/*****************************************************************************\ Snes9x - Portable Super Nintendo Entertainment System (TM) emulator. This file is licensed under the Snes9x License. For further information, consult the LICENSE file in the root directory. \*****************************************************************************/ #include "CWaveOut.h" #include "../snes9x.h" #include "../apu/apu.h" #include "wsnes9x.h" CWaveOut::CWaveOut(void) { hWaveOut = NULL; initDone = false; } CWaveOut::~CWaveOut(void) { DeInitSoundOutput(); } void CALLBACK WaveCallback(HWAVEOUT hWave, UINT uMsg, DWORD_PTR dwUser, DWORD_PTR dw1, DWORD_PTR dw2) { if (uMsg == WOM_DONE) { InterlockedDecrement(((volatile LONG *)dwUser)); SetEvent(GUI.SoundSyncEvent); } } bool CWaveOut::SetupSound() { WAVEFORMATEX wfx; wfx.wFormatTag = WAVE_FORMAT_PCM; wfx.nChannels = 2; wfx.nSamplesPerSec = Settings.SoundPlaybackRate; wfx.nBlockAlign = 2 * 2; wfx.wBitsPerSample = 16; wfx.nAvgBytesPerSec = wfx.nSamplesPerSec * wfx.nBlockAlign; wfx.cbSize = 0; // subtract -1, we added "Default" as first index - Default will yield -1, which is WAVE_MAPPER int device_index = FindDeviceIndex(GUI.AudioDevice) - 1; waveOutOpen(&hWaveOut, device_index, &wfx, (DWORD_PTR)WaveCallback, (DWORD_PTR)&bufferCount, CALLBACK_FUNCTION); UINT32 blockTime = GUI.SoundBufferSize / blockCount; singleBufferSamples = (Settings.SoundPlaybackRate * blockTime) / 1000; if (singleBufferSamples < 256) singleBufferSamples = 256; singleBufferSamples *= 2; singleBufferBytes = singleBufferSamples * 2; sumBufferSize = singleBufferBytes * blockCount; writeOffset = 0; partialOffset = 0; waveHeaders.resize(blockCount); for (auto &w : waveHeaders) { w.lpData = (LPSTR)LocalAlloc(LMEM_FIXED, singleBufferBytes); w.dwBufferLength = singleBufferBytes; w.dwBytesRecorded = 0; w.dwUser = 0; w.dwFlags = 0; w.dwLoops = 0; w.lpNext = 0; w.reserved = 0; waveOutPrepareHeader(hWaveOut, &w, sizeof(WAVEHDR)); } initDone = true; return true; } void CWaveOut::SetVolume(double volume) { uint32 volumeout = (uint32) (volume * 0xffff); waveOutSetVolume(hWaveOut, volumeout + (volumeout << 16)); } void CWaveOut::BeginPlayback() { waveOutRestart(hWaveOut); } bool CWaveOut::InitSoundOutput() { return true; } void CWaveOut::DeInitSoundOutput() { if (!initDone) return; StopPlayback(); waveOutReset(hWaveOut); if (!waveHeaders.empty()) { for (auto &w : waveHeaders) { waveOutUnprepareHeader(hWaveOut, &w, sizeof(WAVEHDR)); LocalFree(w.lpData); } } waveHeaders.clear(); waveOutClose(hWaveOut); initDone = false; } void CWaveOut::StopPlayback() { waveOutPause(hWaveOut); } int CWaveOut::GetAvailableBytes() { return ((blockCount - bufferCount) * singleBufferBytes) - partialOffset; } // Fill the set of blocks preceding writeOffset with silence and write them // to the output to get the buffer back to 50% void CWaveOut::RecoverFromUnderrun() { writeOffset = (writeOffset - (blockCount / 2) + blockCount) % blockCount; for (int i = 0; i < blockCount / 2; i++) { memset(waveHeaders[writeOffset].lpData, 0, singleBufferBytes); waveOutWrite(hWaveOut, &waveHeaders[writeOffset], sizeof(WAVEHDR)); InterlockedIncrement(&bufferCount); writeOffset++; writeOffset %= blockCount; } } void CWaveOut::ProcessSound() { int freeBytes = ((blockCount - bufferCount) * singleBufferBytes) - partialOffset; if (bufferCount == 0) RecoverFromUnderrun(); if (Settings.DynamicRateControl) { S9xUpdateDynamicRate(freeBytes, sumBufferSize); } UINT32 availableSamples; availableSamples = S9xGetSampleCount(); if (Settings.DynamicRateControl && !Settings.SoundSync) { // Using rate control, we should always keep the emulator's sound buffers empty to // maintain an accurate measurement. if (availableSamples > (freeBytes >> 1)) { S9xClearSamples(); return; } } if (!initDone) return; if(Settings.SoundSync && !Settings.TurboMode && !Settings.Mute) { // no sound sync when speed is not set to 100% while((freeBytes >> 1) < availableSamples) { ResetEvent(GUI.SoundSyncEvent); if(!GUI.AllowSoundSync || WaitForSingleObject(GUI.SoundSyncEvent, 1000) != WAIT_OBJECT_0) { S9xClearSamples(); return; } freeBytes = GetAvailableBytes(); } } if (partialOffset != 0) { UINT32 samplesleftinblock = (singleBufferBytes - partialOffset) >> 1; BYTE *offsetBuffer = (BYTE *)waveHeaders[writeOffset].lpData + partialOffset; if (availableSamples <= samplesleftinblock) { S9xMixSamples(offsetBuffer, availableSamples); partialOffset += availableSamples << 1; availableSamples = 0; } else { S9xMixSamples(offsetBuffer, samplesleftinblock); partialOffset = 0; availableSamples -= samplesleftinblock; waveOutWrite(hWaveOut, &waveHeaders[writeOffset], sizeof(WAVEHDR)); InterlockedIncrement(&bufferCount); writeOffset++; writeOffset %= blockCount; } } while (availableSamples >= singleBufferSamples && bufferCount < blockCount) { BYTE *curBuffer = (BYTE *)waveHeaders[writeOffset].lpData; S9xMixSamples(curBuffer, singleBufferSamples); waveOutWrite(hWaveOut, &waveHeaders[writeOffset], sizeof(WAVEHDR)); InterlockedIncrement(&bufferCount); writeOffset++; writeOffset %= blockCount; availableSamples -= singleBufferSamples; } if (availableSamples > 0 && bufferCount < blockCount) { S9xMixSamples((BYTE *)waveHeaders[writeOffset].lpData, availableSamples); partialOffset = availableSamples << 1; } } std::vector CWaveOut::GetDeviceList() { std::vector device_list; UINT num_devices = waveOutGetNumDevs(); device_list.push_back(_T("Default")); for (unsigned int i = 0; i < num_devices; i++) { WAVEOUTCAPS caps; if(waveOutGetDevCaps(i, &caps, sizeof(WAVEOUTCAPS)) == MMSYSERR_NOERROR) { device_list.push_back(caps.szPname); } } return device_list; } int CWaveOut::FindDeviceIndex(TCHAR *audio_device) { std::vector device_list = GetDeviceList(); int index = 0; for (int i = 0; i < device_list.size(); i++) { if (_tcsstr(device_list[i].c_str(), audio_device) != NULL) { index = i; break; } } return index; }