#include <iprt/asm-math.h>

#include <iprt/assert.h>

#ifdef DEBUG_andy

# include <iprt/file.h>

#endif

#include <iprt/mem.h>

#include <iprt/string.h> /* For RT_BZERO. */

#ifdef TESTCASE

# include <iprt/stream.h>

#endif

#include <VBox/err.h>

#include "AudioMixBuffer.h"

#ifdef LOG_GROUP

# undef LOG_GROUP

#endif

#define LOG_GROUP LOG_GROUP_DEV_AUDIO

#include <VBox/log.h>

#ifdef TESTCASE

# define AUDMIXBUF_MACRO_FN

#else

# define AUDMIXBUF_MACRO_FN static inline

#endif

#ifdef DEBUG

static uint64_t s_cSamplesMixedTotal = 0;

#endif

static int audioMixBufInitCommon(PPDMAUDIOMIXBUF pMixBuf, const char *pszName, PPDMPCMPROPS pProps);

static void audioMixBufFreeBuf(PPDMAUDIOMIXBUF pMixBuf);

static inline void audioMixBufPrint(PPDMAUDIOMIXBUF pMixBuf);

static void audioMixBufReset(PPDMAUDIOMIXBUF pMixBuf);

typedef uint32_t (AUDMIXBUF_FN_CONVFROM) (PPDMAUDIOSAMPLE paDst, const void *pvSrc, size_t cbSrc, uint32_t cSamples);

typedef AUDMIXBUF_FN_CONVFROM *PAUDMIXBUF_FN_CONVFROM;

typedef void (AUDMIXBUF_FN_CONVTO) (void *pvDst, const PPDMAUDIOSAMPLE paSrc, uint32_t cSamples);

typedef AUDMIXBUF_FN_CONVTO *PAUDMIXBUF_FN_CONVTO;

int audioMixBufAcquire(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSamplesToRead,

PPDMAUDIOSAMPLE *ppvSamples, uint32_t *pcSamplesRead)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertReturn(cSamplesToRead, VERR_INVALID_PARAMETER);

AssertPtrReturn(ppvSamples, VERR_INVALID_POINTER);

AssertPtrReturn(pcSamplesRead, VERR_INVALID_POINTER);

int rc;

uint32_t cSamplesRead;

if (pMixBuf->offReadWrite + cSamplesToRead > pMixBuf->cSamples)

{

cSamplesRead = pMixBuf->cSamples - pMixBuf->offReadWrite;

rc = VINF_TRY_AGAIN;

}

else

{

cSamplesRead = cSamplesToRead;

rc = VINF_SUCCESS;

}

*ppvSamples = &pMixBuf->pSamples[pMixBuf->offReadWrite];

AssertPtr(ppvSamples);

pMixBuf->offReadWrite = (pMixBuf->offReadWrite + cSamplesRead) % pMixBuf->cSamples;

Assert(pMixBuf->offReadWrite <= pMixBuf->cSamples);

pMixBuf->cProcessed -= RT_CLAMP(cSamplesRead, 0, pMixBuf->cProcessed);

*pcSamplesRead = cSamplesRead;

return rc;

}

void audioMixBufFinish(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSamples)

{

LogFlowFunc(("cSamples=%RU32\n", cSamples));

LogFlowFunc(("%s: offReadWrite=%RU32, cProcessed=%RU32\n",

pMixBuf->pszName, pMixBuf->offReadWrite, pMixBuf->cProcessed));

PPDMAUDIOMIXBUF pIter;

RTListForEach(&pMixBuf->lstBuffers, pIter, PDMAUDIOMIXBUF, Node)

{

LogFlowFunc(("\t%s: cMixed=%RU32 -> %RU32\n",

pIter->pszName, pIter->cMixed, pIter->cMixed - cSamples));

Assert(pIter->cMixed >= cSamples);

pIter->cMixed -= cSamples;

pIter->offReadWrite = 0;

}

uint32_t cLeft = RT_MIN(cSamples, pMixBuf->cSamples);

uint32_t offClear;

if (cLeft > pMixBuf->offReadWrite) /* Zero end of buffer first (wrap-around). */

{

LogFlowFunc(("Clearing1: %RU32 - %RU32\n",

(pMixBuf->cSamples - (cLeft - pMixBuf->offReadWrite)),

pMixBuf->cSamples));

RT_BZERO(pMixBuf->pSamples + (pMixBuf->cSamples - (cLeft - pMixBuf->offReadWrite)),

(cLeft - pMixBuf->offReadWrite) * sizeof(PDMAUDIOSAMPLE));

cLeft -= cLeft - pMixBuf->offReadWrite;

offClear = 0;

}

else

offClear = pMixBuf->offReadWrite - cLeft;

if (cLeft)

{

LogFlowFunc(("Clearing2: %RU32 - %RU32\n",

offClear, offClear + cLeft));

RT_BZERO(pMixBuf->pSamples + offClear, cLeft * sizeof(PDMAUDIOSAMPLE));

}

}

void audioMixBufDestroy(PPDMAUDIOMIXBUF pMixBuf)

{

if (!pMixBuf)

return;

audioMixBufUnlink(pMixBuf);

if (pMixBuf->pszName)

{

LogFlowFunc(("%s\n", pMixBuf->pszName));

RTStrFree(pMixBuf->pszName);

pMixBuf->pszName = NULL;

}

audioMixBufFreeBuf(pMixBuf);

}

uint32_t audioMixBufFree(PPDMAUDIOMIXBUF pMixBuf)

{

AssertPtrReturn(pMixBuf, 0);

uint32_t cFree;

if (pMixBuf->pParent)

{

/*

Assert(pMixBuf->cMixed <= pMixBuf->pParent->cSamples);

cFree = pMixBuf->pParent->cSamples - pMixBuf->cMixed;

}

else

cFree = pMixBuf->cSamples - pMixBuf->cProcessed;

LogFlowFunc(("%s: cFree=%RU32\n", pMixBuf->pszName, cFree));

return cFree;

}

size_t audioMixBufFreeBytes(PPDMAUDIOMIXBUF pMixBuf)

{

return AUDIOMIXBUF_S2B(pMixBuf, audioMixBufFree(pMixBuf));

}

static int audioMixBufAllocBuf(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSamples)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertReturn(cSamples, VERR_INVALID_PARAMETER);

LogFlowFunc(("%s: cSamples=%RU32\n", pMixBuf->pszName, cSamples));

size_t cbSamples = cSamples * sizeof(PDMAUDIOSAMPLE);

if (!cbSamples)

return VERR_INVALID_PARAMETER;

pMixBuf->pSamples = (PPDMAUDIOSAMPLE)RTMemAllocZ(cbSamples);

if (!pMixBuf->pSamples)

return VERR_NO_MEMORY;

pMixBuf->cSamples = cSamples;

return VINF_SUCCESS;

}

#ifdef DEBUG_MACROS

# define AUDMIXBUF_MACRO_LOG(x) LogFlowFunc((x))

#elif defined(TESTCASE)

# define AUDMIXBUF_MACRO_LOG(x) RTPrintf x

#else

# define AUDMIXBUF_MACRO_LOG(x)

#endif

#define AUDMIXBUF_CONVERT(_aName, _aType, _aMin, _aMax, _aSigned, _aShift) \

/* Clips a specific output value to a single sample value. */ \

AUDMIXBUF_MACRO_FN int64_t audioMixBufClipFrom##_aName(_aType aVal) \

{ \

if (_aSigned) \

return ((int64_t) aVal) << (32 - _aShift); \

return ((int64_t) aVal - (_aMax >> 1)) << (32 - _aShift); \

} \

\

/* Clips a single sample value to a specific output value. */ \

AUDMIXBUF_MACRO_FN _aType audioMixBufClipTo##_aName(int64_t iVal) \

{ \

if (iVal >= 0x7f000000) \

return _aMax; \

else if (iVal < -2147483648LL) \

return _aMin; \

\

if (_aSigned) \

return (_aType) (iVal >> (32 - _aShift)); \

return ((_aType) ((iVal >> (32 - _aShift)) + (_aMax >> 1))); \

} \

\

AUDMIXBUF_MACRO_FN uint32_t audioMixBufConvFrom##_aName##Stereo(PPDMAUDIOSAMPLE paDst, const void *pvSrc, size_t cbSrc, uint32_t cSamples) \

{ \

_aType *pSrc = (_aType *)pvSrc; \

cSamples = (uint32_t)RT_MIN(cSamples, cbSrc / sizeof(_aType)); \

AUDMIXBUF_MACRO_LOG(("cSamples=%RU32, sizeof(%zu)\n", cSamples, sizeof(_aType))); \

for (uint32_t i = 0; i < cSamples; i++) \

{ \

AUDMIXBUF_MACRO_LOG(("%p: l=%RI16, r=%RI16\n", paDst, *pSrc, *(pSrc + 1))); \

paDst->u64LSample = (ASMMult2xS32RetS64(audioMixBufClipFrom##_aName(*pSrc++), 0x5F000000 /* Volume */) >> 31); \

paDst->u64RSample = (ASMMult2xS32RetS64(audioMixBufClipFrom##_aName(*pSrc++), 0x5F000000 /* Volume */) >> 31); \

AUDMIXBUF_MACRO_LOG(("\t-> l=%RI64, r=%RI64\n", paDst->u64LSample, paDst->u64RSample)); \

paDst++; \

} \

\

return cSamples; \

} \

\

AUDMIXBUF_MACRO_FN uint32_t audioMixBufConvFrom##_aName##Mono(PPDMAUDIOSAMPLE paDst, const void *pvSrc, size_t cbSrc, uint32_t cSamples) \

{ \

_aType *pSrc = (_aType *)pvSrc; \

cSamples = (uint32_t)RT_MIN(cSamples, cbSrc / sizeof(_aType)); \

AUDMIXBUF_MACRO_LOG(("cSamples=%RU32, sizeof(%zu)\n", cSamples, sizeof(_aType))); \

for (uint32_t i = 0; i < cSamples; i++) \

{ \

paDst->u64LSample = ASMMult2xS32RetS64(audioMixBufClipFrom##_aName(pSrc[0]), 0x5F000000 /* Volume */); \

paDst->u64RSample = paDst->u64LSample; \

pSrc++; \

paDst++; \

} \

\

return cSamples; \

} \

\

/* Note: Does no buffer size checking, so be careful what to do! */ \

AUDMIXBUF_MACRO_FN void audioMixBufConvTo##_aName##Stereo(void *pvDst, const PPDMAUDIOSAMPLE paSrc, uint32_t cSamples) \

{ \

PPDMAUDIOSAMPLE pSrc = paSrc; \

_aType *pDst = (_aType *)pvDst; \

_aType l, r; \

while (cSamples--) \

{ \

AUDMIXBUF_MACRO_LOG(("%p: l=%RI64, r=%RI64\n", pSrc, pSrc->u64LSample, pSrc->u64RSample)); \

l = audioMixBufClipTo##_aName(pSrc->u64LSample); \

r = audioMixBufClipTo##_aName(pSrc->u64RSample); \

AUDMIXBUF_MACRO_LOG(("\t-> l=%RI16, r=%RI16\n", l, r)); \

*pDst++ = l; \

*pDst++ = r; \

pSrc++; \

} \

} \

\

/* Note: Does no buffer size checking, so be careful what to do! */ \

AUDMIXBUF_MACRO_FN void audioMixBufConvTo##_aName##Mono(void *pvDst, const PPDMAUDIOSAMPLE paSrc, uint32_t cSamples) \

{ \

PPDMAUDIOSAMPLE pSrc = paSrc; \

_aType *pDst = (_aType *)pvDst; \

while (cSamples--) \

{ \

*pDst++ = audioMixBufClipTo##_aName(pSrc->u64LSample + pSrc->u64RSample); \

pSrc++; \

} \

}

AUDMIXBUF_CONVERT(S8 /* Name */, int8_t, INT8_MIN /* Min */, INT8_MAX /* Max */, true /* fSigned */, 8 /* cShift */);

AUDMIXBUF_CONVERT(U8 /* Name */, uint8_t, 0 /* Min */, UINT8_MAX /* Max */, false /* fSigned */, 8 /* cShift */);

AUDMIXBUF_CONVERT(S16 /* Name */, int16_t, INT16_MIN /* Min */, INT16_MAX /* Max */, true /* fSigned */, 16 /* cShift */);

AUDMIXBUF_CONVERT(U16 /* Name */, uint16_t, 0 /* Min */, UINT16_MAX /* Max */, false /* fSigned */, 16 /* cShift */);

AUDMIXBUF_CONVERT(S32 /* Name */, int32_t, INT32_MIN /* Min */, INT32_MAX /* Max */, true /* fSigned */, 32 /* cShift */);

AUDMIXBUF_CONVERT(U32 /* Name */, uint32_t, 0 /* Min */, UINT32_MAX /* Max */, false /* fSigned */, 32 /* cShift */);

#undef AUDMIXBUF_CONVERT

#define AUDMIXBUF_MIXOP(_aName, _aOp) \

AUDMIXBUF_MACRO_FN void audioMixBufOp##_aName(PPDMAUDIOSAMPLE paDst, uint32_t cDstSamples, \

PPDMAUDIOSAMPLE paSrc, uint32_t cSrcSamples, \

PPDMAUDIOSTRMRATE pRate, \

uint32_t *pcDstWritten, uint32_t *pcSrcRead) \

{ \

AUDMIXBUF_MACRO_LOG(("pRate=%p, offSrc=%RU32, offDst=%RU64, incDst=%RU64\n", \

pRate, pRate->srcOffset, pRate->dstOffset, pRate->dstInc)); \

\

if (pRate->dstInc == (1ULL + UINT32_MAX)) \

{ \

uint32_t cSamples = cSrcSamples > cDstSamples ? cDstSamples : cSrcSamples; \

AUDMIXBUF_MACRO_LOG(("cSamples=%RU32\n", cSamples)); \

for (uint32_t i = 0; i < cSamples; i++) \

{ \

paDst[i].u64LSample _aOp paSrc[i].u64LSample; \

paDst[i].u64RSample _aOp paSrc[i].u64RSample; \

} \

\

if (pcDstWritten) \

*pcDstWritten = cSamples; \

if (pcSrcRead) \

*pcSrcRead = cSamples; \

return; \

} \

\

PPDMAUDIOSAMPLE paSrcStart = paSrc; \

PPDMAUDIOSAMPLE paSrcEnd = paSrc + cSrcSamples; \

PPDMAUDIOSAMPLE paDstStart = paDst; \

PPDMAUDIOSAMPLE paDstEnd = paDst + cDstSamples; \

PDMAUDIOSAMPLE samCur, samOut; \

PDMAUDIOSAMPLE samLast = pRate->srcSampleLast; \

uint64_t l = 0; \

\

while (paDst < paDstEnd) \

{ \

if (paSrc >= paSrcEnd) \

break; \

\

while (pRate->srcOffset <= (pRate->dstOffset >> 32)) \

{ \

samLast = *paSrc++; \

pRate->srcOffset++; \

l++; \

if (paSrc >= paSrcEnd) \

break; \

} \

\

if (paSrc >= paSrcEnd) \

break; \

\

samCur = *paSrc; \

\

/* Interpolate. */ \

int64_t t = pRate->dstOffset & 0xffffffff; \

\

samOut.u64LSample = (samLast.u64LSample * ((int64_t) UINT32_MAX - t) + samCur.u64LSample * t) >> 32; \

samOut.u64RSample = (samLast.u64RSample * ((int64_t) UINT32_MAX - t) + samCur.u64RSample * t) >> 32; \

\

paDst->u64LSample _aOp samOut.u64LSample; \

paDst->u64RSample _aOp samOut.u64RSample; \

paDst++; \

\

AUDMIXBUF_MACRO_LOG(("\tt=%RI64, l=%RI64, r=%RI64 (cur l=%RI64, r=%RI64)\n", t, \

paDst->u64LSample, paDst->u64RSample, \

samCur.u64LSample, samCur.u64RSample)); \

\

pRate->dstOffset += pRate->dstInc; \

\

AUDMIXBUF_MACRO_LOG(("\t\trate->pos=%RU64\n", pRate->dstOffset)); \

} \

\

pRate->srcSampleLast = samLast; \

\

AUDMIXBUF_MACRO_LOG(("l=%RU64, rate->ilast l=%RI64, r=%RI64\n", \

l, pRate->srcSampleLast.u64LSample, pRate->srcSampleLast.u64RSample)); \

\

if (pcDstWritten) \

*pcDstWritten = paDst - paDstStart; \

if (pcSrcRead) \

*pcSrcRead = paSrc - paSrcStart; \

}

AUDMIXBUF_MIXOP(Assign /* Name */, = /* Operation */);

AUDMIXBUF_MIXOP(Blend /* Name */, += /* Operation */);

#undef AUDMIXBUF_MIXOP

#undef AUDMIXBUF_MACRO_LOG

static inline PAUDMIXBUF_FN_CONVFROM 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 if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 1)

{

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 if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 1)

{

switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt))

{

case 8: return audioMixBufConvFromU8Mono;

case 16: return audioMixBufConvFromU16Mono;

case 32: return audioMixBufConvFromU32Mono;

default: return NULL;

}

}

}

return NULL;

}

static inline PAUDMIXBUF_FN_CONVTO 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 if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 1)

{

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 if (AUDMIXBUF_FMT_CHANNELS(enmFmt) == 1)

{

switch (AUDMIXBUF_FMT_BITS_PER_SAMPLE(enmFmt))

{

case 8: return audioMixBufConvToU8Mono;

case 16: return audioMixBufConvToU16Mono;

case 32: return audioMixBufConvToU32Mono;

default: return NULL;

}

}

}

return NULL;

}

static inline int audioMixBufConvFrom(PPDMAUDIOSAMPLE paDst,

const void *pvSrc, size_t cbSrc,

uint32_t cSamples, PDMAUDIOMIXBUFFMT enmFmt,

uint32_t *pcWritten)

{

AssertPtrReturn(paDst, VERR_INVALID_POINTER);

AssertPtrReturn(pvSrc, VERR_INVALID_POINTER);

AssertReturn(cbSrc, VERR_INVALID_PARAMETER);

/* pcbWritten is optional. */

int rc;

PAUDMIXBUF_FN_CONVFROM pConv = audioMixBufConvFromLookup(enmFmt);

if (pConv)

{

uint32_t cWritten = pConv(paDst, pvSrc, cbSrc, cSamples);

if (pcWritten)

*pcWritten = (uint32_t )cWritten;

rc = VINF_SUCCESS;

}

else

rc = VERR_INVALID_PARAMETER;

return rc;

}

static inline int audioMixBufConvTo(void *pvDst, const PPDMAUDIOSAMPLE paSrc, uint32_t cSamples,

PDMAUDIOMIXBUFFMT enmFmt)

{

AssertPtrReturn(pvDst, VERR_INVALID_POINTER);

AssertPtrReturn(paSrc, VERR_INVALID_POINTER);

int rc;

PAUDMIXBUF_FN_CONVTO pConv = audioMixBufConvToLookup(enmFmt);

if (pConv)

{

pConv(pvDst, paSrc, cSamples);

rc = VINF_SUCCESS;

}

else

rc = VERR_INVALID_PARAMETER;

return rc;

}

static void audioMixBufFreeBuf(PPDMAUDIOMIXBUF pMixBuf)

{

if (pMixBuf)

{

if (pMixBuf->pSamples)

{

RTMemFree(pMixBuf->pSamples);

pMixBuf->pSamples = NULL;

}

pMixBuf->cSamples = 0;

}

}

int audioMixBufInit(PPDMAUDIOMIXBUF pMixBuf, const char *pszName,

PPDMPCMPROPS pProps, uint32_t cSamples)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertPtrReturn(pszName, VERR_INVALID_POINTER);

AssertPtrReturn(pProps, VERR_INVALID_POINTER);

pMixBuf->pParent = NULL;

RTListInit(&pMixBuf->lstBuffers);

pMixBuf->pSamples = NULL;

pMixBuf->cSamples = 0;

pMixBuf->offReadWrite = 0;

pMixBuf->cMixed = 0;

pMixBuf->cProcessed = 0;

/* Prevent division by zero.

pMixBuf->iFreqRatio = 1 << 20;

pMixBuf->pRate = NULL;

pMixBuf->AudioFmt = AUDMIXBUF_AUDIO_FMT_MAKE(pProps->uHz,

pProps->cChannels,

pProps->cBits,

pProps->fSigned);

pMixBuf->cShift = pProps->cShift;

pMixBuf->pszName = RTStrDup(pszName);

if (!pMixBuf->pszName)

return VERR_NO_MEMORY;

LogFlowFunc(("%s: uHz=%RU32, cChan=%RU8, cBits=%RU8, fSigned=%RTbool\n",

pMixBuf->pszName,

AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->AudioFmt),

AUDMIXBUF_FMT_CHANNELS(pMixBuf->AudioFmt),

AUDMIXBUF_FMT_BITS_PER_SAMPLE(pMixBuf->AudioFmt),

RT_BOOL(AUDMIXBUF_FMT_SIGNED(pMixBuf->AudioFmt))));

return audioMixBufAllocBuf(pMixBuf, cSamples);

}

bool audioMixBufIsEmpty(PPDMAUDIOMIXBUF pMixBuf)

{

AssertPtrReturn(pMixBuf, true);

if (pMixBuf->pParent)

return (pMixBuf->cMixed == 0);

return (pMixBuf->cProcessed == 0);

}

int audioMixBufLinkTo(PPDMAUDIOMIXBUF pMixBuf, PPDMAUDIOMIXBUF pParent)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertPtrReturn(pParent, VERR_INVALID_POINTER);

AssertMsgReturn(AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->AudioFmt),

("Parent sample frequency (Hz) not set\n"), VERR_INVALID_PARAMETER);

AssertMsgReturn(AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->AudioFmt),

("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? */

{

LogFlowFunc(("%s: Already linked to \"%s\"\n",

pMixBuf->pszName, pMixBuf->pParent->pszName));

return VERR_ACCESS_DENIED;

}

RTListAppend(&pParent->lstBuffers, &pMixBuf->Node);

pMixBuf->pParent = pParent;

/** @todo Only handles ADC (and not DAC) conversion for now. If you

/* Calculate the frequency ratio. */

pMixBuf->iFreqRatio =

( (int64_t)AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->AudioFmt) << 32)

/ AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->AudioFmt);

if (pMixBuf->iFreqRatio == 0) /* Catch division by zero. */

pMixBuf->iFreqRatio = 1 << 20; /* Do a 1:1 conversion instead. */

uint32_t cSamples = RT_MIN( ((uint64_t)pParent->cSamples << 32)

/ pMixBuf->iFreqRatio, _64K /* 64K samples max. */);

if (!cSamples)

cSamples = pParent->cSamples;

int rc = VINF_SUCCESS;

if (cSamples != pMixBuf->cSamples)

{

LogFlowFunc(("%s: Reallocating samples %RU32 -> %RU32\n",

pMixBuf->pszName, pMixBuf->cSamples, cSamples));

pMixBuf->pSamples = (PPDMAUDIOSAMPLE)RTMemRealloc(pMixBuf->pSamples,

cSamples * sizeof(PDMAUDIOSAMPLE));

if (!pMixBuf->pSamples)

rc = VERR_NO_MEMORY;

if (RT_SUCCESS(rc))

pMixBuf->cSamples = cSamples;

}

if (RT_SUCCESS(rc))

{

/* Create rate conversion. */

pMixBuf->pRate = (PPDMAUDIOSTRMRATE)RTMemAllocZ(sizeof(PDMAUDIOSTRMRATE));

if (!pMixBuf->pRate)

return VERR_NO_MEMORY;

pMixBuf->pRate->dstInc =

( (uint64_t)AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->AudioFmt) << 32)

/ AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->AudioFmt);

LogFlowFunc(("uThisHz=%RU32, uParentHz=%RU32, iFreqRatio=%RI64, uRateInc=%RU64, cSamples=%RU32 (%RU32 parent)\n",

AUDMIXBUF_FMT_SAMPLE_FREQ(pMixBuf->AudioFmt),

AUDMIXBUF_FMT_SAMPLE_FREQ(pParent->AudioFmt),

pMixBuf->iFreqRatio,

pMixBuf->pRate->dstInc,

pMixBuf->cSamples,

pParent->cSamples));

}

return rc;

}

uint32_t audioMixBufMixed(PPDMAUDIOMIXBUF pMixBuf)

{

AssertPtrReturn(pMixBuf, 0);

AssertMsgReturn(VALID_PTR(pMixBuf->pParent),

("Buffer is not linked to a parent buffer\n"),

0);

return pMixBuf->cMixed;

}

static int audioMixBufMixTo(PPDMAUDIOMIXBUF pDst, PPDMAUDIOMIXBUF pSrc,

uint32_t cSamples, uint32_t *pcProcessed)

{

AssertPtrReturn(pDst, VERR_INVALID_POINTER);

AssertPtrReturn(pSrc, VERR_INVALID_POINTER);

/* pcProcessed is optional. */

/* Live samples indicate how many samples there are in the source buffer

uint32_t cLive = pSrc->cMixed;

if (cLive >= pDst->cSamples)

LogFlowFunc(("Destination buffer \"%s\" full (%RU32 samples max), live samples = %RU32\n",

pDst->pszName, pDst->cSamples, cLive));

/* Dead samples are the number of samples in the destination buffer which

uint32_t cDead = pDst->cSamples - cLive;

uint32_t cToReadTotal = RT_MIN(cSamples, AUDIOMIXBUF_S2S_RATIO(pSrc, cDead));

uint32_t offRead = 0;

uint32_t cReadTotal = 0;

uint32_t cWrittenTotal = 0;

uint32_t offWrite = (pDst->offReadWrite + cLive) % pDst->cSamples;

LogFlowFunc(("pSrc=%s (%RU32 samples), pDst=%s (%RU32 samples), cLive=%RU32, cDead=%RU32, cToReadTotal=%RU32, offWrite=%RU32\n",

pSrc->pszName, pSrc->cSamples, pDst->pszName, pDst->cSamples, cLive, cDead, cToReadTotal, offWrite));

uint32_t cToRead, cToWrite;

uint32_t cWritten, cRead;

while (cToReadTotal)

{

cDead = pDst->cSamples - cLive;

cToRead = cToReadTotal;

cToWrite = RT_MIN(cDead,

pDst->cSamples - offWrite);

if (!cToWrite)

{

LogFlowFunc(("Destination buffer \"%s\" full\n", pDst->pszName));

break;

}

Assert(offWrite + cToWrite <= pDst->cSamples);

Assert(offRead + cToRead <= pSrc->cSamples);

LogFlowFunc(("\tcDead=%RU32, offWrite=%RU32, cToWrite=%RU32, offRead=%RU32, cToRead=%RU32\n",

cDead, offWrite, cToWrite, offRead, cToRead));

audioMixBufOpBlend(pDst->pSamples + offWrite, cToWrite,

pSrc->pSamples + offRead, cToRead,

pSrc->pRate,

&cWritten, &cRead);

LogFlowFunc(("\t\tcWritten=%RU32, cRead=%RU32\n", cWritten, cRead));

cReadTotal += cRead;

cWrittenTotal += cWritten;

offRead += cRead;

Assert(cToReadTotal >= cRead);

cToReadTotal -= cRead;

offWrite = (offWrite + cWritten) % pDst->cSamples;

cLive += cWritten;

}

pSrc->cMixed += cWrittenTotal;

pDst->cProcessed += cWrittenTotal;

#ifdef DEBUG

s_cSamplesMixedTotal += cWrittenTotal;

#endif

audioMixBufPrint(pDst);

if (pcProcessed)

*pcProcessed = cReadTotal;

LogFlowFunc(("cSrcRead=%RU32, cSrcMixed=%RU32, rc=%Rrc\n",

cReadTotal, pSrc->cMixed, VINF_SUCCESS));

return VINF_SUCCESS;

}

int audioMixBufMixToChildren(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSamples,

uint32_t *pcProcessed)

{

int rc = VINF_SUCCESS;

uint32_t cProcessed;

uint32_t cProcessedMax = 0;

PPDMAUDIOMIXBUF pIter;

RTListForEach(&pMixBuf->lstBuffers, pIter, PDMAUDIOMIXBUF, Node)

{

rc = audioMixBufMixTo(pIter, pMixBuf, cSamples,

&cProcessed);

if (RT_FAILURE(rc))

break;

cProcessedMax = RT_MAX(cProcessedMax, cProcessed);

}

if (pcProcessed)

*pcProcessed = cProcessedMax;

return rc;

}

int audioMixBufMixToParent(PPDMAUDIOMIXBUF pMixBuf, uint32_t cSamples,

uint32_t *pcProcessed)

{

AssertMsgReturn(VALID_PTR(pMixBuf->pParent),

("Buffer is not linked to a parent buffer\n"),

VERR_INVALID_PARAMETER);

return audioMixBufMixTo(pMixBuf->pParent, pMixBuf, cSamples,

pcProcessed);

}

static inline void audioMixBufPrint(PPDMAUDIOMIXBUF pMixBuf)

{

#ifdef DEBUG

PPDMAUDIOMIXBUF pParent = pMixBuf;

if (pMixBuf->pParent)

pParent = pMixBuf->pParent;

LogFlowFunc(("********************************************\n"));

LogFlowFunc(("%s: offReadWrite=%RU32, cProcessed=%RU32, cMixed=%RU32 (BpS=%RU32)\n",

pParent->pszName,

pParent->offReadWrite, pParent->cProcessed, pParent->cMixed,

AUDIOMIXBUF_S2B(pParent, 1)));

PPDMAUDIOMIXBUF pIter;

RTListForEach(&pParent->lstBuffers, pIter, PDMAUDIOMIXBUF, Node)

{

LogFlowFunc(("\t%s: offReadWrite=%RU32, cProcessed=%RU32, cMixed=%RU32 (BpS=%RU32)\n",

pIter->pszName,

pIter->offReadWrite, pIter->cProcessed, pIter->cMixed,

AUDIOMIXBUF_S2B(pIter, 1)));

}

LogFlowFunc(("Total samples mixed: %RU64\n", s_cSamplesMixedTotal));

LogFlowFunc(("********************************************\n"));

#endif

}

uint32_t audioMixBufProcessed(PPDMAUDIOMIXBUF pMixBuf)

{

AssertPtrReturn(pMixBuf, 0);

return pMixBuf->cProcessed;

}

int audioMixBufReadAt(PPDMAUDIOMIXBUF pMixBuf,

uint32_t offSamples,

void *pvBuf, size_t cbBuf,

uint32_t *pcbRead)

{

return audioMixBufReadAtEx(pMixBuf, pMixBuf->AudioFmt,

offSamples, pvBuf, cbBuf, pcbRead);

}

int audioMixBufReadAtEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt,

uint32_t offSamples,

void *pvBuf, size_t cbBuf,

uint32_t *pcbRead)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertPtrReturn(pvBuf, VERR_INVALID_POINTER);

/* pcbRead is optional. */

uint32_t cDstSamples = pMixBuf->cSamples;

uint32_t cLive = pMixBuf->cProcessed;

uint32_t cDead = cDstSamples - cLive;

uint32_t cToProcess = AUDIOMIXBUF_S2S_RATIO(pMixBuf, cDead);

cToProcess = RT_MIN(cToProcess, AUDIOMIXBUF_B2S(pMixBuf, cbBuf));

LogFlowFunc(("%s: offSamples=%RU32, cLive=%RU32, cDead=%RU32, cToProcess=%RU32\n",

pMixBuf->pszName, offSamples, cLive, cDead, cToProcess));

int rc;

if (cToProcess)

{

rc = audioMixBufConvTo(pvBuf, pMixBuf->pSamples + offSamples,

cToProcess, enmFmt);

audioMixBufPrint(pMixBuf);

}

else

rc = VINF_SUCCESS;

if (pcbRead)

*pcbRead = AUDIOMIXBUF_S2B(pMixBuf, cToProcess);

LogFlowFunc(("cbRead=%RU32, rc=%Rrc\n", AUDIOMIXBUF_S2B(pMixBuf, cToProcess), rc));

return rc;

}

int audioMixBufReadCirc(PPDMAUDIOMIXBUF pMixBuf,

void *pvBuf, size_t cbBuf, uint32_t *pcRead)

{

return audioMixBufReadCircEx(pMixBuf, pMixBuf->AudioFmt,

pvBuf, cbBuf, pcRead);

}

int audioMixBufReadCircEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt,

void *pvBuf, size_t cbBuf, uint32_t *pcRead)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertPtrReturn(pvBuf, VERR_INVALID_POINTER);

AssertReturn(cbBuf, VERR_INVALID_PARAMETER);

/* pcbRead is optional. */

if (!cbBuf)

return VINF_SUCCESS;

uint32_t cToRead = RT_MIN(AUDIOMIXBUF_B2S(pMixBuf, cbBuf),

pMixBuf->cProcessed);

LogFlowFunc(("%s: pvBuf=%p, cbBuf=%zu (%RU32 samples), cToRead=%RU32\n",

pMixBuf->pszName, pvBuf,

cbBuf, AUDIOMIXBUF_B2S(pMixBuf, cbBuf), cToRead));

if (!cToRead)

{

audioMixBufPrint(pMixBuf);

if (pcRead)

*pcRead = 0;

return VINF_SUCCESS;

}

PPDMAUDIOSAMPLE pSamplesSrc1 = pMixBuf->pSamples + pMixBuf->offReadWrite;

size_t cLenSrc1 = cToRead;

PPDMAUDIOSAMPLE pSamplesSrc2 = NULL;

size_t cLenSrc2 = 0;

uint32_t offRead = pMixBuf->offReadWrite + cToRead;

/*

if (offRead >= pMixBuf->cSamples)

{

Assert(pMixBuf->offReadWrite <= pMixBuf->cSamples);

cLenSrc1 = pMixBuf->cSamples - pMixBuf->offReadWrite;

pSamplesSrc2 = pMixBuf->pSamples;

Assert(cToRead >= cLenSrc1);

cLenSrc2 = RT_MIN(cToRead - cLenSrc1, pMixBuf->cSamples);

/* Save new read offset. */

offRead = cLenSrc2;

}

/* Anything to do at all? */

int rc = VINF_SUCCESS;

if (cLenSrc1)

{

LogFlowFunc(("P1: offRead=%RU32, cToRead=%RU32\n", pMixBuf->offReadWrite, cLenSrc1));

rc = audioMixBufConvTo(pvBuf, pSamplesSrc1, cLenSrc1, enmFmt);

}

/* Second part present? */

if ( RT_LIKELY(RT_SUCCESS(rc))

&& cLenSrc2)

{

AssertPtr(pSamplesSrc2);

LogFlowFunc(("P2: cToRead=%RU32, offWrite=%RU32 (%zu bytes)\n", cLenSrc2, cLenSrc1,

AUDIOMIXBUF_S2B(pMixBuf, cLenSrc1)));

rc = audioMixBufConvTo((uint8_t *)pvBuf + AUDIOMIXBUF_S2B(pMixBuf, cLenSrc1),

pSamplesSrc2, cLenSrc2, enmFmt);

}

if (RT_SUCCESS(rc))

{

pMixBuf->offReadWrite = offRead % pMixBuf->cSamples;

pMixBuf->cProcessed -= RT_CLAMP(cLenSrc1 + cLenSrc2, 0, pMixBuf->cProcessed);

if (pcRead)

*pcRead = cLenSrc1 + cLenSrc2;

}

audioMixBufPrint(pMixBuf);

LogFlowFunc(("cRead=%RU32 (%zu bytes), rc=%Rrc\n",

cLenSrc1 + cLenSrc2,

AUDIOMIXBUF_S2B(pMixBuf, cLenSrc1 + cLenSrc2), rc));

return rc;

}

static void audioMixBufReset(PPDMAUDIOMIXBUF pMixBuf)

{

AssertPtrReturnVoid(pMixBuf);

LogFlowFunc(("%s\n", pMixBuf->pszName));

pMixBuf->offReadWrite = 0;

pMixBuf->cMixed = 0;

pMixBuf->cProcessed = 0;

RT_BZERO(pMixBuf->pSamples, AUDIOMIXBUF_S2B(pMixBuf, pMixBuf->cSamples));

}

uint32_t audioMixBufSize(PPDMAUDIOMIXBUF pMixBuf)

{

return pMixBuf->cSamples;

}

size_t audioMixBufSizeBytes(PPDMAUDIOMIXBUF pMixBuf)

{

return AUDIOMIXBUF_S2B(pMixBuf, pMixBuf->cSamples);

}

void audioMixBufUnlink(PPDMAUDIOMIXBUF pMixBuf)

{

if (!pMixBuf)

return;

LogFlowFunc(("%s\n", pMixBuf->pszName));

if (pMixBuf->pParent)

{

LogFlowFunc(("%s: Unlinking from parent \"%s\"\n",

pMixBuf->pszName, pMixBuf->pParent->pszName));

RTListNodeRemove(&pMixBuf->Node);

/* Make sure to reset the parent mixing buffer each time it gets linked

audioMixBufReset(pMixBuf->pParent);

pMixBuf->pParent = NULL;

}

PPDMAUDIOMIXBUF pIter;

while (!RTListIsEmpty(&pMixBuf->lstBuffers))

{

pIter = RTListGetFirst(&pMixBuf->lstBuffers, PDMAUDIOMIXBUF, Node);

LogFlowFunc(("\tUnlinking \"%s\"\n", pIter->pszName));

audioMixBufReset(pIter->pParent);

pIter->pParent = NULL;

RTListNodeRemove(&pIter->Node);

}

pMixBuf->iFreqRatio = 0;

if (pMixBuf->pRate)

{

RTMemFree(pMixBuf->pRate);

pMixBuf->pRate = NULL;

}

}

int audioMixBufWriteAt(PPDMAUDIOMIXBUF pMixBuf,

uint32_t offSamples,

const void *pvBuf, size_t cbBuf,

uint32_t *pcWritten)

{

return audioMixBufWriteAtEx(pMixBuf, pMixBuf->AudioFmt,

offSamples, pvBuf, cbBuf, pcWritten);

}

int audioMixBufWriteAtEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt,

uint32_t offSamples,

const void *pvBuf, size_t cbBuf,

uint32_t *pcWritten)

{

AssertPtrReturn(pMixBuf, VERR_INVALID_POINTER);

AssertPtrReturn(pvBuf, VERR_INVALID_POINTER);

/* pcWritten is optional. */

uint32_t cDstSamples = pMixBuf->pParent

? pMixBuf->pParent->cSamples : pMixBuf->cSamples;

uint32_t cLive = pMixBuf->cProcessed;

uint32_t cDead = cDstSamples - cLive;

uint32_t cToProcess = AUDIOMIXBUF_S2S_RATIO(pMixBuf, cDead);

cToProcess = RT_MIN(cToProcess, AUDIOMIXBUF_B2S(pMixBuf, cbBuf));

LogFlowFunc(("%s: offSamples=%RU32, cLive=%RU32, cDead=%RU32, cToProcess=%RU32\n",

pMixBuf->pszName, offSamples, cLive, cDead, cToProcess));

if (offSamples + cToProcess > pMixBuf->cSamples)

return VERR_BUFFER_OVERFLOW;

int rc;

uint32_t cWritten;

#ifdef DEBUG

RTFILE fh;

rc = RTFileOpen(&fh, "c:\\temp\\test_writeat.pcm",

RTFILE_O_OPEN_CREATE | RTFILE_O_APPEND | RTFILE_O_WRITE | RTFILE_O_DENY_NONE);

if (RT_SUCCESS(rc))

{

RTFileWrite(fh, pvBuf, cbBuf, NULL);

RTFileClose(fh);

}

#endif

if (cToProcess)

{

rc = audioMixBufConvFrom(pMixBuf->pSamples + offSamples, pvBuf, cbBuf,

cToProcess, enmFmt, &cWritten);

audioMixBufPrint(pMixBuf);

}

else

{

cWritten = 0;

rc = VINF_SUCCESS;

}

if (RT_SUCCESS(rc))

{

if (pcWritten)

*pcWritten = cWritten;

}

LogFlowFunc(("cWritten=%RU32, rc=%Rrc\n", cWritten, rc));

return rc;

}

int audioMixBufWriteCirc(PPDMAUDIOMIXBUF pMixBuf,

const void *pvBuf, size_t cbBuf,

uint32_t *pcWritten)

{

return audioMixBufWriteCircEx(pMixBuf, pMixBuf->AudioFmt, pvBuf, cbBuf, pcWritten);

}

int audioMixBufWriteCircEx(PPDMAUDIOMIXBUF pMixBuf, PDMAUDIOMIXBUFFMT enmFmt,

const void *pvBuf, size_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;

}

PPDMAUDIOMIXBUF pParent = pMixBuf->pParent;

LogFlowFunc(("%s: enmFmt=%ld, pBuf=%p, cbBuf=%zu, pParent=%p (%RU32)\n",

pMixBuf->pszName, enmFmt, pvBuf, cbBuf, pParent, pParent ? pParent->cSamples : 0));

if ( pParent

&& pParent->cSamples <= pMixBuf->cMixed)

{

if (pcWritten)

*pcWritten = 0;

LogFlowFunc(("%s: Parent buffer %s is full\n",

pMixBuf->pszName, pMixBuf->pParent->pszName));

return VINF_SUCCESS;

}

int rc = VINF_SUCCESS;

uint32_t cToWrite = AUDIOMIXBUF_B2S(pMixBuf, cbBuf);

Assert(cToWrite);

PPDMAUDIOSAMPLE pSamplesDst1 = pMixBuf->pSamples + pMixBuf->offReadWrite;

size_t cLenDst1 = cToWrite;

PPDMAUDIOSAMPLE pSamplesDst2 = NULL;

size_t cLenDst2 = 0;

uint32_t offWrite = pMixBuf->offReadWrite + cToWrite;

/*

if (offWrite >= pMixBuf->cSamples)

{

Assert(pMixBuf->offReadWrite <= pMixBuf->cSamples);

cLenDst1 = pMixBuf->cSamples - pMixBuf->offReadWrite;

pSamplesDst2 = pMixBuf->pSamples;

Assert(cToWrite >= cLenDst1);

cLenDst2 = RT_MIN(cToWrite - cLenDst1, pMixBuf->cSamples);

/* Save new read offset. */

offWrite = cLenDst2;

}

/* Anything to do at all? */

if (cLenDst1)

rc = audioMixBufConvFrom(pSamplesDst1, pvBuf, cbBuf, cLenDst1, enmFmt, NULL);

/* Second part present? */

if ( RT_LIKELY(RT_SUCCESS(rc))

&& cLenDst2)

{

AssertPtr(pSamplesDst2);

rc = audioMixBufConvFrom(pSamplesDst2,

(uint8_t *)pvBuf + AUDIOMIXBUF_S2B(pMixBuf, cLenDst1), cbBuf,

cLenDst2, enmFmt, NULL);

}

#ifdef DEBUG_andy

RTFILE fh;

RTFileOpen(&fh, "c:\\temp\\test_writeex.pcm",

RTFILE_O_OPEN_CREATE | RTFILE_O_APPEND | RTFILE_O_WRITE | RTFILE_O_DENY_NONE);

RTFileWrite(fh, pSamplesDst1, AUDIOMIXBUF_S2B(pMixBuf, cLenDst1), NULL);

RTFileClose(fh);

#endif

LogFlowFunc(("cLenDst1=%RU32, cLenDst2=%RU32, offWrite=%RU32\n",

cLenDst1, cLenDst2, offWrite));

if (RT_SUCCESS(rc))

{

pMixBuf->offReadWrite = offWrite % pMixBuf->cSamples;

pMixBuf->cProcessed = RT_CLAMP(pMixBuf->cProcessed + cLenDst1 + cLenDst2,

0 /* Min */, pMixBuf->cSamples /* Max */);

if (pcWritten)

*pcWritten = cLenDst1 + cLenDst2;

}

audioMixBufPrint(pMixBuf);

LogFlowFunc(("cWritten=%RU32 (%zu bytes), rc=%Rrc\n",

cLenDst1 + cLenDst2,

AUDIOMIXBUF_S2B(pMixBuf, cLenDst1 + cLenDst2), rc));

return rc;

}