webrtc/common_audio/lapped_transform_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2014 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 "webrtc/common_audio/lapped_transform.h"

 #include <algorithm>
 #include <cmath>
 #include <cstring>

 #include "webrtc/test/gtest.h"

 using std::complex;

 namespace {

 class NoopCallback : public webrtc::LappedTransform::Callback {
  public:
   NoopCallback() : block_num_(0) {}

   virtual void ProcessAudioBlock(const complex<float>* const* in_block,
                                  size_t in_channels,
                                  size_t frames,
                                  size_t out_channels,
                                  complex<float>* const* out_block) {
     RTC_CHECK_EQ(in_channels, out_channels);
     for (size_t i = 0; i < out_channels; ++i) {
       memcpy(out_block[i], in_block[i], sizeof(**in_block) * frames);
     }
     ++block_num_;
   }

   size_t block_num() {
     return block_num_;
   }

  private:
   size_t block_num_;
 };

 class FftCheckerCallback : public webrtc::LappedTransform::Callback {
  public:
   FftCheckerCallback() : block_num_(0) {}

   virtual void ProcessAudioBlock(const complex<float>* const* in_block,
                                  size_t in_channels,
                                  size_t frames,
                                  size_t out_channels,
                                  complex<float>* const* out_block) {
     RTC_CHECK_EQ(in_channels, out_channels);

     size_t full_length = (frames - 1) * 2;
     ++block_num_;

     if (block_num_ > 0) {
       ASSERT_NEAR(in_block[0][0].real(), static_cast<float>(full_length),
                   1e-5f);
       ASSERT_NEAR(in_block[0][0].imag(), 0.0f, 1e-5f);
       for (size_t i = 1; i < frames; ++i) {
         ASSERT_NEAR(in_block[0][i].real(), 0.0f, 1e-5f);
         ASSERT_NEAR(in_block[0][i].imag(), 0.0f, 1e-5f);
       }
     }
   }

   size_t block_num() {
     return block_num_;
   }

  private:
   size_t block_num_;
 };

 void SetFloatArray(float value, int rows, int cols, float* const* array) {
   for (int i = 0; i < rows; ++i) {
     for (int j = 0; j < cols; ++j) {
       array[i][j] = value;
     }
   }
 }

 }  // namespace

 namespace webrtc {

 TEST(LappedTransformTest, Windowless) {
   const size_t kChannels = 3;
   const size_t kChunkLength = 512;
   const size_t kBlockLength = 64;
   const size_t kShiftAmount = 64;
   NoopCallback noop;

   // Rectangular window.
   float window[kBlockLength];
   std::fill(window, &window[kBlockLength], 1.0f);

   LappedTransform trans(kChannels, kChannels, kChunkLength, window,
                         kBlockLength, kShiftAmount, &noop);
   float in_buffer[kChannels][kChunkLength];
   float* in_chunk[kChannels];
   float out_buffer[kChannels][kChunkLength];
   float* out_chunk[kChannels];

   in_chunk[0] = in_buffer[0];
   in_chunk[1] = in_buffer[1];
   in_chunk[2] = in_buffer[2];
   out_chunk[0] = out_buffer[0];
   out_chunk[1] = out_buffer[1];
   out_chunk[2] = out_buffer[2];
   SetFloatArray(2.0f, kChannels, kChunkLength, in_chunk);
   SetFloatArray(-1.0f, kChannels, kChunkLength, out_chunk);

   trans.ProcessChunk(in_chunk, out_chunk);

   for (size_t i = 0; i < kChannels; ++i) {
     for (size_t j = 0; j < kChunkLength; ++j) {
       ASSERT_NEAR(out_chunk[i][j], 2.0f, 1e-5f);
     }
   }

   ASSERT_EQ(kChunkLength / kBlockLength, noop.block_num());
 }

 TEST(LappedTransformTest, IdentityProcessor) {
   const size_t kChunkLength = 512;
   const size_t kBlockLength = 64;
   const size_t kShiftAmount = 32;
   NoopCallback noop;

   // Identity window for |overlap = block_size / 2|.
   float window[kBlockLength];
   std::fill(window, &window[kBlockLength], std::sqrt(0.5f));

   LappedTransform trans(1, 1, kChunkLength, window, kBlockLength, kShiftAmount,
                         &noop);
   float in_buffer[kChunkLength];
   float* in_chunk = in_buffer;
   float out_buffer[kChunkLength];
   float* out_chunk = out_buffer;

   SetFloatArray(2.0f, 1, kChunkLength, &in_chunk);
   SetFloatArray(-1.0f, 1, kChunkLength, &out_chunk);

   trans.ProcessChunk(&in_chunk, &out_chunk);

   for (size_t i = 0; i < kChunkLength; ++i) {
     ASSERT_NEAR(out_chunk[i],
                 (i < kBlockLength - kShiftAmount) ? 0.0f : 2.0f,
                 1e-5f);
   }

   ASSERT_EQ(kChunkLength / kShiftAmount, noop.block_num());
 }

 TEST(LappedTransformTest, Callbacks) {
   const size_t kChunkLength = 512;
   const size_t kBlockLength = 64;
   FftCheckerCallback call;

   // Rectangular window.
   float window[kBlockLength];
   std::fill(window, &window[kBlockLength], 1.0f);

   LappedTransform trans(1, 1, kChunkLength, window, kBlockLength,
                         kBlockLength, &call);
   float in_buffer[kChunkLength];
   float* in_chunk = in_buffer;
   float out_buffer[kChunkLength];
   float* out_chunk = out_buffer;

   SetFloatArray(1.0f, 1, kChunkLength, &in_chunk);
   SetFloatArray(-1.0f, 1, kChunkLength, &out_chunk);

   trans.ProcessChunk(&in_chunk, &out_chunk);

   ASSERT_EQ(kChunkLength / kBlockLength, call.block_num());
 }

 TEST(LappedTransformTest, chunk_length) {
   const size_t kBlockLength = 64;
   FftCheckerCallback call;
   const float window[kBlockLength] = {};

   // Make sure that chunk_length returns the same value passed to the
   // LappedTransform constructor.
   {
     const size_t kExpectedChunkLength = 512;
     const LappedTransform trans(1, 1, kExpectedChunkLength, window,
                                 kBlockLength, kBlockLength, &call);

     EXPECT_EQ(kExpectedChunkLength, trans.chunk_length());
   }
   {
     const size_t kExpectedChunkLength = 160;
     const LappedTransform trans(1, 1, kExpectedChunkLength, window,
                                 kBlockLength, kBlockLength, &call);

     EXPECT_EQ(kExpectedChunkLength, trans.chunk_length());
   }
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2014 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 "webrtc/common_audio/lapped_transform.h"

	#include <algorithm>
	#include <cmath>
	#include <cstring>

	#include "webrtc/test/gtest.h"

	using std::complex;

	namespace {

	class NoopCallback : public webrtc::LappedTransform::Callback {
	public:
	NoopCallback() : block_num_(0) {}

	virtual void ProcessAudioBlock(const complex<float>* const* in_block,
	size_t in_channels,
	size_t frames,
	size_t out_channels,
	complex<float>* const* out_block) {
	RTC_CHECK_EQ(in_channels, out_channels);
	for (size_t i = 0; i < out_channels; ++i) {
	memcpy(out_block[i], in_block[i], sizeof(*in_block) frames);
	}
	++block_num_;
	}

	size_t block_num() {
	return block_num_;
	}

	private:
	size_t block_num_;
	};

	class FftCheckerCallback : public webrtc::LappedTransform::Callback {
	public:
	FftCheckerCallback() : block_num_(0) {}

	virtual void ProcessAudioBlock(const complex<float>* const* in_block,
	size_t in_channels,
	size_t frames,
	size_t out_channels,
	complex<float>* const* out_block) {
	RTC_CHECK_EQ(in_channels, out_channels);

	size_t full_length = (frames - 1) * 2;
	++block_num_;

	if (block_num_ > 0) {
	ASSERT_NEAR(in_block[0][0].real(), static_cast<float>(full_length),
	1e-5f);
	ASSERT_NEAR(in_block[0][0].imag(), 0.0f, 1e-5f);
	for (size_t i = 1; i < frames; ++i) {
	ASSERT_NEAR(in_block[0][i].real(), 0.0f, 1e-5f);
	ASSERT_NEAR(in_block[0][i].imag(), 0.0f, 1e-5f);
	}
	}
	}

	size_t block_num() {
	return block_num_;
	}

	private:
	size_t block_num_;
	};

	void SetFloatArray(float value, int rows, int cols, float* const* array) {
	for (int i = 0; i < rows; ++i) {
	for (int j = 0; j < cols; ++j) {
	array[i][j] = value;
	}
	}
	}

	} // namespace

	namespace webrtc {

	TEST(LappedTransformTest, Windowless) {
	const size_t kChannels = 3;
	const size_t kChunkLength = 512;
	const size_t kBlockLength = 64;
	const size_t kShiftAmount = 64;
	NoopCallback noop;

	// Rectangular window.
	float window[kBlockLength];
	std::fill(window, &window[kBlockLength], 1.0f);

	LappedTransform trans(kChannels, kChannels, kChunkLength, window,
	kBlockLength, kShiftAmount, &noop);
	float in_buffer[kChannels][kChunkLength];
	float* in_chunk[kChannels];
	float out_buffer[kChannels][kChunkLength];
	float* out_chunk[kChannels];

	in_chunk[0] = in_buffer[0];
	in_chunk[1] = in_buffer[1];
	in_chunk[2] = in_buffer[2];
	out_chunk[0] = out_buffer[0];
	out_chunk[1] = out_buffer[1];
	out_chunk[2] = out_buffer[2];
	SetFloatArray(2.0f, kChannels, kChunkLength, in_chunk);
	SetFloatArray(-1.0f, kChannels, kChunkLength, out_chunk);

	trans.ProcessChunk(in_chunk, out_chunk);

	for (size_t i = 0; i < kChannels; ++i) {
	for (size_t j = 0; j < kChunkLength; ++j) {
	ASSERT_NEAR(out_chunk[i][j], 2.0f, 1e-5f);
	}
	}

	ASSERT_EQ(kChunkLength / kBlockLength, noop.block_num());
	}

	TEST(LappedTransformTest, IdentityProcessor) {
	const size_t kChunkLength = 512;
	const size_t kBlockLength = 64;
	const size_t kShiftAmount = 32;
	NoopCallback noop;

	// Identity window for \|overlap = block_size / 2\|.
	float window[kBlockLength];
	std::fill(window, &window[kBlockLength], std::sqrt(0.5f));

	LappedTransform trans(1, 1, kChunkLength, window, kBlockLength, kShiftAmount,
	&noop);
	float in_buffer[kChunkLength];
	float* in_chunk = in_buffer;
	float out_buffer[kChunkLength];
	float* out_chunk = out_buffer;

	SetFloatArray(2.0f, 1, kChunkLength, &in_chunk);
	SetFloatArray(-1.0f, 1, kChunkLength, &out_chunk);

	trans.ProcessChunk(&in_chunk, &out_chunk);

	for (size_t i = 0; i < kChunkLength; ++i) {
	ASSERT_NEAR(out_chunk[i],
	(i < kBlockLength - kShiftAmount) ? 0.0f : 2.0f,
	1e-5f);
	}

	ASSERT_EQ(kChunkLength / kShiftAmount, noop.block_num());
	}

	TEST(LappedTransformTest, Callbacks) {
	const size_t kChunkLength = 512;
	const size_t kBlockLength = 64;
	FftCheckerCallback call;

	// Rectangular window.
	float window[kBlockLength];
	std::fill(window, &window[kBlockLength], 1.0f);

	LappedTransform trans(1, 1, kChunkLength, window, kBlockLength,
	kBlockLength, &call);
	float in_buffer[kChunkLength];
	float* in_chunk = in_buffer;
	float out_buffer[kChunkLength];
	float* out_chunk = out_buffer;

	SetFloatArray(1.0f, 1, kChunkLength, &in_chunk);
	SetFloatArray(-1.0f, 1, kChunkLength, &out_chunk);

	trans.ProcessChunk(&in_chunk, &out_chunk);

	ASSERT_EQ(kChunkLength / kBlockLength, call.block_num());
	}

	TEST(LappedTransformTest, chunk_length) {
	const size_t kBlockLength = 64;
	FftCheckerCallback call;
	const float window[kBlockLength] = {};

	// Make sure that chunk_length returns the same value passed to the
	// LappedTransform constructor.
	{
	const size_t kExpectedChunkLength = 512;
	const LappedTransform trans(1, 1, kExpectedChunkLength, window,
	kBlockLength, kBlockLength, &call);

	EXPECT_EQ(kExpectedChunkLength, trans.chunk_length());
	}
	{
	const size_t kExpectedChunkLength = 160;
	const LappedTransform trans(1, 1, kExpectedChunkLength, window,
	kBlockLength, kBlockLength, &call);

	EXPECT_EQ(kExpectedChunkLength, trans.chunk_length());
	}
	}

	} // namespace webrtc