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

 //------------------------------------------------------------------------------
 // File: AMVideo.cpp
 //
 // Desc: DirectShow base classes - implements helper functions for
 //       bitmap formats.
 //
 // Copyright (c) 1992-2001 Microsoft Corporation.  All rights reserved.
 //------------------------------------------------------------------------------


 #include <streams.h>
 #include <limits.h>

 // These are bit field masks for true colour devices

 const DWORD bits555[] = {0x007C00,0x0003E0,0x00001F};
 const DWORD bits565[] = {0x00F800,0x0007E0,0x00001F};
 const DWORD bits888[] = {0xFF0000,0x00FF00,0x0000FF};

 // This maps bitmap subtypes into a bits per pixel value and also a
 // name. unicode and ansi versions are stored because we have to
 // return a pointer to a static string.
 const struct {
     const GUID *pSubtype;
     WORD BitCount;
     CHAR *pName;
     WCHAR *wszName;
 } BitCountMap[] =  { &MEDIASUBTYPE_RGB1,        1,   "RGB Monochrome",     L"RGB Monochrome",
                      &MEDIASUBTYPE_RGB4,        4,   "RGB VGA",            L"RGB VGA",
                      &MEDIASUBTYPE_RGB8,        8,   "RGB 8",              L"RGB 8",
                      &MEDIASUBTYPE_RGB565,      16,  "RGB 565 (16 bit)",   L"RGB 565 (16 bit)",
                      &MEDIASUBTYPE_RGB555,      16,  "RGB 555 (16 bit)",   L"RGB 555 (16 bit)",
                      &MEDIASUBTYPE_RGB24,       24,  "RGB 24",             L"RGB 24",
                      &MEDIASUBTYPE_RGB32,       32,  "RGB 32",             L"RGB 32",
                      &MEDIASUBTYPE_ARGB32,    32,  "ARGB 32",             L"ARGB 32",
                      &MEDIASUBTYPE_Overlay,     0,   "Overlay",            L"Overlay",
                      &GUID_NULL,                0,   "UNKNOWN",            L"UNKNOWN"
 };

 // Return the size of the bitmap as defined by this header

 STDAPI_(DWORD) GetBitmapSize(const BITMAPINFOHEADER *pHeader)
 {
     return DIBSIZE(*pHeader);
 }


 // This is called if the header has a 16 bit colour depth and needs to work
 // out the detailed type from the bit fields (either RGB 565 or RGB 555)

 STDAPI_(const GUID) GetTrueColorType(const BITMAPINFOHEADER *pbmiHeader)
 {
     BITMAPINFO *pbmInfo = (BITMAPINFO *) pbmiHeader;
     ASSERT(pbmiHeader->biBitCount == 16);

     // If its BI_RGB then it's RGB 555 by default

     if (pbmiHeader->biCompression == BI_RGB) {
         return MEDIASUBTYPE_RGB555;
     }

     // Compare the bit fields with RGB 555

     DWORD *pMask = (DWORD *) pbmInfo->bmiColors;
     if (pMask[0] == bits555[0]) {
         if (pMask[1] == bits555[1]) {
             if (pMask[2] == bits555[2]) {
                 return MEDIASUBTYPE_RGB555;
             }
         }
     }

     // Compare the bit fields with RGB 565

     pMask = (DWORD *) pbmInfo->bmiColors;
     if (pMask[0] == bits565[0]) {
         if (pMask[1] == bits565[1]) {
             if (pMask[2] == bits565[2]) {
                 return MEDIASUBTYPE_RGB565;
             }
         }
     }
     return GUID_NULL;
 }


 // Given a BITMAPINFOHEADER structure this returns the GUID sub type that is
 // used to describe it in format negotiations. For example a video codec fills
 // in the format block with a VIDEOINFO structure, it also fills in the major
 // type with MEDIATYPE_VIDEO and the subtype with a GUID that matches the bit
 // count, for example if it is an eight bit image then MEDIASUBTYPE_RGB8

 STDAPI_(const GUID) GetBitmapSubtype(const BITMAPINFOHEADER *pbmiHeader)
 {
     ASSERT(pbmiHeader);

     // If it's not RGB then create a GUID from the compression type

     if (pbmiHeader->biCompression != BI_RGB) {
         if (pbmiHeader->biCompression != BI_BITFIELDS) {
             FOURCCMap FourCCMap(pbmiHeader->biCompression);
             return (const GUID) FourCCMap;
         }
     }

     // Map the RGB DIB bit depth to a image GUID

     switch(pbmiHeader->biBitCount) {
         case 1    :   return MEDIASUBTYPE_RGB1;
         case 4    :   return MEDIASUBTYPE_RGB4;
         case 8    :   return MEDIASUBTYPE_RGB8;
         case 16   :   return GetTrueColorType(pbmiHeader);
         case 24   :   return MEDIASUBTYPE_RGB24;
         case 32   :   return MEDIASUBTYPE_RGB32;
     }
     return GUID_NULL;
 }


 // Given a video bitmap subtype we return the number of bits per pixel it uses
 // We return a WORD bit count as thats what the BITMAPINFOHEADER uses. If the
 // GUID subtype is not found in the table we return an invalid USHRT_MAX

 STDAPI_(WORD) GetBitCount(const GUID *pSubtype)
 {
     ASSERT(pSubtype);
     const GUID *pMediaSubtype;
     INT iPosition = 0;

     // Scan the mapping list seeing if the source GUID matches any known
     // bitmap subtypes, the list is terminated by a GUID_NULL entry

     while (TRUE) {
         pMediaSubtype = BitCountMap[iPosition].pSubtype;
         if (IsEqualGUID(*pMediaSubtype,GUID_NULL)) {
             return USHRT_MAX;
         }
         if (IsEqualGUID(*pMediaSubtype,*pSubtype)) {
             return BitCountMap[iPosition].BitCount;
         }
         iPosition++;
     }
 }


 // Given a bitmap subtype we return a description name that can be used for
 // debug purposes. In a retail build this function still returns the names
 // If the subtype isn't found in the lookup table we return string UNKNOWN

 int LocateSubtype(const GUID *pSubtype)
 {
     ASSERT(pSubtype);
     const GUID *pMediaSubtype;
     INT iPosition = 0;

     // Scan the mapping list seeing if the source GUID matches any known
     // bitmap subtypes, the list is terminated by a GUID_NULL entry

     while (TRUE) {
         pMediaSubtype = BitCountMap[iPosition].pSubtype;
         if (IsEqualGUID(*pMediaSubtype,*pSubtype) ||
             IsEqualGUID(*pMediaSubtype,GUID_NULL)
             )
         {
             break;
         }

         iPosition++;
     }

     return iPosition;
 }


 STDAPI_(WCHAR *) GetSubtypeNameW(const GUID *pSubtype)
 {
     return BitCountMap[LocateSubtype(pSubtype)].wszName;
 }

 STDAPI_(CHAR *) GetSubtypeNameA(const GUID *pSubtype)
 {
     return BitCountMap[LocateSubtype(pSubtype)].pName;
 }

 #ifndef GetSubtypeName
 #error wxutil.h should have defined GetSubtypeName
 #endif
 #undef GetSubtypeName

 // this is here for people that linked to it directly; most people
 // would use the header file that picks the A or W version.
 STDAPI_(CHAR *) GetSubtypeName(const GUID *pSubtype)
 {
     return GetSubtypeNameA(pSubtype);
 }


 // The mechanism for describing a bitmap format is with the BITMAPINFOHEADER
 // This is really messy to deal with because it invariably has fields that
 // follow it holding bit fields, palettes and the rest. This function gives
 // the number of bytes required to hold a VIDEOINFO that represents it. This
 // count includes the prefix information (like the rcSource rectangle) the
 // BITMAPINFOHEADER field, and any other colour information on the end.
 //
 // WARNING If you want to copy a BITMAPINFOHEADER into a VIDEOINFO always make
 // sure that you use the HEADER macro because the BITMAPINFOHEADER field isn't
 // right at the start of the VIDEOINFO (there are a number of other fields),
 //
 //     CopyMemory(HEADER(pVideoInfo),pbmi,sizeof(BITMAPINFOHEADER));
 //

 STDAPI_(LONG) GetBitmapFormatSize(const BITMAPINFOHEADER *pHeader)
 {
     // Everyone has this to start with this
     LONG Size = SIZE_PREHEADER + pHeader->biSize;

     ASSERT(pHeader->biSize >= sizeof(BITMAPINFOHEADER));

     // Does this format use a palette, if the number of colours actually used
     // is zero then it is set to the maximum that are allowed for that colour
     // depth (an example is 256 for eight bits). Truecolour formats may also
     // pass a palette with them in which case the used count is non zero

     // This would scare me.
     ASSERT(pHeader->biBitCount <= iPALETTE || pHeader->biClrUsed == 0);

     if (pHeader->biBitCount <= iPALETTE || pHeader->biClrUsed) {
         LONG Entries = (DWORD) 1 << pHeader->biBitCount;
         if (pHeader->biClrUsed) {
             Entries = pHeader->biClrUsed;
         }
         Size += Entries * sizeof(RGBQUAD);
     }

     // Truecolour formats may have a BI_BITFIELDS specifier for compression
     // type which means that room for three DWORDs should be allocated that
     // specify where in each pixel the RGB colour components may be found

     if (pHeader->biCompression == BI_BITFIELDS) {
         Size += SIZE_MASKS;
     }

     // A BITMAPINFO for a palettised image may also contain a palette map that
     // provides the information to map from a source palette to a destination
     // palette during a BitBlt for example, because this information is only
     // ever processed during drawing you don't normally store the palette map
     // nor have any way of knowing if it is present in the data structure

     return Size;
 }


 // Returns TRUE if the VIDEOINFO contains a palette

 STDAPI_(BOOL) ContainsPalette(const VIDEOINFOHEADER *pVideoInfo)
 {
     if (PALETTISED(pVideoInfo) == FALSE) {
         if (pVideoInfo->bmiHeader.biClrUsed == 0) {
             return FALSE;
         }
     }
     return TRUE;
 }


 // Return a pointer to the first entry in a palette

 STDAPI_(const RGBQUAD *) GetBitmapPalette(const VIDEOINFOHEADER *pVideoInfo)
 {
     if (pVideoInfo->bmiHeader.biCompression == BI_BITFIELDS) {
         return TRUECOLOR(pVideoInfo)->bmiColors;
     }
     return COLORS(pVideoInfo);
 }
	//------------------------------------------------------------------------------
	// File: AMVideo.cpp
	//
	// Desc: DirectShow base classes - implements helper functions for
	// bitmap formats.
	//
	// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
	//------------------------------------------------------------------------------


	#include <streams.h>
	#include <limits.h>

	// These are bit field masks for true colour devices

	const DWORD bits555[] = {0x007C00,0x0003E0,0x00001F};
	const DWORD bits565[] = {0x00F800,0x0007E0,0x00001F};
	const DWORD bits888[] = {0xFF0000,0x00FF00,0x0000FF};

	// This maps bitmap subtypes into a bits per pixel value and also a
	// name. unicode and ansi versions are stored because we have to
	// return a pointer to a static string.
	const struct {
	const GUID *pSubtype;
	WORD BitCount;
	CHAR *pName;
	WCHAR *wszName;
	} BitCountMap[] = { &MEDIASUBTYPE_RGB1, 1, "RGB Monochrome", L"RGB Monochrome",
	&MEDIASUBTYPE_RGB4, 4, "RGB VGA", L"RGB VGA",
	&MEDIASUBTYPE_RGB8, 8, "RGB 8", L"RGB 8",
	&MEDIASUBTYPE_RGB565, 16, "RGB 565 (16 bit)", L"RGB 565 (16 bit)",
	&MEDIASUBTYPE_RGB555, 16, "RGB 555 (16 bit)", L"RGB 555 (16 bit)",
	&MEDIASUBTYPE_RGB24, 24, "RGB 24", L"RGB 24",
	&MEDIASUBTYPE_RGB32, 32, "RGB 32", L"RGB 32",
	&MEDIASUBTYPE_ARGB32, 32, "ARGB 32", L"ARGB 32",
	&MEDIASUBTYPE_Overlay, 0, "Overlay", L"Overlay",
	&GUID_NULL, 0, "UNKNOWN", L"UNKNOWN"
	};

	// Return the size of the bitmap as defined by this header

	STDAPI_(DWORD) GetBitmapSize(const BITMAPINFOHEADER *pHeader)
	{
	return DIBSIZE(*pHeader);
	}


	// This is called if the header has a 16 bit colour depth and needs to work
	// out the detailed type from the bit fields (either RGB 565 or RGB 555)

	STDAPI_(const GUID) GetTrueColorType(const BITMAPINFOHEADER *pbmiHeader)
	{
	BITMAPINFO pbmInfo = (BITMAPINFO ) pbmiHeader;
	ASSERT(pbmiHeader->biBitCount == 16);

	// If its BI_RGB then it's RGB 555 by default

	if (pbmiHeader->biCompression == BI_RGB) {
	return MEDIASUBTYPE_RGB555;
	}

	// Compare the bit fields with RGB 555

	DWORD pMask = (DWORD ) pbmInfo->bmiColors;
	if (pMask[0] == bits555[0]) {
	if (pMask[1] == bits555[1]) {
	if (pMask[2] == bits555[2]) {
	return MEDIASUBTYPE_RGB555;
	}
	}
	}

	// Compare the bit fields with RGB 565

	pMask = (DWORD *) pbmInfo->bmiColors;
	if (pMask[0] == bits565[0]) {
	if (pMask[1] == bits565[1]) {
	if (pMask[2] == bits565[2]) {
	return MEDIASUBTYPE_RGB565;
	}
	}
	}
	return GUID_NULL;
	}


	// Given a BITMAPINFOHEADER structure this returns the GUID sub type that is
	// used to describe it in format negotiations. For example a video codec fills
	// in the format block with a VIDEOINFO structure, it also fills in the major
	// type with MEDIATYPE_VIDEO and the subtype with a GUID that matches the bit
	// count, for example if it is an eight bit image then MEDIASUBTYPE_RGB8

	STDAPI_(const GUID) GetBitmapSubtype(const BITMAPINFOHEADER *pbmiHeader)
	{
	ASSERT(pbmiHeader);

	// If it's not RGB then create a GUID from the compression type

	if (pbmiHeader->biCompression != BI_RGB) {
	if (pbmiHeader->biCompression != BI_BITFIELDS) {
	FOURCCMap FourCCMap(pbmiHeader->biCompression);
	return (const GUID) FourCCMap;
	}
	}

	// Map the RGB DIB bit depth to a image GUID

	switch(pbmiHeader->biBitCount) {
	case 1 : return MEDIASUBTYPE_RGB1;
	case 4 : return MEDIASUBTYPE_RGB4;
	case 8 : return MEDIASUBTYPE_RGB8;
	case 16 : return GetTrueColorType(pbmiHeader);
	case 24 : return MEDIASUBTYPE_RGB24;
	case 32 : return MEDIASUBTYPE_RGB32;
	}
	return GUID_NULL;
	}


	// Given a video bitmap subtype we return the number of bits per pixel it uses
	// We return a WORD bit count as thats what the BITMAPINFOHEADER uses. If the
	// GUID subtype is not found in the table we return an invalid USHRT_MAX

	STDAPI_(WORD) GetBitCount(const GUID *pSubtype)
	{
	ASSERT(pSubtype);
	const GUID *pMediaSubtype;
	INT iPosition = 0;

	// Scan the mapping list seeing if the source GUID matches any known
	// bitmap subtypes, the list is terminated by a GUID_NULL entry

	while (TRUE) {
	pMediaSubtype = BitCountMap[iPosition].pSubtype;
	if (IsEqualGUID(*pMediaSubtype,GUID_NULL)) {
	return USHRT_MAX;
	}
	if (IsEqualGUID(pMediaSubtype,pSubtype)) {
	return BitCountMap[iPosition].BitCount;
	}
	iPosition++;
	}
	}


	// Given a bitmap subtype we return a description name that can be used for
	// debug purposes. In a retail build this function still returns the names
	// If the subtype isn't found in the lookup table we return string UNKNOWN

	int LocateSubtype(const GUID *pSubtype)
	{
	ASSERT(pSubtype);
	const GUID *pMediaSubtype;
	INT iPosition = 0;

	// Scan the mapping list seeing if the source GUID matches any known
	// bitmap subtypes, the list is terminated by a GUID_NULL entry

	while (TRUE) {
	pMediaSubtype = BitCountMap[iPosition].pSubtype;
	if (IsEqualGUID(pMediaSubtype,pSubtype) \|\|
	IsEqualGUID(*pMediaSubtype,GUID_NULL)
	)
	{
	break;
	}

	iPosition++;
	}

	return iPosition;
	}



	STDAPI_(WCHAR ) GetSubtypeNameW(const GUID pSubtype)
	{
	return BitCountMap[LocateSubtype(pSubtype)].wszName;
	}

	STDAPI_(CHAR ) GetSubtypeNameA(const GUID pSubtype)
	{
	return BitCountMap[LocateSubtype(pSubtype)].pName;
	}

	#ifndef GetSubtypeName
	#error wxutil.h should have defined GetSubtypeName
	#endif
	#undef GetSubtypeName

	// this is here for people that linked to it directly; most people
	// would use the header file that picks the A or W version.
	STDAPI_(CHAR ) GetSubtypeName(const GUID pSubtype)
	{
	return GetSubtypeNameA(pSubtype);
	}


	// The mechanism for describing a bitmap format is with the BITMAPINFOHEADER
	// This is really messy to deal with because it invariably has fields that
	// follow it holding bit fields, palettes and the rest. This function gives
	// the number of bytes required to hold a VIDEOINFO that represents it. This
	// count includes the prefix information (like the rcSource rectangle) the
	// BITMAPINFOHEADER field, and any other colour information on the end.
	//
	// WARNING If you want to copy a BITMAPINFOHEADER into a VIDEOINFO always make
	// sure that you use the HEADER macro because the BITMAPINFOHEADER field isn't
	// right at the start of the VIDEOINFO (there are a number of other fields),
	//
	// CopyMemory(HEADER(pVideoInfo),pbmi,sizeof(BITMAPINFOHEADER));
	//

	STDAPI_(LONG) GetBitmapFormatSize(const BITMAPINFOHEADER *pHeader)
	{
	// Everyone has this to start with this
	LONG Size = SIZE_PREHEADER + pHeader->biSize;

	ASSERT(pHeader->biSize >= sizeof(BITMAPINFOHEADER));

	// Does this format use a palette, if the number of colours actually used
	// is zero then it is set to the maximum that are allowed for that colour
	// depth (an example is 256 for eight bits). Truecolour formats may also
	// pass a palette with them in which case the used count is non zero

	// This would scare me.
	ASSERT(pHeader->biBitCount <= iPALETTE \|\| pHeader->biClrUsed == 0);

	if (pHeader->biBitCount <= iPALETTE \|\| pHeader->biClrUsed) {
	LONG Entries = (DWORD) 1 << pHeader->biBitCount;
	if (pHeader->biClrUsed) {
	Entries = pHeader->biClrUsed;
	}
	Size += Entries * sizeof(RGBQUAD);
	}

	// Truecolour formats may have a BI_BITFIELDS specifier for compression
	// type which means that room for three DWORDs should be allocated that
	// specify where in each pixel the RGB colour components may be found

	if (pHeader->biCompression == BI_BITFIELDS) {
	Size += SIZE_MASKS;
	}

	// A BITMAPINFO for a palettised image may also contain a palette map that
	// provides the information to map from a source palette to a destination
	// palette during a BitBlt for example, because this information is only
	// ever processed during drawing you don't normally store the palette map
	// nor have any way of knowing if it is present in the data structure

	return Size;
	}


	// Returns TRUE if the VIDEOINFO contains a palette

	STDAPI_(BOOL) ContainsPalette(const VIDEOINFOHEADER *pVideoInfo)
	{
	if (PALETTISED(pVideoInfo) == FALSE) {
	if (pVideoInfo->bmiHeader.biClrUsed == 0) {
	return FALSE;
	}
	}
	return TRUE;
	}


	// Return a pointer to the first entry in a palette

	STDAPI_(const RGBQUAD ) GetBitmapPalette(const VIDEOINFOHEADER pVideoInfo)
	{
	if (pVideoInfo->bmiHeader.biCompression == BI_BITFIELDS) {
	return TRUECOLOR(pVideoInfo)->bmiColors;
	}
	return COLORS(pVideoInfo);
	}