1 /*****************************************************************************
2 * mtime.c: high resolution time management functions
3 * Functions are prototyped in vlc_mtime.h.
4 *****************************************************************************
5 * Copyright (C) 1998-2007 the VideoLAN team
6 * Copyright © 2006-2007 Rémi Denis-Courmont
9 * Authors: Vincent Seguin <seguin@via.ecp.fr>
10 * Rémi Denis-Courmont <rem$videolan,org>
13 * This program is free software; you can redistribute it and/or modify
14 * it under the terms of the GNU General Public License as published by
15 * the Free Software Foundation; either version 2 of the License, or
16 * (at your option) any later version.
18 * This program is distributed in the hope that it will be useful,
19 * but WITHOUT ANY WARRANTY; without even the implied warranty of
20 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
21 * GNU General Public License for more details.
23 * You should have received a copy of the GNU General Public License
24 * along with this program; if not, write to the Free Software
25 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston MA 02110-1301, USA.
26 *****************************************************************************/
28 /*****************************************************************************
30 *****************************************************************************/
36 #include <vlc_common.h>
38 #include <time.h> /* clock_gettime(), clock_nanosleep() */
43 # include <unistd.h> /* select() */
46 #ifdef HAVE_KERNEL_OS_H
47 # include <kernel/OS.h>
50 #if defined( WIN32 ) || defined( UNDER_CE )
52 # include <mmsystem.h>
55 #if defined(HAVE_SYS_TIME_H)
56 # include <sys/time.h>
59 #if defined(__APPLE__) && !defined(__powerpc__) && !defined(__ppc__) && !defined(__ppc64__)
60 #define USE_APPLE_MACH 1
61 # include <mach/mach.h>
62 # include <mach/mach_time.h>
65 #if !defined(HAVE_STRUCT_TIMESPEC)
73 #if defined(HAVE_NANOSLEEP) && !defined(HAVE_DECL_NANOSLEEP)
74 int nanosleep(struct timespec *, struct timespec *);
77 #if !defined (_POSIX_CLOCK_SELECTION)
78 # define _POSIX_CLOCK_SELECTION (-1)
81 # if (_POSIX_CLOCK_SELECTION < 0)
83 * We cannot use the monotonic clock if clock selection is not available,
84 * as it would screw vlc_cond_timedwait() completely. Instead, we have to
85 * stick to the realtime clock. Nevermind it screws everything up when ntpdate
86 * warps the wall clock.
88 # undef CLOCK_MONOTONIC
89 # define CLOCK_MONOTONIC CLOCK_REALTIME
90 #elif !defined (HAVE_CLOCK_NANOSLEEP)
91 /* Clock selection without clock in the first place, I don't think so. */
92 # error We have quite a situation here! Fix me if it ever happens.
96 * Return a date in a readable format
98 * This function converts a mtime date into a string.
99 * psz_buffer should be a buffer long enough to store the formatted
101 * \param date to be converted
102 * \param psz_buffer should be a buffer at least MSTRTIME_MAX_SIZE characters
103 * \return psz_buffer is returned so this can be used as printf parameter.
105 char *mstrtime( char *psz_buffer, mtime_t date )
107 static const mtime_t ll1000 = 1000, ll60 = 60, ll24 = 24;
109 snprintf( psz_buffer, MSTRTIME_MAX_SIZE, "%02d:%02d:%02d-%03d.%03d",
110 (int) (date / (ll1000 * ll1000 * ll60 * ll60) % ll24),
111 (int) (date / (ll1000 * ll1000 * ll60) % ll60),
112 (int) (date / (ll1000 * ll1000) % ll60),
113 (int) (date / ll1000 % ll1000),
114 (int) (date % ll1000) );
115 return( psz_buffer );
119 * Convert seconds to a time in the format h:mm:ss.
121 * This function is provided for any interface function which need to print a
122 * time string in the format h:mm:ss
124 * \param secs the date to be converted
125 * \param psz_buffer should be a buffer at least MSTRTIME_MAX_SIZE characters
126 * \return psz_buffer is returned so this can be used as printf parameter.
128 char *secstotimestr( char *psz_buffer, int i_seconds )
132 d = div( i_seconds, 60 );
134 d = div( d.quot, 60 );
137 snprintf( psz_buffer, MSTRTIME_MAX_SIZE, "%d:%2.2d:%2.2d",
138 d.quot, d.rem, i_seconds );
140 snprintf( psz_buffer, MSTRTIME_MAX_SIZE, "%2.2d:%2.2d",
145 #if defined (HAVE_CLOCK_NANOSLEEP)
146 static unsigned prec = 0;
148 static void mprec_once( void )
151 if( clock_getres( CLOCK_MONOTONIC, &ts ))
152 clock_getres( CLOCK_REALTIME, &ts );
154 prec = ts.tv_nsec / 1000;
159 * Return a value that is no bigger than the clock precision
162 static inline unsigned mprec( void )
164 #if defined (HAVE_CLOCK_NANOSLEEP)
165 static pthread_once_t once = PTHREAD_ONCE_INIT;
166 pthread_once( &once, mprec_once );
173 #ifdef USE_APPLE_MACH
174 static mach_timebase_info_data_t mtime_timebase_info;
175 static pthread_once_t mtime_timebase_info_once = PTHREAD_ONCE_INIT;
176 static void mtime_init_timebase(void)
178 mach_timebase_info(&mtime_timebase_info);
183 * Return high precision date
185 * Use a 1 MHz clock when possible, or 1 kHz
187 * Beware ! It doesn't reflect the actual date (since epoch), but can be the machine's uptime or anything (when monotonic clock is used)
189 mtime_t mdate( void )
193 #if defined (HAVE_CLOCK_NANOSLEEP)
196 /* Try to use POSIX monotonic clock if available */
197 if( clock_gettime( CLOCK_MONOTONIC, &ts ) == EINVAL )
198 /* Run-time fallback to real-time clock (always available) */
199 (void)clock_gettime( CLOCK_REALTIME, &ts );
201 res = ((mtime_t)ts.tv_sec * (mtime_t)1000000)
202 + (mtime_t)(ts.tv_nsec / 1000);
204 #elif defined( HAVE_KERNEL_OS_H )
205 res = real_time_clock_usecs();
207 #elif defined( USE_APPLE_MACH )
208 pthread_once(&mtime_timebase_info_once, mtime_init_timebase);
209 uint64_t date = mach_absolute_time();
211 /* Convert to nanoseconds */
212 date *= mtime_timebase_info.numer;
213 date /= mtime_timebase_info.denom;
215 /* Convert to microseconds */
217 #elif defined( WIN32 ) || defined( UNDER_CE )
218 /* We don't need the real date, just the value of a high precision timer */
219 static mtime_t freq = INT64_C(-1);
221 if( freq == INT64_C(-1) )
223 /* Extract from the Tcl source code:
224 * (http://www.cs.man.ac.uk/fellowsd-bin/TIP/7.html)
226 * Some hardware abstraction layers use the CPU clock
227 * in place of the real-time clock as a performance counter
228 * reference. This results in:
229 * - inconsistent results among the processors on
230 * multi-processor systems.
231 * - unpredictable changes in performance counter frequency
232 * on "gearshift" processors such as Transmeta and
234 * There seems to be no way to test whether the performance
235 * counter is reliable, but a useful heuristic is that
236 * if its frequency is 1.193182 MHz or 3.579545 MHz, it's
237 * derived from a colorburst crystal and is therefore
238 * the RTC rather than the TSC. If it's anything else, we
239 * presume that the performance counter is unreliable.
243 freq = ( QueryPerformanceFrequency( &buf ) &&
244 (buf.QuadPart == INT64_C(1193182) || buf.QuadPart == INT64_C(3579545) ) )
248 /* on windows 2000, XP and Vista detect if there are two
249 cores there - that makes QueryPerformanceFrequency in
250 any case not trustable?
251 (may also be true, for single cores with adaptive
252 CPU frequency and active power management?)
254 HINSTANCE h_Kernel32 = LoadLibrary(_T("kernel32.dll"));
257 void WINAPI (*pf_GetSystemInfo)(LPSYSTEM_INFO);
258 pf_GetSystemInfo = (void WINAPI (*)(LPSYSTEM_INFO))
259 GetProcAddress(h_Kernel32, _T("GetSystemInfo"));
262 SYSTEM_INFO system_info;
263 pf_GetSystemInfo(&system_info);
264 if(system_info.dwNumberOfProcessors > 1)
267 FreeLibrary(h_Kernel32);
274 LARGE_INTEGER counter;
275 QueryPerformanceCounter (&counter);
277 /* Convert to from (1/freq) to microsecond resolution */
278 /* We need to split the division to avoid 63-bits overflow */
279 lldiv_t d = lldiv (counter.QuadPart, freq);
281 res = (d.quot * 1000000) + ((d.rem * 1000000) / freq);
285 /* Fallback on timeGetTime() which has a millisecond resolution
286 * (actually, best case is about 5 ms resolution)
287 * timeGetTime() only returns a DWORD thus will wrap after
288 * about 49.7 days so we try to detect the wrapping. */
290 static CRITICAL_SECTION date_lock;
291 static mtime_t i_previous_time = INT64_C(-1);
292 static int i_wrap_counts = -1;
294 if( i_wrap_counts == -1 )
298 i_previous_time = INT64_C(1000) * timeGetTime();
300 i_previous_time = INT64_C(1000) * GetTickCount();
302 InitializeCriticalSection( &date_lock );
306 EnterCriticalSection( &date_lock );
308 res = INT64_C(1000) *
309 (i_wrap_counts * INT64_C(0x100000000) + timeGetTime());
311 res = INT64_C(1000) *
312 (i_wrap_counts * INT64_C(0x100000000) + GetTickCount());
314 if( i_previous_time > res )
316 /* Counter wrapped */
318 res += INT64_C(0x100000000) * 1000;
320 i_previous_time = res;
321 LeaveCriticalSection( &date_lock );
323 #elif defined(USE_APPLE_MACH)
324 /* The version that should be used, if it was cancelable */
325 pthread_once(&mtime_timebase_info_once, mtime_init_timebase);
326 uint64_t mach_time = date * 1000 * mtime_timebase_info.denom / mtime_timebase_info.numer;
327 mach_wait_until(mach_time);
330 struct timeval tv_date;
332 /* gettimeofday() cannot fail given &tv_date is a valid address */
333 (void)gettimeofday( &tv_date, NULL );
334 res = (mtime_t) tv_date.tv_sec * 1000000 + (mtime_t) tv_date.tv_usec;
344 * This function uses select() and an system date function to wake up at a
345 * precise date. It should be used for process synchronization. If current date
346 * is posterior to wished date, the function returns immediately.
347 * \param date The date to wake up at
349 void mwait( mtime_t date )
351 /* If the deadline is already elapsed, or within the clock precision,
352 * do not even bother the system timer. */
355 #if defined (HAVE_CLOCK_NANOSLEEP)
356 lldiv_t d = lldiv( date, 1000000 );
357 struct timespec ts = { d.quot, d.rem * 1000 };
360 while( ( val = clock_nanosleep( CLOCK_MONOTONIC, TIMER_ABSTIME, &ts,
364 ts.tv_sec = d.quot; ts.tv_nsec = d.rem * 1000;
365 while( clock_nanosleep( CLOCK_REALTIME, 0, &ts, NULL ) == EINTR );
368 #elif defined (WIN32)
371 while( (i_total = (date - mdate())) > 0 )
373 const mtime_t i_sleep = i_total / 1000;
374 DWORD i_delay = (i_sleep > 0x7fffffff) ? 0x7fffffff : i_sleep;
376 SleepEx( i_delay, TRUE );
381 mtime_t delay = date - mdate();
389 #include "libvlc.h" /* vlc_backtrace() */
393 * Portable usleep(). Cancellation point.
395 * \param delay the amount of time to sleep
397 void msleep( mtime_t delay )
399 #if defined( HAVE_CLOCK_NANOSLEEP )
400 lldiv_t d = lldiv( delay, 1000000 );
401 struct timespec ts = { d.quot, d.rem * 1000 };
404 while( ( val = clock_nanosleep( CLOCK_MONOTONIC, 0, &ts, &ts ) ) == EINTR );
407 ts.tv_sec = d.quot; ts.tv_nsec = d.rem * 1000;
408 while( clock_nanosleep( CLOCK_REALTIME, 0, &ts, &ts ) == EINTR );
411 #elif defined( HAVE_KERNEL_OS_H )
414 #elif defined( WIN32 ) || defined( UNDER_CE )
415 mwait (mdate () + delay);
417 #elif defined( HAVE_NANOSLEEP )
418 struct timespec ts_delay;
420 ts_delay.tv_sec = delay / 1000000;
421 ts_delay.tv_nsec = (delay % 1000000) * 1000;
423 while( nanosleep( &ts_delay, &ts_delay ) && ( errno == EINTR ) );
425 #elif defined (USE_APPLE_MACH)
426 /* The version that should be used, if it was cancelable */
427 pthread_once(&mtime_timebase_info_once, mtime_init_timebase);
428 uint64_t mach_time = delay * 1000 * mtime_timebase_info.denom / mtime_timebase_info.numer;
429 mach_wait_until(mach_time + mach_absolute_time());
432 struct timeval tv_delay;
434 tv_delay.tv_sec = delay / 1000000;
435 tv_delay.tv_usec = delay % 1000000;
437 /* If a signal is caught, you are screwed. Update your OS to nanosleep()
438 * or clock_nanosleep() if this is an issue. */
439 select( 0, NULL, NULL, NULL, &tv_delay );
444 * Date management (internal and external)
448 * Initialize a date_t.
450 * \param date to initialize
451 * \param divider (sample rate) numerator
452 * \param divider (sample rate) denominator
455 void date_Init( date_t *p_date, uint32_t i_divider_n, uint32_t i_divider_d )
458 p_date->i_divider_num = i_divider_n;
459 p_date->i_divider_den = i_divider_d;
460 p_date->i_remainder = 0;
466 * \param date to change
467 * \param divider (sample rate) numerator
468 * \param divider (sample rate) denominator
471 void date_Change( date_t *p_date, uint32_t i_divider_n, uint32_t i_divider_d )
473 /* change time scale of remainder */
474 p_date->i_remainder = p_date->i_remainder * i_divider_n / p_date->i_divider_num;
475 p_date->i_divider_num = i_divider_n;
476 p_date->i_divider_den = i_divider_d;
480 * Set the date value of a date_t.
485 void date_Set( date_t *p_date, mtime_t i_new_date )
487 p_date->date = i_new_date;
488 p_date->i_remainder = 0;
492 * Get the date of a date_t
497 mtime_t date_Get( const date_t *p_date )
503 * Move forwards or backwards the date of a date_t.
505 * \param date to move
506 * \param difference value
508 void date_Move( date_t *p_date, mtime_t i_difference )
510 p_date->date += i_difference;
514 * Increment the date and return the result, taking into account
517 * \param date to increment
518 * \param incrementation in number of samples
521 mtime_t date_Increment( date_t *p_date, uint32_t i_nb_samples )
523 mtime_t i_dividend = (mtime_t)i_nb_samples * 1000000 * p_date->i_divider_den;
524 p_date->date += i_dividend / p_date->i_divider_num;
525 p_date->i_remainder += (int)(i_dividend % p_date->i_divider_num);
527 if( p_date->i_remainder >= p_date->i_divider_num )
529 /* This is Bresenham algorithm. */
530 assert( p_date->i_remainder < 2*p_date->i_divider_num);
532 p_date->i_remainder -= p_date->i_divider_num;
539 * Decrement the date and return the result, taking into account
542 * \param date to decrement
543 * \param decrementation in number of samples
546 mtime_t date_Decrement( date_t *p_date, uint32_t i_nb_samples )
548 mtime_t i_dividend = (mtime_t)i_nb_samples * 1000000 * p_date->i_divider_den;
549 p_date->date -= i_dividend / p_date->i_divider_num;
550 unsigned i_rem_adjust = i_dividend % p_date->i_divider_num;
552 if( p_date->i_remainder < i_rem_adjust )
554 /* This is Bresenham algorithm. */
555 assert( p_date->i_remainder > -p_date->i_divider_num);
557 p_date->i_remainder += p_date->i_divider_num;
560 p_date->i_remainder -= i_rem_adjust;
565 #ifndef HAVE_GETTIMEOFDAY
570 * Number of micro-seconds between the beginning of the Windows epoch
571 * (Jan. 1, 1601) and the Unix epoch (Jan. 1, 1970).
573 * This assumes all Win32 compilers have 64-bit support.
575 #if defined(_MSC_VER) || defined(_MSC_EXTENSIONS) || defined(__WATCOMC__)
576 # define DELTA_EPOCH_IN_USEC 11644473600000000Ui64
578 # define DELTA_EPOCH_IN_USEC 11644473600000000ULL
581 static uint64_t filetime_to_unix_epoch (const FILETIME *ft)
583 uint64_t res = (uint64_t) ft->dwHighDateTime << 32;
585 res |= ft->dwLowDateTime;
586 res /= 10; /* from 100 nano-sec periods to usec */
587 res -= DELTA_EPOCH_IN_USEC; /* from Win epoch to Unix epoch */
591 static int gettimeofday (struct timeval *tv, void *tz )
599 GetSystemTimeAsFileTime (&ft);
600 tim = filetime_to_unix_epoch (&ft);
601 tv->tv_sec = (long) (tim / 1000000L);
602 tv->tv_usec = (long) (tim % 1000000L);
611 * @return NTP 64-bits timestamp in host byte order.
613 uint64_t NTPtime64 (void)
616 #if defined (CLOCK_REALTIME)
617 clock_gettime (CLOCK_REALTIME, &ts);
621 gettimeofday (&tv, NULL);
622 ts.tv_sec = tv.tv_sec;
623 ts.tv_nsec = tv.tv_usec * 1000;
627 /* Convert nanoseconds to 32-bits fraction (232 picosecond units) */
628 uint64_t t = (uint64_t)(ts.tv_nsec) << 32;
632 /* There is 70 years (incl. 17 leap ones) offset to the Unix Epoch.
633 * No leap seconds during that period since they were not invented yet.
635 assert (t < 0x100000000);
636 t |= ((70LL * 365 + 17) * 24 * 60 * 60 + ts.tv_sec) << 32;