src/media/audio/mac/audio_low_latency_input_mac.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/mac/audio_low_latency_input_mac.h"

 #include <CoreServices/CoreServices.h>

 #include "base/basictypes.h"
 #include "base/logging.h"
 #include "base/mac/mac_logging.h"
 #include "media/audio/audio_util.h"
 #include "media/audio/mac/audio_manager_mac.h"
 #include "media/base/data_buffer.h"

 namespace media {

 static const int kMinIntervalBetweenVolumeUpdatesMs = 1000;

 static std::ostream& operator<<(std::ostream& os,
                                 const AudioStreamBasicDescription& format) {
   os << "sample rate       : " << format.mSampleRate << std::endl
      << "format ID         : " << format.mFormatID << std::endl
      << "format flags      : " << format.mFormatFlags << std::endl
      << "bytes per packet  : " << format.mBytesPerPacket << std::endl
      << "frames per packet : " << format.mFramesPerPacket << std::endl
      << "bytes per frame   : " << format.mBytesPerFrame << std::endl
      << "channels per frame: " << format.mChannelsPerFrame << std::endl
      << "bits per channel  : " << format.mBitsPerChannel;
   return os;
 }

 // See "Technical Note TN2091 - Device input using the HAL Output Audio Unit"
 // http://developer.apple.com/library/mac/#technotes/tn2091/_index.html
 // for more details and background regarding this implementation.

 AUAudioInputStream::AUAudioInputStream(
     AudioManagerMac* manager, const AudioParameters& params,
     AudioDeviceID audio_device_id)
     : manager_(manager),
       sink_(NULL),
       audio_unit_(0),
       input_device_id_(audio_device_id),
       started_(false),
       hardware_latency_frames_(0),
       number_of_channels_in_frame_(0) {
   DCHECK(manager_);

   // Set up the desired (output) format specified by the client.
   format_.mSampleRate = params.sample_rate();
   format_.mFormatID = kAudioFormatLinearPCM;
   format_.mFormatFlags = kLinearPCMFormatFlagIsPacked |
                          kLinearPCMFormatFlagIsSignedInteger;
   format_.mBitsPerChannel = params.bits_per_sample();
   format_.mChannelsPerFrame = params.channels();
   format_.mFramesPerPacket = 1;  // uncompressed audio
   format_.mBytesPerPacket = (format_.mBitsPerChannel *
                              params.channels()) / 8;
   format_.mBytesPerFrame = format_.mBytesPerPacket;
   format_.mReserved = 0;

   DVLOG(1) << "Desired ouput format: " << format_;

   // Set number of sample frames per callback used by the internal audio layer.
   // An internal FIFO is then utilized to adapt the internal size to the size
   // requested by the client.
   // Note that we  use the same native buffer size as for the output side here
   // since the AUHAL implementation requires that both capture and render side
   // use the same buffer size. See http://crbug.com/154352 for more details.
   number_of_frames_ = GetAudioHardwareBufferSize();
   DVLOG(1) << "Size of data buffer in frames : " << number_of_frames_;

   // Derive size (in bytes) of the buffers that we will render to.
   UInt32 data_byte_size = number_of_frames_ * format_.mBytesPerFrame;
   DVLOG(1) << "Size of data buffer in bytes : " << data_byte_size;

   // Allocate AudioBuffers to be used as storage for the received audio.
   // The AudioBufferList structure works as a placeholder for the
   // AudioBuffer structure, which holds a pointer to the actual data buffer.
   audio_data_buffer_.reset(new uint8[data_byte_size]);
   audio_buffer_list_.mNumberBuffers = 1;

   AudioBuffer* audio_buffer = audio_buffer_list_.mBuffers;
   audio_buffer->mNumberChannels = params.channels();
   audio_buffer->mDataByteSize = data_byte_size;
   audio_buffer->mData = audio_data_buffer_.get();

   // Set up an internal FIFO buffer that will accumulate recorded audio frames
   // until a requested size is ready to be sent to the client.
   // It is not possible to ask for less than |kAudioFramesPerCallback| number of
   // audio frames.
   const size_t requested_size_frames =
       params.GetBytesPerBuffer() / format_.mBytesPerPacket;
   DCHECK_GE(requested_size_frames, number_of_frames_);
   requested_size_bytes_ = requested_size_frames * format_.mBytesPerFrame;
   DVLOG(1) << "Requested buffer size in bytes : " << requested_size_bytes_;
   DLOG_IF(INFO, requested_size_frames > number_of_frames_) << "FIFO is used";

   // Allocate some extra memory to avoid memory reallocations.
   // Ensure that the size is an even multiple of |number_of_frames_ and
   // larger than |requested_size_frames|.
   // Example: number_of_frames_=128, requested_size_frames=480 =>
   // allocated space equals 4*128=512 audio frames
   const int max_forward_capacity = format_.mBytesPerFrame * number_of_frames_ *
       ((requested_size_frames / number_of_frames_) + 1);
   fifo_.reset(new media::SeekableBuffer(0, max_forward_capacity));

   data_ = new media::DataBuffer(requested_size_bytes_);
 }

 AUAudioInputStream::~AUAudioInputStream() {}

 // Obtain and open the AUHAL AudioOutputUnit for recording.
 bool AUAudioInputStream::Open() {
   // Verify that we are not already opened.
   if (audio_unit_)
     return false;

   // Verify that we have a valid device.
   if (input_device_id_ == kAudioObjectUnknown) {
     NOTREACHED() << "Device ID is unknown";
     return false;
   }

   // Start by obtaining an AudioOuputUnit using an AUHAL component description.

   Component comp;
   ComponentDescription desc;

   // Description for the Audio Unit we want to use (AUHAL in this case).
   desc.componentType = kAudioUnitType_Output;
   desc.componentSubType = kAudioUnitSubType_HALOutput;
   desc.componentManufacturer = kAudioUnitManufacturer_Apple;
   desc.componentFlags = 0;
   desc.componentFlagsMask = 0;
   comp = FindNextComponent(0, &desc);
   DCHECK(comp);

   // Get access to the service provided by the specified Audio Unit.
   OSStatus result = OpenAComponent(comp, &audio_unit_);
   if (result) {
     HandleError(result);
     return false;
   }

   // Enable IO on the input scope of the Audio Unit.

   // After creating the AUHAL object, we must enable IO on the input scope
   // of the Audio Unit to obtain the device input. Input must be explicitly
   // enabled with the kAudioOutputUnitProperty_EnableIO property on Element 1
   // of the AUHAL. Beacause the AUHAL can be used for both input and output,
   // we must also disable IO on the output scope.

   UInt32 enableIO = 1;

   // Enable input on the AUHAL.
   result = AudioUnitSetProperty(audio_unit_,
                                 kAudioOutputUnitProperty_EnableIO,
                                 kAudioUnitScope_Input,
                                 1,          // input element 1
                                 &enableIO,  // enable
                                 sizeof(enableIO));
   if (result) {
     HandleError(result);
     return false;
   }

   // Disable output on the AUHAL.
   enableIO = 0;
   result = AudioUnitSetProperty(audio_unit_,
                                 kAudioOutputUnitProperty_EnableIO,
                                 kAudioUnitScope_Output,
                                 0,          // output element 0
                                 &enableIO,  // disable
                                 sizeof(enableIO));
   if (result) {
     HandleError(result);
     return false;
   }

   // Next, set the audio device to be the Audio Unit's current device.
   // Note that, devices can only be set to the AUHAL after enabling IO.
   result = AudioUnitSetProperty(audio_unit_,
                                 kAudioOutputUnitProperty_CurrentDevice,
                                 kAudioUnitScope_Global,
                                 0,
                                 &input_device_id_,
                                 sizeof(input_device_id_));
   if (result) {
     HandleError(result);
     return false;
   }

   // Register the input procedure for the AUHAL.
   // This procedure will be called when the AUHAL has received new data
   // from the input device.
   AURenderCallbackStruct callback;
   callback.inputProc = InputProc;
   callback.inputProcRefCon = this;
   result = AudioUnitSetProperty(audio_unit_,
                                 kAudioOutputUnitProperty_SetInputCallback,
                                 kAudioUnitScope_Global,
                                 0,
                                 &callback,
                                 sizeof(callback));
   if (result) {
     HandleError(result);
     return false;
   }

   // Set up the the desired (output) format.
   // For obtaining input from a device, the device format is always expressed
   // on the output scope of the AUHAL's Element 1.
   result = AudioUnitSetProperty(audio_unit_,
                                 kAudioUnitProperty_StreamFormat,
                                 kAudioUnitScope_Output,
                                 1,
                                 &format_,
                                 sizeof(format_));
   if (result) {
     HandleError(result);
     return false;
   }

   // Set the desired number of frames in the IO buffer (output scope).
   // WARNING: Setting this value changes the frame size for all audio units in
   // the current process.  It's imperative that the input and output frame sizes
   // be the same as audio_util::GetAudioHardwareBufferSize().
   // TODO(henrika): Due to http://crrev.com/159666 this is currently not true
   // and should be fixed, a CHECK() should be added at that time.
   result = AudioUnitSetProperty(audio_unit_,
                                 kAudioDevicePropertyBufferFrameSize,
                                 kAudioUnitScope_Output,
                                 1,
                                 &number_of_frames_,  // size is set in the ctor
                                 sizeof(number_of_frames_));
   if (result) {
     HandleError(result);
     return false;
   }

   // Finally, initialize the audio unit and ensure that it is ready to render.
   // Allocates memory according to the maximum number of audio frames
   // it can produce in response to a single render call.
   result = AudioUnitInitialize(audio_unit_);
   if (result) {
     HandleError(result);
     return false;
   }

   // The hardware latency is fixed and will not change during the call.
   hardware_latency_frames_ = GetHardwareLatency();

   // The master channel is 0, Left and right are channels 1 and 2.
   // And the master channel is not counted in |number_of_channels_in_frame_|.
   number_of_channels_in_frame_ = GetNumberOfChannelsFromStream();

   return true;
 }

 void AUAudioInputStream::Start(AudioInputCallback* callback) {
   DCHECK(callback);
   DLOG_IF(ERROR, !audio_unit_) << "Open() has not been called successfully";
   if (started_ || !audio_unit_)
     return;
   sink_ = callback;
   OSStatus result = AudioOutputUnitStart(audio_unit_);
   if (result == noErr) {
     started_ = true;
   }
   OSSTATUS_DLOG_IF(ERROR, result != noErr, result)
       << "Failed to start acquiring data";
 }

 void AUAudioInputStream::Stop() {
   if (!started_)
     return;
   OSStatus result = AudioOutputUnitStop(audio_unit_);
   if (result == noErr) {
     started_ = false;
   }
   OSSTATUS_DLOG_IF(ERROR, result != noErr, result)
       << "Failed to stop acquiring data";
 }

 void AUAudioInputStream::Close() {
   // It is valid to call Close() before calling open or Start().
   // It is also valid to call Close() after Start() has been called.
   if (started_) {
     Stop();
   }
   if (audio_unit_) {
     // Deallocate the audio unit’s resources.
     AudioUnitUninitialize(audio_unit_);

     // Terminates our connection to the AUHAL component.
     CloseComponent(audio_unit_);
     audio_unit_ = 0;
   }
   if (sink_) {
     sink_->OnClose(this);
     sink_ = NULL;
   }

   // Inform the audio manager that we have been closed. This can cause our
   // destruction.
   manager_->ReleaseInputStream(this);
 }

 double AUAudioInputStream::GetMaxVolume() {
   // Verify that we have a valid device.
   if (input_device_id_ == kAudioObjectUnknown) {
     NOTREACHED() << "Device ID is unknown";
     return 0.0;
   }

   // Query if any of the master, left or right channels has volume control.
   for (int i = 0; i <= number_of_channels_in_frame_; ++i) {
     // If the volume is settable, the  valid volume range is [0.0, 1.0].
     if (IsVolumeSettableOnChannel(i))
       return 1.0;
   }

   // Volume control is not available for the audio stream.
   return 0.0;
 }

 void AUAudioInputStream::SetVolume(double volume) {
   DVLOG(1) << "SetVolume(volume=" << volume << ")";
   DCHECK_GE(volume, 0.0);
   DCHECK_LE(volume, 1.0);

   // Verify that we have a valid device.
   if (input_device_id_ == kAudioObjectUnknown) {
     NOTREACHED() << "Device ID is unknown";
     return;
   }

   Float32 volume_float32 = static_cast<Float32>(volume);
   AudioObjectPropertyAddress property_address = {
     kAudioDevicePropertyVolumeScalar,
     kAudioDevicePropertyScopeInput,
     kAudioObjectPropertyElementMaster
   };

   // Try to set the volume for master volume channel.
   if (IsVolumeSettableOnChannel(kAudioObjectPropertyElementMaster)) {
     OSStatus result = AudioObjectSetPropertyData(input_device_id_,
                                                  &property_address,
                                                  0,
                                                  NULL,
                                                  sizeof(volume_float32),
                                                  &volume_float32);
     if (result != noErr) {
       DLOG(WARNING) << "Failed to set volume to " << volume_float32;
     }
     return;
   }

   // There is no master volume control, try to set volume for each channel.
   int successful_channels = 0;
   for (int i = 1; i <= number_of_channels_in_frame_; ++i) {
     property_address.mElement = static_cast<UInt32>(i);
     if (IsVolumeSettableOnChannel(i)) {
       OSStatus result = AudioObjectSetPropertyData(input_device_id_,
                                                    &property_address,
                                                    0,
                                                    NULL,
                                                    sizeof(volume_float32),
                                                    &volume_float32);
       if (result == noErr)
         ++successful_channels;
     }
   }

   DLOG_IF(WARNING, successful_channels == 0)
       << "Failed to set volume to " << volume_float32;

   // Update the AGC volume level based on the last setting above. Note that,
   // the volume-level resolution is not infinite and it is therefore not
   // possible to assume that the volume provided as input parameter can be
   // used directly. Instead, a new query to the audio hardware is required.
   // This method does nothing if AGC is disabled.
   UpdateAgcVolume();
 }

 double AUAudioInputStream::GetVolume() {
   // Verify that we have a valid device.
   if (input_device_id_ == kAudioObjectUnknown){
     NOTREACHED() << "Device ID is unknown";
     return 0.0;
   }

   AudioObjectPropertyAddress property_address = {
     kAudioDevicePropertyVolumeScalar,
     kAudioDevicePropertyScopeInput,
     kAudioObjectPropertyElementMaster
   };

   if (AudioObjectHasProperty(input_device_id_, &property_address)) {
     // The device supports master volume control, get the volume from the
     // master channel.
     Float32 volume_float32 = 0.0;
     UInt32 size = sizeof(volume_float32);
     OSStatus result = AudioObjectGetPropertyData(input_device_id_,
                                                  &property_address,
                                                  0,
                                                  NULL,
                                                  &size,
                                                  &volume_float32);
     if (result == noErr)
       return static_cast<double>(volume_float32);
   } else {
     // There is no master volume control, try to get the average volume of
     // all the channels.
     Float32 volume_float32 = 0.0;
     int successful_channels = 0;
     for (int i = 1; i <= number_of_channels_in_frame_; ++i) {
       property_address.mElement = static_cast<UInt32>(i);
       if (AudioObjectHasProperty(input_device_id_, &property_address)) {
         Float32 channel_volume = 0;
         UInt32 size = sizeof(channel_volume);
         OSStatus result = AudioObjectGetPropertyData(input_device_id_,
                                                      &property_address,
                                                      0,
                                                      NULL,
                                                      &size,
                                                      &channel_volume);
         if (result == noErr) {
           volume_float32 += channel_volume;
           ++successful_channels;
         }
       }
     }

     // Get the average volume of the channels.
     if (successful_channels != 0)
       return static_cast<double>(volume_float32 / successful_channels);
   }

   DLOG(WARNING) << "Failed to get volume";
   return 0.0;
 }

 // AUHAL AudioDeviceOutput unit callback
 OSStatus AUAudioInputStream::InputProc(void* user_data,
                                        AudioUnitRenderActionFlags* flags,
                                        const AudioTimeStamp* time_stamp,
                                        UInt32 bus_number,
                                        UInt32 number_of_frames,
                                        AudioBufferList* io_data) {
   // Verify that the correct bus is used (Input bus/Element 1)
   DCHECK_EQ(bus_number, static_cast<UInt32>(1));
   AUAudioInputStream* audio_input =
       reinterpret_cast<AUAudioInputStream*>(user_data);
   DCHECK(audio_input);
   if (!audio_input)
     return kAudioUnitErr_InvalidElement;

   // Receive audio from the AUHAL from the output scope of the Audio Unit.
   OSStatus result = AudioUnitRender(audio_input->audio_unit(),
                                     flags,
                                     time_stamp,
                                     bus_number,
                                     number_of_frames,
                                     audio_input->audio_buffer_list());
   if (result)
     return result;

   // Deliver recorded data to the consumer as a callback.
   return audio_input->Provide(number_of_frames,
                               audio_input->audio_buffer_list(),
                               time_stamp);
 }

 OSStatus AUAudioInputStream::Provide(UInt32 number_of_frames,
                                      AudioBufferList* io_data,
                                      const AudioTimeStamp* time_stamp) {
   // Update the capture latency.
   double capture_latency_frames = GetCaptureLatency(time_stamp);

   // Update the AGC volume level once every second. Note that, |volume| is
   // also updated each time SetVolume() is called through IPC by the
   // render-side AGC.
   double normalized_volume = 0.0;
   QueryAgcVolume(&normalized_volume);

   AudioBuffer& buffer = io_data->mBuffers[0];
   uint8* audio_data = reinterpret_cast<uint8*>(buffer.mData);
   uint32 capture_delay_bytes = static_cast<uint32>
       ((capture_latency_frames + 0.5) * format_.mBytesPerFrame);
   DCHECK(audio_data);
   if (!audio_data)
     return kAudioUnitErr_InvalidElement;

   // See http://crbug.com/154352 for details.
   CHECK_EQ(number_of_frames, static_cast<UInt32>(number_of_frames_));

   // Accumulate captured audio in FIFO until we can match the output size
   // requested by the client.
   DCHECK_LE(fifo_->forward_bytes(), requested_size_bytes_);
   fifo_->Append(audio_data, buffer.mDataByteSize);

   // Deliver recorded data to the client as soon as the FIFO contains a
   // sufficient amount.
   if (fifo_->forward_bytes() >= requested_size_bytes_) {
     // Read from FIFO into temporary data buffer.
     fifo_->Read(data_->GetWritableData(), requested_size_bytes_);

     // Deliver data packet, delay estimation and volume level to the user.
     sink_->OnData(this,
                   data_->GetData(),
                   requested_size_bytes_,
                   capture_delay_bytes,
                   normalized_volume);
   }

   return noErr;
 }

 int AUAudioInputStream::HardwareSampleRate() {
   // Determine the default input device's sample-rate.
   AudioDeviceID device_id = kAudioObjectUnknown;
   UInt32 info_size = sizeof(device_id);

   AudioObjectPropertyAddress default_input_device_address = {
     kAudioHardwarePropertyDefaultInputDevice,
     kAudioObjectPropertyScopeGlobal,
     kAudioObjectPropertyElementMaster
   };
   OSStatus result = AudioObjectGetPropertyData(kAudioObjectSystemObject,
                                                &default_input_device_address,
                                                0,
                                                0,
                                                &info_size,
                                                &device_id);
   if (result != noErr)
     return 0.0;

   Float64 nominal_sample_rate;
   info_size = sizeof(nominal_sample_rate);

   AudioObjectPropertyAddress nominal_sample_rate_address = {
     kAudioDevicePropertyNominalSampleRate,
     kAudioObjectPropertyScopeGlobal,
     kAudioObjectPropertyElementMaster
   };
   result = AudioObjectGetPropertyData(device_id,
                                       &nominal_sample_rate_address,
                                       0,
                                       0,
                                       &info_size,
                                       &nominal_sample_rate);
   if (result != noErr)
     return 0.0;

   return static_cast<int>(nominal_sample_rate);
 }

 double AUAudioInputStream::GetHardwareLatency() {
   if (!audio_unit_ || input_device_id_ == kAudioObjectUnknown) {
     DLOG(WARNING) << "Audio unit object is NULL or device ID is unknown";
     return 0.0;
   }

   // Get audio unit latency.
   Float64 audio_unit_latency_sec = 0.0;
   UInt32 size = sizeof(audio_unit_latency_sec);
   OSStatus result = AudioUnitGetProperty(audio_unit_,
                                          kAudioUnitProperty_Latency,
                                          kAudioUnitScope_Global,
                                          0,
                                          &audio_unit_latency_sec,
                                          &size);
   OSSTATUS_DLOG_IF(WARNING, result != noErr, result)
       << "Could not get audio unit latency";

   // Get input audio device latency.
   AudioObjectPropertyAddress property_address = {
     kAudioDevicePropertyLatency,
     kAudioDevicePropertyScopeInput,
     kAudioObjectPropertyElementMaster
   };
   UInt32 device_latency_frames = 0;
   size = sizeof(device_latency_frames);
   result = AudioObjectGetPropertyData(input_device_id_,
                                       &property_address,
                                       0,
                                       NULL,
                                       &size,
                                       &device_latency_frames);
   DLOG_IF(WARNING, result != noErr) << "Could not get audio device latency.";

   return static_cast<double>((audio_unit_latency_sec *
       format_.mSampleRate) + device_latency_frames);
 }

 double AUAudioInputStream::GetCaptureLatency(
     const AudioTimeStamp* input_time_stamp) {
   // Get the delay between between the actual recording instant and the time
   // when the data packet is provided as a callback.
   UInt64 capture_time_ns = AudioConvertHostTimeToNanos(
       input_time_stamp->mHostTime);
   UInt64 now_ns = AudioConvertHostTimeToNanos(AudioGetCurrentHostTime());
   double delay_frames = static_cast<double>
       (1e-9 * (now_ns - capture_time_ns) * format_.mSampleRate);

   // Total latency is composed by the dynamic latency and the fixed
   // hardware latency.
   return (delay_frames + hardware_latency_frames_);
 }

 int AUAudioInputStream::GetNumberOfChannelsFromStream() {
   // Get the stream format, to be able to read the number of channels.
   AudioObjectPropertyAddress property_address = {
     kAudioDevicePropertyStreamFormat,
     kAudioDevicePropertyScopeInput,
     kAudioObjectPropertyElementMaster
   };
   AudioStreamBasicDescription stream_format;
   UInt32 size = sizeof(stream_format);
   OSStatus result = AudioObjectGetPropertyData(input_device_id_,
                                                &property_address,
                                                0,
                                                NULL,
                                                &size,
                                                &stream_format);
   if (result != noErr) {
     DLOG(WARNING) << "Could not get stream format";
     return 0;
   }

   return static_cast<int>(stream_format.mChannelsPerFrame);
 }

 void AUAudioInputStream::HandleError(OSStatus err) {
   NOTREACHED() << "error " << GetMacOSStatusErrorString(err)
                << " (" << err << ")";
   if (sink_)
     sink_->OnError(this, static_cast<int>(err));
 }

 bool AUAudioInputStream::IsVolumeSettableOnChannel(int channel) {
   Boolean is_settable = false;
   AudioObjectPropertyAddress property_address = {
     kAudioDevicePropertyVolumeScalar,
     kAudioDevicePropertyScopeInput,
     static_cast<UInt32>(channel)
   };
   OSStatus result = AudioObjectIsPropertySettable(input_device_id_,
                                                   &property_address,
                                                   &is_settable);
   return (result == noErr) ? is_settable : false;
 }

 }  // 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/mac/audio_low_latency_input_mac.h"

	#include <CoreServices/CoreServices.h>

	#include "base/basictypes.h"
	#include "base/logging.h"
	#include "base/mac/mac_logging.h"
	#include "media/audio/audio_util.h"
	#include "media/audio/mac/audio_manager_mac.h"
	#include "media/base/data_buffer.h"

	namespace media {

	static const int kMinIntervalBetweenVolumeUpdatesMs = 1000;

	static std::ostream& operator<<(std::ostream& os,
	const AudioStreamBasicDescription& format) {
	os << "sample rate : " << format.mSampleRate << std::endl
	<< "format ID : " << format.mFormatID << std::endl
	<< "format flags : " << format.mFormatFlags << std::endl
	<< "bytes per packet : " << format.mBytesPerPacket << std::endl
	<< "frames per packet : " << format.mFramesPerPacket << std::endl
	<< "bytes per frame : " << format.mBytesPerFrame << std::endl
	<< "channels per frame: " << format.mChannelsPerFrame << std::endl
	<< "bits per channel : " << format.mBitsPerChannel;
	return os;
	}

	// See "Technical Note TN2091 - Device input using the HAL Output Audio Unit"
	// http://developer.apple.com/library/mac/#technotes/tn2091/_index.html
	// for more details and background regarding this implementation.

	AUAudioInputStream::AUAudioInputStream(
	AudioManagerMac* manager, const AudioParameters& params,
	AudioDeviceID audio_device_id)
	: manager_(manager),
	sink_(NULL),
	audio_unit_(0),
	input_device_id_(audio_device_id),
	started_(false),
	hardware_latency_frames_(0),
	number_of_channels_in_frame_(0) {
	DCHECK(manager_);

	// Set up the desired (output) format specified by the client.
	format_.mSampleRate = params.sample_rate();
	format_.mFormatID = kAudioFormatLinearPCM;
	format_.mFormatFlags = kLinearPCMFormatFlagIsPacked \|
	kLinearPCMFormatFlagIsSignedInteger;
	format_.mBitsPerChannel = params.bits_per_sample();
	format_.mChannelsPerFrame = params.channels();
	format_.mFramesPerPacket = 1; // uncompressed audio
	format_.mBytesPerPacket = (format_.mBitsPerChannel *
	params.channels()) / 8;
	format_.mBytesPerFrame = format_.mBytesPerPacket;
	format_.mReserved = 0;

	DVLOG(1) << "Desired ouput format: " << format_;

	// Set number of sample frames per callback used by the internal audio layer.
	// An internal FIFO is then utilized to adapt the internal size to the size
	// requested by the client.
	// Note that we use the same native buffer size as for the output side here
	// since the AUHAL implementation requires that both capture and render side
	// use the same buffer size. See http://crbug.com/154352 for more details.
	number_of_frames_ = GetAudioHardwareBufferSize();
	DVLOG(1) << "Size of data buffer in frames : " << number_of_frames_;

	// Derive size (in bytes) of the buffers that we will render to.
	UInt32 data_byte_size = number_of_frames_ * format_.mBytesPerFrame;
	DVLOG(1) << "Size of data buffer in bytes : " << data_byte_size;

	// Allocate AudioBuffers to be used as storage for the received audio.
	// The AudioBufferList structure works as a placeholder for the
	// AudioBuffer structure, which holds a pointer to the actual data buffer.
	audio_data_buffer_.reset(new uint8[data_byte_size]);
	audio_buffer_list_.mNumberBuffers = 1;

	AudioBuffer* audio_buffer = audio_buffer_list_.mBuffers;
	audio_buffer->mNumberChannels = params.channels();
	audio_buffer->mDataByteSize = data_byte_size;
	audio_buffer->mData = audio_data_buffer_.get();

	// Set up an internal FIFO buffer that will accumulate recorded audio frames
	// until a requested size is ready to be sent to the client.
	// It is not possible to ask for less than \|kAudioFramesPerCallback\| number of
	// audio frames.
	const size_t requested_size_frames =
	params.GetBytesPerBuffer() / format_.mBytesPerPacket;
	DCHECK_GE(requested_size_frames, number_of_frames_);
	requested_size_bytes_ = requested_size_frames * format_.mBytesPerFrame;
	DVLOG(1) << "Requested buffer size in bytes : " << requested_size_bytes_;
	DLOG_IF(INFO, requested_size_frames > number_of_frames_) << "FIFO is used";

	// Allocate some extra memory to avoid memory reallocations.
	// Ensure that the size is an even multiple of \|number_of_frames_ and
	// larger than \|requested_size_frames\|.
	// Example: number_of_frames_=128, requested_size_frames=480 =>
	// allocated space equals 4*128=512 audio frames
	const int max_forward_capacity = format_.mBytesPerFrame * number_of_frames_ *
	((requested_size_frames / number_of_frames_) + 1);
	fifo_.reset(new media::SeekableBuffer(0, max_forward_capacity));

	data_ = new media::DataBuffer(requested_size_bytes_);
	}

	AUAudioInputStream::~AUAudioInputStream() {}

	// Obtain and open the AUHAL AudioOutputUnit for recording.
	bool AUAudioInputStream::Open() {
	// Verify that we are not already opened.
	if (audio_unit_)
	return false;

	// Verify that we have a valid device.
	if (input_device_id_ == kAudioObjectUnknown) {
	NOTREACHED() << "Device ID is unknown";
	return false;
	}

	// Start by obtaining an AudioOuputUnit using an AUHAL component description.

	Component comp;
	ComponentDescription desc;

	// Description for the Audio Unit we want to use (AUHAL in this case).
	desc.componentType = kAudioUnitType_Output;
	desc.componentSubType = kAudioUnitSubType_HALOutput;
	desc.componentManufacturer = kAudioUnitManufacturer_Apple;
	desc.componentFlags = 0;
	desc.componentFlagsMask = 0;
	comp = FindNextComponent(0, &desc);
	DCHECK(comp);

	// Get access to the service provided by the specified Audio Unit.
	OSStatus result = OpenAComponent(comp, &audio_unit_);
	if (result) {
	HandleError(result);
	return false;
	}

	// Enable IO on the input scope of the Audio Unit.

	// After creating the AUHAL object, we must enable IO on the input scope
	// of the Audio Unit to obtain the device input. Input must be explicitly
	// enabled with the kAudioOutputUnitProperty_EnableIO property on Element 1
	// of the AUHAL. Beacause the AUHAL can be used for both input and output,
	// we must also disable IO on the output scope.

	UInt32 enableIO = 1;

	// Enable input on the AUHAL.
	result = AudioUnitSetProperty(audio_unit_,
	kAudioOutputUnitProperty_EnableIO,
	kAudioUnitScope_Input,
	1, // input element 1
	&enableIO, // enable
	sizeof(enableIO));
	if (result) {
	HandleError(result);
	return false;
	}

	// Disable output on the AUHAL.
	enableIO = 0;
	result = AudioUnitSetProperty(audio_unit_,
	kAudioOutputUnitProperty_EnableIO,
	kAudioUnitScope_Output,
	0, // output element 0
	&enableIO, // disable
	sizeof(enableIO));
	if (result) {
	HandleError(result);
	return false;
	}

	// Next, set the audio device to be the Audio Unit's current device.
	// Note that, devices can only be set to the AUHAL after enabling IO.
	result = AudioUnitSetProperty(audio_unit_,
	kAudioOutputUnitProperty_CurrentDevice,
	kAudioUnitScope_Global,
	0,
	&input_device_id_,
	sizeof(input_device_id_));
	if (result) {
	HandleError(result);
	return false;
	}

	// Register the input procedure for the AUHAL.
	// This procedure will be called when the AUHAL has received new data
	// from the input device.
	AURenderCallbackStruct callback;
	callback.inputProc = InputProc;
	callback.inputProcRefCon = this;
	result = AudioUnitSetProperty(audio_unit_,
	kAudioOutputUnitProperty_SetInputCallback,
	kAudioUnitScope_Global,
	0,
	&callback,
	sizeof(callback));
	if (result) {
	HandleError(result);
	return false;
	}

	// Set up the the desired (output) format.
	// For obtaining input from a device, the device format is always expressed
	// on the output scope of the AUHAL's Element 1.
	result = AudioUnitSetProperty(audio_unit_,
	kAudioUnitProperty_StreamFormat,
	kAudioUnitScope_Output,
	1,
	&format_,
	sizeof(format_));
	if (result) {
	HandleError(result);
	return false;
	}

	// Set the desired number of frames in the IO buffer (output scope).
	// WARNING: Setting this value changes the frame size for all audio units in
	// the current process. It's imperative that the input and output frame sizes
	// be the same as audio_util::GetAudioHardwareBufferSize().
	// TODO(henrika): Due to http://crrev.com/159666 this is currently not true
	// and should be fixed, a CHECK() should be added at that time.
	result = AudioUnitSetProperty(audio_unit_,
	kAudioDevicePropertyBufferFrameSize,
	kAudioUnitScope_Output,
	1,
	&number_of_frames_, // size is set in the ctor
	sizeof(number_of_frames_));
	if (result) {
	HandleError(result);
	return false;
	}

	// Finally, initialize the audio unit and ensure that it is ready to render.
	// Allocates memory according to the maximum number of audio frames
	// it can produce in response to a single render call.
	result = AudioUnitInitialize(audio_unit_);
	if (result) {
	HandleError(result);
	return false;
	}

	// The hardware latency is fixed and will not change during the call.
	hardware_latency_frames_ = GetHardwareLatency();

	// The master channel is 0, Left and right are channels 1 and 2.
	// And the master channel is not counted in \|number_of_channels_in_frame_\|.
	number_of_channels_in_frame_ = GetNumberOfChannelsFromStream();

	return true;
	}

	void AUAudioInputStream::Start(AudioInputCallback* callback) {
	DCHECK(callback);
	DLOG_IF(ERROR, !audio_unit_) << "Open() has not been called successfully";
	if (started_ \|\| !audio_unit_)
	return;
	sink_ = callback;
	OSStatus result = AudioOutputUnitStart(audio_unit_);
	if (result == noErr) {
	started_ = true;
	}
	OSSTATUS_DLOG_IF(ERROR, result != noErr, result)
	<< "Failed to start acquiring data";
	}

	void AUAudioInputStream::Stop() {
	if (!started_)
	return;
	OSStatus result = AudioOutputUnitStop(audio_unit_);
	if (result == noErr) {
	started_ = false;
	}
	OSSTATUS_DLOG_IF(ERROR, result != noErr, result)
	<< "Failed to stop acquiring data";
	}

	void AUAudioInputStream::Close() {
	// It is valid to call Close() before calling open or Start().
	// It is also valid to call Close() after Start() has been called.
	if (started_) {
	Stop();
	}
	if (audio_unit_) {
	// Deallocate the audio unit’s resources.
	AudioUnitUninitialize(audio_unit_);

	// Terminates our connection to the AUHAL component.
	CloseComponent(audio_unit_);
	audio_unit_ = 0;
	}
	if (sink_) {
	sink_->OnClose(this);
	sink_ = NULL;
	}

	// Inform the audio manager that we have been closed. This can cause our
	// destruction.
	manager_->ReleaseInputStream(this);
	}

	double AUAudioInputStream::GetMaxVolume() {
	// Verify that we have a valid device.
	if (input_device_id_ == kAudioObjectUnknown) {
	NOTREACHED() << "Device ID is unknown";
	return 0.0;
	}

	// Query if any of the master, left or right channels has volume control.
	for (int i = 0; i <= number_of_channels_in_frame_; ++i) {
	// If the volume is settable, the valid volume range is [0.0, 1.0].
	if (IsVolumeSettableOnChannel(i))
	return 1.0;
	}

	// Volume control is not available for the audio stream.
	return 0.0;
	}

	void AUAudioInputStream::SetVolume(double volume) {
	DVLOG(1) << "SetVolume(volume=" << volume << ")";
	DCHECK_GE(volume, 0.0);
	DCHECK_LE(volume, 1.0);

	// Verify that we have a valid device.
	if (input_device_id_ == kAudioObjectUnknown) {
	NOTREACHED() << "Device ID is unknown";
	return;
	}

	Float32 volume_float32 = static_cast<Float32>(volume);
	AudioObjectPropertyAddress property_address = {
	kAudioDevicePropertyVolumeScalar,
	kAudioDevicePropertyScopeInput,
	kAudioObjectPropertyElementMaster
	};

	// Try to set the volume for master volume channel.
	if (IsVolumeSettableOnChannel(kAudioObjectPropertyElementMaster)) {
	OSStatus result = AudioObjectSetPropertyData(input_device_id_,
	&property_address,
	0,
	NULL,
	sizeof(volume_float32),
	&volume_float32);
	if (result != noErr) {
	DLOG(WARNING) << "Failed to set volume to " << volume_float32;
	}
	return;
	}

	// There is no master volume control, try to set volume for each channel.
	int successful_channels = 0;
	for (int i = 1; i <= number_of_channels_in_frame_; ++i) {
	property_address.mElement = static_cast<UInt32>(i);
	if (IsVolumeSettableOnChannel(i)) {
	OSStatus result = AudioObjectSetPropertyData(input_device_id_,
	&property_address,
	0,
	NULL,
	sizeof(volume_float32),
	&volume_float32);
	if (result == noErr)
	++successful_channels;
	}
	}

	DLOG_IF(WARNING, successful_channels == 0)
	<< "Failed to set volume to " << volume_float32;

	// Update the AGC volume level based on the last setting above. Note that,
	// the volume-level resolution is not infinite and it is therefore not
	// possible to assume that the volume provided as input parameter can be
	// used directly. Instead, a new query to the audio hardware is required.
	// This method does nothing if AGC is disabled.
	UpdateAgcVolume();
	}

	double AUAudioInputStream::GetVolume() {
	// Verify that we have a valid device.
	if (input_device_id_ == kAudioObjectUnknown){
	NOTREACHED() << "Device ID is unknown";
	return 0.0;
	}

	AudioObjectPropertyAddress property_address = {
	kAudioDevicePropertyVolumeScalar,
	kAudioDevicePropertyScopeInput,
	kAudioObjectPropertyElementMaster
	};

	if (AudioObjectHasProperty(input_device_id_, &property_address)) {
	// The device supports master volume control, get the volume from the
	// master channel.
	Float32 volume_float32 = 0.0;
	UInt32 size = sizeof(volume_float32);
	OSStatus result = AudioObjectGetPropertyData(input_device_id_,
	&property_address,
	0,
	NULL,
	&size,
	&volume_float32);
	if (result == noErr)
	return static_cast<double>(volume_float32);
	} else {
	// There is no master volume control, try to get the average volume of
	// all the channels.
	Float32 volume_float32 = 0.0;
	int successful_channels = 0;
	for (int i = 1; i <= number_of_channels_in_frame_; ++i) {
	property_address.mElement = static_cast<UInt32>(i);
	if (AudioObjectHasProperty(input_device_id_, &property_address)) {
	Float32 channel_volume = 0;
	UInt32 size = sizeof(channel_volume);
	OSStatus result = AudioObjectGetPropertyData(input_device_id_,
	&property_address,
	0,
	NULL,
	&size,
	&channel_volume);
	if (result == noErr) {
	volume_float32 += channel_volume;
	++successful_channels;
	}
	}
	}

	// Get the average volume of the channels.
	if (successful_channels != 0)
	return static_cast<double>(volume_float32 / successful_channels);
	}

	DLOG(WARNING) << "Failed to get volume";
	return 0.0;
	}

	// AUHAL AudioDeviceOutput unit callback
	OSStatus AUAudioInputStream::InputProc(void* user_data,
	AudioUnitRenderActionFlags* flags,
	const AudioTimeStamp* time_stamp,
	UInt32 bus_number,
	UInt32 number_of_frames,
	AudioBufferList* io_data) {
	// Verify that the correct bus is used (Input bus/Element 1)
	DCHECK_EQ(bus_number, static_cast<UInt32>(1));
	AUAudioInputStream* audio_input =
	reinterpret_cast<AUAudioInputStream*>(user_data);
	DCHECK(audio_input);
	if (!audio_input)
	return kAudioUnitErr_InvalidElement;

	// Receive audio from the AUHAL from the output scope of the Audio Unit.
	OSStatus result = AudioUnitRender(audio_input->audio_unit(),
	flags,
	time_stamp,
	bus_number,
	number_of_frames,
	audio_input->audio_buffer_list());
	if (result)
	return result;

	// Deliver recorded data to the consumer as a callback.
	return audio_input->Provide(number_of_frames,
	audio_input->audio_buffer_list(),
	time_stamp);
	}

	OSStatus AUAudioInputStream::Provide(UInt32 number_of_frames,
	AudioBufferList* io_data,
	const AudioTimeStamp* time_stamp) {
	// Update the capture latency.
	double capture_latency_frames = GetCaptureLatency(time_stamp);

	// Update the AGC volume level once every second. Note that, \|volume\| is
	// also updated each time SetVolume() is called through IPC by the
	// render-side AGC.
	double normalized_volume = 0.0;
	QueryAgcVolume(&normalized_volume);

	AudioBuffer& buffer = io_data->mBuffers[0];
	uint8* audio_data = reinterpret_cast<uint8*>(buffer.mData);
	uint32 capture_delay_bytes = static_cast<uint32>
	((capture_latency_frames + 0.5) * format_.mBytesPerFrame);
	DCHECK(audio_data);
	if (!audio_data)
	return kAudioUnitErr_InvalidElement;

	// See http://crbug.com/154352 for details.
	CHECK_EQ(number_of_frames, static_cast<UInt32>(number_of_frames_));

	// Accumulate captured audio in FIFO until we can match the output size
	// requested by the client.
	DCHECK_LE(fifo_->forward_bytes(), requested_size_bytes_);
	fifo_->Append(audio_data, buffer.mDataByteSize);

	// Deliver recorded data to the client as soon as the FIFO contains a
	// sufficient amount.
	if (fifo_->forward_bytes() >= requested_size_bytes_) {
	// Read from FIFO into temporary data buffer.
	fifo_->Read(data_->GetWritableData(), requested_size_bytes_);

	// Deliver data packet, delay estimation and volume level to the user.
	sink_->OnData(this,
	data_->GetData(),
	requested_size_bytes_,
	capture_delay_bytes,
	normalized_volume);
	}

	return noErr;
	}

	int AUAudioInputStream::HardwareSampleRate() {
	// Determine the default input device's sample-rate.
	AudioDeviceID device_id = kAudioObjectUnknown;
	UInt32 info_size = sizeof(device_id);

	AudioObjectPropertyAddress default_input_device_address = {
	kAudioHardwarePropertyDefaultInputDevice,
	kAudioObjectPropertyScopeGlobal,
	kAudioObjectPropertyElementMaster
	};
	OSStatus result = AudioObjectGetPropertyData(kAudioObjectSystemObject,
	&default_input_device_address,
	0,
	0,
	&info_size,
	&device_id);
	if (result != noErr)
	return 0.0;

	Float64 nominal_sample_rate;
	info_size = sizeof(nominal_sample_rate);

	AudioObjectPropertyAddress nominal_sample_rate_address = {
	kAudioDevicePropertyNominalSampleRate,
	kAudioObjectPropertyScopeGlobal,
	kAudioObjectPropertyElementMaster
	};
	result = AudioObjectGetPropertyData(device_id,
	&nominal_sample_rate_address,
	0,
	0,
	&info_size,
	&nominal_sample_rate);
	if (result != noErr)
	return 0.0;

	return static_cast<int>(nominal_sample_rate);
	}

	double AUAudioInputStream::GetHardwareLatency() {
	if (!audio_unit_ \|\| input_device_id_ == kAudioObjectUnknown) {
	DLOG(WARNING) << "Audio unit object is NULL or device ID is unknown";
	return 0.0;
	}

	// Get audio unit latency.
	Float64 audio_unit_latency_sec = 0.0;
	UInt32 size = sizeof(audio_unit_latency_sec);
	OSStatus result = AudioUnitGetProperty(audio_unit_,
	kAudioUnitProperty_Latency,
	kAudioUnitScope_Global,
	0,
	&audio_unit_latency_sec,
	&size);
	OSSTATUS_DLOG_IF(WARNING, result != noErr, result)
	<< "Could not get audio unit latency";

	// Get input audio device latency.
	AudioObjectPropertyAddress property_address = {
	kAudioDevicePropertyLatency,
	kAudioDevicePropertyScopeInput,
	kAudioObjectPropertyElementMaster
	};
	UInt32 device_latency_frames = 0;
	size = sizeof(device_latency_frames);
	result = AudioObjectGetPropertyData(input_device_id_,
	&property_address,
	0,
	NULL,
	&size,
	&device_latency_frames);
	DLOG_IF(WARNING, result != noErr) << "Could not get audio device latency.";

	return static_cast<double>((audio_unit_latency_sec *
	format_.mSampleRate) + device_latency_frames);
	}

	double AUAudioInputStream::GetCaptureLatency(
	const AudioTimeStamp* input_time_stamp) {
	// Get the delay between between the actual recording instant and the time
	// when the data packet is provided as a callback.
	UInt64 capture_time_ns = AudioConvertHostTimeToNanos(
	input_time_stamp->mHostTime);
	UInt64 now_ns = AudioConvertHostTimeToNanos(AudioGetCurrentHostTime());
	double delay_frames = static_cast<double>
	(1e-9 * (now_ns - capture_time_ns) * format_.mSampleRate);

	// Total latency is composed by the dynamic latency and the fixed
	// hardware latency.
	return (delay_frames + hardware_latency_frames_);
	}

	int AUAudioInputStream::GetNumberOfChannelsFromStream() {
	// Get the stream format, to be able to read the number of channels.
	AudioObjectPropertyAddress property_address = {
	kAudioDevicePropertyStreamFormat,
	kAudioDevicePropertyScopeInput,
	kAudioObjectPropertyElementMaster
	};
	AudioStreamBasicDescription stream_format;
	UInt32 size = sizeof(stream_format);
	OSStatus result = AudioObjectGetPropertyData(input_device_id_,
	&property_address,
	0,
	NULL,
	&size,
	&stream_format);
	if (result != noErr) {
	DLOG(WARNING) << "Could not get stream format";
	return 0;
	}

	return static_cast<int>(stream_format.mChannelsPerFrame);
	}

	void AUAudioInputStream::HandleError(OSStatus err) {
	NOTREACHED() << "error " << GetMacOSStatusErrorString(err)
	<< " (" << err << ")";
	if (sink_)
	sink_->OnError(this, static_cast<int>(err));
	}

	bool AUAudioInputStream::IsVolumeSettableOnChannel(int channel) {
	Boolean is_settable = false;
	AudioObjectPropertyAddress property_address = {
	kAudioDevicePropertyVolumeScalar,
	kAudioDevicePropertyScopeInput,
	static_cast<UInt32>(channel)
	};
	OSStatus result = AudioObjectIsPropertySettable(input_device_id_,
	&property_address,
	&is_settable);
	return (result == noErr) ? is_settable : false;
	}

	} // namespace media