modules/audio_processing/agc2/adaptive_digital_gain_applier_unittest.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - 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/adaptive_digital_gain_applier.h"

 #include <algorithm>

 #include "common_audio/include/audio_util.h"
 #include "modules/audio_processing/agc2/agc2_common.h"
 #include "modules/audio_processing/agc2/vector_float_frame.h"
 #include "modules/audio_processing/logging/apm_data_dumper.h"
 #include "rtc_base/gunit.h"

 namespace webrtc {
 namespace {
 // Constants used in place of estimated noise levels.
 constexpr float kNoNoiseDbfs = -90.f;
 constexpr float kWithNoiseDbfs = -20.f;

 // Runs gain applier and returns the applied gain in linear scale.
 float RunOnConstantLevel(int num_iterations,
                          VadWithLevel::LevelAndProbability vad_data,
                          float input_level_dbfs,
                          AdaptiveDigitalGainApplier* gain_applier) {
   float gain_linear = 0.f;

   for (int i = 0; i < num_iterations; ++i) {
     VectorFloatFrame fake_audio(1, 1, 1.f);
     gain_applier->Process(
         input_level_dbfs, kNoNoiseDbfs,
         rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&vad_data, 1),
         fake_audio.float_frame_view());
     gain_linear = fake_audio.float_frame_view().channel(0)[0];
   }
   return gain_linear;
 }

 constexpr VadWithLevel::LevelAndProbability kVadSpeech(1.f, -20.f, 0.f);
 }  // namespace

 TEST(AutomaticGainController2AdaptiveGainApplier, GainApplierShouldNotCrash) {
   static_assert(
       std::is_trivially_destructible<VadWithLevel::LevelAndProbability>::value,
       "");
   ApmDataDumper apm_data_dumper(0);
   AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

   // Make one call with reasonable audio level values and settings.
   VectorFloatFrame fake_audio(2, 480, 10000.f);
   gain_applier.Process(
       -5.0, kNoNoiseDbfs,
       rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
       fake_audio.float_frame_view());
 }

 // Check that the output is -kHeadroom dBFS.
 TEST(AutomaticGainController2AdaptiveGainApplier, TargetLevelIsReached) {
   ApmDataDumper apm_data_dumper(0);
   AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

   constexpr float initial_level_dbfs = -5.f;

   const float applied_gain =
       RunOnConstantLevel(200, kVadSpeech, initial_level_dbfs, &gain_applier);

   EXPECT_NEAR(applied_gain, DbToRatio(-kHeadroomDbfs - initial_level_dbfs),
               0.1f);
 }

 // Check that the output is -kHeadroom dBFS
 TEST(AutomaticGainController2AdaptiveGainApplier, GainApproachesMaxGain) {
   ApmDataDumper apm_data_dumper(0);
   AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

   constexpr float initial_level_dbfs = -kHeadroomDbfs - kMaxGainDb - 10.f;
   // A few extra frames for safety.
   constexpr int kNumFramesToAdapt =
       static_cast<int>(kMaxGainDb / kMaxGainChangePerFrameDb) + 10;

   const float applied_gain = RunOnConstantLevel(
       kNumFramesToAdapt, kVadSpeech, initial_level_dbfs, &gain_applier);
   EXPECT_NEAR(applied_gain, DbToRatio(kMaxGainDb), 0.1f);

   const float applied_gain_db = 20.f * std::log10(applied_gain);
   EXPECT_NEAR(applied_gain_db, kMaxGainDb, 0.1f);
 }

 TEST(AutomaticGainController2AdaptiveGainApplier, GainDoesNotChangeFast) {
   ApmDataDumper apm_data_dumper(0);
   AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

   constexpr float initial_level_dbfs = -25.f;
   // A few extra frames for safety.
   constexpr int kNumFramesToAdapt =
       static_cast<int>(initial_level_dbfs / kMaxGainChangePerFrameDb) + 10;

   const float kMaxChangePerFrameLinear = DbToRatio(kMaxGainChangePerFrameDb);

   float last_gain_linear = 1.f;
   for (int i = 0; i < kNumFramesToAdapt; ++i) {
     SCOPED_TRACE(i);
     VectorFloatFrame fake_audio(1, 1, 1.f);
     gain_applier.Process(
         initial_level_dbfs, kNoNoiseDbfs,
         rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
         fake_audio.float_frame_view());
     float current_gain_linear = fake_audio.float_frame_view().channel(0)[0];
     EXPECT_LE(std::abs(current_gain_linear - last_gain_linear),
               kMaxChangePerFrameLinear);
     last_gain_linear = current_gain_linear;
   }

   // Check that the same is true when gain decreases as well.
   for (int i = 0; i < kNumFramesToAdapt; ++i) {
     SCOPED_TRACE(i);
     VectorFloatFrame fake_audio(1, 1, 1.f);
     gain_applier.Process(
         0.f, kNoNoiseDbfs,
         rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
         fake_audio.float_frame_view());
     float current_gain_linear = fake_audio.float_frame_view().channel(0)[0];
     EXPECT_LE(std::abs(current_gain_linear - last_gain_linear),
               kMaxChangePerFrameLinear);
     last_gain_linear = current_gain_linear;
   }
 }

 TEST(AutomaticGainController2AdaptiveGainApplier, GainIsRampedInAFrame) {
   ApmDataDumper apm_data_dumper(0);
   AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

   constexpr float initial_level_dbfs = -25.f;
   constexpr int num_samples = 480;

   VectorFloatFrame fake_audio(1, num_samples, 1.f);
   gain_applier.Process(
       initial_level_dbfs, kNoNoiseDbfs,
       rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
       fake_audio.float_frame_view());
   float maximal_difference = 0.f;
   float current_value = 1.f * DbToRatio(kInitialAdaptiveDigitalGainDb);
   for (const auto& x : fake_audio.float_frame_view().channel(0)) {
     const float difference = std::abs(x - current_value);
     maximal_difference = std::max(maximal_difference, difference);
     current_value = x;
   }

   const float kMaxChangePerFrameLinear = DbToRatio(kMaxGainChangePerFrameDb);
   const float kMaxChangePerSample = kMaxChangePerFrameLinear / num_samples;

   EXPECT_LE(maximal_difference, kMaxChangePerSample);
 }

 TEST(AutomaticGainController2AdaptiveGainApplier, NoiseLimitsGain) {
   ApmDataDumper apm_data_dumper(0);
   AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

   constexpr float initial_level_dbfs = -25.f;
   constexpr int num_samples = 480;
   constexpr int num_initial_frames =
       kInitialAdaptiveDigitalGainDb / kMaxGainChangePerFrameDb;
   constexpr int num_frames = 50;

   ASSERT_GT(kWithNoiseDbfs, kMaxNoiseLevelDbfs) << "kWithNoiseDbfs is too low";

   for (int i = 0; i < num_initial_frames + num_frames; ++i) {
     VectorFloatFrame fake_audio(1, num_samples, 1.f);
     gain_applier.Process(
         initial_level_dbfs, kWithNoiseDbfs,
         rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
         fake_audio.float_frame_view());

     // Wait so that the adaptive gain applier has time to lower the gain.
     if (i > num_initial_frames) {
       const float maximal_ratio =
           *std::max_element(fake_audio.float_frame_view().channel(0).begin(),
                             fake_audio.float_frame_view().channel(0).end());

       EXPECT_NEAR(maximal_ratio, 1.f, 0.001f);
     }
   }
 }
 }  // 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/adaptive_digital_gain_applier.h"

	#include <algorithm>

	#include "common_audio/include/audio_util.h"
	#include "modules/audio_processing/agc2/agc2_common.h"
	#include "modules/audio_processing/agc2/vector_float_frame.h"
	#include "modules/audio_processing/logging/apm_data_dumper.h"
	#include "rtc_base/gunit.h"

	namespace webrtc {
	namespace {
	// Constants used in place of estimated noise levels.
	constexpr float kNoNoiseDbfs = -90.f;
	constexpr float kWithNoiseDbfs = -20.f;

	// Runs gain applier and returns the applied gain in linear scale.
	float RunOnConstantLevel(int num_iterations,
	VadWithLevel::LevelAndProbability vad_data,
	float input_level_dbfs,
	AdaptiveDigitalGainApplier* gain_applier) {
	float gain_linear = 0.f;

	for (int i = 0; i < num_iterations; ++i) {
	VectorFloatFrame fake_audio(1, 1, 1.f);
	gain_applier->Process(
	input_level_dbfs, kNoNoiseDbfs,
	rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&vad_data, 1),
	fake_audio.float_frame_view());
	gain_linear = fake_audio.float_frame_view().channel(0)[0];
	}
	return gain_linear;
	}

	constexpr VadWithLevel::LevelAndProbability kVadSpeech(1.f, -20.f, 0.f);
	} // namespace

	TEST(AutomaticGainController2AdaptiveGainApplier, GainApplierShouldNotCrash) {
	static_assert(
	std::is_trivially_destructible<VadWithLevel::LevelAndProbability>::value,
	"");
	ApmDataDumper apm_data_dumper(0);
	AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

	// Make one call with reasonable audio level values and settings.
	VectorFloatFrame fake_audio(2, 480, 10000.f);
	gain_applier.Process(
	-5.0, kNoNoiseDbfs,
	rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
	fake_audio.float_frame_view());
	}

	// Check that the output is -kHeadroom dBFS.
	TEST(AutomaticGainController2AdaptiveGainApplier, TargetLevelIsReached) {
	ApmDataDumper apm_data_dumper(0);
	AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

	constexpr float initial_level_dbfs = -5.f;

	const float applied_gain =
	RunOnConstantLevel(200, kVadSpeech, initial_level_dbfs, &gain_applier);

	EXPECT_NEAR(applied_gain, DbToRatio(-kHeadroomDbfs - initial_level_dbfs),
	0.1f);
	}

	// Check that the output is -kHeadroom dBFS
	TEST(AutomaticGainController2AdaptiveGainApplier, GainApproachesMaxGain) {
	ApmDataDumper apm_data_dumper(0);
	AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

	constexpr float initial_level_dbfs = -kHeadroomDbfs - kMaxGainDb - 10.f;
	// A few extra frames for safety.
	constexpr int kNumFramesToAdapt =
	static_cast<int>(kMaxGainDb / kMaxGainChangePerFrameDb) + 10;

	const float applied_gain = RunOnConstantLevel(
	kNumFramesToAdapt, kVadSpeech, initial_level_dbfs, &gain_applier);
	EXPECT_NEAR(applied_gain, DbToRatio(kMaxGainDb), 0.1f);

	const float applied_gain_db = 20.f * std::log10(applied_gain);
	EXPECT_NEAR(applied_gain_db, kMaxGainDb, 0.1f);
	}

	TEST(AutomaticGainController2AdaptiveGainApplier, GainDoesNotChangeFast) {
	ApmDataDumper apm_data_dumper(0);
	AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

	constexpr float initial_level_dbfs = -25.f;
	// A few extra frames for safety.
	constexpr int kNumFramesToAdapt =
	static_cast<int>(initial_level_dbfs / kMaxGainChangePerFrameDb) + 10;

	const float kMaxChangePerFrameLinear = DbToRatio(kMaxGainChangePerFrameDb);

	float last_gain_linear = 1.f;
	for (int i = 0; i < kNumFramesToAdapt; ++i) {
	SCOPED_TRACE(i);
	VectorFloatFrame fake_audio(1, 1, 1.f);
	gain_applier.Process(
	initial_level_dbfs, kNoNoiseDbfs,
	rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
	fake_audio.float_frame_view());
	float current_gain_linear = fake_audio.float_frame_view().channel(0)[0];
	EXPECT_LE(std::abs(current_gain_linear - last_gain_linear),
	kMaxChangePerFrameLinear);
	last_gain_linear = current_gain_linear;
	}

	// Check that the same is true when gain decreases as well.
	for (int i = 0; i < kNumFramesToAdapt; ++i) {
	SCOPED_TRACE(i);
	VectorFloatFrame fake_audio(1, 1, 1.f);
	gain_applier.Process(
	0.f, kNoNoiseDbfs,
	rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
	fake_audio.float_frame_view());
	float current_gain_linear = fake_audio.float_frame_view().channel(0)[0];
	EXPECT_LE(std::abs(current_gain_linear - last_gain_linear),
	kMaxChangePerFrameLinear);
	last_gain_linear = current_gain_linear;
	}
	}

	TEST(AutomaticGainController2AdaptiveGainApplier, GainIsRampedInAFrame) {
	ApmDataDumper apm_data_dumper(0);
	AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

	constexpr float initial_level_dbfs = -25.f;
	constexpr int num_samples = 480;

	VectorFloatFrame fake_audio(1, num_samples, 1.f);
	gain_applier.Process(
	initial_level_dbfs, kNoNoiseDbfs,
	rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
	fake_audio.float_frame_view());
	float maximal_difference = 0.f;
	float current_value = 1.f * DbToRatio(kInitialAdaptiveDigitalGainDb);
	for (const auto& x : fake_audio.float_frame_view().channel(0)) {
	const float difference = std::abs(x - current_value);
	maximal_difference = std::max(maximal_difference, difference);
	current_value = x;
	}

	const float kMaxChangePerFrameLinear = DbToRatio(kMaxGainChangePerFrameDb);
	const float kMaxChangePerSample = kMaxChangePerFrameLinear / num_samples;

	EXPECT_LE(maximal_difference, kMaxChangePerSample);
	}

	TEST(AutomaticGainController2AdaptiveGainApplier, NoiseLimitsGain) {
	ApmDataDumper apm_data_dumper(0);
	AdaptiveDigitalGainApplier gain_applier(&apm_data_dumper);

	constexpr float initial_level_dbfs = -25.f;
	constexpr int num_samples = 480;
	constexpr int num_initial_frames =
	kInitialAdaptiveDigitalGainDb / kMaxGainChangePerFrameDb;
	constexpr int num_frames = 50;

	ASSERT_GT(kWithNoiseDbfs, kMaxNoiseLevelDbfs) << "kWithNoiseDbfs is too low";

	for (int i = 0; i < num_initial_frames + num_frames; ++i) {
	VectorFloatFrame fake_audio(1, num_samples, 1.f);
	gain_applier.Process(
	initial_level_dbfs, kWithNoiseDbfs,
	rtc::ArrayView<const VadWithLevel::LevelAndProbability>(&kVadSpeech, 1),
	fake_audio.float_frame_view());

	// Wait so that the adaptive gain applier has time to lower the gain.
	if (i > num_initial_frames) {
	const float maximal_ratio =
	*std::max_element(fake_audio.float_frame_view().channel(0).begin(),
	fake_audio.float_frame_view().channel(0).end());

	EXPECT_NEAR(maximal_ratio, 1.f, 0.001f);
	}
	}
	}
	} // namespace webrtc