[ViewVC] Diff of: radiance/ray/src/cv/obj2rad.c

Comparing ray/src/cv/obj2rad.c (file contents):
Revision 2.8 by greg, Tue Jun 14 14:30:38 1994 UTC vs.
Revision 2.17 by greg, Sat Feb 22 02:07:23 2003 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1994 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		* Convert a Wavefront .obj file to Radiance format.
6		*
#	Line 17 \| Line 14 \| static char SCCSid[] = "$SunId$ LBL";
14
15		#include "trans.h"
16
17	+	#include "tmesh.h"
18	+
19		#include <ctype.h>
20
22	–	#define TCALNAME "tmesh.cal" /* triangle interp. file */
23	–	#define QCALNAME "surf.cal" /* quad interp. file */
21		#define PATNAME "M-pat" /* mesh pattern name (reused) */
22		#define TEXNAME "M-nor" /* mesh texture name (reused) */
23		#define DEFOBJ "unnamed" /* default object name */
24		#define DEFMAT "white" /* default material name */
25
29	–	#define ABS(x) ((x)>=0 ? (x) : -(x))
30	–
26		#define pvect(v) printf("%18.12g %18.12g %18.12g\n",(v)[0],(v)[1],(v)[2])
27
28		FVECT vlist; / our vertex list */
#	Line 37 \| Line 32 \| int nvns;
32		FLOAT (vtlist)[2]; / map vertex list */
33		int nvts;
34
40	–	typedef FLOAT BARYCCM[3][4]; /* barycentric coordinate system */
41	–
35		typedef int VNDX[3]; /* vertex index (point,map,normal) */
36
37		#define CHUNKSIZ 256 /* vertex allocation chunk size */
#	Line 130 \| Line 123 \| *char argv[];**
123		}
124		exit(0);
125		userr:
126	<	fprintf(stderr, "Usage: %s [-o obj][-m mapping][-n] [file.obj]\n",
126	>	fprintf(stderr, "Usage: %s [-o obj][-m mapping][-n][-f] [file.obj]\n",
127		argv[0]);
128		exit(1);
129		}
#	Line 237 \| Line 230 \| *FILE fp;**
230		if (!puttri(argv[1], argv[2], argv[3]))
231		syntax("Bad triangle");
232		break;
240	–	case 4:
241	–	if (!putquad(argv[1], argv[2],
242	–	argv[3], argv[4]))
243	–	syntax("Bad quad");
244	–	break;
233		default:
234		if (!putface(argc-1, argv+1))
235		syntax("Bad face");
#	Line 440 \| Line 428 \| *register char vs;**
428		if (vi[0]-- > nvs)
429		return(0);
430		} else if (vi[0] < 0) {
431	<	vi[0] = nvs + vi[0];
431	>	vi[0] += nvs;
432		if (vi[0] < 0)
433		return(0);
434		} else
#	Line 454 \| Line 442 \| *register char vs;**
442		if (vi[1]-- > nvts)
443		return(0);
444		} else if (vi[1] < 0) {
445	<	vi[1] = nvts + vi[1];
445	>	vi[1] += nvts;
446		if (vi[1] < 0)
447		return(0);
448		} else
#	Line 468 \| Line 456 \| *register char vs;**
456		if (vi[2]-- > nvns)
457		return(0);
458		} else if (vi[2] < 0) {
459	<	vi[2] = nvns + vi[2];
459	>	vi[2] += nvns;
460		if (vi[2] < 0)
461		return(0);
462		} else
#	Line 477 \| Line 465 \| *register char vs;**
465		}
466
467
468	<	nonplanar(ac, av) /* are vertices are non-planar? */
468	>	nonplanar(ac, av) /* are vertices non-planar? */
469		register int ac;
470		register char **av;
471		{
#	Line 489 \| Line 477 \| register char av;**
477
478		if (!cvtndx(vi, av[0]))
479		return(0);
480	<	if (vi[2] >= 0)
480	>	if (!flatten && vi[2] >= 0)
481		return(1); /* has interpolated normals */
482		if (ac < 4)
483		return(0); /* it's a triangle! */
#	Line 536 \| Line 524 \| register char av;**
524		char *cp;
525		register int i;
526
527	<	if (nonplanar(ac, av)) { /* break into quads and triangles */
528	<	while (ac > 3) {
529	<	if (!putquad(av[0], av[1], av[2], av[3]))
527	>	if (nonplanar(ac, av)) { /* break into triangles */
528	>	while (ac > 2) {
529	>	if (!puttri(av[0], av[1], av[2]))
530		return(0);
531	<	ac -= 2; /* remove two vertices & rotate */
531	>	ac--; /* remove vertex & rotate */
532		cp = av[0];
533		for (i = 0; i < ac-1; i++)
534	<	av[i] = av[i+3];
534	>	av[i] = av[i+2];
535		av[i] = cp;
536		}
549	–	if (ac == 3 && !puttri(av[0], av[1], av[2]))
550	–	return(0);
537		return(1);
538		}
539		if ((cp = getmtl()) == NULL)
#	Line 569 \| Line 555 \| *char v1, v2, v3;**
555		char *mod;
556		VNDX v1i, v2i, v3i;
557		BARYCCM bvecs;
558	+	FLOAT bcoor[3][3];
559		int texOK, patOK;
560	+	register int i;
561
562		if ((mod = getmtl()) == NULL)
563		return(-1);
#	Line 577 \| Line 565 \| *char v1, v2, v3;**
565		if (!cvtndx(v1i, v1) \|\| !cvtndx(v2i, v2) \|\| !cvtndx(v3i, v3))
566		return(0);
567		/* compute barycentric coordinates */
568	<	texOK = !flatten && (v1i[2]>=0 && v2i[2]>=0 && v3i[2]>=0);
568	>	if (!flatten && v1i[2]>=0 && v2i[2]>=0 && v3i[2]>=0)
569	>	switch (flat_tri(vlist[v1i[0]], vlist[v2i[0]], vlist[v3i[0]],
570	>	vnlist[v1i[2]], vnlist[v2i[2]], vnlist[v3i[2]])) {
571	>	case DEGEN: /* zero area */
572	>	return(-1);
573	>	case RVFLAT: /* reversed normals, but flat */
574	>	case ISFLAT: /* smoothing unnecessary */
575	>	texOK = 0;
576	>	break;
577	>	case RVBENT: /* reversed normals with smoothing */
578	>	case ISBENT: /* proper smoothing */
579	>	texOK = 1;
580	>	break;
581	>	}
582	>	else
583	>	texOK = 0;
584		#ifdef TEXMAPS
585		patOK = mapname[0] && (v1i[1]>=0 && v2i[1]>=0 && v3i[1]>=0);
586		#else
587		patOK = 0;
588		#endif
589		if (texOK \| patOK)
590	<	if (comp_baryc(bvecs, vlist[v1i[0]], vlist[v2i[0]],
590	>	if (comp_baryc(&bvecs, vlist[v1i[0]], vlist[v2i[0]],
591		vlist[v3i[0]]) < 0)
592		return(-1);
593		/* put out texture (if any) */
#	Line 592 \| Line 595 \| *char v1, v2, v3;**
595		printf("\n%s texfunc %s\n", mod, TEXNAME);
596		mod = TEXNAME;
597		printf("4 dx dy dz %s\n", TCALNAME);
598	<	printf("0\n21\n");
599	<	put_baryc(bvecs);
600	<	printf("\t%14.12g %14.12g %14.12g\n",
601	<	vnlist[v1i[2]][0], vnlist[v2i[2]][0],
602	<	vnlist[v3i[2]][0]);
603	<	printf("\t%14.12g %14.12g %14.12g\n",
604	<	vnlist[v1i[2]][1], vnlist[v2i[2]][1],
602	<	vnlist[v3i[2]][1]);
603	<	printf("\t%14.12g %14.12g %14.12g\n",
604	<	vnlist[v1i[2]][2], vnlist[v2i[2]][2],
605	<	vnlist[v3i[2]][2]);
598	>	printf("0\n");
599	>	for (i = 0; i < 3; i++) {
600	>	bcoor[i][0] = vnlist[v1i[2]][i];
601	>	bcoor[i][1] = vnlist[v2i[2]][i];
602	>	bcoor[i][2] = vnlist[v3i[2]][i];
603	>	}
604	>	put_baryc(&bvecs, bcoor, 3);
605		}
606		#ifdef TEXMAPS
607		/* put out pattern (if any) */
#	Line 610 \| Line 609 \| *char v1, v2, v3;**
609		printf("\n%s colorpict %s\n", mod, PATNAME);
610		mod = PATNAME;
611		printf("7 noneg noneg noneg %s %s u v\n", mapname, TCALNAME);
612	<	printf("0\n18\n");
613	<	put_baryc(bvecs);
614	<	printf("\t%f %f %f\n", vtlist[v1i[1]][0],
615	<	vtlist[v2i[1]][0], vtlist[v3i[1]][0]);
616	<	printf("\t%f %f %f\n", vtlist[v1i[1]][1],
617	<	vtlist[v2i[1]][1], vtlist[v3i[1]][1]);
612	>	printf("0\n");
613	>	for (i = 0; i < 2; i++) {
614	>	bcoor[i][0] = vtlist[v1i[1]][i];
615	>	bcoor[i][1] = vtlist[v2i[1]][i];
616	>	bcoor[i][2] = vtlist[v3i[1]][i];
617	>	}
618	>	put_baryc(&bvecs, bcoor, 2);
619		}
620		#endif
621		/* put out triangle */
#	Line 629 \| Line 629 \| *char v1, v2, v3;**
629		}
630
631
632	–	int
633	–	comp_baryc(bcm, v1, v2, v3) /* compute barycentric vectors */
634	–	register BARYCCM bcm;
635	–	FLOAT v1, v2, *v3;
636	–	{
637	–	FLOAT *vt;
638	–	FVECT va, vab, vcb;
639	–	double d;
640	–	register int i, j;
641	–
642	–	for (j = 0; j < 3; j++) {
643	–	for (i = 0; i < 3; i++) {
644	–	vab[i] = v1[i] - v2[i];
645	–	vcb[i] = v3[i] - v2[i];
646	–	}
647	–	d = DOT(vcb,vcb);
648	–	if (d <= FTINY)
649	–	return(-1);
650	–	d = DOT(vcb,vab)/d;
651	–	for (i = 0; i < 3; i++)
652	–	va[i] = vab[i] - vcb[i]*d;
653	–	d = DOT(va,va);
654	–	if (d <= FTINY)
655	–	return(-1);
656	–	for (i = 0; i < 3; i++) {
657	–	va[i] /= d;
658	–	bcm[j][i] = va[i];
659	–	}
660	–	bcm[j][3] = -DOT(v2,va);
661	–	/* rotate vertices */
662	–	vt = v1;
663	–	v1 = v2;
664	–	v2 = v3;
665	–	v3 = vt;
666	–	}
667	–	return(0);
668	–	}
669	–
670	–
671	–	put_baryc(bcm) /* put barycentric coord. vectors */
672	–	register BARYCCM bcm;
673	–	{
674	–	register int i;
675	–
676	–	for (i = 0; i < 3; i++)
677	–	printf("%14.8f %14.8f %14.8f %14.8f\n",
678	–	bcm[i][0], bcm[i][1], bcm[i][2], bcm[i][3]);
679	–	}
680	–
681	–
682	–	putquad(p0, p1, p3, p2) /* put out a quadrilateral */
683	–	char p0, p1, p3, p2; /* names correspond to binary pos. */
684	–	{
685	–	VNDX p0i, p1i, p2i, p3i;
686	–	FVECT norm[4];
687	–	char mod, name;
688	–	int axis;
689	–	FVECT v1, v2, vc1, vc2;
690	–	int ok1, ok2;
691	–
692	–	#ifdef TEXMAPS
693	–	/* also should output texture index coordinates,
694	–	* which will require new .cal file
695	–	*/
696	–	#endif
697	–	if ((mod = getmtl()) == NULL)
698	–	return(-1);
699	–	name = getonm();
700	–	/* get actual indices */
701	–	if (!cvtndx(p0i,p0) \|\| !cvtndx(p1i,p1) \|\|
702	–	!cvtndx(p2i,p2) \|\| !cvtndx(p3i,p3))
703	–	return(0);
704	–	/* compute exact normals */
705	–	fvsum(v1, vlist[p1i[0]], vlist[p0i[0]], -1.0);
706	–	fvsum(v2, vlist[p2i[0]], vlist[p0i[0]], -1.0);
707	–	fcross(vc1, v1, v2);
708	–	ok1 = normalize(vc1) != 0.0;
709	–	fvsum(v1, vlist[p2i[0]], vlist[p3i[0]], -1.0);
710	–	fvsum(v2, vlist[p1i[0]], vlist[p3i[0]], -1.0);
711	–	fcross(vc2, v1, v2);
712	–	ok2 = normalize(vc2) != 0.0;
713	–	if (!(ok1 \| ok2))
714	–	return(-1);
715	–	/* compute normal interpolation */
716	–	axis = norminterp(norm, p0i, p1i, p2i, p3i);
717	–
718	–	/* put out quadrilateral? */
719	–	if (ok1 & ok2 && fabs(fdot(vc1,vc2)) >= 1.0-FTINY) {
720	–	printf("\n%s ", mod);
721	–	if (axis != -1) {
722	–	printf("texfunc %s\n", TEXNAME);
723	–	printf("4 surf_dx surf_dy surf_dz %s\n", QCALNAME);
724	–	printf("0\n13\t%d\n", axis);
725	–	pvect(norm[0]);
726	–	pvect(norm[1]);
727	–	pvect(norm[2]);
728	–	fvsum(v1, norm[3], vc1, -0.5);
729	–	fvsum(v1, v1, vc2, -0.5);
730	–	pvect(v1);
731	–	printf("\n%s ", TEXNAME);
732	–	}
733	–	printf("polygon %s.%d\n", name, faceno);
734	–	printf("0\n0\n12\n");
735	–	pvect(vlist[p0i[0]]);
736	–	pvect(vlist[p1i[0]]);
737	–	pvect(vlist[p3i[0]]);
738	–	pvect(vlist[p2i[0]]);
739	–	return(1);
740	–	}
741	–	/* put out triangles? */
742	–	if (ok1) {
743	–	printf("\n%s ", mod);
744	–	if (axis != -1) {
745	–	printf("texfunc %s\n", TEXNAME);
746	–	printf("4 surf_dx surf_dy surf_dz %s\n", QCALNAME);
747	–	printf("0\n13\t%d\n", axis);
748	–	pvect(norm[0]);
749	–	pvect(norm[1]);
750	–	pvect(norm[2]);
751	–	fvsum(v1, norm[3], vc1, -1.0);
752	–	pvect(v1);
753	–	printf("\n%s ", TEXNAME);
754	–	}
755	–	printf("polygon %s.%da\n", name, faceno);
756	–	printf("0\n0\n9\n");
757	–	pvect(vlist[p0i[0]]);
758	–	pvect(vlist[p1i[0]]);
759	–	pvect(vlist[p2i[0]]);
760	–	}
761	–	if (ok2) {
762	–	printf("\n%s ", mod);
763	–	if (axis != -1) {
764	–	printf("texfunc %s\n", TEXNAME);
765	–	printf("4 surf_dx surf_dy surf_dz %s\n", QCALNAME);
766	–	printf("0\n13\t%d\n", axis);
767	–	pvect(norm[0]);
768	–	pvect(norm[1]);
769	–	pvect(norm[2]);
770	–	fvsum(v2, norm[3], vc2, -1.0);
771	–	pvect(v2);
772	–	printf("\n%s ", TEXNAME);
773	–	}
774	–	printf("polygon %s.%db\n", name, faceno);
775	–	printf("0\n0\n9\n");
776	–	pvect(vlist[p2i[0]]);
777	–	pvect(vlist[p1i[0]]);
778	–	pvect(vlist[p3i[0]]);
779	–	}
780	–	return(1);
781	–	}
782	–
783	–
784	–	int
785	–	norminterp(resmat, p0i, p1i, p2i, p3i) /* compute normal interpolation */
786	–	register FVECT resmat[4];
787	–	register VNDX p0i, p1i, p2i, p3i;
788	–	{
789	–	#define u ((ax+1)%3)
790	–	#define v ((ax+2)%3)
791	–
792	–	register int ax;
793	–	MAT4 eqnmat;
794	–	FVECT v1;
795	–	register int i, j;
796	–
797	–	#ifdef TEXMAPS
798	–	/* also check for texture indices */
799	–	#endif
800	–	if (flatten \|\| !(p0i[2]>=0 && p1i[2]>=0 && p2i[2]>=0 && p3i[2]>=0))
801	–	return(-1);
802	–	/* find dominant axis */
803	–	VCOPY(v1, vnlist[p0i[2]]);
804	–	fvsum(v1, v1, vnlist[p1i[2]], 1.0);
805	–	fvsum(v1, v1, vnlist[p2i[2]], 1.0);
806	–	fvsum(v1, v1, vnlist[p3i[2]], 1.0);
807	–	ax = ABS(v1[0]) > ABS(v1[1]) ? 0 : 1;
808	–	ax = ABS(v1[ax]) > ABS(v1[2]) ? ax : 2;
809	–	/* assign equation matrix */
810	–	eqnmat[0][0] = vlist[p0i[0]][u]*vlist[p0i[0]][v];
811	–	eqnmat[0][1] = vlist[p0i[0]][u];
812	–	eqnmat[0][2] = vlist[p0i[0]][v];
813	–	eqnmat[0][3] = 1.0;
814	–	eqnmat[1][0] = vlist[p1i[0]][u]*vlist[p1i[0]][v];
815	–	eqnmat[1][1] = vlist[p1i[0]][u];
816	–	eqnmat[1][2] = vlist[p1i[0]][v];
817	–	eqnmat[1][3] = 1.0;
818	–	eqnmat[2][0] = vlist[p2i[0]][u]*vlist[p2i[0]][v];
819	–	eqnmat[2][1] = vlist[p2i[0]][u];
820	–	eqnmat[2][2] = vlist[p2i[0]][v];
821	–	eqnmat[2][3] = 1.0;
822	–	eqnmat[3][0] = vlist[p3i[0]][u]*vlist[p3i[0]][v];
823	–	eqnmat[3][1] = vlist[p3i[0]][u];
824	–	eqnmat[3][2] = vlist[p3i[0]][v];
825	–	eqnmat[3][3] = 1.0;
826	–	/* invert matrix (solve system) */
827	–	if (!invmat4(eqnmat, eqnmat))
828	–	return(-1); /* no solution */
829	–	/* compute result matrix */
830	–	for (j = 0; j < 4; j++)
831	–	for (i = 0; i < 3; i++)
832	–	resmat[j][i] = eqnmat[j][0]*vnlist[p0i[2]][i] +
833	–	eqnmat[j][1]*vnlist[p1i[2]][i] +
834	–	eqnmat[j][2]*vnlist[p2i[2]][i] +
835	–	eqnmat[j][3]*vnlist[p3i[2]][i];
836	–	#ifdef TEXMAPS
837	–	/* compute result matrix for texture indices */
838	–	#endif
839	–	return(ax);
840	–
841	–	#undef u
842	–	#undef v
843	–	}
844	–
845	–
632		freeverts() /* free all vertices */
633		{
634		if (nvs) {
635	<	free((char *)vlist);
635	>	free((void *)vlist);
636		nvs = 0;
637		}
638		if (nvts) {
639	<	free((char *)vtlist);
639	>	free((void *)vtlist);
640		nvts = 0;
641		}
642		if (nvns) {
643	<	free((char *)vnlist);
643	>	free((void *)vnlist);
644		nvns = 0;
645		}
646		}

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Comparing ray/src/cv/obj2rad.c (file contents): Revision 2.8 by greg, Tue Jun 14 14:30:38 1994 UTC vs. Revision 2.17 by greg, Sat Feb 22 02:07:23 2003 UTC

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Comparing ray/src/cv/obj2rad.c (file contents):
Revision 2.8 by greg, Tue Jun 14 14:30:38 1994 UTC vs.
Revision 2.17 by greg, Sat Feb 22 02:07:23 2003 UTC