diff options
Diffstat (limited to 'nx-X11/extras/Xpm/lib/create.c')
-rw-r--r-- | nx-X11/extras/Xpm/lib/create.c | 2532 |
1 files changed, 2532 insertions, 0 deletions
diff --git a/nx-X11/extras/Xpm/lib/create.c b/nx-X11/extras/Xpm/lib/create.c new file mode 100644 index 000000000..8b1397853 --- /dev/null +++ b/nx-X11/extras/Xpm/lib/create.c @@ -0,0 +1,2532 @@ +/* $XdotOrg: xc/extras/Xpm/lib/create.c,v 1.6 2005/05/19 15:02:48 sandmann Exp $ */ +/* + * Copyright (C) 1989-95 GROUPE BULL + * + * Permission is hereby granted, free of charge, to any person obtaining a copy + * of this software and associated documentation files (the "Software"), to + * deal in the Software without restriction, including without limitation the + * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or + * sell copies of the Software, and to permit persons to whom the Software is + * furnished to do so, subject to the following conditions: + * + * The above copyright notice and this permission notice shall be included in + * all copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL + * GROUPE BULL BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN + * AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN + * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. + * + * Except as contained in this notice, the name of GROUPE BULL shall not be + * used in advertising or otherwise to promote the sale, use or other dealings + * in this Software without prior written authorization from GROUPE BULL. + */ + +/*****************************************************************************\ +* create.c: * +* * +* XPM library * +* Create an X image and possibly its related shape mask * +* from the given XpmImage. * +* * +* Developed by Arnaud Le Hors * +\*****************************************************************************/ +/* $XFree86: xc/extras/Xpm/lib/create.c,v 1.4 2003/05/27 22:26:20 tsi Exp $ */ + +/* + * The code related to FOR_MSW has been added by + * HeDu (hedu@cul-ipn.uni-kiel.de) 4/94 + */ + +/* + * The code related to AMIGA has been added by + * Lorens Younes (d93-hyo@nada.kth.se) 4/96 + */ + +/* October 2004, source code review by Thomas Biege <thomas@suse.de> */ + +#ifdef HAVE_CONFIG_H +#include <config.h> +#endif +#include "XpmI.h" +#include <ctype.h> + +LFUNC(xpmVisualType, int, (Visual *visual)); + +LFUNC(AllocColor, int, (Display *display, Colormap colormap, + char *colorname, XColor *xcolor, void *closure)); +LFUNC(FreeColors, int, (Display *display, Colormap colormap, + Pixel *pixels, int n, void *closure)); + +#ifndef FOR_MSW +LFUNC(SetCloseColor, int, (Display *display, Colormap colormap, + Visual *visual, XColor *col, + Pixel *image_pixel, Pixel *mask_pixel, + Pixel *alloc_pixels, unsigned int *nalloc_pixels, + XpmAttributes *attributes, XColor *cols, int ncols, + XpmAllocColorFunc allocColor, void *closure)); +#else +/* let the window system take care of close colors */ +#endif + +LFUNC(SetColor, int, (Display *display, Colormap colormap, Visual *visual, + char *colorname, unsigned int color_index, + Pixel *image_pixel, Pixel *mask_pixel, + unsigned int *mask_pixel_index, + Pixel *alloc_pixels, unsigned int *nalloc_pixels, + Pixel *used_pixels, unsigned int *nused_pixels, + XpmAttributes *attributes, XColor *cols, int ncols, + XpmAllocColorFunc allocColor, void *closure)); + +LFUNC(CreateXImage, int, (Display *display, Visual *visual, + unsigned int depth, int format, unsigned int width, + unsigned int height, XImage **image_return)); + +LFUNC(CreateColors, int, (Display *display, XpmAttributes *attributes, + XpmColor *colors, unsigned int ncolors, + Pixel *image_pixels, Pixel *mask_pixels, + unsigned int *mask_pixel_index, + Pixel *alloc_pixels, unsigned int *nalloc_pixels, + Pixel *used_pixels, unsigned int *nused_pixels)); + +#ifndef FOR_MSW +LFUNC(ParseAndPutPixels, int, (xpmData *data, unsigned int width, + unsigned int height, unsigned int ncolors, + unsigned int cpp, XpmColor *colorTable, + xpmHashTable *hashtable, + XImage *image, Pixel *image_pixels, + XImage *mask, Pixel *mask_pixels)); +#else /* FOR_MSW */ +LFUNC(ParseAndPutPixels, int, (Display *dc, xpmData *data, unsigned int width, + unsigned int height, unsigned int ncolors, + unsigned int cpp, XpmColor *colorTable, + xpmHashTable *hashtable, + XImage *image, Pixel *image_pixels, + XImage *mask, Pixel *mask_pixels)); +#endif + +#ifndef FOR_MSW +# ifndef AMIGA +/* XImage pixel routines */ +LFUNC(PutImagePixels, void, (XImage *image, unsigned int width, + unsigned int height, unsigned int *pixelindex, + Pixel *pixels)); + +LFUNC(PutImagePixels32, void, (XImage *image, unsigned int width, + unsigned int height, unsigned int *pixelindex, + Pixel *pixels)); + +LFUNC(PutImagePixels16, void, (XImage *image, unsigned int width, + unsigned int height, unsigned int *pixelindex, + Pixel *pixels)); + +LFUNC(PutImagePixels8, void, (XImage *image, unsigned int width, + unsigned int height, unsigned int *pixelindex, + Pixel *pixels)); + +LFUNC(PutImagePixels1, void, (XImage *image, unsigned int width, + unsigned int height, unsigned int *pixelindex, + Pixel *pixels)); + +LFUNC(PutPixel1, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel, int, (XImage *ximage, int x, int y, unsigned long pixel)); +#if !defined(WORD64) && !defined(LONG64) +LFUNC(PutPixel32, int, (XImage *ximage, int x, int y, unsigned long pixel)); +#endif +LFUNC(PutPixel32MSB, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel32LSB, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel16MSB, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel16LSB, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel8, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel1MSB, int, (XImage *ximage, int x, int y, unsigned long pixel)); +LFUNC(PutPixel1LSB, int, (XImage *ximage, int x, int y, unsigned long pixel)); + +# else /* AMIGA */ +LFUNC(APutImagePixels, void, (XImage *ximage, unsigned int width, + unsigned int height, unsigned int *pixelindex, + Pixel *pixels)); +# endif/* AMIGA */ +#else /* FOR_MSW */ +/* FOR_MSW pixel routine */ +LFUNC(MSWPutImagePixels, void, (Display *dc, XImage *image, + unsigned int width, unsigned int height, + unsigned int *pixelindex, Pixel *pixels)); +#endif /* FOR_MSW */ + +#ifdef NEED_STRCASECMP +FUNC(xpmstrcasecmp, int, (char *s1, char *s2)); + +/* + * in case strcasecmp is not provided by the system here is one + * which does the trick + */ +int +xpmstrcasecmp(s1, s2) + register char *s1, *s2; +{ + register int c1, c2; + + while (*s1 && *s2) { + c1 = tolower(*s1); + c2 = tolower(*s2); + if (c1 != c2) + return (c1 - c2); + s1++; + s2++; + } + return (int) (*s1 - *s2); +} + +#endif + +/* + * return the default color key related to the given visual + */ +static int +xpmVisualType(visual) + Visual *visual; +{ +#ifndef FOR_MSW +# ifndef AMIGA + switch (visual->class) { + case StaticGray: + case GrayScale: + switch (visual->map_entries) { + case 2: + return (XPM_MONO); + case 4: + return (XPM_GRAY4); + default: + return (XPM_GRAY); + } + default: + return (XPM_COLOR); + } +# else + /* set the key explicitly in the XpmAttributes to override this */ + return (XPM_COLOR); +# endif +#else + /* there should be a similar switch for MSW */ + return (XPM_COLOR); +#endif +} + + +typedef struct { + int cols_index; + long closeness; +} CloseColor; + +static int +closeness_cmp(Const void *a, Const void *b) +{ + CloseColor *x = (CloseColor *) a, *y = (CloseColor *) b; + + /* cast to int as qsort requires */ + return (int) (x->closeness - y->closeness); +} + + +/* default AllocColor function: + * call XParseColor if colorname is given, return negative value if failure + * call XAllocColor and return 0 if failure, positive otherwise + */ +static int +AllocColor(display, colormap, colorname, xcolor, closure) + Display *display; + Colormap colormap; + char *colorname; + XColor *xcolor; + void *closure; /* not used */ +{ + int status; + if (colorname) + if (!XParseColor(display, colormap, colorname, xcolor)) + return -1; + status = XAllocColor(display, colormap, xcolor); + return status != 0 ? 1 : 0; +} + + +#ifndef FOR_MSW +/* + * set a close color in case the exact one can't be set + * return 0 if success, 1 otherwise. + */ + +static int +SetCloseColor(display, colormap, visual, col, image_pixel, mask_pixel, + alloc_pixels, nalloc_pixels, attributes, cols, ncols, + allocColor, closure) + Display *display; + Colormap colormap; + Visual *visual; + XColor *col; + Pixel *image_pixel, *mask_pixel; + Pixel *alloc_pixels; + unsigned int *nalloc_pixels; + XpmAttributes *attributes; + XColor *cols; + int ncols; + XpmAllocColorFunc allocColor; + void *closure; +{ + + /* + * Allocation failed, so try close colors. To get here the visual must + * be GreyScale, PseudoColor or DirectColor (or perhaps StaticColor? + * What about sharing systems like QDSS?). Beware: we have to treat + * DirectColor differently. + */ + + + long int red_closeness, green_closeness, blue_closeness; + int n; + Bool alloc_color; + + if (attributes && (attributes->valuemask & XpmCloseness)) + red_closeness = green_closeness = blue_closeness = + attributes->closeness; + else { + red_closeness = attributes->red_closeness; + green_closeness = attributes->green_closeness; + blue_closeness = attributes->blue_closeness; + } + if (attributes && (attributes->valuemask & XpmAllocCloseColors)) + alloc_color = attributes->alloc_close_colors; + else + alloc_color = True; + + /* + * We sort the colormap by closeness and try to allocate the color + * closest to the target. If the allocation of this close color fails, + * which almost never happens, then one of two scenarios is possible. + * Either the colormap must have changed (since the last close color + * allocation or possibly while we were sorting the colormap), or the + * color is allocated as Read/Write by some other client. (Note: X + * _should_ allow clients to check if a particular color is Read/Write, + * but it doesn't! :-( ). We cannot determine which of these scenarios + * occurred, so we try the next closest color, and so on, until no more + * colors are within closeness of the target. If we knew that the + * colormap had changed, we could skip this sequence. + * + * If _none_ of the colors within closeness of the target can be allocated, + * then we can finally be pretty sure that the colormap has actually + * changed. In this case we try to allocate the original color (again), + * then try the closecolor stuff (again)... + * + * In theory it would be possible for an infinite loop to occur if another + * process kept changing the colormap every time we sorted it, so we set + * a maximum on the number of iterations. After this many tries, we use + * XGrabServer() to ensure that the colormap remains unchanged. + * + * This approach gives particularly bad worst case performance - as many as + * <MaximumIterations> colormap reads and sorts may be needed, and as + * many as <MaximumIterations> * <ColormapSize> attempted allocations + * may fail. On an 8-bit system, this means as many as 3 colormap reads, + * 3 sorts and 768 failed allocations per execution of this code! + * Luckily, my experiments show that in general use in a typical 8-bit + * color environment only about 1 in every 10000 allocations fails to + * succeed in the fastest possible time. So virtually every time what + * actually happens is a single sort followed by a successful allocate. + * The very first allocation also costs a colormap read, but no further + * reads are usually necessary. + */ + +#define ITERATIONS 2 /* more than one is almost never + * necessary */ + + for (n = 0; n <= ITERATIONS; ++n) { + CloseColor *closenesses = + (CloseColor *) XpmCalloc(ncols, sizeof(CloseColor)); + int i, c; + + for (i = 0; i < ncols; ++i) { /* build & sort closenesses table */ +#define COLOR_FACTOR 3 +#define BRIGHTNESS_FACTOR 1 + + closenesses[i].cols_index = i; + closenesses[i].closeness = + COLOR_FACTOR * (abs((long) col->red - (long) cols[i].red) + + abs((long) col->green - (long) cols[i].green) + + abs((long) col->blue - (long) cols[i].blue)) + + BRIGHTNESS_FACTOR * abs(((long) col->red + + (long) col->green + + (long) col->blue) + - ((long) cols[i].red + + (long) cols[i].green + + (long) cols[i].blue)); + } + qsort(closenesses, ncols, sizeof(CloseColor), closeness_cmp); + + i = 0; + c = closenesses[i].cols_index; + while ((long) cols[c].red >= (long) col->red - red_closeness && + (long) cols[c].red <= (long) col->red + red_closeness && + (long) cols[c].green >= (long) col->green - green_closeness && + (long) cols[c].green <= (long) col->green + green_closeness && + (long) cols[c].blue >= (long) col->blue - blue_closeness && + (long) cols[c].blue <= (long) col->blue + blue_closeness) { + if (alloc_color) { + if ((*allocColor)(display, colormap, NULL, &cols[c], closure)){ + if (n == ITERATIONS) + XUngrabServer(display); + XpmFree(closenesses); + *image_pixel = cols[c].pixel; + *mask_pixel = 1; + alloc_pixels[(*nalloc_pixels)++] = cols[c].pixel; + return (0); + } else { + ++i; + if (i == ncols) + break; + c = closenesses[i].cols_index; + } + } else { + if (n == ITERATIONS) + XUngrabServer(display); + XpmFree(closenesses); + *image_pixel = cols[c].pixel; + *mask_pixel = 1; + return (0); + } + } + + /* Couldn't allocate _any_ of the close colors! */ + + if (n == ITERATIONS) + XUngrabServer(display); + XpmFree(closenesses); + + if (i == 0 || i == ncols) /* no color close enough or cannot */ + return (1); /* alloc any color (full of r/w's) */ + + if ((*allocColor)(display, colormap, NULL, col, closure)) { + *image_pixel = col->pixel; + *mask_pixel = 1; + alloc_pixels[(*nalloc_pixels)++] = col->pixel; + return (0); + } else { /* colormap has probably changed, so + * re-read... */ + if (n == ITERATIONS - 1) + XGrabServer(display); + +#if 0 + if (visual->class == DirectColor) { + /* TODO */ + } else +#endif + XQueryColors(display, colormap, cols, ncols); + } + } + return (1); +} + +#define USE_CLOSECOLOR attributes && \ +(((attributes->valuemask & XpmCloseness) && attributes->closeness != 0) \ + || ((attributes->valuemask & XpmRGBCloseness) && \ + (attributes->red_closeness != 0 \ + || attributes->green_closeness != 0 \ + || attributes->blue_closeness != 0))) + +#else + /* FOR_MSW part */ + /* nothing to do here, the window system does it */ +#endif + +/* + * set the color pixel related to the given colorname, + * return 0 if success, 1 otherwise. + */ + +static int +SetColor(display, colormap, visual, colorname, color_index, + image_pixel, mask_pixel, mask_pixel_index, + alloc_pixels, nalloc_pixels, used_pixels, nused_pixels, + attributes, cols, ncols, allocColor, closure) + Display *display; + Colormap colormap; + Visual *visual; + char *colorname; + unsigned int color_index; + Pixel *image_pixel, *mask_pixel; + unsigned int *mask_pixel_index; + Pixel *alloc_pixels; + unsigned int *nalloc_pixels; + Pixel *used_pixels; + unsigned int *nused_pixels; + XpmAttributes *attributes; + XColor *cols; + int ncols; + XpmAllocColorFunc allocColor; + void *closure; +{ + XColor xcolor; + int status; + + if (xpmstrcasecmp(colorname, TRANSPARENT_COLOR)) { + status = (*allocColor)(display, colormap, colorname, &xcolor, closure); + if (status < 0) /* parse color failed */ + return (1); + + if (status == 0) { +#ifndef FOR_MSW + if (USE_CLOSECOLOR) + return (SetCloseColor(display, colormap, visual, &xcolor, + image_pixel, mask_pixel, + alloc_pixels, nalloc_pixels, + attributes, cols, ncols, + allocColor, closure)); + else +#endif /* ndef FOR_MSW */ + return (1); + } else + alloc_pixels[(*nalloc_pixels)++] = xcolor.pixel; + *image_pixel = xcolor.pixel; +#ifndef FOR_MSW + *mask_pixel = 1; +#else + *mask_pixel = RGB(0,0,0); +#endif + used_pixels[(*nused_pixels)++] = xcolor.pixel; + } else { + *image_pixel = 0; +#ifndef FOR_MSW + *mask_pixel = 0; +#else + *mask_pixel = RGB(255,255,255); +#endif + /* store the color table index */ + *mask_pixel_index = color_index; + } + return (0); +} + + +static int +CreateColors(display, attributes, colors, ncolors, image_pixels, mask_pixels, + mask_pixel_index, alloc_pixels, nalloc_pixels, + used_pixels, nused_pixels) + Display *display; + XpmAttributes *attributes; + XpmColor *colors; + unsigned int ncolors; + Pixel *image_pixels; + Pixel *mask_pixels; + unsigned int *mask_pixel_index; + Pixel *alloc_pixels; + unsigned int *nalloc_pixels; + Pixel *used_pixels; + unsigned int *nused_pixels; +{ + /* variables stored in the XpmAttributes structure */ + Visual *visual; + Colormap colormap; + XpmColorSymbol *colorsymbols = NULL; + unsigned int numsymbols; + XpmAllocColorFunc allocColor; + void *closure; + + char *colorname; + unsigned int color, key; + Bool pixel_defined; + XpmColorSymbol *symbol = NULL; + char **defaults; + int ErrorStatus = XpmSuccess; + char *s; + int default_index; + + XColor *cols = NULL; + unsigned int ncols = 0; + + /* + * retrieve information from the XpmAttributes + */ + if (attributes && attributes->valuemask & XpmColorSymbols) { + colorsymbols = attributes->colorsymbols; + numsymbols = attributes->numsymbols; + } else + numsymbols = 0; + + if (attributes && attributes->valuemask & XpmVisual) + visual = attributes->visual; + else + visual = XDefaultVisual(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmColormap)) + colormap = attributes->colormap; + else + colormap = XDefaultColormap(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmColorKey)) + key = attributes->color_key; + else + key = xpmVisualType(visual); + + if (attributes && (attributes->valuemask & XpmAllocColor)) + allocColor = attributes->alloc_color; + else + allocColor = AllocColor; + if (attributes && (attributes->valuemask & XpmColorClosure)) + closure = attributes->color_closure; + else + closure = NULL; + +#ifndef FOR_MSW + if (USE_CLOSECOLOR) { + /* originally from SetCloseColor */ +#if 0 + if (visual->class == DirectColor) { + + /* + * TODO: Implement close colors for DirectColor visuals. This is + * difficult situation. Chances are that we will never get here, + * because any machine that supports DirectColor will probably + * also support TrueColor (and probably PseudoColor). Also, + * DirectColor colormaps can be very large, so looking for close + * colors may be too slow. + */ + } else { +#endif + unsigned int i; + +#ifndef AMIGA + ncols = visual->map_entries; +#else + ncols = colormap->Count; +#endif + cols = (XColor *) XpmCalloc(ncols, sizeof(XColor)); + for (i = 0; i < ncols; ++i) + cols[i].pixel = i; + XQueryColors(display, colormap, cols, ncols); +#if 0 + } +#endif + } +#endif /* ndef FOR_MSW */ + + switch (key) { + case XPM_MONO: + default_index = 2; + break; + case XPM_GRAY4: + default_index = 3; + break; + case XPM_GRAY: + default_index = 4; + break; + case XPM_COLOR: + default: + default_index = 5; + break; + } + + for (color = 0; color < ncolors; color++, colors++, + image_pixels++, mask_pixels++) { + colorname = NULL; + pixel_defined = False; + defaults = (char **) colors; + + /* + * look for a defined symbol + */ + if (numsymbols) { + + unsigned int n; + + s = defaults[1]; + for (n = 0, symbol = colorsymbols; n < numsymbols; n++, symbol++) { + if (symbol->name && s && !strcmp(symbol->name, s)) + /* override name */ + break; + if (!symbol->name && symbol->value) { /* override value */ + int def_index = default_index; + + while (defaults[def_index] == NULL) /* find defined + * colorname */ + --def_index; + if (def_index < 2) {/* nothing towards mono, so try + * towards color */ + def_index = default_index + 1; + while (def_index <= 5 && defaults[def_index] == NULL) + ++def_index; + } + if (def_index >= 2 && defaults[def_index] != NULL && + !xpmstrcasecmp(symbol->value, defaults[def_index])) + break; + } + } + if (n != numsymbols) { + if (symbol->name && symbol->value) + colorname = symbol->value; + else + pixel_defined = True; + } + } + if (!pixel_defined) { /* pixel not given as symbol value */ + + unsigned int k; + + if (colorname) { /* colorname given as symbol value */ + if (!SetColor(display, colormap, visual, colorname, color, + image_pixels, mask_pixels, mask_pixel_index, + alloc_pixels, nalloc_pixels, used_pixels, + nused_pixels, attributes, cols, ncols, + allocColor, closure)) + pixel_defined = True; + else + ErrorStatus = XpmColorError; + } + k = key; + while (!pixel_defined && k > 1) { + if (defaults[k]) { + if (!SetColor(display, colormap, visual, defaults[k], + color, image_pixels, mask_pixels, + mask_pixel_index, alloc_pixels, + nalloc_pixels, used_pixels, nused_pixels, + attributes, cols, ncols, + allocColor, closure)) { + pixel_defined = True; + break; + } else + ErrorStatus = XpmColorError; + } + k--; + } + k = key + 1; + while (!pixel_defined && k < NKEYS + 1) { + if (defaults[k]) { + if (!SetColor(display, colormap, visual, defaults[k], + color, image_pixels, mask_pixels, + mask_pixel_index, alloc_pixels, + nalloc_pixels, used_pixels, nused_pixels, + attributes, cols, ncols, + allocColor, closure)) { + pixel_defined = True; + break; + } else + ErrorStatus = XpmColorError; + } + k++; + } + if (!pixel_defined) { + if (cols) + XpmFree(cols); + return (XpmColorFailed); + } + } else { + /* simply use the given pixel */ + *image_pixels = symbol->pixel; + /* the following makes the mask to be built even if none + is given a particular pixel */ + if (symbol->value + && !xpmstrcasecmp(symbol->value, TRANSPARENT_COLOR)) { + *mask_pixels = 0; + *mask_pixel_index = color; + } else + *mask_pixels = 1; + used_pixels[(*nused_pixels)++] = *image_pixels; + } + } + if (cols) + XpmFree(cols); + return (ErrorStatus); +} + + +/* default FreeColors function, simply call XFreeColors */ +static int +FreeColors(display, colormap, pixels, n, closure) + Display *display; + Colormap colormap; + Pixel *pixels; + int n; + void *closure; /* not used */ +{ + return XFreeColors(display, colormap, pixels, n, 0); +} + + +/* function call in case of error */ + +#undef RETURN +#define RETURN(status) \ +do \ +{ \ + ErrorStatus = status; \ + goto error; \ +} while(0) + +int +XpmCreateImageFromXpmImage(display, image, + image_return, shapeimage_return, attributes) + Display *display; + XpmImage *image; + XImage **image_return; + XImage **shapeimage_return; + XpmAttributes *attributes; +{ + /* variables stored in the XpmAttributes structure */ + Visual *visual; + Colormap colormap; + unsigned int depth; + int bitmap_format; + XpmFreeColorsFunc freeColors; + + /* variables to return */ + XImage *ximage = NULL; + XImage *shapeimage = NULL; + unsigned int mask_pixel_index = XpmUndefPixel; + int ErrorStatus; + + /* calculation variables */ + Pixel *image_pixels = NULL; + Pixel *mask_pixels = NULL; + Pixel *alloc_pixels = NULL; + Pixel *used_pixels = NULL; + unsigned int nalloc_pixels = 0; + unsigned int nused_pixels = 0; + + /* initialize return values */ + if (image_return) + *image_return = NULL; + if (shapeimage_return) + *shapeimage_return = NULL; + + /* retrieve information from the XpmAttributes */ + if (attributes && (attributes->valuemask & XpmVisual)) + visual = attributes->visual; + else + visual = XDefaultVisual(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmColormap)) + colormap = attributes->colormap; + else + colormap = XDefaultColormap(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmDepth)) + depth = attributes->depth; + else + depth = XDefaultDepth(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmBitmapFormat)) + bitmap_format = attributes->bitmap_format; + else + bitmap_format = ZPixmap; + + if (attributes && (attributes->valuemask & XpmFreeColors)) + freeColors = attributes->free_colors; + else + freeColors = FreeColors; + + ErrorStatus = XpmSuccess; + + if (image->ncolors >= UINT_MAX / sizeof(Pixel)) + return (XpmNoMemory); + + /* malloc pixels index tables */ + image_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * image->ncolors); + if (!image_pixels) + return (XpmNoMemory); + + mask_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * image->ncolors); + if (!mask_pixels) + RETURN(XpmNoMemory); + + /* maximum of allocated pixels will be the number of colors */ + alloc_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * image->ncolors); + if (!alloc_pixels) + RETURN(XpmNoMemory); + + /* maximum of allocated pixels will be the number of colors */ + used_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * image->ncolors); + if (!used_pixels) + RETURN(XpmNoMemory); + + /* get pixel colors, store them in index tables */ + ErrorStatus = CreateColors(display, attributes, image->colorTable, + image->ncolors, image_pixels, mask_pixels, + &mask_pixel_index, alloc_pixels, &nalloc_pixels, + used_pixels, &nused_pixels); + + if (ErrorStatus != XpmSuccess + && (ErrorStatus < 0 || (attributes + && (attributes->valuemask & XpmExactColors) + && attributes->exactColors))) + RETURN(ErrorStatus); + + /* create the ximage */ + if (image_return) { + ErrorStatus = CreateXImage(display, visual, depth, + (depth == 1 ? bitmap_format : ZPixmap), + image->width, image->height, &ximage); + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + +#ifndef FOR_MSW +# ifndef AMIGA + + /* + * set the ximage data using optimized functions for ZPixmap + */ + + if (ximage->bits_per_pixel == 8) + PutImagePixels8(ximage, image->width, image->height, + image->data, image_pixels); + else if (((ximage->bits_per_pixel | ximage->depth) == 1) && + (ximage->byte_order == ximage->bitmap_bit_order)) + PutImagePixels1(ximage, image->width, image->height, + image->data, image_pixels); + else if (ximage->bits_per_pixel == 16) + PutImagePixels16(ximage, image->width, image->height, + image->data, image_pixels); + else if (ximage->bits_per_pixel == 32) + PutImagePixels32(ximage, image->width, image->height, + image->data, image_pixels); + else + PutImagePixels(ximage, image->width, image->height, + image->data, image_pixels); +# else /* AMIGA */ + APutImagePixels(ximage, image->width, image->height, + image->data, image_pixels); +# endif +#else /* FOR_MSW */ + MSWPutImagePixels(display, ximage, image->width, image->height, + image->data, image_pixels); +#endif + } + /* create the shape mask image */ + if (mask_pixel_index != XpmUndefPixel && shapeimage_return) { + ErrorStatus = CreateXImage(display, visual, 1, bitmap_format, + image->width, image->height, &shapeimage); + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + +#ifndef FOR_MSW +# ifndef AMIGA + PutImagePixels1(shapeimage, image->width, image->height, + image->data, mask_pixels); +# else /* AMIGA */ + APutImagePixels(shapeimage, image->width, image->height, + image->data, mask_pixels); +# endif +#else /* FOR_MSW */ + MSWPutImagePixels(display, shapeimage, image->width, image->height, + image->data, mask_pixels); +#endif + + } + XpmFree(image_pixels); + XpmFree(mask_pixels); + + /* if requested return used pixels in the XpmAttributes structure */ + if (attributes && (attributes->valuemask & XpmReturnPixels || +/* 3.2 backward compatibility code */ + attributes->valuemask & XpmReturnInfos)) { +/* end 3.2 bc */ + attributes->pixels = used_pixels; + attributes->npixels = nused_pixels; + attributes->mask_pixel = mask_pixel_index; + } else + XpmFree(used_pixels); + + /* if requested return alloc'ed pixels in the XpmAttributes structure */ + if (attributes && (attributes->valuemask & XpmReturnAllocPixels)) { + attributes->alloc_pixels = alloc_pixels; + attributes->nalloc_pixels = nalloc_pixels; + } else + XpmFree(alloc_pixels); + + /* return created images */ + if (image_return) + *image_return = ximage; + if (shapeimage_return) + *shapeimage_return = shapeimage; + + return (ErrorStatus); + +/* exit point in case of error, free only locally allocated variables */ +error: + if (ximage) + XDestroyImage(ximage); + if (shapeimage) + XDestroyImage(shapeimage); + if (image_pixels) + XpmFree(image_pixels); + if (mask_pixels) + XpmFree(mask_pixels); + if (nalloc_pixels) + (*freeColors)(display, colormap, alloc_pixels, nalloc_pixels, NULL); + if (alloc_pixels) + XpmFree(alloc_pixels); + if (used_pixels) + XpmFree(used_pixels); + + return (ErrorStatus); +} + + +/* + * Create an XImage with its data + */ +static int +CreateXImage(display, visual, depth, format, width, height, image_return) + Display *display; + Visual *visual; + unsigned int depth; + int format; + unsigned int width; + unsigned int height; + XImage **image_return; +{ + int bitmap_pad; + + /* first get bitmap_pad */ + if (depth > 16) + bitmap_pad = 32; + else if (depth > 8) + bitmap_pad = 16; + else + bitmap_pad = 8; + + /* then create the XImage with data = NULL and bytes_per_line = 0 */ + *image_return = XCreateImage(display, visual, depth, format, 0, 0, + width, height, bitmap_pad, 0); + if (!*image_return) + return (XpmNoMemory); + +#if !defined(FOR_MSW) && !defined(AMIGA) + if (height != 0 && (*image_return)->bytes_per_line >= INT_MAX / height) { + XDestroyImage(*image_return); + return XpmNoMemory; + } + /* now that bytes_per_line must have been set properly alloc data */ + if((*image_return)->bytes_per_line == 0 || height == 0) + return XpmNoMemory; + (*image_return)->data = + (char *) XpmMalloc((*image_return)->bytes_per_line * height); + + if (!(*image_return)->data) { + XDestroyImage(*image_return); + *image_return = NULL; + return (XpmNoMemory); + } +#else + /* under FOR_MSW and AMIGA XCreateImage has done it all */ +#endif + return (XpmSuccess); +} + +#ifndef FOR_MSW +# ifndef AMIGA +/* + * The functions below are written from X11R5 MIT's code (XImUtil.c) + * + * The idea is to have faster functions than the standard XPutPixel function + * to build the image data. Indeed we can speed up things by suppressing tests + * performed for each pixel. We do the same tests but at the image level. + * We also assume that we use only ZPixmap images with null offsets. + */ + +LFUNC(_putbits, void, (register char *src, int dstoffset, + register int numbits, register char *dst)); + +LFUNC(_XReverse_Bytes, int, (register unsigned char *bpt, register unsigned int nb)); + +static unsigned char Const _reverse_byte[0x100] = { + 0x00, 0x80, 0x40, 0xc0, 0x20, 0xa0, 0x60, 0xe0, + 0x10, 0x90, 0x50, 0xd0, 0x30, 0xb0, 0x70, 0xf0, + 0x08, 0x88, 0x48, 0xc8, 0x28, 0xa8, 0x68, 0xe8, + 0x18, 0x98, 0x58, 0xd8, 0x38, 0xb8, 0x78, 0xf8, + 0x04, 0x84, 0x44, 0xc4, 0x24, 0xa4, 0x64, 0xe4, + 0x14, 0x94, 0x54, 0xd4, 0x34, 0xb4, 0x74, 0xf4, + 0x0c, 0x8c, 0x4c, 0xcc, 0x2c, 0xac, 0x6c, 0xec, + 0x1c, 0x9c, 0x5c, 0xdc, 0x3c, 0xbc, 0x7c, 0xfc, + 0x02, 0x82, 0x42, 0xc2, 0x22, 0xa2, 0x62, 0xe2, + 0x12, 0x92, 0x52, 0xd2, 0x32, 0xb2, 0x72, 0xf2, + 0x0a, 0x8a, 0x4a, 0xca, 0x2a, 0xaa, 0x6a, 0xea, + 0x1a, 0x9a, 0x5a, 0xda, 0x3a, 0xba, 0x7a, 0xfa, + 0x06, 0x86, 0x46, 0xc6, 0x26, 0xa6, 0x66, 0xe6, + 0x16, 0x96, 0x56, 0xd6, 0x36, 0xb6, 0x76, 0xf6, + 0x0e, 0x8e, 0x4e, 0xce, 0x2e, 0xae, 0x6e, 0xee, + 0x1e, 0x9e, 0x5e, 0xde, 0x3e, 0xbe, 0x7e, 0xfe, + 0x01, 0x81, 0x41, 0xc1, 0x21, 0xa1, 0x61, 0xe1, + 0x11, 0x91, 0x51, 0xd1, 0x31, 0xb1, 0x71, 0xf1, + 0x09, 0x89, 0x49, 0xc9, 0x29, 0xa9, 0x69, 0xe9, + 0x19, 0x99, 0x59, 0xd9, 0x39, 0xb9, 0x79, 0xf9, + 0x05, 0x85, 0x45, 0xc5, 0x25, 0xa5, 0x65, 0xe5, + 0x15, 0x95, 0x55, 0xd5, 0x35, 0xb5, 0x75, 0xf5, + 0x0d, 0x8d, 0x4d, 0xcd, 0x2d, 0xad, 0x6d, 0xed, + 0x1d, 0x9d, 0x5d, 0xdd, 0x3d, 0xbd, 0x7d, 0xfd, + 0x03, 0x83, 0x43, 0xc3, 0x23, 0xa3, 0x63, 0xe3, + 0x13, 0x93, 0x53, 0xd3, 0x33, 0xb3, 0x73, 0xf3, + 0x0b, 0x8b, 0x4b, 0xcb, 0x2b, 0xab, 0x6b, 0xeb, + 0x1b, 0x9b, 0x5b, 0xdb, 0x3b, 0xbb, 0x7b, 0xfb, + 0x07, 0x87, 0x47, 0xc7, 0x27, 0xa7, 0x67, 0xe7, + 0x17, 0x97, 0x57, 0xd7, 0x37, 0xb7, 0x77, 0xf7, + 0x0f, 0x8f, 0x4f, 0xcf, 0x2f, 0xaf, 0x6f, 0xef, + 0x1f, 0x9f, 0x5f, 0xdf, 0x3f, 0xbf, 0x7f, 0xff +}; + +static int +_XReverse_Bytes(bpt, nb) + register unsigned char *bpt; + register unsigned int nb; +{ + do { + *bpt = _reverse_byte[*bpt]; + bpt++; + } while (--nb > 0); /* is nb user-controled? */ + return 0; +} + + +void +xpm_xynormalizeimagebits(bp, img) + register unsigned char *bp; + register XImage *img; +{ + register unsigned char c; + + if (img->byte_order != img->bitmap_bit_order) { + switch (img->bitmap_unit) { + + case 16: + c = *bp; + *bp = *(bp + 1); + *(bp + 1) = c; + break; + + case 32: + c = *(bp + 3); + *(bp + 3) = *bp; + *bp = c; + c = *(bp + 2); + *(bp + 2) = *(bp + 1); + *(bp + 1) = c; + break; + } + } + if (img->bitmap_bit_order == MSBFirst) + _XReverse_Bytes(bp, img->bitmap_unit >> 3); +} + +void +xpm_znormalizeimagebits(bp, img) + register unsigned char *bp; + register XImage *img; +{ + register unsigned char c; + + switch (img->bits_per_pixel) { + + case 2: + _XReverse_Bytes(bp, 1); + break; + + case 4: + *bp = ((*bp >> 4) & 0xF) | ((*bp << 4) & ~0xF); + break; + + case 16: + c = *bp; + *bp = *(bp + 1); + *(bp + 1) = c; + break; + + case 24: + c = *(bp + 2); + *(bp + 2) = *bp; + *bp = c; + break; + + case 32: + c = *(bp + 3); + *(bp + 3) = *bp; + *bp = c; + c = *(bp + 2); + *(bp + 2) = *(bp + 1); + *(bp + 1) = c; + break; + } +} + +static unsigned char Const _lomask[0x09] = { +0x00, 0x01, 0x03, 0x07, 0x0f, 0x1f, 0x3f, 0x7f, 0xff}; +static unsigned char Const _himask[0x09] = { +0xff, 0xfe, 0xfc, 0xf8, 0xf0, 0xe0, 0xc0, 0x80, 0x00}; + +static void +_putbits(src, dstoffset, numbits, dst) + register char *src; /* address of source bit string */ + int dstoffset; /* bit offset into destination; + * range is 0-31 */ + register int numbits; /* number of bits to copy to + * destination */ + register char *dst; /* address of destination bit string */ +{ + register unsigned char chlo, chhi; + int hibits; + + dst = dst + (dstoffset >> 3); + dstoffset = dstoffset & 7; + hibits = 8 - dstoffset; + chlo = *dst & _lomask[dstoffset]; + for (;;) { + chhi = (*src << dstoffset) & _himask[dstoffset]; + if (numbits <= hibits) { + chhi = chhi & _lomask[dstoffset + numbits]; + *dst = (*dst & _himask[dstoffset + numbits]) | chlo | chhi; + break; + } + *dst = chhi | chlo; + dst++; + numbits = numbits - hibits; + chlo = (unsigned char) (*src & _himask[hibits]) >> hibits; + src++; + if (numbits <= dstoffset) { + chlo = chlo & _lomask[numbits]; + *dst = (*dst & _himask[numbits]) | chlo; + break; + } + numbits = numbits - dstoffset; + } +} + +/* + * Default method to write pixels into a Z image data structure. + * The algorithm used is: + * + * copy the destination bitmap_unit or Zpixel to temp + * normalize temp if needed + * copy the pixel bits into the temp + * renormalize temp if needed + * copy the temp back into the destination image data + */ + +static void +PutImagePixels(image, width, height, pixelindex, pixels) + XImage *image; + unsigned int width; + unsigned int height; + unsigned int *pixelindex; + Pixel *pixels; +{ + register char *src; + register char *dst; + register unsigned int *iptr; + register unsigned int x, y; + register char *data; + Pixel pixel, px; + int nbytes, depth, ibu, ibpp, i; + + data = image->data; + iptr = pixelindex; + depth = image->depth; + if (depth == 1) { + ibu = image->bitmap_unit; + for (y = 0; y < height; y++) /* how can we trust height */ + for (x = 0; x < width; x++, iptr++) { /* how can we trust width */ + pixel = pixels[*iptr]; + for (i = 0, px = pixel; i < sizeof(unsigned long); + i++, px >>= 8) + ((unsigned char *) &pixel)[i] = px; + src = &data[XYINDEX(x, y, image)]; + dst = (char *) &px; + px = 0; + nbytes = ibu >> 3; + for (i = nbytes; --i >= 0;) + *dst++ = *src++; + XYNORMALIZE(&px, image); + _putbits((char *) &pixel, (x % ibu), 1, (char *) &px); + XYNORMALIZE(&px, image); + src = (char *) &px; + dst = &data[XYINDEX(x, y, image)]; + for (i = nbytes; --i >= 0;) + *dst++ = *src++; + } + } else { + ibpp = image->bits_per_pixel; + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + pixel = pixels[*iptr]; + if (depth == 4) + pixel &= 0xf; + for (i = 0, px = pixel; i < sizeof(unsigned long); i++, + px >>= 8) + ((unsigned char *) &pixel)[i] = px; + src = &data[ZINDEX(x, y, image)]; + dst = (char *) &px; + px = 0; + nbytes = (ibpp + 7) >> 3; + for (i = nbytes; --i >= 0;) + *dst++ = *src++; + ZNORMALIZE(&px, image); + _putbits((char *) &pixel, (x * ibpp) & 7, ibpp, (char *) &px); + ZNORMALIZE(&px, image); + src = (char *) &px; + dst = &data[ZINDEX(x, y, image)]; + for (i = nbytes; --i >= 0;) + *dst++ = *src++; + } + } +} + +/* + * write pixels into a 32-bits Z image data structure + */ + +#if !defined(WORD64) && !defined(LONG64) +/* this item is static but deterministic so let it slide; doesn't + * hurt re-entrancy of this library. Note if it is actually const then would + * be OK under rules of ANSI-C but probably not C++ which may not + * want to allocate space for it. + */ +static unsigned long byteorderpixel = MSBFirst << 24; + +#endif + +/* + WITHOUT_SPEEDUPS is a flag to be turned on if you wish to use the original + 3.2e code - by default you get the speeded-up version. +*/ + +static void +PutImagePixels32(image, width, height, pixelindex, pixels) + XImage *image; + unsigned int width; + unsigned int height; + unsigned int *pixelindex; + Pixel *pixels; +{ + unsigned char *data; + unsigned int *iptr; + unsigned int y; + Pixel pixel; + +#ifdef WITHOUT_SPEEDUPS + + unsigned int x; + unsigned char *addr; + + data = (unsigned char *) image->data; + iptr = pixelindex; +#if !defined(WORD64) && !defined(LONG64) + if (*((char *) &byteorderpixel) == image->byte_order) { + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + addr = &data[ZINDEX32(x, y, image)]; + *((unsigned long *) addr) = pixels[*iptr]; + } + } else +#endif + if (image->byte_order == MSBFirst) + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + addr = &data[ZINDEX32(x, y, image)]; + pixel = pixels[*iptr]; + addr[0] = pixel >> 24; + addr[1] = pixel >> 16; + addr[2] = pixel >> 8; + addr[3] = pixel; + } + else + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + addr = &data[ZINDEX32(x, y, image)]; + pixel = pixels[*iptr]; + addr[0] = pixel; + addr[1] = pixel >> 8; + addr[2] = pixel >> 16; + addr[3] = pixel >> 24; + } + +#else /* WITHOUT_SPEEDUPS */ + + unsigned int bpl = image->bytes_per_line; + unsigned char *data_ptr, *max_data; + + data = (unsigned char *) image->data; + iptr = pixelindex; +#if !defined(WORD64) && !defined(LONG64) + if (*((char *) &byteorderpixel) == image->byte_order) { + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + (width << 2); + + while (data_ptr < max_data) { + *((unsigned long *) data_ptr) = pixels[*(iptr++)]; + data_ptr += (1 << 2); + } + data += bpl; + } + } else +#endif + if (image->byte_order == MSBFirst) + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + (width << 2); + + while (data_ptr < max_data) { + pixel = pixels[*(iptr++)]; + + *data_ptr++ = pixel >> 24; + *data_ptr++ = pixel >> 16; + *data_ptr++ = pixel >> 8; + *data_ptr++ = pixel; + + } + data += bpl; + } + else + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + (width << 2); + + while (data_ptr < max_data) { + pixel = pixels[*(iptr++)]; + + *data_ptr++ = pixel; + *data_ptr++ = pixel >> 8; + *data_ptr++ = pixel >> 16; + *data_ptr++ = pixel >> 24; + } + data += bpl; + } + +#endif /* WITHOUT_SPEEDUPS */ +} + +/* + * write pixels into a 16-bits Z image data structure + */ + +static void +PutImagePixels16(image, width, height, pixelindex, pixels) + XImage *image; + unsigned int width; + unsigned int height; + unsigned int *pixelindex; + Pixel *pixels; +{ + unsigned char *data; + unsigned int *iptr; + unsigned int y; + +#ifdef WITHOUT_SPEEDUPS + + unsigned int x; + unsigned char *addr; + + data = (unsigned char *) image->data; + iptr = pixelindex; + if (image->byte_order == MSBFirst) + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + addr = &data[ZINDEX16(x, y, image)]; + addr[0] = pixels[*iptr] >> 8; + addr[1] = pixels[*iptr]; + } + else + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + addr = &data[ZINDEX16(x, y, image)]; + addr[0] = pixels[*iptr]; + addr[1] = pixels[*iptr] >> 8; + } + +#else /* WITHOUT_SPEEDUPS */ + + Pixel pixel; + + unsigned int bpl = image->bytes_per_line; + unsigned char *data_ptr, *max_data; + + data = (unsigned char *) image->data; + iptr = pixelindex; + if (image->byte_order == MSBFirst) + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + (width << 1); + + while (data_ptr < max_data) { + pixel = pixels[*(iptr++)]; + + data_ptr[0] = pixel >> 8; + data_ptr[1] = pixel; + + data_ptr += (1 << 1); + } + data += bpl; + } + else + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + (width << 1); + + while (data_ptr < max_data) { + pixel = pixels[*(iptr++)]; + + data_ptr[0] = pixel; + data_ptr[1] = pixel >> 8; + + data_ptr += (1 << 1); + } + data += bpl; + } + +#endif /* WITHOUT_SPEEDUPS */ +} + +/* + * write pixels into a 8-bits Z image data structure + */ + +static void +PutImagePixels8(image, width, height, pixelindex, pixels) + XImage *image; + unsigned int width; + unsigned int height; + unsigned int *pixelindex; + Pixel *pixels; +{ + char *data; + unsigned int *iptr; + unsigned int y; + +#ifdef WITHOUT_SPEEDUPS + + unsigned int x; + + data = image->data; + iptr = pixelindex; + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) + data[ZINDEX8(x, y, image)] = pixels[*iptr]; + +#else /* WITHOUT_SPEEDUPS */ + + unsigned int bpl = image->bytes_per_line; + char *data_ptr, *max_data; + + data = image->data; + iptr = pixelindex; + + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + width; + + while (data_ptr < max_data) + *(data_ptr++) = pixels[*(iptr++)]; + + data += bpl; + } + +#endif /* WITHOUT_SPEEDUPS */ +} + +/* + * write pixels into a 1-bit depth image data structure and **offset null** + */ + +static void +PutImagePixels1(image, width, height, pixelindex, pixels) + XImage *image; + unsigned int width; + unsigned int height; + unsigned int *pixelindex; + Pixel *pixels; +{ + if (image->byte_order != image->bitmap_bit_order) + PutImagePixels(image, width, height, pixelindex, pixels); + else { + unsigned int *iptr; + unsigned int y; + char *data; + +#ifdef WITHOUT_SPEEDUPS + + unsigned int x; + + data = image->data; + iptr = pixelindex; + if (image->bitmap_bit_order == MSBFirst) + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + if (pixels[*iptr] & 1) + data[ZINDEX1(x, y, image)] |= 0x80 >> (x & 7); + else + data[ZINDEX1(x, y, image)] &= ~(0x80 >> (x & 7)); + } + else + for (y = 0; y < height; y++) + for (x = 0; x < width; x++, iptr++) { + if (pixels[*iptr] & 1) + data[ZINDEX1(x, y, image)] |= 1 << (x & 7); + else + data[ZINDEX1(x, y, image)] &= ~(1 << (x & 7)); + } + +#else /* WITHOUT_SPEEDUPS */ + + char value; + char *data_ptr, *max_data; + int bpl = image->bytes_per_line; + int diff, count; + + data = image->data; + iptr = pixelindex; + + diff = width & 7; + width >>= 3; + + if (image->bitmap_bit_order == MSBFirst) + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + width; + while (data_ptr < max_data) { + value = 0; + + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + value = (value << 1) | (pixels[*(iptr++)] & 1); + + *(data_ptr++) = value; + } + if (diff) { + value = 0; + for (count = 0; count < diff; count++) { + if (pixels[*(iptr++)] & 1) + value |= (0x80 >> count); + } + *(data_ptr) = value; + } + data += bpl; + } + else + for (y = 0; y < height; y++) { + data_ptr = data; + max_data = data_ptr + width; + while (data_ptr < max_data) { + value = 0; + iptr += 8; + + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + value = (value << 1) | (pixels[*(--iptr)] & 1); + + iptr += 8; + *(data_ptr++) = value; + } + if (diff) { + value = 0; + for (count = 0; count < diff; count++) { + if (pixels[*(iptr++)] & 1) + value |= (1 << count); + } + *(data_ptr) = value; + } + data += bpl; + } + +#endif /* WITHOUT_SPEEDUPS */ + } +} + +int +XpmCreatePixmapFromXpmImage(display, d, image, + pixmap_return, shapemask_return, attributes) + Display *display; + Drawable d; + XpmImage *image; + Pixmap *pixmap_return; + Pixmap *shapemask_return; + XpmAttributes *attributes; +{ + XImage *ximage, *shapeimage; + int ErrorStatus; + + /* initialize return values */ + if (pixmap_return) + *pixmap_return = 0; + if (shapemask_return) + *shapemask_return = 0; + + /* create the ximages */ + ErrorStatus = XpmCreateImageFromXpmImage(display, image, + (pixmap_return ? &ximage : NULL), + (shapemask_return ? + &shapeimage : NULL), + attributes); + if (ErrorStatus < 0) + return (ErrorStatus); + + /* create the pixmaps and destroy images */ + if (pixmap_return && ximage) { + xpmCreatePixmapFromImage(display, d, ximage, pixmap_return); + XDestroyImage(ximage); + } + if (shapemask_return && shapeimage) { + xpmCreatePixmapFromImage(display, d, shapeimage, shapemask_return); + XDestroyImage(shapeimage); + } + return (ErrorStatus); +} + +# else /* AMIGA */ + +static void +APutImagePixels ( + XImage *image, + unsigned int width, + unsigned int height, + unsigned int *pixelindex, + Pixel *pixels) +{ + unsigned int *data = pixelindex; + unsigned int x, y; + unsigned char *array; + XImage *tmp_img; + BOOL success = FALSE; + + array = XpmMalloc ((((width+15)>>4)<<4)*sizeof (*array)); + if (array != NULL) + { + tmp_img = AllocXImage ((((width+15)>>4)<<4), 1, + image->rp->BitMap->Depth); + if (tmp_img != NULL) + { + for (y = 0; y < height; ++y) + { + for (x = 0; x < width; ++x) + array[x] = pixels[*(data++)]; + WritePixelLine8 (image->rp, 0, y, width, array, tmp_img->rp); + } + FreeXImage (tmp_img); + success = TRUE; + } + XpmFree (array); + } + + if (!success) + { + for (y = 0; y < height; ++y) + for (x = 0; x < width; ++x) + XPutPixel (image, x, y, pixels[*(data++)]); + } +} + +# endif/* AMIGA */ +#else /* FOR_MSW part follows */ +static void +MSWPutImagePixels(dc, image, width, height, pixelindex, pixels) + Display *dc; + XImage *image; + unsigned int width; + unsigned int height; + unsigned int *pixelindex; + Pixel *pixels; +{ + unsigned int *data = pixelindex; + unsigned int x, y; + HBITMAP obm; + + obm = SelectObject(*dc, image->bitmap); + for (y = 0; y < height; y++) { + for (x = 0; x < width; x++) { + SetPixel(*dc, x, y, pixels[*(data++)]); /* data is [x+y*width] */ + } + } + SelectObject(*dc, obm); +} + +#endif /* FOR_MSW */ + + + +#if !defined(FOR_MSW) && !defined(AMIGA) + +static int +PutPixel1(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + register char *src; + register char *dst; + register int i; + Pixel px; + int nbytes; + + if(x < 0 || y < 0) + return 0; + + for (i=0, px=pixel; i<sizeof(unsigned long); i++, px>>=8) + ((unsigned char *)&pixel)[i] = px; + src = &ximage->data[XYINDEX(x, y, ximage)]; + dst = (char *)&px; + px = 0; + nbytes = ximage->bitmap_unit >> 3; + for (i = nbytes; --i >= 0; ) *dst++ = *src++; + XYNORMALIZE(&px, ximage); + i = ((x + ximage->xoffset) % ximage->bitmap_unit); + _putbits ((char *)&pixel, i, 1, (char *)&px); + XYNORMALIZE(&px, ximage); + src = (char *) &px; + dst = &ximage->data[XYINDEX(x, y, ximage)]; + for (i = nbytes; --i >= 0; ) + *dst++ = *src++; + + return 1; +} + +static int +PutPixel(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + register char *src; + register char *dst; + register int i; + Pixel px; + unsigned int nbytes, ibpp; + + if(x < 0 || y < 0) + return 0; + + ibpp = ximage->bits_per_pixel; + if (ximage->depth == 4) + pixel &= 0xf; + for (i = 0, px = pixel; i < sizeof(unsigned long); i++, px >>= 8) + ((unsigned char *) &pixel)[i] = px; + src = &ximage->data[ZINDEX(x, y, ximage)]; + dst = (char *) &px; + px = 0; + nbytes = (ibpp + 7) >> 3; + for (i = nbytes; --i >= 0;) + *dst++ = *src++; + ZNORMALIZE(&px, ximage); + _putbits((char *) &pixel, (x * ibpp) & 7, ibpp, (char *) &px); + ZNORMALIZE(&px, ximage); + src = (char *) &px; + dst = &ximage->data[ZINDEX(x, y, ximage)]; + for (i = nbytes; --i >= 0;) + *dst++ = *src++; + + return 1; +} + +#if !defined(WORD64) && !defined(LONG64) +static int +PutPixel32(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + unsigned char *addr; + + if(x < 0 || y < 0) + return 0; + + addr = &((unsigned char *)ximage->data) [ZINDEX32(x, y, ximage)]; + *((unsigned long *)addr) = pixel; + return 1; +} +#endif + +static int +PutPixel32MSB(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + unsigned char *addr; + + if(x < 0 || y < 0) + return 0; + + addr = &((unsigned char *)ximage->data) [ZINDEX32(x, y, ximage)]; + addr[0] = pixel >> 24; + addr[1] = pixel >> 16; + addr[2] = pixel >> 8; + addr[3] = pixel; + return 1; +} + +static int +PutPixel32LSB(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + unsigned char *addr; + + if(x < 0 || y < 0) + return 0; + + addr = &((unsigned char *)ximage->data) [ZINDEX32(x, y, ximage)]; + addr[3] = pixel >> 24; + addr[2] = pixel >> 16; + addr[1] = pixel >> 8; + addr[0] = pixel; + return 1; +} + +static int +PutPixel16MSB(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + unsigned char *addr; + + if(x < 0 || y < 0) + return 0; + + addr = &((unsigned char *)ximage->data) [ZINDEX16(x, y, ximage)]; + addr[0] = pixel >> 8; + addr[1] = pixel; + return 1; +} + +static int +PutPixel16LSB(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + unsigned char *addr; + + if(x < 0 || y < 0) + return 0; + + addr = &((unsigned char *)ximage->data) [ZINDEX16(x, y, ximage)]; + addr[1] = pixel >> 8; + addr[0] = pixel; + return 1; +} + +static int +PutPixel8(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + if(x < 0 || y < 0) + return 0; + + ximage->data[ZINDEX8(x, y, ximage)] = pixel; + return 1; +} + +static int +PutPixel1MSB(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + if(x < 0 || y < 0) + return 0; + + if (pixel & 1) + ximage->data[ZINDEX1(x, y, ximage)] |= 0x80 >> (x & 7); + else + ximage->data[ZINDEX1(x, y, ximage)] &= ~(0x80 >> (x & 7)); + return 1; +} + +static int +PutPixel1LSB(ximage, x, y, pixel) + register XImage *ximage; + int x; + int y; + unsigned long pixel; +{ + if(x < 0 || y < 0) + return 0; + + if (pixel & 1) + ximage->data[ZINDEX1(x, y, ximage)] |= 1 << (x & 7); + else + ximage->data[ZINDEX1(x, y, ximage)] &= ~(1 << (x & 7)); + return 1; +} + +#endif /* not FOR_MSW && not AMIGA */ + +/* + * This function parses an Xpm file or data and directly create an XImage + */ +int +xpmParseDataAndCreate(display, data, image_return, shapeimage_return, + image, info, attributes) + Display *display; + xpmData *data; + XImage **image_return; + XImage **shapeimage_return; + XpmImage *image; + XpmInfo *info; + XpmAttributes *attributes; +{ + /* variables stored in the XpmAttributes structure */ + Visual *visual; + Colormap colormap; + unsigned int depth; + int bitmap_format; + XpmFreeColorsFunc freeColors; + + /* variables to return */ + XImage *ximage = NULL; + XImage *shapeimage = NULL; + unsigned int mask_pixel_index = XpmUndefPixel; + + /* calculation variables */ + Pixel *image_pixels = NULL; + Pixel *mask_pixels = NULL; + Pixel *alloc_pixels = NULL; + Pixel *used_pixels = NULL; + unsigned int nalloc_pixels = 0; + unsigned int nused_pixels = 0; + unsigned int width, height, ncolors, cpp; + unsigned int x_hotspot, y_hotspot, hotspot = 0, extensions = 0; + XpmColor *colorTable = NULL; + char *hints_cmt = NULL; + char *colors_cmt = NULL; + char *pixels_cmt = NULL; + + unsigned int cmts; + int ErrorStatus; + xpmHashTable hashtable; + + + /* initialize return values */ + if (image_return) + *image_return = NULL; + if (shapeimage_return) + *shapeimage_return = NULL; + + + /* retrieve information from the XpmAttributes */ + if (attributes && (attributes->valuemask & XpmVisual)) + visual = attributes->visual; + else + visual = XDefaultVisual(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmColormap)) + colormap = attributes->colormap; + else + colormap = XDefaultColormap(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmDepth)) + depth = attributes->depth; + else + depth = XDefaultDepth(display, XDefaultScreen(display)); + + if (attributes && (attributes->valuemask & XpmBitmapFormat)) + bitmap_format = attributes->bitmap_format; + else + bitmap_format = ZPixmap; + + if (attributes && (attributes->valuemask & XpmFreeColors)) + freeColors = attributes->free_colors; + else + freeColors = FreeColors; + + cmts = info && (info->valuemask & XpmReturnComments); + + /* + * parse the header + */ + ErrorStatus = xpmParseHeader(data); + if (ErrorStatus != XpmSuccess) + return (ErrorStatus); + + /* + * read values + */ + ErrorStatus = xpmParseValues(data, &width, &height, &ncolors, &cpp, + &x_hotspot, &y_hotspot, &hotspot, + &extensions); + if (ErrorStatus != XpmSuccess) + return (ErrorStatus); + + /* + * store the hints comment line + */ + if (cmts) + xpmGetCmt(data, &hints_cmt); + + /* + * init the hastable + */ + if (USE_HASHTABLE) { + ErrorStatus = xpmHashTableInit(&hashtable); + if (ErrorStatus != XpmSuccess) + return (ErrorStatus); + } + + /* + * read colors + */ + ErrorStatus = xpmParseColors(data, ncolors, cpp, &colorTable, &hashtable); + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + + /* + * store the colors comment line + */ + if (cmts) + xpmGetCmt(data, &colors_cmt); + + /* malloc pixels index tables */ + if (ncolors >= UINT_MAX / sizeof(Pixel)) + RETURN(XpmNoMemory); + + image_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * ncolors); + if (!image_pixels) + RETURN(XpmNoMemory); + + mask_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * ncolors); + if (!mask_pixels) + RETURN(XpmNoMemory); + + /* maximum of allocated pixels will be the number of colors */ + alloc_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * ncolors); + if (!alloc_pixels) + RETURN(XpmNoMemory); + + /* maximum of allocated pixels will be the number of colors */ + used_pixels = (Pixel *) XpmMalloc(sizeof(Pixel) * ncolors); + if (!used_pixels) + RETURN(XpmNoMemory); + + /* get pixel colors, store them in index tables */ + ErrorStatus = CreateColors(display, attributes, colorTable, ncolors, + image_pixels, mask_pixels, &mask_pixel_index, + alloc_pixels, &nalloc_pixels, used_pixels, + &nused_pixels); + + if (ErrorStatus != XpmSuccess + && (ErrorStatus < 0 || (attributes + && (attributes->valuemask & XpmExactColors) + && attributes->exactColors))) + RETURN(ErrorStatus); + + /* now create the ximage */ + if (image_return) { + ErrorStatus = CreateXImage(display, visual, depth, + (depth == 1 ? bitmap_format : ZPixmap), + width, height, &ximage); + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + +#if !defined(FOR_MSW) && !defined(AMIGA) + + /* + * set the XImage pointer function, to be used with XPutPixel, + * to an internal optimized function + */ + + if (ximage->bits_per_pixel == 8) + ximage->f.put_pixel = PutPixel8; + else if (((ximage->bits_per_pixel | ximage->depth) == 1) && + (ximage->byte_order == ximage->bitmap_bit_order)) + if (ximage->bitmap_bit_order == MSBFirst) + ximage->f.put_pixel = PutPixel1MSB; + else + ximage->f.put_pixel = PutPixel1LSB; + else if (ximage->bits_per_pixel == 16) + if (ximage->bitmap_bit_order == MSBFirst) + ximage->f.put_pixel = PutPixel16MSB; + else + ximage->f.put_pixel = PutPixel16LSB; + else if (ximage->bits_per_pixel == 32) +#if !defined(WORD64) && !defined(LONG64) + if (*((char *)&byteorderpixel) == ximage->byte_order) + ximage->f.put_pixel = PutPixel32; + else +#endif + if (ximage->bitmap_bit_order == MSBFirst) + ximage->f.put_pixel = PutPixel32MSB; + else + ximage->f.put_pixel = PutPixel32LSB; + else if ((ximage->bits_per_pixel | ximage->depth) == 1) + ximage->f.put_pixel = PutPixel1; + else + ximage->f.put_pixel = PutPixel; +#endif /* not FOR_MSW && not AMIGA */ + } + + /* create the shape mask image */ + if (mask_pixel_index != XpmUndefPixel && shapeimage_return) { + ErrorStatus = CreateXImage(display, visual, 1, bitmap_format, + width, height, &shapeimage); + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + +#if !defined(FOR_MSW) && !defined(AMIGA) + if (shapeimage->bitmap_bit_order == MSBFirst) + shapeimage->f.put_pixel = PutPixel1MSB; + else + shapeimage->f.put_pixel = PutPixel1LSB; +#endif + } + + /* + * read pixels and put them in the XImage + */ + ErrorStatus = ParseAndPutPixels( +#ifdef FOR_MSW + display, +#endif + data, width, height, ncolors, cpp, + colorTable, &hashtable, + ximage, image_pixels, + shapeimage, mask_pixels); + XpmFree(image_pixels); + image_pixels = NULL; + XpmFree(mask_pixels); + mask_pixels = NULL; + + /* + * free the hastable + */ + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + else if (USE_HASHTABLE) + xpmHashTableFree(&hashtable); + + /* + * store the pixels comment line + */ + if (cmts) + xpmGetCmt(data, &pixels_cmt); + + /* + * parse extensions + */ + if (info && (info->valuemask & XpmReturnExtensions)) { + if (extensions) { + ErrorStatus = xpmParseExtensions(data, &info->extensions, + &info->nextensions); + if (ErrorStatus != XpmSuccess) + RETURN(ErrorStatus); + } else { + info->extensions = NULL; + info->nextensions = 0; + } + } + /* + * store found informations in the XpmImage structure + */ + image->width = width; + image->height = height; + image->cpp = cpp; + image->ncolors = ncolors; + image->colorTable = colorTable; + image->data = NULL; + + if (info) { + if (cmts) { + info->hints_cmt = hints_cmt; + info->colors_cmt = colors_cmt; + info->pixels_cmt = pixels_cmt; + } + if (hotspot) { + info->x_hotspot = x_hotspot; + info->y_hotspot = y_hotspot; + info->valuemask |= XpmHotspot; + } + } + /* if requested return used pixels in the XpmAttributes structure */ + if (attributes && (attributes->valuemask & XpmReturnPixels || +/* 3.2 backward compatibility code */ + attributes->valuemask & XpmReturnInfos)) { +/* end 3.2 bc */ + attributes->pixels = used_pixels; + attributes->npixels = nused_pixels; + attributes->mask_pixel = mask_pixel_index; + } else + XpmFree(used_pixels); + + /* if requested return alloc'ed pixels in the XpmAttributes structure */ + if (attributes && (attributes->valuemask & XpmReturnAllocPixels)) { + attributes->alloc_pixels = alloc_pixels; + attributes->nalloc_pixels = nalloc_pixels; + } else + XpmFree(alloc_pixels); + + /* return created images */ + if (image_return) + *image_return = ximage; + if (shapeimage_return) + *shapeimage_return = shapeimage; + + return (XpmSuccess); + +/* exit point in case of error, free only locally allocated variables */ +error: + if (USE_HASHTABLE) + xpmHashTableFree(&hashtable); + if (colorTable) + xpmFreeColorTable(colorTable, ncolors); + if (hints_cmt) + XpmFree(hints_cmt); + if (colors_cmt) + XpmFree(colors_cmt); + if (pixels_cmt) + XpmFree(pixels_cmt); + if (ximage) + XDestroyImage(ximage); + if (shapeimage) + XDestroyImage(shapeimage); + if (image_pixels) + XpmFree(image_pixels); + if (mask_pixels) + XpmFree(mask_pixels); + if (nalloc_pixels) + (*freeColors)(display, colormap, alloc_pixels, nalloc_pixels, NULL); + if (alloc_pixels) + XpmFree(alloc_pixels); + if (used_pixels) + XpmFree(used_pixels); + + return (ErrorStatus); +} + +static int +ParseAndPutPixels( +#ifdef FOR_MSW + dc, +#endif + data, width, height, ncolors, cpp, colorTable, hashtable, + image, image_pixels, shapeimage, shape_pixels) +#ifdef FOR_MSW + Display *dc; +#endif + xpmData *data; + unsigned int width; + unsigned int height; + unsigned int ncolors; + unsigned int cpp; + XpmColor *colorTable; + xpmHashTable *hashtable; + XImage *image; + Pixel *image_pixels; + XImage *shapeimage; + Pixel *shape_pixels; +{ + unsigned int a, x, y; + + switch (cpp) { + + case (1): /* Optimize for single character + * colors */ + { + unsigned short colidx[256]; +#ifdef FOR_MSW + HDC shapedc; + HBITMAP obm, sobm; + + if ( shapeimage ) { + shapedc = CreateCompatibleDC(*dc); + sobm = SelectObject(shapedc, shapeimage->bitmap); + } else { + shapedc = NULL; + } + obm = SelectObject(*dc, image->bitmap); +#endif + if (ncolors > 256) + return (XpmFileInvalid); + + bzero((char *)colidx, 256 * sizeof(short)); + for (a = 0; a < ncolors; a++) + colidx[(unsigned char)colorTable[a].string[0]] = a + 1; + + for (y = 0; y < height; y++) { + xpmNextString(data); + for (x = 0; x < width; x++) { + int c = xpmGetC(data); + + if (c > 0 && c < 256 && colidx[c] != 0) { +#ifndef FOR_MSW + XPutPixel(image, x, y, image_pixels[colidx[c] - 1]); + if (shapeimage) + XPutPixel(shapeimage, x, y, + shape_pixels[colidx[c] - 1]); +#else + SetPixel(*dc, x, y, image_pixels[colidx[c] - 1]); + if (shapedc) { + SetPixel(shapedc, x, y, shape_pixels[colidx[c] - 1]); + } +#endif + } else + return (XpmFileInvalid); + } + } +#ifdef FOR_MSW + if ( shapedc ) { + SelectObject(shapedc, sobm); + DeleteDC(shapedc); + } + SelectObject(*dc, obm); +#endif + } + break; + + case (2): /* Optimize for double character + * colors */ + { + +/* free all allocated pointers at all exits */ +#define FREE_CIDX {int f; for (f = 0; f < 256; f++) \ +if (cidx[f]) XpmFree(cidx[f]);} + + /* array of pointers malloced by need */ + unsigned short *cidx[256]; + unsigned int char1; + + bzero((char *)cidx, 256 * sizeof(unsigned short *)); /* init */ + for (a = 0; a < ncolors; a++) { + char1 = (unsigned char) colorTable[a].string[0]; + if (cidx[char1] == NULL) { /* get new memory */ + cidx[char1] = (unsigned short *) + XpmCalloc(256, sizeof(unsigned short)); + if (cidx[char1] == NULL) { /* new block failed */ + FREE_CIDX; + return (XpmNoMemory); + } + } + cidx[char1][(unsigned char)colorTable[a].string[1]] = a + 1; + } + + for (y = 0; y < height; y++) { + xpmNextString(data); + for (x = 0; x < width; x++) { + int cc1 = xpmGetC(data); + if (cc1 > 0 && cc1 < 256) { + int cc2 = xpmGetC(data); + if (cc2 > 0 && cc2 < 256 && + cidx[cc1] && cidx[cc1][cc2] != 0) { +#ifndef FOR_MSW + XPutPixel(image, x, y, + image_pixels[cidx[cc1][cc2] - 1]); + if (shapeimage) + XPutPixel(shapeimage, x, y, + shape_pixels[cidx[cc1][cc2] - 1]); +#else + SelectObject(*dc, image->bitmap); + SetPixel(*dc, x, y, image_pixels[cidx[cc1][cc2] - 1]); + if (shapeimage) { + SelectObject(*dc, shapeimage->bitmap); + SetPixel(*dc, x, y, + shape_pixels[cidx[cc1][cc2] - 1]); + } +#endif + } else { + FREE_CIDX; + return (XpmFileInvalid); + } + } else { + FREE_CIDX; + return (XpmFileInvalid); + } + } + } + FREE_CIDX; + } + break; + + default: /* Non-optimized case of long color + * names */ + { + char *s; + char buf[BUFSIZ]; + + if (cpp >= sizeof(buf)) + return (XpmFileInvalid); + + buf[cpp] = '\0'; + if (USE_HASHTABLE) { + xpmHashAtom *slot; + + for (y = 0; y < height; y++) { + xpmNextString(data); + for (x = 0; x < width; x++) { + for (a = 0, s = buf; a < cpp; a++, s++) + *s = xpmGetC(data); + slot = xpmHashSlot(hashtable, buf); + if (!*slot) /* no color matches */ + return (XpmFileInvalid); +#ifndef FOR_MSW + XPutPixel(image, x, y, + image_pixels[HashColorIndex(slot)]); + if (shapeimage) + XPutPixel(shapeimage, x, y, + shape_pixels[HashColorIndex(slot)]); +#else + SelectObject(*dc, image->bitmap); + SetPixel(*dc, x, y, + image_pixels[HashColorIndex(slot)]); + if (shapeimage) { + SelectObject(*dc, shapeimage->bitmap); + SetPixel(*dc, x, y, + shape_pixels[HashColorIndex(slot)]); + } +#endif + } + } + } else { + for (y = 0; y < height; y++) { + xpmNextString(data); + for (x = 0; x < width; x++) { + for (a = 0, s = buf; a < cpp; a++, s++) + *s = xpmGetC(data); + for (a = 0; a < ncolors; a++) + if (!strcmp(colorTable[a].string, buf)) + break; + if (a == ncolors) /* no color matches */ + return (XpmFileInvalid); +#ifndef FOR_MSW + XPutPixel(image, x, y, image_pixels[a]); + if (shapeimage) + XPutPixel(shapeimage, x, y, shape_pixels[a]); +#else + SelectObject(*dc, image->bitmap); + SetPixel(*dc, x, y, image_pixels[a]); + if (shapeimage) { + SelectObject(*dc, shapeimage->bitmap); + SetPixel(*dc, x, y, shape_pixels[a]); + } +#endif + } + } + } + } + break; + } + return (XpmSuccess); +} |