#include struct AudioPulseAudio : Audio { ~AudioPulseAudio() { term(); } struct { pa_mainloop* mainloop = nullptr; pa_context* context = nullptr; pa_stream* stream = nullptr; pa_sample_spec spec; pa_buffer_attr buffer_attr; bool first; } device; struct { uint32_t* data = nullptr; size_t size; unsigned offset; } buffer; struct { bool synchronize = false; unsigned frequency = 48000; unsigned latency = 60; } settings; auto cap(const string& name) -> bool { if(name == Audio::Synchronize) return true; if(name == Audio::Frequency) return true; if(name == Audio::Latency) return true; return false; } auto get(const string& name) -> any { if(name == Audio::Synchronize) return settings.synchronize; if(name == Audio::Frequency) return settings.frequency; if(name == Audio::Latency) return settings.latency; return {}; } auto set(const string& name, const any& value) -> bool { if(name == Audio::Synchronize && value.is()) { settings.synchronize = value.get(); return true; } if(name == Audio::Frequency && value.is()) { settings.frequency = value.get(); if(device.stream) { pa_operation_unref(pa_stream_update_sample_rate(device.stream, settings.frequency, NULL, NULL)); } return true; } if(name == Audio::Latency && value.is()) { settings.latency = value.get(); if(device.stream) { device.buffer_attr.tlength = pa_usec_to_bytes(settings.latency * PA_USEC_PER_MSEC, &device.spec); pa_stream_set_buffer_attr(device.stream, &device.buffer_attr, NULL, NULL); } return true; } return false; } auto sample(uint16_t left, uint16_t right) -> void { pa_stream_begin_write(device.stream, (void**)&buffer.data, &buffer.size); buffer.data[buffer.offset++] = left + (right << 16); if((buffer.offset + 1) * pa_frame_size(&device.spec) <= buffer.size) return; while(true) { if(device.first) { device.first = false; pa_mainloop_iterate(device.mainloop, 0, NULL); } else { pa_mainloop_iterate(device.mainloop, 1, NULL); } unsigned length = pa_stream_writable_size(device.stream); if(length >= buffer.offset * pa_frame_size(&device.spec)) break; if(settings.synchronize == false) { buffer.offset = 0; return; } } pa_stream_write(device.stream, (const void*)buffer.data, buffer.offset * pa_frame_size(&device.spec), NULL, 0LL, PA_SEEK_RELATIVE); buffer.data = 0; buffer.offset = 0; } auto clear() -> void { } auto init() -> bool { device.mainloop = pa_mainloop_new(); device.context = pa_context_new(pa_mainloop_get_api(device.mainloop), "ruby::pulseaudio"); pa_context_connect(device.context, NULL, PA_CONTEXT_NOFLAGS, NULL); pa_context_state_t cstate; do { pa_mainloop_iterate(device.mainloop, 1, NULL); cstate = pa_context_get_state(device.context); if(!PA_CONTEXT_IS_GOOD(cstate)) return false; } while(cstate != PA_CONTEXT_READY); device.spec.format = PA_SAMPLE_S16LE; device.spec.channels = 2; device.spec.rate = settings.frequency; device.stream = pa_stream_new(device.context, "audio", &device.spec, NULL); device.buffer_attr.maxlength = -1; device.buffer_attr.tlength = pa_usec_to_bytes(settings.latency * PA_USEC_PER_MSEC, &device.spec); device.buffer_attr.prebuf = -1; device.buffer_attr.minreq = -1; device.buffer_attr.fragsize = -1; pa_stream_flags_t flags = (pa_stream_flags_t)(PA_STREAM_ADJUST_LATENCY | PA_STREAM_VARIABLE_RATE); pa_stream_connect_playback(device.stream, NULL, &device.buffer_attr, flags, NULL, NULL); pa_stream_state_t sstate; do { pa_mainloop_iterate(device.mainloop, 1, NULL); sstate = pa_stream_get_state(device.stream); if(!PA_STREAM_IS_GOOD(sstate)) return false; } while(sstate != PA_STREAM_READY); buffer.size = 960; buffer.offset = 0; device.first = true; return true; } auto term() -> void { if(buffer.data) { pa_stream_cancel_write(device.stream); buffer.data = nullptr; } if(device.stream) { pa_stream_disconnect(device.stream); pa_stream_unref(device.stream); device.stream = nullptr; } if(device.context) { pa_context_disconnect(device.context); pa_context_unref(device.context); device.context = nullptr; } if(device.mainloop) { pa_mainloop_free(device.mainloop); device.mainloop = nullptr; } } };