system_wrappers/source/rtp_to_ntp_estimator_unittest.cc - src/ - Git at Google

 /*
  *  Copyright (c) 2012 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 "system_wrappers/include/rtp_to_ntp_estimator.h"

 #include <stddef.h>

 #include "rtc_base/random.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace {
 constexpr uint64_t kOneMsInNtp = 4294967;
 constexpr uint64_t kOneHourInNtp = uint64_t{60 * 60} << 32;
 constexpr uint32_t kTimestampTicksPerMs = 90;
 }  // namespace

 TEST(WrapAroundTests, OldRtcpWrapped_OldRtpTimestamp) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(kOneMsInNtp), 0),
             RtpToNtpEstimator::kNewMeasurement);
   // No wraparound will be detected, since we are not allowed to wrap below 0,
   // but there will be huge rtp timestamp jump, e.g. old_timestamp = 0,
   // new_timestamp = 4294967295, which should be detected.
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2 * kOneMsInNtp),
                                          -kTimestampTicksPerMs),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(WrapAroundTests, OldRtcpWrapped_OldRtpTimestamp_Wraparound_Detected) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFE),
             RtpToNtpEstimator::kNewMeasurement);
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + 2 * kOneMsInNtp),
                                          0xFFFFFFFE + 2 * kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);
   // Expected to fail since the older RTCP has a smaller RTP timestamp than the
   // newer (old:10, new:4294967206).
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + 3 * kOneMsInNtp),
                                          0xFFFFFFFE + kTimestampTicksPerMs),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(WrapAroundTests, OldRtcpWrapped_OldRtpTimestamp_NegativeWraparound) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0),
             RtpToNtpEstimator::kNewMeasurement);
   // Expected to fail since the older RTCP has a smaller RTP timestamp than the
   // newer (old:0, new:-180).
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + 2 * kOneMsInNtp),
                                          0xFFFFFFFF - 2 * kTimestampTicksPerMs),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(WrapAroundTests, NewRtcpWrapped) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
             RtpToNtpEstimator::kNewMeasurement);
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
                                          0xFFFFFFFF + kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);
   // Since this RTP packet has the same timestamp as the RTCP packet constructed
   // at time 0 it should be mapped to 0 as well.
   EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1));
 }

 TEST(WrapAroundTests, RtpWrapped) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1),
                                          0xFFFFFFFF - 2 * kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
                                          0xFFFFFFFF - kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);

   // Since this RTP packet has the same timestamp as the RTCP packet constructed
   // at time 0 it should be mapped to 0 as well.
   EXPECT_EQ(estimator.Estimate(0xFFFFFFFF - 2 * kTimestampTicksPerMs),
             NtpTime(1));
   // Two kTimestampTicksPerMs advanced.
   EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1 + 2 * kOneMsInNtp));
   // Wrapped rtp.
   EXPECT_EQ(estimator.Estimate(0xFFFFFFFF + kTimestampTicksPerMs),
             NtpTime(1 + 3 * kOneMsInNtp));
 }

 TEST(WrapAroundTests, OldRtp_RtcpsWrapped) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
             RtpToNtpEstimator::kNewMeasurement);
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
                                          0xFFFFFFFF + kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);

   EXPECT_FALSE(estimator.Estimate(0xFFFFFFFF - kTimestampTicksPerMs).Valid());
 }

 TEST(WrapAroundTests, OldRtp_NewRtcpWrapped) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
             RtpToNtpEstimator::kNewMeasurement);
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
                                          0xFFFFFFFF + kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);

   // Constructed at the same time as the first RTCP and should therefore be
   // mapped to zero.
   EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1));
 }

 TEST(WrapAroundTests, GracefullyHandleRtpJump) {
   RtpToNtpEstimator estimator;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
             RtpToNtpEstimator::kNewMeasurement);
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
                                          0xFFFFFFFF + kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);

   // Constructed at the same time as the first RTCP and should therefore be
   // mapped to zero.
   EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1));

   uint32_t timestamp = 0xFFFFFFFF - 0xFFFFF;
   uint64_t ntp_raw = 1 + 2 * kOneMsInNtp;
   for (int i = 0; i < RtpToNtpEstimator::kMaxInvalidSamples - 1; ++i) {
     EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
               RtpToNtpEstimator::kInvalidMeasurement);
     ntp_raw += kOneMsInNtp;
     timestamp += kTimestampTicksPerMs;
   }
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
             RtpToNtpEstimator::kNewMeasurement);
   ntp_raw += kOneMsInNtp;
   timestamp += kTimestampTicksPerMs;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
             RtpToNtpEstimator::kNewMeasurement);

   EXPECT_EQ(estimator.Estimate(timestamp), NtpTime(ntp_raw));
 }

 TEST(UpdateRtcpMeasurementTests, FailsForZeroNtp) {
   RtpToNtpEstimator estimator;

   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(0), 0x12345678),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(UpdateRtcpMeasurementTests, FailsForEqualNtp) {
   RtpToNtpEstimator estimator;
   NtpTime ntp(0, 699925050);
   uint32_t timestamp = 0x12345678;

   EXPECT_EQ(estimator.UpdateMeasurements(ntp, timestamp),
             RtpToNtpEstimator::kNewMeasurement);
   // Ntp time already added, list not updated.
   EXPECT_EQ(estimator.UpdateMeasurements(ntp, timestamp + 1),
             RtpToNtpEstimator::kSameMeasurement);
 }

 TEST(UpdateRtcpMeasurementTests, FailsForOldNtp) {
   RtpToNtpEstimator estimator;
   uint64_t ntp_raw = 699925050;
   NtpTime ntp(ntp_raw);
   uint32_t timestamp = 0x12345678;
   EXPECT_EQ(estimator.UpdateMeasurements(ntp, timestamp),
             RtpToNtpEstimator::kNewMeasurement);

   // Old ntp time, list not updated.
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw - kOneMsInNtp),
                                          timestamp + kTimestampTicksPerMs),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(UpdateRtcpMeasurementTests, FailsForTooNewNtp) {
   RtpToNtpEstimator estimator;

   uint64_t ntp_raw = 699925050;
   uint32_t timestamp = 0x12345678;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
             RtpToNtpEstimator::kNewMeasurement);

   // Ntp time from far future, list not updated.
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw + 2 * kOneHourInNtp),
                                          timestamp + 10 * kTimestampTicksPerMs),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(UpdateRtcpMeasurementTests, FailsForEqualTimestamp) {
   RtpToNtpEstimator estimator;

   uint32_t timestamp = 0x12345678;
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2), timestamp),
             RtpToNtpEstimator::kNewMeasurement);
   // Timestamp already added, list not updated.
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(3), timestamp),
             RtpToNtpEstimator::kSameMeasurement);
 }

 TEST(UpdateRtcpMeasurementTests, FailsForOldRtpTimestamp) {
   RtpToNtpEstimator estimator;
   uint32_t timestamp = 0x12345678;

   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2), timestamp),
             RtpToNtpEstimator::kNewMeasurement);
   // Old timestamp, list not updated.
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2 + kOneMsInNtp),
                                          timestamp - kTimestampTicksPerMs),
             RtpToNtpEstimator::kInvalidMeasurement);
 }

 TEST(UpdateRtcpMeasurementTests, VerifyParameters) {
   RtpToNtpEstimator estimator;
   uint32_t timestamp = 0x12345678;

   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(kOneMsInNtp), timestamp),
             RtpToNtpEstimator::kNewMeasurement);

   EXPECT_DOUBLE_EQ(estimator.EstimatedFrequencyKhz(), 0.0);

   // Add second report, parameters should be calculated.
   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2 * kOneMsInNtp),
                                          timestamp + kTimestampTicksPerMs),
             RtpToNtpEstimator::kNewMeasurement);

   EXPECT_NEAR(estimator.EstimatedFrequencyKhz(), kTimestampTicksPerMs, 0.01);
 }

 TEST(RtpToNtpTests, FailsForNoParameters) {
   RtpToNtpEstimator estimator;
   uint32_t timestamp = 0x12345678;

   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), timestamp),
             RtpToNtpEstimator::kNewMeasurement);
   // Parameters are not calculated, conversion of RTP to NTP time should fail.
   EXPECT_DOUBLE_EQ(estimator.EstimatedFrequencyKhz(), 0.0);
   EXPECT_FALSE(estimator.Estimate(timestamp).Valid());
 }

 TEST(RtpToNtpTests, AveragesErrorOut) {
   RtpToNtpEstimator estimator;
   uint64_t ntp_raw = 90000000;  // More than 1 ms.
   ASSERT_GT(ntp_raw, kOneMsInNtp);
   uint32_t timestamp = 0x12345678;
   constexpr uint64_t kNtpSecStep = uint64_t{1} << 32;  // 1 second.
   constexpr int kRtpTicksPerMs = 90;
   constexpr int kRtpStep = kRtpTicksPerMs * 1000;

   EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
             RtpToNtpEstimator::kNewMeasurement);

   Random rand(1123536L);
   for (size_t i = 0; i < 1000; i++) {
     // Advance both timestamps by exactly 1 second.
     ntp_raw += kNtpSecStep;
     timestamp += kRtpStep;
     // Add upto 1ms of errors to NTP and RTP timestamps passed to estimator.
     EXPECT_EQ(
         estimator.UpdateMeasurements(
             NtpTime(ntp_raw + rand.Rand(-int{kOneMsInNtp}, int{kOneMsInNtp})),
             timestamp + rand.Rand(-kRtpTicksPerMs, kRtpTicksPerMs)),
         RtpToNtpEstimator::kNewMeasurement);

     NtpTime estimated_ntp = estimator.Estimate(timestamp);
     EXPECT_TRUE(estimated_ntp.Valid());
     // Allow upto 2 ms of error.
     EXPECT_NEAR(ntp_raw, static_cast<uint64_t>(estimated_ntp), 2 * kOneMsInNtp);
   }
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2012 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 "system_wrappers/include/rtp_to_ntp_estimator.h"

	#include <stddef.h>

	#include "rtc_base/random.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace {
	constexpr uint64_t kOneMsInNtp = 4294967;
	constexpr uint64_t kOneHourInNtp = uint64_t{60 * 60} << 32;
	constexpr uint32_t kTimestampTicksPerMs = 90;
	} // namespace

	TEST(WrapAroundTests, OldRtcpWrapped_OldRtpTimestamp) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(kOneMsInNtp), 0),
	RtpToNtpEstimator::kNewMeasurement);
	// No wraparound will be detected, since we are not allowed to wrap below 0,
	// but there will be huge rtp timestamp jump, e.g. old_timestamp = 0,
	// new_timestamp = 4294967295, which should be detected.
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2 * kOneMsInNtp),
	-kTimestampTicksPerMs),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(WrapAroundTests, OldRtcpWrapped_OldRtpTimestamp_Wraparound_Detected) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFE),
	RtpToNtpEstimator::kNewMeasurement);
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + 2 * kOneMsInNtp),
	0xFFFFFFFE + 2 * kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);
	// Expected to fail since the older RTCP has a smaller RTP timestamp than the
	// newer (old:10, new:4294967206).
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + 3 * kOneMsInNtp),
	0xFFFFFFFE + kTimestampTicksPerMs),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(WrapAroundTests, OldRtcpWrapped_OldRtpTimestamp_NegativeWraparound) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0),
	RtpToNtpEstimator::kNewMeasurement);
	// Expected to fail since the older RTCP has a smaller RTP timestamp than the
	// newer (old:0, new:-180).
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + 2 * kOneMsInNtp),
	0xFFFFFFFF - 2 * kTimestampTicksPerMs),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(WrapAroundTests, NewRtcpWrapped) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
	RtpToNtpEstimator::kNewMeasurement);
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
	0xFFFFFFFF + kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);
	// Since this RTP packet has the same timestamp as the RTCP packet constructed
	// at time 0 it should be mapped to 0 as well.
	EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1));
	}

	TEST(WrapAroundTests, RtpWrapped) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1),
	0xFFFFFFFF - 2 * kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
	0xFFFFFFFF - kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);

	// Since this RTP packet has the same timestamp as the RTCP packet constructed
	// at time 0 it should be mapped to 0 as well.
	EXPECT_EQ(estimator.Estimate(0xFFFFFFFF - 2 * kTimestampTicksPerMs),
	NtpTime(1));
	// Two kTimestampTicksPerMs advanced.
	EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1 + 2 * kOneMsInNtp));
	// Wrapped rtp.
	EXPECT_EQ(estimator.Estimate(0xFFFFFFFF + kTimestampTicksPerMs),
	NtpTime(1 + 3 * kOneMsInNtp));
	}

	TEST(WrapAroundTests, OldRtp_RtcpsWrapped) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
	RtpToNtpEstimator::kNewMeasurement);
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
	0xFFFFFFFF + kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);

	EXPECT_FALSE(estimator.Estimate(0xFFFFFFFF - kTimestampTicksPerMs).Valid());
	}

	TEST(WrapAroundTests, OldRtp_NewRtcpWrapped) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
	RtpToNtpEstimator::kNewMeasurement);
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
	0xFFFFFFFF + kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);

	// Constructed at the same time as the first RTCP and should therefore be
	// mapped to zero.
	EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1));
	}

	TEST(WrapAroundTests, GracefullyHandleRtpJump) {
	RtpToNtpEstimator estimator;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), 0xFFFFFFFF),
	RtpToNtpEstimator::kNewMeasurement);
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1 + kOneMsInNtp),
	0xFFFFFFFF + kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);

	// Constructed at the same time as the first RTCP and should therefore be
	// mapped to zero.
	EXPECT_EQ(estimator.Estimate(0xFFFFFFFF), NtpTime(1));

	uint32_t timestamp = 0xFFFFFFFF - 0xFFFFF;
	uint64_t ntp_raw = 1 + 2 * kOneMsInNtp;
	for (int i = 0; i < RtpToNtpEstimator::kMaxInvalidSamples - 1; ++i) {
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
	RtpToNtpEstimator::kInvalidMeasurement);
	ntp_raw += kOneMsInNtp;
	timestamp += kTimestampTicksPerMs;
	}
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
	RtpToNtpEstimator::kNewMeasurement);
	ntp_raw += kOneMsInNtp;
	timestamp += kTimestampTicksPerMs;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
	RtpToNtpEstimator::kNewMeasurement);

	EXPECT_EQ(estimator.Estimate(timestamp), NtpTime(ntp_raw));
	}

	TEST(UpdateRtcpMeasurementTests, FailsForZeroNtp) {
	RtpToNtpEstimator estimator;

	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(0), 0x12345678),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(UpdateRtcpMeasurementTests, FailsForEqualNtp) {
	RtpToNtpEstimator estimator;
	NtpTime ntp(0, 699925050);
	uint32_t timestamp = 0x12345678;

	EXPECT_EQ(estimator.UpdateMeasurements(ntp, timestamp),
	RtpToNtpEstimator::kNewMeasurement);
	// Ntp time already added, list not updated.
	EXPECT_EQ(estimator.UpdateMeasurements(ntp, timestamp + 1),
	RtpToNtpEstimator::kSameMeasurement);
	}

	TEST(UpdateRtcpMeasurementTests, FailsForOldNtp) {
	RtpToNtpEstimator estimator;
	uint64_t ntp_raw = 699925050;
	NtpTime ntp(ntp_raw);
	uint32_t timestamp = 0x12345678;
	EXPECT_EQ(estimator.UpdateMeasurements(ntp, timestamp),
	RtpToNtpEstimator::kNewMeasurement);

	// Old ntp time, list not updated.
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw - kOneMsInNtp),
	timestamp + kTimestampTicksPerMs),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(UpdateRtcpMeasurementTests, FailsForTooNewNtp) {
	RtpToNtpEstimator estimator;

	uint64_t ntp_raw = 699925050;
	uint32_t timestamp = 0x12345678;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
	RtpToNtpEstimator::kNewMeasurement);

	// Ntp time from far future, list not updated.
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw + 2 * kOneHourInNtp),
	timestamp + 10 * kTimestampTicksPerMs),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(UpdateRtcpMeasurementTests, FailsForEqualTimestamp) {
	RtpToNtpEstimator estimator;

	uint32_t timestamp = 0x12345678;
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2), timestamp),
	RtpToNtpEstimator::kNewMeasurement);
	// Timestamp already added, list not updated.
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(3), timestamp),
	RtpToNtpEstimator::kSameMeasurement);
	}

	TEST(UpdateRtcpMeasurementTests, FailsForOldRtpTimestamp) {
	RtpToNtpEstimator estimator;
	uint32_t timestamp = 0x12345678;

	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2), timestamp),
	RtpToNtpEstimator::kNewMeasurement);
	// Old timestamp, list not updated.
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2 + kOneMsInNtp),
	timestamp - kTimestampTicksPerMs),
	RtpToNtpEstimator::kInvalidMeasurement);
	}

	TEST(UpdateRtcpMeasurementTests, VerifyParameters) {
	RtpToNtpEstimator estimator;
	uint32_t timestamp = 0x12345678;

	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(kOneMsInNtp), timestamp),
	RtpToNtpEstimator::kNewMeasurement);

	EXPECT_DOUBLE_EQ(estimator.EstimatedFrequencyKhz(), 0.0);

	// Add second report, parameters should be calculated.
	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(2 * kOneMsInNtp),
	timestamp + kTimestampTicksPerMs),
	RtpToNtpEstimator::kNewMeasurement);

	EXPECT_NEAR(estimator.EstimatedFrequencyKhz(), kTimestampTicksPerMs, 0.01);
	}

	TEST(RtpToNtpTests, FailsForNoParameters) {
	RtpToNtpEstimator estimator;
	uint32_t timestamp = 0x12345678;

	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(1), timestamp),
	RtpToNtpEstimator::kNewMeasurement);
	// Parameters are not calculated, conversion of RTP to NTP time should fail.
	EXPECT_DOUBLE_EQ(estimator.EstimatedFrequencyKhz(), 0.0);
	EXPECT_FALSE(estimator.Estimate(timestamp).Valid());
	}

	TEST(RtpToNtpTests, AveragesErrorOut) {
	RtpToNtpEstimator estimator;
	uint64_t ntp_raw = 90000000; // More than 1 ms.
	ASSERT_GT(ntp_raw, kOneMsInNtp);
	uint32_t timestamp = 0x12345678;
	constexpr uint64_t kNtpSecStep = uint64_t{1} << 32; // 1 second.
	constexpr int kRtpTicksPerMs = 90;
	constexpr int kRtpStep = kRtpTicksPerMs * 1000;

	EXPECT_EQ(estimator.UpdateMeasurements(NtpTime(ntp_raw), timestamp),
	RtpToNtpEstimator::kNewMeasurement);

	Random rand(1123536L);
	for (size_t i = 0; i < 1000; i++) {
	// Advance both timestamps by exactly 1 second.
	ntp_raw += kNtpSecStep;
	timestamp += kRtpStep;
	// Add upto 1ms of errors to NTP and RTP timestamps passed to estimator.
	EXPECT_EQ(
	estimator.UpdateMeasurements(
	NtpTime(ntp_raw + rand.Rand(-int{kOneMsInNtp}, int{kOneMsInNtp})),
	timestamp + rand.Rand(-kRtpTicksPerMs, kRtpTicksPerMs)),
	RtpToNtpEstimator::kNewMeasurement);

	NtpTime estimated_ntp = estimator.Estimate(timestamp);
	EXPECT_TRUE(estimated_ntp.Valid());
	// Allow upto 2 ms of error.
	EXPECT_NEAR(ntp_raw, static_cast<uint64_t>(estimated_ntp), 2 * kOneMsInNtp);
	}
	}

	} // namespace webrtc