modules/audio_processing/aec3/aec_state_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2017 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/aec3/aec_state.h"

 #include "modules/audio_processing/logging/apm_data_dumper.h"
 #include "test/gtest.h"

 namespace webrtc {

 // Verify the general functionality of AecState
 TEST(AecState, NormalUsage) {
   ApmDataDumper data_dumper(42);
   AecState state(EchoCanceller3Config{});
   RenderBuffer render_buffer(Aec3Optimization::kNone, 3, 30,
                              std::vector<size_t>(1, 30));
   std::array<float, kFftLengthBy2Plus1> E2_main = {};
   std::array<float, kFftLengthBy2Plus1> Y2 = {};
   std::vector<std::vector<float>> x(3, std::vector<float>(kBlockSize, 0.f));
   EchoPathVariability echo_path_variability(false, false);
   std::array<float, kBlockSize> s;
   s.fill(100.f);

   std::vector<std::array<float, kFftLengthBy2Plus1>>
       converged_filter_frequency_response(10);
   for (auto& v : converged_filter_frequency_response) {
     v.fill(0.01f);
   }
   std::vector<std::array<float, kFftLengthBy2Plus1>>
       diverged_filter_frequency_response = converged_filter_frequency_response;
   converged_filter_frequency_response[2].fill(100.f);
   converged_filter_frequency_response[2][0] = 1.f;

   std::array<float, kAdaptiveFilterTimeDomainLength> impulse_response;
   impulse_response.fill(0.f);

   // Verify that linear AEC usability is false when the filter is diverged and
   // there is no external delay reported.
   state.Update(diverged_filter_frequency_response, impulse_response, true,
                rtc::nullopt, render_buffer, E2_main, Y2, x[0], s, false);
   EXPECT_FALSE(state.UsableLinearEstimate());

   // Verify that linear AEC usability is true when the filter is converged
   std::fill(x[0].begin(), x[0].end(), 101.f);
   for (int k = 0; k < 3000; ++k) {
     state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                  render_buffer, E2_main, Y2, x[0], s, false);
   }
   EXPECT_TRUE(state.UsableLinearEstimate());

   // Verify that linear AEC usability becomes false after an echo path change is
   // reported
   state.HandleEchoPathChange(EchoPathVariability(true, false));
   state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                render_buffer, E2_main, Y2, x[0], s, false);
   EXPECT_FALSE(state.UsableLinearEstimate());

   // Verify that the active render detection works as intended.
   std::fill(x[0].begin(), x[0].end(), 101.f);
   state.HandleEchoPathChange(EchoPathVariability(true, true));
   state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                render_buffer, E2_main, Y2, x[0], s, false);
   EXPECT_FALSE(state.ActiveRender());

   for (int k = 0; k < 1000; ++k) {
     state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                  render_buffer, E2_main, Y2, x[0], s, false);
   }
   EXPECT_TRUE(state.ActiveRender());

   // Verify that echo leakage is properly reported.
   state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                render_buffer, E2_main, Y2, x[0], s, false);
   EXPECT_FALSE(state.EchoLeakageDetected());

   state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                render_buffer, E2_main, Y2, x[0], s, true);
   EXPECT_TRUE(state.EchoLeakageDetected());

   // Verify that the ERL is properly estimated
   for (auto& x_k : x) {
     x_k = std::vector<float>(kBlockSize, 0.f);
   }

   x[0][0] = 5000.f;
   for (size_t k = 0; k < render_buffer.Buffer().size(); ++k) {
     render_buffer.Insert(x);
   }

   Y2.fill(10.f * 10000.f * 10000.f);
   for (size_t k = 0; k < 1000; ++k) {
     state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                  render_buffer, E2_main, Y2, x[0], s, false);
   }

   ASSERT_TRUE(state.UsableLinearEstimate());
   const std::array<float, kFftLengthBy2Plus1>& erl = state.Erl();
   EXPECT_EQ(erl[0], erl[1]);
   for (size_t k = 1; k < erl.size() - 1; ++k) {
     EXPECT_NEAR(k % 2 == 0 ? 10.f : 1000.f, erl[k], 0.1);
   }
   EXPECT_EQ(erl[erl.size() - 2], erl[erl.size() - 1]);

   // Verify that the ERLE is properly estimated
   E2_main.fill(1.f * 10000.f * 10000.f);
   Y2.fill(10.f * E2_main[0]);
   for (size_t k = 0; k < 1000; ++k) {
     state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                  render_buffer, E2_main, Y2, x[0], s, false);
   }
   ASSERT_TRUE(state.UsableLinearEstimate());
   {
     const auto& erle = state.Erle();
     EXPECT_EQ(erle[0], erle[1]);
     constexpr size_t kLowFrequencyLimit = 32;
     for (size_t k = 1; k < kLowFrequencyLimit; ++k) {
       EXPECT_NEAR(k % 2 == 0 ? 8.f : 1.f, erle[k], 0.1);
     }
     for (size_t k = kLowFrequencyLimit; k < erle.size() - 1; ++k) {
       EXPECT_NEAR(k % 2 == 0 ? 1.5f : 1.f, erle[k], 0.1);
     }
     EXPECT_EQ(erle[erle.size() - 2], erle[erle.size() - 1]);
   }

   E2_main.fill(1.f * 10000.f * 10000.f);
   Y2.fill(5.f * E2_main[0]);
   for (size_t k = 0; k < 1000; ++k) {
     state.Update(converged_filter_frequency_response, impulse_response, true, 2,
                  render_buffer, E2_main, Y2, x[0], s, false);
   }

   ASSERT_TRUE(state.UsableLinearEstimate());
   {
     const auto& erle = state.Erle();
     EXPECT_EQ(erle[0], erle[1]);
     constexpr size_t kLowFrequencyLimit = 32;
     for (size_t k = 1; k < kLowFrequencyLimit; ++k) {
       EXPECT_NEAR(k % 2 == 0 ? 5.f : 1.f, erle[k], 0.1);
     }
     for (size_t k = kLowFrequencyLimit; k < erle.size() - 1; ++k) {
       EXPECT_NEAR(k % 2 == 0 ? 1.5f : 1.f, erle[k], 0.1);
     }
     EXPECT_EQ(erle[erle.size() - 2], erle[erle.size() - 1]);
   }
 }

 // Verifies the delay for a converged filter is correctly identified.
 TEST(AecState, ConvergedFilterDelay) {
   constexpr int kFilterLength = 10;
   AecState state(EchoCanceller3Config{});
   RenderBuffer render_buffer(Aec3Optimization::kNone, 3, 30,
                              std::vector<size_t>(1, 30));
   std::array<float, kFftLengthBy2Plus1> E2_main;
   std::array<float, kFftLengthBy2Plus1> Y2;
   std::array<float, kBlockSize> x;
   EchoPathVariability echo_path_variability(false, false);
   std::array<float, kBlockSize> s;
   s.fill(100.f);
   x.fill(0.f);

   std::vector<std::array<float, kFftLengthBy2Plus1>> frequency_response(
       kFilterLength);

   std::array<float, kAdaptiveFilterTimeDomainLength> impulse_response;
   impulse_response.fill(0.f);

   // Verify that the filter delay for a converged filter is properly identified.
   for (int k = 0; k < kFilterLength; ++k) {
     for (auto& v : frequency_response) {
       v.fill(0.01f);
     }
     frequency_response[k].fill(100.f);
     frequency_response[k][0] = 0.f;
     state.HandleEchoPathChange(echo_path_variability);
     state.Update(frequency_response, impulse_response, true, rtc::nullopt,
                  render_buffer, E2_main, Y2, x, s, false);
     EXPECT_TRUE(k == (kFilterLength - 1) || state.FilterDelay());
     if (k != (kFilterLength - 1)) {
       EXPECT_EQ(k, state.FilterDelay());
     }
   }
 }

 // Verify that the externally reported delay is properly reported and converted.
 TEST(AecState, ExternalDelay) {
   AecState state(EchoCanceller3Config{});
   std::array<float, kFftLengthBy2Plus1> E2_main;
   std::array<float, kFftLengthBy2Plus1> E2_shadow;
   std::array<float, kFftLengthBy2Plus1> Y2;
   std::array<float, kBlockSize> x;
   std::array<float, kBlockSize> s;
   s.fill(100.f);
   E2_main.fill(0.f);
   E2_shadow.fill(0.f);
   Y2.fill(0.f);
   x.fill(0.f);
   RenderBuffer render_buffer(Aec3Optimization::kNone, 3, 30,
                              std::vector<size_t>(1, 30));
   std::vector<std::array<float, kFftLengthBy2Plus1>> frequency_response(
       kAdaptiveFilterLength);
   for (auto& v : frequency_response) {
     v.fill(0.01f);
   }

   std::array<float, kAdaptiveFilterTimeDomainLength> impulse_response;
   impulse_response.fill(0.f);

   for (size_t k = 0; k < frequency_response.size() - 1; ++k) {
     state.HandleEchoPathChange(EchoPathVariability(false, false));
     state.Update(frequency_response, impulse_response, true, k * kBlockSize + 5,
                  render_buffer, E2_main, Y2, x, s, false);
     EXPECT_TRUE(state.ExternalDelay());
     EXPECT_EQ(k, state.ExternalDelay());
   }

   // Verify that the externally reported delay is properly unset when it is no
   // longer present.
   state.HandleEchoPathChange(EchoPathVariability(false, false));
   state.Update(frequency_response, impulse_response, true, rtc::nullopt,
                render_buffer, E2_main, Y2, x, s, false);
   EXPECT_FALSE(state.ExternalDelay());
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2017 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/aec3/aec_state.h"

	#include "modules/audio_processing/logging/apm_data_dumper.h"
	#include "test/gtest.h"

	namespace webrtc {

	// Verify the general functionality of AecState
	TEST(AecState, NormalUsage) {
	ApmDataDumper data_dumper(42);
	AecState state(EchoCanceller3Config{});
	RenderBuffer render_buffer(Aec3Optimization::kNone, 3, 30,
	std::vector<size_t>(1, 30));
	std::array<float, kFftLengthBy2Plus1> E2_main = {};
	std::array<float, kFftLengthBy2Plus1> Y2 = {};
	std::vector<std::vector<float>> x(3, std::vector<float>(kBlockSize, 0.f));
	EchoPathVariability echo_path_variability(false, false);
	std::array<float, kBlockSize> s;
	s.fill(100.f);

	std::vector<std::array<float, kFftLengthBy2Plus1>>
	converged_filter_frequency_response(10);
	for (auto& v : converged_filter_frequency_response) {
	v.fill(0.01f);
	}
	std::vector<std::array<float, kFftLengthBy2Plus1>>
	diverged_filter_frequency_response = converged_filter_frequency_response;
	converged_filter_frequency_response[2].fill(100.f);
	converged_filter_frequency_response[2][0] = 1.f;

	std::array<float, kAdaptiveFilterTimeDomainLength> impulse_response;
	impulse_response.fill(0.f);

	// Verify that linear AEC usability is false when the filter is diverged and
	// there is no external delay reported.
	state.Update(diverged_filter_frequency_response, impulse_response, true,
	rtc::nullopt, render_buffer, E2_main, Y2, x[0], s, false);
	EXPECT_FALSE(state.UsableLinearEstimate());

	// Verify that linear AEC usability is true when the filter is converged
	std::fill(x[0].begin(), x[0].end(), 101.f);
	for (int k = 0; k < 3000; ++k) {
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	}
	EXPECT_TRUE(state.UsableLinearEstimate());

	// Verify that linear AEC usability becomes false after an echo path change is
	// reported
	state.HandleEchoPathChange(EchoPathVariability(true, false));
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	EXPECT_FALSE(state.UsableLinearEstimate());

	// Verify that the active render detection works as intended.
	std::fill(x[0].begin(), x[0].end(), 101.f);
	state.HandleEchoPathChange(EchoPathVariability(true, true));
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	EXPECT_FALSE(state.ActiveRender());

	for (int k = 0; k < 1000; ++k) {
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	}
	EXPECT_TRUE(state.ActiveRender());

	// Verify that echo leakage is properly reported.
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	EXPECT_FALSE(state.EchoLeakageDetected());

	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, true);
	EXPECT_TRUE(state.EchoLeakageDetected());

	// Verify that the ERL is properly estimated
	for (auto& x_k : x) {
	x_k = std::vector<float>(kBlockSize, 0.f);
	}

	x[0][0] = 5000.f;
	for (size_t k = 0; k < render_buffer.Buffer().size(); ++k) {
	render_buffer.Insert(x);
	}

	Y2.fill(10.f * 10000.f * 10000.f);
	for (size_t k = 0; k < 1000; ++k) {
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	}

	ASSERT_TRUE(state.UsableLinearEstimate());
	const std::array<float, kFftLengthBy2Plus1>& erl = state.Erl();
	EXPECT_EQ(erl[0], erl[1]);
	for (size_t k = 1; k < erl.size() - 1; ++k) {
	EXPECT_NEAR(k % 2 == 0 ? 10.f : 1000.f, erl[k], 0.1);
	}
	EXPECT_EQ(erl[erl.size() - 2], erl[erl.size() - 1]);

	// Verify that the ERLE is properly estimated
	E2_main.fill(1.f * 10000.f * 10000.f);
	Y2.fill(10.f * E2_main[0]);
	for (size_t k = 0; k < 1000; ++k) {
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	}
	ASSERT_TRUE(state.UsableLinearEstimate());
	{
	const auto& erle = state.Erle();
	EXPECT_EQ(erle[0], erle[1]);
	constexpr size_t kLowFrequencyLimit = 32;
	for (size_t k = 1; k < kLowFrequencyLimit; ++k) {
	EXPECT_NEAR(k % 2 == 0 ? 8.f : 1.f, erle[k], 0.1);
	}
	for (size_t k = kLowFrequencyLimit; k < erle.size() - 1; ++k) {
	EXPECT_NEAR(k % 2 == 0 ? 1.5f : 1.f, erle[k], 0.1);
	}
	EXPECT_EQ(erle[erle.size() - 2], erle[erle.size() - 1]);
	}

	E2_main.fill(1.f * 10000.f * 10000.f);
	Y2.fill(5.f * E2_main[0]);
	for (size_t k = 0; k < 1000; ++k) {
	state.Update(converged_filter_frequency_response, impulse_response, true, 2,
	render_buffer, E2_main, Y2, x[0], s, false);
	}

	ASSERT_TRUE(state.UsableLinearEstimate());
	{
	const auto& erle = state.Erle();
	EXPECT_EQ(erle[0], erle[1]);
	constexpr size_t kLowFrequencyLimit = 32;
	for (size_t k = 1; k < kLowFrequencyLimit; ++k) {
	EXPECT_NEAR(k % 2 == 0 ? 5.f : 1.f, erle[k], 0.1);
	}
	for (size_t k = kLowFrequencyLimit; k < erle.size() - 1; ++k) {
	EXPECT_NEAR(k % 2 == 0 ? 1.5f : 1.f, erle[k], 0.1);
	}
	EXPECT_EQ(erle[erle.size() - 2], erle[erle.size() - 1]);
	}
	}

	// Verifies the delay for a converged filter is correctly identified.
	TEST(AecState, ConvergedFilterDelay) {
	constexpr int kFilterLength = 10;
	AecState state(EchoCanceller3Config{});
	RenderBuffer render_buffer(Aec3Optimization::kNone, 3, 30,
	std::vector<size_t>(1, 30));
	std::array<float, kFftLengthBy2Plus1> E2_main;
	std::array<float, kFftLengthBy2Plus1> Y2;
	std::array<float, kBlockSize> x;
	EchoPathVariability echo_path_variability(false, false);
	std::array<float, kBlockSize> s;
	s.fill(100.f);
	x.fill(0.f);

	std::vector<std::array<float, kFftLengthBy2Plus1>> frequency_response(
	kFilterLength);

	std::array<float, kAdaptiveFilterTimeDomainLength> impulse_response;
	impulse_response.fill(0.f);

	// Verify that the filter delay for a converged filter is properly identified.
	for (int k = 0; k < kFilterLength; ++k) {
	for (auto& v : frequency_response) {
	v.fill(0.01f);
	}
	frequency_response[k].fill(100.f);
	frequency_response[k][0] = 0.f;
	state.HandleEchoPathChange(echo_path_variability);
	state.Update(frequency_response, impulse_response, true, rtc::nullopt,
	render_buffer, E2_main, Y2, x, s, false);
	EXPECT_TRUE(k == (kFilterLength - 1) \|\| state.FilterDelay());
	if (k != (kFilterLength - 1)) {
	EXPECT_EQ(k, state.FilterDelay());
	}
	}
	}

	// Verify that the externally reported delay is properly reported and converted.
	TEST(AecState, ExternalDelay) {
	AecState state(EchoCanceller3Config{});
	std::array<float, kFftLengthBy2Plus1> E2_main;
	std::array<float, kFftLengthBy2Plus1> E2_shadow;
	std::array<float, kFftLengthBy2Plus1> Y2;
	std::array<float, kBlockSize> x;
	std::array<float, kBlockSize> s;
	s.fill(100.f);
	E2_main.fill(0.f);
	E2_shadow.fill(0.f);
	Y2.fill(0.f);
	x.fill(0.f);
	RenderBuffer render_buffer(Aec3Optimization::kNone, 3, 30,
	std::vector<size_t>(1, 30));
	std::vector<std::array<float, kFftLengthBy2Plus1>> frequency_response(
	kAdaptiveFilterLength);
	for (auto& v : frequency_response) {
	v.fill(0.01f);
	}

	std::array<float, kAdaptiveFilterTimeDomainLength> impulse_response;
	impulse_response.fill(0.f);

	for (size_t k = 0; k < frequency_response.size() - 1; ++k) {
	state.HandleEchoPathChange(EchoPathVariability(false, false));
	state.Update(frequency_response, impulse_response, true, k * kBlockSize + 5,
	render_buffer, E2_main, Y2, x, s, false);
	EXPECT_TRUE(state.ExternalDelay());
	EXPECT_EQ(k, state.ExternalDelay());
	}

	// Verify that the externally reported delay is properly unset when it is no
	// longer present.
	state.HandleEchoPathChange(EchoPathVariability(false, false));
	state.Update(frequency_response, impulse_response, true, rtc::nullopt,
	render_buffer, E2_main, Y2, x, s, false);
	EXPECT_FALSE(state.ExternalDelay());
	}

	} // namespace webrtc