src/base/platform/time.cc - platform/external/v8 - Git at Google

 // Copyright 2013 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/base/platform/time.h"

 #if V8_OS_POSIX
 #include <fcntl.h>  // for O_RDONLY
 #include <sys/time.h>
 #include <unistd.h>
 #endif
 #if V8_OS_MACOSX
 #include <mach/mach_time.h>
 #endif

 #include <cstring>
 #include <ostream>

 #if V8_OS_WIN
 #include "src/base/atomicops.h"
 #include "src/base/lazy-instance.h"
 #include "src/base/win32-headers.h"
 #endif
 #include "src/base/cpu.h"
 #include "src/base/logging.h"
 #include "src/base/platform/platform.h"

 namespace v8 {
 namespace base {

 TimeDelta TimeDelta::FromDays(int days) {
   return TimeDelta(days * Time::kMicrosecondsPerDay);
 }


 TimeDelta TimeDelta::FromHours(int hours) {
   return TimeDelta(hours * Time::kMicrosecondsPerHour);
 }


 TimeDelta TimeDelta::FromMinutes(int minutes) {
   return TimeDelta(minutes * Time::kMicrosecondsPerMinute);
 }


 TimeDelta TimeDelta::FromSeconds(int64_t seconds) {
   return TimeDelta(seconds * Time::kMicrosecondsPerSecond);
 }


 TimeDelta TimeDelta::FromMilliseconds(int64_t milliseconds) {
   return TimeDelta(milliseconds * Time::kMicrosecondsPerMillisecond);
 }


 TimeDelta TimeDelta::FromNanoseconds(int64_t nanoseconds) {
   return TimeDelta(nanoseconds / Time::kNanosecondsPerMicrosecond);
 }


 int TimeDelta::InDays() const {
   return static_cast<int>(delta_ / Time::kMicrosecondsPerDay);
 }


 int TimeDelta::InHours() const {
   return static_cast<int>(delta_ / Time::kMicrosecondsPerHour);
 }


 int TimeDelta::InMinutes() const {
   return static_cast<int>(delta_ / Time::kMicrosecondsPerMinute);
 }


 double TimeDelta::InSecondsF() const {
   return static_cast<double>(delta_) / Time::kMicrosecondsPerSecond;
 }


 int64_t TimeDelta::InSeconds() const {
   return delta_ / Time::kMicrosecondsPerSecond;
 }


 double TimeDelta::InMillisecondsF() const {
   return static_cast<double>(delta_) / Time::kMicrosecondsPerMillisecond;
 }


 int64_t TimeDelta::InMilliseconds() const {
   return delta_ / Time::kMicrosecondsPerMillisecond;
 }


 int64_t TimeDelta::InNanoseconds() const {
   return delta_ * Time::kNanosecondsPerMicrosecond;
 }


 #if V8_OS_MACOSX

 TimeDelta TimeDelta::FromMachTimespec(struct mach_timespec ts) {
   DCHECK_GE(ts.tv_nsec, 0);
   DCHECK_LT(ts.tv_nsec,
             static_cast<long>(Time::kNanosecondsPerSecond));  // NOLINT
   return TimeDelta(ts.tv_sec * Time::kMicrosecondsPerSecond +
                    ts.tv_nsec / Time::kNanosecondsPerMicrosecond);
 }


 struct mach_timespec TimeDelta::ToMachTimespec() const {
   struct mach_timespec ts;
   DCHECK(delta_ >= 0);
   ts.tv_sec = static_cast<unsigned>(delta_ / Time::kMicrosecondsPerSecond);
   ts.tv_nsec = (delta_ % Time::kMicrosecondsPerSecond) *
       Time::kNanosecondsPerMicrosecond;
   return ts;
 }

 #endif  // V8_OS_MACOSX


 #if V8_OS_POSIX

 TimeDelta TimeDelta::FromTimespec(struct timespec ts) {
   DCHECK_GE(ts.tv_nsec, 0);
   DCHECK_LT(ts.tv_nsec,
             static_cast<long>(Time::kNanosecondsPerSecond));  // NOLINT
   return TimeDelta(ts.tv_sec * Time::kMicrosecondsPerSecond +
                    ts.tv_nsec / Time::kNanosecondsPerMicrosecond);
 }


 struct timespec TimeDelta::ToTimespec() const {
   struct timespec ts;
   ts.tv_sec = static_cast<time_t>(delta_ / Time::kMicrosecondsPerSecond);
   ts.tv_nsec = (delta_ % Time::kMicrosecondsPerSecond) *
       Time::kNanosecondsPerMicrosecond;
   return ts;
 }

 #endif  // V8_OS_POSIX


 #if V8_OS_WIN

 // We implement time using the high-resolution timers so that we can get
 // timeouts which are smaller than 10-15ms. To avoid any drift, we
 // periodically resync the internal clock to the system clock.
 class Clock final {
  public:
   Clock() : initial_ticks_(GetSystemTicks()), initial_time_(GetSystemTime()) {}

   Time Now() {
     // Time between resampling the un-granular clock for this API (1 minute).
     const TimeDelta kMaxElapsedTime = TimeDelta::FromMinutes(1);

     LockGuard<Mutex> lock_guard(&mutex_);

     // Determine current time and ticks.
     TimeTicks ticks = GetSystemTicks();
     Time time = GetSystemTime();

     // Check if we need to synchronize with the system clock due to a backwards
     // time change or the amount of time elapsed.
     TimeDelta elapsed = ticks - initial_ticks_;
     if (time < initial_time_ || elapsed > kMaxElapsedTime) {
       initial_ticks_ = ticks;
       initial_time_ = time;
       return time;
     }

     return initial_time_ + elapsed;
   }

   Time NowFromSystemTime() {
     LockGuard<Mutex> lock_guard(&mutex_);
     initial_ticks_ = GetSystemTicks();
     initial_time_ = GetSystemTime();
     return initial_time_;
   }

  private:
   static TimeTicks GetSystemTicks() {
     return TimeTicks::Now();
   }

   static Time GetSystemTime() {
     FILETIME ft;
     ::GetSystemTimeAsFileTime(&ft);
     return Time::FromFiletime(ft);
   }

   TimeTicks initial_ticks_;
   Time initial_time_;
   Mutex mutex_;
 };


 static LazyStaticInstance<Clock, DefaultConstructTrait<Clock>,
                           ThreadSafeInitOnceTrait>::type clock =
     LAZY_STATIC_INSTANCE_INITIALIZER;


 Time Time::Now() {
   return clock.Pointer()->Now();
 }


 Time Time::NowFromSystemTime() {
   return clock.Pointer()->NowFromSystemTime();
 }


 // Time between windows epoch and standard epoch.
 static const int64_t kTimeToEpochInMicroseconds = V8_INT64_C(11644473600000000);


 Time Time::FromFiletime(FILETIME ft) {
   if (ft.dwLowDateTime == 0 && ft.dwHighDateTime == 0) {
     return Time();
   }
   if (ft.dwLowDateTime == std::numeric_limits<DWORD>::max() &&
       ft.dwHighDateTime == std::numeric_limits<DWORD>::max()) {
     return Max();
   }
   int64_t us = (static_cast<uint64_t>(ft.dwLowDateTime) +
                 (static_cast<uint64_t>(ft.dwHighDateTime) << 32)) / 10;
   return Time(us - kTimeToEpochInMicroseconds);
 }


 FILETIME Time::ToFiletime() const {
   DCHECK(us_ >= 0);
   FILETIME ft;
   if (IsNull()) {
     ft.dwLowDateTime = 0;
     ft.dwHighDateTime = 0;
     return ft;
   }
   if (IsMax()) {
     ft.dwLowDateTime = std::numeric_limits<DWORD>::max();
     ft.dwHighDateTime = std::numeric_limits<DWORD>::max();
     return ft;
   }
   uint64_t us = static_cast<uint64_t>(us_ + kTimeToEpochInMicroseconds) * 10;
   ft.dwLowDateTime = static_cast<DWORD>(us);
   ft.dwHighDateTime = static_cast<DWORD>(us >> 32);
   return ft;
 }

 #elif V8_OS_POSIX

 Time Time::Now() {
   struct timeval tv;
   int result = gettimeofday(&tv, NULL);
   DCHECK_EQ(0, result);
   USE(result);
   return FromTimeval(tv);
 }


 Time Time::NowFromSystemTime() {
   return Now();
 }


 Time Time::FromTimespec(struct timespec ts) {
   DCHECK(ts.tv_nsec >= 0);
   DCHECK(ts.tv_nsec < static_cast<long>(kNanosecondsPerSecond));  // NOLINT
   if (ts.tv_nsec == 0 && ts.tv_sec == 0) {
     return Time();
   }
   if (ts.tv_nsec == static_cast<long>(kNanosecondsPerSecond - 1) &&  // NOLINT
       ts.tv_sec == std::numeric_limits<time_t>::max()) {
     return Max();
   }
   return Time(ts.tv_sec * kMicrosecondsPerSecond +
               ts.tv_nsec / kNanosecondsPerMicrosecond);
 }


 struct timespec Time::ToTimespec() const {
   struct timespec ts;
   if (IsNull()) {
     ts.tv_sec = 0;
     ts.tv_nsec = 0;
     return ts;
   }
   if (IsMax()) {
     ts.tv_sec = std::numeric_limits<time_t>::max();
     ts.tv_nsec = static_cast<long>(kNanosecondsPerSecond - 1);  // NOLINT
     return ts;
   }
   ts.tv_sec = static_cast<time_t>(us_ / kMicrosecondsPerSecond);
   ts.tv_nsec = (us_ % kMicrosecondsPerSecond) * kNanosecondsPerMicrosecond;
   return ts;
 }


 Time Time::FromTimeval(struct timeval tv) {
   DCHECK(tv.tv_usec >= 0);
   DCHECK(tv.tv_usec < static_cast<suseconds_t>(kMicrosecondsPerSecond));
   if (tv.tv_usec == 0 && tv.tv_sec == 0) {
     return Time();
   }
   if (tv.tv_usec == static_cast<suseconds_t>(kMicrosecondsPerSecond - 1) &&
       tv.tv_sec == std::numeric_limits<time_t>::max()) {
     return Max();
   }
   return Time(tv.tv_sec * kMicrosecondsPerSecond + tv.tv_usec);
 }


 struct timeval Time::ToTimeval() const {
   struct timeval tv;
   if (IsNull()) {
     tv.tv_sec = 0;
     tv.tv_usec = 0;
     return tv;
   }
   if (IsMax()) {
     tv.tv_sec = std::numeric_limits<time_t>::max();
     tv.tv_usec = static_cast<suseconds_t>(kMicrosecondsPerSecond - 1);
     return tv;
   }
   tv.tv_sec = static_cast<time_t>(us_ / kMicrosecondsPerSecond);
   tv.tv_usec = us_ % kMicrosecondsPerSecond;
   return tv;
 }

 #endif  // V8_OS_WIN


 Time Time::FromJsTime(double ms_since_epoch) {
   // The epoch is a valid time, so this constructor doesn't interpret
   // 0 as the null time.
   if (ms_since_epoch == std::numeric_limits<double>::max()) {
     return Max();
   }
   return Time(
       static_cast<int64_t>(ms_since_epoch * kMicrosecondsPerMillisecond));
 }


 double Time::ToJsTime() const {
   if (IsNull()) {
     // Preserve 0 so the invalid result doesn't depend on the platform.
     return 0;
   }
   if (IsMax()) {
     // Preserve max without offset to prevent overflow.
     return std::numeric_limits<double>::max();
   }
   return static_cast<double>(us_) / kMicrosecondsPerMillisecond;
 }


 std::ostream& operator<<(std::ostream& os, const Time& time) {
   return os << time.ToJsTime();
 }


 #if V8_OS_WIN

 class TickClock {
  public:
   virtual ~TickClock() {}
   virtual int64_t Now() = 0;
   virtual bool IsHighResolution() = 0;
 };


 // Overview of time counters:
 // (1) CPU cycle counter. (Retrieved via RDTSC)
 // The CPU counter provides the highest resolution time stamp and is the least
 // expensive to retrieve. However, the CPU counter is unreliable and should not
 // be used in production. Its biggest issue is that it is per processor and it
 // is not synchronized between processors. Also, on some computers, the counters
 // will change frequency due to thermal and power changes, and stop in some
 // states.
 //
 // (2) QueryPerformanceCounter (QPC). The QPC counter provides a high-
 // resolution (100 nanoseconds) time stamp but is comparatively more expensive
 // to retrieve. What QueryPerformanceCounter actually does is up to the HAL.
 // (with some help from ACPI).
 // According to http://blogs.msdn.com/oldnewthing/archive/2005/09/02/459952.aspx
 // in the worst case, it gets the counter from the rollover interrupt on the
 // programmable interrupt timer. In best cases, the HAL may conclude that the
 // RDTSC counter runs at a constant frequency, then it uses that instead. On
 // multiprocessor machines, it will try to verify the values returned from
 // RDTSC on each processor are consistent with each other, and apply a handful
 // of workarounds for known buggy hardware. In other words, QPC is supposed to
 // give consistent result on a multiprocessor computer, but it is unreliable in
 // reality due to bugs in BIOS or HAL on some, especially old computers.
 // With recent updates on HAL and newer BIOS, QPC is getting more reliable but
 // it should be used with caution.
 //
 // (3) System time. The system time provides a low-resolution (typically 10ms
 // to 55 milliseconds) time stamp but is comparatively less expensive to
 // retrieve and more reliable.
 class HighResolutionTickClock final : public TickClock {
  public:
   explicit HighResolutionTickClock(int64_t ticks_per_second)
       : ticks_per_second_(ticks_per_second) {
     DCHECK_LT(0, ticks_per_second);
   }
   virtual ~HighResolutionTickClock() {}

   int64_t Now() override {
     LARGE_INTEGER now;
     BOOL result = QueryPerformanceCounter(&now);
     DCHECK(result);
     USE(result);

     // Intentionally calculate microseconds in a round about manner to avoid
     // overflow and precision issues. Think twice before simplifying!
     int64_t whole_seconds = now.QuadPart / ticks_per_second_;
     int64_t leftover_ticks = now.QuadPart % ticks_per_second_;
     int64_t ticks = (whole_seconds * Time::kMicrosecondsPerSecond) +
         ((leftover_ticks * Time::kMicrosecondsPerSecond) / ticks_per_second_);

     // Make sure we never return 0 here, so that TimeTicks::HighResolutionNow()
     // will never return 0.
     return ticks + 1;
   }

   bool IsHighResolution() override { return true; }

  private:
   int64_t ticks_per_second_;
 };


 class RolloverProtectedTickClock final : public TickClock {
  public:
   RolloverProtectedTickClock() : rollover_(0) {}
   virtual ~RolloverProtectedTickClock() {}

   int64_t Now() override {
     // We use timeGetTime() to implement TimeTicks::Now(), which rolls over
     // every ~49.7 days. We try to track rollover ourselves, which works if
     // TimeTicks::Now() is called at least every 24 days.
     // Note that we do not use GetTickCount() here, since timeGetTime() gives
     // more predictable delta values, as described here:
     // http://blogs.msdn.com/b/larryosterman/archive/2009/09/02/what-s-the-difference-between-gettickcount-and-timegettime.aspx
     // timeGetTime() provides 1ms granularity when combined with
     // timeBeginPeriod(). If the host application for V8 wants fast timers, it
     // can use timeBeginPeriod() to increase the resolution.
     // We use a lock-free version because the sampler thread calls it
     // while having the rest of the world stopped, that could cause a deadlock.
     base::Atomic32 rollover = base::Acquire_Load(&rollover_);
     uint32_t now = static_cast<uint32_t>(timeGetTime());
     if ((now >> 31) != static_cast<uint32_t>(rollover & 1)) {
       base::Release_CompareAndSwap(&rollover_, rollover, rollover + 1);
       ++rollover;
     }
     uint64_t ms = (static_cast<uint64_t>(rollover) << 31) | now;
     return static_cast<int64_t>(ms * Time::kMicrosecondsPerMillisecond);
   }

   bool IsHighResolution() override { return false; }

  private:
   base::Atomic32 rollover_;
 };


 static LazyStaticInstance<RolloverProtectedTickClock,
                           DefaultConstructTrait<RolloverProtectedTickClock>,
                           ThreadSafeInitOnceTrait>::type tick_clock =
     LAZY_STATIC_INSTANCE_INITIALIZER;


 struct CreateHighResTickClockTrait {
   static TickClock* Create() {
     // Check if the installed hardware supports a high-resolution performance
     // counter, and if not fallback to the low-resolution tick clock.
     LARGE_INTEGER ticks_per_second;
     if (!QueryPerformanceFrequency(&ticks_per_second)) {
       return tick_clock.Pointer();
     }

     // On Athlon X2 CPUs (e.g. model 15) the QueryPerformanceCounter
     // is unreliable, fallback to the low-resolution tick clock.
     CPU cpu;
     if (strcmp(cpu.vendor(), "AuthenticAMD") == 0 && cpu.family() == 15) {
       return tick_clock.Pointer();
     }

     return new HighResolutionTickClock(ticks_per_second.QuadPart);
   }
 };


 static LazyDynamicInstance<TickClock, CreateHighResTickClockTrait,
                            ThreadSafeInitOnceTrait>::type high_res_tick_clock =
     LAZY_DYNAMIC_INSTANCE_INITIALIZER;


 TimeTicks TimeTicks::Now() {
   // Make sure we never return 0 here.
   TimeTicks ticks(tick_clock.Pointer()->Now());
   DCHECK(!ticks.IsNull());
   return ticks;
 }


 TimeTicks TimeTicks::HighResolutionNow() {
   // Make sure we never return 0 here.
   TimeTicks ticks(high_res_tick_clock.Pointer()->Now());
   DCHECK(!ticks.IsNull());
   return ticks;
 }


 // static
 bool TimeTicks::IsHighResolutionClockWorking() {
   return high_res_tick_clock.Pointer()->IsHighResolution();
 }

 #else  // V8_OS_WIN

 TimeTicks TimeTicks::Now() {
   return HighResolutionNow();
 }


 TimeTicks TimeTicks::HighResolutionNow() {
   int64_t ticks;
 #if V8_OS_MACOSX
   static struct mach_timebase_info info;
   if (info.denom == 0) {
     kern_return_t result = mach_timebase_info(&info);
     DCHECK_EQ(KERN_SUCCESS, result);
     USE(result);
   }
   ticks = (mach_absolute_time() / Time::kNanosecondsPerMicrosecond *
            info.numer / info.denom);
 #elif V8_OS_SOLARIS
   ticks = (gethrtime() / Time::kNanosecondsPerMicrosecond);
 #elif V8_OS_POSIX
   struct timespec ts;
   int result = clock_gettime(CLOCK_MONOTONIC, &ts);
   DCHECK_EQ(0, result);
   USE(result);
   ticks = (ts.tv_sec * Time::kMicrosecondsPerSecond +
            ts.tv_nsec / Time::kNanosecondsPerMicrosecond);
 #endif  // V8_OS_MACOSX
   // Make sure we never return 0 here.
   return TimeTicks(ticks + 1);
 }


 // static
 bool TimeTicks::IsHighResolutionClockWorking() {
   return true;
 }

 #endif  // V8_OS_WIN

 }  // namespace base
 }  // namespace v8
	// Copyright 2013 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/base/platform/time.h"

	#if V8_OS_POSIX
	#include <fcntl.h> // for O_RDONLY
	#include <sys/time.h>
	#include <unistd.h>
	#endif
	#if V8_OS_MACOSX
	#include <mach/mach_time.h>
	#endif

	#include <cstring>
	#include <ostream>

	#if V8_OS_WIN
	#include "src/base/atomicops.h"
	#include "src/base/lazy-instance.h"
	#include "src/base/win32-headers.h"
	#endif
	#include "src/base/cpu.h"
	#include "src/base/logging.h"
	#include "src/base/platform/platform.h"

	namespace v8 {
	namespace base {

	TimeDelta TimeDelta::FromDays(int days) {
	return TimeDelta(days * Time::kMicrosecondsPerDay);
	}


	TimeDelta TimeDelta::FromHours(int hours) {
	return TimeDelta(hours * Time::kMicrosecondsPerHour);
	}


	TimeDelta TimeDelta::FromMinutes(int minutes) {
	return TimeDelta(minutes * Time::kMicrosecondsPerMinute);
	}


	TimeDelta TimeDelta::FromSeconds(int64_t seconds) {
	return TimeDelta(seconds * Time::kMicrosecondsPerSecond);
	}


	TimeDelta TimeDelta::FromMilliseconds(int64_t milliseconds) {
	return TimeDelta(milliseconds * Time::kMicrosecondsPerMillisecond);
	}


	TimeDelta TimeDelta::FromNanoseconds(int64_t nanoseconds) {
	return TimeDelta(nanoseconds / Time::kNanosecondsPerMicrosecond);
	}


	int TimeDelta::InDays() const {
	return static_cast<int>(delta_ / Time::kMicrosecondsPerDay);
	}


	int TimeDelta::InHours() const {
	return static_cast<int>(delta_ / Time::kMicrosecondsPerHour);
	}


	int TimeDelta::InMinutes() const {
	return static_cast<int>(delta_ / Time::kMicrosecondsPerMinute);
	}


	double TimeDelta::InSecondsF() const {
	return static_cast<double>(delta_) / Time::kMicrosecondsPerSecond;
	}


	int64_t TimeDelta::InSeconds() const {
	return delta_ / Time::kMicrosecondsPerSecond;
	}


	double TimeDelta::InMillisecondsF() const {
	return static_cast<double>(delta_) / Time::kMicrosecondsPerMillisecond;
	}


	int64_t TimeDelta::InMilliseconds() const {
	return delta_ / Time::kMicrosecondsPerMillisecond;
	}


	int64_t TimeDelta::InNanoseconds() const {
	return delta_ * Time::kNanosecondsPerMicrosecond;
	}


	#if V8_OS_MACOSX

	TimeDelta TimeDelta::FromMachTimespec(struct mach_timespec ts) {
	DCHECK_GE(ts.tv_nsec, 0);
	DCHECK_LT(ts.tv_nsec,
	static_cast<long>(Time::kNanosecondsPerSecond)); // NOLINT
	return TimeDelta(ts.tv_sec * Time::kMicrosecondsPerSecond +
	ts.tv_nsec / Time::kNanosecondsPerMicrosecond);
	}


	struct mach_timespec TimeDelta::ToMachTimespec() const {
	struct mach_timespec ts;
	DCHECK(delta_ >= 0);
	ts.tv_sec = static_cast<unsigned>(delta_ / Time::kMicrosecondsPerSecond);
	ts.tv_nsec = (delta_ % Time::kMicrosecondsPerSecond) *
	Time::kNanosecondsPerMicrosecond;
	return ts;
	}

	#endif // V8_OS_MACOSX


	#if V8_OS_POSIX

	TimeDelta TimeDelta::FromTimespec(struct timespec ts) {
	DCHECK_GE(ts.tv_nsec, 0);
	DCHECK_LT(ts.tv_nsec,
	static_cast<long>(Time::kNanosecondsPerSecond)); // NOLINT
	return TimeDelta(ts.tv_sec * Time::kMicrosecondsPerSecond +
	ts.tv_nsec / Time::kNanosecondsPerMicrosecond);
	}


	struct timespec TimeDelta::ToTimespec() const {
	struct timespec ts;
	ts.tv_sec = static_cast<time_t>(delta_ / Time::kMicrosecondsPerSecond);
	ts.tv_nsec = (delta_ % Time::kMicrosecondsPerSecond) *
	Time::kNanosecondsPerMicrosecond;
	return ts;
	}

	#endif // V8_OS_POSIX


	#if V8_OS_WIN

	// We implement time using the high-resolution timers so that we can get
	// timeouts which are smaller than 10-15ms. To avoid any drift, we
	// periodically resync the internal clock to the system clock.
	class Clock final {
	public:
	Clock() : initial_ticks_(GetSystemTicks()), initial_time_(GetSystemTime()) {}

	Time Now() {
	// Time between resampling the un-granular clock for this API (1 minute).
	const TimeDelta kMaxElapsedTime = TimeDelta::FromMinutes(1);

	LockGuard<Mutex> lock_guard(&mutex_);

	// Determine current time and ticks.
	TimeTicks ticks = GetSystemTicks();
	Time time = GetSystemTime();

	// Check if we need to synchronize with the system clock due to a backwards
	// time change or the amount of time elapsed.
	TimeDelta elapsed = ticks - initial_ticks_;
	if (time < initial_time_ \|\| elapsed > kMaxElapsedTime) {
	initial_ticks_ = ticks;
	initial_time_ = time;
	return time;
	}

	return initial_time_ + elapsed;
	}

	Time NowFromSystemTime() {
	LockGuard<Mutex> lock_guard(&mutex_);
	initial_ticks_ = GetSystemTicks();
	initial_time_ = GetSystemTime();
	return initial_time_;
	}

	private:
	static TimeTicks GetSystemTicks() {
	return TimeTicks::Now();
	}

	static Time GetSystemTime() {
	FILETIME ft;
	::GetSystemTimeAsFileTime(&ft);
	return Time::FromFiletime(ft);
	}

	TimeTicks initial_ticks_;
	Time initial_time_;
	Mutex mutex_;
	};


	static LazyStaticInstance<Clock, DefaultConstructTrait<Clock>,
	ThreadSafeInitOnceTrait>::type clock =
	LAZY_STATIC_INSTANCE_INITIALIZER;


	Time Time::Now() {
	return clock.Pointer()->Now();
	}


	Time Time::NowFromSystemTime() {
	return clock.Pointer()->NowFromSystemTime();
	}


	// Time between windows epoch and standard epoch.
	static const int64_t kTimeToEpochInMicroseconds = V8_INT64_C(11644473600000000);


	Time Time::FromFiletime(FILETIME ft) {
	if (ft.dwLowDateTime == 0 && ft.dwHighDateTime == 0) {
	return Time();
	}
	if (ft.dwLowDateTime == std::numeric_limits<DWORD>::max() &&
	ft.dwHighDateTime == std::numeric_limits<DWORD>::max()) {
	return Max();
	}
	int64_t us = (static_cast<uint64_t>(ft.dwLowDateTime) +
	(static_cast<uint64_t>(ft.dwHighDateTime) << 32)) / 10;
	return Time(us - kTimeToEpochInMicroseconds);
	}


	FILETIME Time::ToFiletime() const {
	DCHECK(us_ >= 0);
	FILETIME ft;
	if (IsNull()) {
	ft.dwLowDateTime = 0;
	ft.dwHighDateTime = 0;
	return ft;
	}
	if (IsMax()) {
	ft.dwLowDateTime = std::numeric_limits<DWORD>::max();
	ft.dwHighDateTime = std::numeric_limits<DWORD>::max();
	return ft;
	}
	uint64_t us = static_cast<uint64_t>(us_ + kTimeToEpochInMicroseconds) * 10;
	ft.dwLowDateTime = static_cast<DWORD>(us);
	ft.dwHighDateTime = static_cast<DWORD>(us >> 32);
	return ft;
	}

	#elif V8_OS_POSIX

	Time Time::Now() {
	struct timeval tv;
	int result = gettimeofday(&tv, NULL);
	DCHECK_EQ(0, result);
	USE(result);
	return FromTimeval(tv);
	}


	Time Time::NowFromSystemTime() {
	return Now();
	}


	Time Time::FromTimespec(struct timespec ts) {
	DCHECK(ts.tv_nsec >= 0);
	DCHECK(ts.tv_nsec < static_cast<long>(kNanosecondsPerSecond)); // NOLINT
	if (ts.tv_nsec == 0 && ts.tv_sec == 0) {
	return Time();
	}
	if (ts.tv_nsec == static_cast<long>(kNanosecondsPerSecond - 1) && // NOLINT
	ts.tv_sec == std::numeric_limits<time_t>::max()) {
	return Max();
	}
	return Time(ts.tv_sec * kMicrosecondsPerSecond +
	ts.tv_nsec / kNanosecondsPerMicrosecond);
	}


	struct timespec Time::ToTimespec() const {
	struct timespec ts;
	if (IsNull()) {
	ts.tv_sec = 0;
	ts.tv_nsec = 0;
	return ts;
	}
	if (IsMax()) {
	ts.tv_sec = std::numeric_limits<time_t>::max();
	ts.tv_nsec = static_cast<long>(kNanosecondsPerSecond - 1); // NOLINT
	return ts;
	}
	ts.tv_sec = static_cast<time_t>(us_ / kMicrosecondsPerSecond);
	ts.tv_nsec = (us_ % kMicrosecondsPerSecond) * kNanosecondsPerMicrosecond;
	return ts;
	}


	Time Time::FromTimeval(struct timeval tv) {
	DCHECK(tv.tv_usec >= 0);
	DCHECK(tv.tv_usec < static_cast<suseconds_t>(kMicrosecondsPerSecond));
	if (tv.tv_usec == 0 && tv.tv_sec == 0) {
	return Time();
	}
	if (tv.tv_usec == static_cast<suseconds_t>(kMicrosecondsPerSecond - 1) &&
	tv.tv_sec == std::numeric_limits<time_t>::max()) {
	return Max();
	}
	return Time(tv.tv_sec * kMicrosecondsPerSecond + tv.tv_usec);
	}


	struct timeval Time::ToTimeval() const {
	struct timeval tv;
	if (IsNull()) {
	tv.tv_sec = 0;
	tv.tv_usec = 0;
	return tv;
	}
	if (IsMax()) {
	tv.tv_sec = std::numeric_limits<time_t>::max();
	tv.tv_usec = static_cast<suseconds_t>(kMicrosecondsPerSecond - 1);
	return tv;
	}
	tv.tv_sec = static_cast<time_t>(us_ / kMicrosecondsPerSecond);
	tv.tv_usec = us_ % kMicrosecondsPerSecond;
	return tv;
	}

	#endif // V8_OS_WIN


	Time Time::FromJsTime(double ms_since_epoch) {
	// The epoch is a valid time, so this constructor doesn't interpret
	// 0 as the null time.
	if (ms_since_epoch == std::numeric_limits<double>::max()) {
	return Max();
	}
	return Time(
	static_cast<int64_t>(ms_since_epoch * kMicrosecondsPerMillisecond));
	}


	double Time::ToJsTime() const {
	if (IsNull()) {
	// Preserve 0 so the invalid result doesn't depend on the platform.
	return 0;
	}
	if (IsMax()) {
	// Preserve max without offset to prevent overflow.
	return std::numeric_limits<double>::max();
	}
	return static_cast<double>(us_) / kMicrosecondsPerMillisecond;
	}


	std::ostream& operator<<(std::ostream& os, const Time& time) {
	return os << time.ToJsTime();
	}


	#if V8_OS_WIN

	class TickClock {
	public:
	virtual ~TickClock() {}
	virtual int64_t Now() = 0;
	virtual bool IsHighResolution() = 0;
	};


	// Overview of time counters:
	// (1) CPU cycle counter. (Retrieved via RDTSC)
	// The CPU counter provides the highest resolution time stamp and is the least
	// expensive to retrieve. However, the CPU counter is unreliable and should not
	// be used in production. Its biggest issue is that it is per processor and it
	// is not synchronized between processors. Also, on some computers, the counters
	// will change frequency due to thermal and power changes, and stop in some
	// states.
	//
	// (2) QueryPerformanceCounter (QPC). The QPC counter provides a high-
	// resolution (100 nanoseconds) time stamp but is comparatively more expensive
	// to retrieve. What QueryPerformanceCounter actually does is up to the HAL.
	// (with some help from ACPI).
	// According to http://blogs.msdn.com/oldnewthing/archive/2005/09/02/459952.aspx
	// in the worst case, it gets the counter from the rollover interrupt on the
	// programmable interrupt timer. In best cases, the HAL may conclude that the
	// RDTSC counter runs at a constant frequency, then it uses that instead. On
	// multiprocessor machines, it will try to verify the values returned from
	// RDTSC on each processor are consistent with each other, and apply a handful
	// of workarounds for known buggy hardware. In other words, QPC is supposed to
	// give consistent result on a multiprocessor computer, but it is unreliable in
	// reality due to bugs in BIOS or HAL on some, especially old computers.
	// With recent updates on HAL and newer BIOS, QPC is getting more reliable but
	// it should be used with caution.
	//
	// (3) System time. The system time provides a low-resolution (typically 10ms
	// to 55 milliseconds) time stamp but is comparatively less expensive to
	// retrieve and more reliable.
	class HighResolutionTickClock final : public TickClock {
	public:
	explicit HighResolutionTickClock(int64_t ticks_per_second)
	: ticks_per_second_(ticks_per_second) {
	DCHECK_LT(0, ticks_per_second);
	}
	virtual ~HighResolutionTickClock() {}

	int64_t Now() override {
	LARGE_INTEGER now;
	BOOL result = QueryPerformanceCounter(&now);
	DCHECK(result);
	USE(result);

	// Intentionally calculate microseconds in a round about manner to avoid
	// overflow and precision issues. Think twice before simplifying!
	int64_t whole_seconds = now.QuadPart / ticks_per_second_;
	int64_t leftover_ticks = now.QuadPart % ticks_per_second_;
	int64_t ticks = (whole_seconds * Time::kMicrosecondsPerSecond) +
	((leftover_ticks * Time::kMicrosecondsPerSecond) / ticks_per_second_);

	// Make sure we never return 0 here, so that TimeTicks::HighResolutionNow()
	// will never return 0.
	return ticks + 1;
	}

	bool IsHighResolution() override { return true; }

	private:
	int64_t ticks_per_second_;
	};


	class RolloverProtectedTickClock final : public TickClock {
	public:
	RolloverProtectedTickClock() : rollover_(0) {}
	virtual ~RolloverProtectedTickClock() {}

	int64_t Now() override {
	// We use timeGetTime() to implement TimeTicks::Now(), which rolls over
	// every ~49.7 days. We try to track rollover ourselves, which works if
	// TimeTicks::Now() is called at least every 24 days.
	// Note that we do not use GetTickCount() here, since timeGetTime() gives
	// more predictable delta values, as described here:
	// http://blogs.msdn.com/b/larryosterman/archive/2009/09/02/what-s-the-difference-between-gettickcount-and-timegettime.aspx
	// timeGetTime() provides 1ms granularity when combined with
	// timeBeginPeriod(). If the host application for V8 wants fast timers, it
	// can use timeBeginPeriod() to increase the resolution.
	// We use a lock-free version because the sampler thread calls it
	// while having the rest of the world stopped, that could cause a deadlock.
	base::Atomic32 rollover = base::Acquire_Load(&rollover_);
	uint32_t now = static_cast<uint32_t>(timeGetTime());
	if ((now >> 31) != static_cast<uint32_t>(rollover & 1)) {
	base::Release_CompareAndSwap(&rollover_, rollover, rollover + 1);
	++rollover;
	}
	uint64_t ms = (static_cast<uint64_t>(rollover) << 31) \| now;
	return static_cast<int64_t>(ms * Time::kMicrosecondsPerMillisecond);
	}

	bool IsHighResolution() override { return false; }

	private:
	base::Atomic32 rollover_;
	};


	static LazyStaticInstance<RolloverProtectedTickClock,
	DefaultConstructTrait<RolloverProtectedTickClock>,
	ThreadSafeInitOnceTrait>::type tick_clock =
	LAZY_STATIC_INSTANCE_INITIALIZER;


	struct CreateHighResTickClockTrait {
	static TickClock* Create() {
	// Check if the installed hardware supports a high-resolution performance
	// counter, and if not fallback to the low-resolution tick clock.
	LARGE_INTEGER ticks_per_second;
	if (!QueryPerformanceFrequency(&ticks_per_second)) {
	return tick_clock.Pointer();
	}

	// On Athlon X2 CPUs (e.g. model 15) the QueryPerformanceCounter
	// is unreliable, fallback to the low-resolution tick clock.
	CPU cpu;
	if (strcmp(cpu.vendor(), "AuthenticAMD") == 0 && cpu.family() == 15) {
	return tick_clock.Pointer();
	}

	return new HighResolutionTickClock(ticks_per_second.QuadPart);
	}
	};


	static LazyDynamicInstance<TickClock, CreateHighResTickClockTrait,
	ThreadSafeInitOnceTrait>::type high_res_tick_clock =
	LAZY_DYNAMIC_INSTANCE_INITIALIZER;


	TimeTicks TimeTicks::Now() {
	// Make sure we never return 0 here.
	TimeTicks ticks(tick_clock.Pointer()->Now());
	DCHECK(!ticks.IsNull());
	return ticks;
	}


	TimeTicks TimeTicks::HighResolutionNow() {
	// Make sure we never return 0 here.
	TimeTicks ticks(high_res_tick_clock.Pointer()->Now());
	DCHECK(!ticks.IsNull());
	return ticks;
	}


	// static
	bool TimeTicks::IsHighResolutionClockWorking() {
	return high_res_tick_clock.Pointer()->IsHighResolution();
	}

	#else // V8_OS_WIN

	TimeTicks TimeTicks::Now() {
	return HighResolutionNow();
	}


	TimeTicks TimeTicks::HighResolutionNow() {
	int64_t ticks;
	#if V8_OS_MACOSX
	static struct mach_timebase_info info;
	if (info.denom == 0) {
	kern_return_t result = mach_timebase_info(&info);
	DCHECK_EQ(KERN_SUCCESS, result);
	USE(result);
	}
	ticks = (mach_absolute_time() / Time::kNanosecondsPerMicrosecond *
	info.numer / info.denom);
	#elif V8_OS_SOLARIS
	ticks = (gethrtime() / Time::kNanosecondsPerMicrosecond);
	#elif V8_OS_POSIX
	struct timespec ts;
	int result = clock_gettime(CLOCK_MONOTONIC, &ts);
	DCHECK_EQ(0, result);
	USE(result);
	ticks = (ts.tv_sec * Time::kMicrosecondsPerSecond +
	ts.tv_nsec / Time::kNanosecondsPerMicrosecond);
	#endif // V8_OS_MACOSX
	// Make sure we never return 0 here.
	return TimeTicks(ticks + 1);
	}


	// static
	bool TimeTicks::IsHighResolutionClockWorking() {
	return true;
	}

	#endif // V8_OS_WIN

	} // namespace base
	} // namespace v8