tor/src/common/compat_time.c

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/* Copyright (c) 2003-2004, Roger Dingledine
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
2017-03-15 21:13:17 +01:00
* Copyright (c) 2007-2017, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file compat_time.c
* \brief Portable wrappers for finding out the current time, running
* timers, etc.
**/
#define COMPAT_TIME_PRIVATE
#include "compat.h"
#ifdef _WIN32
#include <winsock2.h>
#include <windows.h>
#endif
#ifdef HAVE_SYS_TYPES_H
#include <sys/types.h>
#endif
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#ifdef TOR_UNIT_TESTS
#if !defined(HAVE_USLEEP) && defined(HAVE_SYS_SELECT_H)
/* as fallback implementation for tor_sleep_msec */
#include <sys/select.h>
#endif
#endif /* defined(TOR_UNIT_TESTS) */
#ifdef __APPLE__
#include <mach/mach_time.h>
#endif
#include "torlog.h"
#include "util.h"
#include "container.h"
#ifndef HAVE_GETTIMEOFDAY
#ifdef HAVE_FTIME
#include <sys/timeb.h>
#endif
#endif
#ifdef _WIN32
#undef HAVE_CLOCK_GETTIME
#endif
#ifdef TOR_UNIT_TESTS
/** Delay for <b>msec</b> milliseconds. Only used in tests. */
void
tor_sleep_msec(int msec)
{
#ifdef _WIN32
Sleep(msec);
#elif defined(HAVE_USLEEP)
sleep(msec / 1000);
/* Some usleep()s hate sleeping more than 1 sec */
usleep((msec % 1000) * 1000);
#elif defined(HAVE_SYS_SELECT_H)
struct timeval tv = { msec / 1000, (msec % 1000) * 1000};
select(0, NULL, NULL, NULL, &tv);
#else
sleep(CEIL_DIV(msec, 1000));
#endif /* defined(_WIN32) || ... */
}
#endif /* defined(TOR_UNIT_TESTS) */
/** Set *timeval to the current time of day. On error, log and terminate.
* (Same as gettimeofday(timeval,NULL), but never returns -1.)
*/
2018-04-17 02:18:40 +02:00
MOCK_IMPL(void,
tor_gettimeofday, (struct timeval *timeval))
{
#ifdef _WIN32
/* Epoch bias copied from perl: number of units between windows epoch and
* Unix epoch. */
#define EPOCH_BIAS U64_LITERAL(116444736000000000)
#define UNITS_PER_SEC U64_LITERAL(10000000)
#define USEC_PER_SEC U64_LITERAL(1000000)
#define UNITS_PER_USEC U64_LITERAL(10)
union {
uint64_t ft_64;
FILETIME ft_ft;
} ft;
/* number of 100-nsec units since Jan 1, 1601 */
GetSystemTimeAsFileTime(&ft.ft_ft);
if (ft.ft_64 < EPOCH_BIAS) {
/* LCOV_EXCL_START */
log_err(LD_GENERAL,"System time is before 1970; failing.");
exit(1); // exit ok: system clock is broken.
/* LCOV_EXCL_STOP */
}
ft.ft_64 -= EPOCH_BIAS;
timeval->tv_sec = (unsigned) (ft.ft_64 / UNITS_PER_SEC);
timeval->tv_usec = (unsigned) ((ft.ft_64 / UNITS_PER_USEC) % USEC_PER_SEC);
#elif defined(HAVE_GETTIMEOFDAY)
if (gettimeofday(timeval, NULL)) {
/* LCOV_EXCL_START */
log_err(LD_GENERAL,"gettimeofday failed.");
/* If gettimeofday dies, we have either given a bad timezone (we didn't),
or segfaulted.*/
exit(1); // exit ok: gettimeofday failed.
/* LCOV_EXCL_STOP */
}
#elif defined(HAVE_FTIME)
struct timeb tb;
ftime(&tb);
timeval->tv_sec = tb.time;
timeval->tv_usec = tb.millitm * 1000;
#else
#error "No way to get time."
#endif /* defined(_WIN32) || ... */
return;
}
#define ONE_MILLION ((int64_t) (1000 * 1000))
#define ONE_BILLION ((int64_t) (1000 * 1000 * 1000))
/** True iff monotime_init has been called. */
static int monotime_initialized = 0;
static monotime_t initialized_at;
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
static monotime_coarse_t initialized_at_coarse;
#endif
#ifdef TOR_UNIT_TESTS
/** True if we are running unit tests and overriding the current monotonic
* time. Note that mocked monotonic time might not be monotonic.
*/
static int monotime_mocking_enabled = 0;
static monotime_t initialized_at_saved;
static int64_t mock_time_nsec = 0;
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
static int64_t mock_time_nsec_coarse = 0;
static monotime_coarse_t initialized_at_coarse_saved;
#endif
void
monotime_enable_test_mocking(void)
{
if (BUG(monotime_initialized == 0)) {
monotime_init();
}
tor_assert_nonfatal(monotime_mocking_enabled == 0);
monotime_mocking_enabled = 1;
memcpy(&initialized_at_saved,
&initialized_at, sizeof(monotime_t));
memset(&initialized_at, 0, sizeof(monotime_t));
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
memcpy(&initialized_at_coarse_saved,
&initialized_at_coarse, sizeof(monotime_coarse_t));
memset(&initialized_at_coarse, 0, sizeof(monotime_coarse_t));
#endif
}
void
monotime_disable_test_mocking(void)
{
tor_assert_nonfatal(monotime_mocking_enabled == 1);
monotime_mocking_enabled = 0;
memcpy(&initialized_at,
&initialized_at_saved, sizeof(monotime_t));
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
memcpy(&initialized_at_coarse,
&initialized_at_coarse_saved, sizeof(monotime_coarse_t));
#endif
}
void
monotime_set_mock_time_nsec(int64_t nsec)
{
tor_assert_nonfatal(monotime_mocking_enabled == 1);
mock_time_nsec = nsec;
}
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
void
monotime_coarse_set_mock_time_nsec(int64_t nsec)
{
tor_assert_nonfatal(monotime_mocking_enabled == 1);
mock_time_nsec_coarse = nsec;
}
#endif /* defined(MONOTIME_COARSE_FN_IS_DIFFERENT) */
#endif /* defined(TOR_UNIT_TESTS) */
/* "ratchet" functions for monotonic time. */
#if defined(_WIN32) || defined(TOR_UNIT_TESTS)
/** Protected by lock: last value returned by monotime_get(). */
static int64_t last_pctr = 0;
/** Protected by lock: offset we must add to monotonic time values. */
static int64_t pctr_offset = 0;
/* If we are using GetTickCount(), how many times has it rolled over? */
static uint32_t rollover_count = 0;
/* If we are using GetTickCount(), what's the last value it returned? */
static int64_t last_tick_count = 0;
/** Helper for windows: Called with a sequence of times that are supposed
* to be monotonic; increments them as appropriate so that they actually
* _are_ monotonic.
*
* Caller must hold lock. */
STATIC int64_t
ratchet_performance_counter(int64_t count_raw)
{
/* must hold lock */
const int64_t count_adjusted = count_raw + pctr_offset;
if (PREDICT_UNLIKELY(count_adjusted < last_pctr)) {
/* Monotonicity failed! Pretend no time elapsed. */
pctr_offset = last_pctr - count_raw;
return last_pctr;
} else {
last_pctr = count_adjusted;
return count_adjusted;
}
}
STATIC int64_t
ratchet_coarse_performance_counter(const int64_t count_raw)
{
int64_t count = count_raw + (((int64_t)rollover_count) << 32);
while (PREDICT_UNLIKELY(count < last_tick_count)) {
++rollover_count;
count = count_raw + (((int64_t)rollover_count) << 32);
}
last_tick_count = count;
return count;
}
#endif /* defined(_WIN32) || defined(TOR_UNIT_TESTS) */
#if defined(MONOTIME_USING_GETTIMEOFDAY) || defined(TOR_UNIT_TESTS)
static struct timeval last_timeofday = { 0, 0 };
static struct timeval timeofday_offset = { 0, 0 };
/** Helper for gettimeofday(): Called with a sequence of times that are
* supposed to be monotonic; increments them as appropriate so that they
* actually _are_ monotonic.
*
* Caller must hold lock. */
STATIC void
ratchet_timeval(const struct timeval *timeval_raw, struct timeval *out)
{
/* must hold lock */
timeradd(timeval_raw, &timeofday_offset, out);
if (PREDICT_UNLIKELY(timercmp(out, &last_timeofday, OP_LT))) {
/* time ran backwards. Instead, declare that no time occurred. */
timersub(&last_timeofday, timeval_raw, &timeofday_offset);
memcpy(out, &last_timeofday, sizeof(struct timeval));
} else {
memcpy(&last_timeofday, out, sizeof(struct timeval));
}
}
#endif /* defined(MONOTIME_USING_GETTIMEOFDAY) || defined(TOR_UNIT_TESTS) */
#ifdef TOR_UNIT_TESTS
/** For testing: reset all the ratchets */
void
monotime_reset_ratchets_for_testing(void)
{
last_pctr = pctr_offset = last_tick_count = 0;
rollover_count = 0;
memset(&last_timeofday, 0, sizeof(struct timeval));
memset(&timeofday_offset, 0, sizeof(struct timeval));
}
#endif /* defined(TOR_UNIT_TESTS) */
#ifdef __APPLE__
/** Initialized on startup: tells is how to convert from ticks to
* nanoseconds.
*/
static struct mach_timebase_info mach_time_info;
static struct mach_timebase_info mach_time_info_msec_cvt;
static int monotime_shift = 0;
static void
monotime_init_internal(void)
{
tor_assert(!monotime_initialized);
int r = mach_timebase_info(&mach_time_info);
tor_assert(r == 0);
tor_assert(mach_time_info.denom != 0);
{
// approximate only.
uint64_t ns_per_tick = mach_time_info.numer / mach_time_info.denom;
uint64_t ms_per_tick = ns_per_tick * ONE_MILLION;
// requires that tor_log2(0) == 0.
monotime_shift = tor_log2(ms_per_tick);
}
{
// For converting ticks to milliseconds in a 32-bit-friendly way, we
// will first right-shift by 20, and then multiply by 20/19, since
// (1<<20) * 19/20 is about 1e6. We precompute a new numerate and
// denominator here to avoid multiple multiplies.
mach_time_info_msec_cvt.numer = mach_time_info.numer * 20;
mach_time_info_msec_cvt.denom = mach_time_info.denom * 19;
}
}
/**
* Set "out" to the most recent monotonic time value
*/
void
monotime_get(monotime_t *out)
{
#ifdef TOR_UNIT_TESTS
if (monotime_mocking_enabled) {
out->abstime_ = (mock_time_nsec * mach_time_info.denom)
/ mach_time_info.numer;
return;
}
#endif /* defined(TOR_UNIT_TESTS) */
out->abstime_ = mach_absolute_time();
}
#if defined(HAVE_MACH_APPROXIMATE_TIME)
void
monotime_coarse_get(monotime_coarse_t *out)
{
#ifdef TOR_UNIT_TESTS
if (monotime_mocking_enabled) {
out->abstime_ = (mock_time_nsec_coarse * mach_time_info.denom)
/ mach_time_info.numer;
return;
}
#endif /* defined(TOR_UNIT_TESTS) */
out->abstime_ = mach_approximate_time();
}
#endif
/**
* Return the number of nanoseconds between <b>start</b> and <b>end</b>.
*/
int64_t
monotime_diff_nsec(const monotime_t *start,
const monotime_t *end)
{
if (BUG(mach_time_info.denom == 0)) {
monotime_init();
}
const int64_t diff_ticks = end->abstime_ - start->abstime_;
const int64_t diff_nsec =
(diff_ticks * mach_time_info.numer) / mach_time_info.denom;
return diff_nsec;
}
int32_t
monotime_coarse_diff_msec32_(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
if (BUG(mach_time_info.denom == 0)) {
monotime_init();
}
const int64_t diff_ticks = end->abstime_ - start->abstime_;
/* We already require in di_ops.c that right-shift performs a sign-extend. */
const int32_t diff_microticks = (int32_t)(diff_ticks >> 20);
return (diff_microticks * mach_time_info_msec_cvt.numer) /
mach_time_info_msec_cvt.denom;
}
uint32_t
monotime_coarse_to_stamp(const monotime_coarse_t *t)
{
return (uint32_t)(t->abstime_ >> monotime_shift);
}
int
monotime_is_zero(const monotime_t *val)
{
return val->abstime_ == 0;
}
void
monotime_add_msec(monotime_t *out, const monotime_t *val, uint32_t msec)
{
const uint64_t nsec = msec * ONE_MILLION;
const uint64_t ticks = (nsec * mach_time_info.denom) / mach_time_info.numer;
out->abstime_ = val->abstime_ + ticks;
}
/* end of "__APPLE__" */
#elif defined(HAVE_CLOCK_GETTIME)
#ifdef CLOCK_MONOTONIC_COARSE
/**
* Which clock should we use for coarse-grained monotonic time? By default
* this is CLOCK_MONOTONIC_COARSE, but it might not work -- for example,
* if we're compiled with newer Linux headers and then we try to run on
* an old Linux kernel. In that case, we will fall back to CLOCK_MONOTONIC.
*/
static int clock_monotonic_coarse = CLOCK_MONOTONIC_COARSE;
#endif /* defined(CLOCK_MONOTONIC_COARSE) */
static void
monotime_init_internal(void)
{
#ifdef CLOCK_MONOTONIC_COARSE
struct timespec ts;
if (clock_gettime(CLOCK_MONOTONIC_COARSE, &ts) < 0) {
log_info(LD_GENERAL, "CLOCK_MONOTONIC_COARSE isn't working (%s); "
"falling back to CLOCK_MONOTONIC.", strerror(errno));
clock_monotonic_coarse = CLOCK_MONOTONIC;
}
#endif /* defined(CLOCK_MONOTONIC_COARSE) */
}
void
monotime_get(monotime_t *out)
{
#ifdef TOR_UNIT_TESTS
if (monotime_mocking_enabled) {
out->ts_.tv_sec = (time_t) (mock_time_nsec / ONE_BILLION);
out->ts_.tv_nsec = (int) (mock_time_nsec % ONE_BILLION);
return;
}
#endif /* defined(TOR_UNIT_TESTS) */
int r = clock_gettime(CLOCK_MONOTONIC, &out->ts_);
tor_assert(r == 0);
}
#ifdef CLOCK_MONOTONIC_COARSE
void
monotime_coarse_get(monotime_coarse_t *out)
{
#ifdef TOR_UNIT_TESTS
if (monotime_mocking_enabled) {
out->ts_.tv_sec = (time_t) (mock_time_nsec_coarse / ONE_BILLION);
out->ts_.tv_nsec = (int) (mock_time_nsec_coarse % ONE_BILLION);
return;
}
#endif /* defined(TOR_UNIT_TESTS) */
int r = clock_gettime(clock_monotonic_coarse, &out->ts_);
if (PREDICT_UNLIKELY(r < 0) &&
errno == EINVAL &&
clock_monotonic_coarse == CLOCK_MONOTONIC_COARSE) {
/* We should have caught this at startup in monotime_init_internal!
*/
log_warn(LD_BUG, "Falling back to non-coarse monotonic time %s initial "
"system start?", monotime_initialized?"after":"without");
clock_monotonic_coarse = CLOCK_MONOTONIC;
r = clock_gettime(clock_monotonic_coarse, &out->ts_);
}
tor_assert(r == 0);
}
#endif /* defined(CLOCK_MONOTONIC_COARSE) */
int64_t
monotime_diff_nsec(const monotime_t *start,
const monotime_t *end)
{
const int64_t diff_sec = end->ts_.tv_sec - start->ts_.tv_sec;
const int64_t diff_nsec = diff_sec * ONE_BILLION +
(end->ts_.tv_nsec - start->ts_.tv_nsec);
return diff_nsec;
}
int32_t
monotime_coarse_diff_msec32_(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
const int32_t diff_sec = (int32_t)(end->ts_.tv_sec - start->ts_.tv_sec);
const int32_t diff_nsec = (int32_t)(end->ts_.tv_nsec - start->ts_.tv_nsec);
return diff_sec * 1000 + diff_nsec / ONE_MILLION;
}
/* This value is ONE_BILLION >> 20. */
2017-12-06 21:46:54 +01:00
static const uint32_t STAMP_TICKS_PER_SECOND = 953;
uint32_t
monotime_coarse_to_stamp(const monotime_coarse_t *t)
{
uint32_t nsec = (uint32_t)t->ts_.tv_nsec;
uint32_t sec = (uint32_t)t->ts_.tv_sec;
return (sec * STAMP_TICKS_PER_SECOND) + (nsec >> 20);
}
int
monotime_is_zero(const monotime_t *val)
{
return val->ts_.tv_sec == 0 && val->ts_.tv_nsec == 0;
}
void
monotime_add_msec(monotime_t *out, const monotime_t *val, uint32_t msec)
{
const uint32_t sec = msec / 1000;
const uint32_t msec_remainder = msec % 1000;
out->ts_.tv_sec = val->ts_.tv_sec + sec;
out->ts_.tv_nsec = val->ts_.tv_nsec + (msec_remainder * ONE_MILLION);
if (out->ts_.tv_nsec > ONE_BILLION) {
out->ts_.tv_nsec -= ONE_BILLION;
out->ts_.tv_sec += 1;
}
}
/* end of "HAVE_CLOCK_GETTIME" */
#elif defined (_WIN32)
/** Result of QueryPerformanceFrequency, in terms needed to
* convert ticks to nanoseconds. */
static int64_t nsec_per_tick_numer = 1;
static int64_t nsec_per_tick_denom = 1;
/** Lock to protect last_pctr and pctr_offset */
static CRITICAL_SECTION monotime_lock;
/** Lock to protect rollover_count and last_tick_count */
static CRITICAL_SECTION monotime_coarse_lock;
typedef ULONGLONG (WINAPI *GetTickCount64_fn_t)(void);
static GetTickCount64_fn_t GetTickCount64_fn = NULL;
static void
monotime_init_internal(void)
{
tor_assert(!monotime_initialized);
BOOL ok = InitializeCriticalSectionAndSpinCount(&monotime_lock, 200);
tor_assert(ok);
ok = InitializeCriticalSectionAndSpinCount(&monotime_coarse_lock, 200);
tor_assert(ok);
LARGE_INTEGER li;
ok = QueryPerformanceFrequency(&li);
tor_assert(ok);
tor_assert(li.QuadPart);
uint64_t n = ONE_BILLION;
uint64_t d = li.QuadPart;
/* We need to simplify this or we'll probably overflow the int64. */
simplify_fraction64(&n, &d);
tor_assert(n <= INT64_MAX);
tor_assert(d <= INT64_MAX);
nsec_per_tick_numer = (int64_t) n;
nsec_per_tick_denom = (int64_t) d;
last_pctr = 0;
pctr_offset = 0;
HANDLE h = load_windows_system_library(TEXT("kernel32.dll"));
if (h) {
GetTickCount64_fn = (GetTickCount64_fn_t)
GetProcAddress(h, "GetTickCount64");
}
// FreeLibrary(h) ?
}
void
monotime_get(monotime_t *out)
{
if (BUG(monotime_initialized == 0)) {
monotime_init();
}
#ifdef TOR_UNIT_TESTS
if (monotime_mocking_enabled) {
out->pcount_ = (mock_time_nsec * nsec_per_tick_denom)
/ nsec_per_tick_numer;
return;
}
#endif /* defined(TOR_UNIT_TESTS) */
/* Alas, QueryPerformanceCounter is not always monotonic: see bug list at
https://www.python.org/dev/peps/pep-0418/#windows-queryperformancecounter
*/
EnterCriticalSection(&monotime_lock);
LARGE_INTEGER res;
BOOL ok = QueryPerformanceCounter(&res);
tor_assert(ok);
const int64_t count_raw = res.QuadPart;
out->pcount_ = ratchet_performance_counter(count_raw);
LeaveCriticalSection(&monotime_lock);
}
void
monotime_coarse_get(monotime_coarse_t *out)
{
#ifdef TOR_UNIT_TESTS
if (monotime_mocking_enabled) {
out->tick_count_ = mock_time_nsec_coarse / ONE_MILLION;
return;
}
#endif /* defined(TOR_UNIT_TESTS) */
if (GetTickCount64_fn) {
out->tick_count_ = (int64_t)GetTickCount64_fn();
} else {
EnterCriticalSection(&monotime_coarse_lock);
DWORD tick = GetTickCount();
out->tick_count_ = ratchet_coarse_performance_counter(tick);
LeaveCriticalSection(&monotime_coarse_lock);
}
}
int64_t
monotime_diff_nsec(const monotime_t *start,
const monotime_t *end)
{
if (BUG(monotime_initialized == 0)) {
monotime_init();
}
const int64_t diff_ticks = end->pcount_ - start->pcount_;
return (diff_ticks * nsec_per_tick_numer) / nsec_per_tick_denom;
}
int64_t
monotime_coarse_diff_msec(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
const int64_t diff_ticks = end->tick_count_ - start->tick_count_;
return diff_ticks;
}
int32_t
monotime_coarse_diff_msec32_(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
return (int32_t)monotime_coarse_diff_msec(start, end)
}
int64_t
monotime_coarse_diff_usec(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
return monotime_coarse_diff_msec(start, end) * 1000;
}
int64_t
monotime_coarse_diff_nsec(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
return monotime_coarse_diff_msec(start, end) * ONE_MILLION;
}
2017-12-06 21:46:54 +01:00
static const uint32_t STAMP_TICKS_PER_SECOND = 1000;
uint32_t
monotime_coarse_to_stamp(const monotime_coarse_t *t)
{
2017-12-07 21:14:49 +01:00
return (uint32_t) t->tick_count_;
}
int
monotime_is_zero(const monotime_t *val)
{
return val->pcount_ == 0;
}
int
monotime_coarse_is_zero(const monotime_coarse_t *val)
{
return val->tick_count_ == 0;
}
void
monotime_add_msec(monotime_t *out, const monotime_t *val, uint32_t msec)
{
const uint64_t nsec = msec * ONE_MILLION;
const uint64_t ticks = (nsec * nsec_per_tick_denom) / nsec_per_tick_numer;
out->pcount_ = val->pcount_ + ticks;
}
void
monotime_coarse_add_msec(monotime_coarse_t *out, const monotime_coarse_t *val,
uint32_t msec)
{
out->tick_count_ = val->tick_count_ + msec;
}
/* end of "_WIN32" */
#elif defined(MONOTIME_USING_GETTIMEOFDAY)
static tor_mutex_t monotime_lock;
/** Initialize the monotonic timer subsystem. */
static void
monotime_init_internal(void)
{
tor_assert(!monotime_initialized);
tor_mutex_init(&monotime_lock);
}
void
monotime_get(monotime_t *out)
{
if (BUG(monotime_initialized == 0)) {
monotime_init();
}
tor_mutex_acquire(&monotime_lock);
struct timeval timeval_raw;
tor_gettimeofday(&timeval_raw);
ratchet_timeval(&timeval_raw, &out->tv_);
tor_mutex_release(&monotime_lock);
}
int64_t
monotime_diff_nsec(const monotime_t *start,
const monotime_t *end)
{
struct timeval diff;
timersub(&end->tv_, &start->tv_, &diff);
return (diff.tv_sec * ONE_BILLION + diff.tv_usec * 1000);
}
int32_t
monotime_coarse_diff_msec32_(const monotime_coarse_t *start,
const monotime_coarse_t *end)
{
struct timeval diff;
timersub(&end->tv_, &start->tv_, &diff);
return diff.tv_sec * 1000 + diff.tv_usec / 1000;
}
/* This value is ONE_MILLION >> 10. */
2017-12-06 21:46:54 +01:00
static const uint32_t STAMP_TICKS_PER_SECOND = 976;
uint32_t
monotime_coarse_to_stamp(const monotime_coarse_t *t)
{
const uint32_t usec = (uint32_t)t->tv_.tv_usec;
const uint32_t sec = (uint32_t)t->tv_.tv_sec;
return (sec * STAMP_TICKS_PER_SECOND) | (nsec >> 10);
}
int
monotime_is_zero(const monotime_t *val)
{
return val->tv_.tv_sec == 0 && val->tv_.tv_usec == 0;
}
void
monotime_add_msec(monotime_t *out, const monotime_t *val, uint32_t msec)
{
const uint32_t sec = msec / 1000;
const uint32_t msec_remainder = msec % 1000;
out->tv_.tv_sec = val->tv_.tv_sec + sec;
out->tv_.tv_usec = val->tv_.tv_nsec + (msec_remainder * 1000);
if (out->tv_.tv_usec > ONE_MILLION) {
out->tv_.tv_usec -= ONE_MILLION;
out->tv_.tv_sec += 1;
}
}
/* end of "MONOTIME_USING_GETTIMEOFDAY" */
#else
#error "No way to implement monotonic timers."
#endif /* defined(__APPLE__) || ... */
/**
* Initialize the monotonic timer subsystem. Must be called before any
* monotonic timer functions. This function is idempotent.
*/
void
monotime_init(void)
{
if (!monotime_initialized) {
monotime_init_internal();
2016-07-21 15:29:56 +02:00
monotime_initialized = 1;
monotime_get(&initialized_at);
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
monotime_coarse_get(&initialized_at_coarse);
#endif
}
}
void
monotime_zero(monotime_t *out)
{
memset(out, 0, sizeof(*out));
}
#ifdef MONOTIME_COARSE_TYPE_IS_DIFFERENT
void
monotime_coarse_zero(monotime_coarse_t *out)
{
memset(out, 0, sizeof(*out));
}
#endif
int64_t
monotime_diff_usec(const monotime_t *start,
const monotime_t *end)
{
const int64_t nsec = monotime_diff_nsec(start, end);
return CEIL_DIV(nsec, 1000);
}
int64_t
monotime_diff_msec(const monotime_t *start,
const monotime_t *end)
{
const int64_t nsec = monotime_diff_nsec(start, end);
return CEIL_DIV(nsec, ONE_MILLION);
}
uint64_t
monotime_absolute_nsec(void)
{
monotime_t now;
if (BUG(monotime_initialized == 0)) {
monotime_init();
}
monotime_get(&now);
return monotime_diff_nsec(&initialized_at, &now);
}
uint64_t
monotime_absolute_usec(void)
{
return monotime_absolute_nsec() / 1000;
}
uint64_t
monotime_absolute_msec(void)
{
return monotime_absolute_nsec() / ONE_MILLION;
}
#ifdef MONOTIME_COARSE_FN_IS_DIFFERENT
uint64_t
monotime_coarse_absolute_nsec(void)
{
if (BUG(monotime_initialized == 0)) {
monotime_init();
}
monotime_coarse_t now;
monotime_coarse_get(&now);
return monotime_coarse_diff_nsec(&initialized_at_coarse, &now);
}
uint64_t
monotime_coarse_absolute_usec(void)
{
return monotime_coarse_absolute_nsec() / 1000;
}
uint64_t
monotime_coarse_absolute_msec(void)
{
return monotime_coarse_absolute_nsec() / ONE_MILLION;
}
#else
#define initialized_at_coarse initialized_at
#endif /* defined(MONOTIME_COARSE_FN_IS_DIFFERENT) */
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/**
* Return the current time "stamp" as described by monotime_coarse_to_stamp.
*/
uint32_t
monotime_coarse_get_stamp(void)
{
monotime_coarse_t now;
monotime_coarse_get(&now);
return monotime_coarse_to_stamp(&now);
}
#ifdef __APPLE__
uint64_t
monotime_coarse_stamp_units_to_approx_msec(uint64_t units)
{
/* Recover as much precision as we can. */
uint64_t abstime_diff = (units << monotime_shift);
return (abstime_diff * mach_time_info.numer) /
(mach_time_info.denom * ONE_MILLION);
}
uint64_t
monotime_msec_to_approx_coarse_stamp_units(uint64_t msec)
{
uint64_t abstime_val =
(((uint64_t)msec) * ONE_MILLION * mach_time_info.denom) /
mach_time_info.numer;
return abstime_val >> monotime_shift;
}
#else
uint64_t
monotime_coarse_stamp_units_to_approx_msec(uint64_t units)
{
return (units * 1000) / STAMP_TICKS_PER_SECOND;
}
uint64_t
monotime_msec_to_approx_coarse_stamp_units(uint64_t msec)
{
return (msec * STAMP_TICKS_PER_SECOND) / 1000;
}
#endif