src/rt/o_cone.c

#ifndef lint
static const char RCSid[] = "$Id$";
#endif
/*
 *  o_cone.c - routine to determine ray intersection with cones.
 */

#include "copyright.h"

#include  "ray.h"

#include  "otypes.h"

#include  "cone.h"


o_cone(o, r)                    /* intersect ray with cone */
OBJREC  *o;
register RAY  *r;
{
        FVECT  rox, rdx;
        double  a, b, c;
        double  root[2];
        int  nroots, rn;
        register CONE  *co;
        register int  i;

                                                /* get cone structure */
        co = getcone(o, 1);

        /*
         *     To intersect a ray with a cone, we transform the
         *  ray into the cone's normalized space.  This greatly
         *  simplifies the computation.
         *     For a cone or cup, normalization results in the
         *  equation:
         *
         *              x*x + y*y - z*z == 0
         *
         *     For a cylinder or tube, the normalized equation is:
         *
         *              x*x + y*y - r*r == 0
         *
         *     A normalized ring obeys the following set of equations:
         *
         *              z == 0                  &&
         *              x*x + y*y >= r0*r0      &&
         *              x*x + y*y <= r1*r1
         */

                                        /* transform ray */
        multp3(rox, r->rorg, co->tm);
        multv3(rdx, r->rdir, co->tm);
                                        /* compute intersection */

        if (o->otype == OBJ_CONE || o->otype == OBJ_CUP) {

                a = rdx[0]*rdx[0] + rdx[1]*rdx[1] - rdx[2]*rdx[2];
                b = 2.0*(rdx[0]*rox[0] + rdx[1]*rox[1] - rdx[2]*rox[2]);
                c = rox[0]*rox[0] + rox[1]*rox[1] - rox[2]*rox[2];

        } else if (o->otype == OBJ_CYLINDER || o->otype == OBJ_TUBE) {

                a = rdx[0]*rdx[0] + rdx[1]*rdx[1];
                b = 2.0*(rdx[0]*rox[0] + rdx[1]*rox[1]);
                c = rox[0]*rox[0] + rox[1]*rox[1] - CO_R0(co)*CO_R0(co);

        } else { /* OBJ_RING */

                if (rdx[2] <= FTINY && rdx[2] >= -FTINY)
                        return(0);                      /* parallel */
                root[0] = -rox[2]/rdx[2];
                if (root[0] <= FTINY || root[0] >= r->rot)
                        return(0);                      /* distance check */
                b = root[0]*rdx[0] + rox[0];
                c = root[0]*rdx[1] + rox[1];
                a = b*b + c*c;
                if (a < CO_R0(co)*CO_R0(co) || a > CO_R1(co)*CO_R1(co))
                        return(0);                      /* outside radii */
                r->ro = o;
                r->rot = root[0];
                for (i = 0; i < 3; i++)
                        r->rop[i] = r->rorg[i] + r->rdir[i]*r->rot;
                VCOPY(r->ron, co->ad);
                r->rod = -rdx[2];
                r->rox = NULL;
                return(1);                              /* good */
        }
                                        /* roots for cone, cup, cyl., tube */
        nroots = quadratic(root, a, b, c);

        for (rn = 0; rn < nroots; rn++) {       /* check real roots */
                if (root[rn] <= FTINY)
                        continue;               /* too small */
                if (root[rn] >= r->rot)
                        break;                  /* too big */
                                                /* check endpoints */
                for (i = 0; i < 3; i++) {
                        rox[i] = r->rorg[i] + root[rn]*r->rdir[i];
                        rdx[i] = rox[i] - CO_P0(co)[i];
                }
                b = DOT(rdx, co->ad); 
                if (b < 0.0)
                        continue;               /* before p0 */
                if (b > co->al)
                        continue;               /* after p1 */
                r->ro = o;
                r->rot = root[rn];
                VCOPY(r->rop, rox);
                                                /* get normal */
                if (o->otype == OBJ_CYLINDER)
                        a = CO_R0(co);
                else if (o->otype == OBJ_TUBE)
                        a = -CO_R0(co);
                else { /* OBJ_CONE || OBJ_CUP */
                        c = CO_R1(co) - CO_R0(co);
                        a = CO_R0(co) + b*c/co->al;
                        if (o->otype == OBJ_CUP) {
                                c = -c;
                                a = -a;
                        }
                }
                for (i = 0; i < 3; i++)
                        r->ron[i] = (rdx[i] - b*co->ad[i])/a;
                if (o->otype == OBJ_CONE || o->otype == OBJ_CUP)
                        for (i = 0; i < 3; i++)
                                r->ron[i] = (co->al*r->ron[i] - c*co->ad[i])
                                                /co->sl;
                r->rod = -DOT(r->rdir, r->ron);
                r->pert[0] = r->pert[1] = r->pert[2] = 0.0;
                r->uv[0] = r->uv[1] = 0.0;
                r->rox = NULL;
                return(1);                      /* good */
        }
        return(0);
}
Revision:	2.4
Committed:	Tue Mar 11 17:08:55 2003 UTC (21 years, 1 month ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad3R5
Changes since 2.3:	+3 -1 lines
Log Message:	First working version of new "mesh" primitive, obj2mesh converter
#	User	Rev	Content
1	greg	1.1	#ifndef lint
2	greg	2.4	static const char RCSid[] = "$Id$";
3	greg	1.1	#endif
4			/*
5			* o_cone.c - routine to determine ray intersection with cones.
6	greg	2.2	*/
7
8	greg	2.3	#include "copyright.h"
9	greg	1.1
10			#include "ray.h"
11
12			#include "otypes.h"
13
14			#include "cone.h"
15
16
17			o_cone(o, r) /* intersect ray with cone */
18			OBJREC *o;
19			register RAY *r;
20			{
21			FVECT rox, rdx;
22			double a, b, c;
23			double root[2];
24			int nroots, rn;
25			register CONE *co;
26			register int i;
27
28			/* get cone structure */
29			co = getcone(o, 1);
30
31			/*
32			* To intersect a ray with a cone, we transform the
33			* ray into the cone's normalized space. This greatly
34			* simplifies the computation.
35			* For a cone or cup, normalization results in the
36			* equation:
37			*
38			* xx + yy - z*z == 0
39			*
40			* For a cylinder or tube, the normalized equation is:
41			*
42			* xx + yy - r*r == 0
43			*
44			* A normalized ring obeys the following set of equations:
45			*
46			* z == 0 &&
47			* xx + yy >= r0*r0 &&
48			* xx + yy <= r1*r1
49			*/
50
51			/* transform ray */
52			multp3(rox, r->rorg, co->tm);
53			multv3(rdx, r->rdir, co->tm);
54			/* compute intersection */
55
56			if (o->otype == OBJ_CONE \|\| o->otype == OBJ_CUP) {
57
58			a = rdx[0]rdx[0] + rdx[1]rdx[1] - rdx[2]*rdx[2];
59			b = 2.0(rdx[0]rox[0] + rdx[1]rox[1] - rdx[2]rox[2]);
60			c = rox[0]rox[0] + rox[1]rox[1] - rox[2]*rox[2];
61
62			} else if (o->otype == OBJ_CYLINDER \|\| o->otype == OBJ_TUBE) {
63
64			a = rdx[0]rdx[0] + rdx[1]rdx[1];
65			b = 2.0(rdx[0]rox[0] + rdx[1]*rox[1]);
66			c = rox[0]rox[0] + rox[1]rox[1] - CO_R0(co)*CO_R0(co);
67
68			} else { /* OBJ_RING */
69
70			if (rdx[2] <= FTINY && rdx[2] >= -FTINY)
71			return(0); /* parallel */
72			root[0] = -rox[2]/rdx[2];
73			if (root[0] <= FTINY \|\| root[0] >= r->rot)
74			return(0); /* distance check */
75			b = root[0]*rdx[0] + rox[0];
76			c = root[0]*rdx[1] + rox[1];
77			a = bb + cc;
78			if (a < CO_R0(co)CO_R0(co) \|\| a > CO_R1(co)CO_R1(co))
79			return(0); /* outside radii */
80			r->ro = o;
81			r->rot = root[0];
82			for (i = 0; i < 3; i++)
83			r->rop[i] = r->rorg[i] + r->rdir[i]*r->rot;
84			VCOPY(r->ron, co->ad);
85			r->rod = -rdx[2];
86	greg	1.3	r->rox = NULL;
87	greg	1.1	return(1); /* good */
88			}
89			/* roots for cone, cup, cyl., tube */
90			nroots = quadratic(root, a, b, c);
91
92			for (rn = 0; rn < nroots; rn++) { /* check real roots */
93			if (root[rn] <= FTINY)
94			continue; /* too small */
95			if (root[rn] >= r->rot)
96			break; /* too big */
97			/* check endpoints */
98			for (i = 0; i < 3; i++) {
99			rox[i] = r->rorg[i] + root[rn]*r->rdir[i];
100			rdx[i] = rox[i] - CO_P0(co)[i];
101			}
102			b = DOT(rdx, co->ad);
103			if (b < 0.0)
104			continue; /* before p0 */
105			if (b > co->al)
106			continue; /* after p1 */
107			r->ro = o;
108			r->rot = root[rn];
109			VCOPY(r->rop, rox);
110			/* get normal */
111			if (o->otype == OBJ_CYLINDER)
112			a = CO_R0(co);
113			else if (o->otype == OBJ_TUBE)
114			a = -CO_R0(co);
115			else { /* OBJ_CONE \|\| OBJ_CUP */
116			c = CO_R1(co) - CO_R0(co);
117			a = CO_R0(co) + b*c/co->al;
118			if (o->otype == OBJ_CUP) {
119			c = -c;
120			a = -a;
121			}
122			}
123			for (i = 0; i < 3; i++)
124			r->ron[i] = (rdx[i] - b*co->ad[i])/a;
125			if (o->otype == OBJ_CONE \|\| o->otype == OBJ_CUP)
126			for (i = 0; i < 3; i++)
127			r->ron[i] = (co->alr->ron[i] - cco->ad[i])
128			/co->sl;
129			r->rod = -DOT(r->rdir, r->ron);
130	greg	2.4	r->pert[0] = r->pert[1] = r->pert[2] = 0.0;
131			r->uv[0] = r->uv[1] = 0.0;
132	greg	1.3	r->rox = NULL;
133	greg	1.1	return(1); /* good */
134			}
135			return(0);
136			}