| 1 |
#ifndef lint |
| 2 |
static const char RCSid[] = "$Id: macbethcal.c,v 2.19 2003/07/21 22:30:18 schorsch Exp $"; |
| 3 |
#endif |
| 4 |
/* |
| 5 |
* Calibrate a scanned MacBeth Color Checker Chart |
| 6 |
* |
| 7 |
* Produce a .cal file suitable for use with pcomb, |
| 8 |
* or .cwp file suitable for use with pcwarp. |
| 9 |
* |
| 10 |
* Warping code depends on conformance of COLOR and W3VEC types. |
| 11 |
*/ |
| 12 |
|
| 13 |
#include <stdio.h> |
| 14 |
#include <math.h> |
| 15 |
#include <time.h> |
| 16 |
|
| 17 |
#include "platform.h" |
| 18 |
#include "color.h" |
| 19 |
#include "resolu.h" |
| 20 |
#include "pmap.h" |
| 21 |
#include "warp3d.h" |
| 22 |
|
| 23 |
/* MacBeth colors */ |
| 24 |
#define DarkSkin 0 |
| 25 |
#define LightSkin 1 |
| 26 |
#define BlueSky 2 |
| 27 |
#define Foliage 3 |
| 28 |
#define BlueFlower 4 |
| 29 |
#define BluishGreen 5 |
| 30 |
#define Orange 6 |
| 31 |
#define PurplishBlue 7 |
| 32 |
#define ModerateRed 8 |
| 33 |
#define Purple 9 |
| 34 |
#define YellowGreen 10 |
| 35 |
#define OrangeYellow 11 |
| 36 |
#define Blue 12 |
| 37 |
#define Green 13 |
| 38 |
#define Red 14 |
| 39 |
#define Yellow 15 |
| 40 |
#define Magenta 16 |
| 41 |
#define Cyan 17 |
| 42 |
#define White 18 |
| 43 |
#define Neutral8 19 |
| 44 |
#define Neutral65 20 |
| 45 |
#define Neutral5 21 |
| 46 |
#define Neutral35 22 |
| 47 |
#define Black 23 |
| 48 |
/* computed from 5nm spectral measurements */ |
| 49 |
/* CIE 1931 2 degree obs, equal-energy white */ |
| 50 |
float mbxyY[24][3] = { |
| 51 |
{0.462, 0.3769, 0.0932961}, /* DarkSkin */ |
| 52 |
{0.4108, 0.3542, 0.410348}, /* LightSkin */ |
| 53 |
{0.2626, 0.267, 0.181554}, /* BlueSky */ |
| 54 |
{0.36, 0.4689, 0.108447}, /* Foliage */ |
| 55 |
{0.2977, 0.2602, 0.248407}, /* BlueFlower */ |
| 56 |
{0.2719, 0.3485, 0.401156}, /* BluishGreen */ |
| 57 |
{0.52, 0.4197, 0.357899}, /* Orange */ |
| 58 |
{0.229, 0.1866, 0.103911}, /* PurplishBlue */ |
| 59 |
{0.4909, 0.3262, 0.242615}, /* ModerateRed */ |
| 60 |
{0.3361, 0.2249, 0.0600102}, /* Purple */ |
| 61 |
{0.3855, 0.4874, 0.42963}, /* YellowGreen */ |
| 62 |
{0.4853, 0.4457, 0.476343}, /* OrangeYellow */ |
| 63 |
{0.2026, 0.1369, 0.0529249}, /* Blue */ |
| 64 |
{0.3007, 0.4822, 0.221226}, /* Green */ |
| 65 |
{0.5805, 0.3238, 0.162167}, /* Red */ |
| 66 |
{0.4617, 0.472, 0.64909}, /* Yellow */ |
| 67 |
{0.4178, 0.2625, 0.233662}, /* Magenta */ |
| 68 |
{0.2038, 0.2508, 0.167275}, /* Cyan */ |
| 69 |
{0.3358, 0.337, 0.916877}, /* White */ |
| 70 |
{0.3338, 0.3348, 0.604678}, /* Neutral.8 */ |
| 71 |
{0.3333, 0.3349, 0.364566}, /* Neutral.65 */ |
| 72 |
{0.3353, 0.3359, 0.200238}, /* Neutral.5 */ |
| 73 |
{0.3363, 0.336, 0.0878721}, /* Neutral.35 */ |
| 74 |
{0.3346, 0.3349, 0.0308383} /* Black */ |
| 75 |
}; |
| 76 |
|
| 77 |
COLOR mbRGB[24]; /* MacBeth RGB values */ |
| 78 |
|
| 79 |
#define NMBNEU 6 /* Number of MacBeth neutral colors */ |
| 80 |
short mbneu[NMBNEU] = {Black,Neutral35,Neutral5,Neutral65,Neutral8,White}; |
| 81 |
|
| 82 |
#define NEUFLGS (1L<<White|1L<<Neutral8|1L<<Neutral65| \ |
| 83 |
1L<<Neutral5|1L<<Neutral35|1L<<Black) |
| 84 |
|
| 85 |
#define SATFLGS (1L<<Red|1L<<Green|1L<<Blue|1L<<Magenta|1L<<Yellow| \ |
| 86 |
1L<<Cyan|1L<<Orange|1L<<Purple|1L<<PurplishBlue| \ |
| 87 |
1L<<YellowGreen|1<<OrangeYellow|1L<<BlueFlower) |
| 88 |
|
| 89 |
#define UNSFLGS (1L<<DarkSkin|1L<<LightSkin|1L<<BlueSky|1L<<Foliage| \ |
| 90 |
1L<<BluishGreen|1L<<ModerateRed) |
| 91 |
|
| 92 |
#define REQFLGS NEUFLGS /* need these colors */ |
| 93 |
#define MODFLGS (NEUFLGS|UNSFLGS) /* should be in gamut */ |
| 94 |
|
| 95 |
#define RG_BORD 0 /* patch border */ |
| 96 |
#define RG_CENT 01 /* central region of patch */ |
| 97 |
#define RG_ORIG 02 /* original color region */ |
| 98 |
#define RG_CORR 04 /* corrected color region */ |
| 99 |
|
| 100 |
#ifndef DISPCOM |
| 101 |
#define DISPCOM "ximage -op %s" |
| 102 |
#endif |
| 103 |
|
| 104 |
int scanning = 1; /* scanned input (or recorded output)? */ |
| 105 |
double irrad = 1.0; /* irradiance multiplication factor */ |
| 106 |
int rawmap = 0; /* put out raw color mapping? */ |
| 107 |
|
| 108 |
int xmax, ymax; /* input image dimensions */ |
| 109 |
int bounds[4][2]; /* image coordinates of chart corners */ |
| 110 |
double imgxfm[3][3]; /* coordinate transformation matrix */ |
| 111 |
|
| 112 |
COLOR inpRGB[24]; /* measured or scanned input colors */ |
| 113 |
long inpflags = 0; /* flags of which colors were input */ |
| 114 |
long gmtflags = 0; /* flags of out-of-gamut colors */ |
| 115 |
|
| 116 |
COLOR bramp[NMBNEU][2]; /* brightness ramp (per primary) */ |
| 117 |
COLORMAT solmat; /* color mapping matrix */ |
| 118 |
COLOR colmin, colmax; /* gamut limits */ |
| 119 |
|
| 120 |
WARP3D *wcor = NULL; /* color space warp */ |
| 121 |
|
| 122 |
FILE *debugfp = NULL; /* debug output picture */ |
| 123 |
char *progname; |
| 124 |
|
| 125 |
|
| 126 |
main(argc, argv) |
| 127 |
int argc; |
| 128 |
char **argv; |
| 129 |
{ |
| 130 |
int i; |
| 131 |
|
| 132 |
progname = argv[0]; |
| 133 |
for (i = 1; i < argc && argv[i][0] == '-'; i++) |
| 134 |
switch (argv[i][1]) { |
| 135 |
case 'd': /* debug output */ |
| 136 |
i++; |
| 137 |
if (badarg(argc-i, argv+i, "s")) |
| 138 |
goto userr; |
| 139 |
if ((debugfp = fopen(argv[i], "w")) == NULL) { |
| 140 |
perror(argv[i]); |
| 141 |
exit(1); |
| 142 |
} |
| 143 |
SET_FILE_BINARY(debugfp); |
| 144 |
newheader("RADIANCE", debugfp); /* start */ |
| 145 |
printargs(argc, argv, debugfp); /* header */ |
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break; |
| 147 |
case 'p': /* picture position */ |
| 148 |
if (badarg(argc-i-1, argv+i+1, "iiiiiiii")) |
| 149 |
goto userr; |
| 150 |
bounds[0][0] = atoi(argv[++i]); |
| 151 |
bounds[0][1] = atoi(argv[++i]); |
| 152 |
bounds[1][0] = atoi(argv[++i]); |
| 153 |
bounds[1][1] = atoi(argv[++i]); |
| 154 |
bounds[2][0] = atoi(argv[++i]); |
| 155 |
bounds[2][1] = atoi(argv[++i]); |
| 156 |
bounds[3][0] = atoi(argv[++i]); |
| 157 |
bounds[3][1] = atoi(argv[++i]); |
| 158 |
scanning = 2; |
| 159 |
break; |
| 160 |
case 'P': /* pick position */ |
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scanning = 3; |
| 162 |
break; |
| 163 |
case 'i': /* irradiance factor */ |
| 164 |
i++; |
| 165 |
if (badarg(argc-i, argv+i, "f")) |
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goto userr; |
| 167 |
irrad = atof(argv[i]); |
| 168 |
break; |
| 169 |
case 'm': /* raw map output */ |
| 170 |
rawmap = 1; |
| 171 |
break; |
| 172 |
case 'c': /* color input */ |
| 173 |
scanning = 0; |
| 174 |
break; |
| 175 |
default: |
| 176 |
goto userr; |
| 177 |
} |
| 178 |
/* open files */ |
| 179 |
if (i < argc && freopen(argv[i], "r", stdin) == NULL) { |
| 180 |
perror(argv[i]); |
| 181 |
exit(1); |
| 182 |
} |
| 183 |
if (i+1 < argc && freopen(argv[i+1], "w", stdout) == NULL) { |
| 184 |
perror(argv[i+1]); |
| 185 |
exit(1); |
| 186 |
} |
| 187 |
if (scanning) { /* load input picture header */ |
| 188 |
SET_FILE_BINARY(stdin); |
| 189 |
if (checkheader(stdin, COLRFMT, NULL) < 0 || |
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fgetresolu(&xmax, &ymax, stdin) < 0) { |
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fprintf(stderr, "%s: bad input picture\n", progname); |
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exit(1); |
| 193 |
} |
| 194 |
if (scanning == 3) { |
| 195 |
if (i >= argc) |
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goto userr; |
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pickchartpos(argv[i]); |
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scanning = 2; |
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} |
| 200 |
} else { /* else set default xmax and ymax */ |
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xmax = 512; |
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ymax = 2*512/3; |
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} |
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if (scanning != 2) { /* use default boundaries */ |
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bounds[0][0] = bounds[2][0] = .029*xmax + .5; |
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bounds[0][1] = bounds[1][1] = .956*ymax + .5; |
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bounds[1][0] = bounds[3][0] = .971*xmax + .5; |
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bounds[2][1] = bounds[3][1] = .056*ymax + .5; |
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} |
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init(); /* initialize */ |
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if (scanning) /* get picture colors */ |
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getpicture(); |
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else |
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getcolors(); |
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compute(); /* compute color mapping */ |
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if (rawmap) { /* print out raw correspondence */ |
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register int j; |
| 218 |
|
| 219 |
printf("# Color correspondence produced by:\n#\t\t"); |
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printargs(argc, argv, stdout); |
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printf("#\tUsage: pcwarp %s uncorrected.pic > corrected.pic\n", |
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i+1 < argc ? argv[i+1] : "{this_file}"); |
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printf("#\t Or: pcond [options] -m %s orig.pic > output.pic\n", |
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i+1 < argc ? argv[i+1] : "{this_file}"); |
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for (j = 0; j < 24; j++) |
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printf("%f %f %f %f %f %f\n", |
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colval(inpRGB[j],RED), colval(inpRGB[j],GRN), |
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colval(inpRGB[j],BLU), colval(mbRGB[j],RED), |
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colval(mbRGB[j],GRN), colval(mbRGB[j],BLU)); |
| 230 |
if (scanning && debugfp != NULL) |
| 231 |
cwarp(); /* color warp for debugging */ |
| 232 |
} else { /* print color mapping */ |
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/* print header */ |
| 234 |
printf("{\n\tColor correction file computed by:\n\t\t"); |
| 235 |
printargs(argc, argv, stdout); |
| 236 |
printf("\n\tUsage: pcomb -f %s uncorrected.pic > corrected.pic\n", |
| 237 |
i+1 < argc ? argv[i+1] : "{this_file}"); |
| 238 |
if (!scanning) |
| 239 |
printf("\t Or: pcond [options] -f %s orig.pic > output.pic\n", |
| 240 |
i+1 < argc ? argv[i+1] : "{this_file}"); |
| 241 |
printf("}\n"); |
| 242 |
putmapping(); /* put out color mapping */ |
| 243 |
} |
| 244 |
if (debugfp != NULL) { /* put out debug picture */ |
| 245 |
if (scanning) |
| 246 |
picdebug(); |
| 247 |
else |
| 248 |
clrdebug(); |
| 249 |
} |
| 250 |
exit(0); |
| 251 |
userr: |
| 252 |
fprintf(stderr, |
| 253 |
"Usage: %s [-d dbg.pic][-P | -p xul yul xur yur xll yll xlr ylr][-i irrad][-m] input.pic [output.{cal|cwp}]\n", |
| 254 |
progname); |
| 255 |
fprintf(stderr, " or: %s [-d dbg.pic][-i irrad][-m] -c [xyY.dat [output.{cal|cwp}]]\n", |
| 256 |
progname); |
| 257 |
exit(1); |
| 258 |
} |
| 259 |
|
| 260 |
|
| 261 |
init() /* initialize */ |
| 262 |
{ |
| 263 |
double quad[4][2]; |
| 264 |
register int i; |
| 265 |
/* make coordinate transformation */ |
| 266 |
quad[0][0] = bounds[0][0]; |
| 267 |
quad[0][1] = bounds[0][1]; |
| 268 |
quad[1][0] = bounds[1][0]; |
| 269 |
quad[1][1] = bounds[1][1]; |
| 270 |
quad[2][0] = bounds[3][0]; |
| 271 |
quad[2][1] = bounds[3][1]; |
| 272 |
quad[3][0] = bounds[2][0]; |
| 273 |
quad[3][1] = bounds[2][1]; |
| 274 |
|
| 275 |
if (pmap_quad_rect(0., 0., 6., 4., quad, imgxfm) == PMAP_BAD) { |
| 276 |
fprintf(stderr, "%s: bad chart boundaries\n", progname); |
| 277 |
exit(1); |
| 278 |
} |
| 279 |
/* map MacBeth colors to RGB space */ |
| 280 |
for (i = 0; i < 24; i++) { |
| 281 |
xyY2RGB(mbRGB[i], mbxyY[i]); |
| 282 |
scalecolor(mbRGB[i], irrad); |
| 283 |
} |
| 284 |
} |
| 285 |
|
| 286 |
|
| 287 |
int |
| 288 |
chartndx(x, y, np) /* find color number for position */ |
| 289 |
int x, y; |
| 290 |
int *np; |
| 291 |
{ |
| 292 |
double ipos[3], cpos[3]; |
| 293 |
int ix, iy; |
| 294 |
double fx, fy; |
| 295 |
|
| 296 |
ipos[0] = x; |
| 297 |
ipos[1] = y; |
| 298 |
ipos[2] = 1; |
| 299 |
mx3d_transform(ipos, imgxfm, cpos); |
| 300 |
cpos[0] /= cpos[2]; |
| 301 |
cpos[1] /= cpos[2]; |
| 302 |
if (cpos[0] < 0. || cpos[0] >= 6. || cpos[1] < 0. || cpos[1] >= 4.) |
| 303 |
return(RG_BORD); |
| 304 |
ix = cpos[0]; |
| 305 |
iy = cpos[1]; |
| 306 |
fx = cpos[0] - ix; |
| 307 |
fy = cpos[1] - iy; |
| 308 |
*np = iy*6 + ix; |
| 309 |
if (fx >= 0.35 && fx < 0.65 && fy >= 0.35 && fy < 0.65) |
| 310 |
return(RG_CENT); |
| 311 |
if (fx < 0.05 || fx >= 0.95 || fy < 0.05 || fy >= 0.95) |
| 312 |
return(RG_BORD); |
| 313 |
if (fx >= 0.5) /* right side is corrected */ |
| 314 |
return(RG_CORR); |
| 315 |
return(RG_ORIG); /* left side is original */ |
| 316 |
} |
| 317 |
|
| 318 |
|
| 319 |
getpicture() /* load in picture colors */ |
| 320 |
{ |
| 321 |
COLR *scanln; |
| 322 |
COLOR pval; |
| 323 |
int ccount[24]; |
| 324 |
double d; |
| 325 |
int y, i; |
| 326 |
register int x; |
| 327 |
|
| 328 |
scanln = (COLR *)malloc(xmax*sizeof(COLR)); |
| 329 |
if (scanln == NULL) { |
| 330 |
perror(progname); |
| 331 |
exit(1); |
| 332 |
} |
| 333 |
for (i = 0; i < 24; i++) { |
| 334 |
setcolor(inpRGB[i], 0., 0., 0.); |
| 335 |
ccount[i] = 0; |
| 336 |
} |
| 337 |
for (y = ymax-1; y >= 0; y--) { |
| 338 |
if (freadcolrs(scanln, xmax, stdin) < 0) { |
| 339 |
fprintf(stderr, "%s: error reading input picture\n", |
| 340 |
progname); |
| 341 |
exit(1); |
| 342 |
} |
| 343 |
for (x = 0; x < xmax; x++) |
| 344 |
if (chartndx(x, y, &i) == RG_CENT) { |
| 345 |
colr_color(pval, scanln[x]); |
| 346 |
addcolor(inpRGB[i], pval); |
| 347 |
ccount[i]++; |
| 348 |
} |
| 349 |
} |
| 350 |
for (i = 0; i < 24; i++) { /* compute averages */ |
| 351 |
if (ccount[i] == 0) |
| 352 |
continue; |
| 353 |
d = 1./ccount[i]; |
| 354 |
scalecolor(inpRGB[i], d); |
| 355 |
inpflags |= 1L<<i; |
| 356 |
} |
| 357 |
free((void *)scanln); |
| 358 |
} |
| 359 |
|
| 360 |
|
| 361 |
getcolors() /* get xyY colors from standard input */ |
| 362 |
{ |
| 363 |
int gotwhite = 0; |
| 364 |
COLOR whiteclr; |
| 365 |
int n; |
| 366 |
float xyYin[3]; |
| 367 |
|
| 368 |
while (fgetval(stdin, 'i', &n) == 1) { /* read colors */ |
| 369 |
if ((n < 0) | (n > 24) || |
| 370 |
fgetval(stdin, 'f', &xyYin[0]) != 1 || |
| 371 |
fgetval(stdin, 'f', &xyYin[1]) != 1 || |
| 372 |
fgetval(stdin, 'f', &xyYin[2]) != 1 || |
| 373 |
(xyYin[0] < 0.) | (xyYin[1] < 0.) || |
| 374 |
xyYin[0] + xyYin[1] > 1.) { |
| 375 |
fprintf(stderr, "%s: bad color input data\n", |
| 376 |
progname); |
| 377 |
exit(1); |
| 378 |
} |
| 379 |
if (n == 0) { /* calibration white */ |
| 380 |
xyY2RGB(whiteclr, xyYin); |
| 381 |
gotwhite++; |
| 382 |
} else { /* standard color */ |
| 383 |
n--; |
| 384 |
xyY2RGB(inpRGB[n], xyYin); |
| 385 |
inpflags |= 1L<<n; |
| 386 |
} |
| 387 |
} |
| 388 |
/* normalize colors */ |
| 389 |
if (!gotwhite) { |
| 390 |
if (!(inpflags & 1L<<White)) { |
| 391 |
fprintf(stderr, "%s: missing input for White\n", |
| 392 |
progname); |
| 393 |
exit(1); |
| 394 |
} |
| 395 |
setcolor(whiteclr, |
| 396 |
colval(inpRGB[White],RED)/colval(mbRGB[White],RED), |
| 397 |
colval(inpRGB[White],GRN)/colval(mbRGB[White],GRN), |
| 398 |
colval(inpRGB[White],BLU)/colval(mbRGB[White],BLU)); |
| 399 |
} |
| 400 |
for (n = 0; n < 24; n++) |
| 401 |
if (inpflags & 1L<<n) |
| 402 |
setcolor(inpRGB[n], |
| 403 |
colval(inpRGB[n],RED)/colval(whiteclr,RED), |
| 404 |
colval(inpRGB[n],GRN)/colval(whiteclr,GRN), |
| 405 |
colval(inpRGB[n],BLU)/colval(whiteclr,BLU)); |
| 406 |
} |
| 407 |
|
| 408 |
|
| 409 |
bresp(y, x) /* piecewise linear interpolation of primaries */ |
| 410 |
COLOR y, x; |
| 411 |
{ |
| 412 |
register int i, n; |
| 413 |
|
| 414 |
for (i = 0; i < 3; i++) { |
| 415 |
for (n = 0; n < NMBNEU-2; n++) |
| 416 |
if (colval(x,i) < colval(bramp[n+1][0],i)) |
| 417 |
break; |
| 418 |
colval(y,i) = ((colval(bramp[n+1][0],i) - colval(x,i)) * |
| 419 |
colval(bramp[n][1],i) + |
| 420 |
(colval(x,i) - colval(bramp[n][0],i)) * |
| 421 |
colval(bramp[n+1][1],i)) / |
| 422 |
(colval(bramp[n+1][0],i) - colval(bramp[n][0],i)); |
| 423 |
} |
| 424 |
} |
| 425 |
|
| 426 |
|
| 427 |
compute() /* compute color mapping */ |
| 428 |
{ |
| 429 |
COLOR clrin[24], clrout[24]; |
| 430 |
long cflags; |
| 431 |
COLOR ctmp; |
| 432 |
register int i, n; |
| 433 |
/* did we get what we need? */ |
| 434 |
if ((inpflags & REQFLGS) != REQFLGS) { |
| 435 |
fprintf(stderr, "%s: missing required input colors\n", |
| 436 |
progname); |
| 437 |
exit(1); |
| 438 |
} |
| 439 |
/* compute piecewise luminance curve */ |
| 440 |
for (i = 0; i < NMBNEU; i++) { |
| 441 |
copycolor(bramp[i][0], inpRGB[mbneu[i]]); |
| 442 |
copycolor(bramp[i][1], mbRGB[mbneu[i]]); |
| 443 |
} |
| 444 |
/* compute color space gamut */ |
| 445 |
if (scanning) { |
| 446 |
copycolor(colmin, cblack); |
| 447 |
copycolor(colmax, cwhite); |
| 448 |
scalecolor(colmax, irrad); |
| 449 |
} else |
| 450 |
for (i = 0; i < 3; i++) { |
| 451 |
colval(colmin,i) = colval(bramp[0][0],i) - |
| 452 |
colval(bramp[0][1],i) * |
| 453 |
(colval(bramp[1][0],i)-colval(bramp[0][0],i)) / |
| 454 |
(colval(bramp[1][1],i)-colval(bramp[1][0],i)); |
| 455 |
colval(colmax,i) = colval(bramp[NMBNEU-2][0],i) + |
| 456 |
(1.-colval(bramp[NMBNEU-2][1],i)) * |
| 457 |
(colval(bramp[NMBNEU-1][0],i) - |
| 458 |
colval(bramp[NMBNEU-2][0],i)) / |
| 459 |
(colval(bramp[NMBNEU-1][1],i) - |
| 460 |
colval(bramp[NMBNEU-2][1],i)); |
| 461 |
} |
| 462 |
/* compute color mapping */ |
| 463 |
do { |
| 464 |
cflags = inpflags & ~gmtflags; |
| 465 |
n = 0; /* compute transform matrix */ |
| 466 |
for (i = 0; i < 24; i++) |
| 467 |
if (cflags & 1L<<i) { |
| 468 |
bresp(clrin[n], inpRGB[i]); |
| 469 |
copycolor(clrout[n], mbRGB[i]); |
| 470 |
n++; |
| 471 |
} |
| 472 |
compsoln(clrin, clrout, n); |
| 473 |
if (irrad > 0.99 && irrad < 1.01) /* check gamut */ |
| 474 |
for (i = 0; i < 24; i++) |
| 475 |
if (cflags & 1L<<i && cvtcolor(ctmp, mbRGB[i])) |
| 476 |
gmtflags |= 1L<<i; |
| 477 |
} while (cflags & gmtflags); |
| 478 |
if (gmtflags & MODFLGS) |
| 479 |
fprintf(stderr, |
| 480 |
"%s: warning - some moderate colors are out of gamut\n", |
| 481 |
progname); |
| 482 |
} |
| 483 |
|
| 484 |
|
| 485 |
putmapping() /* put out color mapping */ |
| 486 |
{ |
| 487 |
static char cchar[3] = {'r', 'g', 'b'}; |
| 488 |
register int i, j; |
| 489 |
/* print brightness mapping */ |
| 490 |
for (j = 0; j < 3; j++) { |
| 491 |
printf("%cxa(i) : select(i", cchar[j]); |
| 492 |
for (i = 0; i < NMBNEU; i++) |
| 493 |
printf(",%g", colval(bramp[i][0],j)); |
| 494 |
printf(");\n"); |
| 495 |
printf("%cya(i) : select(i", cchar[j]); |
| 496 |
for (i = 0; i < NMBNEU; i++) |
| 497 |
printf(",%g", colval(bramp[i][1],j)); |
| 498 |
printf(");\n"); |
| 499 |
printf("%cfi(n) = if(n-%g, %d, if(%cxa(n+1)-%c, n, %cfi(n+1)));\n", |
| 500 |
cchar[j], NMBNEU-1.5, NMBNEU-1, cchar[j], |
| 501 |
cchar[j], cchar[j]); |
| 502 |
printf("%cndx = %cfi(1);\n", cchar[j], cchar[j]); |
| 503 |
printf("%c%c = ((%cxa(%cndx+1)-%c)*%cya(%cndx) + ", |
| 504 |
cchar[j], scanning?'n':'o', cchar[j], |
| 505 |
cchar[j], cchar[j], cchar[j], cchar[j]); |
| 506 |
printf("(%c-%cxa(%cndx))*%cya(%cndx+1)) /\n", |
| 507 |
cchar[j], cchar[j], cchar[j], |
| 508 |
cchar[j], cchar[j]); |
| 509 |
printf("\t\t(%cxa(%cndx+1) - %cxa(%cndx)) ;\n", |
| 510 |
cchar[j], cchar[j], cchar[j], cchar[j]); |
| 511 |
} |
| 512 |
/* print color mapping */ |
| 513 |
if (scanning) { |
| 514 |
printf("r = ri(1); g = gi(1); b = bi(1);\n"); |
| 515 |
printf("ro = %g*rn + %g*gn + %g*bn ;\n", |
| 516 |
solmat[0][0], solmat[0][1], solmat[0][2]); |
| 517 |
printf("go = %g*rn + %g*gn + %g*bn ;\n", |
| 518 |
solmat[1][0], solmat[1][1], solmat[1][2]); |
| 519 |
printf("bo = %g*rn + %g*gn + %g*bn ;\n", |
| 520 |
solmat[2][0], solmat[2][1], solmat[2][2]); |
| 521 |
} else { |
| 522 |
printf("r1 = ri(1); g1 = gi(1); b1 = bi(1);\n"); |
| 523 |
printf("r = %g*r1 + %g*g1 + %g*b1 ;\n", |
| 524 |
solmat[0][0], solmat[0][1], solmat[0][2]); |
| 525 |
printf("g = %g*r1 + %g*g1 + %g*b1 ;\n", |
| 526 |
solmat[1][0], solmat[1][1], solmat[1][2]); |
| 527 |
printf("b = %g*r1 + %g*g1 + %g*b1 ;\n", |
| 528 |
solmat[2][0], solmat[2][1], solmat[2][2]); |
| 529 |
} |
| 530 |
} |
| 531 |
|
| 532 |
|
| 533 |
compsoln(cin, cout, n) /* solve 3xN system using least-squares */ |
| 534 |
COLOR cin[], cout[]; |
| 535 |
int n; |
| 536 |
{ |
| 537 |
extern double mx3d_adjoint(), fabs(); |
| 538 |
double mat[3][3], invmat[3][3]; |
| 539 |
double det; |
| 540 |
double colv[3], rowv[3]; |
| 541 |
register int i, j, k; |
| 542 |
|
| 543 |
if (n < 3) { |
| 544 |
fprintf(stderr, "%s: too few colors to match!\n", progname); |
| 545 |
exit(1); |
| 546 |
} |
| 547 |
if (n == 3) |
| 548 |
for (i = 0; i < 3; i++) |
| 549 |
for (j = 0; j < 3; j++) |
| 550 |
mat[i][j] = colval(cin[j],i); |
| 551 |
else { /* compute A^t A */ |
| 552 |
for (i = 0; i < 3; i++) |
| 553 |
for (j = i; j < 3; j++) { |
| 554 |
mat[i][j] = 0.; |
| 555 |
for (k = 0; k < n; k++) |
| 556 |
mat[i][j] += colval(cin[k],i) * |
| 557 |
colval(cin[k],j); |
| 558 |
} |
| 559 |
for (i = 1; i < 3; i++) /* using symmetry */ |
| 560 |
for (j = 0; j < i; j++) |
| 561 |
mat[i][j] = mat[j][i]; |
| 562 |
} |
| 563 |
det = mx3d_adjoint(mat, invmat); |
| 564 |
if (fabs(det) < 1e-4) { |
| 565 |
fprintf(stderr, "%s: cannot compute color mapping\n", |
| 566 |
progname); |
| 567 |
solmat[0][0] = solmat[1][1] = solmat[2][2] = 1.; |
| 568 |
solmat[0][1] = solmat[0][2] = solmat[1][0] = |
| 569 |
solmat[1][2] = solmat[2][0] = solmat[2][1] = 0.; |
| 570 |
return; |
| 571 |
} |
| 572 |
for (i = 0; i < 3; i++) |
| 573 |
for (j = 0; j < 3; j++) |
| 574 |
invmat[i][j] /= det; |
| 575 |
for (i = 0; i < 3; i++) { |
| 576 |
if (n == 3) |
| 577 |
for (j = 0; j < 3; j++) |
| 578 |
colv[j] = colval(cout[j],i); |
| 579 |
else |
| 580 |
for (j = 0; j < 3; j++) { |
| 581 |
colv[j] = 0.; |
| 582 |
for (k = 0; k < n; k++) |
| 583 |
colv[j] += colval(cout[k],i) * |
| 584 |
colval(cin[k],j); |
| 585 |
} |
| 586 |
mx3d_transform(colv, invmat, rowv); |
| 587 |
for (j = 0; j < 3; j++) |
| 588 |
solmat[i][j] = rowv[j]; |
| 589 |
} |
| 590 |
} |
| 591 |
|
| 592 |
|
| 593 |
cwarp() /* compute color warp map */ |
| 594 |
{ |
| 595 |
register int i; |
| 596 |
|
| 597 |
if ((wcor = new3dw(W3EXACT)) == NULL) |
| 598 |
goto memerr; |
| 599 |
for (i = 0; i < 24; i++) |
| 600 |
if (!add3dpt(wcor, inpRGB[i], mbRGB[i])) |
| 601 |
goto memerr; |
| 602 |
return; |
| 603 |
memerr: |
| 604 |
perror(progname); |
| 605 |
exit(1); |
| 606 |
} |
| 607 |
|
| 608 |
|
| 609 |
int |
| 610 |
cvtcolor(cout, cin) /* convert color according to our mapping */ |
| 611 |
COLOR cout, cin; |
| 612 |
{ |
| 613 |
COLOR ctmp; |
| 614 |
int clipped; |
| 615 |
|
| 616 |
if (wcor != NULL) { |
| 617 |
clipped = warp3d(cout, cin, wcor); |
| 618 |
clipped |= clipgamut(cout,bright(cout),CGAMUT,colmin,colmax); |
| 619 |
} else if (scanning) { |
| 620 |
bresp(ctmp, cin); |
| 621 |
clipped = cresp(cout, ctmp); |
| 622 |
} else { |
| 623 |
clipped = cresp(ctmp, cin); |
| 624 |
bresp(cout, ctmp); |
| 625 |
} |
| 626 |
return(clipped); |
| 627 |
} |
| 628 |
|
| 629 |
|
| 630 |
int |
| 631 |
cresp(cout, cin) /* transform color according to matrix */ |
| 632 |
COLOR cout, cin; |
| 633 |
{ |
| 634 |
colortrans(cout, solmat, cin); |
| 635 |
return(clipgamut(cout, bright(cout), CGAMUT, colmin, colmax)); |
| 636 |
} |
| 637 |
|
| 638 |
|
| 639 |
xyY2RGB(rgbout, xyYin) /* convert xyY to RGB */ |
| 640 |
COLOR rgbout; |
| 641 |
register float xyYin[3]; |
| 642 |
{ |
| 643 |
COLOR ctmp; |
| 644 |
double d; |
| 645 |
|
| 646 |
d = xyYin[2] / xyYin[1]; |
| 647 |
ctmp[0] = xyYin[0] * d; |
| 648 |
ctmp[1] = xyYin[2]; |
| 649 |
ctmp[2] = (1. - xyYin[0] - xyYin[1]) * d; |
| 650 |
/* allow negative values */ |
| 651 |
colortrans(rgbout, xyz2rgbmat, ctmp); |
| 652 |
} |
| 653 |
|
| 654 |
|
| 655 |
picdebug() /* put out debugging picture */ |
| 656 |
{ |
| 657 |
static COLOR blkcol = BLKCOLOR; |
| 658 |
COLOR *scan; |
| 659 |
int y, i; |
| 660 |
register int x, rg; |
| 661 |
|
| 662 |
if (fseek(stdin, 0L, 0) == EOF) { |
| 663 |
fprintf(stderr, "%s: cannot seek on input picture\n", progname); |
| 664 |
exit(1); |
| 665 |
} |
| 666 |
getheader(stdin, NULL, NULL); /* skip input header */ |
| 667 |
fgetresolu(&xmax, &ymax, stdin); |
| 668 |
/* allocate scanline */ |
| 669 |
scan = (COLOR *)malloc(xmax*sizeof(COLOR)); |
| 670 |
if (scan == NULL) { |
| 671 |
perror(progname); |
| 672 |
exit(1); |
| 673 |
} |
| 674 |
/* finish debug header */ |
| 675 |
fputformat(COLRFMT, debugfp); |
| 676 |
putc('\n', debugfp); |
| 677 |
fprtresolu(xmax, ymax, debugfp); |
| 678 |
/* write debug picture */ |
| 679 |
for (y = ymax-1; y >= 0; y--) { |
| 680 |
if (freadscan(scan, xmax, stdin) < 0) { |
| 681 |
fprintf(stderr, "%s: error rereading input picture\n", |
| 682 |
progname); |
| 683 |
exit(1); |
| 684 |
} |
| 685 |
for (x = 0; x < xmax; x++) { |
| 686 |
rg = chartndx(x, y, &i); |
| 687 |
if (rg == RG_CENT) { |
| 688 |
if (!(1L<<i & gmtflags) || (x+y)&07) { |
| 689 |
copycolor(scan[x], mbRGB[i]); |
| 690 |
clipgamut(scan[x], bright(scan[x]), |
| 691 |
CGAMUT, colmin, colmax); |
| 692 |
} else |
| 693 |
copycolor(scan[x], blkcol); |
| 694 |
} else if (rg == RG_CORR) |
| 695 |
cvtcolor(scan[x], scan[x]); |
| 696 |
else if (rg != RG_ORIG) |
| 697 |
copycolor(scan[x], blkcol); |
| 698 |
} |
| 699 |
if (fwritescan(scan, xmax, debugfp) < 0) { |
| 700 |
fprintf(stderr, "%s: error writing debugging picture\n", |
| 701 |
progname); |
| 702 |
exit(1); |
| 703 |
} |
| 704 |
} |
| 705 |
/* clean up */ |
| 706 |
fclose(debugfp); |
| 707 |
free((void *)scan); |
| 708 |
} |
| 709 |
|
| 710 |
|
| 711 |
clrdebug() /* put out debug picture from color input */ |
| 712 |
{ |
| 713 |
static COLR blkclr = BLKCOLR; |
| 714 |
COLR mbclr[24], cvclr[24], orclr[24]; |
| 715 |
COLR *scan; |
| 716 |
COLOR ctmp, ct2; |
| 717 |
int y, i; |
| 718 |
register int x, rg; |
| 719 |
/* convert colors */ |
| 720 |
for (i = 0; i < 24; i++) { |
| 721 |
copycolor(ctmp, mbRGB[i]); |
| 722 |
clipgamut(ctmp, bright(ctmp), CGAMUT, cblack, cwhite); |
| 723 |
setcolr(mbclr[i], colval(ctmp,RED), |
| 724 |
colval(ctmp,GRN), colval(ctmp,BLU)); |
| 725 |
if (inpflags & 1L<<i) { |
| 726 |
copycolor(ctmp, inpRGB[i]); |
| 727 |
clipgamut(ctmp, bright(ctmp), CGAMUT, cblack, cwhite); |
| 728 |
setcolr(orclr[i], colval(ctmp,RED), |
| 729 |
colval(ctmp,GRN), colval(ctmp,BLU)); |
| 730 |
if (rawmap) |
| 731 |
copycolr(cvclr[i], mbclr[i]); |
| 732 |
else { |
| 733 |
bresp(ctmp, inpRGB[i]); |
| 734 |
colortrans(ct2, solmat, ctmp); |
| 735 |
clipgamut(ct2, bright(ct2), CGAMUT, |
| 736 |
cblack, cwhite); |
| 737 |
setcolr(cvclr[i], colval(ct2,RED), |
| 738 |
colval(ct2,GRN), |
| 739 |
colval(ct2,BLU)); |
| 740 |
} |
| 741 |
} |
| 742 |
} |
| 743 |
/* allocate scanline */ |
| 744 |
scan = (COLR *)malloc(xmax*sizeof(COLR)); |
| 745 |
if (scan == NULL) { |
| 746 |
perror(progname); |
| 747 |
exit(1); |
| 748 |
} |
| 749 |
/* finish debug header */ |
| 750 |
fputformat(COLRFMT, debugfp); |
| 751 |
putc('\n', debugfp); |
| 752 |
fprtresolu(xmax, ymax, debugfp); |
| 753 |
/* write debug picture */ |
| 754 |
for (y = ymax-1; y >= 0; y--) { |
| 755 |
for (x = 0; x < xmax; x++) { |
| 756 |
rg = chartndx(x, y, &i); |
| 757 |
if (rg == RG_CENT) { |
| 758 |
if (!(1L<<i & gmtflags) || (x+y)&07) |
| 759 |
copycolr(scan[x], mbclr[i]); |
| 760 |
else |
| 761 |
copycolr(scan[x], blkclr); |
| 762 |
} else if (rg == RG_BORD || !(1L<<i & inpflags)) |
| 763 |
copycolr(scan[x], blkclr); |
| 764 |
else if (rg == RG_ORIG) |
| 765 |
copycolr(scan[x], orclr[i]); |
| 766 |
else /* rg == RG_CORR */ |
| 767 |
copycolr(scan[x], cvclr[i]); |
| 768 |
} |
| 769 |
if (fwritecolrs(scan, xmax, debugfp) < 0) { |
| 770 |
fprintf(stderr, "%s: error writing debugging picture\n", |
| 771 |
progname); |
| 772 |
exit(1); |
| 773 |
} |
| 774 |
} |
| 775 |
/* clean up */ |
| 776 |
fclose(debugfp); |
| 777 |
free((void *)scan); |
| 778 |
} |
| 779 |
|
| 780 |
|
| 781 |
getpos(name, bnds, fp) /* get boundary position */ |
| 782 |
char *name; |
| 783 |
int bnds[2]; |
| 784 |
FILE *fp; |
| 785 |
{ |
| 786 |
char buf[64]; |
| 787 |
|
| 788 |
fprintf(stderr, "\tSelect corner: %s\n", name); |
| 789 |
if (fgets(buf, sizeof(buf), fp) == NULL || |
| 790 |
sscanf(buf, "%d %d", &bnds[0], &bnds[1]) != 2) { |
| 791 |
fprintf(stderr, "%s: read error from display process\n", |
| 792 |
progname); |
| 793 |
exit(1); |
| 794 |
} |
| 795 |
} |
| 796 |
|
| 797 |
|
| 798 |
pickchartpos(pfn) /* display picture and pick chart location */ |
| 799 |
char *pfn; |
| 800 |
{ |
| 801 |
char combuf[512]; |
| 802 |
FILE *pfp; |
| 803 |
|
| 804 |
sprintf(combuf, DISPCOM, pfn); |
| 805 |
if ((pfp = popen(combuf, "r")) == NULL) { |
| 806 |
perror(combuf); |
| 807 |
exit(1); |
| 808 |
} |
| 809 |
fputs("Use middle mouse button to select chart corners:\n", stderr); |
| 810 |
getpos("upper left (dark skin)", bounds[0], pfp); |
| 811 |
getpos("upper right (bluish green)", bounds[1], pfp); |
| 812 |
getpos("lower left (white)", bounds[2], pfp); |
| 813 |
getpos("lower right (black)", bounds[3], pfp); |
| 814 |
fputs("Got it -- quit display program.\n", stderr); |
| 815 |
pclose(pfp); |
| 816 |
} |
