/* -*- c++ -*- */ /* * Copyright 2006 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 he 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 #include #include #include #include #include #include #include #include #define LOGGING 0 // define to 0 or 1 #define SAMPLE_FORMAT paFloat32 typedef float sample_t; // Number of portaudio buffers in the ringbuffer static const unsigned int N_BUFFERS = 4; static std::string default_device_name () { return gr_prefs::singleton()->get_string("audio_portaudio", "default_input_device", ""); } void audio_portaudio_source::create_ringbuffer(void) { int bufsize_samples = d_portaudio_buffer_size_frames * d_input_parameters.channelCount; if (d_verbose) fprintf(stderr, "ring buffer size = %d frames\n", N_BUFFERS*bufsize_samples/d_input_parameters.channelCount); // FYI, the buffer indicies are in units of samples. d_writer = gr_make_buffer(N_BUFFERS * bufsize_samples, sizeof(sample_t)); d_reader = gr_buffer_add_reader(d_writer, 0); } /* * This routine will be called by the PortAudio engine when audio is needed. * It may called at interrupt level on some machines so don't do anything * that could mess up the system like calling malloc() or free(). * * Our job is to copy framesPerBuffer frames from inputBuffer. */ int portaudio_source_callback (const void *inputBuffer, void *outputBuffer, unsigned long framesPerBuffer, const PaStreamCallbackTimeInfo* timeInfo, PaStreamCallbackFlags statusFlags, void *arg) { audio_portaudio_source *self = (audio_portaudio_source *)arg; int nchan = self->d_input_parameters.channelCount; int nframes_to_copy = framesPerBuffer; int nframes_room = self->d_writer->space_available() / nchan; if (nframes_to_copy <= nframes_room){ // We've got room for the data .. if (LOGGING) self->d_log->printf("PAsrc cb: f/b = %4ld\n", framesPerBuffer); // copy from input buffer to ringbuffer memcpy(self->d_writer->write_pointer(), inputBuffer, nframes_to_copy * nchan * sizeof(sample_t)); self->d_writer->update_write_pointer(nframes_to_copy * nchan); // Tell the source thread there is new data in the ringbuffer. self->d_ringbuffer_ready.post(); return paContinue; } else { // overrun if (LOGGING) self->d_log->printf("PAsrc cb: f/b = %4ld OVERRUN\n", framesPerBuffer); self->d_noverruns++; ::write(2, "aO", 2); // FIXME change to non-blocking call #if 0 // copy any frames that will fit memcpy(self->d_writer->write_pointer(), inputBuffer, nframes_room * nchan * sizeof(sample_t)); self->d_writer->update_write_pointer(nframes_room * nchan); #endif self->d_ringbuffer_ready.post(); // Tell the sink to get going! return paContinue; } } // ---------------------------------------------------------------- audio_portaudio_source_sptr audio_portaudio_make_source (int sampling_rate, const std::string dev, bool ok_to_block) { return audio_portaudio_source_sptr (new audio_portaudio_source (sampling_rate, dev, ok_to_block)); } audio_portaudio_source::audio_portaudio_source(int sampling_rate, const std::string device_name, bool ok_to_block) : gr_sync_block ("audio_portaudio_source", gr_make_io_signature(0, 0, 0), gr_make_io_signature(0, 0, 0)), d_sampling_rate(sampling_rate), d_device_name(device_name.empty() ? default_device_name() : device_name), d_ok_to_block(ok_to_block), d_verbose(gr_prefs::singleton()->get_bool("audio_portaudio", "verbose", false)), d_portaudio_buffer_size_frames(0), d_stream(0), d_ringbuffer_ready(1, 1), // binary semaphore d_noverruns(0) { memset(&d_input_parameters, 0, sizeof(d_input_parameters)); if (LOGGING) d_log = gri_logger::singleton(); PaError err; int i, numDevices; PaDeviceIndex device = 0; const PaDeviceInfo *deviceInfo = NULL; err = Pa_Initialize(); if (err != paNoError) { bail ("Initialize failed", err); } if (d_verbose) gri_print_devices(); numDevices = Pa_GetDeviceCount(); if (numDevices < 0) bail("Pa Device count failed", 0); if (numDevices == 0) bail("no devices available", 0); if (d_device_name.empty()) { // FIXME Get smarter about picking something device = Pa_GetDefaultInputDevice(); deviceInfo = Pa_GetDeviceInfo(device); fprintf(stderr,"%s is the chosen device using %s as the host\n", deviceInfo->name, Pa_GetHostApiInfo(deviceInfo->hostApi)->name); } else { bool found = false; for (i=0;iname); if (deviceInfo->maxInputChannels <= 0) { fprintf(stderr,"\n"); continue; } if (strstr(deviceInfo->name, d_device_name.c_str())){ fprintf(stderr," Chosen!\n"); device = i; fprintf(stderr,"%s using %s as the host\n",d_device_name.c_str(), Pa_GetHostApiInfo(deviceInfo->hostApi)->name), fflush(stderr); found = true; deviceInfo = Pa_GetDeviceInfo(device); i = numDevices; // force loop exit } else fprintf(stderr,"\n"),fflush(stderr); } if (!found){ bail("Failed to find specified device name", 0); } } d_input_parameters.device = device; d_input_parameters.channelCount = deviceInfo->maxInputChannels; d_input_parameters.sampleFormat = SAMPLE_FORMAT; d_input_parameters.suggestedLatency = deviceInfo->defaultLowInputLatency; d_input_parameters.hostApiSpecificStreamInfo = NULL; // We fill in the real channelCount in check_topology when we know // how many inputs are connected to us. // Now that we know the maximum number of channels (allegedly) // supported by the h/w, we can compute a reasonable output // signature. The portaudio specs say that they'll accept any // number of channels from 1 to max. set_output_signature(gr_make_io_signature(1, deviceInfo->maxInputChannels, sizeof (sample_t))); } bool audio_portaudio_source::check_topology (int ninputs, int noutputs) { PaError err; if (Pa_IsStreamActive(d_stream)) { Pa_CloseStream(d_stream); d_stream = 0; d_reader.reset(); // boost::shared_ptr for d_reader = 0 d_writer.reset(); // boost::shared_ptr for d_write = 0 } d_input_parameters.channelCount = noutputs; // # of channels we're really using #if 1 d_portaudio_buffer_size_frames = (int)(0.0213333333 * d_sampling_rate + 0.5); // Force 512 frame buffers at 48000 fprintf(stderr, "Latency = %8.5f, requested sampling_rate = %g\n", // Force latency to 21.3333333.. ms 0.0213333333, (double)d_sampling_rate); #endif err = Pa_OpenStream(&d_stream, &d_input_parameters, NULL, // No output d_sampling_rate, d_portaudio_buffer_size_frames, paClipOff, &portaudio_source_callback, (void*)this); if (err != paNoError) { output_error_msg ("OpenStream failed", err); return false; } #if 0 const PaStreamInfo *psi = Pa_GetStreamInfo(d_stream); d_portaudio_buffer_size_frames = (int)(d_input_parameters.suggestedLatency * psi->sampleRate); fprintf(stderr, "Latency = %7.4f, psi->sampleRate = %g\n", d_input_parameters.suggestedLatency, psi->sampleRate); #endif fprintf(stderr, "d_portaudio_buffer_size_frames = %d\n", d_portaudio_buffer_size_frames); assert(d_portaudio_buffer_size_frames != 0); create_ringbuffer(); err = Pa_StartStream(d_stream); if (err != paNoError) { output_error_msg ("StartStream failed", err); return false; } return true; } audio_portaudio_source::~audio_portaudio_source () { Pa_StopStream(d_stream); // wait for output to drain Pa_CloseStream(d_stream); Pa_Terminate(); } int audio_portaudio_source::work (int noutput_items, gr_vector_const_void_star &input_items, gr_vector_void_star &output_items) { float **out = (float **) &output_items[0]; const unsigned nchan = d_input_parameters.channelCount; // # of channels == samples/frame int k; for (k = 0; k < noutput_items; ){ int nframes = d_reader->items_available() / nchan; // # of frames in ringbuffer if (nframes == 0){ // no data right now... if (k > 0) // If we've produced anything so far, return that return k; if (d_ok_to_block){ d_ringbuffer_ready.wait(); // block here, then try again continue; } assert(k == 0); // There's no data and we're not allowed to block. // (A USRP is most likely controlling the pacing through the pipeline.) // This is an underun. The scheduler wouldn't have called us if it // had anything better to do. Thus we really need to produce some amount // of "fill". // // There are lots of options for comfort noise, etc. // FIXME We'll fill with zeros for now. Yes, it will "click"... // Fill with some frames of zeros int nf = std::min(noutput_items - k, (int) d_portaudio_buffer_size_frames); for (int i = 0; i < nf; i++){ for (unsigned int c = 0; c < nchan; c++){ out[c][k + i] = 0; } } k += nf; return k; } // We can read the smaller of the request and what's in the buffer. int nf = std::min(noutput_items - k, nframes); const float *p = (const float *) d_reader->read_pointer(); for (int i = 0; i < nf; i++){ for (unsigned int c = 0; c < nchan; c++){ out[c][k + i] = *p++; } } d_reader->update_read_pointer(nf * nchan); k += nf; } return k; // tell how many we actually did } void audio_portaudio_source::output_error_msg (const char *msg, int err) { fprintf (stderr, "audio_portaudio_source[%s]: %s: %s\n", d_device_name.c_str (), msg, Pa_GetErrorText(err)); } void audio_portaudio_source::bail (const char *msg, int err) throw (std::runtime_error) { output_error_msg (msg, err); throw std::runtime_error ("audio_portaudio_source"); }