// // Simple test program for imaging library // #include #include #include #include #include #include #include #include #include #include #include "rsrc.h" CHAR* programName; // program name HINSTANCE appInstance; // handle to the application instance HWND hwndMain; // handle to application's main window IImagingFactory* imgfact; // pointer to IImageingFactory object IImage* curImage; // pointer to IImage object CHAR curFilename[MAX_PATH]; // current image filename INT scaleMethod = IDM_SCALE_NEIGHBOR; // // Display an error message dialog // BOOL CheckHRESULT( HRESULT hr, INT line ) { if (SUCCEEDED(hr)) return TRUE; CHAR buf[1024]; sprintf(buf, "Error on line %d: 0x%x\n", line, hr); MessageBoxA(hwndMain, buf, programName, MB_OK); return FALSE; } #define CHECKHR(hr) CheckHRESULT(hr, __LINE__) #define LASTWIN32HRESULT HRESULT_FROM_WIN32(GetLastError()) #if DBG #define VERBOSE(args) printf args #else #define VERBOSE(args) #endif // // Helper class to convert ANSI strings to Unicode strings // inline BOOL UnicodeToAnsiStr( const WCHAR* unicodeStr, CHAR* ansiStr, INT ansiSize ) { return WideCharToMultiByte( CP_ACP, 0, unicodeStr, -1, ansiStr, ansiSize, NULL, NULL) > 0; } inline BOOL AnsiToUnicodeStr( const CHAR* ansiStr, WCHAR* unicodeStr, INT unicodeSize ) { return MultiByteToWideChar( CP_ACP, 0, ansiStr, -1, unicodeStr, unicodeSize) > 0; } class UnicodeStrFromAnsi { public: UnicodeStrFromAnsi(const CHAR* ansiStr) { if (ansiStr == NULL) { valid = TRUE; unicodeStr = NULL; } else { // NOTE: we only handle strings with length < MAX_PATH. valid = AnsiToUnicodeStr(ansiStr, buf, MAX_PATH); unicodeStr = valid ? buf : NULL; } } BOOL IsValid() const { return valid; } operator WCHAR*() { return unicodeStr; } private: BOOL valid; WCHAR* unicodeStr; WCHAR buf[MAX_PATH]; }; // // Get scale method strings and interpolation hints // const CHAR* GetScaleMethodStr() { switch (scaleMethod) { case IDM_SCALE_GDI: return "GDI"; case IDM_SCALE_GDIHT: return "GDI + Halftone"; case IDM_SCALE_NEIGHBOR: return "Nearest Neighbor"; case IDM_SCALE_BILINEAR: return "Bilinear"; case IDM_SCALE_AVERAGING: return "Averaging"; case IDM_SCALE_BICUBIC: return "Bicubic"; default: return "Unknown"; } } InterpolationHint GetScaleMethodInterp() { switch (scaleMethod) { case IDM_SCALE_BILINEAR: return INTERP_BILINEAR; case IDM_SCALE_AVERAGING: return INTERP_AVERAGING; case IDM_SCALE_BICUBIC: return INTERP_BICUBIC; case IDM_SCALE_NEIGHBOR: return INTERP_NEAREST_NEIGHBOR; case IDM_SCALE_GDI: case IDM_SCALE_GDIHT: default: return INTERP_DEFAULT; } } // // Get pixel format strings // const CHAR* GetPixelFormatStr( PixelFormatID pixfmt ) { switch (pixfmt) { case PIXFMT_1BPP_INDEXED: return "1bpp indexed"; case PIXFMT_4BPP_INDEXED: return "4bpp indexed"; case PIXFMT_8BPP_INDEXED: return "8bpp indexed"; case PIXFMT_16BPP_GRAYSCALE: return "16bpp grayscale"; case PIXFMT_16BPP_RGB555: return "16bpp RGB 5-5-5"; case PIXFMT_16BPP_RGB565: return "16bpp RGB 5-6-5"; case PIXFMT_16BPP_ARGB1555: return "16bpp ARGB 1-5-5-5"; case PIXFMT_24BPP_RGB: return "24bpp RGB"; case PIXFMT_32BPP_RGB: return "32bpp RGB"; case PIXFMT_32BPP_ARGB: return "32bpp ARGB"; case PIXFMT_32BPP_PARGB: return "32bpp premultiplied ARGB"; case PIXFMT_48BPP_RGB: return "48bpp RGB"; case PIXFMT_64BPP_ARGB: return "64bpp ARGB"; case PIXFMT_64BPP_PARGB: return "64bpp premultiplied ARGB"; case PIXFMT_UNDEFINED: default: return "Unknown"; } } // // Force a refresh of the image window // VOID RefreshImageDisplay() { InvalidateRect(hwndMain, NULL, FALSE); // Update window title CHAR title[2*MAX_PATH]; CHAR* p = title; strcpy(p, curFilename); p += strlen(p); HRESULT hr; SIZE size; IBitmapImage* bmp; hr = curImage->QueryInterface(IID_IBitmapImage, (VOID**) &bmp); if (FAILED(hr)) { // Decoded image hr = curImage->GetPhysicalDimension(&size); if (SUCCEEDED(hr)) { sprintf(p, ", Dimension: %0.2fx%0.2fmm", size.cx / 100.0, size.cy / 100.0); p += strlen(p); } } else { // In-memory bitmap image hr = bmp->GetSize(&size); if (CHECKHR(hr)) { sprintf(p, ", Size: %dx%d", size.cx, size.cy); p += strlen(p); } PixelFormatID pixfmt; hr = bmp->GetPixelFormatID(&pixfmt); if (CHECKHR(hr)) { sprintf(p, ", Pixel Format: %s", GetPixelFormatStr(pixfmt)); p += strlen(p); } bmp->Release(); } sprintf(p, ", Scale Method: %s", GetScaleMethodStr()); p += strlen(p); SetWindowText(hwndMain, title); } // // Set the current image // VOID SetCurrentImage( IUnknown* unk, const CHAR* filename = NULL ) { IImage* image; if (filename != NULL) { // Decoded image image = (IImage*) unk; strcpy(curFilename, filename); } else { // In-memory bitmap image HRESULT hr; hr = unk->QueryInterface(IID_IImage, (VOID**) &image); unk->Release(); if (!CHECKHR(hr)) return; strcpy(curFilename, "In-memory Bitmap"); } if (curImage) curImage->Release(); curImage = image; RefreshImageDisplay(); } // // Resize the window so it fits the image // #define MINWINWIDTH 200 #define MINWINHEIGHT 100 #define MAXWINWIDTH 1024 #define MAXWINHEIGHT 768 VOID DoSizeWindowToFit( HWND hwnd, BOOL strict = FALSE ) { HRESULT hr; IBitmapImage* bmp; SIZE size; // Check if the current image is a bitmap image // in that case, we'll get the pixel dimension hr = curImage->QueryInterface(IID_IBitmapImage, (VOID**) &bmp); if (SUCCEEDED(hr)) { hr = bmp->GetSize(&size); bmp->Release(); } // Otherwise, try to get device-independent image dimension if (FAILED(hr)) { hr = curImage->GetPhysicalDimension(&size); if (FAILED(hr)) return; size.cx = (INT) (size.cx * 96.0 / 2540.0 + 0.5); size.cy = (INT) (size.cy * 96.0 / 2540.0 + 0.5); } if (SUCCEEDED(hr)) { // Figure out window border dimensions RECT r1, r2; INT w, h; w = size.cx; h = size.cy; if (!strict) { if (w < MINWINWIDTH) w = MINWINWIDTH; else if (w > MAXWINWIDTH) w = MAXWINWIDTH; if (h < MINWINHEIGHT) h = MINWINHEIGHT; else if (h > MAXWINHEIGHT) h = MAXWINHEIGHT; } GetWindowRect(hwnd, &r1); GetClientRect(hwnd, &r2); w += (r1.right - r1.left) - (r2.right - r2.left); h += (r1.bottom - r1.top) - (r2.bottom - r2.top); // Resize the window do { SetWindowPos( hwnd, NULL, 0, 0, w, h, SWP_NOMOVE | SWP_NOZORDER); GetClientRect(hwnd, &r2); h += GetSystemMetrics(SM_CYMENU); } while (r2.bottom == 0); } } // // Convert current image to a bitmap image // IBitmapImage* ConvertImageToBitmap( IImage* image, INT width = 0, INT height = 0, PixelFormatID pixfmt = PIXFMT_DONTCARE, InterpolationHint hint = INTERP_DEFAULT ) { if (!image) return NULL; HRESULT hr; IBitmapImage* bmp; hr = image->QueryInterface(IID_IBitmapImage, (VOID**) &bmp); if (SUCCEEDED(hr)) { SIZE size; PixelFormatID fmt; // Current image is already a bitmap image and // its dimension and pixel format are already as expected hr = bmp->GetSize(&size); if (!CHECKHR(hr)) return NULL; hr = bmp->GetPixelFormatID(&fmt); if (!CHECKHR(hr)) return NULL; if ((width == 0 || size.cx == width) && (height == 0 || size.cy == height) && (pixfmt == PIXFMT_DONTCARE || pixfmt == fmt)) { return bmp; } bmp->Release(); } // Convert the current image to a bitmap image if (width == 0 && height == 0) { ImageInfo imageInfo; hr = image->GetImageInfo(&imageInfo); // If the source image is scalable, then compute // the appropriate pixel dimension for the bitmap if (SUCCEEDED(hr) && (imageInfo.Flags & IMGFLAG_SCALABLE)) { width = (INT) (96.0 * imageInfo.Width / imageInfo.Xdpi + 0.5); height = (INT) (96.0 * imageInfo.Height / imageInfo.Ydpi + 0.5); } } hr = imgfact->CreateBitmapFromImage( image, width, height, pixfmt, hint, &bmp); return SUCCEEDED(hr) ? bmp : NULL; } // // Create an image object from a file // VOID OpenImageFile( const CHAR* filename ) { HRESULT hr; IImage* image; IStream* stream; static BOOL useUrlMon = FALSE; if (useUrlMon) { // Use URLMON.DLL to turn file into stream CHAR fullpath[MAX_PATH]; CHAR* p; if (!GetFullPathName(filename, MAX_PATH, fullpath, &p)) return; hr = URLOpenBlockingStreamA(NULL, fullpath, &stream, 0, NULL); if (!CHECKHR(hr)) return; hr = imgfact->CreateImageFromStream(stream, &image); stream->Release(); } else { // Use filename directly UnicodeStrFromAnsi namestr(filename); if (namestr.IsValid()) hr = imgfact->CreateImageFromFile(namestr, &image); else hr = E_FAIL; } // Set the new image as the current image if (CHECKHR(hr)) { SetCurrentImage(image, filename); DoSizeWindowToFit(hwndMain); } } // // Save the current image to a file // VOID SaveImageFile( const CHAR* filename, const CLSID* clsid ) { if (!curImage) return; // Create an encoder object HRESULT hr; IImageEncoder* encoder; UnicodeStrFromAnsi namestr(filename); if (namestr.IsValid()) hr = imgfact->CreateImageEncoderToFile(clsid, namestr, &encoder); else hr = E_FAIL; if (!CHECKHR(hr)) return; // Get an IImageSink interface to the encoder IImageSink* sink; hr = encoder->GetEncodeSink(&sink); #if defined(ROTATION_TEST) // Rotation test EncoderParams* pMyEncoderParams; pMyEncoderParams = (EncoderParams*)malloc ( sizeof(EncoderParams) + sizeof(EncoderParam)); pMyEncoderParams->Params[0].paramGuid = ENCODER_ROTATION; pMyEncoderParams->Params[0].Value = "90"; pMyEncoderParams->Count = 1; hr = encoder->SetEncoderParam(pMyEncoderParams); free(pMyEncoderParams); #endif if (CHECKHR(hr)) { hr = curImage->PushIntoSink(sink); CHECKHR(hr); sink->Release(); } encoder->TerminateEncoder(); encoder->Release(); } // // Handle window repaint event // VOID DoPaint( HWND hwnd ) { HDC hdc; PAINTSTRUCT ps; RECT rect; DWORD timer; HRESULT hr = E_FAIL; hdc = BeginPaint(hwnd, &ps); GetClientRect(hwnd, &rect); if (scaleMethod == IDM_SCALE_GDIHT) SetStretchBltMode(hdc, HALFTONE); else SetStretchBltMode(hdc, COLORONCOLOR); VERBOSE(("Scale method: %d, ", scaleMethod)); timer = GetTickCount(); if (scaleMethod == IDM_SCALE_GDI || scaleMethod == IDM_SCALE_GDIHT) { hr = curImage->Draw(hdc, &rect, NULL); VERBOSE(("GDI time: %dms\n", GetTickCount() - timer)); } else { IBitmapImage* bmp; bmp = ConvertImageToBitmap( curImage, rect.right, rect.bottom, PIXFMT_DONTCARE, GetScaleMethodInterp()); if (!bmp) goto endPaint; VERBOSE(("Stretch time: %dms, ", GetTickCount() - timer)); IImage* image; hr = bmp->QueryInterface(IID_IImage, (VOID**) &image); bmp->Release(); if (FAILED(hr)) goto endPaint; timer = GetTickCount(); hr = image->Draw(hdc, &rect, NULL); VERBOSE(("GDI time: %dms\n", GetTickCount() - timer)); image->Release(); } endPaint: if (FAILED(hr)) FillRect(hdc, &rect, (HBRUSH) GetStockObject(BLACK_BRUSH)); EndPaint(hwnd, &ps); } // // Convert the current image to a bitmap // VOID DoConvertToBitmap( HWND hwnd, INT menuCmd ) { // Map menu selection to its corresponding pixel format PixelFormatID pixfmt; switch (menuCmd) { case IDM_CONVERT_RGB555: pixfmt = PIXFMT_16BPP_RGB555; break; case IDM_CONVERT_RGB565: pixfmt = PIXFMT_16BPP_RGB565; break; case IDM_CONVERT_RGB24: pixfmt = PIXFMT_24BPP_RGB; break; case IDM_CONVERT_RGB32: pixfmt = PIXFMT_32BPP_RGB; break; case IDM_CONVERT_ARGB: default: pixfmt = PIXFMT_32BPP_ARGB; break; } // Convert the current image to a bitmap image IBitmapImage* bmp = ConvertImageToBitmap(curImage, 0, 0, pixfmt); // Set the bitmap image as the current image if (bmp) SetCurrentImage(bmp); } // // Compose a file type filter string given an array of // ImageCodecInfo structures // #define SizeofWSTR(s) (sizeof(WCHAR) * (wcslen(s) + 1)) #define SizeofSTR(s) (strlen(s) + 1) CHAR* MakeFilterFromCodecs( UINT count, const ImageCodecInfo* codecs, BOOL open ) { static const CHAR allFiles[] = "All Files\0*.*\0"; // Figure out the total size of the filter string UINT index, size; for (index=size=0; index < count; index++) { size += SizeofWSTR(codecs[index].FormatDescription) + SizeofWSTR(codecs[index].FilenameExtension); } if (open) size += sizeof(allFiles); size += sizeof(CHAR); // Allocate memory CHAR *filter = (CHAR*) malloc(size); CHAR* p = filter; const WCHAR* ws; if (!filter) return NULL; for (index=0; index < count; index++) { ws = codecs[index].FormatDescription; size = SizeofWSTR(ws); if (UnicodeToAnsiStr(ws, p, size)) p += SizeofSTR(p); else break; ws = codecs[index].FilenameExtension; size = SizeofWSTR(ws); if (UnicodeToAnsiStr(ws, p, size)) p += SizeofSTR(p); else break; } if (index < count) { free(filter); return NULL; } if (open) { size = sizeof(allFiles); memcpy(p, allFiles, size); p += size; } *((CHAR*) p) = '\0'; return filter; } // // Open image file // VOID DoOpen( HWND hwnd ) { OPENFILENAME ofn; CHAR filename[MAX_PATH]; ZeroMemory(&ofn, sizeof(ofn)); ofn.lStructSize = sizeof(ofn); ofn.hwndOwner = hwnd; ofn.hInstance = appInstance; ofn.lpstrFile = filename; ofn.nMaxFile = MAX_PATH; ofn.lpstrTitle = "Open Image File"; ofn.lpstrInitialDir = "."; ofn.Flags = OFN_FILEMUSTEXIST; filename[0] = '\0'; // Make up the file type filter string HRESULT hr; ImageCodecInfo* codecs; UINT count; hr = imgfact->GetInstalledDecoders(&count, &codecs); if (!CHECKHR(hr)) return; CHAR* filter = MakeFilterFromCodecs(count, codecs, TRUE); if (codecs) CoTaskMemFree(codecs); if (!filter) { CHECKHR(LASTWIN32HRESULT); return; } ofn.lpstrFilter = filter; // Present the file/open dialog if (GetOpenFileName(&ofn)) OpenImageFile(filename); free(filter); } // // Save image file // VOID DoSave( HWND hwnd ) { OPENFILENAME ofn; CHAR filename[MAX_PATH]; ZeroMemory(&ofn, sizeof(ofn)); ofn.lStructSize = sizeof(ofn); ofn.hwndOwner = hwnd; ofn.hInstance = appInstance; ofn.lpstrFile = filename; ofn.nMaxFile = MAX_PATH; ofn.lpstrTitle = "Save Image File"; ofn.lpstrInitialDir = "."; ofn.Flags = OFN_CREATEPROMPT | OFN_OVERWRITEPROMPT; filename[0] = '\0'; // Make up the file type filter string HRESULT hr; ImageCodecInfo* codecs; UINT count; hr = imgfact->GetInstalledEncoders(&count, &codecs); if (!CHECKHR(hr)) return; CHAR* filter = MakeFilterFromCodecs(count, codecs, FALSE); if (!filter) { CHECKHR(LASTWIN32HRESULT); } else { ofn.lpstrFilter = filter; // Present the file/save dialog if (GetSaveFileName(&ofn)) { UINT index = ofn.nFilterIndex; if (index == 0 || index > count) index = 0; else index--; SaveImageFile(filename, &codecs[index].Clsid); } free(filter); } CoTaskMemFree(codecs); } // // Crop the image // // NOTE: We're not spending time here to do a fancy UI. // So we'll just inset the image by 5 pixels each time. // VOID DoCrop( HWND hwnd ) { IBitmapImage* bmp; if (bmp = ConvertImageToBitmap(curImage)) { HRESULT hr; IBasicBitmapOps* bmpops = NULL; SIZE size; hr = bmp->QueryInterface(IID_IBasicBitmapOps, (VOID**) &bmpops); if (CHECKHR(hr)) hr = bmp->GetSize(&size); if (CHECKHR(hr)) { RECT r = { 5, 5, size.cx - 5, size.cy - 5 }; IBitmapImage* newbmp; hr = bmpops->Clone(&r, &newbmp, TRUE); if (CHECKHR(hr)) SetCurrentImage(newbmp); } if (bmp) bmp->Release(); if (bmpops) bmpops->Release(); } } // // Resize the image to the current window size, using bilinear scaling // VOID DoResize( HWND hwnd ) { RECT rect; HRESULT hr; IBitmapImage* bmp; GetClientRect(hwnd, &rect); bmp = ConvertImageToBitmap( curImage, rect.right, rect.bottom, PIXFMT_DONTCARE, INTERP_BILINEAR); if (bmp) SetCurrentImage(bmp); } // // Flip or rotate the image // VOID DoFlipRotate( HWND hwnd, INT menuCmd ) { IBitmapImage* bmp; IBitmapImage* newbmp; IBasicBitmapOps* bmpops; HRESULT hr; bmp = ConvertImageToBitmap(curImage); if (!bmp) return; hr = bmp->QueryInterface(IID_IBasicBitmapOps, (VOID**) &bmpops); if (CHECKHR(hr)) { switch (menuCmd) { case IDM_BMP_FLIPX: hr = bmpops->Flip(TRUE, FALSE, &newbmp); break; case IDM_BMP_FLIPY: hr = bmpops->Flip(FALSE, TRUE, &newbmp); break; case IDM_BMP_ROTATE90: hr = bmpops->Rotate(90, INTERP_DEFAULT, &newbmp); break; case IDM_BMP_ROTATE270: hr = bmpops->Rotate(270, INTERP_DEFAULT, &newbmp); break; } bmpops->Release(); if (CHECKHR(hr)) { SetCurrentImage(newbmp); if (menuCmd == IDM_BMP_ROTATE90 || menuCmd == IDM_BMP_ROTATE270) { DoSizeWindowToFit(hwnd); } } } bmp->Release(); } // // Perform point operation on the image // VOID DoPointOps( HWND hwnd, INT menuCmd ) { IBitmapImage* bmp; IBitmapImage* newbmp; IBasicBitmapOps* bmpops; HRESULT hr; bmp = ConvertImageToBitmap(curImage); if (!bmp) return; hr = bmp->QueryInterface(IID_IBasicBitmapOps, (VOID**) &bmpops); if (CHECKHR(hr)) { switch (menuCmd) { case IDM_BRIGHTEN: hr = bmpops->AdjustBrightness(0.1f); break; case IDM_DARKEN: hr = bmpops->AdjustBrightness(-0.1f); break; case IDM_INCCONTRAST: hr = bmpops->AdjustContrast(-0.1f, 1.1f); break; case IDM_DECCONTRAST: hr = bmpops->AdjustContrast(0.1f, 0.9f); break; case IDM_INCGAMMA: hr = bmpops->AdjustGamma(1.1f); break; case IDM_DECGAMMA: hr = bmpops->AdjustGamma(0.9f); break; } bmpops->Release(); if (CHECKHR(hr)) SetCurrentImage(bmp); } if (FAILED(hr)) bmp->Release(); } VOID DisplayProperties( IPropertySetStorage *propSetStg ) { HRESULT hresult; IPropertyStorage *propStg; IEnumSTATPROPSTG *enumPS; hresult = propSetStg->Open(FMTID_ImageInformation, STGM_READ | STGM_SHARE_EXCLUSIVE, &propStg); if (FAILED(hresult)) { //printf("DisplayProperties: failed to open propSetStg\n"); return; } hresult = propStg->Enum(&enumPS); if (FAILED(hresult)) { printf("DisplayProperties: failed to create enumerator\n"); return; } hresult = enumPS->Reset(); if (FAILED(hresult)) { printf("DisplayProperties: failed to reset enumerator\n"); return; } STATPROPSTG sps; while ((enumPS->Next(1, &sps, NULL)) == S_OK) { if (sps.lpwstrName) { wprintf(sps.lpwstrName); CoTaskMemFree(sps.lpwstrName); PROPSPEC propSpec[1]; PROPVARIANT propVariant[1]; propSpec[0].ulKind = PRSPEC_PROPID; propSpec[0].propid = sps.propid; hresult = propStg->ReadMultiple(1, propSpec, propVariant); if (FAILED(hresult)) { printf("DisplayProperties: failed in ReadMultiple\n"); } switch(propVariant[0].vt) { case VT_BSTR: wprintf(L" : %s\n", propVariant[0].bstrVal); break; case VT_I4: wprintf(L" : %d\n", propVariant[0].lVal); break; case VT_R8: wprintf(L" : %f\n", (FLOAT) propVariant[0].dblVal); break; default: wprintf(L"Unknown VT type\n"); break; } PropVariantClear(&propVariant[0]); } } enumPS->Release(); propStg->Release(); } // // Handle menu commands // VOID DoMenuCommand( HWND hwnd, INT menuCmd ) { switch (menuCmd) { case IDM_OPEN: DoOpen(hwnd); break; case IDM_SAVE: DoSave(hwnd); break; case IDM_QUIT: PostQuitMessage(0); break; case IDM_FIT_WINDOW: DoSizeWindowToFit(hwnd, TRUE); break; case IDM_CONVERT_RGB555: case IDM_CONVERT_RGB565: case IDM_CONVERT_RGB24: case IDM_CONVERT_RGB32: case IDM_CONVERT_ARGB: DoConvertToBitmap(hwnd, menuCmd); break; case IDM_SCALE_GDI: case IDM_SCALE_GDIHT: case IDM_SCALE_NEIGHBOR: case IDM_SCALE_BILINEAR: case IDM_SCALE_AVERAGING: case IDM_SCALE_BICUBIC: scaleMethod = menuCmd; RefreshImageDisplay(); break; case IDM_BMP_CROP: DoCrop(hwnd); break; case IDM_BMP_RESIZE: DoResize(hwnd); break; case IDM_BMP_FLIPX: case IDM_BMP_FLIPY: case IDM_BMP_ROTATE90: case IDM_BMP_ROTATE270: DoFlipRotate(hwnd, menuCmd); break; case IDM_BRIGHTEN: case IDM_DARKEN: case IDM_INCCONTRAST: case IDM_DECCONTRAST: case IDM_INCGAMMA: case IDM_DECGAMMA: DoPointOps(hwnd, menuCmd); break; } } // // Window callback procedure // LRESULT CALLBACK MyWindowProc( HWND hwnd, UINT uMsg, WPARAM wParam, LPARAM lParam ) { switch (uMsg) { case WM_COMMAND: DoMenuCommand(hwnd, LOWORD(wParam)); break; case WM_PAINT: DoPaint(hwnd); break; case WM_DESTROY: PostQuitMessage(0); break; default: return DefWindowProc(hwnd, uMsg, wParam, lParam); } return 0; } // // Create main application window // #define MYWNDCLASSNAME "ImgTest" VOID CreateMainWindow( VOID ) { HBRUSH hBrush = CreateSolidBrush(RGB(255, 250, 250)); // // Register window class // WNDCLASS wndClass = { CS_HREDRAW|CS_VREDRAW, MyWindowProc, 0, 0, appInstance, LoadIcon(NULL, IDI_APPLICATION), LoadCursor(NULL, IDC_ARROW), hBrush, MAKEINTRESOURCE(IDR_MAINMENU), MYWNDCLASSNAME }; RegisterClass(&wndClass); hwndMain = CreateWindow( MYWNDCLASSNAME, MYWNDCLASSNAME, WS_OVERLAPPEDWINDOW, CW_USEDEFAULT, CW_USEDEFAULT, CW_USEDEFAULT, CW_USEDEFAULT, NULL, NULL, appInstance, NULL); if (!hwndMain) { CHECKHR(HRESULT_FROM_WIN32(GetLastError())); exit(-1); } } // // Create a new test bitmap object from scratch // #define STEPS 16 VOID CreateNewTestBitmap() { IBitmapImage* bmp; BitmapData bmpdata; HRESULT hr; hr = imgfact->CreateNewBitmap( STEPS, STEPS, PIXFMT_32BPP_ARGB, &bmp); if (!CHECKHR(hr)) return; hr = bmp->LockBits( NULL, IMGLOCK_WRITE, PIXFMT_DONTCARE, &bmpdata); if (!CHECKHR(hr)) { bmp->Release(); return; } // Make a horizontal blue gradient UINT x, y; ARGB colors[STEPS]; for (x=0; x < STEPS; x++) colors[x] = MAKEARGB(255, 0, 0, x * 255 / (STEPS-1)); for (y=0; y < STEPS; y++) { ARGB* p = (ARGB*) ((BYTE*) bmpdata.Scan0 + y*bmpdata.Stride); for (x=0; x < STEPS; x++) *p++ = colors[(x+y) % STEPS]; } bmp->UnlockBits(&bmpdata); SetCurrentImage(bmp); } // // Main program entrypoint // INT _cdecl main( INT argc, CHAR **argv ) { programName = *argv++; argc--; appInstance = GetModuleHandle(NULL); CoInitialize(NULL); // // Create an IImagingFactory object // HRESULT hr; hr = CoCreateInstance( CLSID_ImagingFactory, NULL, CLSCTX_INPROC_SERVER, IID_IImagingFactory, (VOID**) &imgfact); if (!CHECKHR(hr)) exit(-1); // // Create the main application window // CreateMainWindow(); // // Create a test image // if (argc != 0) OpenImageFile(*argv); if (!curImage) CreateNewTestBitmap(); if (!curImage) exit(-1); DoSizeWindowToFit(hwndMain); ShowWindow(hwndMain, SW_SHOW); // // Main message loop // MSG msg; HACCEL accel; accel = LoadAccelerators(appInstance, MAKEINTRESOURCE(IDR_ACCELTABLE)); while (GetMessage(&msg, NULL, 0, 0)) { if (!TranslateAccelerator(msg.hwnd, accel, &msg)) { TranslateMessage(&msg); DispatchMessage(&msg); } } curImage->Release(); imgfact->Release(); CoUninitialize(); return (INT)(msg.wParam); }