modules/rtp_rtcp/source/time_util_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2015 The WebRTC 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 in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */
 #include "modules/rtp_rtcp/source/time_util.h"

 #include "rtc_base/fake_clock.h"
 #include "rtc_base/time_utils.h"
 #include "system_wrappers/include/clock.h"
 #include "test/gtest.h"

 namespace webrtc {

 TEST(TimeUtilTest, TimeMicrosToNtpDoesntChangeBetweenRuns) {
   rtc::ScopedFakeClock clock;
   // TimeMicrosToNtp is not pure: it behave differently between different
   // execution of the program, but should behave same during same execution.
   const int64_t time_us = 12345;
   clock.SetTime(Timestamp::Micros(2));
   NtpTime time_ntp = TimeMicrosToNtp(time_us);
   clock.SetTime(Timestamp::Micros(time_us));
   EXPECT_EQ(TimeMicrosToNtp(time_us), time_ntp);
   clock.SetTime(Timestamp::Micros(1000000));
   EXPECT_EQ(TimeMicrosToNtp(time_us), time_ntp);
 }

 TEST(TimeUtilTest, TimeMicrosToNtpKeepsIntervals) {
   rtc::ScopedFakeClock clock;
   NtpTime time_ntp1 = TimeMicrosToNtp(rtc::TimeMicros());
   clock.AdvanceTime(TimeDelta::Millis(20));
   NtpTime time_ntp2 = TimeMicrosToNtp(rtc::TimeMicros());
   EXPECT_EQ(time_ntp2.ToMs() - time_ntp1.ToMs(), 20);
 }

 TEST(TimeUtilTest, CompactNtp) {
   const uint32_t kNtpSec = 0x12345678;
   const uint32_t kNtpFrac = 0x23456789;
   const NtpTime kNtp(kNtpSec, kNtpFrac);
   const uint32_t kNtpMid = 0x56782345;
   EXPECT_EQ(kNtpMid, CompactNtp(kNtp));
 }

 TEST(TimeUtilTest, CompactNtpRttToMs) {
   const NtpTime ntp1(0x12345, 0x23456);
   const NtpTime ntp2(0x12654, 0x64335);
   int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();
   uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);

   int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);

   EXPECT_NEAR(ms_diff, ntp_to_ms_diff, 1);
 }

 TEST(TimeUtilTest, CompactNtpRttToMsWithWrap) {
   const NtpTime ntp1(0x1ffff, 0x23456);
   const NtpTime ntp2(0x20000, 0x64335);
   int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();

   // While ntp2 > ntp1, there compact ntp presentation happen to be opposite.
   // That shouldn't be a problem as long as unsigned arithmetic is used.
   ASSERT_GT(ntp2.ToMs(), ntp1.ToMs());
   ASSERT_LT(CompactNtp(ntp2), CompactNtp(ntp1));

   uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);
   int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);

   EXPECT_NEAR(ms_diff, ntp_to_ms_diff, 1);
 }

 TEST(TimeUtilTest, CompactNtpRttToMsLarge) {
   const NtpTime ntp1(0x10000, 0x00006);
   const NtpTime ntp2(0x17fff, 0xffff5);
   int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();
   // Ntp difference close to 2^15 seconds should convert correctly too.
   ASSERT_NEAR(ms_diff, ((1 << 15) - 1) * 1000, 1);
   uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);
   int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);

   EXPECT_NEAR(ms_diff, ntp_to_ms_diff, 1);
 }

 TEST(TimeUtilTest, CompactNtpRttToMsNegative) {
   const NtpTime ntp1(0x20000, 0x23456);
   const NtpTime ntp2(0x1ffff, 0x64335);
   int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();
   ASSERT_GT(0, ms_diff);
   // Ntp difference close to 2^16 seconds should be treated as negative.
   uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);
   int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);
   EXPECT_EQ(1, ntp_to_ms_diff);
 }

 TEST(TimeUtilTest, SaturatedUsToCompactNtp) {
   // Converts negative to zero.
   EXPECT_EQ(SaturatedUsToCompactNtp(-1), 0u);
   EXPECT_EQ(SaturatedUsToCompactNtp(0), 0u);
   // Converts values just above and just below max uint32_t.
   EXPECT_EQ(SaturatedUsToCompactNtp(65536000000), 0xffffffff);
   EXPECT_EQ(SaturatedUsToCompactNtp(65535999985), 0xffffffff);
   EXPECT_EQ(SaturatedUsToCompactNtp(65535999970), 0xfffffffe);
   // Converts half-seconds.
   EXPECT_EQ(SaturatedUsToCompactNtp(500000), 0x8000u);
   EXPECT_EQ(SaturatedUsToCompactNtp(1000000), 0x10000u);
   EXPECT_EQ(SaturatedUsToCompactNtp(1500000), 0x18000u);
   // Convert us -> compact_ntp -> ms. Compact ntp precision is ~15us.
   EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(1516)), 2);
   EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(15000)), 15);
   EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(5485)), 5);
   EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(5515)), 6);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2015 The WebRTC 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 in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/
	#include "modules/rtp_rtcp/source/time_util.h"

	#include "rtc_base/fake_clock.h"
	#include "rtc_base/time_utils.h"
	#include "system_wrappers/include/clock.h"
	#include "test/gtest.h"

	namespace webrtc {

	TEST(TimeUtilTest, TimeMicrosToNtpDoesntChangeBetweenRuns) {
	rtc::ScopedFakeClock clock;
	// TimeMicrosToNtp is not pure: it behave differently between different
	// execution of the program, but should behave same during same execution.
	const int64_t time_us = 12345;
	clock.SetTime(Timestamp::Micros(2));
	NtpTime time_ntp = TimeMicrosToNtp(time_us);
	clock.SetTime(Timestamp::Micros(time_us));
	EXPECT_EQ(TimeMicrosToNtp(time_us), time_ntp);
	clock.SetTime(Timestamp::Micros(1000000));
	EXPECT_EQ(TimeMicrosToNtp(time_us), time_ntp);
	}

	TEST(TimeUtilTest, TimeMicrosToNtpKeepsIntervals) {
	rtc::ScopedFakeClock clock;
	NtpTime time_ntp1 = TimeMicrosToNtp(rtc::TimeMicros());
	clock.AdvanceTime(TimeDelta::Millis(20));
	NtpTime time_ntp2 = TimeMicrosToNtp(rtc::TimeMicros());
	EXPECT_EQ(time_ntp2.ToMs() - time_ntp1.ToMs(), 20);
	}

	TEST(TimeUtilTest, CompactNtp) {
	const uint32_t kNtpSec = 0x12345678;
	const uint32_t kNtpFrac = 0x23456789;
	const NtpTime kNtp(kNtpSec, kNtpFrac);
	const uint32_t kNtpMid = 0x56782345;
	EXPECT_EQ(kNtpMid, CompactNtp(kNtp));
	}

	TEST(TimeUtilTest, CompactNtpRttToMs) {
	const NtpTime ntp1(0x12345, 0x23456);
	const NtpTime ntp2(0x12654, 0x64335);
	int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();
	uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);

	int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);

	EXPECT_NEAR(ms_diff, ntp_to_ms_diff, 1);
	}

	TEST(TimeUtilTest, CompactNtpRttToMsWithWrap) {
	const NtpTime ntp1(0x1ffff, 0x23456);
	const NtpTime ntp2(0x20000, 0x64335);
	int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();

	// While ntp2 > ntp1, there compact ntp presentation happen to be opposite.
	// That shouldn't be a problem as long as unsigned arithmetic is used.
	ASSERT_GT(ntp2.ToMs(), ntp1.ToMs());
	ASSERT_LT(CompactNtp(ntp2), CompactNtp(ntp1));

	uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);
	int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);

	EXPECT_NEAR(ms_diff, ntp_to_ms_diff, 1);
	}

	TEST(TimeUtilTest, CompactNtpRttToMsLarge) {
	const NtpTime ntp1(0x10000, 0x00006);
	const NtpTime ntp2(0x17fff, 0xffff5);
	int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();
	// Ntp difference close to 2^15 seconds should convert correctly too.
	ASSERT_NEAR(ms_diff, ((1 << 15) - 1) * 1000, 1);
	uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);
	int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);

	EXPECT_NEAR(ms_diff, ntp_to_ms_diff, 1);
	}

	TEST(TimeUtilTest, CompactNtpRttToMsNegative) {
	const NtpTime ntp1(0x20000, 0x23456);
	const NtpTime ntp2(0x1ffff, 0x64335);
	int64_t ms_diff = ntp2.ToMs() - ntp1.ToMs();
	ASSERT_GT(0, ms_diff);
	// Ntp difference close to 2^16 seconds should be treated as negative.
	uint32_t ntp_diff = CompactNtp(ntp2) - CompactNtp(ntp1);
	int64_t ntp_to_ms_diff = CompactNtpRttToMs(ntp_diff);
	EXPECT_EQ(1, ntp_to_ms_diff);
	}

	TEST(TimeUtilTest, SaturatedUsToCompactNtp) {
	// Converts negative to zero.
	EXPECT_EQ(SaturatedUsToCompactNtp(-1), 0u);
	EXPECT_EQ(SaturatedUsToCompactNtp(0), 0u);
	// Converts values just above and just below max uint32_t.
	EXPECT_EQ(SaturatedUsToCompactNtp(65536000000), 0xffffffff);
	EXPECT_EQ(SaturatedUsToCompactNtp(65535999985), 0xffffffff);
	EXPECT_EQ(SaturatedUsToCompactNtp(65535999970), 0xfffffffe);
	// Converts half-seconds.
	EXPECT_EQ(SaturatedUsToCompactNtp(500000), 0x8000u);
	EXPECT_EQ(SaturatedUsToCompactNtp(1000000), 0x10000u);
	EXPECT_EQ(SaturatedUsToCompactNtp(1500000), 0x18000u);
	// Convert us -> compact_ntp -> ms. Compact ntp precision is ~15us.
	EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(1516)), 2);
	EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(15000)), 15);
	EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(5485)), 5);
	EXPECT_EQ(CompactNtpRttToMs(SaturatedUsToCompactNtp(5515)), 6);
	}

	} // namespace webrtc