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

Comparing ray/src/rt/virtuals.c (file contents):
Revision 1.4 by greg, Thu Jun 20 16:36:48 1991 UTC vs.
Revision 2.19 by greg, Tue Aug 16 18:09:53 2011 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		* Routines for simulating virtual light sources
6		* Thus far, we only support planar mirrors.
7	+	*
8	+	* External symbols declared in source.h
9		*/
10
11	+	#include "copyright.h"
12	+
13		#include "ray.h"
14
15		#include "otypes.h"
16
17		#include "source.h"
18
19	+	#include "random.h"
20
21	<	double intercircle();
21	>	#define MINSAMPLES 16 /* minimum number of pretest samples */
22	>	#define STESTMAX 32 /* maximum seeks per sample */
23
24	+
25		static OBJECT vobject; / virtual source objects */
26		static int nvobjects = 0; /* number of virtual source objects */
27
28
29	<	markvirtuals() /* find and mark virtual sources */
29	>	extern void
30	>	markvirtuals(void) /* find and mark virtual sources */
31		{
32		register OBJREC *o;
33		register int i;
#	Line 30 \| Line 35 \| *markvirtuals() / find and mark virtual sources /*
35		if (directrelay <= 0)
36		return;
37		/* find virtual source objects */
38	<	for (i = 0; i < nobjects; i++) {
38	>	for (i = 0; i < nsceneobjs; i++) {
39		o = objptr(i);
40		if (!issurface(o->otype) \|\| o->omod == OVOID)
41		continue;
42	<	if (!isvlight(objptr(o->omod)->otype))
42	>	if (!isvlight(vsmaterial(o)->otype))
43		continue;
44		if (sfun[o->otype].of == NULL \|\|
45	<	sfun[o->otype].of->getpleq == NULL)
46	<	objerror(o, USER, "illegal material");
45	>	sfun[o->otype].of->getpleq == NULL) {
46	>	objerror(o,WARNING,"secondary sources not supported");
47	>	continue;
48	>	}
49		if (nvobjects == 0)
50		vobject = (OBJECT *)malloc(sizeof(OBJECT));
51		else
52	<	vobject = (OBJECT )realloc((char )vobject,
52	>	vobject = (OBJECT )realloc((void )vobject,
53		(unsigned)(nvobjects+1)*sizeof(OBJECT));
54		if (vobject == NULL)
55		error(SYSTEM, "out of memory in addvirtuals");
#	Line 55 \| Line 62 \| *markvirtuals() / find and mark virtual sources /*
62		#endif
63		/* append virtual sources */
64		for (i = nsources; i-- > 0; )
65	<	if (!(source[i].sflags & SSKIP))
59	<	addvirtuals(i, directrelay);
65	>	addvirtuals(i, directrelay);
66		/* done with our object list */
67	<	free((char *)vobject);
67	>	free((void *)vobject);
68		nvobjects = 0;
69		}
70
71
72	<	addvirtuals(sn, nr) /* add virtuals associated with source */
73	<	int sn;
74	<	int nr;
72	>	extern void
73	>	addvirtuals( /* add virtuals associated with source */
74	>	int sn,
75	>	int nr
76	>	)
77		{
78		register int i;
79		/* check relay limit first */
80		if (nr <= 0)
81		return;
82	+	if (source[sn].sflags & SSKIP)
83	+	return;
84		/* check each virtual object for projection */
85		for (i = 0; i < nvobjects; i++)
86		/* vproject() calls us recursively */
#	Line 78 \| Line 88 \| int nr;
88		}
89
90
91	<	vproject(o, sn, n) /* create projected source(s) if they exist */
92	<	OBJREC *o;
93	<	int sn;
94	<	int n;
91	>	extern void
92	>	vproject( /* create projected source(s) if they exist */
93	>	OBJREC *o,
94	>	int sn,
95	>	int n
96	>	)
97		{
98		register int i;
99		register VSMATERIAL *vsmat;
#	Line 91 \| Line 103 \| int n;
103		if (o == source[sn].so) /* objects cannot project themselves */
104		return;
105		/* get virtual source material */
106	<	vsmat = sfun[objptr(o->omod)->otype].mf;
106	>	vsmat = sfun[vsmaterial(o)->otype].mf;
107		/* project virtual sources */
108		for (i = 0; i < vsmat->nproj; i++)
109		if ((*vsmat->vproj)(proj, o, &source[sn], i))
110		if ((ns = makevsrc(o, sn, proj)) >= 0) {
111	+	source[ns].sa.sv.pn = i;
112		#ifdef DEBUG
113	<	virtverb(&source[sn], stderr);
113	>	virtverb(ns, stderr);
114		#endif
115		addvirtuals(ns, n);
116		}
117		}
118
119
120	<	int
121	<	makevsrc(op, sn, pm) /* make virtual source if reasonable */
122	<	OBJREC *op;
123	<	register int sn;
111	<	MAT4 pm;
120	>	extern OBJREC *
121	>	vsmaterial( /* get virtual source material pointer */
122	>	OBJREC *o
123	>	)
124		{
125	<	register int nsn;
126	<	FVECT nsloc, ocent, nsnorm;
125	>	register int i;
126	>	register OBJREC *m;
127	>
128	>	i = o->omod;
129	>	m = findmaterial(objptr(i));
130	>	if (m == NULL)
131	>	return(objptr(i));
132	>	if (m->otype != MAT_ILLUM \|\| m->oargs.nsargs < 1 \|\|
133	>	!strcmp(m->oargs.sarg[0], VOIDID) \|\|
134	>	(i = lastmod(objndx(m), m->oargs.sarg[0])) == OVOID)
135	>	return(m); /* direct modifier */
136	>	return(objptr(i)); /* illum alternate */
137	>	}
138	>
139	>
140	>	extern int
141	>	makevsrc( /* make virtual source if reasonable */
142	>	OBJREC *op,
143	>	register int sn,
144	>	MAT4 pm
145	>	)
146	>	{
147	>	FVECT nsloc, nsnorm, ocent, v;
148	>	double maxrad2, d;
149		int nsflags;
116	–	double maxrad2;
117	–	double d1;
150		SPOT theirspot, ourspot;
151		register int i;
152
153	<	nsflags = (source[sn].sflags\|(SVIRTUAL\|SFOLLOW)) & ~SSPOT;
153	>	nsflags = source[sn].sflags \| (SVIRTUAL\|SSPOT\|SFOLLOW);
154		/* get object center and max. radius */
155	<	if (sfun[op->otype].of->getdisk != NULL) {
156	<	maxrad2 = (*sfun[op->otype].of->getdisk)(ocent, op);
157	<	if (maxrad2 <= FTINY) /* too small? */
126	<	return(NULL);
127	<	nsflags \|= SSPOT;
128	<	}
155	>	maxrad2 = getdisk(ocent, op, sn);
156	>	if (maxrad2 <= FTINY) /* too small? */
157	>	return(-1);
158		/* get location and spot */
159		if (source[sn].sflags & SDISTANT) { /* distant source */
160		if (source[sn].sflags & SPROX)
161	<	return(NULL); /* should never get here! */
161	>	return(-1); /* should never get here! */
162		multv3(nsloc, source[sn].sloc, pm);
163	<	if (nsflags & SSPOT) {
164	<	VCOPY(ourspot.aim, ocent);
165	<	ourspot.siz = PI*maxrad2;
166	<	ourspot.flen = 0.;
138	<	}
163	>	normalize(nsloc);
164	>	VCOPY(ourspot.aim, ocent);
165	>	ourspot.siz = PI*maxrad2;
166	>	ourspot.flen = -1.;
167		if (source[sn].sflags & SSPOT) {
140	–	copystruct(&theirspot, source[sn].sl.s);
168		multp3(theirspot.aim, source[sn].sl.s->aim, pm);
169	<	if (nsflags & SSPOT &&
170	<	!commonbeam(&ourspot, &theirspot, nsloc))
171	<	return(NULL); /* no overlap */
169	>	/* adjust for source size */
170	>	d = sqrt(dist2(ourspot.aim, theirspot.aim));
171	>	d = sqrt(source[sn].sl.s->siz/PI) + d*source[sn].srad;
172	>	theirspot.siz = PIdd;
173	>	ourspot.flen = theirspot.flen = source[sn].sl.s->flen;
174	>	d = ourspot.siz;
175	>	if (!commonbeam(&ourspot, &theirspot, nsloc))
176	>	return(-1); /* no overlap */
177	>	if (ourspot.siz < d-FTINY) { /* it shrunk */
178	>	d = beamdisk(v, op, &ourspot, nsloc);
179	>	if (d <= FTINY)
180	>	return(-1);
181	>	if (d < maxrad2) {
182	>	maxrad2 = d;
183	>	VCOPY(ocent, v);
184	>	}
185	>	}
186		}
187		} else { /* local source */
188		multp3(nsloc, source[sn].sloc, pm);
189	<	if (nsflags & SSPOT) {
190	<	for (i = 0; i < 3; i++)
191	<	ourspot.aim[i] = ocent[i] - nsloc[i];
192	<	if ((d1 = normalize(ourspot.aim)) == 0.)
193	<	return(NULL); /* at source!! */
194	<	if (source[sn].sflags & SPROX &&
195	<	d1 > source[sn].sl.prox)
196	<	return(NULL); /* too far away */
197	<	ourspot.siz = 2.PI(1. - d1/sqrt(d1*d1+maxrad2));
198	<	ourspot.flen = 0.;
199	<	} else if (source[sn].sflags & SPROX) {
200	<	FVECT norm;
201	<	double offs;
161	<	/* use distance from plane */
162	<	offs = (*sfun[op->otype].of->getpleq)(norm, op);
163	<	d1 = DOT(norm, nsloc) - offs;
164	<	if (d1 < 0.) d1 = -d1;
165	<	if (d1 > source[sn].sl.prox)
166	<	return(NULL); /* too far away */
167	<	}
189	>	for (i = 0; i < 3; i++)
190	>	ourspot.aim[i] = ocent[i] - nsloc[i];
191	>	if ((d = normalize(ourspot.aim)) == 0.)
192	>	return(-1); /* at source!! */
193	>	if (source[sn].sflags & SPROX && d > source[sn].sl.prox)
194	>	return(-1); /* too far away */
195	>	ourspot.flen = 0.;
196	>	/* adjust for source size */
197	>	d = (sqrt(maxrad2) + source[sn].srad) / d;
198	>	if (d < 1.-FTINY)
199	>	ourspot.siz = 2.PI(1. - sqrt(1.-d*d));
200	>	else
201	>	nsflags &= ~SSPOT;
202		if (source[sn].sflags & SSPOT) {
203	<	copystruct(&theirspot, source[sn].sl.s);
203	>	theirspot = *(source[sn].sl.s);
204		multv3(theirspot.aim, source[sn].sl.s->aim, pm);
205	+	normalize(theirspot.aim);
206		if (nsflags & SSPOT) {
172	–	if (!commonspot(&ourspot, &theirspot, nsloc))
173	–	return(NULL); /* no overlap */
207		ourspot.flen = theirspot.flen;
208	+	d = ourspot.siz;
209	+	if (!commonspot(&ourspot, &theirspot, nsloc))
210	+	return(-1); /* no overlap */
211	+	} else {
212	+	nsflags \|= SSPOT;
213	+	ourspot = theirspot;
214	+	d = 2.*ourspot.siz;
215		}
216	+	if (ourspot.siz < d-FTINY) { /* it shrunk */
217	+	d = spotdisk(v, op, &ourspot, nsloc);
218	+	if (d <= FTINY)
219	+	return(-1);
220	+	if (d < maxrad2) {
221	+	maxrad2 = d;
222	+	VCOPY(ocent, v);
223	+	}
224	+	}
225		}
226		if (source[sn].sflags & SFLAT) { /* behind source? */
227		multv3(nsnorm, source[sn].snorm, pm);
228	<	if (nsflags & SSPOT && checkspot(&ourspot, nsnorm) < 0)
229	<	return(NULL);
228	>	normalize(nsnorm);
229	>	if (nsflags & SSPOT && !checkspot(&ourspot, nsnorm))
230	>	return(-1);
231		}
232		}
233	<	/* everything is OK, make source */
234	<	if ((nsn = newsource()) < 0)
233	>	/* pretest visibility */
234	>	nsflags = vstestvis(nsflags, op, ocent, maxrad2, sn);
235	>	if (nsflags & SSKIP)
236	>	return(-1); /* obstructed */
237	>	/* it all checks out, so make it */
238	>	if ((i = newsource()) < 0)
239		goto memerr;
240	<	source[nsn].sflags = nsflags;
241	<	VCOPY(source[nsn].sloc, nsloc);
240	>	source[i].sflags = nsflags;
241	>	VCOPY(source[i].sloc, nsloc);
242	>	multv3(source[i].ss[SU], source[sn].ss[SU], pm);
243	>	multv3(source[i].ss[SV], source[sn].ss[SV], pm);
244		if (nsflags & SFLAT)
245	<	VCOPY(source[nsn].snorm, nsnorm);
246	<	source[nsn].ss = source[sn].ss; source[nsn].ss2 = source[sn].ss2;
247	<	if ((nsflags \| source[sn].sflags) & SSPOT) {
248	<	if ((source[nsn].sl.s = (SPOT *)malloc(sizeof(SPOT))) == NULL)
245	>	VCOPY(source[i].snorm, nsnorm);
246	>	else
247	>	multv3(source[i].ss[SW], source[sn].ss[SW], pm);
248	>	source[i].srad = source[sn].srad;
249	>	source[i].ss2 = source[sn].ss2;
250	>	if (nsflags & SSPOT) {
251	>	if ((source[i].sl.s = (SPOT *)malloc(sizeof(SPOT))) == NULL)
252		goto memerr;
253	<	if (nsflags & SSPOT)
195	<	copystruct(source[nsn].sl.s, &ourspot);
196	<	else
197	<	copystruct(source[nsn].sl.s, &theirspot);
198	<	source[nsn].sflags \|= SSPOT;
253	>	*(source[i].sl.s) = ourspot;
254		}
255		if (nsflags & SPROX)
256	<	source[nsn].sl.prox = source[sn].sl.prox;
257	<	source[nsn].sa.svnext = sn;
258	<	source[nsn].so = op;
259	<	return(nsn);
256	>	source[i].sl.prox = source[sn].sl.prox;
257	>	source[i].sa.sv.sn = sn;
258	>	source[i].so = op;
259	>	return(i);
260		memerr:
261		error(SYSTEM, "out of memory in makevsrc");
262	+	return -1; /* pro forma return */
263		}
264
265
266	<	commonspot(sp1, sp2, org) /* set sp1 to intersection of sp1 and sp2 */
267	<	register SPOT sp1, sp2;
268	<	FVECT org;
266	>	extern double
267	>	getdisk( /* get visible object disk */
268	>	FVECT oc,
269	>	OBJREC *op,
270	>	register int sn
271	>	)
272		{
273	<	FVECT cent;
274	<	double rad2, cos1, cos2;
275	<
276	<	cos1 = 1. - sp1->siz/(2.*PI);
277	<	cos2 = 1. - sp2->siz/(2.*PI);
278	<	if (sp2->siz >= 2.PI-FTINY) / BIG, just check overlap */
279	<	return(DOT(sp1->aim,sp2->aim) >= cos1*cos2 -
280	<	sqrt((1.-cos1cos1)(1.-cos2*cos2)));
281	<	/* compute and check disks */
282	<	rad2 = intercircle(cent, sp1->aim, sp2->aim,
283	<	1./(cos1cos1) - 1., 1./(cos2cos2) - 1.);
284	<	if (rad2 <= FTINY \|\| normalize(cent) == 0.)
285	<	return(0);
286	<	VCOPY(sp1->aim, cent);
287	<	sp1->siz = 2.PI(1. - 1./sqrt(1.+rad2));
288	<	return(1);
273	>	double rad2, roffs, offs, d, rd, rdoto;
274	>	FVECT rnrm, nrm;
275	>	/* first, use object getdisk function */
276	>	rad2 = getmaxdisk(oc, op);
277	>	if (!(source[sn].sflags & SVIRTUAL))
278	>	return(rad2); /* all done for normal source */
279	>	/* check for correct side of relay surface */
280	>	roffs = getplaneq(rnrm, source[sn].so);
281	>	rd = DOT(rnrm, source[sn].sloc); /* source projection */
282	>	if (!(source[sn].sflags & SDISTANT))
283	>	rd -= roffs;
284	>	d = DOT(rnrm, oc) - roffs; /* disk distance to relay plane */
285	>	if ((d > 0.) ^ (rd > 0.))
286	>	return(rad2); /* OK if opposite sides */
287	>	if (d*d >= rad2)
288	>	return(0.); /* no relay is possible */
289	>	/* we need a closer look */
290	>	offs = getplaneq(nrm, op);
291	>	rdoto = DOT(rnrm, nrm);
292	>	if (dd >= rad2(1.-rdoto*rdoto))
293	>	return(0.); /* disk entirely on projection side */
294	>	/* should shrink disk but I'm lazy */
295	>	return(rad2);
296		}
297
298
299	<	commonbeam(sp1, sp2, dir) /* set sp1 to intersection of sp1 and sp2 */
300	<	register SPOT sp1, sp2;
301	<	FVECT dir;
299	>	extern int
300	>	vstestvis( /* pretest source visibility */
301	>	int f, /* virtual source flags */
302	>	OBJREC o, / relay object */
303	>	FVECT oc, /* relay object center */
304	>	double or2, /* relay object radius squared */
305	>	register int sn /* target source number */
306	>	)
307		{
308	<	FVECT cent, c1, c2;
309	<	double rad2, d;
310	<	register int i;
311	<	/* move centers to common plane */
312	<	d = DOT(sp1->aim, dir);
313	<	for (i = 0; i < 3; i++)
314	<	c1[i] = sp1->aim[i] - d*dir[i];
315	<	d = DOT(sp2->aim, dir);
316	<	for (i = 0; i < 3; i++)
317	<	c2[i] = sp2->aim[i] - d*dir[i];
318	<	/* compute overlap */
319	<	rad2 = intercircle(cent, c1, c2, sp1->siz/PI, sp2->siz/PI);
320	<	if (rad2 <= FTINY)
321	<	return(0);
322	<	VCOPY(sp1->aim, cent);
323	<	sp1->siz = PI*rad2;
324	<	return(1);
254	<	}
255	<
256	<
257	<	checkspot(sp, nrm) /* check spotlight for behind source */
258	<	register SPOT *sp;
259	<	FVECT nrm;
260	<	{
261	<	double d, d1;
262	<
263	<	d = DOT(sp->aim, nrm);
264	<	if (d > FTINY) /* center in front? */
265	<	return(0);
266	<	/* else check horizon */
267	<	d1 = 1. - sp->siz/(2.*PI);
268	<	return(1.-FTINY-dd > d1d1);
269	<	}
270	<
271	<
272	<	double
273	<	intercircle(cc, c1, c2, r1s, r2s) /* intersect two circles */
274	<	FVECT cc; /* midpoint (return value) */
275	<	FVECT c1, c2; /* circle centers */
276	<	double r1s, r2s; /* radii squared */
277	<	{
278	<	double a2, d2, l;
279	<	FVECT disp;
280	<	register int i;
281	<
282	<	for (i = 0; i < 3; i++)
283	<	disp[i] = c2[i] - c1[i];
284	<	d2 = DOT(disp,disp);
285	<	/* circle within overlap? */
286	<	if (r1s < r2s) {
287	<	if (r2s >= r1s + d2) {
288	<	VCOPY(cc, c1);
289	<	return(r1s);
290	<	}
308	>	RAY sr;
309	>	FVECT onorm;
310	>	FVECT offsdir;
311	>	SRCINDEX si;
312	>	double or, d, d1;
313	>	int stestlim, ssn;
314	>	int nhit, nok;
315	>	register int i, n;
316	>	/* return if pretesting disabled */
317	>	if (vspretest <= 0)
318	>	return(f);
319	>	/* get surface normal */
320	>	getplaneq(onorm, o);
321	>	/* set number of rays to sample */
322	>	if (source[sn].sflags & SDISTANT) {
323	>	/* 32. == heuristic constant */
324	>	n = 32.or2/(thescene.cusizethescene.cusize)*vspretest + .5;
325		} else {
326	<	if (r1s >= r2s + d2) {
327	<	VCOPY(cc, c2);
328	<	return(r2s);
326	>	for (i = 0; i < 3; i++)
327	>	offsdir[i] = source[sn].sloc[i] - oc[i];
328	>	d = DOT(offsdir,offsdir);
329	>	if (d <= FTINY)
330	>	n = 2.PI vspretest + .5;
331	>	else
332	>	n = 2.PI (1.-sqrt(1./(1.+or2/d)))*vspretest + .5;
333	>	}
334	>	if (n < MINSAMPLES) n = MINSAMPLES;
335	>	#ifdef DEBUG
336	>	fprintf(stderr, "pretesting source %d in object %s with %d rays\n",
337	>	sn, o->oname, n);
338	>	#endif
339	>	/* sample */
340	>	or = sqrt(or2);
341	>	stestlim = n*STESTMAX;
342	>	ssn = 0;
343	>	nhit = nok = 0;
344	>	initsrcindex(&si);
345	>	while (n-- > 0) {
346	>	/* get sample point */
347	>	do {
348	>	if (ssn >= stestlim) {
349	>	#ifdef DEBUG
350	>	fprintf(stderr, "\ttoo hard to hit\n");
351	>	#endif
352	>	return(f); /* too small a target! */
353	>	}
354	>	multisamp(offsdir, 3, urand(sn*931+5827+ssn));
355	>	for (i = 0; i < 3; i++)
356	>	offsdir[i] = or(1. - 2.offsdir[i]);
357	>	ssn++;
358	>	d = 1. - DOT(offsdir, onorm);
359	>	for (i = 0; i < 3; i++) {
360	>	sr.rorg[i] = oc[i] + offsdir[i] + d*onorm[i];
361	>	sr.rdir[i] = -onorm[i];
362	>	}
363	>	rayorigin(&sr, PRIMARY, NULL, NULL);
364	>	} while (!(*ofun[o->otype].funp)(o, &sr));
365	>	/* check against source */
366	>	VCOPY(sr.rorg, sr.rop); /* starting from intersection */
367	>	samplendx++;
368	>	if (si.sp >= si.np-1 \|\|
369	>	!srcray(&sr, NULL, &si) \|\| sr.rsrc != sn) {
370	>	si.sn = sn-1; /* reset index to our source */
371	>	si.np = 0;
372	>	if (!srcray(&sr, NULL, &si) \|\| sr.rsrc != sn)
373	>	continue; /* can't get there from here */
374		}
375	+	sr.revf = srcvalue;
376	+	rayvalue(&sr); /* check sample validity */
377	+	if ((d = bright(sr.rcol)) <= FTINY)
378	+	continue;
379	+	nok++; /* got sample; check obstructions */
380	+	rayclear(&sr);
381	+	sr.revf = raytrace;
382	+	rayvalue(&sr);
383	+	if ((d1 = bright(sr.rcol)) > FTINY) {
384	+	if (d - d1 > FTINY) {
385	+	#ifdef DEBUG
386	+	fprintf(stderr, "\tpartially shadowed\n");
387	+	#endif
388	+	return(f); /* intervening transmitter */
389	+	}
390	+	nhit++;
391	+	}
392	+	if (nhit > 0 && nhit < nok) {
393	+	#ifdef DEBUG
394	+	fprintf(stderr, "\tpartially occluded\n");
395	+	#endif
396	+	return(f); /* need to shadow test */
397	+	}
398		}
399	<	a2 = .25(2.(r1s+r2s) - d2 - (r2s-r1s)*(r2s-r1s)/d2);
400	<	/* no overlap? */
401	<	if (a2 <= 0.)
402	<	return(0.);
403	<	/* overlap, compute center */
404	<	l = sqrt((r1s - a2)/d2);
405	<	for (i = 0; i < 3; i++)
406	<	cc[i] = c1[i] + l*disp[i];
407	<	return(a2);
399	>	if (nhit == 0) {
400	>	#ifdef DEBUG
401	>	fprintf(stderr, "\t0%% hit rate\n");
402	>	#endif
403	>	return(f \| SSKIP); /* 0% hit rate: totally occluded */
404	>	}
405	>	#ifdef DEBUG
406	>	fprintf(stderr, "\t100%% hit rate\n");
407	>	#endif
408	>	return(f & ~SFOLLOW); /* 100% hit rate: no occlusion */
409		}
410	+
411
308	–
412		#ifdef DEBUG
413	<	virtverb(vs, fp) /* print verbose description of virtual source */
414	<	register SRCREC *vs;
415	<	FILE *fp;
413	>	extern void
414	>	virtverb( /* print verbose description of virtual source */
415	>	register int sn,
416	>	FILE *fp
417	>	)
418		{
314	–	register int i;
315	–
419		fprintf(fp, "%s virtual source %d in %s %s\n",
420	<	vs->sflags & SDISTANT ? "distant" : "local",
421	<	vs-source, ofun[vs->so->otype].funame, vs->so->oname);
420	>	source[sn].sflags & SDISTANT ? "distant" : "local",
421	>	sn, ofun[source[sn].so->otype].funame,
422	>	source[sn].so->oname);
423		fprintf(fp, "\tat (%f,%f,%f)\n",
424	<	vs->sloc[0], vs->sloc[1], vs->sloc[2]);
424	>	source[sn].sloc[0], source[sn].sloc[1], source[sn].sloc[2]);
425		fprintf(fp, "\tlinked to source %d (%s)\n",
426	<	vs->sa.svnext, source[vs->sa.svnext].so->oname);
427	<	if (vs->sflags & SFOLLOW)
426	>	source[sn].sa.sv.sn, source[source[sn].sa.sv.sn].so->oname);
427	>	if (source[sn].sflags & SFOLLOW)
428		fprintf(fp, "\talways followed\n");
429		else
430		fprintf(fp, "\tnever followed\n");
431	<	if (!(vs->sflags & SSPOT))
431	>	if (!(source[sn].sflags & SSPOT))
432		return;
433		fprintf(fp, "\twith spot aim (%f,%f,%f) and size %f\n",
434	<	vs->sl.s->aim[0], vs->sl.s->aim[1], vs->sl.s->aim[2],
435	<	vs->sl.s->siz);
434	>	source[sn].sl.s->aim[0], source[sn].sl.s->aim[1],
435	>	source[sn].sl.s->aim[2], source[sn].sl.s->siz);
436		}
437		#endif

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Comparing ray/src/rt/virtuals.c (file contents): Revision 1.4 by greg, Thu Jun 20 16:36:48 1991 UTC vs. Revision 2.19 by greg, Tue Aug 16 18:09:53 2011 UTC

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Comparing ray/src/rt/virtuals.c (file contents):
Revision 1.4 by greg, Thu Jun 20 16:36:48 1991 UTC vs.
Revision 2.19 by greg, Tue Aug 16 18:09:53 2011 UTC