src/rt/srcobstr.c

#ifndef lint
static const char RCSid[] = "$Id: srcobstr.c,v 2.15 2009/12/12 00:03:42 greg Exp $";
#endif
/*
 * Source occlusion caching routines
 */

#include  "ray.h"

#include  "otypes.h"

#include  "otspecial.h"

#include  "rtotypes.h"

#include  "source.h"

#define ABS(x)  ((x)>0 ? (x) : -(x))


#if  SHADCACHE                  /* preemptive shadow checking */


OBJECT *        antimodlist = NULL;     /* set of clipped materials */


static int                              /* cast source ray to first blocker */
castshadow(int sn, FVECT rorg, FVECT rdir)
{
        RAY     rt;
        
        VCOPY(rt.rorg, rorg);
        VCOPY(rt.rdir, rdir);
        rt.rmax = 0;
        rayorigin(&rt, PRIMARY, NULL, NULL);
                                        /* check for intersection */
        while (localhit(&rt, &thescene)) {
                RAY     rt1 = rt;       /* pretend we were aimed at source */
                rt1.crtype |= rt1.rtype = SHADOW;
                rt1.rdir[0] = -rt.rdir[0];
                rt1.rdir[1] = -rt.rdir[1];
                rt1.rdir[2] = -rt.rdir[2];
                rt1.rod = -rt.rod;
                VSUB(rt1.rorg, rt.rop, rt.rdir);
                rt1.rot = 1.;
                rt1.rsrc = sn;
                                        /* record blocker */
                if (srcblocker(&rt1))
                        return(1);
                                        /* move past failed blocker */
                VSUM(rt.rorg, rt.rop, rt.rdir, FTINY);
                rayclear(&rt);          /* & try again... */
        }
        return(0);                      /* found no blockers */
}


void                                    /* initialize occlusion cache */
initobscache(int sn)
{
        register SRCREC *srcp = &source[sn];
        int             cachelen;
        FVECT           rorg, rdir;
        RREAL           d;
        int             i, j, k;
        int             ax, ax1, ax2;

        if (srcp->sflags & (SSKIP|SPROX|SSPOT|SVIRTUAL))
                return;                 /* don't cache these */
        if (srcp->sflags & SDISTANT)
                cachelen = 4*SHADCACHE*SHADCACHE;
        else if (srcp->sflags & SFLAT)
                cachelen = SHADCACHE*SHADCACHE*3 + (SHADCACHE&1)*SHADCACHE*4;
        else /* spherical distribution */
                cachelen = SHADCACHE*SHADCACHE*6;
                                        /* allocate cache */
        srcp->obscache = (OBSCACHE *)malloc(sizeof(OBSCACHE) +
                                                sizeof(OBJECT)*(cachelen-1));
        if (srcp->obscache == NULL)
                error(SYSTEM, "out of memory in initobscache()");
                                        /* set parameters */
        if (srcp->sflags & SDISTANT) {
                RREAL   amax = 0;
                for (ax1 = 3; ax1--; )
                        if (ABS(srcp->sloc[ax1]) > amax) {
                                amax = ABS(srcp->sloc[ax1]);
                                ax = ax1;
                        }
                srcp->obscache->p.d.ax = ax;
                ax1 = (ax+1)%3;
                ax2 = (ax+2)%3;
                VCOPY(srcp->obscache->p.d.o, thescene.cuorg);
                if (srcp->sloc[ax] > 0)
                        srcp->obscache->p.d.o[ax] += thescene.cusize;
                if (srcp->sloc[ax1] < 0)
                        srcp->obscache->p.d.o[ax1] += thescene.cusize *
                                        srcp->sloc[ax1] / amax;
                if (srcp->sloc[ax2] < 0)
                        srcp->obscache->p.d.o[ax2] += thescene.cusize *
                                        srcp->sloc[ax2] / amax;
                srcp->obscache->p.d.e1 = 1. / (thescene.cusize*(1. +
                                fabs(srcp->sloc[ax1])/amax));
                srcp->obscache->p.d.e2 = 1. / (thescene.cusize*(1. +
                                fabs(srcp->sloc[ax2])/amax));
        } else if (srcp->sflags & SFLAT) {
                VCOPY(srcp->obscache->p.f.u, srcp->ss[SU]);
                normalize(srcp->obscache->p.f.u);
                fcross(srcp->obscache->p.f.v,
                                srcp->snorm, srcp->obscache->p.f.u);
        }
                                        /* clear cache */
        for (i = cachelen; i--; )
                srcp->obscache->obs[i] = OVOID;
                                        /* cast shadow rays */
        if (srcp->sflags & SDISTANT) {
                for (k = 3; k--; )
                        rdir[k] = -srcp->sloc[k];
                for (i = 2*SHADCACHE; i--; )
                        for (j = 2*SHADCACHE; j--; ) {
                                VCOPY(rorg, srcp->obscache->p.d.o);
                                rorg[ax1] += (i+.5) /
                                        (2*SHADCACHE*srcp->obscache->p.d.e1);
                                rorg[ax2] += (j+.5) /
                                        (2*SHADCACHE*srcp->obscache->p.d.e2);
                                castshadow(sn, rorg, rdir);
                        }
        } else if (srcp->sflags & SFLAT) {
                d = 0.01*srcp->srad;
                VSUM(rorg, srcp->sloc, srcp->snorm, d);
                for (i = SHADCACHE; i--; )
                        for (j = SHADCACHE; j--; ) {
                                d = 2./SHADCACHE*(i+.5) - 1.;
                                VSUM(rdir, srcp->snorm,
                                                srcp->obscache->p.f.u, d);
                                d = 2./SHADCACHE*(j+.5) - 1.;
                                VSUM(rdir, rdir, srcp->obscache->p.f.v, d);
                                normalize(rdir);
                                castshadow(sn, rorg, rdir);
                        }
                for (k = 2; k--; )
                    for (i = SHADCACHE; i--; )
                        for (j = SHADCACHE>>1; j--; ) {
                                d = 2./SHADCACHE*(i+.5) - 1.;
                                if (k)
                                        VSUM(rdir, srcp->obscache->p.f.u,
                                                srcp->obscache->p.f.v, d);
                                else
                                        VSUM(rdir, srcp->obscache->p.f.v,
                                                srcp->obscache->p.f.u, d);
                                d = 1. - 2./SHADCACHE*(j+.5);
                                VSUM(rdir, rdir, srcp->snorm, d);
                                normalize(rdir);
                                castshadow(sn, rorg, rdir);
                                d = 2.*DOT(rdir, srcp->snorm);
                                rdir[0] = d*srcp->snorm[0] - rdir[0];
                                rdir[1] = d*srcp->snorm[1] - rdir[1];
                                rdir[2] = d*srcp->snorm[2] - rdir[2];
                                castshadow(sn, rorg, rdir);
                        }
        } else /* spherical distribution */
            for (k = 6; k--; ) {
                ax = k%3;
                ax1 = (k+1)%3;
                ax2 = (k+2)%3;
                for (i = SHADCACHE; i--; )
                        for (j = SHADCACHE; j--; ) {
                                rdir[0]=rdir[1]=rdir[2] = 0.;
                                rdir[ax] = k<3 ? 1. : -1.;
                                rdir[ax1] = 2./SHADCACHE*(i+.5) - 1.;
                                rdir[ax2] = 2./SHADCACHE*(j+.5) - 1.;
                                normalize(rdir);
                                d = 1.05*srcp->srad;
                                VSUM(rorg, srcp->sloc, rdir, d);
                                castshadow(sn, rorg, rdir);
                        }
            }
}


static OBJECT *                 /* return occluder cache entry */
srcobstructp(register RAY *r)
{
        static RNUMBER  lastrno = ~0;
        static OBJECT   noobs;
        static OBJECT   *lastobjp;
        SRCREC          *srcp;
        int             ondx;

        noobs = OVOID;
        if (r->rno == lastrno)
                return lastobjp;        /* just recall last pointer */
        DCHECK(r->rsrc < 0, CONSISTENCY,
                        "srcobstructp() called with unaimed ray");
        lastrno = r->rno;
        lastobjp = &noobs;
        srcp = &source[r->rsrc];
        if (srcp->sflags & (SSKIP|SPROX|SSPOT|SVIRTUAL))
                return(&noobs);         /* don't cache these */
        if (srcp->obscache == NULL)     /* initialize cache */
                initobscache(r->rsrc);
                                        /* compute cache index */
        if (srcp->sflags & SDISTANT) {
                int     ax, ax1, ax2;
                double  t;
                ax = srcp->obscache->p.d.ax;
                if ((ax1 = ax+1) >= 3) ax1 -= 3;
                if ((ax2 = ax+2) >= 3) ax2 -= 3;
                t = (srcp->obscache->p.d.o[ax] - r->rorg[ax]) / srcp->sloc[ax];
                if (t <= FTINY)
                        return(&noobs); /* could happen if ray is outside */
                ondx = 2*SHADCACHE*(int)(2*SHADCACHE*srcp->obscache->p.d.e1 *
                                (r->rorg[ax1] + t*srcp->sloc[ax1] -
                                        srcp->obscache->p.d.o[ax1]));
                ondx += (int)(2*SHADCACHE*srcp->obscache->p.d.e2 *
                                (r->rorg[ax2] + t*srcp->sloc[ax2] -
                                        srcp->obscache->p.d.o[ax2]));
                if ((ondx < 0) | (ondx >= 4*SHADCACHE*SHADCACHE))
                        return(&noobs); /* could happen if ray is outside */
        } else if (srcp->sflags & SFLAT) {
                FVECT   sd;
                RREAL   sd0m, sd1m;
                sd[0] = -DOT(r->rdir, srcp->obscache->p.f.u);
                sd[1] = -DOT(r->rdir, srcp->obscache->p.f.v);
                sd[2] = -DOT(r->rdir, srcp->snorm);
                if (sd[2] < 0)
                        return(&noobs); /* shouldn't happen */
                sd0m = ABS(sd[0]);
                sd1m = ABS(sd[1]);
                if (sd[2] >= sd0m && sd[2] >= sd1m) {
                        ondx = SHADCACHE*(int)(SHADCACHE*(.5-FTINY) *
                                        (1. + sd[0]/sd[2]));
                        ondx += (int)(SHADCACHE*(.5-FTINY) *
                                        (1. + sd[1]/sd[2]));
                } else if (sd0m >= sd1m) {
                        ondx = SHADCACHE*SHADCACHE;
                        if (sd[0] < 0)
                                ondx += ((SHADCACHE+1)>>1)*SHADCACHE;
                        ondx += SHADCACHE*(int)(SHADCACHE*(.5-FTINY) *
                                        (1. - sd[2]/sd0m));
                        ondx += (int)(SHADCACHE*(.5-FTINY) *
                                        (1. + sd[1]/sd0m));
                } else /* sd1m > sd0m */ {
                        ondx = SHADCACHE*SHADCACHE +
                                        ((SHADCACHE+1)>>1)*SHADCACHE*2;
                        if (sd[1] < 0)
                                ondx += ((SHADCACHE+1)>>1)*SHADCACHE;
                        ondx += SHADCACHE*(int)(SHADCACHE*(.5-FTINY) *
                                        (1. - sd[2]/sd1m));
                        ondx += (int)(SHADCACHE*(.5-FTINY) *
                                        (1. + sd[0]/sd1m));
                }
                DCHECK((ondx < 0) | (ondx >= SHADCACHE*SHADCACHE*3 +
                                (SHADCACHE&1)*SHADCACHE*4), CONSISTENCY,
                                "flat source cache index out of bounds");
        } else /* spherical distribution */ {
                int     ax, ax1, ax2;
                RREAL   amax = 0;
                for (ax1 = 3; ax1--; )
                        if (ABS(r->rdir[ax1]) > amax) {
                                amax = ABS(r->rdir[ax1]);
                                ax = ax1;
                        }
                if ((ax1 = ax+1) >= 3) ax1 -= 3;
                if ((ax2 = ax+2) >= 3) ax2 -= 3;
                ondx = 2*SHADCACHE*SHADCACHE * ax;
                if (r->rdir[ax] < 0)
                        ondx += SHADCACHE*SHADCACHE;
                ondx += SHADCACHE*(int)(SHADCACHE*(.5-FTINY) *
                                        (1. + r->rdir[ax1]/amax));
                ondx += (int)(SHADCACHE*(.5-FTINY) *
                                (1. + r->rdir[ax2]/amax));
                DCHECK((ondx < 0) | (ondx >= SHADCACHE*SHADCACHE*6), CONSISTENCY,
                                "radial source cache index out of bounds");
        }
                                        /* return cache pointer */
        return(lastobjp = &srcp->obscache->obs[ondx]);
}


void                            /* free obstruction cache */
freeobscache(SRCREC *srcp)
{
        if (srcp->obscache == NULL)
                return;
        free((void *)srcp->obscache);
        srcp->obscache = NULL;
}

        
int                             /* record a source blocker */
srcblocker(register RAY *r)
{
        OBJREC  *m;

        if (r->robj == OVOID || objptr(r->robj) != r->ro ||
                        isvolume(r->ro->otype))
                return(0);              /* don't record complex blockers */
        if (r->rsrc < 0 || source[r->rsrc].so == r->ro)
                return(0);              /* just a mistake, that's all */
        if (antimodlist != NULL && inset(antimodlist, r->ro->omod))
                return(0);              /* could be clipped */
        m = findmaterial(r->ro);
        if (m == NULL)
                return(0);              /* no material?! */
        if (!isopaque(m->otype))
                return(0);              /* material not a reliable blocker */
        *srcobstructp(r) = r->robj;     /* else record obstructor */
        return(1);
}


int                             /* check ray against cached blocker */
srcblocked(RAY *r)
{
        OBJECT  obs = *srcobstructp(r);
        OBJREC  *op;

        if (obs == OVOID)
                return(0);
        op = objptr(obs);               /* check blocker intersection */
        if (!(*ofun[op->otype].funp)(op, r))
                return(0);
        if (source[r->rsrc].sflags & SDISTANT)
                return(1);
        op = source[r->rsrc].so;        /* check source intersection */
        if (!(*ofun[op->otype].funp)(op, r))
                return(1);
        rayclear(r);
        return(0);                      /* source in front */
}


void                            /* record potentially clipped materials */
markclip(OBJREC *m)
{
        OBJECT  *set2add, *oldset;

        if (m == NULL) {                /* starting over */
                if (antimodlist != NULL)
                        free((void *)antimodlist);
                antimodlist = NULL;
                return;
        }
        m_clip(m, NULL);                /* initialize modifier list */
        if ((set2add = (OBJECT *)m->os) == NULL || !set2add[0])
                return;

        if (antimodlist == NULL) {      /* start of list */
                antimodlist = setsave(set2add);
                return;
        }
                                        /* else add to previous list */
        oldset = antimodlist;
        antimodlist = (OBJECT *)malloc((oldset[0]+set2add[0]+1)*sizeof(OBJECT));
        if (antimodlist == NULL)
                error(SYSTEM, "out of memory in markclip");
        setunion(antimodlist, oldset, set2add);
        free((void *)oldset);
}


#else   /* SHADCACHE */


void                            /* no-op also avoids linker warning */
markclip(OBJREC *m)
{
        (void)m;
}


#endif  /* SHADCACHE */
Revision:	2.16
Committed:	Mon Feb 14 20:13:38 2011 UTC (14 years, 8 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad4R1
Changes since 2.15:	+7 -1 lines
Log Message:	Added clearing of clipped object (antimatter) when sources freed
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: srcobstr.c,v 2.15 2009/12/12 00:03:42 greg Exp $";
3	#endif
4	/*
5	* Source occlusion caching routines
6	*/
7
8	#include "ray.h"
9
10	#include "otypes.h"
11
12	#include "otspecial.h"
13
14	#include "rtotypes.h"
15
16	#include "source.h"
17
18	#define ABS(x) ((x)>0 ? (x) : -(x))
19
20
21	#if SHADCACHE /* preemptive shadow checking */
22
23
24	OBJECT * antimodlist = NULL; /* set of clipped materials */
25
26
27	static int /* cast source ray to first blocker */
28	castshadow(int sn, FVECT rorg, FVECT rdir)
29	{
30	RAY rt;
31
32	VCOPY(rt.rorg, rorg);
33	VCOPY(rt.rdir, rdir);
34	rt.rmax = 0;
35	rayorigin(&rt, PRIMARY, NULL, NULL);
36	/* check for intersection */
37	while (localhit(&rt, &thescene)) {
38	RAY rt1 = rt; /* pretend we were aimed at source */
39	rt1.crtype \|= rt1.rtype = SHADOW;
40	rt1.rdir[0] = -rt.rdir[0];
41	rt1.rdir[1] = -rt.rdir[1];
42	rt1.rdir[2] = -rt.rdir[2];
43	rt1.rod = -rt.rod;
44	VSUB(rt1.rorg, rt.rop, rt.rdir);
45	rt1.rot = 1.;
46	rt1.rsrc = sn;
47	/* record blocker */
48	if (srcblocker(&rt1))
49	return(1);
50	/* move past failed blocker */
51	VSUM(rt.rorg, rt.rop, rt.rdir, FTINY);
52	rayclear(&rt); /* & try again... */
53	}
54	return(0); /* found no blockers */
55	}
56
57
58	void /* initialize occlusion cache */
59	initobscache(int sn)
60	{
61	register SRCREC *srcp = &source[sn];
62	int cachelen;
63	FVECT rorg, rdir;
64	RREAL d;
65	int i, j, k;
66	int ax, ax1, ax2;
67
68	if (srcp->sflags & (SSKIP\|SPROX\|SSPOT\|SVIRTUAL))
69	return; /* don't cache these */
70	if (srcp->sflags & SDISTANT)
71	cachelen = 4SHADCACHESHADCACHE;
72	else if (srcp->sflags & SFLAT)
73	cachelen = SHADCACHESHADCACHE3 + (SHADCACHE&1)SHADCACHE4;
74	else /* spherical distribution */
75	cachelen = SHADCACHESHADCACHE6;
76	/* allocate cache */
77	srcp->obscache = (OBSCACHE *)malloc(sizeof(OBSCACHE) +
78	sizeof(OBJECT)*(cachelen-1));
79	if (srcp->obscache == NULL)
80	error(SYSTEM, "out of memory in initobscache()");
81	/* set parameters */
82	if (srcp->sflags & SDISTANT) {
83	RREAL amax = 0;
84	for (ax1 = 3; ax1--; )
85	if (ABS(srcp->sloc[ax1]) > amax) {
86	amax = ABS(srcp->sloc[ax1]);
87	ax = ax1;
88	}
89	srcp->obscache->p.d.ax = ax;
90	ax1 = (ax+1)%3;
91	ax2 = (ax+2)%3;
92	VCOPY(srcp->obscache->p.d.o, thescene.cuorg);
93	if (srcp->sloc[ax] > 0)
94	srcp->obscache->p.d.o[ax] += thescene.cusize;
95	if (srcp->sloc[ax1] < 0)
96	srcp->obscache->p.d.o[ax1] += thescene.cusize *
97	srcp->sloc[ax1] / amax;
98	if (srcp->sloc[ax2] < 0)
99	srcp->obscache->p.d.o[ax2] += thescene.cusize *
100	srcp->sloc[ax2] / amax;
101	srcp->obscache->p.d.e1 = 1. / (thescene.cusize*(1. +
102	fabs(srcp->sloc[ax1])/amax));
103	srcp->obscache->p.d.e2 = 1. / (thescene.cusize*(1. +
104	fabs(srcp->sloc[ax2])/amax));
105	} else if (srcp->sflags & SFLAT) {
106	VCOPY(srcp->obscache->p.f.u, srcp->ss[SU]);
107	normalize(srcp->obscache->p.f.u);
108	fcross(srcp->obscache->p.f.v,
109	srcp->snorm, srcp->obscache->p.f.u);
110	}
111	/* clear cache */
112	for (i = cachelen; i--; )
113	srcp->obscache->obs[i] = OVOID;
114	/* cast shadow rays */
115	if (srcp->sflags & SDISTANT) {
116	for (k = 3; k--; )
117	rdir[k] = -srcp->sloc[k];
118	for (i = 2*SHADCACHE; i--; )
119	for (j = 2*SHADCACHE; j--; ) {
120	VCOPY(rorg, srcp->obscache->p.d.o);
121	rorg[ax1] += (i+.5) /
122	(2SHADCACHEsrcp->obscache->p.d.e1);
123	rorg[ax2] += (j+.5) /
124	(2SHADCACHEsrcp->obscache->p.d.e2);
125	castshadow(sn, rorg, rdir);
126	}
127	} else if (srcp->sflags & SFLAT) {
128	d = 0.01*srcp->srad;
129	VSUM(rorg, srcp->sloc, srcp->snorm, d);
130	for (i = SHADCACHE; i--; )
131	for (j = SHADCACHE; j--; ) {
132	d = 2./SHADCACHE*(i+.5) - 1.;
133	VSUM(rdir, srcp->snorm,
134	srcp->obscache->p.f.u, d);
135	d = 2./SHADCACHE*(j+.5) - 1.;
136	VSUM(rdir, rdir, srcp->obscache->p.f.v, d);
137	normalize(rdir);
138	castshadow(sn, rorg, rdir);
139	}
140	for (k = 2; k--; )
141	for (i = SHADCACHE; i--; )
142	for (j = SHADCACHE>>1; j--; ) {
143	d = 2./SHADCACHE*(i+.5) - 1.;
144	if (k)
145	VSUM(rdir, srcp->obscache->p.f.u,
146	srcp->obscache->p.f.v, d);
147	else
148	VSUM(rdir, srcp->obscache->p.f.v,
149	srcp->obscache->p.f.u, d);
150	d = 1. - 2./SHADCACHE*(j+.5);
151	VSUM(rdir, rdir, srcp->snorm, d);
152	normalize(rdir);
153	castshadow(sn, rorg, rdir);
154	d = 2.*DOT(rdir, srcp->snorm);
155	rdir[0] = d*srcp->snorm[0] - rdir[0];
156	rdir[1] = d*srcp->snorm[1] - rdir[1];
157	rdir[2] = d*srcp->snorm[2] - rdir[2];
158	castshadow(sn, rorg, rdir);
159	}
160	} else /* spherical distribution */
161	for (k = 6; k--; ) {
162	ax = k%3;
163	ax1 = (k+1)%3;
164	ax2 = (k+2)%3;
165	for (i = SHADCACHE; i--; )
166	for (j = SHADCACHE; j--; ) {
167	rdir[0]=rdir[1]=rdir[2] = 0.;
168	rdir[ax] = k<3 ? 1. : -1.;
169	rdir[ax1] = 2./SHADCACHE*(i+.5) - 1.;
170	rdir[ax2] = 2./SHADCACHE*(j+.5) - 1.;
171	normalize(rdir);
172	d = 1.05*srcp->srad;
173	VSUM(rorg, srcp->sloc, rdir, d);
174	castshadow(sn, rorg, rdir);
175	}
176	}
177	}
178
179
180	static OBJECT * /* return occluder cache entry */
181	srcobstructp(register RAY *r)
182	{
183	static RNUMBER lastrno = ~0;
184	static OBJECT noobs;
185	static OBJECT *lastobjp;
186	SRCREC *srcp;
187	int ondx;
188
189	noobs = OVOID;
190	if (r->rno == lastrno)
191	return lastobjp; /* just recall last pointer */
192	DCHECK(r->rsrc < 0, CONSISTENCY,
193	"srcobstructp() called with unaimed ray");
194	lastrno = r->rno;
195	lastobjp = &noobs;
196	srcp = &source[r->rsrc];
197	if (srcp->sflags & (SSKIP\|SPROX\|SSPOT\|SVIRTUAL))
198	return(&noobs); /* don't cache these */
199	if (srcp->obscache == NULL) /* initialize cache */
200	initobscache(r->rsrc);
201	/* compute cache index */
202	if (srcp->sflags & SDISTANT) {
203	int ax, ax1, ax2;
204	double t;
205	ax = srcp->obscache->p.d.ax;
206	if ((ax1 = ax+1) >= 3) ax1 -= 3;
207	if ((ax2 = ax+2) >= 3) ax2 -= 3;
208	t = (srcp->obscache->p.d.o[ax] - r->rorg[ax]) / srcp->sloc[ax];
209	if (t <= FTINY)
210	return(&noobs); /* could happen if ray is outside */
211	ondx = 2SHADCACHE(int)(2SHADCACHEsrcp->obscache->p.d.e1 *
212	(r->rorg[ax1] + t*srcp->sloc[ax1] -
213	srcp->obscache->p.d.o[ax1]));
214	ondx += (int)(2SHADCACHEsrcp->obscache->p.d.e2 *
215	(r->rorg[ax2] + t*srcp->sloc[ax2] -
216	srcp->obscache->p.d.o[ax2]));
217	if ((ondx < 0) \| (ondx >= 4SHADCACHESHADCACHE))
218	return(&noobs); /* could happen if ray is outside */
219	} else if (srcp->sflags & SFLAT) {
220	FVECT sd;
221	RREAL sd0m, sd1m;
222	sd[0] = -DOT(r->rdir, srcp->obscache->p.f.u);
223	sd[1] = -DOT(r->rdir, srcp->obscache->p.f.v);
224	sd[2] = -DOT(r->rdir, srcp->snorm);
225	if (sd[2] < 0)
226	return(&noobs); /* shouldn't happen */
227	sd0m = ABS(sd[0]);
228	sd1m = ABS(sd[1]);
229	if (sd[2] >= sd0m && sd[2] >= sd1m) {
230	ondx = SHADCACHE(int)(SHADCACHE(.5-FTINY) *
231	(1. + sd[0]/sd[2]));
232	ondx += (int)(SHADCACHE(.5-FTINY)
233	(1. + sd[1]/sd[2]));
234	} else if (sd0m >= sd1m) {
235	ondx = SHADCACHE*SHADCACHE;
236	if (sd[0] < 0)
237	ondx += ((SHADCACHE+1)>>1)*SHADCACHE;
238	ondx += SHADCACHE(int)(SHADCACHE(.5-FTINY) *
239	(1. - sd[2]/sd0m));
240	ondx += (int)(SHADCACHE(.5-FTINY)
241	(1. + sd[1]/sd0m));
242	} else /* sd1m > sd0m */ {
243	ondx = SHADCACHE*SHADCACHE +
244	((SHADCACHE+1)>>1)SHADCACHE2;
245	if (sd[1] < 0)
246	ondx += ((SHADCACHE+1)>>1)*SHADCACHE;
247	ondx += SHADCACHE(int)(SHADCACHE(.5-FTINY) *
248	(1. - sd[2]/sd1m));
249	ondx += (int)(SHADCACHE(.5-FTINY)
250	(1. + sd[0]/sd1m));
251	}
252	DCHECK((ondx < 0) \| (ondx >= SHADCACHESHADCACHE3 +
253	(SHADCACHE&1)SHADCACHE4), CONSISTENCY,
254	"flat source cache index out of bounds");
255	} else /* spherical distribution */ {
256	int ax, ax1, ax2;
257	RREAL amax = 0;
258	for (ax1 = 3; ax1--; )
259	if (ABS(r->rdir[ax1]) > amax) {
260	amax = ABS(r->rdir[ax1]);
261	ax = ax1;
262	}
263	if ((ax1 = ax+1) >= 3) ax1 -= 3;
264	if ((ax2 = ax+2) >= 3) ax2 -= 3;
265	ondx = 2SHADCACHESHADCACHE * ax;
266	if (r->rdir[ax] < 0)
267	ondx += SHADCACHE*SHADCACHE;
268	ondx += SHADCACHE(int)(SHADCACHE(.5-FTINY) *
269	(1. + r->rdir[ax1]/amax));
270	ondx += (int)(SHADCACHE(.5-FTINY)
271	(1. + r->rdir[ax2]/amax));
272	DCHECK((ondx < 0) \| (ondx >= SHADCACHESHADCACHE6), CONSISTENCY,
273	"radial source cache index out of bounds");
274	}
275	/* return cache pointer */
276	return(lastobjp = &srcp->obscache->obs[ondx]);
277	}
278
279
280	void /* free obstruction cache */
281	freeobscache(SRCREC *srcp)
282	{
283	if (srcp->obscache == NULL)
284	return;
285	free((void *)srcp->obscache);
286	srcp->obscache = NULL;
287	}
288
289
290	int /* record a source blocker */
291	srcblocker(register RAY *r)
292	{
293	OBJREC *m;
294
295	if (r->robj == OVOID \|\| objptr(r->robj) != r->ro \|\|
296	isvolume(r->ro->otype))
297	return(0); /* don't record complex blockers */
298	if (r->rsrc < 0 \|\| source[r->rsrc].so == r->ro)
299	return(0); /* just a mistake, that's all */
300	if (antimodlist != NULL && inset(antimodlist, r->ro->omod))
301	return(0); /* could be clipped */
302	m = findmaterial(r->ro);
303	if (m == NULL)
304	return(0); /* no material?! */
305	if (!isopaque(m->otype))
306	return(0); /* material not a reliable blocker */
307	srcobstructp(r) = r->robj; / else record obstructor */
308	return(1);
309	}
310
311
312	int /* check ray against cached blocker */
313	srcblocked(RAY *r)
314	{
315	OBJECT obs = *srcobstructp(r);
316	OBJREC *op;
317
318	if (obs == OVOID)
319	return(0);
320	op = objptr(obs); /* check blocker intersection */
321	if (!(*ofun[op->otype].funp)(op, r))
322	return(0);
323	if (source[r->rsrc].sflags & SDISTANT)
324	return(1);
325	op = source[r->rsrc].so; /* check source intersection */
326	if (!(*ofun[op->otype].funp)(op, r))
327	return(1);
328	rayclear(r);
329	return(0); /* source in front */
330	}
331
332
333	void /* record potentially clipped materials */
334	markclip(OBJREC *m)
335	{
336	OBJECT set2add, oldset;
337
338	if (m == NULL) { /* starting over */
339	if (antimodlist != NULL)
340	free((void *)antimodlist);
341	antimodlist = NULL;
342	return;
343	}
344	m_clip(m, NULL); /* initialize modifier list */
345	if ((set2add = (OBJECT *)m->os) == NULL \|\| !set2add[0])
346	return;
347
348	if (antimodlist == NULL) { /* start of list */
349	antimodlist = setsave(set2add);
350	return;
351	}
352	/* else add to previous list */
353	oldset = antimodlist;
354	antimodlist = (OBJECT )malloc((oldset[0]+set2add[0]+1)sizeof(OBJECT));
355	if (antimodlist == NULL)
356	error(SYSTEM, "out of memory in markclip");
357	setunion(antimodlist, oldset, set2add);
358	free((void *)oldset);
359	}
360
361
362	#else /* SHADCACHE */
363
364
365	void /* no-op also avoids linker warning */
366	markclip(OBJREC *m)
367	{
368	(void)m;
369	}
370
371
372	#endif /* SHADCACHE */