rtc_base/timestamp_aligner_unittest.cc - src - Git at Google

 /*
  *  Copyright 2016 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 <math.h>
 #include <algorithm>
 #include <limits>

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

 namespace rtc {

 namespace {
 // Computes the difference x_k - mean(x), when x_k is the linear sequence x_k =
 // k, and the "mean" is plain mean for the first |window_size| samples, followed
 // by exponential averaging with weight 1 / |window_size| for each new sample.
 // This is needed to predict the effect of camera clock drift on the timestamp
 // translation. See the comment on TimestampAligner::UpdateOffset for more
 // context.
 double MeanTimeDifference(int nsamples, int window_size) {
   if (nsamples <= window_size) {
     // Plain averaging.
     return nsamples / 2.0;
   } else {
     // Exponential convergence towards
     // interval_error * (window_size - 1)
     double alpha = 1.0 - 1.0 / window_size;

     return ((window_size - 1) -
             (window_size / 2.0 - 1) * pow(alpha, nsamples - window_size));
   }
 }

 class TimestampAlignerForTest : public TimestampAligner {
   // Make internal methods accessible to testing.
  public:
   using TimestampAligner::UpdateOffset;
   using TimestampAligner::ClipTimestamp;
 };

 void TestTimestampFilter(double rel_freq_error) {
   TimestampAlignerForTest timestamp_aligner_for_test;
   TimestampAligner timestamp_aligner;
   const int64_t kEpoch = 10000;
   const int64_t kJitterUs = 5000;
   const int64_t kIntervalUs = 33333;  // 30 FPS
   const int kWindowSize = 100;
   const int kNumFrames = 3 * kWindowSize;

   int64_t interval_error_us = kIntervalUs * rel_freq_error;
   int64_t system_start_us = rtc::TimeMicros();
   webrtc::Random random(17);

   int64_t prev_translated_time_us = system_start_us;

   for (int i = 0; i < kNumFrames; i++) {
     // Camera time subject to drift.
     int64_t camera_time_us = kEpoch + i * (kIntervalUs + interval_error_us);
     int64_t system_time_us = system_start_us + i * kIntervalUs;
     // And system time readings are subject to jitter.
     int64_t system_measured_us = system_time_us + random.Rand(kJitterUs);

     int64_t offset_us = timestamp_aligner_for_test.UpdateOffset(
         camera_time_us, system_measured_us);

     int64_t filtered_time_us = camera_time_us + offset_us;
     int64_t translated_time_us = timestamp_aligner_for_test.ClipTimestamp(
         filtered_time_us, system_measured_us);

     // Check that we get identical result from the all-in-one helper method.
     ASSERT_EQ(translated_time_us, timestamp_aligner.TranslateTimestamp(
                                       camera_time_us, system_measured_us));

     EXPECT_LE(translated_time_us, system_measured_us);
     EXPECT_GE(translated_time_us,
               prev_translated_time_us + rtc::kNumMicrosecsPerMillisec);

     // The relative frequency error contributes to the expected error
     // by a factor which is the difference between the current time
     // and the average of earlier sample times.
     int64_t expected_error_us =
         kJitterUs / 2 +
         rel_freq_error * kIntervalUs * MeanTimeDifference(i, kWindowSize);

     int64_t bias_us = filtered_time_us - translated_time_us;
     EXPECT_GE(bias_us, 0);

     if (i == 0) {
       EXPECT_EQ(translated_time_us, system_measured_us);
     } else {
       EXPECT_NEAR(filtered_time_us, system_time_us + expected_error_us,
                   2.0 * kJitterUs / sqrt(std::max(i, kWindowSize)));
     }
     // If the camera clock runs too fast (rel_freq_error > 0.0), The
     // bias is expected to roughly cancel the expected error from the
     // clock drift, as this grows. Otherwise, it reflects the
     // measurement noise. The tolerances here were selected after some
     // trial and error.
     if (i < 10 || rel_freq_error <= 0.0) {
       EXPECT_LE(bias_us, 3000);
     } else {
       EXPECT_NEAR(bias_us, expected_error_us, 1500);
     }
     prev_translated_time_us = translated_time_us;
   }
 }

 }  // Anonymous namespace

 TEST(TimestampAlignerTest, AttenuateTimestampJitterNoDrift) {
   TestTimestampFilter(0.0);
 }

 // 100 ppm is a worst case for a reasonable crystal.
 TEST(TimestampAlignerTest, AttenuateTimestampJitterSmallPosDrift) {
   TestTimestampFilter(0.0001);
 }

 TEST(TimestampAlignerTest, AttenuateTimestampJitterSmallNegDrift) {
   TestTimestampFilter(-0.0001);
 }

 // 3000 ppm, 3 ms / s, is the worst observed drift, see
 // https://bugs.chromium.org/p/webrtc/issues/detail?id=5456
 TEST(TimestampAlignerTest, AttenuateTimestampJitterLargePosDrift) {
   TestTimestampFilter(0.003);
 }

 TEST(TimestampAlignerTest, AttenuateTimestampJitterLargeNegDrift) {
   TestTimestampFilter(-0.003);
 }

 // Exhibits a mostly hypothetical problem, where certain inputs to the
 // TimestampAligner.UpdateOffset filter result in non-monotonous
 // translated timestamps. This test verifies that the ClipTimestamp
 // logic handles this case correctly.
 TEST(TimestampAlignerTest, ClipToMonotonous) {
   TimestampAlignerForTest timestamp_aligner;

   // For system time stamps { 0, s1, s1 + s2 }, and camera timestamps
   // {0, c1, c1 + c2}, we exhibit non-monotonous behaviour if and only
   // if c1 > s1 + 2 s2 + 4 c2.
   const int kNumSamples = 3;
   const int64_t camera_time_us[kNumSamples] = {0, 80000, 90001};
   const int64_t system_time_us[kNumSamples] = {0, 10000, 20000};
   const int64_t expected_offset_us[kNumSamples] = {0, -35000, -46667};

   // Non-monotonic translated timestamps can happen when only for
   // translated timestamps in the future. Which is tolerated if
   // |timestamp_aligner.clip_bias_us| is large enough. Instead of
   // changing that private member for this test, just add the bias to
   // |system_time_us| when calling ClipTimestamp.
   const int64_t kClipBiasUs = 100000;

   bool did_clip = false;
   int64_t prev_timestamp_us = std::numeric_limits<int64_t>::min();
   for (int i = 0; i < kNumSamples; i++) {
     int64_t offset_us =
         timestamp_aligner.UpdateOffset(camera_time_us[i], system_time_us[i]);
     EXPECT_EQ(offset_us, expected_offset_us[i]);

     int64_t translated_timestamp_us = camera_time_us[i] + offset_us;
     int64_t clip_timestamp_us = timestamp_aligner.ClipTimestamp(
         translated_timestamp_us, system_time_us[i] + kClipBiasUs);
     if (translated_timestamp_us <= prev_timestamp_us) {
       did_clip = true;
       EXPECT_EQ(clip_timestamp_us,
                 prev_timestamp_us + rtc::kNumMicrosecsPerMillisec);
     } else {
       // No change from clipping.
       EXPECT_EQ(clip_timestamp_us, translated_timestamp_us);
     }
     prev_timestamp_us = clip_timestamp_us;
   }
   EXPECT_TRUE(did_clip);
 }

 }  // namespace rtc
	/*
	* Copyright 2016 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 <math.h>
	#include <algorithm>
	#include <limits>

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

	namespace rtc {

	namespace {
	// Computes the difference x_k - mean(x), when x_k is the linear sequence x_k =
	// k, and the "mean" is plain mean for the first \|window_size\| samples, followed
	// by exponential averaging with weight 1 / \|window_size\| for each new sample.
	// This is needed to predict the effect of camera clock drift on the timestamp
	// translation. See the comment on TimestampAligner::UpdateOffset for more
	// context.
	double MeanTimeDifference(int nsamples, int window_size) {
	if (nsamples <= window_size) {
	// Plain averaging.
	return nsamples / 2.0;
	} else {
	// Exponential convergence towards
	// interval_error * (window_size - 1)
	double alpha = 1.0 - 1.0 / window_size;

	return ((window_size - 1) -
	(window_size / 2.0 - 1) * pow(alpha, nsamples - window_size));
	}
	}

	class TimestampAlignerForTest : public TimestampAligner {
	// Make internal methods accessible to testing.
	public:
	using TimestampAligner::UpdateOffset;
	using TimestampAligner::ClipTimestamp;
	};

	void TestTimestampFilter(double rel_freq_error) {
	TimestampAlignerForTest timestamp_aligner_for_test;
	TimestampAligner timestamp_aligner;
	const int64_t kEpoch = 10000;
	const int64_t kJitterUs = 5000;
	const int64_t kIntervalUs = 33333; // 30 FPS
	const int kWindowSize = 100;
	const int kNumFrames = 3 * kWindowSize;

	int64_t interval_error_us = kIntervalUs * rel_freq_error;
	int64_t system_start_us = rtc::TimeMicros();
	webrtc::Random random(17);

	int64_t prev_translated_time_us = system_start_us;

	for (int i = 0; i < kNumFrames; i++) {
	// Camera time subject to drift.
	int64_t camera_time_us = kEpoch + i * (kIntervalUs + interval_error_us);
	int64_t system_time_us = system_start_us + i * kIntervalUs;
	// And system time readings are subject to jitter.
	int64_t system_measured_us = system_time_us + random.Rand(kJitterUs);

	int64_t offset_us = timestamp_aligner_for_test.UpdateOffset(
	camera_time_us, system_measured_us);

	int64_t filtered_time_us = camera_time_us + offset_us;
	int64_t translated_time_us = timestamp_aligner_for_test.ClipTimestamp(
	filtered_time_us, system_measured_us);

	// Check that we get identical result from the all-in-one helper method.
	ASSERT_EQ(translated_time_us, timestamp_aligner.TranslateTimestamp(
	camera_time_us, system_measured_us));

	EXPECT_LE(translated_time_us, system_measured_us);
	EXPECT_GE(translated_time_us,
	prev_translated_time_us + rtc::kNumMicrosecsPerMillisec);

	// The relative frequency error contributes to the expected error
	// by a factor which is the difference between the current time
	// and the average of earlier sample times.
	int64_t expected_error_us =
	kJitterUs / 2 +
	rel_freq_error * kIntervalUs * MeanTimeDifference(i, kWindowSize);

	int64_t bias_us = filtered_time_us - translated_time_us;
	EXPECT_GE(bias_us, 0);

	if (i == 0) {
	EXPECT_EQ(translated_time_us, system_measured_us);
	} else {
	EXPECT_NEAR(filtered_time_us, system_time_us + expected_error_us,
	2.0 * kJitterUs / sqrt(std::max(i, kWindowSize)));
	}
	// If the camera clock runs too fast (rel_freq_error > 0.0), The
	// bias is expected to roughly cancel the expected error from the
	// clock drift, as this grows. Otherwise, it reflects the
	// measurement noise. The tolerances here were selected after some
	// trial and error.
	if (i < 10 \|\| rel_freq_error <= 0.0) {
	EXPECT_LE(bias_us, 3000);
	} else {
	EXPECT_NEAR(bias_us, expected_error_us, 1500);
	}
	prev_translated_time_us = translated_time_us;
	}
	}

	} // Anonymous namespace

	TEST(TimestampAlignerTest, AttenuateTimestampJitterNoDrift) {
	TestTimestampFilter(0.0);
	}

	// 100 ppm is a worst case for a reasonable crystal.
	TEST(TimestampAlignerTest, AttenuateTimestampJitterSmallPosDrift) {
	TestTimestampFilter(0.0001);
	}

	TEST(TimestampAlignerTest, AttenuateTimestampJitterSmallNegDrift) {
	TestTimestampFilter(-0.0001);
	}

	// 3000 ppm, 3 ms / s, is the worst observed drift, see
	// https://bugs.chromium.org/p/webrtc/issues/detail?id=5456
	TEST(TimestampAlignerTest, AttenuateTimestampJitterLargePosDrift) {
	TestTimestampFilter(0.003);
	}

	TEST(TimestampAlignerTest, AttenuateTimestampJitterLargeNegDrift) {
	TestTimestampFilter(-0.003);
	}

	// Exhibits a mostly hypothetical problem, where certain inputs to the
	// TimestampAligner.UpdateOffset filter result in non-monotonous
	// translated timestamps. This test verifies that the ClipTimestamp
	// logic handles this case correctly.
	TEST(TimestampAlignerTest, ClipToMonotonous) {
	TimestampAlignerForTest timestamp_aligner;

	// For system time stamps { 0, s1, s1 + s2 }, and camera timestamps
	// {0, c1, c1 + c2}, we exhibit non-monotonous behaviour if and only
	// if c1 > s1 + 2 s2 + 4 c2.
	const int kNumSamples = 3;
	const int64_t camera_time_us[kNumSamples] = {0, 80000, 90001};
	const int64_t system_time_us[kNumSamples] = {0, 10000, 20000};
	const int64_t expected_offset_us[kNumSamples] = {0, -35000, -46667};

	// Non-monotonic translated timestamps can happen when only for
	// translated timestamps in the future. Which is tolerated if
	// \|timestamp_aligner.clip_bias_us\| is large enough. Instead of
	// changing that private member for this test, just add the bias to
	// \|system_time_us\| when calling ClipTimestamp.
	const int64_t kClipBiasUs = 100000;

	bool did_clip = false;
	int64_t prev_timestamp_us = std::numeric_limits<int64_t>::min();
	for (int i = 0; i < kNumSamples; i++) {
	int64_t offset_us =
	timestamp_aligner.UpdateOffset(camera_time_us[i], system_time_us[i]);
	EXPECT_EQ(offset_us, expected_offset_us[i]);

	int64_t translated_timestamp_us = camera_time_us[i] + offset_us;
	int64_t clip_timestamp_us = timestamp_aligner.ClipTimestamp(
	translated_timestamp_us, system_time_us[i] + kClipBiasUs);
	if (translated_timestamp_us <= prev_timestamp_us) {
	did_clip = true;
	EXPECT_EQ(clip_timestamp_us,
	prev_timestamp_us + rtc::kNumMicrosecsPerMillisec);
	} else {
	// No change from clipping.
	EXPECT_EQ(clip_timestamp_us, translated_timestamp_us);
	}
	prev_timestamp_us = clip_timestamp_us;
	}
	EXPECT_TRUE(did_clip);
	}

	} // namespace rtc