/* * 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/blocker.h" #include #include "webrtc/base/checks.h" namespace { // Adds |a| and |b| frame by frame into |result| (basically matrix addition). void AddFrames(const float* const* a, int a_start_index, const float* const* b, int b_start_index, int num_frames, int num_channels, float* const* result, int result_start_index) { for (int i = 0; i < num_channels; ++i) { for (int j = 0; j < num_frames; ++j) { result[i][j + result_start_index] = a[i][j + a_start_index] + b[i][j + b_start_index]; } } } // Copies |src| into |dst| channel by channel. void CopyFrames(const float* const* src, int src_start_index, int num_frames, int num_channels, float* const* dst, int dst_start_index) { for (int i = 0; i < num_channels; ++i) { memcpy(&dst[i][dst_start_index], &src[i][src_start_index], num_frames * sizeof(float)); } } void ZeroOut(float* const* buffer, int starting_idx, int num_frames, int num_channels) { for (int i = 0; i < num_channels; ++i) { memset(&buffer[i][starting_idx], 0, num_frames * sizeof(float)); } } // Pointwise multiplies each channel of |frames| with |window|. Results are // stored in |frames|. void ApplyWindow(const float* window, int num_frames, int num_channels, float* const* frames) { for (int i = 0; i < num_channels; ++i) { for (int j = 0; j < num_frames; ++j) { frames[i][j] = frames[i][j] * window[j]; } } } } // namespace namespace webrtc { Blocker::Blocker(int chunk_size, int block_size, int num_input_channels, int num_output_channels, const float* window, int shift_amount, BlockerCallback* callback) : chunk_size_(chunk_size), block_size_(block_size), num_input_channels_(num_input_channels), num_output_channels_(num_output_channels), initial_delay_(block_size_), frame_offset_(0), input_buffer_(chunk_size_ + initial_delay_, num_input_channels_), output_buffer_(chunk_size_ + initial_delay_, num_output_channels_), input_block_(block_size_, num_input_channels_), output_block_(block_size_, num_output_channels_), window_(new float[block_size_]), shift_amount_(shift_amount), callback_(callback) { CHECK_LE(num_output_channels_, num_input_channels_); CHECK_GE(chunk_size_, block_size_); memcpy(window_.get(), window, block_size_ * sizeof(float)); size_t buffer_size = chunk_size_ + initial_delay_; memset(input_buffer_.channels()[0], 0, buffer_size * num_input_channels_ * sizeof(float)); memset(output_buffer_.channels()[0], 0, buffer_size * num_output_channels_ * sizeof(float)); } // Both the input and output buffers look like this: // // delay* chunk_size chunk_size + delay* // buffer: <-------------|---------------------|---------------|> // _a_ _b_ _c_ // // On each call to ProcessChunk(): // 1. New input gets read into sections _b_ and _c_ of the input buffer. // 2. We block starting from frame_offset. // 3. We block until we reach a block |bl| that doesn't contain any frames // from sections _a_ or _b_ of the input buffer. // 4. We window the current block, fire the callback for processing, window // again, and overlap/add to the output buffer. // 5. We copy sections _a_ and _b_ of the output buffer into output. // 6. For both the input and the output buffers, we copy section c into // section a. // 7. We set the new frame_offset to be the difference between the first frame // of |bl| and the border between sections _b_ and _c_. // // * delay here refers to inintial_delay_ // // TODO(claguna): Look at using ring buffers to eliminate some copies. void Blocker::ProcessChunk(const float* const* input, int chunk_size, int num_input_channels, int num_output_channels, float* const* output) { CHECK_EQ(chunk_size, chunk_size_); CHECK_EQ(num_input_channels, num_input_channels_); CHECK_EQ(num_output_channels, num_output_channels_); // Copy new data into input buffer at // [|initial_delay_|, |chunk_size_| + |initial_delay_|]. CopyFrames(input, 0, chunk_size_, num_input_channels_, input_buffer_.channels(), initial_delay_); int first_frame_in_block = frame_offset_; // Loop through blocks. while (first_frame_in_block < chunk_size_) { CopyFrames(input_buffer_.channels(), first_frame_in_block, block_size_, num_input_channels_, input_block_.channels(), 0); ApplyWindow(window_.get(), block_size_, num_input_channels_, input_block_.channels()); callback_->ProcessBlock(input_block_.channels(), block_size_, num_input_channels_, num_output_channels_, output_block_.channels()); ApplyWindow(window_.get(), block_size_, num_output_channels_, output_block_.channels()); AddFrames(output_buffer_.channels(), first_frame_in_block, output_block_.channels(), 0, block_size_, num_output_channels_, output_buffer_.channels(), first_frame_in_block); first_frame_in_block += shift_amount_; } // Copy output buffer to output CopyFrames(output_buffer_.channels(), 0, chunk_size_, num_output_channels_, output, 0); // Copy input buffer [chunk_size_, chunk_size_ + initial_delay] // to input buffer [0, initial_delay] CopyFrames(input_buffer_.channels(), chunk_size, initial_delay_, num_input_channels_, input_buffer_.channels(), 0); // Copy output buffer [chunk_size_, chunk_size_ + initial_delay] // to output buffer [0, initial_delay], zero the rest. CopyFrames(output_buffer_.channels(), chunk_size, initial_delay_, num_output_channels_, output_buffer_.channels(), 0); ZeroOut(output_buffer_.channels(), initial_delay_, chunk_size_, num_output_channels_); // Calculate new starting frames. frame_offset_ = first_frame_in_block - chunk_size_; } } // namespace webrtc