modules/audio_coding/neteq/merge.h - src - Git at Google

 /*
  *  Copyright (c) 2012 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_NETEQ_MERGE_H_
 #define MODULES_AUDIO_CODING_NETEQ_MERGE_H_

 #include "modules/audio_coding/neteq/audio_multi_vector.h"

 namespace webrtc {

 // Forward declarations.
 class Expand;
 class SyncBuffer;

 // This class handles the transition from expansion to normal operation.
 // When a packet is not available for decoding when needed, the expand operation
 // is called to generate extrapolation data. If the missing packet arrives,
 // i.e., it was just delayed, it can be decoded and appended directly to the
 // end of the expanded data (thanks to how the Expand class operates). However,
 // if a later packet arrives instead, the loss is a fact, and the new data must
 // be stitched together with the end of the expanded data. This stitching is
 // what the Merge class does.
 class Merge {
  public:
   Merge(int fs_hz,
         size_t num_channels,
         Expand* expand,
         SyncBuffer* sync_buffer);
   virtual ~Merge();

   Merge(const Merge&) = delete;
   Merge& operator=(const Merge&) = delete;

   // The main method to produce the audio data. The decoded data is supplied in
   // `input`, having `input_length` samples in total for all channels
   // (interleaved). The result is written to `output`. The number of channels
   // allocated in `output` defines the number of channels that will be used when
   // de-interleaving `input`.
   virtual size_t Process(int16_t* input,
                          size_t input_length,
                          AudioMultiVector* output);

   virtual size_t RequiredFutureSamples();

  protected:
   const int fs_hz_;
   const size_t num_channels_;

  private:
   static const int kMaxSampleRate = 48000;
   static const size_t kExpandDownsampLength = 100;
   static const size_t kInputDownsampLength = 40;
   static const size_t kMaxCorrelationLength = 60;

   // Calls `expand_` to get more expansion data to merge with. The data is
   // written to `expanded_signal_`. Returns the length of the expanded data,
   // while `expand_period` will be the number of samples in one expansion period
   // (typically one pitch period). The value of `old_length` will be the number
   // of samples that were taken from the `sync_buffer_`.
   size_t GetExpandedSignal(size_t* old_length, size_t* expand_period);

   // Analyzes `input` and `expanded_signal` and returns muting factor (Q14) to
   // be used on the new data.
   int16_t SignalScaling(const int16_t* input,
                         size_t input_length,
                         const int16_t* expanded_signal) const;

   // Downsamples `input` (`input_length` samples) and `expanded_signal` to
   // 4 kHz sample rate. The downsampled signals are written to
   // `input_downsampled_` and `expanded_downsampled_`, respectively.
   void Downsample(const int16_t* input,
                   size_t input_length,
                   const int16_t* expanded_signal,
                   size_t expanded_length);

   // Calculates cross-correlation between `input_downsampled_` and
   // `expanded_downsampled_`, and finds the correlation maximum. The maximizing
   // lag is returned.
   size_t CorrelateAndPeakSearch(size_t start_position,
                                 size_t input_length,
                                 size_t expand_period) const;

   const int fs_mult_;  // fs_hz_ / 8000.
   const size_t timestamps_per_call_;
   Expand* expand_;
   SyncBuffer* sync_buffer_;
   int16_t expanded_downsampled_[kExpandDownsampLength];
   int16_t input_downsampled_[kInputDownsampLength];
   AudioMultiVector expanded_;
   std::vector<int16_t> temp_data_;
 };

 }  // namespace webrtc
 #endif  // MODULES_AUDIO_CODING_NETEQ_MERGE_H_
	/*
	* Copyright (c) 2012 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_NETEQ_MERGE_H_
	#define MODULES_AUDIO_CODING_NETEQ_MERGE_H_

	#include "modules/audio_coding/neteq/audio_multi_vector.h"

	namespace webrtc {

	// Forward declarations.
	class Expand;
	class SyncBuffer;

	// This class handles the transition from expansion to normal operation.
	// When a packet is not available for decoding when needed, the expand operation
	// is called to generate extrapolation data. If the missing packet arrives,
	// i.e., it was just delayed, it can be decoded and appended directly to the
	// end of the expanded data (thanks to how the Expand class operates). However,
	// if a later packet arrives instead, the loss is a fact, and the new data must
	// be stitched together with the end of the expanded data. This stitching is
	// what the Merge class does.
	class Merge {
	public:
	Merge(int fs_hz,
	size_t num_channels,
	Expand* expand,
	SyncBuffer* sync_buffer);
	virtual ~Merge();

	Merge(const Merge&) = delete;
	Merge& operator=(const Merge&) = delete;

	// The main method to produce the audio data. The decoded data is supplied in
	// `input`, having `input_length` samples in total for all channels
	// (interleaved). The result is written to `output`. The number of channels
	// allocated in `output` defines the number of channels that will be used when
	// de-interleaving `input`.
	virtual size_t Process(int16_t* input,
	size_t input_length,
	AudioMultiVector* output);

	virtual size_t RequiredFutureSamples();

	protected:
	const int fs_hz_;
	const size_t num_channels_;

	private:
	static const int kMaxSampleRate = 48000;
	static const size_t kExpandDownsampLength = 100;
	static const size_t kInputDownsampLength = 40;
	static const size_t kMaxCorrelationLength = 60;

	// Calls `expand_` to get more expansion data to merge with. The data is
	// written to `expanded_signal_`. Returns the length of the expanded data,
	// while `expand_period` will be the number of samples in one expansion period
	// (typically one pitch period). The value of `old_length` will be the number
	// of samples that were taken from the `sync_buffer_`.
	size_t GetExpandedSignal(size_t* old_length, size_t* expand_period);

	// Analyzes `input` and `expanded_signal` and returns muting factor (Q14) to
	// be used on the new data.
	int16_t SignalScaling(const int16_t* input,
	size_t input_length,
	const int16_t* expanded_signal) const;

	// Downsamples `input` (`input_length` samples) and `expanded_signal` to
	// 4 kHz sample rate. The downsampled signals are written to
	// `input_downsampled_` and `expanded_downsampled_`, respectively.
	void Downsample(const int16_t* input,
	size_t input_length,
	const int16_t* expanded_signal,
	size_t expanded_length);

	// Calculates cross-correlation between `input_downsampled_` and
	// `expanded_downsampled_`, and finds the correlation maximum. The maximizing
	// lag is returned.
	size_t CorrelateAndPeakSearch(size_t start_position,
	size_t input_length,
	size_t expand_period) const;

	const int fs_mult_; // fs_hz_ / 8000.
	const size_t timestamps_per_call_;
	Expand* expand_;
	SyncBuffer* sync_buffer_;
	int16_t expanded_downsampled_[kExpandDownsampLength];
	int16_t input_downsampled_[kInputDownsampLength];
	AudioMultiVector expanded_;
	std::vector<int16_t> temp_data_;
	};

	} // namespace webrtc
	#endif // MODULES_AUDIO_CODING_NETEQ_MERGE_H_