[fio.git] / gettime.c

/*
 * Clock functions
 */

#include <unistd.h>
#include <math.h>
#include <sys/time.h>
#include <time.h>

#include "fio.h"
#include "smalloc.h"

#include "hash.h"

#ifdef ARCH_HAVE_CPU_CLOCK
static unsigned long cycles_per_usec;
static unsigned long last_cycles;
int tsc_reliable = 0;
#endif
static struct timeval last_tv;
static int last_tv_valid;

enum fio_cs fio_clock_source = FIO_PREFERRED_CLOCK_SOURCE;
int fio_clock_source_set = 0;

#ifdef FIO_DEBUG_TIME

#define HASH_BITS	8
#define HASH_SIZE	(1 << HASH_BITS)

static struct flist_head hash[HASH_SIZE];
static int gtod_inited;

struct gtod_log {
	struct flist_head list;
	void *caller;
	unsigned long calls;
};

static struct gtod_log *find_hash(void *caller)
{
	unsigned long h = hash_ptr(caller, HASH_BITS);
	struct flist_head *entry;

	flist_for_each(entry, &hash[h]) {
		struct gtod_log *log = flist_entry(entry, struct gtod_log,
									list);

		if (log->caller == caller)
			return log;
	}

	return NULL;
}

static struct gtod_log *find_log(void *caller)
{
	struct gtod_log *log = find_hash(caller);

	if (!log) {
		unsigned long h;

		log = malloc(sizeof(*log));
		INIT_FLIST_HEAD(&log->list);
		log->caller = caller;
		log->calls = 0;

		h = hash_ptr(caller, HASH_BITS);
		flist_add_tail(&log->list, &hash[h]);
	}

	return log;
}

static void gtod_log_caller(void *caller)
{
	if (gtod_inited) {
		struct gtod_log *log = find_log(caller);

		log->calls++;
	}
}

static void fio_exit fio_dump_gtod(void)
{
	unsigned long total_calls = 0;
	int i;

	for (i = 0; i < HASH_SIZE; i++) {
		struct flist_head *entry;
		struct gtod_log *log;

		flist_for_each(entry, &hash[i]) {
			log = flist_entry(entry, struct gtod_log, list);

			printf("function %p, calls %lu\n", log->caller,
								log->calls);
			total_calls += log->calls;
		}
	}

	printf("Total %lu gettimeofday\n", total_calls);
}

static void fio_init gtod_init(void)
{
	int i;

	for (i = 0; i < HASH_SIZE; i++)
		INIT_FLIST_HEAD(&hash[i]);

	gtod_inited = 1;
}

#endif /* FIO_DEBUG_TIME */

#ifdef FIO_DEBUG_TIME
void fio_gettime(struct timeval *tp, void *caller)
#else
void fio_gettime(struct timeval *tp, void fio_unused *caller)
#endif
{
#ifdef FIO_DEBUG_TIME
	if (!caller)
		caller = __builtin_return_address(0);

	gtod_log_caller(caller);
#endif
	if (fio_tv) {
		memcpy(tp, fio_tv, sizeof(*tp));
		return;
	}

	switch (fio_clock_source) {
	case CS_GTOD:
		gettimeofday(tp, NULL);
		break;
	case CS_CGETTIME: {
		struct timespec ts;

#ifdef FIO_HAVE_CLOCK_MONOTONIC
		if (clock_gettime(CLOCK_MONOTONIC, &ts) < 0) {
#else
		if (clock_gettime(CLOCK_REALTIME, &ts) < 0) {
#endif
			log_err("fio: clock_gettime fails\n");
			assert(0);
		}

		tp->tv_sec = ts.tv_sec;
		tp->tv_usec = ts.tv_nsec / 1000;
		break;
		}
#ifdef ARCH_HAVE_CPU_CLOCK
	case CS_CPUCLOCK: {
		unsigned long long usecs, t;

		t = get_cpu_clock();
		if (t < last_cycles) {
			dprint(FD_TIME, "CPU clock going back in time\n");
			t = last_cycles;
		}

		usecs = t / cycles_per_usec;
		tp->tv_sec = usecs / 1000000;
		tp->tv_usec = usecs % 1000000;
		last_cycles = t;
		break;
		}
#endif
	default:
		log_err("fio: invalid clock source %d\n", fio_clock_source);
		break;
	}

	/*
	 * If Linux is using the tsc clock on non-synced processors,
	 * sometimes time can appear to drift backwards. Fix that up.
	 */
	if (last_tv_valid) {
		if (tp->tv_sec < last_tv.tv_sec)
			tp->tv_sec = last_tv.tv_sec;
		else if (last_tv.tv_sec == tp->tv_sec &&
			 tp->tv_usec < last_tv.tv_usec)
			tp->tv_usec = last_tv.tv_usec;
	}
	last_tv_valid = 1;
	memcpy(&last_tv, tp, sizeof(*tp));
}

#ifdef ARCH_HAVE_CPU_CLOCK
static unsigned long get_cycles_per_usec(void)
{
	struct timeval s, e;
	unsigned long long c_s, c_e;

	gettimeofday(&s, NULL);
	c_s = get_cpu_clock();
	do {
		unsigned long long elapsed;

		gettimeofday(&e, NULL);
		elapsed = utime_since(&s, &e);
		if (elapsed >= 1280) {
			c_e = get_cpu_clock();
			break;
		}
	} while (1);

	return (c_e - c_s) >> 7;
}

#define NR_TIME_ITERS	50

static void calibrate_cpu_clock(void)
{
	double delta, mean, S;
	unsigned long avg, cycles[NR_TIME_ITERS];
	int i, samples;

	cycles[0] = get_cycles_per_usec();
	S = delta = mean = 0.0;
	for (i = 0; i < NR_TIME_ITERS; i++) {
		cycles[i] = get_cycles_per_usec();
		delta = cycles[i] - mean;
		if (delta) {
			mean += delta / (i + 1.0);
			S += delta * (cycles[i] - mean);
		}
	}

	S = sqrt(S / (NR_TIME_ITERS - 1.0));

	samples = avg = 0;
	for (i = 0; i < NR_TIME_ITERS; i++) {
		double this = cycles[i];

		if ((fmax(this, mean) - fmin(this, mean)) > S)
			continue;
		samples++;
		avg += this;
	}

	S /= (double) NR_TIME_ITERS;
	mean /= (double) NR_TIME_ITERS;

	for (i = 0; i < NR_TIME_ITERS; i++)
		dprint(FD_TIME, "cycles[%d]=%lu\n", i, cycles[i] / 10);

	avg /= (samples * 10);
	dprint(FD_TIME, "avg: %lu\n", avg);
	dprint(FD_TIME, "mean=%f, S=%f\n", mean, S);

	cycles_per_usec = avg;
}
#else
static void calibrate_cpu_clock(void)
{
}
#endif

void fio_clock_init(void)
{
	last_tv_valid = 0;
	calibrate_cpu_clock();

	/*
	 * If the arch sets tsc_reliable != 0, then it must be good enough
	 * to use as THE clock source. For x86 CPUs, this means the TSC
	 * runs at a constant rate and is synced across CPU cores.
	 */
	if (tsc_reliable) {
		if (!fio_clock_source_set)
			fio_clock_source = CS_CPUCLOCK;
	} else if (fio_clock_source == CS_CPUCLOCK)
		log_info("fio: clocksource=cpu may not be reliable\n");
}

unsigned long long utime_since(struct timeval *s, struct timeval *e)
{
	long sec, usec;
	unsigned long long ret;

	sec = e->tv_sec - s->tv_sec;
	usec = e->tv_usec - s->tv_usec;
	if (sec > 0 && usec < 0) {
		sec--;
		usec += 1000000;
	}

	/*
	 * time warp bug on some kernels?
	 */
	if (sec < 0 || (sec == 0 && usec < 0))
		return 0;

	ret = sec * 1000000ULL + usec;

	return ret;
}

unsigned long long utime_since_now(struct timeval *s)
{
	struct timeval t;

	fio_gettime(&t, NULL);
	return utime_since(s, &t);
}

unsigned long mtime_since(struct timeval *s, struct timeval *e)
{
	long sec, usec, ret;

	sec = e->tv_sec - s->tv_sec;
	usec = e->tv_usec - s->tv_usec;
	if (sec > 0 && usec < 0) {
		sec--;
		usec += 1000000;
	}

	if (sec < 0 || (sec == 0 && usec < 0))
		return 0;

	sec *= 1000UL;
	usec /= 1000UL;
	ret = sec + usec;

	return ret;
}

unsigned long mtime_since_now(struct timeval *s)
{
	struct timeval t;
	void *p = __builtin_return_address(0);

	fio_gettime(&t, p);
	return mtime_since(s, &t);
}

unsigned long time_since_now(struct timeval *s)
{
	return mtime_since_now(s) / 1000;
}
Commit	Line	Data
	1	/*
	2	* Clock functions
	3	*/
	4
	5	#include <unistd.h>
	6	#include <math.h>
	7	#include <sys/time.h>
	8	#include <time.h>
	9
	10	#include "fio.h"
	11	#include "smalloc.h"
	12
	13	#include "hash.h"
	14
	15	#ifdef ARCH_HAVE_CPU_CLOCK
	16	static unsigned long cycles_per_usec;
	17	static unsigned long last_cycles;
	18	int tsc_reliable = 0;
	19	#endif
	20	static struct timeval last_tv;
	21	static int last_tv_valid;
	22
	23	enum fio_cs fio_clock_source = FIO_PREFERRED_CLOCK_SOURCE;
	24	int fio_clock_source_set = 0;
	25
	26	#ifdef FIO_DEBUG_TIME
	27
	28	#define HASH_BITS 8
	29	#define HASH_SIZE (1 << HASH_BITS)
	30
	31	static struct flist_head hash[HASH_SIZE];
	32	static int gtod_inited;
	33
	34	struct gtod_log {
	35	struct flist_head list;
	36	void *caller;
	37	unsigned long calls;
	38	};
	39
	40	static struct gtod_log find_hash(void caller)
	41	{
	42	unsigned long h = hash_ptr(caller, HASH_BITS);
	43	struct flist_head *entry;
	44
	45	flist_for_each(entry, &hash[h]) {
	46	struct gtod_log *log = flist_entry(entry, struct gtod_log,
	47	list);
	48
	49	if (log->caller == caller)
	50	return log;
	51	}
	52
	53	return NULL;
	54	}
	55
	56	static struct gtod_log find_log(void caller)
	57	{
	58	struct gtod_log *log = find_hash(caller);
	59
	60	if (!log) {
	61	unsigned long h;
	62
	63	log = malloc(sizeof(*log));
	64	INIT_FLIST_HEAD(&log->list);
	65	log->caller = caller;
	66	log->calls = 0;
	67
	68	h = hash_ptr(caller, HASH_BITS);
	69	flist_add_tail(&log->list, &hash[h]);
	70	}
	71
	72	return log;
	73	}
	74
	75	static void gtod_log_caller(void *caller)
	76	{
	77	if (gtod_inited) {
	78	struct gtod_log *log = find_log(caller);
	79
	80	log->calls++;
	81	}
	82	}
	83
	84	static void fio_exit fio_dump_gtod(void)
	85	{
	86	unsigned long total_calls = 0;
	87	int i;
	88
	89	for (i = 0; i < HASH_SIZE; i++) {
	90	struct flist_head *entry;
	91	struct gtod_log *log;
	92
	93	flist_for_each(entry, &hash[i]) {
	94	log = flist_entry(entry, struct gtod_log, list);
	95
	96	printf("function %p, calls %lu\n", log->caller,
	97	log->calls);
	98	total_calls += log->calls;
	99	}
	100	}
	101
	102	printf("Total %lu gettimeofday\n", total_calls);
	103	}
	104
	105	static void fio_init gtod_init(void)
	106	{
	107	int i;
	108
	109	for (i = 0; i < HASH_SIZE; i++)
	110	INIT_FLIST_HEAD(&hash[i]);
	111
	112	gtod_inited = 1;
	113	}
	114
	115	#endif /* FIO_DEBUG_TIME */
	116
	117	#ifdef FIO_DEBUG_TIME
	118	void fio_gettime(struct timeval tp, void caller)
	119	#else
	120	void fio_gettime(struct timeval tp, void fio_unused caller)
	121	#endif
	122	{
	123	#ifdef FIO_DEBUG_TIME
	124	if (!caller)
	125	caller = __builtin_return_address(0);
	126
	127	gtod_log_caller(caller);
	128	#endif
	129	if (fio_tv) {
	130	memcpy(tp, fio_tv, sizeof(*tp));
	131	return;
	132	}
	133
	134	switch (fio_clock_source) {
	135	case CS_GTOD:
	136	gettimeofday(tp, NULL);
	137	break;
	138	case CS_CGETTIME: {
	139	struct timespec ts;
	140
	141	#ifdef FIO_HAVE_CLOCK_MONOTONIC
	142	if (clock_gettime(CLOCK_MONOTONIC, &ts) < 0) {
	143	#else
	144	if (clock_gettime(CLOCK_REALTIME, &ts) < 0) {
	145	#endif
	146	log_err("fio: clock_gettime fails\n");
	147	assert(0);
	148	}
	149
	150	tp->tv_sec = ts.tv_sec;
	151	tp->tv_usec = ts.tv_nsec / 1000;
	152	break;
	153	}
	154	#ifdef ARCH_HAVE_CPU_CLOCK
	155	case CS_CPUCLOCK: {
	156	unsigned long long usecs, t;
	157
	158	t = get_cpu_clock();
	159	if (t < last_cycles) {
	160	dprint(FD_TIME, "CPU clock going back in time\n");
	161	t = last_cycles;
	162	}
	163
	164	usecs = t / cycles_per_usec;
	165	tp->tv_sec = usecs / 1000000;
	166	tp->tv_usec = usecs % 1000000;
	167	last_cycles = t;
	168	break;
	169	}
	170	#endif
	171	default:
	172	log_err("fio: invalid clock source %d\n", fio_clock_source);
	173	break;
	174	}
	175
	176	/*
	177	* If Linux is using the tsc clock on non-synced processors,
	178	* sometimes time can appear to drift backwards. Fix that up.
	179	*/
	180	if (last_tv_valid) {
	181	if (tp->tv_sec < last_tv.tv_sec)
	182	tp->tv_sec = last_tv.tv_sec;
	183	else if (last_tv.tv_sec == tp->tv_sec &&
	184	tp->tv_usec < last_tv.tv_usec)
	185	tp->tv_usec = last_tv.tv_usec;
	186	}
	187	last_tv_valid = 1;
	188	memcpy(&last_tv, tp, sizeof(*tp));
	189	}
	190
	191	#ifdef ARCH_HAVE_CPU_CLOCK
	192	static unsigned long get_cycles_per_usec(void)
	193	{
	194	struct timeval s, e;
	195	unsigned long long c_s, c_e;
	196
	197	gettimeofday(&s, NULL);
	198	c_s = get_cpu_clock();
	199	do {
	200	unsigned long long elapsed;
	201
	202	gettimeofday(&e, NULL);
	203	elapsed = utime_since(&s, &e);
	204	if (elapsed >= 1280) {
	205	c_e = get_cpu_clock();
	206	break;
	207	}
	208	} while (1);
	209
	210	return (c_e - c_s) >> 7;
	211	}
	212
	213	#define NR_TIME_ITERS 50
	214
	215	static void calibrate_cpu_clock(void)
	216	{
	217	double delta, mean, S;
	218	unsigned long avg, cycles[NR_TIME_ITERS];
	219	int i, samples;
	220
	221	cycles[0] = get_cycles_per_usec();
	222	S = delta = mean = 0.0;
	223	for (i = 0; i < NR_TIME_ITERS; i++) {
	224	cycles[i] = get_cycles_per_usec();
	225	delta = cycles[i] - mean;
	226	if (delta) {
	227	mean += delta / (i + 1.0);
	228	S += delta * (cycles[i] - mean);
	229	}
	230	}
	231
	232	S = sqrt(S / (NR_TIME_ITERS - 1.0));
	233
	234	samples = avg = 0;
	235	for (i = 0; i < NR_TIME_ITERS; i++) {
	236	double this = cycles[i];
	237
	238	if ((fmax(this, mean) - fmin(this, mean)) > S)
	239	continue;
	240	samples++;
	241	avg += this;
	242	}
	243
	244	S /= (double) NR_TIME_ITERS;
	245	mean /= (double) NR_TIME_ITERS;
	246
	247	for (i = 0; i < NR_TIME_ITERS; i++)
	248	dprint(FD_TIME, "cycles[%d]=%lu\n", i, cycles[i] / 10);
	249
	250	avg /= (samples * 10);
	251	dprint(FD_TIME, "avg: %lu\n", avg);
	252	dprint(FD_TIME, "mean=%f, S=%f\n", mean, S);
	253
	254	cycles_per_usec = avg;
	255	}
	256	#else
	257	static void calibrate_cpu_clock(void)
	258	{
	259	}
	260	#endif
	261
	262	void fio_clock_init(void)
	263	{
	264	last_tv_valid = 0;
	265	calibrate_cpu_clock();
	266
	267	/*
	268	* If the arch sets tsc_reliable != 0, then it must be good enough
	269	* to use as THE clock source. For x86 CPUs, this means the TSC
	270	* runs at a constant rate and is synced across CPU cores.
	271	*/
	272	if (tsc_reliable) {
	273	if (!fio_clock_source_set)
	274	fio_clock_source = CS_CPUCLOCK;
	275	} else if (fio_clock_source == CS_CPUCLOCK)
	276	log_info("fio: clocksource=cpu may not be reliable\n");
	277	}
	278
	279	unsigned long long utime_since(struct timeval s, struct timeval e)
	280	{
	281	long sec, usec;
	282	unsigned long long ret;
	283
	284	sec = e->tv_sec - s->tv_sec;
	285	usec = e->tv_usec - s->tv_usec;
	286	if (sec > 0 && usec < 0) {
	287	sec--;
	288	usec += 1000000;
	289	}
	290
	291	/*
	292	* time warp bug on some kernels?
	293	*/
	294	if (sec < 0 \|\| (sec == 0 && usec < 0))
	295	return 0;
	296
	297	ret = sec * 1000000ULL + usec;
	298
	299	return ret;
	300	}
	301
	302	unsigned long long utime_since_now(struct timeval *s)
	303	{
	304	struct timeval t;
	305
	306	fio_gettime(&t, NULL);
	307	return utime_since(s, &t);
	308	}
	309
	310	unsigned long mtime_since(struct timeval s, struct timeval e)
	311	{
	312	long sec, usec, ret;
	313
	314	sec = e->tv_sec - s->tv_sec;
	315	usec = e->tv_usec - s->tv_usec;
	316	if (sec > 0 && usec < 0) {
	317	sec--;
	318	usec += 1000000;
	319	}
	320
	321	if (sec < 0 \|\| (sec == 0 && usec < 0))
	322	return 0;
	323
	324	sec *= 1000UL;
	325	usec /= 1000UL;
	326	ret = sec + usec;
	327
	328	return ret;
	329	}
	330
	331	unsigned long mtime_since_now(struct timeval *s)
	332	{
	333	struct timeval t;
	334	void *p = __builtin_return_address(0);
	335
	336	fio_gettime(&t, p);
	337	return mtime_since(s, &t);
	338	}
	339
	340	unsigned long time_since_now(struct timeval *s)
	341	{
	342	return mtime_since_now(s) / 1000;
	343	}