/* * Copyright (c) 2015 Andrew Kelley * * This file is part of libsoundio, which is MIT licensed. * See http://opensource.org/licenses/MIT */ #include #include #include #include #include #include static int usage(char *exe) { fprintf(stderr, "Usage: %s [options]\n" "Options:\n" " [--backend dummy|alsa|pulseaudio|jack|coreaudio|wasapi]\n" " [--device id]\n" " [--raw]\n" " [--name stream_name]\n" " [--latency seconds]\n" " [--sample-rate hz]\n" , exe); return 1; } static void write_sample_s16ne(char *ptr, double sample) { int16_t *buf = (int16_t *)ptr; double range = (double)INT16_MAX - (double)INT16_MIN; double val = sample * range / 2.0; *buf = val; } static void write_sample_s32ne(char *ptr, double sample) { int32_t *buf = (int32_t *)ptr; double range = (double)INT32_MAX - (double)INT32_MIN; double val = sample * range / 2.0; *buf = val; } static void write_sample_float32ne(char *ptr, double sample) { float *buf = (float *)ptr; *buf = sample; } static void write_sample_float64ne(char *ptr, double sample) { double *buf = (double *)ptr; *buf = sample; } static void (*write_sample)(char *ptr, double sample); static const double PI = 3.14159265358979323846264338328; static double seconds_offset = 0.0; static volatile bool want_pause = false; static void write_callback(struct SoundIoOutStream *outstream, int frame_count_min, int frame_count_max) { double float_sample_rate = outstream->sample_rate; double seconds_per_frame = 1.0 / float_sample_rate; struct SoundIoChannelArea *areas; int err; int frames_left = frame_count_max; for (;;) { int frame_count = frames_left; if ((err = soundio_outstream_begin_write(outstream, &areas, &frame_count))) { fprintf(stderr, "unrecoverable stream error: %s\n", soundio_strerror(err)); exit(1); } if (!frame_count) break; const struct SoundIoChannelLayout *layout = &outstream->layout; double pitch = 440.0; double radians_per_second = pitch * 2.0 * PI; for (int frame = 0; frame < frame_count; frame += 1) { double sample = sin((seconds_offset + frame * seconds_per_frame) * radians_per_second); for (int channel = 0; channel < layout->channel_count; channel += 1) { write_sample(areas[channel].ptr, sample); areas[channel].ptr += areas[channel].step; } } seconds_offset = fmod(seconds_offset + seconds_per_frame * frame_count, 1.0); if ((err = soundio_outstream_end_write(outstream))) { if (err == SoundIoErrorUnderflow) return; fprintf(stderr, "unrecoverable stream error: %s\n", soundio_strerror(err)); exit(1); } frames_left -= frame_count; if (frames_left <= 0) break; } soundio_outstream_pause(outstream, want_pause); } static void underflow_callback(struct SoundIoOutStream *outstream) { static int count = 0; fprintf(stderr, "underflow %d\n", count++); } int main(int argc, char **argv) { char *exe = argv[0]; enum SoundIoBackend backend = SoundIoBackendNone; char *device_id = NULL; bool raw = false; char *stream_name = NULL; double latency = 0.0; int sample_rate = 0; for (int i = 1; i < argc; i += 1) { char *arg = argv[i]; if (arg[0] == '-' && arg[1] == '-') { if (strcmp(arg, "--raw") == 0) { raw = true; } else { i += 1; if (i >= argc) { return usage(exe); } else if (strcmp(arg, "--backend") == 0) { if (strcmp(argv[i], "dummy") == 0) { backend = SoundIoBackendDummy; } else if (strcmp(argv[i], "alsa") == 0) { backend = SoundIoBackendAlsa; } else if (strcmp(argv[i], "pulseaudio") == 0) { backend = SoundIoBackendPulseAudio; } else if (strcmp(argv[i], "jack") == 0) { backend = SoundIoBackendJack; } else if (strcmp(argv[i], "coreaudio") == 0) { backend = SoundIoBackendCoreAudio; } else if (strcmp(argv[i], "wasapi") == 0) { backend = SoundIoBackendWasapi; } else { fprintf(stderr, "Invalid backend: %s\n", argv[i]); return 1; } } else if (strcmp(arg, "--device") == 0) { device_id = argv[i]; } else if (strcmp(arg, "--name") == 0) { stream_name = argv[i]; } else if (strcmp(arg, "--latency") == 0) { latency = atof(argv[i]); } else if (strcmp(arg, "--sample-rate") == 0) { sample_rate = atoi(argv[i]); } else { return usage(exe); } } } else { return usage(exe); } } struct SoundIo *soundio = soundio_create(); if (!soundio) { fprintf(stderr, "out of memory\n"); return 1; } int err = (backend == SoundIoBackendNone) ? soundio_connect(soundio) : soundio_connect_backend(soundio, backend); if (err) { fprintf(stderr, "Unable to connect to backend: %s\n", soundio_strerror(err)); return 1; } fprintf(stderr, "Backend: %s\n", soundio_backend_name(soundio->current_backend)); soundio_flush_events(soundio); int selected_device_index = -1; if (device_id) { int device_count = soundio_output_device_count(soundio); for (int i = 0; i < device_count; i += 1) { struct SoundIoDevice *device = soundio_get_output_device(soundio, i); bool select_this_one = strcmp(device->id, device_id) == 0 && device->is_raw == raw; soundio_device_unref(device); if (select_this_one) { selected_device_index = i; break; } } } else { selected_device_index = soundio_default_output_device_index(soundio); } if (selected_device_index < 0) { fprintf(stderr, "Output device not found\n"); return 1; } struct SoundIoDevice *device = soundio_get_output_device(soundio, selected_device_index); if (!device) { fprintf(stderr, "out of memory\n"); return 1; } fprintf(stderr, "Output device: %s\n", device->name); if (device->probe_error) { fprintf(stderr, "Cannot probe device: %s\n", soundio_strerror(device->probe_error)); return 1; } struct SoundIoOutStream *outstream = soundio_outstream_create(device); if (!outstream) { fprintf(stderr, "out of memory\n"); return 1; } outstream->write_callback = write_callback; outstream->underflow_callback = underflow_callback; outstream->name = stream_name; outstream->software_latency = latency; outstream->sample_rate = sample_rate; if (soundio_device_supports_format(device, SoundIoFormatFloat32NE)) { outstream->format = SoundIoFormatFloat32NE; write_sample = write_sample_float32ne; } else if (soundio_device_supports_format(device, SoundIoFormatFloat64NE)) { outstream->format = SoundIoFormatFloat64NE; write_sample = write_sample_float64ne; } else if (soundio_device_supports_format(device, SoundIoFormatS32NE)) { outstream->format = SoundIoFormatS32NE; write_sample = write_sample_s32ne; } else if (soundio_device_supports_format(device, SoundIoFormatS16NE)) { outstream->format = SoundIoFormatS16NE; write_sample = write_sample_s16ne; } else { fprintf(stderr, "No suitable device format available.\n"); return 1; } if ((err = soundio_outstream_open(outstream))) { fprintf(stderr, "unable to open device: %s", soundio_strerror(err)); return 1; } fprintf(stderr, "Software latency: %f\n", outstream->software_latency); fprintf(stderr, "'p\\n' - pause\n" "'u\\n' - unpause\n" "'P\\n' - pause from within callback\n" "'c\\n' - clear buffer\n" "'q\\n' - quit\n"); if (outstream->layout_error) fprintf(stderr, "unable to set channel layout: %s\n", soundio_strerror(outstream->layout_error)); if ((err = soundio_outstream_start(outstream))) { fprintf(stderr, "unable to start device: %s\n", soundio_strerror(err)); return 1; } for (;;) { soundio_flush_events(soundio); int c = getc(stdin); if (c == 'p') { fprintf(stderr, "pausing result: %s\n", soundio_strerror(soundio_outstream_pause(outstream, true))); } else if (c == 'P') { want_pause = true; } else if (c == 'u') { want_pause = false; fprintf(stderr, "unpausing result: %s\n", soundio_strerror(soundio_outstream_pause(outstream, false))); } else if (c == 'c') { fprintf(stderr, "clear buffer result: %s\n", soundio_strerror(soundio_outstream_clear_buffer(outstream))); } else if (c == 'q') { break; } else if (c == '\r' || c == '\n') { // ignore } else { fprintf(stderr, "Unrecognized command: %c\n", c); } } soundio_outstream_destroy(outstream); soundio_device_unref(device); soundio_destroy(soundio); return 0; }