#include <X11/Xos.h>
#include <X11/Xlib.h>
#include <X11/Xutil.h>
#include <X11/Xatom.h>
#include <stdio.h>
#include <X11/XWDFile.h>
#define XK_LATIN1
#include <X11/keysymdef.h>
#include <errno.h>
#include <stdlib.h>
Atom wm_protocols;
Atom wm_delete_window;
int split;
char *progname;
static void usage(void);
static Bool Read(char *ptr, int size, int nitems, FILE *stream);
static void putImage(Display *dpy, Window image_win, GC gc,
XImage *out_image, int x, int y, int w, int h);
static void putScaledImage(Display *display, Drawable d, GC gc,
XImage *src_image, int exp_x, int exp_y,
unsigned int exp_width, unsigned int exp_height,
unsigned int dest_width, unsigned dest_height);
static void Latin1Upper(char *s);
static void Extract_Plane(XImage *in_image, XImage *out_image, int plane);
static int EffectiveSize(XVisualInfo *vinfo);
static int VisualRank(int class);
static int IsGray(Display *dpy, XStandardColormap *stdmap);
static void Do_StdGray(Display *dpy, XStandardColormap *stdmap, int ncolors,
XColor *colors, XImage *in_image, XImage *out_image);
static void Do_StdCol(Display *dpy, XStandardColormap *stdmap, int ncolors,
XColor *colors, XImage *in_image, XImage *out_image);
static Colormap CopyColormapAndFree(Display *dpy, Colormap colormap);
static void Do_Pseudo(Display *dpy, Colormap *colormap, int ncolors,
XColor *colors, XImage *in_image, XImage *out_image);
static void Do_Direct(Display *dpy, XWDFileHeader *header, Colormap *colormap,
int ncolors, XColor *colors,
XImage *in_image, XImage *out_image, XVisualInfo *vinfo);
static unsigned int Image_Size(XImage *image);
static void Error(char *string);
static void _swapshort(char *bp, unsigned int n);
static void _swaplong(char *bp, unsigned int n);
static void DumpHeader(const XWDFileHeader *header, const char *win_name);
static void
usage(void)
{
fprintf(stderr, "usage: %s [-in <file>] [-noclick] [-geometry <geom>] [-display <display>]\n", progname);
fprintf(stderr, " [-new] [-std <maptype>] [-raw] [-vis <vis-type-or-id>]\n");
fprintf(stderr, " [-help] [-rv] [-plane <number>] [-fg <color>] [-bg <color>]\n");
fprintf(stderr, " [-scale]\n");
exit(1);
}
static Bool
Read(char *ptr, int size, int nitems, FILE *stream)
{
size *= nitems;
while (size) {
nitems = fread(ptr, 1, size, stream);
if (nitems <= 0)
return False;
size -= nitems;
ptr += nitems;
}
return True;
}
int
main(int argc, char *argv[])
{
Display *dpy;
int screen;
register int i;
XImage in_image_struct;
XImage *in_image, *out_image;
XSetWindowAttributes attributes;
XVisualInfo vinfo, *vinfos;
long mask;
register char *buffer;
unsigned long swaptest = 1;
int count, stdcnt;
unsigned buffer_size;
int win_name_size;
int ncolors;
char *file_name = NULL;
char *win_name;
Bool inverse = False, rawbits = False, newmap = False;
Bool onclick = True;
Bool scale = False;
int plane = -1;
char *std = NULL;
char *vis = NULL;
char *display_name = NULL;
char *fgname = NULL;
char *bgname = NULL;
char *geom = NULL;
int gbits = 0;
XSizeHints hints;
XTextProperty textprop;
XClassHint class_hint;
XColor *colors = NULL, color, igncolor;
Window image_win;
Colormap colormap;
XEvent event;
register XExposeEvent *expose = (XExposeEvent *)&event;
GC gc;
XGCValues gc_val;
XWDFileHeader header;
XWDColor xwdcolor;
FILE *in_file = stdin;
char *map_name;
Atom map_prop;
XStandardColormap *stdmaps, *stdmap = NULL;
char c;
int win_width, win_height;
Bool dump_header = False;
progname = argv[0];
for (i = 1; i < argc; i++) {
if (strcmp(argv[i], "-bg") == 0) {
if (++i >= argc) usage();
bgname = argv[i];
continue;
}
if (strcmp(argv[i], "-display") == 0) {
if (++i >= argc) usage();
display_name = argv[i];
continue;
}
if (strcmp(argv[i], "-dumpheader") == 0) {
dump_header = True;
continue;
}
if (strcmp(argv[i], "-fg") == 0) {
if (++i >= argc) usage();
fgname = argv[i];
continue;
}
if (strcmp(argv[i], "-geometry") == 0) {
if (++i >= argc) usage();
geom = argv[i];
continue;
}
if (strcmp(argv[i], "-help") == 0) {
usage();
}
if (strcmp(argv[i], "-in") == 0) {
if (++i >= argc) usage();
file_name = argv[i];
continue;
}
if (strcmp(argv[i], "-inverse") == 0) {
inverse = True;
continue;
}
if (strcmp(argv[i], "-new") == 0) {
newmap = True;
if (std) usage();
continue;
}
if (strcmp(argv[i], "-noclick") == 0) {
onclick = False;
continue;
}
if (strcmp(argv[i], "-plane") == 0) {
if (++i >= argc) usage();
plane = atoi(argv[i]);
continue;
}
if (strcmp(argv[i], "-raw") == 0) {
rawbits = True;
if (std) usage();
continue;
}
if (strcmp(argv[i], "-rv") == 0) {
inverse = True;
continue;
}
if (strcmp(argv[i], "-scale") == 0) {
scale = True;
continue;
}
if (strcmp(argv[i], "-split") == 0) {
split = True;
continue;
}
if (strcmp(argv[i], "-std") == 0) {
if (++i >= argc) usage();
std = argv[i];
if (newmap || rawbits) usage();
continue;
}
if (strcmp(argv[i], "-vis") == 0) {
if (++i >= argc) usage();
vis = argv[i];
continue;
}
usage();
}
if (file_name) {
in_file = fopen(file_name, "rb");
if (in_file == NULL)
Error("Can't open input file as specified.");
}
#ifdef WIN32
else
_setmode(fileno(in_file), _O_BINARY);
#endif
dpy = XOpenDisplay(display_name);
if (dpy == NULL) {
fprintf(stderr, "%s: unable to open display \"%s\"\n",
progname, XDisplayName(display_name));
exit(1);
}
screen = DefaultScreen(dpy);
if(!Read((char *)&header, SIZEOF(XWDheader), 1, in_file))
Error("Unable to read dump file header.");
if (*(char *) &swaptest)
_swaplong((char *) &header, SIZEOF(XWDheader));
if (header.file_version != XWD_FILE_VERSION) {
fprintf(stderr,"xwud: XWD file format version mismatch.");
Error("exiting.");
}
if (header.header_size < SIZEOF(XWDheader)) {
fprintf(stderr,"xwud: XWD header size is too small.");
Error("exiting.");
}
win_name_size = (header.header_size - SIZEOF(XWDheader));
if((win_name = malloc((unsigned) win_name_size + 6)) == NULL)
Error("Can't malloc window name storage.");
strcpy(win_name, "xwud: ");
if(!Read(win_name + 6, sizeof(char), win_name_size, in_file))
Error("Unable to read window name from dump file.");
if (dump_header) {
DumpHeader(&header, win_name);
exit(0);
}
in_image = &in_image_struct;
in_image->depth = header.pixmap_depth;
in_image->format = header.pixmap_format;
in_image->xoffset = header.xoffset;
in_image->data = NULL;
in_image->width = header.pixmap_width;
in_image->height = header.pixmap_height;
in_image->bitmap_pad = header.bitmap_pad;
in_image->bytes_per_line = header.bytes_per_line;
in_image->byte_order = header.byte_order;
in_image->bitmap_unit = header.bitmap_unit;
in_image->bitmap_bit_order = header.bitmap_bit_order;
in_image->bits_per_pixel = header.bits_per_pixel;
in_image->red_mask = header.red_mask;
in_image->green_mask = header.green_mask;
in_image->blue_mask = header.blue_mask;
if (!XInitImage(in_image))
Error("Invalid input image header data.");
if((ncolors = header.ncolors)) {
colors = (XColor *)malloc((unsigned) ncolors * sizeof(XColor));
if (!colors)
Error("Can't malloc color table");
for (i = 0; i < ncolors; i++) {
if(!Read((char *) &xwdcolor, SIZEOF(XWDColor), 1, in_file))
Error("Unable to read color map from dump file.");
colors[i].pixel = xwdcolor.pixel;
colors[i].red = xwdcolor.red;
colors[i].green = xwdcolor.green;
colors[i].blue = xwdcolor.blue;
colors[i].flags = xwdcolor.flags;
}
if (*(char *) &swaptest) {
for (i = 0; i < ncolors; i++) {
_swaplong((char *) &colors[i].pixel, sizeof(long));
_swapshort((char *) &colors[i].red, 3 * sizeof(short));
}
}
}
else
rawbits = True;
buffer_size = Image_Size(in_image);
if((buffer = malloc(buffer_size)) == NULL)
Error("Can't malloc data buffer.");
if (!Read(buffer, sizeof(char), (int)buffer_size, in_file))
Error("Unable to read pixmap from dump file.");
(void) fclose(in_file);
if (plane >= in_image->depth)
Error("plane number exceeds image depth");
if ((in_image->format == XYPixmap) && (plane >= 0)) {
buffer += in_image->bytes_per_line * in_image->height *
(in_image->depth - (plane + 1));
in_image->depth = 1;
ncolors = 0;
}
if (in_image->bits_per_pixel == 1 && in_image->depth == 1) {
in_image->format = XYBitmap;
newmap = False;
rawbits = True;
}
in_image->data = buffer;
if (std) {
map_name = malloc(strlen(std) + 9);
strcpy(map_name, "RGB_");
strcat(map_name, std);
strcat(map_name, "_MAP");
Latin1Upper(map_name);
map_prop = XInternAtom(dpy, map_name, True);
if (!map_prop || !XGetRGBColormaps(dpy, RootWindow(dpy, screen),
&stdmaps, &stdcnt, map_prop))
Error("specified standard colormap does not exist");
}
vinfo.screen = screen;
mask = VisualScreenMask;
if (vis)
{
char *vt;
vt = malloc(strlen(vis) + 1);
strcpy(vt, vis);
Latin1Upper(vt);
if (strcmp(vt, "STATICGRAY") == 0) {
vinfo.class = StaticGray;
mask |= VisualClassMask;
} else if (strcmp(vt, "GRAYSCALE") == 0) {
vinfo.class = GrayScale;
mask |= VisualClassMask;
} else if (strcmp(vt, "STATICCOLOR") == 0) {
vinfo.class = StaticColor;
mask |= VisualClassMask;
} else if (strcmp(vt, "PSEUDOCOLOR") == 0) {
vinfo.class = PseudoColor;
mask |= VisualClassMask;
} else if (strcmp(vt, "DIRECTCOLOR") == 0) {
vinfo.class = DirectColor;
mask |= VisualClassMask;
} else if (strcmp(vt, "TRUECOLOR") == 0) {
vinfo.class = TrueColor;
mask |= VisualClassMask;
} else if (strcmp(vt, "MATCH") == 0) {
vinfo.class = header.visual_class;
mask |= VisualClassMask;
} else if (strcmp(vt, "DEFAULT") == 0) {
vinfo.visualid= XVisualIDFromVisual(DefaultVisual(dpy, screen));
mask |= VisualIDMask;
} else {
vinfo.visualid = 0;
mask |= VisualIDMask;
sscanf(vis, "0x%lx", &vinfo.visualid);
if (!vinfo.visualid)
sscanf(vis, "%lu", &vinfo.visualid);
if (!vinfo.visualid)
Error("invalid visual specifier");
}
}
if (rawbits && (in_image->depth > 1) && (plane < 0)) {
vinfo.depth = in_image->depth;
mask |= VisualDepthMask;
}
vinfos = XGetVisualInfo(dpy, mask, &vinfo, &count);
if (count == 0)
Error("no matching visual found");
if (std) {
stdmap = &stdmaps[0];
if (mask & VisualIDMask) {
for (i = 0; i < stdcnt; i++) {
if (stdmaps[i].visualid == vinfo.visualid) {
stdmap = &stdmaps[i];
break;
}
}
if (stdmap->visualid != vinfo.visualid)
Error("no standard colormap matching specified visual");
}
for (i = 0; i < count; i++) {
if (stdmap->visualid == vinfos[i].visualid) {
vinfo = vinfos[i];
break;
}
}
} else if ((in_image->depth == 1) ||
((in_image->format == ZPixmap) && (plane >= 0)) ||
rawbits) {
vinfo = vinfos[0];
if (!(mask & VisualIDMask)) {
for (i = 0; i < count; i++) {
if ((vinfos[i].visualid ==
XVisualIDFromVisual(DefaultVisual(dpy, screen))) &&
(vinfos[i].depth == DefaultDepth(dpy, screen))) {
vinfo = vinfos[i];
break;
}
}
}
} else {
vinfo = vinfos[0];
for (i = 0; i < count; i++) {
int z1, z2;
z2 = EffectiveSize(&vinfos[i]);
if ((z2 >= ncolors) &&
(vinfos[i].depth == in_image->depth) &&
(vinfos[i].class == header.visual_class))
{
vinfo = vinfos[i];
break;
}
z1 = EffectiveSize(&vinfo);
if ((z2 > z1) ||
((z2 == z1) &&
(VisualRank(vinfos[i].class) >= VisualRank(vinfo.class))))
vinfo = vinfos[i];
}
if ((newmap || (vinfo.visual != DefaultVisual(dpy, screen))) &&
(vinfo.class != StaticGray) &&
(vinfo.class != StaticColor) &&
(vinfo.class == header.visual_class) &&
(vinfo.depth == in_image->depth) &&
((vinfo.class == PseudoColor) ||
(vinfo.class == GrayScale) ||
((vinfo.red_mask == header.red_mask) &&
(vinfo.green_mask == header.green_mask) &&
(vinfo.blue_mask == header.blue_mask)))) {
rawbits = True;
newmap = True;
}
}
if (newmap && (vinfo.class & 1) &&
(vinfo.depth == in_image->depth) &&
(vinfo.class == header.visual_class) &&
(vinfo.colormap_size >= ncolors) &&
(vinfo.red_mask == header.red_mask) &&
(vinfo.green_mask == header.green_mask) &&
(vinfo.blue_mask == header.blue_mask)) {
colormap = XCreateColormap(dpy, RootWindow(dpy, screen), vinfo.visual,
AllocAll);
if (ncolors) {
for (i = 0; i < ncolors; i++)
colors[i].flags = DoRed|DoGreen|DoBlue;
XStoreColors(dpy, colormap, colors, ncolors);
}
} else if (std) {
colormap = stdmap->colormap;
} else {
if (!newmap && (vinfo.visual == DefaultVisual(dpy, screen)))
colormap = DefaultColormap(dpy, screen);
else
colormap = XCreateColormap(dpy, RootWindow(dpy, screen),
vinfo.visual, AllocNone);
newmap = False;
}
if ((in_image->format == ZPixmap) && (plane >= 0)) {
out_image = XCreateImage(dpy, vinfo.visual, 1,
XYBitmap, 0, NULL,
in_image->width, in_image->height,
XBitmapPad(dpy), 0);
out_image->data = malloc(Image_Size(out_image));
Extract_Plane(in_image, out_image, plane);
ncolors = 0;
} else if (rawbits || newmap) {
out_image = in_image;
} else {
out_image = XCreateImage(dpy, vinfo.visual, vinfo.depth,
(vinfo.depth == 1) ? XYBitmap :
in_image->format,
in_image->xoffset, NULL,
in_image->width, in_image->height,
XBitmapPad(dpy), 0);
out_image->data = malloc(Image_Size(out_image));
if (std) {
if (!stdmap->green_max && !stdmap->blue_max && IsGray(dpy, stdmap))
Do_StdGray(dpy, stdmap, ncolors, colors, in_image, out_image);
else
Do_StdCol(dpy, stdmap, ncolors, colors, in_image, out_image);
} else if ((header.visual_class == TrueColor) ||
(header.visual_class == DirectColor))
Do_Direct(dpy, &header, &colormap, ncolors, colors,
in_image, out_image, &vinfo);
else
Do_Pseudo(dpy, &colormap, ncolors, colors, in_image, out_image);
}
if (out_image->depth == 1) {
if (fgname &&
XAllocNamedColor(dpy, colormap, fgname, &color, &igncolor))
gc_val.foreground = color.pixel;
else if ((ncolors == 2) && XAllocColor(dpy, colormap, &colors[1]))
gc_val.foreground = colors[1].pixel;
else
gc_val.foreground = BlackPixel (dpy, screen);
if (bgname &&
XAllocNamedColor(dpy, colormap, bgname, &color, &igncolor))
gc_val.background = color.pixel;
else if ((ncolors == 2) && XAllocColor(dpy, colormap, &colors[0]))
gc_val.background = colors[0].pixel;
else
gc_val.background = WhitePixel (dpy, screen);
if (inverse) {
unsigned long tmp;
tmp = gc_val.foreground;
gc_val.foreground = gc_val.background;
gc_val.background = tmp;
}
} else {
gc_val.background = XGetPixel(out_image, 0, 0);
gc_val.foreground = 0;
}
attributes.background_pixel = gc_val.background;
attributes.border_pixel = gc_val.background;
if (scale)
attributes.bit_gravity = ForgetGravity;
else
attributes.bit_gravity = NorthWestGravity;
attributes.event_mask = ButtonPressMask|ButtonReleaseMask|KeyPressMask|
ExposureMask;
if (scale)
attributes.event_mask |= StructureNotifyMask;
attributes.colormap = colormap;
hints.x = header.window_x;
hints.y = header.window_y;
hints.width = out_image->width;
hints.height = out_image->height;
if (geom)
gbits = XParseGeometry(geom, &hints.x, &hints.y,
(unsigned int *)&hints.width,
(unsigned int *)&hints.height);
hints.flags = ((gbits & (XValue|YValue)) ? USPosition : 0) |
((gbits & (HeightValue|WidthValue)) ? USSize : PSize);
if (!scale) {
hints.flags |= PMaxSize;
hints.max_width = (hints.width > out_image->width) ?
hints.width : out_image->width;
hints.max_height = (hints.height > out_image->height) ?
hints.height : out_image->height;
}
if ((gbits & XValue) && (gbits & XNegative))
hints.x += DisplayWidth(dpy, screen) - hints.width;
if ((gbits & YValue) && (gbits & YNegative))
hints.y += DisplayHeight(dpy, screen) - hints.height;
image_win = XCreateWindow(dpy, RootWindow(dpy, screen),
hints.x, hints.y, hints.width, hints.height,
0, vinfo.depth, InputOutput, vinfo.visual,
CWBorderPixel|CWBackPixel|CWColormap|CWEventMask|CWBitGravity,
&attributes);
win_width = hints.width;
win_height = hints.height;
wm_protocols = XInternAtom(dpy, "WM_PROTOCOLS", False);
wm_delete_window = XInternAtom(dpy, "WM_DELETE_WINDOW", False);
(void) XSetWMProtocols (dpy, image_win, &wm_delete_window, 1);
textprop.value = (unsigned char *) win_name;
textprop.encoding = XA_STRING;
textprop.format = 8;
textprop.nitems = strlen(win_name);
class_hint.res_name = (char *)NULL;
class_hint.res_class = "Xwud";
XSetWMProperties(dpy, image_win, &textprop, (XTextProperty *)NULL,
argv, argc, &hints, (XWMHints *)NULL, &class_hint);
XMapWindow(dpy, image_win);
gc = XCreateGC (dpy, image_win, GCForeground|GCBackground, &gc_val);
while (1) {
XNextEvent(dpy, &event);
switch(event.type) {
case ClientMessage:
if (event.xclient.message_type == wm_protocols &&
event.xclient.data.l[0] == wm_delete_window) {
XCloseDisplay(dpy);
exit(0);
}
break;
case ButtonPress:
break;
case ButtonRelease:
if (onclick) {
XCloseDisplay(dpy);
exit(0);
}
break;
case KeyPress:
i = XLookupString(&event.xkey, &c, 1, NULL, NULL);
if ((i == 1) && ((c == 'q') || (c == 'Q') || (c == '\03'))) {
XCloseDisplay(dpy);
exit(0);
}
break;
case ConfigureNotify:
win_width = event.xconfigure.width;
win_height = event.xconfigure.height;
break;
case Expose:
if (scale)
putScaledImage(dpy, image_win, gc, out_image,
expose->x, expose->y,
expose->width, expose->height,
win_width, win_height);
else if ((expose->x < out_image->width) &&
(expose->y < out_image->height)) {
if ((out_image->width - expose->x) < expose->width)
expose->width = out_image->width - expose->x;
if ((out_image->height - expose->y) < expose->height)
expose->height = out_image->height - expose->y;
putImage(dpy, image_win, gc, out_image,
expose->x, expose->y,
expose->width, expose->height);
}
break;
}
}
exit(0);
}
static void
putImage(Display *dpy, Window image_win, GC gc, XImage *out_image,
int x, int y, int w, int h)
{
#define SPLIT_SIZE 100
int t_x, t_y, t_w, t_h;
if (split) {
for (t_y = y; t_y < y + h; t_y += t_h) {
t_h = SPLIT_SIZE;
if (t_y + t_h > y + h)
t_h = y + h - t_y;
for (t_x = x; t_x < x + w; t_x += t_w) {
t_w = SPLIT_SIZE;
if (t_x + t_w > x + w)
t_w = x + w - t_x;
XPutImage(dpy, image_win, gc, out_image,
t_x, t_y, t_x, t_y, t_w, t_h);
}
}
} else {
XPutImage (dpy, image_win, gc, out_image, x, y, x, y, w, h);
}
}
typedef short Position;
typedef unsigned short Dimension;
typedef unsigned long Pixel;
#define roundint(x) (int)((x) + 0.5)
typedef struct {
Position *x, *y;
Dimension *width, *height;
} Table;
static void
putScaledImage(Display *display, Drawable d, GC gc, XImage *src_image,
int exp_x, int exp_y,
unsigned int exp_width, unsigned int exp_height,
unsigned int dest_width, unsigned dest_height)
{
XImage *dest_image;
Position x, y, min_y, max_y, exp_max_y, src_x, src_max_x, src_y;
Dimension w, h, strip_height;
Table table;
Pixel pixel;
double ratio_x, ratio_y;
Bool fast8;
if (dest_width == src_image->width && dest_height == src_image->height) {
XPutImage(display, d, gc, src_image, exp_x, exp_y,
exp_x, exp_y, exp_width, exp_height);
return;
}
ratio_x = (double)dest_width / (double)src_image->width;
ratio_y = (double)dest_height / (double)src_image->height;
src_x = exp_x / ratio_x;
if (src_x >= src_image->width)
src_x = src_image->width - 1;
src_y = exp_y / ratio_y;
if (src_y >= src_image->height)
src_y = src_image->height - 1;
exp_max_y = exp_y + exp_height;
src_max_x = roundint((exp_x + exp_width) / ratio_x) + 1;
if (src_max_x > src_image->width)
src_max_x = src_image->width;
strip_height = 65536 / roundint(ratio_x * src_image->bytes_per_line);
if (strip_height == 0)
strip_height = 1;
if (strip_height > exp_height)
strip_height = exp_height;
h = strip_height + roundint(ratio_y);
dest_image = XCreateImage(display,
DefaultVisualOfScreen(
DefaultScreenOfDisplay(display)),
src_image->depth, src_image->format,
0, NULL,
dest_width, h,
src_image->bitmap_pad, 0);
dest_image->data = malloc(dest_image->bytes_per_line * h);
fast8 = (src_image->depth == 8 && src_image->bits_per_pixel == 8 &&
dest_image->bits_per_pixel == 8 && src_image->format == ZPixmap);
table.x = (Position *) malloc(sizeof(Position) * (src_image->width + 1));
table.y = (Position *) malloc(sizeof(Position) * (src_image->height + 1));
table.width = (Dimension *) malloc(sizeof(Dimension) * src_image->width);
table.height = (Dimension *) malloc(sizeof(Dimension)*src_image->height);
table.x[0] = 0;
for (x = 1; x <= src_image->width; x++) {
table.x[x] = roundint(ratio_x * x);
table.width[x - 1] = table.x[x] - table.x[x - 1];
}
table.y[0] = 0;
for (y = 1; y <= src_image->height; y++) {
table.y[y] = roundint(ratio_y * y);
table.height[y - 1] = table.y[y] - table.y[y - 1];
}
for (min_y = table.y[src_y]; min_y < exp_max_y; min_y = table.y[y]) {
max_y = min_y + strip_height;
if (max_y > exp_max_y) {
strip_height = exp_max_y - min_y;
max_y = exp_max_y;
}
for (y = src_y; table.y[y] < max_y; y++) {
if (table.y[y] < min_y)
continue;
if (fast8) {
for (x = src_x; x < src_max_x; x++) {
pixel = ((unsigned char *)src_image->data)
[y * src_image->bytes_per_line + x];
for (h = 0; h < table.height[y]; h++) {
memset(dest_image->data +
(table.y[y] + h - min_y) *
dest_image->bytes_per_line + table.x[x],
pixel, table.width[x]);
}
}
} else {
for (x = src_x; x < src_max_x; x++) {
pixel = XGetPixel(src_image, x, y);
for (h = 0; h < table.height[y]; h++) {
for (w = 0; w < table.width[x]; w++)
XPutPixel(dest_image,
table.x[x] + w,
table.y[y] + h - min_y,
pixel);
}
}
}
}
XPutImage(display, d, gc, dest_image, exp_x, 0,
exp_x, min_y, exp_width, table.y[y] - min_y);
if (y >= src_image->height)
break;
}
XFree((char *)table.x);
XFree((char *)table.y);
XFree((char *)table.width);
XFree((char *)table.height);
XDestroyImage(dest_image);
}
static void
Latin1Upper(char *s)
{
unsigned char *str = (unsigned char *)s;
unsigned char c;
for (; (c = *str); str++)
{
if ((c >= XK_a) && (c <= XK_z))
*str = c - (XK_a - XK_A);
else if ((c >= XK_agrave) && (c <= XK_odiaeresis))
*str = c - (XK_agrave - XK_Agrave);
else if ((c >= XK_oslash) && (c <= XK_thorn))
*str = c - (XK_oslash - XK_Ooblique);
}
}
static void
Extract_Plane(XImage *in_image, XImage *out_image, int plane)
{
register int x, y;
for (y = 0; y < in_image->height; y++)
for (x = 0; x < in_image->width; x++)
XPutPixel(out_image, x, y,
(XGetPixel(in_image, x, y) >> plane) & 1);
}
static int
EffectiveSize(XVisualInfo *vinfo)
{
if ((vinfo->class == DirectColor) || (vinfo->class == TrueColor))
return (vinfo->red_mask | vinfo->green_mask | vinfo->blue_mask) + 1;
else
return vinfo->colormap_size;
}
static int
VisualRank(int class)
{
switch (class) {
case PseudoColor:
return 5;
case TrueColor:
return 4;
case DirectColor:
return 3;
case StaticColor:
return 2;
case GrayScale:
return 1;
case StaticGray:
return 0;
}
return -1;
}
static int
IsGray(Display *dpy, XStandardColormap *stdmap)
{
XColor color;
color.pixel = stdmap->base_pixel + (stdmap->red_max * stdmap->red_mult);
XQueryColor(dpy, stdmap->colormap, &color);
return (color.green || color.blue);
}
static void
Do_StdGray(Display *dpy, XStandardColormap *stdmap,
int ncolors, XColor *colors, XImage *in_image, XImage *out_image)
{
register int i, x, y;
register XColor *color;
unsigned lim;
lim = stdmap->red_max + 1;
for (i = 0, color = colors; i < ncolors; i++, color++)
color->pixel = stdmap->base_pixel +
(((((int)(30L * color->red +
59L * color->green +
11L * color->blue) / 100)
* lim) >> 16) * stdmap->red_mult);
for (y = 0; y < in_image->height; y++) {
for (x = 0; x < in_image->width; x++) {
XPutPixel(out_image, x, y,
colors[XGetPixel(in_image, x, y)].pixel);
}
}
}
#define MapVal(val,lim,mult) ((((val * lim) + 32768) / 65535) * mult)
static void
Do_StdCol(Display *dpy, XStandardColormap *stdmap,
int ncolors, XColor *colors, XImage *in_image, XImage *out_image)
{
register int i, x, y;
register XColor *color;
unsigned limr, limg, limb;
limr = stdmap->red_max;
limg = stdmap->green_max;
limb = stdmap->blue_max;
for (i = 0, color = colors; i < ncolors; i++, color++)
color->pixel = stdmap->base_pixel +
MapVal(color->red, limr, stdmap->red_mult) +
MapVal(color->green, limg, stdmap->green_mult) +
MapVal(color->blue, limb, stdmap->blue_mult);
for (y = 0; y < in_image->height; y++) {
for (x = 0; x < in_image->width; x++) {
XPutPixel(out_image, x, y,
colors[XGetPixel(in_image, x, y)].pixel);
}
}
}
static Colormap
CopyColormapAndFree(Display *dpy, Colormap colormap)
{
if (colormap == DefaultColormap(dpy, DefaultScreen(dpy)))
return XCopyColormapAndFree(dpy, colormap);
Error("Visual type is not large enough to hold all colors of the image.");
return (Colormap)0;
}
static void
Do_Pseudo(Display *dpy, Colormap *colormap,
int ncolors, XColor *colors, XImage *in_image, XImage *out_image)
{
register int i, x, y;
register XColor *color;
for (i = 0; i < ncolors; i++)
colors[i].flags = 0;
for (y = 0; y < in_image->height; y++) {
for (x = 0; x < in_image->width; x++) {
color = &colors[XGetPixel(in_image, x, y)];
if (!color->flags) {
color->flags = DoRed | DoGreen | DoBlue;
if (!XAllocColor(dpy, *colormap, color)) {
*colormap = CopyColormapAndFree(dpy, *colormap);
XAllocColor(dpy, *colormap, color);
}
}
XPutPixel(out_image, x, y, color->pixel);
}
}
}
static void
Do_Direct(Display *dpy, XWDFileHeader *header, Colormap *colormap,
int ncolors, XColor *colors, XImage *in_image, XImage *out_image,
XVisualInfo *vinfo)
{
register int x, y;
XColor color;
unsigned long rmask, gmask, bmask;
unsigned long ormask, ogmask, obmask;
unsigned long rshift = 0, gshift = 0, bshift = 0;
unsigned long orshift = 0, ogshift = 0, obshift = 0;
int i;
unsigned long pix, xpix;
unsigned long *pixels, *rpixels;
rmask = header->red_mask;
while (!(rmask & 1)) {
rmask >>= 1;
rshift++;
}
gmask = header->green_mask;
while (!(gmask & 1)) {
gmask >>= 1;
gshift++;
}
bmask = header->blue_mask;
while (!(bmask & 1)) {
bmask >>= 1;
bshift++;
}
if (in_image->depth <= 12) {
pix = 1 << in_image->depth;
pixels = (unsigned long *)malloc(sizeof(unsigned long) * pix);
for (i = 0; i < pix; i++)
pixels[i] = ~0L;
color.flags = DoRed | DoGreen | DoBlue;
for (y = 0; y < in_image->height; y++) {
for (x = 0; x < in_image->width; x++) {
pix = XGetPixel(in_image, x, y);
if ((color.pixel = pixels[pix]) == ~0L) {
color.red = (pix >> rshift) & rmask;
color.green = (pix >> gshift) & gmask;
color.blue = (pix >> bshift) & bmask;
if (ncolors) {
color.red = colors[color.red].red;
color.green = colors[color.green].green;
color.blue = colors[color.blue].blue;
} else {
color.red = (((unsigned long)color.red * 65535) /
rmask);
color.green = (((unsigned long)color.green * 65535) /
gmask);
color.blue = (((unsigned long)color.blue * 65535) /
bmask);
}
if (!XAllocColor(dpy, *colormap, &color)) {
*colormap = CopyColormapAndFree(dpy, *colormap);
XAllocColor(dpy, *colormap, &color);
}
pixels[pix] = color.pixel;
}
XPutPixel(out_image, x, y, color.pixel);
}
}
} else if (header->visual_class == TrueColor &&
vinfo->class == TrueColor) {
ormask = vinfo->red_mask;
while (!(ormask & 1)) {
ormask >>= 1;
orshift++;
}
ogmask = vinfo->green_mask;
while (!(ogmask & 1)) {
ogmask >>= 1;
ogshift++;
}
obmask = vinfo->blue_mask;
while (!(obmask & 1)) {
obmask >>= 1;
obshift++;
}
for (y = 0; y < in_image->height; y++) {
for (x = 0; x < in_image->width; x++) {
pix = XGetPixel(in_image, x, y);
xpix = (((((pix >> rshift) & rmask) * 65535 / rmask)
* ormask / 65535) << orshift) |
(((((pix >> gshift) & gmask) * 65535 / gmask)
* ogmask / 65535) << ogshift) |
(((((pix >> bshift) & bmask) * 65535 / bmask)
* obmask / 65535) << obshift);
XPutPixel(out_image, x, y, xpix);
}
}
} else {
if (header->visual_class == TrueColor)
ncolors = 0;
pix = 1 << 12;
pixels = (unsigned long *)malloc(sizeof(unsigned long) * pix);
rpixels = (unsigned long *)malloc(sizeof(unsigned long) * pix);
for (i = 0; i < pix; i++) {
pixels[i] = ~0L;
rpixels[i] = ~0L;
}
color.flags = DoRed | DoGreen | DoBlue;
for (y = 0; y < in_image->height; y++) {
for (x = 0; x < in_image->width; x++) {
pix = XGetPixel(in_image, x, y);
xpix = ((pix >> 12) ^ pix) & ((1 << 12) - 1);
if (((color.pixel = pixels[xpix]) == ~0L) ||
(rpixels[xpix] != pix)) {
color.red = (pix >> rshift) & rmask;
color.green = (pix >> gshift) & gmask;
color.blue = (pix >> bshift) & bmask;
if (ncolors) {
color.red = colors[color.red].red;
color.green = colors[color.green].green;
color.blue = colors[color.blue].blue;
} else {
color.red = (((unsigned long)color.red * 65535) /
rmask);
color.green = (((unsigned long)color.green * 65535) /
gmask);
color.blue = (((unsigned long)color.blue * 65535) /
bmask);
}
if (!XAllocColor(dpy, *colormap, &color)) {
*colormap = CopyColormapAndFree(dpy, *colormap);
XAllocColor(dpy, *colormap, &color);
}
pixels[xpix] = color.pixel;
rpixels[xpix] = pix;
}
XPutPixel(out_image, x, y, color.pixel);
}
}
}
}
static unsigned int
Image_Size(XImage *image)
{
if (image->format != ZPixmap)
return(image->bytes_per_line * image->height * image->depth);
return((unsigned)image->bytes_per_line * image->height);
}
static void
Error(char *string)
{
fprintf(stderr, "xwud: Error => %s\n", string);
if (errno != 0) {
perror("xwud");
fprintf(stderr, "\n");
}
exit(1);
}
static void
_swapshort(char *bp, unsigned int n)
{
register char c;
register char *ep = bp + n;
while (bp < ep) {
c = *bp;
*bp = *(bp + 1);
bp++;
*bp++ = c;
}
}
static void
_swaplong(char *bp, unsigned int n)
{
register char c;
register char *ep = bp + n;
register char *sp;
while (bp < ep) {
sp = bp + 3;
c = *sp;
*sp = *bp;
*bp++ = c;
sp = bp + 1;
c = *sp;
*sp = *bp;
*bp++ = c;
bp += 2;
}
}
static void
DumpHeader(const XWDFileHeader *header, const char *win_name)
{
printf("window name: %s\n", win_name);
printf("sizeof(XWDheader): %d\n", (int)sizeof(*header));
printf("header size: %d\n", (int)header->header_size);
printf("file version: %d\n", (int)header->file_version);
printf("pixmap format: %d\n", (int)header->pixmap_format);
printf("pixmap depth: %d\n", (int)header->pixmap_depth);
printf("pixmap width: %d\n", (int)header->pixmap_width);
printf("pixmap height: %d\n", (int)header->pixmap_height);
printf("x offset: %d\n", (int)header->xoffset);
printf("byte order: %d\n", (int)header->byte_order);
printf("bitmap unit: %d\n", (int)header->bitmap_unit);
printf("bitmap bit order: %d\n", (int)header->bitmap_bit_order);
printf("bitmap pad: %d\n", (int)header->bitmap_pad);
printf("bits per pixel: %d\n", (int)header->bits_per_pixel);
printf("bytes per line: %d\n", (int)header->bytes_per_line);
printf("visual class: %d\n", (int)header->visual_class);
printf("red mask: %d\n", (int)header->red_mask);
printf("green mask: %d\n", (int)header->green_mask);
printf("blue mask: %d\n", (int)header->blue_mask);
printf("bits per rgb: %d\n", (int)header->bits_per_rgb);
printf("colormap entries: %d\n", (int)header->colormap_entries);
printf("num colors: %d\n", (int)header->ncolors);
printf("window width: %d\n", (int)header->window_width);
printf("window height: %d\n", (int)header->window_height);
printf("window x: %d\n", (int)header->window_x);
printf("window y: %d\n", (int)header->window_y);
printf("border width: %d\n", (int)header->window_bdrwidth);
}