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/*
* 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.
*/
#ifndef MODULES_AUDIO_CODING_CODECS_OPUS_TEST_LAPPED_TRANSFORM_H_
#define MODULES_AUDIO_CODING_CODECS_OPUS_TEST_LAPPED_TRANSFORM_H_
#include <complex>
#include <memory>
#include "common_audio/real_fourier.h"
#include "modules/audio_coding/codecs/opus/test/blocker.h"
#include "rtc_base/memory/aligned_malloc.h"
namespace webrtc {
// Wrapper class for aligned arrays. Every row (and the first dimension) are
// aligned to the given byte alignment.
template <typename T>
class AlignedArray {
public:
AlignedArray(size_t rows, size_t cols, size_t alignment)
: rows_(rows), cols_(cols) {
RTC_CHECK_GT(alignment, 0);
head_row_ =
static_cast<T**>(AlignedMalloc(rows_ * sizeof(*head_row_), alignment));
for (size_t i = 0; i < rows_; ++i) {
head_row_[i] = static_cast<T*>(
AlignedMalloc(cols_ * sizeof(**head_row_), alignment));
}
}
~AlignedArray() {
for (size_t i = 0; i < rows_; ++i) {
AlignedFree(head_row_[i]);
}
AlignedFree(head_row_);
}
T* const* Array() { return head_row_; }
const T* const* Array() const { return head_row_; }
T* Row(size_t row) {
RTC_CHECK_LE(row, rows_);
return head_row_[row];
}
const T* Row(size_t row) const {
RTC_CHECK_LE(row, rows_);
return head_row_[row];
}
private:
size_t rows_;
size_t cols_;
T** head_row_;
};
// Helper class for audio processing modules which operate on frequency domain
// input derived from the windowed time domain audio stream.
//
// The input audio chunk is sliced into possibly overlapping blocks, multiplied
// by a window and transformed with an FFT implementation. The transformed data
// is supplied to the given callback for processing. The processed output is
// then inverse transformed into the time domain and spliced back into a chunk
// which constitutes the final output of this processing module.
class LappedTransform {
public:
class Callback {
public:
virtual ~Callback() {}
virtual void ProcessAudioBlock(const std::complex<float>* const* in_block,
size_t num_in_channels,
size_t frames,
size_t num_out_channels,
std::complex<float>* const* out_block) = 0;
};
// Construct a transform instance. `chunk_length` is the number of samples in
// each channel. `window` defines the window, owned by the caller (a copy is
// made internally); `window` should have length equal to `block_length`.
// `block_length` defines the length of a block, in samples.
// `shift_amount` is in samples. `callback` is the caller-owned audio
// processing function called for each block of the input chunk.
LappedTransform(size_t num_in_channels,
size_t num_out_channels,
size_t chunk_length,
const float* window,
size_t block_length,
size_t shift_amount,
Callback* callback);
~LappedTransform();
// Main audio processing helper method. Internally slices `in_chunk` into
// blocks, transforms them to frequency domain, calls the callback for each
// block and returns a de-blocked time domain chunk of audio through
// `out_chunk`. Both buffers are caller-owned.
void ProcessChunk(const float* const* in_chunk, float* const* out_chunk);
// Get the chunk length.
//
// The chunk length is the number of samples per channel that must be passed
// to ProcessChunk via the parameter in_chunk.
//
// Returns the same chunk_length passed to the LappedTransform constructor.
size_t chunk_length() const { return chunk_length_; }
// Get the number of input channels.
//
// This is the number of arrays that must be passed to ProcessChunk via
// in_chunk.
//
// Returns the same num_in_channels passed to the LappedTransform constructor.
size_t num_in_channels() const { return num_in_channels_; }
// Get the number of output channels.
//
// This is the number of arrays that must be passed to ProcessChunk via
// out_chunk.
//
// Returns the same num_out_channels passed to the LappedTransform
// constructor.
size_t num_out_channels() const { return num_out_channels_; }
// Returns the initial delay.
//
// This is the delay introduced by the `blocker_` to be able to get and return
// chunks of `chunk_length`, but process blocks of `block_length`.
size_t initial_delay() const { return blocker_.initial_delay(); }
private:
// Internal middleware callback, given to the blocker. Transforms each block
// and hands it over to the processing method given at construction time.
class BlockThunk : public BlockerCallback {
public:
explicit BlockThunk(LappedTransform* parent) : parent_(parent) {}
void ProcessBlock(const float* const* input,
size_t num_frames,
size_t num_input_channels,
size_t num_output_channels,
float* const* output) override;
private:
LappedTransform* const parent_;
} blocker_callback_;
const size_t num_in_channels_;
const size_t num_out_channels_;
const size_t block_length_;
const size_t chunk_length_;
Callback* const block_processor_;
Blocker blocker_;
// TODO(alessiob): Replace RealFourier with a different FFT library.
std::unique_ptr<RealFourier> fft_;
const size_t cplx_length_;
AlignedArray<float> real_buf_;
AlignedArray<std::complex<float> > cplx_pre_;
AlignedArray<std::complex<float> > cplx_post_;
};
} // namespace webrtc
#endif // MODULES_AUDIO_CODING_CODECS_OPUS_TEST_LAPPED_TRANSFORM_H_