modules/audio_device/linux/audio_device_pulse_linux.h - 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.
  */

 #ifndef AUDIO_DEVICE_AUDIO_DEVICE_PULSE_LINUX_H_
 #define AUDIO_DEVICE_AUDIO_DEVICE_PULSE_LINUX_H_

 #include <memory>

 #include "api/sequence_checker.h"
 #include "modules/audio_device/audio_device_buffer.h"
 #include "modules/audio_device/audio_device_generic.h"
 #include "modules/audio_device/include/audio_device.h"
 #include "modules/audio_device/include/audio_device_defines.h"
 #include "modules/audio_device/linux/audio_mixer_manager_pulse_linux.h"
 #include "modules/audio_device/linux/pulseaudiosymboltable_linux.h"
 #include "rtc_base/event.h"
 #include "rtc_base/platform_thread.h"
 #include "rtc_base/synchronization/mutex.h"
 #include "rtc_base/thread_annotations.h"

 #if defined(WEBRTC_USE_X11)
 #include <X11/Xlib.h>
 #endif

 #include <pulse/pulseaudio.h>
 #include <stddef.h>
 #include <stdint.h>

 // We define this flag if it's missing from our headers, because we want to be
 // able to compile against old headers but still use PA_STREAM_ADJUST_LATENCY
 // if run against a recent version of the library.
 #ifndef PA_STREAM_ADJUST_LATENCY
 #define PA_STREAM_ADJUST_LATENCY 0x2000U
 #endif
 #ifndef PA_STREAM_START_MUTED
 #define PA_STREAM_START_MUTED 0x1000U
 #endif

 // Set this constant to 0 to disable latency reading
 const uint32_t WEBRTC_PA_REPORT_LATENCY = 1;

 // Constants from implementation by Tristan Schmelcher [tschmelcher@google.com]

 // First PulseAudio protocol version that supports PA_STREAM_ADJUST_LATENCY.
 const uint32_t WEBRTC_PA_ADJUST_LATENCY_PROTOCOL_VERSION = 13;

 // Some timing constants for optimal operation. See
 // https://tango.0pointer.de/pipermail/pulseaudio-discuss/2008-January/001170.html
 // for a good explanation of some of the factors that go into this.

 // Playback.

 // For playback, there is a round-trip delay to fill the server-side playback
 // buffer, so setting too low of a latency is a buffer underflow risk. We will
 // automatically increase the latency if a buffer underflow does occur, but we
 // also enforce a sane minimum at start-up time. Anything lower would be
 // virtually guaranteed to underflow at least once, so there's no point in
 // allowing lower latencies.
 const uint32_t WEBRTC_PA_PLAYBACK_LATENCY_MINIMUM_MSECS = 20;

 // Every time a playback stream underflows, we will reconfigure it with target
 // latency that is greater by this amount.
 const uint32_t WEBRTC_PA_PLAYBACK_LATENCY_INCREMENT_MSECS = 20;

 // We also need to configure a suitable request size. Too small and we'd burn
 // CPU from the overhead of transfering small amounts of data at once. Too large
 // and the amount of data remaining in the buffer right before refilling it
 // would be a buffer underflow risk. We set it to half of the buffer size.
 const uint32_t WEBRTC_PA_PLAYBACK_REQUEST_FACTOR = 2;

 // Capture.

 // For capture, low latency is not a buffer overflow risk, but it makes us burn
 // CPU from the overhead of transfering small amounts of data at once, so we set
 // a recommended value that we use for the kLowLatency constant (but if the user
 // explicitly requests something lower then we will honour it).
 // 1ms takes about 6-7% CPU. 5ms takes about 5%. 10ms takes about 4.x%.
 const uint32_t WEBRTC_PA_LOW_CAPTURE_LATENCY_MSECS = 10;

 // There is a round-trip delay to ack the data to the server, so the
 // server-side buffer needs extra space to prevent buffer overflow. 20ms is
 // sufficient, but there is no penalty to making it bigger, so we make it huge.
 // (750ms is libpulse's default value for the _total_ buffer size in the
 // kNoLatencyRequirements case.)
 const uint32_t WEBRTC_PA_CAPTURE_BUFFER_EXTRA_MSECS = 750;

 const uint32_t WEBRTC_PA_MSECS_PER_SEC = 1000;

 // Init _configuredLatencyRec/Play to this value to disable latency requirements
 const int32_t WEBRTC_PA_NO_LATENCY_REQUIREMENTS = -1;

 // Set this const to 1 to account for peeked and used data in latency
 // calculation
 const uint32_t WEBRTC_PA_CAPTURE_BUFFER_LATENCY_ADJUSTMENT = 0;

 typedef webrtc::adm_linux_pulse::PulseAudioSymbolTable WebRTCPulseSymbolTable;
 WebRTCPulseSymbolTable* GetPulseSymbolTable();

 namespace webrtc {

 class AudioDeviceLinuxPulse : public AudioDeviceGeneric {
  public:
   AudioDeviceLinuxPulse();
   virtual ~AudioDeviceLinuxPulse();

   // Retrieve the currently utilized audio layer
   int32_t ActiveAudioLayer(
       AudioDeviceModule::AudioLayer& audioLayer) const override;

   // Main initializaton and termination
   InitStatus Init() override;
   int32_t Terminate() RTC_LOCKS_EXCLUDED(mutex_) override;
   bool Initialized() const override;

   // Device enumeration
   int16_t PlayoutDevices() override;
   int16_t RecordingDevices() override;
   int32_t PlayoutDeviceName(uint16_t index,
                             char name[kAdmMaxDeviceNameSize],
                             char guid[kAdmMaxGuidSize]) override;
   int32_t RecordingDeviceName(uint16_t index,
                               char name[kAdmMaxDeviceNameSize],
                               char guid[kAdmMaxGuidSize]) override;

   // Device selection
   int32_t SetPlayoutDevice(uint16_t index) override;
   int32_t SetPlayoutDevice(
       AudioDeviceModule::WindowsDeviceType device) override;
   int32_t SetRecordingDevice(uint16_t index) override;
   int32_t SetRecordingDevice(
       AudioDeviceModule::WindowsDeviceType device) override;

   // Audio transport initialization
   int32_t PlayoutIsAvailable(bool& available) override;
   int32_t InitPlayout() RTC_LOCKS_EXCLUDED(mutex_) override;
   bool PlayoutIsInitialized() const override;
   int32_t RecordingIsAvailable(bool& available) override;
   int32_t InitRecording() override;
   bool RecordingIsInitialized() const override;

   // Audio transport control
   int32_t StartPlayout() RTC_LOCKS_EXCLUDED(mutex_) override;
   int32_t StopPlayout() RTC_LOCKS_EXCLUDED(mutex_) override;
   bool Playing() const override;
   int32_t StartRecording() RTC_LOCKS_EXCLUDED(mutex_) override;
   int32_t StopRecording() RTC_LOCKS_EXCLUDED(mutex_) override;
   bool Recording() const override;

   // Audio mixer initialization
   int32_t InitSpeaker() override;
   bool SpeakerIsInitialized() const override;
   int32_t InitMicrophone() override;
   bool MicrophoneIsInitialized() const override;

   // Speaker volume controls
   int32_t SpeakerVolumeIsAvailable(bool& available) override;
   int32_t SetSpeakerVolume(uint32_t volume) override;
   int32_t SpeakerVolume(uint32_t& volume) const override;
   int32_t MaxSpeakerVolume(uint32_t& maxVolume) const override;
   int32_t MinSpeakerVolume(uint32_t& minVolume) const override;

   // Microphone volume controls
   int32_t MicrophoneVolumeIsAvailable(bool& available) override;
   int32_t SetMicrophoneVolume(uint32_t volume) override;
   int32_t MicrophoneVolume(uint32_t& volume) const override;
   int32_t MaxMicrophoneVolume(uint32_t& maxVolume) const override;
   int32_t MinMicrophoneVolume(uint32_t& minVolume) const override;

   // Speaker mute control
   int32_t SpeakerMuteIsAvailable(bool& available) override;
   int32_t SetSpeakerMute(bool enable) override;
   int32_t SpeakerMute(bool& enabled) const override;

   // Microphone mute control
   int32_t MicrophoneMuteIsAvailable(bool& available) override;
   int32_t SetMicrophoneMute(bool enable) override;
   int32_t MicrophoneMute(bool& enabled) const override;

   // Stereo support
   int32_t StereoPlayoutIsAvailable(bool& available) override;
   int32_t SetStereoPlayout(bool enable) override;
   int32_t StereoPlayout(bool& enabled) const override;
   int32_t StereoRecordingIsAvailable(bool& available) override;
   int32_t SetStereoRecording(bool enable) override;
   int32_t StereoRecording(bool& enabled) const override;

   // Delay information and control
   int32_t PlayoutDelay(uint16_t& delayMS) const
       RTC_LOCKS_EXCLUDED(mutex_) override;

   void AttachAudioBuffer(AudioDeviceBuffer* audioBuffer) override;

  private:
   void Lock() RTC_EXCLUSIVE_LOCK_FUNCTION(mutex_) { mutex_.Lock(); }
   void UnLock() RTC_UNLOCK_FUNCTION(mutex_) { mutex_.Unlock(); }
   void WaitForOperationCompletion(pa_operation* paOperation) const;
   void WaitForSuccess(pa_operation* paOperation) const;

   bool KeyPressed() const;

   static void PaContextStateCallback(pa_context* c, void* pThis);
   static void PaSinkInfoCallback(pa_context* c,
                                  const pa_sink_info* i,
                                  int eol,
                                  void* pThis);
   static void PaSourceInfoCallback(pa_context* c,
                                    const pa_source_info* i,
                                    int eol,
                                    void* pThis);
   static void PaServerInfoCallback(pa_context* c,
                                    const pa_server_info* i,
                                    void* pThis);
   static void PaStreamStateCallback(pa_stream* p, void* pThis);
   void PaContextStateCallbackHandler(pa_context* c);
   void PaSinkInfoCallbackHandler(const pa_sink_info* i, int eol);
   void PaSourceInfoCallbackHandler(const pa_source_info* i, int eol);
   void PaServerInfoCallbackHandler(const pa_server_info* i);
   void PaStreamStateCallbackHandler(pa_stream* p);

   void EnableWriteCallback();
   void DisableWriteCallback();
   static void PaStreamWriteCallback(pa_stream* unused,
                                     size_t buffer_space,
                                     void* pThis);
   void PaStreamWriteCallbackHandler(size_t buffer_space);
   static void PaStreamUnderflowCallback(pa_stream* unused, void* pThis);
   void PaStreamUnderflowCallbackHandler();
   void EnableReadCallback();
   void DisableReadCallback();
   static void PaStreamReadCallback(pa_stream* unused1,
                                    size_t unused2,
                                    void* pThis);
   void PaStreamReadCallbackHandler();
   static void PaStreamOverflowCallback(pa_stream* unused, void* pThis);
   void PaStreamOverflowCallbackHandler();
   int32_t LatencyUsecs(pa_stream* stream);
   int32_t ReadRecordedData(const void* bufferData, size_t bufferSize);
   int32_t ProcessRecordedData(int8_t* bufferData,
                               uint32_t bufferSizeInSamples,
                               uint32_t recDelay);

   int32_t CheckPulseAudioVersion();
   int32_t InitSamplingFrequency();
   int32_t GetDefaultDeviceInfo(bool recDevice, char* name, uint16_t& index);
   int32_t InitPulseAudio();
   int32_t TerminatePulseAudio();

   void PaLock();
   void PaUnLock();

   static void RecThreadFunc(void*);
   static void PlayThreadFunc(void*);
   bool RecThreadProcess() RTC_LOCKS_EXCLUDED(mutex_);
   bool PlayThreadProcess() RTC_LOCKS_EXCLUDED(mutex_);

   AudioDeviceBuffer* _ptrAudioBuffer;

   mutable Mutex mutex_;
   rtc::Event _timeEventRec;
   rtc::Event _timeEventPlay;
   rtc::Event _recStartEvent;
   rtc::Event _playStartEvent;

   rtc::PlatformThread _ptrThreadPlay;
   rtc::PlatformThread _ptrThreadRec;

   AudioMixerManagerLinuxPulse _mixerManager;

   uint16_t _inputDeviceIndex;
   uint16_t _outputDeviceIndex;
   bool _inputDeviceIsSpecified;
   bool _outputDeviceIsSpecified;

   int sample_rate_hz_;
   uint8_t _recChannels;
   uint8_t _playChannels;

   // Stores thread ID in constructor.
   // We can then use RTC_DCHECK_RUN_ON(&worker_thread_checker_) to ensure that
   // other methods are called from the same thread.
   // Currently only does RTC_DCHECK(thread_checker_.IsCurrent()).
   SequenceChecker thread_checker_;

   bool _initialized;
   bool _recording;
   bool _playing;
   bool _recIsInitialized;
   bool _playIsInitialized;
   bool _startRec;
   bool _startPlay;
   bool update_speaker_volume_at_startup_;
   bool quit_ RTC_GUARDED_BY(&mutex_);

   uint32_t _sndCardPlayDelay RTC_GUARDED_BY(&mutex_);

   int32_t _writeErrors;

   uint16_t _deviceIndex;
   int16_t _numPlayDevices;
   int16_t _numRecDevices;
   char* _playDeviceName;
   char* _recDeviceName;
   char* _playDisplayDeviceName;
   char* _recDisplayDeviceName;
   char _paServerVersion[32];

   int8_t* _playBuffer;
   size_t _playbackBufferSize;
   size_t _playbackBufferUnused;
   size_t _tempBufferSpace;
   int8_t* _recBuffer;
   size_t _recordBufferSize;
   size_t _recordBufferUsed;
   const void* _tempSampleData;
   size_t _tempSampleDataSize;
   int32_t _configuredLatencyPlay;
   int32_t _configuredLatencyRec;

   // PulseAudio
   uint16_t _paDeviceIndex;
   bool _paStateChanged;

   pa_threaded_mainloop* _paMainloop;
   pa_mainloop_api* _paMainloopApi;
   pa_context* _paContext;

   pa_stream* _recStream;
   pa_stream* _playStream;
   uint32_t _recStreamFlags;
   uint32_t _playStreamFlags;
   pa_buffer_attr _playBufferAttr;
   pa_buffer_attr _recBufferAttr;

   char _oldKeyState[32];
 #if defined(WEBRTC_USE_X11)
   Display* _XDisplay;
 #endif
 };

 }  // namespace webrtc

 #endif  // MODULES_AUDIO_DEVICE_MAIN_SOURCE_LINUX_AUDIO_DEVICE_PULSE_LINUX_H_
	/*
	* 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.
	*/

	#ifndef AUDIO_DEVICE_AUDIO_DEVICE_PULSE_LINUX_H_
	#define AUDIO_DEVICE_AUDIO_DEVICE_PULSE_LINUX_H_

	#include <memory>

	#include "api/sequence_checker.h"
	#include "modules/audio_device/audio_device_buffer.h"
	#include "modules/audio_device/audio_device_generic.h"
	#include "modules/audio_device/include/audio_device.h"
	#include "modules/audio_device/include/audio_device_defines.h"
	#include "modules/audio_device/linux/audio_mixer_manager_pulse_linux.h"
	#include "modules/audio_device/linux/pulseaudiosymboltable_linux.h"
	#include "rtc_base/event.h"
	#include "rtc_base/platform_thread.h"
	#include "rtc_base/synchronization/mutex.h"
	#include "rtc_base/thread_annotations.h"

	#if defined(WEBRTC_USE_X11)
	#include <X11/Xlib.h>
	#endif

	#include <pulse/pulseaudio.h>
	#include <stddef.h>
	#include <stdint.h>

	// We define this flag if it's missing from our headers, because we want to be
	// able to compile against old headers but still use PA_STREAM_ADJUST_LATENCY
	// if run against a recent version of the library.
	#ifndef PA_STREAM_ADJUST_LATENCY
	#define PA_STREAM_ADJUST_LATENCY 0x2000U
	#endif
	#ifndef PA_STREAM_START_MUTED
	#define PA_STREAM_START_MUTED 0x1000U
	#endif

	// Set this constant to 0 to disable latency reading
	const uint32_t WEBRTC_PA_REPORT_LATENCY = 1;

	// Constants from implementation by Tristan Schmelcher [tschmelcher@google.com]

	// First PulseAudio protocol version that supports PA_STREAM_ADJUST_LATENCY.
	const uint32_t WEBRTC_PA_ADJUST_LATENCY_PROTOCOL_VERSION = 13;

	// Some timing constants for optimal operation. See
	// https://tango.0pointer.de/pipermail/pulseaudio-discuss/2008-January/001170.html
	// for a good explanation of some of the factors that go into this.

	// Playback.

	// For playback, there is a round-trip delay to fill the server-side playback
	// buffer, so setting too low of a latency is a buffer underflow risk. We will
	// automatically increase the latency if a buffer underflow does occur, but we
	// also enforce a sane minimum at start-up time. Anything lower would be
	// virtually guaranteed to underflow at least once, so there's no point in
	// allowing lower latencies.
	const uint32_t WEBRTC_PA_PLAYBACK_LATENCY_MINIMUM_MSECS = 20;

	// Every time a playback stream underflows, we will reconfigure it with target
	// latency that is greater by this amount.
	const uint32_t WEBRTC_PA_PLAYBACK_LATENCY_INCREMENT_MSECS = 20;

	// We also need to configure a suitable request size. Too small and we'd burn
	// CPU from the overhead of transfering small amounts of data at once. Too large
	// and the amount of data remaining in the buffer right before refilling it
	// would be a buffer underflow risk. We set it to half of the buffer size.
	const uint32_t WEBRTC_PA_PLAYBACK_REQUEST_FACTOR = 2;

	// Capture.

	// For capture, low latency is not a buffer overflow risk, but it makes us burn
	// CPU from the overhead of transfering small amounts of data at once, so we set
	// a recommended value that we use for the kLowLatency constant (but if the user
	// explicitly requests something lower then we will honour it).
	// 1ms takes about 6-7% CPU. 5ms takes about 5%. 10ms takes about 4.x%.
	const uint32_t WEBRTC_PA_LOW_CAPTURE_LATENCY_MSECS = 10;

	// There is a round-trip delay to ack the data to the server, so the
	// server-side buffer needs extra space to prevent buffer overflow. 20ms is
	// sufficient, but there is no penalty to making it bigger, so we make it huge.
	// (750ms is libpulse's default value for the _total_ buffer size in the
	// kNoLatencyRequirements case.)
	const uint32_t WEBRTC_PA_CAPTURE_BUFFER_EXTRA_MSECS = 750;

	const uint32_t WEBRTC_PA_MSECS_PER_SEC = 1000;

	// Init _configuredLatencyRec/Play to this value to disable latency requirements
	const int32_t WEBRTC_PA_NO_LATENCY_REQUIREMENTS = -1;

	// Set this const to 1 to account for peeked and used data in latency
	// calculation
	const uint32_t WEBRTC_PA_CAPTURE_BUFFER_LATENCY_ADJUSTMENT = 0;

	typedef webrtc::adm_linux_pulse::PulseAudioSymbolTable WebRTCPulseSymbolTable;
	WebRTCPulseSymbolTable* GetPulseSymbolTable();

	namespace webrtc {

	class AudioDeviceLinuxPulse : public AudioDeviceGeneric {
	public:
	AudioDeviceLinuxPulse();
	virtual ~AudioDeviceLinuxPulse();

	// Retrieve the currently utilized audio layer
	int32_t ActiveAudioLayer(
	AudioDeviceModule::AudioLayer& audioLayer) const override;

	// Main initializaton and termination
	InitStatus Init() override;
	int32_t Terminate() RTC_LOCKS_EXCLUDED(mutex_) override;
	bool Initialized() const override;

	// Device enumeration
	int16_t PlayoutDevices() override;
	int16_t RecordingDevices() override;
	int32_t PlayoutDeviceName(uint16_t index,
	char name[kAdmMaxDeviceNameSize],
	char guid[kAdmMaxGuidSize]) override;
	int32_t RecordingDeviceName(uint16_t index,
	char name[kAdmMaxDeviceNameSize],
	char guid[kAdmMaxGuidSize]) override;

	// Device selection
	int32_t SetPlayoutDevice(uint16_t index) override;
	int32_t SetPlayoutDevice(
	AudioDeviceModule::WindowsDeviceType device) override;
	int32_t SetRecordingDevice(uint16_t index) override;
	int32_t SetRecordingDevice(
	AudioDeviceModule::WindowsDeviceType device) override;

	// Audio transport initialization
	int32_t PlayoutIsAvailable(bool& available) override;
	int32_t InitPlayout() RTC_LOCKS_EXCLUDED(mutex_) override;
	bool PlayoutIsInitialized() const override;
	int32_t RecordingIsAvailable(bool& available) override;
	int32_t InitRecording() override;
	bool RecordingIsInitialized() const override;

	// Audio transport control
	int32_t StartPlayout() RTC_LOCKS_EXCLUDED(mutex_) override;
	int32_t StopPlayout() RTC_LOCKS_EXCLUDED(mutex_) override;
	bool Playing() const override;
	int32_t StartRecording() RTC_LOCKS_EXCLUDED(mutex_) override;
	int32_t StopRecording() RTC_LOCKS_EXCLUDED(mutex_) override;
	bool Recording() const override;

	// Audio mixer initialization
	int32_t InitSpeaker() override;
	bool SpeakerIsInitialized() const override;
	int32_t InitMicrophone() override;
	bool MicrophoneIsInitialized() const override;

	// Speaker volume controls
	int32_t SpeakerVolumeIsAvailable(bool& available) override;
	int32_t SetSpeakerVolume(uint32_t volume) override;
	int32_t SpeakerVolume(uint32_t& volume) const override;
	int32_t MaxSpeakerVolume(uint32_t& maxVolume) const override;
	int32_t MinSpeakerVolume(uint32_t& minVolume) const override;

	// Microphone volume controls
	int32_t MicrophoneVolumeIsAvailable(bool& available) override;
	int32_t SetMicrophoneVolume(uint32_t volume) override;
	int32_t MicrophoneVolume(uint32_t& volume) const override;
	int32_t MaxMicrophoneVolume(uint32_t& maxVolume) const override;
	int32_t MinMicrophoneVolume(uint32_t& minVolume) const override;

	// Speaker mute control
	int32_t SpeakerMuteIsAvailable(bool& available) override;
	int32_t SetSpeakerMute(bool enable) override;
	int32_t SpeakerMute(bool& enabled) const override;

	// Microphone mute control
	int32_t MicrophoneMuteIsAvailable(bool& available) override;
	int32_t SetMicrophoneMute(bool enable) override;
	int32_t MicrophoneMute(bool& enabled) const override;

	// Stereo support
	int32_t StereoPlayoutIsAvailable(bool& available) override;
	int32_t SetStereoPlayout(bool enable) override;
	int32_t StereoPlayout(bool& enabled) const override;
	int32_t StereoRecordingIsAvailable(bool& available) override;
	int32_t SetStereoRecording(bool enable) override;
	int32_t StereoRecording(bool& enabled) const override;

	// Delay information and control
	int32_t PlayoutDelay(uint16_t& delayMS) const
	RTC_LOCKS_EXCLUDED(mutex_) override;

	void AttachAudioBuffer(AudioDeviceBuffer* audioBuffer) override;

	private:
	void Lock() RTC_EXCLUSIVE_LOCK_FUNCTION(mutex_) { mutex_.Lock(); }
	void UnLock() RTC_UNLOCK_FUNCTION(mutex_) { mutex_.Unlock(); }
	void WaitForOperationCompletion(pa_operation* paOperation) const;
	void WaitForSuccess(pa_operation* paOperation) const;

	bool KeyPressed() const;

	static void PaContextStateCallback(pa_context* c, void* pThis);
	static void PaSinkInfoCallback(pa_context* c,
	const pa_sink_info* i,
	int eol,
	void* pThis);
	static void PaSourceInfoCallback(pa_context* c,
	const pa_source_info* i,
	int eol,
	void* pThis);
	static void PaServerInfoCallback(pa_context* c,
	const pa_server_info* i,
	void* pThis);
	static void PaStreamStateCallback(pa_stream* p, void* pThis);
	void PaContextStateCallbackHandler(pa_context* c);
	void PaSinkInfoCallbackHandler(const pa_sink_info* i, int eol);
	void PaSourceInfoCallbackHandler(const pa_source_info* i, int eol);
	void PaServerInfoCallbackHandler(const pa_server_info* i);
	void PaStreamStateCallbackHandler(pa_stream* p);

	void EnableWriteCallback();
	void DisableWriteCallback();
	static void PaStreamWriteCallback(pa_stream* unused,
	size_t buffer_space,
	void* pThis);
	void PaStreamWriteCallbackHandler(size_t buffer_space);
	static void PaStreamUnderflowCallback(pa_stream* unused, void* pThis);
	void PaStreamUnderflowCallbackHandler();
	void EnableReadCallback();
	void DisableReadCallback();
	static void PaStreamReadCallback(pa_stream* unused1,
	size_t unused2,
	void* pThis);
	void PaStreamReadCallbackHandler();
	static void PaStreamOverflowCallback(pa_stream* unused, void* pThis);
	void PaStreamOverflowCallbackHandler();
	int32_t LatencyUsecs(pa_stream* stream);
	int32_t ReadRecordedData(const void* bufferData, size_t bufferSize);
	int32_t ProcessRecordedData(int8_t* bufferData,
	uint32_t bufferSizeInSamples,
	uint32_t recDelay);

	int32_t CheckPulseAudioVersion();
	int32_t InitSamplingFrequency();
	int32_t GetDefaultDeviceInfo(bool recDevice, char* name, uint16_t& index);
	int32_t InitPulseAudio();
	int32_t TerminatePulseAudio();

	void PaLock();
	void PaUnLock();

	static void RecThreadFunc(void*);
	static void PlayThreadFunc(void*);
	bool RecThreadProcess() RTC_LOCKS_EXCLUDED(mutex_);
	bool PlayThreadProcess() RTC_LOCKS_EXCLUDED(mutex_);

	AudioDeviceBuffer* _ptrAudioBuffer;

	mutable Mutex mutex_;
	rtc::Event _timeEventRec;
	rtc::Event _timeEventPlay;
	rtc::Event _recStartEvent;
	rtc::Event _playStartEvent;

	rtc::PlatformThread _ptrThreadPlay;
	rtc::PlatformThread _ptrThreadRec;

	AudioMixerManagerLinuxPulse _mixerManager;

	uint16_t _inputDeviceIndex;
	uint16_t _outputDeviceIndex;
	bool _inputDeviceIsSpecified;
	bool _outputDeviceIsSpecified;

	int sample_rate_hz_;
	uint8_t _recChannels;
	uint8_t _playChannels;

	// Stores thread ID in constructor.
	// We can then use RTC_DCHECK_RUN_ON(&worker_thread_checker_) to ensure that
	// other methods are called from the same thread.
	// Currently only does RTC_DCHECK(thread_checker_.IsCurrent()).
	SequenceChecker thread_checker_;

	bool _initialized;
	bool _recording;
	bool _playing;
	bool _recIsInitialized;
	bool _playIsInitialized;
	bool _startRec;
	bool _startPlay;
	bool update_speaker_volume_at_startup_;
	bool quit_ RTC_GUARDED_BY(&mutex_);

	uint32_t _sndCardPlayDelay RTC_GUARDED_BY(&mutex_);

	int32_t _writeErrors;

	uint16_t _deviceIndex;
	int16_t _numPlayDevices;
	int16_t _numRecDevices;
	char* _playDeviceName;
	char* _recDeviceName;
	char* _playDisplayDeviceName;
	char* _recDisplayDeviceName;
	char _paServerVersion[32];

	int8_t* _playBuffer;
	size_t _playbackBufferSize;
	size_t _playbackBufferUnused;
	size_t _tempBufferSpace;
	int8_t* _recBuffer;
	size_t _recordBufferSize;
	size_t _recordBufferUsed;
	const void* _tempSampleData;
	size_t _tempSampleDataSize;
	int32_t _configuredLatencyPlay;
	int32_t _configuredLatencyRec;

	// PulseAudio
	uint16_t _paDeviceIndex;
	bool _paStateChanged;

	pa_threaded_mainloop* _paMainloop;
	pa_mainloop_api* _paMainloopApi;
	pa_context* _paContext;

	pa_stream* _recStream;
	pa_stream* _playStream;
	uint32_t _recStreamFlags;
	uint32_t _playStreamFlags;
	pa_buffer_attr _playBufferAttr;
	pa_buffer_attr _recBufferAttr;

	char _oldKeyState[32];
	#if defined(WEBRTC_USE_X11)
	Display* _XDisplay;
	#endif
	};

	} // namespace webrtc

	#endif // MODULES_AUDIO_DEVICE_MAIN_SOURCE_LINUX_AUDIO_DEVICE_PULSE_LINUX_H_