modules/audio_processing/aec3/suppression_filter_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/suppression_filter.h"

 #include <math.h>

 #include <algorithm>
 #include <cmath>
 #include <numeric>

 #include "test/gtest.h"

 namespace webrtc {
 namespace {

 constexpr float kPi = 3.141592f;

 void ProduceSinusoid(int sample_rate_hz,
                      float sinusoidal_frequency_hz,
                      size_t* sample_counter,
                      Block* x) {
   // Produce a sinusoid of the specified frequency.
   for (size_t k = *sample_counter, j = 0; k < (*sample_counter + kBlockSize);
        ++k, ++j) {
     for (int channel = 0; channel < x->NumChannels(); ++channel) {
       x->View(/*band=*/0, channel)[j] =
           32767.f *
           std::sin(2.f * kPi * sinusoidal_frequency_hz * k / sample_rate_hz);
     }
   }
   *sample_counter = *sample_counter + kBlockSize;

   for (int band = 1; band < x->NumBands(); ++band) {
     for (int channel = 0; channel < x->NumChannels(); ++channel) {
       std::fill(x->begin(band, channel), x->end(band, channel), 0.f);
     }
   }
 }

 }  // namespace

 #if RTC_DCHECK_IS_ON && GTEST_HAS_DEATH_TEST && !defined(WEBRTC_ANDROID)

 // Verifies the check for null suppressor output.
 TEST(SuppressionFilterDeathTest, NullOutput) {
   std::vector<FftData> cn(1);
   std::vector<FftData> cn_high_bands(1);
   std::vector<FftData> E(1);
   std::array<float, kFftLengthBy2Plus1> gain;

   EXPECT_DEATH(SuppressionFilter(Aec3Optimization::kNone, 16000, 1)
                    .ApplyGain(cn, cn_high_bands, gain, 1.0f, E, nullptr),
                "");
 }

 // Verifies the check for allowed sample rate.
 TEST(SuppressionFilterDeathTest, ProperSampleRate) {
   EXPECT_DEATH(SuppressionFilter(Aec3Optimization::kNone, 16001, 1), "");
 }

 #endif

 // Verifies that no comfort noise is added when the gain is 1.
 TEST(SuppressionFilter, ComfortNoiseInUnityGain) {
   SuppressionFilter filter(Aec3Optimization::kNone, 48000, 1);
   std::vector<FftData> cn(1);
   std::vector<FftData> cn_high_bands(1);
   std::array<float, kFftLengthBy2Plus1> gain;
   std::array<float, kFftLengthBy2> e_old_;
   Aec3Fft fft;

   e_old_.fill(0.f);
   gain.fill(1.f);
   cn[0].re.fill(1.f);
   cn[0].im.fill(1.f);
   cn_high_bands[0].re.fill(1.f);
   cn_high_bands[0].im.fill(1.f);

   Block e(3, kBlockSize);
   Block e_ref = e;

   std::vector<FftData> E(1);
   fft.PaddedFft(e.View(/*band=*/0, /*channel=*/0), e_old_,
                 Aec3Fft::Window::kSqrtHanning, &E[0]);
   std::copy(e.begin(/*band=*/0, /*channel=*/0),
             e.end(/*band=*/0, /*channel=*/0), e_old_.begin());

   filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);

   for (int band = 0; band < e.NumBands(); ++band) {
     for (int channel = 0; channel < e.NumChannels(); ++channel) {
       const auto e_view = e.View(band, channel);
       const auto e_ref_view = e_ref.View(band, channel);
       for (size_t sample = 0; sample < e_view.size(); ++sample) {
         EXPECT_EQ(e_ref_view[sample], e_view[sample]);
       }
     }
   }
 }

 // Verifies that the suppressor is able to suppress a signal.
 TEST(SuppressionFilter, SignalSuppression) {
   constexpr int kSampleRateHz = 48000;
   constexpr size_t kNumBands = NumBandsForRate(kSampleRateHz);
   constexpr size_t kNumChannels = 1;

   SuppressionFilter filter(Aec3Optimization::kNone, kSampleRateHz, 1);
   std::vector<FftData> cn(1);
   std::vector<FftData> cn_high_bands(1);
   std::array<float, kFftLengthBy2> e_old_;
   Aec3Fft fft;
   std::array<float, kFftLengthBy2Plus1> gain;
   Block e(kNumBands, kNumChannels);
   e_old_.fill(0.f);

   gain.fill(1.f);
   std::for_each(gain.begin() + 10, gain.end(), [](float& a) { a = 0.f; });

   cn[0].re.fill(0.f);
   cn[0].im.fill(0.f);
   cn_high_bands[0].re.fill(0.f);
   cn_high_bands[0].im.fill(0.f);

   size_t sample_counter = 0;

   float e0_input = 0.f;
   float e0_output = 0.f;
   for (size_t k = 0; k < 100; ++k) {
     ProduceSinusoid(16000, 16000 * 40 / kFftLengthBy2 / 2, &sample_counter, &e);
     e0_input = std::inner_product(e.begin(/*band=*/0, /*channel=*/0),
                                   e.end(/*band=*/0, /*channel=*/0),
                                   e.begin(/*band=*/0, /*channel=*/0), e0_input);

     std::vector<FftData> E(1);
     fft.PaddedFft(e.View(/*band=*/0, /*channel=*/0), e_old_,
                   Aec3Fft::Window::kSqrtHanning, &E[0]);
     std::copy(e.begin(/*band=*/0, /*channel=*/0),
               e.end(/*band=*/0, /*channel=*/0), e_old_.begin());

     filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);
     e0_output = std::inner_product(
         e.begin(/*band=*/0, /*channel=*/0), e.end(/*band=*/0, /*channel=*/0),
         e.begin(/*band=*/0, /*channel=*/0), e0_output);
   }

   EXPECT_LT(e0_output, e0_input / 1000.f);
 }

 // Verifies that the suppressor is able to pass through a desired signal while
 // applying suppressing for some frequencies.
 TEST(SuppressionFilter, SignalTransparency) {
   constexpr size_t kNumChannels = 1;
   constexpr int kSampleRateHz = 48000;
   constexpr size_t kNumBands = NumBandsForRate(kSampleRateHz);

   SuppressionFilter filter(Aec3Optimization::kNone, kSampleRateHz, 1);
   std::vector<FftData> cn(1);
   std::array<float, kFftLengthBy2> e_old_;
   Aec3Fft fft;
   std::vector<FftData> cn_high_bands(1);
   std::array<float, kFftLengthBy2Plus1> gain;
   Block e(kNumBands, kNumChannels);
   e_old_.fill(0.f);
   gain.fill(1.f);
   std::for_each(gain.begin() + 30, gain.end(), [](float& a) { a = 0.f; });

   cn[0].re.fill(0.f);
   cn[0].im.fill(0.f);
   cn_high_bands[0].re.fill(0.f);
   cn_high_bands[0].im.fill(0.f);

   size_t sample_counter = 0;

   float e0_input = 0.f;
   float e0_output = 0.f;
   for (size_t k = 0; k < 100; ++k) {
     ProduceSinusoid(16000, 16000 * 10 / kFftLengthBy2 / 2, &sample_counter, &e);
     e0_input = std::inner_product(e.begin(/*band=*/0, /*channel=*/0),
                                   e.end(/*band=*/0, /*channel=*/0),
                                   e.begin(/*band=*/0, /*channel=*/0), e0_input);

     std::vector<FftData> E(1);
     fft.PaddedFft(e.View(/*band=*/0, /*channel=*/0), e_old_,
                   Aec3Fft::Window::kSqrtHanning, &E[0]);
     std::copy(e.begin(/*band=*/0, /*channel=*/0),
               e.end(/*band=*/0, /*channel=*/0), e_old_.begin());

     filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);
     e0_output = std::inner_product(
         e.begin(/*band=*/0, /*channel=*/0), e.end(/*band=*/0, /*channel=*/0),
         e.begin(/*band=*/0, /*channel=*/0), e0_output);
   }

   EXPECT_LT(0.9f * e0_input, e0_output);
 }

 // Verifies that the suppressor delay.
 TEST(SuppressionFilter, Delay) {
   constexpr size_t kNumChannels = 1;
   constexpr int kSampleRateHz = 48000;
   constexpr size_t kNumBands = NumBandsForRate(kSampleRateHz);

   SuppressionFilter filter(Aec3Optimization::kNone, kSampleRateHz, 1);
   std::vector<FftData> cn(1);
   std::vector<FftData> cn_high_bands(1);
   std::array<float, kFftLengthBy2> e_old_;
   Aec3Fft fft;
   std::array<float, kFftLengthBy2Plus1> gain;
   Block e(kNumBands, kNumChannels);

   gain.fill(1.f);

   cn[0].re.fill(0.f);
   cn[0].im.fill(0.f);
   cn_high_bands[0].re.fill(0.f);
   cn_high_bands[0].im.fill(0.f);

   for (size_t k = 0; k < 100; ++k) {
     for (size_t band = 0; band < kNumBands; ++band) {
       for (size_t channel = 0; channel < kNumChannels; ++channel) {
         auto e_view = e.View(band, channel);
         for (size_t sample = 0; sample < kBlockSize; ++sample) {
           e_view[sample] = k * kBlockSize + sample + channel;
         }
       }
     }

     std::vector<FftData> E(1);
     fft.PaddedFft(e.View(/*band=*/0, /*channel=*/0), e_old_,
                   Aec3Fft::Window::kSqrtHanning, &E[0]);
     std::copy(e.begin(/*band=*/0, /*channel=*/0),
               e.end(/*band=*/0, /*channel=*/0), e_old_.begin());

     filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);
     if (k > 2) {
       for (size_t band = 0; band < kNumBands; ++band) {
         for (size_t channel = 0; channel < kNumChannels; ++channel) {
           const auto e_view = e.View(band, channel);
           for (size_t sample = 0; sample < kBlockSize; ++sample) {
             EXPECT_NEAR(k * kBlockSize + sample - kBlockSize + channel,
                         e_view[sample], 0.01);
           }
         }
       }
     }
   }
 }

 }  // 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/suppression_filter.h"

	#include <math.h>

	#include <algorithm>
	#include <cmath>
	#include <numeric>

	#include "test/gtest.h"

	namespace webrtc {
	namespace {

	constexpr float kPi = 3.141592f;

	void ProduceSinusoid(int sample_rate_hz,
	float sinusoidal_frequency_hz,
	size_t* sample_counter,
	Block* x) {
	// Produce a sinusoid of the specified frequency.
	for (size_t k = sample_counter, j = 0; k < (sample_counter + kBlockSize);
	++k, ++j) {
	for (int channel = 0; channel < x->NumChannels(); ++channel) {
	x->View(/band=/0, channel)[j] =
	32767.f *
	std::sin(2.f * kPi * sinusoidal_frequency_hz * k / sample_rate_hz);
	}
	}
	sample_counter = sample_counter + kBlockSize;

	for (int band = 1; band < x->NumBands(); ++band) {
	for (int channel = 0; channel < x->NumChannels(); ++channel) {
	std::fill(x->begin(band, channel), x->end(band, channel), 0.f);
	}
	}
	}

	} // namespace

	#if RTC_DCHECK_IS_ON && GTEST_HAS_DEATH_TEST && !defined(WEBRTC_ANDROID)

	// Verifies the check for null suppressor output.
	TEST(SuppressionFilterDeathTest, NullOutput) {
	std::vector<FftData> cn(1);
	std::vector<FftData> cn_high_bands(1);
	std::vector<FftData> E(1);
	std::array<float, kFftLengthBy2Plus1> gain;

	EXPECT_DEATH(SuppressionFilter(Aec3Optimization::kNone, 16000, 1)
	.ApplyGain(cn, cn_high_bands, gain, 1.0f, E, nullptr),
	"");
	}

	// Verifies the check for allowed sample rate.
	TEST(SuppressionFilterDeathTest, ProperSampleRate) {
	EXPECT_DEATH(SuppressionFilter(Aec3Optimization::kNone, 16001, 1), "");
	}

	#endif

	// Verifies that no comfort noise is added when the gain is 1.
	TEST(SuppressionFilter, ComfortNoiseInUnityGain) {
	SuppressionFilter filter(Aec3Optimization::kNone, 48000, 1);
	std::vector<FftData> cn(1);
	std::vector<FftData> cn_high_bands(1);
	std::array<float, kFftLengthBy2Plus1> gain;
	std::array<float, kFftLengthBy2> e_old_;
	Aec3Fft fft;

	e_old_.fill(0.f);
	gain.fill(1.f);
	cn[0].re.fill(1.f);
	cn[0].im.fill(1.f);
	cn_high_bands[0].re.fill(1.f);
	cn_high_bands[0].im.fill(1.f);

	Block e(3, kBlockSize);
	Block e_ref = e;

	std::vector<FftData> E(1);
	fft.PaddedFft(e.View(/band=/0, /channel=/0), e_old_,
	Aec3Fft::Window::kSqrtHanning, &E[0]);
	std::copy(e.begin(/band=/0, /channel=/0),
	e.end(/band=/0, /channel=/0), e_old_.begin());

	filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);

	for (int band = 0; band < e.NumBands(); ++band) {
	for (int channel = 0; channel < e.NumChannels(); ++channel) {
	const auto e_view = e.View(band, channel);
	const auto e_ref_view = e_ref.View(band, channel);
	for (size_t sample = 0; sample < e_view.size(); ++sample) {
	EXPECT_EQ(e_ref_view[sample], e_view[sample]);
	}
	}
	}
	}

	// Verifies that the suppressor is able to suppress a signal.
	TEST(SuppressionFilter, SignalSuppression) {
	constexpr int kSampleRateHz = 48000;
	constexpr size_t kNumBands = NumBandsForRate(kSampleRateHz);
	constexpr size_t kNumChannels = 1;

	SuppressionFilter filter(Aec3Optimization::kNone, kSampleRateHz, 1);
	std::vector<FftData> cn(1);
	std::vector<FftData> cn_high_bands(1);
	std::array<float, kFftLengthBy2> e_old_;
	Aec3Fft fft;
	std::array<float, kFftLengthBy2Plus1> gain;
	Block e(kNumBands, kNumChannels);
	e_old_.fill(0.f);

	gain.fill(1.f);
	std::for_each(gain.begin() + 10, gain.end(), [](float& a) { a = 0.f; });

	cn[0].re.fill(0.f);
	cn[0].im.fill(0.f);
	cn_high_bands[0].re.fill(0.f);
	cn_high_bands[0].im.fill(0.f);

	size_t sample_counter = 0;

	float e0_input = 0.f;
	float e0_output = 0.f;
	for (size_t k = 0; k < 100; ++k) {
	ProduceSinusoid(16000, 16000 * 40 / kFftLengthBy2 / 2, &sample_counter, &e);
	e0_input = std::inner_product(e.begin(/band=/0, /channel=/0),
	e.end(/band=/0, /channel=/0),
	e.begin(/band=/0, /channel=/0), e0_input);

	std::vector<FftData> E(1);
	fft.PaddedFft(e.View(/band=/0, /channel=/0), e_old_,
	Aec3Fft::Window::kSqrtHanning, &E[0]);
	std::copy(e.begin(/band=/0, /channel=/0),
	e.end(/band=/0, /channel=/0), e_old_.begin());

	filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);
	e0_output = std::inner_product(
	e.begin(/band=/0, /channel=/0), e.end(/band=/0, /channel=/0),
	e.begin(/band=/0, /channel=/0), e0_output);
	}

	EXPECT_LT(e0_output, e0_input / 1000.f);
	}

	// Verifies that the suppressor is able to pass through a desired signal while
	// applying suppressing for some frequencies.
	TEST(SuppressionFilter, SignalTransparency) {
	constexpr size_t kNumChannels = 1;
	constexpr int kSampleRateHz = 48000;
	constexpr size_t kNumBands = NumBandsForRate(kSampleRateHz);

	SuppressionFilter filter(Aec3Optimization::kNone, kSampleRateHz, 1);
	std::vector<FftData> cn(1);
	std::array<float, kFftLengthBy2> e_old_;
	Aec3Fft fft;
	std::vector<FftData> cn_high_bands(1);
	std::array<float, kFftLengthBy2Plus1> gain;
	Block e(kNumBands, kNumChannels);
	e_old_.fill(0.f);
	gain.fill(1.f);
	std::for_each(gain.begin() + 30, gain.end(), [](float& a) { a = 0.f; });

	cn[0].re.fill(0.f);
	cn[0].im.fill(0.f);
	cn_high_bands[0].re.fill(0.f);
	cn_high_bands[0].im.fill(0.f);

	size_t sample_counter = 0;

	float e0_input = 0.f;
	float e0_output = 0.f;
	for (size_t k = 0; k < 100; ++k) {
	ProduceSinusoid(16000, 16000 * 10 / kFftLengthBy2 / 2, &sample_counter, &e);
	e0_input = std::inner_product(e.begin(/band=/0, /channel=/0),
	e.end(/band=/0, /channel=/0),
	e.begin(/band=/0, /channel=/0), e0_input);

	std::vector<FftData> E(1);
	fft.PaddedFft(e.View(/band=/0, /channel=/0), e_old_,
	Aec3Fft::Window::kSqrtHanning, &E[0]);
	std::copy(e.begin(/band=/0, /channel=/0),
	e.end(/band=/0, /channel=/0), e_old_.begin());

	filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);
	e0_output = std::inner_product(
	e.begin(/band=/0, /channel=/0), e.end(/band=/0, /channel=/0),
	e.begin(/band=/0, /channel=/0), e0_output);
	}

	EXPECT_LT(0.9f * e0_input, e0_output);
	}

	// Verifies that the suppressor delay.
	TEST(SuppressionFilter, Delay) {
	constexpr size_t kNumChannels = 1;
	constexpr int kSampleRateHz = 48000;
	constexpr size_t kNumBands = NumBandsForRate(kSampleRateHz);

	SuppressionFilter filter(Aec3Optimization::kNone, kSampleRateHz, 1);
	std::vector<FftData> cn(1);
	std::vector<FftData> cn_high_bands(1);
	std::array<float, kFftLengthBy2> e_old_;
	Aec3Fft fft;
	std::array<float, kFftLengthBy2Plus1> gain;
	Block e(kNumBands, kNumChannels);

	gain.fill(1.f);

	cn[0].re.fill(0.f);
	cn[0].im.fill(0.f);
	cn_high_bands[0].re.fill(0.f);
	cn_high_bands[0].im.fill(0.f);

	for (size_t k = 0; k < 100; ++k) {
	for (size_t band = 0; band < kNumBands; ++band) {
	for (size_t channel = 0; channel < kNumChannels; ++channel) {
	auto e_view = e.View(band, channel);
	for (size_t sample = 0; sample < kBlockSize; ++sample) {
	e_view[sample] = k * kBlockSize + sample + channel;
	}
	}
	}

	std::vector<FftData> E(1);
	fft.PaddedFft(e.View(/band=/0, /channel=/0), e_old_,
	Aec3Fft::Window::kSqrtHanning, &E[0]);
	std::copy(e.begin(/band=/0, /channel=/0),
	e.end(/band=/0, /channel=/0), e_old_.begin());

	filter.ApplyGain(cn, cn_high_bands, gain, 1.f, E, &e);
	if (k > 2) {
	for (size_t band = 0; band < kNumBands; ++band) {
	for (size_t channel = 0; channel < kNumChannels; ++channel) {
	const auto e_view = e.View(band, channel);
	for (size_t sample = 0; sample < kBlockSize; ++sample) {
	EXPECT_NEAR(k * kBlockSize + sample - kBlockSize + channel,
	e_view[sample], 0.01);
	}
	}
	}
	}
	}
	}

	} // namespace webrtc