/* * Copyright © 2012 David Richards * Copyright © 2013 Sebastien Alaiwan * Copyright © 2016 Damien Zammit * * This program is made available under an ISC-style license. See the * accompanying file LICENSE for details. */ #define _DEFAULT_SOURCE #define _BSD_SOURCE #define _POSIX_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include "cubeb/cubeb.h" #include "cubeb-internal.h" #include "cubeb_resampler.h" #include #include #define JACK_API_VISIT(X) \ X(jack_activate) \ X(jack_client_close) \ X(jack_client_open) \ X(jack_connect) \ X(jack_free) \ X(jack_get_ports) \ X(jack_get_sample_rate) \ X(jack_get_xrun_delayed_usecs) \ X(jack_get_buffer_size) \ X(jack_port_get_buffer) \ X(jack_port_name) \ X(jack_port_register) \ X(jack_port_unregister) \ X(jack_port_get_latency_range) \ X(jack_set_process_callback) \ X(jack_set_xrun_callback) \ X(jack_set_graph_order_callback) \ X(jack_set_error_function) \ X(jack_set_info_function) #define IMPORT_FUNC(x) static decltype(x) * api_##x; JACK_API_VISIT(IMPORT_FUNC); static const int MAX_STREAMS = 16; static const int MAX_CHANNELS = 8; static const int FIFO_SIZE = 4096 * sizeof(float); enum devstream { NONE = 0, IN_ONLY, OUT_ONLY, DUPLEX, }; static void s16ne_to_float(float * dst, const int16_t * src, size_t n) { for (size_t i = 0; i < n; i++) *(dst++) = (float)((float)*(src++) / 32767.0f); } static void float_to_s16ne(int16_t * dst, float * src, size_t n) { for (size_t i = 0; i < n; i++) { if (*src > 1.f) *src = 1.f; if (*src < -1.f) *src = -1.f; *(dst++) = (int16_t)((int16_t)(*(src++) * 32767)); } } extern "C" { /*static*/ int jack_init (cubeb ** context, char const * context_name); } static char const * cbjack_get_backend_id(cubeb * context); static int cbjack_get_max_channel_count(cubeb * ctx, uint32_t * max_channels); static int cbjack_get_min_latency(cubeb * ctx, cubeb_stream_params params, uint32_t * latency_frames); static int cbjack_get_latency(cubeb_stream * stm, unsigned int * latency_frames); static int cbjack_get_preferred_sample_rate(cubeb * ctx, uint32_t * rate); static void cbjack_destroy(cubeb * context); static void cbjack_interleave_capture(cubeb_stream * stream, float **in, jack_nframes_t nframes, bool format_mismatch); static void cbjack_deinterleave_playback_refill_s16ne(cubeb_stream * stream, short **bufs_in, float **bufs_out, jack_nframes_t nframes); static void cbjack_deinterleave_playback_refill_float(cubeb_stream * stream, float **bufs_in, float **bufs_out, jack_nframes_t nframes); static int cbjack_stream_device_destroy(cubeb_stream * stream, cubeb_device * device); static int cbjack_stream_get_current_device(cubeb_stream * stm, cubeb_device ** const device); static int cbjack_enumerate_devices(cubeb * context, cubeb_device_type type, cubeb_device_collection ** collection); static int cbjack_stream_init(cubeb * context, cubeb_stream ** stream, char const * stream_name, cubeb_devid input_device, cubeb_stream_params * input_stream_params, cubeb_devid output_device, cubeb_stream_params * output_stream_params, unsigned int latency_frames, cubeb_data_callback data_callback, cubeb_state_callback state_callback, void * user_ptr); static void cbjack_stream_destroy(cubeb_stream * stream); static int cbjack_stream_start(cubeb_stream * stream); static int cbjack_stream_stop(cubeb_stream * stream); static int cbjack_stream_get_position(cubeb_stream * stream, uint64_t * position); static int cbjack_stream_set_volume(cubeb_stream * stm, float volume); static struct cubeb_ops const cbjack_ops = { .init = jack_init, .get_backend_id = cbjack_get_backend_id, .get_max_channel_count = cbjack_get_max_channel_count, .get_min_latency = cbjack_get_min_latency, .get_preferred_sample_rate = cbjack_get_preferred_sample_rate, .enumerate_devices = cbjack_enumerate_devices, .destroy = cbjack_destroy, .stream_init = cbjack_stream_init, .stream_destroy = cbjack_stream_destroy, .stream_start = cbjack_stream_start, .stream_stop = cbjack_stream_stop, .stream_get_position = cbjack_stream_get_position, .stream_get_latency = cbjack_get_latency, .stream_set_volume = cbjack_stream_set_volume, .stream_set_panning = NULL, .stream_get_current_device = cbjack_stream_get_current_device, .stream_device_destroy = cbjack_stream_device_destroy, .stream_register_device_changed_callback = NULL, .register_device_collection_changed = NULL }; struct cubeb_stream { cubeb * context; /**< Mutex for each stream */ pthread_mutex_t mutex; bool in_use; /**< Set to false iff the stream is free */ bool ports_ready; /**< Set to true iff the JACK ports are ready */ cubeb_data_callback data_callback; cubeb_state_callback state_callback; void * user_ptr; cubeb_stream_params in_params; cubeb_stream_params out_params; cubeb_resampler * resampler; uint64_t position; bool pause; float ratio; enum devstream devs; char stream_name[256]; jack_port_t * output_ports[MAX_CHANNELS]; jack_port_t * input_ports[MAX_CHANNELS]; float volume; }; struct cubeb { struct cubeb_ops const * ops; void * libjack; /**< Mutex for whole context */ pthread_mutex_t mutex; /**< Audio buffers, converted to float */ float in_float_interleaved_buffer[FIFO_SIZE * MAX_CHANNELS]; float out_float_interleaved_buffer[FIFO_SIZE * MAX_CHANNELS]; /**< Audio buffer, at the sampling rate of the output */ float in_resampled_interleaved_buffer_float[FIFO_SIZE * MAX_CHANNELS * 3]; int16_t in_resampled_interleaved_buffer_s16ne[FIFO_SIZE * MAX_CHANNELS * 3]; float out_resampled_interleaved_buffer_float[FIFO_SIZE * MAX_CHANNELS * 3]; int16_t out_resampled_interleaved_buffer_s16ne[FIFO_SIZE * MAX_CHANNELS * 3]; cubeb_stream streams[MAX_STREAMS]; unsigned int active_streams; cubeb_device_info * devinfo[2]; cubeb_device_collection_changed_callback collection_changed_callback; bool active; unsigned int jack_sample_rate; unsigned int jack_latency; unsigned int jack_xruns; unsigned int jack_buffer_size; unsigned int fragment_size; unsigned int output_bytes_per_frame; jack_client_t * jack_client; }; static int load_jack_lib(cubeb * context) { #ifdef __APPLE__ context->libjack = dlopen("libjack.0.dylib", RTLD_LAZY); context->libjack = dlopen("/usr/local/lib/libjack.0.dylib", RTLD_LAZY); #elif defined(__WIN32__) # ifdef _WIN64 context->libjack = LoadLibrary("libjack64.dll"); # else context->libjack = LoadLibrary("libjack.dll"); # endif #else context->libjack = dlopen("libjack.so.0", RTLD_LAZY); #endif if (!context->libjack) { return CUBEB_ERROR; } #define LOAD(x) \ { \ api_##x = (decltype(x)*)dlsym(context->libjack, #x); \ if (!api_##x) { \ dlclose(context->libjack); \ return CUBEB_ERROR; \ } \ } JACK_API_VISIT(LOAD); #undef LOAD return CUBEB_OK; } static void cbjack_connect_ports (cubeb_stream * stream) { const char ** phys_in_ports = api_jack_get_ports (stream->context->jack_client, NULL, NULL, JackPortIsInput | JackPortIsPhysical); const char ** phys_out_ports = api_jack_get_ports (stream->context->jack_client, NULL, NULL, JackPortIsOutput | JackPortIsPhysical); if (*phys_in_ports == NULL) { goto skipplayback; } // Connect outputs to playback for (unsigned int c = 0; c < stream->out_params.channels && phys_in_ports[c] != NULL; c++) { const char *src_port = api_jack_port_name (stream->output_ports[c]); api_jack_connect (stream->context->jack_client, src_port, phys_in_ports[c]); } skipplayback: if (*phys_out_ports == NULL) { goto end; } // Connect inputs to capture for (unsigned int c = 0; c < stream->in_params.channels && phys_out_ports[c] != NULL; c++) { const char *src_port = api_jack_port_name (stream->input_ports[c]); api_jack_connect (stream->context->jack_client, phys_out_ports[c], src_port); } end: api_jack_free(phys_out_ports); api_jack_free(phys_in_ports); } static int cbjack_xrun_callback(void * arg) { cubeb * ctx = (cubeb *)arg; float delay = api_jack_get_xrun_delayed_usecs(ctx->jack_client); int fragments = (int)ceilf( ((delay / 1000000.0) * ctx->jack_sample_rate ) / (float)(ctx->jack_buffer_size) ); ctx->jack_xruns += fragments; return 0; } static int cbjack_graph_order_callback(void * arg) { cubeb * ctx = (cubeb *)arg; int i; jack_latency_range_t latency_range; jack_nframes_t port_latency, max_latency = 0; for (int j = 0; j < MAX_STREAMS; j++) { cubeb_stream *stm = &ctx->streams[j]; if (!stm->in_use) continue; if (!stm->ports_ready) continue; for (i = 0; i < (int)stm->out_params.channels; ++i) { api_jack_port_get_latency_range(stm->output_ports[i], JackPlaybackLatency, &latency_range); port_latency = latency_range.max; if (port_latency > max_latency) max_latency = port_latency; } /* Cap minimum latency to 128 frames */ if (max_latency < 128) max_latency = 128; } ctx->jack_latency = max_latency; return 0; } static int cbjack_process(jack_nframes_t nframes, void * arg) { cubeb * ctx = (cubeb *)arg; int t_jack_xruns = ctx->jack_xruns; int i; for (int j = 0; j < MAX_STREAMS; j++) { cubeb_stream *stm = &ctx->streams[j]; float *bufs_out[stm->out_params.channels]; float *bufs_in[stm->in_params.channels]; if (!stm->in_use) continue; // handle xruns by skipping audio that should have been played for (i = 0; i < t_jack_xruns; i++) { stm->position += ctx->fragment_size * stm->ratio; } ctx->jack_xruns -= t_jack_xruns; if (!stm->ports_ready) continue; if (stm->devs & OUT_ONLY) { // get jack output buffers for (i = 0; i < (int)stm->out_params.channels; i++) bufs_out[i] = (float*)api_jack_port_get_buffer(stm->output_ports[i], nframes); } if (stm->devs & IN_ONLY) { // get jack input buffers for (i = 0; i < (int)stm->in_params.channels; i++) bufs_in[i] = (float*)api_jack_port_get_buffer(stm->input_ports[i], nframes); } if (stm->pause) { // paused, play silence on output if (stm->devs & OUT_ONLY) { for (unsigned int c = 0; c < stm->out_params.channels; c++) { float* buffer_out = bufs_out[c]; for (long f = 0; f < nframes; f++) { buffer_out[f] = 0.f; } } } if (stm->devs & IN_ONLY) { // paused, capture silence for (unsigned int c = 0; c < stm->in_params.channels; c++) { float* buffer_in = bufs_in[c]; for (long f = 0; f < nframes; f++) { buffer_in[f] = 0.f; } } } } else { // try to lock stream mutex if (pthread_mutex_trylock(&stm->mutex) == 0) { int16_t *in_s16ne = stm->context->in_resampled_interleaved_buffer_s16ne; float *in_float = stm->context->in_resampled_interleaved_buffer_float; // unpaused, play audio if (stm->devs == DUPLEX) { if (stm->out_params.format == CUBEB_SAMPLE_S16NE) { cbjack_interleave_capture(stm, bufs_in, nframes, true); cbjack_deinterleave_playback_refill_s16ne(stm, &in_s16ne, bufs_out, nframes); } else if (stm->out_params.format == CUBEB_SAMPLE_FLOAT32NE) { cbjack_interleave_capture(stm, bufs_in, nframes, false); cbjack_deinterleave_playback_refill_float(stm, &in_float, bufs_out, nframes); } } else if (stm->devs == IN_ONLY) { if (stm->in_params.format == CUBEB_SAMPLE_S16NE) { cbjack_interleave_capture(stm, bufs_in, nframes, true); cbjack_deinterleave_playback_refill_s16ne(stm, &in_s16ne, nullptr, nframes); } else if (stm->in_params.format == CUBEB_SAMPLE_FLOAT32NE) { cbjack_interleave_capture(stm, bufs_in, nframes, false); cbjack_deinterleave_playback_refill_float(stm, &in_float, nullptr, nframes); } } else if (stm->devs == OUT_ONLY) { if (stm->out_params.format == CUBEB_SAMPLE_S16NE) { cbjack_deinterleave_playback_refill_s16ne(stm, nullptr, bufs_out, nframes); } else if (stm->out_params.format == CUBEB_SAMPLE_FLOAT32NE) { cbjack_deinterleave_playback_refill_float(stm, nullptr, bufs_out, nframes); } } // unlock stream mutex pthread_mutex_unlock(&stm->mutex); } else { // could not lock mutex // output silence if (stm->devs & OUT_ONLY) { for (unsigned int c = 0; c < stm->out_params.channels; c++) { float* buffer_out = bufs_out[c]; for (long f = 0; f < nframes; f++) { buffer_out[f] = 0.f; } } } if (stm->devs & IN_ONLY) { // capture silence for (unsigned int c = 0; c < stm->in_params.channels; c++) { float* buffer_in = bufs_in[c]; for (long f = 0; f < nframes; f++) { buffer_in[f] = 0.f; } } } } } } return 0; } static void cbjack_deinterleave_playback_refill_float(cubeb_stream * stream, float ** in, float ** bufs_out, jack_nframes_t nframes) { float * out_interleaved_buffer = nullptr; float * inptr = (in != NULL) ? *in : nullptr; float * outptr = (bufs_out != NULL) ? *bufs_out : nullptr; long needed_frames = (bufs_out != NULL) ? nframes : 0; long done_frames = 0; long input_frames_count = (in != NULL) ? nframes : 0; done_frames = cubeb_resampler_fill(stream->resampler, inptr, &input_frames_count, (bufs_out != NULL) ? stream->context->out_resampled_interleaved_buffer_float : NULL, needed_frames); out_interleaved_buffer = stream->context->out_resampled_interleaved_buffer_float; if (outptr) { // convert interleaved output buffers to contiguous buffers for (unsigned int c = 0; c < stream->out_params.channels; c++) { float* buffer = bufs_out[c]; for (long f = 0; f < done_frames; f++) { buffer[f] = out_interleaved_buffer[(f * stream->out_params.channels) + c] * stream->volume; } if (done_frames < needed_frames) { // draining for (long f = done_frames; f < needed_frames; f++) { buffer[f] = 0.f; } } if (done_frames == 0) { // stop, but first zero out the existing buffer for (long f = 0; f < needed_frames; f++) { buffer[f] = 0.f; } } } } if (done_frames >= 0 && done_frames < needed_frames) { // set drained stream->state_callback(stream, stream->user_ptr, CUBEB_STATE_DRAINED); // stop stream cbjack_stream_stop(stream); } if (done_frames > 0 && done_frames <= needed_frames) { // advance stream position stream->position += done_frames * stream->ratio; } if (done_frames < 0 || done_frames > needed_frames) { // stream error stream->state_callback(stream, stream->user_ptr, CUBEB_STATE_ERROR); } } static void cbjack_deinterleave_playback_refill_s16ne(cubeb_stream * stream, short ** in, float ** bufs_out, jack_nframes_t nframes) { float * out_interleaved_buffer = nullptr; short * inptr = (in != NULL) ? *in : nullptr; float * outptr = (bufs_out != NULL) ? *bufs_out : nullptr; long needed_frames = (bufs_out != NULL) ? nframes : 0; long done_frames = 0; long input_frames_count = (in != NULL) ? nframes : 0; done_frames = cubeb_resampler_fill(stream->resampler, inptr, &input_frames_count, (bufs_out != NULL) ? stream->context->out_resampled_interleaved_buffer_s16ne : NULL, needed_frames); s16ne_to_float(stream->context->out_resampled_interleaved_buffer_float, stream->context->out_resampled_interleaved_buffer_s16ne, done_frames * stream->out_params.channels); out_interleaved_buffer = stream->context->out_resampled_interleaved_buffer_float; if (outptr) { // convert interleaved output buffers to contiguous buffers for (unsigned int c = 0; c < stream->out_params.channels; c++) { float* buffer = bufs_out[c]; for (long f = 0; f < done_frames; f++) { buffer[f] = out_interleaved_buffer[(f * stream->out_params.channels) + c] * stream->volume; } if (done_frames < needed_frames) { // draining for (long f = done_frames; f < needed_frames; f++) { buffer[f] = 0.f; } } if (done_frames == 0) { // stop, but first zero out the existing buffer for (long f = 0; f < needed_frames; f++) { buffer[f] = 0.f; } } } } if (done_frames >= 0 && done_frames < needed_frames) { // set drained stream->state_callback(stream, stream->user_ptr, CUBEB_STATE_DRAINED); // stop stream cbjack_stream_stop(stream); } if (done_frames > 0 && done_frames <= needed_frames) { // advance stream position stream->position += done_frames * stream->ratio; } if (done_frames < 0 || done_frames > needed_frames) { // stream error stream->state_callback(stream, stream->user_ptr, CUBEB_STATE_ERROR); } } static void cbjack_interleave_capture(cubeb_stream * stream, float **in, jack_nframes_t nframes, bool format_mismatch) { float *in_buffer = stream->context->in_float_interleaved_buffer; for (unsigned int c = 0; c < stream->in_params.channels; c++) { for (long f = 0; f < nframes; f++) { in_buffer[(f * stream->in_params.channels) + c] = in[c][f] * stream->volume; } } if (format_mismatch) { float_to_s16ne(stream->context->in_resampled_interleaved_buffer_s16ne, in_buffer, nframes * stream->in_params.channels); } else { memset(stream->context->in_resampled_interleaved_buffer_float, 0, (FIFO_SIZE * MAX_CHANNELS * 3) * sizeof(float)); memcpy(stream->context->in_resampled_interleaved_buffer_float, in_buffer, (FIFO_SIZE * MAX_CHANNELS * 2) * sizeof(float)); } } static void silent_jack_error_callback(char const * /*msg*/) { } /*static*/ int jack_init (cubeb ** context, char const * context_name) { int r; *context = NULL; cubeb * ctx = (cubeb *)calloc(1, sizeof(*ctx)); if (ctx == NULL) { return CUBEB_ERROR; } r = load_jack_lib(ctx); if (r != 0) { cbjack_destroy(ctx); return CUBEB_ERROR; } api_jack_set_error_function(silent_jack_error_callback); api_jack_set_info_function(silent_jack_error_callback); ctx->ops = &cbjack_ops; ctx->mutex = PTHREAD_MUTEX_INITIALIZER; for (r = 0; r < MAX_STREAMS; r++) { ctx->streams[r].mutex = PTHREAD_MUTEX_INITIALIZER; } const char * jack_client_name = "cubeb"; if (context_name) jack_client_name = context_name; ctx->jack_client = api_jack_client_open(jack_client_name, JackNoStartServer, NULL); if (ctx->jack_client == NULL) { cbjack_destroy(ctx); return CUBEB_ERROR; } ctx->jack_xruns = 0; api_jack_set_process_callback (ctx->jack_client, cbjack_process, ctx); api_jack_set_xrun_callback (ctx->jack_client, cbjack_xrun_callback, ctx); api_jack_set_graph_order_callback (ctx->jack_client, cbjack_graph_order_callback, ctx); if (api_jack_activate (ctx->jack_client)) { cbjack_destroy(ctx); return CUBEB_ERROR; } ctx->jack_sample_rate = api_jack_get_sample_rate(ctx->jack_client); ctx->jack_latency = 128 * 1000 / ctx->jack_sample_rate; ctx->active = true; *context = ctx; return CUBEB_OK; } static char const * cbjack_get_backend_id(cubeb * /*context*/) { return "jack"; } static int cbjack_get_max_channel_count(cubeb * /*ctx*/, uint32_t * max_channels) { *max_channels = MAX_CHANNELS; return CUBEB_OK; } static int cbjack_get_latency(cubeb_stream * stm, unsigned int * latency_ms) { *latency_ms = stm->context->jack_latency; return CUBEB_OK; } static int cbjack_get_min_latency(cubeb * ctx, cubeb_stream_params /*params*/, uint32_t * latency_ms) { *latency_ms = ctx->jack_latency; return CUBEB_OK; } static int cbjack_get_preferred_sample_rate(cubeb * ctx, uint32_t * rate) { if (!ctx->jack_client) { jack_client_t * testclient = api_jack_client_open("test-samplerate", JackNoStartServer, NULL); if (!testclient) { return CUBEB_ERROR; } *rate = api_jack_get_sample_rate(testclient); api_jack_client_close(testclient); } else { *rate = api_jack_get_sample_rate(ctx->jack_client); } return CUBEB_OK; } static void cbjack_destroy(cubeb * context) { context->active = false; if (context->jack_client != NULL) api_jack_client_close (context->jack_client); if (context->libjack) dlclose(context->libjack); free(context); } static cubeb_stream * context_alloc_stream(cubeb * context, char const * stream_name) { for (int i = 0; i < MAX_STREAMS; i++) { if (!context->streams[i].in_use) { cubeb_stream * stm = &context->streams[i]; stm->in_use = true; snprintf(stm->stream_name, 255, "%s_%u", stream_name, i); return stm; } } return NULL; } static int cbjack_stream_init(cubeb * context, cubeb_stream ** stream, char const * stream_name, cubeb_devid input_device, cubeb_stream_params * input_stream_params, cubeb_devid output_device, cubeb_stream_params * output_stream_params, unsigned int /*latency_frames*/, cubeb_data_callback data_callback, cubeb_state_callback state_callback, void * user_ptr) { int stream_actual_rate = 0; int jack_rate = api_jack_get_sample_rate(context->jack_client); if (output_stream_params && (output_stream_params->format != CUBEB_SAMPLE_FLOAT32NE && output_stream_params->format != CUBEB_SAMPLE_S16NE) ) { return CUBEB_ERROR_INVALID_FORMAT; } if (input_stream_params && (input_stream_params->format != CUBEB_SAMPLE_FLOAT32NE && input_stream_params->format != CUBEB_SAMPLE_S16NE) ) { return CUBEB_ERROR_INVALID_FORMAT; } if (input_device || output_device) return CUBEB_ERROR_NOT_SUPPORTED; *stream = NULL; // Find a free stream. pthread_mutex_lock(&context->mutex); cubeb_stream * stm = context_alloc_stream(context, stream_name); // No free stream? if (stm == NULL) { pthread_mutex_unlock(&context->mutex); return CUBEB_ERROR; } // unlock context mutex pthread_mutex_unlock(&context->mutex); // Lock active stream pthread_mutex_lock(&stm->mutex); stm->ports_ready = false; stm->user_ptr = user_ptr; stm->context = context; stm->devs = NONE; if (output_stream_params && !input_stream_params) { stm->out_params = *output_stream_params; stream_actual_rate = stm->out_params.rate; stm->out_params.rate = jack_rate; stm->devs = OUT_ONLY; if (stm->out_params.format == CUBEB_SAMPLE_FLOAT32NE) { context->output_bytes_per_frame = sizeof(float); } else { context->output_bytes_per_frame = sizeof(short); } } if (input_stream_params && output_stream_params) { stm->in_params = *input_stream_params; stm->out_params = *output_stream_params; stream_actual_rate = stm->out_params.rate; stm->in_params.rate = jack_rate; stm->out_params.rate = jack_rate; stm->devs = DUPLEX; if (stm->out_params.format == CUBEB_SAMPLE_FLOAT32NE) { context->output_bytes_per_frame = sizeof(float); stm->in_params.format = CUBEB_SAMPLE_FLOAT32NE; } else { context->output_bytes_per_frame = sizeof(short); stm->in_params.format = CUBEB_SAMPLE_S16NE; } } else if (input_stream_params && !output_stream_params) { stm->in_params = *input_stream_params; stream_actual_rate = stm->in_params.rate; stm->in_params.rate = jack_rate; stm->devs = IN_ONLY; if (stm->in_params.format == CUBEB_SAMPLE_FLOAT32NE) { context->output_bytes_per_frame = sizeof(float); } else { context->output_bytes_per_frame = sizeof(short); } } stm->ratio = (float)stream_actual_rate / (float)jack_rate; stm->data_callback = data_callback; stm->state_callback = state_callback; stm->position = 0; stm->volume = 1.0f; context->jack_buffer_size = api_jack_get_buffer_size(context->jack_client); context->fragment_size = context->jack_buffer_size; if (stm->devs == NONE) { pthread_mutex_unlock(&stm->mutex); return CUBEB_ERROR; } stm->resampler = NULL; if (stm->devs == DUPLEX) { stm->resampler = cubeb_resampler_create(stm, &stm->in_params, &stm->out_params, stream_actual_rate, stm->data_callback, stm->user_ptr, CUBEB_RESAMPLER_QUALITY_DESKTOP); } else if (stm->devs == IN_ONLY) { stm->resampler = cubeb_resampler_create(stm, &stm->in_params, nullptr, stream_actual_rate, stm->data_callback, stm->user_ptr, CUBEB_RESAMPLER_QUALITY_DESKTOP); } else if (stm->devs == OUT_ONLY) { stm->resampler = cubeb_resampler_create(stm, nullptr, &stm->out_params, stream_actual_rate, stm->data_callback, stm->user_ptr, CUBEB_RESAMPLER_QUALITY_DESKTOP); } if (!stm->resampler) { stm->in_use = false; pthread_mutex_unlock(&stm->mutex); return CUBEB_ERROR; } if (stm->devs == DUPLEX || stm->devs == OUT_ONLY) { for (unsigned int c = 0; c < stm->out_params.channels; c++) { char portname[256]; snprintf(portname, 255, "%s_out_%d", stm->stream_name, c); stm->output_ports[c] = api_jack_port_register(stm->context->jack_client, portname, JACK_DEFAULT_AUDIO_TYPE, JackPortIsOutput, 0); } } if (stm->devs == DUPLEX || stm->devs == IN_ONLY) { for (unsigned int c = 0; c < stm->in_params.channels; c++) { char portname[256]; snprintf(portname, 255, "%s_in_%d", stm->stream_name, c); stm->input_ports[c] = api_jack_port_register(stm->context->jack_client, portname, JACK_DEFAULT_AUDIO_TYPE, JackPortIsInput, 0); } } cbjack_connect_ports(stm); *stream = stm; stm->ports_ready = true; stm->pause = true; pthread_mutex_unlock(&stm->mutex); return CUBEB_OK; } static void cbjack_stream_destroy(cubeb_stream * stream) { pthread_mutex_lock(&stream->mutex); stream->ports_ready = false; if (stream->devs == DUPLEX || stream->devs == OUT_ONLY) { for (unsigned int c = 0; c < stream->out_params.channels; c++) { if (stream->output_ports[c]) { api_jack_port_unregister (stream->context->jack_client, stream->output_ports[c]); stream->output_ports[c] = NULL; } } } if (stream->devs == DUPLEX || stream->devs == IN_ONLY) { for (unsigned int c = 0; c < stream->in_params.channels; c++) { if (stream->input_ports[c]) { api_jack_port_unregister (stream->context->jack_client, stream->input_ports[c]); stream->input_ports[c] = NULL; } } } if (stream->resampler) { cubeb_resampler_destroy(stream->resampler); stream->resampler = NULL; } stream->in_use = false; pthread_mutex_unlock(&stream->mutex); } static int cbjack_stream_start(cubeb_stream * stream) { stream->pause = false; stream->state_callback(stream, stream->user_ptr, CUBEB_STATE_STARTED); return CUBEB_OK; } static int cbjack_stream_stop(cubeb_stream * stream) { stream->pause = true; stream->state_callback(stream, stream->user_ptr, CUBEB_STATE_STOPPED); return CUBEB_OK; } static int cbjack_stream_get_position(cubeb_stream * stream, uint64_t * position) { *position = stream->position; return CUBEB_OK; } static int cbjack_stream_set_volume(cubeb_stream * stm, float volume) { stm->volume = volume; return CUBEB_OK; } static int cbjack_stream_get_current_device(cubeb_stream * stm, cubeb_device ** const device) { *device = (cubeb_device *)calloc(1, sizeof(cubeb_device)); if (*device == NULL) return CUBEB_ERROR; const char * j_in = "JACK capture"; const char * j_out = "JACK playback"; const char * empty = ""; if (stm->devs == DUPLEX) { (*device)->input_name = strdup(j_in); (*device)->output_name = strdup(j_out); } else if (stm->devs == IN_ONLY) { (*device)->input_name = strdup(j_in); (*device)->output_name = strdup(empty); } else if (stm->devs == OUT_ONLY) { (*device)->input_name = strdup(empty); (*device)->output_name = strdup(j_out); } return CUBEB_OK; } static int cbjack_stream_device_destroy(cubeb_stream * /*stream*/, cubeb_device * device) { if (device->input_name) free(device->input_name); if (device->output_name) free(device->output_name); free(device); return CUBEB_OK; } static int cbjack_enumerate_devices(cubeb * context, cubeb_device_type type, cubeb_device_collection ** collection) { if (!context) return CUBEB_ERROR; uint32_t rate; uint8_t i = 0; uint8_t j; cbjack_get_preferred_sample_rate(context, &rate); const char * j_in = "JACK capture"; const char * j_out = "JACK playback"; if (type & CUBEB_DEVICE_TYPE_OUTPUT) { context->devinfo[i] = (cubeb_device_info *)malloc(sizeof(cubeb_device_info)); context->devinfo[i]->device_id = strdup(j_out); context->devinfo[i]->devid = context->devinfo[i]->device_id; context->devinfo[i]->friendly_name = strdup(j_out); context->devinfo[i]->group_id = strdup(j_out); context->devinfo[i]->vendor_name = strdup(j_out); context->devinfo[i]->type = CUBEB_DEVICE_TYPE_OUTPUT; context->devinfo[i]->state = CUBEB_DEVICE_STATE_ENABLED; context->devinfo[i]->preferred = CUBEB_DEVICE_PREF_ALL; context->devinfo[i]->format = CUBEB_DEVICE_FMT_F32NE; context->devinfo[i]->default_format = CUBEB_DEVICE_FMT_F32NE; context->devinfo[i]->max_channels = MAX_CHANNELS; context->devinfo[i]->min_rate = rate; context->devinfo[i]->max_rate = rate; context->devinfo[i]->default_rate = rate; context->devinfo[i]->latency_lo = 0; context->devinfo[i]->latency_hi = 0; i++; } if (type & CUBEB_DEVICE_TYPE_INPUT) { context->devinfo[i] = (cubeb_device_info *)malloc(sizeof(cubeb_device_info)); context->devinfo[i]->device_id = strdup(j_in); context->devinfo[i]->devid = context->devinfo[i]->device_id; context->devinfo[i]->friendly_name = strdup(j_in); context->devinfo[i]->group_id = strdup(j_in); context->devinfo[i]->vendor_name = strdup(j_in); context->devinfo[i]->type = CUBEB_DEVICE_TYPE_INPUT; context->devinfo[i]->state = CUBEB_DEVICE_STATE_ENABLED; context->devinfo[i]->preferred = CUBEB_DEVICE_PREF_ALL; context->devinfo[i]->format = CUBEB_DEVICE_FMT_F32NE; context->devinfo[i]->default_format = CUBEB_DEVICE_FMT_F32NE; context->devinfo[i]->max_channels = MAX_CHANNELS; context->devinfo[i]->min_rate = rate; context->devinfo[i]->max_rate = rate; context->devinfo[i]->default_rate = rate; context->devinfo[i]->latency_lo = 0; context->devinfo[i]->latency_hi = 0; i++; } *collection = (cubeb_device_collection *) malloc(sizeof(cubeb_device_collection) + i * sizeof(cubeb_device_info *)); (*collection)->count = i; for (j = 0; j < i; j++) { (*collection)->device[j] = context->devinfo[j]; } return CUBEB_OK; }