/* * 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/audio_vector.h" #include #include #include #include "rtc_base/checks.h" namespace webrtc { AudioVector::AudioVector() : AudioVector(kDefaultInitialSize) { Clear(); } AudioVector::AudioVector(size_t initial_size) : array_(new int16_t[initial_size + 1]), capacity_(initial_size + 1), begin_index_(0), end_index_(capacity_ - 1) { memset(array_.get(), 0, capacity_ * sizeof(int16_t)); } AudioVector::~AudioVector() = default; void AudioVector::Clear() { end_index_ = begin_index_ = 0; } void AudioVector::CopyTo(AudioVector* copy_to) const { RTC_DCHECK(copy_to); copy_to->Reserve(Size()); CopyTo(Size(), 0, copy_to->array_.get()); copy_to->begin_index_ = 0; copy_to->end_index_ = Size(); } void AudioVector::CopyTo(size_t length, size_t position, int16_t* copy_to) const { if (length == 0) return; length = std::min(length, Size() - position); const size_t copy_index = (begin_index_ + position) % capacity_; const size_t first_chunk_length = std::min(length, capacity_ - copy_index); memcpy(copy_to, &array_[copy_index], first_chunk_length * sizeof(int16_t)); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) { memcpy(©_to[first_chunk_length], array_.get(), remaining_length * sizeof(int16_t)); } } void AudioVector::PushFront(const AudioVector& prepend_this) { const size_t length = prepend_this.Size(); if (length == 0) return; // Although the subsequent calling to PushFront does Reserve in it, it is // always more efficient to do a big Reserve first. Reserve(Size() + length); const size_t first_chunk_length = std::min(length, prepend_this.capacity_ - prepend_this.begin_index_); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) PushFront(prepend_this.array_.get(), remaining_length); PushFront(&prepend_this.array_[prepend_this.begin_index_], first_chunk_length); } void AudioVector::PushFront(const int16_t* prepend_this, size_t length) { if (length == 0) return; Reserve(Size() + length); const size_t first_chunk_length = std::min(length, begin_index_); memcpy(&array_[begin_index_ - first_chunk_length], &prepend_this[length - first_chunk_length], first_chunk_length * sizeof(int16_t)); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) { memcpy(&array_[capacity_ - remaining_length], prepend_this, remaining_length * sizeof(int16_t)); } begin_index_ = (begin_index_ + capacity_ - length) % capacity_; } void AudioVector::PushBack(const AudioVector& append_this) { PushBack(append_this, append_this.Size(), 0); } void AudioVector::PushBack(const AudioVector& append_this, size_t length, size_t position) { RTC_DCHECK_LE(position, append_this.Size()); RTC_DCHECK_LE(length, append_this.Size() - position); if (length == 0) return; // Although the subsequent calling to PushBack does Reserve in it, it is // always more efficient to do a big Reserve first. Reserve(Size() + length); const size_t start_index = (append_this.begin_index_ + position) % append_this.capacity_; const size_t first_chunk_length = std::min(length, append_this.capacity_ - start_index); PushBack(&append_this.array_[start_index], first_chunk_length); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) PushBack(append_this.array_.get(), remaining_length); } void AudioVector::PushBack(const int16_t* append_this, size_t length) { if (length == 0) return; Reserve(Size() + length); const size_t first_chunk_length = std::min(length, capacity_ - end_index_); memcpy(&array_[end_index_], append_this, first_chunk_length * sizeof(int16_t)); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) { memcpy(array_.get(), &append_this[first_chunk_length], remaining_length * sizeof(int16_t)); } end_index_ = (end_index_ + length) % capacity_; } void AudioVector::PopFront(size_t length) { if (length == 0) return; length = std::min(length, Size()); begin_index_ = (begin_index_ + length) % capacity_; } void AudioVector::PopBack(size_t length) { if (length == 0) return; // Never remove more than what is in the array. length = std::min(length, Size()); end_index_ = (end_index_ + capacity_ - length) % capacity_; } void AudioVector::Extend(size_t extra_length) { if (extra_length == 0) return; InsertZerosByPushBack(extra_length, Size()); } void AudioVector::InsertAt(const int16_t* insert_this, size_t length, size_t position) { if (length == 0) return; // Cap the insert position at the current array length. position = std::min(Size(), position); // When inserting to a position closer to the beginning, it is more efficient // to insert by pushing front than to insert by pushing back, since less data // will be moved, vice versa. if (position <= Size() - position) { InsertByPushFront(insert_this, length, position); } else { InsertByPushBack(insert_this, length, position); } } void AudioVector::InsertZerosAt(size_t length, size_t position) { if (length == 0) return; // Cap the insert position at the current array length. position = std::min(Size(), position); // When inserting to a position closer to the beginning, it is more efficient // to insert by pushing front than to insert by pushing back, since less data // will be moved, vice versa. if (position <= Size() - position) { InsertZerosByPushFront(length, position); } else { InsertZerosByPushBack(length, position); } } void AudioVector::OverwriteAt(const AudioVector& insert_this, size_t length, size_t position) { RTC_DCHECK_LE(length, insert_this.Size()); if (length == 0) return; // Cap the insert position at the current array length. position = std::min(Size(), position); // Although the subsequent calling to OverwriteAt does Reserve in it, it is // always more efficient to do a big Reserve first. size_t new_size = std::max(Size(), position + length); Reserve(new_size); const size_t first_chunk_length = std::min(length, insert_this.capacity_ - insert_this.begin_index_); OverwriteAt(&insert_this.array_[insert_this.begin_index_], first_chunk_length, position); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) { OverwriteAt(insert_this.array_.get(), remaining_length, position + first_chunk_length); } } void AudioVector::OverwriteAt(const int16_t* insert_this, size_t length, size_t position) { if (length == 0) return; // Cap the insert position at the current array length. position = std::min(Size(), position); size_t new_size = std::max(Size(), position + length); Reserve(new_size); const size_t overwrite_index = (begin_index_ + position) % capacity_; const size_t first_chunk_length = std::min(length, capacity_ - overwrite_index); memcpy(&array_[overwrite_index], insert_this, first_chunk_length * sizeof(int16_t)); const size_t remaining_length = length - first_chunk_length; if (remaining_length > 0) { memcpy(array_.get(), &insert_this[first_chunk_length], remaining_length * sizeof(int16_t)); } end_index_ = (begin_index_ + new_size) % capacity_; } void AudioVector::CrossFade(const AudioVector& append_this, size_t fade_length) { // Fade length cannot be longer than the current vector or |append_this|. assert(fade_length <= Size()); assert(fade_length <= append_this.Size()); fade_length = std::min(fade_length, Size()); fade_length = std::min(fade_length, append_this.Size()); size_t position = Size() - fade_length + begin_index_; // Cross fade the overlapping regions. // |alpha| is the mixing factor in Q14. // TODO(hlundin): Consider skipping +1 in the denominator to produce a // smoother cross-fade, in particular at the end of the fade. int alpha_step = 16384 / (static_cast(fade_length) + 1); int alpha = 16384; for (size_t i = 0; i < fade_length; ++i) { alpha -= alpha_step; array_[(position + i) % capacity_] = (alpha * array_[(position + i) % capacity_] + (16384 - alpha) * append_this[i] + 8192) >> 14; } assert(alpha >= 0); // Verify that the slope was correct. // Append what is left of |append_this|. size_t samples_to_push_back = append_this.Size() - fade_length; if (samples_to_push_back > 0) PushBack(append_this, samples_to_push_back, fade_length); } // Returns the number of elements in this AudioVector. size_t AudioVector::Size() const { return (end_index_ + capacity_ - begin_index_) % capacity_; } // Returns true if this AudioVector is empty. bool AudioVector::Empty() const { return begin_index_ == end_index_; } void AudioVector::Reserve(size_t n) { if (capacity_ > n) return; const size_t length = Size(); // Reserve one more sample to remove the ambiguity between empty vector and // full vector. Therefore |begin_index_| == |end_index_| indicates empty // vector, and |begin_index_| == (|end_index_| + 1) % capacity indicates // full vector. std::unique_ptr temp_array(new int16_t[n + 1]); CopyTo(length, 0, temp_array.get()); array_.swap(temp_array); begin_index_ = 0; end_index_ = length; capacity_ = n + 1; } void AudioVector::InsertByPushBack(const int16_t* insert_this, size_t length, size_t position) { const size_t move_chunk_length = Size() - position; std::unique_ptr temp_array(nullptr); if (move_chunk_length > 0) { // TODO(minyue): see if it is possible to avoid copying to a buffer. temp_array.reset(new int16_t[move_chunk_length]); CopyTo(move_chunk_length, position, temp_array.get()); PopBack(move_chunk_length); } Reserve(Size() + length + move_chunk_length); PushBack(insert_this, length); if (move_chunk_length > 0) PushBack(temp_array.get(), move_chunk_length); } void AudioVector::InsertByPushFront(const int16_t* insert_this, size_t length, size_t position) { std::unique_ptr temp_array(nullptr); if (position > 0) { // TODO(minyue): see if it is possible to avoid copying to a buffer. temp_array.reset(new int16_t[position]); CopyTo(position, 0, temp_array.get()); PopFront(position); } Reserve(Size() + length + position); PushFront(insert_this, length); if (position > 0) PushFront(temp_array.get(), position); } void AudioVector::InsertZerosByPushBack(size_t length, size_t position) { const size_t move_chunk_length = Size() - position; std::unique_ptr temp_array(nullptr); if (move_chunk_length > 0) { temp_array.reset(new int16_t[move_chunk_length]); CopyTo(move_chunk_length, position, temp_array.get()); PopBack(move_chunk_length); } Reserve(Size() + length + move_chunk_length); const size_t first_zero_chunk_length = std::min(length, capacity_ - end_index_); memset(&array_[end_index_], 0, first_zero_chunk_length * sizeof(int16_t)); const size_t remaining_zero_length = length - first_zero_chunk_length; if (remaining_zero_length > 0) memset(array_.get(), 0, remaining_zero_length * sizeof(int16_t)); end_index_ = (end_index_ + length) % capacity_; if (move_chunk_length > 0) PushBack(temp_array.get(), move_chunk_length); } void AudioVector::InsertZerosByPushFront(size_t length, size_t position) { std::unique_ptr temp_array(nullptr); if (position > 0) { temp_array.reset(new int16_t[position]); CopyTo(position, 0, temp_array.get()); PopFront(position); } Reserve(Size() + length + position); const size_t first_zero_chunk_length = std::min(length, begin_index_); memset(&array_[begin_index_ - first_zero_chunk_length], 0, first_zero_chunk_length * sizeof(int16_t)); const size_t remaining_zero_length = length - first_zero_chunk_length; if (remaining_zero_length > 0) memset(&array_[capacity_ - remaining_zero_length], 0, remaining_zero_length * sizeof(int16_t)); begin_index_ = (begin_index_ + capacity_ - length) % capacity_; if (position > 0) PushFront(temp_array.get(), position); } } // namespace webrtc