src/nstime.c - third_party/github.com/jemalloc/jemalloc - Git at Google

 #include "jemalloc/internal/jemalloc_preamble.h"
 #include "jemalloc/internal/jemalloc_internal_includes.h"

 #include "jemalloc/internal/nstime.h"

 #include "jemalloc/internal/assert.h"

 #define BILLION	UINT64_C(1000000000)
 #define MILLION	UINT64_C(1000000)

 static void
 nstime_set_initialized(nstime_t *time) {
 #ifdef JEMALLOC_DEBUG
 	time->magic = NSTIME_MAGIC;
 #endif
 }

 static void
 nstime_assert_initialized(const nstime_t *time) {
 #ifdef JEMALLOC_DEBUG
 	/*
 	 * Some parts (e.g. stats) rely on memset to zero initialize.  Treat
 	 * these as valid initialization.
 	 */
 	assert(time->magic == NSTIME_MAGIC ||
 	    (time->magic == 0 && time->ns == 0));
 #endif
 }

 static void
 nstime_pair_assert_initialized(const nstime_t *t1, const nstime_t *t2) {
 	nstime_assert_initialized(t1);
 	nstime_assert_initialized(t2);
 }

 static void
 nstime_initialize_operand(nstime_t *time) {
 	/*
 	 * Operations like nstime_add may have the initial operand being zero
 	 * initialized (covered by the assert below).  Full-initialize needed
 	 * before changing it to non-zero.
 	 */
 	nstime_assert_initialized(time);
 	nstime_set_initialized(time);
 }

 void
 nstime_init(nstime_t *time, uint64_t ns) {
 	nstime_set_initialized(time);
 	time->ns = ns;
 }

 void
 nstime_init2(nstime_t *time, uint64_t sec, uint64_t nsec) {
 	nstime_set_initialized(time);
 	time->ns = sec * BILLION + nsec;
 }

 uint64_t
 nstime_ns(const nstime_t *time) {
 	nstime_assert_initialized(time);
 	return time->ns;
 }

 uint64_t
 nstime_msec(const nstime_t *time) {
 	nstime_assert_initialized(time);
 	return time->ns / MILLION;
 }

 uint64_t
 nstime_sec(const nstime_t *time) {
 	nstime_assert_initialized(time);
 	return time->ns / BILLION;
 }

 uint64_t
 nstime_nsec(const nstime_t *time) {
 	nstime_assert_initialized(time);
 	return time->ns % BILLION;
 }

 void
 nstime_copy(nstime_t *time, const nstime_t *source) {
 	/* Source is required to be initialized. */
 	nstime_assert_initialized(source);
 	*time = *source;
 	nstime_assert_initialized(time);
 }

 int
 nstime_compare(const nstime_t *a, const nstime_t *b) {
 	nstime_pair_assert_initialized(a, b);
 	return (a->ns > b->ns) - (a->ns < b->ns);
 }

 void
 nstime_add(nstime_t *time, const nstime_t *addend) {
 	nstime_pair_assert_initialized(time, addend);
 	assert(UINT64_MAX - time->ns >= addend->ns);

 	nstime_initialize_operand(time);
 	time->ns += addend->ns;
 }

 void
 nstime_iadd(nstime_t *time, uint64_t addend) {
 	nstime_assert_initialized(time);
 	assert(UINT64_MAX - time->ns >= addend);

 	nstime_initialize_operand(time);
 	time->ns += addend;
 }

 void
 nstime_subtract(nstime_t *time, const nstime_t *subtrahend) {
 	nstime_pair_assert_initialized(time, subtrahend);
 	assert(nstime_compare(time, subtrahend) >= 0);

 	/* No initialize operand -- subtraction must be initialized. */
 	time->ns -= subtrahend->ns;
 }

 void
 nstime_isubtract(nstime_t *time, uint64_t subtrahend) {
 	nstime_assert_initialized(time);
 	assert(time->ns >= subtrahend);

 	/* No initialize operand -- subtraction must be initialized. */
 	time->ns -= subtrahend;
 }

 void
 nstime_imultiply(nstime_t *time, uint64_t multiplier) {
 	nstime_assert_initialized(time);
 	assert((((time->ns | multiplier) & (UINT64_MAX << (sizeof(uint64_t) <<
 	    2))) == 0) || ((time->ns * multiplier) / multiplier == time->ns));

 	nstime_initialize_operand(time);
 	time->ns *= multiplier;
 }

 void
 nstime_idivide(nstime_t *time, uint64_t divisor) {
 	nstime_assert_initialized(time);
 	assert(divisor != 0);

 	nstime_initialize_operand(time);
 	time->ns /= divisor;
 }

 uint64_t
 nstime_divide(const nstime_t *time, const nstime_t *divisor) {
 	nstime_pair_assert_initialized(time, divisor);
 	assert(divisor->ns != 0);

 	/* No initialize operand -- *time itself remains unchanged. */
 	return time->ns / divisor->ns;
 }

 /* Returns time since *past, w/o updating *past. */
 uint64_t
 nstime_ns_since(const nstime_t *past) {
 	nstime_assert_initialized(past);

 	nstime_t now;
 	nstime_copy(&now, past);
 	nstime_update(&now);

 	assert(nstime_compare(&now, past) >= 0);
 	return now.ns - past->ns;
 }

 #ifdef _WIN32
 #  define NSTIME_MONOTONIC true
 static void
 nstime_get(nstime_t *time) {
 	FILETIME ft;
 	uint64_t ticks_100ns;

 	GetSystemTimeAsFileTime(&ft);
 	ticks_100ns = (((uint64_t)ft.dwHighDateTime) << 32) | ft.dwLowDateTime;

 	nstime_init(time, ticks_100ns * 100);
 }
 #elif defined(JEMALLOC_HAVE_CLOCK_MONOTONIC_COARSE)
 #  define NSTIME_MONOTONIC true
 static void
 nstime_get(nstime_t *time) {
 	struct timespec ts;

 	clock_gettime(CLOCK_MONOTONIC_COARSE, &ts);
 	nstime_init2(time, ts.tv_sec, ts.tv_nsec);
 }
 #elif defined(JEMALLOC_HAVE_CLOCK_MONOTONIC)
 #  define NSTIME_MONOTONIC true
 static void
 nstime_get(nstime_t *time) {
 	struct timespec ts;

 	clock_gettime(CLOCK_MONOTONIC, &ts);
 	nstime_init2(time, ts.tv_sec, ts.tv_nsec);
 }
 #elif defined(JEMALLOC_HAVE_MACH_ABSOLUTE_TIME)
 #  define NSTIME_MONOTONIC true
 static void
 nstime_get(nstime_t *time) {
 	nstime_init(time, mach_absolute_time());
 }
 #else
 #  define NSTIME_MONOTONIC false
 static void
 nstime_get(nstime_t *time) {
 	struct timeval tv;

 	gettimeofday(&tv, NULL);
 	nstime_init2(time, tv.tv_sec, tv.tv_usec * 1000);
 }
 #endif

 static bool
 nstime_monotonic_impl(void) {
 	return NSTIME_MONOTONIC;
 #undef NSTIME_MONOTONIC
 }
 nstime_monotonic_t *JET_MUTABLE nstime_monotonic = nstime_monotonic_impl;

 prof_time_res_t opt_prof_time_res =
 	prof_time_res_default;

 const char *prof_time_res_mode_names[] = {
 	"default",
 	"high",
 };


 static void
 nstime_get_realtime(nstime_t *time) {
 #if defined(JEMALLOC_HAVE_CLOCK_REALTIME) && !defined(_WIN32)
 	struct timespec ts;

 	clock_gettime(CLOCK_REALTIME, &ts);
 	nstime_init2(time, ts.tv_sec, ts.tv_nsec);
 #else
 	unreachable();
 #endif
 }

 static void
 nstime_prof_update_impl(nstime_t *time) {
 	nstime_t old_time;

 	nstime_copy(&old_time, time);

 	if (opt_prof_time_res == prof_time_res_high) {
 		nstime_get_realtime(time);
 	} else {
 		nstime_get(time);
 	}
 }
 nstime_prof_update_t *JET_MUTABLE nstime_prof_update = nstime_prof_update_impl;

 static void
 nstime_update_impl(nstime_t *time) {
 	nstime_t old_time;

 	nstime_copy(&old_time, time);
 	nstime_get(time);

 	/* Handle non-monotonic clocks. */
 	if (unlikely(nstime_compare(&old_time, time) > 0)) {
 		nstime_copy(time, &old_time);
 	}
 }
 nstime_update_t *JET_MUTABLE nstime_update = nstime_update_impl;

 void
 nstime_init_update(nstime_t *time) {
 	nstime_init_zero(time);
 	nstime_update(time);
 }

 void
 nstime_prof_init_update(nstime_t *time) {
 	nstime_init_zero(time);
 	nstime_prof_update(time);
 }
	#include "jemalloc/internal/jemalloc_preamble.h"
	#include "jemalloc/internal/jemalloc_internal_includes.h"

	#include "jemalloc/internal/nstime.h"

	#include "jemalloc/internal/assert.h"

	#define BILLION UINT64_C(1000000000)
	#define MILLION UINT64_C(1000000)

	static void
	nstime_set_initialized(nstime_t *time) {
	#ifdef JEMALLOC_DEBUG
	time->magic = NSTIME_MAGIC;
	#endif
	}

	static void
	nstime_assert_initialized(const nstime_t *time) {
	#ifdef JEMALLOC_DEBUG
	/*
	* Some parts (e.g. stats) rely on memset to zero initialize. Treat
	* these as valid initialization.
	*/
	assert(time->magic == NSTIME_MAGIC \|\|
	(time->magic == 0 && time->ns == 0));
	#endif
	}

	static void
	nstime_pair_assert_initialized(const nstime_t t1, const nstime_t t2) {
	nstime_assert_initialized(t1);
	nstime_assert_initialized(t2);
	}

	static void
	nstime_initialize_operand(nstime_t *time) {
	/*
	* Operations like nstime_add may have the initial operand being zero
	* initialized (covered by the assert below). Full-initialize needed
	* before changing it to non-zero.
	*/
	nstime_assert_initialized(time);
	nstime_set_initialized(time);
	}

	void
	nstime_init(nstime_t *time, uint64_t ns) {
	nstime_set_initialized(time);
	time->ns = ns;
	}

	void
	nstime_init2(nstime_t *time, uint64_t sec, uint64_t nsec) {
	nstime_set_initialized(time);
	time->ns = sec * BILLION + nsec;
	}

	uint64_t
	nstime_ns(const nstime_t *time) {
	nstime_assert_initialized(time);
	return time->ns;
	}

	uint64_t
	nstime_msec(const nstime_t *time) {
	nstime_assert_initialized(time);
	return time->ns / MILLION;
	}

	uint64_t
	nstime_sec(const nstime_t *time) {
	nstime_assert_initialized(time);
	return time->ns / BILLION;
	}

	uint64_t
	nstime_nsec(const nstime_t *time) {
	nstime_assert_initialized(time);
	return time->ns % BILLION;
	}

	void
	nstime_copy(nstime_t time, const nstime_t source) {
	/* Source is required to be initialized. */
	nstime_assert_initialized(source);
	time = source;
	nstime_assert_initialized(time);
	}

	int
	nstime_compare(const nstime_t a, const nstime_t b) {
	nstime_pair_assert_initialized(a, b);
	return (a->ns > b->ns) - (a->ns < b->ns);
	}

	void
	nstime_add(nstime_t time, const nstime_t addend) {
	nstime_pair_assert_initialized(time, addend);
	assert(UINT64_MAX - time->ns >= addend->ns);

	nstime_initialize_operand(time);
	time->ns += addend->ns;
	}

	void
	nstime_iadd(nstime_t *time, uint64_t addend) {
	nstime_assert_initialized(time);
	assert(UINT64_MAX - time->ns >= addend);

	nstime_initialize_operand(time);
	time->ns += addend;
	}

	void
	nstime_subtract(nstime_t time, const nstime_t subtrahend) {
	nstime_pair_assert_initialized(time, subtrahend);
	assert(nstime_compare(time, subtrahend) >= 0);

	/* No initialize operand -- subtraction must be initialized. */
	time->ns -= subtrahend->ns;
	}

	void
	nstime_isubtract(nstime_t *time, uint64_t subtrahend) {
	nstime_assert_initialized(time);
	assert(time->ns >= subtrahend);

	/* No initialize operand -- subtraction must be initialized. */
	time->ns -= subtrahend;
	}

	void
	nstime_imultiply(nstime_t *time, uint64_t multiplier) {
	nstime_assert_initialized(time);
	assert((((time->ns \| multiplier) & (UINT64_MAX << (sizeof(uint64_t) <<
	2))) == 0) \|\| ((time->ns * multiplier) / multiplier == time->ns));

	nstime_initialize_operand(time);
	time->ns *= multiplier;
	}

	void
	nstime_idivide(nstime_t *time, uint64_t divisor) {
	nstime_assert_initialized(time);
	assert(divisor != 0);

	nstime_initialize_operand(time);
	time->ns /= divisor;
	}

	uint64_t
	nstime_divide(const nstime_t time, const nstime_t divisor) {
	nstime_pair_assert_initialized(time, divisor);
	assert(divisor->ns != 0);

	/* No initialize operand -- time itself remains unchanged. /
	return time->ns / divisor->ns;
	}

	/* Returns time since past, w/o updating past. */
	uint64_t
	nstime_ns_since(const nstime_t *past) {
	nstime_assert_initialized(past);

	nstime_t now;
	nstime_copy(&now, past);
	nstime_update(&now);

	assert(nstime_compare(&now, past) >= 0);
	return now.ns - past->ns;
	}

	#ifdef _WIN32
	# define NSTIME_MONOTONIC true
	static void
	nstime_get(nstime_t *time) {
	FILETIME ft;
	uint64_t ticks_100ns;

	GetSystemTimeAsFileTime(&ft);
	ticks_100ns = (((uint64_t)ft.dwHighDateTime) << 32) \| ft.dwLowDateTime;

	nstime_init(time, ticks_100ns * 100);
	}
	#elif defined(JEMALLOC_HAVE_CLOCK_MONOTONIC_COARSE)
	# define NSTIME_MONOTONIC true
	static void
	nstime_get(nstime_t *time) {
	struct timespec ts;

	clock_gettime(CLOCK_MONOTONIC_COARSE, &ts);
	nstime_init2(time, ts.tv_sec, ts.tv_nsec);
	}
	#elif defined(JEMALLOC_HAVE_CLOCK_MONOTONIC)
	# define NSTIME_MONOTONIC true
	static void
	nstime_get(nstime_t *time) {
	struct timespec ts;

	clock_gettime(CLOCK_MONOTONIC, &ts);
	nstime_init2(time, ts.tv_sec, ts.tv_nsec);
	}
	#elif defined(JEMALLOC_HAVE_MACH_ABSOLUTE_TIME)
	# define NSTIME_MONOTONIC true
	static void
	nstime_get(nstime_t *time) {
	nstime_init(time, mach_absolute_time());
	}
	#else
	# define NSTIME_MONOTONIC false
	static void
	nstime_get(nstime_t *time) {
	struct timeval tv;

	gettimeofday(&tv, NULL);
	nstime_init2(time, tv.tv_sec, tv.tv_usec * 1000);
	}
	#endif

	static bool
	nstime_monotonic_impl(void) {
	return NSTIME_MONOTONIC;
	#undef NSTIME_MONOTONIC
	}
	nstime_monotonic_t *JET_MUTABLE nstime_monotonic = nstime_monotonic_impl;

	prof_time_res_t opt_prof_time_res =
	prof_time_res_default;

	const char *prof_time_res_mode_names[] = {
	"default",
	"high",
	};


	static void
	nstime_get_realtime(nstime_t *time) {
	#if defined(JEMALLOC_HAVE_CLOCK_REALTIME) && !defined(_WIN32)
	struct timespec ts;

	clock_gettime(CLOCK_REALTIME, &ts);
	nstime_init2(time, ts.tv_sec, ts.tv_nsec);
	#else
	unreachable();
	#endif
	}

	static void
	nstime_prof_update_impl(nstime_t *time) {
	nstime_t old_time;

	nstime_copy(&old_time, time);

	if (opt_prof_time_res == prof_time_res_high) {
	nstime_get_realtime(time);
	} else {
	nstime_get(time);
	}
	}
	nstime_prof_update_t *JET_MUTABLE nstime_prof_update = nstime_prof_update_impl;

	static void
	nstime_update_impl(nstime_t *time) {
	nstime_t old_time;

	nstime_copy(&old_time, time);
	nstime_get(time);

	/* Handle non-monotonic clocks. */
	if (unlikely(nstime_compare(&old_time, time) > 0)) {
	nstime_copy(time, &old_time);
	}
	}
	nstime_update_t *JET_MUTABLE nstime_update = nstime_update_impl;

	void
	nstime_init_update(nstime_t *time) {
	nstime_init_zero(time);
	nstime_update(time);
	}

	void
	nstime_prof_init_update(nstime_t *time) {
	nstime_init_zero(time);
	nstime_prof_update(time);
	}