third_party/chromium/media/audio/audio_input_device.cc - cobalt - Git at Google

 // 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 "media/audio/audio_input_device.h"

 #include <stdint.h>
 #include <utility>
 #include <vector>

 #include "base/bind.h"
 #include "base/callback_helpers.h"
 #include "base/format_macros.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/memory/ptr_util.h"
 #include "base/metrics/histogram_macros.h"
 #include "base/strings/stringprintf.h"
 #include "base/threading/thread_restrictions.h"
 #include "base/trace_event/trace_event.h"
 #include "build/build_config.h"
 #include "media/audio/audio_manager_base.h"
 #include "media/base/audio_bus.h"

 namespace media {

 namespace {

 // The number of shared memory buffer segments indicated to browser process
 // in order to avoid data overwriting. This number can be any positive number,
 // dependent how fast the renderer process can pick up captured data from
 // shared memory.
 const int kRequestedSharedMemoryCount = 10;

 // The number of seconds with missing callbacks before we report a capture
 // error. The value is based on that the Mac audio implementation can defer
 // start for 5 seconds when resuming after standby, and has a startup success
 // check 5 seconds after actually starting, where stats is logged. We must allow
 // enough time for this. See AUAudioInputStream::CheckInputStartupSuccess().
 const int kMissingCallbacksTimeBeforeErrorSeconds = 12;

 // The interval for checking missing callbacks.
 const int kCheckMissingCallbacksIntervalSeconds = 5;

 // How often AudioInputDevice::AudioThreadCallback informs that it has gotten
 // data from the source.
 const int kGotDataCallbackIntervalSeconds = 1;

 base::ThreadPriority ThreadPriorityFromPurpose(
     AudioInputDevice::Purpose purpose) {
   switch (purpose) {
     case AudioInputDevice::Purpose::kUserInput:
       return base::ThreadPriority::REALTIME_AUDIO;
     case AudioInputDevice::Purpose::kLoopback:
       return base::ThreadPriority::NORMAL;
   }
 }

 }  // namespace

 // Takes care of invoking the capture callback on the audio thread.
 // An instance of this class is created for each capture stream in
 // OnLowLatencyCreated().
 class AudioInputDevice::AudioThreadCallback
     : public AudioDeviceThread::Callback {
  public:
   AudioThreadCallback(const AudioParameters& audio_parameters,
                       base::ReadOnlySharedMemoryRegion shared_memory_region,
                       uint32_t total_segments,
                       bool enable_uma,
                       CaptureCallback* capture_callback,
                       base::RepeatingClosure got_data_callback);

   AudioThreadCallback(const AudioThreadCallback&) = delete;
   AudioThreadCallback& operator=(const AudioThreadCallback&) = delete;

   ~AudioThreadCallback() override;

   void MapSharedMemory() override;

   // Called whenever we receive notifications about pending data.
   void Process(uint32_t pending_data) override;

  private:
   const bool enable_uma_;
   base::ReadOnlySharedMemoryRegion shared_memory_region_;
   base::ReadOnlySharedMemoryMapping shared_memory_mapping_;
   const base::TimeTicks start_time_;
   size_t current_segment_id_;
   uint32_t last_buffer_id_;
   std::vector<std::unique_ptr<const media::AudioBus>> audio_buses_;
   CaptureCallback* capture_callback_;

   // Used for informing AudioInputDevice that we have gotten data, i.e. the
   // stream is alive. |got_data_callback_| is run every
   // |got_data_callback_interval_in_frames_| frames, calculated from
   // kGotDataCallbackIntervalSeconds.
   const int got_data_callback_interval_in_frames_;
   int frames_since_last_got_data_callback_;
   base::RepeatingClosure got_data_callback_;
 };

 AudioInputDevice::AudioInputDevice(std::unique_ptr<AudioInputIPC> ipc,
                                    Purpose purpose,
                                    DeadStreamDetection detect_dead_stream)
     : thread_priority_(ThreadPriorityFromPurpose(purpose)),
       enable_uma_(purpose == AudioInputDevice::Purpose::kUserInput),
       callback_(nullptr),
       ipc_(std::move(ipc)),
       state_(IDLE),
       agc_is_enabled_(false),
       detect_dead_stream_(detect_dead_stream) {
   CHECK(ipc_);

   // The correctness of the code depends on the relative values assigned in the
   // State enum.
   static_assert(IPC_CLOSED < IDLE, "invalid enum value assignment 0");
   static_assert(IDLE < CREATING_STREAM, "invalid enum value assignment 1");
   static_assert(CREATING_STREAM < RECORDING, "invalid enum value assignment 2");
 }

 void AudioInputDevice::Initialize(const AudioParameters& params,
                                   CaptureCallback* callback) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   DCHECK(params.IsValid());
   DCHECK(!callback_);
   audio_parameters_ = params;
   callback_ = callback;
 }

 void AudioInputDevice::Start() {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   DCHECK(callback_) << "Initialize hasn't been called";
   TRACE_EVENT0("audio", "AudioInputDevice::Start");

   // Make sure we don't call Start() more than once.
   if (state_ != IDLE)
     return;

   state_ = CREATING_STREAM;
   ipc_->CreateStream(this, audio_parameters_, agc_is_enabled_,
                      kRequestedSharedMemoryCount);
 }

 void AudioInputDevice::Stop() {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT0("audio", "AudioInputDevice::Stop");

   if (enable_uma_) {
     if (detect_dead_stream_ == DeadStreamDetection::kEnabled) {
       UMA_HISTOGRAM_BOOLEAN(
           "Media.Audio.Capture.DetectedMissingCallbacks",
           alive_checker_ ? alive_checker_->DetectedDead() : false);
     }

     UMA_HISTOGRAM_ENUMERATION("Media.Audio.Capture.StreamCallbackError2",
                               had_error_);
   }
   had_error_ = kNoError;

   // Close the stream, if we haven't already.
   if (state_ >= CREATING_STREAM) {
     ipc_->CloseStream();
     state_ = IDLE;
     agc_is_enabled_ = false;
   }

   // We can run into an issue where Stop is called right after
   // OnStreamCreated is called in cases where Start/Stop are called before we
   // get the OnStreamCreated callback.  To handle that corner case, we call
   // audio_thread_.reset(). In most cases, the thread will already be stopped.
   //
   // |alive_checker_| must outlive |audio_callback_|.
   base::ScopedAllowBaseSyncPrimitivesOutsideBlockingScope allow_thread_join;
   audio_thread_.reset();
   audio_callback_.reset();
   alive_checker_.reset();
 }

 void AudioInputDevice::SetVolume(double volume) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT1("audio", "AudioInputDevice::SetVolume", "volume", volume);

   if (volume < 0 || volume > 1.0) {
     DLOG(ERROR) << "Invalid volume value specified";
     return;
   }

   if (state_ >= CREATING_STREAM)
     ipc_->SetVolume(volume);
 }

 void AudioInputDevice::SetAutomaticGainControl(bool enabled) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT1("audio", "AudioInputDevice::SetAutomaticGainControl", "enabled",
                enabled);

   if (state_ >= CREATING_STREAM) {
     DLOG(WARNING) << "The AGC state can not be modified after starting.";
     return;
   }

   // We simply store the new AGC setting here. This value will be used when
   // a new stream is initialized and by GetAutomaticGainControl().
   agc_is_enabled_ = enabled;
 }

 void AudioInputDevice::SetOutputDeviceForAec(
     const std::string& output_device_id) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT1("audio", "AudioInputDevice::SetOutputDeviceForAec",
                "output_device_id", output_device_id);

   output_device_id_for_aec_ = output_device_id;
   if (state_ > CREATING_STREAM)
     ipc_->SetOutputDeviceForAec(output_device_id);
 }

 void AudioInputDevice::OnStreamCreated(
     base::ReadOnlySharedMemoryRegion shared_memory_region,
     base::SyncSocket::ScopedHandle socket_handle,
     bool initially_muted) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT0("audio", "AudioInputDevice::OnStreamCreated");
   DCHECK(shared_memory_region.IsValid());
 #if defined(OS_WIN)
   DCHECK(socket_handle.IsValid());
 #else
   DCHECK(socket_handle.is_valid());
 #endif
   DCHECK_GT(shared_memory_region.GetSize(), 0u);

   if (state_ != CREATING_STREAM)
     return;

   DCHECK(!audio_callback_);
   DCHECK(!audio_thread_);

   if (initially_muted)
     callback_->OnCaptureMuted(true);

   if (auto* controls = ipc_->GetProcessorControls())
     callback_->OnCaptureProcessorCreated(controls);

   if (output_device_id_for_aec_)
     ipc_->SetOutputDeviceForAec(*output_device_id_for_aec_);

 // Set up checker for detecting missing audio data. We pass a callback which
 // holds a reference to this. |alive_checker_| is deleted in
 // Stop() which we expect to always be called (see comment in
 // destructor). Suspend/resume notifications are not supported on Linux and
 // there's a risk of false positives when suspending. So on Linux we only detect
 // missing audio data until the first audio buffer arrives. Note that there's
 // also a risk of false positives if we are suspending when starting the stream
 // here. See comments in AliveChecker and PowerObserverHelper for details and
 // todos.
   if (detect_dead_stream_ == DeadStreamDetection::kEnabled) {
 #if defined(OS_LINUX) || defined(OS_CHROMEOS)
     const bool stop_at_first_alive_notification = true;
     const bool pause_check_during_suspend = false;
 #else
   const bool stop_at_first_alive_notification = false;
   const bool pause_check_during_suspend = true;
 #endif
     alive_checker_ = std::make_unique<AliveChecker>(
         base::BindRepeating(&AudioInputDevice::DetectedDeadInputStream, this),
         base::Seconds(kCheckMissingCallbacksIntervalSeconds),
         base::Seconds(kMissingCallbacksTimeBeforeErrorSeconds),
         stop_at_first_alive_notification, pause_check_during_suspend);
   }

   // Unretained is safe since |alive_checker_| outlives |audio_callback_|.
   base::RepeatingClosure notify_alive_closure =
       alive_checker_
           ? base::BindRepeating(&AliveChecker::NotifyAlive,
                                 base::Unretained(alive_checker_.get()))
           : base::DoNothing();

   audio_callback_ = std::make_unique<AudioInputDevice::AudioThreadCallback>(
       audio_parameters_, std::move(shared_memory_region),
       kRequestedSharedMemoryCount, enable_uma_, callback_,
       notify_alive_closure);
   audio_thread_ = std::make_unique<AudioDeviceThread>(
       audio_callback_.get(), std::move(socket_handle), "AudioInputDevice",
       thread_priority_);

   state_ = RECORDING;
   ipc_->RecordStream();

   // Start detecting missing audio data.
   if (alive_checker_)
     alive_checker_->Start();
 }

 void AudioInputDevice::OnError(AudioCapturerSource::ErrorCode code) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT0("audio", "AudioInputDevice::OnError");

   // Do nothing if the stream has been closed.
   if (state_ < CREATING_STREAM)
     return;

   if (state_ == CREATING_STREAM) {
     // At this point, we haven't attempted to start the audio thread.
     // Accessing the hardware might have failed or we may have reached
     // the limit of the number of allowed concurrent streams.
     // We must report the error to the |callback_| so that a potential
     // audio source object will enter the correct state (e.g. 'ended' for
     // a local audio source).
     had_error_ = kErrorDuringCreation;
     callback_->OnCaptureError(
         code, code == AudioCapturerSource::ErrorCode::kSystemPermissions
                   ? "Unable to open due to failing an OS Permissions check."
                   : "Maximum allowed input device limit reached or an OS "
                     "failure occured.");
   } else {
     // Don't dereference the callback object if the audio thread
     // is stopped or stopping.  That could mean that the callback
     // object has been deleted.
     // TODO(tommi): Add an explicit contract for clearing the callback
     // object.  Possibly require calling Initialize again or provide
     // a callback object via Start() and clear it in Stop().
     had_error_ = kErrorDuringCapture;
     if (audio_thread_)
       callback_->OnCaptureError(code, "IPC delegate state error.");
   }
 }

 void AudioInputDevice::OnMuted(bool is_muted) {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT0("audio", "AudioInputDevice::OnMuted");

   // Do nothing if the stream has been closed.
   if (state_ < CREATING_STREAM)
     return;
   callback_->OnCaptureMuted(is_muted);
 }

 void AudioInputDevice::OnIPCClosed() {
   DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
   TRACE_EVENT0("audio", "AudioInputDevice::OnIPCClosed");

   state_ = IPC_CLOSED;
   ipc_.reset();
 }

 AudioInputDevice::~AudioInputDevice() {
 #if DCHECK_IS_ON()
   // Make sure we've stopped the stream properly before destructing |this|.
   DCHECK_LE(state_, IDLE);
   DCHECK(!audio_thread_);
   DCHECK(!audio_callback_);
   DCHECK(!alive_checker_);
 #endif  // DCHECK_IS_ON()
 }

 void AudioInputDevice::DetectedDeadInputStream() {
   callback_->OnCaptureError(media::AudioCapturerSource::ErrorCode::kUnknown,
                             "No audio received from audio capture device.");
 }

 // AudioInputDevice::AudioThreadCallback
 AudioInputDevice::AudioThreadCallback::AudioThreadCallback(
     const AudioParameters& audio_parameters,
     base::ReadOnlySharedMemoryRegion shared_memory_region,
     uint32_t total_segments,
     bool enable_uma,
     CaptureCallback* capture_callback,
     base::RepeatingClosure got_data_callback_)
     : AudioDeviceThread::Callback(
           audio_parameters,
           ComputeAudioInputBufferSize(audio_parameters, 1u),
           total_segments),
       enable_uma_(enable_uma),
       shared_memory_region_(std::move(shared_memory_region)),
       start_time_(base::TimeTicks::Now()),
       current_segment_id_(0u),
       last_buffer_id_(UINT32_MAX),
       capture_callback_(capture_callback),
       got_data_callback_interval_in_frames_(kGotDataCallbackIntervalSeconds *
                                             audio_parameters.sample_rate()),
       frames_since_last_got_data_callback_(0),
       got_data_callback_(std::move(got_data_callback_)) {
   // CHECK that the shared memory is large enough. The memory allocated must
   // be at least as large as expected.
   CHECK_LE(memory_length_, shared_memory_region_.GetSize());
 }

 AudioInputDevice::AudioThreadCallback::~AudioThreadCallback() {
   if (enable_uma_) {
     UMA_HISTOGRAM_LONG_TIMES("Media.Audio.Capture.InputStreamDuration",
                              base::TimeTicks::Now() - start_time_);
   }
 }

 void AudioInputDevice::AudioThreadCallback::MapSharedMemory() {
   shared_memory_mapping_ = shared_memory_region_.MapAt(0, memory_length_);

   // Create vector of audio buses by wrapping existing blocks of memory.
   const uint8_t* ptr =
       static_cast<const uint8_t*>(shared_memory_mapping_.memory());
   for (uint32_t i = 0; i < total_segments_; ++i) {
     const media::AudioInputBuffer* buffer =
         reinterpret_cast<const media::AudioInputBuffer*>(ptr);
     audio_buses_.push_back(
         media::AudioBus::WrapReadOnlyMemory(audio_parameters_, buffer->audio));
     ptr += segment_length_;
   }

   // Indicate that browser side capture initialization has succeeded and IPC
   // channel initialized. This effectively completes the
   // AudioCapturerSource::Start()' phase as far as the caller of that function
   // is concerned.
   capture_callback_->OnCaptureStarted();
 }

 void AudioInputDevice::AudioThreadCallback::Process(uint32_t pending_data) {
   TRACE_EVENT_BEGIN0("audio", "AudioInputDevice::AudioThreadCallback::Process");
   // The shared memory represents parameters, size of the data buffer and the
   // actual data buffer containing audio data. Map the memory into this
   // structure and parse out parameters and the data area.
   const uint8_t* ptr =
       static_cast<const uint8_t*>(shared_memory_mapping_.memory());
   ptr += current_segment_id_ * segment_length_;
   const AudioInputBuffer* buffer =
       reinterpret_cast<const AudioInputBuffer*>(ptr);

   // Usually this will be equal but in the case of low sample rate (e.g. 8kHz,
   // the buffer may be bigger (on mac at least)).
   DCHECK_GE(buffer->params.size,
             segment_length_ - sizeof(AudioInputBufferParameters));

   // Verify correct sequence.
   if (buffer->params.id != last_buffer_id_ + 1) {
     std::string message = base::StringPrintf(
         "Incorrect buffer sequence. Expected = %u. Actual = %u.",
         last_buffer_id_ + 1, buffer->params.id);
     LOG(ERROR) << message;
     capture_callback_->OnCaptureError(
         media::AudioCapturerSource::ErrorCode::kUnknown, message);
   }
   if (current_segment_id_ != pending_data) {
     std::string message = base::StringPrintf(
         "Segment id not matching. Remote = %u. Local = %" PRIuS ".",
         pending_data, current_segment_id_);
     LOG(ERROR) << message;
     capture_callback_->OnCaptureError(
         media::AudioCapturerSource::ErrorCode::kUnknown, message);
   }
   last_buffer_id_ = buffer->params.id;

   // Use pre-allocated audio bus wrapping existing block of shared memory.
   const media::AudioBus* audio_bus = audio_buses_[current_segment_id_].get();

   // Regularly inform that we have gotten data.
   frames_since_last_got_data_callback_ += audio_bus->frames();
   if (frames_since_last_got_data_callback_ >=
       got_data_callback_interval_in_frames_) {
     got_data_callback_.Run();
     frames_since_last_got_data_callback_ = 0;
   }

   // Deliver captured data to the client in floating point format and update
   // the audio delay measurement.
   // TODO(olka, tommi): Take advantage of |capture_time| in the renderer.
   const base::TimeTicks capture_time =
       base::TimeTicks() + base::Microseconds(buffer->params.capture_time_us);
   const base::TimeTicks now_time = base::TimeTicks::Now();
   DCHECK_GE(now_time, capture_time);

   capture_callback_->Capture(audio_bus, capture_time, buffer->params.volume,
                              buffer->params.key_pressed);

   if (++current_segment_id_ >= total_segments_)
     current_segment_id_ = 0u;

   TRACE_EVENT_END2(
       "audio", "AudioInputDevice::AudioThreadCallback::Process",
       "capture_time (ms)", (capture_time - base::TimeTicks()).InMillisecondsF(),
       "now_time (ms)", (now_time - base::TimeTicks()).InMillisecondsF());
 }

 }  // namespace media
	// 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 "media/audio/audio_input_device.h"

	#include <stdint.h>
	#include <utility>
	#include <vector>

	#include "base/bind.h"
	#include "base/callback_helpers.h"
	#include "base/format_macros.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/memory/ptr_util.h"
	#include "base/metrics/histogram_macros.h"
	#include "base/strings/stringprintf.h"
	#include "base/threading/thread_restrictions.h"
	#include "base/trace_event/trace_event.h"
	#include "build/build_config.h"
	#include "media/audio/audio_manager_base.h"
	#include "media/base/audio_bus.h"

	namespace media {

	namespace {

	// The number of shared memory buffer segments indicated to browser process
	// in order to avoid data overwriting. This number can be any positive number,
	// dependent how fast the renderer process can pick up captured data from
	// shared memory.
	const int kRequestedSharedMemoryCount = 10;

	// The number of seconds with missing callbacks before we report a capture
	// error. The value is based on that the Mac audio implementation can defer
	// start for 5 seconds when resuming after standby, and has a startup success
	// check 5 seconds after actually starting, where stats is logged. We must allow
	// enough time for this. See AUAudioInputStream::CheckInputStartupSuccess().
	const int kMissingCallbacksTimeBeforeErrorSeconds = 12;

	// The interval for checking missing callbacks.
	const int kCheckMissingCallbacksIntervalSeconds = 5;

	// How often AudioInputDevice::AudioThreadCallback informs that it has gotten
	// data from the source.
	const int kGotDataCallbackIntervalSeconds = 1;

	base::ThreadPriority ThreadPriorityFromPurpose(
	AudioInputDevice::Purpose purpose) {
	switch (purpose) {
	case AudioInputDevice::Purpose::kUserInput:
	return base::ThreadPriority::REALTIME_AUDIO;
	case AudioInputDevice::Purpose::kLoopback:
	return base::ThreadPriority::NORMAL;
	}
	}

	} // namespace

	// Takes care of invoking the capture callback on the audio thread.
	// An instance of this class is created for each capture stream in
	// OnLowLatencyCreated().
	class AudioInputDevice::AudioThreadCallback
	: public AudioDeviceThread::Callback {
	public:
	AudioThreadCallback(const AudioParameters& audio_parameters,
	base::ReadOnlySharedMemoryRegion shared_memory_region,
	uint32_t total_segments,
	bool enable_uma,
	CaptureCallback* capture_callback,
	base::RepeatingClosure got_data_callback);

	AudioThreadCallback(const AudioThreadCallback&) = delete;
	AudioThreadCallback& operator=(const AudioThreadCallback&) = delete;

	~AudioThreadCallback() override;

	void MapSharedMemory() override;

	// Called whenever we receive notifications about pending data.
	void Process(uint32_t pending_data) override;

	private:
	const bool enable_uma_;
	base::ReadOnlySharedMemoryRegion shared_memory_region_;
	base::ReadOnlySharedMemoryMapping shared_memory_mapping_;
	const base::TimeTicks start_time_;
	size_t current_segment_id_;
	uint32_t last_buffer_id_;
	std::vector<std::unique_ptr<const media::AudioBus>> audio_buses_;
	CaptureCallback* capture_callback_;

	// Used for informing AudioInputDevice that we have gotten data, i.e. the
	// stream is alive. \|got_data_callback_\| is run every
	// \|got_data_callback_interval_in_frames_\| frames, calculated from
	// kGotDataCallbackIntervalSeconds.
	const int got_data_callback_interval_in_frames_;
	int frames_since_last_got_data_callback_;
	base::RepeatingClosure got_data_callback_;
	};

	AudioInputDevice::AudioInputDevice(std::unique_ptr<AudioInputIPC> ipc,
	Purpose purpose,
	DeadStreamDetection detect_dead_stream)
	: thread_priority_(ThreadPriorityFromPurpose(purpose)),
	enable_uma_(purpose == AudioInputDevice::Purpose::kUserInput),
	callback_(nullptr),
	ipc_(std::move(ipc)),
	state_(IDLE),
	agc_is_enabled_(false),
	detect_dead_stream_(detect_dead_stream) {
	CHECK(ipc_);

	// The correctness of the code depends on the relative values assigned in the
	// State enum.
	static_assert(IPC_CLOSED < IDLE, "invalid enum value assignment 0");
	static_assert(IDLE < CREATING_STREAM, "invalid enum value assignment 1");
	static_assert(CREATING_STREAM < RECORDING, "invalid enum value assignment 2");
	}

	void AudioInputDevice::Initialize(const AudioParameters& params,
	CaptureCallback* callback) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	DCHECK(params.IsValid());
	DCHECK(!callback_);
	audio_parameters_ = params;
	callback_ = callback;
	}

	void AudioInputDevice::Start() {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	DCHECK(callback_) << "Initialize hasn't been called";
	TRACE_EVENT0("audio", "AudioInputDevice::Start");

	// Make sure we don't call Start() more than once.
	if (state_ != IDLE)
	return;

	state_ = CREATING_STREAM;
	ipc_->CreateStream(this, audio_parameters_, agc_is_enabled_,
	kRequestedSharedMemoryCount);
	}

	void AudioInputDevice::Stop() {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT0("audio", "AudioInputDevice::Stop");

	if (enable_uma_) {
	if (detect_dead_stream_ == DeadStreamDetection::kEnabled) {
	UMA_HISTOGRAM_BOOLEAN(
	"Media.Audio.Capture.DetectedMissingCallbacks",
	alive_checker_ ? alive_checker_->DetectedDead() : false);
	}

	UMA_HISTOGRAM_ENUMERATION("Media.Audio.Capture.StreamCallbackError2",
	had_error_);
	}
	had_error_ = kNoError;

	// Close the stream, if we haven't already.
	if (state_ >= CREATING_STREAM) {
	ipc_->CloseStream();
	state_ = IDLE;
	agc_is_enabled_ = false;
	}

	// We can run into an issue where Stop is called right after
	// OnStreamCreated is called in cases where Start/Stop are called before we
	// get the OnStreamCreated callback. To handle that corner case, we call
	// audio_thread_.reset(). In most cases, the thread will already be stopped.
	//
	// \|alive_checker_\| must outlive \|audio_callback_\|.
	base::ScopedAllowBaseSyncPrimitivesOutsideBlockingScope allow_thread_join;
	audio_thread_.reset();
	audio_callback_.reset();
	alive_checker_.reset();
	}

	void AudioInputDevice::SetVolume(double volume) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT1("audio", "AudioInputDevice::SetVolume", "volume", volume);

	if (volume < 0 \|\| volume > 1.0) {
	DLOG(ERROR) << "Invalid volume value specified";
	return;
	}

	if (state_ >= CREATING_STREAM)
	ipc_->SetVolume(volume);
	}

	void AudioInputDevice::SetAutomaticGainControl(bool enabled) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT1("audio", "AudioInputDevice::SetAutomaticGainControl", "enabled",
	enabled);

	if (state_ >= CREATING_STREAM) {
	DLOG(WARNING) << "The AGC state can not be modified after starting.";
	return;
	}

	// We simply store the new AGC setting here. This value will be used when
	// a new stream is initialized and by GetAutomaticGainControl().
	agc_is_enabled_ = enabled;
	}

	void AudioInputDevice::SetOutputDeviceForAec(
	const std::string& output_device_id) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT1("audio", "AudioInputDevice::SetOutputDeviceForAec",
	"output_device_id", output_device_id);

	output_device_id_for_aec_ = output_device_id;
	if (state_ > CREATING_STREAM)
	ipc_->SetOutputDeviceForAec(output_device_id);
	}

	void AudioInputDevice::OnStreamCreated(
	base::ReadOnlySharedMemoryRegion shared_memory_region,
	base::SyncSocket::ScopedHandle socket_handle,
	bool initially_muted) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT0("audio", "AudioInputDevice::OnStreamCreated");
	DCHECK(shared_memory_region.IsValid());
	#if defined(OS_WIN)
	DCHECK(socket_handle.IsValid());
	#else
	DCHECK(socket_handle.is_valid());
	#endif
	DCHECK_GT(shared_memory_region.GetSize(), 0u);

	if (state_ != CREATING_STREAM)
	return;

	DCHECK(!audio_callback_);
	DCHECK(!audio_thread_);

	if (initially_muted)
	callback_->OnCaptureMuted(true);

	if (auto* controls = ipc_->GetProcessorControls())
	callback_->OnCaptureProcessorCreated(controls);

	if (output_device_id_for_aec_)
	ipc_->SetOutputDeviceForAec(*output_device_id_for_aec_);

	// Set up checker for detecting missing audio data. We pass a callback which
	// holds a reference to this. \|alive_checker_\| is deleted in
	// Stop() which we expect to always be called (see comment in
	// destructor). Suspend/resume notifications are not supported on Linux and
	// there's a risk of false positives when suspending. So on Linux we only detect
	// missing audio data until the first audio buffer arrives. Note that there's
	// also a risk of false positives if we are suspending when starting the stream
	// here. See comments in AliveChecker and PowerObserverHelper for details and
	// todos.
	if (detect_dead_stream_ == DeadStreamDetection::kEnabled) {
	#if defined(OS_LINUX) \|\| defined(OS_CHROMEOS)
	const bool stop_at_first_alive_notification = true;
	const bool pause_check_during_suspend = false;
	#else
	const bool stop_at_first_alive_notification = false;
	const bool pause_check_during_suspend = true;
	#endif
	alive_checker_ = std::make_unique<AliveChecker>(
	base::BindRepeating(&AudioInputDevice::DetectedDeadInputStream, this),
	base::Seconds(kCheckMissingCallbacksIntervalSeconds),
	base::Seconds(kMissingCallbacksTimeBeforeErrorSeconds),
	stop_at_first_alive_notification, pause_check_during_suspend);
	}

	// Unretained is safe since \|alive_checker_\| outlives \|audio_callback_\|.
	base::RepeatingClosure notify_alive_closure =
	alive_checker_
	? base::BindRepeating(&AliveChecker::NotifyAlive,
	base::Unretained(alive_checker_.get()))
	: base::DoNothing();

	audio_callback_ = std::make_unique<AudioInputDevice::AudioThreadCallback>(
	audio_parameters_, std::move(shared_memory_region),
	kRequestedSharedMemoryCount, enable_uma_, callback_,
	notify_alive_closure);
	audio_thread_ = std::make_unique<AudioDeviceThread>(
	audio_callback_.get(), std::move(socket_handle), "AudioInputDevice",
	thread_priority_);

	state_ = RECORDING;
	ipc_->RecordStream();

	// Start detecting missing audio data.
	if (alive_checker_)
	alive_checker_->Start();
	}

	void AudioInputDevice::OnError(AudioCapturerSource::ErrorCode code) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT0("audio", "AudioInputDevice::OnError");

	// Do nothing if the stream has been closed.
	if (state_ < CREATING_STREAM)
	return;

	if (state_ == CREATING_STREAM) {
	// At this point, we haven't attempted to start the audio thread.
	// Accessing the hardware might have failed or we may have reached
	// the limit of the number of allowed concurrent streams.
	// We must report the error to the \|callback_\| so that a potential
	// audio source object will enter the correct state (e.g. 'ended' for
	// a local audio source).
	had_error_ = kErrorDuringCreation;
	callback_->OnCaptureError(
	code, code == AudioCapturerSource::ErrorCode::kSystemPermissions
	? "Unable to open due to failing an OS Permissions check."
	: "Maximum allowed input device limit reached or an OS "
	"failure occured.");
	} else {
	// Don't dereference the callback object if the audio thread
	// is stopped or stopping. That could mean that the callback
	// object has been deleted.
	// TODO(tommi): Add an explicit contract for clearing the callback
	// object. Possibly require calling Initialize again or provide
	// a callback object via Start() and clear it in Stop().
	had_error_ = kErrorDuringCapture;
	if (audio_thread_)
	callback_->OnCaptureError(code, "IPC delegate state error.");
	}
	}

	void AudioInputDevice::OnMuted(bool is_muted) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT0("audio", "AudioInputDevice::OnMuted");

	// Do nothing if the stream has been closed.
	if (state_ < CREATING_STREAM)
	return;
	callback_->OnCaptureMuted(is_muted);
	}

	void AudioInputDevice::OnIPCClosed() {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	TRACE_EVENT0("audio", "AudioInputDevice::OnIPCClosed");

	state_ = IPC_CLOSED;
	ipc_.reset();
	}

	AudioInputDevice::~AudioInputDevice() {
	#if DCHECK_IS_ON()
	// Make sure we've stopped the stream properly before destructing \|this\|.
	DCHECK_LE(state_, IDLE);
	DCHECK(!audio_thread_);
	DCHECK(!audio_callback_);
	DCHECK(!alive_checker_);
	#endif // DCHECK_IS_ON()
	}

	void AudioInputDevice::DetectedDeadInputStream() {
	callback_->OnCaptureError(media::AudioCapturerSource::ErrorCode::kUnknown,
	"No audio received from audio capture device.");
	}

	// AudioInputDevice::AudioThreadCallback
	AudioInputDevice::AudioThreadCallback::AudioThreadCallback(
	const AudioParameters& audio_parameters,
	base::ReadOnlySharedMemoryRegion shared_memory_region,
	uint32_t total_segments,
	bool enable_uma,
	CaptureCallback* capture_callback,
	base::RepeatingClosure got_data_callback_)
	: AudioDeviceThread::Callback(
	audio_parameters,
	ComputeAudioInputBufferSize(audio_parameters, 1u),
	total_segments),
	enable_uma_(enable_uma),
	shared_memory_region_(std::move(shared_memory_region)),
	start_time_(base::TimeTicks::Now()),
	current_segment_id_(0u),
	last_buffer_id_(UINT32_MAX),
	capture_callback_(capture_callback),
	got_data_callback_interval_in_frames_(kGotDataCallbackIntervalSeconds *
	audio_parameters.sample_rate()),
	frames_since_last_got_data_callback_(0),
	got_data_callback_(std::move(got_data_callback_)) {
	// CHECK that the shared memory is large enough. The memory allocated must
	// be at least as large as expected.
	CHECK_LE(memory_length_, shared_memory_region_.GetSize());
	}

	AudioInputDevice::AudioThreadCallback::~AudioThreadCallback() {
	if (enable_uma_) {
	UMA_HISTOGRAM_LONG_TIMES("Media.Audio.Capture.InputStreamDuration",
	base::TimeTicks::Now() - start_time_);
	}
	}

	void AudioInputDevice::AudioThreadCallback::MapSharedMemory() {
	shared_memory_mapping_ = shared_memory_region_.MapAt(0, memory_length_);

	// Create vector of audio buses by wrapping existing blocks of memory.
	const uint8_t* ptr =
	static_cast<const uint8_t*>(shared_memory_mapping_.memory());
	for (uint32_t i = 0; i < total_segments_; ++i) {
	const media::AudioInputBuffer* buffer =
	reinterpret_cast<const media::AudioInputBuffer*>(ptr);
	audio_buses_.push_back(
	media::AudioBus::WrapReadOnlyMemory(audio_parameters_, buffer->audio));
	ptr += segment_length_;
	}

	// Indicate that browser side capture initialization has succeeded and IPC
	// channel initialized. This effectively completes the
	// AudioCapturerSource::Start()' phase as far as the caller of that function
	// is concerned.
	capture_callback_->OnCaptureStarted();
	}

	void AudioInputDevice::AudioThreadCallback::Process(uint32_t pending_data) {
	TRACE_EVENT_BEGIN0("audio", "AudioInputDevice::AudioThreadCallback::Process");
	// The shared memory represents parameters, size of the data buffer and the
	// actual data buffer containing audio data. Map the memory into this
	// structure and parse out parameters and the data area.
	const uint8_t* ptr =
	static_cast<const uint8_t*>(shared_memory_mapping_.memory());
	ptr += current_segment_id_ * segment_length_;
	const AudioInputBuffer* buffer =
	reinterpret_cast<const AudioInputBuffer*>(ptr);

	// Usually this will be equal but in the case of low sample rate (e.g. 8kHz,
	// the buffer may be bigger (on mac at least)).
	DCHECK_GE(buffer->params.size,
	segment_length_ - sizeof(AudioInputBufferParameters));

	// Verify correct sequence.
	if (buffer->params.id != last_buffer_id_ + 1) {
	std::string message = base::StringPrintf(
	"Incorrect buffer sequence. Expected = %u. Actual = %u.",
	last_buffer_id_ + 1, buffer->params.id);
	LOG(ERROR) << message;
	capture_callback_->OnCaptureError(
	media::AudioCapturerSource::ErrorCode::kUnknown, message);
	}
	if (current_segment_id_ != pending_data) {
	std::string message = base::StringPrintf(
	"Segment id not matching. Remote = %u. Local = %" PRIuS ".",
	pending_data, current_segment_id_);
	LOG(ERROR) << message;
	capture_callback_->OnCaptureError(
	media::AudioCapturerSource::ErrorCode::kUnknown, message);
	}
	last_buffer_id_ = buffer->params.id;

	// Use pre-allocated audio bus wrapping existing block of shared memory.
	const media::AudioBus* audio_bus = audio_buses_[current_segment_id_].get();

	// Regularly inform that we have gotten data.
	frames_since_last_got_data_callback_ += audio_bus->frames();
	if (frames_since_last_got_data_callback_ >=
	got_data_callback_interval_in_frames_) {
	got_data_callback_.Run();
	frames_since_last_got_data_callback_ = 0;
	}

	// Deliver captured data to the client in floating point format and update
	// the audio delay measurement.
	// TODO(olka, tommi): Take advantage of \|capture_time\| in the renderer.
	const base::TimeTicks capture_time =
	base::TimeTicks() + base::Microseconds(buffer->params.capture_time_us);
	const base::TimeTicks now_time = base::TimeTicks::Now();
	DCHECK_GE(now_time, capture_time);

	capture_callback_->Capture(audio_bus, capture_time, buffer->params.volume,
	buffer->params.key_pressed);

	if (++current_segment_id_ >= total_segments_)
	current_segment_id_ = 0u;

	TRACE_EVENT_END2(
	"audio", "AudioInputDevice::AudioThreadCallback::Process",
	"capture_time (ms)", (capture_time - base::TimeTicks()).InMillisecondsF(),
	"now_time (ms)", (now_time - base::TimeTicks()).InMillisecondsF());
	}

	} // namespace media