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

Comparing ray/src/px/pinterp.c (file contents):
Revision 1.20 by greg, Tue Jan 16 16:10:57 1990 UTC vs.
Revision 2.17 by greg, Fri Dec 23 17:23:05 1994 UTC

#	Line 1 \| Line 1
1	+	/* Copyright (c) 1994 Regents of the University of California */
2	+
3		#ifndef lint
4		static char SCCSid[] = "$SunId$ LBL";
5		#endif
#	Line 10 \| Line 12 \| static char SCCSid[] = "$SunId$ LBL";
12
13		#include "standard.h"
14
15	<	#include <sys/fcntl.h>
15	>	#include <ctype.h>
16
17		#include "view.h"
18
19		#include "color.h"
20
21	+	#include "resolu.h"
22	+
23		#define pscan(y) (ourpict+(y)*hresolu)
24		#define zscan(y) (ourzbuf+(y)*hresolu)
25
26		#define F_FORE 1 /* fill foreground */
27		#define F_BACK 2 /* fill background */
28
29	<	#define PACKSIZ 42 /* calculation packet size */
29	>	#define PACKSIZ 256 /* max. calculation packet size */
30
31	<	#define RTCOM "rtrace -h -ovl -fff -x %d %s"
31	>	#define RTCOM "rtrace -h- -ovl -fff "
32
33		#define ABS(x) ((x)>0?(x):-(x))
34
35		struct position {int x,y; float z;};
36
37	+	#define NSTEPS 64 /* number steps in overlap prescan */
38	+	#define MINSTEP 4 /* minimum worthwhile preview step */
39	+
40	+	struct bound {int min,max;};
41	+
42		VIEW ourview = STDVIEW; /* desired view */
43		int hresolu = 512; /* horizontal resolution */
44		int vresolu = 512; /* vertical resolution */
#	Line 42 \| Line 51 \| *float ourzbuf; /* corresponding z-buffer /*
51
52		char *progname;
53
54	<	int fill = F_FORE\|F_BACK; /* selected fill algorithm */
54	>	int fillo = F_FORE\|F_BACK; /* selected fill options */
55	>	int fillsamp = 0; /* sample separation (0 == inf) */
56		extern int backfill(), rcalfill(); /* fill functions */
57	<	int (deffill)() = backfill; / selected fill function */
57	>	int (fillfunc)() = backfill; / selected fill function */
58		COLR backcolr = BLKCOLR; /* background color */
59		double backz = 0.0; /* background z value */
60		int normdist = 1; /* normalized distance? */
#	Line 52 \| Line 62 \| *double ourexp = -1; / output picture exposure /*
62
63		VIEW theirview = STDVIEW; /* input view */
64		int gotview; /* got input view? */
65	<	int thresolu, tvresolu; /* input resolution */
65	>	int wrongformat = 0; /* input in another format? */
66	>	RESOLU tresolu; /* input resolution */
67		double theirexp; /* input picture exposure */
68		double theirs2ours[4][4]; /* transformation matrix */
69	+	int hasmatrix = 0; /* has transformation matrix */
70
71	<	int childpid = -1; /* id of fill process */
72	<	FILE psend, precv; /* pipes to/from fill calculation */
73	<	int queue[PACKSIZ][2]; /* pending pixels */
71	>	int PDesc[3] = {-1,-1,-1}; /* rtrace process descriptor */
72	>	#define childpid (PDesc[2])
73	>	unsigned short queue[PACKSIZ][2]; /* pending pixels */
74	>	int packsiz; /* actual packet size */
75		int queuesiz; /* number of pixels pending */
76
77
#	Line 66 \| Line 79 \| *main(argc, argv) / interpolate pictures /*
79		int argc;
80		char *argv[];
81		{
82	<	#define check(olen,narg) if (argv[i][olen] \|\| narg >= argc-i) goto badopt
83	<	extern double atof();
82	>	#define check(ol,al) if (argv[i][ol] \|\| \
83	>	badarg(argc-i-1,argv+i+1,al)) \
84	>	goto badopt
85		int gotvfile = 0;
86		char *zfile = NULL;
87		char *err;
#	Line 83 \| Line 97 \| *char argv[];**
97		}
98		switch (argv[i][1]) {
99		case 't': /* threshold */
100	<	check(2,1);
100	>	check(2,"f");
101		zeps = atof(argv[++i]);
102		break;
103		case 'n': /* dist. normalized? */
104	<	check(2,0);
104	>	check(2,NULL);
105		normdist = !normdist;
106		break;
107		case 'f': /* fill type */
108		switch (argv[i][2]) {
109		case '0': /* none */
110	<	check(3,0);
111	<	fill = 0;
110	>	check(3,NULL);
111	>	fillo = 0;
112		break;
113		case 'f': /* foreground */
114	<	check(3,0);
115	<	fill = F_FORE;
114	>	check(3,NULL);
115	>	fillo = F_FORE;
116		break;
117		case 'b': /* background */
118	<	check(3,0);
119	<	fill = F_BACK;
118	>	check(3,NULL);
119	>	fillo = F_BACK;
120		break;
121		case 'a': /* all */
122	<	check(3,0);
123	<	fill = F_FORE\|F_BACK;
122	>	check(3,NULL);
123	>	fillo = F_FORE\|F_BACK;
124		break;
125	+	case 's': /* sample */
126	+	check(3,"i");
127	+	fillsamp = atoi(argv[++i]);
128	+	break;
129		case 'c': /* color */
130	<	check(3,3);
131	<	deffill = backfill;
130	>	check(3,"fff");
131	>	fillfunc = backfill;
132		setcolr(backcolr, atof(argv[i+1]),
133		atof(argv[i+2]), atof(argv[i+3]));
134		i += 3;
135		break;
136		case 'z': /* z value */
137	<	check(3,1);
138	<	deffill = backfill;
137	>	check(3,"f");
138	>	fillfunc = backfill;
139		backz = atof(argv[++i]);
140		break;
141		case 'r': /* rtrace */
142	<	check(3,1);
143	<	deffill = rcalfill;
142	>	check(3,"s");
143	>	fillfunc = rcalfill;
144		calstart(RTCOM, argv[++i]);
145		break;
146		default:
#	Line 130 \| Line 148 \| *char argv[];**
148		}
149		break;
150		case 'z': /* z file */
151	<	check(2,1);
151	>	check(2,"s");
152		zfile = argv[++i];
153		break;
154		case 'x': /* x resolution */
155	<	check(2,1);
155	>	check(2,"i");
156		hresolu = atoi(argv[++i]);
157		break;
158		case 'y': /* y resolution */
159	<	check(2,1);
159	>	check(2,"i");
160		vresolu = atoi(argv[++i]);
161		break;
162		case 'p': /* pixel aspect */
163	<	check(2,1);
163	>	if (argv[i][2] != 'a')
164	>	goto badopt;
165	>	check(3,"f");
166		pixaspect = atof(argv[++i]);
167		break;
168		case 'v': /* view file */
169		if (argv[i][2] != 'f')
170		goto badopt;
171	<	check(3,1);
171	>	check(3,"s");
172		gotvfile = viewfile(argv[++i], &ourview, 0, 0);
173	<	if (gotvfile < 0) {
174	<	perror(argv[i]);
175	<	exit(1);
156	<	} else if (gotvfile == 0) {
173	>	if (gotvfile < 0)
174	>	syserror(argv[i]);
175	>	else if (gotvfile == 0) {
176		fprintf(stderr, "%s: bad view file\n",
177		argv[i]);
178		exit(1);
#	Line 169 \| Line 188 \| *char argv[];**
188		/* check arguments */
189		if ((argc-i)%2)
190		goto userr;
191	+	if (fillsamp == 1)
192	+	fillo &= ~F_BACK;
193		/* set view */
194	<	if (err = setview(&ourview)) {
194	>	if ((err = setview(&ourview)) != NULL) {
195		fprintf(stderr, "%s: %s\n", progname, err);
196		exit(1);
197		}
198		normaspect(viewaspect(&ourview), &pixaspect, &hresolu, &vresolu);
199		/* allocate frame */
200	<	ourpict = (COLR )malloc(hresoluvresolu*sizeof(COLR));
201	<	ourzbuf = (float )calloc(hresoluvresolu,sizeof(float));
200	>	ourpict = (COLR )bmalloc(hresoluvresolu*sizeof(COLR));
201	>	ourzbuf = (float )bmalloc(hresoluvresolu*sizeof(float));
202		if (ourpict == NULL \|\| ourzbuf == NULL)
203	<	syserror();
203	>	syserror(progname);
204	>	bzero((char )ourzbuf, hresoluvresolu*sizeof(float));
205	>	/* new header */
206	>	newheader("RADIANCE", stdout);
207		/* get input */
208		for ( ; i < argc; i += 2)
209		addpicture(argv[i], argv[i+1]);
210		/* fill in spaces */
211	<	if (fill&F_BACK)
212	<	backpicture();
211	>	if (fillo&F_BACK)
212	>	backpicture(fillfunc, fillsamp);
213		else
214	<	fillpicture();
214	>	fillpicture(fillfunc);
215		/* close calculation */
216		caldone();
217	+	/* aft clipping */
218	+	clipaft();
219		/* add to header */
220		printargs(argc, argv, stdout);
221		if (gotvfile) {
222	<	printf(VIEWSTR);
222	>	fputs(VIEWSTR, stdout);
223		fprintview(&ourview, stdout);
224	<	printf("\n");
224	>	putc('\n', stdout);
225		}
226		if (pixaspect < .99 \|\| pixaspect > 1.01)
227		fputaspect(pixaspect, stdout);
228		if (ourexp > 0 && (ourexp < .995 \|\| ourexp > 1.005))
229		fputexpos(ourexp, stdout);
230	<	printf("\n");
230	>	fputformat(COLRFMT, stdout);
231	>	putc('\n', stdout);
232		/* write picture */
233		writepicture();
234		/* write z file */
#	Line 221 \| Line 248 \| userr:
248		headline(s) /* process header string */
249		char *s;
250		{
251	<	static char *altname[] = {"rview","rpict","pinterp",VIEWSTR,NULL};
225	<	register char **an;
251	>	char fmt[32];
252
253	<	printf("\t%s", s);
253	>	if (isheadid(s))
254	>	return;
255	>	if (formatval(fmt, s)) {
256	>	wrongformat = strcmp(fmt, COLRFMT);
257	>	return;
258	>	}
259	>	putc('\t', stdout);
260	>	fputs(s, stdout);
261
262		if (isexpos(s)) {
263		theirexp *= exposval(s);
264		return;
265		}
266	<	for (an = altname; *an != NULL; an++)
267	<	if (!strncmp(an, s, strlen(an))) {
235	<	if (sscanview(&theirview, s+strlen(*an)) > 0)
236	<	gotview++;
237	<	break;
238	<	}
266	>	if (isview(s) && sscanview(&theirview, s) > 0)
267	>	gotview++;
268		}
269
270
271		addpicture(pfile, zspec) /* add picture to output */
272		char pfile, zspec;
273		{
245	–	extern double atof();
274		FILE *pfp;
275		int zfd;
276		char *err;
277		COLR *scanin;
278		float *zin;
279		struct position *plast;
280	+	struct bound *xlim, ylim;
281		int y;
282		/* open picture file */
283	<	if ((pfp = fopen(pfile, "r")) == NULL) {
284	<	perror(pfile);
256	<	exit(1);
257	<	}
283	>	if ((pfp = fopen(pfile, "r")) == NULL)
284	>	syserror(pfile);
285		/* get header with exposure and view */
286		theirexp = 1.0;
287		gotview = 0;
288		printf("%s:\n", pfile);
289	<	getheader(pfp, headline);
290	<	if (!gotview \|\| fgetresolu(&thresolu, &tvresolu, pfp)
291	<	!= (YMAJOR\|YDECR)) {
265	<	fprintf(stderr, "%s: picture view error\n", pfile);
289	>	getheader(pfp, headline, NULL);
290	>	if (wrongformat \|\| !gotview \|\| !fgetsresolu(&tresolu, pfp)) {
291	>	fprintf(stderr, "%s: picture format error\n", pfile);
292		exit(1);
293		}
294		if (ourexp <= 0)
#	Line 274 \| Line 300 \| *char pfile, zspec;*
300		exit(1);
301		}
302		/* compute transformation */
303	<	pixform(theirs2ours, &theirview, &ourview);
278	<	/* allocate scanlines */
279	<	scanin = (COLR )malloc(thresolusizeof(COLR));
280	<	zin = (float )malloc(thresolusizeof(float));
281	<	plast = (struct position *)calloc(thresolu, sizeof(struct position));
282	<	if (scanin == NULL \|\| zin == NULL \|\| plast == NULL)
283	<	syserror();
303	>	hasmatrix = pixform(theirs2ours, &theirview, &ourview);
304		/* get z specification or file */
305	+	zin = (float )malloc(scanlen(&tresolu)sizeof(float));
306	+	if (zin == NULL)
307	+	syserror(progname);
308		if ((zfd = open(zspec, O_RDONLY)) == -1) {
309		double zvalue;
310		register int x;
311	<	if (!isfloat(zspec) \|\| (zvalue = atof(zspec)) <= 0.0) {
312	<	perror(zspec);
313	<	exit(1);
291	<	}
292	<	for (x = 0; x < thresolu; x++)
311	>	if (!isfloat(zspec) \|\| (zvalue = atof(zspec)) <= 0.0)
312	>	syserror(zspec);
313	>	for (x = scanlen(&tresolu); x-- > 0; )
314		zin[x] = zvalue;
315		}
316	<	/* load image */
317	<	for (y = tvresolu-1; y >= 0; y--) {
318	<	if (freadcolrs(scanin, thresolu, pfp) < 0) {
316	>	/* compute transferrable perimeter */
317	>	xlim = (struct bound )malloc(numscans(&tresolu)sizeof(struct bound));
318	>	if (xlim == NULL)
319	>	syserror(progname);
320	>	if (!getperim(xlim, &ylim, zin, zfd)) { /* overlapping area? */
321	>	free((char *)zin);
322	>	free((char *)xlim);
323	>	if (zfd != -1)
324	>	close(zfd);
325	>	fclose(pfp);
326	>	return;
327	>	}
328	>	/* allocate scanlines */
329	>	scanin = (COLR )malloc(scanlen(&tresolu)sizeof(COLR));
330	>	plast = (struct position *)calloc(scanlen(&tresolu),
331	>	sizeof(struct position));
332	>	if (scanin == NULL \| plast == NULL)
333	>	syserror(progname);
334	>	/* skip to starting point */
335	>	for (y = 0; y < ylim.min; y++)
336	>	if (freadcolrs(scanin, scanlen(&tresolu), pfp) < 0) {
337		fprintf(stderr, "%s: read error\n", pfile);
338		exit(1);
339		}
340	<	if (zfd != -1 && read(zfd,zin,thresolu*sizeof(float))
341	<	< thresolu*sizeof(float)) {
342	<	fprintf(stderr, "%s: read error\n", zspec);
340	>	if (zfd != -1 && lseek(zfd,
341	>	(long)ylim.minscanlen(&tresolu)sizeof(float), 0) < 0)
342	>	syserror(zspec);
343	>	/* load image */
344	>	for (y = ylim.min; y <= ylim.max; y++) {
345	>	if (freadcolrs(scanin, scanlen(&tresolu), pfp) < 0) {
346	>	fprintf(stderr, "%s: read error\n", pfile);
347		exit(1);
348		}
349	<	addscanline(y, scanin, zin, plast);
349	>	if (zfd != -1 && read(zfd, (char *)zin,
350	>	scanlen(&tresolu)*sizeof(float))
351	>	< scanlen(&tresolu)*sizeof(float))
352	>	syserror(zspec);
353	>	addscanline(xlim+y, y, scanin, zin, plast);
354		}
355		/* clean up */
356	+	free((char *)xlim);
357		free((char *)scanin);
358		free((char *)zin);
359		free((char *)plast);
#	Line 321 \| Line 369 \| *register VIEW vw1, vw2;*
369		{
370		double m4t[4][4];
371
372	+	if (vw1->type != VT_PER && vw1->type != VT_PAR)
373	+	return(0);
374	+	if (vw2->type != VT_PER && vw2->type != VT_PAR)
375	+	return(0);
376		setident4(xfmat);
377		xfmat[0][0] = vw1->hvec[0];
378		xfmat[0][1] = vw1->hvec[1];
#	Line 348 \| Line 400 \| *register VIEW vw1, vw2;*
400		m4t[2][2] = vw2->vdir[2];
401		m4t[3][2] = -DOT(vw2->vp,vw2->vdir);
402		multmat4(xfmat, xfmat, m4t);
403	+	return(1);
404		}
405
406
407	<	addscanline(y, pline, zline, lasty) /* add scanline to output */
407	>	addscanline(xl, y, pline, zline, lasty) /* add scanline to output */
408	>	struct bound *xl;
409		int y;
410		COLR *pline;
411		float *zline;
412		struct position lasty; / input/output */
413		{
414	<	extern double sqrt();
361	<	double pos[3];
414	>	FVECT pos;
415		struct position lastx, newpos;
416		register int x;
417
418		lastx.z = 0;
419	<	for (x = thresolu-1; x >= 0; x--) {
420	<	pos[0] = (x+.5)/thresolu + theirview.hoff - .5;
368	<	pos[1] = (y+.5)/tvresolu + theirview.voff - .5;
419	>	for (x = xl->max; x >= xl->min; x--) {
420	>	pix2loc(pos, &tresolu, x, y);
421		pos[2] = zline[x];
422	<	if (theirview.type == VT_PER) {
371	<	if (normdist) /* adjust for eye-ray distance */
372	<	pos[2] /= sqrt( 1.
373	<	+ pos[0]pos[0]theirview.hn2
374	<	+ pos[1]pos[1]theirview.vn2 );
375	<	pos[0] *= pos[2];
376	<	pos[1] *= pos[2];
377	<	}
378	<	multp3(pos, pos, theirs2ours);
379	<	if (pos[2] <= 0) {
422	>	if (movepixel(pos) < 0) {
423		lasty[x].z = lastx.z = 0; /* mark invalid */
424		continue;
425		}
383	–	if (ourview.type == VT_PER) {
384	–	pos[0] /= pos[2];
385	–	pos[1] /= pos[2];
386	–	}
387	–	pos[0] += .5 - ourview.hoff;
388	–	pos[1] += .5 - ourview.voff;
426		newpos.x = pos[0] * hresolu;
427		newpos.y = pos[1] * vresolu;
428		newpos.z = zline[x];
#	Line 415 \| Line 452 \| double z;
452		register int x, y; /* final position */
453
454		/* compute vector p0p1 */
455	<	if (fill&F_FORE && ABS(p1->z-p0->z) <= zt) {
455	>	if (fillo&F_FORE && ABS(p1->z-p0->z) <= zt) {
456		s1x = p1->x - p0->x;
457		s1y = p1->y - p0->y;
458		l1 = ABS(s1x);
#	Line 426 \| Line 463 \| double z;
463		p1isy = -1;
464		}
465		/* compute vector p0p2 */
466	<	if (fill&F_FORE && ABS(p2->z-p0->z) <= zt) {
466	>	if (fillo&F_FORE && ABS(p2->z-p0->z) <= zt) {
467		s2x = p2->x - p0->x;
468		s2y = p2->y - p0->y;
469		if (p1isy == 1)
#	Line 444 \| Line 481 \| double z;
481		y1 = p0->y + c1*s1y/l1;
482		for (c2 = l2; c2-- > 0; ) {
483		x = x1 + c2*s2x/l2;
484	+	if (x < 0 \|\| x >= hresolu)
485	+	continue;
486		y = y1 + c2*s2y/l2;
487	+	if (y < 0 \|\| y >= vresolu)
488	+	continue;
489		if (zscan(y)[x] <= 0 \|\| zscan(y)[x]-z
490		> zeps*zscan(y)[x]) {
491		zscan(y)[x] = z;
#	Line 455 \| Line 496 \| double z;
496		}
497
498
499	<	backpicture() /* background fill algorithm */
499	>	getperim(xl, yl, zline, zfd) /* compute overlapping image area */
500	>	register struct bound *xl;
501	>	struct bound *yl;
502	>	float *zline;
503	>	int zfd;
504		{
505	+	int step;
506	+	FVECT pos;
507	+	register int x, y;
508	+	/* set up step size */
509	+	if (scanlen(&tresolu) < numscans(&tresolu))
510	+	step = scanlen(&tresolu)/NSTEPS;
511	+	else
512	+	step = numscans(&tresolu)/NSTEPS;
513	+	if (step < MINSTEP) { /* not worth cropping? */
514	+	yl->min = 0;
515	+	yl->max = numscans(&tresolu) - 1;
516	+	x = scanlen(&tresolu) - 1;
517	+	for (y = numscans(&tresolu); y--; ) {
518	+	xl[y].min = 0;
519	+	xl[y].max = x;
520	+	}
521	+	return(1);
522	+	}
523	+	yl->min = 32000; yl->max = 0; /* search for points on image */
524	+	for (y = step - 1; y < numscans(&tresolu); y += step) {
525	+	if (zfd != -1) {
526	+	if (lseek(zfd, (long)yscanlen(&tresolu)sizeof(float),
527	+	0) < 0)
528	+	syserror("lseek");
529	+	if (read(zfd, (char *)zline,
530	+	scanlen(&tresolu)*sizeof(float))
531	+	< scanlen(&tresolu)*sizeof(float))
532	+	syserror("read");
533	+	}
534	+	xl[y].min = 32000; xl[y].max = 0; /* x max */
535	+	for (x = scanlen(&tresolu); (x -= step) > 0; ) {
536	+	pix2loc(pos, &tresolu, x, y);
537	+	pos[2] = zline[x];
538	+	if (movepixel(pos) == 0 && pos[0] >= 0 &&
539	+	pos[0] < 1 && pos[1] >= 0 &&
540	+	pos[1] < 1) {
541	+	xl[y].max = x + step - 1;
542	+	xl[y].min = x - step + 1; /* x min */
543	+	if (xl[y].min < 0)
544	+	xl[y].min = 0;
545	+	for (x = step - 1; x < xl[y].max; x += step) {
546	+	pix2loc(pos, &tresolu, x, y);
547	+	pos[2] = zline[x];
548	+	if (movepixel(pos) == 0 &&
549	+	pos[0] >= 0 &&
550	+	pos[0] < 1 &&
551	+	pos[1] >= 0 &&
552	+	pos[1] < 1) {
553	+	xl[y].min = x - step + 1;
554	+	break;
555	+	}
556	+	}
557	+	if (y < yl->min) /* y limits */
558	+	yl->min = y - step + 1;
559	+	yl->max = y + step - 1;
560	+	break;
561	+	}
562	+	}
563	+	/* fill in between */
564	+	if (xl[y].min < xl[y-step].min)
565	+	xl[y-1].min = xl[y].min;
566	+	else
567	+	xl[y-1].min = xl[y-step].min;
568	+	if (xl[y].max > xl[y-step].max)
569	+	xl[y-1].max = xl[y].max;
570	+	else
571	+	xl[y-1].max = xl[y-step].max;
572	+	for (x = 2; x < step; x++)
573	+	copystruct(xl+y-x, xl+y-1);
574	+	}
575	+	if (yl->max >= numscans(&tresolu))
576	+	yl->max = numscans(&tresolu) - 1;
577	+	for (x = numscans(&tresolu) - 1; x > y; x--) /* fill bottom rows */
578	+	copystruct(xl+x, xl+y);
579	+	return(yl->max >= yl->min);
580	+	}
581	+
582	+
583	+	movepixel(pos) /* reposition image point */
584	+	FVECT pos;
585	+	{
586	+	double d0, d1;
587	+	FVECT pt, direc;
588	+
589	+	if (pos[2] <= 0) /* empty pixel */
590	+	return(-1);
591	+	if (normdist && theirview.type == VT_PER) { /* adjust distance */
592	+	d0 = pos[0] + theirview.hoff - .5;
593	+	d1 = pos[1] + theirview.voff - .5;
594	+	pos[2] /= sqrt(1. + d0d0theirview.hn2 + d1d1theirview.vn2);
595	+	}
596	+	if (hasmatrix) {
597	+	pos[0] += theirview.hoff - .5;
598	+	pos[1] += theirview.voff - .5;
599	+	if (theirview.type == VT_PER) {
600	+	pos[0] *= pos[2];
601	+	pos[1] *= pos[2];
602	+	}
603	+	multp3(pos, pos, theirs2ours);
604	+	if (pos[2] <= 0)
605	+	return(-1);
606	+	if (ourview.type == VT_PER) {
607	+	pos[0] /= pos[2];
608	+	pos[1] /= pos[2];
609	+	}
610	+	pos[0] += .5 - ourview.hoff;
611	+	pos[1] += .5 - ourview.voff;
612	+	return(0);
613	+	}
614	+	if (viewray(pt, direc, &theirview, pos[0], pos[1]) < -FTINY)
615	+	return(-1);
616	+	pt[0] += direc[0]*pos[2];
617	+	pt[1] += direc[1]*pos[2];
618	+	pt[2] += direc[2]*pos[2];
619	+	viewloc(pos, &ourview, pt);
620	+	if (pos[2] <= 0)
621	+	return(-1);
622	+	return(0);
623	+	}
624	+
625	+
626	+	backpicture(fill, samp) /* background fill algorithm */
627	+	int (*fill)();
628	+	int samp;
629	+	{
630		int *yback, xback;
631		int y;
462	–	COLR pfill;
632		register int x, i;
633		/* get back buffer */
634		yback = (int )malloc(hresolusizeof(int));
635		if (yback == NULL)
636	<	syserror();
636	>	syserror(progname);
637		for (x = 0; x < hresolu; x++)
638		yback[x] = -2;
639		/*
#	Line 506 \| Line 675 \| *backpicture() / background fill algorithm /*
675		xback = x-1;
676		}
677		/*
678	<	* Check to see if we have no background for
679	<	* this pixel. If not, use background color.
678	>	* If we have no background for this pixel,
679	>	* use the given fill function.
680		*/
681	<	if (xback < 0 && yback[x] < 0) {
682	<	(*deffill)(x,y);
514	<	continue;
515	<	}
681	>	if (xback < 0 && yback[x] < 0)
682	>	goto fillit;
683		/*
684		* Compare, and use the background that is
685		* farther, unless one of them is next to us.
686	+	* If the background is too distant, call
687	+	* the fill function.
688		*/
689		if ( yback[x] < 0
690		\|\| (xback >= 0 && ABS(x-xback) <= 1)
691		\|\| ( ABS(y-yback[x]) > 1
692		&& zscan(yback[x])[x]
693		< zscan(y)[xback] ) ) {
694	+	if (samp > 0 && ABS(x-xback) >= samp)
695	+	goto fillit;
696		copycolr(pscan(y)[x],pscan(y)[xback]);
697		zscan(y)[x] = zscan(y)[xback];
698		} else {
699	+	if (samp > 0 && ABS(y-yback[x]) > samp)
700	+	goto fillit;
701		copycolr(pscan(y)[x],pscan(yback[x])[x]);
702		zscan(y)[x] = zscan(yback[x])[x];
703		}
704	+	continue;
705	+	fillit:
706	+	(*fill)(x,y);
707	+	if (fill == rcalfill) { /* use it */
708	+	clearqueue();
709	+	xback = x;
710	+	yback[x] = y;
711	+	}
712		} else { /* full pixel */
713		yback[x] = -2;
714		xback = -2;
#	Line 537 \| Line 718 \| *backpicture() / background fill algorithm /*
718		}
719
720
721	<	fillpicture() /* paint in empty pixels with default */
721	>	fillpicture(fill) /* paint in empty pixels using fill */
722	>	int (*fill)();
723		{
724		register int x, y;
725
726		for (y = 0; y < vresolu; y++)
727		for (x = 0; x < hresolu; x++)
728		if (zscan(y)[x] <= 0)
729	<	(*deffill)(x,y);
729	>	(*fill)(x,y);
730		}
731
732
733	+	clipaft() /* perform aft clipping as indicated */
734	+	{
735	+	register int x, y;
736	+	double tstdist;
737	+	double yzn2, vx;
738	+
739	+	if (ourview.vaft <= FTINY)
740	+	return;
741	+	tstdist = ourview.vaft - ourview.vfore;
742	+	for (y = 0; y < vresolu; y++) {
743	+	if (ourview.type == VT_PER) { /* adjust distance */
744	+	yzn2 = (y+.5)/vresolu + ourview.voff - .5;
745	+	yzn2 = 1. + yzn2yzn2ourview.vn2;
746	+	tstdist = (ourview.vaft - ourview.vfore)*sqrt(yzn2);
747	+	}
748	+	for (x = 0; x < hresolu; x++)
749	+	if (zscan(y)[x] > tstdist) {
750	+	if (ourview.type == VT_PER) {
751	+	vx = (x+.5)/hresolu + ourview.hoff - .5;
752	+	if (zscan(y)[x] <= (ourview.vaft -
753	+	ourview.vfore) *
754	+	sqrt(vxvxourview.hn2 + yzn2))
755	+	continue;
756	+	}
757	+	bzero(pscan(y)[x], sizeof(COLR));
758	+	zscan(y)[x] = 0.0;
759	+	}
760	+	}
761	+	}
762	+
763	+
764		writepicture() /* write out picture */
765		{
766		int y;
767
768	<	fputresolu(YMAJOR\|YDECR, hresolu, vresolu, stdout);
768	>	fprtresolu(hresolu, vresolu, stdout);
769		for (y = vresolu-1; y >= 0; y--)
770		if (fwritecolrs(pscan(y), hresolu, stdout) < 0)
771	<	syserror();
771	>	syserror(progname);
772		}
773
774
775		writedistance(fname) /* write out z file */
776		char *fname;
777		{
565	–	extern double sqrt();
778		int donorm = normdist && ourview.type == VT_PER;
779		int fd;
780		int y;
781		float *zout;
782
783	<	if ((fd = open(fname, O_WRONLY\|O_CREAT\|O_TRUNC, 0666)) == -1) {
784	<	perror(fname);
573	<	exit(1);
574	<	}
783	>	if ((fd = open(fname, O_WRONLY\|O_CREAT\|O_TRUNC, 0666)) == -1)
784	>	syserror(fname);
785		if (donorm
786		&& (zout = (float )malloc(hresolusizeof(float))) == NULL)
787	<	syserror();
787	>	syserror(progname);
788		for (y = vresolu-1; y >= 0; y--) {
789		if (donorm) {
790		double vx, yzn2;
791		register int x;
792	<	yzn2 = y - .5*(vresolu-1);
792	>	yzn2 = (y+.5)/vresolu + ourview.voff - .5;
793		yzn2 = 1. + yzn2yzn2ourview.vn2;
794		for (x = 0; x < hresolu; x++) {
795	<	vx = x - .5*(hresolu-1);
795	>	vx = (x+.5)/hresolu + ourview.hoff - .5;
796		zout[x] = zscan(y)[x]
797		* sqrt(vxvxourview.hn2 + yzn2);
798		}
799		} else
800		zout = zscan(y);
801	<	if (write(fd, zout, hresolu*sizeof(float))
802	<	< hresolu*sizeof(float)) {
803	<	perror(fname);
594	<	exit(1);
595	<	}
801	>	if (write(fd, (char )zout, hresolusizeof(float))
802	>	< hresolu*sizeof(float))
803	>	syserror(fname);
804		}
805		if (donorm)
806		free((char *)zout);
#	Line 621 \| Line 829 \| int x, y;
829		}
830
831
832	<	calstart(prog, args) /* start fill calculation */
832	>	calstart(prog, args) /* start fill calculation */
833		char prog, args;
834		{
835		char combuf[512];
836	<	int p0[2], p1[2];
836	>	char *argv[64];
837	>	int rval;
838	>	register char *wp, cp;
839
840		if (childpid != -1) {
841		fprintf(stderr, "%s: too many calculations\n", progname);
842		exit(1);
843		}
844	<	sprintf(combuf, prog, PACKSIZ, args);
845	<	if (pipe(p0) < 0 \|\| pipe(p1) < 0)
846	<	syserror();
847	<	if ((childpid = vfork()) == 0) { /* fork calculation */
848	<	close(p0[1]);
849	<	close(p1[0]);
850	<	if (p0[0] != 0) {
851	<	dup2(p0[0], 0);
852	<	close(p0[0]);
853	<	}
854	<	if (p1[1] != 1) {
855	<	dup2(p1[1], 1);
646	<	close(p1[1]);
647	<	}
648	<	execl("/bin/sh", "sh", "-c", combuf, 0);
649	<	perror("/bin/sh");
650	<	_exit(127);
844	>	strcpy(combuf, prog);
845	>	strcat(combuf, args);
846	>	cp = combuf;
847	>	wp = argv;
848	>	for ( ; ; ) {
849	>	while (isspace(cp)) / nullify spaces */
850	>	*cp++ = '\0';
851	>	if (!cp) / all done? */
852	>	break;
853	>	wp++ = cp; / add argument to list */
854	>	while (++cp && !isspace(cp))
855	>	;
856		}
857	<	if (childpid == -1)
858	<	syserror();
859	<	close(p0[0]);
860	<	close(p1[1]);
861	<	if ((psend = fdopen(p0[1], "w")) == NULL)
862	<	syserror();
863	<	if ((precv = fdopen(p1[0], "r")) == NULL)
864	<	syserror();
857	>	*wp = NULL;
858	>	/* start process */
859	>	if ((rval = open_process(PDesc, argv)) < 0)
860	>	syserror(progname);
861	>	if (rval == 0) {
862	>	fprintf(stderr, "%s: command not found\n", argv[0]);
863	>	exit(1);
864	>	}
865	>	packsiz = rval/(6*sizeof(float)) - 1;
866	>	if (packsiz > PACKSIZ)
867	>	packsiz = PACKSIZ;
868		queuesiz = 0;
869		}
870
871
872	<	caldone() /* done with calculation */
872	>	caldone() /* done with calculation */
873		{
666	–	int pid;
667	–
874		if (childpid == -1)
875		return;
670	–	if (fclose(psend) == EOF)
671	–	syserror();
876		clearqueue();
877	<	fclose(precv);
674	<	while ((pid = wait(0)) != -1 && pid != childpid)
675	<	;
877	>	close_process(PDesc);
878		childpid = -1;
879		}
880
#	Line 680 \| Line 882 \| *caldone() / done with calculation /*
882		rcalfill(x, y) /* fill with ray-calculated pixel */
883		int x, y;
884		{
885	<	FVECT orig, dir;
684	<	float outbuf[6];
685	<
686	<	if (queuesiz >= PACKSIZ) { /* flush queue */
687	<	if (fflush(psend) == EOF)
688	<	syserror();
885	>	if (queuesiz >= packsiz) /* flush queue if needed */
886		clearqueue();
887	<	}
691	<	/* send new ray */
692	<	viewray(orig, dir, &ourview, (x+.5)/hresolu, (y+.5)/vresolu);
693	<	outbuf[0] = orig[0]; outbuf[1] = orig[1]; outbuf[2] = orig[2];
694	<	outbuf[3] = dir[0]; outbuf[4] = dir[1]; outbuf[5] = dir[2];
695	<	if (fwrite(outbuf, sizeof(float), 6, psend) < 6)
696	<	syserror();
697	<	/* remember it */
887	>	/* add position to queue */
888		queue[queuesiz][0] = x;
889		queue[queuesiz][1] = y;
890		queuesiz++;
891		}
892
893
894	<	clearqueue() /* get results from queue */
894	>	clearqueue() /* process queue */
895		{
896	<	float inbuf[4];
896	>	FVECT orig, dir;
897	>	float fbuf[6*(PACKSIZ+1)];
898	>	register float *fbp;
899		register int i;
900
901	+	if (queuesiz == 0)
902	+	return;
903	+	fbp = fbuf;
904		for (i = 0; i < queuesiz; i++) {
905	<	if (fread(inbuf, sizeof(float), 4, precv) < 4) {
906	<	fprintf(stderr, "%s: read error in clearqueue\n",
907	<	progname);
908	<	exit(1);
909	<	}
905	>	viewray(orig, dir, &ourview,
906	>	(queue[i][0]+.5)/hresolu,
907	>	(queue[i][1]+.5)/vresolu);
908	>	fbp++ = orig[0]; fbp++ = orig[1]; *fbp++ = orig[2];
909	>	fbp++ = dir[0]; fbp++ = dir[1]; *fbp++ = dir[2];
910	>	}
911	>	/* mark end and get results */
912	>	bzero((char )fbp, 6sizeof(float));
913	>	if (process(PDesc, fbuf, fbuf, 4sizeof(float)queuesiz,
914	>	6sizeof(float)(queuesiz+1)) !=
915	>	4sizeof(float)queuesiz) {
916	>	fprintf(stderr, "%s: error reading from rtrace process\n",
917	>	progname);
918	>	exit(1);
919	>	}
920	>	fbp = fbuf;
921	>	for (i = 0; i < queuesiz; i++) {
922		if (ourexp > 0 && ourexp != 1.0) {
923	<	inbuf[0] *= ourexp;
924	<	inbuf[1] *= ourexp;
925	<	inbuf[2] *= ourexp;
923	>	fbp[0] *= ourexp;
924	>	fbp[1] *= ourexp;
925	>	fbp[2] *= ourexp;
926		}
927		setcolr(pscan(queue[i][1])[queue[i][0]],
928	<	inbuf[0], inbuf[1], inbuf[2]);
929	<	zscan(queue[i][1])[queue[i][0]] = inbuf[3];
928	>	fbp[0], fbp[1], fbp[2]);
929	>	zscan(queue[i][1])[queue[i][0]] = fbp[3];
930	>	fbp += 4;
931		}
932		queuesiz = 0;
933		}
934
935
936	<	syserror() /* report error and exit */
936	>	syserror(s) /* report error and exit */
937	>	char *s;
938		{
939	<	perror(progname);
939	>	perror(s);
940		exit(1);
941		}

Diff Legend

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+Removed lines
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+Added lines
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Comparing ray/src/px/pinterp.c (file contents): Revision 1.20 by greg, Tue Jan 16 16:10:57 1990 UTC vs. Revision 2.17 by greg, Fri Dec 23 17:23:05 1994 UTC

Diff Legend

Comparing ray/src/px/pinterp.c (file contents):
Revision 1.20 by greg, Tue Jan 16 16:10:57 1990 UTC vs.
Revision 2.17 by greg, Fri Dec 23 17:23:05 1994 UTC