modules/audio_processing/agc2/fixed_gain_controller_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/fixed_gain_controller.h"

 #include "absl/memory/memory.h"
 #include "api/array_view.h"
 #include "modules/audio_processing/agc2/agc2_testing_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"
 #include "system_wrappers/include/metrics.h"

 namespace webrtc {
 namespace {

 constexpr float kInputLevelLinear = 15000.f;

 constexpr float kGainToApplyDb = 15.f;

 float RunFixedGainControllerWithConstantInput(FixedGainController* fixed_gc,
                                               const float input_level,
                                               const size_t num_frames,
                                               const int sample_rate) {
   // Give time to the level etimator to converge.
   for (size_t i = 0; i < num_frames; ++i) {
     VectorFloatFrame vectors_with_float_frame(
         1, rtc::CheckedDivExact(sample_rate, 100), input_level);
     fixed_gc->Process(vectors_with_float_frame.float_frame_view());
   }

   // Process the last frame with constant input level.
   VectorFloatFrame vectors_with_float_frame_last(
       1, rtc::CheckedDivExact(sample_rate, 100), input_level);
   fixed_gc->Process(vectors_with_float_frame_last.float_frame_view());

   // Return the last sample from the last processed frame.
   const auto channel =
       vectors_with_float_frame_last.float_frame_view().channel(0);
   return channel[channel.size() - 1];
 }

 std::unique_ptr<ApmDataDumper> GetApmDataDumper() {
   return absl::make_unique<ApmDataDumper>(0);
 }

 std::unique_ptr<FixedGainController> CreateFixedGainController(
     float gain_to_apply,
     size_t rate,
     std::string histogram_name_prefix,
     ApmDataDumper* test_data_dumper) {
   std::unique_ptr<FixedGainController> fgc =
       absl::make_unique<FixedGainController>(test_data_dumper,
                                              histogram_name_prefix);
   fgc->SetGain(gain_to_apply);
   fgc->SetSampleRate(rate);
   return fgc;
 }

 std::unique_ptr<FixedGainController> CreateFixedGainController(
     float gain_to_apply,
     size_t rate,
     ApmDataDumper* test_data_dumper) {
   return CreateFixedGainController(gain_to_apply, rate, "", test_data_dumper);
 }

 }  // namespace

 TEST(AutomaticGainController2FixedDigital, CreateUse) {
   const int kSampleRate = 44000;
   auto test_data_dumper = GetApmDataDumper();
   std::unique_ptr<FixedGainController> fixed_gc = CreateFixedGainController(
       kGainToApplyDb, kSampleRate, test_data_dumper.get());
   VectorFloatFrame vectors_with_float_frame(
       1, rtc::CheckedDivExact(kSampleRate, 100), kInputLevelLinear);
   auto float_frame = vectors_with_float_frame.float_frame_view();
   fixed_gc->Process(float_frame);
   const auto channel = float_frame.channel(0);
   EXPECT_LT(kInputLevelLinear, channel[0]);
 }

 TEST(AutomaticGainController2FixedDigital, CheckSaturationBehaviorWithLimiter) {
   const float kInputLevel = 32767.f;
   const size_t kNumFrames = 5;
   const size_t kSampleRate = 42000;

   auto test_data_dumper = GetApmDataDumper();

   const auto gains_no_saturation =
       test::LinSpace(0.1, test::kLimiterMaxInputLevelDbFs - 0.01, 10);
   for (const auto gain_db : gains_no_saturation) {
     // Since |test::kLimiterMaxInputLevelDbFs| > |gain_db|, the
     // limiter will not saturate the signal.
     std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
         CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

     // Saturation not expected.
     SCOPED_TRACE(std::to_string(gain_db));
     EXPECT_LT(
         RunFixedGainControllerWithConstantInput(
             fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
         32767.f);
   }

   const auto gains_saturation =
       test::LinSpace(test::kLimiterMaxInputLevelDbFs + 0.01, 10, 10);
   for (const auto gain_db : gains_saturation) {
     // Since |test::kLimiterMaxInputLevelDbFs| < |gain|, the limiter
     // will saturate the signal.
     std::unique_ptr<FixedGainController> fixed_gc_saturation =
         CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

     // Saturation expected.
     SCOPED_TRACE(std::to_string(gain_db));
     EXPECT_FLOAT_EQ(
         RunFixedGainControllerWithConstantInput(
             fixed_gc_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
         32767.f);
   }
 }

 TEST(AutomaticGainController2FixedDigital,
      CheckSaturationBehaviorWithLimiterSingleSample) {
   const float kInputLevel = 32767.f;
   const size_t kNumFrames = 5;
   const size_t kSampleRate = 8000;

   auto test_data_dumper = GetApmDataDumper();

   const auto gains_no_saturation =
       test::LinSpace(0.1, test::kLimiterMaxInputLevelDbFs - 0.01, 10);
   for (const auto gain_db : gains_no_saturation) {
     // Since |gain| > |test::kLimiterMaxInputLevelDbFs|, the limiter will
     // not saturate the signal.
     std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
         CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

     // Saturation not expected.
     SCOPED_TRACE(std::to_string(gain_db));
     EXPECT_LT(
         RunFixedGainControllerWithConstantInput(
             fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
         32767.f);
   }

   const auto gains_saturation =
       test::LinSpace(test::kLimiterMaxInputLevelDbFs + 0.01, 10, 10);
   for (const auto gain_db : gains_saturation) {
     // Singe |gain| < |test::kLimiterMaxInputLevelDbFs|, the limiter will
     // saturate the signal.
     std::unique_ptr<FixedGainController> fixed_gc_saturation =
         CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

     // Saturation expected.
     SCOPED_TRACE(std::to_string(gain_db));
     EXPECT_FLOAT_EQ(
         RunFixedGainControllerWithConstantInput(
             fixed_gc_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
         32767.f);
   }
 }

 TEST(AutomaticGainController2FixedDigital, GainShouldChangeOnSetGain) {
   constexpr float kInputLevel = 1000.f;
   constexpr size_t kNumFrames = 5;
   constexpr size_t kSampleRate = 8000;
   constexpr float kGainDbNoChange = 0.f;
   constexpr float kGainDbFactor10 = 20.f;

   auto test_data_dumper = GetApmDataDumper();
   std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
       CreateFixedGainController(kGainDbNoChange, kSampleRate,
                                 test_data_dumper.get());

   // Signal level is unchanged with 0 db gain.
   EXPECT_FLOAT_EQ(
       RunFixedGainControllerWithConstantInput(
           fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
       kInputLevel);

   fixed_gc_no_saturation->SetGain(kGainDbFactor10);

   // +20db should increase signal by a factor of 10.
   EXPECT_FLOAT_EQ(
       RunFixedGainControllerWithConstantInput(
           fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
       kInputLevel * 10);
 }

 TEST(AutomaticGainController2FixedDigital,
      SetGainShouldBeFastAndTimeInvariant) {
   // Number of frames required for the fixed gain controller to adapt on the
   // input signal when the gain changes.
   constexpr size_t kNumFrames = 5;

   constexpr float kInputLevel = 1000.f;
   constexpr size_t kSampleRate = 8000;
   constexpr float kGainDbLow = 0.f;
   constexpr float kGainDbHigh = 40.f;
   static_assert(kGainDbLow < kGainDbHigh, "");

   auto test_data_dumper = GetApmDataDumper();
   std::unique_ptr<FixedGainController> fixed_gc = CreateFixedGainController(
       kGainDbLow, kSampleRate, test_data_dumper.get());

   fixed_gc->SetGain(kGainDbLow);
   const float output_level_pre = RunFixedGainControllerWithConstantInput(
       fixed_gc.get(), kInputLevel, kNumFrames, kSampleRate);

   fixed_gc->SetGain(kGainDbHigh);
   RunFixedGainControllerWithConstantInput(fixed_gc.get(), kInputLevel,
                                           kNumFrames, kSampleRate);

   fixed_gc->SetGain(kGainDbLow);
   const float output_level_post = RunFixedGainControllerWithConstantInput(
       fixed_gc.get(), kInputLevel, kNumFrames, kSampleRate);

   EXPECT_EQ(output_level_pre, output_level_post);
 }

 TEST(AutomaticGainController2FixedDigital, RegionHistogramIsUpdated) {
   constexpr size_t kSampleRate = 8000;
   constexpr float kGainDb = 0.f;
   constexpr float kInputLevel = 1000.f;
   constexpr size_t kNumFrames = 5;

   metrics::Reset();

   auto test_data_dumper = GetApmDataDumper();
   std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
       CreateFixedGainController(kGainDb, kSampleRate, "Test",
                                 test_data_dumper.get());

   static_cast<void>(RunFixedGainControllerWithConstantInput(
       fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate));

   // Destroying FixedGainController should cause the last limiter region to be
   // logged.
   fixed_gc_no_saturation.reset();

   EXPECT_EQ(1, metrics::NumSamples(
                    "WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Identity"));
   EXPECT_EQ(0, metrics::NumSamples(
                    "WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Knee"));
   EXPECT_EQ(0, metrics::NumSamples(
                    "WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Limiter"));
   EXPECT_EQ(0, metrics::NumSamples(
                    "WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Saturation"));
 }

 }  // 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/fixed_gain_controller.h"

	#include "absl/memory/memory.h"
	#include "api/array_view.h"
	#include "modules/audio_processing/agc2/agc2_testing_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"
	#include "system_wrappers/include/metrics.h"

	namespace webrtc {
	namespace {

	constexpr float kInputLevelLinear = 15000.f;

	constexpr float kGainToApplyDb = 15.f;

	float RunFixedGainControllerWithConstantInput(FixedGainController* fixed_gc,
	const float input_level,
	const size_t num_frames,
	const int sample_rate) {
	// Give time to the level etimator to converge.
	for (size_t i = 0; i < num_frames; ++i) {
	VectorFloatFrame vectors_with_float_frame(
	1, rtc::CheckedDivExact(sample_rate, 100), input_level);
	fixed_gc->Process(vectors_with_float_frame.float_frame_view());
	}

	// Process the last frame with constant input level.
	VectorFloatFrame vectors_with_float_frame_last(
	1, rtc::CheckedDivExact(sample_rate, 100), input_level);
	fixed_gc->Process(vectors_with_float_frame_last.float_frame_view());

	// Return the last sample from the last processed frame.
	const auto channel =
	vectors_with_float_frame_last.float_frame_view().channel(0);
	return channel[channel.size() - 1];
	}

	std::unique_ptr<ApmDataDumper> GetApmDataDumper() {
	return absl::make_unique<ApmDataDumper>(0);
	}

	std::unique_ptr<FixedGainController> CreateFixedGainController(
	float gain_to_apply,
	size_t rate,
	std::string histogram_name_prefix,
	ApmDataDumper* test_data_dumper) {
	std::unique_ptr<FixedGainController> fgc =
	absl::make_unique<FixedGainController>(test_data_dumper,
	histogram_name_prefix);
	fgc->SetGain(gain_to_apply);
	fgc->SetSampleRate(rate);
	return fgc;
	}

	std::unique_ptr<FixedGainController> CreateFixedGainController(
	float gain_to_apply,
	size_t rate,
	ApmDataDumper* test_data_dumper) {
	return CreateFixedGainController(gain_to_apply, rate, "", test_data_dumper);
	}

	} // namespace

	TEST(AutomaticGainController2FixedDigital, CreateUse) {
	const int kSampleRate = 44000;
	auto test_data_dumper = GetApmDataDumper();
	std::unique_ptr<FixedGainController> fixed_gc = CreateFixedGainController(
	kGainToApplyDb, kSampleRate, test_data_dumper.get());
	VectorFloatFrame vectors_with_float_frame(
	1, rtc::CheckedDivExact(kSampleRate, 100), kInputLevelLinear);
	auto float_frame = vectors_with_float_frame.float_frame_view();
	fixed_gc->Process(float_frame);
	const auto channel = float_frame.channel(0);
	EXPECT_LT(kInputLevelLinear, channel[0]);
	}

	TEST(AutomaticGainController2FixedDigital, CheckSaturationBehaviorWithLimiter) {
	const float kInputLevel = 32767.f;
	const size_t kNumFrames = 5;
	const size_t kSampleRate = 42000;

	auto test_data_dumper = GetApmDataDumper();

	const auto gains_no_saturation =
	test::LinSpace(0.1, test::kLimiterMaxInputLevelDbFs - 0.01, 10);
	for (const auto gain_db : gains_no_saturation) {
	// Since \|test::kLimiterMaxInputLevelDbFs\| > \|gain_db\|, the
	// limiter will not saturate the signal.
	std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
	CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

	// Saturation not expected.
	SCOPED_TRACE(std::to_string(gain_db));
	EXPECT_LT(
	RunFixedGainControllerWithConstantInput(
	fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
	32767.f);
	}

	const auto gains_saturation =
	test::LinSpace(test::kLimiterMaxInputLevelDbFs + 0.01, 10, 10);
	for (const auto gain_db : gains_saturation) {
	// Since \|test::kLimiterMaxInputLevelDbFs\| < \|gain\|, the limiter
	// will saturate the signal.
	std::unique_ptr<FixedGainController> fixed_gc_saturation =
	CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

	// Saturation expected.
	SCOPED_TRACE(std::to_string(gain_db));
	EXPECT_FLOAT_EQ(
	RunFixedGainControllerWithConstantInput(
	fixed_gc_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
	32767.f);
	}
	}

	TEST(AutomaticGainController2FixedDigital,
	CheckSaturationBehaviorWithLimiterSingleSample) {
	const float kInputLevel = 32767.f;
	const size_t kNumFrames = 5;
	const size_t kSampleRate = 8000;

	auto test_data_dumper = GetApmDataDumper();

	const auto gains_no_saturation =
	test::LinSpace(0.1, test::kLimiterMaxInputLevelDbFs - 0.01, 10);
	for (const auto gain_db : gains_no_saturation) {
	// Since \|gain\| > \|test::kLimiterMaxInputLevelDbFs\|, the limiter will
	// not saturate the signal.
	std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
	CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

	// Saturation not expected.
	SCOPED_TRACE(std::to_string(gain_db));
	EXPECT_LT(
	RunFixedGainControllerWithConstantInput(
	fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
	32767.f);
	}

	const auto gains_saturation =
	test::LinSpace(test::kLimiterMaxInputLevelDbFs + 0.01, 10, 10);
	for (const auto gain_db : gains_saturation) {
	// Singe \|gain\| < \|test::kLimiterMaxInputLevelDbFs\|, the limiter will
	// saturate the signal.
	std::unique_ptr<FixedGainController> fixed_gc_saturation =
	CreateFixedGainController(gain_db, kSampleRate, test_data_dumper.get());

	// Saturation expected.
	SCOPED_TRACE(std::to_string(gain_db));
	EXPECT_FLOAT_EQ(
	RunFixedGainControllerWithConstantInput(
	fixed_gc_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
	32767.f);
	}
	}

	TEST(AutomaticGainController2FixedDigital, GainShouldChangeOnSetGain) {
	constexpr float kInputLevel = 1000.f;
	constexpr size_t kNumFrames = 5;
	constexpr size_t kSampleRate = 8000;
	constexpr float kGainDbNoChange = 0.f;
	constexpr float kGainDbFactor10 = 20.f;

	auto test_data_dumper = GetApmDataDumper();
	std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
	CreateFixedGainController(kGainDbNoChange, kSampleRate,
	test_data_dumper.get());

	// Signal level is unchanged with 0 db gain.
	EXPECT_FLOAT_EQ(
	RunFixedGainControllerWithConstantInput(
	fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
	kInputLevel);

	fixed_gc_no_saturation->SetGain(kGainDbFactor10);

	// +20db should increase signal by a factor of 10.
	EXPECT_FLOAT_EQ(
	RunFixedGainControllerWithConstantInput(
	fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate),
	kInputLevel * 10);
	}

	TEST(AutomaticGainController2FixedDigital,
	SetGainShouldBeFastAndTimeInvariant) {
	// Number of frames required for the fixed gain controller to adapt on the
	// input signal when the gain changes.
	constexpr size_t kNumFrames = 5;

	constexpr float kInputLevel = 1000.f;
	constexpr size_t kSampleRate = 8000;
	constexpr float kGainDbLow = 0.f;
	constexpr float kGainDbHigh = 40.f;
	static_assert(kGainDbLow < kGainDbHigh, "");

	auto test_data_dumper = GetApmDataDumper();
	std::unique_ptr<FixedGainController> fixed_gc = CreateFixedGainController(
	kGainDbLow, kSampleRate, test_data_dumper.get());

	fixed_gc->SetGain(kGainDbLow);
	const float output_level_pre = RunFixedGainControllerWithConstantInput(
	fixed_gc.get(), kInputLevel, kNumFrames, kSampleRate);

	fixed_gc->SetGain(kGainDbHigh);
	RunFixedGainControllerWithConstantInput(fixed_gc.get(), kInputLevel,
	kNumFrames, kSampleRate);

	fixed_gc->SetGain(kGainDbLow);
	const float output_level_post = RunFixedGainControllerWithConstantInput(
	fixed_gc.get(), kInputLevel, kNumFrames, kSampleRate);

	EXPECT_EQ(output_level_pre, output_level_post);
	}

	TEST(AutomaticGainController2FixedDigital, RegionHistogramIsUpdated) {
	constexpr size_t kSampleRate = 8000;
	constexpr float kGainDb = 0.f;
	constexpr float kInputLevel = 1000.f;
	constexpr size_t kNumFrames = 5;

	metrics::Reset();

	auto test_data_dumper = GetApmDataDumper();
	std::unique_ptr<FixedGainController> fixed_gc_no_saturation =
	CreateFixedGainController(kGainDb, kSampleRate, "Test",
	test_data_dumper.get());

	static_cast<void>(RunFixedGainControllerWithConstantInput(
	fixed_gc_no_saturation.get(), kInputLevel, kNumFrames, kSampleRate));

	// Destroying FixedGainController should cause the last limiter region to be
	// logged.
	fixed_gc_no_saturation.reset();

	EXPECT_EQ(1, metrics::NumSamples(
	"WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Identity"));
	EXPECT_EQ(0, metrics::NumSamples(
	"WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Knee"));
	EXPECT_EQ(0, metrics::NumSamples(
	"WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Limiter"));
	EXPECT_EQ(0, metrics::NumSamples(
	"WebRTC.Audio.Test.FixedDigitalGainCurveRegion.Saturation"));
	}

	} // namespace webrtc