/* * tkImgPhInstance.c -- * * Implements the rendering of images of type "photo" for Tk. Photo * images are stored in full color (32 bits per pixel including alpha * channel) and displayed using dithering if necessary. * * Copyright (c) 1994 The Australian National University. * Copyright (c) 1994-1997 Sun Microsystems, Inc. * Copyright (c) 2002-2008 Donal K. Fellows * Copyright (c) 2003 ActiveState Corporation. * * See the file "license.terms" for information on usage and redistribution of * this file, and for a DISCLAIMER OF ALL WARRANTIES. * * Author: Paul Mackerras (paulus@cs.anu.edu.au), * Department of Computer Science, * Australian National University. */ #include "tkImgPhoto.h" /* * Declaration for internal Xlib function used here: */ extern int _XInitImageFuncPtrs(XImage *image); /* * Forward declarations */ static void BlendComplexAlpha(XImage *bgImg, PhotoInstance *iPtr, int xOffset, int yOffset, int width, int height); static int IsValidPalette(PhotoInstance *instancePtr, const char *palette); static int CountBits(pixel mask); static void GetColorTable(PhotoInstance *instancePtr); static void FreeColorTable(ColorTable *colorPtr, int force); static void AllocateColors(ColorTable *colorPtr); static void DisposeColorTable(ClientData clientData); static int ReclaimColors(ColorTableId *id, int numColors); /* * Hash table used to hash from (display, colormap, palette, gamma) to * ColorTable address. */ static Tcl_HashTable imgPhotoColorHash; static int imgPhotoColorHashInitialized; #define N_COLOR_HASH (sizeof(ColorTableId) / sizeof(int)) /* *---------------------------------------------------------------------- * * TkImgPhotoConfigureInstance -- * * This function is called to create displaying information for a photo * image instance based on the configuration information in the master. * It is invoked both when new instances are created and when the master * is reconfigured. * * Results: * None. * * Side effects: * Generates errors via Tcl_BackgroundException if there are problems in * setting up the instance. * *---------------------------------------------------------------------- */ void TkImgPhotoConfigureInstance( PhotoInstance *instancePtr) /* Instance to reconfigure. */ { PhotoMaster *masterPtr = instancePtr->masterPtr; XImage *imagePtr; int bitsPerPixel; ColorTable *colorTablePtr; XRectangle validBox; /* * If the -palette configuration option has been set for the master, use * the value specified for our palette, but only if it is a valid palette * for our windows. Use the gamma value specified the master. */ if ((masterPtr->palette && masterPtr->palette[0]) && IsValidPalette(instancePtr, masterPtr->palette)) { instancePtr->palette = masterPtr->palette; } else { instancePtr->palette = instancePtr->defaultPalette; } instancePtr->gamma = masterPtr->gamma; /* * If we don't currently have a color table, or if the one we have no * longer applies (e.g. because our palette or gamma has changed), get a * new one. */ colorTablePtr = instancePtr->colorTablePtr; if ((colorTablePtr == NULL) || (instancePtr->colormap != colorTablePtr->id.colormap) || (instancePtr->palette != colorTablePtr->id.palette) || (instancePtr->gamma != colorTablePtr->id.gamma)) { /* * Free up our old color table, and get a new one. */ if (colorTablePtr != NULL) { colorTablePtr->liveRefCount--; FreeColorTable(colorTablePtr, 0); } GetColorTable(instancePtr); /* * Create a new XImage structure for sending data to the X server, if * necessary. */ if (instancePtr->colorTablePtr->flags & BLACK_AND_WHITE) { bitsPerPixel = 1; } else { bitsPerPixel = instancePtr->visualInfo.depth; } if ((instancePtr->imagePtr == NULL) || (instancePtr->imagePtr->bits_per_pixel != bitsPerPixel)) { if (instancePtr->imagePtr != NULL) { XDestroyImage(instancePtr->imagePtr); } imagePtr = XCreateImage(instancePtr->display, instancePtr->visualInfo.visual, (unsigned) bitsPerPixel, (bitsPerPixel > 1? ZPixmap: XYBitmap), 0, NULL, 1, 1, 32, 0); instancePtr->imagePtr = imagePtr; /* * We create images using the local host's endianness, rather than * the endianness of the server; otherwise we would have to * byte-swap any 16 or 32 bit values that we store in the image * if the server's endianness is different from ours. */ if (imagePtr != NULL) { #ifdef WORDS_BIGENDIAN imagePtr->byte_order = MSBFirst; #else imagePtr->byte_order = LSBFirst; #endif _XInitImageFuncPtrs(imagePtr); } } } /* * If the user has specified a width and/or height for the master which is * different from our current width/height, set the size to the values * specified by the user. If we have no pixmap, we do this also, since it * has the side effect of allocating a pixmap for us. */ if ((instancePtr->pixels == None) || (instancePtr->error == NULL) || (instancePtr->width != masterPtr->width) || (instancePtr->height != masterPtr->height)) { TkImgPhotoInstanceSetSize(instancePtr); } /* * Redither this instance if necessary. */ if ((masterPtr->flags & IMAGE_CHANGED) || (instancePtr->colorTablePtr != colorTablePtr)) { TkClipBox(masterPtr->validRegion, &validBox); if ((validBox.width > 0) && (validBox.height > 0)) { TkImgDitherInstance(instancePtr, validBox.x, validBox.y, validBox.width, validBox.height); } } } /* *---------------------------------------------------------------------- * * TkImgPhotoGet -- * * This function is called for each use of a photo image in a widget. * * Results: * The return value is a token for the instance, which is passed back to * us in calls to TkImgPhotoDisplay and ImgPhotoFree. * * Side effects: * A data structure is set up for the instance (or, an existing instance * is re-used for the new one). * *---------------------------------------------------------------------- */ ClientData TkImgPhotoGet( Tk_Window tkwin, /* Window in which the instance will be * used. */ ClientData masterData) /* Pointer to our master structure for the * image. */ { PhotoMaster *masterPtr = masterData; PhotoInstance *instancePtr; Colormap colormap; int mono, nRed, nGreen, nBlue, numVisuals; XVisualInfo visualInfo, *visInfoPtr; char buf[TCL_INTEGER_SPACE * 3]; XColor *white, *black; XGCValues gcValues; /* * Table of "best" choices for palette for PseudoColor displays with * between 3 and 15 bits/pixel. */ static const int paletteChoice[13][3] = { /* #red, #green, #blue */ {2, 2, 2, /* 3 bits, 8 colors */}, {2, 3, 2, /* 4 bits, 12 colors */}, {3, 4, 2, /* 5 bits, 24 colors */}, {4, 5, 3, /* 6 bits, 60 colors */}, {5, 6, 4, /* 7 bits, 120 colors */}, {7, 7, 4, /* 8 bits, 198 colors */}, {8, 10, 6, /* 9 bits, 480 colors */}, {10, 12, 8, /* 10 bits, 960 colors */}, {14, 15, 9, /* 11 bits, 1890 colors */}, {16, 20, 12, /* 12 bits, 3840 colors */}, {20, 24, 16, /* 13 bits, 7680 colors */}, {26, 30, 20, /* 14 bits, 15600 colors */}, {32, 32, 30, /* 15 bits, 30720 colors */} }; /* * See if there is already an instance for windows using the same * colormap. If so then just re-use it. */ colormap = Tk_Colormap(tkwin); for (instancePtr = masterPtr->instancePtr; instancePtr != NULL; instancePtr = instancePtr->nextPtr) { if ((colormap == instancePtr->colormap) && (Tk_Display(tkwin) == instancePtr->display)) { /* * Re-use this instance. */ if (instancePtr->refCount == 0) { /* * We are resurrecting this instance. */ Tcl_CancelIdleCall(TkImgDisposeInstance, instancePtr); if (instancePtr->colorTablePtr != NULL) { FreeColorTable(instancePtr->colorTablePtr, 0); } GetColorTable(instancePtr); } instancePtr->refCount++; return instancePtr; } } /* * The image isn't already in use in a window with the same colormap. Make * a new instance of the image. */ instancePtr = ckalloc(sizeof(PhotoInstance)); instancePtr->masterPtr = masterPtr; instancePtr->display = Tk_Display(tkwin); instancePtr->colormap = Tk_Colormap(tkwin); Tk_PreserveColormap(instancePtr->display, instancePtr->colormap); instancePtr->refCount = 1; instancePtr->colorTablePtr = NULL; instancePtr->pixels = None; instancePtr->error = NULL; instancePtr->width = 0; instancePtr->height = 0; instancePtr->imagePtr = 0; instancePtr->nextPtr = masterPtr->instancePtr; masterPtr->instancePtr = instancePtr; /* * Obtain information about the visual and decide on the default palette. */ visualInfo.screen = Tk_ScreenNumber(tkwin); visualInfo.visualid = XVisualIDFromVisual(Tk_Visual(tkwin)); visInfoPtr = XGetVisualInfo(Tk_Display(tkwin), VisualScreenMask | VisualIDMask, &visualInfo, &numVisuals); if (visInfoPtr == NULL) { Tcl_Panic("TkImgPhotoGet couldn't find visual for window"); } nRed = 2; nGreen = nBlue = 0; mono = 1; instancePtr->visualInfo = *visInfoPtr; switch (visInfoPtr->class) { case DirectColor: case TrueColor: nRed = 1 << CountBits(visInfoPtr->red_mask); nGreen = 1 << CountBits(visInfoPtr->green_mask); nBlue = 1 << CountBits(visInfoPtr->blue_mask); mono = 0; break; case PseudoColor: case StaticColor: if (visInfoPtr->depth > 15) { nRed = 32; nGreen = 32; nBlue = 32; mono = 0; } else if (visInfoPtr->depth >= 3) { const int *ip = paletteChoice[visInfoPtr->depth - 3]; nRed = ip[0]; nGreen = ip[1]; nBlue = ip[2]; mono = 0; } break; case GrayScale: case StaticGray: nRed = 1 << visInfoPtr->depth; break; } XFree((char *) visInfoPtr); if (mono) { sprintf(buf, "%d", nRed); } else { sprintf(buf, "%d/%d/%d", nRed, nGreen, nBlue); } instancePtr->defaultPalette = Tk_GetUid(buf); /* * Make a GC with background = black and foreground = white. */ white = Tk_GetColor(masterPtr->interp, tkwin, "white"); black = Tk_GetColor(masterPtr->interp, tkwin, "black"); gcValues.foreground = (white != NULL)? white->pixel: WhitePixelOfScreen(Tk_Screen(tkwin)); gcValues.background = (black != NULL)? black->pixel: BlackPixelOfScreen(Tk_Screen(tkwin)); Tk_FreeColor(white); Tk_FreeColor(black); gcValues.graphics_exposures = False; instancePtr->gc = Tk_GetGC(tkwin, GCForeground|GCBackground|GCGraphicsExposures, &gcValues); /* * Set configuration options and finish the initialization of the * instance. This will also dither the image if necessary. */ TkImgPhotoConfigureInstance(instancePtr); /* * If this is the first instance, must set the size of the image. */ if (instancePtr->nextPtr == NULL) { Tk_ImageChanged(masterPtr->tkMaster, 0, 0, 0, 0, masterPtr->width, masterPtr->height); } return instancePtr; } /* *---------------------------------------------------------------------- * * BlendComplexAlpha -- * * This function is called when an image with partially transparent * pixels must be drawn over another image. It blends the photo data onto * a local copy of the surface that we are drawing on, *including* the * pixels drawn by everything that should be drawn underneath the image. * * Much of this code has hard-coded values in for speed because this * routine is performance critical for complex image drawing. * * Results: * None. * * Side effects: * Background image passed in gets drawn over with image data. * * Notes: * This should work on all platforms that set mask and shift data * properly from the visualInfo. RGB is really only a 24+ bpp version * whereas RGB15 is the correct version and works for 15bpp+, but it * slower, so it's only used for 15bpp+. * * Note that Win32 pre-defines those operations that we really need. * * Note that on MacOS, if the background comes from a Retina display * then it will be twice as wide and twice as high as the photoimage. * *---------------------------------------------------------------------- */ #ifndef _WIN32 #define GetRValue(rgb) (UCHAR(((rgb) & red_mask) >> red_shift)) #define GetGValue(rgb) (UCHAR(((rgb) & green_mask) >> green_shift)) #define GetBValue(rgb) (UCHAR(((rgb) & blue_mask) >> blue_shift)) #define RGB(r, g, b) ((unsigned)( \ (UCHAR(r) << red_shift) | \ (UCHAR(g) << green_shift) | \ (UCHAR(b) << blue_shift) )) #ifdef MAC_OSX_TK #define RGBA(r, g, b, a) ((unsigned)( \ (UCHAR(r) << red_shift) | \ (UCHAR(g) << green_shift) | \ (UCHAR(b) << blue_shift) | \ (UCHAR(a) << alpha_shift) )) #endif #define RGB15(r, g, b) ((unsigned)( \ (((r) * red_mask / 255) & red_mask) | \ (((g) * green_mask / 255) & green_mask) | \ (((b) * blue_mask / 255) & blue_mask) )) #endif /* !_WIN32 */ static void BlendComplexAlpha( XImage *bgImg, /* Background image to draw on. */ PhotoInstance *iPtr, /* Image instance to draw. */ int xOffset, int yOffset, /* X & Y offset into image instance to * draw. */ int width, int height) /* Width & height of image to draw. */ { int x, y, line; unsigned long pixel; unsigned char r, g, b, alpha, unalpha, *masterPtr; unsigned char *alphaAr = iPtr->masterPtr->pix32; #if defined(MAC_OSX_TK) /* Background "pixels" are actually 2^pp x 2^pp blocks of subpixels. Each * block gets blended with the color of one image pixel. Since we iterate * over the background subpixels, we reset the width and height to the * subpixel dimensions of the background image we are using. */ int pp = bgImg->pixelpower; width = width << pp; height = height << pp; #endif /* * This blending is an integer version of the Source-Over compositing rule * (see Porter&Duff, "Compositing Digital Images", proceedings of SIGGRAPH * 1984) that has been hard-coded (for speed) to work with targetting a * solid surface. * * The 'unalpha' field must be 255-alpha; it is separated out to encourage * more efficient compilation. */ #define ALPHA_BLEND(bgPix, imgPix, alpha, unalpha) \ ((bgPix * unalpha + imgPix * alpha) / 255) /* * We have to get the mask and shift info from the visual on non-Win32 so * that the macros Get*Value(), RGB() and RGB15() work correctly. This * might be cached for better performance. */ #ifndef _WIN32 unsigned long red_mask, green_mask, blue_mask; unsigned long red_shift, green_shift, blue_shift; Visual *visual = iPtr->visualInfo.visual; red_mask = visual->red_mask; green_mask = visual->green_mask; blue_mask = visual->blue_mask; red_shift = 0; green_shift = 0; blue_shift = 0; while ((0x0001 & (red_mask >> red_shift)) == 0) { red_shift++; } while ((0x0001 & (green_mask >> green_shift)) == 0) { green_shift++; } while ((0x0001 & (blue_mask >> blue_shift)) == 0) { blue_shift++; } #ifdef MAC_OSX_TK unsigned long alpha_mask = visual->alpha_mask; unsigned long alpha_shift = 0; while ((0x0001 & (alpha_mask >> alpha_shift)) == 0) { alpha_shift++; } #endif #endif /* !_WIN32 */ /* * Only UNIX requires the special case for <24bpp. It varies with 3 extra * shifts and uses RGB15. The 24+bpp version could also then be further * optimized. */ #if !(defined(_WIN32) || defined(MAC_OSX_TK)) if (bgImg->depth < 24) { unsigned char red_mlen, green_mlen, blue_mlen; red_mlen = 8 - CountBits(red_mask >> red_shift); green_mlen = 8 - CountBits(green_mask >> green_shift); blue_mlen = 8 - CountBits(blue_mask >> blue_shift); for (y = 0; y < height; y++) { line = (y + yOffset) * iPtr->masterPtr->width; for (x = 0; x < width; x++) { masterPtr = alphaAr + ((line + x + xOffset) * 4); alpha = masterPtr[3]; /* * Ignore pixels that are fully transparent */ if (alpha) { /* * We could perhaps be more efficient than XGetPixel for * 24 and 32 bit displays, but this seems "fast enough". */ r = masterPtr[0]; g = masterPtr[1]; b = masterPtr[2]; if (alpha != 255) { /* * Only blend pixels that have some transparency */ unsigned char ra, ga, ba; pixel = XGetPixel(bgImg, x, y); ra = GetRValue(pixel) << red_mlen; ga = GetGValue(pixel) << green_mlen; ba = GetBValue(pixel) << blue_mlen; unalpha = 255 - alpha; /* Calculate once. */ r = ALPHA_BLEND(ra, r, alpha, unalpha); g = ALPHA_BLEND(ga, g, alpha, unalpha); b = ALPHA_BLEND(ba, b, alpha, unalpha); } XPutPixel(bgImg, x, y, RGB15(r, g, b)); } } } return; } #endif /* !_WIN32 && !MAC_OSX_TK */ for (y = 0; y < height; y++) { # if !defined(MAC_OSX_TK) line = (y + yOffset) * iPtr->masterPtr->width; for (x = 0; x < width; x++) { masterPtr = alphaAr + ((line + x + xOffset) * 4); #else /* Repeat each image row and column 2^pp times. */ line = ((y>>pp) + yOffset) * iPtr->masterPtr->width; for (x = 0; x < width; x++) { masterPtr = alphaAr + ((line + (x>>pp) + xOffset) * 4); #endif alpha = masterPtr[3]; /* * Ignore pixels that are fully transparent */ if (alpha) { /* * We could perhaps be more efficient than XGetPixel for 24 * and 32 bit displays, but this seems "fast enough". */ r = masterPtr[0]; g = masterPtr[1]; b = masterPtr[2]; if (alpha != 255) { /* * Only blend pixels that have some transparency */ unsigned char ra, ga, ba; pixel = XGetPixel(bgImg, x, y); ra = GetRValue(pixel); ga = GetGValue(pixel); ba = GetBValue(pixel); unalpha = 255 - alpha; /* Calculate once. */ r = ALPHA_BLEND(ra, r, alpha, unalpha); g = ALPHA_BLEND(ga, g, alpha, unalpha); b = ALPHA_BLEND(ba, b, alpha, unalpha); } #ifndef MAC_OSX_TK XPutPixel(bgImg, x, y, RGB(r, g, b)); #else XPutPixel(bgImg, x, y, RGBA(r, g, b, alpha)); #endif } } } #undef ALPHA_BLEND } /* *---------------------------------------------------------------------- * * TkImgPhotoDisplay -- * * This function is invoked to draw a photo image. * * Results: * None. * * Side effects: * A portion of the image gets rendered in a pixmap or window. * *---------------------------------------------------------------------- */ void TkImgPhotoDisplay( ClientData clientData, /* Pointer to PhotoInstance structure for * instance to be displayed. */ Display *display, /* Display on which to draw image. */ Drawable drawable, /* Pixmap or window in which to draw image. */ int imageX, int imageY, /* Upper-left corner of region within image to * draw. */ int width, int height, /* Dimensions of region within image to * draw. */ int drawableX,int drawableY)/* Coordinates within drawable that correspond * to imageX and imageY. */ { PhotoInstance *instancePtr = clientData; XVisualInfo visInfo = instancePtr->visualInfo; /* * If there's no pixmap, it means that an error occurred while creating * the image instance so it can't be displayed. */ if (instancePtr->pixels == None) { return; } if ((instancePtr->masterPtr->flags & COMPLEX_ALPHA) && visInfo.depth >= 15 && (visInfo.class == DirectColor || visInfo.class == TrueColor)) { Tk_ErrorHandler handler; XImage *bgImg = NULL; /* * Create an error handler to suppress the case where the input was * not properly constrained, which can cause an X error. [Bug 979239] */ handler = Tk_CreateErrorHandler(display, -1, -1, -1, NULL, NULL); /* * Pull the current background from the display to blend with */ bgImg = XGetImage(display, drawable, drawableX, drawableY, (unsigned int)width, (unsigned int)height, AllPlanes, ZPixmap); if (bgImg == NULL) { Tk_DeleteErrorHandler(handler); /* We failed to get the image, so draw without blending alpha. * It's the best we can do. */ goto fallBack; } BlendComplexAlpha(bgImg, instancePtr, imageX, imageY, width, height); /* * Color info is unimportant as we only do this operation for depth >= * 15. */ TkPutImage(NULL, 0, display, drawable, instancePtr->gc, bgImg, 0, 0, drawableX, drawableY, (unsigned int) width, (unsigned int) height); XDestroyImage(bgImg); Tk_DeleteErrorHandler(handler); } else { /* * masterPtr->region describes which parts of the image contain valid * data. We set this region as the clip mask for the gc, setting its * origin appropriately, and use it when drawing the image. */ fallBack: TkSetRegion(display, instancePtr->gc, instancePtr->masterPtr->validRegion); XSetClipOrigin(display, instancePtr->gc, drawableX - imageX, drawableY - imageY); XCopyArea(display, instancePtr->pixels, drawable, instancePtr->gc, imageX, imageY, (unsigned) width, (unsigned) height, drawableX, drawableY); XSetClipMask(display, instancePtr->gc, None); XSetClipOrigin(display, instancePtr->gc, 0, 0); } XFlush(display); } /* *---------------------------------------------------------------------- * * TkImgPhotoFree -- * * This function is called when a widget ceases to use a particular * instance of an image. We don't actually get rid of the instance until * later because we may be about to get this instance again. * * Results: * None. * * Side effects: * Internal data structures get cleaned up, later. * *---------------------------------------------------------------------- */ void TkImgPhotoFree( ClientData clientData, /* Pointer to PhotoInstance structure for * instance to be displayed. */ Display *display) /* Display containing window that used * image. */ { PhotoInstance *instancePtr = clientData; ColorTable *colorPtr; if (instancePtr->refCount-- > 1) { return; } /* * There are no more uses of the image within this widget. Decrement the * count of live uses of its color table, so that its colors can be * reclaimed if necessary, and set up an idle call to free the instance * structure. */ colorPtr = instancePtr->colorTablePtr; if (colorPtr != NULL) { colorPtr->liveRefCount--; } Tcl_DoWhenIdle(TkImgDisposeInstance, instancePtr); } /* *---------------------------------------------------------------------- * * TkImgPhotoInstanceSetSize -- * * This function reallocates the instance pixmap and dithering error * array for a photo instance, as necessary, to change the image's size * to `width' x `height' pixels. * * Results: * None. * * Side effects: * Storage gets reallocated, here and in the X server. * *---------------------------------------------------------------------- */ void TkImgPhotoInstanceSetSize( PhotoInstance *instancePtr) /* Instance whose size is to be changed. */ { PhotoMaster *masterPtr; schar *newError, *errSrcPtr, *errDestPtr; int h, offset; XRectangle validBox; Pixmap newPixmap; masterPtr = instancePtr->masterPtr; TkClipBox(masterPtr->validRegion, &validBox); if ((instancePtr->width != masterPtr->width) || (instancePtr->height != masterPtr->height) || (instancePtr->pixels == None)) { newPixmap = Tk_GetPixmap(instancePtr->display, RootWindow(instancePtr->display, instancePtr->visualInfo.screen), (masterPtr->width > 0) ? masterPtr->width: 1, (masterPtr->height > 0) ? masterPtr->height: 1, instancePtr->visualInfo.depth); if (!newPixmap) { Tcl_Panic("Fail to create pixmap with Tk_GetPixmap in TkImgPhotoInstanceSetSize"); } /* * The following is a gross hack needed to properly support colormaps * under Windows. Before the pixels can be copied to the pixmap, the * relevent colormap must be associated with the drawable. Normally we * can infer this association from the window that was used to create * the pixmap. However, in this case we're using the root window, so * we have to be more explicit. */ TkSetPixmapColormap(newPixmap, instancePtr->colormap); if (instancePtr->pixels != None) { /* * Copy any common pixels from the old pixmap and free it. */ XCopyArea(instancePtr->display, instancePtr->pixels, newPixmap, instancePtr->gc, validBox.x, validBox.y, validBox.width, validBox.height, validBox.x, validBox.y); Tk_FreePixmap(instancePtr->display, instancePtr->pixels); } instancePtr->pixels = newPixmap; } if ((instancePtr->width != masterPtr->width) || (instancePtr->height != masterPtr->height) || (instancePtr->error == NULL)) { if (masterPtr->height > 0 && masterPtr->width > 0) { /* * TODO: use attemptckalloc() here once there is a strategy that * will allow us to recover from failure. Right now, there's no * such possibility. */ newError = ckalloc(masterPtr->height * masterPtr->width * 3 * sizeof(schar)); /* * Zero the new array so that we don't get bogus error values * propagating into areas we dither later. */ if ((instancePtr->error != NULL) && ((instancePtr->width == masterPtr->width) || (validBox.width == masterPtr->width))) { if (validBox.y > 0) { memset(newError, 0, (size_t) validBox.y * masterPtr->width * 3 * sizeof(schar)); } h = validBox.y + validBox.height; if (h < masterPtr->height) { memset(newError + h*masterPtr->width*3, 0, (size_t) (masterPtr->height - h) * masterPtr->width * 3 * sizeof(schar)); } } else { memset(newError, 0, (size_t) masterPtr->height * masterPtr->width *3*sizeof(schar)); } } else { newError = NULL; } if (instancePtr->error != NULL) { /* * Copy the common area over to the new array and free the old * array. */ if (masterPtr->width == instancePtr->width) { offset = validBox.y * masterPtr->width * 3; memcpy(newError + offset, instancePtr->error + offset, (size_t) (validBox.height * masterPtr->width * 3 * sizeof(schar))); } else if (validBox.width > 0 && validBox.height > 0) { errDestPtr = newError + (validBox.y * masterPtr->width + validBox.x) * 3; errSrcPtr = instancePtr->error + (validBox.y * instancePtr->width + validBox.x) * 3; for (h = validBox.height; h > 0; --h) { memcpy(errDestPtr, errSrcPtr, validBox.width * 3 * sizeof(schar)); errDestPtr += masterPtr->width * 3; errSrcPtr += instancePtr->width * 3; } } ckfree(instancePtr->error); } instancePtr->error = newError; } instancePtr->width = masterPtr->width; instancePtr->height = masterPtr->height; } /* *---------------------------------------------------------------------- * * IsValidPalette -- * * This function is called to check whether a value given for the * -palette option is valid for a particular instance of a photo image. * * Results: * A boolean value: 1 if the palette is acceptable, 0 otherwise. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int IsValidPalette( PhotoInstance *instancePtr, /* Instance to which the palette specification * is to be applied. */ const char *palette) /* Palette specification string. */ { int nRed, nGreen, nBlue, mono, numColors; char *endp; /* * First parse the specification: it must be of the form %d or %d/%d/%d. */ nRed = strtol(palette, &endp, 10); if ((endp == palette) || ((*endp != 0) && (*endp != '/')) || (nRed < 2) || (nRed > 256)) { return 0; } if (*endp == 0) { mono = 1; nGreen = nBlue = nRed; } else { palette = endp + 1; nGreen = strtol(palette, &endp, 10); if ((endp == palette) || (*endp != '/') || (nGreen < 2) || (nGreen > 256)) { return 0; } palette = endp + 1; nBlue = strtol(palette, &endp, 10); if ((endp == palette) || (*endp != 0) || (nBlue < 2) || (nBlue > 256)) { return 0; } mono = 0; } switch (instancePtr->visualInfo.class) { case DirectColor: case TrueColor: if ((nRed > (1 << CountBits(instancePtr->visualInfo.red_mask))) || (nGreen>(1<visualInfo.green_mask))) || (nBlue>(1<visualInfo.blue_mask)))) { return 0; } break; case PseudoColor: case StaticColor: numColors = nRed; if (!mono) { numColors *= nGreen * nBlue; } if (numColors > (1 << instancePtr->visualInfo.depth)) { return 0; } break; case GrayScale: case StaticGray: if (!mono || (nRed > (1 << instancePtr->visualInfo.depth))) { return 0; } break; } return 1; } /* *---------------------------------------------------------------------- * * CountBits -- * * This function counts how many bits are set to 1 in `mask'. * * Results: * The integer number of bits. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int CountBits( pixel mask) /* Value to count the 1 bits in. */ { int n; for (n=0 ; mask!=0 ; mask&=mask-1) { n++; } return n; } /* *---------------------------------------------------------------------- * * GetColorTable -- * * This function is called to allocate a table of colormap information * for an instance of a photo image. Only one such table is allocated for * all photo instances using the same display, colormap, palette and * gamma values, so that the application need only request a set of * colors from the X server once for all such photo widgets. This * function maintains a hash table to find previously-allocated * ColorTables. * * Results: * None. * * Side effects: * A new ColorTable may be allocated and placed in the hash table, and * have colors allocated for it. * *---------------------------------------------------------------------- */ static void GetColorTable( PhotoInstance *instancePtr) /* Instance needing a color table. */ { ColorTable *colorPtr; Tcl_HashEntry *entry; ColorTableId id; int isNew; /* * Look for an existing ColorTable in the hash table. */ memset(&id, 0, sizeof(id)); id.display = instancePtr->display; id.colormap = instancePtr->colormap; id.palette = instancePtr->palette; id.gamma = instancePtr->gamma; if (!imgPhotoColorHashInitialized) { Tcl_InitHashTable(&imgPhotoColorHash, N_COLOR_HASH); imgPhotoColorHashInitialized = 1; } entry = Tcl_CreateHashEntry(&imgPhotoColorHash, (char *) &id, &isNew); if (!isNew) { /* * Re-use the existing entry. */ colorPtr = Tcl_GetHashValue(entry); } else { /* * No color table currently available; need to make one. */ colorPtr = ckalloc(sizeof(ColorTable)); /* * The following line of code should not normally be needed due to the * assignment in the following line. However, it compensates for bugs * in some compilers (HP, for example) where sizeof(ColorTable) is 24 * but the assignment only copies 20 bytes, leaving 4 bytes * uninitialized; these cause problems when using the id for lookups * in imgPhotoColorHash, and can result in core dumps. */ memset(&colorPtr->id, 0, sizeof(ColorTableId)); colorPtr->id = id; Tk_PreserveColormap(colorPtr->id.display, colorPtr->id.colormap); colorPtr->flags = 0; colorPtr->refCount = 0; colorPtr->liveRefCount = 0; colorPtr->numColors = 0; colorPtr->visualInfo = instancePtr->visualInfo; colorPtr->pixelMap = NULL; Tcl_SetHashValue(entry, colorPtr); } colorPtr->refCount++; colorPtr->liveRefCount++; instancePtr->colorTablePtr = colorPtr; if (colorPtr->flags & DISPOSE_PENDING) { Tcl_CancelIdleCall(DisposeColorTable, colorPtr); colorPtr->flags &= ~DISPOSE_PENDING; } /* * Allocate colors for this color table if necessary. */ if ((colorPtr->numColors == 0) && !(colorPtr->flags & BLACK_AND_WHITE)) { AllocateColors(colorPtr); } } /* *---------------------------------------------------------------------- * * FreeColorTable -- * * This function is called when an instance ceases using a color table. * * Results: * None. * * Side effects: * If no other instances are using this color table, a when-idle handler * is registered to free up the color table and the colors allocated for * it. * *---------------------------------------------------------------------- */ static void FreeColorTable( ColorTable *colorPtr, /* Pointer to the color table which is no * longer required by an instance. */ int force) /* Force free to happen immediately. */ { if (colorPtr->refCount-- > 1) { return; } if (force) { if (colorPtr->flags & DISPOSE_PENDING) { Tcl_CancelIdleCall(DisposeColorTable, colorPtr); colorPtr->flags &= ~DISPOSE_PENDING; } DisposeColorTable(colorPtr); } else if (!(colorPtr->flags & DISPOSE_PENDING)) { Tcl_DoWhenIdle(DisposeColorTable, colorPtr); colorPtr->flags |= DISPOSE_PENDING; } } /* *---------------------------------------------------------------------- * * AllocateColors -- * * This function allocates the colors required by a color table, and sets * up the fields in the color table data structure which are used in * dithering. * * Results: * None. * * Side effects: * Colors are allocated from the X server. Fields in the color table data * structure are updated. * *---------------------------------------------------------------------- */ static void AllocateColors( ColorTable *colorPtr) /* Pointer to the color table requiring colors * to be allocated. */ { int i, r, g, b, rMult, mono; int numColors, nRed, nGreen, nBlue; double fr, fg, fb, igam; XColor *colors; unsigned long *pixels; /* * 16-bit intensity value for i/n of full intensity. */ #define CFRAC(i, n) ((i) * 65535 / (n)) /* As for CFRAC, but apply exponent of g. */ #define CGFRAC(i, n, g) ((int)(65535 * pow((double)(i) / (n), (g)))) /* * First parse the palette specification to get the required number of * shades of each primary. */ mono = sscanf(colorPtr->id.palette, "%d/%d/%d", &nRed, &nGreen, &nBlue) <= 1; igam = 1.0 / colorPtr->id.gamma; /* * Each time around this loop, we reduce the number of colors we're trying * to allocate until we succeed in allocating all of the colors we need. */ for (;;) { /* * If we are using 1 bit/pixel, we don't need to allocate any colors * (we just use the foreground and background colors in the GC). */ if (mono && (nRed <= 2)) { colorPtr->flags |= BLACK_AND_WHITE; return; } /* * Calculate the RGB coordinates of the colors we want to allocate and * store them in *colors. */ if ((colorPtr->visualInfo.class == DirectColor) || (colorPtr->visualInfo.class == TrueColor)) { /* * Direct/True Color: allocate shades of red, green, blue * independently. */ if (mono) { numColors = nGreen = nBlue = nRed; } else { numColors = MAX(MAX(nRed, nGreen), nBlue); } colors = ckalloc(numColors * sizeof(XColor)); for (i = 0; i < numColors; ++i) { if (igam == 1.0) { colors[i].red = CFRAC(i, nRed - 1); colors[i].green = CFRAC(i, nGreen - 1); colors[i].blue = CFRAC(i, nBlue - 1); } else { colors[i].red = CGFRAC(i, nRed - 1, igam); colors[i].green = CGFRAC(i, nGreen - 1, igam); colors[i].blue = CGFRAC(i, nBlue - 1, igam); } } } else { /* * PseudoColor, StaticColor, GrayScale or StaticGray visual: we * have to allocate each color in the color cube separately. */ numColors = (mono) ? nRed: (nRed * nGreen * nBlue); colors = ckalloc(numColors * sizeof(XColor)); if (!mono) { /* * Color display using a PseudoColor or StaticColor visual. */ i = 0; for (r = 0; r < nRed; ++r) { for (g = 0; g < nGreen; ++g) { for (b = 0; b < nBlue; ++b) { if (igam == 1.0) { colors[i].red = CFRAC(r, nRed - 1); colors[i].green = CFRAC(g, nGreen - 1); colors[i].blue = CFRAC(b, nBlue - 1); } else { colors[i].red = CGFRAC(r, nRed - 1, igam); colors[i].green = CGFRAC(g, nGreen - 1, igam); colors[i].blue = CGFRAC(b, nBlue - 1, igam); } i++; } } } } else { /* * Monochrome display - allocate the shades of gray we want. */ for (i = 0; i < numColors; ++i) { if (igam == 1.0) { r = CFRAC(i, numColors - 1); } else { r = CGFRAC(i, numColors - 1, igam); } colors[i].red = colors[i].green = colors[i].blue = r; } } } /* * Now try to allocate the colors we've calculated. */ pixels = ckalloc(numColors * sizeof(unsigned long)); for (i = 0; i < numColors; ++i) { if (!XAllocColor(colorPtr->id.display, colorPtr->id.colormap, &colors[i])) { /* * Can't get all the colors we want in the default colormap; * first try freeing colors from other unused color tables. */ if (!ReclaimColors(&colorPtr->id, numColors - i) || !XAllocColor(colorPtr->id.display, colorPtr->id.colormap, &colors[i])) { /* * Still can't allocate the color. */ break; } } pixels[i] = colors[i].pixel; } /* * If we didn't get all of the colors, reduce the resolution of the * color cube, free the ones we got, and try again. */ if (i >= numColors) { break; } XFreeColors(colorPtr->id.display, colorPtr->id.colormap, pixels, i, 0); ckfree(colors); ckfree(pixels); if (!mono) { if ((nRed == 2) && (nGreen == 2) && (nBlue == 2)) { /* * Fall back to 1-bit monochrome display. */ mono = 1; } else { /* * Reduce the number of shades of each primary to about 3/4 of * the previous value. This should reduce the total number of * colors required to about half the previous value for * PseudoColor displays. */ nRed = (nRed * 3 + 2) / 4; nGreen = (nGreen * 3 + 2) / 4; nBlue = (nBlue * 3 + 2) / 4; } } else { /* * Reduce the number of shades of gray to about 1/2. */ nRed = nRed / 2; } } /* * We have allocated all of the necessary colors: fill in various fields * of the ColorTable record. */ if (!mono) { colorPtr->flags |= COLOR_WINDOW; /* * The following is a hairy hack. We only want to index into the * pixelMap on colormap displays. However, if the display is on * Windows, then we actually want to store the index not the value * since we will be passing the color table into the TkPutImage call. */ #ifndef _WIN32 if ((colorPtr->visualInfo.class != DirectColor) && (colorPtr->visualInfo.class != TrueColor)) { colorPtr->flags |= MAP_COLORS; } #endif /* _WIN32 */ } colorPtr->numColors = numColors; colorPtr->pixelMap = pixels; /* * Set up quantization tables for dithering. */ rMult = nGreen * nBlue; for (i = 0; i < 256; ++i) { r = (i * (nRed - 1) + 127) / 255; if (mono) { fr = (double) colors[r].red / 65535.0; if (colorPtr->id.gamma != 1.0 ) { fr = pow(fr, colorPtr->id.gamma); } colorPtr->colorQuant[0][i] = (int)(fr * 255.99); colorPtr->redValues[i] = colors[r].pixel; } else { g = (i * (nGreen - 1) + 127) / 255; b = (i * (nBlue - 1) + 127) / 255; if ((colorPtr->visualInfo.class == DirectColor) || (colorPtr->visualInfo.class == TrueColor)) { colorPtr->redValues[i] = colors[r].pixel & colorPtr->visualInfo.red_mask; colorPtr->greenValues[i] = colors[g].pixel & colorPtr->visualInfo.green_mask; colorPtr->blueValues[i] = colors[b].pixel & colorPtr->visualInfo.blue_mask; } else { r *= rMult; g *= nBlue; colorPtr->redValues[i] = r; colorPtr->greenValues[i] = g; colorPtr->blueValues[i] = b; } fr = (double) colors[r].red / 65535.0; fg = (double) colors[g].green / 65535.0; fb = (double) colors[b].blue / 65535.0; if (colorPtr->id.gamma != 1.0) { fr = pow(fr, colorPtr->id.gamma); fg = pow(fg, colorPtr->id.gamma); fb = pow(fb, colorPtr->id.gamma); } colorPtr->colorQuant[0][i] = (int)(fr * 255.99); colorPtr->colorQuant[1][i] = (int)(fg * 255.99); colorPtr->colorQuant[2][i] = (int)(fb * 255.99); } } ckfree(colors); } /* *---------------------------------------------------------------------- * * DisposeColorTable -- * * Release a color table and its associated resources. * * Results: * None. * * Side effects: * The colors in the argument color table are freed, as is the color * table structure itself. The color table is removed from the hash table * which is used to locate color tables. * *---------------------------------------------------------------------- */ static void DisposeColorTable( ClientData clientData) /* Pointer to the ColorTable whose * colors are to be released. */ { ColorTable *colorPtr = clientData; Tcl_HashEntry *entry; if (colorPtr->pixelMap != NULL) { if (colorPtr->numColors > 0) { XFreeColors(colorPtr->id.display, colorPtr->id.colormap, colorPtr->pixelMap, colorPtr->numColors, 0); Tk_FreeColormap(colorPtr->id.display, colorPtr->id.colormap); } ckfree(colorPtr->pixelMap); } entry = Tcl_FindHashEntry(&imgPhotoColorHash, (char *) &colorPtr->id); if (entry == NULL) { Tcl_Panic("DisposeColorTable couldn't find hash entry"); } Tcl_DeleteHashEntry(entry); ckfree(colorPtr); } /* *---------------------------------------------------------------------- * * ReclaimColors -- * * This function is called to try to free up colors in the colormap used * by a color table. It looks for other color tables with the same * colormap and with a zero live reference count, and frees their colors. * It only does so if there is the possibility of freeing up at least * `numColors' colors. * * Results: * The return value is TRUE if any colors were freed, FALSE otherwise. * * Side effects: * ColorTables which are not currently in use may lose their color * allocations. * *---------------------------------------------------------------------- */ static int ReclaimColors( ColorTableId *id, /* Pointer to information identifying * the color table which needs more colors. */ int numColors) /* Number of colors required. */ { Tcl_HashSearch srch; Tcl_HashEntry *entry; ColorTable *colorPtr; int nAvail = 0; /* * First scan through the color hash table to get an upper bound on how * many colors we might be able to free. */ entry = Tcl_FirstHashEntry(&imgPhotoColorHash, &srch); while (entry != NULL) { colorPtr = Tcl_GetHashValue(entry); if ((colorPtr->id.display == id->display) && (colorPtr->id.colormap == id->colormap) && (colorPtr->liveRefCount == 0 )&& (colorPtr->numColors != 0) && ((colorPtr->id.palette != id->palette) || (colorPtr->id.gamma != id->gamma))) { /* * We could take this guy's colors off him. */ nAvail += colorPtr->numColors; } entry = Tcl_NextHashEntry(&srch); } /* * nAvail is an (over)estimate of the number of colors we could free. */ if (nAvail < numColors) { return 0; } /* * Scan through a second time freeing colors. */ entry = Tcl_FirstHashEntry(&imgPhotoColorHash, &srch); while ((entry != NULL) && (numColors > 0)) { colorPtr = Tcl_GetHashValue(entry); if ((colorPtr->id.display == id->display) && (colorPtr->id.colormap == id->colormap) && (colorPtr->liveRefCount == 0) && (colorPtr->numColors != 0) && ((colorPtr->id.palette != id->palette) || (colorPtr->id.gamma != id->gamma))) { /* * Free the colors that this ColorTable has. */ XFreeColors(colorPtr->id.display, colorPtr->id.colormap, colorPtr->pixelMap, colorPtr->numColors, 0); numColors -= colorPtr->numColors; colorPtr->numColors = 0; ckfree(colorPtr->pixelMap); colorPtr->pixelMap = NULL; } entry = Tcl_NextHashEntry(&srch); } return 1; /* We freed some colors. */ } /* *---------------------------------------------------------------------- * * TkImgDisposeInstance -- * * This function is called to finally free up an instance of a photo * image which is no longer required. * * Results: * None. * * Side effects: * The instance data structure and the resources it references are freed. * *---------------------------------------------------------------------- */ void TkImgDisposeInstance( ClientData clientData) /* Pointer to the instance whose resources are * to be released. */ { PhotoInstance *instancePtr = clientData; PhotoInstance *prevPtr; if (instancePtr->pixels != None) { Tk_FreePixmap(instancePtr->display, instancePtr->pixels); } if (instancePtr->gc != None) { Tk_FreeGC(instancePtr->display, instancePtr->gc); } if (instancePtr->imagePtr != NULL) { XDestroyImage(instancePtr->imagePtr); } if (instancePtr->error != NULL) { ckfree(instancePtr->error); } if (instancePtr->colorTablePtr != NULL) { FreeColorTable(instancePtr->colorTablePtr, 1); } if (instancePtr->masterPtr->instancePtr == instancePtr) { instancePtr->masterPtr->instancePtr = instancePtr->nextPtr; } else { for (prevPtr = instancePtr->masterPtr->instancePtr; prevPtr->nextPtr != instancePtr; prevPtr = prevPtr->nextPtr) { /* Empty loop body. */ } prevPtr->nextPtr = instancePtr->nextPtr; } Tk_FreeColormap(instancePtr->display, instancePtr->colormap); ckfree(instancePtr); } /* *---------------------------------------------------------------------- * * TkImgDitherInstance -- * * This function is called to update an area of an instance's pixmap by * dithering the corresponding area of the master. * * Results: * None. * * Side effects: * The instance's pixmap gets updated. * *---------------------------------------------------------------------- */ void TkImgDitherInstance( PhotoInstance *instancePtr, /* The instance to be updated. */ int xStart, int yStart, /* Coordinates of the top-left pixel in the * block to be dithered. */ int width, int height) /* Dimensions of the block to be dithered. */ { PhotoMaster *masterPtr = instancePtr->masterPtr; ColorTable *colorPtr = instancePtr->colorTablePtr; XImage *imagePtr; int nLines, bigEndian, i, c, x, y, xEnd, doDithering = 1; int bitsPerPixel, bytesPerLine, lineLength; unsigned char *srcLinePtr; schar *errLinePtr; pixel firstBit, word, mask; /* * Turn dithering off in certain cases where it is not needed (TrueColor, * DirectColor with many colors). */ if ((colorPtr->visualInfo.class == DirectColor) || (colorPtr->visualInfo.class == TrueColor)) { int nRed, nGreen, nBlue, result; result = sscanf(colorPtr->id.palette, "%d/%d/%d", &nRed, &nGreen, &nBlue); if ((nRed >= 256) && ((result == 1) || ((nGreen >= 256) && (nBlue >= 256)))) { doDithering = 0; } } /* * First work out how many lines to do at a time, then how many bytes * we'll need for pixel storage, and allocate it. */ nLines = (MAX_PIXELS + width - 1) / width; if (nLines < 1) { nLines = 1; } if (nLines > height ) { nLines = height; } imagePtr = instancePtr->imagePtr; if (imagePtr == NULL) { return; /* We must be really tight on memory. */ } bitsPerPixel = imagePtr->bits_per_pixel; bytesPerLine = ((bitsPerPixel * width + 31) >> 3) & ~3; imagePtr->width = width; imagePtr->height = nLines; imagePtr->bytes_per_line = bytesPerLine; /* * TODO: use attemptckalloc() here once we have some strategy for * recovering from the failure. */ imagePtr->data = ckalloc(imagePtr->bytes_per_line * nLines); bigEndian = imagePtr->bitmap_bit_order == MSBFirst; firstBit = bigEndian? (1 << (imagePtr->bitmap_unit - 1)): 1; lineLength = masterPtr->width * 3; srcLinePtr = masterPtr->pix32 + (yStart * masterPtr->width + xStart) * 4; errLinePtr = instancePtr->error + yStart * lineLength + xStart * 3; xEnd = xStart + width; /* * Loop over the image, doing at most nLines lines before updating the * screen image. */ for (; height > 0; height -= nLines) { unsigned char *dstLinePtr = (unsigned char *) imagePtr->data; int yEnd; if (nLines > height) { nLines = height; } yEnd = yStart + nLines; for (y = yStart; y < yEnd; ++y) { unsigned char *srcPtr = srcLinePtr; schar *errPtr = errLinePtr; unsigned char *destBytePtr = dstLinePtr; pixel *destLongPtr = (pixel *) dstLinePtr; if (colorPtr->flags & COLOR_WINDOW) { /* * Color window. We dither the three components independently, * using Floyd-Steinberg dithering, which propagates errors * from the quantization of pixels to the pixels below and to * the right. */ for (x = xStart; x < xEnd; ++x) { int col[3]; if (doDithering) { for (i = 0; i < 3; ++i) { /* * Compute the error propagated into this pixel * for this component. If e[x,y] is the array of * quantization error values, we compute * 7/16 * e[x-1,y] + 1/16 * e[x-1,y-1] * + 5/16 * e[x,y-1] + 3/16 * e[x+1,y-1] * and round it to an integer. * * The expression ((c + 2056) >> 4) - 128 computes * round(c / 16), and works correctly on machines * without a sign-extending right shift. */ c = (x > 0) ? errPtr[-3] * 7: 0; if (y > 0) { if (x > 0) { c += errPtr[-lineLength-3]; } c += errPtr[-lineLength] * 5; if ((x + 1) < masterPtr->width) { c += errPtr[-lineLength+3] * 3; } } /* * Add the propagated error to the value of this * component, quantize it, and store the * quantization error. */ c = ((c + 2056) >> 4) - 128 + *srcPtr++; if (c < 0) { c = 0; } else if (c > 255) { c = 255; } col[i] = colorPtr->colorQuant[i][c]; *errPtr++ = c - col[i]; } } else { /* * Output is virtually continuous in this case, so * don't bother dithering. */ col[0] = *srcPtr++; col[1] = *srcPtr++; col[2] = *srcPtr++; } srcPtr++; /* * Translate the quantized component values into an X * pixel value, and store it in the image. */ i = colorPtr->redValues[col[0]] + colorPtr->greenValues[col[1]] + colorPtr->blueValues[col[2]]; if (colorPtr->flags & MAP_COLORS) { i = colorPtr->pixelMap[i]; } switch (bitsPerPixel) { case NBBY: *destBytePtr++ = i; break; #ifndef _WIN32 /* * This case is not valid for Windows because the * image format is different from the pixel format in * Win32. Eventually we need to fix the image code in * Tk to use the Windows native image ordering. This * would speed up the image code for all of the common * sizes. */ case NBBY * sizeof(pixel): *destLongPtr++ = i; break; #endif default: XPutPixel(imagePtr, x - xStart, y - yStart, (unsigned) i); } } } else if (bitsPerPixel > 1) { /* * Multibit monochrome window. The operation here is similar * to the color window case above, except that there is only * one component. If the master image is in color, use the * luminance computed as * 0.344 * red + 0.5 * green + 0.156 * blue. */ for (x = xStart; x < xEnd; ++x) { c = (x > 0) ? errPtr[-1] * 7: 0; if (y > 0) { if (x > 0) { c += errPtr[-lineLength-1]; } c += errPtr[-lineLength] * 5; if (x + 1 < masterPtr->width) { c += errPtr[-lineLength+1] * 3; } } c = ((c + 2056) >> 4) - 128; if (masterPtr->flags & COLOR_IMAGE) { c += (unsigned) (srcPtr[0] * 11 + srcPtr[1] * 16 + srcPtr[2] * 5 + 16) >> 5; } else { c += srcPtr[0]; } srcPtr += 4; if (c < 0) { c = 0; } else if (c > 255) { c = 255; } i = colorPtr->colorQuant[0][c]; *errPtr++ = c - i; i = colorPtr->redValues[i]; switch (bitsPerPixel) { case NBBY: *destBytePtr++ = i; break; #ifndef _WIN32 /* * This case is not valid for Windows because the * image format is different from the pixel format in * Win32. Eventually we need to fix the image code in * Tk to use the Windows native image ordering. This * would speed up the image code for all of the common * sizes. */ case NBBY * sizeof(pixel): *destLongPtr++ = i; break; #endif default: XPutPixel(imagePtr, x - xStart, y - yStart, (unsigned) i); } } } else { /* * 1-bit monochrome window. This is similar to the multibit * monochrome case above, except that the quantization is * simpler (we only have black = 0 and white = 255), and we * produce an XY-Bitmap. */ word = 0; mask = firstBit; for (x = xStart; x < xEnd; ++x) { /* * If we have accumulated a whole word, store it in the * image and start a new word. */ if (mask == 0) { *destLongPtr++ = word; mask = firstBit; word = 0; } c = (x > 0) ? errPtr[-1] * 7: 0; if (y > 0) { if (x > 0) { c += errPtr[-lineLength-1]; } c += errPtr[-lineLength] * 5; if (x + 1 < masterPtr->width) { c += errPtr[-lineLength+1] * 3; } } c = ((c + 2056) >> 4) - 128; if (masterPtr->flags & COLOR_IMAGE) { c += (unsigned)(srcPtr[0] * 11 + srcPtr[1] * 16 + srcPtr[2] * 5 + 16) >> 5; } else { c += srcPtr[0]; } srcPtr += 4; if (c < 0) { c = 0; } else if (c > 255) { c = 255; } if (c >= 128) { word |= mask; *errPtr++ = c - 255; } else { *errPtr++ = c; } mask = bigEndian? (mask >> 1): (mask << 1); } *destLongPtr = word; } srcLinePtr += masterPtr->width * 4; errLinePtr += lineLength; dstLinePtr += bytesPerLine; } /* * Update the pixmap for this instance with the block of pixels that * we have just computed. */ TkPutImage(colorPtr->pixelMap, colorPtr->numColors, instancePtr->display, instancePtr->pixels, instancePtr->gc, imagePtr, 0, 0, xStart, yStart, (unsigned) width, (unsigned) nLines); yStart = yEnd; } ckfree(imagePtr->data); imagePtr->data = NULL; } /* *---------------------------------------------------------------------- * * TkImgResetDither -- * * This function is called to eliminate the content of a photo instance's * dither error buffer. It's called when the overall image is blanked. * * Results: * None. * * Side effects: * The instance's dither buffer gets cleared. * *---------------------------------------------------------------------- */ void TkImgResetDither( PhotoInstance *instancePtr) { if (instancePtr->error) { memset(instancePtr->error, 0, /*(size_t)*/ (instancePtr->masterPtr->width * instancePtr->masterPtr->height * 3 * sizeof(schar))); } } /* * Local Variables: * mode: c * c-basic-offset: 4 * fill-column: 78 * End: */