common_audio/resampler/sinc_resampler_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2013 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.
  */

 // Modified from the Chromium original:
 // src/media/base/sinc_resampler_unittest.cc

 // MSVC++ requires this to be set before any other includes to get M_PI.
 #define _USE_MATH_DEFINES

 #include "common_audio/resampler/sinc_resampler.h"

 #include <math.h>

 #include <algorithm>
 #include <memory>
 #include <tuple>

 #include "common_audio/resampler/sinusoidal_linear_chirp_source.h"
 #include "rtc_base/system/arch.h"
 #include "rtc_base/time_utils.h"
 #include "system_wrappers/include/cpu_features_wrapper.h"
 #include "test/gmock.h"
 #include "test/gtest.h"

 using ::testing::_;

 namespace webrtc {

 static const double kSampleRateRatio = 192000.0 / 44100.0;
 static const double kKernelInterpolationFactor = 0.5;

 // Helper class to ensure ChunkedResample() functions properly.
 class MockSource : public SincResamplerCallback {
  public:
   MOCK_METHOD(void, Run, (size_t frames, float* destination), (override));
 };

 ACTION(ClearBuffer) {
   memset(arg1, 0, arg0 * sizeof(float));
 }

 ACTION(FillBuffer) {
   // Value chosen arbitrarily such that SincResampler resamples it to something
   // easily representable on all platforms; e.g., using kSampleRateRatio this
   // becomes 1.81219.
   memset(arg1, 64, arg0 * sizeof(float));
 }

 // Test requesting multiples of ChunkSize() frames results in the proper number
 // of callbacks.
 TEST(SincResamplerTest, ChunkedResample) {
   MockSource mock_source;

   // Choose a high ratio of input to output samples which will result in quick
   // exhaustion of SincResampler's internal buffers.
   SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
                           &mock_source);

   static const int kChunks = 2;
   size_t max_chunk_size = resampler.ChunkSize() * kChunks;
   std::unique_ptr<float[]> resampled_destination(new float[max_chunk_size]);

   // Verify requesting ChunkSize() frames causes a single callback.
   EXPECT_CALL(mock_source, Run(_, _)).Times(1).WillOnce(ClearBuffer());
   resampler.Resample(resampler.ChunkSize(), resampled_destination.get());

   // Verify requesting kChunks * ChunkSize() frames causes kChunks callbacks.
   ::testing::Mock::VerifyAndClear(&mock_source);
   EXPECT_CALL(mock_source, Run(_, _))
       .Times(kChunks)
       .WillRepeatedly(ClearBuffer());
   resampler.Resample(max_chunk_size, resampled_destination.get());
 }

 // Test flush resets the internal state properly.
 TEST(SincResamplerTest, Flush) {
   MockSource mock_source;
   SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
                           &mock_source);
   std::unique_ptr<float[]> resampled_destination(
       new float[resampler.ChunkSize()]);

   // Fill the resampler with junk data.
   EXPECT_CALL(mock_source, Run(_, _)).Times(1).WillOnce(FillBuffer());
   resampler.Resample(resampler.ChunkSize() / 2, resampled_destination.get());
   ASSERT_NE(resampled_destination[0], 0);

   // Flush and request more data, which should all be zeros now.
   resampler.Flush();
   ::testing::Mock::VerifyAndClear(&mock_source);
   EXPECT_CALL(mock_source, Run(_, _)).Times(1).WillOnce(ClearBuffer());
   resampler.Resample(resampler.ChunkSize() / 2, resampled_destination.get());
   for (size_t i = 0; i < resampler.ChunkSize() / 2; ++i)
     ASSERT_FLOAT_EQ(resampled_destination[i], 0);
 }

 // Test flush resets the internal state properly.
 TEST(SincResamplerTest, DISABLED_SetRatioBench) {
   MockSource mock_source;
   SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
                           &mock_source);

   int64_t start = rtc::TimeNanos();
   for (int i = 1; i < 10000; ++i)
     resampler.SetRatio(1.0 / i);
   double total_time_c_us =
       (rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
   printf("SetRatio() took %.2fms.\n", total_time_c_us / 1000);
 }

 // Ensure various optimized Convolve() methods return the same value.  Only run
 // this test if other optimized methods exist, otherwise the default Convolve()
 // will be tested by the parameterized SincResampler tests below.
 TEST(SincResamplerTest, Convolve) {
 #if defined(WEBRTC_ARCH_X86_FAMILY)
   ASSERT_TRUE(GetCPUInfo(kSSE2));
 #elif defined(WEBRTC_ARCH_ARM_V7)
   ASSERT_TRUE(GetCPUFeaturesARM() & kCPUFeatureNEON);
 #endif

   // Initialize a dummy resampler.
   MockSource mock_source;
   SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
                           &mock_source);

   // The optimized Convolve methods are slightly more precise than Convolve_C(),
   // so comparison must be done using an epsilon.
   static const double kEpsilon = 0.00000005;

   // Use a kernel from SincResampler as input and kernel data, this has the
   // benefit of already being properly sized and aligned for Convolve_SSE().
   double result = resampler.Convolve_C(
       resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
       resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   double result2 = resampler.convolve_proc_(
       resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
       resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   EXPECT_NEAR(result2, result, kEpsilon);

   // Test Convolve() w/ unaligned input pointer.
   result = resampler.Convolve_C(
       resampler.kernel_storage_.get() + 1, resampler.kernel_storage_.get(),
       resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   result2 = resampler.convolve_proc_(
       resampler.kernel_storage_.get() + 1, resampler.kernel_storage_.get(),
       resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   EXPECT_NEAR(result2, result, kEpsilon);
 }

 // Benchmark for the various Convolve() methods.  Make sure to build with
 // branding=Chrome so that RTC_DCHECKs are compiled out when benchmarking.
 // Original benchmarks were run with --convolve-iterations=50000000.
 TEST(SincResamplerTest, ConvolveBenchmark) {
   // Initialize a dummy resampler.
   MockSource mock_source;
   SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
                           &mock_source);

   // Retrieve benchmark iterations from command line.
   // TODO(ajm): Reintroduce this as a command line option.
   const int kConvolveIterations = 1000000;

   printf("Benchmarking %d iterations:\n", kConvolveIterations);

   // Benchmark Convolve_C().
   int64_t start = rtc::TimeNanos();
   for (int i = 0; i < kConvolveIterations; ++i) {
     resampler.Convolve_C(
         resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
         resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   }
   double total_time_c_us =
       (rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
   printf("Convolve_C took %.2fms.\n", total_time_c_us / 1000);

 #if defined(WEBRTC_ARCH_X86_FAMILY)
   ASSERT_TRUE(GetCPUInfo(kSSE2));
 #elif defined(WEBRTC_ARCH_ARM_V7)
   ASSERT_TRUE(GetCPUFeaturesARM() & kCPUFeatureNEON);
 #endif

   // Benchmark with unaligned input pointer.
   start = rtc::TimeNanos();
   for (int j = 0; j < kConvolveIterations; ++j) {
     resampler.convolve_proc_(
         resampler.kernel_storage_.get() + 1, resampler.kernel_storage_.get(),
         resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   }
   double total_time_optimized_unaligned_us =
       (rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
   printf(
       "convolve_proc_(unaligned) took %.2fms; which is %.2fx "
       "faster than Convolve_C.\n",
       total_time_optimized_unaligned_us / 1000,
       total_time_c_us / total_time_optimized_unaligned_us);

   // Benchmark with aligned input pointer.
   start = rtc::TimeNanos();
   for (int j = 0; j < kConvolveIterations; ++j) {
     resampler.convolve_proc_(
         resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
         resampler.kernel_storage_.get(), kKernelInterpolationFactor);
   }
   double total_time_optimized_aligned_us =
       (rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
   printf(
       "convolve_proc_ (aligned) took %.2fms; which is %.2fx "
       "faster than Convolve_C and %.2fx faster than "
       "convolve_proc_ (unaligned).\n",
       total_time_optimized_aligned_us / 1000,
       total_time_c_us / total_time_optimized_aligned_us,
       total_time_optimized_unaligned_us / total_time_optimized_aligned_us);
 }

 typedef std::tuple<int, int, double, double> SincResamplerTestData;
 class SincResamplerTest
     : public ::testing::TestWithParam<SincResamplerTestData> {
  public:
   SincResamplerTest()
       : input_rate_(std::get<0>(GetParam())),
         output_rate_(std::get<1>(GetParam())),
         rms_error_(std::get<2>(GetParam())),
         low_freq_error_(std::get<3>(GetParam())) {}

   virtual ~SincResamplerTest() {}

  protected:
   int input_rate_;
   int output_rate_;
   double rms_error_;
   double low_freq_error_;
 };

 // Tests resampling using a given input and output sample rate.
 TEST_P(SincResamplerTest, Resample) {
   // Make comparisons using one second of data.
   static const double kTestDurationSecs = 1;
   const size_t input_samples =
       static_cast<size_t>(kTestDurationSecs * input_rate_);
   const size_t output_samples =
       static_cast<size_t>(kTestDurationSecs * output_rate_);

   // Nyquist frequency for the input sampling rate.
   const double input_nyquist_freq = 0.5 * input_rate_;

   // Source for data to be resampled.
   SinusoidalLinearChirpSource resampler_source(input_rate_, input_samples,
                                                input_nyquist_freq, 0);

   const double io_ratio = input_rate_ / static_cast<double>(output_rate_);
   SincResampler resampler(io_ratio, SincResampler::kDefaultRequestSize,
                           &resampler_source);

   // Force an update to the sample rate ratio to ensure dynamic sample rate
   // changes are working correctly.
   std::unique_ptr<float[]> kernel(new float[SincResampler::kKernelStorageSize]);
   memcpy(kernel.get(), resampler.get_kernel_for_testing(),
          SincResampler::kKernelStorageSize);
   resampler.SetRatio(M_PI);
   ASSERT_NE(0, memcmp(kernel.get(), resampler.get_kernel_for_testing(),
                       SincResampler::kKernelStorageSize));
   resampler.SetRatio(io_ratio);
   ASSERT_EQ(0, memcmp(kernel.get(), resampler.get_kernel_for_testing(),
                       SincResampler::kKernelStorageSize));

   // TODO(dalecurtis): If we switch to AVX/SSE optimization, we'll need to
   // allocate these on 32-byte boundaries and ensure they're sized % 32 bytes.
   std::unique_ptr<float[]> resampled_destination(new float[output_samples]);
   std::unique_ptr<float[]> pure_destination(new float[output_samples]);

   // Generate resampled signal.
   resampler.Resample(output_samples, resampled_destination.get());

   // Generate pure signal.
   SinusoidalLinearChirpSource pure_source(output_rate_, output_samples,
                                           input_nyquist_freq, 0);
   pure_source.Run(output_samples, pure_destination.get());

   // Range of the Nyquist frequency (0.5 * min(input rate, output_rate)) which
   // we refer to as low and high.
   static const double kLowFrequencyNyquistRange = 0.7;
   static const double kHighFrequencyNyquistRange = 0.9;

   // Calculate Root-Mean-Square-Error and maximum error for the resampling.
   double sum_of_squares = 0;
   double low_freq_max_error = 0;
   double high_freq_max_error = 0;
   int minimum_rate = std::min(input_rate_, output_rate_);
   double low_frequency_range = kLowFrequencyNyquistRange * 0.5 * minimum_rate;
   double high_frequency_range = kHighFrequencyNyquistRange * 0.5 * minimum_rate;
   for (size_t i = 0; i < output_samples; ++i) {
     double error = fabs(resampled_destination[i] - pure_destination[i]);

     if (pure_source.Frequency(i) < low_frequency_range) {
       if (error > low_freq_max_error)
         low_freq_max_error = error;
     } else if (pure_source.Frequency(i) < high_frequency_range) {
       if (error > high_freq_max_error)
         high_freq_max_error = error;
     }
     // TODO(dalecurtis): Sanity check frequencies > kHighFrequencyNyquistRange.

     sum_of_squares += error * error;
   }

   double rms_error = sqrt(sum_of_squares / output_samples);

 // Convert each error to dbFS.
 #define DBFS(x) 20 * log10(x)
   rms_error = DBFS(rms_error);
   low_freq_max_error = DBFS(low_freq_max_error);
   high_freq_max_error = DBFS(high_freq_max_error);

   EXPECT_LE(rms_error, rms_error_);
   EXPECT_LE(low_freq_max_error, low_freq_error_);

   // All conversions currently have a high frequency error around -6 dbFS.
   static const double kHighFrequencyMaxError = -6.02;
   EXPECT_LE(high_freq_max_error, kHighFrequencyMaxError);
 }

 // Almost all conversions have an RMS error of around -14 dbFS.
 static const double kResamplingRMSError = -14.58;

 // Thresholds chosen arbitrarily based on what each resampling reported during
 // testing.  All thresholds are in dbFS, http://en.wikipedia.org/wiki/DBFS.
 INSTANTIATE_TEST_SUITE_P(
     SincResamplerTest,
     SincResamplerTest,
     ::testing::Values(
         // To 22.05kHz
         std::make_tuple(8000, 22050, kResamplingRMSError, -62.73),
         std::make_tuple(11025, 22050, kResamplingRMSError, -72.19),
         std::make_tuple(16000, 22050, kResamplingRMSError, -62.54),
         std::make_tuple(22050, 22050, kResamplingRMSError, -73.53),
         std::make_tuple(32000, 22050, kResamplingRMSError, -46.45),
         std::make_tuple(44100, 22050, kResamplingRMSError, -28.49),
         std::make_tuple(48000, 22050, -15.01, -25.56),
         std::make_tuple(96000, 22050, -18.49, -13.42),
         std::make_tuple(192000, 22050, -20.50, -9.23),

         // To 44.1kHz
         std::make_tuple(8000, 44100, kResamplingRMSError, -62.73),
         std::make_tuple(11025, 44100, kResamplingRMSError, -72.19),
         std::make_tuple(16000, 44100, kResamplingRMSError, -62.54),
         std::make_tuple(22050, 44100, kResamplingRMSError, -73.53),
         std::make_tuple(32000, 44100, kResamplingRMSError, -63.32),
         std::make_tuple(44100, 44100, kResamplingRMSError, -73.52),
         std::make_tuple(48000, 44100, -15.01, -64.04),
         std::make_tuple(96000, 44100, -18.49, -25.51),
         std::make_tuple(192000, 44100, -20.50, -13.31),

         // To 48kHz
         std::make_tuple(8000, 48000, kResamplingRMSError, -63.43),
         std::make_tuple(11025, 48000, kResamplingRMSError, -62.61),
         std::make_tuple(16000, 48000, kResamplingRMSError, -63.95),
         std::make_tuple(22050, 48000, kResamplingRMSError, -62.42),
         std::make_tuple(32000, 48000, kResamplingRMSError, -64.04),
         std::make_tuple(44100, 48000, kResamplingRMSError, -62.63),
         std::make_tuple(48000, 48000, kResamplingRMSError, -73.52),
         std::make_tuple(96000, 48000, -18.40, -28.44),
         std::make_tuple(192000, 48000, -20.43, -14.11),

         // To 96kHz
         std::make_tuple(8000, 96000, kResamplingRMSError, -63.19),
         std::make_tuple(11025, 96000, kResamplingRMSError, -62.61),
         std::make_tuple(16000, 96000, kResamplingRMSError, -63.39),
         std::make_tuple(22050, 96000, kResamplingRMSError, -62.42),
         std::make_tuple(32000, 96000, kResamplingRMSError, -63.95),
         std::make_tuple(44100, 96000, kResamplingRMSError, -62.63),
         std::make_tuple(48000, 96000, kResamplingRMSError, -73.52),
         std::make_tuple(96000, 96000, kResamplingRMSError, -73.52),
         std::make_tuple(192000, 96000, kResamplingRMSError, -28.41),

         // To 192kHz
         std::make_tuple(8000, 192000, kResamplingRMSError, -63.10),
         std::make_tuple(11025, 192000, kResamplingRMSError, -62.61),
         std::make_tuple(16000, 192000, kResamplingRMSError, -63.14),
         std::make_tuple(22050, 192000, kResamplingRMSError, -62.42),
         std::make_tuple(32000, 192000, kResamplingRMSError, -63.38),
         std::make_tuple(44100, 192000, kResamplingRMSError, -62.63),
         std::make_tuple(48000, 192000, kResamplingRMSError, -73.44),
         std::make_tuple(96000, 192000, kResamplingRMSError, -73.52),
         std::make_tuple(192000, 192000, kResamplingRMSError, -73.52)));

 }  // namespace webrtc
	/*
	* Copyright (c) 2013 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.
	*/

	// Modified from the Chromium original:
	// src/media/base/sinc_resampler_unittest.cc

	// MSVC++ requires this to be set before any other includes to get M_PI.
	#define _USE_MATH_DEFINES

	#include "common_audio/resampler/sinc_resampler.h"

	#include <math.h>

	#include <algorithm>
	#include <memory>
	#include <tuple>

	#include "common_audio/resampler/sinusoidal_linear_chirp_source.h"
	#include "rtc_base/system/arch.h"
	#include "rtc_base/time_utils.h"
	#include "system_wrappers/include/cpu_features_wrapper.h"
	#include "test/gmock.h"
	#include "test/gtest.h"

	using ::testing::_;

	namespace webrtc {

	static const double kSampleRateRatio = 192000.0 / 44100.0;
	static const double kKernelInterpolationFactor = 0.5;

	// Helper class to ensure ChunkedResample() functions properly.
	class MockSource : public SincResamplerCallback {
	public:
	MOCK_METHOD(void, Run, (size_t frames, float* destination), (override));
	};

	ACTION(ClearBuffer) {
	memset(arg1, 0, arg0 * sizeof(float));
	}

	ACTION(FillBuffer) {
	// Value chosen arbitrarily such that SincResampler resamples it to something
	// easily representable on all platforms; e.g., using kSampleRateRatio this
	// becomes 1.81219.
	memset(arg1, 64, arg0 * sizeof(float));
	}

	// Test requesting multiples of ChunkSize() frames results in the proper number
	// of callbacks.
	TEST(SincResamplerTest, ChunkedResample) {
	MockSource mock_source;

	// Choose a high ratio of input to output samples which will result in quick
	// exhaustion of SincResampler's internal buffers.
	SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
	&mock_source);

	static const int kChunks = 2;
	size_t max_chunk_size = resampler.ChunkSize() * kChunks;
	std::unique_ptr<float[]> resampled_destination(new float[max_chunk_size]);

	// Verify requesting ChunkSize() frames causes a single callback.
	EXPECT_CALL(mock_source, Run(_, _)).Times(1).WillOnce(ClearBuffer());
	resampler.Resample(resampler.ChunkSize(), resampled_destination.get());

	// Verify requesting kChunks * ChunkSize() frames causes kChunks callbacks.
	::testing::Mock::VerifyAndClear(&mock_source);
	EXPECT_CALL(mock_source, Run(_, _))
	.Times(kChunks)
	.WillRepeatedly(ClearBuffer());
	resampler.Resample(max_chunk_size, resampled_destination.get());
	}

	// Test flush resets the internal state properly.
	TEST(SincResamplerTest, Flush) {
	MockSource mock_source;
	SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
	&mock_source);
	std::unique_ptr<float[]> resampled_destination(
	new float[resampler.ChunkSize()]);

	// Fill the resampler with junk data.
	EXPECT_CALL(mock_source, Run(_, _)).Times(1).WillOnce(FillBuffer());
	resampler.Resample(resampler.ChunkSize() / 2, resampled_destination.get());
	ASSERT_NE(resampled_destination[0], 0);

	// Flush and request more data, which should all be zeros now.
	resampler.Flush();
	::testing::Mock::VerifyAndClear(&mock_source);
	EXPECT_CALL(mock_source, Run(_, _)).Times(1).WillOnce(ClearBuffer());
	resampler.Resample(resampler.ChunkSize() / 2, resampled_destination.get());
	for (size_t i = 0; i < resampler.ChunkSize() / 2; ++i)
	ASSERT_FLOAT_EQ(resampled_destination[i], 0);
	}

	// Test flush resets the internal state properly.
	TEST(SincResamplerTest, DISABLED_SetRatioBench) {
	MockSource mock_source;
	SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
	&mock_source);

	int64_t start = rtc::TimeNanos();
	for (int i = 1; i < 10000; ++i)
	resampler.SetRatio(1.0 / i);
	double total_time_c_us =
	(rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
	printf("SetRatio() took %.2fms.\n", total_time_c_us / 1000);
	}

	// Ensure various optimized Convolve() methods return the same value. Only run
	// this test if other optimized methods exist, otherwise the default Convolve()
	// will be tested by the parameterized SincResampler tests below.
	TEST(SincResamplerTest, Convolve) {
	#if defined(WEBRTC_ARCH_X86_FAMILY)
	ASSERT_TRUE(GetCPUInfo(kSSE2));
	#elif defined(WEBRTC_ARCH_ARM_V7)
	ASSERT_TRUE(GetCPUFeaturesARM() & kCPUFeatureNEON);
	#endif

	// Initialize a dummy resampler.
	MockSource mock_source;
	SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
	&mock_source);

	// The optimized Convolve methods are slightly more precise than Convolve_C(),
	// so comparison must be done using an epsilon.
	static const double kEpsilon = 0.00000005;

	// Use a kernel from SincResampler as input and kernel data, this has the
	// benefit of already being properly sized and aligned for Convolve_SSE().
	double result = resampler.Convolve_C(
	resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	double result2 = resampler.convolve_proc_(
	resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	EXPECT_NEAR(result2, result, kEpsilon);

	// Test Convolve() w/ unaligned input pointer.
	result = resampler.Convolve_C(
	resampler.kernel_storage_.get() + 1, resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	result2 = resampler.convolve_proc_(
	resampler.kernel_storage_.get() + 1, resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	EXPECT_NEAR(result2, result, kEpsilon);
	}

	// Benchmark for the various Convolve() methods. Make sure to build with
	// branding=Chrome so that RTC_DCHECKs are compiled out when benchmarking.
	// Original benchmarks were run with --convolve-iterations=50000000.
	TEST(SincResamplerTest, ConvolveBenchmark) {
	// Initialize a dummy resampler.
	MockSource mock_source;
	SincResampler resampler(kSampleRateRatio, SincResampler::kDefaultRequestSize,
	&mock_source);

	// Retrieve benchmark iterations from command line.
	// TODO(ajm): Reintroduce this as a command line option.
	const int kConvolveIterations = 1000000;

	printf("Benchmarking %d iterations:\n", kConvolveIterations);

	// Benchmark Convolve_C().
	int64_t start = rtc::TimeNanos();
	for (int i = 0; i < kConvolveIterations; ++i) {
	resampler.Convolve_C(
	resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	}
	double total_time_c_us =
	(rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
	printf("Convolve_C took %.2fms.\n", total_time_c_us / 1000);

	#if defined(WEBRTC_ARCH_X86_FAMILY)
	ASSERT_TRUE(GetCPUInfo(kSSE2));
	#elif defined(WEBRTC_ARCH_ARM_V7)
	ASSERT_TRUE(GetCPUFeaturesARM() & kCPUFeatureNEON);
	#endif

	// Benchmark with unaligned input pointer.
	start = rtc::TimeNanos();
	for (int j = 0; j < kConvolveIterations; ++j) {
	resampler.convolve_proc_(
	resampler.kernel_storage_.get() + 1, resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	}
	double total_time_optimized_unaligned_us =
	(rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
	printf(
	"convolve_proc_(unaligned) took %.2fms; which is %.2fx "
	"faster than Convolve_C.\n",
	total_time_optimized_unaligned_us / 1000,
	total_time_c_us / total_time_optimized_unaligned_us);

	// Benchmark with aligned input pointer.
	start = rtc::TimeNanos();
	for (int j = 0; j < kConvolveIterations; ++j) {
	resampler.convolve_proc_(
	resampler.kernel_storage_.get(), resampler.kernel_storage_.get(),
	resampler.kernel_storage_.get(), kKernelInterpolationFactor);
	}
	double total_time_optimized_aligned_us =
	(rtc::TimeNanos() - start) / rtc::kNumNanosecsPerMicrosec;
	printf(
	"convolve_proc_ (aligned) took %.2fms; which is %.2fx "
	"faster than Convolve_C and %.2fx faster than "
	"convolve_proc_ (unaligned).\n",
	total_time_optimized_aligned_us / 1000,
	total_time_c_us / total_time_optimized_aligned_us,
	total_time_optimized_unaligned_us / total_time_optimized_aligned_us);
	}

	typedef std::tuple<int, int, double, double> SincResamplerTestData;
	class SincResamplerTest
	: public ::testing::TestWithParam<SincResamplerTestData> {
	public:
	SincResamplerTest()
	: input_rate_(std::get<0>(GetParam())),
	output_rate_(std::get<1>(GetParam())),
	rms_error_(std::get<2>(GetParam())),
	low_freq_error_(std::get<3>(GetParam())) {}

	virtual ~SincResamplerTest() {}

	protected:
	int input_rate_;
	int output_rate_;
	double rms_error_;
	double low_freq_error_;
	};

	// Tests resampling using a given input and output sample rate.
	TEST_P(SincResamplerTest, Resample) {
	// Make comparisons using one second of data.
	static const double kTestDurationSecs = 1;
	const size_t input_samples =
	static_cast<size_t>(kTestDurationSecs * input_rate_);
	const size_t output_samples =
	static_cast<size_t>(kTestDurationSecs * output_rate_);

	// Nyquist frequency for the input sampling rate.
	const double input_nyquist_freq = 0.5 * input_rate_;

	// Source for data to be resampled.
	SinusoidalLinearChirpSource resampler_source(input_rate_, input_samples,
	input_nyquist_freq, 0);

	const double io_ratio = input_rate_ / static_cast<double>(output_rate_);
	SincResampler resampler(io_ratio, SincResampler::kDefaultRequestSize,
	&resampler_source);

	// Force an update to the sample rate ratio to ensure dynamic sample rate
	// changes are working correctly.
	std::unique_ptr<float[]> kernel(new float[SincResampler::kKernelStorageSize]);
	memcpy(kernel.get(), resampler.get_kernel_for_testing(),
	SincResampler::kKernelStorageSize);
	resampler.SetRatio(M_PI);
	ASSERT_NE(0, memcmp(kernel.get(), resampler.get_kernel_for_testing(),
	SincResampler::kKernelStorageSize));
	resampler.SetRatio(io_ratio);
	ASSERT_EQ(0, memcmp(kernel.get(), resampler.get_kernel_for_testing(),
	SincResampler::kKernelStorageSize));

	// TODO(dalecurtis): If we switch to AVX/SSE optimization, we'll need to
	// allocate these on 32-byte boundaries and ensure they're sized % 32 bytes.
	std::unique_ptr<float[]> resampled_destination(new float[output_samples]);
	std::unique_ptr<float[]> pure_destination(new float[output_samples]);

	// Generate resampled signal.
	resampler.Resample(output_samples, resampled_destination.get());

	// Generate pure signal.
	SinusoidalLinearChirpSource pure_source(output_rate_, output_samples,
	input_nyquist_freq, 0);
	pure_source.Run(output_samples, pure_destination.get());

	// Range of the Nyquist frequency (0.5 * min(input rate, output_rate)) which
	// we refer to as low and high.
	static const double kLowFrequencyNyquistRange = 0.7;
	static const double kHighFrequencyNyquistRange = 0.9;

	// Calculate Root-Mean-Square-Error and maximum error for the resampling.
	double sum_of_squares = 0;
	double low_freq_max_error = 0;
	double high_freq_max_error = 0;
	int minimum_rate = std::min(input_rate_, output_rate_);
	double low_frequency_range = kLowFrequencyNyquistRange * 0.5 * minimum_rate;
	double high_frequency_range = kHighFrequencyNyquistRange * 0.5 * minimum_rate;
	for (size_t i = 0; i < output_samples; ++i) {
	double error = fabs(resampled_destination[i] - pure_destination[i]);

	if (pure_source.Frequency(i) < low_frequency_range) {
	if (error > low_freq_max_error)
	low_freq_max_error = error;
	} else if (pure_source.Frequency(i) < high_frequency_range) {
	if (error > high_freq_max_error)
	high_freq_max_error = error;
	}
	// TODO(dalecurtis): Sanity check frequencies > kHighFrequencyNyquistRange.

	sum_of_squares += error * error;
	}

	double rms_error = sqrt(sum_of_squares / output_samples);

	// Convert each error to dbFS.
	#define DBFS(x) 20 * log10(x)
	rms_error = DBFS(rms_error);
	low_freq_max_error = DBFS(low_freq_max_error);
	high_freq_max_error = DBFS(high_freq_max_error);

	EXPECT_LE(rms_error, rms_error_);
	EXPECT_LE(low_freq_max_error, low_freq_error_);

	// All conversions currently have a high frequency error around -6 dbFS.
	static const double kHighFrequencyMaxError = -6.02;
	EXPECT_LE(high_freq_max_error, kHighFrequencyMaxError);
	}

	// Almost all conversions have an RMS error of around -14 dbFS.
	static const double kResamplingRMSError = -14.58;

	// Thresholds chosen arbitrarily based on what each resampling reported during
	// testing. All thresholds are in dbFS, http://en.wikipedia.org/wiki/DBFS.
	INSTANTIATE_TEST_SUITE_P(
	SincResamplerTest,
	SincResamplerTest,
	::testing::Values(
	// To 22.05kHz
	std::make_tuple(8000, 22050, kResamplingRMSError, -62.73),
	std::make_tuple(11025, 22050, kResamplingRMSError, -72.19),
	std::make_tuple(16000, 22050, kResamplingRMSError, -62.54),
	std::make_tuple(22050, 22050, kResamplingRMSError, -73.53),
	std::make_tuple(32000, 22050, kResamplingRMSError, -46.45),
	std::make_tuple(44100, 22050, kResamplingRMSError, -28.49),
	std::make_tuple(48000, 22050, -15.01, -25.56),
	std::make_tuple(96000, 22050, -18.49, -13.42),
	std::make_tuple(192000, 22050, -20.50, -9.23),

	// To 44.1kHz
	std::make_tuple(8000, 44100, kResamplingRMSError, -62.73),
	std::make_tuple(11025, 44100, kResamplingRMSError, -72.19),
	std::make_tuple(16000, 44100, kResamplingRMSError, -62.54),
	std::make_tuple(22050, 44100, kResamplingRMSError, -73.53),
	std::make_tuple(32000, 44100, kResamplingRMSError, -63.32),
	std::make_tuple(44100, 44100, kResamplingRMSError, -73.52),
	std::make_tuple(48000, 44100, -15.01, -64.04),
	std::make_tuple(96000, 44100, -18.49, -25.51),
	std::make_tuple(192000, 44100, -20.50, -13.31),

	// To 48kHz
	std::make_tuple(8000, 48000, kResamplingRMSError, -63.43),
	std::make_tuple(11025, 48000, kResamplingRMSError, -62.61),
	std::make_tuple(16000, 48000, kResamplingRMSError, -63.95),
	std::make_tuple(22050, 48000, kResamplingRMSError, -62.42),
	std::make_tuple(32000, 48000, kResamplingRMSError, -64.04),
	std::make_tuple(44100, 48000, kResamplingRMSError, -62.63),
	std::make_tuple(48000, 48000, kResamplingRMSError, -73.52),
	std::make_tuple(96000, 48000, -18.40, -28.44),
	std::make_tuple(192000, 48000, -20.43, -14.11),

	// To 96kHz
	std::make_tuple(8000, 96000, kResamplingRMSError, -63.19),
	std::make_tuple(11025, 96000, kResamplingRMSError, -62.61),
	std::make_tuple(16000, 96000, kResamplingRMSError, -63.39),
	std::make_tuple(22050, 96000, kResamplingRMSError, -62.42),
	std::make_tuple(32000, 96000, kResamplingRMSError, -63.95),
	std::make_tuple(44100, 96000, kResamplingRMSError, -62.63),
	std::make_tuple(48000, 96000, kResamplingRMSError, -73.52),
	std::make_tuple(96000, 96000, kResamplingRMSError, -73.52),
	std::make_tuple(192000, 96000, kResamplingRMSError, -28.41),

	// To 192kHz
	std::make_tuple(8000, 192000, kResamplingRMSError, -63.10),
	std::make_tuple(11025, 192000, kResamplingRMSError, -62.61),
	std::make_tuple(16000, 192000, kResamplingRMSError, -63.14),
	std::make_tuple(22050, 192000, kResamplingRMSError, -62.42),
	std::make_tuple(32000, 192000, kResamplingRMSError, -63.38),
	std::make_tuple(44100, 192000, kResamplingRMSError, -62.63),
	std::make_tuple(48000, 192000, kResamplingRMSError, -73.44),
	std::make_tuple(96000, 192000, kResamplingRMSError, -73.52),
	std::make_tuple(192000, 192000, kResamplingRMSError, -73.52)));

	} // namespace webrtc