modules/audio_processing/agc2/saturation_protector_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2018 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/audio_processing/agc2/saturation_protector.h"

 #include <algorithm>

 #include "modules/audio_processing/agc2/agc2_common.h"
 #include "modules/audio_processing/logging/apm_data_dumper.h"
 #include "rtc_base/gunit.h"
 #include "test/gmock.h"

 namespace webrtc {
 namespace {

 constexpr float kInitialMarginDb = 20.f;

 using saturation_protector_impl::RingBuffer;

 SaturationProtectorState CreateSaturationProtectorState() {
   SaturationProtectorState state;
   ResetSaturationProtectorState(kInitialMarginDb, state);
   return state;
 }

 // Updates `state` for `num_iterations` times with constant speech level and
 // peak powers and returns the maximum margin.
 float RunOnConstantLevel(int num_iterations,
                          float speech_peak_dbfs,
                          float speech_level_dbfs,
                          SaturationProtectorState& state) {
   float last_margin = state.margin_db;
   float max_difference = 0.f;
   for (int i = 0; i < num_iterations; ++i) {
     UpdateSaturationProtectorState(speech_peak_dbfs, speech_level_dbfs, state);
     const float new_margin = state.margin_db;
     max_difference =
         std::max(max_difference, std::abs(new_margin - last_margin));
     last_margin = new_margin;
   }
   return max_difference;
 }

 }  // namespace

 TEST(AutomaticGainController2SaturationProtector, RingBufferInit) {
   RingBuffer b;
   EXPECT_EQ(b.Size(), 0);
   EXPECT_FALSE(b.Front().has_value());
 }

 TEST(AutomaticGainController2SaturationProtector, RingBufferPushBack) {
   RingBuffer b;
   constexpr float kValue = 123.f;
   b.PushBack(kValue);
   EXPECT_EQ(b.Size(), 1);
   ASSERT_TRUE(b.Front().has_value());
   EXPECT_EQ(b.Front().value(), kValue);
 }

 TEST(AutomaticGainController2SaturationProtector, RingBufferReset) {
   RingBuffer b;
   b.PushBack(123.f);
   b.Reset();
   EXPECT_EQ(b.Size(), 0);
   EXPECT_FALSE(b.Front().has_value());
 }

 // Checks that the front value does not change until the ring buffer gets full.
 TEST(AutomaticGainController2SaturationProtector,
      RingBufferFrontUntilBufferIsFull) {
   RingBuffer b;
   constexpr float kValue = 123.f;
   b.PushBack(kValue);
   for (int i = 1; i < b.Capacity(); ++i) {
     EXPECT_EQ(b.Front().value(), kValue);
     b.PushBack(kValue + i);
   }
 }

 // Checks that when the buffer is full it behaves as a shift register.
 TEST(AutomaticGainController2SaturationProtector,
      FullRingBufferFrontIsDelayed) {
   RingBuffer b;
   // Fill the buffer.
   for (int i = 0; i < b.Capacity(); ++i) {
     b.PushBack(i);
   }
   // The ring buffer should now behave as a shift register with a delay equal to
   // its capacity.
   for (int i = b.Capacity(); i < 2 * b.Capacity() + 1; ++i) {
     EXPECT_EQ(b.Front().value(), i - b.Capacity());
     b.PushBack(i);
   }
 }

 // Checks that a state after reset equals a state after construction.
 TEST(AutomaticGainController2SaturationProtector, ResetState) {
   SaturationProtectorState init_state;
   ResetSaturationProtectorState(kInitialMarginDb, init_state);

   SaturationProtectorState state;
   ResetSaturationProtectorState(kInitialMarginDb, state);
   RunOnConstantLevel(/*num_iterations=*/10, /*speech_level_dbfs=*/-20.f,
                      /*speech_peak_dbfs=*/-10.f, state);
   ASSERT_NE(init_state, state);  // Make sure that there are side-effects.
   ResetSaturationProtectorState(kInitialMarginDb, state);

   EXPECT_EQ(init_state, state);
 }

 // Checks that the estimate converges to the ratio between peaks and level
 // estimator values after a while.
 TEST(AutomaticGainController2SaturationProtector,
      ProtectorEstimatesCrestRatio) {
   constexpr int kNumIterations = 2000;
   constexpr float kPeakLevel = -20.f;
   constexpr float kCrestFactor = kInitialMarginDb + 1.f;
   constexpr float kSpeechLevel = kPeakLevel - kCrestFactor;
   const float kMaxDifference = 0.5f * std::abs(kInitialMarginDb - kCrestFactor);

   auto state = CreateSaturationProtectorState();
   RunOnConstantLevel(kNumIterations, kPeakLevel, kSpeechLevel, state);

   EXPECT_NEAR(state.margin_db, kCrestFactor, kMaxDifference);
 }

 // Checks that the margin does not change too quickly.
 TEST(AutomaticGainController2SaturationProtector, ChangeSlowly) {
   constexpr int kNumIterations = 1000;
   constexpr float kPeakLevel = -20.f;
   constexpr float kCrestFactor = kInitialMarginDb - 5.f;
   constexpr float kOtherCrestFactor = kInitialMarginDb;
   constexpr float kSpeechLevel = kPeakLevel - kCrestFactor;
   constexpr float kOtherSpeechLevel = kPeakLevel - kOtherCrestFactor;

   auto state = CreateSaturationProtectorState();
   float max_difference =
       RunOnConstantLevel(kNumIterations, kPeakLevel, kSpeechLevel, state);
   max_difference = std::max(
       RunOnConstantLevel(kNumIterations, kPeakLevel, kOtherSpeechLevel, state),
       max_difference);

   constexpr float kMaxChangeSpeedDbPerSecond = 0.5f;  // 1 db / 2 seconds.
   EXPECT_LE(max_difference,
             kMaxChangeSpeedDbPerSecond / 1000 * kFrameDurationMs);
 }

 // Checks that there is a delay between input change and margin adaptations.
 TEST(AutomaticGainController2SaturationProtector, AdaptToDelayedChanges) {
   constexpr int kDelayIterations = kFullBufferSizeMs / kFrameDurationMs;
   constexpr float kInitialSpeechLevelDbfs = -30.f;
   constexpr float kLaterSpeechLevelDbfs = -15.f;

   auto state = CreateSaturationProtectorState();
   // First run on initial level.
   float max_difference = RunOnConstantLevel(
       kDelayIterations, kInitialSpeechLevelDbfs + kInitialMarginDb,
       kInitialSpeechLevelDbfs, state);
   // Then peak changes, but not RMS.
   max_difference =
       std::max(RunOnConstantLevel(kDelayIterations,
                                   kLaterSpeechLevelDbfs + kInitialMarginDb,
                                   kInitialSpeechLevelDbfs, state),
                max_difference);
   // Then both change.
   max_difference =
       std::max(RunOnConstantLevel(kDelayIterations,
                                   kLaterSpeechLevelDbfs + kInitialMarginDb,
                                   kLaterSpeechLevelDbfs, state),
                max_difference);

   // The saturation protector expects that the RMS changes roughly
   // 'kFullBufferSizeMs' after peaks change. This is to account for delay
   // introduced by the level estimator. Therefore, the input above is 'normal'
   // and 'expected', and shouldn't influence the margin by much.
   const float total_difference = std::abs(state.margin_db - kInitialMarginDb);

   EXPECT_LE(total_difference, 0.05f);
   EXPECT_LE(max_difference, 0.01f);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2018 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/audio_processing/agc2/saturation_protector.h"

	#include <algorithm>

	#include "modules/audio_processing/agc2/agc2_common.h"
	#include "modules/audio_processing/logging/apm_data_dumper.h"
	#include "rtc_base/gunit.h"
	#include "test/gmock.h"

	namespace webrtc {
	namespace {

	constexpr float kInitialMarginDb = 20.f;

	using saturation_protector_impl::RingBuffer;

	SaturationProtectorState CreateSaturationProtectorState() {
	SaturationProtectorState state;
	ResetSaturationProtectorState(kInitialMarginDb, state);
	return state;
	}

	// Updates `state` for `num_iterations` times with constant speech level and
	// peak powers and returns the maximum margin.
	float RunOnConstantLevel(int num_iterations,
	float speech_peak_dbfs,
	float speech_level_dbfs,
	SaturationProtectorState& state) {
	float last_margin = state.margin_db;
	float max_difference = 0.f;
	for (int i = 0; i < num_iterations; ++i) {
	UpdateSaturationProtectorState(speech_peak_dbfs, speech_level_dbfs, state);
	const float new_margin = state.margin_db;
	max_difference =
	std::max(max_difference, std::abs(new_margin - last_margin));
	last_margin = new_margin;
	}
	return max_difference;
	}

	} // namespace

	TEST(AutomaticGainController2SaturationProtector, RingBufferInit) {
	RingBuffer b;
	EXPECT_EQ(b.Size(), 0);
	EXPECT_FALSE(b.Front().has_value());
	}

	TEST(AutomaticGainController2SaturationProtector, RingBufferPushBack) {
	RingBuffer b;
	constexpr float kValue = 123.f;
	b.PushBack(kValue);
	EXPECT_EQ(b.Size(), 1);
	ASSERT_TRUE(b.Front().has_value());
	EXPECT_EQ(b.Front().value(), kValue);
	}

	TEST(AutomaticGainController2SaturationProtector, RingBufferReset) {
	RingBuffer b;
	b.PushBack(123.f);
	b.Reset();
	EXPECT_EQ(b.Size(), 0);
	EXPECT_FALSE(b.Front().has_value());
	}

	// Checks that the front value does not change until the ring buffer gets full.
	TEST(AutomaticGainController2SaturationProtector,
	RingBufferFrontUntilBufferIsFull) {
	RingBuffer b;
	constexpr float kValue = 123.f;
	b.PushBack(kValue);
	for (int i = 1; i < b.Capacity(); ++i) {
	EXPECT_EQ(b.Front().value(), kValue);
	b.PushBack(kValue + i);
	}
	}

	// Checks that when the buffer is full it behaves as a shift register.
	TEST(AutomaticGainController2SaturationProtector,
	FullRingBufferFrontIsDelayed) {
	RingBuffer b;
	// Fill the buffer.
	for (int i = 0; i < b.Capacity(); ++i) {
	b.PushBack(i);
	}
	// The ring buffer should now behave as a shift register with a delay equal to
	// its capacity.
	for (int i = b.Capacity(); i < 2 * b.Capacity() + 1; ++i) {
	EXPECT_EQ(b.Front().value(), i - b.Capacity());
	b.PushBack(i);
	}
	}

	// Checks that a state after reset equals a state after construction.
	TEST(AutomaticGainController2SaturationProtector, ResetState) {
	SaturationProtectorState init_state;
	ResetSaturationProtectorState(kInitialMarginDb, init_state);

	SaturationProtectorState state;
	ResetSaturationProtectorState(kInitialMarginDb, state);
	RunOnConstantLevel(/num_iterations=/10, /speech_level_dbfs=/-20.f,
	/speech_peak_dbfs=/-10.f, state);
	ASSERT_NE(init_state, state); // Make sure that there are side-effects.
	ResetSaturationProtectorState(kInitialMarginDb, state);

	EXPECT_EQ(init_state, state);
	}

	// Checks that the estimate converges to the ratio between peaks and level
	// estimator values after a while.
	TEST(AutomaticGainController2SaturationProtector,
	ProtectorEstimatesCrestRatio) {
	constexpr int kNumIterations = 2000;
	constexpr float kPeakLevel = -20.f;
	constexpr float kCrestFactor = kInitialMarginDb + 1.f;
	constexpr float kSpeechLevel = kPeakLevel - kCrestFactor;
	const float kMaxDifference = 0.5f * std::abs(kInitialMarginDb - kCrestFactor);

	auto state = CreateSaturationProtectorState();
	RunOnConstantLevel(kNumIterations, kPeakLevel, kSpeechLevel, state);

	EXPECT_NEAR(state.margin_db, kCrestFactor, kMaxDifference);
	}

	// Checks that the margin does not change too quickly.
	TEST(AutomaticGainController2SaturationProtector, ChangeSlowly) {
	constexpr int kNumIterations = 1000;
	constexpr float kPeakLevel = -20.f;
	constexpr float kCrestFactor = kInitialMarginDb - 5.f;
	constexpr float kOtherCrestFactor = kInitialMarginDb;
	constexpr float kSpeechLevel = kPeakLevel - kCrestFactor;
	constexpr float kOtherSpeechLevel = kPeakLevel - kOtherCrestFactor;

	auto state = CreateSaturationProtectorState();
	float max_difference =
	RunOnConstantLevel(kNumIterations, kPeakLevel, kSpeechLevel, state);
	max_difference = std::max(
	RunOnConstantLevel(kNumIterations, kPeakLevel, kOtherSpeechLevel, state),
	max_difference);

	constexpr float kMaxChangeSpeedDbPerSecond = 0.5f; // 1 db / 2 seconds.
	EXPECT_LE(max_difference,
	kMaxChangeSpeedDbPerSecond / 1000 * kFrameDurationMs);
	}

	// Checks that there is a delay between input change and margin adaptations.
	TEST(AutomaticGainController2SaturationProtector, AdaptToDelayedChanges) {
	constexpr int kDelayIterations = kFullBufferSizeMs / kFrameDurationMs;
	constexpr float kInitialSpeechLevelDbfs = -30.f;
	constexpr float kLaterSpeechLevelDbfs = -15.f;

	auto state = CreateSaturationProtectorState();
	// First run on initial level.
	float max_difference = RunOnConstantLevel(
	kDelayIterations, kInitialSpeechLevelDbfs + kInitialMarginDb,
	kInitialSpeechLevelDbfs, state);
	// Then peak changes, but not RMS.
	max_difference =
	std::max(RunOnConstantLevel(kDelayIterations,
	kLaterSpeechLevelDbfs + kInitialMarginDb,
	kInitialSpeechLevelDbfs, state),
	max_difference);
	// Then both change.
	max_difference =
	std::max(RunOnConstantLevel(kDelayIterations,
	kLaterSpeechLevelDbfs + kInitialMarginDb,
	kLaterSpeechLevelDbfs, state),
	max_difference);

	// The saturation protector expects that the RMS changes roughly
	// 'kFullBufferSizeMs' after peaks change. This is to account for delay
	// introduced by the level estimator. Therefore, the input above is 'normal'
	// and 'expected', and shouldn't influence the margin by much.
	const float total_difference = std::abs(state.margin_db - kInitialMarginDb);

	EXPECT_LE(total_difference, 0.05f);
	EXPECT_LE(max_difference, 0.01f);
	}

	} // namespace webrtc