/** ------------------------------------------------------------------------ This file contains functions to create a list of regions which tile a specified window. Each region contains all visible portions of the window which are drawn with the same visual. If the window consists of subwindows of two different visual types, there will be two regions in the list. The list can be traversed to correctly pull an image of the window using XGetImage or the Image Library. Copyright 1994 Hewlett-Packard Co. Copyright 1996, 1998 The Open Group Permission to use, copy, modify, distribute, and sell this software and its documentation for any purpose is hereby granted without fee, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation. 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 THE OPEN GROUP 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 The Open Group shall not be used in advertising or otherwise to promote the sale, use or other dealings in this Software without prior written authorization from The Open Group. ------------------------------------------------------------------------ **/ #include #include #include #include #include #include #include "list.h" #include "wsutils.h" #include "multiVis.h" /* These structures are copied from X11/region.h. For some reason * they're invisible from the outside. */ typedef struct { short x1, x2, y1, y2; } myBox, myBOX, myBoxRec, *myBoxPtr; typedef struct my_XRegion { long size; long numRects; myBOX *rects; myBOX extents; } myREGION; /* Items in long list of windows that have some part in the grabbed area */ typedef struct { Window win; Visual *vis; Colormap cmap; int x_rootrel, y_rootrel; /* root relative location of window */ int x_vis, y_vis; /* rt rel x,y of vis part, not parent clipped */ int width, height; /* width and height of visible part */ int border_width; /* border width of the window */ Window parent; /* id of parent (for debugging) */ } image_win_type; /* Items in short list of regions that tile the grabbed area. May have multiple windows in the region. */ typedef struct { Window win; /* lowest window of this visual */ Visual *vis; Colormap cmap; int x_rootrel, y_rootrel; /* root relative location of bottom window */ int x_vis, y_vis; /* rt rel x,y of vis part, not parent clipped */ int width, height; /* w & h of visible rect of bottom window */ int border; /* border width of the window */ Region visible_region; } image_region_type; /** ------------------------------------------------------------------------ Returns TRUE if the two structs pointed to have the same "vis" & "cmap" fields and s2 lies completely within s1. s1 and s2 can point to structs of image_win_type or image_region_type. ------------------------------------------------------------------------ **/ #define SAME_REGIONS( s1, s2) \ ((s1)->vis == (s2)->vis && (s1)->cmap == (s2)->cmap && \ (s1)->x_vis <= (s2)->x_vis && \ (s1)->y_vis <= (s2)->y_vis && \ (s1)->x_vis + (s1)->width >= (s2)->x_vis + (s2)->width && \ (s1)->y_vis + (s1)->height >= (s2)->y_vis + (s2)->height) #ifndef MIN #define MIN( a, b) ((a) < (b) ? a : b) #define MAX( a, b) ((a) > (b) ? a : b) #endif #define RED_SHIFT 16 #define GREEN_SHIFT 8 #define BLUE_SHIFT 0 /* Prototype Declarations for Static Functions */ static void QueryColorMap(Display *, Colormap, Visual *, XColor **, int *, int *, int *); static void TransferImage(Display *, XImage *, int, int, image_region_type *, XImage *, int, int); static XImage *ReadRegionsInList(Display *, Visual *, int, int, unsigned int, unsigned int, XRectangle, list_ptr); static list_ptr make_region_list(Display *, Window, XRectangle *, int *, int, XVisualInfo **, int *); static void destroy_region_list(list_ptr); static void subtr_rect_from_image_region(image_region_type *, int, int, int, int); static void add_rect_to_image_region(image_region_type *, int, int, int, int); static int src_in_region_list(image_win_type *, list_ptr); static void add_window_to_list(list_ptr, Window, int, int, int, int, int, int, int, Visual *, Colormap, Window); static int src_in_image(image_win_type *, int, XVisualInfo **); static int src_in_overlay(image_region_type *, int, OverlayInfo *, int *, int *); static void make_src_list(Display *, list_ptr, XRectangle *, Window, int, int, XWindowAttributes *, XRectangle *); static void destroy_image_region(image_region_type *); /* End of Prototype Declarations */ void initFakeVisual(Visual *Vis) { Vis->ext_data = NULL; Vis->class = DirectColor; Vis->red_mask = 0x00FF0000; Vis->green_mask = 0x0000FF00; Vis->blue_mask = 0x000000FF; Vis->map_entries = 256; Vis->bits_per_rgb = 8; } static void QueryColorMap(Display *disp, Colormap src_cmap, Visual *src_vis, XColor **src_colors, int *rShift, int *gShift, int *bShift) { unsigned int ncolors; XColor *colors; ncolors = (unsigned) src_vis->map_entries; *src_colors = colors = calloc(ncolors, sizeof(XColor)); if (src_vis->class != TrueColor && src_vis->class != DirectColor) { for (unsigned int i = 0; i < ncolors; i++) { colors[i].pixel = i; colors[i].pad = 0; colors[i].flags = DoRed | DoGreen | DoBlue; } } else { /** src is decomposed rgb ***/ unsigned long redMask, greenMask, blueMask; int redShift, greenShift, blueShift; /* Get the X colormap */ redMask = src_vis->red_mask; greenMask = src_vis->green_mask; blueMask = src_vis->blue_mask; redShift = 0; while (!(redMask & 0x1)) { redShift++; redMask = redMask >> 1; } greenShift = 0; while (!(greenMask & 0x1)) { greenShift++; greenMask = greenMask >> 1; } blueShift = 0; while (!(blueMask & 0x1)) { blueShift++; blueMask = blueMask >> 1; } *rShift = redShift; *gShift = greenShift; *bShift = blueShift; for (unsigned int i = 0; i < ncolors; i++) { if (i <= redMask) colors[i].pixel = (i << redShift); if (i <= greenMask) colors[i].pixel |= (i << greenShift); if (i <= blueMask) colors[i].pixel |= (i << blueShift); /***** example: for gecko's 3-3-2 map, blue index should be <= 3. colors[i].pixel = (i<next && (*vis_regions)->next->next) || (*vis_image_regions && (*vis_image_regions)->next && (*vis_image_regions)->next->next)) return 1; else return 0; } static void TransferImage(Display *disp, XImage *reg_image, int srcw, int srch, image_region_type *reg, XImage *target_image, int dst_x, int dst_y) { XColor *colors; int rShift = 0, gShift = 0, bShift = 0; QueryColorMap(disp, reg->cmap, reg->vis, &colors, &rShift, &gShift, &bShift); switch (reg->vis->class) { case TrueColor: for (int i = 0; i < srch; i++) { for (int j = 0; j < srcw; j++) { int old_pixel = XGetPixel(reg_image, j, i); int new_pixel; if (reg->vis->map_entries == 16) { int red_ind = (old_pixel & reg->vis->red_mask) >> rShift; int green_ind = (old_pixel & reg->vis->green_mask) >> gShift; int blue_ind = (old_pixel & reg->vis->blue_mask) >> bShift; new_pixel = ( ((colors[red_ind].red >> 8) << RED_SHIFT) | ((colors[green_ind].green >> 8) << GREEN_SHIFT) | ((colors[blue_ind].blue >> 8) << BLUE_SHIFT) ); } else new_pixel = old_pixel; XPutPixel(target_image, dst_x + j, dst_y + i, new_pixel); } } break; case DirectColor: for (int i = 0; i < srch; i++) { for (int j = 0; j < srcw; j++) { int old_pixel = XGetPixel(reg_image, j, i); int red_ind = (old_pixel & reg->vis->red_mask) >> rShift; int green_ind = (old_pixel & reg->vis->green_mask) >> gShift; int blue_ind = (old_pixel & reg->vis->blue_mask) >> bShift; int new_pixel = ( ((colors[red_ind].red >> 8) << RED_SHIFT) | ((colors[green_ind].green >> 8) << GREEN_SHIFT) | ((colors[blue_ind].blue >> 8) << BLUE_SHIFT) ); XPutPixel(target_image, dst_x + j, dst_y + i, new_pixel); } } break; default: for (int i = 0; i < srch; i++) { for (int j = 0; j < srcw; j++) { int old_pixel = XGetPixel(reg_image, j, i); int new_pixel = ( ((colors[old_pixel].red >> 8) << RED_SHIFT) | ((colors[old_pixel].green >> 8) << GREEN_SHIFT) | ((colors[old_pixel].blue >> 8) << BLUE_SHIFT) ); XPutPixel(target_image, dst_x + j, dst_y + i, new_pixel); } } break; } } static XImage * ReadRegionsInList(Display *disp, Visual *fakeVis, int depth, int format, unsigned int width, unsigned int height, XRectangle bbox, /* bounding box of grabbed area */ list_ptr regions) /* list of regions to read from */ { int datalen; XImage *reg_image, *ximage; int bytes_per_line; ximage = XCreateImage(disp, fakeVis, depth, format, 0, NULL, width, height, 8, 0); bytes_per_line = ximage->bytes_per_line; datalen = height * bytes_per_line; if (format != ZPixmap) datalen *= depth; ximage->data = malloc(datalen); memset(ximage->data, 0, datalen); ximage->bits_per_pixel = depth; /** Valid only if format is ZPixmap ***/ for (image_region_type *reg = (image_region_type *) first_in_list(regions); reg; reg = (image_region_type *) next_in_list(regions)) { struct my_XRegion *vis_reg = (struct my_XRegion *) (reg->visible_region); for (int rect = 0; rect < vis_reg->numRects; rect++) { /** ------------------------------------------------------------------------ Intersect bbox with visible part of region giving src rect & output location. Width is the min right side minus the max left side. Similar for height. Offset src rect so x,y are relative to origin of win, not the root-relative visible rect of win. ------------------------------------------------------------------------ **/ int srcRect_width = MIN(vis_reg->rects[rect].x2, bbox.width + bbox.x) - MAX(vis_reg->rects[rect].x1, bbox.x); int srcRect_height = MIN(vis_reg->rects[rect].y2, bbox.height + bbox.y) - MAX(vis_reg->rects[rect].y1, bbox.y); int srcRect_x, srcRect_y; int dst_x, dst_y; /* where in pixmap to write (UL) */ int diff = bbox.x - vis_reg->rects[rect].x1; srcRect_x = MAX(0,diff) + (vis_reg->rects[rect].x1 - reg->x_rootrel - reg->border); dst_x = MAX(0, -diff); diff = bbox.y - vis_reg->rects[rect].y1; srcRect_y = MAX(0, diff) + (vis_reg->rects[rect].y1 - reg->y_rootrel - reg->border); dst_y = MAX(0, -diff); reg_image = XGetImage(disp, reg->win, srcRect_x, srcRect_y, srcRect_width, srcRect_height, AllPlanes, format); TransferImage(disp, reg_image, srcRect_width, srcRect_height, reg, ximage, dst_x, dst_y); } } return ximage; } /** ------------------------------------------------------------------------ ------------------------------------------------------------------------ **/ XImage * ReadAreaToImage(Display *disp, /* root win on which grab was done */ Window srcRootWinid, /* root rel UL corner of bounding box of grab */ int x, int y, /* size of bounding box of grab */ unsigned int width, unsigned int height, int numVisuals, XVisualInfo *pVisuals, int numOverlayVisuals, OverlayInfo *pOverlayVisuals, int numImageVisuals, XVisualInfo **pImageVisuals, /* list of regions to read from */ list_ptr vis_regions, /* list of regions to read from */ list_ptr vis_image_regions, int format, int allImage) { image_region_type *reg; XRectangle bbox; /* bounding box of grabbed area */ int depth; XImage *ximage, *ximage_ipm = NULL; Visual fakeVis; XImage *image; #if 0 unsigned char *pmData, *ipmData; #endif int transparentColor, transparentType; bbox.x = x; /* init X rect for bounding box */ bbox.y = y; bbox.width = width; bbox.height = height; initFakeVisual(&fakeVis); depth = 24; ximage = ReadRegionsInList(disp, &fakeVis, depth, format, width, height, bbox, vis_regions); #if 0 pmData = (unsigned char *) ximage->data; #endif /* if transparency possible do it again, but this time for image planes only */ if (vis_image_regions && (vis_image_regions->next) && !allImage) { ximage_ipm = ReadRegionsInList(disp, &fakeVis, depth, format, width, height, bbox, vis_image_regions); #if 0 ipmData = (unsigned char *) ximage_ipm->data; #endif } /* Now tranverse the overlay visual windows and test for transparency index. */ /* If you find one, substitute the value from the matching image plane pixmap. */ for (reg = (image_region_type *) first_in_list(vis_regions); reg; reg = (image_region_type *) next_in_list(vis_regions)) { if (src_in_overlay(reg, numOverlayVisuals, pOverlayVisuals, &transparentColor, &transparentType)) { int srcRect_x, srcRect_y, srcRect_width, srcRect_height; int diff; int dst_x, dst_y; /* where in pixmap to write (UL) */ int test = 0; srcRect_width = MIN(reg->width + reg->x_vis, bbox.width + bbox.x) - MAX(reg->x_vis, bbox.x); srcRect_height = MIN(reg->height + reg->y_vis, bbox.height + bbox.y) - MAX(reg->y_vis, bbox.y); diff = bbox.x - reg->x_vis; srcRect_x = MAX(0, diff) + (reg->x_vis - reg->x_rootrel - reg->border); dst_x = MAX(0, -diff); diff = bbox.y - reg->y_vis; srcRect_y = MAX(0, diff) + (reg->y_vis - reg->y_rootrel - reg->border); dst_y = MAX(0, -diff); /* let's test some pixels for transparency */ image = XGetImage(disp, reg->win, srcRect_x, srcRect_y, srcRect_width, srcRect_height, 0xffffffff, ZPixmap); /* let's assume byte per pixel for overlay image for now */ if ((image->depth == 8) && (transparentType == TransparentPixel)) { unsigned char *pixel_ptr; unsigned char *start_of_line = (unsigned char *) image->data; for (int y1 = 0; y1 < srcRect_height; y1++) { pixel_ptr = start_of_line; for (int x1 = 0; x1 < srcRect_width; x1++) { if (*pixel_ptr++ == transparentColor) { int pixel; #if 0 *pmData++ = *ipmData++; *pmData++ = *ipmData++; *pmData++ = *ipmData++; #endif pixel = XGetPixel(ximage_ipm, dst_x + x1, dst_y + y1); XPutPixel(ximage, dst_x + x1, dst_y + y1, pixel); if (!test) { test = 1; } } #if 0 else { pmData += 3; ipmData += 3; } #endif } start_of_line += image->bytes_per_line; } } else { if (transparentType == TransparentPixel) { for (int y1 = 0; y1 < srcRect_height; y1++) { for (int x1 = 0; x1 < srcRect_width; x1++) { int pixel_value = XGetPixel(image, x1, y1); if (pixel_value == transparentColor) { int pixel; #if 0 *pmData++ = *ipmData++; *pmData++ = *ipmData++; *pmData++ = *ipmData++; #endif pixel = XGetPixel(ximage_ipm, dst_x + x1, dst_y + y1); XPutPixel(ximage, dst_x + x1, dst_y + y1, pixel); if (!test) { test = 1; } } #if 0 else { pmData += 3; ipmData += 3; } #endif } } } else { for (int y1 = 0; y1 < srcRect_height; y1++) { for (int x1 = 0; x1 < srcRect_width; x1++) { int pixel_value = XGetPixel(image, x1, y1); if (pixel_value & transparentColor) { int pixel; #if 0 *pmData++ = *ipmData++; *pmData++ = *ipmData++; *pmData++ = *ipmData++; #endif pixel = XGetPixel(ximage_ipm, dst_x + x1, dst_y + y1); XPutPixel(ximage, dst_x + x1, dst_y + y1, pixel); if (!test) { test = 1; } } #if 0 else { pmData += 3; ipmData += 3; } #endif } } } } XDestroyImage(image); } /* end of src_in_overlay */ } /** end transparency **/ destroy_region_list(vis_regions); if (vis_image_regions) destroy_region_list(vis_image_regions); FreeXVisualInfo(pVisuals, pOverlayVisuals, pImageVisuals); XSync(disp, 0); return ximage; } /** ------------------------------------------------------------------------ Creates a list of the subwindows of a given window which have a different visual than their parents. The function is recursive. This list is used in make_region_list(), which coalesces the windows with the same visual into a region. image_wins must point to an existing list struct that's already been zeroed (zero_list()). ------------------------------------------------------------------------ **/ static void make_src_list(Display *disp, list_ptr image_wins, /* bnding box of area we want */ XRectangle *bbox, Window curr, /* pos of curr WRT root */ int x_rootrel, int y_rootrel, XWindowAttributes *curr_attrs, /* visible part of curr, not obscurred by ancestors */ XRectangle *pclip) { XWindowAttributes child_attrs; Window root, parent, *child; /* variables for XQueryTree() */ unsigned int nchild; /* variables for XQueryTree() */ XRectangle child_clip; /* vis part of child */ /* check that win is mapped & not outside bounding box */ if (curr_attrs->map_state == IsViewable && curr_attrs->class == InputOutput && !(pclip->x >= (int) (bbox->x + bbox->width) || pclip->y >= (int) (bbox->y + bbox->height) || (int) (pclip->x + pclip->width) <= bbox->x || (int) (pclip->y + pclip->height) <= bbox->y)) { Window *save_child_list; int curr_clipX, curr_clipY, curr_clipRt, curr_clipBt; XQueryTree(disp, curr, &root, &parent, &child, &nchild); save_child_list = child; /* so we can free list when we're done */ add_window_to_list(image_wins, curr, x_rootrel, y_rootrel, pclip->x, pclip->y, pclip->width, pclip->height, curr_attrs->border_width, curr_attrs->visual, curr_attrs->colormap, parent); /** ------------------------------------------------------------------------ set RR coords of right (Rt), left (X), bottom (Bt) and top (Y) of rect we clip all children by. This is our own clip rect (pclip) inflicted on us by our parent plus our own borders. Within the child loop, we figure the clip rect for each child by adding in it's rectangle (not taking into account the child's borders). ------------------------------------------------------------------------ **/ curr_clipX = MAX(pclip->x, x_rootrel + (int) curr_attrs->border_width); curr_clipY = MAX(pclip->y, y_rootrel + (int) curr_attrs->border_width); curr_clipRt = MIN(pclip->x + (int) pclip->width, x_rootrel + (int) curr_attrs->width + 2 * (int) curr_attrs->border_width); curr_clipBt = MIN(pclip->y + (int) pclip->height, y_rootrel + (int) curr_attrs->height + 2 * (int) curr_attrs->border_width); while (nchild--) { int new_width, new_height; int child_xrr, child_yrr; /* root relative x & y of child */ XGetWindowAttributes(disp, *child, &child_attrs); /* intersect parent & child clip rects */ child_xrr = x_rootrel + child_attrs.x + curr_attrs->border_width; child_clip.x = MAX(curr_clipX, child_xrr); new_width = MIN(curr_clipRt, child_xrr + (int) child_attrs.width + 2 * child_attrs.border_width) - child_clip.x; if (new_width >= 0) { child_clip.width = new_width; child_yrr = y_rootrel + child_attrs.y + curr_attrs->border_width; child_clip.y = MAX(curr_clipY, child_yrr); new_height = MIN(curr_clipBt, child_yrr + (int) child_attrs.height + 2 * child_attrs.border_width) - child_clip.y; if (new_height >= 0) { child_clip.height = new_height; make_src_list(disp, image_wins, bbox, *child, child_xrr, child_yrr, &child_attrs, &child_clip); } } child++; } XFree(save_child_list); } } /** ------------------------------------------------------------------------ This function creates a list of regions which tile a specified window. Each region contains all visible portions of the window which are drawn with the same visual. For example, if the window consists of subwindows of two different visual types, there will be two regions in the list. Returns a pointer to the list. ------------------------------------------------------------------------ **/ static list_ptr make_region_list(Display *disp, Window win, XRectangle *bbox, int *hasNonDefault, int numImageVisuals, XVisualInfo **pImageVisuals, int *allImage) { XWindowAttributes win_attrs; list image_wins; list_ptr image_regions; list_ptr srcs_left; image_region_type *new_reg; image_win_type *base_src, *src; Region bbox_region = XCreateRegion(); XRectangle clip; int image_only; int count = 0; *hasNonDefault = False; XUnionRectWithRegion(bbox, bbox_region, bbox_region); XGetWindowAttributes(disp, win, &win_attrs); zero_list(&image_wins); clip.x = 0; clip.y = 0; clip.width = win_attrs.width; clip.height = win_attrs.height; make_src_list(disp, &image_wins, bbox, win, 0 /* x_rootrel */, 0 /* y_rootrel */, &win_attrs, &clip); image_regions = new_list(); image_only = (*allImage) ? True : False; for (base_src = (image_win_type *) first_in_list(&image_wins); base_src; base_src = (image_win_type *) next_in_list(&image_wins)) { /* test for image visual */ if (!image_only || src_in_image(base_src, numImageVisuals, pImageVisuals)) { /* find a window whose visual hasn't been put in list yet */ if (!src_in_region_list(base_src, image_regions)) { if (!(new_reg = malloc(sizeof(image_region_type)))) { return (list_ptr) NULL; } count++; new_reg->visible_region = XCreateRegion(); new_reg->win = base_src->win; new_reg->vis = base_src->vis; new_reg->cmap = base_src->cmap; new_reg->x_rootrel = base_src->x_rootrel; new_reg->y_rootrel = base_src->y_rootrel; new_reg->x_vis = base_src->x_vis; new_reg->y_vis = base_src->y_vis; new_reg->width = base_src->width; new_reg->height = base_src->height; new_reg->border = base_src->border_width; srcs_left = (list_ptr) dup_list_head(&image_wins, START_AT_CURR); for (src = (image_win_type *) first_in_list(srcs_left); src; src = (image_win_type *) next_in_list(srcs_left)) { if (SAME_REGIONS(base_src, src)) { add_rect_to_image_region(new_reg, src->x_vis, src->y_vis, src->width, src->height); } else { if (!image_only || src_in_image(src, numImageVisuals, pImageVisuals)) { subtr_rect_from_image_region(new_reg, src->x_vis, src->y_vis, src->width, src->height); } } } XIntersectRegion(bbox_region, new_reg->visible_region, new_reg->visible_region); if (!XEmptyRegion(new_reg->visible_region)) { add_to_list(image_regions, new_reg); if (new_reg->vis != DefaultVisualOfScreen(win_attrs.screen) || new_reg->cmap != DefaultColormapOfScreen(win_attrs.screen)) { *hasNonDefault = True; } } else { XDestroyRegion(new_reg->visible_region); free(new_reg); } } } else *allImage = 0; } delete_list(&image_wins, True); XDestroyRegion(bbox_region); return image_regions; } /** ------------------------------------------------------------------------ Destructor called from destroy_region_list(). ------------------------------------------------------------------------ **/ static void destroy_image_region(image_region_type *image_region) { XDestroyRegion(image_region->visible_region); free(image_region); } /** ------------------------------------------------------------------------ Destroys the region list, destroying all the regions contained in it. ------------------------------------------------------------------------ **/ static void destroy_region_list(list_ptr rlist) { delete_list_destroying(rlist, (DESTRUCT_FUNC_PTR) destroy_image_region); } /** ------------------------------------------------------------------------ Subtracts the specified rectangle from the region in image_region. First converts the rectangle to a region of its own, since X only provides a way to subtract one region from another, not a rectangle from a region. ------------------------------------------------------------------------ **/ static void subtr_rect_from_image_region(image_region_type *image_region, int x, int y, int width, int height) { XRectangle rect; Region rect_region; rect_region = XCreateRegion(); rect.x = x; rect.y = y; rect.width = width; rect.height = height; XUnionRectWithRegion(&rect, rect_region, rect_region); XSubtractRegion(image_region->visible_region, rect_region, image_region->visible_region); XDestroyRegion(rect_region); } /** ------------------------------------------------------------------------ Adds the specified rectangle to the region in image_region. ------------------------------------------------------------------------ **/ static void add_rect_to_image_region(image_region_type *image_region, int x, int y, int width, int height) { XRectangle rect; rect.x = x; rect.y = y; rect.width = width; rect.height = height; XUnionRectWithRegion(&rect, image_region->visible_region, image_region->visible_region); } /** ------------------------------------------------------------------------ Returns TRUE if the given src's visual is already represented in the image_regions list, FALSE otherwise. ------------------------------------------------------------------------ **/ static int src_in_region_list(image_win_type *src, list_ptr image_regions) { image_region_type *ir; for (ir = (image_region_type *) first_in_list(image_regions); ir; ir = (image_region_type *) next_in_list(image_regions)) { if (SAME_REGIONS(ir, src)) { return 1; } } return 0; } /** ------------------------------------------------------------------------ Makes a new entry in image_wins with the given fields filled in. ------------------------------------------------------------------------ **/ static void add_window_to_list(list_ptr image_wins, Window w, int xrr, int yrr, int x_vis, int y_vis, int width, int height, int border_width, Visual *vis, Colormap cmap, Window parent) { image_win_type *new_src; if ((new_src = malloc(sizeof(image_win_type))) == NULL) return; new_src->win = w; new_src->x_rootrel = xrr; new_src->y_rootrel = yrr; new_src->x_vis = x_vis; new_src->y_vis = y_vis; new_src->width = width; new_src->height = height; new_src->border_width = border_width; new_src->vis = vis; new_src->cmap = cmap; new_src->parent = parent; add_to_list(image_wins, new_src); } /** ------------------------------------------------------------------------ Returns TRUE if the given src's visual is in the image planes, FALSE otherwise. ------------------------------------------------------------------------ **/ static int src_in_image(image_win_type *src, int numImageVisuals, XVisualInfo **pImageVisuals) { int i; for (i = 0; i < numImageVisuals; i++) { if (pImageVisuals[i]->visual == src->vis) return 1; } return 0; } /** ------------------------------------------------------------------------ Returns TRUE if the given src's visual is in the overlay planes and transparency is possible, FALSE otherwise. ------------------------------------------------------------------------ **/ static int src_in_overlay(image_region_type *src, int numOverlayVisuals, OverlayInfo *pOverlayVisuals, int *transparentColor, int *transparentType) { int i; for (i = 0; i < numOverlayVisuals; i++) { if (((pOverlayVisuals[i].pOverlayVisualInfo)->visual == src->vis) && (pOverlayVisuals[i].transparentType != None)) { *transparentColor = pOverlayVisuals[i].value; *transparentType = pOverlayVisuals[i].transparentType; return 1; } } return 0; } /********************** from wsutils.c ******************************/ /****************************************************************************** * * This file contains a set of example utility procedures; procedures that can * help a "window-smart" Starbase or PHIGS program determine information about * a device, and create image and overlay plane windows. To use these * utilities, #include "wsutils.h" and compile this file and link the results * with your program. * ******************************************************************************/ static int weCreateServerOverlayVisualsProperty = False; /****************************************************************************** * * GetXVisualInfo() * * This routine takes an X11 Display, screen number, and returns whether the * screen supports transparent overlays and three arrays: * * 1) All of the XVisualInfo struct's for the screen. * 2) All of the OverlayInfo struct's for the screen. * 3) An array of pointers to the screen's image plane XVisualInfo * structs. * * The code below obtains the array of all the screen's visuals, and obtains * the array of all the screen's overlay visual information. It then processes * the array of the screen's visuals, determining whether the visual is an * overlay or image visual. * * If the routine successfully obtained the visual information, it returns zero. * If the routine didn't obtain the visual information, it returns non-zero. * ******************************************************************************/ int GetXVisualInfo( /* Which X server (aka "display"). */ Display *display, /* Which screen of the "display". */ int screen, /* Non-zero if there's at least one overlay visual and * if at least one of those supports a transparent pixel. */ int *transparentOverlays, /* Number of XVisualInfo struct's pointed to by pVisuals. */ int *numVisuals, /* All of the device's visuals. */ XVisualInfo **pVisuals, /* Number of OverlayInfo's pointed to by pOverlayVisuals. * If this number is zero, the device does not have * overlay planes. */ int *numOverlayVisuals, /* The device's overlay plane visual information. */ OverlayInfo **pOverlayVisuals, /* Number of XVisualInfo's pointed to by pImageVisuals. */ int *numImageVisuals, /* The device's image visuals. */ XVisualInfo ***pImageVisuals) { XVisualInfo getVisInfo; /* Parameters of XGetVisualInfo */ int mask; XVisualInfo *pVis, **pIVis; /* Faster, local copies */ OverlayVisualPropertyRec *pOOldVis; int nVisuals; Atom overlayVisualsAtom; /* Parameters for XGetWindowProperty */ Atom actualType; unsigned long numLongs, bytesAfter; int actualFormat; int nImageVisualsAlloced; /* Values to process the XVisualInfo */ /* First, get the list of visuals for this screen. */ getVisInfo.screen = screen; mask = VisualScreenMask; *pVisuals = XGetVisualInfo(display, mask, &getVisInfo, numVisuals); if ((nVisuals = *numVisuals) <= 0) { /* Return that the information wasn't successfully obtained: */ return (1); } pVis = *pVisuals; /* Now, get the overlay visual information for this screen. To obtain * this information, get the SERVER_OVERLAY_VISUALS property. */ overlayVisualsAtom = XInternAtom(display, "SERVER_OVERLAY_VISUALS", True); if (overlayVisualsAtom != None) { /* Since the Atom exists, we can request the property's contents. The * do-while loop makes sure we get the entire list from the X server. */ bytesAfter = 0; numLongs = sizeof(OverlayVisualPropertyRec) / sizeof(long); do { numLongs += bytesAfter * sizeof(long); XGetWindowProperty(display, RootWindow(display, screen), overlayVisualsAtom, 0, numLongs, False, overlayVisualsAtom, &actualType, &actualFormat, &numLongs, &bytesAfter, (unsigned char **) pOverlayVisuals); } while (bytesAfter > 0); /* Calculate the number of overlay visuals in the list. */ *numOverlayVisuals = numLongs / (sizeof(OverlayVisualPropertyRec) / sizeof(long)); } else { /* This screen doesn't have overlay planes. */ *numOverlayVisuals = 0; *pOverlayVisuals = NULL; *transparentOverlays = 0; } /* Process the pVisuals array. */ *numImageVisuals = 0; nImageVisualsAlloced = 1; pIVis = *pImageVisuals = malloc(sizeof(XVisualInfo *)); while (--nVisuals >= 0) { int nOVisuals = *numOverlayVisuals; OverlayInfo *pOVis = *pOverlayVisuals; int imageVisual = True; while (--nOVisuals >= 0) { pOOldVis = (OverlayVisualPropertyRec *) pOVis; if (pVis->visualid == pOOldVis->visualID) { imageVisual = False; pOVis->pOverlayVisualInfo = pVis; if (pOVis->transparentType == TransparentPixel) *transparentOverlays = 1; } pOVis++; } if (imageVisual) { if ((*numImageVisuals += 1) > nImageVisualsAlloced) { nImageVisualsAlloced++; *pImageVisuals = (XVisualInfo **) realloc(*pImageVisuals, (nImageVisualsAlloced * sizeof(XVisualInfo *))); pIVis = *pImageVisuals + (*numImageVisuals - 1); } *pIVis++ = pVis; } pVis++; } /* Return that the information was successfully obtained: */ return (0); } /* GetXVisualInfo() */ /****************************************************************************** * * FreeXVisualInfo() * * This routine frees the data that was allocated by GetXVisualInfo(). * ******************************************************************************/ void FreeXVisualInfo(XVisualInfo *pVisuals, OverlayInfo *pOverlayVisuals, XVisualInfo **pImageVisuals) { XFree(pVisuals); if (weCreateServerOverlayVisualsProperty) free(pOverlayVisuals); else XFree(pOverlayVisuals); free(pImageVisuals); } /* FreeXVisualInfo() */