modules/audio_coding/acm2/audio_coding_module.cc - 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.
  */

 #include "modules/audio_coding/include/audio_coding_module.h"

 #include <assert.h>
 #include <algorithm>
 #include <cstdint>

 #include "absl/strings/match.h"
 #include "api/array_view.h"
 #include "modules/audio_coding/acm2/acm_receiver.h"
 #include "modules/audio_coding/acm2/acm_remixing.h"
 #include "modules/audio_coding/acm2/acm_resampler.h"
 #include "modules/include/module_common_types.h"
 #include "modules/include/module_common_types_public.h"
 #include "rtc_base/buffer.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/logging.h"
 #include "rtc_base/numerics/safe_conversions.h"
 #include "rtc_base/synchronization/mutex.h"
 #include "rtc_base/thread_annotations.h"
 #include "system_wrappers/include/metrics.h"

 namespace webrtc {

 namespace {

 // Initial size for the buffer in InputBuffer. This matches 6 channels of 10 ms
 // 48 kHz data.
 constexpr size_t kInitialInputDataBufferSize = 6 * 480;

 constexpr int32_t kMaxInputSampleRateHz = 192000;

 class AudioCodingModuleImpl final : public AudioCodingModule {
  public:
   explicit AudioCodingModuleImpl(const AudioCodingModule::Config& config);
   ~AudioCodingModuleImpl() override;

   /////////////////////////////////////////
   //   Sender
   //

   void ModifyEncoder(rtc::FunctionView<void(std::unique_ptr<AudioEncoder>*)>
                          modifier) override;

   // Register a transport callback which will be
   // called to deliver the encoded buffers.
   int RegisterTransportCallback(AudioPacketizationCallback* transport) override;

   // Add 10 ms of raw (PCM) audio data to the encoder.
   int Add10MsData(const AudioFrame& audio_frame) override;

   /////////////////////////////////////////
   // (FEC) Forward Error Correction (codec internal)
   //

   // Set target packet loss rate
   int SetPacketLossRate(int loss_rate) override;

   /////////////////////////////////////////
   //   Receiver
   //

   // Initialize receiver, resets codec database etc.
   int InitializeReceiver() override;

   void SetReceiveCodecs(const std::map<int, SdpAudioFormat>& codecs) override;

   // Incoming packet from network parsed and ready for decode.
   int IncomingPacket(const uint8_t* incoming_payload,
                      const size_t payload_length,
                      const RTPHeader& rtp_info) override;

   // Get 10 milliseconds of raw audio data to play out, and
   // automatic resample to the requested frequency if > 0.
   int PlayoutData10Ms(int desired_freq_hz,
                       AudioFrame* audio_frame,
                       bool* muted) override;

   /////////////////////////////////////////
   //   Statistics
   //

   int GetNetworkStatistics(NetworkStatistics* statistics) override;

   ANAStats GetANAStats() const override;

  private:
   struct InputData {
     InputData() : buffer(kInitialInputDataBufferSize) {}
     uint32_t input_timestamp;
     const int16_t* audio;
     size_t length_per_channel;
     size_t audio_channel;
     // If a re-mix is required (up or down), this buffer will store a re-mixed
     // version of the input.
     std::vector<int16_t> buffer;
   };

   InputData input_data_ RTC_GUARDED_BY(acm_mutex_);

   // This member class writes values to the named UMA histogram, but only if
   // the value has changed since the last time (and always for the first call).
   class ChangeLogger {
    public:
     explicit ChangeLogger(const std::string& histogram_name)
         : histogram_name_(histogram_name) {}
     // Logs the new value if it is different from the last logged value, or if
     // this is the first call.
     void MaybeLog(int value);

    private:
     int last_value_ = 0;
     int first_time_ = true;
     const std::string histogram_name_;
   };

   int Add10MsDataInternal(const AudioFrame& audio_frame, InputData* input_data)
       RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

   // TODO(bugs.webrtc.org/10739): change |absolute_capture_timestamp_ms| to
   // int64_t when it always receives a valid value.
   int Encode(const InputData& input_data,
              absl::optional<int64_t> absolute_capture_timestamp_ms)
       RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

   int InitializeReceiverSafe() RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

   bool HaveValidEncoder(const char* caller_name) const
       RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

   // Preprocessing of input audio, including resampling and down-mixing if
   // required, before pushing audio into encoder's buffer.
   //
   // in_frame: input audio-frame
   // ptr_out: pointer to output audio_frame. If no preprocessing is required
   //          |ptr_out| will be pointing to |in_frame|, otherwise pointing to
   //          |preprocess_frame_|.
   //
   // Return value:
   //   -1: if encountering an error.
   //    0: otherwise.
   int PreprocessToAddData(const AudioFrame& in_frame,
                           const AudioFrame** ptr_out)
       RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

   // Change required states after starting to receive the codec corresponding
   // to |index|.
   int UpdateUponReceivingCodec(int index);

   mutable Mutex acm_mutex_;
   rtc::Buffer encode_buffer_ RTC_GUARDED_BY(acm_mutex_);
   uint32_t expected_codec_ts_ RTC_GUARDED_BY(acm_mutex_);
   uint32_t expected_in_ts_ RTC_GUARDED_BY(acm_mutex_);
   acm2::ACMResampler resampler_ RTC_GUARDED_BY(acm_mutex_);
   acm2::AcmReceiver receiver_;  // AcmReceiver has it's own internal lock.
   ChangeLogger bitrate_logger_ RTC_GUARDED_BY(acm_mutex_);

   // Current encoder stack, provided by a call to RegisterEncoder.
   std::unique_ptr<AudioEncoder> encoder_stack_ RTC_GUARDED_BY(acm_mutex_);

   // This is to keep track of CN instances where we can send DTMFs.
   uint8_t previous_pltype_ RTC_GUARDED_BY(acm_mutex_);

   bool receiver_initialized_ RTC_GUARDED_BY(acm_mutex_);

   AudioFrame preprocess_frame_ RTC_GUARDED_BY(acm_mutex_);
   bool first_10ms_data_ RTC_GUARDED_BY(acm_mutex_);

   bool first_frame_ RTC_GUARDED_BY(acm_mutex_);
   uint32_t last_timestamp_ RTC_GUARDED_BY(acm_mutex_);
   uint32_t last_rtp_timestamp_ RTC_GUARDED_BY(acm_mutex_);

   Mutex callback_mutex_;
   AudioPacketizationCallback* packetization_callback_
       RTC_GUARDED_BY(callback_mutex_);

   int codec_histogram_bins_log_[static_cast<size_t>(
       AudioEncoder::CodecType::kMaxLoggedAudioCodecTypes)];
   int number_of_consecutive_empty_packets_;
 };

 // Adds a codec usage sample to the histogram.
 void UpdateCodecTypeHistogram(size_t codec_type) {
   RTC_HISTOGRAM_ENUMERATION(
       "WebRTC.Audio.Encoder.CodecType", static_cast<int>(codec_type),
       static_cast<int>(
           webrtc::AudioEncoder::CodecType::kMaxLoggedAudioCodecTypes));
 }

 void AudioCodingModuleImpl::ChangeLogger::MaybeLog(int value) {
   if (value != last_value_ || first_time_) {
     first_time_ = false;
     last_value_ = value;
     RTC_HISTOGRAM_COUNTS_SPARSE_100(histogram_name_, value);
   }
 }

 AudioCodingModuleImpl::AudioCodingModuleImpl(
     const AudioCodingModule::Config& config)
     : expected_codec_ts_(0xD87F3F9F),
       expected_in_ts_(0xD87F3F9F),
       receiver_(config),
       bitrate_logger_("WebRTC.Audio.TargetBitrateInKbps"),
       encoder_stack_(nullptr),
       previous_pltype_(255),
       receiver_initialized_(false),
       first_10ms_data_(false),
       first_frame_(true),
       packetization_callback_(NULL),
       codec_histogram_bins_log_(),
       number_of_consecutive_empty_packets_(0) {
   if (InitializeReceiverSafe() < 0) {
     RTC_LOG(LS_ERROR) << "Cannot initialize receiver";
   }
   RTC_LOG(LS_INFO) << "Created";
 }

 AudioCodingModuleImpl::~AudioCodingModuleImpl() = default;

 int32_t AudioCodingModuleImpl::Encode(
     const InputData& input_data,
     absl::optional<int64_t> absolute_capture_timestamp_ms) {
   // TODO(bugs.webrtc.org/10739): add dcheck that
   // |audio_frame.absolute_capture_timestamp_ms()| always has a value.
   AudioEncoder::EncodedInfo encoded_info;
   uint8_t previous_pltype;

   // Check if there is an encoder before.
   if (!HaveValidEncoder("Process"))
     return -1;

   if (!first_frame_) {
     RTC_DCHECK(IsNewerTimestamp(input_data.input_timestamp, last_timestamp_))
         << "Time should not move backwards";
   }

   // Scale the timestamp to the codec's RTP timestamp rate.
   uint32_t rtp_timestamp =
       first_frame_
           ? input_data.input_timestamp
           : last_rtp_timestamp_ +
                 rtc::dchecked_cast<uint32_t>(rtc::CheckedDivExact(
                     int64_t{input_data.input_timestamp - last_timestamp_} *
                         encoder_stack_->RtpTimestampRateHz(),
                     int64_t{encoder_stack_->SampleRateHz()}));

   last_timestamp_ = input_data.input_timestamp;
   last_rtp_timestamp_ = rtp_timestamp;
   first_frame_ = false;

   // Clear the buffer before reuse - encoded data will get appended.
   encode_buffer_.Clear();
   encoded_info = encoder_stack_->Encode(
       rtp_timestamp,
       rtc::ArrayView<const int16_t>(
           input_data.audio,
           input_data.audio_channel * input_data.length_per_channel),
       &encode_buffer_);

   bitrate_logger_.MaybeLog(encoder_stack_->GetTargetBitrate() / 1000);
   if (encode_buffer_.size() == 0 && !encoded_info.send_even_if_empty) {
     // Not enough data.
     return 0;
   }
   previous_pltype = previous_pltype_;  // Read it while we have the critsect.

   // Log codec type to histogram once every 500 packets.
   if (encoded_info.encoded_bytes == 0) {
     ++number_of_consecutive_empty_packets_;
   } else {
     size_t codec_type = static_cast<size_t>(encoded_info.encoder_type);
     codec_histogram_bins_log_[codec_type] +=
         number_of_consecutive_empty_packets_ + 1;
     number_of_consecutive_empty_packets_ = 0;
     if (codec_histogram_bins_log_[codec_type] >= 500) {
       codec_histogram_bins_log_[codec_type] -= 500;
       UpdateCodecTypeHistogram(codec_type);
     }
   }

   AudioFrameType frame_type;
   if (encode_buffer_.size() == 0 && encoded_info.send_even_if_empty) {
     frame_type = AudioFrameType::kEmptyFrame;
     encoded_info.payload_type = previous_pltype;
   } else {
     RTC_DCHECK_GT(encode_buffer_.size(), 0);
     frame_type = encoded_info.speech ? AudioFrameType::kAudioFrameSpeech
                                      : AudioFrameType::kAudioFrameCN;
   }

   {
     MutexLock lock(&callback_mutex_);
     if (packetization_callback_) {
       packetization_callback_->SendData(
           frame_type, encoded_info.payload_type, encoded_info.encoded_timestamp,
           encode_buffer_.data(), encode_buffer_.size(),
           absolute_capture_timestamp_ms.value_or(-1));
     }
   }
   previous_pltype_ = encoded_info.payload_type;
   return static_cast<int32_t>(encode_buffer_.size());
 }

 /////////////////////////////////////////
 //   Sender
 //

 void AudioCodingModuleImpl::ModifyEncoder(
     rtc::FunctionView<void(std::unique_ptr<AudioEncoder>*)> modifier) {
   MutexLock lock(&acm_mutex_);
   modifier(&encoder_stack_);
 }

 // Register a transport callback which will be called to deliver
 // the encoded buffers.
 int AudioCodingModuleImpl::RegisterTransportCallback(
     AudioPacketizationCallback* transport) {
   MutexLock lock(&callback_mutex_);
   packetization_callback_ = transport;
   return 0;
 }

 // Add 10MS of raw (PCM) audio data to the encoder.
 int AudioCodingModuleImpl::Add10MsData(const AudioFrame& audio_frame) {
   MutexLock lock(&acm_mutex_);
   int r = Add10MsDataInternal(audio_frame, &input_data_);
   // TODO(bugs.webrtc.org/10739): add dcheck that
   // |audio_frame.absolute_capture_timestamp_ms()| always has a value.
   return r < 0
              ? r
              : Encode(input_data_, audio_frame.absolute_capture_timestamp_ms());
 }

 int AudioCodingModuleImpl::Add10MsDataInternal(const AudioFrame& audio_frame,
                                                InputData* input_data) {
   if (audio_frame.samples_per_channel_ == 0) {
     assert(false);
     RTC_LOG(LS_ERROR) << "Cannot Add 10 ms audio, payload length is zero";
     return -1;
   }

   if (audio_frame.sample_rate_hz_ > kMaxInputSampleRateHz) {
     assert(false);
     RTC_LOG(LS_ERROR) << "Cannot Add 10 ms audio, input frequency not valid";
     return -1;
   }

   // If the length and frequency matches. We currently just support raw PCM.
   if (static_cast<size_t>(audio_frame.sample_rate_hz_ / 100) !=
       audio_frame.samples_per_channel_) {
     RTC_LOG(LS_ERROR)
         << "Cannot Add 10 ms audio, input frequency and length doesn't match";
     return -1;
   }

   if (audio_frame.num_channels_ != 1 && audio_frame.num_channels_ != 2 &&
       audio_frame.num_channels_ != 4 && audio_frame.num_channels_ != 6 &&
       audio_frame.num_channels_ != 8) {
     RTC_LOG(LS_ERROR) << "Cannot Add 10 ms audio, invalid number of channels.";
     return -1;
   }

   // Do we have a codec registered?
   if (!HaveValidEncoder("Add10MsData")) {
     return -1;
   }

   const AudioFrame* ptr_frame;
   // Perform a resampling, also down-mix if it is required and can be
   // performed before resampling (a down mix prior to resampling will take
   // place if both primary and secondary encoders are mono and input is in
   // stereo).
   if (PreprocessToAddData(audio_frame, &ptr_frame) < 0) {
     return -1;
   }

   // Check whether we need an up-mix or down-mix?
   const size_t current_num_channels = encoder_stack_->NumChannels();
   const bool same_num_channels =
       ptr_frame->num_channels_ == current_num_channels;

   // TODO(yujo): Skip encode of muted frames.
   input_data->input_timestamp = ptr_frame->timestamp_;
   input_data->length_per_channel = ptr_frame->samples_per_channel_;
   input_data->audio_channel = current_num_channels;

   if (!same_num_channels) {
     // Remixes the input frame to the output data and in the process resize the
     // output data if needed.
     ReMixFrame(*ptr_frame, current_num_channels, &input_data->buffer);

     // For pushing data to primary, point the |ptr_audio| to correct buffer.
     input_data->audio = input_data->buffer.data();
     RTC_DCHECK_GE(input_data->buffer.size(),
                   input_data->length_per_channel * input_data->audio_channel);
   } else {
     // When adding data to encoders this pointer is pointing to an audio buffer
     // with correct number of channels.
     input_data->audio = ptr_frame->data();
   }

   return 0;
 }

 // Perform a resampling and down-mix if required. We down-mix only if
 // encoder is mono and input is stereo. In case of dual-streaming, both
 // encoders has to be mono for down-mix to take place.
 // |*ptr_out| will point to the pre-processed audio-frame. If no pre-processing
 // is required, |*ptr_out| points to |in_frame|.
 // TODO(yujo): Make this more efficient for muted frames.
 int AudioCodingModuleImpl::PreprocessToAddData(const AudioFrame& in_frame,
                                                const AudioFrame** ptr_out) {
   const bool resample =
       in_frame.sample_rate_hz_ != encoder_stack_->SampleRateHz();

   // This variable is true if primary codec and secondary codec (if exists)
   // are both mono and input is stereo.
   // TODO(henrik.lundin): This condition should probably be
   //   in_frame.num_channels_ > encoder_stack_->NumChannels()
   const bool down_mix =
       in_frame.num_channels_ == 2 && encoder_stack_->NumChannels() == 1;

   if (!first_10ms_data_) {
     expected_in_ts_ = in_frame.timestamp_;
     expected_codec_ts_ = in_frame.timestamp_;
     first_10ms_data_ = true;
   } else if (in_frame.timestamp_ != expected_in_ts_) {
     RTC_LOG(LS_WARNING) << "Unexpected input timestamp: " << in_frame.timestamp_
                         << ", expected: " << expected_in_ts_;
     expected_codec_ts_ +=
         (in_frame.timestamp_ - expected_in_ts_) *
         static_cast<uint32_t>(
             static_cast<double>(encoder_stack_->SampleRateHz()) /
             static_cast<double>(in_frame.sample_rate_hz_));
     expected_in_ts_ = in_frame.timestamp_;
   }

   if (!down_mix && !resample) {
     // No pre-processing is required.
     if (expected_in_ts_ == expected_codec_ts_) {
       // If we've never resampled, we can use the input frame as-is
       *ptr_out = &in_frame;
     } else {
       // Otherwise we'll need to alter the timestamp. Since in_frame is const,
       // we'll have to make a copy of it.
       preprocess_frame_.CopyFrom(in_frame);
       preprocess_frame_.timestamp_ = expected_codec_ts_;
       *ptr_out = &preprocess_frame_;
     }

     expected_in_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
     expected_codec_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
     return 0;
   }

   *ptr_out = &preprocess_frame_;
   preprocess_frame_.num_channels_ = in_frame.num_channels_;
   preprocess_frame_.samples_per_channel_ = in_frame.samples_per_channel_;
   std::array<int16_t, AudioFrame::kMaxDataSizeSamples> audio;
   const int16_t* src_ptr_audio;
   if (down_mix) {
     // If a resampling is required, the output of a down-mix is written into a
     // local buffer, otherwise, it will be written to the output frame.
     int16_t* dest_ptr_audio =
         resample ? audio.data() : preprocess_frame_.mutable_data();
     RTC_DCHECK_GE(audio.size(), preprocess_frame_.samples_per_channel_);
     RTC_DCHECK_GE(audio.size(), in_frame.samples_per_channel_);
     DownMixFrame(in_frame,
                  rtc::ArrayView<int16_t>(
                      dest_ptr_audio, preprocess_frame_.samples_per_channel_));
     preprocess_frame_.num_channels_ = 1;

     // Set the input of the resampler to the down-mixed signal.
     src_ptr_audio = audio.data();
   } else {
     // Set the input of the resampler to the original data.
     src_ptr_audio = in_frame.data();
   }

   preprocess_frame_.timestamp_ = expected_codec_ts_;
   preprocess_frame_.sample_rate_hz_ = in_frame.sample_rate_hz_;
   // If it is required, we have to do a resampling.
   if (resample) {
     // The result of the resampler is written to output frame.
     int16_t* dest_ptr_audio = preprocess_frame_.mutable_data();

     int samples_per_channel = resampler_.Resample10Msec(
         src_ptr_audio, in_frame.sample_rate_hz_, encoder_stack_->SampleRateHz(),
         preprocess_frame_.num_channels_, AudioFrame::kMaxDataSizeSamples,
         dest_ptr_audio);

     if (samples_per_channel < 0) {
       RTC_LOG(LS_ERROR) << "Cannot add 10 ms audio, resampling failed";
       return -1;
     }
     preprocess_frame_.samples_per_channel_ =
         static_cast<size_t>(samples_per_channel);
     preprocess_frame_.sample_rate_hz_ = encoder_stack_->SampleRateHz();
   }

   expected_codec_ts_ +=
       static_cast<uint32_t>(preprocess_frame_.samples_per_channel_);
   expected_in_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);

   return 0;
 }

 /////////////////////////////////////////
 //   (FEC) Forward Error Correction (codec internal)
 //

 int AudioCodingModuleImpl::SetPacketLossRate(int loss_rate) {
   MutexLock lock(&acm_mutex_);
   if (HaveValidEncoder("SetPacketLossRate")) {
     encoder_stack_->OnReceivedUplinkPacketLossFraction(loss_rate / 100.0);
   }
   return 0;
 }

 /////////////////////////////////////////
 //   Receiver
 //

 int AudioCodingModuleImpl::InitializeReceiver() {
   MutexLock lock(&acm_mutex_);
   return InitializeReceiverSafe();
 }

 // Initialize receiver, resets codec database etc.
 int AudioCodingModuleImpl::InitializeReceiverSafe() {
   // If the receiver is already initialized then we want to destroy any
   // existing decoders. After a call to this function, we should have a clean
   // start-up.
   if (receiver_initialized_)
     receiver_.RemoveAllCodecs();
   receiver_.FlushBuffers();

   receiver_initialized_ = true;
   return 0;
 }

 void AudioCodingModuleImpl::SetReceiveCodecs(
     const std::map<int, SdpAudioFormat>& codecs) {
   MutexLock lock(&acm_mutex_);
   receiver_.SetCodecs(codecs);
 }

 // Incoming packet from network parsed and ready for decode.
 int AudioCodingModuleImpl::IncomingPacket(const uint8_t* incoming_payload,
                                           const size_t payload_length,
                                           const RTPHeader& rtp_header) {
   RTC_DCHECK_EQ(payload_length == 0, incoming_payload == nullptr);
   return receiver_.InsertPacket(
       rtp_header,
       rtc::ArrayView<const uint8_t>(incoming_payload, payload_length));
 }

 // Get 10 milliseconds of raw audio data to play out.
 // Automatic resample to the requested frequency.
 int AudioCodingModuleImpl::PlayoutData10Ms(int desired_freq_hz,
                                            AudioFrame* audio_frame,
                                            bool* muted) {
   // GetAudio always returns 10 ms, at the requested sample rate.
   if (receiver_.GetAudio(desired_freq_hz, audio_frame, muted) != 0) {
     RTC_LOG(LS_ERROR) << "PlayoutData failed, RecOut Failed";
     return -1;
   }
   return 0;
 }

 /////////////////////////////////////////
 //   Statistics
 //

 // TODO(turajs) change the return value to void. Also change the corresponding
 // NetEq function.
 int AudioCodingModuleImpl::GetNetworkStatistics(NetworkStatistics* statistics) {
   receiver_.GetNetworkStatistics(statistics);
   return 0;
 }

 bool AudioCodingModuleImpl::HaveValidEncoder(const char* caller_name) const {
   if (!encoder_stack_) {
     RTC_LOG(LS_ERROR) << caller_name << " failed: No send codec is registered.";
     return false;
   }
   return true;
 }

 ANAStats AudioCodingModuleImpl::GetANAStats() const {
   MutexLock lock(&acm_mutex_);
   if (encoder_stack_)
     return encoder_stack_->GetANAStats();
   // If no encoder is set, return default stats.
   return ANAStats();
 }

 }  // namespace

 AudioCodingModule::Config::Config(
     rtc::scoped_refptr<AudioDecoderFactory> decoder_factory)
     : neteq_config(),
       clock(Clock::GetRealTimeClock()),
       decoder_factory(decoder_factory) {
   // Post-decode VAD is disabled by default in NetEq, however, Audio
   // Conference Mixer relies on VAD decisions and fails without them.
   neteq_config.enable_post_decode_vad = true;
 }

 AudioCodingModule::Config::Config(const Config&) = default;
 AudioCodingModule::Config::~Config() = default;

 AudioCodingModule* AudioCodingModule::Create(const Config& config) {
   return new AudioCodingModuleImpl(config);
 }

 }  // namespace webrtc
	/*
	* 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/include/audio_coding_module.h"

	#include <assert.h>
	#include <algorithm>
	#include <cstdint>

	#include "absl/strings/match.h"
	#include "api/array_view.h"
	#include "modules/audio_coding/acm2/acm_receiver.h"
	#include "modules/audio_coding/acm2/acm_remixing.h"
	#include "modules/audio_coding/acm2/acm_resampler.h"
	#include "modules/include/module_common_types.h"
	#include "modules/include/module_common_types_public.h"
	#include "rtc_base/buffer.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/logging.h"
	#include "rtc_base/numerics/safe_conversions.h"
	#include "rtc_base/synchronization/mutex.h"
	#include "rtc_base/thread_annotations.h"
	#include "system_wrappers/include/metrics.h"

	namespace webrtc {

	namespace {

	// Initial size for the buffer in InputBuffer. This matches 6 channels of 10 ms
	// 48 kHz data.
	constexpr size_t kInitialInputDataBufferSize = 6 * 480;

	constexpr int32_t kMaxInputSampleRateHz = 192000;

	class AudioCodingModuleImpl final : public AudioCodingModule {
	public:
	explicit AudioCodingModuleImpl(const AudioCodingModule::Config& config);
	~AudioCodingModuleImpl() override;

	/////////////////////////////////////////
	// Sender
	//

	void ModifyEncoder(rtc::FunctionView<void(std::unique_ptr<AudioEncoder>*)>
	modifier) override;

	// Register a transport callback which will be
	// called to deliver the encoded buffers.
	int RegisterTransportCallback(AudioPacketizationCallback* transport) override;

	// Add 10 ms of raw (PCM) audio data to the encoder.
	int Add10MsData(const AudioFrame& audio_frame) override;

	/////////////////////////////////////////
	// (FEC) Forward Error Correction (codec internal)
	//

	// Set target packet loss rate
	int SetPacketLossRate(int loss_rate) override;

	/////////////////////////////////////////
	// Receiver
	//

	// Initialize receiver, resets codec database etc.
	int InitializeReceiver() override;

	void SetReceiveCodecs(const std::map<int, SdpAudioFormat>& codecs) override;

	// Incoming packet from network parsed and ready for decode.
	int IncomingPacket(const uint8_t* incoming_payload,
	const size_t payload_length,
	const RTPHeader& rtp_info) override;

	// Get 10 milliseconds of raw audio data to play out, and
	// automatic resample to the requested frequency if > 0.
	int PlayoutData10Ms(int desired_freq_hz,
	AudioFrame* audio_frame,
	bool* muted) override;

	/////////////////////////////////////////
	// Statistics
	//

	int GetNetworkStatistics(NetworkStatistics* statistics) override;

	ANAStats GetANAStats() const override;

	private:
	struct InputData {
	InputData() : buffer(kInitialInputDataBufferSize) {}
	uint32_t input_timestamp;
	const int16_t* audio;
	size_t length_per_channel;
	size_t audio_channel;
	// If a re-mix is required (up or down), this buffer will store a re-mixed
	// version of the input.
	std::vector<int16_t> buffer;
	};

	InputData input_data_ RTC_GUARDED_BY(acm_mutex_);

	// This member class writes values to the named UMA histogram, but only if
	// the value has changed since the last time (and always for the first call).
	class ChangeLogger {
	public:
	explicit ChangeLogger(const std::string& histogram_name)
	: histogram_name_(histogram_name) {}
	// Logs the new value if it is different from the last logged value, or if
	// this is the first call.
	void MaybeLog(int value);

	private:
	int last_value_ = 0;
	int first_time_ = true;
	const std::string histogram_name_;
	};

	int Add10MsDataInternal(const AudioFrame& audio_frame, InputData* input_data)
	RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

	// TODO(bugs.webrtc.org/10739): change \|absolute_capture_timestamp_ms\| to
	// int64_t when it always receives a valid value.
	int Encode(const InputData& input_data,
	absl::optional<int64_t> absolute_capture_timestamp_ms)
	RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

	int InitializeReceiverSafe() RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

	bool HaveValidEncoder(const char* caller_name) const
	RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

	// Preprocessing of input audio, including resampling and down-mixing if
	// required, before pushing audio into encoder's buffer.
	//
	// in_frame: input audio-frame
	// ptr_out: pointer to output audio_frame. If no preprocessing is required
	// \|ptr_out\| will be pointing to \|in_frame\|, otherwise pointing to
	// \|preprocess_frame_\|.
	//
	// Return value:
	// -1: if encountering an error.
	// 0: otherwise.
	int PreprocessToAddData(const AudioFrame& in_frame,
	const AudioFrame** ptr_out)
	RTC_EXCLUSIVE_LOCKS_REQUIRED(acm_mutex_);

	// Change required states after starting to receive the codec corresponding
	// to \|index\|.
	int UpdateUponReceivingCodec(int index);

	mutable Mutex acm_mutex_;
	rtc::Buffer encode_buffer_ RTC_GUARDED_BY(acm_mutex_);
	uint32_t expected_codec_ts_ RTC_GUARDED_BY(acm_mutex_);
	uint32_t expected_in_ts_ RTC_GUARDED_BY(acm_mutex_);
	acm2::ACMResampler resampler_ RTC_GUARDED_BY(acm_mutex_);
	acm2::AcmReceiver receiver_; // AcmReceiver has it's own internal lock.
	ChangeLogger bitrate_logger_ RTC_GUARDED_BY(acm_mutex_);

	// Current encoder stack, provided by a call to RegisterEncoder.
	std::unique_ptr<AudioEncoder> encoder_stack_ RTC_GUARDED_BY(acm_mutex_);

	// This is to keep track of CN instances where we can send DTMFs.
	uint8_t previous_pltype_ RTC_GUARDED_BY(acm_mutex_);

	bool receiver_initialized_ RTC_GUARDED_BY(acm_mutex_);

	AudioFrame preprocess_frame_ RTC_GUARDED_BY(acm_mutex_);
	bool first_10ms_data_ RTC_GUARDED_BY(acm_mutex_);

	bool first_frame_ RTC_GUARDED_BY(acm_mutex_);
	uint32_t last_timestamp_ RTC_GUARDED_BY(acm_mutex_);
	uint32_t last_rtp_timestamp_ RTC_GUARDED_BY(acm_mutex_);

	Mutex callback_mutex_;
	AudioPacketizationCallback* packetization_callback_
	RTC_GUARDED_BY(callback_mutex_);

	int codec_histogram_bins_log_[static_cast<size_t>(
	AudioEncoder::CodecType::kMaxLoggedAudioCodecTypes)];
	int number_of_consecutive_empty_packets_;
	};

	// Adds a codec usage sample to the histogram.
	void UpdateCodecTypeHistogram(size_t codec_type) {
	RTC_HISTOGRAM_ENUMERATION(
	"WebRTC.Audio.Encoder.CodecType", static_cast<int>(codec_type),
	static_cast<int>(
	webrtc::AudioEncoder::CodecType::kMaxLoggedAudioCodecTypes));
	}

	void AudioCodingModuleImpl::ChangeLogger::MaybeLog(int value) {
	if (value != last_value_ \|\| first_time_) {
	first_time_ = false;
	last_value_ = value;
	RTC_HISTOGRAM_COUNTS_SPARSE_100(histogram_name_, value);
	}
	}

	AudioCodingModuleImpl::AudioCodingModuleImpl(
	const AudioCodingModule::Config& config)
	: expected_codec_ts_(0xD87F3F9F),
	expected_in_ts_(0xD87F3F9F),
	receiver_(config),
	bitrate_logger_("WebRTC.Audio.TargetBitrateInKbps"),
	encoder_stack_(nullptr),
	previous_pltype_(255),
	receiver_initialized_(false),
	first_10ms_data_(false),
	first_frame_(true),
	packetization_callback_(NULL),
	codec_histogram_bins_log_(),
	number_of_consecutive_empty_packets_(0) {
	if (InitializeReceiverSafe() < 0) {
	RTC_LOG(LS_ERROR) << "Cannot initialize receiver";
	}
	RTC_LOG(LS_INFO) << "Created";
	}

	AudioCodingModuleImpl::~AudioCodingModuleImpl() = default;

	int32_t AudioCodingModuleImpl::Encode(
	const InputData& input_data,
	absl::optional<int64_t> absolute_capture_timestamp_ms) {
	// TODO(bugs.webrtc.org/10739): add dcheck that
	// \|audio_frame.absolute_capture_timestamp_ms()\| always has a value.
	AudioEncoder::EncodedInfo encoded_info;
	uint8_t previous_pltype;

	// Check if there is an encoder before.
	if (!HaveValidEncoder("Process"))
	return -1;

	if (!first_frame_) {
	RTC_DCHECK(IsNewerTimestamp(input_data.input_timestamp, last_timestamp_))
	<< "Time should not move backwards";
	}

	// Scale the timestamp to the codec's RTP timestamp rate.
	uint32_t rtp_timestamp =
	first_frame_
	? input_data.input_timestamp
	: last_rtp_timestamp_ +
	rtc::dchecked_cast<uint32_t>(rtc::CheckedDivExact(
	int64_t{input_data.input_timestamp - last_timestamp_} *
	encoder_stack_->RtpTimestampRateHz(),
	int64_t{encoder_stack_->SampleRateHz()}));

	last_timestamp_ = input_data.input_timestamp;
	last_rtp_timestamp_ = rtp_timestamp;
	first_frame_ = false;

	// Clear the buffer before reuse - encoded data will get appended.
	encode_buffer_.Clear();
	encoded_info = encoder_stack_->Encode(
	rtp_timestamp,
	rtc::ArrayView<const int16_t>(
	input_data.audio,
	input_data.audio_channel * input_data.length_per_channel),
	&encode_buffer_);

	bitrate_logger_.MaybeLog(encoder_stack_->GetTargetBitrate() / 1000);
	if (encode_buffer_.size() == 0 && !encoded_info.send_even_if_empty) {
	// Not enough data.
	return 0;
	}
	previous_pltype = previous_pltype_; // Read it while we have the critsect.

	// Log codec type to histogram once every 500 packets.
	if (encoded_info.encoded_bytes == 0) {
	++number_of_consecutive_empty_packets_;
	} else {
	size_t codec_type = static_cast<size_t>(encoded_info.encoder_type);
	codec_histogram_bins_log_[codec_type] +=
	number_of_consecutive_empty_packets_ + 1;
	number_of_consecutive_empty_packets_ = 0;
	if (codec_histogram_bins_log_[codec_type] >= 500) {
	codec_histogram_bins_log_[codec_type] -= 500;
	UpdateCodecTypeHistogram(codec_type);
	}
	}

	AudioFrameType frame_type;
	if (encode_buffer_.size() == 0 && encoded_info.send_even_if_empty) {
	frame_type = AudioFrameType::kEmptyFrame;
	encoded_info.payload_type = previous_pltype;
	} else {
	RTC_DCHECK_GT(encode_buffer_.size(), 0);
	frame_type = encoded_info.speech ? AudioFrameType::kAudioFrameSpeech
	: AudioFrameType::kAudioFrameCN;
	}

	{
	MutexLock lock(&callback_mutex_);
	if (packetization_callback_) {
	packetization_callback_->SendData(
	frame_type, encoded_info.payload_type, encoded_info.encoded_timestamp,
	encode_buffer_.data(), encode_buffer_.size(),
	absolute_capture_timestamp_ms.value_or(-1));
	}
	}
	previous_pltype_ = encoded_info.payload_type;
	return static_cast<int32_t>(encode_buffer_.size());
	}

	/////////////////////////////////////////
	// Sender
	//

	void AudioCodingModuleImpl::ModifyEncoder(
	rtc::FunctionView<void(std::unique_ptr<AudioEncoder>*)> modifier) {
	MutexLock lock(&acm_mutex_);
	modifier(&encoder_stack_);
	}

	// Register a transport callback which will be called to deliver
	// the encoded buffers.
	int AudioCodingModuleImpl::RegisterTransportCallback(
	AudioPacketizationCallback* transport) {
	MutexLock lock(&callback_mutex_);
	packetization_callback_ = transport;
	return 0;
	}

	// Add 10MS of raw (PCM) audio data to the encoder.
	int AudioCodingModuleImpl::Add10MsData(const AudioFrame& audio_frame) {
	MutexLock lock(&acm_mutex_);
	int r = Add10MsDataInternal(audio_frame, &input_data_);
	// TODO(bugs.webrtc.org/10739): add dcheck that
	// \|audio_frame.absolute_capture_timestamp_ms()\| always has a value.
	return r < 0
	? r
	: Encode(input_data_, audio_frame.absolute_capture_timestamp_ms());
	}

	int AudioCodingModuleImpl::Add10MsDataInternal(const AudioFrame& audio_frame,
	InputData* input_data) {
	if (audio_frame.samples_per_channel_ == 0) {
	assert(false);
	RTC_LOG(LS_ERROR) << "Cannot Add 10 ms audio, payload length is zero";
	return -1;
	}

	if (audio_frame.sample_rate_hz_ > kMaxInputSampleRateHz) {
	assert(false);
	RTC_LOG(LS_ERROR) << "Cannot Add 10 ms audio, input frequency not valid";
	return -1;
	}

	// If the length and frequency matches. We currently just support raw PCM.
	if (static_cast<size_t>(audio_frame.sample_rate_hz_ / 100) !=
	audio_frame.samples_per_channel_) {
	RTC_LOG(LS_ERROR)
	<< "Cannot Add 10 ms audio, input frequency and length doesn't match";
	return -1;
	}

	if (audio_frame.num_channels_ != 1 && audio_frame.num_channels_ != 2 &&
	audio_frame.num_channels_ != 4 && audio_frame.num_channels_ != 6 &&
	audio_frame.num_channels_ != 8) {
	RTC_LOG(LS_ERROR) << "Cannot Add 10 ms audio, invalid number of channels.";
	return -1;
	}

	// Do we have a codec registered?
	if (!HaveValidEncoder("Add10MsData")) {
	return -1;
	}

	const AudioFrame* ptr_frame;
	// Perform a resampling, also down-mix if it is required and can be
	// performed before resampling (a down mix prior to resampling will take
	// place if both primary and secondary encoders are mono and input is in
	// stereo).
	if (PreprocessToAddData(audio_frame, &ptr_frame) < 0) {
	return -1;
	}

	// Check whether we need an up-mix or down-mix?
	const size_t current_num_channels = encoder_stack_->NumChannels();
	const bool same_num_channels =
	ptr_frame->num_channels_ == current_num_channels;

	// TODO(yujo): Skip encode of muted frames.
	input_data->input_timestamp = ptr_frame->timestamp_;
	input_data->length_per_channel = ptr_frame->samples_per_channel_;
	input_data->audio_channel = current_num_channels;

	if (!same_num_channels) {
	// Remixes the input frame to the output data and in the process resize the
	// output data if needed.
	ReMixFrame(*ptr_frame, current_num_channels, &input_data->buffer);

	// For pushing data to primary, point the \|ptr_audio\| to correct buffer.
	input_data->audio = input_data->buffer.data();
	RTC_DCHECK_GE(input_data->buffer.size(),
	input_data->length_per_channel * input_data->audio_channel);
	} else {
	// When adding data to encoders this pointer is pointing to an audio buffer
	// with correct number of channels.
	input_data->audio = ptr_frame->data();
	}

	return 0;
	}

	// Perform a resampling and down-mix if required. We down-mix only if
	// encoder is mono and input is stereo. In case of dual-streaming, both
	// encoders has to be mono for down-mix to take place.
	// \|*ptr_out\| will point to the pre-processed audio-frame. If no pre-processing
	// is required, \|*ptr_out\| points to \|in_frame\|.
	// TODO(yujo): Make this more efficient for muted frames.
	int AudioCodingModuleImpl::PreprocessToAddData(const AudioFrame& in_frame,
	const AudioFrame** ptr_out) {
	const bool resample =
	in_frame.sample_rate_hz_ != encoder_stack_->SampleRateHz();

	// This variable is true if primary codec and secondary codec (if exists)
	// are both mono and input is stereo.
	// TODO(henrik.lundin): This condition should probably be
	// in_frame.num_channels_ > encoder_stack_->NumChannels()
	const bool down_mix =
	in_frame.num_channels_ == 2 && encoder_stack_->NumChannels() == 1;

	if (!first_10ms_data_) {
	expected_in_ts_ = in_frame.timestamp_;
	expected_codec_ts_ = in_frame.timestamp_;
	first_10ms_data_ = true;
	} else if (in_frame.timestamp_ != expected_in_ts_) {
	RTC_LOG(LS_WARNING) << "Unexpected input timestamp: " << in_frame.timestamp_
	<< ", expected: " << expected_in_ts_;
	expected_codec_ts_ +=
	(in_frame.timestamp_ - expected_in_ts_) *
	static_cast<uint32_t>(
	static_cast<double>(encoder_stack_->SampleRateHz()) /
	static_cast<double>(in_frame.sample_rate_hz_));
	expected_in_ts_ = in_frame.timestamp_;
	}

	if (!down_mix && !resample) {
	// No pre-processing is required.
	if (expected_in_ts_ == expected_codec_ts_) {
	// If we've never resampled, we can use the input frame as-is
	*ptr_out = &in_frame;
	} else {
	// Otherwise we'll need to alter the timestamp. Since in_frame is const,
	// we'll have to make a copy of it.
	preprocess_frame_.CopyFrom(in_frame);
	preprocess_frame_.timestamp_ = expected_codec_ts_;
	*ptr_out = &preprocess_frame_;
	}

	expected_in_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
	expected_codec_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
	return 0;
	}

	*ptr_out = &preprocess_frame_;
	preprocess_frame_.num_channels_ = in_frame.num_channels_;
	preprocess_frame_.samples_per_channel_ = in_frame.samples_per_channel_;
	std::array<int16_t, AudioFrame::kMaxDataSizeSamples> audio;
	const int16_t* src_ptr_audio;
	if (down_mix) {
	// If a resampling is required, the output of a down-mix is written into a
	// local buffer, otherwise, it will be written to the output frame.
	int16_t* dest_ptr_audio =
	resample ? audio.data() : preprocess_frame_.mutable_data();
	RTC_DCHECK_GE(audio.size(), preprocess_frame_.samples_per_channel_);
	RTC_DCHECK_GE(audio.size(), in_frame.samples_per_channel_);
	DownMixFrame(in_frame,
	rtc::ArrayView<int16_t>(
	dest_ptr_audio, preprocess_frame_.samples_per_channel_));
	preprocess_frame_.num_channels_ = 1;

	// Set the input of the resampler to the down-mixed signal.
	src_ptr_audio = audio.data();
	} else {
	// Set the input of the resampler to the original data.
	src_ptr_audio = in_frame.data();
	}

	preprocess_frame_.timestamp_ = expected_codec_ts_;
	preprocess_frame_.sample_rate_hz_ = in_frame.sample_rate_hz_;
	// If it is required, we have to do a resampling.
	if (resample) {
	// The result of the resampler is written to output frame.
	int16_t* dest_ptr_audio = preprocess_frame_.mutable_data();

	int samples_per_channel = resampler_.Resample10Msec(
	src_ptr_audio, in_frame.sample_rate_hz_, encoder_stack_->SampleRateHz(),
	preprocess_frame_.num_channels_, AudioFrame::kMaxDataSizeSamples,
	dest_ptr_audio);

	if (samples_per_channel < 0) {
	RTC_LOG(LS_ERROR) << "Cannot add 10 ms audio, resampling failed";
	return -1;
	}
	preprocess_frame_.samples_per_channel_ =
	static_cast<size_t>(samples_per_channel);
	preprocess_frame_.sample_rate_hz_ = encoder_stack_->SampleRateHz();
	}

	expected_codec_ts_ +=
	static_cast<uint32_t>(preprocess_frame_.samples_per_channel_);
	expected_in_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);

	return 0;
	}

	/////////////////////////////////////////
	// (FEC) Forward Error Correction (codec internal)
	//

	int AudioCodingModuleImpl::SetPacketLossRate(int loss_rate) {
	MutexLock lock(&acm_mutex_);
	if (HaveValidEncoder("SetPacketLossRate")) {
	encoder_stack_->OnReceivedUplinkPacketLossFraction(loss_rate / 100.0);
	}
	return 0;
	}

	/////////////////////////////////////////
	// Receiver
	//

	int AudioCodingModuleImpl::InitializeReceiver() {
	MutexLock lock(&acm_mutex_);
	return InitializeReceiverSafe();
	}

	// Initialize receiver, resets codec database etc.
	int AudioCodingModuleImpl::InitializeReceiverSafe() {
	// If the receiver is already initialized then we want to destroy any
	// existing decoders. After a call to this function, we should have a clean
	// start-up.
	if (receiver_initialized_)
	receiver_.RemoveAllCodecs();
	receiver_.FlushBuffers();

	receiver_initialized_ = true;
	return 0;
	}

	void AudioCodingModuleImpl::SetReceiveCodecs(
	const std::map<int, SdpAudioFormat>& codecs) {
	MutexLock lock(&acm_mutex_);
	receiver_.SetCodecs(codecs);
	}

	// Incoming packet from network parsed and ready for decode.
	int AudioCodingModuleImpl::IncomingPacket(const uint8_t* incoming_payload,
	const size_t payload_length,
	const RTPHeader& rtp_header) {
	RTC_DCHECK_EQ(payload_length == 0, incoming_payload == nullptr);
	return receiver_.InsertPacket(
	rtp_header,
	rtc::ArrayView<const uint8_t>(incoming_payload, payload_length));
	}

	// Get 10 milliseconds of raw audio data to play out.
	// Automatic resample to the requested frequency.
	int AudioCodingModuleImpl::PlayoutData10Ms(int desired_freq_hz,
	AudioFrame* audio_frame,
	bool* muted) {
	// GetAudio always returns 10 ms, at the requested sample rate.
	if (receiver_.GetAudio(desired_freq_hz, audio_frame, muted) != 0) {
	RTC_LOG(LS_ERROR) << "PlayoutData failed, RecOut Failed";
	return -1;
	}
	return 0;
	}

	/////////////////////////////////////////
	// Statistics
	//

	// TODO(turajs) change the return value to void. Also change the corresponding
	// NetEq function.
	int AudioCodingModuleImpl::GetNetworkStatistics(NetworkStatistics* statistics) {
	receiver_.GetNetworkStatistics(statistics);
	return 0;
	}

	bool AudioCodingModuleImpl::HaveValidEncoder(const char* caller_name) const {
	if (!encoder_stack_) {
	RTC_LOG(LS_ERROR) << caller_name << " failed: No send codec is registered.";
	return false;
	}
	return true;
	}

	ANAStats AudioCodingModuleImpl::GetANAStats() const {
	MutexLock lock(&acm_mutex_);
	if (encoder_stack_)
	return encoder_stack_->GetANAStats();
	// If no encoder is set, return default stats.
	return ANAStats();
	}

	} // namespace

	AudioCodingModule::Config::Config(
	rtc::scoped_refptr<AudioDecoderFactory> decoder_factory)
	: neteq_config(),
	clock(Clock::GetRealTimeClock()),
	decoder_factory(decoder_factory) {
	// Post-decode VAD is disabled by default in NetEq, however, Audio
	// Conference Mixer relies on VAD decisions and fails without them.
	neteq_config.enable_post_decode_vad = true;
	}

	AudioCodingModule::Config::Config(const Config&) = default;
	AudioCodingModule::Config::~Config() = default;

	AudioCodingModule* AudioCodingModule::Create(const Config& config) {
	return new AudioCodingModuleImpl(config);
	}

	} // namespace webrtc