/* $Id: AudioMixBuffer.cpp 82255 2019-11-27 23:20:26Z vboxsync $ */ /** @file * Audio mixing buffer for converting reading/writing audio data. */ /* * Copyright (C) 2014-2019 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ #define LOG_GROUP LOG_GROUP_AUDIO_MIXER_BUFFER #include #if 0 /* * AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA enables dumping the raw PCM data * to a file on the host. Be sure to adjust AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH * to your needs before using this! */ # define AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA # ifdef RT_OS_WINDOWS # define AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH "c:\\temp\\" # else # define AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH "/tmp/" # endif /* Warning: Enabling this will generate *huge* logs! */ //# define AUDIOMIXBUF_DEBUG_MACROS #endif #include #include #ifdef AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA # include #endif #include #include /* For RT_BZERO. */ #ifdef VBOX_AUDIO_TESTCASE # define LOG_ENABLED # include #endif #include #include "AudioMixBuffer.h" #ifndef VBOX_AUDIO_TESTCASE # ifdef DEBUG # define AUDMIXBUF_LOG(x) LogFlowFunc(x) # else # define AUDMIXBUF_LOG(x) do {} while (0) # endif #else /* VBOX_AUDIO_TESTCASE */ # define AUDMIXBUF_LOG(x) RTPrintf x #endif #ifdef DEBUG DECLINLINE(void) audioMixBufDbgPrintInternal(PPDMAUDIOMIXBUF pMixBuf, const char *pszFunc); DECL_FORCE_INLINE(bool) audioMixBufDbgValidate(PPDMAUDIOMIXBUF pMixBuf); #endif /* * Soft Volume Control * * The external code supplies an 8-bit volume (attenuation) value in the * 0 .. 255 range. This represents 0 to -96dB attenuation where an input * value of 0 corresponds to -96dB and 255 corresponds to 0dB (unchanged). * * Each step thus corresponds to 96 / 256 or 0.375dB. Every 6dB (16 steps) * represents doubling the sample value. * * For internal use, the volume control needs to be converted to a 16-bit * (sort of) exponential value between 1 and 65536. This is used with fixed * point arithmetic such that 65536 means 1.0 and 1 means 1/65536. * * For actual volume calculation, 33.31 fixed point is used. Maximum (or * unattenuated) volume is represented as 0x40000000; conveniently, this * value fits into a uint32_t. * * To enable fast processing, the maximum volume must be a power of two * and must not have a sign when converted to int32_t. While 0x80000000 * violates these constraints, 0x40000000 does not. */ /** Logarithmic/exponential volume conversion table. */ static uint32_t s_aVolumeConv[256] = { 1, 1, 1, 1, 1, 1, 1, 1, /* 7 */ 1, 2, 2, 2, 2, 2, 2, 2, /* 15 */ 2, 2, 2, 2, 2, 3, 3, 3, /* 23 */ 3, 3, 3, 3, 4, 4, 4, 4, /* 31 */ 4, 4, 5, 5, 5, 5, 5, 6, /* 39 */ 6, 6, 6, 7, 7, 7, 8, 8, /* 47 */ 8, 9, 9, 10, 10, 10, 11, 11, /* 55 */ 12, 12, 13, 13, 14, 15, 15, 16, /* 63 */ 17, 17, 18, 19, 20, 21, 22, 23, /* 71 */ 24, 25, 26, 27, 28, 29, 31, 32, /* 79 */ 33, 35, 36, 38, 40, 41, 43, 45, /* 87 */ 47, 49, 52, 54, 56, 59, 61, 64, /* 95 */ 67, 70, 73, 76, 79, 83, 87, 91, /* 103 */ 95, 99, 103, 108, 112, 117, 123, 128, /* 111 */ 134, 140, 146, 152, 159, 166, 173, 181, /* 119 */ 189, 197, 206, 215, 225, 235, 245, 256, /* 127 */ 267, 279, 292, 304, 318, 332, 347, 362, /* 135 */ 378, 395, 412, 431, 450, 470, 490, 512, /* 143 */ 535, 558, 583, 609, 636, 664, 693, 724, /* 151 */ 756, 790, 825, 861, 899, 939, 981, 1024, /* 159 */ 1069, 1117, 1166, 1218, 1272, 1328, 1387, 1448, /* 167 */ 1512, 1579, 1649, 1722, 1798, 1878, 1961, 2048, /* 175 */ 2139, 2233, 2332, 2435, 2543, 2656, 2774, 2896, /* 183 */ 3025, 3158, 3298, 3444, 3597, 3756, 3922, 4096, /* 191 */ 4277, 4467, 4664, 4871, 5087, 5312, 5547, 5793, /* 199 */ 6049, 6317, 6597, 6889, 7194, 7512, 7845, 8192, /* 207 */ 8555, 8933, 9329, 9742, 10173, 10624, 11094, 11585, /* 215 */ 12098, 12634, 13193, 13777, 14387, 15024, 15689, 16384, /* 223 */ 17109, 17867, 18658, 19484, 20347, 21247, 22188, 23170, /* 231 */ 24196, 25268, 26386, 27554, 28774, 30048, 31379, 32768, /* 239 */ 34219, 35734, 37316, 38968, 40693, 42495, 44376, 46341, /* 247 */ 48393, 50535, 52773, 55109, 57549, 60097, 62757, 65536, /* 255 */ }; /* Bit shift for fixed point conversion. */ #define AUDIOMIXBUF_VOL_SHIFT 30 /* Internal representation of 0dB volume (1.0 in fixed point). */ #define AUDIOMIXBUF_VOL_0DB (1 << AUDIOMIXBUF_VOL_SHIFT) AssertCompile(AUDIOMIXBUF_VOL_0DB <= 0x40000000); /* Must always hold. */ AssertCompile(AUDIOMIXBUF_VOL_0DB == 0x40000000); /* For now -- when only attenuation is used. */ /** * Peeks for audio frames without any conversion done. * This will get the raw frame data out of a mixing buffer. * * @return IPRT status code or VINF_AUDIO_MORE_DATA_AVAILABLE if more data is available to read. * * @param pMixBuf Mixing buffer to acquire audio frames from. * @param cFramesToRead Number of audio frames to read. * @param paFrameBuf Buffer where to store the returned audio frames. * @param cFrameBuf Size (in frames) of the buffer to store audio frames into. * @param pcFramesRead Returns number of read audio frames. Optional. * * @remark This function is not thread safe! */ int AudioMixBufPeek(PPDMAUDIOMIXBUF pMixBuf, uint32_t cFramesToRead, PPDMAUDIOFRAME paFrameBuf, uint32_t cFrameBuf, uint32_t *pcFramesRead) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertPtrReturn(paFrameBuf, VERR_INVALID_POINTER); AssertReturn(cFrameBuf, VERR_INVALID_PARAMETER); /* pcRead is optional. */ int rc; if (!cFramesToRead) { if (pcFramesRead) *pcFramesRead = 0; return VINF_SUCCESS; } uint32_t cRead; if (pMixBuf->offRead + cFramesToRead > pMixBuf->cFrames) { cRead = pMixBuf->cFrames - pMixBuf->offRead; rc = VINF_AUDIO_MORE_DATA_AVAILABLE; } else { cRead = cFramesToRead; rc = VINF_SUCCESS; } if (cRead > cFrameBuf) { cRead = cFrameBuf; rc = VINF_AUDIO_MORE_DATA_AVAILABLE; } if (cRead) { memcpy(paFrameBuf, &pMixBuf->pFrames[pMixBuf->offRead], sizeof(PDMAUDIOFRAME) * cRead); pMixBuf->offRead = (pMixBuf->offRead + cRead) % pMixBuf->cFrames; Assert(pMixBuf->offRead <= pMixBuf->cFrames); pMixBuf->cUsed -= RT_MIN(cRead, pMixBuf->cUsed); } if (pcFramesRead) *pcFramesRead = cRead; return rc; } /** * Returns a mutable pointer to the mixing buffer's audio frame buffer for writing raw * audio frames. * * @return IPRT status code. VINF_TRY_AGAIN for getting next pointer at beginning (circular). * @param pMixBuf Mixing buffer to acquire audio frames from. * @param cFrames Number of requested audio frames to write. * @param ppvFrames Returns a mutable pointer to the buffer's audio frame data. * @param pcFramesToWrite Number of available audio frames to write. * * @remark This function is not thread safe! */ int AudioMixBufPeekMutable(PPDMAUDIOMIXBUF pMixBuf, uint32_t cFrames, PPDMAUDIOFRAME *ppvFrames, uint32_t *pcFramesToWrite) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertPtrReturn(ppvFrames, VERR_INVALID_POINTER); AssertPtrReturn(pcFramesToWrite, VERR_INVALID_POINTER); int rc; if (!cFrames) { *pcFramesToWrite = 0; return VINF_SUCCESS; } uint32_t cFramesToWrite; if (pMixBuf->offWrite + cFrames > pMixBuf->cFrames) { cFramesToWrite = pMixBuf->cFrames - pMixBuf->offWrite; rc = VINF_TRY_AGAIN; } else { cFramesToWrite = cFrames; rc = VINF_SUCCESS; } *ppvFrames = &pMixBuf->pFrames[pMixBuf->offWrite]; AssertPtr(ppvFrames); pMixBuf->offWrite = (pMixBuf->offWrite + cFramesToWrite) % pMixBuf->cFrames; Assert(pMixBuf->offWrite <= pMixBuf->cFrames); pMixBuf->cUsed += RT_MIN(cFramesToWrite, pMixBuf->cUsed); *pcFramesToWrite = cFramesToWrite; return rc; } /** * Clears the entire frame buffer. * * @param pMixBuf Mixing buffer to clear. * */ void AudioMixBufClear(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturnVoid(pMixBuf); if (pMixBuf->cFrames) RT_BZERO(pMixBuf->pFrames, pMixBuf->cFrames * sizeof(PDMAUDIOFRAME)); } /** * Clears (zeroes) the buffer by a certain amount of (used) frames and * keeps track to eventually assigned children buffers. * * @param pMixBuf Mixing buffer to clear. * @param cFramesToClear Number of audio frames to clear. */ void AudioMixBufFinish(PPDMAUDIOMIXBUF pMixBuf, uint32_t cFramesToClear) { AUDMIXBUF_LOG(("cFramesToClear=%RU32\n", cFramesToClear)); AUDMIXBUF_LOG(("%s: offRead=%RU32, cUsed=%RU32\n", pMixBuf->pszName, pMixBuf->offRead, pMixBuf->cUsed)); AssertStmt(cFramesToClear <= pMixBuf->cFrames, cFramesToClear = pMixBuf->cFrames); PPDMAUDIOMIXBUF pIter; RTListForEach(&pMixBuf->lstChildren, pIter, PDMAUDIOMIXBUF, Node) { AUDMIXBUF_LOG(("\t%s: cMixed=%RU32 -> %RU32\n", pIter->pszName, pIter->cMixed, pIter->cMixed - cFramesToClear)); pIter->cMixed -= RT_MIN(pIter->cMixed, cFramesToClear); /* Note: Do not increment pIter->cUsed here, as this gets done when reading from that buffer using AudioMixBufReadXXX. */ } uint32_t cClearOff; uint32_t cClearLen; /* Clear end of buffer (wrap around). */ if (cFramesToClear > pMixBuf->offRead) { cClearOff = pMixBuf->cFrames - (cFramesToClear - pMixBuf->offRead); cClearLen = pMixBuf->cFrames - cClearOff; AUDMIXBUF_LOG(("Clearing1: %RU32 - %RU32\n", cClearOff, cClearOff + cClearLen)); RT_BZERO(pMixBuf->pFrames + cClearOff, cClearLen * sizeof(PDMAUDIOFRAME)); Assert(cFramesToClear >= cClearLen); cFramesToClear -= cClearLen; } /* Clear beginning of buffer. */ if ( cFramesToClear && pMixBuf->offRead) { Assert(pMixBuf->offRead >= cFramesToClear); cClearOff = pMixBuf->offRead - cFramesToClear; cClearLen = cFramesToClear; Assert(cClearOff + cClearLen <= pMixBuf->cFrames); AUDMIXBUF_LOG(("Clearing2: %RU32 - %RU32\n", cClearOff, cClearOff + cClearLen)); RT_BZERO(pMixBuf->pFrames + cClearOff, cClearLen * sizeof(PDMAUDIOFRAME)); } } /** * Destroys (uninitializes) a mixing buffer. * * @param pMixBuf Mixing buffer to destroy. */ void AudioMixBufDestroy(PPDMAUDIOMIXBUF pMixBuf) { if (!pMixBuf) return; AudioMixBufUnlink(pMixBuf); if (pMixBuf->pszName) { AUDMIXBUF_LOG(("%s\n", pMixBuf->pszName)); RTStrFree(pMixBuf->pszName); pMixBuf->pszName = NULL; } if (pMixBuf->pRate) { RTMemFree(pMixBuf->pRate); pMixBuf->pRate = NULL; } if (pMixBuf->pFrames) { Assert(pMixBuf->cFrames); RTMemFree(pMixBuf->pFrames); pMixBuf->pFrames = NULL; } pMixBuf->cFrames = 0; } /** * Returns the size (in audio frames) of free audio buffer space. * * @return uint32_t Size (in audio frames) of free audio buffer space. * @param pMixBuf Mixing buffer to return free size for. */ uint32_t AudioMixBufFree(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); uint32_t cFrames, cFramesFree; if (pMixBuf->pParent) { /* * As a linked child buffer we want to know how many frames * already have been consumed by the parent. */ cFrames = pMixBuf->pParent->cFrames; Assert(pMixBuf->cMixed <= cFrames); cFramesFree = cFrames - pMixBuf->cMixed; } else /* As a parent. */ { cFrames = pMixBuf->cFrames; Assert(cFrames >= pMixBuf->cUsed); cFramesFree = pMixBuf->cFrames - pMixBuf->cUsed; } AUDMIXBUF_LOG(("%s: %RU32 of %RU32\n", pMixBuf->pszName, cFramesFree, cFrames)); return cFramesFree; } /** * Returns the size (in bytes) of free audio buffer space. * * @return uint32_t Size (in bytes) of free audio buffer space. * @param pMixBuf Mixing buffer to return free size for. */ uint32_t AudioMixBufFreeBytes(PPDMAUDIOMIXBUF pMixBuf) { return AUDIOMIXBUF_F2B(pMixBuf, AudioMixBufFree(pMixBuf)); } /** * Allocates the internal audio frame buffer. * * @return IPRT status code. * @param pMixBuf Mixing buffer to allocate frame buffer for. * @param cFrames Number of audio frames to allocate. */ static int audioMixBufAlloc(PPDMAUDIOMIXBUF pMixBuf, uint32_t cFrames) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertReturn(cFrames, VERR_INVALID_PARAMETER); AUDMIXBUF_LOG(("%s: cFrames=%RU32\n", pMixBuf->pszName, cFrames)); size_t cbFrames = cFrames * sizeof(PDMAUDIOFRAME); pMixBuf->pFrames = (PPDMAUDIOFRAME)RTMemAllocZ(cbFrames); if (pMixBuf->pFrames) { pMixBuf->cFrames = cFrames; return VINF_SUCCESS; } return VERR_NO_MEMORY; } #ifdef AUDIOMIXBUF_DEBUG_MACROS # define AUDMIXBUF_MACRO_LOG(x) AUDMIXBUF_LOG(x) #elif defined(VBOX_AUDIO_TESTCASE_VERBOSE) /* Warning: VBOX_AUDIO_TESTCASE_VERBOSE will generate huge logs! */ # define AUDMIXBUF_MACRO_LOG(x) RTPrintf x #else # define AUDMIXBUF_MACRO_LOG(x) do {} while (0) #endif /** * Macro for generating the conversion routines from/to different formats. * Be careful what to pass in/out, as most of the macros are optimized for speed and * thus don't do any bounds checking! * * Note: Currently does not handle any endianness conversion yet! */ #define AUDMIXBUF_CONVERT(_aName, _aType, _aMin, _aMax, _aSigned, _aShift) \ /* Clips a specific output value to a single sample value. */ \ DECLCALLBACK(int64_t) audioMixBufClipFrom##_aName(_aType aVal) \ { \ /* left shifting of signed values is not defined, therefore the intermediate uint64_t cast */ \ if (_aSigned) \ return (int64_t) (((uint64_t) ((int64_t) aVal )) << (32 - _aShift)); \ return (int64_t) (((uint64_t) ((int64_t) aVal - ((_aMax >> 1) + 1))) << (32 - _aShift)); \ } \ \ /* Clips a single sample value to a specific output value. */ \ DECLCALLBACK(_aType) audioMixBufClipTo##_aName(int64_t iVal) \ { \ if (iVal >= 0x7fffffff) \ return _aMax; \ if (iVal < -INT64_C(0x80000000)) \ return _aMin; \ \ if (_aSigned) \ return (_aType) (iVal >> (32 - _aShift)); \ return ((_aType) ((iVal >> (32 - _aShift)) + ((_aMax >> 1) + 1))); \ } \ \ DECLCALLBACK(uint32_t) audioMixBufConvFrom##_aName##Stereo(PPDMAUDIOFRAME paDst, const void *pvSrc, uint32_t cbSrc, \ PCPDMAUDMIXBUFCONVOPTS pOpts) \ { \ _aType const *pSrc = (_aType const *)pvSrc; \ uint32_t cFrames = RT_MIN(pOpts->cFrames, cbSrc / sizeof(_aType)); \ AUDMIXBUF_MACRO_LOG(("cFrames=%RU32, BpS=%zu, lVol=%RU32, rVol=%RU32\n", \ pOpts->cFrames, sizeof(_aType), pOpts->From.Volume.uLeft, pOpts->From.Volume.uRight)); \ for (uint32_t i = 0; i < cFrames; i++) \ { \ paDst->i64LSample = ASMMult2xS32RetS64((int32_t)audioMixBufClipFrom##_aName(*pSrc++), pOpts->From.Volume.uLeft ) >> AUDIOMIXBUF_VOL_SHIFT; \ paDst->i64RSample = ASMMult2xS32RetS64((int32_t)audioMixBufClipFrom##_aName(*pSrc++), pOpts->From.Volume.uRight) >> AUDIOMIXBUF_VOL_SHIFT; \ paDst++; \ } \ \ return cFrames; \ } \ \ DECLCALLBACK(uint32_t) audioMixBufConvFrom##_aName##Mono(PPDMAUDIOFRAME paDst, const void *pvSrc, uint32_t cbSrc, \ PCPDMAUDMIXBUFCONVOPTS pOpts) \ { \ _aType const *pSrc = (_aType const *)pvSrc; \ const uint32_t cFrames = RT_MIN(pOpts->cFrames, cbSrc / sizeof(_aType)); \ AUDMIXBUF_MACRO_LOG(("cFrames=%RU32, BpS=%zu, lVol=%RU32, rVol=%RU32\n", \ cFrames, sizeof(_aType), pOpts->From.Volume.uLeft, pOpts->From.Volume.uRight)); \ for (uint32_t i = 0; i < cFrames; i++) \ { \ paDst->i64LSample = ASMMult2xS32RetS64((int32_t)audioMixBufClipFrom##_aName(*pSrc), pOpts->From.Volume.uLeft) >> AUDIOMIXBUF_VOL_SHIFT; \ paDst->i64RSample = ASMMult2xS32RetS64((int32_t)audioMixBufClipFrom##_aName(*pSrc), pOpts->From.Volume.uRight) >> AUDIOMIXBUF_VOL_SHIFT; \ pSrc++; \ paDst++; \ } \ \ return cFrames; \ } \ \ DECLCALLBACK(void) audioMixBufConvTo##_aName##Stereo(void *pvDst, PCPDMAUDIOFRAME paSrc, PCPDMAUDMIXBUFCONVOPTS pOpts) \ { \ PCPDMAUDIOFRAME pSrc = paSrc; \ _aType *pDst = (_aType *)pvDst; \ _aType l, r; \ uint32_t cFrames = pOpts->cFrames; \ while (cFrames--) \ { \ AUDMIXBUF_MACRO_LOG(("%p: l=%RI64, r=%RI64\n", pSrc, pSrc->i64LSample, pSrc->i64RSample)); \ l = audioMixBufClipTo##_aName(pSrc->i64LSample); \ r = audioMixBufClipTo##_aName(pSrc->i64RSample); \ AUDMIXBUF_MACRO_LOG(("\t-> l=%RI16, r=%RI16\n", l, r)); \ *pDst++ = l; \ *pDst++ = r; \ pSrc++; \ } \ } \ \ DECLCALLBACK(void) audioMixBufConvTo##_aName##Mono(void *pvDst, PCPDMAUDIOFRAME paSrc, PCPDMAUDMIXBUFCONVOPTS pOpts) \ { \ PCPDMAUDIOFRAME pSrc = paSrc; \ _aType *pDst = (_aType *)pvDst; \ uint32_t cFrames = pOpts->cFrames; \ while (cFrames--) \ { \ *pDst++ = audioMixBufClipTo##_aName((pSrc->i64LSample + pSrc->i64RSample) / 2); \ pSrc++; \ } \ } /* audioMixBufConvXXXS8: 8 bit, signed. */ AUDMIXBUF_CONVERT(S8 /* Name */, int8_t, INT8_MIN /* Min */, INT8_MAX /* Max */, true /* fSigned */, 8 /* cShift */) /* audioMixBufConvXXXU8: 8 bit, unsigned. */ AUDMIXBUF_CONVERT(U8 /* Name */, uint8_t, 0 /* Min */, UINT8_MAX /* Max */, false /* fSigned */, 8 /* cShift */) /* audioMixBufConvXXXS16: 16 bit, signed. */ AUDMIXBUF_CONVERT(S16 /* Name */, int16_t, INT16_MIN /* Min */, INT16_MAX /* Max */, true /* fSigned */, 16 /* cShift */) /* audioMixBufConvXXXU16: 16 bit, unsigned. */ AUDMIXBUF_CONVERT(U16 /* Name */, uint16_t, 0 /* Min */, UINT16_MAX /* Max */, false /* fSigned */, 16 /* cShift */) /* audioMixBufConvXXXS32: 32 bit, signed. */ AUDMIXBUF_CONVERT(S32 /* Name */, int32_t, INT32_MIN /* Min */, INT32_MAX /* Max */, true /* fSigned */, 32 /* cShift */) /* audioMixBufConvXXXU32: 32 bit, unsigned. */ AUDMIXBUF_CONVERT(U32 /* Name */, uint32_t, 0 /* Min */, UINT32_MAX /* Max */, false /* fSigned */, 32 /* cShift */) #undef AUDMIXBUF_CONVERT #define AUDMIXBUF_MIXOP(_aName, _aOp) \ static void audioMixBufOp##_aName(PPDMAUDIOFRAME paDst, uint32_t cDstFrames, \ PPDMAUDIOFRAME paSrc, uint32_t cSrcFrames, \ PPDMAUDIOSTREAMRATE pRate, \ uint32_t *pcDstWritten, uint32_t *pcSrcRead) \ { \ AUDMIXBUF_MACRO_LOG(("cSrcFrames=%RU32, cDstFrames=%RU32\n", cSrcFrames, cDstFrames)); \ AUDMIXBUF_MACRO_LOG(("Rate: offSrc=%RU32, offDst=%RU32, uDstInc=%RU32\n", \ pRate->offSrc, \ (uint32_t)(pRate->offDst >> 32), (uint32_t)(pRate->uDstInc >> 32))); \ \ if (pRate->uDstInc == (UINT64_C(1) + UINT32_MAX)) /* No conversion needed? */ \ { \ uint32_t cFrames = RT_MIN(cSrcFrames, cDstFrames); \ AUDMIXBUF_MACRO_LOG(("cFrames=%RU32\n", cFrames)); \ for (uint32_t i = 0; i < cFrames; i++) \ { \ paDst[i].i64LSample _aOp paSrc[i].i64LSample; \ paDst[i].i64RSample _aOp paSrc[i].i64RSample; \ } \ \ if (pcDstWritten) \ *pcDstWritten = cFrames; \ if (pcSrcRead) \ *pcSrcRead = cFrames; \ return; \ } \ \ PPDMAUDIOFRAME paSrcStart = paSrc; \ PPDMAUDIOFRAME paSrcEnd = paSrc + cSrcFrames; \ PPDMAUDIOFRAME paDstStart = paDst; \ PPDMAUDIOFRAME paDstEnd = paDst + cDstFrames; \ PDMAUDIOFRAME frameCur = { 0 }; \ PDMAUDIOFRAME frameOut; \ PDMAUDIOFRAME frameLast = pRate->SrcFrameLast; \ \ while (paDst < paDstEnd) \ { \ Assert(paSrc <= paSrcEnd); \ Assert(paDst <= paDstEnd); \ if (paSrc >= paSrcEnd) \ break; \ \ while (pRate->offSrc <= (pRate->offDst >> 32)) \ { \ Assert(paSrc <= paSrcEnd); \ frameLast = *paSrc++; \ pRate->offSrc++; \ if (paSrc == paSrcEnd) \ break; \ } \ \ Assert(paSrc <= paSrcEnd); \ if (paSrc == paSrcEnd) \ break; \ \ frameCur = *paSrc; \ \ /* Interpolate. */ \ int64_t iDstOffInt = pRate->offDst & UINT32_MAX; \ \ frameOut.i64LSample = (frameLast.i64LSample * ((int64_t) (INT64_C(1) << 32) - iDstOffInt) + frameCur.i64LSample * iDstOffInt) >> 32; \ frameOut.i64RSample = (frameLast.i64RSample * ((int64_t) (INT64_C(1) << 32) - iDstOffInt) + frameCur.i64RSample * iDstOffInt) >> 32; \ \ paDst->i64LSample _aOp frameOut.i64LSample; \ paDst->i64RSample _aOp frameOut.i64RSample; \ \ AUDMIXBUF_MACRO_LOG(("\tiDstOffInt=%RI64, l=%RI64, r=%RI64 (cur l=%RI64, r=%RI64)\n", \ iDstOffInt, \ paDst->i64LSample >> 32, paDst->i64RSample >> 32, \ frameCur.i64LSample >> 32, frameCur.i64RSample >> 32)); \ \ paDst++; \ pRate->offDst += pRate->uDstInc; \ \ AUDMIXBUF_MACRO_LOG(("\t\tpRate->offDst=%RU32\n", pRate->offDst >> 32)); \ \ } \ \ AUDMIXBUF_MACRO_LOG(("%zu source frames -> %zu dest frames\n", paSrc - paSrcStart, paDst - paDstStart)); \ \ pRate->SrcFrameLast = frameLast; \ \ AUDMIXBUF_MACRO_LOG(("pRate->srcSampleLast l=%RI64, r=%RI64\n", \ pRate->SrcFrameLast.i64LSample, pRate->SrcFrameLast.i64RSample)); \ \ if (pcDstWritten) \ *pcDstWritten = paDst - paDstStart; \ if (pcSrcRead) \ *pcSrcRead = paSrc - paSrcStart; \ } /* audioMixBufOpAssign: Assigns values from source buffer to destination bufffer, overwriting the destination. */ AUDMIXBUF_MIXOP(Assign /* Name */, = /* Operation */) #if 0 /* unused */ /* audioMixBufOpBlend: Blends together the values from both, the source and the destination buffer. */ AUDMIXBUF_MIXOP(Blend /* Name */, += /* Operation */) #endif #undef AUDMIXBUF_MIXOP #undef AUDMIXBUF_MACRO_LOG /** Dummy conversion used when the source is muted. */ static DECLCALLBACK(uint32_t) audioMixBufConvFromSilence(PPDMAUDIOFRAME paDst, const void *pvSrc, uint32_t cbSrc, PCPDMAUDMIXBUFCONVOPTS pOpts) { RT_NOREF(cbSrc, pvSrc); /* Internally zero always corresponds to silence. */ RT_BZERO(paDst, pOpts->cFrames * sizeof(paDst[0])); return pOpts->cFrames; } /** * Looks up the matching conversion (macro) routine for converting * audio frames from a source format. * ** @todo Speed up the lookup by binding it to the actual stream state. * * @return PAUDMIXBUF_FN_CONVFROM Function pointer to conversion macro if found, NULL if not supported. * @param enmFmt Audio format to lookup conversion macro for. */ static PFNPDMAUDIOMIXBUFCONVFROM audioMixBufConvFromLookup(PDMAUDIOMIXBUFFMT enmFmt) { if (AUDMIXBUF_FMT_SIGNED(enmFmt)) { if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 2) { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvFromS8Stereo; case 16: return audioMixBufConvFromS16Stereo; case 32: return audioMixBufConvFromS32Stereo; default: return NULL; } } else { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvFromS8Mono; case 16: return audioMixBufConvFromS16Mono; case 32: return audioMixBufConvFromS32Mono; default: return NULL; } } } else /* Unsigned */ { if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 2) { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvFromU8Stereo; case 16: return audioMixBufConvFromU16Stereo; case 32: return audioMixBufConvFromU32Stereo; default: return NULL; } } else { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvFromU8Mono; case 16: return audioMixBufConvFromU16Mono; case 32: return audioMixBufConvFromU32Mono; default: return NULL; } } } /* not reached */ } /** * Looks up the matching conversion (macro) routine for converting * audio frames to a destination format. * ** @todo Speed up the lookup by binding it to the actual stream state. * * @return PAUDMIXBUF_FN_CONVTO Function pointer to conversion macro if found, NULL if not supported. * @param enmFmt Audio format to lookup conversion macro for. */ static PFNPDMAUDIOMIXBUFCONVTO audioMixBufConvToLookup(PDMAUDIOMIXBUFFMT enmFmt) { if (AUDMIXBUF_FMT_SIGNED(enmFmt)) { if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 2) { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvToS8Stereo; case 16: return audioMixBufConvToS16Stereo; case 32: return audioMixBufConvToS32Stereo; default: return NULL; } } else { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvToS8Mono; case 16: return audioMixBufConvToS16Mono; case 32: return audioMixBufConvToS32Mono; default: return NULL; } } } else /* Unsigned */ { if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 2) { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvToU8Stereo; case 16: return audioMixBufConvToU16Stereo; case 32: return audioMixBufConvToU32Stereo; default: return NULL; } } else { switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt)) { case 8: return audioMixBufConvToU8Mono; case 16: return audioMixBufConvToU16Mono; case 32: return audioMixBufConvToU32Mono; default: return NULL; } } } /* not reached */ } /** * Converts a PDM audio volume to an internal mixing buffer volume. * * @returns IPRT status code. * @param pVolDst Where to store the converted mixing buffer volume. * @param pVolSrc Volume to convert. */ static int audioMixBufConvVol(PPDMAUDMIXBUFVOL pVolDst, PPDMAUDIOVOLUME pVolSrc) { if (!pVolSrc->fMuted) /* Only change/convert the volume value if we're not muted. */ { uint8_t uVolL = pVolSrc->uLeft & 0xFF; uint8_t uVolR = pVolSrc->uRight & 0xFF; /** @todo Ensure that the input is in the correct range/initialized! */ pVolDst->uLeft = s_aVolumeConv[uVolL] * (AUDIOMIXBUF_VOL_0DB >> 16); pVolDst->uRight = s_aVolumeConv[uVolR] * (AUDIOMIXBUF_VOL_0DB >> 16); } pVolDst->fMuted = pVolSrc->fMuted; return VINF_SUCCESS; } /** * Initializes a mixing buffer. * * @return IPRT status code. * @param pMixBuf Mixing buffer to initialize. * @param pszName Name of mixing buffer for easier identification. Optional. * @param pProps PCM audio properties to use for the mixing buffer. * @param cFrames Maximum number of audio frames the mixing buffer can hold. */ int AudioMixBufInit(PPDMAUDIOMIXBUF pMixBuf, const char *pszName, PPDMAUDIOPCMPROPS pProps, uint32_t cFrames) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertPtrReturn(pszName, VERR_INVALID_POINTER); AssertPtrReturn(pProps, VERR_INVALID_POINTER); pMixBuf->pParent = NULL; RTListInit(&pMixBuf->lstChildren); pMixBuf->cChildren = 0; pMixBuf->pFrames = NULL; pMixBuf->cFrames = 0; pMixBuf->offRead = 0; pMixBuf->offWrite = 0; pMixBuf->cMixed = 0; pMixBuf->cUsed = 0; /* Set initial volume to max. */ pMixBuf->Volume.fMuted = false; pMixBuf->Volume.uLeft = AUDIOMIXBUF_VOL_0DB; pMixBuf->Volume.uRight = AUDIOMIXBUF_VOL_0DB; /* Prevent division by zero. * Do a 1:1 conversion according to AUDIOMIXBUF_S2B_RATIO. */ pMixBuf->iFreqRatio = 1 << 20; pMixBuf->pRate = NULL; pMixBuf->uAudioFmt = AUDMIXBUF_AUDIO_FMT_MAKE(pProps->uHz, pProps->cChannels, pProps->cbSample * 8 /* Bit */, pProps->fSigned); pMixBuf->pfnConvFrom = audioMixBufConvFromLookup(pMixBuf->uAudioFmt); pMixBuf->pfnConvTo = audioMixBufConvToLookup(pMixBuf->uAudioFmt); pMixBuf->cShift = pProps->cShift; pMixBuf->pszName = RTStrDup(pszName); if (!pMixBuf->pszName) return VERR_NO_MEMORY; AUDMIXBUF_LOG(("%s: uHz=%RU32, cChan=%RU8, cBits=%RU8, fSigned=%RTbool\n", pMixBuf->pszName, AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->uAudioFmt), AUDMIXBUF_FMT_CHANNELS(pMixBuf->uAudioFmt), AUDMIXBUF_FMT_BITS_PER_SAMPLE(pMixBuf->uAudioFmt), RT_BOOL(AUDMIXBUF_FMT_SIGNED(pMixBuf->uAudioFmt)))); return audioMixBufAlloc(pMixBuf, cFrames); } /** * Returns @c true if there are any audio frames available for processing, * @c false if not. * * @return bool @c true if there are any audio frames available for processing, @c false if not. * @param pMixBuf Mixing buffer to return value for. */ bool AudioMixBufIsEmpty(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, true); if (pMixBuf->pParent) return (pMixBuf->cMixed == 0); return (pMixBuf->cUsed == 0); } /** * Calculates the frequency (sample rate) ratio of mixing buffer A in relation to mixing buffer B. * * @returns Calculated frequency ratio. * @param pMixBufA First mixing buffer. * @param pMixBufB Second mixing buffer. */ static int64_t audioMixBufCalcFreqRatio(PPDMAUDIOMIXBUF pMixBufA, PPDMAUDIOMIXBUF pMixBufB) { int64_t iRatio = ((int64_t)AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBufA->uAudioFmt) << 32) / AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBufB->uAudioFmt); if (iRatio == 0) /* Catch division by zero. */ iRatio = 1 << 20; /* Do a 1:1 conversion instead. */ return iRatio; } /** * Links an audio mixing buffer to a parent mixing buffer. A parent mixing * buffer can have multiple children mixing buffers [1:N], whereas a child only can * have one parent mixing buffer [N:1]. * * The mixing direction always goes from the child/children buffer(s) to the * parent buffer. * * For guest audio output the host backend owns the parent mixing buffer, the * device emulation owns the child/children. * * The audio format of each mixing buffer can vary; the internal mixing code * then will automatically do the (needed) conversion. * * @return IPRT status code. * @param pMixBuf Mixing buffer to link parent to. * @param pParent Parent mixing buffer to use for linking. * * @remark Circular linking is not allowed. */ int AudioMixBufLinkTo(PPDMAUDIOMIXBUF pMixBuf, PPDMAUDIOMIXBUF pParent) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertPtrReturn(pParent, VERR_INVALID_POINTER); AssertMsgReturn(AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->uAudioFmt), ("Parent frame frequency (Hz) not set\n"), VERR_INVALID_PARAMETER); AssertMsgReturn(AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->uAudioFmt), ("Buffer sample frequency (Hz) not set\n"), VERR_INVALID_PARAMETER); AssertMsgReturn(pMixBuf != pParent, ("Circular linking not allowed\n"), VERR_INVALID_PARAMETER); if (pMixBuf->pParent) /* Already linked? */ { AUDMIXBUF_LOG(("%s: Already linked to parent '%s'\n", pMixBuf->pszName, pMixBuf->pParent->pszName)); return VERR_ACCESS_DENIED; } RTListAppend(&pParent->lstChildren, &pMixBuf->Node); pParent->cChildren++; /* Set the parent. */ pMixBuf->pParent = pParent; /* Calculate the frequency ratios. */ pMixBuf->iFreqRatio = audioMixBufCalcFreqRatio(pParent, pMixBuf); int rc = VINF_SUCCESS; #if 0 uint32_t cFrames = (uint32_t)RT_MIN( ((uint64_t)pParent->cFrames << 32) / pMixBuf->iFreqRatio, _64K /* 64K frames max. */); if (!cFrames) cFrames = pParent->cFrames; int rc = VINF_SUCCESS; if (cFrames != pMixBuf->cFrames) { AUDMIXBUF_LOG(("%s: Reallocating frames %RU32 -> %RU32\n", pMixBuf->pszName, pMixBuf->cFrames, cFrames)); uint32_t cbSamples = cFrames * sizeof(PDMAUDIOSAMPLE); Assert(cbSamples); pMixBuf->pSamples = (PPDMAUDIOSAMPLE)RTMemRealloc(pMixBuf->pSamples, cbSamples); if (!pMixBuf->pSamples) rc = VERR_NO_MEMORY; if (RT_SUCCESS(rc)) { pMixBuf->cFrames = cFrames; /* Make sure to zero the reallocated buffer so that it can be * used properly when blending with another buffer later. */ RT_BZERO(pMixBuf->pSamples, cbSamples); } } #endif if (RT_SUCCESS(rc)) { if (!pMixBuf->pRate) { /* Create rate conversion. */ pMixBuf->pRate = (PPDMAUDIOSTREAMRATE)RTMemAllocZ(sizeof(PDMAUDIOSTREAMRATE)); if (!pMixBuf->pRate) return VERR_NO_MEMORY; } else RT_BZERO(pMixBuf->pRate, sizeof(PDMAUDIOSTREAMRATE)); pMixBuf->pRate->uDstInc = ((uint64_t)AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->uAudioFmt) << 32) / AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->uAudioFmt); AUDMIXBUF_LOG(("uThisHz=%RU32, uParentHz=%RU32, iFreqRatio=0x%RX64 (%RI64), uRateInc=0x%RX64 (%RU64), cFrames=%RU32 (%RU32 parent)\n", AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->uAudioFmt), AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->uAudioFmt), pMixBuf->iFreqRatio, pMixBuf->iFreqRatio, pMixBuf->pRate->uDstInc, pMixBuf->pRate->uDstInc, pMixBuf->cFrames, pParent->cFrames)); AUDMIXBUF_LOG(("%s (%RU32Hz) -> %s (%RU32Hz)\n", pMixBuf->pszName, AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->uAudioFmt), pMixBuf->pParent->pszName, AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->uAudioFmt))); } return rc; } /** * Returns number of available live frames, that is, frames that * have been written into the mixing buffer but not have been processed yet. * * For a parent buffer, this simply returns the currently used number of frames * in the buffer. * * For a child buffer, this returns the number of frames which have been mixed * to the parent and were not processed by the parent yet. * * @return uint32_t Number of live frames available. * @param pMixBuf Mixing buffer to return value for. */ uint32_t AudioMixBufLive(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); #ifdef RT_STRICT uint32_t cFrames; #endif uint32_t cAvail; if (pMixBuf->pParent) /* Is this a child buffer? */ { #ifdef RT_STRICT /* Use the frame count from the parent, as * pMixBuf->cMixed specifies the frame count * in parent frames. */ cFrames = pMixBuf->pParent->cFrames; #endif cAvail = pMixBuf->cMixed; } else { #ifdef RT_STRICT cFrames = pMixBuf->cFrames; #endif cAvail = pMixBuf->cUsed; } Assert(cAvail <= cFrames); return cAvail; } /** * Mixes audio frames from a source mixing buffer to a destination mixing buffer. * * @return IPRT status code. * VERR_BUFFER_UNDERFLOW if the source did not have enough audio data. * VERR_BUFFER_OVERFLOW if the destination did not have enough space to store the converted source audio data. * * @param pDst Destination mixing buffer. * @param pSrc Source mixing buffer. * @param cSrcOff Offset of source audio frames to mix. * @param cSrcFrames Number of source audio frames to mix. * @param pcSrcMixed Number of source audio frames successfully mixed. Optional. */ static int audioMixBufMixTo(PPDMAUDIOMIXBUF pDst, PPDMAUDIOMIXBUF pSrc, uint32_t cSrcOff, uint32_t cSrcFrames, uint32_t *pcSrcMixed) { AssertPtrReturn(pDst, VERR_INVALID_POINTER); AssertPtrReturn(pSrc, VERR_INVALID_POINTER); /* pcSrcMixed is optional. */ AssertMsgReturn(pDst == pSrc->pParent, ("Source buffer '%s' is not a child of destination '%s'\n", pSrc->pszName, pDst->pszName), VERR_INVALID_PARAMETER); uint32_t cReadTotal = 0; uint32_t cWrittenTotal = 0; Assert(pSrc->cMixed <= pDst->cFrames); Assert(pSrc->cUsed >= pDst->cMixed); Assert(pDst->cUsed <= pDst->cFrames); uint32_t offSrcRead = cSrcOff; uint32_t offDstWrite = pDst->offWrite; uint32_t cDstMixed = pSrc->cMixed; uint32_t cSrcAvail = RT_MIN(cSrcFrames, pSrc->cUsed); uint32_t cDstAvail = pDst->cFrames - pDst->cUsed; /** @todo Use pDst->cMixed later? */ AUDMIXBUF_LOG(("%s (%RU32 available) -> %s (%RU32 available)\n", pSrc->pszName, cSrcAvail, pDst->pszName, cDstAvail)); #ifdef DEBUG audioMixBufDbgPrintInternal(pDst, __FUNCTION__); #endif if (!cSrcAvail) return VERR_BUFFER_UNDERFLOW; if (!cDstAvail) return VERR_BUFFER_OVERFLOW; uint32_t cSrcToRead = 0; uint32_t cSrcRead; uint32_t cDstToWrite; uint32_t cDstWritten; int rc = VINF_SUCCESS; while (cSrcAvail && cDstAvail) { cSrcToRead = RT_MIN(cSrcAvail, pSrc->cFrames - offSrcRead); cDstToWrite = RT_MIN(cDstAvail, pDst->cFrames - offDstWrite); AUDMIXBUF_LOG(("\tSource: %RU32 @ %RU32 -> reading %RU32\n", cSrcAvail, offSrcRead, cSrcToRead)); AUDMIXBUF_LOG(("\tDest : %RU32 @ %RU32 -> writing %RU32\n", cDstAvail, offDstWrite, cDstToWrite)); if ( !cDstToWrite || !cSrcToRead) { break; } cDstWritten = cSrcRead = 0; Assert(offSrcRead < pSrc->cFrames); Assert(offSrcRead + cSrcToRead <= pSrc->cFrames); Assert(offDstWrite < pDst->cFrames); Assert(offDstWrite + cDstToWrite <= pDst->cFrames); audioMixBufOpAssign(pDst->pFrames + offDstWrite, cDstToWrite, pSrc->pFrames + offSrcRead, cSrcToRead, pSrc->pRate, &cDstWritten, &cSrcRead); cReadTotal += cSrcRead; cWrittenTotal += cDstWritten; offSrcRead = (offSrcRead + cSrcRead) % pSrc->cFrames; offDstWrite = (offDstWrite + cDstWritten) % pDst->cFrames; cDstMixed += cDstWritten; Assert(cSrcAvail >= cSrcRead); cSrcAvail -= cSrcRead; Assert(cDstAvail >= cDstWritten); cDstAvail -= cDstWritten; AUDMIXBUF_LOG(("\t%RU32 read (%RU32 left @ %RU32), %RU32 written (%RU32 left @ %RU32)\n", cSrcRead, cSrcAvail, offSrcRead, cDstWritten, cDstAvail, offDstWrite)); } pSrc->offRead = offSrcRead; Assert(pSrc->cUsed >= cReadTotal); pSrc->cUsed -= RT_MIN(pSrc->cUsed, cReadTotal); /* Note: Always count in parent frames, as the rate can differ! */ pSrc->cMixed = RT_MIN(cDstMixed, pDst->cFrames); pDst->offWrite = offDstWrite; Assert(pDst->offWrite <= pDst->cFrames); Assert((pDst->cUsed + cWrittenTotal) <= pDst->cFrames); pDst->cUsed += cWrittenTotal; /* If there are more used frames than fitting in the destination buffer, * adjust the values accordingly. * * This can happen if this routine has been called too often without * actually processing the destination buffer in between. */ if (pDst->cUsed > pDst->cFrames) { LogFunc(("%s: Warning: Destination buffer used %RU32 / %RU32 frames\n", pDst->pszName, pDst->cUsed, pDst->cFrames)); pDst->offWrite = 0; pDst->cUsed = pDst->cFrames; rc = VERR_BUFFER_OVERFLOW; } #ifdef DEBUG audioMixBufDbgValidate(pSrc); audioMixBufDbgValidate(pDst); Assert(pSrc->cMixed <= pDst->cFrames); #endif #ifdef AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA uint32_t offRead = pDst->offRead; uint32_t cLeft = cWrittenTotal; while (cLeft) { uint8_t auBuf[256]; RT_ZERO(auBuf); Assert(sizeof(auBuf) >= 4); Assert(sizeof(auBuf) % 4 == 0); uint32_t cToRead = RT_MIN(AUDIOMIXBUF_B2F(pDst, sizeof(auBuf)), RT_MIN(cLeft, pDst->cFrames - offRead)); Assert(cToRead <= pDst->cUsed); PDMAUDMIXBUFCONVOPTS convOpts; RT_ZERO(convOpts); convOpts.cFrames = cToRead; pDst->pfnConvTo(auBuf, pDst->pFrames + offRead, &convOpts); RTFILE fh; int rc2 = RTFileOpen(&fh, AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH "mixbuf_mixto.pcm", RTFILE_O_OPEN_CREATE | RTFILE_O_APPEND | RTFILE_O_WRITE | RTFILE_O_DENY_NONE); if (RT_SUCCESS(rc2)) { RTFileWrite(fh, auBuf, AUDIOMIXBUF_F2B(pDst, cToRead), NULL); RTFileClose(fh); } offRead = (offRead + cToRead) % pDst->cFrames; cLeft -= cToRead; } #endif /* AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA */ #ifdef DEBUG audioMixBufDbgPrintInternal(pDst, __FUNCTION__); #endif if (pcSrcMixed) *pcSrcMixed = cReadTotal; AUDMIXBUF_LOG(("cReadTotal=%RU32, cWrittenTotal=%RU32, cSrcMixed=%RU32, cDstUsed=%RU32, rc=%Rrc\n", cReadTotal, cWrittenTotal, pSrc->cMixed, pDst->cUsed, rc)); return rc; } /** * Mixes audio frames down to the parent mixing buffer, extended version. * * @return IPRT status code. See audioMixBufMixTo() for a more detailed explanation. * @param pMixBuf Source mixing buffer to mix to its parent. * @param cSrcOffset Offset (in frames) of source mixing buffer. * @param cSrcFrames Number of source audio frames to mix to its parent. * @param pcSrcMixed Number of source audio frames successfully mixed. Optional. */ int AudioMixBufMixToParentEx(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSrcOffset, uint32_t cSrcFrames, uint32_t *pcSrcMixed) { AssertMsgReturn(VALID_PTR(pMixBuf->pParent), ("Buffer is not linked to a parent buffer\n"), VERR_INVALID_PARAMETER); return audioMixBufMixTo(pMixBuf->pParent, pMixBuf, cSrcOffset, cSrcFrames, pcSrcMixed); } /** * Mixes audio frames down to the parent mixing buffer. * * @return IPRT status code. See audioMixBufMixTo() for a more detailed explanation. * @param pMixBuf Source mixing buffer to mix to its parent. * @param cSrcFrames Number of source audio frames to mix to its parent. * @param pcSrcMixed Number of source audio frames successfully mixed. Optional. */ int AudioMixBufMixToParent(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSrcFrames, uint32_t *pcSrcMixed) { return audioMixBufMixTo(pMixBuf->pParent, pMixBuf, pMixBuf->offRead, cSrcFrames, pcSrcMixed); } #ifdef DEBUG /** * Prints a single mixing buffer. * Internal helper function for debugging. Do not use directly. * * @return IPRT status code. * @param pMixBuf Mixing buffer to print. * @param pszFunc Function name to log this for. * @param fIsParent Whether this is a parent buffer or not. * @param uIdtLvl Indention level to use. */ DECL_FORCE_INLINE(void) audioMixBufDbgPrintSingle(PPDMAUDIOMIXBUF pMixBuf, const char *pszFunc, bool fIsParent, uint16_t uIdtLvl) { Log(("%s: %*s[%s] %s: offRead=%RU32, offWrite=%RU32, cMixed=%RU32 -> %RU32/%RU32\n", pszFunc, uIdtLvl * 4, "", fIsParent ? "PARENT" : "CHILD", pMixBuf->pszName, pMixBuf->offRead, pMixBuf->offWrite, pMixBuf->cMixed, pMixBuf->cUsed, pMixBuf->cFrames)); } /** * Validates a single mixing buffer. * * @return @true if the buffer state is valid or @false if not. * @param pMixBuf Mixing buffer to validate. */ DECL_FORCE_INLINE(bool) audioMixBufDbgValidate(PPDMAUDIOMIXBUF pMixBuf) { //const uint32_t offReadEnd = (pMixBuf->offRead + pMixBuf->cUsed) % pMixBuf->cFrames; //const uint32_t offWriteEnd = (pMixBuf->offWrite + (pMixBuf->cFrames - pMixBuf->cUsed)) % pMixBuf->cFrames; bool fValid = true; AssertStmt(pMixBuf->offRead <= pMixBuf->cFrames, fValid = false); AssertStmt(pMixBuf->offWrite <= pMixBuf->cFrames, fValid = false); AssertStmt(pMixBuf->cUsed <= pMixBuf->cFrames, fValid = false); if (pMixBuf->offWrite > pMixBuf->offRead) { if (pMixBuf->offWrite - pMixBuf->offRead != pMixBuf->cUsed) fValid = false; } else if (pMixBuf->offWrite < pMixBuf->offRead) { if (pMixBuf->offWrite + pMixBuf->cFrames - pMixBuf->offRead != pMixBuf->cUsed) fValid = false; } if (!fValid) { audioMixBufDbgPrintInternal(pMixBuf, __FUNCTION__); AssertFailed(); } return fValid; } /** * Internal helper function for audioMixBufPrintChain(). * Do not use directly. * * @return IPRT status code. * @param pMixBuf Mixing buffer to print. * @param pszFunc Function name to print the chain for. * @param uIdtLvl Indention level to use. * @param pcChildren Pointer to children counter. */ DECL_FORCE_INLINE(void) audioMixBufDbgPrintChainHelper(PPDMAUDIOMIXBUF pMixBuf, const char *pszFunc, uint16_t uIdtLvl, size_t *pcChildren) { PPDMAUDIOMIXBUF pIter; RTListForEach(&pMixBuf->lstChildren, pIter, PDMAUDIOMIXBUF, Node) { audioMixBufDbgPrintSingle(pIter, pszFunc, false /* ifIsParent */, uIdtLvl + 1); *pcChildren++; } } DECL_FORCE_INLINE(void) audioMixBufDbgPrintChainInternal(PPDMAUDIOMIXBUF pMixBuf, const char *pszFunc) { PPDMAUDIOMIXBUF pParent = pMixBuf->pParent; while (pParent) { if (!pParent->pParent) break; pParent = pParent->pParent; } if (!pParent) pParent = pMixBuf; audioMixBufDbgPrintSingle(pParent, pszFunc, true /* fIsParent */, 0 /* uIdtLvl */); /* Recursively iterate children. */ size_t cChildren = 0; audioMixBufDbgPrintChainHelper(pParent, pszFunc, 0 /* uIdtLvl */, &cChildren); Log(("%s: Children: %zu\n", pszFunc, cChildren)); } /** * Prints statistics and status of the full chain of a mixing buffer to the logger, * starting from the top root mixing buffer. * For debug versions only. * * @return IPRT status code. * @param pMixBuf Mixing buffer to print. */ void AudioMixBufDbgPrintChain(PPDMAUDIOMIXBUF pMixBuf) { audioMixBufDbgPrintChainInternal(pMixBuf, __FUNCTION__); } DECL_FORCE_INLINE(void) audioMixBufDbgPrintInternal(PPDMAUDIOMIXBUF pMixBuf, const char *pszFunc) { PPDMAUDIOMIXBUF pParent = pMixBuf; if (pMixBuf->pParent) pParent = pMixBuf->pParent; audioMixBufDbgPrintSingle(pMixBuf, pszFunc, pParent == pMixBuf /* fIsParent */, 0 /* iIdtLevel */); PPDMAUDIOMIXBUF pIter; RTListForEach(&pMixBuf->lstChildren, pIter, PDMAUDIOMIXBUF, Node) { if (pIter == pMixBuf) continue; audioMixBufDbgPrintSingle(pIter, pszFunc, false /* fIsParent */, 1 /* iIdtLevel */); } } /** * Prints statistics and status of a mixing buffer to the logger. * For debug versions only. * * @return IPRT status code. * @param pMixBuf Mixing buffer to print. */ void AudioMixBufDbgPrint(PPDMAUDIOMIXBUF pMixBuf) { audioMixBufDbgPrintInternal(pMixBuf, __FUNCTION__); } #endif /* DEBUG */ /** * Returns the total number of audio frames used. * * @return uint32_t * @param pMixBuf */ uint32_t AudioMixBufUsed(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); return pMixBuf->cUsed; } /** * Returns the total number of bytes used. * * @return uint32_t * @param pMixBuf */ uint32_t AudioMixBufUsedBytes(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); return AUDIOMIXBUF_F2B(pMixBuf, pMixBuf->cUsed); } /** * Reads audio frames at a specific offset. * * @return IPRT status code. * @param pMixBuf Mixing buffer to read audio frames from. * @param offFrames Offset (in audio frames) to start reading from. * @param pvBuf Pointer to buffer to write output to. * @param cbBuf Size (in bytes) of buffer to write to. * @param pcbRead Size (in bytes) of data read. Optional. */ int AudioMixBufReadAt(PPDMAUDIOMIXBUF pMixBuf, uint32_t offFrames, void *pvBuf, uint32_t cbBuf, uint32_t *pcbRead) { return AudioMixBufReadAtEx(pMixBuf, pMixBuf->uAudioFmt, offFrames, pvBuf, cbBuf, pcbRead); } /** * Reads audio frames at a specific offset. * If the audio format of the mixing buffer and the requested audio format do * not match the output will be converted accordingly. * * @return IPRT status code. * @param pMixBuf Mixing buffer to read audio frames from. * @param enmFmt Audio format to use for output. * @param offFrames Offset (in audio frames) to start reading from. * @param pvBuf Pointer to buffer to write output to. * @param cbBuf Size (in bytes) of buffer to write to. * @param pcbRead Size (in bytes) of data read. Optional. */ int AudioMixBufReadAtEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt, uint32_t offFrames, void *pvBuf, uint32_t cbBuf, uint32_t *pcbRead) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertPtrReturn(pvBuf, VERR_INVALID_POINTER); /* pcbRead is optional. */ uint32_t cDstFrames = pMixBuf->cFrames; uint32_t cLive = pMixBuf->cUsed; uint32_t cDead = cDstFrames - cLive; uint32_t cToProcess = (uint32_t)AUDIOMIXBUF_F2F_RATIO(pMixBuf, cDead); cToProcess = RT_MIN(cToProcess, AUDIOMIXBUF_B2F(pMixBuf, cbBuf)); AUDMIXBUF_LOG(("%s: offFrames=%RU32, cLive=%RU32, cDead=%RU32, cToProcess=%RU32\n", pMixBuf->pszName, offFrames, cLive, cDead, cToProcess)); int rc; if (cToProcess) { PFNPDMAUDIOMIXBUFCONVTO pfnConvTo = NULL; if (pMixBuf->uAudioFmt != enmFmt) pfnConvTo = audioMixBufConvToLookup(enmFmt); else pfnConvTo = pMixBuf->pfnConvTo; if (pfnConvTo) { PDMAUDMIXBUFCONVOPTS convOpts; RT_ZERO(convOpts); /* Note: No volume handling/conversion done in the conversion-to macros (yet). */ convOpts.cFrames = cToProcess; pfnConvTo(pvBuf, pMixBuf->pFrames + offFrames, &convOpts); #ifdef DEBUG AudioMixBufDbgPrint(pMixBuf); #endif rc = VINF_SUCCESS; } else { AssertFailed(); rc = VERR_NOT_SUPPORTED; } } else rc = VINF_SUCCESS; if (RT_SUCCESS(rc)) { if (pcbRead) *pcbRead = AUDIOMIXBUF_F2B(pMixBuf, cToProcess); } AUDMIXBUF_LOG(("cbRead=%RU32, rc=%Rrc\n", AUDIOMIXBUF_F2B(pMixBuf, cToProcess), rc)); return rc; } /** * Reads audio frames. The audio format of the mixing buffer will be used. * * @return IPRT status code. * @param pMixBuf Mixing buffer to read audio frames from. * @param pvBuf Pointer to buffer to write output to. * @param cbBuf Size (in bytes) of buffer to write to. * @param pcBlock Returns acquired block to read (in audio frames). */ int AudioMixBufAcquireReadBlock(PPDMAUDIOMIXBUF pMixBuf, void *pvBuf, uint32_t cbBuf, uint32_t *pcBlock) { return AudioMixBufAcquireReadBlockEx(pMixBuf, pMixBuf->uAudioFmt, pvBuf, cbBuf, pcBlock); } /** * Reads audio frames in a specific audio format. * If the audio format of the mixing buffer and the requested audio format do * not match the output will be converted accordingly. * * @return IPRT status code. * @param pMixBuf Mixing buffer to read audio frames from. * @param enmFmt Audio format to use for output. * @param pvBuf Pointer to buffer to write output to. * @param cbBuf Size (in bytes) of buffer to write to. * @param pcBlock Returns acquired block to read (in audio frames). */ int AudioMixBufAcquireReadBlockEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt, void *pvBuf, uint32_t cbBuf, uint32_t *pcBlock) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertReturn(cbBuf, VERR_INVALID_PARAMETER); AssertPtrReturn(pvBuf, VERR_INVALID_POINTER); AssertPtrReturn(pcBlock, VERR_INVALID_POINTER); /* Make sure that we at least have space for a full audio frame. */ AssertReturn(AUDIOMIXBUF_B2F(pMixBuf, cbBuf), VERR_INVALID_PARAMETER); uint32_t cToRead = RT_MIN(pMixBuf->cUsed, AUDIOMIXBUF_B2F(pMixBuf, cbBuf)); AUDMIXBUF_LOG(("%s: cbBuf=%RU32 (%RU32 frames), cToRead=%RU32, fmtSrc=0x%x, fmtDst=0x%x\n", pMixBuf->pszName, cbBuf, AUDIOMIXBUF_B2F(pMixBuf, cbBuf), cToRead, pMixBuf->uAudioFmt, enmFmt)); if (!cToRead) { #ifdef DEBUG audioMixBufDbgPrintInternal(pMixBuf, __FUNCTION__); #endif *pcBlock = 0; return VINF_SUCCESS; } PFNPDMAUDIOMIXBUFCONVTO pfnConvTo = NULL; if (pMixBuf->uAudioFmt != enmFmt) pfnConvTo = audioMixBufConvToLookup(enmFmt); else pfnConvTo = pMixBuf->pfnConvTo; if (!pfnConvTo) /* Audio format not supported. */ { AssertFailed(); return VERR_NOT_SUPPORTED; } cToRead = RT_MIN(cToRead, pMixBuf->cFrames - pMixBuf->offRead); if (cToRead) { PDMAUDMIXBUFCONVOPTS convOpts; RT_ZERO(convOpts); convOpts.cFrames = cToRead; AUDMIXBUF_LOG(("cToRead=%RU32\n", cToRead)); pfnConvTo(pvBuf, pMixBuf->pFrames + pMixBuf->offRead, &convOpts); #ifdef AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA RTFILE fh; int rc2 = RTFileOpen(&fh, AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH "mixbuf_readcirc.pcm", RTFILE_O_OPEN_CREATE | RTFILE_O_APPEND | RTFILE_O_WRITE | RTFILE_O_DENY_NONE); if (RT_SUCCESS(rc2)) { RTFileWrite(fh, pvBuf, AUDIOMIXBUF_F2B(pMixBuf, cToRead), NULL); RTFileClose(fh); } #endif } *pcBlock = cToRead; #ifdef DEBUG audioMixBufDbgValidate(pMixBuf); #endif AUDMIXBUF_LOG(("cRead=%RU32 (%RU32 bytes)\n", cToRead, AUDIOMIXBUF_F2B(pMixBuf, cToRead))); return VINF_SUCCESS; } /** * Releases a formerly acquired read block again. * * @param pMixBuf Mixing buffer to release acquired read block for. * @param cBlock Size of the block to release (in audio frames). */ void AudioMixBufReleaseReadBlock(PPDMAUDIOMIXBUF pMixBuf, uint32_t cBlock) { AssertPtrReturnVoid(pMixBuf); if (!cBlock) return; pMixBuf->offRead = (pMixBuf->offRead + cBlock) % pMixBuf->cFrames; Assert(pMixBuf->cUsed >= cBlock); pMixBuf->cUsed -= RT_MIN(cBlock, pMixBuf->cUsed); } /** * Returns the current read position of a mixing buffer. * * @returns IPRT status code. * @param pMixBuf Mixing buffer to return position for. */ uint32_t AudioMixBufReadPos(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); return pMixBuf->offRead; } /** * Resets a mixing buffer. * * @param pMixBuf Mixing buffer to reset. */ void AudioMixBufReset(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturnVoid(pMixBuf); AUDMIXBUF_LOG(("%s\n", pMixBuf->pszName)); pMixBuf->offRead = 0; pMixBuf->offWrite = 0; pMixBuf->cMixed = 0; pMixBuf->cUsed = 0; AudioMixBufClear(pMixBuf); } /** * Sets the overall (master) volume. * * @param pMixBuf Mixing buffer to set volume for. * @param pVol Pointer to volume structure to set. */ void AudioMixBufSetVolume(PPDMAUDIOMIXBUF pMixBuf, PPDMAUDIOVOLUME pVol) { AssertPtrReturnVoid(pMixBuf); AssertPtrReturnVoid(pVol); LogFlowFunc(("%s: lVol=%RU8, rVol=%RU8, fMuted=%RTbool\n", pMixBuf->pszName, pVol->uLeft, pVol->uRight, pVol->fMuted)); int rc2 = audioMixBufConvVol(&pMixBuf->Volume /* Dest */, pVol /* Source */); AssertRC(rc2); } /** * Returns the maximum amount of audio frames this buffer can hold. * * @return uint32_t Size (in audio frames) the mixing buffer can hold. * @param pMixBuf Mixing buffer to retrieve maximum for. */ uint32_t AudioMixBufSize(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); return pMixBuf->cFrames; } /** * Returns the maximum amount of bytes this buffer can hold. * * @return uint32_t Size (in bytes) the mixing buffer can hold. * @param pMixBuf Mixing buffer to retrieve maximum for. */ uint32_t AudioMixBufSizeBytes(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); return AUDIOMIXBUF_F2B(pMixBuf, pMixBuf->cFrames); } /** * Unlinks a mixing buffer from its parent, if any. * * @return IPRT status code. * @param pMixBuf Mixing buffer to unlink from parent. */ void AudioMixBufUnlink(PPDMAUDIOMIXBUF pMixBuf) { if (!pMixBuf || !pMixBuf->pszName) return; AUDMIXBUF_LOG(("%s\n", pMixBuf->pszName)); if (pMixBuf->pParent) /* IS this a children buffer? */ { AUDMIXBUF_LOG(("%s: Unlinking from parent \"%s\"\n", pMixBuf->pszName, pMixBuf->pParent->pszName)); RTListNodeRemove(&pMixBuf->Node); /* Decrease the paren't children count. */ Assert(pMixBuf->pParent->cChildren); pMixBuf->pParent->cChildren--; /* Make sure to reset the parent mixing buffer each time it gets linked * to a new child. */ AudioMixBufReset(pMixBuf->pParent); pMixBuf->pParent = NULL; } PPDMAUDIOMIXBUF pChild, pChildNext; RTListForEachSafe(&pMixBuf->lstChildren, pChild, pChildNext, PDMAUDIOMIXBUF, Node) { AUDMIXBUF_LOG(("\tUnlinking \"%s\"\n", pChild->pszName)); AudioMixBufReset(pChild); Assert(pChild->pParent == pMixBuf); pChild->pParent = NULL; RTListNodeRemove(&pChild->Node); /* Decrease the children count. */ Assert(pMixBuf->cChildren); pMixBuf->cChildren--; } Assert(RTListIsEmpty(&pMixBuf->lstChildren)); Assert(pMixBuf->cChildren == 0); AudioMixBufReset(pMixBuf); if (pMixBuf->pRate) { pMixBuf->pRate->offDst = pMixBuf->pRate->offSrc = 0; pMixBuf->pRate->uDstInc = 0; } pMixBuf->iFreqRatio = 1; /* Prevent division by zero. */ } /** * Writes audio frames at a specific offset. * The sample format being written must match the format of the mixing buffer. * * @return IPRT status code. * @param pMixBuf Pointer to mixing buffer to write to. * @param offFrames Offset (in frames) starting to write at. * @param pvBuf Pointer to audio buffer to be written. * @param cbBuf Size (in bytes) of audio buffer. * @param pcWritten Returns number of audio frames written. Optional. */ int AudioMixBufWriteAt(PPDMAUDIOMIXBUF pMixBuf, uint32_t offFrames, const void *pvBuf, uint32_t cbBuf, uint32_t *pcWritten) { return AudioMixBufWriteAtEx(pMixBuf, pMixBuf->uAudioFmt, offFrames, pvBuf, cbBuf, pcWritten); } /** * Writes audio frames at a specific offset. * * Note that this operation also modifies the current read and write position * to \a offFrames + written frames on success. * * The audio sample format to be written can be different from the audio format * the mixing buffer operates on. * * @return IPRT status code. * @param pMixBuf Pointer to mixing buffer to write to. * @param enmFmt Audio format supplied in the buffer. * @param offFrames Offset (in frames) starting to write at. * @param pvBuf Pointer to audio buffer to be written. * @param cbBuf Size (in bytes) of audio buffer. * @param pcWritten Returns number of audio frames written. Optional. */ int AudioMixBufWriteAtEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt, uint32_t offFrames, const void *pvBuf, uint32_t cbBuf, uint32_t *pcWritten) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertReturn(cbBuf, VERR_INVALID_PARAMETER); AssertPtrReturn(pvBuf, VERR_INVALID_POINTER); /* pcbWritten is optional. */ if (offFrames >= pMixBuf->cFrames) { if (pcWritten) *pcWritten = 0; return VERR_BUFFER_OVERFLOW; } /* * Adjust cToWrite so we don't overflow our buffers. */ uint32_t cToWrite = RT_MIN(AUDIOMIXBUF_B2F(pMixBuf, cbBuf), pMixBuf->cFrames - offFrames); #ifdef AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA /* * Now that we know how much we'll be converting we can log it. */ RTFILE hFile; int rc2 = RTFileOpen(&hFile, AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH "mixbuf_writeat.pcm", RTFILE_O_OPEN_CREATE | RTFILE_O_APPEND | RTFILE_O_WRITE | RTFILE_O_DENY_NONE); if (RT_SUCCESS(rc2)) { RTFileWrite(hFile, pvBuf, AUDIOMIXBUF_F2B(pMixBuf, cToWrite), NULL); RTFileClose(hFile); } #endif /* * Pick the conversion function and do the conversion. */ PFNPDMAUDIOMIXBUFCONVFROM pfnConvFrom = NULL; if (!pMixBuf->Volume.fMuted) { if (pMixBuf->uAudioFmt != enmFmt) pfnConvFrom = audioMixBufConvFromLookup(enmFmt); else pfnConvFrom = pMixBuf->pfnConvFrom; } else pfnConvFrom = &audioMixBufConvFromSilence; int rc = VINF_SUCCESS; uint32_t cWritten; if ( pfnConvFrom && cToWrite) { PDMAUDMIXBUFCONVOPTS convOpts; convOpts.cFrames = cToWrite; convOpts.From.Volume.fMuted = pMixBuf->Volume.fMuted; convOpts.From.Volume.uLeft = pMixBuf->Volume.uLeft; convOpts.From.Volume.uRight = pMixBuf->Volume.uRight; cWritten = pfnConvFrom(pMixBuf->pFrames + offFrames, pvBuf, AUDIOMIXBUF_F2B(pMixBuf, cToWrite), &convOpts); } else { cWritten = 0; if (!pfnConvFrom) { AssertFailed(); rc = VERR_NOT_SUPPORTED; } } AUDMIXBUF_LOG(("%s: offFrames=%RU32, cbBuf=%RU32, cToWrite=%RU32 (%zu bytes), cWritten=%RU32 (%zu bytes), rc=%Rrc\n", pMixBuf->pszName, offFrames, cbBuf, cToWrite, AUDIOMIXBUF_F2B(pMixBuf, cToWrite), cWritten, AUDIOMIXBUF_F2B(pMixBuf, cWritten), rc)); if (RT_SUCCESS(rc)) { pMixBuf->offRead = offFrames % pMixBuf->cFrames; pMixBuf->offWrite = (offFrames + cWritten) % pMixBuf->cFrames; pMixBuf->cUsed = cWritten; pMixBuf->cMixed = 0; #ifdef DEBUG audioMixBufDbgValidate(pMixBuf); #endif if (pcWritten) *pcWritten = cWritten; } else AUDMIXBUF_LOG(("%s: Failed with %Rrc\n", pMixBuf->pszName, rc)); return rc; } /** * Writes audio frames. * * The sample format being written must match the format of the mixing buffer. * * @return IPRT status code, or VERR_BUFFER_OVERFLOW if frames which not have * been processed yet have been overwritten (due to cyclic buffer). * @param pMixBuf Pointer to mixing buffer to write to. * @param pvBuf Pointer to audio buffer to be written. * @param cbBuf Size (in bytes) of audio buffer. * @param pcWritten Returns number of audio frames written. Optional. */ int AudioMixBufWriteCirc(PPDMAUDIOMIXBUF pMixBuf, const void *pvBuf, uint32_t cbBuf, uint32_t *pcWritten) { return AudioMixBufWriteCircEx(pMixBuf, pMixBuf->uAudioFmt, pvBuf, cbBuf, pcWritten); } /** * Writes audio frames of a specific format. * This function might write less data at once than requested. * * @return IPRT status code, or VERR_BUFFER_OVERFLOW no space is available for writing anymore. * @param pMixBuf Pointer to mixing buffer to write to. * @param enmFmt Audio format supplied in the buffer. * @param pvBuf Pointer to audio buffer to be written. * @param cbBuf Size (in bytes) of audio buffer. * @param pcWritten Returns number of audio frames written. Optional. */ int AudioMixBufWriteCircEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt, const void *pvBuf, uint32_t cbBuf, uint32_t *pcWritten) { AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER); AssertPtrReturn(pvBuf, VERR_INVALID_POINTER); /* pcbWritten is optional. */ if (!cbBuf) { if (pcWritten) *pcWritten = 0; return VINF_SUCCESS; } /* Make sure that we at least write a full audio frame. */ AssertReturn(AUDIOMIXBUF_B2F(pMixBuf, cbBuf), VERR_INVALID_PARAMETER); Assert(pMixBuf->cFrames); AssertPtr(pMixBuf->pFrames); PFNPDMAUDIOMIXBUFCONVFROM pfnConvFrom = NULL; if (!pMixBuf->Volume.fMuted) { if (pMixBuf->uAudioFmt != enmFmt) pfnConvFrom = audioMixBufConvFromLookup(enmFmt); else pfnConvFrom = pMixBuf->pfnConvFrom; } else pfnConvFrom = &audioMixBufConvFromSilence; if (!pfnConvFrom) { AssertFailed(); return VERR_NOT_SUPPORTED; } int rc = VINF_SUCCESS; uint32_t cWritten = 0; uint32_t cFree = pMixBuf->cFrames - pMixBuf->cUsed; if (cFree) { if ((pMixBuf->cFrames - pMixBuf->offWrite) == 0) pMixBuf->offWrite = 0; uint32_t cToWrite = RT_MIN(AUDIOMIXBUF_B2F(pMixBuf, cbBuf), RT_MIN(pMixBuf->cFrames - pMixBuf->offWrite, cFree)); Assert(cToWrite); PDMAUDMIXBUFCONVOPTS convOpts; RT_ZERO(convOpts); convOpts.From.Volume.fMuted = pMixBuf->Volume.fMuted; convOpts.From.Volume.uLeft = pMixBuf->Volume.uLeft; convOpts.From.Volume.uRight = pMixBuf->Volume.uRight; convOpts.cFrames = cToWrite; cWritten = pfnConvFrom(pMixBuf->pFrames + pMixBuf->offWrite, pvBuf, AUDIOMIXBUF_F2B(pMixBuf, cToWrite), &convOpts); Assert(cWritten == cToWrite); #ifdef AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA RTFILE fh; RTFileOpen(&fh, AUDIOMIXBUF_DEBUG_DUMP_PCM_DATA_PATH "mixbuf_writecirc_ex.pcm", RTFILE_O_OPEN_CREATE | RTFILE_O_APPEND | RTFILE_O_WRITE | RTFILE_O_DENY_NONE); RTFileWrite(fh, pvBuf, AUDIOMIXBUF_F2B(pMixBuf, cToWrite), NULL); RTFileClose(fh); #endif pMixBuf->cUsed += cWritten; Assert(pMixBuf->cUsed <= pMixBuf->cFrames); pMixBuf->offWrite = (pMixBuf->offWrite + cWritten) % pMixBuf->cFrames; Assert(pMixBuf->offWrite <= pMixBuf->cFrames); } else rc = VERR_BUFFER_OVERFLOW; #ifdef DEBUG audioMixBufDbgPrintInternal(pMixBuf, __FUNCTION__); audioMixBufDbgValidate(pMixBuf); #endif if (pcWritten) *pcWritten = cWritten; AUDMIXBUF_LOG(("%s: enmFmt=0x%x, cbBuf=%RU32 (%RU32 frames), cWritten=%RU32, rc=%Rrc\n", pMixBuf->pszName, enmFmt, cbBuf, AUDIOMIXBUF_B2F(pMixBuf, cbBuf), cWritten, rc)); return rc; } /** * Returns the current write position of a mixing buffer. * * @returns IPRT status code. * @param pMixBuf Mixing buffer to return position for. */ uint32_t AudioMixBufWritePos(PPDMAUDIOMIXBUF pMixBuf) { AssertPtrReturn(pMixBuf, 0); return pMixBuf->offWrite; }