[ViewVC] Diff of: radiance/ray/src/rt/srcsupp.c

Comparing ray/src/rt/srcsupp.c (file contents):
Revision 1.13 by greg, Fri Sep 13 13:44:10 1991 UTC vs.
Revision 2.21 by greg, Thu Dec 4 05:26:28 2014 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1991 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		* Support routines for source objects and materials
6	+	*
7	+	* External symbols declared in source.h
8		*/
9
10	+	#include "copyright.h"
11	+
12		#include "ray.h"
13
14		#include "otypes.h"
#	Line 18 \| Line 19 \| static char SCCSid[] = "$SunId$ LBL";
19
20		#include "face.h"
21
22	+	#define SRCINC 32 /* realloc increment for array */
23
24		SRCREC source = NULL; / our list of sources */
25		int nsources = 0; /* the number of sources */
#	Line 25 \| Line 27 \| *int nsources = 0; / the number of sources /*
27		SRCFUNC sfun[NUMOTYPE]; /* source dispatch table */
28
29
30	<	initstypes() /* initialize source dispatch table */
30	>	void
31	>	initstypes(void) /* initialize source dispatch table */
32		{
33		extern VSMATERIAL mirror_vs, direct1_vs, direct2_vs;
34	<	extern int fsetsrc(), ssetsrc(), sphsetsrc(), rsetsrc();
35	<	extern double fgetplaneq(), rgetplaneq();
36	<	extern double fgetmaxdisk(), rgetmaxdisk();
37	<	static SOBJECT fsobj = {fsetsrc, fgetplaneq, fgetmaxdisk};
38	<	static SOBJECT ssobj = {ssetsrc};
36	<	static SOBJECT sphsobj = {sphsetsrc};
37	<	static SOBJECT rsobj = {rsetsrc, rgetplaneq, rgetmaxdisk};
34	>	static SOBJECT fsobj = {fsetsrc, flatpart, fgetplaneq, fgetmaxdisk};
35	>	static SOBJECT ssobj = {ssetsrc, nopart};
36	>	static SOBJECT sphsobj = {sphsetsrc, nopart};
37	>	static SOBJECT cylsobj = {cylsetsrc, cylpart};
38	>	static SOBJECT rsobj = {rsetsrc, flatpart, rgetplaneq, rgetmaxdisk};
39
40		sfun[MAT_MIRROR].mf = &mirror_vs;
41		sfun[MAT_DIRECT1].mf = &direct1_vs;
#	Line 42 \| Line 43 \| *initstypes() / initialize source dispatch table /*
43		sfun[OBJ_FACE].of = &fsobj;
44		sfun[OBJ_SOURCE].of = &ssobj;
45		sfun[OBJ_SPHERE].of = &sphsobj;
46	+	sfun[OBJ_CYLINDER].of = &cylsobj;
47		sfun[OBJ_RING].of = &rsobj;
48		}
49
50
51		int
52	<	newsource() /* allocate new source in our array */
52	>	newsource(void) /* allocate new source in our array */
53		{
52	–	#define SRCINC 4
54		if (nsources == 0)
55		source = (SRCREC )malloc(SRCINCsizeof(SRCREC));
56		else if (nsources%SRCINC == 0)
57	<	source = (SRCREC )realloc((char )source,
57	>	source = (SRCREC )realloc((void )source,
58		(unsigned)(nsources+SRCINC)*sizeof(SRCREC));
59		if (source == NULL)
60		return(-1);
61		source[nsources].sflags = 0;
62		source[nsources].nhits = 1;
63	<	source[nsources].ntests = 2; /* initial hit probability = 1/2 */
63	>	source[nsources].ntests = 2; /* initial hit probability = 50% */
64	>	#if SHADCACHE
65	>	source[nsources].obscache = NULL;
66	>	#endif
67		return(nsources++);
64	–	#undef SRCINC
68		}
69
70
71	<	fsetsrc(src, so) /* set a face as a source */
72	<	register SRCREC *src;
73	<	OBJREC *so;
71	>	void
72	>	setflatss( /* set sampling for a flat source */
73	>	SRCREC *src
74	>	)
75		{
76	<	register FACE *f;
77	<	register int i, j;
76	>	double mult;
77	>	int i;
78	>
79	>	getperpendicular(src->ss[SU], src->snorm);
80	>	mult = .5 * sqrt( src->ss2 );
81	>	for (i = 0; i < 3; i++)
82	>	src->ss[SU][i] *= mult;
83	>	fcross(src->ss[SV], src->snorm, src->ss[SU]);
84	>	}
85	>
86	>
87	>	void
88	>	fsetsrc( /* set a face as a source */
89	>	SRCREC *src,
90	>	OBJREC *so
91	>	)
92	>	{
93	>	FACE *f;
94	>	int i, j;
95	>	double d;
96
97		src->sa.success = 2AIMREQT-1; / bitch on second failure */
98		src->so = so;
99		/* get the face */
100		f = getface(so);
101	+	if (f->area == 0.0)
102	+	objerror(so, USER, "zero source area");
103		/* find the center */
104		for (j = 0; j < 3; j++) {
105		src->sloc[j] = 0.0;
#	Line 84 \| Line 108 \| *OBJREC so;**
108		src->sloc[j] /= (double)f->nv;
109		}
110		if (!inface(src->sloc, f))
111	<	objerror(so, USER, "cannot hit center");
111	>	objerror(so, USER, "cannot hit source center");
112		src->sflags \|= SFLAT;
113		VCOPY(src->snorm, f->norm);
90	–	src->ss = sqrt(f->area / PI);
114		src->ss2 = f->area;
115	+	/* find maximum radius */
116	+	src->srad = 0.;
117	+	for (i = 0; i < f->nv; i++) {
118	+	d = dist2(VERTEX(f,i), src->sloc);
119	+	if (d > src->srad)
120	+	src->srad = d;
121	+	}
122	+	src->srad = sqrt(src->srad);
123	+	/* compute size vectors */
124	+	if (f->nv == 4) /* parallelogram case */
125	+	for (j = 0; j < 3; j++) {
126	+	src->ss[SU][j] = .5*(VERTEX(f,1)[j]-VERTEX(f,0)[j]);
127	+	src->ss[SV][j] = .5*(VERTEX(f,3)[j]-VERTEX(f,0)[j]);
128	+	}
129	+	else
130	+	setflatss(src);
131		}
132
133
134	<	ssetsrc(src, so) /* set a source as a source */
135	<	register SRCREC *src;
136	<	register OBJREC *so;
134	>	void
135	>	ssetsrc( /* set a source as a source */
136	>	SRCREC *src,
137	>	OBJREC *so
138	>	)
139		{
140		double theta;
141
#	Line 102 \| Line 143 \| *register OBJREC so;**
143		src->so = so;
144		if (so->oargs.nfargs != 4)
145		objerror(so, USER, "bad arguments");
146	<	src->sflags \|= SDISTANT;
146	>	src->sflags \|= (SDISTANT\|SCIR);
147		VCOPY(src->sloc, so->oargs.farg);
148		if (normalize(src->sloc) == 0.0)
149		objerror(so, USER, "zero direction");
150		theta = PI/180.0/2.0 * so->oargs.farg[3];
151		if (theta <= FTINY)
152		objerror(so, USER, "zero size");
112	–	src->ss = theta >= PI/4.0 ? 1.0 : tan(theta);
153		src->ss2 = 2.0PI (1.0 - cos(theta));
154	+	/* the following is approximate */
155	+	src->srad = sqrt(src->ss2/PI);
156	+	VCOPY(src->snorm, src->sloc);
157	+	setflatss(src); /* hey, whatever works */
158	+	src->ss[SW][0] = src->ss[SW][1] = src->ss[SW][2] = 0.0;
159		}
160
161
162	<	sphsetsrc(src, so) /* set a sphere as a source */
163	<	register SRCREC *src;
164	<	register OBJREC *so;
162	>	void
163	>	sphsetsrc( /* set a sphere as a source */
164	>	SRCREC *src,
165	>	OBJREC *so
166	>	)
167		{
168	+	int i;
169	+
170		src->sa.success = 2AIMREQT-1; / bitch on second failure */
171		src->so = so;
172		if (so->oargs.nfargs != 4)
173		objerror(so, USER, "bad # arguments");
174		if (so->oargs.farg[3] <= FTINY)
175	<	objerror(so, USER, "illegal radius");
175	>	objerror(so, USER, "illegal source radius");
176	>	src->sflags \|= SCIR;
177		VCOPY(src->sloc, so->oargs.farg);
178	<	src->ss = so->oargs.farg[3];
179	<	src->ss2 = PI * src->ss * src->ss;
178	>	src->srad = so->oargs.farg[3];
179	>	src->ss2 = PI * src->srad * src->srad;
180	>	for (i = 0; i < 3; i++)
181	>	src->ss[SU][i] = src->ss[SV][i] = src->ss[SW][i] = 0.0;
182	>	for (i = 0; i < 3; i++)
183	>	src->ss[i][i] = 0.7236 * so->oargs.farg[3];
184		}
185
186
187	<	rsetsrc(src, so) /* set a ring (disk) as a source */
188	<	register SRCREC *src;
189	<	OBJREC *so;
187	>	void
188	>	rsetsrc( /* set a ring (disk) as a source */
189	>	SRCREC *src,
190	>	OBJREC *so
191	>	)
192		{
193	<	register CONE *co;
193	>	CONE *co;
194
195		src->sa.success = 2AIMREQT-1; / bitch on second failure */
196		src->so = so;
197		/* get the ring */
198		co = getcone(so, 0);
199	+	if (CO_R1(co) <= FTINY)
200	+	objerror(so, USER, "illegal source radius");
201		VCOPY(src->sloc, CO_P0(co));
202		if (CO_R0(co) > 0.0)
203	<	objerror(so, USER, "cannot hit center");
204	<	src->sflags \|= SFLAT;
203	>	objerror(so, USER, "cannot hit source center");
204	>	src->sflags \|= (SFLAT\|SCIR);
205		VCOPY(src->snorm, co->ad);
206	<	src->ss = CO_R1(co);
207	<	src->ss2 = PI * src->ss * src->ss;
206	>	src->srad = CO_R1(co);
207	>	src->ss2 = PI * src->srad * src->srad;
208	>	setflatss(src);
209		}
210
211
212	+	void
213	+	cylsetsrc( /* set a cylinder as a source */
214	+	SRCREC *src,
215	+	OBJREC *so
216	+	)
217	+	{
218	+	CONE *co;
219	+	int i;
220	+
221	+	src->sa.success = 4AIMREQT-1; / bitch on fourth failure */
222	+	src->so = so;
223	+	/* get the cylinder */
224	+	co = getcone(so, 0);
225	+	if (CO_R0(co) <= FTINY)
226	+	objerror(so, USER, "illegal source radius");
227	+	if (CO_R0(co) > .2co->al) / heuristic constraint */
228	+	objerror(so, WARNING, "source aspect too small");
229	+	src->sflags \|= SCYL;
230	+	for (i = 0; i < 3; i++)
231	+	src->sloc[i] = .5 * (CO_P1(co)[i] + CO_P0(co)[i]);
232	+	src->srad = .5*co->al;
233	+	src->ss2 = 2.CO_R0(co)co->al;
234	+	/* set sampling vectors */
235	+	for (i = 0; i < 3; i++)
236	+	src->ss[SU][i] = .5 * co->al * co->ad[i];
237	+	getperpendicular(src->ss[SW], co->ad);
238	+	for (i = 0; i < 3; i++)
239	+	src->ss[SW][i] = .8559 CO_R0(co);
240	+	fcross(src->ss[SV], src->ss[SW], co->ad);
241	+	}
242	+
243	+
244		SPOT *
245	<	makespot(m) /* make a spotlight */
246	<	register OBJREC *m;
245	>	makespot( /* make a spotlight */
246	>	OBJREC *m
247	>	)
248		{
249	<	register SPOT *ns;
249	>	SPOT *ns;
250
251	+	if ((ns = (SPOT *)m->os) != NULL)
252	+	return(ns);
253		if ((ns = (SPOT *)malloc(sizeof(SPOT))) == NULL)
254		return(NULL);
255	+	if (m->oargs.farg[3] <= FTINY)
256	+	objerror(m, USER, "zero angle");
257		ns->siz = 2.0PI (1.0 - cos(PI/180.0/2.0 * m->oargs.farg[3]));
258		VCOPY(ns->aim, m->oargs.farg+4);
259		if ((ns->flen = normalize(ns->aim)) == 0.0)
260		objerror(m, USER, "zero focus vector");
261	+	m->os = (char *)ns;
262		return(ns);
263		}
264
265
266	+	int
267	+	spotout( /* check if we're outside spot region */
268	+	RAY *r,
269	+	SPOT *s
270	+	)
271	+	{
272	+	double d;
273	+	FVECT vd;
274	+
275	+	if (s == NULL)
276	+	return(0);
277	+	if (s->flen < -FTINY) { /* distant source */
278	+	vd[0] = s->aim[0] - r->rorg[0];
279	+	vd[1] = s->aim[1] - r->rorg[1];
280	+	vd[2] = s->aim[2] - r->rorg[2];
281	+	d = DOT(r->rdir,vd);
282	+	/* wrong side?
283	+	if (d <= FTINY)
284	+	return(1); */
285	+	d = DOT(vd,vd) - d*d;
286	+	if (PI*d > s->siz)
287	+	return(1); /* out */
288	+	return(0); /* OK */
289	+	}
290	+	/* local source */
291	+	if (s->siz < 2.0PI (1.0 + DOT(s->aim,r->rdir)))
292	+	return(1); /* out */
293	+	return(0); /* OK */
294	+	}
295	+
296	+
297		double
298	<	fgetmaxdisk(ocent, op) /* get center and squared radius of face */
299	<	FVECT ocent;
300	<	OBJREC *op;
298	>	fgetmaxdisk( /* get center and squared radius of face */
299	>	FVECT ocent,
300	>	OBJREC *op
301	>	)
302		{
303		double maxrad2;
304		double d;
305	<	register int i, j;
306	<	register FACE *f;
305	>	int i, j;
306	>	FACE *f;
307
308		f = getface(op);
309		if (f->area == 0.)
#	Line 199 \| Line 328 \| *OBJREC op;**
328
329
330		double
331	<	rgetmaxdisk(ocent, op) /* get center and squared radius of ring */
332	<	FVECT ocent;
333	<	OBJREC *op;
331	>	rgetmaxdisk( /* get center and squared radius of ring */
332	>	FVECT ocent,
333	>	OBJREC *op
334	>	)
335		{
336	<	register CONE *co;
336	>	CONE *co;
337
338		co = getcone(op, 0);
339		VCOPY(ocent, CO_P0(co));
#	Line 212 \| Line 342 \| *OBJREC op;**
342
343
344		double
345	<	fgetplaneq(nvec, op) /* get plane equation for face */
346	<	FVECT nvec;
347	<	OBJREC *op;
345	>	fgetplaneq( /* get plane equation for face */
346	>	FVECT nvec,
347	>	OBJREC *op
348	>	)
349		{
350	<	register FACE *fo;
350	>	FACE *fo;
351
352		fo = getface(op);
353		VCOPY(nvec, fo->norm);
#	Line 225 \| Line 356 \| *OBJREC op;**
356
357
358		double
359	<	rgetplaneq(nvec, op) /* get plane equation for ring */
360	<	FVECT nvec;
361	<	OBJREC *op;
359	>	rgetplaneq( /* get plane equation for ring */
360	>	FVECT nvec,
361	>	OBJREC *op
362	>	)
363		{
364	<	register CONE *co;
364	>	CONE *co;
365
366		co = getcone(op, 0);
367		VCOPY(nvec, co->ad);
#	Line 237 \| Line 369 \| *OBJREC op;**
369		}
370
371
372	<	commonspot(sp1, sp2, org) /* set sp1 to intersection of sp1 and sp2 */
373	<	register SPOT sp1, sp2;
374	<	FVECT org;
372	>	int
373	>	commonspot( /* set sp1 to intersection of sp1 and sp2 */
374	>	SPOT *sp1,
375	>	SPOT *sp2,
376	>	FVECT org
377	>	)
378		{
379		FVECT cent;
380		double rad2, cos1, cos2;
#	Line 260 \| Line 395 \| FVECT org;
395		}
396
397
398	<	commonbeam(sp1, sp2, dir) /* set sp1 to intersection of sp1 and sp2 */
399	<	register SPOT sp1, sp2;
400	<	FVECT dir;
398	>	int
399	>	commonbeam( /* set sp1 to intersection of sp1 and sp2 */
400	>	SPOT *sp1,
401	>	SPOT *sp2,
402	>	FVECT dir
403	>	)
404		{
405		FVECT cent, c1, c2;
406		double rad2, d;
269	–	register int i;
407		/* move centers to common plane */
408		d = DOT(sp1->aim, dir);
409	<	for (i = 0; i < 3; i++)
273	<	c1[i] = sp1->aim[i] - d*dir[i];
409	>	VSUM(c1, sp1->aim, dir, -d);
410		d = DOT(sp2->aim, dir);
411	<	for (i = 0; i < 3; i++)
276	<	c2[i] = sp2->aim[i] - d*dir[i];
411	>	VSUM(c2, sp2->aim, dir, -d);
412		/* compute overlap */
413		rad2 = intercircle(cent, c1, c2, sp1->siz/PI, sp2->siz/PI);
414		if (rad2 <= FTINY)
#	Line 284 \| Line 419 \| FVECT dir;
419		}
420
421
422	<	checkspot(sp, nrm) /* check spotlight for behind source */
423	<	register SPOT sp; / spotlight */
424	<	FVECT nrm; /* source surface normal */
422	>	int
423	>	checkspot( /* check spotlight for behind source */
424	>	SPOT sp, / spotlight */
425	>	FVECT nrm /* source surface normal */
426	>	)
427		{
428		double d, d1;
429
#	Line 300 \| Line 437 \| *FVECT nrm; / source surface normal /*
437
438
439		double
440	<	spotdisk(oc, op, sp, pos) /* intersect spot with object op */
441	<	FVECT oc;
442	<	OBJREC *op;
443	<	register SPOT *sp;
444	<	FVECT pos;
440	>	spotdisk( /* intersect spot with object op */
441	>	FVECT oc,
442	>	OBJREC *op,
443	>	SPOT *sp,
444	>	FVECT pos
445	>	)
446		{
447		FVECT onorm;
448		double offs, d, dist;
311	–	register int i;
449
450		offs = getplaneq(onorm, op);
451		d = -DOT(onorm, sp->aim);
#	Line 317 \| Line 454 \| FVECT pos;
454		dist = (DOT(pos, onorm) - offs)/d;
455		if (dist < 0.)
456		return(0.);
457	<	for (i = 0; i < 3; i++)
321	<	oc[i] = pos[i] + dist*sp->aim[i];
457	>	VSUM(oc, pos, sp->aim, dist);
458		return(sp->sizdistdist/PI/(d*d));
459		}
460
461
462		double
463	<	beamdisk(oc, op, sp, dir) /* intersect beam with object op */
464	<	FVECT oc;
465	<	OBJREC *op;
466	<	register SPOT *sp;
467	<	FVECT dir;
463	>	beamdisk( /* intersect beam with object op */
464	>	FVECT oc,
465	>	OBJREC *op,
466	>	SPOT *sp,
467	>	FVECT dir
468	>	)
469		{
470		FVECT onorm;
471		double offs, d, dist;
335	–	register int i;
472
473		offs = getplaneq(onorm, op);
474		d = -DOT(onorm, dir);
475		if (d >= -FTINY && d <= FTINY)
476		return(0.);
477		dist = (DOT(sp->aim, onorm) - offs)/d;
478	<	for (i = 0; i < 3; i++)
343	<	oc[i] = sp->aim[i] + dist*dir[i];
478	>	VSUM(oc, sp->aim, dir, dist);
479		return(sp->siz/PI/(d*d));
480		}
481
482
483		double
484	<	intercircle(cc, c1, c2, r1s, r2s) /* intersect two circles */
485	<	FVECT cc; /* midpoint (return value) */
486	<	FVECT c1, c2; /* circle centers */
487	<	double r1s, r2s; /* radii squared */
484	>	intercircle( /* intersect two circles */
485	>	FVECT cc, /* midpoint (return value) */
486	>	FVECT c1, /* circle centers */
487	>	FVECT c2,
488	>	double r1s, /* radii squared */
489	>	double r2s
490	>	)
491		{
492		double a2, d2, l;
493		FVECT disp;
356	–	register int i;
494
495	<	for (i = 0; i < 3; i++)
359	<	disp[i] = c2[i] - c1[i];
495	>	VSUB(disp, c2, c1);
496		d2 = DOT(disp,disp);
497		/* circle within overlap? */
498		if (r1s < r2s) {
#	Line 376 \| Line 512 \| *double r1s, r2s; / radii squared /*
512		return(0.);
513		/* overlap, compute center */
514		l = sqrt((r1s - a2)/d2);
515	<	for (i = 0; i < 3; i++)
380	<	cc[i] = c1[i] + l*disp[i];
515	>	VSUM(cc, c1, disp, l);
516		return(a2);
382	–	}
383	–
384	–
385	–	sourcehit(r) /* check to see if ray hit distant source */
386	–	register RAY *r;
387	–	{
388	–	int first, last;
389	–	register int i;
390	–
391	–	if (r->rsrc >= 0) { /* check only one if aimed */
392	–	first = last = r->rsrc;
393	–	} else { /* otherwise check all */
394	–	first = 0; last = nsources-1;
395	–	}
396	–	for (i = first; i <= last; i++)
397	–	if ((source[i].sflags & (SDISTANT\|SVIRTUAL)) == SDISTANT)
398	–	/*
399	–	* Check to see if ray is within
400	–	* solid angle of source.
401	–	*/
402	–	if (2.0PI (1.0 - DOT(source[i].sloc,r->rdir))
403	–	<= source[i].ss2) {
404	–	r->ro = source[i].so;
405	–	if (!(source[i].sflags & SSKIP))
406	–	break;
407	–	}
408	–
409	–	if (r->ro != NULL) {
410	–	for (i = 0; i < 3; i++)
411	–	r->ron[i] = -r->rdir[i];
412	–	r->rod = 1.0;
413	–	r->rox = NULL;
414	–	return(1);
415	–	}
416	–	return(0);
417	–	}
418	–
419	–
420	–	#define wrongsource(m, r) (r->rsrc>=0 && \
421	–	source[r->rsrc].so!=r->ro && \
422	–	(m->otype!=MAT_ILLUM \|\| \
423	–	objptr(source[r->rsrc].so->omod)->otype==MAT_ILLUM))
424	–
425	–	#define distglow(m, r) (m->otype==MAT_GLOW && \
426	–	r->rot > m->oargs.farg[3])
427	–
428	–	#define badambient(m, r) ((r->crtype&(AMBIENT\|SHADOW))==AMBIENT && \
429	–	!distglow(m, r))
430	–
431	–	#define passillum(m, r) (m->otype==MAT_ILLUM && \
432	–	!(r->rsrc>=0&&source[r->rsrc].so==r->ro))
433	–
434	–	#define srcignore(m, r) (directinvis && !(r->crtype&SHADOW) && \
435	–	!distglow(m, r))
436	–
437	–
438	–	m_light(m, r) /* ray hit a light source */
439	–	register OBJREC *m;
440	–	register RAY *r;
441	–	{
442	–	/* check for over-counting */
443	–	if (wrongsource(m, r) \|\| badambient(m, r))
444	–	return;
445	–	/* check for passed illum */
446	–	if (passillum(m, r)) {
447	–	if (m->oargs.nsargs < 1 \|\| !strcmp(m->oargs.sarg[0], VOIDID))
448	–	raytrans(r);
449	–	else
450	–	rayshade(r, modifier(m->oargs.sarg[0]));
451	–	return;
452	–	}
453	–	/* otherwise treat as source */
454	–	/* check for behind */
455	–	if (r->rod < 0.0)
456	–	return;
457	–	/* check for invisibility */
458	–	if (srcignore(m, r))
459	–	return;
460	–	/* get distribution pattern */
461	–	raytexture(r, m->omod);
462	–	/* get source color */
463	–	setcolor(r->rcol, m->oargs.farg[0],
464	–	m->oargs.farg[1],
465	–	m->oargs.farg[2]);
466	–	/* modify value */
467	–	multcolor(r->rcol, r->pcol);
517		}

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Comparing ray/src/rt/srcsupp.c (file contents): Revision 1.13 by greg, Fri Sep 13 13:44:10 1991 UTC vs. Revision 2.21 by greg, Thu Dec 4 05:26:28 2014 UTC

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Comparing ray/src/rt/srcsupp.c (file contents):
Revision 1.13 by greg, Fri Sep 13 13:44:10 1991 UTC vs.
Revision 2.21 by greg, Thu Dec 4 05:26:28 2014 UTC