test/unittests/base/platform/time-unittest.cc - fp2-dev/platform/external/v8 - Gitiles

 // Copyright 2014 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_MACOSX
 #include <mach/mach_time.h>
 #endif
 #if V8_OS_POSIX
 #include <sys/time.h>
 #endif

 #if V8_OS_WIN
 #include "src/base/win32-headers.h"
 #endif

 #include <vector>

 #include "src/base/platform/elapsed-timer.h"
 #include "src/base/platform/platform.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace v8 {
 namespace base {

 TEST(TimeDelta, FromAndIn) {
   EXPECT_EQ(TimeDelta::FromDays(2), TimeDelta::FromHours(48));
   EXPECT_EQ(TimeDelta::FromHours(3), TimeDelta::FromMinutes(180));
   EXPECT_EQ(TimeDelta::FromMinutes(2), TimeDelta::FromSeconds(120));
   EXPECT_EQ(TimeDelta::FromSeconds(2), TimeDelta::FromMilliseconds(2000));
   EXPECT_EQ(TimeDelta::FromMilliseconds(2), TimeDelta::FromMicroseconds(2000));
   EXPECT_EQ(static_cast<int>(13), TimeDelta::FromDays(13).InDays());
   EXPECT_EQ(static_cast<int>(13), TimeDelta::FromHours(13).InHours());
   EXPECT_EQ(static_cast<int>(13), TimeDelta::FromMinutes(13).InMinutes());
   EXPECT_EQ(static_cast<int64_t>(13), TimeDelta::FromSeconds(13).InSeconds());
   EXPECT_DOUBLE_EQ(13.0, TimeDelta::FromSeconds(13).InSecondsF());
   EXPECT_EQ(static_cast<int64_t>(13),
             TimeDelta::FromMilliseconds(13).InMilliseconds());
   EXPECT_DOUBLE_EQ(13.0, TimeDelta::FromMilliseconds(13).InMillisecondsF());
   EXPECT_EQ(static_cast<int64_t>(13),
             TimeDelta::FromMicroseconds(13).InMicroseconds());
 }


 #if V8_OS_MACOSX
 TEST(TimeDelta, MachTimespec) {
   TimeDelta null = TimeDelta();
   EXPECT_EQ(null, TimeDelta::FromMachTimespec(null.ToMachTimespec()));
   TimeDelta delta1 = TimeDelta::FromMilliseconds(42);
   EXPECT_EQ(delta1, TimeDelta::FromMachTimespec(delta1.ToMachTimespec()));
   TimeDelta delta2 = TimeDelta::FromDays(42);
   EXPECT_EQ(delta2, TimeDelta::FromMachTimespec(delta2.ToMachTimespec()));
 }
 #endif


 TEST(Time, JsTime) {
   Time t = Time::FromJsTime(700000.3);
   EXPECT_DOUBLE_EQ(700000.3, t.ToJsTime());
 }


 #if V8_OS_POSIX
 TEST(Time, Timespec) {
   Time null;
   EXPECT_TRUE(null.IsNull());
   EXPECT_EQ(null, Time::FromTimespec(null.ToTimespec()));
   Time now = Time::Now();
   EXPECT_EQ(now, Time::FromTimespec(now.ToTimespec()));
   Time now_sys = Time::NowFromSystemTime();
   EXPECT_EQ(now_sys, Time::FromTimespec(now_sys.ToTimespec()));
   Time unix_epoch = Time::UnixEpoch();
   EXPECT_EQ(unix_epoch, Time::FromTimespec(unix_epoch.ToTimespec()));
   Time max = Time::Max();
   EXPECT_TRUE(max.IsMax());
   EXPECT_EQ(max, Time::FromTimespec(max.ToTimespec()));
 }


 TEST(Time, Timeval) {
   Time null;
   EXPECT_TRUE(null.IsNull());
   EXPECT_EQ(null, Time::FromTimeval(null.ToTimeval()));
   Time now = Time::Now();
   EXPECT_EQ(now, Time::FromTimeval(now.ToTimeval()));
   Time now_sys = Time::NowFromSystemTime();
   EXPECT_EQ(now_sys, Time::FromTimeval(now_sys.ToTimeval()));
   Time unix_epoch = Time::UnixEpoch();
   EXPECT_EQ(unix_epoch, Time::FromTimeval(unix_epoch.ToTimeval()));
   Time max = Time::Max();
   EXPECT_TRUE(max.IsMax());
   EXPECT_EQ(max, Time::FromTimeval(max.ToTimeval()));
 }
 #endif


 #if V8_OS_WIN
 TEST(Time, Filetime) {
   Time null;
   EXPECT_TRUE(null.IsNull());
   EXPECT_EQ(null, Time::FromFiletime(null.ToFiletime()));
   Time now = Time::Now();
   EXPECT_EQ(now, Time::FromFiletime(now.ToFiletime()));
   Time now_sys = Time::NowFromSystemTime();
   EXPECT_EQ(now_sys, Time::FromFiletime(now_sys.ToFiletime()));
   Time unix_epoch = Time::UnixEpoch();
   EXPECT_EQ(unix_epoch, Time::FromFiletime(unix_epoch.ToFiletime()));
   Time max = Time::Max();
   EXPECT_TRUE(max.IsMax());
   EXPECT_EQ(max, Time::FromFiletime(max.ToFiletime()));
 }
 #endif


 namespace {

 template <typename T>
 static void ResolutionTest(T (*Now)(), TimeDelta target_granularity) {
   // We're trying to measure that intervals increment in a VERY small amount
   // of time -- according to the specified target granularity. Unfortunately,
   // if we happen to have a context switch in the middle of our test, the
   // context switch could easily exceed our limit. So, we iterate on this
   // several times. As long as we're able to detect the fine-granularity
   // timers at least once, then the test has succeeded.
   static const TimeDelta kExpirationTimeout = TimeDelta::FromSeconds(1);
   ElapsedTimer timer;
   timer.Start();
   TimeDelta delta;
   do {
     T start = Now();
     T now = start;
     // Loop until we can detect that the clock has changed. Non-HighRes timers
     // will increment in chunks, i.e. 15ms. By spinning until we see a clock
     // change, we detect the minimum time between measurements.
     do {
       now = Now();
       delta = now - start;
     } while (now <= start);
     EXPECT_NE(static_cast<int64_t>(0), delta.InMicroseconds());
   } while (delta > target_granularity && !timer.HasExpired(kExpirationTimeout));
   EXPECT_LE(delta, target_granularity);
 }

 }  // namespace


 TEST(Time, NowResolution) {
   // We assume that Time::Now() has at least 16ms resolution.
   static const TimeDelta kTargetGranularity = TimeDelta::FromMilliseconds(16);
   ResolutionTest<Time>(&Time::Now, kTargetGranularity);
 }


 TEST(TimeTicks, NowResolution) {
   // We assume that TimeTicks::Now() has at least 16ms resolution.
   static const TimeDelta kTargetGranularity = TimeDelta::FromMilliseconds(16);
   ResolutionTest<TimeTicks>(&TimeTicks::Now, kTargetGranularity);
 }


 TEST(TimeTicks, HighResolutionNowResolution) {
   if (!TimeTicks::IsHighResolutionClockWorking()) return;

   // We assume that TimeTicks::HighResolutionNow() has sub-ms resolution.
   static const TimeDelta kTargetGranularity = TimeDelta::FromMilliseconds(1);
   ResolutionTest<TimeTicks>(&TimeTicks::HighResolutionNow, kTargetGranularity);
 }


 TEST(TimeTicks, IsMonotonic) {
   TimeTicks previous_normal_ticks;
   TimeTicks previous_highres_ticks;
   ElapsedTimer timer;
   timer.Start();
   while (!timer.HasExpired(TimeDelta::FromMilliseconds(100))) {
     TimeTicks normal_ticks = TimeTicks::Now();
     TimeTicks highres_ticks = TimeTicks::HighResolutionNow();
     EXPECT_GE(normal_ticks, previous_normal_ticks);
     EXPECT_GE((normal_ticks - previous_normal_ticks).InMicroseconds(), 0);
     EXPECT_GE(highres_ticks, previous_highres_ticks);
     EXPECT_GE((highres_ticks - previous_highres_ticks).InMicroseconds(), 0);
     previous_normal_ticks = normal_ticks;
     previous_highres_ticks = highres_ticks;
   }
 }


 // Disable on windows until it is implemented.
 #if V8_OS_ANDROID
 #define MAYBE_ThreadNow DISABLED_ThreadNow
 #else
 #define MAYBE_ThreadNow ThreadNow
 #endif
 TEST(ThreadTicks, MAYBE_ThreadNow) {
   if (ThreadTicks::IsSupported()) {
     TimeTicks begin = TimeTicks::Now();
     ThreadTicks begin_thread = ThreadTicks::Now();
     // Make sure that ThreadNow value is non-zero.
     EXPECT_GT(begin_thread, ThreadTicks());
     // Sleep for 10 milliseconds to get the thread de-scheduled.
     OS::Sleep(base::TimeDelta::FromMilliseconds(10));
     ThreadTicks end_thread = ThreadTicks::Now();
     TimeTicks end = TimeTicks::Now();
     TimeDelta delta = end - begin;
     TimeDelta delta_thread = end_thread - begin_thread;
     // Make sure that some thread time have elapsed.
     EXPECT_GT(delta_thread.InMicroseconds(), 0);
     // But the thread time is at least 9ms less than clock time.
     TimeDelta difference = delta - delta_thread;
     EXPECT_GE(difference.InMicroseconds(), 9000);
   }
 }


 #if V8_OS_WIN
 TEST(TimeTicks, TimerPerformance) {
   // Verify that various timer mechanisms can always complete quickly.
   // Note:  This is a somewhat arbitrary test.
   const int kLoops = 10000;

   typedef TimeTicks (*TestFunc)();
   struct TestCase {
     TestFunc func;
     const char *description;
   };
   // Cheating a bit here:  assumes sizeof(TimeTicks) == sizeof(Time)
   // in order to create a single test case list.
   static_assert(sizeof(TimeTicks) == sizeof(Time),
                 "TimeTicks and Time must be the same size");
   std::vector<TestCase> cases;
   cases.push_back({reinterpret_cast<TestFunc>(&Time::Now), "Time::Now"});
   cases.push_back({&TimeTicks::Now, "TimeTicks::Now"});

   if (ThreadTicks::IsSupported()) {
     ThreadTicks::WaitUntilInitialized();
     cases.push_back(
         {reinterpret_cast<TestFunc>(&ThreadTicks::Now), "ThreadTicks::Now"});
   }

   for (const auto& test_case : cases) {
     TimeTicks start = TimeTicks::Now();
     for (int index = 0; index < kLoops; index++)
       test_case.func();
     TimeTicks stop = TimeTicks::Now();
     // Turning off the check for acceptible delays.  Without this check,
     // the test really doesn't do much other than measure.  But the
     // measurements are still useful for testing timers on various platforms.
     // The reason to remove the check is because the tests run on many
     // buildbots, some of which are VMs.  These machines can run horribly
     // slow, and there is really no value for checking against a max timer.
     // const int kMaxTime = 35;  // Maximum acceptible milliseconds for test.
     // EXPECT_LT((stop - start).InMilliseconds(), kMaxTime);
     printf("%s: %1.2fus per call\n", test_case.description,
            (stop - start).InMillisecondsF() * 1000 / kLoops);
   }
 }
 #endif  // V8_OS_WIN

 }  // namespace base
 }  // namespace v8
	// Copyright 2014 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_MACOSX
	#include <mach/mach_time.h>
	#endif
	#if V8_OS_POSIX
	#include <sys/time.h>
	#endif

	#if V8_OS_WIN
	#include "src/base/win32-headers.h"
	#endif

	#include <vector>

	#include "src/base/platform/elapsed-timer.h"
	#include "src/base/platform/platform.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace v8 {
	namespace base {

	TEST(TimeDelta, FromAndIn) {
	EXPECT_EQ(TimeDelta::FromDays(2), TimeDelta::FromHours(48));
	EXPECT_EQ(TimeDelta::FromHours(3), TimeDelta::FromMinutes(180));
	EXPECT_EQ(TimeDelta::FromMinutes(2), TimeDelta::FromSeconds(120));
	EXPECT_EQ(TimeDelta::FromSeconds(2), TimeDelta::FromMilliseconds(2000));
	EXPECT_EQ(TimeDelta::FromMilliseconds(2), TimeDelta::FromMicroseconds(2000));
	EXPECT_EQ(static_cast<int>(13), TimeDelta::FromDays(13).InDays());
	EXPECT_EQ(static_cast<int>(13), TimeDelta::FromHours(13).InHours());
	EXPECT_EQ(static_cast<int>(13), TimeDelta::FromMinutes(13).InMinutes());
	EXPECT_EQ(static_cast<int64_t>(13), TimeDelta::FromSeconds(13).InSeconds());
	EXPECT_DOUBLE_EQ(13.0, TimeDelta::FromSeconds(13).InSecondsF());
	EXPECT_EQ(static_cast<int64_t>(13),
	TimeDelta::FromMilliseconds(13).InMilliseconds());
	EXPECT_DOUBLE_EQ(13.0, TimeDelta::FromMilliseconds(13).InMillisecondsF());
	EXPECT_EQ(static_cast<int64_t>(13),
	TimeDelta::FromMicroseconds(13).InMicroseconds());
	}


	#if V8_OS_MACOSX
	TEST(TimeDelta, MachTimespec) {
	TimeDelta null = TimeDelta();
	EXPECT_EQ(null, TimeDelta::FromMachTimespec(null.ToMachTimespec()));
	TimeDelta delta1 = TimeDelta::FromMilliseconds(42);
	EXPECT_EQ(delta1, TimeDelta::FromMachTimespec(delta1.ToMachTimespec()));
	TimeDelta delta2 = TimeDelta::FromDays(42);
	EXPECT_EQ(delta2, TimeDelta::FromMachTimespec(delta2.ToMachTimespec()));
	}
	#endif


	TEST(Time, JsTime) {
	Time t = Time::FromJsTime(700000.3);
	EXPECT_DOUBLE_EQ(700000.3, t.ToJsTime());
	}


	#if V8_OS_POSIX
	TEST(Time, Timespec) {
	Time null;
	EXPECT_TRUE(null.IsNull());
	EXPECT_EQ(null, Time::FromTimespec(null.ToTimespec()));
	Time now = Time::Now();
	EXPECT_EQ(now, Time::FromTimespec(now.ToTimespec()));
	Time now_sys = Time::NowFromSystemTime();
	EXPECT_EQ(now_sys, Time::FromTimespec(now_sys.ToTimespec()));
	Time unix_epoch = Time::UnixEpoch();
	EXPECT_EQ(unix_epoch, Time::FromTimespec(unix_epoch.ToTimespec()));
	Time max = Time::Max();
	EXPECT_TRUE(max.IsMax());
	EXPECT_EQ(max, Time::FromTimespec(max.ToTimespec()));
	}


	TEST(Time, Timeval) {
	Time null;
	EXPECT_TRUE(null.IsNull());
	EXPECT_EQ(null, Time::FromTimeval(null.ToTimeval()));
	Time now = Time::Now();
	EXPECT_EQ(now, Time::FromTimeval(now.ToTimeval()));
	Time now_sys = Time::NowFromSystemTime();
	EXPECT_EQ(now_sys, Time::FromTimeval(now_sys.ToTimeval()));
	Time unix_epoch = Time::UnixEpoch();
	EXPECT_EQ(unix_epoch, Time::FromTimeval(unix_epoch.ToTimeval()));
	Time max = Time::Max();
	EXPECT_TRUE(max.IsMax());
	EXPECT_EQ(max, Time::FromTimeval(max.ToTimeval()));
	}
	#endif


	#if V8_OS_WIN
	TEST(Time, Filetime) {
	Time null;
	EXPECT_TRUE(null.IsNull());
	EXPECT_EQ(null, Time::FromFiletime(null.ToFiletime()));
	Time now = Time::Now();
	EXPECT_EQ(now, Time::FromFiletime(now.ToFiletime()));
	Time now_sys = Time::NowFromSystemTime();
	EXPECT_EQ(now_sys, Time::FromFiletime(now_sys.ToFiletime()));
	Time unix_epoch = Time::UnixEpoch();
	EXPECT_EQ(unix_epoch, Time::FromFiletime(unix_epoch.ToFiletime()));
	Time max = Time::Max();
	EXPECT_TRUE(max.IsMax());
	EXPECT_EQ(max, Time::FromFiletime(max.ToFiletime()));
	}
	#endif


	namespace {

	template <typename T>
	static void ResolutionTest(T (*Now)(), TimeDelta target_granularity) {
	// We're trying to measure that intervals increment in a VERY small amount
	// of time -- according to the specified target granularity. Unfortunately,
	// if we happen to have a context switch in the middle of our test, the
	// context switch could easily exceed our limit. So, we iterate on this
	// several times. As long as we're able to detect the fine-granularity
	// timers at least once, then the test has succeeded.
	static const TimeDelta kExpirationTimeout = TimeDelta::FromSeconds(1);
	ElapsedTimer timer;
	timer.Start();
	TimeDelta delta;
	do {
	T start = Now();
	T now = start;
	// Loop until we can detect that the clock has changed. Non-HighRes timers
	// will increment in chunks, i.e. 15ms. By spinning until we see a clock
	// change, we detect the minimum time between measurements.
	do {
	now = Now();
	delta = now - start;
	} while (now <= start);
	EXPECT_NE(static_cast<int64_t>(0), delta.InMicroseconds());
	} while (delta > target_granularity && !timer.HasExpired(kExpirationTimeout));
	EXPECT_LE(delta, target_granularity);
	}

	} // namespace


	TEST(Time, NowResolution) {
	// We assume that Time::Now() has at least 16ms resolution.
	static const TimeDelta kTargetGranularity = TimeDelta::FromMilliseconds(16);
	ResolutionTest<Time>(&Time::Now, kTargetGranularity);
	}


	TEST(TimeTicks, NowResolution) {
	// We assume that TimeTicks::Now() has at least 16ms resolution.
	static const TimeDelta kTargetGranularity = TimeDelta::FromMilliseconds(16);
	ResolutionTest<TimeTicks>(&TimeTicks::Now, kTargetGranularity);
	}


	TEST(TimeTicks, HighResolutionNowResolution) {
	if (!TimeTicks::IsHighResolutionClockWorking()) return;

	// We assume that TimeTicks::HighResolutionNow() has sub-ms resolution.
	static const TimeDelta kTargetGranularity = TimeDelta::FromMilliseconds(1);
	ResolutionTest<TimeTicks>(&TimeTicks::HighResolutionNow, kTargetGranularity);
	}


	TEST(TimeTicks, IsMonotonic) {
	TimeTicks previous_normal_ticks;
	TimeTicks previous_highres_ticks;
	ElapsedTimer timer;
	timer.Start();
	while (!timer.HasExpired(TimeDelta::FromMilliseconds(100))) {
	TimeTicks normal_ticks = TimeTicks::Now();
	TimeTicks highres_ticks = TimeTicks::HighResolutionNow();
	EXPECT_GE(normal_ticks, previous_normal_ticks);
	EXPECT_GE((normal_ticks - previous_normal_ticks).InMicroseconds(), 0);
	EXPECT_GE(highres_ticks, previous_highres_ticks);
	EXPECT_GE((highres_ticks - previous_highres_ticks).InMicroseconds(), 0);
	previous_normal_ticks = normal_ticks;
	previous_highres_ticks = highres_ticks;
	}
	}


	// Disable on windows until it is implemented.
	#if V8_OS_ANDROID
	#define MAYBE_ThreadNow DISABLED_ThreadNow
	#else
	#define MAYBE_ThreadNow ThreadNow
	#endif
	TEST(ThreadTicks, MAYBE_ThreadNow) {
	if (ThreadTicks::IsSupported()) {
	TimeTicks begin = TimeTicks::Now();
	ThreadTicks begin_thread = ThreadTicks::Now();
	// Make sure that ThreadNow value is non-zero.
	EXPECT_GT(begin_thread, ThreadTicks());
	// Sleep for 10 milliseconds to get the thread de-scheduled.
	OS::Sleep(base::TimeDelta::FromMilliseconds(10));
	ThreadTicks end_thread = ThreadTicks::Now();
	TimeTicks end = TimeTicks::Now();
	TimeDelta delta = end - begin;
	TimeDelta delta_thread = end_thread - begin_thread;
	// Make sure that some thread time have elapsed.
	EXPECT_GT(delta_thread.InMicroseconds(), 0);
	// But the thread time is at least 9ms less than clock time.
	TimeDelta difference = delta - delta_thread;
	EXPECT_GE(difference.InMicroseconds(), 9000);
	}
	}


	#if V8_OS_WIN
	TEST(TimeTicks, TimerPerformance) {
	// Verify that various timer mechanisms can always complete quickly.
	// Note: This is a somewhat arbitrary test.
	const int kLoops = 10000;

	typedef TimeTicks (*TestFunc)();
	struct TestCase {
	TestFunc func;
	const char *description;
	};
	// Cheating a bit here: assumes sizeof(TimeTicks) == sizeof(Time)
	// in order to create a single test case list.
	static_assert(sizeof(TimeTicks) == sizeof(Time),
	"TimeTicks and Time must be the same size");
	std::vector<TestCase> cases;
	cases.push_back({reinterpret_cast<TestFunc>(&Time::Now), "Time::Now"});
	cases.push_back({&TimeTicks::Now, "TimeTicks::Now"});

	if (ThreadTicks::IsSupported()) {
	ThreadTicks::WaitUntilInitialized();
	cases.push_back(
	{reinterpret_cast<TestFunc>(&ThreadTicks::Now), "ThreadTicks::Now"});
	}

	for (const auto& test_case : cases) {
	TimeTicks start = TimeTicks::Now();
	for (int index = 0; index < kLoops; index++)
	test_case.func();
	TimeTicks stop = TimeTicks::Now();
	// Turning off the check for acceptible delays. Without this check,
	// the test really doesn't do much other than measure. But the
	// measurements are still useful for testing timers on various platforms.
	// The reason to remove the check is because the tests run on many
	// buildbots, some of which are VMs. These machines can run horribly
	// slow, and there is really no value for checking against a max timer.
	// const int kMaxTime = 35; // Maximum acceptible milliseconds for test.
	// EXPECT_LT((stop - start).InMilliseconds(), kMaxTime);
	printf("%s: %1.2fus per call\n", test_case.description,
	(stop - start).InMillisecondsF() * 1000 / kLoops);
	}
	}
	#endif // V8_OS_WIN

	} // namespace base
	} // namespace v8