base/time/time_apple_unittest.mm - chromium/src - Git at Google

 // Copyright 2021 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "base/time/time.h"

 #include "base/test/gtest_util.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace {

 class ScopedTimebase {
  public:
   explicit ScopedTimebase(mach_timebase_info_data_t timebase) {
     orig_timebase_ = base::TimeTicks::SetMachTimebaseInfoForTesting(timebase);
   }

   ScopedTimebase(const ScopedTimebase&) = delete;

   ScopedTimebase& operator=(const ScopedTimebase&) = delete;

   ~ScopedTimebase() {
     base::TimeTicks::SetMachTimebaseInfoForTesting(orig_timebase_);
   }

  private:
   mach_timebase_info_data_t orig_timebase_;
 };

 mach_timebase_info_data_t kIntelTimebase = {1, 1};

 // A sample (not definitive) timebase for M1.
 mach_timebase_info_data_t kM1Timebase = {125, 3};

 }  // namespace

 namespace base {
 namespace {

 base::Time NoonOnDate(int year, int month, int day) {
   const base::Time::Exploded exploded = {
       .year = year, .month = month, .day_of_month = day, .hour = 12};
   base::Time imploded;
   CHECK(base::Time::FromUTCExploded(exploded, &imploded));
   return imploded;
 }

 void CheckRoundTrip(int y, int m, int d) {
   base::Time original = NoonOnDate(y, m, d);
   base::Time roundtrip = Time::FromNSDate(original.ToNSDate());
   EXPECT_EQ(original, roundtrip);
 }

 TEST(TimeMacTest, RoundTripNSDate) {
   CheckRoundTrip(1911, 12, 14);
   CheckRoundTrip(1924, 9, 28);
   CheckRoundTrip(1926, 5, 12);
   CheckRoundTrip(1969, 7, 24);
 }

 TEST(TimeMacTest, MachTimeToMicrosecondsIntelTimebase) {
   ScopedTimebase timebase(kIntelTimebase);

   // Perform the conversion.
   uint64_t kArbitraryTicks = 59090101000;
   TimeDelta result = TimeDelta::FromMachTime(kArbitraryTicks);

   // With Intel the output should be the input.
   EXPECT_EQ(Nanoseconds(kArbitraryTicks), result);
 }

 TEST(TimeMacTest, MachTimeToMicrosecondsM1Timebase) {
   ScopedTimebase timebase(kM1Timebase);

   // Use a tick count that's divisible by 3.
   const uint64_t kArbitraryTicks = 92738127000;
   TimeDelta result = TimeDelta::FromMachTime(kArbitraryTicks);

   const uint64_t kExpectedResult =
       kArbitraryTicks * kM1Timebase.numer / kM1Timebase.denom;
   EXPECT_EQ(Nanoseconds(kExpectedResult), result);
 }

 // Tests MachTimeToMicroseconds when
 // mach_timebase_info_data_t.numer and mach_timebase_info_data_t.denom
 // are equal.
 TEST(TimeMacTest, MachTimeToMicrosecondsEqualTimebaseMembers) {
   // These members would produce overflow but don't because
   // MachTimeToMicroseconds should skip the timebase conversion
   // when they're equal.
   ScopedTimebase timebase({UINT_MAX, UINT_MAX});

   uint64_t kArbitraryTicks = 175920053729;
   TimeDelta result = TimeDelta::FromMachTime(kArbitraryTicks);

   // With a unity timebase the output should be the input.
   EXPECT_EQ(Nanoseconds(kArbitraryTicks), result);
 }

 TEST(TimeMacTest, MachTimeToMicrosecondsOverflowDetection) {
   const uint32_t kArbitraryNumer = 1234567;
   ScopedTimebase timebase({kArbitraryNumer, 1});

   // Expect an overflow.
   EXPECT_CHECK_DEATH(
       TimeDelta::FromMachTime(std::numeric_limits<uint64_t>::max()));
 }

 // Tests that there's no overflow in MachTimeToMicroseconds even with
 // std::numeric_limits<uint64_t>::max() ticks on Intel.
 TEST(TimeMacTest, MachTimeToMicrosecondsNoOverflowIntel) {
   ScopedTimebase timebase(kIntelTimebase);

   // The incoming Mach time ticks are on the order of nanoseconds while the
   // return result is microseconds. Even though we're passing in the largest
   // tick count the result should be orders of magnitude smaller. On Intel the
   // mapping from ticks to nanoseconds is 1:1 so we wouldn't ever expect an
   // overflow when applying the timebase conversion.
   TimeDelta::FromMachTime(std::numeric_limits<uint64_t>::max());
 }

 // Tests that there's no overflow in MachTimeToMicroseconds even with
 // std::numeric_limits<uint64_t>::max() ticks on M1.
 TEST(TimeMacTest, MachTimeToMicrosecondsNoOverflowM1) {
   ScopedTimebase timebase(kM1Timebase);

   // The incoming Mach time ticks are on the order of nanoseconds while the
   // return result is microseconds. Even though we're passing in the largest
   // tick count the result should be orders of magnitude smaller. Expect that
   // FromMachTime(), when applying the timebase conversion, is smart enough to
   // not multiply first and generate an overflow.
   TimeDelta::FromMachTime(std::numeric_limits<uint64_t>::max());
 }

 // Tests that there's no underflow in MachTimeToMicroseconds on Intel.
 TEST(TimeMacTest, MachTimeToMicrosecondsNoUnderflowIntel) {
   ScopedTimebase timebase(kIntelTimebase);

   // On Intel the timebase conversion is 1:1, so min ticks is one microsecond
   // worth of nanoseconds.
   const uint64_t kMinimumTicks = base::Time::kNanosecondsPerMicrosecond;
   const uint64_t kOneMicrosecond = 1;
   EXPECT_EQ(kOneMicrosecond,
             TimeDelta::FromMachTime(kMinimumTicks).InMicroseconds() * 1UL);

   // If we have even one fewer tick (i.e. not enough ticks to constitute a full
   // microsecond) the integer rounding should result in 0 microseconds.
   const uint64_t kZeroMicroseconds = 0;
   EXPECT_EQ(kZeroMicroseconds,
             TimeDelta::FromMachTime(kMinimumTicks - 1).InMicroseconds() * 1UL);
 }

 // Tests that there's no underflow in MachTimeToMicroseconds for M1.
 TEST(TimeMacTest, MachTimeToMicrosecondsNoUnderflowM1) {
   ScopedTimebase timebase(kM1Timebase);

   // Microseconds is mach_time multiplied by kM1Timebase.numer /
   // (kM1Timebase.denom * base::Time::kNanosecondsPerMicrosecond). Inverting
   // that should be the minimum number of ticks to get a single microsecond in
   // return. If we get zero it means an underflow in the conversion. For example
   // if FromMachTime() first divides mach_time by kM1Timebase.denom *
   // base::Time::kNanosecondsPerMicrosecond we'll get zero back.
   const uint64_t kMinimumTicks =
       (kM1Timebase.denom * base::Time::kNanosecondsPerMicrosecond) /
       kM1Timebase.numer;
   const uint64_t kOneMicrosecond = 1;
   EXPECT_EQ(kOneMicrosecond,
             TimeDelta::FromMachTime(kMinimumTicks).InMicroseconds() * 1UL);

   // If we have even one fewer tick (i.e. not enough ticks to constitute a full
   // microsecond) the integer rounding should result in 0 microseconds.
   const uint64_t kZeroMicroseconds = 0;
   EXPECT_EQ(kZeroMicroseconds,
             TimeDelta::FromMachTime(kMinimumTicks - 1).InMicroseconds() * 1UL);
 }

 }  // namespace
 }  // namespace base
	// Copyright 2021 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "base/time/time.h"

	#include "base/test/gtest_util.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace {

	class ScopedTimebase {
	public:
	explicit ScopedTimebase(mach_timebase_info_data_t timebase) {
	orig_timebase_ = base::TimeTicks::SetMachTimebaseInfoForTesting(timebase);
	}

	ScopedTimebase(const ScopedTimebase&) = delete;

	ScopedTimebase& operator=(const ScopedTimebase&) = delete;

	~ScopedTimebase() {
	base::TimeTicks::SetMachTimebaseInfoForTesting(orig_timebase_);
	}

	private:
	mach_timebase_info_data_t orig_timebase_;
	};

	mach_timebase_info_data_t kIntelTimebase = {1, 1};

	// A sample (not definitive) timebase for M1.
	mach_timebase_info_data_t kM1Timebase = {125, 3};

	} // namespace

	namespace base {
	namespace {

	base::Time NoonOnDate(int year, int month, int day) {
	const base::Time::Exploded exploded = {
	.year = year, .month = month, .day_of_month = day, .hour = 12};
	base::Time imploded;
	CHECK(base::Time::FromUTCExploded(exploded, &imploded));
	return imploded;
	}

	void CheckRoundTrip(int y, int m, int d) {
	base::Time original = NoonOnDate(y, m, d);
	base::Time roundtrip = Time::FromNSDate(original.ToNSDate());
	EXPECT_EQ(original, roundtrip);
	}

	TEST(TimeMacTest, RoundTripNSDate) {
	CheckRoundTrip(1911, 12, 14);
	CheckRoundTrip(1924, 9, 28);
	CheckRoundTrip(1926, 5, 12);
	CheckRoundTrip(1969, 7, 24);
	}

	TEST(TimeMacTest, MachTimeToMicrosecondsIntelTimebase) {
	ScopedTimebase timebase(kIntelTimebase);

	// Perform the conversion.
	uint64_t kArbitraryTicks = 59090101000;
	TimeDelta result = TimeDelta::FromMachTime(kArbitraryTicks);

	// With Intel the output should be the input.
	EXPECT_EQ(Nanoseconds(kArbitraryTicks), result);
	}

	TEST(TimeMacTest, MachTimeToMicrosecondsM1Timebase) {
	ScopedTimebase timebase(kM1Timebase);

	// Use a tick count that's divisible by 3.
	const uint64_t kArbitraryTicks = 92738127000;
	TimeDelta result = TimeDelta::FromMachTime(kArbitraryTicks);

	const uint64_t kExpectedResult =
	kArbitraryTicks * kM1Timebase.numer / kM1Timebase.denom;
	EXPECT_EQ(Nanoseconds(kExpectedResult), result);
	}

	// Tests MachTimeToMicroseconds when
	// mach_timebase_info_data_t.numer and mach_timebase_info_data_t.denom
	// are equal.
	TEST(TimeMacTest, MachTimeToMicrosecondsEqualTimebaseMembers) {
	// These members would produce overflow but don't because
	// MachTimeToMicroseconds should skip the timebase conversion
	// when they're equal.
	ScopedTimebase timebase({UINT_MAX, UINT_MAX});

	uint64_t kArbitraryTicks = 175920053729;
	TimeDelta result = TimeDelta::FromMachTime(kArbitraryTicks);

	// With a unity timebase the output should be the input.
	EXPECT_EQ(Nanoseconds(kArbitraryTicks), result);
	}

	TEST(TimeMacTest, MachTimeToMicrosecondsOverflowDetection) {
	const uint32_t kArbitraryNumer = 1234567;
	ScopedTimebase timebase({kArbitraryNumer, 1});

	// Expect an overflow.
	EXPECT_CHECK_DEATH(
	TimeDelta::FromMachTime(std::numeric_limits<uint64_t>::max()));
	}

	// Tests that there's no overflow in MachTimeToMicroseconds even with
	// std::numeric_limits<uint64_t>::max() ticks on Intel.
	TEST(TimeMacTest, MachTimeToMicrosecondsNoOverflowIntel) {
	ScopedTimebase timebase(kIntelTimebase);

	// The incoming Mach time ticks are on the order of nanoseconds while the
	// return result is microseconds. Even though we're passing in the largest
	// tick count the result should be orders of magnitude smaller. On Intel the
	// mapping from ticks to nanoseconds is 1:1 so we wouldn't ever expect an
	// overflow when applying the timebase conversion.
	TimeDelta::FromMachTime(std::numeric_limits<uint64_t>::max());
	}

	// Tests that there's no overflow in MachTimeToMicroseconds even with
	// std::numeric_limits<uint64_t>::max() ticks on M1.
	TEST(TimeMacTest, MachTimeToMicrosecondsNoOverflowM1) {
	ScopedTimebase timebase(kM1Timebase);

	// The incoming Mach time ticks are on the order of nanoseconds while the
	// return result is microseconds. Even though we're passing in the largest
	// tick count the result should be orders of magnitude smaller. Expect that
	// FromMachTime(), when applying the timebase conversion, is smart enough to
	// not multiply first and generate an overflow.
	TimeDelta::FromMachTime(std::numeric_limits<uint64_t>::max());
	}

	// Tests that there's no underflow in MachTimeToMicroseconds on Intel.
	TEST(TimeMacTest, MachTimeToMicrosecondsNoUnderflowIntel) {
	ScopedTimebase timebase(kIntelTimebase);

	// On Intel the timebase conversion is 1:1, so min ticks is one microsecond
	// worth of nanoseconds.
	const uint64_t kMinimumTicks = base::Time::kNanosecondsPerMicrosecond;
	const uint64_t kOneMicrosecond = 1;
	EXPECT_EQ(kOneMicrosecond,
	TimeDelta::FromMachTime(kMinimumTicks).InMicroseconds() * 1UL);

	// If we have even one fewer tick (i.e. not enough ticks to constitute a full
	// microsecond) the integer rounding should result in 0 microseconds.
	const uint64_t kZeroMicroseconds = 0;
	EXPECT_EQ(kZeroMicroseconds,
	TimeDelta::FromMachTime(kMinimumTicks - 1).InMicroseconds() * 1UL);
	}

	// Tests that there's no underflow in MachTimeToMicroseconds for M1.
	TEST(TimeMacTest, MachTimeToMicrosecondsNoUnderflowM1) {
	ScopedTimebase timebase(kM1Timebase);

	// Microseconds is mach_time multiplied by kM1Timebase.numer /
	// (kM1Timebase.denom * base::Time::kNanosecondsPerMicrosecond). Inverting
	// that should be the minimum number of ticks to get a single microsecond in
	// return. If we get zero it means an underflow in the conversion. For example
	// if FromMachTime() first divides mach_time by kM1Timebase.denom *
	// base::Time::kNanosecondsPerMicrosecond we'll get zero back.
	const uint64_t kMinimumTicks =
	(kM1Timebase.denom * base::Time::kNanosecondsPerMicrosecond) /
	kM1Timebase.numer;
	const uint64_t kOneMicrosecond = 1;
	EXPECT_EQ(kOneMicrosecond,
	TimeDelta::FromMachTime(kMinimumTicks).InMicroseconds() * 1UL);

	// If we have even one fewer tick (i.e. not enough ticks to constitute a full
	// microsecond) the integer rounding should result in 0 microseconds.
	const uint64_t kZeroMicroseconds = 0;
	EXPECT_EQ(kZeroMicroseconds,
	TimeDelta::FromMachTime(kMinimumTicks - 1).InMicroseconds() * 1UL);
	}

	} // namespace
	} // namespace base