// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "remoting/host/audio_capturer_win.h" #include #include #include #include #include #include #include "base/logging.h" namespace { const int kChannels = 2; const int kBytesPerSample = 2; const int kBitsPerSample = kBytesPerSample * 8; // Conversion factor from 100ns to 1ms. const int k100nsPerMillisecond = 10000; // Tolerance for catching packets of silence. If all samples have absolute // value less than this threshold, the packet will be counted as a packet of // silence. A value of 2 was chosen, because Windows can give samples of 1 and // -1, even when no audio is playing. const int kSilenceThreshold = 2; // Lower bound for timer intervals, in milliseconds. const int kMinTimerInterval = 30; // Upper bound for the timer precision error, in milliseconds. // Timers are supposed to be accurate to 20ms, so we use 30ms to be safe. const int kMaxExpectedTimerLag = 30; } // namespace namespace remoting { AudioCapturerWin::AudioCapturerWin() : sampling_rate_(AudioPacket::SAMPLING_RATE_INVALID), silence_detector_(kSilenceThreshold), last_capture_error_(S_OK) { thread_checker_.DetachFromThread(); } AudioCapturerWin::~AudioCapturerWin() { } bool AudioCapturerWin::Start(const PacketCapturedCallback& callback) { DCHECK(!audio_capture_client_.get()); DCHECK(!audio_client_.get()); DCHECK(!mm_device_.get()); DCHECK(static_cast(wave_format_ex_) == NULL); DCHECK(thread_checker_.CalledOnValidThread()); callback_ = callback; // Initialize the capture timer. capture_timer_.reset(new base::RepeatingTimer()); HRESULT hr = S_OK; base::win::ScopedComPtr mm_device_enumerator; hr = mm_device_enumerator.CreateInstance(__uuidof(MMDeviceEnumerator)); if (FAILED(hr)) { LOG(ERROR) << "Failed to create IMMDeviceEnumerator. Error " << hr; return false; } // Get the audio endpoint. hr = mm_device_enumerator->GetDefaultAudioEndpoint(eRender, eConsole, mm_device_.Receive()); if (FAILED(hr)) { LOG(ERROR) << "Failed to get IMMDevice. Error " << hr; return false; } // Get an audio client. hr = mm_device_->Activate(__uuidof(IAudioClient), CLSCTX_ALL, NULL, audio_client_.ReceiveVoid()); if (FAILED(hr)) { LOG(ERROR) << "Failed to get an IAudioClient. Error " << hr; return false; } REFERENCE_TIME device_period; hr = audio_client_->GetDevicePeriod(&device_period, NULL); if (FAILED(hr)) { LOG(ERROR) << "IAudioClient::GetDevicePeriod failed. Error " << hr; return false; } // We round up, if |device_period| / |k100nsPerMillisecond| // is not a whole number. int device_period_in_milliseconds = 1 + ((device_period - 1) / k100nsPerMillisecond); audio_device_period_ = base::TimeDelta::FromMilliseconds( std::max(device_period_in_milliseconds, kMinTimerInterval)); // Get the wave format. hr = audio_client_->GetMixFormat(&wave_format_ex_); if (FAILED(hr)) { LOG(ERROR) << "Failed to get WAVEFORMATEX. Error " << hr; return false; } // Set the wave format switch (wave_format_ex_->wFormatTag) { case WAVE_FORMAT_IEEE_FLOAT: // Intentional fall-through. case WAVE_FORMAT_PCM: if (!AudioCapturer::IsValidSampleRate(wave_format_ex_->nSamplesPerSec)) { LOG(ERROR) << "Host sampling rate is neither 44.1 kHz nor 48 kHz."; return false; } sampling_rate_ = static_cast( wave_format_ex_->nSamplesPerSec); wave_format_ex_->wFormatTag = WAVE_FORMAT_PCM; wave_format_ex_->nChannels = kChannels; wave_format_ex_->wBitsPerSample = kBitsPerSample; wave_format_ex_->nBlockAlign = kChannels * kBytesPerSample; wave_format_ex_->nAvgBytesPerSec = sampling_rate_ * kChannels * kBytesPerSample; break; case WAVE_FORMAT_EXTENSIBLE: { PWAVEFORMATEXTENSIBLE wave_format_extensible = reinterpret_cast( static_cast(wave_format_ex_)); if (IsEqualGUID(KSDATAFORMAT_SUBTYPE_IEEE_FLOAT, wave_format_extensible->SubFormat)) { if (!AudioCapturer::IsValidSampleRate( wave_format_extensible->Format.nSamplesPerSec)) { LOG(ERROR) << "Host sampling rate is neither 44.1 kHz nor 48 kHz."; return false; } sampling_rate_ = static_cast( wave_format_extensible->Format.nSamplesPerSec); wave_format_extensible->SubFormat = KSDATAFORMAT_SUBTYPE_PCM; wave_format_extensible->Samples.wValidBitsPerSample = kBitsPerSample; wave_format_extensible->Format.nChannels = kChannels; wave_format_extensible->Format.nSamplesPerSec = sampling_rate_; wave_format_extensible->Format.wBitsPerSample = kBitsPerSample; wave_format_extensible->Format.nBlockAlign = kChannels * kBytesPerSample; wave_format_extensible->Format.nAvgBytesPerSec = sampling_rate_ * kChannels * kBytesPerSample; } else { LOG(ERROR) << "Failed to force 16-bit samples"; return false; } break; } default: LOG(ERROR) << "Failed to force 16-bit PCM"; return false; } // Initialize the IAudioClient. hr = audio_client_->Initialize( AUDCLNT_SHAREMODE_SHARED, AUDCLNT_STREAMFLAGS_LOOPBACK, (kMaxExpectedTimerLag + audio_device_period_.InMilliseconds()) * k100nsPerMillisecond, 0, wave_format_ex_, NULL); if (FAILED(hr)) { LOG(ERROR) << "Failed to initialize IAudioClient. Error " << hr; return false; } // Get an IAudioCaptureClient. hr = audio_client_->GetService(__uuidof(IAudioCaptureClient), audio_capture_client_.ReceiveVoid()); if (FAILED(hr)) { LOG(ERROR) << "Failed to get an IAudioCaptureClient. Error " << hr; return false; } // Start the IAudioClient. hr = audio_client_->Start(); if (FAILED(hr)) { LOG(ERROR) << "Failed to start IAudioClient. Error " << hr; return false; } silence_detector_.Reset(sampling_rate_, kChannels); // Start capturing. capture_timer_->Start(FROM_HERE, audio_device_period_, this, &AudioCapturerWin::DoCapture); return true; } void AudioCapturerWin::Stop() { DCHECK(thread_checker_.CalledOnValidThread()); DCHECK(IsStarted()); capture_timer_.reset(); mm_device_.Release(); audio_client_.Release(); audio_capture_client_.Release(); wave_format_ex_.Reset(NULL); thread_checker_.DetachFromThread(); } bool AudioCapturerWin::IsStarted() { DCHECK(thread_checker_.CalledOnValidThread()); return capture_timer_.get() != NULL; } void AudioCapturerWin::DoCapture() { DCHECK(AudioCapturer::IsValidSampleRate(sampling_rate_)); DCHECK(thread_checker_.CalledOnValidThread()); DCHECK(IsStarted()); // Fetch all packets from the audio capture endpoint buffer. HRESULT hr = S_OK; while (true) { UINT32 next_packet_size; HRESULT hr = audio_capture_client_->GetNextPacketSize(&next_packet_size); if (FAILED(hr)) break; if (next_packet_size <= 0) { return; } BYTE* data; UINT32 frames; DWORD flags; hr = audio_capture_client_->GetBuffer(&data, &frames, &flags, NULL, NULL); if (FAILED(hr)) break; if ((flags & AUDCLNT_BUFFERFLAGS_SILENT) == 0 && !silence_detector_.IsSilence( reinterpret_cast(data), frames * kChannels)) { scoped_ptr packet(new AudioPacket()); packet->add_data(data, frames * wave_format_ex_->nBlockAlign); packet->set_encoding(AudioPacket::ENCODING_RAW); packet->set_sampling_rate(sampling_rate_); packet->set_bytes_per_sample(AudioPacket::BYTES_PER_SAMPLE_2); packet->set_channels(AudioPacket::CHANNELS_STEREO); callback_.Run(packet.Pass()); } hr = audio_capture_client_->ReleaseBuffer(frames); if (FAILED(hr)) break; } // There is nothing to capture if the audio endpoint device has been unplugged // or disabled. if (hr == AUDCLNT_E_DEVICE_INVALIDATED) return; // Avoid reporting the same error multiple times. if (FAILED(hr) && hr != last_capture_error_) { last_capture_error_ = hr; LOG(ERROR) << "Failed to capture an audio packet: 0x" << std::hex << hr << std::dec << "."; } } bool AudioCapturer::IsSupported() { return true; } scoped_ptr AudioCapturer::Create() { return make_scoped_ptr(new AudioCapturerWin()); } } // namespace remoting