Leaked source code of windows server 2003
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//
// loadimag.cpp
//
// implementation of loading a file from disk via an installed graphic filter
//
#include "stdafx.h"
#include "pbrush.h"
#include "imgwnd.h"
#include "imgsuprt.h"
#include "loadimag.h"
#include "bmpstrm.h"
#include "imaging.h"
#include <atlbase.h>
// must define one of the following:
//#define _USE_FLT_API
#ifdef _X86_
#define _USE_IFL_API
#endif
#ifdef _USE_FLT_API
#include "filtapi.h"
#endif
#ifdef _USE_IFL_API
#include "image.h"
#include "interlac.h"
#define MAX_PAL_SIZE 256
#ifdef PNG_SUPPORT // for Portable Network Graphics. As of 12/10/1996 the support was broken
//----------------------------------------------------------------------------
// Places a line of image data from an ADAM 7 interlaced file (i.e., currently
// a PNG file) into its correct position in a memory buffer: this memory
// buffer is essentially an array of pointers to the rows of the image in
// which the pixel data is to be set.
//----------------------------------------------------------------------------
IFLERROR ReadADAM7InterlacedImage(LPBYTE apbImageBuffer[], IFLHANDLE pfpbFROM,
int ImageHeight, int ImageWidth, int cbPixelSize,
IFLCLASS ImageClass)
{
int cRasterLines = iflGetRasterLineCount(pfpbFROM);
ADAM7_STRUCT stAdam7;
stAdam7.iImageHeight = ImageHeight;
stAdam7.iImageWidth = ImageWidth;
stAdam7.Class = ImageClass;
stAdam7.cbPixelSize = iflGetBitsPerPixel (pfpbFROM)/8;//cbPixelSize;
stAdam7.iPassLine = 0;
LPBYTE pbScanLine = (LPBYTE)HeapAlloc(GetProcessHeap(), 0, ImageWidth * stAdam7.cbPixelSize);
wsprintf (buf, TEXT("Pixel size: %d, Size of a scan line: %d\n"), stAdam7.cbPixelSize,
ImageWidth*stAdam7.cbPixelSize);
if (pbScanLine == NULL)
return IFLERR_MEMORY;
int cTotalScanLines = iADAM7CalculateNumberOfScanLines(&stAdam7);
int iLine;
IFLERROR idErr;
BOOL fEmptyLine;
for (iLine = 0, idErr = IFLERR_NONE, fEmptyLine = FALSE;
idErr == IFLERR_NONE && iLine < (int)cRasterLines;
iLine++)
{
if (!fEmptyLine)
idErr = iflRead(pfpbFROM, pbScanLine, 1);
stAdam7.iScanLine = iLine;
fEmptyLine = ADAM7AddRowToImageBuffer(apbImageBuffer, pbScanLine, &stAdam7);
}
HeapFree(GetProcessHeap(), 0, pbScanLine);
return idErr;
}
//----------------------------------------------------------------------------
// Deallocates the image space allocated in the function AllocateImageSpace()
//----------------------------------------------------------------------------
LPBYTE *FreeImageSpace(HANDLE hHeap, LPBYTE ppImageSpace[], int height)
{
if (ppImageSpace != NULL)
{
for (int i = 0; i < height; i++)
{
if (ppImageSpace[i] != NULL)
{
HeapFree(hHeap, 0, ppImageSpace[i]);
ppImageSpace[i] = NULL;
}
}
HeapFree(hHeap, 0, ppImageSpace);
ppImageSpace = NULL;
}
return ppImageSpace;
}
//----------------------------------------------------------------------------
// Allocate some image space: this function will create a dynamic array
// of "height" pointers which each point to an allocated row of bytes of
// size "width".
//----------------------------------------------------------------------------
LPBYTE *AllocateImageSpace(HANDLE hHeap, int height, int width, int cbSize)
{
LPBYTE *ppImageSpace = (LPBYTE *)HeapAlloc(hHeap, 0, height * sizeof(void *));
TCHAR buf[200];
wsprintf (buf, TEXT("Size of image line: %d\n"), width*cbSize);
if (ppImageSpace != NULL)
{
// Init the pointers to NULL: this makes error recovery easier
for (int i = 0; i < height; i++)
ppImageSpace[i] = NULL;
// NOW allocate the pointer space for the image
for (i = 0; i < height; i++)
{
ppImageSpace[i] = (LPBYTE)HeapAlloc(hHeap, 0, width * cbSize);
if (ppImageSpace[i] == NULL)
break;
}
if (i < height) // We weren't able to allocate the required space
ppImageSpace = FreeImageSpace(hHeap, ppImageSpace, height);
}
return ppImageSpace;
}
#endif // PNG_SUPPORT
#endif // _USE_IFL_API
// returns a pointer to the extension of a file.
//
// in:
// qualified or unqualfied file name
//
// returns:
// pointer to the extension of this file. if there is no extension
// as in "foo" we return a pointer to the NULL at the end
// of the file
//
// foo.txt ==> ".txt"
// foo ==> ""
// foo. ==> "."
//
LPCTSTR FindExtension(LPCTSTR pszPath)
{
for (LPCTSTR pszDot = NULL; *pszPath; pszPath = CharNext(pszPath))
{
switch (*pszPath)
{
case TEXT('.'):
pszDot = pszPath; // remember the last dot
break;
case TEXT('\\'):
case TEXT(' '): // extensions can't have spaces
pszDot = NULL; // forget last dot, it was in a directory
break;
}
}
// if we found the extension, return ptr to the dot, else
// ptr to end of the string (NULL extension)
return pszDot ? pszDot : pszPath;
}
//
// GetFilterInfo
//
// 32-bit import filters are listed in the registry...
//
// HKLM\SOFTWARE\Microsoft\Shared Tools\Graphics Filters\Import\XXX
// Path = filename
// Name = friendly name
// Extenstions = file extenstion list
//
#pragma data_seg(".text")
static const TCHAR c_szImpHandlerKey[] = TEXT("SOFTWARE\\Microsoft\\Shared Tools\\Graphics Filters\\Import");
static const TCHAR c_szExpHandlerKey[] = TEXT("SOFTWARE\\Microsoft\\Shared Tools\\Graphics Filters\\Export");
static const TCHAR c_szName[] = TEXT("Name");
static const TCHAR c_szPath[] = TEXT("Path");
static const TCHAR c_szExts[] = TEXT("Extensions");
static const TCHAR c_szImageAPI[] = TEXT("Image API Enabled Filters");
#pragma data_seg()
BOOL GetInstalledFilters(BOOL bOpenFileDialog, int i, LPTSTR szName, UINT cbName,
LPTSTR szExt, UINT cbExt, LPTSTR szHandler, UINT cbHandler, BOOL& bImageAPI)
{
HKEY hkey;
HKEY hkeyT;
TCHAR ach[80];
BOOL rc = FALSE; // return code
bImageAPI = FALSE;
if (RegOpenKey(HKEY_LOCAL_MACHINE,
bOpenFileDialog ? c_szImpHandlerKey : c_szExpHandlerKey, &hkey) == 0)
{
if (RegEnumKey(hkey, i, ach, sizeof(ach)/sizeof(ach[0]))==0)
{
if (RegOpenKey(hkey, ach, &hkeyT) == 0)
{
if (szName)
{
szName[0] = 0;
RegQueryValueEx(hkeyT, c_szName, NULL, NULL,
(LPBYTE)szName, (LPDWORD)&cbName);
}
if (szExt)
{
szExt[0] = 0;
RegQueryValueEx(hkeyT, c_szExts, NULL, NULL,
(LPBYTE)szExt, (LPDWORD)&cbExt);
}
if (szHandler)
{
szHandler[0] = 0;
RegQueryValueEx(hkeyT, c_szPath, NULL, NULL,
(LPBYTE)szHandler, (LPDWORD)&cbHandler);
}
RegCloseKey(hkeyT);
rc = TRUE;
}
TCHAR szEnabledFilters[1024];
DWORD dwEnabledFiltersSize = sizeof(szEnabledFilters);
// Does the filter support Image Library Files API ?
if (RegQueryValueEx(hkey, c_szImageAPI, NULL, NULL,
(LPBYTE)szEnabledFilters, &dwEnabledFiltersSize) == 0)
{
for (
LPCTSTR pExt = _tcstok(szEnabledFilters, _T(" "));
pExt != NULL && bImageAPI != TRUE;
pExt = _tcstok(NULL, _T(" ")))
{
if (_tcsicmp(pExt, ach) == 0)
{
bImageAPI = TRUE;
}
}
}
}
RegCloseKey(hkey);
}
return rc;
}
#ifdef _USE_FLT_API
//
// GetHandlerForFile
//
// find an import/export filter for the given file.
//
BOOL GetHandlerForFile(BOOL bImport, LPCTSTR szFile, LPTSTR szHandler, UINT cb)
{
TCHAR buf[40];
BOOL rc = FALSE; // return code
*szHandler = 0;
if (szFile == NULL)
return FALSE;
// find the extension
LPCTSTR ext = FindExtension(szFile);
BOOL bImageAPI;
for (int i = 0;
GetInstalledFilters(bImport, i, NULL, 0, buf, sizeof(buf), szHandler, cb, bImageAPI);
i++)
{
if (lstrcmpi(ext+1, buf) == 0)
break;
else
*szHandler = 0;
}
// make sure the handler file does exist
if (*szHandler && GetFileAttributes(szHandler) != -1)
rc = TRUE;
return rc;
}
//
// FindBitmapInfo
//
// find the DIB bitmap in a memory meta file...
//
LPBITMAPINFOHEADER FindBitmapInfo(LPMETAHEADER pmh)
{
for (LPMETARECORD pmr = (LPMETARECORD)((LPBYTE)pmh + pmh->mtHeaderSize*2);
pmr < (LPMETARECORD)((LPBYTE)pmh + pmh->mtSize*2);
pmr = (LPMETARECORD)((LPBYTE)pmr + pmr->rdSize*2))
{
switch (pmr->rdFunction)
{
case META_DIBBITBLT:
return (LPBITMAPINFOHEADER)&(pmr->rdParm[8]);
case META_DIBSTRETCHBLT:
return (LPBITMAPINFOHEADER)&(pmr->rdParm[10]);
case META_STRETCHDIB:
return (LPBITMAPINFOHEADER)&(pmr->rdParm[11]);
case META_SETDIBTODEV:
return (LPBITMAPINFOHEADER)&(pmr->rdParm[9]);
}
}
return NULL;
}
#endif // _USE_FLT_API
#ifdef _USE_IFL_API
IFLERROR ReadGIFInterlacedImage(BYTE *ppbImageBuffer,
IFLHANDLE pfpbFROM,
int ImageHeight, DWORD dwWidthInBytes)
{
int iLine, iPass, iIntLine, iTempLine;
IFLERROR idErr;
WORD InterlaceMultiplier[] = { 8, 8, 4, 2 };
WORD InterlaceOffset[] = { 0, 4, 2, 1 };
idErr = IFLERR_NONE;
iPass = 0;
iIntLine = InterlaceOffset[iPass];
iLine = 0;
while (idErr == IFLERR_NONE && iLine < ImageHeight)
{
iTempLine = InterlaceMultiplier[iPass] * iIntLine + InterlaceOffset[iPass];
if (iTempLine >= ImageHeight)
{
iPass++;
iIntLine = 0;
iTempLine = InterlaceOffset[iPass];
}
if (iTempLine < ImageHeight)
{
idErr = iflRead(pfpbFROM,
(LPBYTE)ppbImageBuffer+((ImageHeight-iTempLine-1)*dwWidthInBytes),
1);
iLine++;
}
iIntLine++;
}
return idErr;
}
#endif // _USE_IFL_API
//
// LoadDIBFromFile
//
// load a image file using a image import filter. The filters use ANSI strings.
//
HGLOBAL LoadDIBFromFileA(LPCSTR szFileName, GUID *pguidFltTypeUsed)
{
#ifdef _USE_IFL_API
IFLTYPE iflType;
iflImageType((LPSTR)szFileName, &iflType);
// make sure the image is of a type we know how to import
if (iflType == IFLT_PNG)
{
return NULL;
}
IFLHANDLE iflHandle = iflCreateReadHandle(iflType);
if (!iflHandle)
{
//
// No filter installed for this type
//
return NULL;
}
LPBYTE lpStart = 0;
__try
{
IFLERROR iflErr = iflOpen(iflHandle, (LPSTR)szFileName, IFLM_READ);
if (iflErr != IFLERR_NONE)
{
iflFreeHandle(iflHandle);
return NULL;
}
ASSERT(pguidFltTypeUsed);
switch (iflType)
{
case IFLT_GIF: *pguidFltTypeUsed = WiaImgFmt_GIF; break;
case IFLT_BMP: *pguidFltTypeUsed = WiaImgFmt_BMP; break;
case IFLT_JPEG: *pguidFltTypeUsed = WiaImgFmt_JPEG; break;
case IFLT_TIFF: *pguidFltTypeUsed = WiaImgFmt_TIFF; break;
case IFLT_PNG: *pguidFltTypeUsed = WiaImgFmt_PNG; break;
case IFLT_PCD: *pguidFltTypeUsed = WiaImgFmt_PHOTOCD; break;
default: *pguidFltTypeUsed = WiaImgFmt_UNDEFINED; break;
}
IFLCLASS iflClass = iflGetClass(iflHandle);
IFLSEQUENCE iflSequence = iflGetSequence(iflHandle);
IFLCOMPRESSION iflCompression = iflGetCompression(iflHandle);
WORD iBPS = (WORD) iflGetBitsPerChannel(iflHandle);
if (iflClass != IFLCL_RGB && iflClass != IFLCL_PALETTE &&
iflClass != IFLCL_GRAY && iflClass != IFLCL_BILEVEL)
{
#ifdef _DEBUG
TRACE(TEXT("LoadDIBFromFile: Not a RGB/PALETTE/GRAY/BW image.\n"));
MessageBox (NULL, TEXT("Not a RGB/PALETTE/GRAY/BW image."),
TEXT("Loadimag.cpp"), MB_OK);
#endif
iflClose(iflHandle);
iflFreeHandle(iflHandle);
return NULL;
}
// get the transparent color
if (iflClass == IFLCL_RGB)
{
IFLCOLOR iflTransColor;
g_bUseTrans = (IFLERR_NONE ==
iflControl(iflHandle, IFLCMD_TRANS_RGB, 0, 0, &iflTransColor));
if (g_bUseTrans)
crTrans = RGB(iflTransColor.wRed,
iflTransColor.wGreen,
iflTransColor.wBlue);
}
else // must be IFLCL_PALETTE or IFLCL_GRAY or IFLCL_BILEVEL
{
BYTE byTransIdx;
g_bUseTrans = (IFLERR_NONE ==
iflControl(iflHandle, IFLCMD_TRANS_IDX, 0, 0, &byTransIdx));
if (g_bUseTrans)
crTrans = byTransIdx; // need to convert to COLORREF below
}
BITMAPINFOHEADER bi;
memset(&bi, 0, sizeof(BITMAPINFOHEADER));
bi.biSize = sizeof(BITMAPINFOHEADER); // should be 0x28 or 40 decimal
bi.biWidth = iflGetWidth(iflHandle);
bi.biHeight = iflGetHeight(iflHandle);
bi.biPlanes = 1;
if (iflClass == IFLCL_RGB)
{
#ifdef PNG_SUPPORT
if (iflType == IFLT_PNG)
{
bi.biBitCount = iBPS*3;
}
else
#endif // PNG_SUPPORT
{
bi.biBitCount = (WORD) iflGetBitsPerPixel (iflHandle);
}
}
else // must be IFLCL_PALETTE or IFLCL_GRAY or IFLCL_BILEVEL
{
bi.biBitCount = 8;
}
bi.biCompression = 0;
// convert width in pixels to bytes after rounding it up first
DWORD dwWidthInBytes = ((bi.biWidth * bi.biBitCount + 31) & ~31)/8;
bi.biSizeImage = abs(bi.biHeight) * dwWidthInBytes;
// bi.biXPelsPerMeter = 0;
// bi.biYPelsPerMeter = 0;
if (iflClass == IFLCL_PALETTE || iflClass == IFLCL_GRAY
|| iflClass == IFLCL_BILEVEL)
bi.biClrUsed = MAX_PAL_SIZE;
// bi.biClrImportant = 0;
LPBYTE lpBMP;
if ((lpBMP = lpStart = (LPBYTE) GlobalAlloc(GMEM_FIXED,
bi.biSize + bi.biClrUsed*sizeof(RGBQUAD) + bi.biSizeImage)) == NULL)
goto exit;
memcpy(lpBMP, &bi, bi.biSize);
lpBMP += bi.biSize;
BYTE byTemp;
int i, j;
switch (iflSequence)
{
case IFLSEQ_TOPDOWN:
switch (iflClass)
{
case IFLCL_RGB:
lpBMP += bi.biClrUsed*sizeof(RGBQUAD) + bi.biSizeImage -
dwWidthInBytes;
for (i = 0; i < abs(bi.biHeight); lpBMP-=dwWidthInBytes, i++)
{
// read in one line at a time
iflRead(iflHandle, (LPBYTE)lpBMP, 1);
// need to swap RED with BLUE for internal DIB display
for (j = 0; j < bi.biWidth*3; j+=3)
{
byTemp = *(lpBMP+j);
*(lpBMP+j) = *(lpBMP+j+2);
*(lpBMP+j+2) = byTemp;
}
}
break;
case IFLCL_PALETTE:
// get palette info first...
RGBTRIPLE Pal3[MAX_PAL_SIZE];
RGBQUAD Pal4[MAX_PAL_SIZE];
ZeroMemory (Pal3, MAX_PAL_SIZE*(sizeof(RGBTRIPLE)));
iflErr = iflControl(iflHandle, IFLCMD_PALETTE, 0, 0, &Pal3);
for (i = 0; i < MAX_PAL_SIZE; i++)
{
Pal4[i].rgbBlue = Pal3[i].rgbtRed;
Pal4[i].rgbGreen = Pal3[i].rgbtGreen;
Pal4[i].rgbRed = Pal3[i].rgbtBlue;
Pal4[i].rgbReserved = 0;
}
memcpy(lpBMP, Pal4, sizeof(Pal4));
if (g_bUseTrans)
// convert the transparent color index to COLORREF
crTrans = RGB(Pal4[crTrans].rgbRed,Pal4[crTrans].rgbGreen,
Pal4[crTrans].rgbBlue);
lpBMP += sizeof(Pal4) + bi.biSizeImage - dwWidthInBytes;
for (i = 0;i < abs(bi.biHeight);lpBMP-=dwWidthInBytes, i++)
{
// read in one line at a time
iflRead(iflHandle, (LPBYTE)lpBMP, 1);
}
break;
case IFLCL_GRAY:
// get palette info first...
//BYTE PalGray[MAX_PAL_SIZE];
//iflErr = iflControl(iflHandle, IFLCMD_PALETTE, 0, 0, &PalGray);
for (i = 0; i < MAX_PAL_SIZE; i++)
{
Pal4[i].rgbBlue = (BYTE) i;//PalGray[i];
Pal4[i].rgbGreen = (BYTE) i;//PalGray[i];
Pal4[i].rgbRed = (BYTE) i;//PalGray[i];
Pal4[i].rgbReserved = 0;
}
memcpy(lpBMP, Pal4, sizeof(Pal4));
if (g_bUseTrans)
// convert the transparent color index to COLORREF
crTrans = RGB(Pal4[crTrans].rgbRed, Pal4[crTrans].rgbGreen,
Pal4[crTrans].rgbBlue);
lpBMP += sizeof(Pal4) + bi.biSizeImage - dwWidthInBytes;
for (i = 0;i < abs(bi.biHeight);lpBMP-=dwWidthInBytes, i++)
{
// read in one line at a time
iflRead(iflHandle, (LPBYTE)lpBMP, 1);
}
break;
case IFLCL_BILEVEL:
// set color Black
Pal4[0].rgbBlue = 0;
Pal4[0].rgbGreen = 0;
Pal4[0].rgbRed = 0;
Pal4[0].rgbReserved = 0;
// set color White
Pal4[1].rgbBlue = 255;
Pal4[1].rgbGreen = 255;
Pal4[1].rgbRed = 255;
Pal4[1].rgbReserved = 0;
memcpy(lpBMP, Pal4, sizeof(Pal4));
if (g_bUseTrans)
// convert the transparent color index to COLORREF
crTrans = RGB(Pal4[crTrans].rgbRed,
Pal4[crTrans].rgbGreen,
Pal4[crTrans].rgbBlue);
lpBMP += sizeof(Pal4) + bi.biSizeImage - dwWidthInBytes;
for (i = 0;i < abs(bi.biHeight);lpBMP-=dwWidthInBytes, i++)
{
// read in one line at a time
iflRead(iflHandle, (LPBYTE)lpBMP, 1);
}
break;
default:
// currently not supported
break;
}
break;
case IFLSEQ_BOTTOMUP:
lpBMP += bi.biClrUsed*sizeof(RGBQUAD) + bi.biSizeImage - dwWidthInBytes;
for (i = 0;i < abs(bi.biHeight);lpBMP-=dwWidthInBytes, i++)
{
// read in one line at a time
iflRead(iflHandle, (LPBYTE)lpBMP, 1);
// need to swap RED with BLUE for internal DIB display
for (j = 0; j < bi.biWidth*3; j+=3)
{
byTemp = *(lpBMP+j);
*(lpBMP+j) = *(lpBMP+j+2);
*(lpBMP+j+2) = byTemp;
}
}
break;
case IFLSEQ_GIF_INTERLACED:
{
// get color palette info first...
RGBTRIPLE Pal3[MAX_PAL_SIZE];
RGBQUAD Pal4[MAX_PAL_SIZE];
iflErr = iflControl(iflHandle, IFLCMD_PALETTE, 0, 0, &Pal3);
for (i = 0; i < MAX_PAL_SIZE; i++)
{
Pal4[i].rgbBlue = Pal3[i].rgbtRed;
Pal4[i].rgbGreen = Pal3[i].rgbtGreen;
Pal4[i].rgbRed = Pal3[i].rgbtBlue;
Pal4[i].rgbReserved = 0;
}
memcpy(lpBMP, Pal4, sizeof(Pal4));
if (g_bUseTrans)
// convert the transparent color index to COLORREF
crTrans = RGB(Pal4[crTrans].rgbRed,Pal4[crTrans].rgbGreen,
Pal4[crTrans].rgbBlue);
LPBYTE lpTemp = lpBMP + sizeof(Pal4);
ReadGIFInterlacedImage (lpTemp, iflHandle, bi.biHeight, dwWidthInBytes);
}
break;
/* case 1010101:
{
int IM[] = { 8, 8, 4, 2 }; // interlace multiplier
//int IO[] = { 1, 5, 3 ,2 }; // interface offset
int IO[] = { 0, 4, 2,1 };
for (j = 0; j < 4; j++)
{
lpBMP = lpTemp + bi.biSizeImage - dwWidthInBytes*IO[j];
for (i = 0; i < abs(bi.biHeight) && lpBMP >= lpTemp;
lpBMP-=dwWidthInBytes*IM[j], i+=8)
{
// read in one line at a time
iflRead(iflHandle, (LPBYTE)lpBMP, 1);
}
}
break;
}*/
#ifdef PNG_SUPPORT
case IFLSEQ_ADAM7_INTERLACED:
{
// get color palette info first...
RGBTRIPLE Pal3[MAX_PAL_SIZE];
RGBQUAD Pal4[MAX_PAL_SIZE];
iflErr = iflControl(iflHandle, IFLCMD_PALETTE, 0, 0, &Pal3);
for (i = 0; i < MAX_PAL_SIZE; i++)
{
Pal4[i].rgbBlue = Pal3[i].rgbtRed;
Pal4[i].rgbGreen = Pal3[i].rgbtGreen;
Pal4[i].rgbRed = Pal3[i].rgbtBlue;
Pal4[i].rgbReserved = 0;
}
memcpy(lpBMP, Pal4, sizeof(Pal4));
if (g_bUseTrans)
// convert the transparent color index to COLORREF
crTrans = RGB(Pal4[crTrans].rgbRed,
Pal4[crTrans].rgbGreen,
Pal4[crTrans].rgbBlue);
/////////////////////////////
HANDLE hHeap = GetProcessHeap();
LPBYTE *ppbRGBRowPtrs =(LPBYTE *)AllocateImageSpace(hHeap,
bi.biHeight, dwWidthInBytes, /*bi.biWidth, */sizeof(BYTE));
if (ppbRGBRowPtrs != NULL)
{
// First get the image. This function will de-interlace the image
// AND any alpha channel information: it will also resize the alpha
// channel data structure to the image height from the number of
// raster lines, if necessary.
iflErr = ReadADAM7InterlacedImage(ppbRGBRowPtrs, iflHandle,
bi.biHeight, bi.biWidth,
sizeof(BYTE)*3, iflClass);
/////////////////////////////
if (iflErr == IFLERR_NONE)
{
lpBMP += bi.biClrUsed*sizeof(RGBQUAD) + bi.biSizeImage -
dwWidthInBytes;
for (i = 0;i < abs(bi.biHeight);lpBMP-=dwWidthInBytes, i++)
{
// read in one line at a time
memcpy((LPBYTE)lpBMP, ppbRGBRowPtrs[i], dwWidthInBytes);
// need to swap RED with BLUE for internal DIB display
for (j = 0; j < bi.biWidth*3; j+=3)
{
byTemp = *(lpBMP+j);
*(lpBMP+j) = *(lpBMP+j+2);
*(lpBMP+j+2) = byTemp;
}
}
}
ppbRGBRowPtrs = (LPBYTE *)FreeImageSpace(hHeap,
ppbRGBRowPtrs,
bi.biHeight);
}
break;
}
#endif // PNG_SUPPORT
default:
break;
}
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
}
exit:
iflClose(iflHandle);
iflFreeHandle(iflHandle);
return (HGLOBAL)lpStart;
#endif // _USE_IFL_API
//////////////////////////////////////////////////////////////////////////////
#ifdef _USE_FLT_API
HINSTANCE hLib = NULL;
FILESPEC fileSpec; // file to load
GRPI pict;
UINT rc; // return code
HANDLE hPrefMem = NULL; // filter-supplied preferences
UINT wFilterType; // 2 = graphics filter
char szHandler[128];
HGLOBAL hDib = NULL;
PFNGetFilterInfo lpfnGetFilterInfo;
PFNImportGr lpfnImportGr;
if (!GetHandlerForFile(TRUE, szFileName, szHandler, sizeof(szHandler)))
return FALSE;
if (szHandler[0] == 0)
return FALSE;
if ((hLib = LoadLibrary(szHandler)) == NULL)
goto exit;
// get a pointer to the ImportGR function
lpfnGetFilterInfo = (PFNGetFilterInfo)GetProcAddress(hLib, "GetFilterInfo");
lpfnImportGr = (PFNImportGr)GetProcAddress(hLib, "ImportGr");
if (lpfnGetFilterInfo == NULL)
lpfnGetFilterInfo = (PFNGetFilterInfo)GetProcAddress(hLib, "GetFilterInfo@16");
if (lpfnImportGr == NULL)
lpfnImportGr = (PFNImportGr)GetProcAddress(hLib, "ImportGr@16");
if (lpfnImportGr == NULL)
goto exit;
if (lpfnGetFilterInfo != NULL)
{
wFilterType = (*lpfnGetFilterInfo)
((short) 2, // interface version no.
(char *)NULL, // unused
(HANDLE *) &hPrefMem, // fill in: preferences
(DWORD) 0x00020000); // unused in Windows
// the return value is the type of filter: 0=error,
// 1=text-filter, 2=graphics-filter
if (wFilterType != 2)
goto exit;
}
fileSpec.slippery = FALSE; // TRUE if file may disappear
fileSpec.write = FALSE; // TRUE if open for write
fileSpec.unnamed = FALSE; // TRUE if unnamed
fileSpec.linked = FALSE; // Linked to an FS FCB
fileSpec.mark = FALSE; // Generic mark bit
fileSpec.dcbFile = 0L;
//the converters need a pathname without spaces...
GetShortPathName(szFileName, fileSpec.szName, sizeof(fileSpec.szName));
pict.hmf = NULL;
rc = (*lpfnImportGr)
(NULL, // "the target DC" (printer?)
(FILESPEC *) &fileSpec, // file to read
(GRPI *) &pict, // fill in: result metafile
(HANDLE) hPrefMem); // preferences memory
if (pict.hmf != NULL)
{
if (rc == 0)
{
// find the BITMAPINFO in the returned metafile
LPMETAHEADER lpMetaHeader = (LPMETAHEADER) GlobalLock(pict.hmf);
LPBITMAPINFOHEADER lpbi = FindBitmapInfo(lpMetaHeader);
if (lpbi != NULL)
{
// copy the DIB
SIZE_T nSize = FindDibSize(lpbi);
hDib = GlobalAlloc(GMEM_FIXED, nSize);
CopyMemory(hDib, lpbi, nSize);
}
GlobalUnlock(pict.hmf);
}
GlobalFree(pict.hmf);
}
exit:
if (hPrefMem != NULL)
GlobalFree(hPrefMem);
if (hLib)
FreeLibrary(hLib);
return hDib;
#endif // _USE_FLT_API
return NULL;
}
CGdiplusInit::CGdiplusInit(
Gdiplus::DebugEventProc debugEventCallback /*= 0*/,
BOOL suppressBackgroundThread /*= FALSE*/,
BOOL suppressExternalCodecs /*= FALSE*/
)
{
Gdiplus::GdiplusStartupInput StartupInput(
debugEventCallback,
suppressBackgroundThread,
suppressExternalCodecs
);
StartupStatus = GdiplusSafeStartup(&Token, &StartupInput, this);
}
CGdiplusInit::~CGdiplusInit()
{
if (StartupStatus == Gdiplus::Ok)
{
Gdiplus::GdiplusShutdown(Token);
}
}
Gdiplus::Status
CGdiplusInit::GdiplusSafeStartup(
ULONG_PTR *token,
const Gdiplus::GdiplusStartupInput *input,
Gdiplus::GdiplusStartupOutput *output
)
{
__try
{
return Gdiplus::GdiplusStartup(token, input, output);
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
return Gdiplus::GdiplusNotInitialized;
}
}
BOOL GetGdiplusDecoders(UINT *pnCodecs, Gdiplus::ImageCodecInfo **ppCodecs)
{
ASSERT(pnCodecs);
ASSERT(ppCodecs);
*ppCodecs = 0;
*pnCodecs = 0;
if (theApp.GdiplusInit.StartupStatus == Gdiplus::Ok)
{
__try
{
UINT cbCodecs;
if (Gdiplus::GetImageDecodersSize(pnCodecs, &cbCodecs) == Gdiplus::Ok)
{
if (*pnCodecs > 0)
{
*ppCodecs = (Gdiplus::ImageCodecInfo *) LocalAlloc(LMEM_FIXED, cbCodecs);
if (*ppCodecs != 0)
{
if (Gdiplus::GetImageDecoders(*pnCodecs, cbCodecs, *ppCodecs) == Gdiplus::Ok)
{
return TRUE;
}
}
}
}
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
}
LocalFree(*ppCodecs);
*ppCodecs = 0;
*pnCodecs = 0;
}
return FALSE;
}
BOOL GetGdiplusEncoders(UINT *pnCodecs, Gdiplus::ImageCodecInfo **ppCodecs)
{
ASSERT(pnCodecs);
ASSERT(ppCodecs);
*ppCodecs = 0;
*pnCodecs = 0;
if (theApp.GdiplusInit.StartupStatus == Gdiplus::Ok)
{
__try
{
UINT cbCodecs;
if (Gdiplus::GetImageEncodersSize(pnCodecs, &cbCodecs) == Gdiplus::Ok)
{
if (*pnCodecs > 0)
{
*ppCodecs = (Gdiplus::ImageCodecInfo *) LocalAlloc(LMEM_FIXED, cbCodecs);
if (*ppCodecs != 0)
{
if (Gdiplus::GetImageEncoders(*pnCodecs, cbCodecs, *ppCodecs) == Gdiplus::Ok)
{
return TRUE;
}
}
}
}
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
}
LocalFree(*ppCodecs);
*ppCodecs = 0;
*pnCodecs = 0;
}
return FALSE;
}
BOOL GetClsidOfEncoder(REFGUID guidFormatID, CLSID *pClsid)
{
Gdiplus::ImageCodecInfo *pCodecs = 0;
UINT nCodecs = 0;
GetGdiplusEncoders(&nCodecs, &pCodecs);
for (UINT i = 0; i < nCodecs; ++i)
{
if (pCodecs[i].FormatID == guidFormatID)
{
if (pClsid)
{
*pClsid = pCodecs[i].Clsid;
}
LocalFree(pCodecs);
return TRUE;
}
}
LocalFree(pCodecs);
return FALSE;
}
HGLOBAL LoadDIBGdiplus(LPCTSTR szFileName, GUID *pguidFltTypeUsed)
{
// check that the BMP encoder exists
CLSID ClsidBmpEncoder;
if (GetClsidOfEncoder(WiaImgFmt_BMP, &ClsidBmpEncoder))
{
// let GDI+ import the file
USES_CONVERSION;
Gdiplus::Bitmap image(T2CW(szFileName));
if (image.GetLastStatus() == Gdiplus::Ok)
{
// read the image type
ASSERT(pguidFltTypeUsed);
image.GetRawFormat(pguidFltTypeUsed);
// create a stream that emulates a bmp file
CComPtr<CBmpStream> pStream;
if (CBmpStream::Create(&pStream) == S_OK)
{
// convert the image into a BMP
if (image.Save(pStream, &ClsidBmpEncoder, 0) == Gdiplus::Ok)
{
return pStream->GetBuffer();
}
pStream->FreeBuffer();
}
}
}
return 0;
}
HGLOBAL LoadDIBFromFile(LPCTSTR szFileName, GUID *pguidFltTypeUsed)
{
// Try GDI+ filters first. If it fails to convert the image or
// if it's not available, try the old method
HGLOBAL hResult = 0;
if (theApp.GdiplusInit.StartupStatus == Gdiplus::Ok)
{
__try
{
hResult = LoadDIBGdiplus(szFileName, pguidFltTypeUsed);
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
}
}
if (!hResult)
{
USES_CONVERSION;
hResult = LoadDIBFromFileA(T2CA(szFileName), pguidFltTypeUsed);
}
return hResult;
}