Mercurial > fife-parpg
view ext/openal-soft/Alc/winmm.c @ 33:112fc4af772d
moved grid ownership to model in similar way as with pathers
author | jasoka@33b003aa-7bff-0310-803a-e67f0ece8222 |
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date | Fri, 11 Jul 2008 15:42:54 +0000 |
parents | 4a0efb7baf70 |
children |
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/** * OpenAL cross platform audio library * Copyright (C) 1999-2007 by authors. * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include <stdlib.h> #include <stdio.h> #include <memory.h> #include <windows.h> #include <mmsystem.h> #include "alMain.h" #include "AL/al.h" #include "AL/alc.h" typedef struct { // MMSYSTEM Capture Device ALboolean bWaveInShutdown; HANDLE hWaveInHdrEvent; HANDLE hWaveInThreadEvent; HANDLE hWaveInThread; DWORD ulWaveInThreadID; ALint lWaveInBuffersCommitted; HWAVEIN hWaveInHandle; WAVEHDR WaveInBuffer[4]; ALCchar *pCapturedSampleData; ALuint ulCapturedDataSize; ALuint ulReadCapturedDataPos; ALuint ulWriteCapturedDataPos; } WinMMData; static ALCchar *CaptureDeviceList[16]; /* WaveInProc Posts a message to 'CaptureThreadProc' everytime a WaveIn Buffer is completed and returns to the application (with more data) */ static void CALLBACK WaveInProc(HWAVEIN hDevice,UINT uMsg,DWORD_PTR dwInstance,DWORD_PTR dwParam1,DWORD_PTR dwParam2) { ALCdevice *pDevice = (ALCdevice *)dwInstance; WinMMData *pData = pDevice->ExtraData; (void)hDevice; (void)dwParam2; if ((uMsg==WIM_DATA)) { // Decrement number of buffers in use pData->lWaveInBuffersCommitted--; if (pData->bWaveInShutdown == AL_FALSE) { // Notify Wave Processor Thread that a Wave Header has returned PostThreadMessage(pData->ulWaveInThreadID,uMsg,0,dwParam1); } else { if (pData->lWaveInBuffersCommitted == 0) { // Signal Wave Buffers Returned event if (pData->hWaveInHdrEvent) SetEvent(pData->hWaveInHdrEvent); // Post 'Quit' Message to WaveIn Processor Thread PostThreadMessage(pData->ulWaveInThreadID,WM_QUIT,0,0); } } } } /* CaptureThreadProc Used by "MMSYSTEM" Device. Called when a WaveIn buffer had been filled with new audio data. */ DWORD WINAPI CaptureThreadProc(LPVOID lpParameter) { ALCdevice *pDevice = (ALCdevice*)lpParameter; WinMMData *pData = pDevice->ExtraData; ALuint ulOffset, ulMaxSize, ulSection; LPWAVEHDR pWaveHdr; MSG msg; while (GetMessage(&msg, NULL, 0, 0)) { if ((msg.message==WIM_DATA)&&(!pData->bWaveInShutdown)) { SuspendContext(NULL); pWaveHdr = ((LPWAVEHDR)msg.lParam); // Calculate offset in local buffer to write data to ulOffset = pData->ulWriteCapturedDataPos % pData->ulCapturedDataSize; if ((ulOffset + pWaveHdr->dwBytesRecorded) > pData->ulCapturedDataSize) { ulSection = pData->ulCapturedDataSize - ulOffset; memcpy(pData->pCapturedSampleData + ulOffset, pWaveHdr->lpData, ulSection); memcpy(pData->pCapturedSampleData, pWaveHdr->lpData + ulSection, pWaveHdr->dwBytesRecorded - ulSection); } else { memcpy(pData->pCapturedSampleData + ulOffset, pWaveHdr->lpData, pWaveHdr->dwBytesRecorded); } pData->ulWriteCapturedDataPos += pWaveHdr->dwBytesRecorded; if (pData->ulWriteCapturedDataPos > (pData->ulReadCapturedDataPos + pData->ulCapturedDataSize)) { // Application has not read enough audio data from the capture buffer so data has been // overwritten. Reset ReadPosition. pData->ulReadCapturedDataPos = pData->ulWriteCapturedDataPos - pData->ulCapturedDataSize; } // To prevent an over-flow prevent the offset values from getting too large ulMaxSize = pData->ulCapturedDataSize << 4; if ((pData->ulReadCapturedDataPos > ulMaxSize) && (pData->ulWriteCapturedDataPos > ulMaxSize)) { pData->ulReadCapturedDataPos -= ulMaxSize; pData->ulWriteCapturedDataPos -= ulMaxSize; } // Send buffer back to capture more data waveInAddBuffer(pData->hWaveInHandle,pWaveHdr,sizeof(WAVEHDR)); pData->lWaveInBuffersCommitted++; ProcessContext(NULL); } } // Signal Wave Thread completed event if (pData->hWaveInThreadEvent) SetEvent(pData->hWaveInThreadEvent); ExitThread(0); return 0; } static ALCboolean WinMMOpenPlayback(ALCdevice *device, const ALCchar *deviceName) { (void)device; (void)deviceName; return ALC_FALSE; } static void WinMMClosePlayback(ALCdevice *device) { (void)device; } static ALCboolean WinMMOpenCapture(ALCdevice *pDevice, const ALCchar *deviceName, ALCuint frequency, ALCenum format, ALCsizei SampleSize) { WAVEFORMATEX wfexCaptureFormat; WinMMData *pData = NULL; ALint lDeviceID = 0; ALint lBufferSize; ALint i; (void)format; // Find the Device ID matching the deviceName if valid if (deviceName) { for(i = 0;CaptureDeviceList[i];i++) { if (!strcmp(deviceName, CaptureDeviceList[i])) { lDeviceID = i; break; } } if(!CaptureDeviceList[i]) return ALC_FALSE; } pDevice->szDeviceName = CaptureDeviceList[lDeviceID]; pData = calloc(1, sizeof(*pData)); if(!pData) { SetALCError(ALC_OUT_OF_MEMORY); return ALC_FALSE; } memset(&wfexCaptureFormat, 0, sizeof(WAVEFORMATEX)); wfexCaptureFormat.wFormatTag = WAVE_FORMAT_PCM; wfexCaptureFormat.nChannels = aluChannelsFromFormat(pDevice->Format); wfexCaptureFormat.wBitsPerSample = aluBytesFromFormat(pDevice->Format) * 8; wfexCaptureFormat.nBlockAlign = wfexCaptureFormat.wBitsPerSample * wfexCaptureFormat.nChannels / 8; wfexCaptureFormat.nSamplesPerSec = frequency; wfexCaptureFormat.nAvgBytesPerSec = wfexCaptureFormat.nSamplesPerSec * wfexCaptureFormat.nBlockAlign; wfexCaptureFormat.cbSize = 0; if (waveInOpen(&pData->hWaveInHandle, lDeviceID, &wfexCaptureFormat, (DWORD_PTR)&WaveInProc, (DWORD_PTR)pDevice, CALLBACK_FUNCTION) != MMSYSERR_NOERROR) goto failure; pData->hWaveInHdrEvent = CreateEvent(NULL, AL_TRUE, AL_FALSE, "WaveInAllHeadersReturned"); if (pData->hWaveInHdrEvent == NULL) goto failure; pData->hWaveInThreadEvent = CreateEvent(NULL, AL_TRUE, AL_FALSE, "WaveInThreadDestroyed"); if (pData->hWaveInThreadEvent == NULL) goto failure; // Allocate circular memory buffer for the captured audio pData->ulCapturedDataSize = SampleSize * wfexCaptureFormat.nBlockAlign; // Make sure circular buffer is at least 100ms in size (and an exact multiple of // the block alignment if (pData->ulCapturedDataSize < (wfexCaptureFormat.nAvgBytesPerSec / 10)) { pData->ulCapturedDataSize = wfexCaptureFormat.nAvgBytesPerSec / 10; pData->ulCapturedDataSize -= (pData->ulCapturedDataSize % wfexCaptureFormat.nBlockAlign); } pData->pCapturedSampleData = (ALCchar*)malloc(pData->ulCapturedDataSize); pData->lWaveInBuffersCommitted=0; // Create 4 Buffers of 50ms each lBufferSize = wfexCaptureFormat.nAvgBytesPerSec / 20; lBufferSize -= (lBufferSize % wfexCaptureFormat.nBlockAlign); for (i=0;i<4;i++) { memset(&pData->WaveInBuffer[i], 0, sizeof(WAVEHDR)); pData->WaveInBuffer[i].dwBufferLength = lBufferSize; pData->WaveInBuffer[i].lpData = calloc(1,pData->WaveInBuffer[i].dwBufferLength); pData->WaveInBuffer[i].dwFlags = 0; pData->WaveInBuffer[i].dwLoops = 0; waveInPrepareHeader(pData->hWaveInHandle, &pData->WaveInBuffer[i], sizeof(WAVEHDR)); waveInAddBuffer(pData->hWaveInHandle, &pData->WaveInBuffer[i], sizeof(WAVEHDR)); pData->lWaveInBuffersCommitted++; } pData->ulReadCapturedDataPos = 0; pData->ulWriteCapturedDataPos = 0; pDevice->ExtraData = pData; pData->hWaveInThread = CreateThread(NULL, 0, (LPTHREAD_START_ROUTINE)CaptureThreadProc, (LPVOID)pDevice, 0, &pData->ulWaveInThreadID); if (pData->hWaveInThread == NULL) goto failure; return ALC_TRUE; failure: for (i=0;i<4;i++) { if(pData->WaveInBuffer[i].lpData) { waveInUnprepareHeader(pData->hWaveInHandle, &pData->WaveInBuffer[i], sizeof(WAVEHDR)); free(pData->WaveInBuffer[i].lpData); } } free(pData->pCapturedSampleData); if(pData->hWaveInHandle) waveInClose(pData->hWaveInHandle); if(pData->hWaveInThread) CloseHandle(pData->hWaveInThread); if (pData->hWaveInHdrEvent) CloseHandle(pData->hWaveInHdrEvent); if (pData->hWaveInThreadEvent) CloseHandle(pData->hWaveInThreadEvent); free(pData); return ALC_FALSE; } static void WinMMCloseCapture(ALCdevice *pDevice) { WinMMData *pData = (WinMMData*)pDevice->ExtraData; int i; // Call waveOutReset to shutdown wave device pData->bWaveInShutdown = AL_TRUE; waveInReset(pData->hWaveInHandle); // Wait for signal that all Wave Buffers have returned WaitForSingleObjectEx(pData->hWaveInHdrEvent, 5000, FALSE); // Wait for signal that Wave Thread has been destroyed WaitForSingleObjectEx(pData->hWaveInThreadEvent, 5000, FALSE); // Release the wave buffers for (i=0;i<4;i++) { waveInUnprepareHeader(pData->hWaveInHandle, &pData->WaveInBuffer[i], sizeof(WAVEHDR)); free(pData->WaveInBuffer[i].lpData); } // Free Audio Buffer data free(pData->pCapturedSampleData); pData->pCapturedSampleData = NULL; // Close the Wave device waveInClose(pData->hWaveInHandle); pData->hWaveInHandle = 0; CloseHandle(pData->hWaveInThread); pData->hWaveInThread = 0; if (pData->hWaveInHdrEvent) { CloseHandle(pData->hWaveInHdrEvent); pData->hWaveInHdrEvent = 0; } if (pData->hWaveInThreadEvent) { CloseHandle(pData->hWaveInThreadEvent); pData->hWaveInThreadEvent = 0; } free(pData); pDevice->ExtraData = NULL; } static void WinMMStartCapture(ALCdevice *pDevice) { WinMMData *pData = (WinMMData*)pDevice->ExtraData; waveInStart(pData->hWaveInHandle); } static void WinMMStopCapture(ALCdevice *pDevice) { WinMMData *pData = (WinMMData*)pDevice->ExtraData; waveInStop(pData->hWaveInHandle); } static void WinMMCaptureSamples(ALCdevice *pDevice, ALCvoid *pBuffer, ALCuint lSamples) { WinMMData *pData = (WinMMData*)pDevice->ExtraData; ALuint ulSamples = (unsigned long)lSamples; ALuint ulBytes, ulBytesToCopy; ALuint ulCapturedSamples; ALuint ulReadOffset; ALuint frameSize = aluBytesFromFormat(pDevice->Format) * aluChannelsFromFormat(pDevice->Format); // Check that we have the requested numbers of Samples ulCapturedSamples = (pData->ulWriteCapturedDataPos - pData->ulReadCapturedDataPos) / frameSize; if(ulSamples > ulCapturedSamples) { SetALCError(ALC_INVALID_VALUE); return; } ulBytes = ulSamples * frameSize; // Get Read Offset ulReadOffset = (pData->ulReadCapturedDataPos % pData->ulCapturedDataSize); // Check for wrap-around condition if ((ulReadOffset + ulBytes) > pData->ulCapturedDataSize) { // Copy data from last Read position to end of data ulBytesToCopy = pData->ulCapturedDataSize - ulReadOffset; memcpy(pBuffer, pData->pCapturedSampleData + ulReadOffset, ulBytesToCopy); // Copy rest of the data from the start of the captured data memcpy(((char *)pBuffer) + ulBytesToCopy, pData->pCapturedSampleData, ulBytes - ulBytesToCopy); } else { // Copy data from the read position in the captured data memcpy(pBuffer, pData->pCapturedSampleData + ulReadOffset, ulBytes); } // Update Read Position pData->ulReadCapturedDataPos += ulBytes; } static ALCuint WinMMAvailableSamples(ALCdevice *pDevice) { WinMMData *pData = (WinMMData*)pDevice->ExtraData; ALCuint lCapturedBytes = (pData->ulWriteCapturedDataPos - pData->ulReadCapturedDataPos); return lCapturedBytes / (aluBytesFromFormat(pDevice->Format) * aluChannelsFromFormat(pDevice->Format)); } BackendFuncs WinMMFuncs = { WinMMOpenPlayback, WinMMClosePlayback, WinMMOpenCapture, WinMMCloseCapture, WinMMStartCapture, WinMMStopCapture, WinMMCaptureSamples, WinMMAvailableSamples }; void alcWinMMInit(BackendFuncs *FuncList) { ALint lNumDevs; ALint lLoop; *FuncList = WinMMFuncs; lNumDevs = waveInGetNumDevs(); for (lLoop = 0; lLoop < lNumDevs; lLoop++) { WAVEINCAPS WaveInCaps; if(waveInGetDevCaps(lLoop, &WaveInCaps, sizeof(WAVEINCAPS)) == MMSYSERR_NOERROR) { char name[128]; snprintf(name, sizeof(name), "WaveIn on %s", WaveInCaps.szPname); CaptureDeviceList[lLoop] = AppendCaptureDeviceList(name); } } }