src/clock.c - haproxy - Gitiles

 /*
  * General time-keeping code and variables
  *
  * Copyright 2000-2021 Willy Tarreau <w@1wt.eu>
  *
  * This program is free software; you can redistribute it and/or
  * modify it under the terms of the GNU General Public License
  * as published by the Free Software Foundation; either version
  * 2 of the License, or (at your option) any later version.
  *
  */

 #include <sys/time.h>
 #include <signal.h>
 #include <time.h>

 #ifdef USE_THREAD
 #include <pthread.h>
 #endif

 #include <haproxy/api.h>
 #include <haproxy/activity.h>
 #include <haproxy/clock.h>
 #include <haproxy/signal-t.h>
 #include <haproxy/time.h>
 #include <haproxy/tinfo-t.h>
 #include <haproxy/tools.h>

 struct timeval                   start_date;      /* the process's start date in wall-clock time */
 volatile ullong                  global_now;      /* common monotonic date between all threads (32:32) */
 volatile uint                    global_now_ms;   /* common monotonic date in milliseconds (may wrap) */

 THREAD_ALIGNED(64) static ullong now_offset;      /* global offset between system time and global time */

 THREAD_LOCAL uint                now_ms;          /* internal monotonic date in milliseconds (may wrap) */
 THREAD_LOCAL struct timeval      now;             /* internal monotonic date derived from real clock */
 THREAD_LOCAL struct timeval      date;            /* the real current date (wall-clock time) */

 static THREAD_LOCAL struct timeval before_poll;   /* system date before calling poll() */
 static THREAD_LOCAL struct timeval after_poll;    /* system date after leaving poll() */
 static THREAD_LOCAL unsigned int samp_time;       /* total elapsed time over current sample */
 static THREAD_LOCAL unsigned int idle_time;       /* total idle time over current sample */
 static THREAD_LOCAL unsigned int iso_time_sec;     /* last iso time value for this thread */
 static THREAD_LOCAL char         iso_time_str[34]; /* ISO time representation of gettimeofday() */

 #if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
 static clockid_t per_thread_clock_id[MAX_THREADS];
 #endif

 /* returns the system's monotonic time in nanoseconds if supported, otherwise zero */
 uint64_t now_mono_time(void)
 {
 	uint64_t ret = 0;
 #if defined(_POSIX_TIMERS) && defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_MONOTONIC_CLOCK)
 	struct timespec ts;
 	clock_gettime(CLOCK_MONOTONIC, &ts);
 	ret = ts.tv_sec * 1000000000ULL + ts.tv_nsec;
 #endif
 	return ret;
 }

 /* returns the current thread's cumulated CPU time in nanoseconds if supported, otherwise zero */
 uint64_t now_cpu_time(void)
 {
 	uint64_t ret = 0;
 #if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
 	struct timespec ts;
 	clock_gettime(CLOCK_THREAD_CPUTIME_ID, &ts);
 	ret = ts.tv_sec * 1000000000ULL + ts.tv_nsec;
 #endif
 	return ret;
 }

 /* returns another thread's cumulated CPU time in nanoseconds if supported, otherwise zero */
 uint64_t now_cpu_time_thread(int thr)
 {
 	uint64_t ret = 0;
 #if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
 	struct timespec ts;
 	clock_gettime(per_thread_clock_id[thr], &ts);
 	ret = ts.tv_sec * 1000000000ULL + ts.tv_nsec;
 #endif
 	return ret;
 }

 /* set the clock source for the local thread */
 void clock_set_local_source(void)
 {
 #if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
 #ifdef USE_THREAD
 	pthread_getcpuclockid(pthread_self(), &per_thread_clock_id[tid]);
 #else
 	per_thread_clock_id[tid] = CLOCK_THREAD_CPUTIME_ID;
 #endif
 #endif
 }

 /* registers a timer <tmr> of type timer_t delivering signal <sig> with value
  * <val>. It tries on the current thread's clock ID first and falls back to
  * CLOCK_REALTIME. Returns non-zero on success, 1 on failure.
  */
 int clock_setup_signal_timer(void *tmr, int sig, int val)
 {
 	int ret = 0;

 #if defined(USE_RT) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
 	struct sigevent sev = { };
 	timer_t *timer = tmr;
 	sigset_t set;

 	/* unblock the WDTSIG signal we intend to use */
 	sigemptyset(&set);
 	sigaddset(&set, WDTSIG);
 	ha_sigmask(SIG_UNBLOCK, &set, NULL);

 	/* this timer will signal WDTSIG when it fires, with tid in the si_int
 	 * field (important since any thread will receive the signal).
 	 */
 	sev.sigev_notify          = SIGEV_SIGNAL;
 	sev.sigev_signo           = sig;
 	sev.sigev_value.sival_int = val;
 	if (timer_create(per_thread_clock_id[tid], &sev, timer) != -1 ||
 	    timer_create(CLOCK_REALTIME, &sev, timer) != -1)
 		ret = 1;
 #endif
 	return ret;
 }

 /* clock_update_date: sets <date> to system time, and sets <now> to something as
  * close as possible to real time, following a monotonic function. The main
  * principle consists in detecting backwards and forwards time jumps and adjust
  * an offset to correct them. This function should be called once after each
  * poll, and never farther apart than MAX_DELAY_MS*2. The poll's timeout should
  * be passed in <max_wait>, and the return value in <interrupted> (a non-zero
  * value means that we have not expired the timeout).
  *
  * clock_init_process_date() must have been called once first, and
  * clock_init_thread_date() must also have been called once for each thread.
  *
  * An offset is used to adjust the current time (date), to figure a monotonic
  * local time (now). The offset is not critical, as it is only updated after a
  * clock jump is detected. From this point all threads will apply it to their
  * locally measured time, and will then agree around a common monotonic
  * global_now value that serves to further refine their local time. As it is
  * not possible to atomically update a timeval, both global_now and the
  * now_offset values are instead stored as 64-bit integers made of two 32 bit
  * values for the tv_sec and tv_usec parts. The offset is made of two signed
  * ints so that the clock can be adjusted in the two directions.
  */
 void clock_update_local_date(int max_wait, int interrupted)
 {
 	struct timeval min_deadline, max_deadline;
 	ullong ofs;

 	gettimeofday(&date, NULL);

 	/* compute the minimum and maximum local date we may have reached based
 	 * on our past date and the associated timeout. There are three possible
 	 * extremities:
 	 *    - the new date cannot be older than before_poll
 	 *    - if not interrupted, the new date cannot be older than
 	 *      before_poll+max_wait
 	 *    - in any case the new date cannot be newer than
 	 *      before_poll+max_wait+some margin (100ms used here).
 	 * In case of violation, we'll ignore the current date and instead
 	 * restart from the last date we knew.
 	 */
 	_tv_ms_add(&min_deadline, &before_poll, max_wait);
 	_tv_ms_add(&max_deadline, &before_poll, max_wait + 100);

 	ofs = HA_ATOMIC_LOAD(&now_offset);

 	if (unlikely(__tv_islt(&date, &before_poll)                    || // big jump backwards
 		     (!interrupted && __tv_islt(&date, &min_deadline)) || // small jump backwards
 		     __tv_islt(&max_deadline, &date))) {                  // big jump forwards
 		if (!interrupted)
 			_tv_ms_add(&now, &now, max_wait);
 	} else {
 		/* The date is still within expectations. Let's apply the
 		 * now_offset to the system date. Note: ofs if made of two
 		 * independent signed ints.
 		 */
 		now.tv_sec  = date.tv_sec  + (int)(ofs >> 32); // note: may be positive or negative
 		now.tv_usec = date.tv_usec + (int)ofs;         // note: may be positive or negative
 		if ((int)now.tv_usec < 0) {
 			now.tv_usec += 1000000;
 			now.tv_sec  -= 1;
 		} else if (now.tv_usec >= 1000000) {
 			now.tv_usec -= 1000000;
 			now.tv_sec  += 1;
 		}
 	}
 	now_ms = __tv_to_ms(&now);
 }

 void clock_update_global_date()
 {
 	struct timeval tmp_now;
 	uint old_now_ms;
 	ullong old_now;
 	ullong new_now;
 	ullong ofs_new;
 	uint sec_ofs, usec_ofs;

 	/* now that we have bounded the local time, let's check if it's
 	 * realistic regarding the global date, which only moves forward,
 	 * otherwise catch up.
 	 */
 	old_now    = global_now;
 	old_now_ms = global_now_ms;

 	do {
 		tmp_now.tv_sec  = (unsigned int)(old_now >> 32);
 		tmp_now.tv_usec = old_now & 0xFFFFFFFFU;

 		if (__tv_islt(&now, &tmp_now))
 			now = tmp_now;

 		/* now <now> is expected to be the most accurate date,
 		 * equal to <global_now> or newer. Updating the global
 		 * date too often causes extreme contention and is not
 		 * needed: it's only used to help threads run at the
 		 * same date in case of local drift, and the global date,
 		 * which changes, is only used by freq counters (a choice
 		 * which is debatable by the way since it changes under us).
 		 * Tests have seen that the contention can be reduced from
 		 * 37% in this function to almost 0% when keeping clocks
 		 * synchronized no better than 32 microseconds, so that's
 		 * what we're doing here.
 		 */

 		new_now = ((ullong)now.tv_sec << 32) + (uint)now.tv_usec;
 		now_ms = __tv_to_ms(&now);

 		if (!((new_now ^ old_now) & ~0x1FULL))
 			return;

 		/* let's try to update the global <now> (both in timeval
 		 * and ms forms) or loop again.
 		 */
 	} while ((!_HA_ATOMIC_CAS(&global_now, &old_now, new_now) ||
 		  (now_ms  != old_now_ms && !_HA_ATOMIC_CAS(&global_now_ms, &old_now_ms, now_ms))) &&
 		 __ha_cpu_relax());

 	/* <now> and <now_ms> are now updated to the last value of global_now
 	 * and global_now_ms, which were also monotonically updated. We can
 	 * compute the latest offset, we don't care who writes it last, the
 	 * variations will not break the monotonic property.
 	 */

 	sec_ofs  = now.tv_sec  - date.tv_sec;
 	usec_ofs = now.tv_usec - date.tv_usec;
 	if ((int)usec_ofs < 0) {
 		usec_ofs += 1000000;
 		sec_ofs  -= 1;
 	}
 	ofs_new = ((ullong)sec_ofs << 32) + usec_ofs;
 	HA_ATOMIC_STORE(&now_offset, ofs_new);
 }

 /* must be called once at boot to initialize some global variables */
 void clock_init_process_date(void)
 {
 	now_offset = 0;
 	gettimeofday(&date, NULL);
 	now = after_poll = before_poll = date;
 	global_now = ((ullong)date.tv_sec << 32) + (uint)date.tv_usec;
 	global_now_ms = now.tv_sec * 1000 + now.tv_usec / 1000;
 	th_ctx->idle_pct = 100;
 	clock_update_date(0, 1);
 }

 /* must be called once per thread to initialize their thread-local variables.
  * Note that other threads might also be initializing and running in parallel.
  */
 void clock_init_thread_date(void)
 {
 	ullong old_now;

 	gettimeofday(&date, NULL);
 	after_poll = before_poll = date;

 	old_now = _HA_ATOMIC_LOAD(&global_now);
 	now.tv_sec = old_now >> 32;
 	now.tv_usec = (uint)old_now;
 	th_ctx->idle_pct = 100;
 	clock_update_date(0, 1);
 }

 /* report the average CPU idle percentage over all running threads, between 0 and 100 */
 uint clock_report_idle(void)
 {
 	uint total = 0;
 	uint rthr = 0;
 	uint thr;

 	for (thr = 0; thr < MAX_THREADS; thr++) {
 		if (!ha_thread_info[thr].tg ||
 		    !(ha_thread_info[thr].tg->threads_enabled & ha_thread_info[thr].ltid_bit))
 			continue;
 		total += HA_ATOMIC_LOAD(&ha_thread_ctx[thr].idle_pct);
 		rthr++;
 	}
 	return rthr ? total / rthr : 0;
 }

 /* Update the idle time value twice a second, to be called after
  * clock_update_date() when called after poll(), and currently called only by
  * clock_leaving_poll() below. It relies on <before_poll> to be updated to
  * the system time before calling poll().
  */
 static inline void clock_measure_idle(void)
 {
 	/* Let's compute the idle to work ratio. We worked between after_poll
 	 * and before_poll, and slept between before_poll and date. The idle_pct
 	 * is updated at most twice every second. Note that the current second
 	 * rarely changes so we avoid a multiply when not needed.
 	 */
 	int delta;

 	if ((delta = date.tv_sec - before_poll.tv_sec))
 		delta *= 1000000;
 	idle_time += delta + (date.tv_usec - before_poll.tv_usec);

 	if ((delta = date.tv_sec - after_poll.tv_sec))
 		delta *= 1000000;
 	samp_time += delta + (date.tv_usec - after_poll.tv_usec);

 	after_poll.tv_sec = date.tv_sec; after_poll.tv_usec = date.tv_usec;
 	if (samp_time < 500000)
 		return;

 	HA_ATOMIC_STORE(&th_ctx->idle_pct, (100ULL * idle_time + samp_time / 2) / samp_time);
 	idle_time = samp_time = 0;
 }

 /* Collect date and time information after leaving poll(). <timeout> must be
  * set to the maximum sleep time passed to poll (in milliseconds), and
  * <interrupted> must be zero if the poller reached the timeout or non-zero
  * otherwise, which generally is provided by the poller's return value.
  */
 void clock_leaving_poll(int timeout, int interrupted)
 {
 	clock_measure_idle();
 	th_ctx->prev_cpu_time  = now_cpu_time();
 	th_ctx->prev_mono_time = now_mono_time();
 }

 /* Collect date and time information before calling poll(). This will be used
  * to count the run time of the past loop and the sleep time of the next poll.
  * It also compares the elapsed and cpu times during the activity period to
  * estimate the amount of stolen time, which is reported if higher than half
  * a millisecond.
  */
 void clock_entering_poll(void)
 {
 	uint64_t new_mono_time;
 	uint64_t new_cpu_time;
 	uint32_t run_time;
 	int64_t stolen;

 	gettimeofday(&before_poll, NULL);

 	run_time = (before_poll.tv_sec - after_poll.tv_sec) * 1000000U + (before_poll.tv_usec - after_poll.tv_usec);

 	new_cpu_time   = now_cpu_time();
 	new_mono_time  = now_mono_time();

 	if (th_ctx->prev_cpu_time && th_ctx->prev_mono_time) {
 		new_cpu_time  -= th_ctx->prev_cpu_time;
 		new_mono_time -= th_ctx->prev_mono_time;
 		stolen = new_mono_time - new_cpu_time;
 		if (unlikely(stolen >= 500000)) {
 			stolen /= 500000;
 			/* more than half a millisecond difference might
 			 * indicate an undesired preemption.
 			 */
 			report_stolen_time(stolen);
 		}
 	}

 	/* update the average runtime */
 	activity_count_runtime(run_time);
 }

 /* returns the current date as returned by gettimeofday() in ISO+microsecond
  * format. It uses a thread-local static variable that the reader can consume
  * for as long as it wants until next call. Thus, do not call it from a signal
  * handler. If <pad> is non-0, a trailing space will be added. It will always
  * return exactly 32 or 33 characters (depending on padding) and will always be
  * zero-terminated, thus it will always fit into a 34 bytes buffer.
  * This also always include the local timezone (in +/-HH:mm format) .
  */
 char *timeofday_as_iso_us(int pad)
 {
 	struct timeval new_date;
 	struct tm tm;
 	const char *offset;
 	char c;

 	gettimeofday(&new_date, NULL);
 	if (new_date.tv_sec != iso_time_sec || !new_date.tv_sec) {
 		get_localtime(new_date.tv_sec, &tm);
 		offset = get_gmt_offset(new_date.tv_sec, &tm);
 		if (unlikely(strftime(iso_time_str, sizeof(iso_time_str), "%Y-%m-%dT%H:%M:%S.000000+00:00", &tm) != 32))
 			strcpy(iso_time_str, "YYYY-mm-ddTHH:MM:SS.000000-00:00"); // make the failure visible but respect format.
 		iso_time_str[26] = offset[0];
 		iso_time_str[27] = offset[1];
 		iso_time_str[28] = offset[2];
 		iso_time_str[30] = offset[3];
 		iso_time_str[31] = offset[4];
 		iso_time_sec = new_date.tv_sec;
 	}

 	/* utoa_pad adds a trailing 0 so we save the char for restore */
 	c = iso_time_str[26];
 	utoa_pad(new_date.tv_usec, iso_time_str + 20, 7);
 	iso_time_str[26] = c;
 	if (pad) {
 		iso_time_str[32] = ' ';
 		iso_time_str[33] = 0;
 	}
 	return iso_time_str;
 }
	/*
	* General time-keeping code and variables
	*
	* Copyright 2000-2021 Willy Tarreau <w@1wt.eu>
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License
	* as published by the Free Software Foundation; either version
	* 2 of the License, or (at your option) any later version.
	*
	*/

	#include <sys/time.h>
	#include <signal.h>
	#include <time.h>

	#ifdef USE_THREAD
	#include <pthread.h>
	#endif

	#include <haproxy/api.h>
	#include <haproxy/activity.h>
	#include <haproxy/clock.h>
	#include <haproxy/signal-t.h>
	#include <haproxy/time.h>
	#include <haproxy/tinfo-t.h>
	#include <haproxy/tools.h>

	struct timeval start_date; /* the process's start date in wall-clock time */
	volatile ullong global_now; /* common monotonic date between all threads (32:32) */
	volatile uint global_now_ms; /* common monotonic date in milliseconds (may wrap) */

	THREAD_ALIGNED(64) static ullong now_offset; /* global offset between system time and global time */

	THREAD_LOCAL uint now_ms; /* internal monotonic date in milliseconds (may wrap) */
	THREAD_LOCAL struct timeval now; /* internal monotonic date derived from real clock */
	THREAD_LOCAL struct timeval date; /* the real current date (wall-clock time) */

	static THREAD_LOCAL struct timeval before_poll; /* system date before calling poll() */
	static THREAD_LOCAL struct timeval after_poll; /* system date after leaving poll() */
	static THREAD_LOCAL unsigned int samp_time; /* total elapsed time over current sample */
	static THREAD_LOCAL unsigned int idle_time; /* total idle time over current sample */
	static THREAD_LOCAL unsigned int iso_time_sec; /* last iso time value for this thread */
	static THREAD_LOCAL char iso_time_str[34]; /* ISO time representation of gettimeofday() */

	#if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
	static clockid_t per_thread_clock_id[MAX_THREADS];
	#endif

	/* returns the system's monotonic time in nanoseconds if supported, otherwise zero */
	uint64_t now_mono_time(void)
	{
	uint64_t ret = 0;
	#if defined(_POSIX_TIMERS) && defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_MONOTONIC_CLOCK)
	struct timespec ts;
	clock_gettime(CLOCK_MONOTONIC, &ts);
	ret = ts.tv_sec * 1000000000ULL + ts.tv_nsec;
	#endif
	return ret;
	}

	/* returns the current thread's cumulated CPU time in nanoseconds if supported, otherwise zero */
	uint64_t now_cpu_time(void)
	{
	uint64_t ret = 0;
	#if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
	struct timespec ts;
	clock_gettime(CLOCK_THREAD_CPUTIME_ID, &ts);
	ret = ts.tv_sec * 1000000000ULL + ts.tv_nsec;
	#endif
	return ret;
	}

	/* returns another thread's cumulated CPU time in nanoseconds if supported, otherwise zero */
	uint64_t now_cpu_time_thread(int thr)
	{
	uint64_t ret = 0;
	#if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
	struct timespec ts;
	clock_gettime(per_thread_clock_id[thr], &ts);
	ret = ts.tv_sec * 1000000000ULL + ts.tv_nsec;
	#endif
	return ret;
	}

	/* set the clock source for the local thread */
	void clock_set_local_source(void)
	{
	#if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
	#ifdef USE_THREAD
	pthread_getcpuclockid(pthread_self(), &per_thread_clock_id[tid]);
	#else
	per_thread_clock_id[tid] = CLOCK_THREAD_CPUTIME_ID;
	#endif
	#endif
	}

	/* registers a timer <tmr> of type timer_t delivering signal <sig> with value
	* <val>. It tries on the current thread's clock ID first and falls back to
	* CLOCK_REALTIME. Returns non-zero on success, 1 on failure.
	*/
	int clock_setup_signal_timer(void *tmr, int sig, int val)
	{
	int ret = 0;

	#if defined(USE_RT) && (_POSIX_TIMERS > 0) && defined(_POSIX_THREAD_CPUTIME)
	struct sigevent sev = { };
	timer_t *timer = tmr;
	sigset_t set;

	/* unblock the WDTSIG signal we intend to use */
	sigemptyset(&set);
	sigaddset(&set, WDTSIG);
	ha_sigmask(SIG_UNBLOCK, &set, NULL);

	/* this timer will signal WDTSIG when it fires, with tid in the si_int
	* field (important since any thread will receive the signal).
	*/
	sev.sigev_notify = SIGEV_SIGNAL;
	sev.sigev_signo = sig;
	sev.sigev_value.sival_int = val;
	if (timer_create(per_thread_clock_id[tid], &sev, timer) != -1 \|\|
	timer_create(CLOCK_REALTIME, &sev, timer) != -1)
	ret = 1;
	#endif
	return ret;
	}

	/* clock_update_date: sets <date> to system time, and sets <now> to something as
	* close as possible to real time, following a monotonic function. The main
	* principle consists in detecting backwards and forwards time jumps and adjust
	* an offset to correct them. This function should be called once after each
	* poll, and never farther apart than MAX_DELAY_MS*2. The poll's timeout should
	* be passed in <max_wait>, and the return value in <interrupted> (a non-zero
	* value means that we have not expired the timeout).
	*
	* clock_init_process_date() must have been called once first, and
	* clock_init_thread_date() must also have been called once for each thread.
	*
	* An offset is used to adjust the current time (date), to figure a monotonic
	* local time (now). The offset is not critical, as it is only updated after a
	* clock jump is detected. From this point all threads will apply it to their
	* locally measured time, and will then agree around a common monotonic
	* global_now value that serves to further refine their local time. As it is
	* not possible to atomically update a timeval, both global_now and the
	* now_offset values are instead stored as 64-bit integers made of two 32 bit
	* values for the tv_sec and tv_usec parts. The offset is made of two signed
	* ints so that the clock can be adjusted in the two directions.
	*/
	void clock_update_local_date(int max_wait, int interrupted)
	{
	struct timeval min_deadline, max_deadline;
	ullong ofs;

	gettimeofday(&date, NULL);

	/* compute the minimum and maximum local date we may have reached based
	* on our past date and the associated timeout. There are three possible
	* extremities:
	* - the new date cannot be older than before_poll
	* - if not interrupted, the new date cannot be older than
	* before_poll+max_wait
	* - in any case the new date cannot be newer than
	* before_poll+max_wait+some margin (100ms used here).
	* In case of violation, we'll ignore the current date and instead
	* restart from the last date we knew.
	*/
	_tv_ms_add(&min_deadline, &before_poll, max_wait);
	_tv_ms_add(&max_deadline, &before_poll, max_wait + 100);

	ofs = HA_ATOMIC_LOAD(&now_offset);

	if (unlikely(__tv_islt(&date, &before_poll) \|\| // big jump backwards
	(!interrupted && __tv_islt(&date, &min_deadline)) \|\| // small jump backwards
	__tv_islt(&max_deadline, &date))) { // big jump forwards
	if (!interrupted)
	_tv_ms_add(&now, &now, max_wait);
	} else {
	/* The date is still within expectations. Let's apply the
	* now_offset to the system date. Note: ofs if made of two
	* independent signed ints.
	*/
	now.tv_sec = date.tv_sec + (int)(ofs >> 32); // note: may be positive or negative
	now.tv_usec = date.tv_usec + (int)ofs; // note: may be positive or negative
	if ((int)now.tv_usec < 0) {
	now.tv_usec += 1000000;
	now.tv_sec -= 1;
	} else if (now.tv_usec >= 1000000) {
	now.tv_usec -= 1000000;
	now.tv_sec += 1;
	}
	}
	now_ms = __tv_to_ms(&now);
	}

	void clock_update_global_date()
	{
	struct timeval tmp_now;
	uint old_now_ms;
	ullong old_now;
	ullong new_now;
	ullong ofs_new;
	uint sec_ofs, usec_ofs;

	/* now that we have bounded the local time, let's check if it's
	* realistic regarding the global date, which only moves forward,
	* otherwise catch up.
	*/
	old_now = global_now;
	old_now_ms = global_now_ms;

	do {
	tmp_now.tv_sec = (unsigned int)(old_now >> 32);
	tmp_now.tv_usec = old_now & 0xFFFFFFFFU;

	if (__tv_islt(&now, &tmp_now))
	now = tmp_now;

	/* now <now> is expected to be the most accurate date,
	* equal to <global_now> or newer. Updating the global
	* date too often causes extreme contention and is not
	* needed: it's only used to help threads run at the
	* same date in case of local drift, and the global date,
	* which changes, is only used by freq counters (a choice
	* which is debatable by the way since it changes under us).
	* Tests have seen that the contention can be reduced from
	* 37% in this function to almost 0% when keeping clocks
	* synchronized no better than 32 microseconds, so that's
	* what we're doing here.
	*/

	new_now = ((ullong)now.tv_sec << 32) + (uint)now.tv_usec;
	now_ms = __tv_to_ms(&now);

	if (!((new_now ^ old_now) & ~0x1FULL))
	return;

	/* let's try to update the global <now> (both in timeval
	* and ms forms) or loop again.
	*/
	} while ((!_HA_ATOMIC_CAS(&global_now, &old_now, new_now) \|\|
	(now_ms != old_now_ms && !_HA_ATOMIC_CAS(&global_now_ms, &old_now_ms, now_ms))) &&
	__ha_cpu_relax());

	/* <now> and <now_ms> are now updated to the last value of global_now
	* and global_now_ms, which were also monotonically updated. We can
	* compute the latest offset, we don't care who writes it last, the
	* variations will not break the monotonic property.
	*/

	sec_ofs = now.tv_sec - date.tv_sec;
	usec_ofs = now.tv_usec - date.tv_usec;
	if ((int)usec_ofs < 0) {
	usec_ofs += 1000000;
	sec_ofs -= 1;
	}
	ofs_new = ((ullong)sec_ofs << 32) + usec_ofs;
	HA_ATOMIC_STORE(&now_offset, ofs_new);
	}

	/* must be called once at boot to initialize some global variables */
	void clock_init_process_date(void)
	{
	now_offset = 0;
	gettimeofday(&date, NULL);
	now = after_poll = before_poll = date;
	global_now = ((ullong)date.tv_sec << 32) + (uint)date.tv_usec;
	global_now_ms = now.tv_sec * 1000 + now.tv_usec / 1000;
	th_ctx->idle_pct = 100;
	clock_update_date(0, 1);
	}

	/* must be called once per thread to initialize their thread-local variables.
	* Note that other threads might also be initializing and running in parallel.
	*/
	void clock_init_thread_date(void)
	{
	ullong old_now;

	gettimeofday(&date, NULL);
	after_poll = before_poll = date;

	old_now = _HA_ATOMIC_LOAD(&global_now);
	now.tv_sec = old_now >> 32;
	now.tv_usec = (uint)old_now;
	th_ctx->idle_pct = 100;
	clock_update_date(0, 1);
	}

	/* report the average CPU idle percentage over all running threads, between 0 and 100 */
	uint clock_report_idle(void)
	{
	uint total = 0;
	uint rthr = 0;
	uint thr;

	for (thr = 0; thr < MAX_THREADS; thr++) {
	if (!ha_thread_info[thr].tg \|\|
	!(ha_thread_info[thr].tg->threads_enabled & ha_thread_info[thr].ltid_bit))
	continue;
	total += HA_ATOMIC_LOAD(&ha_thread_ctx[thr].idle_pct);
	rthr++;
	}
	return rthr ? total / rthr : 0;
	}

	/* Update the idle time value twice a second, to be called after
	* clock_update_date() when called after poll(), and currently called only by
	* clock_leaving_poll() below. It relies on <before_poll> to be updated to
	* the system time before calling poll().
	*/
	static inline void clock_measure_idle(void)
	{
	/* Let's compute the idle to work ratio. We worked between after_poll
	* and before_poll, and slept between before_poll and date. The idle_pct
	* is updated at most twice every second. Note that the current second
	* rarely changes so we avoid a multiply when not needed.
	*/
	int delta;

	if ((delta = date.tv_sec - before_poll.tv_sec))
	delta *= 1000000;
	idle_time += delta + (date.tv_usec - before_poll.tv_usec);

	if ((delta = date.tv_sec - after_poll.tv_sec))
	delta *= 1000000;
	samp_time += delta + (date.tv_usec - after_poll.tv_usec);

	after_poll.tv_sec = date.tv_sec; after_poll.tv_usec = date.tv_usec;
	if (samp_time < 500000)
	return;

	HA_ATOMIC_STORE(&th_ctx->idle_pct, (100ULL * idle_time + samp_time / 2) / samp_time);
	idle_time = samp_time = 0;
	}

	/* Collect date and time information after leaving poll(). <timeout> must be
	* set to the maximum sleep time passed to poll (in milliseconds), and
	* <interrupted> must be zero if the poller reached the timeout or non-zero
	* otherwise, which generally is provided by the poller's return value.
	*/
	void clock_leaving_poll(int timeout, int interrupted)
	{
	clock_measure_idle();
	th_ctx->prev_cpu_time = now_cpu_time();
	th_ctx->prev_mono_time = now_mono_time();
	}

	/* Collect date and time information before calling poll(). This will be used
	* to count the run time of the past loop and the sleep time of the next poll.
	* It also compares the elapsed and cpu times during the activity period to
	* estimate the amount of stolen time, which is reported if higher than half
	* a millisecond.
	*/
	void clock_entering_poll(void)
	{
	uint64_t new_mono_time;
	uint64_t new_cpu_time;
	uint32_t run_time;
	int64_t stolen;

	gettimeofday(&before_poll, NULL);

	run_time = (before_poll.tv_sec - after_poll.tv_sec) * 1000000U + (before_poll.tv_usec - after_poll.tv_usec);

	new_cpu_time = now_cpu_time();
	new_mono_time = now_mono_time();

	if (th_ctx->prev_cpu_time && th_ctx->prev_mono_time) {
	new_cpu_time -= th_ctx->prev_cpu_time;
	new_mono_time -= th_ctx->prev_mono_time;
	stolen = new_mono_time - new_cpu_time;
	if (unlikely(stolen >= 500000)) {
	stolen /= 500000;
	/* more than half a millisecond difference might
	* indicate an undesired preemption.
	*/
	report_stolen_time(stolen);
	}
	}

	/* update the average runtime */
	activity_count_runtime(run_time);
	}

	/* returns the current date as returned by gettimeofday() in ISO+microsecond
	* format. It uses a thread-local static variable that the reader can consume
	* for as long as it wants until next call. Thus, do not call it from a signal
	* handler. If <pad> is non-0, a trailing space will be added. It will always
	* return exactly 32 or 33 characters (depending on padding) and will always be
	* zero-terminated, thus it will always fit into a 34 bytes buffer.
	* This also always include the local timezone (in +/-HH:mm format) .
	*/
	char *timeofday_as_iso_us(int pad)
	{
	struct timeval new_date;
	struct tm tm;
	const char *offset;
	char c;

	gettimeofday(&new_date, NULL);
	if (new_date.tv_sec != iso_time_sec \|\| !new_date.tv_sec) {
	get_localtime(new_date.tv_sec, &tm);
	offset = get_gmt_offset(new_date.tv_sec, &tm);
	if (unlikely(strftime(iso_time_str, sizeof(iso_time_str), "%Y-%m-%dT%H:%M:%S.000000+00:00", &tm) != 32))
	strcpy(iso_time_str, "YYYY-mm-ddTHH:MM:SS.000000-00:00"); // make the failure visible but respect format.
	iso_time_str[26] = offset[0];
	iso_time_str[27] = offset[1];
	iso_time_str[28] = offset[2];
	iso_time_str[30] = offset[3];
	iso_time_str[31] = offset[4];
	iso_time_sec = new_date.tv_sec;
	}

	/* utoa_pad adds a trailing 0 so we save the char for restore */
	c = iso_time_str[26];
	utoa_pad(new_date.tv_usec, iso_time_str + 20, 7);
	iso_time_str[26] = c;
	if (pad) {
	iso_time_str[32] = ' ';
	iso_time_str[33] = 0;
	}
	return iso_time_str;
	}