[ViewVC] Diff of: radiance/ray/src/px/macbethcal.c

Comparing ray/src/px/macbethcal.c (file contents):
Revision 2.7 by greg, Fri Oct 20 15:26:11 1995 UTC vs.
Revision 2.24 by greg, Wed Dec 15 06:30:36 2004 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1995 Regents of the University of California */
2	–
1		#ifndef lint
2	<	static char SCCSid[] = "$SunId$ LBL";
2	>	static const char RCSid[] = "$Id$";
3		#endif
6	–
4		/*
5		* Calibrate a scanned MacBeth Color Checker Chart
6		*
7	<	* Produce a .cal file suitable for use with pcomb.
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	<	#ifdef MSDOS
15	<	#include <fcntl.h>
16	<	#endif
14	>	#include <math.h>
15	>	#include <time.h>
16	>
17	>	#include "platform.h"
18	>	#include "rtprocess.h"
19	>	#include "rtio.h"
20		#include "color.h"
21		#include "resolu.h"
22		#include "pmap.h"
23	+	#include "warp3d.h"
24	+	#include "mx3.h"
25
26		/* MacBeth colors */
27		#define DarkSkin 0
#	Line 77 \| Line 82 \| *COLOR mbRGB[24]; / MacBeth RGB values /*
82		#define NMBNEU 6 /* Number of MacBeth neutral colors */
83		short mbneu[NMBNEU] = {Black,Neutral35,Neutral5,Neutral65,Neutral8,White};
84
85	<	#define NMBMOD 16 /* Number of MacBeth unsaturated colors */
86	<	short mbmod[NMBMOD] = {
82	<	DarkSkin,LightSkin,BlueSky,Foliage,BlueFlower,BluishGreen,
83	<	PurplishBlue,ModerateRed,YellowGreen,OrangeYellow,
84	<	Black,Neutral35,Neutral5,Neutral65,Neutral8,White
85	<	};
85	>	#define NEUFLGS (1L<<White\|1L<<Neutral8\|1L<<Neutral65\| \
86	>	1L<<Neutral5\|1L<<Neutral35\|1L<<Black)
87
88	<	#define NMBSAT 8 /* Number of MacBeth saturated colors */
89	<	short mbsat[NMBSAT] = {
90	<	Red,Green,Blue,Magenta,Yellow,Cyan,
90	<	Orange,Purple
91	<	};
88	>	#define SATFLGS (1L<<Red\|1L<<Green\|1L<<Blue\|1L<<Magenta\|1L<<Yellow\| \
89	>	1L<<Cyan\|1L<<Orange\|1L<<Purple\|1L<<PurplishBlue\| \
90	>	1L<<YellowGreen\|1<<OrangeYellow\|1L<<BlueFlower)
91
92	<	#define REQFLGS (1L<<White\|1L<<Neutral8\|1L<<Neutral65\| \
93	<	1L<<Neutral5\|1L<<Neutral35\|1L<<Black)
92	>	#define UNSFLGS (1L<<DarkSkin\|1L<<LightSkin\|1L<<BlueSky\|1L<<Foliage\| \
93	>	1L<<BluishGreen\|1L<<ModerateRed)
94
95	<	#define CENTCVG 0.3 /* measured coverage of square sample */
96	<	#define FULLCVG 0.9 /* coverage of entire square */
95	>	#define REQFLGS NEUFLGS /* need these colors */
96	>	#define MODFLGS (NEUFLGS\|UNSFLGS) /* should be in gamut */
97
98	+	#define RG_BORD 0 /* patch border */
99	+	#define RG_CENT 01 /* central region of patch */
100	+	#define RG_ORIG 02 /* original color region */
101	+	#define RG_CORR 04 /* corrected color region */
102	+
103	+	#ifndef DISPCOM
104	+	#define DISPCOM "ximage -op \"%s\""
105	+	#endif
106	+
107	+	int scanning = 1; /* scanned input (or recorded output)? */
108	+	double irrad = 1.0; /* irradiance multiplication factor */
109	+	int rawmap = 0; /* put out raw color mapping? */
110	+
111		int xmax, ymax; /* input image dimensions */
112		int bounds[4][2]; /* image coordinates of chart corners */
113		double imgxfm[3][3]; /* coordinate transformation matrix */
114
115		COLOR inpRGB[24]; /* measured or scanned input colors */
116		long inpflags = 0; /* flags of which colors were input */
117	+	long gmtflags = 0; /* flags of out-of-gamut colors */
118
119		COLOR bramp[NMBNEU][2]; /* brightness ramp (per primary) */
120	<	double solmat[3][3]; /* color mapping matrix */
120	>	COLORMAT solmat; /* color mapping matrix */
121	>	COLOR colmin, colmax; /* gamut limits */
122
123	+	WARP3D wcor = NULL; / color space warp */
124	+
125		FILE debugfp = NULL; / debug output picture */
126		char *progname;
127
128	<	extern char *malloc();
128	>	static void init(void);
129	>	static int chartndx(int x, int y, int *np);
130	>	static void getpicture(void);
131	>	static void getcolors(void);
132	>	static void bresp(COLOR y, COLOR x);
133	>	static void compute(void);
134	>	static void putmapping(void);
135	>	static void compsoln(COLOR cin[], COLOR cout[], int n);
136	>	static void cwarp(void);
137	>	static int cvtcolor(COLOR cout, COLOR cin);
138	>	static int cresp(COLOR cout, COLOR cin);
139	>	static void xyY2RGB(COLOR rgbout, float xyYin[3]);
140	>	static void picdebug(void);
141	>	static void clrdebug(void);
142	>	static void getpos(char name, int bnds[2], FILE fp);
143	>	static void pickchartpos(char *pfn);
144
145
146	<	main(argc, argv)
147	<	int argc;
148	<	char **argv;
146	>	int
147	>	main(
148	>	int argc,
149	>	char **argv
150	>	)
151		{
119	–	int inpispic = 1;
152		int i;
153
154		progname = argv[0];
#	Line 130 \| Line 162 \| char argv;**
162		perror(argv[i]);
163		exit(1);
164		}
165	<	#ifdef MSDOS
134	<	setmode(fileno(debugfp), O_BINARY);
135	<	#endif
165	>	SET_FILE_BINARY(debugfp);
166		newheader("RADIANCE", debugfp); /* start */
167		printargs(argc, argv, debugfp); /* header */
168		break;
#	Line 147 \| Line 177 \| char argv;**
177		bounds[2][1] = atoi(argv[++i]);
178		bounds[3][0] = atoi(argv[++i]);
179		bounds[3][1] = atoi(argv[++i]);
180	<	inpispic = 2;
180	>	scanning = 2;
181		break;
182	+	case 'P': /* pick position */
183	+	scanning = 3;
184	+	break;
185	+	case 'i': /* irradiance factor */
186	+	i++;
187	+	if (badarg(argc-i, argv+i, "f"))
188	+	goto userr;
189	+	irrad = atof(argv[i]);
190	+	break;
191	+	case 'm': /* raw map output */
192	+	rawmap = 1;
193	+	break;
194		case 'c': /* color input */
195	<	inpispic = 0;
195	>	scanning = 0;
196		break;
197		default:
198		goto userr;
199		}
200		/* open files */
201		if (i < argc && freopen(argv[i], "r", stdin) == NULL) {
202	<	perror(argv[1]);
202	>	perror(argv[i]);
203		exit(1);
204		}
205		if (i+1 < argc && freopen(argv[i+1], "w", stdout) == NULL) {
206	<	perror(argv[2]);
206	>	perror(argv[i+1]);
207		exit(1);
208		}
209	<	if (inpispic) { /* load input picture header */
210	<	#ifdef MSDOS
169	<	setmode(fileno(stdin), O_BINARY);
170	<	#endif
209	>	if (scanning) { /* load input picture header */
210	>	SET_FILE_BINARY(stdin);
211		if (checkheader(stdin, COLRFMT, NULL) < 0 \|\|
212		fgetresolu(&xmax, &ymax, stdin) < 0) {
213		fprintf(stderr, "%s: bad input picture\n", progname);
214		exit(1);
215		}
216	+	if (scanning == 3) {
217	+	if (i >= argc)
218	+	goto userr;
219	+	pickchartpos(argv[i]);
220	+	scanning = 2;
221	+	}
222		} else { /* else set default xmax and ymax */
223		xmax = 512;
224		ymax = 2*512/3;
225		}
226	<	if (inpispic != 2) { /* use default boundaries */
226	>	if (scanning != 2) { /* use default boundaries */
227		bounds[0][0] = bounds[2][0] = .029*xmax + .5;
228		bounds[0][1] = bounds[1][1] = .956*ymax + .5;
229		bounds[1][0] = bounds[3][0] = .971*xmax + .5;
230		bounds[2][1] = bounds[3][1] = .056*ymax + .5;
231		}
232		init(); /* initialize */
233	<	if (inpispic) /* get picture colors */
233	>	if (scanning) /* get picture colors */
234		getpicture();
235		else
236		getcolors();
237		compute(); /* compute color mapping */
238	<	/* print comment */
239	<	printf("{ Color correction file computed by:\n\t");
240	<	printargs(argc, argv, stdout);
241	<	printf("}\n");
242	<	putmapping(); /* put out color mapping */
243	<	if (debugfp != NULL) /* put out debug picture */
244	<	if (inpispic)
238	>	if (rawmap) { /* print out raw correspondence */
239	>	register int j;
240	>
241	>	printf("# Color correspondence produced by:\n#\t\t");
242	>	printargs(argc, argv, stdout);
243	>	printf("#\tUsage: pcwarp %s uncorrected.pic > corrected.pic\n",
244	>	i+1 < argc ? argv[i+1] : "{this_file}");
245	>	printf("#\t Or: pcond [options] -m %s orig.pic > output.pic\n",
246	>	i+1 < argc ? argv[i+1] : "{this_file}");
247	>	for (j = 0; j < 24; j++)
248	>	printf("%f %f %f %f %f %f\n",
249	>	colval(inpRGB[j],RED), colval(inpRGB[j],GRN),
250	>	colval(inpRGB[j],BLU), colval(mbRGB[j],RED),
251	>	colval(mbRGB[j],GRN), colval(mbRGB[j],BLU));
252	>	if (scanning && debugfp != NULL)
253	>	cwarp(); /* color warp for debugging */
254	>	} else { /* print color mapping */
255	>	/* print header */
256	>	printf("{\n\tColor correction file computed by:\n\t\t");
257	>	printargs(argc, argv, stdout);
258	>	printf("\n\tUsage: pcomb -f %s uncorrected.pic > corrected.pic\n",
259	>	i+1 < argc ? argv[i+1] : "{this_file}");
260	>	if (!scanning)
261	>	printf("\t Or: pcond [options] -f %s orig.pic > output.pic\n",
262	>	i+1 < argc ? argv[i+1] : "{this_file}");
263	>	printf("}\n");
264	>	putmapping(); /* put out color mapping */
265	>	}
266	>	if (debugfp != NULL) { /* put out debug picture */
267	>	if (scanning)
268		picdebug();
269		else
270		clrdebug();
271	+	}
272		exit(0);
273		userr:
274		fprintf(stderr,
275	<	"Usage: %s [-d dbg.pic][-p xul yul xur yur xll yll xlr ylr] input.pic [output.cal]\n",
275	>	"Usage: %s [-d dbg.pic][-P \| -p xul yul xur yur xll yll xlr ylr][-i irrad][-m] input.pic [output.{cal\|cwp}]\n",
276		progname);
277	<	fprintf(stderr, " or: %s [-d dbg.pic] -c [xyY.dat [output.cal]]\n",
277	>	fprintf(stderr, " or: %s [-d dbg.pic][-i irrad][-m] -c [xyY.dat [output.{cal\|cwp}]]\n",
278		progname);
279		exit(1);
280	+	return 1; /* pro forma return */
281		}
282
283
284	<	init() /* initialize */
284	>	static void
285	>	init(void) /* initialize */
286		{
287		double quad[4][2];
288		register int i;
#	Line 229 \| Line 301 \| *init() / initialize /*
301		exit(1);
302		}
303		/* map MacBeth colors to RGB space */
304	<	for (i = 0; i < 24; i++)
304	>	for (i = 0; i < 24; i++) {
305		xyY2RGB(mbRGB[i], mbxyY[i]);
306	+	scalecolor(mbRGB[i], irrad);
307	+	}
308		}
309
310
311	<	int
312	<	chartndx(x, y, cvg) /* find color number for position */
313	<	int x, y;
314	<	double cvg;
311	>	static int
312	>	chartndx( /* find color number for position */
313	>	int x,
314	>	int y,
315	>	int *np
316	>	)
317		{
318		double ipos[3], cpos[3];
319		int ix, iy;
320		double fx, fy;
245	–	double cmin, cmax;
321
322		ipos[0] = x;
323		ipos[1] = y;
#	Line 251 \| Line 326 \| double cvg;
326		cpos[0] /= cpos[2];
327		cpos[1] /= cpos[2];
328		if (cpos[0] < 0. \|\| cpos[0] >= 6. \|\| cpos[1] < 0. \|\| cpos[1] >= 4.)
329	<	return(-1);
329	>	return(RG_BORD);
330		ix = cpos[0];
331		iy = cpos[1];
332		fx = cpos[0] - ix;
333		fy = cpos[1] - iy;
334	<	cmin = .5*(1.-cvg);
335	<	cmax = 1. - cmin;
336	<	if (fx < cmin \|\| fx >= cmax \|\| fy < cmin \|\| fy >= cmax)
337	<	return(-1);
338	<	return(iy*6 + ix);
334	>	np = iy6 + ix;
335	>	if (fx >= 0.35 && fx < 0.65 && fy >= 0.35 && fy < 0.65)
336	>	return(RG_CENT);
337	>	if (fx < 0.05 \|\| fx >= 0.95 \|\| fy < 0.05 \|\| fy >= 0.95)
338	>	return(RG_BORD);
339	>	if (fx >= 0.5) /* right side is corrected */
340	>	return(RG_CORR);
341	>	return(RG_ORIG); /* left side is original */
342		}
343
344
345	<	getpicture() /* load in picture colors */
345	>	static void
346	>	getpicture(void) /* load in picture colors */
347		{
348		COLR *scanln;
349		COLOR pval;
350		int ccount[24];
351		double d;
352	<	int y;
353	<	register int x, i;
352	>	int y, i;
353	>	register int x;
354
355		scanln = (COLR )malloc(xmaxsizeof(COLR));
356		if (scanln == NULL) {
#	Line 288 \| Line 367 \| *getpicture() / load in picture colors /*
367		progname);
368		exit(1);
369		}
370	<	for (x = 0; x < xmax; x++) {
371	<	i = chartndx(x, y, CENTCVG);
293	<	if (i >= 0) {
370	>	for (x = 0; x < xmax; x++)
371	>	if (chartndx(x, y, &i) == RG_CENT) {
372		colr_color(pval, scanln[x]);
373		addcolor(inpRGB[i], pval);
374		ccount[i]++;
375		}
298	–	}
376		}
377		for (i = 0; i < 24; i++) { /* compute averages */
378		if (ccount[i] == 0)
#	Line 304 \| Line 381 \| *getpicture() / load in picture colors /*
381		scalecolor(inpRGB[i], d);
382		inpflags \|= 1L<<i;
383		}
384	<	free((char *)scanln);
384	>	free((void *)scanln);
385		}
386
387
388	<	getcolors() /* get xyY colors from standard input */
388	>	static void
389	>	getcolors(void) /* get xyY colors from standard input */
390		{
391		int gotwhite = 0;
392		COLOR whiteclr;
#	Line 316 \| Line 394 \| *getcolors() / get xyY colors from standard input /*
394		float xyYin[3];
395
396		while (fgetval(stdin, 'i', &n) == 1) { /* read colors */
397	<	if (n < 0 \| n > 24 \|\|
397	>	if ((n < 0) \| (n > 24) \|\|
398		fgetval(stdin, 'f', &xyYin[0]) != 1 \|\|
399		fgetval(stdin, 'f', &xyYin[1]) != 1 \|\|
400		fgetval(stdin, 'f', &xyYin[2]) != 1 \|\|
401	<	xyYin[0] < 0. \| xyYin[0] > 1. \|
402	<	xyYin[1] < 0. \| xyYin[1] > 1.) {
401	>	(xyYin[0] < 0.) \| (xyYin[1] < 0.) \|\|
402	>	xyYin[0] + xyYin[1] > 1.) {
403		fprintf(stderr, "%s: bad color input data\n",
404		progname);
405		exit(1);
#	Line 356 \| Line 434 \| *getcolors() / get xyY colors from standard input /*
434		}
435
436
437	<	bresp(y, x) /* piecewise linear interpolation of primaries */
438	<	COLOR y, x;
437	>	static void
438	>	bresp( /* piecewise linear interpolation of primaries */
439	>	COLOR y,
440	>	COLOR x
441	>	)
442		{
362	–	double cv[3];
443		register int i, n;
444
445		for (i = 0; i < 3; i++) {
446		for (n = 0; n < NMBNEU-2; n++)
447		if (colval(x,i) < colval(bramp[n+1][0],i))
448		break;
449	<	cv[i] = ((colval(bramp[n+1][0],i) - colval(x,i)) *
449	>	colval(y,i) = ((colval(bramp[n+1][0],i) - colval(x,i)) *
450		colval(bramp[n][1],i) +
451		(colval(x,i) - colval(bramp[n][0],i)) *
452		colval(bramp[n+1][1],i)) /
453		(colval(bramp[n+1][0],i) - colval(bramp[n][0],i));
374	–	if (cv[i] < 0.) cv[i] = 0.;
454		}
376	–	setcolor(y, cv[0], cv[1], cv[2]);
455		}
456
457
458	<	compute() /* compute color mapping */
458	>	static void
459	>	compute(void) /* compute color mapping */
460		{
461	<	COLOR clrin[NMBMOD], clrout[NMBMOD];
461	>	COLOR clrin[24], clrout[24];
462	>	long cflags;
463	>	COLOR ctmp;
464		register int i, n;
465		/* did we get what we need? */
466		if ((inpflags & REQFLGS) != REQFLGS) {
#	Line 390 \| Line 471 \| *compute() / compute color mapping /*
471		/* compute piecewise luminance curve */
472		for (i = 0; i < NMBNEU; i++) {
473		copycolor(bramp[i][0], inpRGB[mbneu[i]]);
474	+	for (n = i ? 3 : 0; n--; )
475	+	if (colval(bramp[i][0],n) <=
476	+	colval(bramp[i-1][0],n)+1e-7) {
477	+	fprintf(stderr,
478	+	"%s: non-increasing neutral patch\n", progname);
479	+	exit(1);
480	+	}
481		copycolor(bramp[i][1], mbRGB[mbneu[i]]);
482		}
483	<	/* compute color matrix */
484	<	for (n = 0, i = 0; i < NMBMOD; i++)
485	<	if (inpflags & 1L<<mbmod[i]) {
486	<	bresp(clrin[n], inpRGB[mbmod[i]]);
487	<	copycolor(clrout[n], mbRGB[mbmod[i]]);
488	<	n++;
483	>	/* compute color space gamut */
484	>	if (scanning) {
485	>	copycolor(colmin, cblack);
486	>	copycolor(colmax, cwhite);
487	>	scalecolor(colmax, irrad);
488	>	} else
489	>	for (i = 0; i < 3; i++) {
490	>	colval(colmin,i) = colval(bramp[0][0],i) -
491	>	colval(bramp[0][1],i) *
492	>	(colval(bramp[1][0],i)-colval(bramp[0][0],i)) /
493	>	(colval(bramp[1][1],i)-colval(bramp[1][0],i));
494	>	colval(colmax,i) = colval(bramp[NMBNEU-2][0],i) +
495	>	(1.-colval(bramp[NMBNEU-2][1],i)) *
496	>	(colval(bramp[NMBNEU-1][0],i) -
497	>	colval(bramp[NMBNEU-2][0],i)) /
498	>	(colval(bramp[NMBNEU-1][1],i) -
499	>	colval(bramp[NMBNEU-2][1],i));
500		}
501	<	compsoln(clrin, clrout, n);
501	>	/* compute color mapping */
502	>	do {
503	>	cflags = inpflags & ~gmtflags;
504	>	n = 0; /* compute transform matrix */
505	>	for (i = 0; i < 24; i++)
506	>	if (cflags & 1L<<i) {
507	>	bresp(clrin[n], inpRGB[i]);
508	>	copycolor(clrout[n], mbRGB[i]);
509	>	n++;
510	>	}
511	>	compsoln(clrin, clrout, n);
512	>	if (irrad > 0.99 && irrad < 1.01) /* check gamut */
513	>	for (i = 0; i < 24; i++)
514	>	if (cflags & 1L<<i && cvtcolor(ctmp, mbRGB[i]))
515	>	gmtflags \|= 1L<<i;
516	>	} while (cflags & gmtflags);
517	>	if (gmtflags & MODFLGS)
518	>	fprintf(stderr,
519	>	"%s: warning - some moderate colors are out of gamut\n",
520	>	progname);
521		}
522
523
524	<	putmapping() /* put out color mapping for pcomb -f */
524	>	static void
525	>	putmapping(void) /* put out color mapping */
526		{
527		static char cchar[3] = {'r', 'g', 'b'};
528		register int i, j;
#	Line 417 \| Line 536 \| putmapping() /* put out color mapping for pcomb -f *
536		for (i = 0; i < NMBNEU; i++)
537		printf(",%g", colval(bramp[i][1],j));
538		printf(");\n");
420	–	printf("%c = %ci(1);\n", cchar[j], cchar[j]);
539		printf("%cfi(n) = if(n-%g, %d, if(%cxa(n+1)-%c, n, %cfi(n+1)));\n",
540		cchar[j], NMBNEU-1.5, NMBNEU-1, cchar[j],
541		cchar[j], cchar[j]);
542		printf("%cndx = %cfi(1);\n", cchar[j], cchar[j]);
543	<	printf("%cn = ((%cxa(%cndx+1)-%c)*%cya(%cndx) + ",
544	<	cchar[j], cchar[j], cchar[j],
545	<	cchar[j], cchar[j], cchar[j]);
543	>	printf("%c%c = ((%cxa(%cndx+1)-%c)*%cya(%cndx) + ",
544	>	cchar[j], scanning?'n':'o', cchar[j],
545	>	cchar[j], cchar[j], cchar[j], cchar[j]);
546		printf("(%c-%cxa(%cndx))*%cya(%cndx+1)) /\n",
547		cchar[j], cchar[j], cchar[j],
548		cchar[j], cchar[j]);
#	Line 432 \| Line 550 \| putmapping() /* put out color mapping for pcomb -f *
550		cchar[j], cchar[j], cchar[j], cchar[j]);
551		}
552		/* print color mapping */
553	<	printf("ro = %grn + %ggn + %g*bn ;\n",
554	<	solmat[0][0], solmat[0][1], solmat[0][2]);
555	<	printf("go = %grn + %ggn + %g*bn ;\n",
556	<	solmat[1][0], solmat[1][1], solmat[1][2]);
557	<	printf("bo = %grn + %ggn + %g*bn ;\n",
558	<	solmat[2][0], solmat[2][1], solmat[2][2]);
553	>	if (scanning) {
554	>	printf("r = ri(1); g = gi(1); b = bi(1);\n");
555	>	printf("ro = %grn + %ggn + %g*bn ;\n",
556	>	solmat[0][0], solmat[0][1], solmat[0][2]);
557	>	printf("go = %grn + %ggn + %g*bn ;\n",
558	>	solmat[1][0], solmat[1][1], solmat[1][2]);
559	>	printf("bo = %grn + %ggn + %g*bn ;\n",
560	>	solmat[2][0], solmat[2][1], solmat[2][2]);
561	>	} else {
562	>	printf("r1 = ri(1); g1 = gi(1); b1 = bi(1);\n");
563	>	printf("r = %gr1 + %gg1 + %g*b1 ;\n",
564	>	solmat[0][0], solmat[0][1], solmat[0][2]);
565	>	printf("g = %gr1 + %gg1 + %g*b1 ;\n",
566	>	solmat[1][0], solmat[1][1], solmat[1][2]);
567	>	printf("b = %gr1 + %gg1 + %g*b1 ;\n",
568	>	solmat[2][0], solmat[2][1], solmat[2][2]);
569	>	}
570		}
571
572
573	<	compsoln(cin, cout, n) /* solve 3xN system using least-squares */
574	<	COLOR cin[], cout[];
575	<	int n;
573	>	static void
574	>	compsoln( /* solve 3xN system using least-squares */
575	>	COLOR cin[],
576	>	COLOR cout[],
577	>	int n
578	>	)
579		{
580		extern double mx3d_adjoint(), fabs();
581		double mat[3][3], invmat[3][3];
#	Line 451 \| Line 583 \| int n;
583		double colv[3], rowv[3];
584		register int i, j, k;
585
586	<	if (n < 3 \| n > NMBMOD) {
587	<	fprintf(stderr, "%s: bad number of colors to match\n", progname);
586	>	if (n < 3) {
587	>	fprintf(stderr, "%s: too few colors to match!\n", progname);
588		exit(1);
589		}
590		if (n == 3)
#	Line 501 \| Line 633 \| int n;
633		}
634
635
636	<	cvtcolor(cout, cin) /* convert color according to our mapping */
637	<	COLOR cout, cin;
636	>	static void
637	>	cwarp(void) /* compute color warp map */
638		{
639	<	double r, g, b;
639	>	register int i;
640
641	<	bresp(cout, cin);
642	<	r = colval(cout,0)solmat[0][0] + colval(cout,1)solmat[0][1]
643	<	+ colval(cout,2)*solmat[0][2];
644	<	if (r < 0) r = 0;
645	<	g = colval(cout,0)solmat[1][0] + colval(cout,1)solmat[1][1]
646	<	+ colval(cout,2)*solmat[1][2];
647	<	if (g < 0) g = 0;
648	<	b = colval(cout,0)solmat[2][0] + colval(cout,1)solmat[2][1]
649	<	+ colval(cout,2)*solmat[2][2];
518	<	if (b < 0) b = 0;
519	<	setcolor(cout, r, g, b);
641	>	if ((wcor = new3dw(W3EXACT)) == NULL)
642	>	goto memerr;
643	>	for (i = 0; i < 24; i++)
644	>	if (!add3dpt(wcor, inpRGB[i], mbRGB[i]))
645	>	goto memerr;
646	>	return;
647	>	memerr:
648	>	perror(progname);
649	>	exit(1);
650		}
651
652
653	<	xyY2RGB(rgbout, xyYin) /* convert xyY to RGB */
654	<	COLOR rgbout;
655	<	register float xyYin[3];
653	>	static int
654	>	cvtcolor( /* convert color according to our mapping */
655	>	COLOR cout,
656	>	COLOR cin
657	>	)
658		{
659		COLOR ctmp;
660	+	int clipped;
661	+
662	+	if (wcor != NULL) {
663	+	clipped = warp3d(cout, cin, wcor);
664	+	clipped \|= clipgamut(cout,bright(cout),CGAMUT,colmin,colmax);
665	+	} else if (scanning) {
666	+	bresp(ctmp, cin);
667	+	clipped = cresp(cout, ctmp);
668	+	} else {
669	+	clipped = cresp(ctmp, cin);
670	+	bresp(cout, ctmp);
671	+	}
672	+	return(clipped);
673	+	}
674	+
675	+
676	+	static int
677	+	cresp( /* transform color according to matrix */
678	+	COLOR cout,
679	+	COLOR cin
680	+	)
681	+	{
682	+	colortrans(cout, solmat, cin);
683	+	return(clipgamut(cout, bright(cout), CGAMUT, colmin, colmax));
684	+	}
685	+
686	+
687	+	static void
688	+	xyY2RGB( /* convert xyY to RGB */
689	+	COLOR rgbout,
690	+	register float xyYin[3]
691	+	)
692	+	{
693	+	COLOR ctmp;
694		double d;
695
696		d = xyYin[2] / xyYin[1];
697		ctmp[0] = xyYin[0] * d;
698		ctmp[1] = xyYin[2];
699		ctmp[2] = (1. - xyYin[0] - xyYin[1]) * d;
700	<	cie_rgb(rgbout, ctmp);
700	>	/* allow negative values */
701	>	colortrans(rgbout, xyz2rgbmat, ctmp);
702		}
703
704
705	<	picdebug() /* put out debugging picture */
705	>	static void
706	>	picdebug(void) /* put out debugging picture */
707		{
708	+	static COLOR blkcol = BLKCOLOR;
709		COLOR *scan;
710	<	int y;
711	<	register int x, i;
710	>	int y, i;
711	>	register int x, rg;
712
713		if (fseek(stdin, 0L, 0) == EOF) {
714		fprintf(stderr, "%s: cannot seek on input picture\n", progname);
#	Line 565 \| Line 734 \| *picdebug() / put out debugging picture /*
734		exit(1);
735		}
736		for (x = 0; x < xmax; x++) {
737	<	i = chartndx(x, y, CENTCVG);
738	<	if (i < 0)
737	>	rg = chartndx(x, y, &i);
738	>	if (rg == RG_CENT) {
739	>	if (!(1L<<i & gmtflags) \|\| (x+y)&07) {
740	>	copycolor(scan[x], mbRGB[i]);
741	>	clipgamut(scan[x], bright(scan[x]),
742	>	CGAMUT, colmin, colmax);
743	>	} else
744	>	copycolor(scan[x], blkcol);
745	>	} else if (rg == RG_CORR)
746		cvtcolor(scan[x], scan[x]);
747	<	else
748	<	copycolor(scan[x], mbRGB[i]);
747	>	else if (rg != RG_ORIG)
748	>	copycolor(scan[x], blkcol);
749		}
750		if (fwritescan(scan, xmax, debugfp) < 0) {
751		fprintf(stderr, "%s: error writing debugging picture\n",
#	Line 579 \| Line 755 \| *picdebug() / put out debugging picture /*
755		}
756		/* clean up */
757		fclose(debugfp);
758	<	free((char *)scan);
758	>	free((void *)scan);
759		}
760
761
762	<	clrdebug() /* put out debug picture from color input */
762	>	static void
763	>	clrdebug(void) /* put out debug picture from color input */
764		{
765		static COLR blkclr = BLKCOLR;
766	<	COLR mbclr[24], cvclr[24];
766	>	COLR mbclr[24], cvclr[24], orclr[24];
767		COLR *scan;
768	<	COLOR ctmp;
769	<	int y;
770	<	register int i, x;
768	>	COLOR ctmp, ct2;
769	>	int y, i;
770	>	register int x, rg;
771		/* convert colors */
772		for (i = 0; i < 24; i++) {
773	<	setcolr(mbclr[i], colval(mbRGB[i],RED),
774	<	colval(mbRGB[i],GRN), colval(mbRGB[i],BLU));
773	>	copycolor(ctmp, mbRGB[i]);
774	>	clipgamut(ctmp, bright(ctmp), CGAMUT, cblack, cwhite);
775	>	setcolr(mbclr[i], colval(ctmp,RED),
776	>	colval(ctmp,GRN), colval(ctmp,BLU));
777		if (inpflags & 1L<<i) {
778	<	cvtcolor(ctmp, inpRGB[i]);
779	<	setcolr(cvclr[i], colval(ctmp,RED),
778	>	copycolor(ctmp, inpRGB[i]);
779	>	clipgamut(ctmp, bright(ctmp), CGAMUT, cblack, cwhite);
780	>	setcolr(orclr[i], colval(ctmp,RED),
781		colval(ctmp,GRN), colval(ctmp,BLU));
782	+	if (rawmap)
783	+	copycolr(cvclr[i], mbclr[i]);
784	+	else {
785	+	bresp(ctmp, inpRGB[i]);
786	+	colortrans(ct2, solmat, ctmp);
787	+	clipgamut(ct2, bright(ct2), CGAMUT,
788	+	cblack, cwhite);
789	+	setcolr(cvclr[i], colval(ct2,RED),
790	+	colval(ct2,GRN),
791	+	colval(ct2,BLU));
792	+	}
793		}
794		}
795		/* allocate scanline */
#	Line 613 \| Line 804 \| *clrdebug() / put out debug picture from color input**
804		fprtresolu(xmax, ymax, debugfp);
805		/* write debug picture */
806		for (y = ymax-1; y >= 0; y--) {
807	<	for (x = 0; x < xmax; x++)
808	<	if ((i = chartndx(x, y, CENTCVG)) >= 0)
809	<	copycolr(scan[x], mbclr[i]);
810	<	else if ((i = chartndx(x, y, FULLCVG)) >= 0 &&
811	<	inpflags & 1L<<i)
812	<	copycolr(scan[x], cvclr[i]);
813	<	else
807	>	for (x = 0; x < xmax; x++) {
808	>	rg = chartndx(x, y, &i);
809	>	if (rg == RG_CENT) {
810	>	if (!(1L<<i & gmtflags) \|\| (x+y)&07)
811	>	copycolr(scan[x], mbclr[i]);
812	>	else
813	>	copycolr(scan[x], blkclr);
814	>	} else if (rg == RG_BORD \|\| !(1L<<i & inpflags))
815		copycolr(scan[x], blkclr);
816	+	else if (rg == RG_ORIG)
817	+	copycolr(scan[x], orclr[i]);
818	+	else /* rg == RG_CORR */
819	+	copycolr(scan[x], cvclr[i]);
820	+	}
821		if (fwritecolrs(scan, xmax, debugfp) < 0) {
822		fprintf(stderr, "%s: error writing debugging picture\n",
823		progname);
#	Line 629 \| Line 826 \| *clrdebug() / put out debug picture from color input**
826		}
827		/* clean up */
828		fclose(debugfp);
829	<	free((char *)scan);
829	>	free((void *)scan);
830	>	}
831	>
832	>
833	>	static void
834	>	getpos( /* get boundary position */
835	>	char *name,
836	>	int bnds[2],
837	>	FILE *fp
838	>	)
839	>	{
840	>	char buf[64];
841	>
842	>	fprintf(stderr, "\tSelect corner: %s\n", name);
843	>	if (fgets(buf, sizeof(buf), fp) == NULL \|\|
844	>	sscanf(buf, "%d %d", &bnds[0], &bnds[1]) != 2) {
845	>	fprintf(stderr, "%s: read error from display process\n",
846	>	progname);
847	>	exit(1);
848	>	}
849	>	}
850	>
851	>
852	>	static void
853	>	pickchartpos( /* display picture and pick chart location */
854	>	char *pfn
855	>	)
856	>	{
857	>	char combuf[PATH_MAX];
858	>	FILE *pfp;
859	>
860	>	sprintf(combuf, DISPCOM, pfn);
861	>	if ((pfp = popen(combuf, "r")) == NULL) {
862	>	perror(combuf);
863	>	exit(1);
864	>	}
865	>	fputs("Use middle mouse button to select chart corners:\n", stderr);
866	>	getpos("upper left (dark skin)", bounds[0], pfp);
867	>	getpos("upper right (bluish green)", bounds[1], pfp);
868	>	getpos("lower left (white)", bounds[2], pfp);
869	>	getpos("lower right (black)", bounds[3], pfp);
870	>	fputs("Got it -- quit display program.\n", stderr);
871	>	pclose(pfp);
872		}

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Comparing ray/src/px/macbethcal.c (file contents): Revision 2.7 by greg, Fri Oct 20 15:26:11 1995 UTC vs. Revision 2.24 by greg, Wed Dec 15 06:30:36 2004 UTC

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Comparing ray/src/px/macbethcal.c (file contents):
Revision 2.7 by greg, Fri Oct 20 15:26:11 1995 UTC vs.
Revision 2.24 by greg, Wed Dec 15 06:30:36 2004 UTC