_to_timeval(const struct timespec ts)
838 struct timeval tv;
839 tv.tv_sec = ts.tv_sec;
840 tv.tv_usec = ts.tv_nsec / 1000;
841 return tv;
844 /****************************************************************************
845 Return a timespec for the current time
846 ****************************************************************************/
848 struct timespec timespec_current(void)
850 struct timespec ts;
851 clock_gettime(CLOCK_REALTIME, &ts);
852 return ts;
855 /****************************************************************************
856 Return the lesser of two timespecs.
857 ****************************************************************************/
859 struct timespec timespec_min(const struct timespec *ts1,
860 const struct timespec *ts2)
862 if (ts1->tv_sec < ts2->tv_sec) return *ts1;
863 if (ts1->tv_sec > ts2->tv_sec) return *ts2;
864 if (ts1->tv_nsec < ts2->tv_nsec) return *ts1;
865 return *ts2;
868 /****************************************************************************
869 compare two timespec structures.
870 Return -1 if ts1 < ts2
871 Return 0 if ts1 == ts2
872 Return 1 if ts1 > ts2
873 ****************************************************************************/
875 int timespec_compare(const struct timespec *ts1, const struct timespec *ts2)
877 if (ts1->tv_sec > ts2->tv_sec) return 1;
878 if (ts1->tv_sec < ts2->tv_sec) return -1;
879 if (ts1->tv_nsec > ts2->tv_nsec) return 1;
880 if (ts1->tv_nsec < ts2->tv_nsec) return -1;
881 return 0;
884 /****************************************************************************
885 Round up a timespec if nsec > 500000000, round down if lower,
886 then zero nsec.
887 ****************************************************************************/
889 void round_timespec_to_sec(struct timespec *ts)
891 ts->tv_sec = convert_timespec_to_time_t(*ts);
892 ts->tv_nsec = 0;
895 /****************************************************************************
896 Round a timespec to usec value.
897 ****************************************************************************/
899 void round_timespec_to_usec(struct timespec *ts)
901 struct timeval tv = convert_timespec_to_timeval(*ts);
902 *ts = convert_timeval_to_timespec(tv);
903 while (ts->tv_nsec > 1000000000) {
904 ts->tv_sec += 1;
905 ts->tv_nsec -= 1000000000;
909 /****************************************************************************
910 Put a 8 byte filetime from a struct timespec. Uses GMT.
911 ****************************************************************************/
913 void unix_timespec_to_nt_time(NTTIME *nt, struct timespec ts)
915 uint64_t d;
917 if (ts.tv_sec ==0 && ts.tv_nsec == 0) {
918 *nt = 0;
919 return;
921 if (ts.tv_sec == TIME_T_MAX) {
922 *nt = 0x7fffffffffffffffLL;
923 return;
925 if (ts.tv_sec == (time_t)-1) {
926 *nt = (uint64_t)-1;
927 return;
930 d = ts.tv_sec;
931 d += TIME_FIXUP_CONSTANT_INT;
932 d *= 1000*1000*10;
933 /* d is now in 100ns units. */
934 d += (ts.tv_nsec / 100);
936 *nt = d;