ref: 36a83aede9accc17bf02d97d2ac7d1c306e0eff7
dir: /src/coreaudio.c/
/* AudioCore sound handler * * Copyright 2008 Chris Bagwell And Sundry Contributors */ #include "sox_i.h" #include <CoreAudio/CoreAudio.h> #include <pthread.h> typedef struct { AudioDeviceID adid; pthread_mutex_t mutex; pthread_cond_t cond; int device_started; size_t buf_size; size_t buf_offset; float *buffer; } priv_t; static OSStatus PlaybackIOProc(AudioDeviceID inDevice UNUSED, const AudioTimeStamp *inNow UNUSED, const AudioBufferList *inInputData UNUSED, const AudioTimeStamp *inInputTime UNUSED, AudioBufferList *outOutputData, const AudioTimeStamp *inOutputTime UNUSED, void *inClientData) { sox_format_t *ft = (sox_format_t *)inClientData; priv_t *ac = (priv_t *)ft->priv; char *buf = outOutputData->mBuffers[0].mData; unsigned int len, output_len; if (outOutputData->mNumberBuffers != 1) { lsx_warn("coreaudio: unhandled extra buffer. Data discarded."); return kAudioHardwareNoError; } buf = (char *)outOutputData->mBuffers[0].mData; output_len = outOutputData->mBuffers[0].mDataByteSize; pthread_mutex_lock(&ac->mutex); len = (ac->buf_offset < output_len) ? ac->buf_offset : output_len; /* Make sure to write 2 (stereo) floats at a time */ if (len % 8) len -= len % 8; memcpy(buf, ac->buffer, len); /* Fill partial output buffers with silence */ if (len < output_len) memset(buf+len, 0, output_len-len); ac->buf_offset -= len; pthread_mutex_unlock(&ac->mutex); pthread_cond_signal(&ac->cond); return kAudioHardwareNoError; } static OSStatus RecIOProc(AudioDeviceID inDevice UNUSED, const AudioTimeStamp *inNow UNUSED, const AudioBufferList *inInputData, const AudioTimeStamp *inInputTime UNUSED, AudioBufferList *outOutputData UNUSED, const AudioTimeStamp *inOutputTime UNUSED, void *inClientData) { sox_format_t *ft = (sox_format_t *)inClientData; priv_t *ac = (priv_t *)ft->priv; size_t len, output_len; char *destbuf; char *buf; int i; pthread_mutex_lock(&ac->mutex); if (inInputData->mNumberBuffers != 1) { lsx_warn("coreaudio: unhandled extra buffer. Data discarded."); return kAudioHardwareNoError; } destbuf = ((char *)ac->buffer + ac->buf_offset); buf = inInputData->mBuffers[0].mData; output_len = inInputData->mBuffers[0].mDataByteSize; /* mDataByteSize may be non-zero even when mData is NULL, but that is * not an error. */ if (buf == NULL) return kAudioHardwareNoError; len = ac->buf_size - ac->buf_offset; /* Make sure to read 2 (stereo) floats at a time */ if (len % 8) len -= len % 8; if (len > output_len) len = output_len; /* FIXME: Handle buffer overrun. */ if (len < output_len) lsx_warn("coreaudio: unhandled buffer overrun. Data discarded."); memcpy(destbuf, buf, len); ac->buf_offset += len; pthread_mutex_unlock(&ac->mutex); pthread_cond_signal(&ac->cond); return kAudioHardwareNoError; } static int setup(sox_format_t *ft, int is_input) { priv_t *ac = (priv_t *)ft->priv; OSStatus status; UInt32 property_size; struct AudioStreamBasicDescription stream_desc; int32_t buf_size; int rc; if (strncmp(ft->filename, "default", (size_t)7) == 0) { property_size = sizeof(ac->adid); if (is_input) status = AudioHardwareGetProperty(kAudioHardwarePropertyDefaultInputDevice, &property_size, &ac->adid); else status = AudioHardwareGetProperty(kAudioHardwarePropertyDefaultOutputDevice, &property_size, &ac->adid); } else { Boolean is_writable; status = AudioHardwareGetPropertyInfo(kAudioHardwarePropertyDevices, &property_size, &is_writable); if (status == noErr) { int device_count = property_size/sizeof(AudioDeviceID); AudioDeviceID *devices; devices = malloc(property_size); status = AudioHardwareGetProperty(kAudioHardwarePropertyDevices, &property_size, devices); if (status == noErr) { int i; for (i = 0; i < device_count; i++) { char name[256]; status = AudioDeviceGetProperty(devices[i],0,false,kAudioDevicePropertyDeviceName,&property_size,&name); lsx_report("Found Audio Device \"%s\"\n",name); /* String returned from OS is truncated so only compare * as much as returned. */ if (strncmp(name,ft->filename,strlen(name)) == 0) { ac->adid = devices[i]; break; } } } free(devices); } } if (status || ac->adid == kAudioDeviceUnknown) { lsx_fail_errno(ft, SOX_EPERM, "can not open audio device"); return SOX_EOF; } /* Query device to get initial values */ property_size = sizeof(struct AudioStreamBasicDescription); status = AudioDeviceGetProperty(ac->adid, 0, is_input, kAudioDevicePropertyStreamFormat, &property_size, &stream_desc); if (status) { lsx_fail_errno(ft, SOX_EPERM, "can not get audio device properties"); return SOX_EOF; } if (!(stream_desc.mFormatFlags & kLinearPCMFormatFlagIsFloat)) { lsx_fail_errno(ft, SOX_EPERM, "audio device does not accept floats"); return SOX_EOF; } /* OS X effectively only supports these values. */ ft->signal.channels = 2; ft->signal.rate = 44100; ft->encoding.bits_per_sample = 32; /* TODO: My limited experience with hardware can only get floats working * withh a fixed sample rate and stereo. I know that is a limitiation of * audio device I have so this may not be standard operating orders. * If some hardware supports setting sample rates and channel counts * then should do that over resampling and mixing. */ #if 0 stream_desc.mSampleRate = ft->signal.rate; stream_desc.mChannelsPerFrame = ft->signal.channels; /* Write them back */ property_size = sizeof(struct AudioStreamBasicDescription); status = AudioDeviceSetProperty(ac->adid, NULL, 0, is_input, kAudioDevicePropertyStreamFormat, property_size, &stream_desc); if (status) { lsx_fail_errno(ft, SOX_EPERM, "can not set audio device properties"); return SOX_EOF; } /* Query device to see if it worked */ property_size = sizeof(struct AudioStreamBasicDescription); status = AudioDeviceGetProperty(ac->adid, 0, is_input, kAudioDevicePropertyStreamFormat, &property_size, &stream_desc); if (status) { lsx_fail_errno(ft, SOX_EPERM, "can not get audio device properties"); return SOX_EOF; } #endif if (stream_desc.mChannelsPerFrame != ft->signal.channels) { lsx_debug("audio device did not accept %d channels. Use %d channels instead.", (int)ft->signal.channels, (int)stream_desc.mChannelsPerFrame); ft->signal.channels = stream_desc.mChannelsPerFrame; } if (stream_desc.mSampleRate != ft->signal.rate) { lsx_debug("audio device did not accept %d sample rate. Use %d instead.", (int)ft->signal.rate, (int)stream_desc.mSampleRate); ft->signal.rate = stream_desc.mSampleRate; } ac->buf_size = sox_globals.bufsiz * sizeof(float); ac->buf_offset = 0; ac->buffer = lsx_malloc(ac->buf_size); buf_size = ac->buf_size; property_size = sizeof(buf_size); status = AudioDeviceSetProperty(ac->adid, NULL, 0, is_input, kAudioDevicePropertyBufferSize, property_size, &buf_size); rc = pthread_mutex_init(&ac->mutex, NULL); if (rc) { lsx_fail_errno(ft, SOX_EPERM, "failed initializing mutex"); return SOX_EOF; } rc = pthread_cond_init(&ac->cond, NULL); if (rc) { lsx_fail_errno(ft, SOX_EPERM, "failed initializing condition"); return SOX_EOF; } ac->device_started = 0; /* Registers callback with the device without activating it. */ if (is_input) status = AudioDeviceAddIOProc(ac->adid, RecIOProc, (void *)ft); else status = AudioDeviceAddIOProc(ac->adid, PlaybackIOProc, (void *)ft); return SOX_SUCCESS; } static int startread(sox_format_t *ft) { return setup(ft, 1); } static size_t read_samples(sox_format_t *ft, sox_sample_t *buf, size_t nsamp) { priv_t *ac = (priv_t *)ft->priv; size_t len = nsamp; size_t samp_left; OSStatus status; float *p; SOX_SAMPLE_LOCALS; if (!ac->device_started) { status = AudioDeviceStart(ac->adid, RecIOProc); ac->device_started = 1; } pthread_mutex_lock(&ac->mutex); /* Wait until input buffer has been filled by device driver */ while (ac->buf_offset < ac->buf_size) pthread_cond_wait(&ac->cond, &ac->mutex); len = ac->buf_offset / sizeof(float); for (p = ac->buffer, samp_left = len; samp_left > 0; samp_left--, buf++, p++) *buf = SOX_FLOAT_32BIT_TO_SAMPLE(*p, ft->clips); ac->buf_offset = 0; pthread_mutex_unlock(&ac->mutex); return len; } static int stopread(sox_format_t * ft) { priv_t *ac = (priv_t *)ft->priv; AudioDeviceStop(ac->adid, RecIOProc); AudioDeviceRemoveIOProc(ac->adid, RecIOProc); pthread_cond_destroy(&ac->cond); pthread_mutex_destroy(&ac->mutex); return SOX_SUCCESS; } static int startwrite(sox_format_t * ft) { return setup(ft, 0); } static size_t write_samples(sox_format_t *ft, const sox_sample_t *buf, size_t nsamp) { priv_t *ac = (priv_t *)ft->priv; size_t len, written = 0; size_t samp_left; OSStatus status; float *p; SOX_SAMPLE_LOCALS; pthread_mutex_lock(&ac->mutex); /* Wait to start until mutex is locked to help prevent callback * getting zero samples. */ if (!ac->device_started) { status = AudioDeviceStart(ac->adid, PlaybackIOProc); if (status) { pthread_mutex_unlock(&ac->mutex); return SOX_EOF; } ac->device_started = 1; } /* globals.bufsize is in samples * buf_offset is in bytes * buf_size is in bytes */ do { while (ac->buf_offset >= ac->buf_size) pthread_cond_wait(&ac->cond, &ac->mutex); len = nsamp - written; if (len > (ac->buf_size - ac->buf_offset) / sizeof(float)) len = (ac->buf_size - ac->buf_offset) / sizeof(float); samp_left = len; p = ((unsigned char *)ac->buffer) + ac->buf_offset; while (samp_left--) *p++ = SOX_SAMPLE_TO_FLOAT_32BIT(*buf++, ft->clips); ac->buf_offset += len * sizeof(float); written += len; } while (written < nsamp); pthread_mutex_unlock(&ac->mutex); return written; } static int stopwrite(sox_format_t * ft) { priv_t *ac = (priv_t *)ft->priv; if (!ac->device_started) { pthread_mutex_lock(&ac->mutex); while (ac->buf_offset) pthread_cond_wait(&ac->cond, &ac->mutex); pthread_mutex_unlock(&ac->mutex); AudioDeviceStop(ac->adid, PlaybackIOProc); } AudioDeviceRemoveIOProc(ac->adid, PlaybackIOProc); pthread_cond_destroy(&ac->cond); pthread_mutex_destroy(&ac->mutex); return SOX_SUCCESS; } LSX_FORMAT_HANDLER(coreaudio) { static char const *const names[] = { "coreaudio", NULL }; static unsigned const write_encodings[] = { SOX_ENCODING_FLOAT, 32, 0, 0}; static sox_format_handler_t const handler = {SOX_LIB_VERSION_CODE, "Mac AudioCore device driver", names, SOX_FILE_DEVICE | SOX_FILE_NOSTDIO, startread, read_samples, stopread, startwrite, write_samples, stopwrite, NULL, write_encodings, NULL, sizeof(priv_t) }; return &handler; }