modules/audio_coding/neteq/delay_manager_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.
  */

 // Unit tests for DelayManager class.

 #include "modules/audio_coding/neteq/delay_manager.h"

 #include <math.h>

 #include <memory>

 #include "absl/types/optional.h"
 #include "modules/audio_coding/neteq/histogram.h"
 #include "modules/audio_coding/neteq/mock/mock_histogram.h"
 #include "modules/audio_coding/neteq/mock/mock_statistics_calculator.h"
 #include "rtc_base/checks.h"
 #include "test/field_trial.h"
 #include "test/gmock.h"
 #include "test/gtest.h"

 namespace webrtc {

 namespace {
 constexpr int kMaxNumberOfPackets = 200;
 constexpr int kTimeStepMs = 10;
 constexpr int kFrameSizeMs = 20;
 constexpr int kMaxBufferSizeMs = kMaxNumberOfPackets * kFrameSizeMs;

 }  // namespace

 class DelayManagerTest : public ::testing::Test {
  protected:
   DelayManagerTest();
   virtual void SetUp();
   void Update(int delay);
   void IncreaseTime(int inc_ms);

   TickTimer tick_timer_;
   DelayManager dm_;
 };

 DelayManagerTest::DelayManagerTest()
     : dm_(DelayManager::Config(), &tick_timer_) {}

 void DelayManagerTest::SetUp() {
   dm_.SetPacketAudioLength(kFrameSizeMs);
 }

 void DelayManagerTest::Update(int delay) {
   dm_.Update(delay, false);
 }

 void DelayManagerTest::IncreaseTime(int inc_ms) {
   for (int t = 0; t < inc_ms; t += kTimeStepMs) {
     tick_timer_.Increment();
   }
 }

 TEST_F(DelayManagerTest, CreateAndDestroy) {
   // Nothing to do here. The test fixture creates and destroys the DelayManager
   // object.
 }

 TEST_F(DelayManagerTest, UpdateNormal) {
   for (int i = 0; i < 50; ++i) {
     Update(0);
     IncreaseTime(kFrameSizeMs);
   }
   EXPECT_EQ(20, dm_.TargetDelayMs());
 }

 TEST_F(DelayManagerTest, MaxDelay) {
   Update(0);
   const int kMaxDelayMs = 60;
   EXPECT_GT(dm_.TargetDelayMs(), kMaxDelayMs);
   EXPECT_TRUE(dm_.SetMaximumDelay(kMaxDelayMs));
   Update(0);
   EXPECT_EQ(kMaxDelayMs, dm_.TargetDelayMs());
 }

 TEST_F(DelayManagerTest, MinDelay) {
   Update(0);
   int kMinDelayMs = 7 * kFrameSizeMs;
   EXPECT_LT(dm_.TargetDelayMs(), kMinDelayMs);
   dm_.SetMinimumDelay(kMinDelayMs);
   IncreaseTime(kFrameSizeMs);
   Update(0);
   EXPECT_EQ(kMinDelayMs, dm_.TargetDelayMs());
 }

 TEST_F(DelayManagerTest, BaseMinimumDelayCheckValidRange) {
   // Base minimum delay should be between [0, 10000] milliseconds.
   EXPECT_FALSE(dm_.SetBaseMinimumDelay(-1));
   EXPECT_FALSE(dm_.SetBaseMinimumDelay(10001));
   EXPECT_EQ(dm_.GetBaseMinimumDelay(), 0);

   EXPECT_TRUE(dm_.SetBaseMinimumDelay(7999));
   EXPECT_EQ(dm_.GetBaseMinimumDelay(), 7999);
 }

 TEST_F(DelayManagerTest, BaseMinimumDelayLowerThanMinimumDelay) {
   constexpr int kBaseMinimumDelayMs = 100;
   constexpr int kMinimumDelayMs = 200;

   // Base minimum delay sets lower bound on minimum. That is why when base
   // minimum delay is lower than minimum delay we use minimum delay.
   RTC_DCHECK_LT(kBaseMinimumDelayMs, kMinimumDelayMs);

   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
   EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMinimumDelayMs);
 }

 TEST_F(DelayManagerTest, BaseMinimumDelayGreaterThanMinimumDelay) {
   constexpr int kBaseMinimumDelayMs = 70;
   constexpr int kMinimumDelayMs = 30;

   // Base minimum delay sets lower bound on minimum. That is why when base
   // minimum delay is greater than minimum delay we use base minimum delay.
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);

   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
   EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kBaseMinimumDelayMs);
 }

 TEST_F(DelayManagerTest, BaseMinimumDelayGreaterThanBufferSize) {
   constexpr int kBaseMinimumDelayMs = kMaxBufferSizeMs + 1;
   constexpr int kMinimumDelayMs = 12;
   constexpr int kMaximumDelayMs = 20;
   constexpr int kMaxBufferSizeMsQ75 = 3 * kMaxBufferSizeMs / 4;

   EXPECT_TRUE(dm_.SetMaximumDelay(kMaximumDelayMs));

   // Base minimum delay is greater than minimum delay, that is why we clamp
   // it to current the highest possible value which is maximum delay.
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMaxBufferSizeMs);
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMaximumDelayMs);
   RTC_DCHECK_LT(kMaximumDelayMs, kMaxBufferSizeMsQ75);

   EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));

   // Unset maximum value.
   EXPECT_TRUE(dm_.SetMaximumDelay(0));

   // With maximum value unset, the highest possible value now is 75% of
   // currently possible maximum buffer size.
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMaxBufferSizeMsQ75);
 }

 TEST_F(DelayManagerTest, BaseMinimumDelayGreaterThanMaximumDelay) {
   constexpr int kMaximumDelayMs = 400;
   constexpr int kBaseMinimumDelayMs = kMaximumDelayMs + 1;
   constexpr int kMinimumDelayMs = 20;

   // Base minimum delay is greater than minimum delay, that is why we clamp
   // it to current the highest possible value which is kMaximumDelayMs.
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMaximumDelayMs);
   RTC_DCHECK_LT(kMaximumDelayMs, kMaxBufferSizeMs);

   EXPECT_TRUE(dm_.SetMaximumDelay(kMaximumDelayMs));
   EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMaximumDelayMs);
 }

 TEST_F(DelayManagerTest, BaseMinimumDelayLowerThanMaxSize) {
   constexpr int kMaximumDelayMs = 400;
   constexpr int kBaseMinimumDelayMs = kMaximumDelayMs - 1;
   constexpr int kMinimumDelayMs = 20;

   // Base minimum delay is greater than minimum delay, and lower than maximum
   // delays that is why it is used.
   RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);
   RTC_DCHECK_LT(kBaseMinimumDelayMs, kMaximumDelayMs);

   EXPECT_TRUE(dm_.SetMaximumDelay(kMaximumDelayMs));
   EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kBaseMinimumDelayMs);
 }

 TEST_F(DelayManagerTest, MinimumDelayMemorization) {
   // Check that when we increase base minimum delay to value higher than
   // minimum delay then minimum delay is still memorized. This allows to
   // restore effective minimum delay to memorized minimum delay value when we
   // decrease base minimum delay.
   constexpr int kBaseMinimumDelayMsLow = 10;
   constexpr int kMinimumDelayMs = 20;
   constexpr int kBaseMinimumDelayMsHigh = 30;

   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMsLow));
   EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
   // Minimum delay is used as it is higher than base minimum delay.
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMinimumDelayMs);

   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMsHigh));
   // Base minimum delay is used as it is now higher than minimum delay.
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kBaseMinimumDelayMsHigh);

   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMsLow));
   // Check that minimum delay is memorized and is used again.
   EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMinimumDelayMs);
 }

 TEST_F(DelayManagerTest, BaseMinimumDelay) {
   // First packet arrival.
   Update(0);

   constexpr int kBaseMinimumDelayMs = 7 * kFrameSizeMs;
   EXPECT_LT(dm_.TargetDelayMs(), kBaseMinimumDelayMs);
   EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
   EXPECT_EQ(dm_.GetBaseMinimumDelay(), kBaseMinimumDelayMs);

   IncreaseTime(kFrameSizeMs);
   Update(0);
   EXPECT_EQ(dm_.GetBaseMinimumDelay(), kBaseMinimumDelayMs);
   EXPECT_EQ(kBaseMinimumDelayMs, dm_.TargetDelayMs());
 }

 TEST_F(DelayManagerTest, Failures) {
   // Wrong packet size.
   EXPECT_EQ(-1, dm_.SetPacketAudioLength(0));
   EXPECT_EQ(-1, dm_.SetPacketAudioLength(-1));

   // Minimum delay higher than a maximum delay is not accepted.
   EXPECT_TRUE(dm_.SetMaximumDelay(20));
   EXPECT_FALSE(dm_.SetMinimumDelay(40));

   // Maximum delay less than minimum delay is not accepted.
   EXPECT_TRUE(dm_.SetMaximumDelay(100));
   EXPECT_TRUE(dm_.SetMinimumDelay(80));
   EXPECT_FALSE(dm_.SetMaximumDelay(60));
 }

 }  // 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.
	*/

	// Unit tests for DelayManager class.

	#include "modules/audio_coding/neteq/delay_manager.h"

	#include <math.h>

	#include <memory>

	#include "absl/types/optional.h"
	#include "modules/audio_coding/neteq/histogram.h"
	#include "modules/audio_coding/neteq/mock/mock_histogram.h"
	#include "modules/audio_coding/neteq/mock/mock_statistics_calculator.h"
	#include "rtc_base/checks.h"
	#include "test/field_trial.h"
	#include "test/gmock.h"
	#include "test/gtest.h"

	namespace webrtc {

	namespace {
	constexpr int kMaxNumberOfPackets = 200;
	constexpr int kTimeStepMs = 10;
	constexpr int kFrameSizeMs = 20;
	constexpr int kMaxBufferSizeMs = kMaxNumberOfPackets * kFrameSizeMs;

	} // namespace

	class DelayManagerTest : public ::testing::Test {
	protected:
	DelayManagerTest();
	virtual void SetUp();
	void Update(int delay);
	void IncreaseTime(int inc_ms);

	TickTimer tick_timer_;
	DelayManager dm_;
	};

	DelayManagerTest::DelayManagerTest()
	: dm_(DelayManager::Config(), &tick_timer_) {}

	void DelayManagerTest::SetUp() {
	dm_.SetPacketAudioLength(kFrameSizeMs);
	}

	void DelayManagerTest::Update(int delay) {
	dm_.Update(delay, false);
	}

	void DelayManagerTest::IncreaseTime(int inc_ms) {
	for (int t = 0; t < inc_ms; t += kTimeStepMs) {
	tick_timer_.Increment();
	}
	}

	TEST_F(DelayManagerTest, CreateAndDestroy) {
	// Nothing to do here. The test fixture creates and destroys the DelayManager
	// object.
	}

	TEST_F(DelayManagerTest, UpdateNormal) {
	for (int i = 0; i < 50; ++i) {
	Update(0);
	IncreaseTime(kFrameSizeMs);
	}
	EXPECT_EQ(20, dm_.TargetDelayMs());
	}

	TEST_F(DelayManagerTest, MaxDelay) {
	Update(0);
	const int kMaxDelayMs = 60;
	EXPECT_GT(dm_.TargetDelayMs(), kMaxDelayMs);
	EXPECT_TRUE(dm_.SetMaximumDelay(kMaxDelayMs));
	Update(0);
	EXPECT_EQ(kMaxDelayMs, dm_.TargetDelayMs());
	}

	TEST_F(DelayManagerTest, MinDelay) {
	Update(0);
	int kMinDelayMs = 7 * kFrameSizeMs;
	EXPECT_LT(dm_.TargetDelayMs(), kMinDelayMs);
	dm_.SetMinimumDelay(kMinDelayMs);
	IncreaseTime(kFrameSizeMs);
	Update(0);
	EXPECT_EQ(kMinDelayMs, dm_.TargetDelayMs());
	}

	TEST_F(DelayManagerTest, BaseMinimumDelayCheckValidRange) {
	// Base minimum delay should be between [0, 10000] milliseconds.
	EXPECT_FALSE(dm_.SetBaseMinimumDelay(-1));
	EXPECT_FALSE(dm_.SetBaseMinimumDelay(10001));
	EXPECT_EQ(dm_.GetBaseMinimumDelay(), 0);

	EXPECT_TRUE(dm_.SetBaseMinimumDelay(7999));
	EXPECT_EQ(dm_.GetBaseMinimumDelay(), 7999);
	}

	TEST_F(DelayManagerTest, BaseMinimumDelayLowerThanMinimumDelay) {
	constexpr int kBaseMinimumDelayMs = 100;
	constexpr int kMinimumDelayMs = 200;

	// Base minimum delay sets lower bound on minimum. That is why when base
	// minimum delay is lower than minimum delay we use minimum delay.
	RTC_DCHECK_LT(kBaseMinimumDelayMs, kMinimumDelayMs);

	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
	EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMinimumDelayMs);
	}

	TEST_F(DelayManagerTest, BaseMinimumDelayGreaterThanMinimumDelay) {
	constexpr int kBaseMinimumDelayMs = 70;
	constexpr int kMinimumDelayMs = 30;

	// Base minimum delay sets lower bound on minimum. That is why when base
	// minimum delay is greater than minimum delay we use base minimum delay.
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);

	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
	EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kBaseMinimumDelayMs);
	}

	TEST_F(DelayManagerTest, BaseMinimumDelayGreaterThanBufferSize) {
	constexpr int kBaseMinimumDelayMs = kMaxBufferSizeMs + 1;
	constexpr int kMinimumDelayMs = 12;
	constexpr int kMaximumDelayMs = 20;
	constexpr int kMaxBufferSizeMsQ75 = 3 * kMaxBufferSizeMs / 4;

	EXPECT_TRUE(dm_.SetMaximumDelay(kMaximumDelayMs));

	// Base minimum delay is greater than minimum delay, that is why we clamp
	// it to current the highest possible value which is maximum delay.
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMaxBufferSizeMs);
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMaximumDelayMs);
	RTC_DCHECK_LT(kMaximumDelayMs, kMaxBufferSizeMsQ75);

	EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));

	// Unset maximum value.
	EXPECT_TRUE(dm_.SetMaximumDelay(0));

	// With maximum value unset, the highest possible value now is 75% of
	// currently possible maximum buffer size.
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMaxBufferSizeMsQ75);
	}

	TEST_F(DelayManagerTest, BaseMinimumDelayGreaterThanMaximumDelay) {
	constexpr int kMaximumDelayMs = 400;
	constexpr int kBaseMinimumDelayMs = kMaximumDelayMs + 1;
	constexpr int kMinimumDelayMs = 20;

	// Base minimum delay is greater than minimum delay, that is why we clamp
	// it to current the highest possible value which is kMaximumDelayMs.
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMaximumDelayMs);
	RTC_DCHECK_LT(kMaximumDelayMs, kMaxBufferSizeMs);

	EXPECT_TRUE(dm_.SetMaximumDelay(kMaximumDelayMs));
	EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMaximumDelayMs);
	}

	TEST_F(DelayManagerTest, BaseMinimumDelayLowerThanMaxSize) {
	constexpr int kMaximumDelayMs = 400;
	constexpr int kBaseMinimumDelayMs = kMaximumDelayMs - 1;
	constexpr int kMinimumDelayMs = 20;

	// Base minimum delay is greater than minimum delay, and lower than maximum
	// delays that is why it is used.
	RTC_DCHECK_GT(kBaseMinimumDelayMs, kMinimumDelayMs);
	RTC_DCHECK_LT(kBaseMinimumDelayMs, kMaximumDelayMs);

	EXPECT_TRUE(dm_.SetMaximumDelay(kMaximumDelayMs));
	EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kBaseMinimumDelayMs);
	}

	TEST_F(DelayManagerTest, MinimumDelayMemorization) {
	// Check that when we increase base minimum delay to value higher than
	// minimum delay then minimum delay is still memorized. This allows to
	// restore effective minimum delay to memorized minimum delay value when we
	// decrease base minimum delay.
	constexpr int kBaseMinimumDelayMsLow = 10;
	constexpr int kMinimumDelayMs = 20;
	constexpr int kBaseMinimumDelayMsHigh = 30;

	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMsLow));
	EXPECT_TRUE(dm_.SetMinimumDelay(kMinimumDelayMs));
	// Minimum delay is used as it is higher than base minimum delay.
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMinimumDelayMs);

	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMsHigh));
	// Base minimum delay is used as it is now higher than minimum delay.
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kBaseMinimumDelayMsHigh);

	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMsLow));
	// Check that minimum delay is memorized and is used again.
	EXPECT_EQ(dm_.effective_minimum_delay_ms_for_test(), kMinimumDelayMs);
	}

	TEST_F(DelayManagerTest, BaseMinimumDelay) {
	// First packet arrival.
	Update(0);

	constexpr int kBaseMinimumDelayMs = 7 * kFrameSizeMs;
	EXPECT_LT(dm_.TargetDelayMs(), kBaseMinimumDelayMs);
	EXPECT_TRUE(dm_.SetBaseMinimumDelay(kBaseMinimumDelayMs));
	EXPECT_EQ(dm_.GetBaseMinimumDelay(), kBaseMinimumDelayMs);

	IncreaseTime(kFrameSizeMs);
	Update(0);
	EXPECT_EQ(dm_.GetBaseMinimumDelay(), kBaseMinimumDelayMs);
	EXPECT_EQ(kBaseMinimumDelayMs, dm_.TargetDelayMs());
	}

	TEST_F(DelayManagerTest, Failures) {
	// Wrong packet size.
	EXPECT_EQ(-1, dm_.SetPacketAudioLength(0));
	EXPECT_EQ(-1, dm_.SetPacketAudioLength(-1));

	// Minimum delay higher than a maximum delay is not accepted.
	EXPECT_TRUE(dm_.SetMaximumDelay(20));
	EXPECT_FALSE(dm_.SetMinimumDelay(40));

	// Maximum delay less than minimum delay is not accepted.
	EXPECT_TRUE(dm_.SetMaximumDelay(100));
	EXPECT_TRUE(dm_.SetMinimumDelay(80));
	EXPECT_FALSE(dm_.SetMaximumDelay(60));
	}

	} // namespace webrtc