modules/audio_processing/agc2/rnn_vad/spectral_features_internal_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/rnn_vad/spectral_features_internal.h"

 #include <algorithm>
 #include <array>
 #include <complex>
 #include <numeric>
 #include <vector>

 #include "api/array_view.h"
 #include "modules/audio_processing/agc2/rnn_vad/test_utils.h"
 #include "modules/audio_processing/utility/pffft_wrapper.h"
 // TODO(bugs.webrtc.org/8948): Add when the issue is fixed.
 // #include "test/fpe_observer.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace rnn_vad {
 namespace test {
 namespace {

 // Generates the values for the array named |kOpusBandWeights24kHz20ms| in the
 // anonymous namespace of the .cc file, which is the array of FFT coefficient
 // weights for the Opus scale triangular filters.
 std::vector<float> ComputeTriangularFiltersWeights() {
   constexpr auto kOpusScaleNumBins24kHz20ms = GetOpusScaleNumBins24kHz20ms();
   const auto& v = kOpusScaleNumBins24kHz20ms;  // Alias.
   const size_t num_weights = std::accumulate(
       kOpusScaleNumBins24kHz20ms.begin(), kOpusScaleNumBins24kHz20ms.end(), 0);
   std::vector<float> weights(num_weights);
   size_t next_fft_coeff_index = 0;
   for (size_t band = 0; band < v.size(); ++band) {
     const size_t band_size = v[band];
     for (size_t j = 0; j < band_size; ++j) {
       weights[next_fft_coeff_index + j] = static_cast<float>(j) / band_size;
     }
     next_fft_coeff_index += band_size;
   }
   return weights;
 }

 }  // namespace

 // Checks that the values returned by GetOpusScaleNumBins24kHz20ms() match the
 // Opus scale frequency boundaries.
 TEST(RnnVadTest, TestOpusScaleBoundaries) {
   constexpr int kBandFrequencyBoundariesHz[kNumBands - 1] = {
       200,  400,  600,  800,  1000, 1200, 1400, 1600,  2000,  2400, 2800,
       3200, 4000, 4800, 5600, 6800, 8000, 9600, 12000, 15600, 20000};
   constexpr auto kOpusScaleNumBins24kHz20ms = GetOpusScaleNumBins24kHz20ms();
   int prev = 0;
   for (size_t i = 0; i < kOpusScaleNumBins24kHz20ms.size(); ++i) {
     int boundary =
         kBandFrequencyBoundariesHz[i] * kFrameSize20ms24kHz / kSampleRate24kHz;
     EXPECT_EQ(kOpusScaleNumBins24kHz20ms[i], boundary - prev);
     prev = boundary;
   }
 }

 // Checks that the computed triangular filters weights for the Opus scale are
 // monotonic withing each Opus band. This test should only be enabled when
 // ComputeTriangularFiltersWeights() is changed and |kOpusBandWeights24kHz20ms|
 // is updated accordingly.
 TEST(RnnVadTest, DISABLED_TestOpusScaleWeights) {
   auto weights = ComputeTriangularFiltersWeights();
   size_t i = 0;
   for (size_t band_size : GetOpusScaleNumBins24kHz20ms()) {
     SCOPED_TRACE(band_size);
     rtc::ArrayView<float> band_weights(weights.data() + i, band_size);
     float prev = -1.f;
     for (float weight : band_weights) {
       EXPECT_LT(prev, weight);
       prev = weight;
     }
     i += band_size;
   }
 }

 // Checks that the computed band-wise auto-correlation is non-negative for a
 // simple input vector of FFT coefficients.
 TEST(RnnVadTest, SpectralCorrelatorValidOutput) {
   // Input: vector of (1, 1j) values.
   Pffft fft(kFrameSize20ms24kHz, Pffft::FftType::kReal);
   auto in = fft.CreateBuffer();
   std::array<float, kOpusBands24kHz> out;
   auto in_view = in->GetView();
   std::fill(in_view.begin(), in_view.end(), 1.f);
   in_view[1] = 0.f;  // Nyquist frequency.
   // Compute and check output.
   SpectralCorrelator e;
   e.ComputeAutoCorrelation(in_view, out);
   for (size_t i = 0; i < kOpusBands24kHz; ++i) {
     SCOPED_TRACE(i);
     EXPECT_GT(out[i], 0.f);
   }
 }

 // Checks that the computed smoothed log magnitude spectrum is within tolerance
 // given hard-coded test input data.
 TEST(RnnVadTest, ComputeSmoothedLogMagnitudeSpectrumWithinTolerance) {
   constexpr std::array<float, kNumBands> input = {
       {86.060539245605f, 275.668334960938f, 43.406528472900f, 6.541896820068f,
        17.964015960693f, 8.090919494629f,   1.261920094490f,  1.212702631950f,
        1.619154453278f,  0.508935272694f,   0.346316039562f,  0.237035423517f,
        0.172424271703f,  0.271657168865f,   0.126088857651f,  0.139967113733f,
        0.207200810313f,  0.155893072486f,   0.091090843081f,  0.033391401172f,
        0.013879744336f,  0.011973354965f}};
   constexpr std::array<float, kNumBands> expected_output = {
       {1.934854507446f,  2.440402746201f,  1.637655138969f,  0.816367030144f,
        1.254645109177f,  0.908534288406f,  0.104459829628f,  0.087320849299f,
        0.211962252855f,  -0.284886807203f, -0.448164641857f, -0.607240796089f,
        -0.738917350769f, -0.550279200077f, -0.866177439690f, -0.824003994465f,
        -0.663138568401f, -0.780171751976f, -0.995288193226f, -1.362596273422f,
        -1.621970295906f, -1.658103585243f}};
   std::array<float, kNumBands> computed_output;
   {
     // TODO(bugs.webrtc.org/8948): Add when the issue is fixed.
     // FloatingPointExceptionObserver fpe_observer;
     ComputeSmoothedLogMagnitudeSpectrum(input, computed_output);
     ExpectNearAbsolute(expected_output, computed_output, 1e-5f);
   }
 }

 // Checks that the computed DCT is within tolerance given hard-coded test input
 // data.
 TEST(RnnVadTest, ComputeDctWithinTolerance) {
   constexpr std::array<float, kNumBands> input = {
       {0.232155621052f,  0.678957760334f, 0.220818966627f,  -0.077363930643f,
        -0.559227049351f, 0.432545185089f, 0.353900641203f,  0.398993015289f,
        0.409774333239f,  0.454977899790f, 0.300520688295f,  -0.010286616161f,
        0.272525429726f,  0.098067551851f, 0.083649002016f,  0.046226885170f,
        -0.033228103071f, 0.144773483276f, -0.117661058903f, -0.005628800020f,
        -0.009547689930f, -0.045382082462f}};
   constexpr std::array<float, kNumBands> expected_output = {
       {0.697072803974f,  0.442710995674f,  -0.293156713247f, -0.060711503029f,
        0.292050391436f,  0.489301353693f,  0.402255415916f,  0.134404733777f,
        -0.086305990815f, -0.199605688453f, -0.234511867166f, -0.413774639368f,
        -0.388507157564f, -0.032798115164f, 0.044605545700f,  0.112466648221f,
        -0.050096966326f, 0.045971218497f,  -0.029815061018f, -0.410366982222f,
        -0.209233760834f, -0.128037497401f}};
   auto dct_table = ComputeDctTable();
   std::array<float, kNumBands> computed_output;
   {
     // TODO(bugs.webrtc.org/8948): Add when the issue is fixed.
     // FloatingPointExceptionObserver fpe_observer;
     ComputeDct(input, dct_table, computed_output);
     ExpectNearAbsolute(expected_output, computed_output, 1e-5f);
   }
 }

 }  // namespace test
 }  // namespace rnn_vad
 }  // 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/rnn_vad/spectral_features_internal.h"

	#include <algorithm>
	#include <array>
	#include <complex>
	#include <numeric>
	#include <vector>

	#include "api/array_view.h"
	#include "modules/audio_processing/agc2/rnn_vad/test_utils.h"
	#include "modules/audio_processing/utility/pffft_wrapper.h"
	// TODO(bugs.webrtc.org/8948): Add when the issue is fixed.
	// #include "test/fpe_observer.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace rnn_vad {
	namespace test {
	namespace {

	// Generates the values for the array named \|kOpusBandWeights24kHz20ms\| in the
	// anonymous namespace of the .cc file, which is the array of FFT coefficient
	// weights for the Opus scale triangular filters.
	std::vector<float> ComputeTriangularFiltersWeights() {
	constexpr auto kOpusScaleNumBins24kHz20ms = GetOpusScaleNumBins24kHz20ms();
	const auto& v = kOpusScaleNumBins24kHz20ms; // Alias.
	const size_t num_weights = std::accumulate(
	kOpusScaleNumBins24kHz20ms.begin(), kOpusScaleNumBins24kHz20ms.end(), 0);
	std::vector<float> weights(num_weights);
	size_t next_fft_coeff_index = 0;
	for (size_t band = 0; band < v.size(); ++band) {
	const size_t band_size = v[band];
	for (size_t j = 0; j < band_size; ++j) {
	weights[next_fft_coeff_index + j] = static_cast<float>(j) / band_size;
	}
	next_fft_coeff_index += band_size;
	}
	return weights;
	}

	} // namespace

	// Checks that the values returned by GetOpusScaleNumBins24kHz20ms() match the
	// Opus scale frequency boundaries.
	TEST(RnnVadTest, TestOpusScaleBoundaries) {
	constexpr int kBandFrequencyBoundariesHz[kNumBands - 1] = {
	200, 400, 600, 800, 1000, 1200, 1400, 1600, 2000, 2400, 2800,
	3200, 4000, 4800, 5600, 6800, 8000, 9600, 12000, 15600, 20000};
	constexpr auto kOpusScaleNumBins24kHz20ms = GetOpusScaleNumBins24kHz20ms();
	int prev = 0;
	for (size_t i = 0; i < kOpusScaleNumBins24kHz20ms.size(); ++i) {
	int boundary =
	kBandFrequencyBoundariesHz[i] * kFrameSize20ms24kHz / kSampleRate24kHz;
	EXPECT_EQ(kOpusScaleNumBins24kHz20ms[i], boundary - prev);
	prev = boundary;
	}
	}

	// Checks that the computed triangular filters weights for the Opus scale are
	// monotonic withing each Opus band. This test should only be enabled when
	// ComputeTriangularFiltersWeights() is changed and \|kOpusBandWeights24kHz20ms\|
	// is updated accordingly.
	TEST(RnnVadTest, DISABLED_TestOpusScaleWeights) {
	auto weights = ComputeTriangularFiltersWeights();
	size_t i = 0;
	for (size_t band_size : GetOpusScaleNumBins24kHz20ms()) {
	SCOPED_TRACE(band_size);
	rtc::ArrayView<float> band_weights(weights.data() + i, band_size);
	float prev = -1.f;
	for (float weight : band_weights) {
	EXPECT_LT(prev, weight);
	prev = weight;
	}
	i += band_size;
	}
	}

	// Checks that the computed band-wise auto-correlation is non-negative for a
	// simple input vector of FFT coefficients.
	TEST(RnnVadTest, SpectralCorrelatorValidOutput) {
	// Input: vector of (1, 1j) values.
	Pffft fft(kFrameSize20ms24kHz, Pffft::FftType::kReal);
	auto in = fft.CreateBuffer();
	std::array<float, kOpusBands24kHz> out;
	auto in_view = in->GetView();
	std::fill(in_view.begin(), in_view.end(), 1.f);
	in_view[1] = 0.f; // Nyquist frequency.
	// Compute and check output.
	SpectralCorrelator e;
	e.ComputeAutoCorrelation(in_view, out);
	for (size_t i = 0; i < kOpusBands24kHz; ++i) {
	SCOPED_TRACE(i);
	EXPECT_GT(out[i], 0.f);
	}
	}

	// Checks that the computed smoothed log magnitude spectrum is within tolerance
	// given hard-coded test input data.
	TEST(RnnVadTest, ComputeSmoothedLogMagnitudeSpectrumWithinTolerance) {
	constexpr std::array<float, kNumBands> input = {
	{86.060539245605f, 275.668334960938f, 43.406528472900f, 6.541896820068f,
	17.964015960693f, 8.090919494629f, 1.261920094490f, 1.212702631950f,
	1.619154453278f, 0.508935272694f, 0.346316039562f, 0.237035423517f,
	0.172424271703f, 0.271657168865f, 0.126088857651f, 0.139967113733f,
	0.207200810313f, 0.155893072486f, 0.091090843081f, 0.033391401172f,
	0.013879744336f, 0.011973354965f}};
	constexpr std::array<float, kNumBands> expected_output = {
	{1.934854507446f, 2.440402746201f, 1.637655138969f, 0.816367030144f,
	1.254645109177f, 0.908534288406f, 0.104459829628f, 0.087320849299f,
	0.211962252855f, -0.284886807203f, -0.448164641857f, -0.607240796089f,
	-0.738917350769f, -0.550279200077f, -0.866177439690f, -0.824003994465f,
	-0.663138568401f, -0.780171751976f, -0.995288193226f, -1.362596273422f,
	-1.621970295906f, -1.658103585243f}};
	std::array<float, kNumBands> computed_output;
	{
	// TODO(bugs.webrtc.org/8948): Add when the issue is fixed.
	// FloatingPointExceptionObserver fpe_observer;
	ComputeSmoothedLogMagnitudeSpectrum(input, computed_output);
	ExpectNearAbsolute(expected_output, computed_output, 1e-5f);
	}
	}

	// Checks that the computed DCT is within tolerance given hard-coded test input
	// data.
	TEST(RnnVadTest, ComputeDctWithinTolerance) {
	constexpr std::array<float, kNumBands> input = {
	{0.232155621052f, 0.678957760334f, 0.220818966627f, -0.077363930643f,
	-0.559227049351f, 0.432545185089f, 0.353900641203f, 0.398993015289f,
	0.409774333239f, 0.454977899790f, 0.300520688295f, -0.010286616161f,
	0.272525429726f, 0.098067551851f, 0.083649002016f, 0.046226885170f,
	-0.033228103071f, 0.144773483276f, -0.117661058903f, -0.005628800020f,
	-0.009547689930f, -0.045382082462f}};
	constexpr std::array<float, kNumBands> expected_output = {
	{0.697072803974f, 0.442710995674f, -0.293156713247f, -0.060711503029f,
	0.292050391436f, 0.489301353693f, 0.402255415916f, 0.134404733777f,
	-0.086305990815f, -0.199605688453f, -0.234511867166f, -0.413774639368f,
	-0.388507157564f, -0.032798115164f, 0.044605545700f, 0.112466648221f,
	-0.050096966326f, 0.045971218497f, -0.029815061018f, -0.410366982222f,
	-0.209233760834f, -0.128037497401f}};
	auto dct_table = ComputeDctTable();
	std::array<float, kNumBands> computed_output;
	{
	// TODO(bugs.webrtc.org/8948): Add when the issue is fixed.
	// FloatingPointExceptionObserver fpe_observer;
	ComputeDct(input, dct_table, computed_output);
	ExpectNearAbsolute(expected_output, computed_output, 1e-5f);
	}
	}

	} // namespace test
	} // namespace rnn_vad
	} // namespace webrtc