/* -*- c++ -*- */ /* * Copyright 2006-2011 Free Software Foundation, Inc. * * This file is part of GNU Radio. * * GNU Radio is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3, or (at your option) * any later version. * * GNU Radio is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GNU Radio; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, * Boston, MA 02110-1301, USA. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "gr_audio_registry.h" #include #include #include #include #define _OSX_AU_DEBUG_ 0 AUDIO_REGISTER_SINK(REG_PRIO_HIGH, osx)( int sampling_rate, const std::string &device_name, bool ok_to_block ){ return audio_sink::sptr(new audio_osx_sink(sampling_rate, device_name, ok_to_block)); } audio_osx_sink::audio_osx_sink (int sample_rate, const std::string device_name, bool do_block, int channel_config, int max_sample_count) : audio_sink ("audio_osx_sink", gr_make_io_signature (0, 0, 0), gr_make_io_signature (0, 0, 0)), d_sample_rate (0.0), d_channel_config (0), d_n_channels (0), d_queueSampleCount (0), d_max_sample_count (0), d_do_block (do_block), d_internal (0), d_cond_data (0), d_OutputAU (0) { if (sample_rate <= 0) { std::cerr << "Invalid Sample Rate: " << sample_rate << std::endl; throw std::invalid_argument ("audio_osx_sink::audio_osx_sink"); } else d_sample_rate = (Float64) sample_rate; if (channel_config <= 0 & channel_config != -1) { std::cerr << "Invalid Channel Config: " << channel_config << std::endl; throw std::invalid_argument ("audio_osx_sink::audio_osx_sink"); } else if (channel_config == -1) { // no user input; try "device name" instead int l_n_channels = (int) strtol (device_name.data(), (char **)NULL, 10); if (l_n_channels == 0 & errno) { std::cerr << "Error Converting Device Name: " << errno << std::endl; throw std::invalid_argument ("audio_osx_sink::audio_osx_sink"); } if (l_n_channels <= 0) channel_config = 2; else channel_config = l_n_channels; } d_n_channels = d_channel_config = channel_config; // set the input signature set_input_signature (gr_make_io_signature (1, d_n_channels, sizeof (float))); // check that the max # of samples to store is valid if (max_sample_count == -1) max_sample_count = sample_rate; else if (max_sample_count <= 0) { std::cerr << "Invalid Max Sample Count: " << max_sample_count << std::endl; throw std::invalid_argument ("audio_osx_sink::audio_osx_sink"); } d_max_sample_count = max_sample_count; // allocate the output circular buffer(s), one per channel d_buffers = (circular_buffer**) new circular_buffer* [d_n_channels]; UInt32 n_alloc = (UInt32) ceil ((double) d_max_sample_count); for (UInt32 n = 0; n < d_n_channels; n++) { d_buffers[n] = new circular_buffer (n_alloc, false, false); } // create the default AudioUnit for output OSStatus err = noErr; // Open the default output unit #ifndef GR_USE_OLD_AUDIO_UNIT AudioComponentDescription desc; #else ComponentDescription desc; #endif desc.componentType = kAudioUnitType_Output; desc.componentSubType = kAudioUnitSubType_DefaultOutput; desc.componentManufacturer = kAudioUnitManufacturer_Apple; desc.componentFlags = 0; desc.componentFlagsMask = 0; #ifndef GR_USE_OLD_AUDIO_UNIT AudioComponent comp = AudioComponentFindNext(NULL, &desc); if (comp == NULL) { std::cerr << "AudioComponentFindNext Error" << std::endl; throw std::runtime_error ("audio_osx_sink::audio_osx_sink"); } #else Component comp = FindNextComponent (NULL, &desc); if (comp == NULL) { std::cerr << "FindNextComponent Error" << std::endl; throw std::runtime_error ("audio_osx_sink::audio_osx_sink"); } #endif #ifndef GR_USE_OLD_AUDIO_UNIT err = AudioComponentInstanceNew (comp, &d_OutputAU); CheckErrorAndThrow (err, "AudioComponentInstanceNew", "audio_osx_sink::audio_osx_sink"); #else err = OpenAComponent (comp, &d_OutputAU); CheckErrorAndThrow (err, "OpenAComponent", "audio_osx_sink::audio_osx_sink"); #endif // Set up a callback function to generate output to the output unit AURenderCallbackStruct input; input.inputProc = (AURenderCallback)(audio_osx_sink::AUOutputCallback); input.inputProcRefCon = this; err = AudioUnitSetProperty (d_OutputAU, kAudioUnitProperty_SetRenderCallback, kAudioUnitScope_Input, 0, &input, sizeof (input)); CheckErrorAndThrow (err, "AudioUnitSetProperty Render Callback", "audio_osx_sink::audio_osx_sink"); // tell the Output Unit what format data will be supplied to it // so that it handles any format conversions AudioStreamBasicDescription streamFormat; streamFormat.mSampleRate = (Float64)(sample_rate); streamFormat.mFormatID = kAudioFormatLinearPCM; streamFormat.mFormatFlags = (kLinearPCMFormatFlagIsFloat | GR_PCM_ENDIANNESS | kLinearPCMFormatFlagIsPacked | kAudioFormatFlagIsNonInterleaved); streamFormat.mBytesPerPacket = 4; streamFormat.mFramesPerPacket = 1; streamFormat.mBytesPerFrame = 4; streamFormat.mChannelsPerFrame = d_n_channels; streamFormat.mBitsPerChannel = 32; err = AudioUnitSetProperty (d_OutputAU, kAudioUnitProperty_StreamFormat, kAudioUnitScope_Input, 0, &streamFormat, sizeof (AudioStreamBasicDescription)); CheckErrorAndThrow (err, "AudioUnitSetProperty StreamFormat", "audio_osx_sink::audio_osx_sink"); // create the stuff to regulate I/O d_cond_data = new gruel::condition_variable (); if (d_cond_data == NULL) CheckErrorAndThrow (errno, "new condition (data)", "audio_osx_sink::audio_osx_sink"); d_internal = new gruel::mutex (); if (d_internal == NULL) CheckErrorAndThrow (errno, "new mutex (internal)", "audio_osx_sink::audio_osx_sink"); // initialize the AU for output err = AudioUnitInitialize (d_OutputAU); CheckErrorAndThrow (err, "AudioUnitInitialize", "audio_osx_sink::audio_osx_sink"); #if _OSX_AU_DEBUG_ std::cerr << "audio_osx_sink Parameters:" << std::endl; std::cerr << " Sample Rate is " << d_sample_rate << std::endl; std::cerr << " Number of Channels is " << d_n_channels << std::endl; std::cerr << " Max # samples to store per channel is " << d_max_sample_count << std::endl; #endif } bool audio_osx_sink::IsRunning () { UInt32 AURunning = 0, AUSize = sizeof (UInt32); OSStatus err = AudioUnitGetProperty (d_OutputAU, kAudioOutputUnitProperty_IsRunning, kAudioUnitScope_Global, 0, &AURunning, &AUSize); CheckErrorAndThrow (err, "AudioUnitGetProperty IsRunning", "audio_osx_sink::IsRunning"); return (AURunning); } bool audio_osx_sink::start () { if (! IsRunning ()) { OSStatus err = AudioOutputUnitStart (d_OutputAU); CheckErrorAndThrow (err, "AudioOutputUnitStart", "audio_osx_sink::start"); } return (true); } bool audio_osx_sink::stop () { if (IsRunning ()) { OSStatus err = AudioOutputUnitStop (d_OutputAU); CheckErrorAndThrow (err, "AudioOutputUnitStop", "audio_osx_sink::stop"); for (UInt32 n = 0; n < d_n_channels; n++) { d_buffers[n]->abort (); } } return (true); } audio_osx_sink::~audio_osx_sink () { // stop and close the AudioUnit stop (); AudioUnitUninitialize (d_OutputAU); #ifndef GR_USE_OLD_AUDIO_UNIT AudioComponentInstanceDispose (d_OutputAU); #else CloseComponent (d_OutputAU); #endif // empty and delete the queues for (UInt32 n = 0; n < d_n_channels; n++) { delete d_buffers[n]; d_buffers[n] = 0; } delete [] d_buffers; d_buffers = 0; // close and delete control stuff delete d_cond_data; d_cond_data = 0; delete d_internal; d_internal = 0; } int audio_osx_sink::work (int noutput_items, gr_vector_const_void_star &input_items, gr_vector_void_star &output_items) { gruel::scoped_lock l (*d_internal); /* take the input data, copy it, and push it to the bottom of the queue mono input are pushed onto queue[0]; stereo input are pushed onto queue[1]. Start the AudioUnit if necessary. */ UInt32 l_max_count; int diff_count = d_max_sample_count - noutput_items; if (diff_count < 0) l_max_count = 0; else l_max_count = (UInt32) diff_count; #if 0 if (l_max_count < d_queueItemLength->back()) { // allow 2 buffers at a time, regardless of length l_max_count = d_queueItemLength->back(); } #endif #if _OSX_AU_DEBUG_ std::cerr << "work1: qSC = " << d_queueSampleCount << ", lMC = "<< l_max_count << ", dmSC = " << d_max_sample_count << ", nOI = " << noutput_items << std::endl; #endif if (d_queueSampleCount > l_max_count) { // data coming in too fast; do_block decides what to do if (d_do_block == true) { // block until there is data to return while (d_queueSampleCount > l_max_count) { // release control so-as to allow data to be retrieved; // block until there is data to return d_cond_data->wait (l); // the condition's 'notify' was called; acquire control // to keep thread safe } } } // not blocking case and overflow is handled by the circular buffer // add the input frames to the buffers' queue, checking for overflow UInt32 l_counter; int res = 0; float* inBuffer = (float*) input_items[0]; const UInt32 l_size = input_items.size(); for (l_counter = 0; l_counter < l_size; l_counter++) { inBuffer = (float*) input_items[l_counter]; int l_res = d_buffers[l_counter]->enqueue (inBuffer, noutput_items); if (l_res == -1) res = -1; } while (l_counter < d_n_channels) { // for extra channels, copy the last input's data int l_res = d_buffers[l_counter++]->enqueue (inBuffer, noutput_items); if (l_res == -1) res = -1; } if (res == -1) { // data coming in too fast // drop oldest buffer fputs ("aO", stderr); fflush (stderr); // set the local number of samples available to the max d_queueSampleCount = d_buffers[0]->buffer_length_items (); } else { // keep up the local sample count d_queueSampleCount += noutput_items; } #if _OSX_AU_DEBUG_ std::cerr << "work2: #OI = " << noutput_items << ", #Cnt = " << d_queueSampleCount << ", mSC = " << d_max_sample_count << std::endl; #endif return (noutput_items); } OSStatus audio_osx_sink::AUOutputCallback (void *inRefCon, AudioUnitRenderActionFlags *ioActionFlags, const AudioTimeStamp *inTimeStamp, UInt32 inBusNumber, UInt32 inNumberFrames, AudioBufferList *ioData) { audio_osx_sink* This = (audio_osx_sink*) inRefCon; OSStatus err = noErr; gruel::scoped_lock l (*This->d_internal); #if _OSX_AU_DEBUG_ std::cerr << "cb_in: SC = " << This->d_queueSampleCount << ", in#F = " << inNumberFrames << std::endl; #endif if (This->d_queueSampleCount < inNumberFrames) { // not enough data to fill request err = -1; } else { // enough data; remove data from our buffers into the AU's buffers int l_counter = This->d_n_channels; while (--l_counter >= 0) { size_t t_n_output_items = inNumberFrames; float* outBuffer = (float*) ioData->mBuffers[l_counter].mData; This->d_buffers[l_counter]->dequeue (outBuffer, &t_n_output_items); if (t_n_output_items != inNumberFrames) { throw std::runtime_error ("audio_osx_sink::AUOutputCallback(): " "number of available items changing " "unexpectedly.\n"); } } This->d_queueSampleCount -= inNumberFrames; } #if _OSX_AU_DEBUG_ std::cerr << "cb_out: SC = " << This->d_queueSampleCount << std::endl; #endif // signal that data is available This->d_cond_data->notify_one (); return (err); }