bool CxImageIG::decodeSubLayer (CxFile& file, IGLibrary::IGLayer *pSubLayerOwner, IGSECTIONHEADER_LAYER *pLayerSection)
{
CxImage cxSubLayer;
if (!file.Seek (pLayerSection->commonHeader.nFirstByteOffset, SEEK_SET))
throw IGEXCEPTION (CxImageIGException, "decodeSubLayer", "file.Seek failed");
// read sub-layer pixels
BYTE *pBufImg = new BYTE [pLayerSection->commonHeader.nSizeBuf];
file.Read (pBufImg, pLayerSection->commonHeader.nSizeBuf, 1);
if (!cxSubLayer.Decode (pBufImg, pLayerSection->commonHeader.nSizeBuf, CXIMAGEIG_LAYERFORMAT))
throw IGEXCEPTION (CxImageIGException, "decodeSubLayer", "cxSubLayer.Decode failed");
delete [] pBufImg;
// read sub-layer alpha
cxSubLayer.AlphaCreate (255);
file.Read (cxSubLayer.pAlpha, cxSubLayer.GetWidth() * cxSubLayer.GetHeight(), 1);
// decode sub-layer into layer
BYTE *pLayerBits = NULL;
BYTE *pSubLayerBits = NULL;
for (int i = 0; i < pLayerSection->ptSize.y; i++)
{
pSubLayerBits = cxSubLayer.GetBits (i);
pLayerBits = pSubLayerOwner->GetBits (pLayerSection->ptOffset.y + i) + 3 * pLayerSection->ptOffset.x;
::memcpy (pLayerBits, pSubLayerBits, (pLayerSection->ptSize.x) * 3);
}
BYTE *pLayerAlpha = NULL;
BYTE *pSubLayerAlpha = NULL;
for (int i = 0; i < (pLayerSection->ptSize.y); i++)
{
pLayerAlpha = pSubLayerOwner->AlphaGetPointer (pLayerSection->ptOffset.x, pLayerSection->ptOffset.y + i);
pSubLayerAlpha = cxSubLayer.AlphaGetPointer (0, i);
::memcpy (pLayerAlpha, pSubLayerAlpha, (pLayerSection->ptSize.x));
}
return true;
}
BOOL CSonicImage::Load(HGLOBAL hGlobal, DWORD dwSize)
{
if(m_gif.LoadGif(hGlobal, dwSize) == 1)
{
if(PrepareMemDC(m_gif.GetWidth(), m_gif.GetHeight()) == FALSE)
{
m_gif.Clear();
return FALSE;
}
m_gif.Draw(m_Dib.GetSafeHdc());
}
else
{
BYTE * pData = (BYTE *)GlobalLock(hGlobal);
CxImage img;
img.Decode(pData, dwSize, 0);
GlobalUnlock(hGlobal);
if(PrepareMemDC(img.GetWidth(), img.GetHeight()) == FALSE)
{
img.Clear();
return FALSE;
}
if(!img.AlphaIsValid())
{
img.Draw(m_Dib.GetSafeHdc());
CSSE::DoOr(0xff000000, m_Dib.GetBits(), m_Dib.GetSize());
}
else
{
if(img.GetBpp() != 24)
{
img.Clear();
return FALSE;
}
BYTE * pSrc = img.GetBits();
BYTE * pAlpha = img.AlphaGetBits();
BYTE * pMyBits = m_Dib.GetBits();
int nLineTail = m_nWidth % 4;
for(int i = 0; i < m_nHeight; i++)
{
for(int j = 0; j < m_nWidth; j++)
{
*pMyBits++ = *pSrc++;
*pMyBits++ = *pSrc++;
*pMyBits++ = *pSrc++;
*pMyBits++ = *pAlpha++;
}
pSrc += nLineTail;
}
EnableAlphaChannel();
}
img.Clear();
}
return TRUE;
}
bool CxImageIG::DecodeLayer (CxFile &file, int nLayerIdx, int nLayerPos, RECT *p_rcSubLayer, bool bUndo, int nSubLayerId)
{
// read current header
IGHEADER igHeader;
if (!decodeHeader (&file, &igHeader))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "decodeHeader failed");
if (nLayerIdx < 0)
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "nLayerIdx failed");
if ((nLayerPos < 0) || (nLayerPos >= info.nNumLayers))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "nLayerPos failed");
IGSECTIONHEADER_LAYER *pLayerSections = new IGSECTIONHEADER_LAYER [CXIMAGEIG_MAX_NBLAYERS];
IGSECTIONHEADER_SELECTION *pSelectionSections = new IGSECTIONHEADER_SELECTION [CXIMAGEIG_MAX_NBSELECTIONS];
if (!decodeSections (&file, &igHeader, &pLayerSections[0], &pSelectionSections[0]))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "decodeSections failed");
IGLibrary::IGLayer *pLayer = GetLayer (nLayerPos);
if (!pLayer)
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "GetLayer failed");
CxImage cxSubLayer;
CxImage *pDecodingLayer = p_rcSubLayer ? &cxSubLayer : pLayer;
bool bIsSubLayerOwner = bUndo && p_rcSubLayer; // no need to find sub-layer owner in do mode
int nLayerSectionIndex = findLayerSectionIndex (&igHeader, pLayerSections, nLayerIdx, bIsSubLayerOwner);
if ((nLayerSectionIndex < 0) || (nLayerSectionIndex >= igHeader.nNbLayers))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "findLayerSectionIndex failed");
// in undo mode, if a sub-layer owner is found, decode it
if (bUndo){
if (bIsSubLayerOwner)
{
// decode sub-layer owner
if (!DecodeLayer (file, pLayerSections [nLayerSectionIndex].commonHeader.nId, nLayerPos))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "DecodeLayer failed");
// decode sub-layers
int nSubLayerSectionIndex = findLayerSectionIndex (&igHeader, pLayerSections, nLayerIdx, bIsSubLayerOwner);
if ((nSubLayerSectionIndex < 0) || (nSubLayerSectionIndex >= igHeader.nNbLayers))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "findLayerSectionIndex failed");
RECT rcSubLayer;
rcSubLayer.left = pLayerSections[nSubLayerSectionIndex].ptOffset.x;
rcSubLayer.right = pLayerSections[nSubLayerSectionIndex].ptOffset.x + pLayerSections[nSubLayerSectionIndex].ptSize.x - 1;
rcSubLayer.top = pLayerSections[nSubLayerSectionIndex].ptOffset.y;
rcSubLayer.bottom = pLayerSections[nSubLayerSectionIndex].ptOffset.y + pLayerSections[nSubLayerSectionIndex].ptSize.y - 1;
return DecodeLayer (file, pLayerSections [nLayerSectionIndex].commonHeader.nId, nLayerPos, &rcSubLayer, true, nLayerIdx);
}
}
if (!file.Seek (pLayerSections [nLayerSectionIndex].commonHeader.nFirstByteOffset, SEEK_SET))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "file.Seek failed");
// read layer pixels
BYTE *pBufImg = new BYTE [pLayerSections [nLayerSectionIndex].commonHeader.nSizeBuf];
file.Read (pBufImg, pLayerSections [nLayerSectionIndex].commonHeader.nSizeBuf, 1);
if (!pDecodingLayer->Decode (pBufImg, pLayerSections [nLayerSectionIndex].commonHeader.nSizeBuf, CXIMAGEIG_LAYERFORMAT))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "pDecodingLayer->Decode failed");
delete [] pBufImg;
// read layer alpha
pDecodingLayer->AlphaCreate (255);
file.Read (pDecodingLayer->pAlpha, pDecodingLayer->GetWidth() * pDecodingLayer->GetHeight(), 1);
int nSubLayerWidth = 0;
int nSubLayerHeight = 0;
if (p_rcSubLayer)
{
// decode sub-layer
nSubLayerWidth = p_rcSubLayer->right - p_rcSubLayer->left + 1;
nSubLayerHeight = p_rcSubLayer->bottom - p_rcSubLayer->top + 1;
BYTE *pLayerBits = NULL;
BYTE *pSubLayerBits = NULL;
for (int i = 0; i < nSubLayerHeight; i++)
{
// if undo, then sub-layer == original layer
pSubLayerBits = bUndo ? pDecodingLayer->GetBits (p_rcSubLayer->top + i) + 3 * p_rcSubLayer->left : pDecodingLayer->GetBits (i);
pLayerBits = pLayer->GetBits (p_rcSubLayer->top + i) + 3 * p_rcSubLayer->left;
::memcpy (pLayerBits, pSubLayerBits, nSubLayerWidth * 3);
}
BYTE *pLayerAlpha = NULL;
BYTE *pSubLayerAlpha = NULL;
for (int i = 0; i < nSubLayerHeight; i++)
{
pLayerAlpha = pLayer->AlphaGetPointer (p_rcSubLayer->left, p_rcSubLayer->top + i);
pSubLayerAlpha = bUndo ? pDecodingLayer->AlphaGetPointer (p_rcSubLayer->left, p_rcSubLayer->top + i) : pDecodingLayer->AlphaGetPointer (0, i);
::memcpy (pLayerAlpha, pSubLayerAlpha, nSubLayerWidth);
}
if (bUndo)
{
// original layer is now decoded. decode sub-layers
bIsSubLayerOwner = false;
int nMaxSubLayerSectionIndex = findLayerSectionIndex (&igHeader, pLayerSections, nSubLayerId, bIsSubLayerOwner); // we always have bIsSubLayerOwner = false, its used for the reference only
if (nMaxSubLayerSectionIndex < 0)
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "findLayerSectionIndex failed");
if (nMaxSubLayerSectionIndex <= igHeader.nNbLayers)
{
for (int i = 0; i < pLayerSections [nLayerSectionIndex].nSubLayers; i++)
{
if (pLayerSections [nLayerSectionIndex].pnSubLayers [i] <= nMaxSubLayerSectionIndex)
{
if (!decodeSubLayer (file, pLayer, &pLayerSections [pLayerSections [nLayerSectionIndex].pnSubLayers [i]]))
throw IGEXCEPTION (CxImageIGException, "DecodeLayer", "decodeSubLayer failed");
}
}
}
}
}
else
{
pLayer->info.xOffset = pLayerSections [nLayerSectionIndex].ptOffset.x;
pLayer->info.yOffset = pLayerSections [nLayerSectionIndex].ptOffset.y;
}
pLayer->SetId (nLayerIdx);
pLayer->UpdateImageParameters();
delete [] pLayerSections;
delete [] pSelectionSections;
return true;
}
UINT CFrameGrabThread::GrabFrames(){
#define TIMEBETWEENFRAMES 50.0 // could be a param later, if needed
for (int i = 0; i!= nFramesToGrab; i++)
imgResults[i] = NULL;
try{
HRESULT hr;
CComPtr<IMediaDet> pDet;
hr = pDet.CoCreateInstance(__uuidof(MediaDet));
if (!SUCCEEDED(hr))
return 0;
// Convert the file name to a BSTR.
CComBSTR bstrFilename(strFileName);
hr = pDet->put_Filename(bstrFilename);
long lStreams;
bool bFound = false;
hr = pDet->get_OutputStreams(&lStreams);
for (long i = 0; i < lStreams; i++)
{
GUID major_type;
hr = pDet->put_CurrentStream(i);
hr = pDet->get_StreamType(&major_type);
if (major_type == MEDIATYPE_Video)
{
bFound = true;
break;
}
}
if (!bFound)
return 0;
double dLength = 0;
pDet->get_StreamLength(&dLength);
if (dStartTime > dLength)
dStartTime = 0;
long width = 0, height = 0;
AM_MEDIA_TYPE mt;
hr = pDet->get_StreamMediaType(&mt);
if (mt.formattype == FORMAT_VideoInfo)
{
VIDEOINFOHEADER *pVih = (VIDEOINFOHEADER*)(mt.pbFormat);
width = pVih->bmiHeader.biWidth;
height = pVih->bmiHeader.biHeight;
// We want the absolute height, don't care about orientation.
if (height < 0) height *= -1;
}
else {
return 0; // Should not happen, in theory.
}
/*FreeMediaType(mt); = */
if (mt.cbFormat != 0){
CoTaskMemFree((PVOID)mt.pbFormat);
mt.cbFormat = 0;
mt.pbFormat = NULL;
}
if (mt.pUnk != NULL){
mt.pUnk->Release();
mt.pUnk = NULL;
}
/**/
long size;
uint32 nFramesGrabbed;
for (nFramesGrabbed = 0; nFramesGrabbed != nFramesToGrab; nFramesGrabbed++){
hr = pDet->GetBitmapBits(dStartTime + (nFramesGrabbed*TIMEBETWEENFRAMES), &size, NULL, width, height);
if (SUCCEEDED(hr))
{
// we could also directly create a Bitmap in memory, however this caused problems/failed with *some* movie files
// when I tried it for the MMPreview, while this method works always - so I'll continue to use this one
long nFullBufferLen = sizeof( BITMAPFILEHEADER ) + size;
char* buffer = new char[nFullBufferLen];
BITMAPFILEHEADER bfh;
memset( &bfh, 0, sizeof( bfh ) );
bfh.bfType = 'MB';
bfh.bfSize = nFullBufferLen;
bfh.bfOffBits = sizeof( BITMAPINFOHEADER ) + sizeof( BITMAPFILEHEADER );
memcpy(buffer,&bfh,sizeof( bfh ) );
try {
hr = pDet->GetBitmapBits(dStartTime+ (nFramesGrabbed*TIMEBETWEENFRAMES), NULL, buffer + sizeof( bfh ), width, height);
}
catch (...) {
ASSERT(0);
hr = E_FAIL;
}
if (SUCCEEDED(hr))
{
// decode
CxImage* imgResult = new CxImage();
imgResult->Decode((BYTE*)buffer, nFullBufferLen, CXIMAGE_FORMAT_BMP);
delete[] buffer;
if (!imgResult->IsValid()){
delete imgResult;
break;
}
// resize if needed
if (nMaxWidth > 0 && nMaxWidth < width){
float scale = (float)nMaxWidth / imgResult->GetWidth();
int nMaxHeigth = (int)(imgResult->GetHeight() * scale);
imgResult->Resample(nMaxWidth, nMaxHeigth, 0);
}
// decrease bpp if needed
if (bReduceColor){
RGBQUAD* ppal=(RGBQUAD*)malloc(256*sizeof(RGBQUAD));
if (ppal) {
CQuantizer q(256,8);
q.ProcessImage(imgResult->GetDIB());
q.SetColorTable(ppal);
imgResult->DecreaseBpp(8, true, ppal);
free(ppal);
}
}
//CString TestName;
//TestName.Format("G:\\testframe%i.png",nFramesGrabbed);
//imgResult->Save(TestName,CXIMAGE_FORMAT_PNG);
// done
imgResults[nFramesGrabbed] = imgResult;
}
else{
delete[] buffer;
break;
}
}
}
return nFramesGrabbed;
}
catch(...){
ASSERT(0);
return 0;
}
}
bool CxImageICO::Decode(CxFile *hFile)
{
if (hFile==NULL) return false;
DWORD off = hFile->Tell(); //<yuandi>
int page=info.nFrame; //internal icon structure indexes
// read the first part of the header
ICONHEADER icon_header;
hFile->Read(&icon_header,sizeof(ICONHEADER),1);
icon_header.idType = my_ntohs(icon_header.idType);
icon_header.idCount = my_ntohs(icon_header.idCount);
// check if it's an icon or a cursor
if ((icon_header.idReserved == 0) && ((icon_header.idType == 1)||(icon_header.idType == 2))) {
info.nNumFrames = icon_header.idCount;
// load the icon descriptions
ICONDIRENTRY *icon_list = (ICONDIRENTRY *)malloc(icon_header.idCount * sizeof(ICONDIRENTRY));
int c;
for (c = 0; c < icon_header.idCount; c++) {
hFile->Read(icon_list + c, sizeof(ICONDIRENTRY), 1);
icon_list[c].wPlanes = my_ntohs(icon_list[c].wPlanes);
icon_list[c].wBitCount = my_ntohs(icon_list[c].wBitCount);
icon_list[c].dwBytesInRes = my_ntohl(icon_list[c].dwBytesInRes);
icon_list[c].dwImageOffset = my_ntohl(icon_list[c].dwImageOffset);
}
if ((page>=0)&&(page<icon_header.idCount)){
if (info.nEscape == -1) {
// Return output dimensions only
head.biWidth = icon_list[page].bWidth;
head.biHeight = icon_list[page].bHeight;
#if CXIMAGE_SUPPORT_PNG
if (head.biWidth==0 && head.biHeight==0)
{ // Vista icon support
hFile->Seek(off + icon_list[page].dwImageOffset, SEEK_SET);
CxImage png;
png.SetEscape(-1);
if (png.Decode(hFile,CXIMAGE_FORMAT_PNG)){
Transfer(png);
info.nNumFrames = icon_header.idCount;
}
}
#endif //CXIMAGE_SUPPORT_PNG
free(icon_list);
info.dwType = CXIMAGE_FORMAT_ICO;
return true;
}
// get the bit count for the colors in the icon <CoreyRLucier>
BITMAPINFOHEADER bih;
hFile->Seek(off + icon_list[page].dwImageOffset, SEEK_SET);
if (icon_list[page].bWidth==0 && icon_list[page].bHeight==0)
{ // Vista icon support
#if CXIMAGE_SUPPORT_PNG
CxImage png;
if (png.Decode(hFile,CXIMAGE_FORMAT_PNG)){
Transfer(png);
info.nNumFrames = icon_header.idCount;
}
SetType(CXIMAGE_FORMAT_ICO);
#endif //CXIMAGE_SUPPORT_PNG
}
else
{ // standard icon
hFile->Read(&bih,sizeof(BITMAPINFOHEADER),1);
bihtoh(&bih);
c = bih.biBitCount;
// allocate memory for one icon
Create(icon_list[page].bWidth,icon_list[page].bHeight, c, CXIMAGE_FORMAT_ICO); //image creation
// read the palette
RGBQUAD pal[256];
if (bih.biClrUsed)
hFile->Read(pal,bih.biClrUsed*sizeof(RGBQUAD), 1);
else
hFile->Read(pal,head.biClrUsed*sizeof(RGBQUAD), 1);
SetPalette(pal,head.biClrUsed); //palette assign
//read the icon
if (c<=24){
hFile->Read(info.pImage, head.biSizeImage, 1);
} else { // 32 bit icon
BYTE* buf=(BYTE*)malloc(4*head.biHeight*head.biWidth);
BYTE* src = buf;
hFile->Read(buf, 4*head.biHeight*head.biWidth, 1);
#if CXIMAGE_SUPPORT_ALPHA
if (!AlphaIsValid()) AlphaCreate();
#endif //CXIMAGE_SUPPORT_ALPHA
for (long y = 0; y < head.biHeight; y++) {
BYTE* dst = GetBits(y);
for(long x=0;x<head.biWidth;x++){
*dst++=src[0];
*dst++=src[1];
*dst++=src[2];
#if CXIMAGE_SUPPORT_ALPHA
AlphaSet(x,y,src[3]);
#endif //CXIMAGE_SUPPORT_ALPHA
src+=4;
}
}
free(buf);
}
// apply the AND and XOR masks
int maskwdt = ((head.biWidth+31) / 32) * 4; //line width of AND mask (always 1 Bpp)
int masksize = head.biHeight * maskwdt; //size of mask
BYTE *mask = (BYTE *)malloc(masksize);
if (hFile->Read(mask, masksize, 1)){
bool bGoodMask=false;
for (int im=0;im<masksize;im++){
if (mask[im]!=255){
bGoodMask=true;
break;
}
}
if (bGoodMask && c != 32){
#if CXIMAGE_SUPPORT_ALPHA
bool bNeedAlpha = false;
if (!AlphaIsValid()){
AlphaCreate();
} else {
bNeedAlpha=true; //32bit icon
}
int x,y;
for (y = 0; y < head.biHeight; y++) {
for (x = 0; x < head.biWidth; x++) {
if (((mask[y*maskwdt+(x>>3)]>>(7-x%8))&0x01)){
AlphaSet(x,y,0);
bNeedAlpha=true;
}
}
}
if (!bNeedAlpha) AlphaDelete();
#endif //CXIMAGE_SUPPORT_ALPHA
//check if there is only one transparent color
RGBQUAD cc,ct;
long* pcc = (long*)&cc;
long* pct = (long*)&ct;
int nTransColors=0;
int nTransIndex=0;
for (y = 0; y < head.biHeight; y++){
for (x = 0; x < head.biWidth; x++){
if (((mask[y*maskwdt+(x>>3)] >> (7-x%8)) & 0x01)){
cc = GetPixelColor(x,y,false);
if (nTransColors==0){
nTransIndex = GetPixelIndex(x,y);
nTransColors++;
ct = cc;
} else {
if (*pct!=*pcc){
nTransColors++;
}
}
}
}
}
if (nTransColors==1){
SetTransColor(ct);
SetTransIndex(nTransIndex);
#if CXIMAGE_SUPPORT_ALPHA
AlphaDelete(); //because we have a unique transparent color in the image
#endif //CXIMAGE_SUPPORT_ALPHA
}
// <vho> - Transparency support w/o Alpha support
if (c <= 8){ // only for icons with less than 256 colors (XP icons need alpha).
// find a color index, which is not used in the image
// it is almost sure to find one, bcs. nobody uses all possible colors for an icon
BYTE colorsUsed[256];
memset(colorsUsed, 0, sizeof(colorsUsed));
for (y = 0; y < head.biHeight; y++){
for (x = 0; x < head.biWidth; x++){
colorsUsed[BlindGetPixelIndex(x,y)] = 1;
}
}
int iTransIdx = -1;
for (x = (int)(head.biClrUsed-1); x>=0 ; x--){
if (colorsUsed[x] == 0){
iTransIdx = x; // this one is not in use. we may use it as transparent color
break;
}
}
// Go thru image and set unused color as transparent index if needed
if (iTransIdx >= 0){
bool bNeedTrans = false;
for (y = 0; y < head.biHeight; y++){
for (x = 0; x < head.biWidth; x++){
// AND mask (Each Byte represents 8 Pixels)
if (((mask[y*maskwdt+(x>>3)] >> (7-x%8)) & 0x01)){
// AND mask is set (!=0). This is a transparent part
SetPixelIndex(x, y, (BYTE)iTransIdx);
bNeedTrans = true;
}
}
}
// set transparent index if needed
if (bNeedTrans) SetTransIndex(iTransIdx);
#if CXIMAGE_SUPPORT_ALPHA
AlphaDelete(); //because we have a transparent color in the palette
#endif //CXIMAGE_SUPPORT_ALPHA
}
}
} else if(c != 32){
__declspec(dllexport) bool LoadImageFromMemory(const BYTE *buffer, unsigned int size, const char *mime, unsigned int maxwidth, unsigned int maxheight, ImageInfo *info)
{
if (!buffer || !size || !mime || !info) return false;
// load the image
DWORD dwImageType = CXIMAGE_FORMAT_UNKNOWN;
if (strlen(mime))
dwImageType = GetImageType(mime);
if (dwImageType == CXIMAGE_FORMAT_UNKNOWN)
dwImageType = DetectFileType(buffer, size);
if (dwImageType == CXIMAGE_FORMAT_UNKNOWN)
{
printf("PICTURE::LoadImageFromMemory: Unable to determine image type.");
return false;
}
CxImage *image = new CxImage(dwImageType);
if (!image)
return false;
int actualwidth = maxwidth;
int actualheight = maxheight;
try
{
bool success = image->Decode((BYTE*)buffer, size, dwImageType, actualwidth, actualheight);
if (!success && dwImageType != CXIMAGE_FORMAT_UNKNOWN)
{ // try to decode with unknown imagetype
success = image->Decode((BYTE*)buffer, size, CXIMAGE_FORMAT_UNKNOWN);
}
if (!success || !image->IsValid())
{
printf("PICTURE::LoadImageFromMemory: Unable to decode image. Error:%s\n", image->GetLastError());
delete image;
return false;
}
}
catch (...)
{
printf("PICTURE::LoadImageFromMemory: Unable to decode image.");
delete image;
return false;
}
// ok, now resample the image down if necessary
if (ResampleKeepAspect(*image, maxwidth, maxheight) < 0)
{
printf("PICTURE::LoadImage: Unable to resample picture\n");
delete image;
return false;
}
// make sure our image is 24bit minimum
image->IncreaseBpp(24);
// fill in our struct
info->width = image->GetWidth();
info->height = image->GetHeight();
info->originalwidth = actualwidth;
info->originalheight = actualheight;
memcpy(&info->exifInfo, image->GetExifInfo(), sizeof(EXIFINFO));
// create our texture
info->context = image;
info->texture = image->GetBits();
info->alpha = image->AlphaGetBits();
return (info->texture != NULL);
};
BOOL
CResponseParser::SaveAsImage( const wchar_t* lpszPath,const char* lpszContentData,
uint32 dwContentSize, DWORD dwType)
{
CxImage image;
bool bRet = false;
DWORD dwFileType = CResponseParser::CheckImageFileHeader( (BYTE*)lpszContentData, dwContentSize);
if( dwFileType == CXIMAGE_FORMAT_BMP )
{
bRet = image.Decode( (BYTE*)lpszContentData, dwContentSize, CXIMAGE_FORMAT_BMP);
}
else if( dwFileType == CXIMAGE_FORMAT_GIF)
{
bRet = image.Decode( (BYTE*)lpszContentData, dwContentSize, CXIMAGE_FORMAT_GIF);
}
else if( dwFileType == CXIMAGE_FORMAT_JPG )
{
bRet = image.Decode( (BYTE*)lpszContentData, dwContentSize, CXIMAGE_FORMAT_JPG);
}
else if( dwFileType == CXIMAGE_FORMAT_PNG)
{
bRet = image.Decode( (BYTE*)lpszContentData, dwContentSize, CXIMAGE_FORMAT_PNG);
}
if( bRet == true)
{
if( dwType == CXIMAGE_FORMAT_BMP)
{
return image.SaveW( lpszPath, CXIMAGE_FORMAT_BMP);
}
else if( dwType == CXIMAGE_FORMAT_GIF)
{
return image.SaveW( lpszPath, CXIMAGE_FORMAT_GIF);
}
else if( dwType == CXIMAGE_FORMAT_JPG)
{
return image.SaveW( lpszPath, CXIMAGE_FORMAT_JPG);
}
else if( dwType == CXIMAGE_FORMAT_PNG)
{
return image.SaveW( lpszPath, CXIMAGE_FORMAT_PNG);
}
else
return image.SaveW( lpszPath, CXIMAGE_FORMAT_BMP);
}
return FALSE;
}
