media/audio/audio_input_device.cc - platform/external/chromium_org - 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 "base/basictypes.h"
 #include "base/bind.h"
 #include "base/memory/scoped_vector.h"
 #include "base/threading/thread_restrictions.h"
 #include "base/time/time.h"
 #include "media/audio/audio_manager_base.h"
 #include "media/base/audio_bus.h"

 namespace media {

 // 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.
 static const int kRequestedSharedMemoryCount = 10;

 // 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::SharedMemoryHandle memory,
                       int memory_length,
                       int total_segments,
                       CaptureCallback* capture_callback);
   virtual ~AudioThreadCallback();

   virtual void MapSharedMemory() OVERRIDE;

   // Called whenever we receive notifications about pending data.
   virtual void Process(int pending_data) OVERRIDE;

  private:
   int current_segment_id_;
   ScopedVector<media::AudioBus> audio_buses_;
   CaptureCallback* capture_callback_;

   DISALLOW_COPY_AND_ASSIGN(AudioThreadCallback);
 };

 AudioInputDevice::AudioInputDevice(
     scoped_ptr<AudioInputIPC> ipc,
     const scoped_refptr<base::SingleThreadTaskRunner>& io_task_runner)
     : ScopedTaskRunnerObserver(io_task_runner),
       callback_(NULL),
       ipc_(ipc.Pass()),
       state_(IDLE),
       session_id_(0),
       agc_is_enabled_(false),
       stopping_hack_(false) {
   CHECK(ipc_);

   // The correctness of the code depends on the relative values assigned in the
   // State enum.
   COMPILE_ASSERT(IPC_CLOSED < IDLE, invalid_enum_value_assignment_0);
   COMPILE_ASSERT(IDLE < CREATING_STREAM, invalid_enum_value_assignment_1);
   COMPILE_ASSERT(CREATING_STREAM < RECORDING, invalid_enum_value_assignment_2);
 }

 void AudioInputDevice::Initialize(const AudioParameters& params,
                                   CaptureCallback* callback,
                                   int session_id) {
   DCHECK(params.IsValid());
   DCHECK(!callback_);
   DCHECK_EQ(0, session_id_);
   audio_parameters_ = params;
   callback_ = callback;
   session_id_ = session_id;
 }

 void AudioInputDevice::Start() {
   DCHECK(callback_) << "Initialize hasn't been called";
   DVLOG(1) << "Start()";
   task_runner()->PostTask(FROM_HERE,
       base::Bind(&AudioInputDevice::StartUpOnIOThread, this));
 }

 void AudioInputDevice::Stop() {
   DVLOG(1) << "Stop()";

   {
     base::AutoLock auto_lock(audio_thread_lock_);
     audio_thread_.Stop(base::MessageLoop::current());
     stopping_hack_ = true;
   }

   task_runner()->PostTask(FROM_HERE,
       base::Bind(&AudioInputDevice::ShutDownOnIOThread, this));
 }

 void AudioInputDevice::SetVolume(double volume) {
   if (volume < 0 || volume > 1.0) {
     DLOG(ERROR) << "Invalid volume value specified";
     return;
   }

   task_runner()->PostTask(FROM_HERE,
       base::Bind(&AudioInputDevice::SetVolumeOnIOThread, this, volume));
 }

 void AudioInputDevice::SetAutomaticGainControl(bool enabled) {
   DVLOG(1) << "SetAutomaticGainControl(enabled=" << enabled << ")";
   task_runner()->PostTask(FROM_HERE,
       base::Bind(&AudioInputDevice::SetAutomaticGainControlOnIOThread,
           this, enabled));
 }

 void AudioInputDevice::OnStreamCreated(
     base::SharedMemoryHandle handle,
     base::SyncSocket::Handle socket_handle,
     int length,
     int total_segments) {
   DCHECK(task_runner()->BelongsToCurrentThread());
 #if defined(OS_WIN)
   DCHECK(handle);
   DCHECK(socket_handle);
 #else
   DCHECK_GE(handle.fd, 0);
   DCHECK_GE(socket_handle, 0);
 #endif
   DCHECK_GT(length, 0);

   if (state_ != CREATING_STREAM)
     return;

   base::AutoLock auto_lock(audio_thread_lock_);
   // TODO(miu): See TODO in OnStreamCreated method for AudioOutputDevice.
   // Interface changes need to be made; likely, after AudioInputDevice is merged
   // into AudioOutputDevice (http://crbug.com/179597).
   if (stopping_hack_)
     return;

   DCHECK(audio_thread_.IsStopped());
   audio_callback_.reset(new AudioInputDevice::AudioThreadCallback(
       audio_parameters_, handle, length, total_segments, callback_));
   audio_thread_.Start(
       audio_callback_.get(), socket_handle, "AudioInputDevice", false);

   state_ = RECORDING;
   ipc_->RecordStream();
 }

 void AudioInputDevice::OnVolume(double volume) {
   NOTIMPLEMENTED();
 }

 void AudioInputDevice::OnStateChanged(
     AudioInputIPCDelegate::State state) {
   DCHECK(task_runner()->BelongsToCurrentThread());

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

   // TODO(miu): Clean-up inconsistent and incomplete handling here.
   // http://crbug.com/180640
   switch (state) {
     case AudioInputIPCDelegate::kStopped:
       ShutDownOnIOThread();
       break;
     case AudioInputIPCDelegate::kRecording:
       NOTIMPLEMENTED();
       break;
     case AudioInputIPCDelegate::kError:
       DLOG(WARNING) << "AudioInputDevice::OnStateChanged(kError)";
       // 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().
       if (!audio_thread_.IsStopped())
         callback_->OnCaptureError();
       break;
     default:
       NOTREACHED();
       break;
   }
 }

 void AudioInputDevice::OnIPCClosed() {
   DCHECK(task_runner()->BelongsToCurrentThread());
   state_ = IPC_CLOSED;
   ipc_.reset();
 }

 AudioInputDevice::~AudioInputDevice() {
   // TODO(henrika): The current design requires that the user calls
   // Stop before deleting this class.
   DCHECK(audio_thread_.IsStopped());
 }

 void AudioInputDevice::StartUpOnIOThread() {
   DCHECK(task_runner()->BelongsToCurrentThread());

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

   if (session_id_ <= 0) {
     DLOG(WARNING) << "Invalid session id for the input stream " << session_id_;
     return;
   }

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

 void AudioInputDevice::ShutDownOnIOThread() {
   DCHECK(task_runner()->BelongsToCurrentThread());

   // 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 ShutDownOnIOThread 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
   // Stop(). In most cases, the thread will already be stopped.
   //
   // Another situation is when the IO thread goes away before Stop() is called
   // in which case, we cannot use the message loop to close the thread handle
   // and can't not rely on the main thread existing either.
   base::AutoLock auto_lock_(audio_thread_lock_);
   base::ThreadRestrictions::ScopedAllowIO allow_io;
   audio_thread_.Stop(NULL);
   audio_callback_.reset();
   stopping_hack_ = false;
 }

 void AudioInputDevice::SetVolumeOnIOThread(double volume) {
   DCHECK(task_runner()->BelongsToCurrentThread());
   if (state_ >= CREATING_STREAM)
     ipc_->SetVolume(volume);
 }

 void AudioInputDevice::SetAutomaticGainControlOnIOThread(bool enabled) {
   DCHECK(task_runner()->BelongsToCurrentThread());

   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::WillDestroyCurrentMessageLoop() {
   LOG(ERROR) << "IO loop going away before the input device has been stopped";
   ShutDownOnIOThread();
 }

 // AudioInputDevice::AudioThreadCallback
 AudioInputDevice::AudioThreadCallback::AudioThreadCallback(
     const AudioParameters& audio_parameters,
     base::SharedMemoryHandle memory,
     int memory_length,
     int total_segments,
     CaptureCallback* capture_callback)
     : AudioDeviceThread::Callback(audio_parameters, memory, memory_length,
                                   total_segments),
       current_segment_id_(0),
       capture_callback_(capture_callback) {
 }

 AudioInputDevice::AudioThreadCallback::~AudioThreadCallback() {
 }

 void AudioInputDevice::AudioThreadCallback::MapSharedMemory() {
   shared_memory_.Map(memory_length_);

   // Create vector of audio buses by wrapping existing blocks of memory.
   uint8* ptr = static_cast<uint8*>(shared_memory_.memory());
   for (int i = 0; i < total_segments_; ++i) {
     media::AudioInputBuffer* buffer =
         reinterpret_cast<media::AudioInputBuffer*>(ptr);
     scoped_ptr<media::AudioBus> audio_bus =
         media::AudioBus::WrapMemory(audio_parameters_, buffer->audio);
     audio_buses_.push_back(audio_bus.release());
     ptr += segment_length_;
   }
 }

 void AudioInputDevice::AudioThreadCallback::Process(int pending_data) {
   // 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.
   uint8* ptr = static_cast<uint8*>(shared_memory_.memory());
   ptr += current_segment_id_ * segment_length_;
   AudioInputBuffer* buffer = reinterpret_cast<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));
   double volume = buffer->params.volume;
   bool key_pressed = buffer->params.key_pressed;

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

   // Deliver captured data to the client in floating point format
   // and update the audio-delay measurement.
   int audio_delay_milliseconds = pending_data / bytes_per_ms_;
   capture_callback_->Capture(
       audio_bus, audio_delay_milliseconds, volume, key_pressed);

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

 }  // 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 "base/basictypes.h"
	#include "base/bind.h"
	#include "base/memory/scoped_vector.h"
	#include "base/threading/thread_restrictions.h"
	#include "base/time/time.h"
	#include "media/audio/audio_manager_base.h"
	#include "media/base/audio_bus.h"

	namespace media {

	// 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.
	static const int kRequestedSharedMemoryCount = 10;

	// 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::SharedMemoryHandle memory,
	int memory_length,
	int total_segments,
	CaptureCallback* capture_callback);
	virtual ~AudioThreadCallback();

	virtual void MapSharedMemory() OVERRIDE;

	// Called whenever we receive notifications about pending data.
	virtual void Process(int pending_data) OVERRIDE;

	private:
	int current_segment_id_;
	ScopedVector<media::AudioBus> audio_buses_;
	CaptureCallback* capture_callback_;

	DISALLOW_COPY_AND_ASSIGN(AudioThreadCallback);
	};

	AudioInputDevice::AudioInputDevice(
	scoped_ptr<AudioInputIPC> ipc,
	const scoped_refptr<base::SingleThreadTaskRunner>& io_task_runner)
	: ScopedTaskRunnerObserver(io_task_runner),
	callback_(NULL),
	ipc_(ipc.Pass()),
	state_(IDLE),
	session_id_(0),
	agc_is_enabled_(false),
	stopping_hack_(false) {
	CHECK(ipc_);

	// The correctness of the code depends on the relative values assigned in the
	// State enum.
	COMPILE_ASSERT(IPC_CLOSED < IDLE, invalid_enum_value_assignment_0);
	COMPILE_ASSERT(IDLE < CREATING_STREAM, invalid_enum_value_assignment_1);
	COMPILE_ASSERT(CREATING_STREAM < RECORDING, invalid_enum_value_assignment_2);
	}

	void AudioInputDevice::Initialize(const AudioParameters& params,
	CaptureCallback* callback,
	int session_id) {
	DCHECK(params.IsValid());
	DCHECK(!callback_);
	DCHECK_EQ(0, session_id_);
	audio_parameters_ = params;
	callback_ = callback;
	session_id_ = session_id;
	}

	void AudioInputDevice::Start() {
	DCHECK(callback_) << "Initialize hasn't been called";
	DVLOG(1) << "Start()";
	task_runner()->PostTask(FROM_HERE,
	base::Bind(&AudioInputDevice::StartUpOnIOThread, this));
	}

	void AudioInputDevice::Stop() {
	DVLOG(1) << "Stop()";

	{
	base::AutoLock auto_lock(audio_thread_lock_);
	audio_thread_.Stop(base::MessageLoop::current());
	stopping_hack_ = true;
	}

	task_runner()->PostTask(FROM_HERE,
	base::Bind(&AudioInputDevice::ShutDownOnIOThread, this));
	}

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

	task_runner()->PostTask(FROM_HERE,
	base::Bind(&AudioInputDevice::SetVolumeOnIOThread, this, volume));
	}

	void AudioInputDevice::SetAutomaticGainControl(bool enabled) {
	DVLOG(1) << "SetAutomaticGainControl(enabled=" << enabled << ")";
	task_runner()->PostTask(FROM_HERE,
	base::Bind(&AudioInputDevice::SetAutomaticGainControlOnIOThread,
	this, enabled));
	}

	void AudioInputDevice::OnStreamCreated(
	base::SharedMemoryHandle handle,
	base::SyncSocket::Handle socket_handle,
	int length,
	int total_segments) {
	DCHECK(task_runner()->BelongsToCurrentThread());
	#if defined(OS_WIN)
	DCHECK(handle);
	DCHECK(socket_handle);
	#else
	DCHECK_GE(handle.fd, 0);
	DCHECK_GE(socket_handle, 0);
	#endif
	DCHECK_GT(length, 0);

	if (state_ != CREATING_STREAM)
	return;

	base::AutoLock auto_lock(audio_thread_lock_);
	// TODO(miu): See TODO in OnStreamCreated method for AudioOutputDevice.
	// Interface changes need to be made; likely, after AudioInputDevice is merged
	// into AudioOutputDevice (http://crbug.com/179597).
	if (stopping_hack_)
	return;

	DCHECK(audio_thread_.IsStopped());
	audio_callback_.reset(new AudioInputDevice::AudioThreadCallback(
	audio_parameters_, handle, length, total_segments, callback_));
	audio_thread_.Start(
	audio_callback_.get(), socket_handle, "AudioInputDevice", false);

	state_ = RECORDING;
	ipc_->RecordStream();
	}

	void AudioInputDevice::OnVolume(double volume) {
	NOTIMPLEMENTED();
	}

	void AudioInputDevice::OnStateChanged(
	AudioInputIPCDelegate::State state) {
	DCHECK(task_runner()->BelongsToCurrentThread());

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

	// TODO(miu): Clean-up inconsistent and incomplete handling here.
	// http://crbug.com/180640
	switch (state) {
	case AudioInputIPCDelegate::kStopped:
	ShutDownOnIOThread();
	break;
	case AudioInputIPCDelegate::kRecording:
	NOTIMPLEMENTED();
	break;
	case AudioInputIPCDelegate::kError:
	DLOG(WARNING) << "AudioInputDevice::OnStateChanged(kError)";
	// 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().
	if (!audio_thread_.IsStopped())
	callback_->OnCaptureError();
	break;
	default:
	NOTREACHED();
	break;
	}
	}

	void AudioInputDevice::OnIPCClosed() {
	DCHECK(task_runner()->BelongsToCurrentThread());
	state_ = IPC_CLOSED;
	ipc_.reset();
	}

	AudioInputDevice::~AudioInputDevice() {
	// TODO(henrika): The current design requires that the user calls
	// Stop before deleting this class.
	DCHECK(audio_thread_.IsStopped());
	}

	void AudioInputDevice::StartUpOnIOThread() {
	DCHECK(task_runner()->BelongsToCurrentThread());

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

	if (session_id_ <= 0) {
	DLOG(WARNING) << "Invalid session id for the input stream " << session_id_;
	return;
	}

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

	void AudioInputDevice::ShutDownOnIOThread() {
	DCHECK(task_runner()->BelongsToCurrentThread());

	// 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 ShutDownOnIOThread 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
	// Stop(). In most cases, the thread will already be stopped.
	//
	// Another situation is when the IO thread goes away before Stop() is called
	// in which case, we cannot use the message loop to close the thread handle
	// and can't not rely on the main thread existing either.
	base::AutoLock auto_lock_(audio_thread_lock_);
	base::ThreadRestrictions::ScopedAllowIO allow_io;
	audio_thread_.Stop(NULL);
	audio_callback_.reset();
	stopping_hack_ = false;
	}

	void AudioInputDevice::SetVolumeOnIOThread(double volume) {
	DCHECK(task_runner()->BelongsToCurrentThread());
	if (state_ >= CREATING_STREAM)
	ipc_->SetVolume(volume);
	}

	void AudioInputDevice::SetAutomaticGainControlOnIOThread(bool enabled) {
	DCHECK(task_runner()->BelongsToCurrentThread());

	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::WillDestroyCurrentMessageLoop() {
	LOG(ERROR) << "IO loop going away before the input device has been stopped";
	ShutDownOnIOThread();
	}

	// AudioInputDevice::AudioThreadCallback
	AudioInputDevice::AudioThreadCallback::AudioThreadCallback(
	const AudioParameters& audio_parameters,
	base::SharedMemoryHandle memory,
	int memory_length,
	int total_segments,
	CaptureCallback* capture_callback)
	: AudioDeviceThread::Callback(audio_parameters, memory, memory_length,
	total_segments),
	current_segment_id_(0),
	capture_callback_(capture_callback) {
	}

	AudioInputDevice::AudioThreadCallback::~AudioThreadCallback() {
	}

	void AudioInputDevice::AudioThreadCallback::MapSharedMemory() {
	shared_memory_.Map(memory_length_);

	// Create vector of audio buses by wrapping existing blocks of memory.
	uint8* ptr = static_cast<uint8*>(shared_memory_.memory());
	for (int i = 0; i < total_segments_; ++i) {
	media::AudioInputBuffer* buffer =
	reinterpret_cast<media::AudioInputBuffer*>(ptr);
	scoped_ptr<media::AudioBus> audio_bus =
	media::AudioBus::WrapMemory(audio_parameters_, buffer->audio);
	audio_buses_.push_back(audio_bus.release());
	ptr += segment_length_;
	}
	}

	void AudioInputDevice::AudioThreadCallback::Process(int pending_data) {
	// 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.
	uint8* ptr = static_cast<uint8*>(shared_memory_.memory());
	ptr += current_segment_id_ * segment_length_;
	AudioInputBuffer* buffer = reinterpret_cast<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));
	double volume = buffer->params.volume;
	bool key_pressed = buffer->params.key_pressed;

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

	// Deliver captured data to the client in floating point format
	// and update the audio-delay measurement.
	int audio_delay_milliseconds = pending_data / bytes_per_ms_;
	capture_callback_->Capture(
	audio_bus, audio_delay_milliseconds, volume, key_pressed);

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

	} // namespace media