2010-01-07 09:21:28 -08:00
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/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim:set ts=2 sw=2 sts=2 et cindent: */
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2012-05-21 04:12:37 -07:00
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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2010-01-07 09:21:28 -08:00
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//
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// Implement TimeStamp::Now() with POSIX clocks.
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//
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// The "tick" unit for POSIX clocks is simply a nanosecond, as this is
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// the smallest unit of time representable by struct timespec. That
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// doesn't mean that a nanosecond is the resolution of TimeDurations
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// obtained with this API; see TimeDuration::Resolution;
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//
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#include <time.h>
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#include "mozilla/TimeStamp.h"
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// Estimate of the smallest duration of time we can measure.
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2012-08-22 08:56:38 -07:00
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static uint64_t sResolution;
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static uint64_t sResolutionSigDigs;
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2010-01-07 09:21:28 -08:00
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2012-08-22 08:56:38 -07:00
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static const uint16_t kNsPerUs = 1000;
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static const uint64_t kNsPerMs = 1000000;
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static const uint64_t kNsPerSec = 1000000000;
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2010-07-21 12:57:33 -07:00
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static const double kNsPerMsd = 1000000.0;
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2010-01-07 09:21:28 -08:00
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static const double kNsPerSecd = 1000000000.0;
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2012-08-22 08:56:38 -07:00
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static uint64_t
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2010-03-01 13:44:05 -08:00
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TimespecToNs(const struct timespec& ts)
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{
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2012-08-22 08:56:38 -07:00
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uint64_t baseNs = uint64_t(ts.tv_sec) * kNsPerSec;
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return baseNs + uint64_t(ts.tv_nsec);
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2010-03-01 13:44:05 -08:00
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}
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2010-01-07 09:21:28 -08:00
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2012-08-22 08:56:38 -07:00
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static uint64_t
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2010-01-07 09:21:28 -08:00
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ClockTimeNs()
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{
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struct timespec ts;
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2012-10-20 08:12:20 -07:00
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// this can't fail: we know &ts is valid, and TimeStamp::Startup()
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2010-01-07 09:21:28 -08:00
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// checks that CLOCK_MONOTONIC is supported (and aborts if not)
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clock_gettime(CLOCK_MONOTONIC, &ts);
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// tv_sec is defined to be relative to an arbitrary point in time,
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// but it would be madness for that point in time to be earlier than
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// the Epoch. So we can safely assume that even if time_t is 32
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// bits, tv_sec won't overflow while the browser is open. Revisit
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// this argument if we're still building with 32-bit time_t around
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// the year 2037.
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2010-03-01 13:44:05 -08:00
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return TimespecToNs(ts);
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2010-01-07 09:21:28 -08:00
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}
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2012-08-22 08:56:38 -07:00
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static uint64_t
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2010-01-07 09:21:28 -08:00
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ClockResolutionNs()
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{
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2010-03-01 13:44:05 -08:00
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// NB: why not rely on clock_getres()? Two reasons: (i) it might
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// lie, and (ii) it might return an "ideal" resolution that while
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2010-01-07 09:21:28 -08:00
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// theoretically true, could never be measured in practice. Since
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// clock_gettime() likely involves a system call on your platform,
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// the "actual" timing resolution shouldn't be lower than syscall
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// overhead.
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2012-08-22 08:56:38 -07:00
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uint64_t start = ClockTimeNs();
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uint64_t end = ClockTimeNs();
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uint64_t minres = (end - start);
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2010-01-07 09:21:28 -08:00
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// 10 total trials is arbitrary: what we're trying to avoid by
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// looping is getting unlucky and being interrupted by a context
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// switch or signal, or being bitten by paging/cache effects
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for (int i = 0; i < 9; ++i) {
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start = ClockTimeNs();
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end = ClockTimeNs();
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2012-08-22 08:56:38 -07:00
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uint64_t candidate = (start - end);
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2010-01-07 09:21:28 -08:00
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if (candidate < minres)
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minres = candidate;
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}
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if (0 == minres) {
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2010-03-01 13:44:05 -08:00
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// measurable resolution is either incredibly low, ~1ns, or very
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// high. fall back on clock_getres()
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struct timespec ts;
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2010-07-15 12:27:43 -07:00
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if (0 == clock_getres(CLOCK_MONOTONIC, &ts)) {
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minres = TimespecToNs(ts);
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}
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2010-03-01 13:44:05 -08:00
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}
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if (0 == minres) {
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// clock_getres probably failed. fall back on NSPR's resolution
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// assumption
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minres = 1 * kNsPerMs;
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2010-01-07 09:21:28 -08:00
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}
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return minres;
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}
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2013-04-09 13:25:42 -07:00
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namespace mozilla {
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2013-03-28 03:28:09 -07:00
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2010-01-07 09:21:28 -08:00
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double
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TimeDuration::ToSeconds() const
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{
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return double(mValue) / kNsPerSecd;
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}
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double
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TimeDuration::ToSecondsSigDigits() const
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{
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// don't report a value < mResolution ...
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2012-08-22 08:56:38 -07:00
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int64_t valueSigDigs = sResolution * (mValue / sResolution);
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2010-01-07 09:21:28 -08:00
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// and chop off insignificant digits
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valueSigDigs = sResolutionSigDigs * (valueSigDigs / sResolutionSigDigs);
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return double(valueSigDigs) / kNsPerSecd;
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}
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TimeDuration
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2010-07-21 12:57:33 -07:00
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TimeDuration::FromMilliseconds(double aMilliseconds)
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2010-01-07 09:21:28 -08:00
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{
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2010-07-21 12:57:33 -07:00
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return TimeDuration::FromTicks(aMilliseconds * kNsPerMsd);
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2010-01-07 09:21:28 -08:00
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}
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TimeDuration
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TimeDuration::Resolution()
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{
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2012-08-22 08:56:38 -07:00
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return TimeDuration::FromTicks(int64_t(sResolution));
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2010-01-07 09:21:28 -08:00
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}
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2010-04-26 14:26:40 -07:00
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struct TimeStampInitialization
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{
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TimeStampInitialization() {
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TimeStamp::Startup();
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}
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~TimeStampInitialization() {
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TimeStamp::Shutdown();
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}
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};
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static TimeStampInitialization initOnce;
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2011-09-28 23:19:26 -07:00
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static bool gInitialized = false;
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2010-01-07 09:21:28 -08:00
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nsresult
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TimeStamp::Startup()
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{
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2010-04-26 14:26:40 -07:00
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if (gInitialized)
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return NS_OK;
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2010-01-07 09:21:28 -08:00
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struct timespec dummy;
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if (0 != clock_gettime(CLOCK_MONOTONIC, &dummy))
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NS_RUNTIMEABORT("CLOCK_MONOTONIC is absent!");
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sResolution = ClockResolutionNs();
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// find the number of significant digits in sResolution, for the
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// sake of ToSecondsSigDigits()
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for (sResolutionSigDigs = 1;
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!(sResolutionSigDigs == sResolution
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|| 10*sResolutionSigDigs > sResolution);
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sResolutionSigDigs *= 10);
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2011-10-17 07:59:28 -07:00
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gInitialized = true;
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2010-01-07 09:21:28 -08:00
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return NS_OK;
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}
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void
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TimeStamp::Shutdown()
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{
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}
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TimeStamp
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2013-02-11 13:56:59 -08:00
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TimeStamp::Now(bool aHighResolution)
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2010-01-07 09:21:28 -08:00
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{
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return TimeStamp(ClockTimeNs());
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}
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}
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