src/rt/o_mesh.c

#ifndef lint
static const char RCSid[] = "$Id: o_mesh.c,v 2.6 2003/06/20 00:25:50 greg Exp $";
#endif
/*
 *  Routines for computing ray intersections with meshes.
 *
 *  Intersection with a triangle mesh is based on Segura and Feito's
 *  WSCG 2001 paper, "Algorithms to Test Ray-Triangle Intersection,
 *  Comparative Study."  This method avoids additional storage
 *  requirements, floating divides, and allows some savings by
 *  caching ray-edge comparisons that are otherwise repeated locally
 *  in typical mesh geometries.  (This is our own optimization.)
 *
 *  The code herein is quite similar to that in o_instance.c, the
 *  chief differences being the custom triangle intersection routines
 *  and the fact that an "OBJECT" in the mesh octree is not an index
 *  into the Radiance OBJREC list, but a mesh triangle index.  We still
 *  utilize the standard octree traversal code by setting the hitf
 *  function pointer in the RAY struct to our custom mesh_hit() call.
 */

#include  "copyright.h"

#include  "ray.h"

#include  "mesh.h"

#include  "tmesh.h"


#define  EDGE_CACHE_SIZ         251     /* length of mesh edge cache */

#define  curmi                  (edge_cache.mi)
#define  curmsh                 (curmi->msh)


/* Cache of signed volumes for this ray and this mesh */
struct EdgeCache {
        OBJREC          *o;     /* mesh object */
        MESHINST        *mi;    /* current mesh instance */
        struct EdgeSide {
                int32   v1i, v2i;       /* vertex indices (lowest first) */
                short   signum;         /* signed volume */
        }               cache[EDGE_CACHE_SIZ];
}       edge_cache;


static void
prep_edge_cache(o)              /* get instance and clear edge cache */
OBJREC  *o;
{
                                        /* get mesh instance */
        edge_cache.mi = getmeshinst(edge_cache.o = o, IO_ALL);
                                        /* clear edge cache */
        bzero((void *)edge_cache.cache, sizeof(edge_cache.cache));
}


static int
signed_volume(r, v1, v2)        /* get signed volume for ray and edge */
register RAY    *r;
int32           v1, v2;
{
        int                             reversed = 0;
        register struct EdgeSide        *ecp;
        
        if (v1 > v2) {
                int32   t = v2; v2 = v1; v1 = t;
                reversed = 1;
        }
        ecp = &edge_cache.cache[((v2<<11 ^ v1) & 0x7fffffff) % EDGE_CACHE_SIZ];
        if (ecp->v1i != v1 || ecp->v2i != v2) {
                MESHVERT        tv1, tv2;       /* compute signed volume */
                FVECT           v2d;
                double          vol;
                if (!getmeshvert(&tv1, edge_cache.mi->msh, v1, MT_V) ||
                            !getmeshvert(&tv2, edge_cache.mi->msh, v2, MT_V))
                        objerror(edge_cache.o, INTERNAL,
                                "missing mesh vertex in signed_volume");
                VSUB(v2d, tv2.v, r->rorg);
                vol = (tv1.v[0] - r->rorg[0]) *
                                (v2d[1]*r->rdir[2] - v2d[2]*r->rdir[1]);
                vol += (tv1.v[1] - r->rorg[1]) *
                                (v2d[2]*r->rdir[0] - v2d[0]*r->rdir[2]);
                vol += (tv1.v[2] - r->rorg[2]) *
                                (v2d[0]*r->rdir[1] - v2d[1]*r->rdir[0]);
                if (vol > .0)
                        ecp->signum = 1;
                else if (vol < .0)
                        ecp->signum = -1;
                else
                        ecp->signum = 0;
                ecp->v1i = v1;
                ecp->v2i = v2;
        }
        return(reversed ? -ecp->signum : ecp->signum);
}


static void
mesh_hit(oset, r)               /* intersect ray with mesh triangle(s) */
OBJECT  *oset;
RAY     *r;
{
        int32           tvi[3];
        int             sv1, sv2, sv3;
        MESHVERT        tv[3];
        OBJECT          tmod;
        FVECT           va, vb, nrm;
        double          d;
        int             i;
                                        /* check each triangle */
        for (i = oset[0]; i > 0; i--) {
                if (!getmeshtrivid(tvi, &tmod, curmsh, oset[i]))
                        objerror(edge_cache.o, INTERNAL,
                                "missing triangle vertices in mesh_hit");
                sv1 = signed_volume(r, tvi[0], tvi[1]);
                sv2 = signed_volume(r, tvi[1], tvi[2]);
                sv3 = signed_volume(r, tvi[2], tvi[0]);
                if (sv1 != sv2 || sv2 != sv3)   /* compare volume signs */
                        if (sv1 && sv2 && sv3)
                                continue;
                                                /* compute intersection */
                getmeshvert(&tv[0], curmsh, tvi[0], MT_V);
                getmeshvert(&tv[1], curmsh, tvi[1], MT_V);
                getmeshvert(&tv[2], curmsh, tvi[2], MT_V);
                VSUB(va, tv[0].v, tv[2].v);
                VSUB(vb, tv[1].v, tv[0].v);
                VCROSS(nrm, va, vb);
                d = DOT(r->rdir, nrm);
                if (d == 0.0)
                        continue;               /* ray is tangent */
                VSUB(va, tv[0].v, r->rorg);
                d = DOT(va, nrm) / d;
                if (d <= FTINY || d >= r->rot)
                        continue;               /* not good enough */
                r->robj = oset[i];              /* else record hit */
                r->ro = edge_cache.o;
                r->rot = d;
                VSUM(r->rop, r->rorg, r->rdir, d);
                VCOPY(r->ron, nrm);
                /* normalize(r->ron) called & r->rod set in o_mesh() */
        }
}


int
o_mesh(o, r)                    /* compute ray intersection with a mesh */
OBJREC          *o;
register RAY    *r;
{
        RAY             rcont;
        int             flags;
        MESHVERT        tv[3];
        OBJECT          tmod;
        RREAL           wt[3];
        int             i;
                                        /* get the mesh instance */
        prep_edge_cache(o);
                                        /* copy and transform ray */
        copystruct(&rcont, r);
        multp3(rcont.rorg, r->rorg, curmi->x.b.xfm);
        multv3(rcont.rdir, r->rdir, curmi->x.b.xfm);
        for (i = 0; i < 3; i++)
                rcont.rdir[i] /= curmi->x.b.sca;
        rcont.rmax *= curmi->x.b.sca;
                                        /* clear and trace ray */
        rayclear(&rcont);
        rcont.hitf = mesh_hit;
        if (!localhit(&rcont, &curmi->msh->mcube))
                return(0);                      /* missed */
        if (rcont.rot * curmi->x.f.sca >= r->rot)
                return(0);                      /* not close enough */
                                        /* transform ray back */
        r->rot = rcont.rot * curmi->x.f.sca;
        multp3(r->rop, rcont.rop, curmi->x.f.xfm);
        multv3(r->ron, rcont.ron, curmi->x.f.xfm);
        normalize(r->ron);
        r->rod = -DOT(r->rdir, r->ron);
                                        /* get triangle */
        flags = getmeshtri(tv, &tmod, curmsh, rcont.robj, MT_ALL);
        if (!(flags & MT_V))
                objerror(o, INTERNAL, "missing mesh vertices in o_mesh");
        r->robj = objndx(o);            /* set object and material */
        if (o->omod == OVOID && tmod != OVOID) {
                r->ro = getmeshpseudo(curmsh, tmod);
                r->rox = &curmi->x;
        } else
                r->ro = o;
                                        /* compute barycentric weights */
        if (flags & (MT_N|MT_UV))
                if (get_baryc(wt, rcont.rop, tv[0].v, tv[1].v, tv[2].v) < 0) {
                        objerror(o, WARNING, "bad triangle in o_mesh");
                        flags &= ~(MT_N|MT_UV);
                }
        if (flags & MT_N) {             /* interpolate normal */
                for (i = 0; i < 3; i++)
                        rcont.pert[i] = wt[0]*tv[0].n[i] +
                                        wt[1]*tv[1].n[i] +
                                        wt[2]*tv[2].n[i];
                multv3(r->pert, rcont.pert, curmi->x.f.xfm);
                if (normalize(r->pert) != 0.0)
                        for (i = 0; i < 3; i++)
                                r->pert[i] -= r->ron[i];
        } else
                r->pert[0] = r->pert[1] = r->pert[2] = .0;

        if (flags & MT_UV)              /* interpolate uv coordinates */
                for (i = 0; i < 2; i++)
                        r->uv[i] = wt[0]*tv[0].uv[i] +
                                        wt[1]*tv[1].uv[i] +
                                        wt[2]*tv[2].uv[i];
        else
                r->uv[0] = r->uv[1] = .0;

                                        /* return hit */
        return(1);
}
Revision:	2.7
Committed:	Thu Jun 26 00:58:10 2003 UTC (20 years, 10 months ago) by schorsch
Content type:	text/plain
Branch:	MAIN
Changes since 2.6:	+2 -2 lines
Log Message:	Abstracted process and path handling for Windows. Renamed FLOAT to RREAL because of conflict on Windows. Added conditional compiles for some signal handlers.
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: o_mesh.c,v 2.6 2003/06/20 00:25:50 greg Exp $";
3	#endif
4	/*
5	* Routines for computing ray intersections with meshes.
6	*
7	* Intersection with a triangle mesh is based on Segura and Feito's
8	* WSCG 2001 paper, "Algorithms to Test Ray-Triangle Intersection,
9	* Comparative Study." This method avoids additional storage
10	* requirements, floating divides, and allows some savings by
11	* caching ray-edge comparisons that are otherwise repeated locally
12	* in typical mesh geometries. (This is our own optimization.)
13	*
14	* The code herein is quite similar to that in o_instance.c, the
15	* chief differences being the custom triangle intersection routines
16	* and the fact that an "OBJECT" in the mesh octree is not an index
17	* into the Radiance OBJREC list, but a mesh triangle index. We still
18	* utilize the standard octree traversal code by setting the hitf
19	* function pointer in the RAY struct to our custom mesh_hit() call.
20	*/
21
22	#include "copyright.h"
23
24	#include "ray.h"
25
26	#include "mesh.h"
27
28	#include "tmesh.h"
29
30
31	#define EDGE_CACHE_SIZ 251 /* length of mesh edge cache */
32
33	#define curmi (edge_cache.mi)
34	#define curmsh (curmi->msh)
35
36
37	/* Cache of signed volumes for this ray and this mesh */
38	struct EdgeCache {
39	OBJREC o; / mesh object */
40	MESHINST mi; / current mesh instance */
41	struct EdgeSide {
42	int32 v1i, v2i; /* vertex indices (lowest first) */
43	short signum; /* signed volume */
44	} cache[EDGE_CACHE_SIZ];
45	} edge_cache;
46
47
48	static void
49	prep_edge_cache(o) /* get instance and clear edge cache */
50	OBJREC *o;
51	{
52	/* get mesh instance */
53	edge_cache.mi = getmeshinst(edge_cache.o = o, IO_ALL);
54	/* clear edge cache */
55	bzero((void *)edge_cache.cache, sizeof(edge_cache.cache));
56	}
57
58
59	static int
60	signed_volume(r, v1, v2) /* get signed volume for ray and edge */
61	register RAY *r;
62	int32 v1, v2;
63	{
64	int reversed = 0;
65	register struct EdgeSide *ecp;
66
67	if (v1 > v2) {
68	int32 t = v2; v2 = v1; v1 = t;
69	reversed = 1;
70	}
71	ecp = &edge_cache.cache[((v2<<11 ^ v1) & 0x7fffffff) % EDGE_CACHE_SIZ];
72	if (ecp->v1i != v1 \|\| ecp->v2i != v2) {
73	MESHVERT tv1, tv2; /* compute signed volume */
74	FVECT v2d;
75	double vol;
76	if (!getmeshvert(&tv1, edge_cache.mi->msh, v1, MT_V) \|\|
77	!getmeshvert(&tv2, edge_cache.mi->msh, v2, MT_V))
78	objerror(edge_cache.o, INTERNAL,
79	"missing mesh vertex in signed_volume");
80	VSUB(v2d, tv2.v, r->rorg);
81	vol = (tv1.v[0] - r->rorg[0]) *
82	(v2d[1]r->rdir[2] - v2d[2]r->rdir[1]);
83	vol += (tv1.v[1] - r->rorg[1]) *
84	(v2d[2]r->rdir[0] - v2d[0]r->rdir[2]);
85	vol += (tv1.v[2] - r->rorg[2]) *
86	(v2d[0]r->rdir[1] - v2d[1]r->rdir[0]);
87	if (vol > .0)
88	ecp->signum = 1;
89	else if (vol < .0)
90	ecp->signum = -1;
91	else
92	ecp->signum = 0;
93	ecp->v1i = v1;
94	ecp->v2i = v2;
95	}
96	return(reversed ? -ecp->signum : ecp->signum);
97	}
98
99
100	static void
101	mesh_hit(oset, r) /* intersect ray with mesh triangle(s) */
102	OBJECT *oset;
103	RAY *r;
104	{
105	int32 tvi[3];
106	int sv1, sv2, sv3;
107	MESHVERT tv[3];
108	OBJECT tmod;
109	FVECT va, vb, nrm;
110	double d;
111	int i;
112	/* check each triangle */
113	for (i = oset[0]; i > 0; i--) {
114	if (!getmeshtrivid(tvi, &tmod, curmsh, oset[i]))
115	objerror(edge_cache.o, INTERNAL,
116	"missing triangle vertices in mesh_hit");
117	sv1 = signed_volume(r, tvi[0], tvi[1]);
118	sv2 = signed_volume(r, tvi[1], tvi[2]);
119	sv3 = signed_volume(r, tvi[2], tvi[0]);
120	if (sv1 != sv2 \|\| sv2 != sv3) /* compare volume signs */
121	if (sv1 && sv2 && sv3)
122	continue;
123	/* compute intersection */
124	getmeshvert(&tv[0], curmsh, tvi[0], MT_V);
125	getmeshvert(&tv[1], curmsh, tvi[1], MT_V);
126	getmeshvert(&tv[2], curmsh, tvi[2], MT_V);
127	VSUB(va, tv[0].v, tv[2].v);
128	VSUB(vb, tv[1].v, tv[0].v);
129	VCROSS(nrm, va, vb);
130	d = DOT(r->rdir, nrm);
131	if (d == 0.0)
132	continue; /* ray is tangent */
133	VSUB(va, tv[0].v, r->rorg);
134	d = DOT(va, nrm) / d;
135	if (d <= FTINY \|\| d >= r->rot)
136	continue; /* not good enough */
137	r->robj = oset[i]; /* else record hit */
138	r->ro = edge_cache.o;
139	r->rot = d;
140	VSUM(r->rop, r->rorg, r->rdir, d);
141	VCOPY(r->ron, nrm);
142	/* normalize(r->ron) called & r->rod set in o_mesh() */
143	}
144	}
145
146
147	int
148	o_mesh(o, r) /* compute ray intersection with a mesh */
149	OBJREC *o;
150	register RAY *r;
151	{
152	RAY rcont;
153	int flags;
154	MESHVERT tv[3];
155	OBJECT tmod;
156	RREAL wt[3];
157	int i;
158	/* get the mesh instance */
159	prep_edge_cache(o);
160	/* copy and transform ray */
161	copystruct(&rcont, r);
162	multp3(rcont.rorg, r->rorg, curmi->x.b.xfm);
163	multv3(rcont.rdir, r->rdir, curmi->x.b.xfm);
164	for (i = 0; i < 3; i++)
165	rcont.rdir[i] /= curmi->x.b.sca;
166	rcont.rmax *= curmi->x.b.sca;
167	/* clear and trace ray */
168	rayclear(&rcont);
169	rcont.hitf = mesh_hit;
170	if (!localhit(&rcont, &curmi->msh->mcube))
171	return(0); /* missed */
172	if (rcont.rot * curmi->x.f.sca >= r->rot)
173	return(0); /* not close enough */
174	/* transform ray back */
175	r->rot = rcont.rot * curmi->x.f.sca;
176	multp3(r->rop, rcont.rop, curmi->x.f.xfm);
177	multv3(r->ron, rcont.ron, curmi->x.f.xfm);
178	normalize(r->ron);
179	r->rod = -DOT(r->rdir, r->ron);
180	/* get triangle */
181	flags = getmeshtri(tv, &tmod, curmsh, rcont.robj, MT_ALL);
182	if (!(flags & MT_V))
183	objerror(o, INTERNAL, "missing mesh vertices in o_mesh");
184	r->robj = objndx(o); /* set object and material */
185	if (o->omod == OVOID && tmod != OVOID) {
186	r->ro = getmeshpseudo(curmsh, tmod);
187	r->rox = &curmi->x;
188	} else
189	r->ro = o;
190	/* compute barycentric weights */
191	if (flags & (MT_N\|MT_UV))
192	if (get_baryc(wt, rcont.rop, tv[0].v, tv[1].v, tv[2].v) < 0) {
193	objerror(o, WARNING, "bad triangle in o_mesh");
194	flags &= ~(MT_N\|MT_UV);
195	}
196	if (flags & MT_N) { /* interpolate normal */
197	for (i = 0; i < 3; i++)
198	rcont.pert[i] = wt[0]*tv[0].n[i] +
199	wt[1]*tv[1].n[i] +
200	wt[2]*tv[2].n[i];
201	multv3(r->pert, rcont.pert, curmi->x.f.xfm);
202	if (normalize(r->pert) != 0.0)
203	for (i = 0; i < 3; i++)
204	r->pert[i] -= r->ron[i];
205	} else
206	r->pert[0] = r->pert[1] = r->pert[2] = .0;
207
208	if (flags & MT_UV) /* interpolate uv coordinates */
209	for (i = 0; i < 2; i++)
210	r->uv[i] = wt[0]*tv[0].uv[i] +
211	wt[1]*tv[1].uv[i] +
212	wt[2]*tv[2].uv[i];
213	else
214	r->uv[0] = r->uv[1] = .0;
215
216	/* return hit */
217	return(1);
218	}