ref: aac1c9c844bb05bf39b8659b2e9a8641e387ce97
dir: /src/Backends/Audio/SoftwareMixer/miniaudio.cpp/
#include "Backend.h" #include <stddef.h> #include <string.h> #define MINIAUDIO_IMPLEMENTATION #define MA_NO_DECODING #define MA_NO_ENCODING #define MA_NO_WAV #define MA_NO_FLAC #define MA_NO_MP3 #define MA_API static #include "../../../../external/miniaudio.h" #include "../../Misc.h" #define MIN(a, b) ((a) < (b) ? (a) : (b)) static void (*parent_callback)(long *stream, size_t frames_total); static ma_context context; static ma_device device; static ma_mutex mutex; static ma_mutex organya_mutex; static void Callback(ma_device *device, void *output_stream, const void *input_stream, ma_uint32 frames_total) { (void)device; (void)input_stream; short *stream = (short*)output_stream; size_t frames_done = 0; while (frames_done != frames_total) { long mix_buffer[0x800 * 2]; // 2 because stereo size_t subframes = MIN(0x800, frames_total - frames_done); memset(mix_buffer, 0, subframes * sizeof(long) * 2); parent_callback(mix_buffer, subframes); for (size_t i = 0; i < subframes * 2; ++i) { if (mix_buffer[i] > 0x7FFF) *stream++ = 0x7FFF; else if (mix_buffer[i] < -0x7FFF) *stream++ = -0x7FFF; else *stream++ = mix_buffer[i]; } frames_done += subframes; } } unsigned long SoftwareMixerBackend_Init(void (*callback)(long *stream, size_t frames_total)) { ma_device_config config = ma_device_config_init(ma_device_type_playback); config.playback.pDeviceID = NULL; config.playback.format = ma_format_s16; config.playback.channels = 2; config.sampleRate = 0; // Let miniaudio decide what sample rate to use config.dataCallback = Callback; config.pUserData = NULL; ma_result return_value; return_value = ma_context_init(NULL, 0, NULL, &context); if (return_value == MA_SUCCESS) { return_value = ma_device_init(&context, &config, &device); if (return_value == MA_SUCCESS) { return_value = ma_mutex_init(&mutex); if (return_value == MA_SUCCESS) { return_value = ma_mutex_init(&organya_mutex); if (return_value == MA_SUCCESS) { parent_callback = callback; return device.sampleRate; } else { Backend_PrintError("Failed to create organya mutex: %s", ma_result_description(return_value)); } ma_mutex_uninit(&mutex); } else { Backend_PrintError("Failed to create mutex: %s", ma_result_description(return_value)); } ma_device_uninit(&device); } else { Backend_PrintError("Failed to initialize playback device: %s", ma_result_description(return_value)); } ma_context_uninit(&context); } else { Backend_PrintError("Failed to initialize context: %s", ma_result_description(return_value)); } return 0; } void SoftwareMixerBackend_Deinit(void) { ma_result return_value = ma_device_stop(&device); if (return_value != MA_SUCCESS) Backend_PrintError("Failed to stop playback device: %s", ma_result_description(return_value)); ma_mutex_uninit(&organya_mutex); ma_mutex_uninit(&mutex); ma_device_uninit(&device); ma_context_uninit(&context); } bool SoftwareMixerBackend_Start(void) { ma_result return_value = ma_device_start(&device); if (return_value != MA_SUCCESS) { Backend_PrintError("Failed to start playback device: %s", ma_result_description(return_value)); return false; } return true; } void SoftwareMixerBackend_LockMixerMutex(void) { ma_mutex_lock(&mutex); } void SoftwareMixerBackend_UnlockMixerMutex(void) { ma_mutex_unlock(&mutex); } void SoftwareMixerBackend_LockOrganyaMutex(void) { ma_mutex_lock(&organya_mutex); } void SoftwareMixerBackend_UnlockOrganyaMutex(void) { ma_mutex_unlock(&organya_mutex); }