/** * @file llwebrtc.cpp * @brief WebRTC interface implementation * * $LicenseInfo:firstyear=2023&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2023, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #include "llwebrtc_impl.h" #include #include #include "api/audio_codecs/audio_decoder_factory.h" #include "api/audio_codecs/audio_encoder_factory.h" #include "api/audio_codecs/builtin_audio_decoder_factory.h" #include "api/audio_codecs/builtin_audio_encoder_factory.h" #include "api/media_stream_interface.h" #include "api/media_stream_track.h" #include "modules/audio_processing/audio_buffer.h" namespace llwebrtc { static int16_t PLAYOUT_DEVICE_DEFAULT = -1; static int16_t PLAYOUT_DEVICE_BAD = -2; static int16_t RECORD_DEVICE_DEFAULT = -1; static int16_t RECORD_DEVICE_BAD = -2; LLAudioDeviceObserver::LLAudioDeviceObserver() : mSumVector {0}, mMicrophoneEnergy(0.0) {} float LLAudioDeviceObserver::getMicrophoneEnergy() { return mMicrophoneEnergy; } // TODO: Pull smoothing/filtering code into a common helper function // for LLAudioDeviceObserver and LLCustomProcessor void LLAudioDeviceObserver::OnCaptureData(const void *audio_samples, const size_t num_samples, const size_t bytes_per_sample, const size_t num_channels, const uint32_t samples_per_sec) { // calculate the energy float energy = 0; const short *samples = (const short *) audio_samples; for (size_t index = 0; index < num_samples * num_channels; index++) { float sample = (static_cast(samples[index]) / (float) 32767); energy += sample * sample; } // smooth it. size_t buffer_size = sizeof(mSumVector) / sizeof(mSumVector[0]); float totalSum = 0; int i; for (i = 0; i < (buffer_size - 1); i++) { mSumVector[i] = mSumVector[i + 1]; totalSum += mSumVector[i]; } mSumVector[i] = energy; totalSum += energy; mMicrophoneEnergy = std::sqrt(totalSum / (num_samples * buffer_size)); } void LLAudioDeviceObserver::OnRenderData(const void *audio_samples, const size_t num_samples, const size_t bytes_per_sample, const size_t num_channels, const uint32_t samples_per_sec) { } LLCustomProcessor::LLCustomProcessor() : mSampleRateHz(0), mNumChannels(0), mMicrophoneEnergy(0.0) { memset(mSumVector, 0, sizeof(mSumVector)); } void LLCustomProcessor::Initialize(int sample_rate_hz, int num_channels) { mSampleRateHz = sample_rate_hz; mNumChannels = num_channels; memset(mSumVector, 0, sizeof(mSumVector)); } void LLCustomProcessor::Process(webrtc::AudioBuffer *audio_in) { webrtc::StreamConfig stream_config; stream_config.set_sample_rate_hz(mSampleRateHz); stream_config.set_num_channels(mNumChannels); std::vector frame; std::vector frame_samples; if (audio_in->num_channels() < 1 || audio_in->num_frames() < 480) { return; } // grab the input audio frame_samples.resize(stream_config.num_samples()); frame.resize(stream_config.num_channels()); for (size_t ch = 0; ch < stream_config.num_channels(); ++ch) { frame[ch] = &(frame_samples)[ch * stream_config.num_frames()]; } audio_in->CopyTo(stream_config, &frame[0]); // calculate the energy float energy = 0; for (size_t index = 0; index < stream_config.num_samples(); index++) { float sample = frame_samples[index]; energy += sample * sample; } // smooth it. size_t buffer_size = sizeof(mSumVector) / sizeof(mSumVector[0]); float totalSum = 0; int i; for (i = 0; i < (buffer_size - 1); i++) { mSumVector[i] = mSumVector[i + 1]; totalSum += mSumVector[i]; } mSumVector[i] = energy; totalSum += energy; mMicrophoneEnergy = std::sqrt(totalSum / (stream_config.num_samples() * buffer_size)); } // // LLWebRTCImpl implementation // LLWebRTCImpl::LLWebRTCImpl() : mPeerCustomProcessor(nullptr), mMute(true), mTuningMode(false), mPlayoutDevice(0), mRecordingDevice(0), mTuningAudioDeviceObserver(nullptr) { } void LLWebRTCImpl::init() { mPlayoutDevice = 0; mRecordingDevice = 0; rtc::InitializeSSL(); // Normal logging is rather spammy, so turn it off. rtc::LogMessage::LogToDebug(rtc::LS_NONE); rtc::LogMessage::SetLogToStderr(true); mTaskQueueFactory = webrtc::CreateDefaultTaskQueueFactory(); // Create the native threads. mNetworkThread = rtc::Thread::CreateWithSocketServer(); mNetworkThread->SetName("WebRTCNetworkThread", nullptr); mNetworkThread->Start(); mWorkerThread = rtc::Thread::Create(); mWorkerThread->SetName("WebRTCWorkerThread", nullptr); mWorkerThread->Start(); mSignalingThread = rtc::Thread::Create(); mSignalingThread->SetName("WebRTCSignalingThread", nullptr); mSignalingThread->Start(); mTuningAudioDeviceObserver = new LLAudioDeviceObserver; mWorkerThread->PostTask( [this]() { // Initialize the audio devices on the Worker Thread mTuningDeviceModule = webrtc::CreateAudioDeviceWithDataObserver(webrtc::AudioDeviceModule::AudioLayer::kPlatformDefaultAudio, mTaskQueueFactory.get(), std::unique_ptr(mTuningAudioDeviceObserver)); mTuningDeviceModule->Init(); mTuningDeviceModule->SetPlayoutDevice(mPlayoutDevice); mTuningDeviceModule->SetRecordingDevice(mRecordingDevice); mTuningDeviceModule->EnableBuiltInAEC(false); mTuningDeviceModule->SetAudioDeviceSink(this); mTuningDeviceModule->InitMicrophone(); mTuningDeviceModule->InitSpeaker(); mTuningDeviceModule->InitRecording(); mTuningDeviceModule->InitPlayout(); mTuningDeviceModule->SetStereoRecording(true); mTuningDeviceModule->SetStereoPlayout(true); updateDevices(); }); mWorkerThread->BlockingCall( [this]() { // the peer device module doesn't need an observer // as we pull peer data after audio processing. mPeerDeviceModule = webrtc::CreateAudioDeviceWithDataObserver(webrtc::AudioDeviceModule::AudioLayer::kPlatformDefaultAudio, mTaskQueueFactory.get(), nullptr); mPeerDeviceModule->Init(); mPeerDeviceModule->SetPlayoutDevice(mPlayoutDevice); mPeerDeviceModule->SetRecordingDevice(mRecordingDevice); mPeerDeviceModule->EnableBuiltInAEC(false); mPeerDeviceModule->InitMicrophone(); mPeerDeviceModule->InitSpeaker(); mPeerDeviceModule->InitRecording(); mPeerDeviceModule->InitPlayout(); mPeerDeviceModule->SetStereoRecording(true); mPeerDeviceModule->SetStereoPlayout(true); }); // The custom processor allows us to retrieve audio data (and levels) // from after other audio processing such as AEC, AGC, etc. mPeerCustomProcessor = new LLCustomProcessor; webrtc::AudioProcessingBuilder apb; apb.SetCapturePostProcessing(std::unique_ptr(mPeerCustomProcessor)); mAudioProcessingModule = apb.Create(); webrtc::AudioProcessing::Config apm_config; apm_config.echo_canceller.enabled = false; apm_config.echo_canceller.mobile_mode = false; apm_config.gain_controller1.enabled = true; apm_config.gain_controller1.mode = webrtc::AudioProcessing::Config::GainController1::kAdaptiveAnalog; apm_config.gain_controller2.enabled = true; apm_config.high_pass_filter.enabled = true; apm_config.noise_suppression.enabled = true; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kVeryHigh; apm_config.transient_suppression.enabled = true; apm_config.pipeline.multi_channel_render = true; apm_config.pipeline.multi_channel_capture = true; apm_config.pipeline.multi_channel_capture = true; webrtc::ProcessingConfig processing_config; processing_config.input_stream().set_num_channels(2); processing_config.input_stream().set_sample_rate_hz(48000); processing_config.output_stream().set_num_channels(2); processing_config.output_stream().set_sample_rate_hz(48000); processing_config.reverse_input_stream().set_num_channels(2); processing_config.reverse_input_stream().set_sample_rate_hz(48000); processing_config.reverse_output_stream().set_num_channels(2); processing_config.reverse_output_stream().set_sample_rate_hz(48000); mAudioProcessingModule->ApplyConfig(apm_config); mAudioProcessingModule->Initialize(processing_config); mPeerConnectionFactory = webrtc::CreatePeerConnectionFactory(mNetworkThread.get(), mWorkerThread.get(), mSignalingThread.get(), mPeerDeviceModule, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::CreateBuiltinAudioDecoderFactory(), nullptr /* video_encoder_factory */, nullptr /* video_decoder_factory */, nullptr /* audio_mixer */, mAudioProcessingModule); mWorkerThread->BlockingCall([this]() { mPeerDeviceModule->StartPlayout(); }); } void LLWebRTCImpl::terminate() { for (auto &connection : mPeerConnections) { connection->terminate(); } // connection->terminate() above spawns a number of Signaling thread calls to // shut down the connection. The following Blocking Call will wait // until they're done before it's executed, allowing time to clean up. mSignalingThread->BlockingCall([this]() { mPeerConnectionFactory = nullptr; }); mPeerConnections.clear(); mWorkerThread->BlockingCall( [this]() { if (mTuningDeviceModule) { mTuningDeviceModule->StopRecording(); mTuningDeviceModule->Terminate(); } if (mPeerDeviceModule) { mPeerDeviceModule->StopRecording(); mPeerDeviceModule->Terminate(); } mTuningDeviceModule = nullptr; mPeerDeviceModule = nullptr; mTaskQueueFactory = nullptr; }); } // // Devices functions // // Most device-related functionality needs to happen // on the worker thread (the audio thread,) so those calls will be // proxied over to that thread. // void LLWebRTCImpl::setRecording(bool recording) { mWorkerThread->PostTask( [this, recording]() { if (recording) { mPeerDeviceModule->StartRecording(); } else { mPeerDeviceModule->StopRecording(); } }); } void LLWebRTCImpl::setAudioConfig(LLWebRTCDeviceInterface::AudioConfig config) { webrtc::AudioProcessing::Config apm_config; apm_config.echo_canceller.enabled = config.mEchoCancellation; apm_config.echo_canceller.mobile_mode = false; apm_config.gain_controller1.enabled = true; apm_config.gain_controller1.mode = webrtc::AudioProcessing::Config::GainController1::kAdaptiveAnalog; apm_config.gain_controller2.enabled = true; apm_config.high_pass_filter.enabled = true; apm_config.transient_suppression.enabled = true; apm_config.pipeline.multi_channel_render = true; apm_config.pipeline.multi_channel_capture = true; apm_config.pipeline.multi_channel_capture = true; switch (config.mNoiseSuppressionLevel) { case LLWebRTCDeviceInterface::AudioConfig::NOISE_SUPPRESSION_LEVEL_NONE: apm_config.noise_suppression.enabled = false; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kLow; break; case LLWebRTCDeviceInterface::AudioConfig::NOISE_SUPPRESSION_LEVEL_LOW: apm_config.noise_suppression.enabled = true; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kLow; break; case LLWebRTCDeviceInterface::AudioConfig::NOISE_SUPPRESSION_LEVEL_MODERATE: apm_config.noise_suppression.enabled = true; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kModerate; break; case LLWebRTCDeviceInterface::AudioConfig::NOISE_SUPPRESSION_LEVEL_HIGH: apm_config.noise_suppression.enabled = true; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kHigh; break; case LLWebRTCDeviceInterface::AudioConfig::NOISE_SUPPRESSION_LEVEL_VERY_HIGH: apm_config.noise_suppression.enabled = true; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kVeryHigh; break; default: apm_config.noise_suppression.enabled = false; apm_config.noise_suppression.level = webrtc::AudioProcessing::Config::NoiseSuppression::kLow; } mAudioProcessingModule->ApplyConfig(apm_config); } void LLWebRTCImpl::refreshDevices() { mWorkerThread->PostTask([this]() { updateDevices(); }); } void LLWebRTCImpl::setDevicesObserver(LLWebRTCDevicesObserver *observer) { mVoiceDevicesObserverList.emplace_back(observer); } void LLWebRTCImpl::unsetDevicesObserver(LLWebRTCDevicesObserver *observer) { std::vector::iterator it = std::find(mVoiceDevicesObserverList.begin(), mVoiceDevicesObserverList.end(), observer); if (it != mVoiceDevicesObserverList.end()) { mVoiceDevicesObserverList.erase(it); } } void ll_set_device_module_capture_device(rtc::scoped_refptr device_module, int16_t device) { device_module->StopRecording(); #if WEBRTC_WIN if (device < 0) { device_module->SetRecordingDevice(webrtc::AudioDeviceModule::kDefaultDevice); } else { device_module->SetRecordingDevice(device); } #else // passed in default is -1, but the device list // has it at 0 device_module->SetRecordingDevice(device + 1); #endif device_module->InitMicrophone(); device_module->InitRecording(); device_module->SetStereoRecording(false); device_module->StartRecording(); } void LLWebRTCImpl::setCaptureDevice(const std::string &id) { int16_t recordingDevice = RECORD_DEVICE_DEFAULT; if (id != "Default") { for (int16_t i = 0; i < mRecordingDeviceList.size(); i++) { if (mRecordingDeviceList[i].mID == id) { recordingDevice = i; break; } } } if (recordingDevice == mRecordingDevice) { return; } mRecordingDevice = recordingDevice; if (mTuningMode) { mWorkerThread->PostTask([this, recordingDevice]() { ll_set_device_module_capture_device(mTuningDeviceModule, recordingDevice); }); } else { mWorkerThread->PostTask([this, recordingDevice]() { ll_set_device_module_capture_device(mPeerDeviceModule, recordingDevice); }); } } void ll_set_device_module_render_device(rtc::scoped_refptr device_module, int16_t device) { device_module->StopPlayout(); #if WEBRTC_WIN if (device < 0) { device_module->SetPlayoutDevice(webrtc::AudioDeviceModule::kDefaultDevice); } else { device_module->SetPlayoutDevice(device); } #else device_module->SetPlayoutDevice(device + 1); #endif device_module->InitSpeaker(); device_module->InitPlayout(); device_module->SetStereoPlayout(true); } void LLWebRTCImpl::setRenderDevice(const std::string &id) { int16_t playoutDevice = PLAYOUT_DEVICE_DEFAULT; if (id != "Default") { for (int16_t i = 0; i < mPlayoutDeviceList.size(); i++) { if (mPlayoutDeviceList[i].mID == id) { playoutDevice = i; break; } } } if (playoutDevice == mPlayoutDevice) { return; } mPlayoutDevice = playoutDevice; if (mTuningMode) { mWorkerThread->PostTask( [this, playoutDevice]() { ll_set_device_module_render_device(mTuningDeviceModule, playoutDevice); }); } else { mWorkerThread->PostTask( [this, playoutDevice]() { ll_set_device_module_render_device(mPeerDeviceModule, playoutDevice); mPeerDeviceModule->StartPlayout(); }); } } // updateDevices needs to happen on the worker thread. void LLWebRTCImpl::updateDevices() { int16_t renderDeviceCount = mTuningDeviceModule->PlayoutDevices(); mPlayoutDeviceList.clear(); #if WEBRTC_WIN int16_t index = 0; #else // index zero is always "Default" for darwin/linux, // which is a special case, so skip it. int16_t index = 1; #endif for (; index < renderDeviceCount; index++) { char name[webrtc::kAdmMaxDeviceNameSize]; char guid[webrtc::kAdmMaxGuidSize]; mTuningDeviceModule->PlayoutDeviceName(index, name, guid); mPlayoutDeviceList.emplace_back(name, guid); } int16_t captureDeviceCount = mTuningDeviceModule->RecordingDevices(); mRecordingDeviceList.clear(); #if WEBRTC_WIN index = 0; #else // index zero is always "Default" for darwin/linux, // which is a special case, so skip it. index = 1; #endif for (; index < captureDeviceCount; index++) { char name[webrtc::kAdmMaxDeviceNameSize]; char guid[webrtc::kAdmMaxGuidSize]; mTuningDeviceModule->RecordingDeviceName(index, name, guid); mRecordingDeviceList.emplace_back(name, guid); } for (auto &observer : mVoiceDevicesObserverList) { observer->OnDevicesChanged(mPlayoutDeviceList, mRecordingDeviceList); } } void LLWebRTCImpl::OnDevicesUpdated() { // reset these to a bad value so an update is forced mRecordingDevice = RECORD_DEVICE_BAD; mPlayoutDevice = PLAYOUT_DEVICE_BAD; updateDevices(); } void LLWebRTCImpl::setTuningMode(bool enable) { mTuningMode = enable; mWorkerThread->PostTask( [this, enable] { if (enable) { mPeerDeviceModule->StopRecording(); mPeerDeviceModule->StopPlayout(); ll_set_device_module_render_device(mTuningDeviceModule, mPlayoutDevice); ll_set_device_module_capture_device(mTuningDeviceModule, mRecordingDevice); mTuningDeviceModule->InitPlayout(); mTuningDeviceModule->InitRecording(); mTuningDeviceModule->StartRecording(); // TODO: Starting Playout on the TDM appears to create an audio artifact (click) // in this case, so disabling it for now. We may have to do something different // if we enable 'echo playback' via the TDM when tuning. //mTuningDeviceModule->StartPlayout(); } else { mTuningDeviceModule->StopRecording(); //mTuningDeviceModule->StopPlayout(); ll_set_device_module_render_device(mPeerDeviceModule, mPlayoutDevice); ll_set_device_module_capture_device(mPeerDeviceModule, mRecordingDevice); mPeerDeviceModule->InitPlayout(); mPeerDeviceModule->InitRecording(); mPeerDeviceModule->StartPlayout(); mPeerDeviceModule->StartRecording(); } } ); mSignalingThread->PostTask( [this, enable] { for (auto &connection : mPeerConnections) { if (enable) { connection->enableSenderTracks(false); } else { connection->resetMute(); } connection->enableReceiverTracks(!enable); } }); } float LLWebRTCImpl::getTuningAudioLevel() { return -20 * log10f(mTuningAudioDeviceObserver->getMicrophoneEnergy()); } float LLWebRTCImpl::getPeerConnectionAudioLevel() { return -20 * log10f(mPeerCustomProcessor->getMicrophoneEnergy()); } // // Peer Connection Helpers // LLWebRTCPeerConnectionInterface *LLWebRTCImpl::newPeerConnection() { rtc::scoped_refptr peerConnection = rtc::scoped_refptr(new rtc::RefCountedObject()); peerConnection->init(this); mPeerConnections.emplace_back(peerConnection); peerConnection->enableSenderTracks(!mMute); return peerConnection.get(); } void LLWebRTCImpl::freePeerConnection(LLWebRTCPeerConnectionInterface* peer_connection) { std::vector>::iterator it = std::find(mPeerConnections.begin(), mPeerConnections.end(), peer_connection); if (it != mPeerConnections.end()) { mPeerConnections.erase(it); } if (mPeerConnections.empty()) { setRecording(false); } } // // LLWebRTCPeerConnectionImpl implementation. // // Most peer connection (signaling) happens on // the signaling thread. LLWebRTCPeerConnectionImpl::LLWebRTCPeerConnectionImpl() : mWebRTCImpl(nullptr), mPeerConnection(nullptr), mMute(false), mAnswerReceived(false) { } LLWebRTCPeerConnectionImpl::~LLWebRTCPeerConnectionImpl() { mSignalingObserverList.clear(); mDataObserverList.clear(); } // // LLWebRTCPeerConnection interface // void LLWebRTCPeerConnectionImpl::init(LLWebRTCImpl * webrtc_impl) { mWebRTCImpl = webrtc_impl; mPeerConnectionFactory = mWebRTCImpl->getPeerConnectionFactory(); } void LLWebRTCPeerConnectionImpl::terminate() { mWebRTCImpl->PostSignalingTask( [=]() { if (mPeerConnection) { if (mDataChannel) { { mDataChannel->Close(); mDataChannel = nullptr; } } mPeerConnection->Close(); if (mLocalStream) { auto tracks = mLocalStream->GetAudioTracks(); for (auto& track : tracks) { mLocalStream->RemoveTrack(track); } mLocalStream = nullptr; } mPeerConnection = nullptr; for (auto &observer : mSignalingObserverList) { observer->OnPeerConnectionClosed(); } } }); } void LLWebRTCPeerConnectionImpl::setSignalingObserver(LLWebRTCSignalingObserver *observer) { mSignalingObserverList.emplace_back(observer); } void LLWebRTCPeerConnectionImpl::unsetSignalingObserver(LLWebRTCSignalingObserver *observer) { std::vector::iterator it = std::find(mSignalingObserverList.begin(), mSignalingObserverList.end(), observer); if (it != mSignalingObserverList.end()) { mSignalingObserverList.erase(it); } } bool LLWebRTCPeerConnectionImpl::initializeConnection(const LLWebRTCPeerConnectionInterface::InitOptions& options) { RTC_DCHECK(!mPeerConnection); mAnswerReceived = false; mWebRTCImpl->PostSignalingTask( [this,options]() { webrtc::PeerConnectionInterface::RTCConfiguration config; for (auto server : options.mServers) { webrtc::PeerConnectionInterface::IceServer ice_server; for (auto url : server.mUrls) { ice_server.urls.push_back(url); } ice_server.username = server.mUserName; ice_server.password = server.mPassword; config.servers.push_back(ice_server); } config.sdp_semantics = webrtc::SdpSemantics::kUnifiedPlan; config.set_min_port(60000); config.set_max_port(60100); webrtc::PeerConnectionDependencies pc_dependencies(this); auto error_or_peer_connection = mPeerConnectionFactory->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); if (error_or_peer_connection.ok()) { mPeerConnection = std::move(error_or_peer_connection.value()); } else { RTC_LOG(LS_ERROR) << __FUNCTION__ << "Error creating peer connection: " << error_or_peer_connection.error().message(); for (auto &observer : mSignalingObserverList) { observer->OnRenegotiationNeeded(); } return; } webrtc::DataChannelInit init; init.ordered = true; auto data_channel_or_error = mPeerConnection->CreateDataChannelOrError("SLData", &init); if (data_channel_or_error.ok()) { mDataChannel = std::move(data_channel_or_error.value()); mDataChannel->RegisterObserver(this); } cricket::AudioOptions audioOptions; audioOptions.auto_gain_control = true; audioOptions.echo_cancellation = true; audioOptions.noise_suppression = true; mLocalStream = mPeerConnectionFactory->CreateLocalMediaStream("SLStream"); rtc::scoped_refptr audio_track( mPeerConnectionFactory->CreateAudioTrack("SLAudio", mPeerConnectionFactory->CreateAudioSource(audioOptions).get())); audio_track->set_enabled(false); mLocalStream->AddTrack(audio_track); mPeerConnection->AddTrack(audio_track, {"SLStream"}); auto senders = mPeerConnection->GetSenders(); for (auto &sender : senders) { webrtc::RtpParameters params; webrtc::RtpCodecParameters codecparam; codecparam.name = "opus"; codecparam.kind = cricket::MEDIA_TYPE_AUDIO; codecparam.clock_rate = 48000; codecparam.num_channels = 2; codecparam.parameters["stereo"] = "1"; codecparam.parameters["sprop-stereo"] = "1"; params.codecs.push_back(codecparam); sender->SetParameters(params); } auto receivers = mPeerConnection->GetReceivers(); for (auto &receiver : receivers) { webrtc::RtpParameters params; webrtc::RtpCodecParameters codecparam; codecparam.name = "opus"; codecparam.kind = cricket::MEDIA_TYPE_AUDIO; codecparam.clock_rate = 48000; codecparam.num_channels = 2; codecparam.parameters["stereo"] = "1"; codecparam.parameters["sprop-stereo"] = "1"; params.codecs.push_back(codecparam); receiver->SetParameters(params); } webrtc::PeerConnectionInterface::RTCOfferAnswerOptions offerOptions; mPeerConnection->CreateOffer(this, offerOptions); }); return true; } bool LLWebRTCPeerConnectionImpl::shutdownConnection() { terminate(); return true; } void LLWebRTCPeerConnectionImpl::enableSenderTracks(bool enable) { // set_enabled shouldn't be done on the worker thread. if (mPeerConnection) { auto senders = mPeerConnection->GetSenders(); for (auto &sender : senders) { sender->track()->set_enabled(enable); } } } void LLWebRTCPeerConnectionImpl::enableReceiverTracks(bool enable) { // set_enabled shouldn't be done on the worker thread if (mPeerConnection) { auto receivers = mPeerConnection->GetReceivers(); for (auto &receiver : receivers) { receiver->track()->set_enabled(enable); } } } // Tell the peer connection that we've received a SDP answer from the sim. void LLWebRTCPeerConnectionImpl::AnswerAvailable(const std::string &sdp) { RTC_LOG(LS_INFO) << __FUNCTION__ << " Remote SDP: " << sdp; mWebRTCImpl->PostSignalingTask( [this, sdp]() { if (mPeerConnection) { RTC_LOG(LS_INFO) << __FUNCTION__ << " " << mPeerConnection->peer_connection_state(); mPeerConnection->SetRemoteDescription(webrtc::CreateSessionDescription(webrtc::SdpType::kAnswer, sdp), rtc::scoped_refptr(this)); } }); } // // LLWebRTCAudioInterface implementation // void LLWebRTCPeerConnectionImpl::setMute(bool mute) { mMute = mute; mWebRTCImpl->PostSignalingTask( [this]() { if (mPeerConnection) { auto senders = mPeerConnection->GetSenders(); RTC_LOG(LS_INFO) << __FUNCTION__ << (mMute ? "disabling" : "enabling") << " streams count " << senders.size(); for (auto &sender : senders) { auto track = sender->track(); if (track) { track->set_enabled(!mMute); } } } }); } void LLWebRTCPeerConnectionImpl::resetMute() { setMute(mMute); } void LLWebRTCPeerConnectionImpl::setReceiveVolume(float volume) { mWebRTCImpl->PostSignalingTask( [this, volume]() { if (mPeerConnection) { auto receivers = mPeerConnection->GetReceivers(); for (auto &receiver : receivers) { for (auto &stream : receiver->streams()) { for (auto &track : stream->GetAudioTracks()) { track->GetSource()->SetVolume(volume); } } } } }); } void LLWebRTCPeerConnectionImpl::setSendVolume(float volume) { mWebRTCImpl->PostSignalingTask( [this, volume]() { if (mLocalStream) { for (auto &track : mLocalStream->GetAudioTracks()) { track->GetSource()->SetVolume(volume); } } }); } // // PeerConnectionObserver implementation. // void LLWebRTCPeerConnectionImpl::OnAddTrack(rtc::scoped_refptr receiver, const std::vector> &streams) { RTC_LOG(LS_INFO) << __FUNCTION__ << " " << receiver->id(); webrtc::RtpParameters params; webrtc::RtpCodecParameters codecparam; codecparam.name = "opus"; codecparam.kind = cricket::MEDIA_TYPE_AUDIO; codecparam.clock_rate = 48000; codecparam.num_channels = 2; codecparam.parameters["stereo"] = "1"; codecparam.parameters["sprop-stereo"] = "1"; params.codecs.push_back(codecparam); receiver->SetParameters(params); } void LLWebRTCPeerConnectionImpl::OnRemoveTrack(rtc::scoped_refptr receiver) { RTC_LOG(LS_INFO) << __FUNCTION__ << " " << receiver->id(); } void LLWebRTCPeerConnectionImpl::OnDataChannel(rtc::scoped_refptr channel) { if (mDataChannel) { mDataChannel->UnregisterObserver(); } mDataChannel = channel; channel->RegisterObserver(this); } void LLWebRTCPeerConnectionImpl::OnIceGatheringChange(webrtc::PeerConnectionInterface::IceGatheringState new_state) { LLWebRTCSignalingObserver::EIceGatheringState webrtc_new_state = LLWebRTCSignalingObserver::EIceGatheringState::ICE_GATHERING_NEW; switch (new_state) { case webrtc::PeerConnectionInterface::IceGatheringState::kIceGatheringNew: webrtc_new_state = LLWebRTCSignalingObserver::EIceGatheringState::ICE_GATHERING_NEW; break; case webrtc::PeerConnectionInterface::IceGatheringState::kIceGatheringGathering: webrtc_new_state = LLWebRTCSignalingObserver::EIceGatheringState::ICE_GATHERING_GATHERING; break; case webrtc::PeerConnectionInterface::IceGatheringState::kIceGatheringComplete: webrtc_new_state = LLWebRTCSignalingObserver::EIceGatheringState::ICE_GATHERING_COMPLETE; break; default: RTC_LOG(LS_ERROR) << __FUNCTION__ << " Bad Ice Gathering State" << new_state; webrtc_new_state = LLWebRTCSignalingObserver::EIceGatheringState::ICE_GATHERING_NEW; return; } if (mAnswerReceived) { for (auto &observer : mSignalingObserverList) { observer->OnIceGatheringState(webrtc_new_state); } } } // Called any time the PeerConnectionState changes. void LLWebRTCPeerConnectionImpl::OnConnectionChange(webrtc::PeerConnectionInterface::PeerConnectionState new_state) { RTC_LOG(LS_ERROR) << __FUNCTION__ << " Peer Connection State Change " << new_state; switch (new_state) { case webrtc::PeerConnectionInterface::PeerConnectionState::kConnected: { mWebRTCImpl->PostWorkerTask([this]() { for (auto &observer : mSignalingObserverList) { observer->OnAudioEstablished(this); } }); break; } case webrtc::PeerConnectionInterface::PeerConnectionState::kFailed: case webrtc::PeerConnectionInterface::PeerConnectionState::kDisconnected: { for (auto &observer : mSignalingObserverList) { observer->OnRenegotiationNeeded(); } break; } default: { break; } } } // Convert an ICE candidate into a string appropriate for trickling // to the Secondlife WebRTC server via the sim. static std::string iceCandidateToTrickleString(const webrtc::IceCandidateInterface *candidate) { std::ostringstream candidate_stream; candidate_stream << candidate->candidate().foundation() << " " << std::to_string(candidate->candidate().component()) << " " << candidate->candidate().protocol() << " " << std::to_string(candidate->candidate().priority()) << " " << candidate->candidate().address().ipaddr().ToString() << " " << candidate->candidate().address().PortAsString() << " typ "; if (candidate->candidate().type() == cricket::LOCAL_PORT_TYPE) { candidate_stream << "host"; } else if (candidate->candidate().type() == cricket::STUN_PORT_TYPE) { candidate_stream << "srflx " << "raddr " << candidate->candidate().related_address().ipaddr().ToString() << " " << "rport " << candidate->candidate().related_address().PortAsString(); } else if (candidate->candidate().type() == cricket::RELAY_PORT_TYPE) { candidate_stream << "relay " << "raddr " << candidate->candidate().related_address().ipaddr().ToString() << " " << "rport " << candidate->candidate().related_address().PortAsString(); } else if (candidate->candidate().type() == cricket::PRFLX_PORT_TYPE) { candidate_stream << "prflx " << "raddr " << candidate->candidate().related_address().ipaddr().ToString() << " " << "rport " << candidate->candidate().related_address().PortAsString(); } else { RTC_LOG(LS_ERROR) << __FUNCTION__ << " Unknown candidate type " << candidate->candidate().type(); } if (candidate->candidate().protocol() == "tcp") { candidate_stream << " tcptype " << candidate->candidate().tcptype(); } return candidate_stream.str(); } // The webrtc library has a new ice candidate. void LLWebRTCPeerConnectionImpl::OnIceCandidate(const webrtc::IceCandidateInterface *candidate) { RTC_LOG(LS_INFO) << __FUNCTION__ << " " << candidate->sdp_mline_index(); if (!candidate) { RTC_LOG(LS_ERROR) << __FUNCTION__ << " No Ice Candidate Given"; return; } if (mAnswerReceived) { // We've already received an answer SDP from the Secondlife WebRTC server // so simply tell observers about our new ice candidate. for (auto &observer : mSignalingObserverList) { LLWebRTCIceCandidate ice_candidate; ice_candidate.mCandidate = iceCandidateToTrickleString(candidate); ice_candidate.mMLineIndex = candidate->sdp_mline_index(); ice_candidate.mSdpMid = candidate->sdp_mid(); observer->OnIceCandidate(ice_candidate); } } else { // As we've not yet received our answer, cache the candidate. mCachedIceCandidates.push_back( webrtc::CreateIceCandidate(candidate->sdp_mid(), candidate->sdp_mline_index(), candidate->candidate())); } } // // CreateSessionDescriptionObserver implementation. // void LLWebRTCPeerConnectionImpl::OnSuccess(webrtc::SessionDescriptionInterface *desc) { std::string sdp; desc->ToString(&sdp); RTC_LOG(LS_INFO) << sdp; ; // mangle the sdp as this is the only way currently to bump up // the send audio rate to 48k std::istringstream sdp_stream(sdp); std::ostringstream sdp_mangled_stream; std::string sdp_line; std::string opus_payload; while (std::getline(sdp_stream, sdp_line)) { int bandwidth = 0; int payload_id = 0; // force mono down, stereo up if (std::sscanf(sdp_line.c_str(), "a=rtpmap:%i opus/%i/2", &payload_id, &bandwidth) == 2) { opus_payload = std::to_string(payload_id); sdp_mangled_stream << "a=rtpmap:" << opus_payload << " opus/48000/2" << "\n"; } else if (sdp_line.find("a=fmtp:" + opus_payload) == 0) { sdp_mangled_stream << sdp_line << "a=fmtp:" << opus_payload << " minptime=10;useinbandfec=1;stereo=1;sprop-stereo=1;maxplaybackrate=48000;sprop-maxplaybackrate=48000;sprop-maxcapturerate=48000\n"; } else { sdp_mangled_stream << sdp_line << "\n"; } } RTC_LOG(LS_INFO) << __FUNCTION__ << " Local SDP: " << sdp_mangled_stream.str(); std::string mangled_sdp = sdp_mangled_stream.str(); for (auto &observer : mSignalingObserverList) { observer->OnOfferAvailable(mangled_sdp); } mPeerConnection->SetLocalDescription(std::unique_ptr( webrtc::CreateSessionDescription(webrtc::SdpType::kOffer, mangled_sdp)), rtc::scoped_refptr(this)); } void LLWebRTCPeerConnectionImpl::OnFailure(webrtc::RTCError error) { RTC_LOG(LS_ERROR) << ToString(error.type()) << ": " << error.message(); for (auto &observer : mSignalingObserverList) { observer->OnRenegotiationNeeded(); } } // // SetRemoteDescriptionObserverInterface implementation. // void LLWebRTCPeerConnectionImpl::OnSetRemoteDescriptionComplete(webrtc::RTCError error) { // we've received an answer SDP from the sim. RTC_LOG(LS_INFO) << __FUNCTION__ << " " << mPeerConnection->signaling_state(); if (!error.ok()) { RTC_LOG(LS_ERROR) << ToString(error.type()) << ": " << error.message(); for (auto &observer : mSignalingObserverList) { observer->OnRenegotiationNeeded(); } return; } mAnswerReceived = true; // tell the observers about any cached ICE candidates. for (auto &observer : mSignalingObserverList) { for (auto &candidate : mCachedIceCandidates) { LLWebRTCIceCandidate ice_candidate; ice_candidate.mCandidate = iceCandidateToTrickleString(candidate.get()); ice_candidate.mMLineIndex = candidate->sdp_mline_index(); ice_candidate.mSdpMid = candidate->sdp_mid(); observer->OnIceCandidate(ice_candidate); } } mCachedIceCandidates.clear(); if (mPeerConnection) { OnIceGatheringChange(mPeerConnection->ice_gathering_state()); } } // // SetLocalDescriptionObserverInterface implementation. // void LLWebRTCPeerConnectionImpl::OnSetLocalDescriptionComplete(webrtc::RTCError error) { } // // DataChannelObserver implementation // void LLWebRTCPeerConnectionImpl::OnStateChange() { if (!mDataChannel) { return; } RTC_LOG(LS_INFO) << __FUNCTION__ << " Data Channel State: " << webrtc::DataChannelInterface::DataStateString(mDataChannel->state()); switch (mDataChannel->state()) { case webrtc::DataChannelInterface::kOpen: RTC_LOG(LS_INFO) << __FUNCTION__ << " Data Channel State Open"; for (auto &observer : mSignalingObserverList) { observer->OnDataChannelReady(this); } break; case webrtc::DataChannelInterface::kConnecting: RTC_LOG(LS_INFO) << __FUNCTION__ << " Data Channel State Connecting"; break; case webrtc::DataChannelInterface::kClosing: RTC_LOG(LS_INFO) << __FUNCTION__ << " Data Channel State closing"; break; case webrtc::DataChannelInterface::kClosed: RTC_LOG(LS_INFO) << __FUNCTION__ << " Data Channel State closed"; break; default: break; } } void LLWebRTCPeerConnectionImpl::OnMessage(const webrtc::DataBuffer& buffer) { std::string data((const char*)buffer.data.cdata(), buffer.size()); for (auto &observer : mDataObserverList) { observer->OnDataReceived(data, buffer.binary); } } // // LLWebRTCDataInterface // void LLWebRTCPeerConnectionImpl::sendData(const std::string& data, bool binary) { if (mDataChannel) { rtc::CopyOnWriteBuffer cowBuffer(data.data(), data.length()); webrtc::DataBuffer buffer(cowBuffer, binary); mWebRTCImpl->PostNetworkTask([this, buffer]() { if (mDataChannel) { mDataChannel->Send(buffer); } }); } } void LLWebRTCPeerConnectionImpl::setDataObserver(LLWebRTCDataObserver* observer) { mDataObserverList.emplace_back(observer); } void LLWebRTCPeerConnectionImpl::unsetDataObserver(LLWebRTCDataObserver* observer) { std::vector::iterator it = std::find(mDataObserverList.begin(), mDataObserverList.end(), observer); if (it != mDataObserverList.end()) { mDataObserverList.erase(it); } } LLWebRTCImpl * gWebRTCImpl = nullptr; LLWebRTCDeviceInterface * getDeviceInterface() { return gWebRTCImpl; } LLWebRTCPeerConnectionInterface* newPeerConnection() { return gWebRTCImpl->newPeerConnection(); } void freePeerConnection(LLWebRTCPeerConnectionInterface* peer_connection) { gWebRTCImpl->freePeerConnection(peer_connection); } void init() { gWebRTCImpl = new LLWebRTCImpl(); gWebRTCImpl->init(); } void terminate() { if (gWebRTCImpl) { gWebRTCImpl->terminate(); gWebRTCImpl = nullptr; } } } // namespace llwebrtc