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ac4053478a29a8661a9d26e84e233ca5c233bb73
wmaker/wrlib/convert.c
kojima ac4053478a updated po files, fixed some bugs
1999-09-16 03:01:14 +00:00

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/* convert.c - convert RImage to Pixmap
*
* Raster graphics library
*
* Copyright (c) 1997 Alfredo K. Kojima
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the Free
* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <config.h>
/* AIX requires this to be the first thing in the file. */
#ifdef __GNUC__
# define alloca __builtin_alloca
#else
# if HAVE_ALLOCA_H
# include <alloca.h>
# else
# ifdef _AIX
# pragma alloca
# else
# ifndef alloca /* predefined by HP cc +Olibcalls */
char *alloca ();
# endif
# endif
# endif
#endif
#include <X11/Xlib.h>
#include <X11/Xutil.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include "wraster.h"
#ifdef XSHM
Pixmap R_CreateXImageMappedPixmap(RContext *context, RXImage *ximage);
#endif
typedef struct RConversionTable {
unsigned short table[256];
unsigned short index;
struct RConversionTable *next;
} RConversionTable;
static RConversionTable *conversionTable = NULL;
static unsigned short*
computeTable(unsigned short mask)
{
RConversionTable *tmp = conversionTable;
int i;
while (tmp) {
if (tmp->index == mask)
break;
tmp = tmp->next;
}
if (tmp)
return tmp->table;
tmp = (RConversionTable *)malloc(sizeof(RConversionTable));
if (tmp == NULL)
return NULL;
for (i=0;i<256;i++)
tmp->table[i] = (i*mask + 0x7f)/0xff;
tmp->index = mask;
tmp->next = conversionTable;
conversionTable = tmp;
return tmp->table;
}
static RXImage*
image2TrueColorD16(RContext *ctx, RImage *image)
{
RXImage *ximg;
register int x, y, r, g, b;
unsigned char *red, *grn, *blu;
unsigned short rmask, gmask, bmask;
unsigned short roffs, goffs, boffs;
unsigned short *rtable, *gtable, *btable;
int ofs;
ximg = RCreateXImage(ctx, ctx->depth, image->width, image->height);
if (!ximg) {
return NULL;
}
red = image->data[0];
grn = image->data[1];
blu = image->data[2];
roffs = ctx->red_offset;
goffs = ctx->green_offset;
boffs = ctx->blue_offset;
rmask = ctx->visual->red_mask >> roffs;
gmask = ctx->visual->green_mask >> goffs;
bmask = ctx->visual->blue_mask >> boffs;
rtable = computeTable(rmask);
gtable = computeTable(gmask);
btable = computeTable(bmask);
if (rtable==NULL || gtable==NULL || btable==NULL) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
{
/* dither */
short *rerr, *gerr, *berr;
short *nrerr, *ngerr, *nberr;
short *terr;
unsigned short *dataP;
int line_offset;
int rer, ger, ber;
const int dr=0xff/rmask;
const int dg=0xff/gmask;
const int db=0xff/bmask;
rerr = (short*)alloca((image->width+2)*sizeof(short));
gerr = (short*)alloca((image->width+2)*sizeof(short));
berr = (short*)alloca((image->width+2)*sizeof(short));
nrerr = (short*)alloca((image->width+2)*sizeof(short));
ngerr = (short*)alloca((image->width+2)*sizeof(short));
nberr = (short*)alloca((image->width+2)*sizeof(short));
if (!rerr || !gerr || !berr || !nrerr || !ngerr || !nberr) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
for (x=0; x<image->width; x++) {
rerr[x] = red[x];
gerr[x] = grn[x];
berr[x] = blu[x];
}
rerr[x] = gerr[x] = berr[x] = 0;
dataP = (unsigned short*)ximg->image->data;
line_offset = ximg->image->bytes_per_line - image->width * 2;
/* convert and dither the image to XImage */
for (y=0, ofs=0; y<image->height; y++) {
if (y<image->height-1) {
int x1;
for (x=0, x1=ofs+image->width; x<image->width; x++, x1++) {
nrerr[x] = red[x1];
ngerr[x] = grn[x1];
nberr[x] = blu[x1];
}
/* last column */
x1--;
nrerr[x] = red[x1];
ngerr[x] = grn[x1];
nberr[x] = blu[x1];
}
for (x=0; x<image->width; x++) {
/* reduce pixel */
if (rerr[x]>0xff) rerr[x]=0xff; else if (rerr[x]<0) rerr[x]=0;
if (gerr[x]>0xff) gerr[x]=0xff; else if (gerr[x]<0) gerr[x]=0;
if (berr[x]>0xff) berr[x]=0xff; else if (berr[x]<0) berr[x]=0;
r = rtable[rerr[x]];
g = gtable[gerr[x]];
b = btable[berr[x]];
*(dataP++) = (r<<roffs) | (g<<goffs) | (b<<boffs);
/* calc error */
rer = rerr[x] - r*dr;
ger = gerr[x] - g*dg;
ber = berr[x] - b*db;
/* distribute error */
r = (rer*3)/8;
g = (ger*3)/8;
b = (ber*3)/8;
/* x+1, y */
rerr[x+1]+=r;
gerr[x+1]+=g;
berr[x+1]+=b;
/* x, y+1 */
nrerr[x]+=r;
ngerr[x]+=g;
nberr[x]+=b;
/* x+1, y+1 */
nrerr[x+1]+=rer-2*r;
ngerr[x+1]+=ger-2*g;
nberr[x+1]+=ber-2*b;
}
ofs += image->width;
/*(char*)dataP += line_offset;*/
dataP = (unsigned short *)((char *)dataP + line_offset);
/* skip to next line */
terr = rerr;
rerr = nrerr;
nrerr = terr;
terr = gerr;
gerr = ngerr;
ngerr = terr;
terr = berr;
berr = nberr;
nberr = terr;
}
}
return ximg;
}
static RXImage*
image2TrueColor(RContext *ctx, RImage *image)
{
RXImage *ximg;
register int x, y, r, g, b;
unsigned char *red, *grn, *blu;
unsigned long pixel;
unsigned short rmask, gmask, bmask;
unsigned short roffs, goffs, boffs;
unsigned short *rtable, *gtable, *btable;
int ofs;
ximg = RCreateXImage(ctx, ctx->depth, image->width, image->height);
if (!ximg) {
return NULL;
}
red = image->data[0];
grn = image->data[1];
blu = image->data[2];
roffs = ctx->red_offset;
goffs = ctx->green_offset;
boffs = ctx->blue_offset;
rmask = ctx->visual->red_mask >> roffs;
gmask = ctx->visual->green_mask >> goffs;
bmask = ctx->visual->blue_mask >> boffs;
#if 0
/* this do not seem to increase speed. Only 0.06 second faster in
* rendering a 800x600 image to pixmap. 1.12 sec instead of 1.18.
* But does not require a 256*256*256 lookup table.
*/
if (ctx->depth==24) {
#ifdef DEBUG
puts("true color match for 24bpp");
#endif
for (y=0; y < image->height; y++) {
for (x=0; x < image->width; x++) {
pixel = (*(red++)<<roffs) | (*(grn++)<<goffs) | (*(blu++)<<boffs);
XPutPixel(ximg->image, x, y, pixel);
}
}
return ximg;
}
#endif
rtable = computeTable(rmask);
gtable = computeTable(gmask);
btable = computeTable(bmask);
if (rtable==NULL || gtable==NULL || btable==NULL) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
if (ctx->attribs->render_mode==RBestMatchRendering) {
/* fake match */
#ifdef DEBUG
puts("true color match");
#endif
for (y=0, ofs=0; y < image->height; y++) {
for (x=0; x < image->width; x++, ofs++) {
/* reduce pixel */
r = rtable[red[ofs]];
g = gtable[grn[ofs]];
b = btable[blu[ofs]];
pixel = (r<<roffs) | (g<<goffs) | (b<<boffs);
XPutPixel(ximg->image, x, y, pixel);
}
}
} else {
/* dither */
short *rerr, *gerr, *berr;
short *nrerr, *ngerr, *nberr;
short *terr;
int rer, ger, ber;
const int dr=0xff/rmask;
const int dg=0xff/gmask;
const int db=0xff/bmask;
#ifdef DEBUG
puts("true color dither");
#endif
rerr = (short*)alloca((image->width+2)*sizeof(short));
gerr = (short*)alloca((image->width+2)*sizeof(short));
berr = (short*)alloca((image->width+2)*sizeof(short));
nrerr = (short*)alloca((image->width+2)*sizeof(short));
ngerr = (short*)alloca((image->width+2)*sizeof(short));
nberr = (short*)alloca((image->width+2)*sizeof(short));
if (!rerr || !gerr || !berr || !nrerr || !ngerr || !nberr) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
for (x=0; x<image->width; x++) {
rerr[x] = red[x];
gerr[x] = grn[x];
berr[x] = blu[x];
}
rerr[x] = gerr[x] = berr[x] = 0;
/* convert and dither the image to XImage */
for (y=0, ofs=0; y<image->height; y++) {
if (y<image->height-1) {
int x1;
for (x=0, x1=ofs+image->width; x<image->width; x++, x1++) {
nrerr[x] = red[x1];
ngerr[x] = grn[x1];
nberr[x] = blu[x1];
}
/* last column */
x1--;
nrerr[x] = red[x1];
ngerr[x] = grn[x1];
nberr[x] = blu[x1];
}
for (x=0; x<image->width; x++) {
/* reduce pixel */
if (rerr[x]>0xff) rerr[x]=0xff; else if (rerr[x]<0) rerr[x]=0;
if (gerr[x]>0xff) gerr[x]=0xff; else if (gerr[x]<0) gerr[x]=0;
if (berr[x]>0xff) berr[x]=0xff; else if (berr[x]<0) berr[x]=0;
r = rtable[rerr[x]];
g = gtable[gerr[x]];
b = btable[berr[x]];
pixel = (r<<roffs) | (g<<goffs) | (b<<boffs);
XPutPixel(ximg->image, x, y, pixel);
/* calc error */
rer = rerr[x] - r*dr;
ger = gerr[x] - g*dg;
ber = berr[x] - b*db;
/* distribute error */
r = (rer*3)/8;
g = (ger*3)/8;
b = (ber*3)/8;
/* x+1, y */
rerr[x+1]+=r;
gerr[x+1]+=g;
berr[x+1]+=b;
/* x, y+1 */
nrerr[x]+=r;
ngerr[x]+=g;
nberr[x]+=b;
/* x+1, y+1 */
nrerr[x+1]+=rer-2*r;
ngerr[x+1]+=ger-2*g;
nberr[x+1]+=ber-2*b;
}
ofs+=image->width;
/* skip to next line */
terr = rerr;
rerr = nrerr;
nrerr = terr;
terr = gerr;
gerr = ngerr;
ngerr = terr;
terr = berr;
berr = nberr;
nberr = terr;
}
}
return ximg;
}
static RXImage*
image2PseudoColor(RContext *ctx, RImage *image)
{
RXImage *ximg;
register int x, y, r, g, b;
unsigned char *red, *grn, *blu;
unsigned long pixel;
const int cpc=ctx->attribs->colors_per_channel;
const unsigned short rmask = cpc-1; /* different sizes could be used */
const unsigned short gmask = rmask; /* for r,g,b */
const unsigned short bmask = rmask;
unsigned short *rtable, *gtable, *btable;
const int cpccpc = cpc*cpc;
unsigned char *data;
int ofs;
/*register unsigned char maxrgb = 0xff;*/
ximg = RCreateXImage(ctx, ctx->depth, image->width, image->height);
if (!ximg) {
return NULL;
}
red = image->data[0];
grn = image->data[1];
blu = image->data[2];
data = (unsigned char *)ximg->image->data;
/* Tables are same at the moment because rmask==gmask==bmask. */
rtable = computeTable(rmask);
gtable = computeTable(gmask);
btable = computeTable(bmask);
if (rtable==NULL || gtable==NULL || btable==NULL) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
if (ctx->attribs->render_mode == RBestMatchRendering) {
/* fake match */
#ifdef DEBUG
printf("pseudo color match with %d colors per channel\n", cpc);
#endif
for (y=0, ofs = 0; y<image->height; y++) {
for (x=0; x<image->width; x++, ofs++) {
/* reduce pixel */
r = rtable[red[ofs]];
g = gtable[grn[ofs]];
b = btable[blu[ofs]];
pixel = r*cpccpc + g*cpc + b;
/*data[ofs] = ctx->colors[pixel].pixel;*/
XPutPixel(ximg->image, x, y, ctx->colors[pixel].pixel);
}
}
} else {
/* dither */
short *rerr, *gerr, *berr;
short *nrerr, *ngerr, *nberr;
short *terr;
int rer, ger, ber;
const int dr=0xff/rmask;
const int dg=0xff/gmask;
const int db=0xff/bmask;
#ifdef DEBUG
printf("pseudo color dithering with %d colors per channel\n", cpc);
#endif
rerr = (short*)alloca((image->width+2)*sizeof(short));
gerr = (short*)alloca((image->width+2)*sizeof(short));
berr = (short*)alloca((image->width+2)*sizeof(short));
nrerr = (short*)alloca((image->width+2)*sizeof(short));
ngerr = (short*)alloca((image->width+2)*sizeof(short));
nberr = (short*)alloca((image->width+2)*sizeof(short));
if (!rerr || !gerr || !berr || !nrerr || !ngerr || !nberr) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
for (x=0; x<image->width; x++) {
rerr[x] = red[x];
gerr[x] = grn[x];
berr[x] = blu[x];
}
rerr[x] = gerr[x] = berr[x] = 0;
/* convert and dither the image to XImage */
for (y=0, ofs=0; y<image->height; y++) {
if (y<image->height-1) {
int x1;
for (x=0, x1=ofs+image->width; x<image->width; x++, x1++) {
nrerr[x] = red[x1];
ngerr[x] = grn[x1];
nberr[x] = blu[x1];
}
/* last column */
x1--;
nrerr[x] = red[x1];
ngerr[x] = grn[x1];
nberr[x] = blu[x1];
}
for (x=0; x<image->width; x++, ofs++) {
/* reduce pixel */
if (rerr[x]>0xff) rerr[x]=0xff; else if (rerr[x]<0) rerr[x]=0;
if (gerr[x]>0xff) gerr[x]=0xff; else if (gerr[x]<0) gerr[x]=0;
if (berr[x]>0xff) berr[x]=0xff; else if (berr[x]<0) berr[x]=0;
r = rtable[rerr[x]];
g = gtable[gerr[x]];
b = btable[berr[x]];
pixel = r*cpccpc + g*cpc + b;
/*data[ofs] = ctx->colors[pixel].pixel;*/
XPutPixel(ximg->image, x, y, ctx->colors[pixel].pixel);
/* calc error */
rer = rerr[x] - r*dr;
ger = gerr[x] - g*dg;
ber = berr[x] - b*db;
/* distribute error */
rerr[x+1]+=(rer*7)/16;
gerr[x+1]+=(ger*7)/16;
berr[x+1]+=(ber*7)/16;
nrerr[x]+=(rer*5)/16;
ngerr[x]+=(ger*5)/16;
nberr[x]+=(ber*5)/16;
if (x>0) {
nrerr[x-1]+=(rer*3)/16;
ngerr[x-1]+=(ger*3)/16;
nberr[x-1]+=(ber*3)/16;
}
nrerr[x+1]+=rer/16;
ngerr[x+1]+=ger/16;
nberr[x+1]+=ber/16;
#if 0
/* distribute error */
r = (rer*3)/8;
g = (ger*3)/8;
b = (ber*3)/8;
/* x+1, y */
rerr[x+1]+=r;
gerr[x+1]+=g;
berr[x+1]+=b;
/* x, y+1 */
nrerr[x]+=r;
ngerr[x]+=g;
nberr[x]+=b;
/* x+1, y+1 */
nrerr[x+1]+=rer-2*r;
ngerr[x+1]+=ger-2*g;
nberr[x+1]+=ber-2*b;
#endif
}
/* skip to next line */
terr = rerr;
rerr = nrerr;
nrerr = terr;
terr = gerr;
gerr = ngerr;
ngerr = terr;
terr = berr;
berr = nberr;
nberr = terr;
}
}
ximg->image->data = (char*)data;
return ximg;
}
static RXImage*
image2GrayScale(RContext *ctx, RImage *image)
{
RXImage *ximg;
register int x, y, g;
unsigned char *red, *grn, *blu;
const int cpc=ctx->attribs->colors_per_channel;
unsigned short gmask;
unsigned short *table;
unsigned char *data;
int ofs;
/*register unsigned char maxrgb = 0xff;*/
ximg = RCreateXImage(ctx, ctx->depth, image->width, image->height);
if (!ximg) {
return NULL;
}
red = image->data[0];
grn = image->data[1];
blu = image->data[2];
data = (unsigned char *)ximg->image->data;
if (ctx->vclass == StaticGray)
gmask = (1<<ctx->depth) - 1; /* use all grays */
else
gmask = cpc*cpc*cpc-1;
table = computeTable(gmask);
if (table==NULL) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
if (ctx->attribs->render_mode == RBestMatchRendering) {
/* fake match */
#ifdef DEBUG
printf("grayscale match with %d colors per channel\n", cpc);
#endif
for (y=0, ofs = 0; y<image->height; y++) {
for (x=0; x<image->width; x++, ofs++) {
/* reduce pixel */
g = table[(red[ofs]*30+grn[ofs]*59+blu[ofs]*11)/100];
/*data[ofs] = ctx->colors[g].pixel;*/
XPutPixel(ximg->image, x, y, ctx->colors[g].pixel);
}
}
} else {
/* dither */
short *gerr;
short *ngerr;
short *terr;
int ger;
const int dg=0xff/gmask;
#ifdef DEBUG
printf("grayscale dither with %d colors per channel\n", cpc);
#endif
gerr = (short*)alloca((image->width+2)*sizeof(short));
ngerr = (short*)alloca((image->width+2)*sizeof(short));
if (!gerr || !ngerr) {
RErrorCode = RERR_NOMEMORY;
RDestroyXImage(ctx, ximg);
return NULL;
}
for (x=0; x<image->width; x++) {
gerr[x] = (red[x]*30 + grn[x]*59 + blu[x]*11)/100;
}
gerr[x] = 0;
/* convert and dither the image to XImage */
for (y=0, ofs=0; y<image->height; y++) {
if (y<image->height-1) {
int x1;
for (x=0, x1=ofs+image->width; x<image->width; x++, x1++) {
ngerr[x] = (red[x1]*30 + grn[x1]*59 + blu[x1]*11)/100;
}
/* last column */
x1--;
ngerr[x] = (red[x1]*30 + grn[x1]*59 + blu[x1]*11)/100;
}
for (x=0; x<image->width; x++, ofs++) {
/* reduce pixel */
if (gerr[x]>0xff) gerr[x]=0xff; else if (gerr[x]<0) gerr[x]=0;
g = table[gerr[x]];
/*data[ofs] = ctx->colors[g].pixel;*/
XPutPixel(ximg->image, x, y, ctx->colors[g].pixel);
/* calc error */
ger = gerr[x] - g*dg;
/* distribute error */
g = (ger*3)/8;
/* x+1, y */
gerr[x+1]+=g;
/* x, y+1 */
ngerr[x]+=g;
/* x+1, y+1 */
ngerr[x+1]+=ger-2*g;
}
/* skip to next line */
terr = gerr;
gerr = ngerr;
ngerr = terr;
}
}
ximg->image->data = (char*)data;
return ximg;
}
static RXImage*
image2Bitmap(RContext *ctx, RImage *image, int threshold)
{
RXImage *ximg;
unsigned char *alpha;
int x, y;
ximg = RCreateXImage(ctx, 1, image->width, image->height);
if (!ximg) {
return NULL;
}
alpha = image->data[3];
for (y = 0; y < image->height; y++) {
for (x = 0; x < image->width; x++) {
XPutPixel(ximg->image, x, y, (*alpha <= threshold ? 0 : 1));
alpha++;
}
}
return ximg;
}
int
RConvertImage(RContext *context, RImage *image, Pixmap *pixmap)
{
RXImage *ximg=NULL;
#ifdef XSHM
Pixmap tmp;
#endif
assert(context!=NULL);
assert(image!=NULL);
assert(pixmap!=NULL);
/* clear error message */
if (context->vclass == TrueColor) {
if (context->attribs->render_mode == RDitheredRendering
&& (context->depth == 15 || context->depth == 16))
ximg = image2TrueColorD16(context, image);
else
ximg = image2TrueColor(context, image);
} else if (context->vclass == PseudoColor || context->vclass == StaticColor)
ximg = image2PseudoColor(context, image);
else if (context->vclass == GrayScale || context->vclass == StaticGray)
ximg = image2GrayScale(context, image);
if (!ximg) {
#ifdef C_ALLOCA
alloca(0);
#endif
return False;
}
*pixmap = XCreatePixmap(context->dpy, context->drawable, image->width,
image->height, context->depth);
#ifdef XSHM
if (context->flags.use_shared_pixmap && ximg->is_shared)
tmp = R_CreateXImageMappedPixmap(context, ximg);
else
tmp = None;
if (tmp) {
/*
* We have to copy the shm Pixmap into a normal Pixmap because
* otherwise, we would have to control when Pixmaps are freed so
* that we can detach their shm segments. This is a problem if the
* program crash, leaving stale shared memory segments in the
* system (lots of them). But with some work, we can optimize
* things and remove this XCopyArea. This will require
* explicitly freeing all pixmaps when exiting or restarting
* wmaker.
*/
XCopyArea(context->dpy, tmp, *pixmap, context->copy_gc, 0, 0,
image->width, image->height, 0, 0);
XFreePixmap(context->dpy, tmp);
} else {
RPutXImage(context, *pixmap, context->copy_gc, ximg, 0, 0, 0, 0,
image->width, image->height);
}
#else /* !XSHM */
RPutXImage(context, *pixmap, context->copy_gc, ximg, 0, 0, 0, 0,
image->width, image->height);
#endif /* !XSHM */
RDestroyXImage(context, ximg);
#ifdef C_ALLOCA
alloca(0);
#endif
return True;
}
int
RConvertImageMask(RContext *context, RImage *image, Pixmap *pixmap,
Pixmap *mask, int threshold)
{
GC gc;
XGCValues gcv;
RXImage *ximg=NULL;
assert(context!=NULL);
assert(image!=NULL);
assert(pixmap!=NULL);
assert(mask!=NULL);
if (!RConvertImage(context, image, pixmap))
return False;
if (image->data[3]==NULL) {
*mask = None;
return True;
}
ximg = image2Bitmap(context, image, threshold);
if (!ximg) {
#ifdef C_ALLOCA
alloca(0);
#endif
return False;
}
*mask = XCreatePixmap(context->dpy, context->drawable, image->width,
image->height, 1);
gcv.foreground = context->black;
gcv.background = context->white;
gcv.graphics_exposures = False;
gc = XCreateGC(context->dpy, *mask, GCForeground|GCBackground
|GCGraphicsExposures, &gcv);
RPutXImage(context, *mask, gc, ximg, 0, 0, 0, 0,
image->width, image->height);
RDestroyXImage(context, ximg);
#ifdef C_ALLOCA
alloca(0);
#endif
return True;
}
Bool
RGetClosestXColor(RContext *context, RColor *color, XColor *retColor)
{
if (context->vclass == TrueColor) {
unsigned short rmask, gmask, bmask;
unsigned short roffs, goffs, boffs;
unsigned short *rtable, *gtable, *btable;
roffs = context->red_offset;
goffs = context->green_offset;
boffs = context->blue_offset;
rmask = context->visual->red_mask >> roffs;
gmask = context->visual->green_mask >> goffs;
bmask = context->visual->blue_mask >> boffs;
rtable = computeTable(rmask);
gtable = computeTable(gmask);
btable = computeTable(bmask);
retColor->pixel = (rtable[color->red]<<roffs) |
(gtable[color->green]<<goffs) | (btable[color->blue]<<boffs);
retColor->red = color->red << 8;
retColor->green = color->green << 8;
retColor->blue = color->blue << 8;
retColor->flags = DoRed|DoGreen|DoBlue;
} else if (context->vclass == PseudoColor || context->vclass == StaticColor) {
const int cpc=context->attribs->colors_per_channel;
const unsigned short rmask = cpc-1; /* different sizes could be used */
const unsigned short gmask = rmask; /* for r,g,b */
const unsigned short bmask = rmask;
unsigned short *rtable, *gtable, *btable;
const int cpccpc = cpc*cpc;
int index;
rtable = computeTable(rmask);
gtable = computeTable(gmask);
btable = computeTable(bmask);
if (rtable==NULL || gtable==NULL || btable==NULL) {
RErrorCode = RERR_NOMEMORY;
return False;
}
index = rtable[color->red]*cpccpc + gtable[color->green]*cpc
+ btable[color->blue];
*retColor = context->colors[index];
} else if (context->vclass == GrayScale || context->vclass == StaticGray) {
const int cpc = context->attribs->colors_per_channel;
unsigned short gmask;
unsigned short *table;
int index;
if (context->vclass == StaticGray)
gmask = (1<<context->depth) - 1; /* use all grays */
else
gmask = cpc*cpc*cpc-1;
table = computeTable(gmask);
if (!table)
return False;
index = table[(color->red*30 + color->green*59 + color->blue*11)/100];
*retColor = context->colors[index];
} else {
RErrorCode = RERR_INTERNAL;
return False;
}
return True;
}
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