modules/audio_processing/agc2/rnn_vad/rnn_gru_unittest.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 /*
  *  Copyright (c) 2020 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/rnn_gru.h"

 #include <array>
 #include <memory>
 #include <vector>

 #include "api/array_view.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_vad_weights.h"

 namespace webrtc {
 namespace rnn_vad {
 namespace {

 void TestGatedRecurrentLayer(
     GatedRecurrentLayer& gru,
     rtc::ArrayView<const float> input_sequence,
     rtc::ArrayView<const float> expected_output_sequence) {
   const int input_sequence_length = rtc::CheckedDivExact(
       rtc::dchecked_cast<int>(input_sequence.size()), gru.input_size());
   const int output_sequence_length = rtc::CheckedDivExact(
       rtc::dchecked_cast<int>(expected_output_sequence.size()), gru.size());
   ASSERT_EQ(input_sequence_length, output_sequence_length)
       << "The test data length is invalid.";
   // Feed the GRU layer and check the output at every step.
   gru.Reset();
   for (int i = 0; i < input_sequence_length; ++i) {
     SCOPED_TRACE(i);
     gru.ComputeOutput(
         input_sequence.subview(i * gru.input_size(), gru.input_size()));
     const auto expected_output =
         expected_output_sequence.subview(i * gru.size(), gru.size());
     ExpectNearAbsolute(expected_output, gru, 3e-6f);
   }
 }

 // Gated recurrent units layer test data.
 constexpr int kGruInputSize = 5;
 constexpr int kGruOutputSize = 4;
 constexpr std::array<int8_t, 12> kGruBias = {96,   -99, -81, -114, 49,  119,
                                              -118, 68,  -76, 91,   121, 125};
 constexpr std::array<int8_t, 60> kGruWeights = {
     // Input 0.
     124, 9, 1, 116,        // Update.
     -66, -21, -118, -110,  // Reset.
     104, 75, -23, -51,     // Output.
     // Input 1.
     -72, -111, 47, 93,   // Update.
     77, -98, 41, -8,     // Reset.
     40, -23, -43, -107,  // Output.
     // Input 2.
     9, -73, 30, -32,      // Update.
     -2, 64, -26, 91,      // Reset.
     -48, -24, -28, -104,  // Output.
     // Input 3.
     74, -46, 116, 15,    // Update.
     32, 52, -126, -38,   // Reset.
     -121, 12, -16, 110,  // Output.
     // Input 4.
     -95, 66, -103, -35,  // Update.
     -38, 3, -126, -61,   // Reset.
     28, 98, -117, -43    // Output.
 };
 constexpr std::array<int8_t, 48> kGruRecurrentWeights = {
     // Output 0.
     -3, 87, 50, 51,     // Update.
     -22, 27, -39, 62,   // Reset.
     31, -83, -52, -48,  // Output.
     // Output 1.
     -6, 83, -19, 104,  // Update.
     105, 48, 23, 68,   // Reset.
     23, 40, 7, -120,   // Output.
     // Output 2.
     64, -62, 117, 85,     // Update.
     51, -43, 54, -105,    // Reset.
     120, 56, -128, -107,  // Output.
     // Output 3.
     39, 50, -17, -47,   // Update.
     -117, 14, 108, 12,  // Reset.
     -7, -72, 103, -87,  // Output.
 };
 constexpr std::array<float, 20> kGruInputSequence = {
     0.89395463f, 0.93224651f, 0.55788344f, 0.32341808f, 0.93355054f,
     0.13475326f, 0.97370994f, 0.14253306f, 0.93710381f, 0.76093364f,
     0.65780413f, 0.41657975f, 0.49403164f, 0.46843281f, 0.75138855f,
     0.24517593f, 0.47657707f, 0.57064998f, 0.435184f,   0.19319285f};
 constexpr std::array<float, 16> kGruExpectedOutputSequence = {
     0.0239123f,  0.5773077f,  0.f,         0.f,
     0.01282811f, 0.64330572f, 0.f,         0.04863098f,
     0.00781069f, 0.75267816f, 0.f,         0.02579715f,
     0.00471378f, 0.59162533f, 0.11087593f, 0.01334511f};

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

 // Checks that the output of a GRU layer is within tolerance given test input
 // data.
 TEST_P(RnnGruParametrization, CheckGatedRecurrentLayer) {
   GatedRecurrentLayer gru(kGruInputSize, kGruOutputSize, kGruBias, kGruWeights,
                           kGruRecurrentWeights,
                           /*cpu_features=*/GetParam(),
                           /*layer_name=*/"GRU");
   TestGatedRecurrentLayer(gru, kGruInputSequence, kGruExpectedOutputSequence);
 }

 TEST_P(RnnGruParametrization, DISABLED_BenchmarkGatedRecurrentLayer) {
   // Prefetch test data.
   std::unique_ptr<FileReader> reader = CreateGruInputReader();
   std::vector<float> gru_input_sequence(reader->size());
   reader->ReadChunk(gru_input_sequence);

   using ::rnnoise::kHiddenGruBias;
   using ::rnnoise::kHiddenGruRecurrentWeights;
   using ::rnnoise::kHiddenGruWeights;
   using ::rnnoise::kHiddenLayerOutputSize;
   using ::rnnoise::kInputLayerOutputSize;

   GatedRecurrentLayer gru(kInputLayerOutputSize, kHiddenLayerOutputSize,
                           kHiddenGruBias, kHiddenGruWeights,
                           kHiddenGruRecurrentWeights,
                           /*cpu_features=*/GetParam(),
                           /*layer_name=*/"GRU");

   rtc::ArrayView<const float> input_sequence(gru_input_sequence);
   ASSERT_EQ(input_sequence.size() % kInputLayerOutputSize,
             static_cast<size_t>(0));
   const int input_sequence_length =
       input_sequence.size() / kInputLayerOutputSize;

   constexpr int kNumTests = 100;
   ::webrtc::test::PerformanceTimer perf_timer(kNumTests);
   for (int k = 0; k < kNumTests; ++k) {
     perf_timer.StartTimer();
     for (int i = 0; i < input_sequence_length; ++i) {
       gru.ComputeOutput(
           input_sequence.subview(i * gru.input_size(), gru.input_size()));
     }
     perf_timer.StopTimer();
   }
   RTC_LOG(LS_INFO) << (perf_timer.GetDurationAverage() / 1000) << " +/- "
                    << (perf_timer.GetDurationStandardDeviation() / 1000)
                    << " ms";
 }

 // 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.sse2) {
     v.push_back({/*sse2=*/true, /*avx2=*/false, /*neon=*/false});
   }
   if (available.avx2) {
     v.push_back({/*sse2=*/false, /*avx2=*/true, /*neon=*/false});
   }
   if (available.neon) {
     v.push_back({/*sse2=*/false, /*avx2=*/false, /*neon=*/true});
   }
   return v;
 }

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

 }  // namespace
 }  // namespace rnn_vad
 }  // namespace webrtc
	/*
	* Copyright (c) 2020 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/rnn_gru.h"

	#include <array>
	#include <memory>
	#include <vector>

	#include "api/array_view.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_vad_weights.h"

	namespace webrtc {
	namespace rnn_vad {
	namespace {

	void TestGatedRecurrentLayer(
	GatedRecurrentLayer& gru,
	rtc::ArrayView<const float> input_sequence,
	rtc::ArrayView<const float> expected_output_sequence) {
	const int input_sequence_length = rtc::CheckedDivExact(
	rtc::dchecked_cast<int>(input_sequence.size()), gru.input_size());
	const int output_sequence_length = rtc::CheckedDivExact(
	rtc::dchecked_cast<int>(expected_output_sequence.size()), gru.size());
	ASSERT_EQ(input_sequence_length, output_sequence_length)
	<< "The test data length is invalid.";
	// Feed the GRU layer and check the output at every step.
	gru.Reset();
	for (int i = 0; i < input_sequence_length; ++i) {
	SCOPED_TRACE(i);
	gru.ComputeOutput(
	input_sequence.subview(i * gru.input_size(), gru.input_size()));
	const auto expected_output =
	expected_output_sequence.subview(i * gru.size(), gru.size());
	ExpectNearAbsolute(expected_output, gru, 3e-6f);
	}
	}

	// Gated recurrent units layer test data.
	constexpr int kGruInputSize = 5;
	constexpr int kGruOutputSize = 4;
	constexpr std::array<int8_t, 12> kGruBias = {96, -99, -81, -114, 49, 119,
	-118, 68, -76, 91, 121, 125};
	constexpr std::array<int8_t, 60> kGruWeights = {
	// Input 0.
	124, 9, 1, 116, // Update.
	-66, -21, -118, -110, // Reset.
	104, 75, -23, -51, // Output.
	// Input 1.
	-72, -111, 47, 93, // Update.
	77, -98, 41, -8, // Reset.
	40, -23, -43, -107, // Output.
	// Input 2.
	9, -73, 30, -32, // Update.
	-2, 64, -26, 91, // Reset.
	-48, -24, -28, -104, // Output.
	// Input 3.
	74, -46, 116, 15, // Update.
	32, 52, -126, -38, // Reset.
	-121, 12, -16, 110, // Output.
	// Input 4.
	-95, 66, -103, -35, // Update.
	-38, 3, -126, -61, // Reset.
	28, 98, -117, -43 // Output.
	};
	constexpr std::array<int8_t, 48> kGruRecurrentWeights = {
	// Output 0.
	-3, 87, 50, 51, // Update.
	-22, 27, -39, 62, // Reset.
	31, -83, -52, -48, // Output.
	// Output 1.
	-6, 83, -19, 104, // Update.
	105, 48, 23, 68, // Reset.
	23, 40, 7, -120, // Output.
	// Output 2.
	64, -62, 117, 85, // Update.
	51, -43, 54, -105, // Reset.
	120, 56, -128, -107, // Output.
	// Output 3.
	39, 50, -17, -47, // Update.
	-117, 14, 108, 12, // Reset.
	-7, -72, 103, -87, // Output.
	};
	constexpr std::array<float, 20> kGruInputSequence = {
	0.89395463f, 0.93224651f, 0.55788344f, 0.32341808f, 0.93355054f,
	0.13475326f, 0.97370994f, 0.14253306f, 0.93710381f, 0.76093364f,
	0.65780413f, 0.41657975f, 0.49403164f, 0.46843281f, 0.75138855f,
	0.24517593f, 0.47657707f, 0.57064998f, 0.435184f, 0.19319285f};
	constexpr std::array<float, 16> kGruExpectedOutputSequence = {
	0.0239123f, 0.5773077f, 0.f, 0.f,
	0.01282811f, 0.64330572f, 0.f, 0.04863098f,
	0.00781069f, 0.75267816f, 0.f, 0.02579715f,
	0.00471378f, 0.59162533f, 0.11087593f, 0.01334511f};

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

	// Checks that the output of a GRU layer is within tolerance given test input
	// data.
	TEST_P(RnnGruParametrization, CheckGatedRecurrentLayer) {
	GatedRecurrentLayer gru(kGruInputSize, kGruOutputSize, kGruBias, kGruWeights,
	kGruRecurrentWeights,
	/cpu_features=/GetParam(),
	/layer_name=/"GRU");
	TestGatedRecurrentLayer(gru, kGruInputSequence, kGruExpectedOutputSequence);
	}

	TEST_P(RnnGruParametrization, DISABLED_BenchmarkGatedRecurrentLayer) {
	// Prefetch test data.
	std::unique_ptr<FileReader> reader = CreateGruInputReader();
	std::vector<float> gru_input_sequence(reader->size());
	reader->ReadChunk(gru_input_sequence);

	using ::rnnoise::kHiddenGruBias;
	using ::rnnoise::kHiddenGruRecurrentWeights;
	using ::rnnoise::kHiddenGruWeights;
	using ::rnnoise::kHiddenLayerOutputSize;
	using ::rnnoise::kInputLayerOutputSize;

	GatedRecurrentLayer gru(kInputLayerOutputSize, kHiddenLayerOutputSize,
	kHiddenGruBias, kHiddenGruWeights,
	kHiddenGruRecurrentWeights,
	/cpu_features=/GetParam(),
	/layer_name=/"GRU");

	rtc::ArrayView<const float> input_sequence(gru_input_sequence);
	ASSERT_EQ(input_sequence.size() % kInputLayerOutputSize,
	static_cast<size_t>(0));
	const int input_sequence_length =
	input_sequence.size() / kInputLayerOutputSize;

	constexpr int kNumTests = 100;
	::webrtc::test::PerformanceTimer perf_timer(kNumTests);
	for (int k = 0; k < kNumTests; ++k) {
	perf_timer.StartTimer();
	for (int i = 0; i < input_sequence_length; ++i) {
	gru.ComputeOutput(
	input_sequence.subview(i * gru.input_size(), gru.input_size()));
	}
	perf_timer.StopTimer();
	}
	RTC_LOG(LS_INFO) << (perf_timer.GetDurationAverage() / 1000) << " +/- "
	<< (perf_timer.GetDurationStandardDeviation() / 1000)
	<< " ms";
	}

	// 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.sse2) {
	v.push_back({/sse2=/true, /avx2=/false, /neon=/false});
	}
	if (available.avx2) {
	v.push_back({/sse2=/false, /avx2=/true, /neon=/false});
	}
	if (available.neon) {
	v.push_back({/sse2=/false, /avx2=/false, /neon=/true});
	}
	return v;
	}

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

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