modules/audio_processing/agc2/rnn_vad/rnn_vad_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 <array>
 #include <memory>
 #include <string>
 #include <vector>

 #include "common_audio/resampler/push_sinc_resampler.h"
 #include "modules/audio_processing/agc2/cpu_features.h"
 #include "modules/audio_processing/agc2/rnn_vad/features_extraction.h"
 #include "modules/audio_processing/agc2/rnn_vad/rnn.h"
 #include "modules/audio_processing/agc2/rnn_vad/test_utils.h"
 #include "modules/audio_processing/test/performance_timer.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/logging.h"
 #include "test/gtest.h"
 #include "third_party/rnnoise/src/rnn_activations.h"
 #include "third_party/rnnoise/src/rnn_vad_weights.h"

 namespace webrtc {
 namespace rnn_vad {
 namespace {

 constexpr int kFrameSize10ms48kHz = 480;

 void DumpPerfStats(int num_samples,
                    int sample_rate,
                    double average_us,
                    double standard_deviation) {
   float audio_track_length_ms =
       1e3f * static_cast<float>(num_samples) / static_cast<float>(sample_rate);
   float average_ms = static_cast<float>(average_us) / 1e3f;
   float speed = audio_track_length_ms / average_ms;
   RTC_LOG(LS_INFO) << "track duration (ms): " << audio_track_length_ms;
   RTC_LOG(LS_INFO) << "average processing time (ms): " << average_ms << " +/- "
                    << (standard_deviation / 1e3);
   RTC_LOG(LS_INFO) << "speed: " << speed << "x";
 }

 // When the RNN VAD model is updated and the expected output changes, set the
 // constant below to true in order to write new expected output binary files.
 constexpr bool kWriteComputedOutputToFile = false;

 // Avoids that one forgets to set |kWriteComputedOutputToFile| back to false
 // when the expected output files are re-exported.
 TEST(RnnVadTest, CheckWriteComputedOutputIsFalse) {
   ASSERT_FALSE(kWriteComputedOutputToFile)
       << "Cannot land if kWriteComputedOutput is true.";
 }

 class RnnVadProbabilityParametrization
     : public ::testing::TestWithParam<AvailableCpuFeatures> {};

 // Checks that the computed VAD probability for a test input sequence sampled at
 // 48 kHz is within tolerance.
 TEST_P(RnnVadProbabilityParametrization, RnnVadProbabilityWithinTolerance) {
   // Init resampler, feature extractor and RNN.
   PushSincResampler decimator(kFrameSize10ms48kHz, kFrameSize10ms24kHz);
   const AvailableCpuFeatures cpu_features = GetParam();
   FeaturesExtractor features_extractor(cpu_features);
   RnnVad rnn_vad(cpu_features);

   // Init input samples and expected output readers.
   std::unique_ptr<FileReader> samples_reader = CreatePcmSamplesReader();
   std::unique_ptr<FileReader> expected_vad_prob_reader = CreateVadProbsReader();

   // Input length. The last incomplete frame is ignored.
   const int num_frames = samples_reader->size() / kFrameSize10ms48kHz;

   // Init buffers.
   std::vector<float> samples_48k(kFrameSize10ms48kHz);
   std::vector<float> samples_24k(kFrameSize10ms24kHz);
   std::vector<float> feature_vector(kFeatureVectorSize);
   std::vector<float> computed_vad_prob(num_frames);
   std::vector<float> expected_vad_prob(num_frames);

   // Read expected output.
   ASSERT_TRUE(expected_vad_prob_reader->ReadChunk(expected_vad_prob));

   // Compute VAD probabilities on the downsampled input.
   float cumulative_error = 0.f;
   for (int i = 0; i < num_frames; ++i) {
     ASSERT_TRUE(samples_reader->ReadChunk(samples_48k));
     decimator.Resample(samples_48k.data(), samples_48k.size(),
                        samples_24k.data(), samples_24k.size());
     bool is_silence = features_extractor.CheckSilenceComputeFeatures(
         {samples_24k.data(), kFrameSize10ms24kHz},
         {feature_vector.data(), kFeatureVectorSize});
     computed_vad_prob[i] = rnn_vad.ComputeVadProbability(
         {feature_vector.data(), kFeatureVectorSize}, is_silence);
     EXPECT_NEAR(computed_vad_prob[i], expected_vad_prob[i], 1e-3f);
     cumulative_error += std::abs(computed_vad_prob[i] - expected_vad_prob[i]);
   }
   // Check average error.
   EXPECT_LT(cumulative_error / num_frames, 1e-4f);

   if (kWriteComputedOutputToFile) {
     FileWriter vad_prob_writer("new_vad_prob.dat");
     vad_prob_writer.WriteChunk(computed_vad_prob);
   }
 }

 // Performance test for the RNN VAD (pre-fetching and downsampling are
 // excluded). Keep disabled and only enable locally to measure performance as
 // follows:
 // - on desktop: run the this unit test adding "--logs";
 // - on android: run the this unit test adding "--logcat-output-file".
 TEST_P(RnnVadProbabilityParametrization, DISABLED_RnnVadPerformance) {
   // PCM samples reader and buffers.
   std::unique_ptr<FileReader> samples_reader = CreatePcmSamplesReader();
   // The last incomplete frame is ignored.
   const int num_frames = samples_reader->size() / kFrameSize10ms48kHz;
   std::array<float, kFrameSize10ms48kHz> samples;
   // Pre-fetch and decimate samples.
   PushSincResampler decimator(kFrameSize10ms48kHz, kFrameSize10ms24kHz);
   std::vector<float> prefetched_decimated_samples;
   prefetched_decimated_samples.resize(num_frames * kFrameSize10ms24kHz);
   for (int i = 0; i < num_frames; ++i) {
     ASSERT_TRUE(samples_reader->ReadChunk(samples));
     decimator.Resample(samples.data(), samples.size(),
                        &prefetched_decimated_samples[i * kFrameSize10ms24kHz],
                        kFrameSize10ms24kHz);
   }
   // Initialize.
   const AvailableCpuFeatures cpu_features = GetParam();
   FeaturesExtractor features_extractor(cpu_features);
   std::array<float, kFeatureVectorSize> feature_vector;
   RnnVad rnn_vad(cpu_features);
   constexpr int number_of_tests = 100;
   ::webrtc::test::PerformanceTimer perf_timer(number_of_tests);
   for (int k = 0; k < number_of_tests; ++k) {
     features_extractor.Reset();
     rnn_vad.Reset();
     // Process frames.
     perf_timer.StartTimer();
     for (int i = 0; i < num_frames; ++i) {
       bool is_silence = features_extractor.CheckSilenceComputeFeatures(
           {&prefetched_decimated_samples[i * kFrameSize10ms24kHz],
            kFrameSize10ms24kHz},
           feature_vector);
       rnn_vad.ComputeVadProbability(feature_vector, is_silence);
     }
     perf_timer.StopTimer();
   }
   DumpPerfStats(num_frames * kFrameSize10ms24kHz, kSampleRate24kHz,
                 perf_timer.GetDurationAverage(),
                 perf_timer.GetDurationStandardDeviation());
 }

 // Finds the relevant CPU features combinations to test.
 std::vector<AvailableCpuFeatures> GetCpuFeaturesToTest() {
   std::vector<AvailableCpuFeatures> v;
   v.push_back(NoAvailableCpuFeatures());
   AvailableCpuFeatures available = GetAvailableCpuFeatures();
   if (available.avx2 && available.sse2) {
     v.push_back({/*sse2=*/true, /*avx2=*/true, /*neon=*/false});
   }
   if (available.sse2) {
     v.push_back({/*sse2=*/true, /*avx2=*/false, /*neon=*/false});
   }
   if (available.neon) {
     v.push_back({/*sse2=*/false, /*avx2=*/false, /*neon=*/true});
   }
   return v;
 }

 INSTANTIATE_TEST_SUITE_P(
     RnnVadTest,
     RnnVadProbabilityParametrization,
     ::testing::ValuesIn(GetCpuFeaturesToTest()),
     [](const ::testing::TestParamInfo<AvailableCpuFeatures>& info) {
       return info.param.ToString();
     });

 }  // namespace
 }  // 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 <array>
	#include <memory>
	#include <string>
	#include <vector>

	#include "common_audio/resampler/push_sinc_resampler.h"
	#include "modules/audio_processing/agc2/cpu_features.h"
	#include "modules/audio_processing/agc2/rnn_vad/features_extraction.h"
	#include "modules/audio_processing/agc2/rnn_vad/rnn.h"
	#include "modules/audio_processing/agc2/rnn_vad/test_utils.h"
	#include "modules/audio_processing/test/performance_timer.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/logging.h"
	#include "test/gtest.h"
	#include "third_party/rnnoise/src/rnn_activations.h"
	#include "third_party/rnnoise/src/rnn_vad_weights.h"

	namespace webrtc {
	namespace rnn_vad {
	namespace {

	constexpr int kFrameSize10ms48kHz = 480;

	void DumpPerfStats(int num_samples,
	int sample_rate,
	double average_us,
	double standard_deviation) {
	float audio_track_length_ms =
	1e3f * static_cast<float>(num_samples) / static_cast<float>(sample_rate);
	float average_ms = static_cast<float>(average_us) / 1e3f;
	float speed = audio_track_length_ms / average_ms;
	RTC_LOG(LS_INFO) << "track duration (ms): " << audio_track_length_ms;
	RTC_LOG(LS_INFO) << "average processing time (ms): " << average_ms << " +/- "
	<< (standard_deviation / 1e3);
	RTC_LOG(LS_INFO) << "speed: " << speed << "x";
	}

	// When the RNN VAD model is updated and the expected output changes, set the
	// constant below to true in order to write new expected output binary files.
	constexpr bool kWriteComputedOutputToFile = false;

	// Avoids that one forgets to set \|kWriteComputedOutputToFile\| back to false
	// when the expected output files are re-exported.
	TEST(RnnVadTest, CheckWriteComputedOutputIsFalse) {
	ASSERT_FALSE(kWriteComputedOutputToFile)
	<< "Cannot land if kWriteComputedOutput is true.";
	}

	class RnnVadProbabilityParametrization
	: public ::testing::TestWithParam<AvailableCpuFeatures> {};

	// Checks that the computed VAD probability for a test input sequence sampled at
	// 48 kHz is within tolerance.
	TEST_P(RnnVadProbabilityParametrization, RnnVadProbabilityWithinTolerance) {
	// Init resampler, feature extractor and RNN.
	PushSincResampler decimator(kFrameSize10ms48kHz, kFrameSize10ms24kHz);
	const AvailableCpuFeatures cpu_features = GetParam();
	FeaturesExtractor features_extractor(cpu_features);
	RnnVad rnn_vad(cpu_features);

	// Init input samples and expected output readers.
	std::unique_ptr<FileReader> samples_reader = CreatePcmSamplesReader();
	std::unique_ptr<FileReader> expected_vad_prob_reader = CreateVadProbsReader();

	// Input length. The last incomplete frame is ignored.
	const int num_frames = samples_reader->size() / kFrameSize10ms48kHz;

	// Init buffers.
	std::vector<float> samples_48k(kFrameSize10ms48kHz);
	std::vector<float> samples_24k(kFrameSize10ms24kHz);
	std::vector<float> feature_vector(kFeatureVectorSize);
	std::vector<float> computed_vad_prob(num_frames);
	std::vector<float> expected_vad_prob(num_frames);

	// Read expected output.
	ASSERT_TRUE(expected_vad_prob_reader->ReadChunk(expected_vad_prob));

	// Compute VAD probabilities on the downsampled input.
	float cumulative_error = 0.f;
	for (int i = 0; i < num_frames; ++i) {
	ASSERT_TRUE(samples_reader->ReadChunk(samples_48k));
	decimator.Resample(samples_48k.data(), samples_48k.size(),
	samples_24k.data(), samples_24k.size());
	bool is_silence = features_extractor.CheckSilenceComputeFeatures(
	{samples_24k.data(), kFrameSize10ms24kHz},
	{feature_vector.data(), kFeatureVectorSize});
	computed_vad_prob[i] = rnn_vad.ComputeVadProbability(
	{feature_vector.data(), kFeatureVectorSize}, is_silence);
	EXPECT_NEAR(computed_vad_prob[i], expected_vad_prob[i], 1e-3f);
	cumulative_error += std::abs(computed_vad_prob[i] - expected_vad_prob[i]);
	}
	// Check average error.
	EXPECT_LT(cumulative_error / num_frames, 1e-4f);

	if (kWriteComputedOutputToFile) {
	FileWriter vad_prob_writer("new_vad_prob.dat");
	vad_prob_writer.WriteChunk(computed_vad_prob);
	}
	}

	// Performance test for the RNN VAD (pre-fetching and downsampling are
	// excluded). Keep disabled and only enable locally to measure performance as
	// follows:
	// - on desktop: run the this unit test adding "--logs";
	// - on android: run the this unit test adding "--logcat-output-file".
	TEST_P(RnnVadProbabilityParametrization, DISABLED_RnnVadPerformance) {
	// PCM samples reader and buffers.
	std::unique_ptr<FileReader> samples_reader = CreatePcmSamplesReader();
	// The last incomplete frame is ignored.
	const int num_frames = samples_reader->size() / kFrameSize10ms48kHz;
	std::array<float, kFrameSize10ms48kHz> samples;
	// Pre-fetch and decimate samples.
	PushSincResampler decimator(kFrameSize10ms48kHz, kFrameSize10ms24kHz);
	std::vector<float> prefetched_decimated_samples;
	prefetched_decimated_samples.resize(num_frames * kFrameSize10ms24kHz);
	for (int i = 0; i < num_frames; ++i) {
	ASSERT_TRUE(samples_reader->ReadChunk(samples));
	decimator.Resample(samples.data(), samples.size(),
	&prefetched_decimated_samples[i * kFrameSize10ms24kHz],
	kFrameSize10ms24kHz);
	}
	// Initialize.
	const AvailableCpuFeatures cpu_features = GetParam();
	FeaturesExtractor features_extractor(cpu_features);
	std::array<float, kFeatureVectorSize> feature_vector;
	RnnVad rnn_vad(cpu_features);
	constexpr int number_of_tests = 100;
	::webrtc::test::PerformanceTimer perf_timer(number_of_tests);
	for (int k = 0; k < number_of_tests; ++k) {
	features_extractor.Reset();
	rnn_vad.Reset();
	// Process frames.
	perf_timer.StartTimer();
	for (int i = 0; i < num_frames; ++i) {
	bool is_silence = features_extractor.CheckSilenceComputeFeatures(
	{&prefetched_decimated_samples[i * kFrameSize10ms24kHz],
	kFrameSize10ms24kHz},
	feature_vector);
	rnn_vad.ComputeVadProbability(feature_vector, is_silence);
	}
	perf_timer.StopTimer();
	}
	DumpPerfStats(num_frames * kFrameSize10ms24kHz, kSampleRate24kHz,
	perf_timer.GetDurationAverage(),
	perf_timer.GetDurationStandardDeviation());
	}

	// Finds the relevant CPU features combinations to test.
	std::vector<AvailableCpuFeatures> GetCpuFeaturesToTest() {
	std::vector<AvailableCpuFeatures> v;
	v.push_back(NoAvailableCpuFeatures());
	AvailableCpuFeatures available = GetAvailableCpuFeatures();
	if (available.avx2 && available.sse2) {
	v.push_back({/sse2=/true, /avx2=/true, /neon=/false});
	}
	if (available.sse2) {
	v.push_back({/sse2=/true, /avx2=/false, /neon=/false});
	}
	if (available.neon) {
	v.push_back({/sse2=/false, /avx2=/false, /neon=/true});
	}
	return v;
	}

	INSTANTIATE_TEST_SUITE_P(
	RnnVadTest,
	RnnVadProbabilityParametrization,
	::testing::ValuesIn(GetCpuFeaturesToTest()),
	[](const ::testing::TestParamInfo<AvailableCpuFeatures>& info) {
	return info.param.ToString();
	});

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