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      1 /*
      2  *  Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
      3  *
      4  *  Use of this source code is governed by a BSD-style license
      5  *  that can be found in the LICENSE file in the root of the source
      6  *  tree. An additional intellectual property rights grant can be found
      7  *  in the file PATENTS.  All contributing project authors may
      8  *  be found in the AUTHORS file in the root of the source tree.
      9  */
     10 
     11 #include "webrtc/modules/audio_coding/acm2/audio_coding_module_impl.h"
     12 
     13 #include <assert.h>
     14 #include <stdlib.h>
     15 #include <vector>
     16 
     17 #include "webrtc/base/checks.h"
     18 #include "webrtc/base/safe_conversions.h"
     19 #include "webrtc/engine_configurations.h"
     20 #include "webrtc/modules/audio_coding/include/audio_coding_module_typedefs.h"
     21 #include "webrtc/modules/audio_coding/acm2/acm_common_defs.h"
     22 #include "webrtc/modules/audio_coding/acm2/acm_resampler.h"
     23 #include "webrtc/modules/audio_coding/acm2/call_statistics.h"
     24 #include "webrtc/system_wrappers/include/critical_section_wrapper.h"
     25 #include "webrtc/system_wrappers/include/logging.h"
     26 #include "webrtc/system_wrappers/include/metrics.h"
     27 #include "webrtc/system_wrappers/include/rw_lock_wrapper.h"
     28 #include "webrtc/system_wrappers/include/trace.h"
     29 #include "webrtc/typedefs.h"
     30 
     31 namespace webrtc {
     32 
     33 namespace acm2 {
     34 
     35 namespace {
     36 
     37 // TODO(turajs): the same functionality is used in NetEq. If both classes
     38 // need them, make it a static function in ACMCodecDB.
     39 bool IsCodecRED(const CodecInst& codec) {
     40   return (STR_CASE_CMP(codec.plname, "RED") == 0);
     41 }
     42 
     43 bool IsCodecCN(const CodecInst& codec) {
     44   return (STR_CASE_CMP(codec.plname, "CN") == 0);
     45 }
     46 
     47 // Stereo-to-mono can be used as in-place.
     48 int DownMix(const AudioFrame& frame,
     49             size_t length_out_buff,
     50             int16_t* out_buff) {
     51   if (length_out_buff < frame.samples_per_channel_) {
     52     return -1;
     53   }
     54   for (size_t n = 0; n < frame.samples_per_channel_; ++n)
     55     out_buff[n] = (frame.data_[2 * n] + frame.data_[2 * n + 1]) >> 1;
     56   return 0;
     57 }
     58 
     59 // Mono-to-stereo can be used as in-place.
     60 int UpMix(const AudioFrame& frame, size_t length_out_buff, int16_t* out_buff) {
     61   if (length_out_buff < frame.samples_per_channel_) {
     62     return -1;
     63   }
     64   for (size_t n = frame.samples_per_channel_; n != 0; --n) {
     65     size_t i = n - 1;
     66     int16_t sample = frame.data_[i];
     67     out_buff[2 * i + 1] = sample;
     68     out_buff[2 * i] = sample;
     69   }
     70   return 0;
     71 }
     72 
     73 void ConvertEncodedInfoToFragmentationHeader(
     74     const AudioEncoder::EncodedInfo& info,
     75     RTPFragmentationHeader* frag) {
     76   if (info.redundant.empty()) {
     77     frag->fragmentationVectorSize = 0;
     78     return;
     79   }
     80 
     81   frag->VerifyAndAllocateFragmentationHeader(
     82       static_cast<uint16_t>(info.redundant.size()));
     83   frag->fragmentationVectorSize = static_cast<uint16_t>(info.redundant.size());
     84   size_t offset = 0;
     85   for (size_t i = 0; i < info.redundant.size(); ++i) {
     86     frag->fragmentationOffset[i] = offset;
     87     offset += info.redundant[i].encoded_bytes;
     88     frag->fragmentationLength[i] = info.redundant[i].encoded_bytes;
     89     frag->fragmentationTimeDiff[i] = rtc::checked_cast<uint16_t>(
     90         info.encoded_timestamp - info.redundant[i].encoded_timestamp);
     91     frag->fragmentationPlType[i] = info.redundant[i].payload_type;
     92   }
     93 }
     94 }  // namespace
     95 
     96 void AudioCodingModuleImpl::ChangeLogger::MaybeLog(int value) {
     97   if (value != last_value_ || first_time_) {
     98     first_time_ = false;
     99     last_value_ = value;
    100     RTC_HISTOGRAM_COUNTS_SPARSE_100(histogram_name_, value);
    101   }
    102 }
    103 
    104 AudioCodingModuleImpl::AudioCodingModuleImpl(
    105     const AudioCodingModule::Config& config)
    106     : acm_crit_sect_(CriticalSectionWrapper::CreateCriticalSection()),
    107       id_(config.id),
    108       expected_codec_ts_(0xD87F3F9F),
    109       expected_in_ts_(0xD87F3F9F),
    110       receiver_(config),
    111       bitrate_logger_("WebRTC.Audio.TargetBitrateInKbps"),
    112       previous_pltype_(255),
    113       receiver_initialized_(false),
    114       first_10ms_data_(false),
    115       first_frame_(true),
    116       callback_crit_sect_(CriticalSectionWrapper::CreateCriticalSection()),
    117       packetization_callback_(NULL),
    118       vad_callback_(NULL) {
    119   if (InitializeReceiverSafe() < 0) {
    120     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    121                  "Cannot initialize receiver");
    122   }
    123   WEBRTC_TRACE(webrtc::kTraceMemory, webrtc::kTraceAudioCoding, id_, "Created");
    124 }
    125 
    126 AudioCodingModuleImpl::~AudioCodingModuleImpl() = default;
    127 
    128 int32_t AudioCodingModuleImpl::Encode(const InputData& input_data) {
    129   AudioEncoder::EncodedInfo encoded_info;
    130   uint8_t previous_pltype;
    131 
    132   // Check if there is an encoder before.
    133   if (!HaveValidEncoder("Process"))
    134     return -1;
    135 
    136   AudioEncoder* audio_encoder = rent_a_codec_.GetEncoderStack();
    137   // Scale the timestamp to the codec's RTP timestamp rate.
    138   uint32_t rtp_timestamp =
    139       first_frame_ ? input_data.input_timestamp
    140                    : last_rtp_timestamp_ +
    141                          rtc::CheckedDivExact(
    142                              input_data.input_timestamp - last_timestamp_,
    143                              static_cast<uint32_t>(rtc::CheckedDivExact(
    144                                  audio_encoder->SampleRateHz(),
    145                                  audio_encoder->RtpTimestampRateHz())));
    146   last_timestamp_ = input_data.input_timestamp;
    147   last_rtp_timestamp_ = rtp_timestamp;
    148   first_frame_ = false;
    149 
    150   encode_buffer_.SetSize(audio_encoder->MaxEncodedBytes());
    151   encoded_info = audio_encoder->Encode(
    152       rtp_timestamp, rtc::ArrayView<const int16_t>(
    153                          input_data.audio, input_data.audio_channel *
    154                                                input_data.length_per_channel),
    155       encode_buffer_.size(), encode_buffer_.data());
    156   encode_buffer_.SetSize(encoded_info.encoded_bytes);
    157   bitrate_logger_.MaybeLog(audio_encoder->GetTargetBitrate() / 1000);
    158   if (encode_buffer_.size() == 0 && !encoded_info.send_even_if_empty) {
    159     // Not enough data.
    160     return 0;
    161   }
    162   previous_pltype = previous_pltype_;  // Read it while we have the critsect.
    163 
    164   RTPFragmentationHeader my_fragmentation;
    165   ConvertEncodedInfoToFragmentationHeader(encoded_info, &my_fragmentation);
    166   FrameType frame_type;
    167   if (encode_buffer_.size() == 0 && encoded_info.send_even_if_empty) {
    168     frame_type = kEmptyFrame;
    169     encoded_info.payload_type = previous_pltype;
    170   } else {
    171     RTC_DCHECK_GT(encode_buffer_.size(), 0u);
    172     frame_type = encoded_info.speech ? kAudioFrameSpeech : kAudioFrameCN;
    173   }
    174 
    175   {
    176     CriticalSectionScoped lock(callback_crit_sect_.get());
    177     if (packetization_callback_) {
    178       packetization_callback_->SendData(
    179           frame_type, encoded_info.payload_type, encoded_info.encoded_timestamp,
    180           encode_buffer_.data(), encode_buffer_.size(),
    181           my_fragmentation.fragmentationVectorSize > 0 ? &my_fragmentation
    182                                                        : nullptr);
    183     }
    184 
    185     if (vad_callback_) {
    186       // Callback with VAD decision.
    187       vad_callback_->InFrameType(frame_type);
    188     }
    189   }
    190   previous_pltype_ = encoded_info.payload_type;
    191   return static_cast<int32_t>(encode_buffer_.size());
    192 }
    193 
    194 /////////////////////////////////////////
    195 //   Sender
    196 //
    197 
    198 // Can be called multiple times for Codec, CNG, RED.
    199 int AudioCodingModuleImpl::RegisterSendCodec(const CodecInst& send_codec) {
    200   CriticalSectionScoped lock(acm_crit_sect_.get());
    201   if (!codec_manager_.RegisterEncoder(send_codec)) {
    202     return -1;
    203   }
    204   auto* sp = codec_manager_.GetStackParams();
    205   if (!sp->speech_encoder && codec_manager_.GetCodecInst()) {
    206     // We have no speech encoder, but we have a specification for making one.
    207     AudioEncoder* enc =
    208         rent_a_codec_.RentEncoder(*codec_manager_.GetCodecInst());
    209     if (!enc)
    210       return -1;
    211     sp->speech_encoder = enc;
    212   }
    213   if (sp->speech_encoder)
    214     rent_a_codec_.RentEncoderStack(sp);
    215   return 0;
    216 }
    217 
    218 void AudioCodingModuleImpl::RegisterExternalSendCodec(
    219     AudioEncoder* external_speech_encoder) {
    220   CriticalSectionScoped lock(acm_crit_sect_.get());
    221   auto* sp = codec_manager_.GetStackParams();
    222   sp->speech_encoder = external_speech_encoder;
    223   rent_a_codec_.RentEncoderStack(sp);
    224 }
    225 
    226 // Get current send codec.
    227 rtc::Optional<CodecInst> AudioCodingModuleImpl::SendCodec() const {
    228   CriticalSectionScoped lock(acm_crit_sect_.get());
    229   auto* ci = codec_manager_.GetCodecInst();
    230   if (ci) {
    231     return rtc::Optional<CodecInst>(*ci);
    232   }
    233   auto* enc = codec_manager_.GetStackParams()->speech_encoder;
    234   if (enc) {
    235     return rtc::Optional<CodecInst>(CodecManager::ForgeCodecInst(enc));
    236   }
    237   return rtc::Optional<CodecInst>();
    238 }
    239 
    240 // Get current send frequency.
    241 int AudioCodingModuleImpl::SendFrequency() const {
    242   WEBRTC_TRACE(webrtc::kTraceStream, webrtc::kTraceAudioCoding, id_,
    243                "SendFrequency()");
    244   CriticalSectionScoped lock(acm_crit_sect_.get());
    245 
    246   const auto* enc = rent_a_codec_.GetEncoderStack();
    247   if (!enc) {
    248     WEBRTC_TRACE(webrtc::kTraceStream, webrtc::kTraceAudioCoding, id_,
    249                  "SendFrequency Failed, no codec is registered");
    250     return -1;
    251   }
    252 
    253   return enc->SampleRateHz();
    254 }
    255 
    256 void AudioCodingModuleImpl::SetBitRate(int bitrate_bps) {
    257   CriticalSectionScoped lock(acm_crit_sect_.get());
    258   auto* enc = rent_a_codec_.GetEncoderStack();
    259   if (enc) {
    260     enc->SetTargetBitrate(bitrate_bps);
    261   }
    262 }
    263 
    264 // Register a transport callback which will be called to deliver
    265 // the encoded buffers.
    266 int AudioCodingModuleImpl::RegisterTransportCallback(
    267     AudioPacketizationCallback* transport) {
    268   CriticalSectionScoped lock(callback_crit_sect_.get());
    269   packetization_callback_ = transport;
    270   return 0;
    271 }
    272 
    273 // Add 10MS of raw (PCM) audio data to the encoder.
    274 int AudioCodingModuleImpl::Add10MsData(const AudioFrame& audio_frame) {
    275   InputData input_data;
    276   CriticalSectionScoped lock(acm_crit_sect_.get());
    277   int r = Add10MsDataInternal(audio_frame, &input_data);
    278   return r < 0 ? r : Encode(input_data);
    279 }
    280 
    281 int AudioCodingModuleImpl::Add10MsDataInternal(const AudioFrame& audio_frame,
    282                                                InputData* input_data) {
    283   if (audio_frame.samples_per_channel_ == 0) {
    284     assert(false);
    285     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    286                  "Cannot Add 10 ms audio, payload length is zero");
    287     return -1;
    288   }
    289 
    290   if (audio_frame.sample_rate_hz_ > 48000) {
    291     assert(false);
    292     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    293                  "Cannot Add 10 ms audio, input frequency not valid");
    294     return -1;
    295   }
    296 
    297   // If the length and frequency matches. We currently just support raw PCM.
    298   if (static_cast<size_t>(audio_frame.sample_rate_hz_ / 100) !=
    299       audio_frame.samples_per_channel_) {
    300     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    301                  "Cannot Add 10 ms audio, input frequency and length doesn't"
    302                  " match");
    303     return -1;
    304   }
    305 
    306   if (audio_frame.num_channels_ != 1 && audio_frame.num_channels_ != 2) {
    307     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    308                  "Cannot Add 10 ms audio, invalid number of channels.");
    309     return -1;
    310   }
    311 
    312   // Do we have a codec registered?
    313   if (!HaveValidEncoder("Add10MsData")) {
    314     return -1;
    315   }
    316 
    317   const AudioFrame* ptr_frame;
    318   // Perform a resampling, also down-mix if it is required and can be
    319   // performed before resampling (a down mix prior to resampling will take
    320   // place if both primary and secondary encoders are mono and input is in
    321   // stereo).
    322   if (PreprocessToAddData(audio_frame, &ptr_frame) < 0) {
    323     return -1;
    324   }
    325 
    326   // Check whether we need an up-mix or down-mix?
    327   const size_t current_num_channels =
    328       rent_a_codec_.GetEncoderStack()->NumChannels();
    329   const bool same_num_channels =
    330       ptr_frame->num_channels_ == current_num_channels;
    331 
    332   if (!same_num_channels) {
    333     if (ptr_frame->num_channels_ == 1) {
    334       if (UpMix(*ptr_frame, WEBRTC_10MS_PCM_AUDIO, input_data->buffer) < 0)
    335         return -1;
    336     } else {
    337       if (DownMix(*ptr_frame, WEBRTC_10MS_PCM_AUDIO, input_data->buffer) < 0)
    338         return -1;
    339     }
    340   }
    341 
    342   // When adding data to encoders this pointer is pointing to an audio buffer
    343   // with correct number of channels.
    344   const int16_t* ptr_audio = ptr_frame->data_;
    345 
    346   // For pushing data to primary, point the |ptr_audio| to correct buffer.
    347   if (!same_num_channels)
    348     ptr_audio = input_data->buffer;
    349 
    350   input_data->input_timestamp = ptr_frame->timestamp_;
    351   input_data->audio = ptr_audio;
    352   input_data->length_per_channel = ptr_frame->samples_per_channel_;
    353   input_data->audio_channel = current_num_channels;
    354 
    355   return 0;
    356 }
    357 
    358 // Perform a resampling and down-mix if required. We down-mix only if
    359 // encoder is mono and input is stereo. In case of dual-streaming, both
    360 // encoders has to be mono for down-mix to take place.
    361 // |*ptr_out| will point to the pre-processed audio-frame. If no pre-processing
    362 // is required, |*ptr_out| points to |in_frame|.
    363 int AudioCodingModuleImpl::PreprocessToAddData(const AudioFrame& in_frame,
    364                                                const AudioFrame** ptr_out) {
    365   const auto* enc = rent_a_codec_.GetEncoderStack();
    366   const bool resample = in_frame.sample_rate_hz_ != enc->SampleRateHz();
    367 
    368   // This variable is true if primary codec and secondary codec (if exists)
    369   // are both mono and input is stereo.
    370   // TODO(henrik.lundin): This condition should probably be
    371   //   in_frame.num_channels_ > enc->NumChannels()
    372   const bool down_mix = in_frame.num_channels_ == 2 && enc->NumChannels() == 1;
    373 
    374   if (!first_10ms_data_) {
    375     expected_in_ts_ = in_frame.timestamp_;
    376     expected_codec_ts_ = in_frame.timestamp_;
    377     first_10ms_data_ = true;
    378   } else if (in_frame.timestamp_ != expected_in_ts_) {
    379     // TODO(turajs): Do we need a warning here.
    380     expected_codec_ts_ +=
    381         (in_frame.timestamp_ - expected_in_ts_) *
    382         static_cast<uint32_t>(static_cast<double>(enc->SampleRateHz()) /
    383                               static_cast<double>(in_frame.sample_rate_hz_));
    384     expected_in_ts_ = in_frame.timestamp_;
    385   }
    386 
    387 
    388   if (!down_mix && !resample) {
    389     // No pre-processing is required.
    390     expected_in_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
    391     expected_codec_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
    392     *ptr_out = &in_frame;
    393     return 0;
    394   }
    395 
    396   *ptr_out = &preprocess_frame_;
    397   preprocess_frame_.num_channels_ = in_frame.num_channels_;
    398   int16_t audio[WEBRTC_10MS_PCM_AUDIO];
    399   const int16_t* src_ptr_audio = in_frame.data_;
    400   int16_t* dest_ptr_audio = preprocess_frame_.data_;
    401   if (down_mix) {
    402     // If a resampling is required the output of a down-mix is written into a
    403     // local buffer, otherwise, it will be written to the output frame.
    404     if (resample)
    405       dest_ptr_audio = audio;
    406     if (DownMix(in_frame, WEBRTC_10MS_PCM_AUDIO, dest_ptr_audio) < 0)
    407       return -1;
    408     preprocess_frame_.num_channels_ = 1;
    409     // Set the input of the resampler is the down-mixed signal.
    410     src_ptr_audio = audio;
    411   }
    412 
    413   preprocess_frame_.timestamp_ = expected_codec_ts_;
    414   preprocess_frame_.samples_per_channel_ = in_frame.samples_per_channel_;
    415   preprocess_frame_.sample_rate_hz_ = in_frame.sample_rate_hz_;
    416   // If it is required, we have to do a resampling.
    417   if (resample) {
    418     // The result of the resampler is written to output frame.
    419     dest_ptr_audio = preprocess_frame_.data_;
    420 
    421     int samples_per_channel = resampler_.Resample10Msec(
    422         src_ptr_audio, in_frame.sample_rate_hz_, enc->SampleRateHz(),
    423         preprocess_frame_.num_channels_, AudioFrame::kMaxDataSizeSamples,
    424         dest_ptr_audio);
    425 
    426     if (samples_per_channel < 0) {
    427       WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    428                    "Cannot add 10 ms audio, resampling failed");
    429       return -1;
    430     }
    431     preprocess_frame_.samples_per_channel_ =
    432         static_cast<size_t>(samples_per_channel);
    433     preprocess_frame_.sample_rate_hz_ = enc->SampleRateHz();
    434   }
    435 
    436   expected_codec_ts_ +=
    437       static_cast<uint32_t>(preprocess_frame_.samples_per_channel_);
    438   expected_in_ts_ += static_cast<uint32_t>(in_frame.samples_per_channel_);
    439 
    440   return 0;
    441 }
    442 
    443 /////////////////////////////////////////
    444 //   (RED) Redundant Coding
    445 //
    446 
    447 bool AudioCodingModuleImpl::REDStatus() const {
    448   CriticalSectionScoped lock(acm_crit_sect_.get());
    449   return codec_manager_.GetStackParams()->use_red;
    450 }
    451 
    452 // Configure RED status i.e on/off.
    453 int AudioCodingModuleImpl::SetREDStatus(bool enable_red) {
    454 #ifdef WEBRTC_CODEC_RED
    455   CriticalSectionScoped lock(acm_crit_sect_.get());
    456   if (!codec_manager_.SetCopyRed(enable_red)) {
    457     return -1;
    458   }
    459   auto* sp = codec_manager_.GetStackParams();
    460   if (sp->speech_encoder)
    461     rent_a_codec_.RentEncoderStack(sp);
    462   return 0;
    463 #else
    464   WEBRTC_TRACE(webrtc::kTraceWarning, webrtc::kTraceAudioCoding, id_,
    465                "  WEBRTC_CODEC_RED is undefined");
    466   return -1;
    467 #endif
    468 }
    469 
    470 /////////////////////////////////////////
    471 //   (FEC) Forward Error Correction (codec internal)
    472 //
    473 
    474 bool AudioCodingModuleImpl::CodecFEC() const {
    475   CriticalSectionScoped lock(acm_crit_sect_.get());
    476   return codec_manager_.GetStackParams()->use_codec_fec;
    477 }
    478 
    479 int AudioCodingModuleImpl::SetCodecFEC(bool enable_codec_fec) {
    480   CriticalSectionScoped lock(acm_crit_sect_.get());
    481   if (!codec_manager_.SetCodecFEC(enable_codec_fec)) {
    482     return -1;
    483   }
    484   auto* sp = codec_manager_.GetStackParams();
    485   if (sp->speech_encoder)
    486     rent_a_codec_.RentEncoderStack(sp);
    487   if (enable_codec_fec) {
    488     return sp->use_codec_fec ? 0 : -1;
    489   } else {
    490     RTC_DCHECK(!sp->use_codec_fec);
    491     return 0;
    492   }
    493 }
    494 
    495 int AudioCodingModuleImpl::SetPacketLossRate(int loss_rate) {
    496   CriticalSectionScoped lock(acm_crit_sect_.get());
    497   if (HaveValidEncoder("SetPacketLossRate")) {
    498     rent_a_codec_.GetEncoderStack()->SetProjectedPacketLossRate(loss_rate /
    499                                                                 100.0);
    500   }
    501   return 0;
    502 }
    503 
    504 /////////////////////////////////////////
    505 //   (VAD) Voice Activity Detection
    506 //
    507 int AudioCodingModuleImpl::SetVAD(bool enable_dtx,
    508                                   bool enable_vad,
    509                                   ACMVADMode mode) {
    510   // Note: |enable_vad| is not used; VAD is enabled based on the DTX setting.
    511   RTC_DCHECK_EQ(enable_dtx, enable_vad);
    512   CriticalSectionScoped lock(acm_crit_sect_.get());
    513   if (!codec_manager_.SetVAD(enable_dtx, mode)) {
    514     return -1;
    515   }
    516   auto* sp = codec_manager_.GetStackParams();
    517   if (sp->speech_encoder)
    518     rent_a_codec_.RentEncoderStack(sp);
    519   return 0;
    520 }
    521 
    522 // Get VAD/DTX settings.
    523 int AudioCodingModuleImpl::VAD(bool* dtx_enabled, bool* vad_enabled,
    524                                ACMVADMode* mode) const {
    525   CriticalSectionScoped lock(acm_crit_sect_.get());
    526   const auto* sp = codec_manager_.GetStackParams();
    527   *dtx_enabled = *vad_enabled = sp->use_cng;
    528   *mode = sp->vad_mode;
    529   return 0;
    530 }
    531 
    532 /////////////////////////////////////////
    533 //   Receiver
    534 //
    535 
    536 int AudioCodingModuleImpl::InitializeReceiver() {
    537   CriticalSectionScoped lock(acm_crit_sect_.get());
    538   return InitializeReceiverSafe();
    539 }
    540 
    541 // Initialize receiver, resets codec database etc.
    542 int AudioCodingModuleImpl::InitializeReceiverSafe() {
    543   // If the receiver is already initialized then we want to destroy any
    544   // existing decoders. After a call to this function, we should have a clean
    545   // start-up.
    546   if (receiver_initialized_) {
    547     if (receiver_.RemoveAllCodecs() < 0)
    548       return -1;
    549   }
    550   receiver_.set_id(id_);
    551   receiver_.ResetInitialDelay();
    552   receiver_.SetMinimumDelay(0);
    553   receiver_.SetMaximumDelay(0);
    554   receiver_.FlushBuffers();
    555 
    556   // Register RED and CN.
    557   auto db = RentACodec::Database();
    558   for (size_t i = 0; i < db.size(); i++) {
    559     if (IsCodecRED(db[i]) || IsCodecCN(db[i])) {
    560       if (receiver_.AddCodec(static_cast<int>(i),
    561                              static_cast<uint8_t>(db[i].pltype), 1,
    562                              db[i].plfreq, nullptr, db[i].plname) < 0) {
    563         WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    564                      "Cannot register master codec.");
    565         return -1;
    566       }
    567     }
    568   }
    569   receiver_initialized_ = true;
    570   return 0;
    571 }
    572 
    573 // Get current receive frequency.
    574 int AudioCodingModuleImpl::ReceiveFrequency() const {
    575   const auto last_packet_sample_rate = receiver_.last_packet_sample_rate_hz();
    576   return last_packet_sample_rate ? *last_packet_sample_rate
    577                                  : receiver_.last_output_sample_rate_hz();
    578 }
    579 
    580 // Get current playout frequency.
    581 int AudioCodingModuleImpl::PlayoutFrequency() const {
    582   WEBRTC_TRACE(webrtc::kTraceStream, webrtc::kTraceAudioCoding, id_,
    583                "PlayoutFrequency()");
    584   return receiver_.last_output_sample_rate_hz();
    585 }
    586 
    587 // Register possible receive codecs, can be called multiple times,
    588 // for codecs, CNG (NB, WB and SWB), DTMF, RED.
    589 int AudioCodingModuleImpl::RegisterReceiveCodec(const CodecInst& codec) {
    590   CriticalSectionScoped lock(acm_crit_sect_.get());
    591   RTC_DCHECK(receiver_initialized_);
    592   if (codec.channels > 2) {
    593     LOG_F(LS_ERROR) << "Unsupported number of channels: " << codec.channels;
    594     return -1;
    595   }
    596 
    597   auto codec_id =
    598       RentACodec::CodecIdByParams(codec.plname, codec.plfreq, codec.channels);
    599   if (!codec_id) {
    600     LOG_F(LS_ERROR) << "Wrong codec params to be registered as receive codec";
    601     return -1;
    602   }
    603   auto codec_index = RentACodec::CodecIndexFromId(*codec_id);
    604   RTC_CHECK(codec_index) << "Invalid codec ID: " << static_cast<int>(*codec_id);
    605 
    606   // Check if the payload-type is valid.
    607   if (!RentACodec::IsPayloadTypeValid(codec.pltype)) {
    608     LOG_F(LS_ERROR) << "Invalid payload type " << codec.pltype << " for "
    609                     << codec.plname;
    610     return -1;
    611   }
    612 
    613   // Get |decoder| associated with |codec|. |decoder| is NULL if |codec| does
    614   // not own its decoder.
    615   return receiver_.AddCodec(
    616       *codec_index, codec.pltype, codec.channels, codec.plfreq,
    617       STR_CASE_CMP(codec.plname, "isac") == 0 ? rent_a_codec_.RentIsacDecoder()
    618                                               : nullptr,
    619       codec.plname);
    620 }
    621 
    622 int AudioCodingModuleImpl::RegisterExternalReceiveCodec(
    623     int rtp_payload_type,
    624     AudioDecoder* external_decoder,
    625     int sample_rate_hz,
    626     int num_channels,
    627     const std::string& name) {
    628   CriticalSectionScoped lock(acm_crit_sect_.get());
    629   RTC_DCHECK(receiver_initialized_);
    630   if (num_channels > 2 || num_channels < 0) {
    631     LOG_F(LS_ERROR) << "Unsupported number of channels: " << num_channels;
    632     return -1;
    633   }
    634 
    635   // Check if the payload-type is valid.
    636   if (!RentACodec::IsPayloadTypeValid(rtp_payload_type)) {
    637     LOG_F(LS_ERROR) << "Invalid payload-type " << rtp_payload_type
    638                     << " for external decoder.";
    639     return -1;
    640   }
    641 
    642   return receiver_.AddCodec(-1 /* external */, rtp_payload_type, num_channels,
    643                             sample_rate_hz, external_decoder, name);
    644 }
    645 
    646 // Get current received codec.
    647 int AudioCodingModuleImpl::ReceiveCodec(CodecInst* current_codec) const {
    648   CriticalSectionScoped lock(acm_crit_sect_.get());
    649   return receiver_.LastAudioCodec(current_codec);
    650 }
    651 
    652 // Incoming packet from network parsed and ready for decode.
    653 int AudioCodingModuleImpl::IncomingPacket(const uint8_t* incoming_payload,
    654                                           const size_t payload_length,
    655                                           const WebRtcRTPHeader& rtp_header) {
    656   return receiver_.InsertPacket(
    657       rtp_header,
    658       rtc::ArrayView<const uint8_t>(incoming_payload, payload_length));
    659 }
    660 
    661 // Minimum playout delay (Used for lip-sync).
    662 int AudioCodingModuleImpl::SetMinimumPlayoutDelay(int time_ms) {
    663   if ((time_ms < 0) || (time_ms > 10000)) {
    664     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    665                  "Delay must be in the range of 0-1000 milliseconds.");
    666     return -1;
    667   }
    668   return receiver_.SetMinimumDelay(time_ms);
    669 }
    670 
    671 int AudioCodingModuleImpl::SetMaximumPlayoutDelay(int time_ms) {
    672   if ((time_ms < 0) || (time_ms > 10000)) {
    673     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    674                  "Delay must be in the range of 0-1000 milliseconds.");
    675     return -1;
    676   }
    677   return receiver_.SetMaximumDelay(time_ms);
    678 }
    679 
    680 // Get 10 milliseconds of raw audio data to play out.
    681 // Automatic resample to the requested frequency.
    682 int AudioCodingModuleImpl::PlayoutData10Ms(int desired_freq_hz,
    683                                            AudioFrame* audio_frame) {
    684   // GetAudio always returns 10 ms, at the requested sample rate.
    685   if (receiver_.GetAudio(desired_freq_hz, audio_frame) != 0) {
    686     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    687                  "PlayoutData failed, RecOut Failed");
    688     return -1;
    689   }
    690   audio_frame->id_ = id_;
    691   return 0;
    692 }
    693 
    694 /////////////////////////////////////////
    695 //   Statistics
    696 //
    697 
    698 // TODO(turajs) change the return value to void. Also change the corresponding
    699 // NetEq function.
    700 int AudioCodingModuleImpl::GetNetworkStatistics(NetworkStatistics* statistics) {
    701   receiver_.GetNetworkStatistics(statistics);
    702   return 0;
    703 }
    704 
    705 int AudioCodingModuleImpl::RegisterVADCallback(ACMVADCallback* vad_callback) {
    706   WEBRTC_TRACE(webrtc::kTraceDebug, webrtc::kTraceAudioCoding, id_,
    707                "RegisterVADCallback()");
    708   CriticalSectionScoped lock(callback_crit_sect_.get());
    709   vad_callback_ = vad_callback;
    710   return 0;
    711 }
    712 
    713 // TODO(kwiberg): Remove this method, and have callers call IncomingPacket
    714 // instead. The translation logic and state belong with them, not with
    715 // AudioCodingModuleImpl.
    716 int AudioCodingModuleImpl::IncomingPayload(const uint8_t* incoming_payload,
    717                                            size_t payload_length,
    718                                            uint8_t payload_type,
    719                                            uint32_t timestamp) {
    720   // We are not acquiring any lock when interacting with |aux_rtp_header_| no
    721   // other method uses this member variable.
    722   if (!aux_rtp_header_) {
    723     // This is the first time that we are using |dummy_rtp_header_|
    724     // so we have to create it.
    725     aux_rtp_header_.reset(new WebRtcRTPHeader);
    726     aux_rtp_header_->header.payloadType = payload_type;
    727     // Don't matter in this case.
    728     aux_rtp_header_->header.ssrc = 0;
    729     aux_rtp_header_->header.markerBit = false;
    730     // Start with random numbers.
    731     aux_rtp_header_->header.sequenceNumber = 0x1234;  // Arbitrary.
    732     aux_rtp_header_->type.Audio.channel = 1;
    733   }
    734 
    735   aux_rtp_header_->header.timestamp = timestamp;
    736   IncomingPacket(incoming_payload, payload_length, *aux_rtp_header_);
    737   // Get ready for the next payload.
    738   aux_rtp_header_->header.sequenceNumber++;
    739   return 0;
    740 }
    741 
    742 int AudioCodingModuleImpl::SetOpusApplication(OpusApplicationMode application) {
    743   CriticalSectionScoped lock(acm_crit_sect_.get());
    744   if (!HaveValidEncoder("SetOpusApplication")) {
    745     return -1;
    746   }
    747   AudioEncoder::Application app;
    748   switch (application) {
    749     case kVoip:
    750       app = AudioEncoder::Application::kSpeech;
    751       break;
    752     case kAudio:
    753       app = AudioEncoder::Application::kAudio;
    754       break;
    755     default:
    756       FATAL();
    757       return 0;
    758   }
    759   return rent_a_codec_.GetEncoderStack()->SetApplication(app) ? 0 : -1;
    760 }
    761 
    762 // Informs Opus encoder of the maximum playback rate the receiver will render.
    763 int AudioCodingModuleImpl::SetOpusMaxPlaybackRate(int frequency_hz) {
    764   CriticalSectionScoped lock(acm_crit_sect_.get());
    765   if (!HaveValidEncoder("SetOpusMaxPlaybackRate")) {
    766     return -1;
    767   }
    768   rent_a_codec_.GetEncoderStack()->SetMaxPlaybackRate(frequency_hz);
    769   return 0;
    770 }
    771 
    772 int AudioCodingModuleImpl::EnableOpusDtx() {
    773   CriticalSectionScoped lock(acm_crit_sect_.get());
    774   if (!HaveValidEncoder("EnableOpusDtx")) {
    775     return -1;
    776   }
    777   return rent_a_codec_.GetEncoderStack()->SetDtx(true) ? 0 : -1;
    778 }
    779 
    780 int AudioCodingModuleImpl::DisableOpusDtx() {
    781   CriticalSectionScoped lock(acm_crit_sect_.get());
    782   if (!HaveValidEncoder("DisableOpusDtx")) {
    783     return -1;
    784   }
    785   return rent_a_codec_.GetEncoderStack()->SetDtx(false) ? 0 : -1;
    786 }
    787 
    788 int AudioCodingModuleImpl::PlayoutTimestamp(uint32_t* timestamp) {
    789   return receiver_.GetPlayoutTimestamp(timestamp) ? 0 : -1;
    790 }
    791 
    792 bool AudioCodingModuleImpl::HaveValidEncoder(const char* caller_name) const {
    793   if (!rent_a_codec_.GetEncoderStack()) {
    794     WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceAudioCoding, id_,
    795                  "%s failed: No send codec is registered.", caller_name);
    796     return false;
    797   }
    798   return true;
    799 }
    800 
    801 int AudioCodingModuleImpl::UnregisterReceiveCodec(uint8_t payload_type) {
    802   return receiver_.RemoveCodec(payload_type);
    803 }
    804 
    805 int AudioCodingModuleImpl::EnableNack(size_t max_nack_list_size) {
    806   return receiver_.EnableNack(max_nack_list_size);
    807 }
    808 
    809 void AudioCodingModuleImpl::DisableNack() {
    810   receiver_.DisableNack();
    811 }
    812 
    813 std::vector<uint16_t> AudioCodingModuleImpl::GetNackList(
    814     int64_t round_trip_time_ms) const {
    815   return receiver_.GetNackList(round_trip_time_ms);
    816 }
    817 
    818 int AudioCodingModuleImpl::LeastRequiredDelayMs() const {
    819   return receiver_.LeastRequiredDelayMs();
    820 }
    821 
    822 void AudioCodingModuleImpl::GetDecodingCallStatistics(
    823       AudioDecodingCallStats* call_stats) const {
    824   receiver_.GetDecodingCallStatistics(call_stats);
    825 }
    826 
    827 }  // namespace acm2
    828 }  // namespace webrtc
    829