#include "../qcommon/q_shared.h" #include "../client/snd_local.h" #include // @TODO: cvars for freq and samples? // @TODO: cvar for the device name? ("alsa", "pulseaudio", etc) static const int bits = 16; static const int channels = 2; static const int freq = 44100; // got issues with 22050 in the VM static const int samples = 2048; static const SDL_AudioFormat format = AUDIO_S16SYS; struct audio_t { qbool valid; int q3SamplePos; int q3Bytes; SDL_AudioDeviceID device; }; static audio_t audio; static void FillAudioBufferCallback( void* userData, Uint8* sdlBuffer, int sdlBytesToWrite ) { if (sdlBuffer == NULL || sdlBytesToWrite == 0) return; if (!audio.valid) { memset(sdlBuffer, 0, sdlBytesToWrite); return; } // fix up sample offset if needed const int bytesPerSample = dma.samplebits / 8; int q3BytePos = audio.q3SamplePos * bytesPerSample; if (q3BytePos >= audio.q3Bytes) { q3BytePos = 0; audio.q3SamplePos = 0; } // compute the sizes for the memcpy call(s) int q3BytesToEnd = audio.q3Bytes - q3BytePos; int bytes1 = sdlBytesToWrite; int bytes2 = 0; if (bytes1 > q3BytesToEnd) { bytes1 = q3BytesToEnd; bytes2 = sdlBytesToWrite - q3BytesToEnd; } // copy the new mixed data to the device memcpy(sdlBuffer, dma.buffer + q3BytePos, bytes1); if (bytes2 > 0) { memcpy(sdlBuffer + bytes1, dma.buffer, bytes2); audio.q3SamplePos = bytes2 / bytesPerSample; } else { audio.q3SamplePos += bytes1 / bytesPerSample; } // fix up sample offset if needed if (audio.q3SamplePos * bytesPerSample >= audio.q3Bytes) audio.q3SamplePos = 0; } qbool Sys_S_Init() { if (audio.valid) return qtrue; if (SDL_Init(SDL_INIT_AUDIO) < 0) { Com_Printf("SDL_Init failed: %s\n", SDL_GetError()); return qfalse; } // open the default audio device SDL_AudioSpec desired; memset(&desired, 0, sizeof(desired)); desired.freq = freq; desired.format = format; desired.samples = samples; desired.channels = channels; desired.callback = &FillAudioBufferCallback; SDL_AudioSpec obtained; memset(&obtained, 0, sizeof(obtained)); audio.device = SDL_OpenAudioDevice(NULL, 0, &desired, &obtained, 0); if (audio.device == 0) { Com_Printf("SDL_OpenAudioDevice failed: %s\n", SDL_GetError()); Sys_S_Shutdown(); return qfalse; } // save all the data we need to const int q3Samples = obtained.samples * 16; audio.q3SamplePos = 0; dma.samplebits = obtained.format & 0xFF; dma.channels = obtained.channels; dma.samples = q3Samples; dma.submission_chunk = 1; dma.speed = obtained.freq; audio.q3Bytes = dma.samples * (dma.samplebits / 8); dma.buffer = (byte*)calloc(1, audio.q3Bytes); audio.valid = qtrue; // opened devices are always paused by default SDL_PauseAudioDevice(audio.device, 0); return qtrue; } int Sys_S_GetDMAPos() { if (!audio.valid) return 0; return audio.q3SamplePos; } void Sys_S_Shutdown() { if (audio.device != 0) { SDL_PauseAudioDevice(audio.device, 1); SDL_CloseAudioDevice(audio.device); audio.device = 0; } SDL_QuitSubSystem(SDL_INIT_AUDIO); free(dma.buffer); dma.buffer = NULL; audio.q3SamplePos = 0; audio.q3Bytes = 0; audio.valid = qfalse; } void Sys_S_Submit() { if (!audio.valid) return; // let SDL call our registered callback function again SDL_UnlockAudioDevice(audio.device); } void Sys_S_BeginPainting() { if (!audio.valid) return; // prevent SDL from calling our registered callback function SDL_LockAudioDevice(audio.device); } void sdl_MuteAudio( qbool mute ) { if (!audio.valid) return; const qbool playing = SDL_GetAudioDeviceStatus(audio.device) == SDL_AUDIO_PLAYING; if (mute && playing) { SDL_PauseAudioDevice(audio.device, 1); } else if (!mute && !playing) { S_ClearSoundBuffer(); SDL_PauseAudioDevice(audio.device, 0); } }