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

Comparing ray/src/rt/raytrace.c (file contents):
Revision 2.34 by greg, Sat Feb 22 02:07:29 2003 UTC vs.
Revision 2.71 by greg, Mon May 16 17:32:10 2016 UTC

#	Line 1 \| Line 1
1		#ifndef lint
2	<	static const char RCSid[] = "$Id$";
2	>	static const char RCSid[] = "$Id$";
3		#endif
4		/*
5		* raytrace.c - routines for tracing and shading rays.
#	Line 7 \| Line 7 \| static const char RCSid[] = "$Id$";
7		* External symbols declared in ray.h
8		*/
9
10	<	/* ====================================================================
11	<	* The Radiance Software License, Version 1.0
12	<	*
13	<	* Copyright (c) 1990 - 2002 The Regents of the University of California,
14	<	* through Lawrence Berkeley National Laboratory. All rights reserved.
15	<	*
16	<	* Redistribution and use in source and binary forms, with or without
17	<	* modification, are permitted provided that the following conditions
18	<	* are met:
19	<	*
20	<	* 1. Redistributions of source code must retain the above copyright
21	<	* notice, this list of conditions and the following disclaimer.
22	<	*
23	<	* 2. Redistributions in binary form must reproduce the above copyright
24	<	* notice, this list of conditions and the following disclaimer in
25	<	* the documentation and/or other materials provided with the
26	<	* distribution.
27	<	*
28	<	* 3. The end-user documentation included with the redistribution,
29	<	* if any, must include the following acknowledgment:
30	<	* "This product includes Radiance software
31	<	* (http://radsite.lbl.gov/)
32	<	* developed by the Lawrence Berkeley National Laboratory
33	<	* (http://www.lbl.gov/)."
34	<	* Alternately, this acknowledgment may appear in the software itself,
35	<	* if and wherever such third-party acknowledgments normally appear.
36	<	*
37	<	* 4. The names "Radiance," "Lawrence Berkeley National Laboratory"
38	<	* and "The Regents of the University of California" must
39	<	* not be used to endorse or promote products derived from this
40	<	* software without prior written permission. For written
41	<	* permission, please contact [email protected].
42	<	*
43	<	* 5. Products derived from this software may not be called "Radiance",
44	<	* nor may "Radiance" appear in their name, without prior written
45	<	* permission of Lawrence Berkeley National Laboratory.
46	<	*
47	<	* THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED OR IMPLIED
48	<	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
49	<	* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
50	<	* DISCLAIMED. IN NO EVENT SHALL Lawrence Berkeley National Laboratory OR
51	<	* ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
52	<	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
53	<	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
54	<	* USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
55	<	* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
56	<	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
57	<	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
58	<	* SUCH DAMAGE.
59	<	* ====================================================================
60	<	*
61	<	* This software consists of voluntary contributions made by many
62	<	* individuals on behalf of Lawrence Berkeley National Laboratory. For more
63	<	* information on Lawrence Berkeley National Laboratory, please see
64	<	* <http://www.lbl.gov/>.
65	<	*/
10	>	#include "copyright.h"
11
12		#include "ray.h"
13	<
13	>	#include "source.h"
14		#include "otypes.h"
70	–
15		#include "otspecial.h"
16	+	#include "random.h"
17	+	#include "pmap.h"
18
19		#define MAXCSET ((MAXSET+1)2-1) / maximum check set size */
20
21	<	unsigned long raynum = 0; /* next unique ray number */
22	<	unsigned long nrays = 0; /* number of calls to localhit */
21	>	RNUMBER raynum = 0; /* next unique ray number */
22	>	RNUMBER nrays = 0; /* number of calls to localhit */
23
24	<	static FLOAT Lambfa[5] = {PI, PI, PI, 0.0, 0.0};
24	>	static RREAL Lambfa[5] = {PI, PI, PI, 0.0, 0.0};
25		OBJREC Lamb = {
26		OVOID, MAT_PLASTIC, "Lambertian",
27	<	{0, 5, NULL, Lambfa}, NULL,
27	>	{NULL, Lambfa, 0, 5}, NULL
28		}; /* a Lambertian surface */
29
30		OBJREC Aftplane; /* aft clipping plane object */
31
86	–	static int raymove(), checkhit();
87	–	static void checkset();
88	–
89	–	#ifndef MAXLOOP
90	–	#define MAXLOOP 0 /* modifier loop detection */
91	–	#endif
92	–
32		#define RAYHIT (-1) /* return value for intercepted ray */
33
34	+	static int raymove(FVECT pos, OBJECT cxs, int dirf, RAY r, CUBE *cu);
35	+	static int checkhit(RAY r, CUBE cu, OBJECT *cxs);
36	+	static void checkset(OBJECT os, OBJECT cs);
37
38	+
39		int
40	<	rayorigin(r, ro, rt, rw) /* start new ray from old one */
41	<	register RAY r, ro;
42	<	int rt;
43	<	double rw;
40	>	rayorigin( /* start new ray from old one */
41	>	RAY *r,
42	>	int rt,
43	>	const RAY *ro,
44	>	const COLOR rc
45	>	)
46		{
47	<	double re;
48	<
47	>	double rw, re;
48	>	/* assign coefficient/weight */
49	>	if (rc == NULL) {
50	>	rw = 1.0;
51	>	setcolor(r->rcoef, 1., 1., 1.);
52	>	} else {
53	>	rw = intens(rc);
54	>	if (rw > 1.0)
55	>	rw = 1.0; /* avoid calculation growth */
56	>	if (rc != r->rcoef)
57	>	copycolor(r->rcoef, rc);
58	>	}
59		if ((r->parent = ro) == NULL) { /* primary ray */
60		r->rlvl = 0;
61		r->rweight = rw;
#	Line 113 \| Line 68 \| double rw;
68		r->gecc = seccg;
69		r->slights = NULL;
70		} else { /* spawned ray */
71	+	if (ro->rot >= FHUGE) {
72	+	memset(r, 0, sizeof(RAY));
73	+	return(-1); /* illegal continuation */
74	+	}
75		r->rlvl = ro->rlvl;
76		if (rt & RAYREFL) {
77		r->rlvl++;
#	Line 132 \| Line 91 \| double rw;
91		r->crtype = ro->crtype \| (r->rtype = rt);
92		VCOPY(r->rorg, ro->rop);
93		r->rweight = ro->rweight * rw;
94	<	/* estimate absorption */
94	>	/* estimate extinction */
95		re = colval(ro->cext,RED) < colval(ro->cext,GRN) ?
96		colval(ro->cext,RED) : colval(ro->cext,GRN);
97		if (colval(ro->cext,BLU) < re) re = colval(ro->cext,BLU);
98	<	if (re > 0.)
99	<	r->rweight = exp(-rero->rot);
98	>	re *= ro->rot;
99	>	if (re > 0.1) {
100	>	if (re > 92.) {
101	>	r->rweight = 0.0;
102	>	} else {
103	>	r->rweight *= exp(-re);
104	>	}
105	>	}
106		}
107		rayclear(r);
108	<	return(r->rlvl <= maxdepth && r->rweight >= minweight ? 0 : -1);
108	>	if (r->rweight <= 0.0) /* check for expiration */
109	>	return(-1);
110	>	if (r->crtype & SHADOW) /* shadow commitment */
111	>	return(0);
112	>	/* ambient in photon map? */
113	>	if (ro != NULL && ro->crtype & AMBIENT) {
114	>	if (causticPhotonMapping)
115	>	return(-1);
116	>	if (photonMapping && rt != TRANS)
117	>	return(-1);
118	>	}
119	>	if (maxdepth <= 0 && rc != NULL) { /* Russian roulette */
120	>	if (minweight <= 0.0)
121	>	error(USER, "zero ray weight in Russian roulette");
122	>	if (maxdepth < 0 && r->rlvl > -maxdepth)
123	>	return(-1); /* upper reflection limit */
124	>	if (r->rweight >= minweight)
125	>	return(0);
126	>	if (frandom() > r->rweight/minweight)
127	>	return(-1);
128	>	rw = minweight/r->rweight; /* promote survivor */
129	>	scalecolor(r->rcoef, rw);
130	>	r->rweight = minweight;
131	>	return(0);
132	>	}
133	>	return(r->rweight >= minweight && r->rlvl <= abs(maxdepth) ? 0 : -1);
134		}
135
136
137		void
138	<	rayclear(r) /* clear a ray for (re)evaluation */
139	<	register RAY *r;
138	>	rayclear( /* clear a ray for (re)evaluation */
139	>	RAY *r
140	>	)
141		{
142		r->rno = raynum++;
143		r->newcset = r->clipset;
144	+	r->hitf = rayhit;
145		r->robj = OVOID;
146		r->ro = NULL;
147		r->rox = NULL;
148		r->rt = r->rot = FHUGE;
149		r->pert[0] = r->pert[1] = r->pert[2] = 0.0;
150	+	r->uv[0] = r->uv[1] = 0.0;
151		setcolor(r->pcol, 1.0, 1.0, 1.0);
152		setcolor(r->rcol, 0.0, 0.0, 0.0);
153		}
154
155
156		void
157	<	raytrace(r) /* trace a ray and compute its value */
158	<	RAY *r;
157	>	raytrace( /* trace a ray and compute its value */
158	>	RAY *r
159	>	)
160		{
161		if (localhit(r, &thescene))
162		raycont(r); /* hit local surface, evaluate */
#	Line 172 \| Line 166 \| *RAY r;**
166		} else if (sourcehit(r))
167		rayshade(r, r->ro->omod); /* distant source */
168
175	–	rayparticipate(r); /* for participating medium */
176	–
169		if (trace != NULL)
170		(trace)(r); / trace execution */
171	+
172	+	rayparticipate(r); /* for participating medium */
173		}
174
175
176		void
177	<	raycont(r) /* check for clipped object and continue */
178	<	register RAY *r;
177	>	raycont( /* check for clipped object and continue */
178	>	RAY *r
179	>	)
180		{
181		if ((r->clipset != NULL && inset(r->clipset, r->ro->omod)) \|\|
182		!rayshade(r, r->ro->omod))
#	Line 190 \| Line 185 \| *register RAY r;**
185
186
187		void
188	<	raytrans(r) /* transmit ray as is */
189	<	register RAY *r;
188	>	raytrans( /* transmit ray as is */
189	>	RAY *r
190	>	)
191		{
192		RAY tr;
193
194	<	if (rayorigin(&tr, r, TRANS, 1.0) == 0) {
195	<	VCOPY(tr.rdir, r->rdir);
196	<	rayvalue(&tr);
197	<	copycolor(r->rcol, tr.rcol);
198	<	r->rt = r->rot + tr.rt;
203	<	}
194	>	rayorigin(&tr, TRANS, r, NULL); /* always continue */
195	>	VCOPY(tr.rdir, r->rdir);
196	>	rayvalue(&tr);
197	>	copycolor(r->rcol, tr.rcol);
198	>	r->rt = r->rot + tr.rt;
199		}
200
201
202	+	/* Macro for test to see if BSDF material uses proxy */
203	+	#define isBSDFproxy(m) ((m)->otype == MAT_BSDF && (m)->oargs.nsargs && \
204	+	strcmp((m)->oargs.sarg[0], "0"))
205	+
206	+
207		int
208	<	rayshade(r, mod) /* shade ray r with material mod */
209	<	register RAY *r;
210	<	int mod;
208	>	rayshade( /* shade ray r with material mod */
209	>	RAY *r,
210	>	int mod
211	>	)
212		{
213	<	int gotmat;
214	<	register OBJREC *m;
215	<	#if MAXLOOP
216	<	static int depth = 0;
216	<	/* check for infinite loop */
217	<	if (depth++ >= MAXLOOP)
218	<	objerror(r->ro, USER, "possible modifier loop");
219	<	#endif
220	<	r->rt = r->rot; /* set effective ray length */
221	<	for (gotmat = 0; !gotmat && mod != OVOID; mod = m->omod) {
213	>	OBJREC *m;
214	>
215	>	r->rt = r->rot; /* preset effective ray length */
216	>	for ( ; mod != OVOID; mod = m->omod) {
217		m = objptr(mod);
218		/****** unnecessary test since modifier() is always called
219		if (!ismodifier(m->otype)) {
#	Line 227 \| Line 222 \| int mod;
222		}
223		******/
224		/* hack for irradiance calculation */
225	<	if (do_irrad && !(r->crtype & ~(PRIMARY\|TRANS))) {
225	>	if (do_irrad && !(r->crtype & ~(PRIMARY\|TRANS)) &&
226	>	(ofun[m->otype].flags & (T_M\|T_X)) &&
227	>	m->otype != MAT_CLIP &&
228	>	!isBSDFproxy(m)) {
229		if (irr_ignore(m->otype)) {
232	–	#if MAXLOOP
233	–	depth--;
234	–	#endif
230		raytrans(r);
231		return(1);
232		}
233		if (!islight(m->otype))
234		m = &Lamb;
235		}
236	<	/* materials call raytexture */
237	<	gotmat = (*ofun[m->otype].funp)(m, r);
236	>	if ((*ofun[m->otype].funp)(m, r))
237	>	return(1); /* materials call raytexture() */
238		}
239	<	#if MAXLOOP
245	<	depth--;
246	<	#endif
247	<	return(gotmat);
239	>	return(0); /* no material! */
240		}
241
242
243		void
244	<	rayparticipate(r) /* compute ray medium participation */
245	<	register RAY *r;
244	>	rayparticipate( /* compute ray medium participation */
245	>	RAY *r
246	>	)
247		{
248		COLOR ce, ca;
249		double re, ge, be;
#	Line 265 \| Line 258 \| *register RAY r;**
258		ge *= 1. - colval(r->albedo,GRN);
259		be *= 1. - colval(r->albedo,BLU);
260		}
261	<	setcolor(ce, re<=0. ? 1. : re>92. ? 0. : exp(-re),
262	<	ge<=0. ? 1. : ge>92. ? 0. : exp(-ge),
263	<	be<=0. ? 1. : be>92. ? 0. : exp(-be));
264	<	multcolor(r->rcol, ce); /* path absorption */
261	>	setcolor(ce, re<=FTINY ? 1. : re>92. ? 0. : exp(-re),
262	>	ge<=FTINY ? 1. : ge>92. ? 0. : exp(-ge),
263	>	be<=FTINY ? 1. : be>92. ? 0. : exp(-be));
264	>	multcolor(r->rcol, ce); /* path extinction */
265		if (r->crtype & SHADOW \|\| intens(r->albedo) <= FTINY)
266		return; /* no scattering */
267	<	setcolor(ca,
268	<	colval(r->albedo,RED)colval(ambval,RED)(1.-colval(ce,RED)),
269	<	colval(r->albedo,GRN)colval(ambval,GRN)(1.-colval(ce,GRN)),
270	<	colval(r->albedo,BLU)colval(ambval,BLU)(1.-colval(ce,BLU)));
271	<	addcolor(r->rcol, ca); /* ambient in scattering */
267	>
268	>	/* PMAP: indirect inscattering accounted for by volume photons? */
269	>	if (!volumePhotonMapping) {
270	>	setcolor(ca,
271	>	colval(r->albedo,RED)colval(ambval,RED)(1.-colval(ce,RED)),
272	>	colval(r->albedo,GRN)colval(ambval,GRN)(1.-colval(ce,GRN)),
273	>	colval(r->albedo,BLU)colval(ambval,BLU)(1.-colval(ce,BLU)));
274	>	addcolor(r->rcol, ca); /* ambient in scattering */
275	>	}
276	>
277		srcscatter(r); /* source in scattering */
278		}
279
280
281	<	raytexture(r, mod) /* get material modifiers */
282	<	RAY *r;
283	<	int mod;
281	>	void
282	>	raytexture( /* get material modifiers */
283	>	RAY *r,
284	>	OBJECT mod
285	>	)
286		{
287	<	register OBJREC *m;
288	<	#if MAXLOOP
289	<	static int depth = 0;
290	<	/* check for infinite loop */
291	<	if (depth++ >= MAXLOOP)
292	<	objerror(r->ro, USER, "modifier loop");
293	<	#endif
287	>	OBJREC *m;
288		/* execute textures and patterns */
289		for ( ; mod != OVOID; mod = m->omod) {
290		m = objptr(mod);
#	Line 306 \| Line 300 \| int mod;
300		objerror(r->ro, USER, errmsg);
301		}
302		}
309	–	#if MAXLOOP
310	–	depth--; /* end here */
311	–	#endif
303		}
304
305
306		int
307	<	raymixture(r, fore, back, coef) /* mix modifiers */
308	<	register RAY *r;
309	<	OBJECT fore, back;
310	<	double coef;
307	>	raymixture( /* mix modifiers */
308	>	RAY *r,
309	>	OBJECT fore,
310	>	OBJECT back,
311	>	double coef
312	>	)
313		{
314		RAY fr, br;
315		int foremat, backmat;
316	<	register int i;
316	>	int i;
317		/* bound coefficient */
318		if (coef > 1.0)
319		coef = 1.0;
#	Line 329 \| Line 322 \| double coef;
322		/* compute foreground and background */
323		foremat = backmat = 0;
324		/* foreground */
325	<	copystruct(&fr, r);
326	<	if (coef > FTINY)
325	>	fr = *r;
326	>	if (coef > FTINY) {
327	>	fr.rweight *= coef;
328	>	scalecolor(fr.rcoef, coef);
329		foremat = rayshade(&fr, fore);
330	+	}
331		/* background */
332	<	copystruct(&br, r);
333	<	if (coef < 1.0-FTINY)
332	>	br = *r;
333	>	if (coef < 1.0-FTINY) {
334	>	br.rweight *= 1.0-coef;
335	>	scalecolor(br.rcoef, 1.0-coef);
336		backmat = rayshade(&br, back);
337	+	}
338		/* check for transparency */
339	<	if (backmat ^ foremat)
339	>	if (backmat ^ foremat) {
340		if (backmat && coef > FTINY)
341		raytrans(&fr);
342		else if (foremat && coef < 1.0-FTINY)
343		raytrans(&br);
344	+	}
345		/* mix perturbations */
346		for (i = 0; i < 3; i++)
347		r->pert[i] = coeffr.pert[i] + (1.0-coef)br.pert[i];
#	Line 364 \| Line 364 \| double coef;
364
365
366		double
367	<	raydist(r, flags) /* compute (cumulative) ray distance */
368	<	register RAY *r;
369	<	register int flags;
367	>	raydist( /* compute (cumulative) ray distance */
368	>	const RAY *r,
369	>	int flags
370	>	)
371		{
372		double sum = 0.0;
373
#	Line 378 \| Line 379 \| register int flags;
379		}
380
381
382	+	void
383	+	raycontrib( /* compute (cumulative) ray contribution */
384	+	RREAL rc[3],
385	+	const RAY *r,
386	+	int flags
387	+	)
388	+	{
389	+	double eext[3];
390	+	int i;
391	+
392	+	eext[0] = eext[1] = eext[2] = 0.;
393	+	rc[0] = rc[1] = rc[2] = 1.;
394	+
395	+	while (r != NULL && r->crtype&flags) {
396	+	for (i = 3; i--; ) {
397	+	rc[i] *= colval(r->rcoef,i);
398	+	eext[i] += r->rot * colval(r->cext,i);
399	+	}
400	+	r = r->parent;
401	+	}
402	+	for (i = 3; i--; )
403	+	rc[i] *= (eext[i] <= FTINY) ? 1. :
404	+	(eext[i] > 92.) ? 0. : exp(-eext[i]);
405	+	}
406	+
407	+
408		double
409	<	raynormal(norm, r) /* compute perturbed normal for ray */
410	<	FVECT norm;
411	<	register RAY *r;
409	>	raynormal( /* compute perturbed normal for ray */
410	>	FVECT norm,
411	>	RAY *r
412	>	)
413		{
414		double newdot;
415	<	register int i;
415	>	int i;
416
417		/* The perturbation is added to the surface normal to obtain
418		* the new normal. If the new normal would affect the surface
#	Line 414 \| Line 442 \| *register RAY r;**
442
443
444		void
445	<	newrayxf(r) /* get new tranformation matrix for ray */
446	<	RAY *r;
445	>	newrayxf( /* get new tranformation matrix for ray */
446	>	RAY *r
447	>	)
448		{
449		static struct xfn {
450		struct xfn *next;
451		FULLXF xf;
452		} xfseed = { &xfseed }, *xflast = &xfseed;
453	<	register struct xfn *xp;
454	<	register RAY *rp;
453	>	struct xfn *xp;
454	>	const RAY *rp;
455
456		/*
457		* Search for transform in circular list that
#	Line 433 \| Line 462 \| *RAY r;**
462		if (rp->rox == &xp->xf) { /* xp in use */
463		xp = xp->next; /* move to next */
464		if (xp == xflast) { /* need new one */
465	<	xp = (struct xfn *)malloc(sizeof(struct xfn));
465	>	xp = (struct xfn *)bmalloc(sizeof(struct xfn));
466		if (xp == NULL)
467		error(SYSTEM,
468		"out of memory in newrayxf");
#	Line 451 \| Line 480 \| *RAY r;**
480
481
482		void
483	<	flipsurface(r) /* reverse surface orientation */
484	<	register RAY *r;
483	>	flipsurface( /* reverse surface orientation */
484	>	RAY *r
485	>	)
486		{
487		r->rod = -r->rod;
488		r->ron[0] = -r->ron[0];
#	Line 464 \| Line 494 \| *register RAY r;**
494		}
495
496
497	+	void
498	+	rayhit( /* standard ray hit test */
499	+	OBJECT *oset,
500	+	RAY *r
501	+	)
502	+	{
503	+	OBJREC *o;
504	+	int i;
505	+
506	+	for (i = oset[0]; i > 0; i--) {
507	+	o = objptr(oset[i]);
508	+	if ((*ofun[o->otype].funp)(o, r))
509	+	r->robj = oset[i];
510	+	}
511	+	}
512	+
513	+
514		int
515	<	localhit(r, scene) /* check for hit in the octree */
516	<	register RAY *r;
517	<	register CUBE *scene;
515	>	localhit( /* check for hit in the octree */
516	>	RAY *r,
517	>	CUBE *scene
518	>	)
519		{
520		OBJECT cxset[MAXCSET+1]; /* set of checked objects */
521		FVECT curpos; /* current cube position */
522		int sflags; /* sign flags */
523		double t, dt;
524	<	register int i;
524	>	int i;
525
526		nrays++; /* increment trace counter */
527		sflags = 0;
#	Line 484 \| Line 532 \| *register CUBE scene;**
532		else if (r->rdir[i] < -1e-7)
533		sflags \|= 0x10 << i;
534		}
535	<	if (sflags == 0)
536	<	error(CONSISTENCY, "zero ray direction in localhit");
535	>	if (!sflags) {
536	>	error(WARNING, "zero ray direction in localhit");
537	>	return(0);
538	>	}
539		/* start off assuming nothing hit */
540		if (r->rmax > FTINY) { /* except aft plane if one */
541		r->ro = &Aftplane;
542		r->rot = r->rmax;
543	<	for (i = 0; i < 3; i++)
494	<	r->rop[i] = r->rorg[i] + r->rot*r->rdir[i];
543	>	VSUM(r->rop, r->rorg, r->rdir, r->rot);
544		}
545		/* find global cube entrance point */
546		t = 0.0;
#	Line 514 \| Line 563 \| *register CUBE scene;**
563		if (t >= r->rot) /* clipped already */
564		return(0);
565		/* advance position */
566	<	for (i = 0; i < 3; i++)
518	<	curpos[i] += r->rdir[i]*t;
566	>	VSUM(curpos, curpos, r->rdir, t);
567
568		if (!incube(scene, curpos)) /* non-intersecting ray */
569		return(0);
570		}
571		cxset[0] = 0;
572		raymove(curpos, cxset, sflags, r, scene);
573	<	return(r->ro != NULL & r->ro != &Aftplane);
573	>	return((r->ro != NULL) & (r->ro != &Aftplane));
574		}
575
576
577		static int
578	<	raymove(pos, cxs, dirf, r, cu) /* check for hit as we move */
579	<	FVECT pos; /* current position, modified herein */
580	<	OBJECT cxs; / checked objects, modified by checkhit */
581	<	int dirf; /* direction indicators to speed tests */
582	<	register RAY *r;
583	<	register CUBE *cu;
578	>	raymove( /* check for hit as we move */
579	>	FVECT pos, /* current position, modified herein */
580	>	OBJECT cxs, / checked objects, modified by checkhit */
581	>	int dirf, /* direction indicators to speed tests */
582	>	RAY *r,
583	>	CUBE *cu
584	>	)
585		{
586		int ax;
587		double dt, t;
588
589		if (istree(cu->cutree)) { /* recurse on subcubes */
590		CUBE cukid;
591	<	register int br, sgn;
591	>	int br, sgn;
592
593		cukid.cusize = cu->cusize * 0.5; /* find subcube */
594		VCOPY(cukid.cuorg, cu->cuorg);
#	Line 605 \| Line 654 \| *register CUBE cu;**
654		ax = 2;
655		}
656		}
657	<	pos[0] += r->rdir[0]*t;
609	<	pos[1] += r->rdir[1]*t;
610	<	pos[2] += r->rdir[2]*t;
657	>	VSUM(pos, pos, r->rdir, t);
658		return(ax);
659		}
660
661
662		static int
663	<	checkhit(r, cu, cxs) /* check for hit in full cube */
664	<	register RAY *r;
665	<	CUBE *cu;
666	<	OBJECT *cxs;
663	>	checkhit( /* check for hit in full cube */
664	>	RAY *r,
665	>	CUBE *cu,
666	>	OBJECT *cxs
667	>	)
668		{
669		OBJECT oset[MAXSET+1];
622	–	register OBJREC *o;
623	–	register int i;
670
671		objset(oset, cu->cutree);
672	<	checkset(oset, cxs); /* eliminate double-checking */
673	<	for (i = oset[0]; i > 0; i--) {
674	<	o = objptr(oset[i]);
675	<	if ((*ofun[o->otype].funp)(o, r))
676	<	r->robj = oset[i];
631	<	}
632	<	if (r->ro == NULL)
672	>	checkset(oset, cxs); /* avoid double-checking */
673	>
674	>	(r->hitf)(oset, r); / test for hit in set */
675	>
676	>	if (r->robj == OVOID)
677		return(0); /* no scores yet */
678
679		return(incube(cu, r->rop)); /* hit OK if in current cube */
#	Line 637 \| Line 681 \| *OBJECT cxs;**
681
682
683		static void
684	<	checkset(os, cs) /* modify checked set and set to check */
685	<	register OBJECT os; / os' = os - cs */
686	<	register OBJECT cs; / cs' = cs + os */
684	>	checkset( /* modify checked set and set to check */
685	>	OBJECT os, / os' = os - cs */
686	>	OBJECT cs / cs' = cs + os */
687	>	)
688		{
689		OBJECT cset[MAXCSET+MAXSET+1];
690	<	register int i, j;
690	>	int i, j;
691		int k;
692		/* copy os in place, cset <- cs */
693		cset[0] = 0;

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Comparing ray/src/rt/raytrace.c (file contents): Revision 2.34 by greg, Sat Feb 22 02:07:29 2003 UTC vs. Revision 2.71 by greg, Mon May 16 17:32:10 2016 UTC

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Comparing ray/src/rt/raytrace.c (file contents):
Revision 2.34 by greg, Sat Feb 22 02:07:29 2003 UTC vs.
Revision 2.71 by greg, Mon May 16 17:32:10 2016 UTC