src/common/tmesh.c

#ifndef lint
static const char RCSid[] = "$Id: tmesh.c,v 2.5 2006/03/02 17:16:56 greg Exp $";
#endif
/*
 * Compute and print barycentric coordinates for triangle meshes
 */

#include <stdio.h>
#include "fvect.h"
#include "tmesh.h"


int
flat_tri(                       /* determine if triangle is flat */
        FVECT   v1,
        FVECT   v2,
        FVECT   v3,
        FVECT   n1,
        FVECT   n2,
        FVECT   n3
)
{
        double  d1, d2, d3;
        FVECT   vt1, vt2, vn;
                                        /* compute default normal */
        VSUB(vt1, v2, v1);
        VSUB(vt2, v3, v2);
        VCROSS(vn, vt1, vt2);
        if (normalize(vn) == 0.0)
                return(DEGEN);
                                        /* compare to supplied normals */
        d1 = DOT(vn, n1); d2 = DOT(vn, n2); d3 = DOT(vn, n3);
        if (d1 < 0 && d2 < 0 && d3 < 0) {
                if (d1 > -COSTOL || d2 > -COSTOL || d3 > -COSTOL)
                        return(RVBENT);
                return(RVFLAT);
        }
        if (d1 < COSTOL || d2 < COSTOL || d3 < COSTOL)
                return(ISBENT);
        return(ISFLAT);
}


int
comp_baryc(                     /* compute barycentric vectors */
        BARYCCM *bcm,
        RREAL   *v1,
        RREAL   *v2,
        RREAL   *v3
)
{
        RREAL   *vt;
        FVECT   va, vab, vcb;
        double  d;
        int     ax0, ax1;
        int     i;
                                        /* compute major axis */
        VSUB(vab, v1, v2);
        VSUB(vcb, v3, v2);
        VCROSS(va, vab, vcb);
        bcm->ax = (va[1]*va[1] > va[0]*va[0]);
        if (va[2]*va[2] > va[bcm->ax]*va[bcm->ax]) bcm->ax = 2;
        ax0 = (bcm->ax + 1)%3;
        ax1 = (bcm->ax + 2)%3;
        for (i = 0; i < 2; i++) {
                vab[0] = v1[ax0] - v2[ax0];
                vcb[0] = v3[ax0] - v2[ax0];
                vab[1] = v1[ax1] - v2[ax1];
                vcb[1] = v3[ax1] - v2[ax1];
                d = vcb[0]*vcb[0] + vcb[1]*vcb[1];
                if (d <= FTINY*FTINY)
                        return(-1);
                d = (vcb[0]*vab[0] + vcb[1]*vab[1])/d;
                va[0] = vab[0] - vcb[0]*d;
                va[1] = vab[1] - vcb[1]*d;
                d = va[0]*va[0] + va[1]*va[1];
                if (d <= FTINY*FTINY)
                        return(-1);
                d = 1.0/d;
                bcm->tm[i][0] = va[0] *= d;
                bcm->tm[i][1] = va[1] *= d;
                bcm->tm[i][2] = -(v2[ax0]*va[0] + v2[ax1]*va[1]);
                                        /* rotate vertices */
                vt = v1;
                v1 = v2;
                v2 = v3;
                v3 = vt;
        }
        return(0);
}


void
eval_baryc(                     /* evaluate barycentric weights at p */
        RREAL   wt[3],
        FVECT   p,
        BARYCCM *bcm
)
{
        double  u, v;
        int     i;
        
        if ((i = bcm->ax + 1) >= 3) i -= 3;
        u = p[i];
        if (++i >= 3) i -= 3;
        v = p[i];
        wt[0] = u*bcm->tm[0][0] + v*bcm->tm[0][1] + bcm->tm[0][2];
        wt[1] = u*bcm->tm[1][0] + v*bcm->tm[1][1] + bcm->tm[1][2];
        wt[2] = 1. - wt[1] - wt[0];
}


int
get_baryc(              /* compute barycentric weights at p */
        RREAL   wt[3],
        FVECT   p,
        FVECT   v1,
        FVECT   v2,
        FVECT   v3
)
{
        BARYCCM bcm;
        
        if (comp_baryc(&bcm, v1, v2, v3) < 0)
                return(-1);
        eval_baryc(wt, p, &bcm);
        return(0);
}


#if 0
int
get_baryc(wt, p, v1, v2, v3)    /* compute barycentric weights at p */
RREAL   wt[3];
FVECT   p;
FVECT   v1, v2, v3;
{
        FVECT   ac, bc, pc, cros;
        double  normf;
                                /* area formula w/o 2-D optimization */
        VSUB(ac, v1, v3);
        VSUB(bc, v2, v3);
        VSUB(pc, p, v3);
        VCROSS(cros, ac, bc);
        normf = DOT(cros,cros)
        if (normf <= 0.0)
                return(-1);
        normf = 1./sqrt(normf);
        VCROSS(cros, bc, pc);
        wt[0] = VLEN(cros) * normf;
        VCROSS(cros, ac, pc);
        wt[1] = VLEN(cros) * normf;
        wt[2] = 1. - wt[1] - wt[0];
        return(0);
}
#endif


void
fput_baryc(                     /* put barycentric coord. vectors */
        BARYCCM *bcm,
        RREAL   com[][3],
        int     n,
        FILE    *fp
)
{
        double  a, b;
        int     i;

        fprintf(fp, "%d\t%d\n", 1+3*n, bcm->ax);
        for (i = 0; i < n; i++) {
                a = com[i][0] - com[i][2];
                b = com[i][1] - com[i][2];
                fprintf(fp, "%14.8f %14.8f %14.8f\n",
                        bcm->tm[0][0]*a + bcm->tm[1][0]*b,
                        bcm->tm[0][1]*a + bcm->tm[1][1]*b,
                        bcm->tm[0][2]*a + bcm->tm[1][2]*b + com[i][2]);
        }
}
Revision:	2.6
Committed:	Thu Apr 15 23:51:04 2021 UTC (4 years, 6 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad5R4, rad6R0, HEAD
Changes since 2.5:	+43 -32 lines
Log Message:	feat(genbox,robjutil): Added Radiance normal smoothing support to wfobj library
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: tmesh.c,v 2.5 2006/03/02 17:16:56 greg Exp $";
3	#endif
4	/*
5	* Compute and print barycentric coordinates for triangle meshes
6	*/
7
8	#include <stdio.h>
9	#include "fvect.h"
10	#include "tmesh.h"
11
12
13	int
14	flat_tri( /* determine if triangle is flat */
15	FVECT v1,
16	FVECT v2,
17	FVECT v3,
18	FVECT n1,
19	FVECT n2,
20	FVECT n3
21	)
22	{
23	double d1, d2, d3;
24	FVECT vt1, vt2, vn;
25	/* compute default normal */
26	VSUB(vt1, v2, v1);
27	VSUB(vt2, v3, v2);
28	VCROSS(vn, vt1, vt2);
29	if (normalize(vn) == 0.0)
30	return(DEGEN);
31	/* compare to supplied normals */
32	d1 = DOT(vn, n1); d2 = DOT(vn, n2); d3 = DOT(vn, n3);
33	if (d1 < 0 && d2 < 0 && d3 < 0) {
34	if (d1 > -COSTOL \|\| d2 > -COSTOL \|\| d3 > -COSTOL)
35	return(RVBENT);
36	return(RVFLAT);
37	}
38	if (d1 < COSTOL \|\| d2 < COSTOL \|\| d3 < COSTOL)
39	return(ISBENT);
40	return(ISFLAT);
41	}
42
43
44	int
45	comp_baryc( /* compute barycentric vectors */
46	BARYCCM *bcm,
47	RREAL *v1,
48	RREAL *v2,
49	RREAL *v3
50	)
51	{
52	RREAL *vt;
53	FVECT va, vab, vcb;
54	double d;
55	int ax0, ax1;
56	int i;
57	/* compute major axis */
58	VSUB(vab, v1, v2);
59	VSUB(vcb, v3, v2);
60	VCROSS(va, vab, vcb);
61	bcm->ax = (va[1]va[1] > va[0]va[0]);
62	if (va[2]va[2] > va[bcm->ax]va[bcm->ax]) bcm->ax = 2;
63	ax0 = (bcm->ax + 1)%3;
64	ax1 = (bcm->ax + 2)%3;
65	for (i = 0; i < 2; i++) {
66	vab[0] = v1[ax0] - v2[ax0];
67	vcb[0] = v3[ax0] - v2[ax0];
68	vab[1] = v1[ax1] - v2[ax1];
69	vcb[1] = v3[ax1] - v2[ax1];
70	d = vcb[0]vcb[0] + vcb[1]vcb[1];
71	if (d <= FTINY*FTINY)
72	return(-1);
73	d = (vcb[0]vab[0] + vcb[1]vab[1])/d;
74	va[0] = vab[0] - vcb[0]*d;
75	va[1] = vab[1] - vcb[1]*d;
76	d = va[0]va[0] + va[1]va[1];
77	if (d <= FTINY*FTINY)
78	return(-1);
79	d = 1.0/d;
80	bcm->tm[i][0] = va[0] *= d;
81	bcm->tm[i][1] = va[1] *= d;
82	bcm->tm[i][2] = -(v2[ax0]va[0] + v2[ax1]va[1]);
83	/* rotate vertices */
84	vt = v1;
85	v1 = v2;
86	v2 = v3;
87	v3 = vt;
88	}
89	return(0);
90	}
91
92
93	void
94	eval_baryc( /* evaluate barycentric weights at p */
95	RREAL wt[3],
96	FVECT p,
97	BARYCCM *bcm
98	)
99	{
100	double u, v;
101	int i;
102
103	if ((i = bcm->ax + 1) >= 3) i -= 3;
104	u = p[i];
105	if (++i >= 3) i -= 3;
106	v = p[i];
107	wt[0] = ubcm->tm[0][0] + vbcm->tm[0][1] + bcm->tm[0][2];
108	wt[1] = ubcm->tm[1][0] + vbcm->tm[1][1] + bcm->tm[1][2];
109	wt[2] = 1. - wt[1] - wt[0];
110	}
111
112
113	int
114	get_baryc( /* compute barycentric weights at p */
115	RREAL wt[3],
116	FVECT p,
117	FVECT v1,
118	FVECT v2,
119	FVECT v3
120	)
121	{
122	BARYCCM bcm;
123
124	if (comp_baryc(&bcm, v1, v2, v3) < 0)
125	return(-1);
126	eval_baryc(wt, p, &bcm);
127	return(0);
128	}
129
130
131	#if 0
132	int
133	get_baryc(wt, p, v1, v2, v3) /* compute barycentric weights at p */
134	RREAL wt[3];
135	FVECT p;
136	FVECT v1, v2, v3;
137	{
138	FVECT ac, bc, pc, cros;
139	double normf;
140	/* area formula w/o 2-D optimization */
141	VSUB(ac, v1, v3);
142	VSUB(bc, v2, v3);
143	VSUB(pc, p, v3);
144	VCROSS(cros, ac, bc);
145	normf = DOT(cros,cros)
146	if (normf <= 0.0)
147	return(-1);
148	normf = 1./sqrt(normf);
149	VCROSS(cros, bc, pc);
150	wt[0] = VLEN(cros) * normf;
151	VCROSS(cros, ac, pc);
152	wt[1] = VLEN(cros) * normf;
153	wt[2] = 1. - wt[1] - wt[0];
154	return(0);
155	}
156	#endif
157
158
159	void
160	fput_baryc( /* put barycentric coord. vectors */
161	BARYCCM *bcm,
162	RREAL com[][3],
163	int n,
164	FILE *fp
165	)
166	{
167	double a, b;
168	int i;
169
170	fprintf(fp, "%d\t%d\n", 1+3*n, bcm->ax);
171	for (i = 0; i < n; i++) {
172	a = com[i][0] - com[i][2];
173	b = com[i][1] - com[i][2];
174	fprintf(fp, "%14.8f %14.8f %14.8f\n",
175	bcm->tm[0][0]a + bcm->tm[1][0]b,
176	bcm->tm[0][1]a + bcm->tm[1][1]b,
177	bcm->tm[0][2]a + bcm->tm[1][2]b + com[i][2]);
178	}
179	}