Samples/multimedia/directshow/baseclasses/mtype.cpp - deps/third_party/winsdk_samples_v71 - Git at Google

 //------------------------------------------------------------------------------
 // File: MType.cpp
 //
 // Desc: DirectShow base classes - implements a class that holds and
 //       manages media type information.
 //
 // Copyright (c) 1992-2001 Microsoft Corporation.  All rights reserved.
 //------------------------------------------------------------------------------


 // helper class that derived pin objects can use to compare media
 // types etc. Has same data members as the struct AM_MEDIA_TYPE defined
 // in the streams IDL file, but also has (non-virtual) functions

 #include <streams.h>
 #include <mmreg.h>

 CMediaType::~CMediaType(){
     FreeMediaType(*this);
 }


 CMediaType::CMediaType()
 {
     InitMediaType();
 }


 CMediaType::CMediaType(const GUID * type)
 {
     InitMediaType();
     majortype = *type;
 }


 // copy constructor does a deep copy of the format block

 CMediaType::CMediaType(const AM_MEDIA_TYPE& rt, __out_opt HRESULT* phr)
 {
     HRESULT hr = CopyMediaType(this, &rt);
     if (FAILED(hr) && (NULL != phr)) {
         *phr = hr;
     }
 }


 CMediaType::CMediaType(const CMediaType& rt, __out_opt HRESULT* phr)
 {
     HRESULT hr = CopyMediaType(this, &rt);
     if (FAILED(hr) && (NULL != phr)) {
         *phr = hr;
     }
 }


 // this class inherits publicly from AM_MEDIA_TYPE so the compiler could generate
 // the following assignment operator itself, however it could introduce some
 // memory conflicts and leaks in the process because the structure contains
 // a dynamically allocated block (pbFormat) which it will not copy correctly

 CMediaType&
 CMediaType::operator=(const AM_MEDIA_TYPE& rt)
 {
     Set(rt);
     return *this;
 }

 CMediaType&
 CMediaType::operator=(const CMediaType& rt)
 {
     *this = (AM_MEDIA_TYPE &) rt;
     return *this;
 }

 BOOL
 CMediaType::operator == (const CMediaType& rt) const
 {
     // I don't believe we need to check sample size or
     // temporal compression flags, since I think these must
     // be represented in the type, subtype and format somehow. They
     // are pulled out as separate flags so that people who don't understand
     // the particular format representation can still see them, but
     // they should duplicate information in the format block.

     return ((IsEqualGUID(majortype,rt.majortype) == TRUE) &&
         (IsEqualGUID(subtype,rt.subtype) == TRUE) &&
         (IsEqualGUID(formattype,rt.formattype) == TRUE) &&
         (cbFormat == rt.cbFormat) &&
         ( (cbFormat == 0) ||
           pbFormat != NULL && rt.pbFormat != NULL &&
           (memcmp(pbFormat, rt.pbFormat, cbFormat) == 0)));
 }


 BOOL
 CMediaType::operator != (const CMediaType& rt) const
 {
     /* Check to see if they are equal */

     if (*this == rt) {
         return FALSE;
     }
     return TRUE;
 }


 HRESULT
 CMediaType::Set(const CMediaType& rt)
 {
     return Set((AM_MEDIA_TYPE &) rt);
 }


 HRESULT
 CMediaType::Set(const AM_MEDIA_TYPE& rt)
 {
     if (&rt != this) {
         FreeMediaType(*this);
         HRESULT hr = CopyMediaType(this, &rt);
         if (FAILED(hr)) {
             return E_OUTOFMEMORY;
         }
     }

     return S_OK;
 }


 BOOL
 CMediaType::IsValid() const
 {
     return (!IsEqualGUID(majortype,GUID_NULL));
 }


 void
 CMediaType::SetType(const GUID* ptype)
 {
     majortype = *ptype;
 }


 void
 CMediaType::SetSubtype(const GUID* ptype)
 {
     subtype = *ptype;
 }


 ULONG
 CMediaType::GetSampleSize() const {
     if (IsFixedSize()) {
         return lSampleSize;
     } else {
         return 0;
     }
 }


 void
 CMediaType::SetSampleSize(ULONG sz) {
     if (sz == 0) {
         SetVariableSize();
     } else {
         bFixedSizeSamples = TRUE;
         lSampleSize = sz;
     }
 }


 void
 CMediaType::SetVariableSize() {
     bFixedSizeSamples = FALSE;
 }


 void
 CMediaType::SetTemporalCompression(BOOL bCompressed) {
     bTemporalCompression = bCompressed;
 }

 BOOL
 CMediaType::SetFormat(__in_bcount(cb) BYTE * pformat, ULONG cb)
 {
     if (NULL == AllocFormatBuffer(cb))
 	return(FALSE);

     ASSERT(pbFormat);
     memcpy(pbFormat, pformat, cb);
     return(TRUE);
 }


 // set the type of the media type format block, this type defines what you
 // will actually find in the format pointer. For example FORMAT_VideoInfo or
 // FORMAT_WaveFormatEx. In the future this may be an interface pointer to a
 // property set. Before sending out media types this should be filled in.

 void
 CMediaType::SetFormatType(const GUID *pformattype)
 {
     formattype = *pformattype;
 }


 // reset the format buffer

 void CMediaType::ResetFormatBuffer()
 {
     if (cbFormat) {
         CoTaskMemFree((PVOID)pbFormat);
     }
     cbFormat = 0;
     pbFormat = NULL;
 }


 // allocate length bytes for the format and return a read/write pointer
 // If we cannot allocate the new block of memory we return NULL leaving
 // the original block of memory untouched (as does ReallocFormatBuffer)

 BYTE*
 CMediaType::AllocFormatBuffer(ULONG length)
 {
     ASSERT(length);

     // do the types have the same buffer size

     if (cbFormat == length) {
         return pbFormat;
     }

     // allocate the new format buffer

     BYTE *pNewFormat = (PBYTE)CoTaskMemAlloc(length);
     if (pNewFormat == NULL) {
         if (length <= cbFormat) return pbFormat; //reuse the old block anyway.
         return NULL;
     }

     // delete the old format

     if (cbFormat != 0) {
         ASSERT(pbFormat);
         CoTaskMemFree((PVOID)pbFormat);
     }

     cbFormat = length;
     pbFormat = pNewFormat;
     return pbFormat;
 }


 // reallocate length bytes for the format and return a read/write pointer
 // to it. We keep as much information as we can given the new buffer size
 // if this fails the original format buffer is left untouched. The caller
 // is responsible for ensuring the size of memory required is non zero

 BYTE*
 CMediaType::ReallocFormatBuffer(ULONG length)
 {
     ASSERT(length);

     // do the types have the same buffer size

     if (cbFormat == length) {
         return pbFormat;
     }

     // allocate the new format buffer

     BYTE *pNewFormat = (PBYTE)CoTaskMemAlloc(length);
     if (pNewFormat == NULL) {
         if (length <= cbFormat) return pbFormat; //reuse the old block anyway.
         return NULL;
     }

     // copy any previous format (or part of if new is smaller)
     // delete the old format and replace with the new one

     if (cbFormat != 0) {
         ASSERT(pbFormat);
         memcpy(pNewFormat,pbFormat,min(length,cbFormat));
         CoTaskMemFree((PVOID)pbFormat);
     }

     cbFormat = length;
     pbFormat = pNewFormat;
     return pNewFormat;
 }

 // initialise a media type structure

 void CMediaType::InitMediaType()
 {
     ZeroMemory((PVOID)this, sizeof(*this));
     lSampleSize = 1;
     bFixedSizeSamples = TRUE;
 }


 // a partially specified media type can be passed to IPin::Connect
 // as a constraint on the media type used in the connection.
 // the type, subtype or format type can be null.
 BOOL
 CMediaType::IsPartiallySpecified(void) const
 {
     if ((majortype == GUID_NULL) ||
         (formattype == GUID_NULL)) {
             return TRUE;
     } else {
         return FALSE;
     }
 }

 BOOL
 CMediaType::MatchesPartial(const CMediaType* ppartial) const
 {
     if ((ppartial->majortype != GUID_NULL) &&
         (majortype != ppartial->majortype)) {
             return FALSE;
     }
     if ((ppartial->subtype != GUID_NULL) &&
         (subtype != ppartial->subtype)) {
             return FALSE;
     }

     if (ppartial->formattype != GUID_NULL) {
         // if the format block is specified then it must match exactly
         if (formattype != ppartial->formattype) {
             return FALSE;
         }
         if (cbFormat != ppartial->cbFormat) {
             return FALSE;
         }
         if ((cbFormat != 0) &&
             (memcmp(pbFormat, ppartial->pbFormat, cbFormat) != 0)) {
                 return FALSE;
         }
     }

     return TRUE;

 }


 // general purpose function to delete a heap allocated AM_MEDIA_TYPE structure
 // which is useful when calling IEnumMediaTypes::Next as the interface
 // implementation allocates the structures which you must later delete
 // the format block may also be a pointer to an interface to release

 void WINAPI DeleteMediaType(__inout_opt AM_MEDIA_TYPE *pmt)
 {
     // allow NULL pointers for coding simplicity

     if (pmt == NULL) {
         return;
     }

     FreeMediaType(*pmt);
     CoTaskMemFree((PVOID)pmt);
 }


 // this also comes in useful when using the IEnumMediaTypes interface so
 // that you can copy a media type, you can do nearly the same by creating
 // a CMediaType object but as soon as it goes out of scope the destructor
 // will delete the memory it allocated (this takes a copy of the memory)

 AM_MEDIA_TYPE * WINAPI CreateMediaType(AM_MEDIA_TYPE const *pSrc)
 {
     ASSERT(pSrc);

     // Allocate a block of memory for the media type

     AM_MEDIA_TYPE *pMediaType =
         (AM_MEDIA_TYPE *)CoTaskMemAlloc(sizeof(AM_MEDIA_TYPE));

     if (pMediaType == NULL) {
         return NULL;
     }
     // Copy the variable length format block

     HRESULT hr = CopyMediaType(pMediaType,pSrc);
     if (FAILED(hr)) {
         CoTaskMemFree((PVOID)pMediaType);
         return NULL;
     }

     return pMediaType;
 }


 //  Copy 1 media type to another

 HRESULT WINAPI CopyMediaType(__out AM_MEDIA_TYPE *pmtTarget, const AM_MEDIA_TYPE *pmtSource)
 {
     //  We'll leak if we copy onto one that already exists - there's one
     //  case we can check like that - copying to itself.
     ASSERT(pmtSource != pmtTarget);
     *pmtTarget = *pmtSource;
     if (pmtSource->cbFormat != 0) {
         ASSERT(pmtSource->pbFormat != NULL);
         pmtTarget->pbFormat = (PBYTE)CoTaskMemAlloc(pmtSource->cbFormat);
         if (pmtTarget->pbFormat == NULL) {
             pmtTarget->cbFormat = 0;
             return E_OUTOFMEMORY;
         } else {
             CopyMemory((PVOID)pmtTarget->pbFormat, (PVOID)pmtSource->pbFormat,
                        pmtTarget->cbFormat);
         }
     }
     if (pmtTarget->pUnk != NULL) {
         pmtTarget->pUnk->AddRef();
     }

     return S_OK;
 }

 //  Free an existing media type (ie free resources it holds)

 void WINAPI FreeMediaType(__inout AM_MEDIA_TYPE& mt)
 {
     if (mt.cbFormat != 0) {
         CoTaskMemFree((PVOID)mt.pbFormat);

         // Strictly unnecessary but tidier
         mt.cbFormat = 0;
         mt.pbFormat = NULL;
     }
     if (mt.pUnk != NULL) {
         mt.pUnk->Release();
         mt.pUnk = NULL;
     }
 }

 //  Initialize a media type from a WAVEFORMATEX

 STDAPI CreateAudioMediaType(
     const WAVEFORMATEX *pwfx,
     __out AM_MEDIA_TYPE *pmt,
     BOOL bSetFormat
 )
 {
     pmt->majortype            = MEDIATYPE_Audio;
     if (pwfx->wFormatTag == WAVE_FORMAT_EXTENSIBLE) {
         pmt->subtype = ((PWAVEFORMATEXTENSIBLE)pwfx)->SubFormat;
     } else {
         pmt->subtype              = FOURCCMap(pwfx->wFormatTag);
     }
     pmt->formattype           = FORMAT_WaveFormatEx;
     pmt->bFixedSizeSamples    = TRUE;
     pmt->bTemporalCompression = FALSE;
     pmt->lSampleSize          = pwfx->nBlockAlign;
     pmt->pUnk                 = NULL;
     if (bSetFormat) {
         if (pwfx->wFormatTag == WAVE_FORMAT_PCM) {
             pmt->cbFormat         = sizeof(WAVEFORMATEX);
         } else {
             pmt->cbFormat         = sizeof(WAVEFORMATEX) + pwfx->cbSize;
         }
         pmt->pbFormat             = (PBYTE)CoTaskMemAlloc(pmt->cbFormat);
         if (pmt->pbFormat == NULL) {
             return E_OUTOFMEMORY;
         }
         if (pwfx->wFormatTag == WAVE_FORMAT_PCM) {
             CopyMemory(pmt->pbFormat, pwfx, sizeof(PCMWAVEFORMAT));
             ((WAVEFORMATEX *)pmt->pbFormat)->cbSize = 0;
         } else {
             CopyMemory(pmt->pbFormat, pwfx, pmt->cbFormat);
         }
     }
     return S_OK;
 }

 // eliminate very many spurious warnings from MS compiler
 #pragma warning(disable:4514)
	//------------------------------------------------------------------------------
	// File: MType.cpp
	//
	// Desc: DirectShow base classes - implements a class that holds and
	// manages media type information.
	//
	// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
	//------------------------------------------------------------------------------


	// helper class that derived pin objects can use to compare media
	// types etc. Has same data members as the struct AM_MEDIA_TYPE defined
	// in the streams IDL file, but also has (non-virtual) functions

	#include <streams.h>
	#include <mmreg.h>

	CMediaType::~CMediaType(){
	FreeMediaType(*this);
	}


	CMediaType::CMediaType()
	{
	InitMediaType();
	}


	CMediaType::CMediaType(const GUID * type)
	{
	InitMediaType();
	majortype = *type;
	}


	// copy constructor does a deep copy of the format block

	CMediaType::CMediaType(const AM_MEDIA_TYPE& rt, __out_opt HRESULT* phr)
	{
	HRESULT hr = CopyMediaType(this, &rt);
	if (FAILED(hr) && (NULL != phr)) {
	*phr = hr;
	}
	}


	CMediaType::CMediaType(const CMediaType& rt, __out_opt HRESULT* phr)
	{
	HRESULT hr = CopyMediaType(this, &rt);
	if (FAILED(hr) && (NULL != phr)) {
	*phr = hr;
	}
	}


	// this class inherits publicly from AM_MEDIA_TYPE so the compiler could generate
	// the following assignment operator itself, however it could introduce some
	// memory conflicts and leaks in the process because the structure contains
	// a dynamically allocated block (pbFormat) which it will not copy correctly

	CMediaType&
	CMediaType::operator=(const AM_MEDIA_TYPE& rt)
	{
	Set(rt);
	return *this;
	}

	CMediaType&
	CMediaType::operator=(const CMediaType& rt)
	{
	*this = (AM_MEDIA_TYPE &) rt;
	return *this;
	}

	BOOL
	CMediaType::operator == (const CMediaType& rt) const
	{
	// I don't believe we need to check sample size or
	// temporal compression flags, since I think these must
	// be represented in the type, subtype and format somehow. They
	// are pulled out as separate flags so that people who don't understand
	// the particular format representation can still see them, but
	// they should duplicate information in the format block.

	return ((IsEqualGUID(majortype,rt.majortype) == TRUE) &&
	(IsEqualGUID(subtype,rt.subtype) == TRUE) &&
	(IsEqualGUID(formattype,rt.formattype) == TRUE) &&
	(cbFormat == rt.cbFormat) &&
	( (cbFormat == 0) \|\|
	pbFormat != NULL && rt.pbFormat != NULL &&
	(memcmp(pbFormat, rt.pbFormat, cbFormat) == 0)));
	}


	BOOL
	CMediaType::operator != (const CMediaType& rt) const
	{
	/* Check to see if they are equal */

	if (*this == rt) {
	return FALSE;
	}
	return TRUE;
	}


	HRESULT
	CMediaType::Set(const CMediaType& rt)
	{
	return Set((AM_MEDIA_TYPE &) rt);
	}


	HRESULT
	CMediaType::Set(const AM_MEDIA_TYPE& rt)
	{
	if (&rt != this) {
	FreeMediaType(*this);
	HRESULT hr = CopyMediaType(this, &rt);
	if (FAILED(hr)) {
	return E_OUTOFMEMORY;
	}
	}

	return S_OK;
	}


	BOOL
	CMediaType::IsValid() const
	{
	return (!IsEqualGUID(majortype,GUID_NULL));
	}


	void
	CMediaType::SetType(const GUID* ptype)
	{
	majortype = *ptype;
	}


	void
	CMediaType::SetSubtype(const GUID* ptype)
	{
	subtype = *ptype;
	}


	ULONG
	CMediaType::GetSampleSize() const {
	if (IsFixedSize()) {
	return lSampleSize;
	} else {
	return 0;
	}
	}


	void
	CMediaType::SetSampleSize(ULONG sz) {
	if (sz == 0) {
	SetVariableSize();
	} else {
	bFixedSizeSamples = TRUE;
	lSampleSize = sz;
	}
	}


	void
	CMediaType::SetVariableSize() {
	bFixedSizeSamples = FALSE;
	}


	void
	CMediaType::SetTemporalCompression(BOOL bCompressed) {
	bTemporalCompression = bCompressed;
	}

	BOOL
	CMediaType::SetFormat(__in_bcount(cb) BYTE * pformat, ULONG cb)
	{
	if (NULL == AllocFormatBuffer(cb))
	return(FALSE);

	ASSERT(pbFormat);
	memcpy(pbFormat, pformat, cb);
	return(TRUE);
	}


	// set the type of the media type format block, this type defines what you
	// will actually find in the format pointer. For example FORMAT_VideoInfo or
	// FORMAT_WaveFormatEx. In the future this may be an interface pointer to a
	// property set. Before sending out media types this should be filled in.

	void
	CMediaType::SetFormatType(const GUID *pformattype)
	{
	formattype = *pformattype;
	}


	// reset the format buffer

	void CMediaType::ResetFormatBuffer()
	{
	if (cbFormat) {
	CoTaskMemFree((PVOID)pbFormat);
	}
	cbFormat = 0;
	pbFormat = NULL;
	}


	// allocate length bytes for the format and return a read/write pointer
	// If we cannot allocate the new block of memory we return NULL leaving
	// the original block of memory untouched (as does ReallocFormatBuffer)

	BYTE*
	CMediaType::AllocFormatBuffer(ULONG length)
	{
	ASSERT(length);

	// do the types have the same buffer size

	if (cbFormat == length) {
	return pbFormat;
	}

	// allocate the new format buffer

	BYTE *pNewFormat = (PBYTE)CoTaskMemAlloc(length);
	if (pNewFormat == NULL) {
	if (length <= cbFormat) return pbFormat; //reuse the old block anyway.
	return NULL;
	}

	// delete the old format

	if (cbFormat != 0) {
	ASSERT(pbFormat);
	CoTaskMemFree((PVOID)pbFormat);
	}

	cbFormat = length;
	pbFormat = pNewFormat;
	return pbFormat;
	}


	// reallocate length bytes for the format and return a read/write pointer
	// to it. We keep as much information as we can given the new buffer size
	// if this fails the original format buffer is left untouched. The caller
	// is responsible for ensuring the size of memory required is non zero

	BYTE*
	CMediaType::ReallocFormatBuffer(ULONG length)
	{
	ASSERT(length);

	// do the types have the same buffer size

	if (cbFormat == length) {
	return pbFormat;
	}

	// allocate the new format buffer

	BYTE *pNewFormat = (PBYTE)CoTaskMemAlloc(length);
	if (pNewFormat == NULL) {
	if (length <= cbFormat) return pbFormat; //reuse the old block anyway.
	return NULL;
	}

	// copy any previous format (or part of if new is smaller)
	// delete the old format and replace with the new one

	if (cbFormat != 0) {
	ASSERT(pbFormat);
	memcpy(pNewFormat,pbFormat,min(length,cbFormat));
	CoTaskMemFree((PVOID)pbFormat);
	}

	cbFormat = length;
	pbFormat = pNewFormat;
	return pNewFormat;
	}

	// initialise a media type structure

	void CMediaType::InitMediaType()
	{
	ZeroMemory((PVOID)this, sizeof(*this));
	lSampleSize = 1;
	bFixedSizeSamples = TRUE;
	}


	// a partially specified media type can be passed to IPin::Connect
	// as a constraint on the media type used in the connection.
	// the type, subtype or format type can be null.
	BOOL
	CMediaType::IsPartiallySpecified(void) const
	{
	if ((majortype == GUID_NULL) \|\|
	(formattype == GUID_NULL)) {
	return TRUE;
	} else {
	return FALSE;
	}
	}

	BOOL
	CMediaType::MatchesPartial(const CMediaType* ppartial) const
	{
	if ((ppartial->majortype != GUID_NULL) &&
	(majortype != ppartial->majortype)) {
	return FALSE;
	}
	if ((ppartial->subtype != GUID_NULL) &&
	(subtype != ppartial->subtype)) {
	return FALSE;
	}

	if (ppartial->formattype != GUID_NULL) {
	// if the format block is specified then it must match exactly
	if (formattype != ppartial->formattype) {
	return FALSE;
	}
	if (cbFormat != ppartial->cbFormat) {
	return FALSE;
	}
	if ((cbFormat != 0) &&
	(memcmp(pbFormat, ppartial->pbFormat, cbFormat) != 0)) {
	return FALSE;
	}
	}

	return TRUE;

	}



	// general purpose function to delete a heap allocated AM_MEDIA_TYPE structure
	// which is useful when calling IEnumMediaTypes::Next as the interface
	// implementation allocates the structures which you must later delete
	// the format block may also be a pointer to an interface to release

	void WINAPI DeleteMediaType(__inout_opt AM_MEDIA_TYPE *pmt)
	{
	// allow NULL pointers for coding simplicity

	if (pmt == NULL) {
	return;
	}

	FreeMediaType(*pmt);
	CoTaskMemFree((PVOID)pmt);
	}


	// this also comes in useful when using the IEnumMediaTypes interface so
	// that you can copy a media type, you can do nearly the same by creating
	// a CMediaType object but as soon as it goes out of scope the destructor
	// will delete the memory it allocated (this takes a copy of the memory)

	AM_MEDIA_TYPE * WINAPI CreateMediaType(AM_MEDIA_TYPE const *pSrc)
	{
	ASSERT(pSrc);

	// Allocate a block of memory for the media type

	AM_MEDIA_TYPE *pMediaType =
	(AM_MEDIA_TYPE *)CoTaskMemAlloc(sizeof(AM_MEDIA_TYPE));

	if (pMediaType == NULL) {
	return NULL;
	}
	// Copy the variable length format block

	HRESULT hr = CopyMediaType(pMediaType,pSrc);
	if (FAILED(hr)) {
	CoTaskMemFree((PVOID)pMediaType);
	return NULL;
	}

	return pMediaType;
	}


	// Copy 1 media type to another

	HRESULT WINAPI CopyMediaType(__out AM_MEDIA_TYPE pmtTarget, const AM_MEDIA_TYPE pmtSource)
	{
	// We'll leak if we copy onto one that already exists - there's one
	// case we can check like that - copying to itself.
	ASSERT(pmtSource != pmtTarget);
	pmtTarget = pmtSource;
	if (pmtSource->cbFormat != 0) {
	ASSERT(pmtSource->pbFormat != NULL);
	pmtTarget->pbFormat = (PBYTE)CoTaskMemAlloc(pmtSource->cbFormat);
	if (pmtTarget->pbFormat == NULL) {
	pmtTarget->cbFormat = 0;
	return E_OUTOFMEMORY;
	} else {
	CopyMemory((PVOID)pmtTarget->pbFormat, (PVOID)pmtSource->pbFormat,
	pmtTarget->cbFormat);
	}
	}
	if (pmtTarget->pUnk != NULL) {
	pmtTarget->pUnk->AddRef();
	}

	return S_OK;
	}

	// Free an existing media type (ie free resources it holds)

	void WINAPI FreeMediaType(__inout AM_MEDIA_TYPE& mt)
	{
	if (mt.cbFormat != 0) {
	CoTaskMemFree((PVOID)mt.pbFormat);

	// Strictly unnecessary but tidier
	mt.cbFormat = 0;
	mt.pbFormat = NULL;
	}
	if (mt.pUnk != NULL) {
	mt.pUnk->Release();
	mt.pUnk = NULL;
	}
	}

	// Initialize a media type from a WAVEFORMATEX

	STDAPI CreateAudioMediaType(
	const WAVEFORMATEX *pwfx,
	__out AM_MEDIA_TYPE *pmt,
	BOOL bSetFormat
	)
	{
	pmt->majortype = MEDIATYPE_Audio;
	if (pwfx->wFormatTag == WAVE_FORMAT_EXTENSIBLE) {
	pmt->subtype = ((PWAVEFORMATEXTENSIBLE)pwfx)->SubFormat;
	} else {
	pmt->subtype = FOURCCMap(pwfx->wFormatTag);
	}
	pmt->formattype = FORMAT_WaveFormatEx;
	pmt->bFixedSizeSamples = TRUE;
	pmt->bTemporalCompression = FALSE;
	pmt->lSampleSize = pwfx->nBlockAlign;
	pmt->pUnk = NULL;
	if (bSetFormat) {
	if (pwfx->wFormatTag == WAVE_FORMAT_PCM) {
	pmt->cbFormat = sizeof(WAVEFORMATEX);
	} else {
	pmt->cbFormat = sizeof(WAVEFORMATEX) + pwfx->cbSize;
	}
	pmt->pbFormat = (PBYTE)CoTaskMemAlloc(pmt->cbFormat);
	if (pmt->pbFormat == NULL) {
	return E_OUTOFMEMORY;
	}
	if (pwfx->wFormatTag == WAVE_FORMAT_PCM) {
	CopyMemory(pmt->pbFormat, pwfx, sizeof(PCMWAVEFORMAT));
	((WAVEFORMATEX *)pmt->pbFormat)->cbSize = 0;
	} else {
	CopyMemory(pmt->pbFormat, pwfx, pmt->cbFormat);
	}
	}
	return S_OK;
	}

	// eliminate very many spurious warnings from MS compiler
	#pragma warning(disable:4514)