/* * 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. */ #include "modules/audio_coding/neteq/sync_buffer.h" #include // Access to min. #include "rtc_base/checks.h" namespace webrtc { size_t SyncBuffer::FutureLength() const { return Size() - next_index_; } void SyncBuffer::PushBack(const AudioMultiVector& append_this) { size_t samples_added = append_this.Size(); AudioMultiVector::PushBack(append_this); AudioMultiVector::PopFront(samples_added); if (samples_added <= next_index_) { next_index_ -= samples_added; } else { // This means that we are pushing out future data that was never used. // assert(false); // TODO(hlundin): This assert must be disabled to support 60 ms frames. // This should not happen even for 60 ms frames, but it does. Investigate // why. next_index_ = 0; } dtmf_index_ -= std::min(dtmf_index_, samples_added); } void SyncBuffer::PushBackInterleaved(const rtc::BufferT& append_this) { const size_t size_before_adding = Size(); AudioMultiVector::PushBackInterleaved(append_this); const size_t samples_added_per_channel = Size() - size_before_adding; RTC_DCHECK_EQ(samples_added_per_channel * Channels(), append_this.size()); AudioMultiVector::PopFront(samples_added_per_channel); next_index_ -= std::min(next_index_, samples_added_per_channel); dtmf_index_ -= std::min(dtmf_index_, samples_added_per_channel); } void SyncBuffer::PushFrontZeros(size_t length) { InsertZerosAtIndex(length, 0); } void SyncBuffer::InsertZerosAtIndex(size_t length, size_t position) { position = std::min(position, Size()); length = std::min(length, Size() - position); AudioMultiVector::PopBack(length); for (size_t channel = 0; channel < Channels(); ++channel) { channels_[channel]->InsertZerosAt(length, position); } if (next_index_ >= position) { // We are moving the |next_index_| sample. set_next_index(next_index_ + length); // Overflow handled by subfunction. } if (dtmf_index_ > 0 && dtmf_index_ >= position) { // We are moving the |dtmf_index_| sample. set_dtmf_index(dtmf_index_ + length); // Overflow handled by subfunction. } } void SyncBuffer::ReplaceAtIndex(const AudioMultiVector& insert_this, size_t length, size_t position) { position = std::min(position, Size()); // Cap |position| in the valid range. length = std::min(length, Size() - position); AudioMultiVector::OverwriteAt(insert_this, length, position); } void SyncBuffer::ReplaceAtIndex(const AudioMultiVector& insert_this, size_t position) { ReplaceAtIndex(insert_this, insert_this.Size(), position); } void SyncBuffer::GetNextAudioInterleaved(size_t requested_len, AudioFrame* output) { RTC_DCHECK(output); const size_t samples_to_read = std::min(FutureLength(), requested_len); output->ResetWithoutMuting(); const size_t tot_samples_read = ReadInterleavedFromIndex( next_index_, samples_to_read, output->mutable_data()); const size_t samples_read_per_channel = tot_samples_read / Channels(); next_index_ += samples_read_per_channel; output->num_channels_ = Channels(); output->samples_per_channel_ = samples_read_per_channel; } void SyncBuffer::IncreaseEndTimestamp(uint32_t increment) { end_timestamp_ += increment; } void SyncBuffer::Flush() { Zeros(Size()); next_index_ = Size(); end_timestamp_ = 0; dtmf_index_ = 0; } void SyncBuffer::set_next_index(size_t value) { // Cannot set |next_index_| larger than the size of the buffer. next_index_ = std::min(value, Size()); } void SyncBuffer::set_dtmf_index(size_t value) { // Cannot set |dtmf_index_| larger than the size of the buffer. dtmf_index_ = std::min(value, Size()); } } // namespace webrtc