src/gen/genprism.c

/* Copyright (c) 1996 Regents of the University of California */

#ifndef lint
static char SCCSid[] = "$SunId$ LBL";
#endif

/*
 *  genprism.c - generate a prism.
 *              2D vertices in the xy plane are given on the
 *              command line or from a file.  Their order together
 *              with the extrude direction will determine surface
 *              orientation.
 */

#include  <stdio.h>

#include  <math.h>

#include  <ctype.h>

#define  MAXVERT        1024            /* maximum # vertices */

#define  FTINY          1e-6

#ifdef  DCL_ATOF
extern double  atof();
#endif

char  *pmtype;          /* material type */
char  *pname;           /* name */

double  lvect[3] = {0.0, 0.0, 1.0};
double  llen = 1.0;

double  vert[MAXVERT][2];
int  nverts = 0;

double  u[MAXVERT][2];          /* edge unit vectors */
double  a[MAXVERT];             /* corner trim sizes */

int  do_ends = 1;               /* include end caps */
int  iscomplete = 0;            /* polygon is already completed */
double  crad = 0.0;             /* radius for corners */

#define rounding        (crad > FTINY)


main(argc, argv)
int  argc;
char  **argv;
{
        int  an;
        
        if (argc < 4)
                goto userr;

        pmtype = argv[1];
        pname = argv[2];

        if (!strcmp(argv[3], "-")) {
                readverts(NULL);
                an = 4;
        } else if (isdigit(argv[3][0])) {
                nverts = atoi(argv[3]);
                if (argc-3 < 2*nverts)
                        goto userr;
                for (an = 0; an < nverts; an++) {
                        vert[an][0] = atof(argv[2*an+4]);
                        vert[an][1] = atof(argv[2*an+5]);
                }
                an = 2*nverts+4;
        } else {
                readverts(argv[3]);
                an = 4;
        }
        if (nverts < 3) {
                fprintf(stderr, "%s: not enough vertices\n", argv[0]);
                exit(1);
        }

        for ( ; an < argc; an++) {
                if (argv[an][0] != '-')
                        goto userr;
                switch (argv[an][1]) {
                case 'l':                               /* length vector */
                        lvect[0] = atof(argv[++an]);
                        lvect[1] = atof(argv[++an]);
                        lvect[2] = atof(argv[++an]);
                        llen = sqrt(lvect[0]*lvect[0] + lvect[1]*lvect[1] +
                                        lvect[2]*lvect[2]);
                        if (llen <= FTINY) {
                                fprintf(stderr, "%s: zero extrusion vector\n",
                                                argv[0]);
                                exit(1);
                        }
                        break;
                case 'r':                               /* radius */
                        crad = atof(argv[++an]);
                        break;
                case 'e':                               /* ends */
                        do_ends = !do_ends;
                        break;
                case 'c':                               /* complete */
                        iscomplete = !iscomplete;
                        break;
                default:
                        goto userr;
                }
        }
        if (rounding) {
                if (crad > fabs(lvect[2])) {
                        fprintf(stderr, "%s: rounding greater than height\n",
                                        argv[0]);
                        exit(1);
                }
                compute_rounding();
        }
        printhead(argc, argv);

        if (do_ends)
                if (rounding)
                        printrends();
                else
                        printends();

        printsides(rounding);

        exit(0);
userr:
        fprintf(stderr, "Usage: %s material name ", argv[0]);
        fprintf(stderr, "{ - | vfile | N v1 v2 .. vN } ");
        fprintf(stderr, "[-l lvect][-r radius][-c][-e]\n");
        exit(1);
}


readverts(fname)                /* read vertices from a file */
char  *fname;
{
        FILE  *fp;

        if (fname == NULL)
                fp = stdin;
        else if ((fp = fopen(fname, "r")) == NULL) {
                fprintf(stderr, "%s: cannot open\n", fname);
                exit(1);
        }
        while (fscanf(fp, "%lf %lf", &vert[nverts][0], &vert[nverts][1]) == 2)
                nverts++;
        fclose(fp);
}


compute_rounding()              /* compute vectors for rounding operations */
{
        register int  i;
        register double *v0, *v1;
        double  l;

        v0 = vert[nverts-1];
        for (i = 0; i < nverts; i++) {          /* compute u[*] */
                v1 = vert[i];
                u[i][0] = v0[0] - v1[0];
                u[i][1] = v0[1] - v1[1];
                l = sqrt(u[i][0]*u[i][0] + u[i][1]*u[i][1]);
                if (l <= FTINY) {
                        fprintf(stderr, "Degenerate side in prism\n");
                        exit(1);
                }
                u[i][0] /= l;
                u[i][1] /= l;
                v0 = v1;
        }
        v1 = u[0];
        for (i = nverts; i--; ) {               /* compute a[*] */
                v0 = u[i];
                l = v0[0]*v1[0] + v0[1]*v1[1];
                if (1+l <= FTINY) {
                        fprintf(stderr, "Overlapping sides in prism\n");
                        exit(1);
                }
                if (1-l <= 0.)
                        a[i] = 0.;
                else {
                        a[i] = sqrt((1-l)/(1+l));
                        if ((v1[0]*v0[1]-v1[1]*v0[0] > 0.) != (lvect[2] > 0.))
                                a[i] = -a[i];
                }
                v1 = v0;
        }
}


printends()                     /* print ends of prism */
{
        register int  i;
                                                /* bottom face */
        printf("\n%s polygon %s.b\n", pmtype, pname);
        printf("0\n0\n%d\n", nverts*3);
        for (i = 0; i < nverts; i++)
                printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[i][0],
                                vert[i][1], 0.0);
                                                /* top face */
        printf("\n%s polygon %s.t\n", pmtype, pname);
        printf("0\n0\n%d\n", nverts*3);
        for (i = nverts; i--; )
                printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[i][0]+lvect[0],
                                vert[i][1]+lvect[1], lvect[2]);
}


printrends()                    /* print ends of prism with rounding */
{
        register int  i;
        double  c0[3], c1[3], cl[3];
                                                /* bottom face */
        printf("\n%s polygon %s.b\n", pmtype, pname);
        printf("0\n0\n%d\n", nverts*3);
        for (i = 0; i < nverts; i++) {
                printf("\t%18.12g\t%18.12g\t%18.12g\n",
                        vert[i][0] + crad*(a[i]*u[i][0] - u[i][1]),
                        vert[i][1] + crad*(a[i]*u[i][1] + u[i][0]),
                        0.0);
        }
                                                /* bottom corners and edges */
        c0[0] = cl[0] = vert[nverts-1][0] +
                        crad*(a[nverts-1]*u[nverts-1][0] - u[nverts-1][1]);
        c0[1] = cl[1] = vert[nverts-1][1] +
                        crad*(a[nverts-1]*u[nverts-1][1] + u[nverts-1][0]);
        c0[2] = cl[2] = crad;
        for (i = 0; i < nverts; i++) {
                if (i < nverts-1) {
                        c1[0] = vert[i][0] + crad*(a[i]*u[i][0] - u[i][1]);
                        c1[1] = vert[i][1] + crad*(a[i]*u[i][1] + u[i][0]);
                        c1[2] = crad;
                } else {
                        c1[0] = cl[0]; c1[1] = cl[1]; c1[2] = cl[2];
                }
                if (a[i] > 0.) {
                        printf("\n%s sphere %s.bc%d\n", pmtype, pname, i+1);
                        printf("0\n0\n4 %18.12g %18.12g %18.12g %18.12g\n",
                                c1[0], c1[1], c1[2], crad);
                }
                printf("\n%s cylinder %s.be%d\n", pmtype, pname, i+1);
                printf("0\n0\n7\n");
                printf("\t%18.12g\t%18.12g\t%18.12g\n", c0[0], c0[1], c0[2]);
                printf("\t%18.12g\t%18.12g\t%18.12g\n", c1[0], c1[1], c1[2]);
                printf("\t%18.12g\n", crad);
                c0[0] = c1[0]; c0[1] = c1[1]; c0[2] = c1[2];
        }
                                                /* top face */
        printf("\n%s polygon %s.t\n", pmtype, pname);
        printf("0\n0\n%d\n", nverts*3);
        for (i = nverts; i--; ) {
                printf("\t%18.12g\t%18.12g\t%18.12g\n",
                vert[i][0] + lvect[0] + crad*(a[i]*u[i][0] - u[i][1]),
                vert[i][1] + lvect[1] + crad*(a[i]*u[i][1] + u[i][0]),
                lvect[2]);
        }
                                                /* top corners and edges */
        c0[0] = cl[0] = vert[nverts-1][0] + lvect[0] +
                        crad*(a[nverts-1]*u[nverts-1][0] - u[nverts-1][1]);
        c0[1] = cl[1] = vert[nverts-1][1] + lvect[1] +
                        crad*(a[nverts-1]*u[nverts-1][1] + u[nverts-1][0]);
        c0[2] = cl[2] = lvect[2] - crad;
        for (i = 0; i < nverts; i++) {
                if (i < nverts-1) {
                        c1[0] = vert[i][0] + lvect[0] +
                                        crad*(a[i]*u[i][0] - u[i][1]);
                        c1[1] = vert[i][1] + lvect[1] +
                                        crad*(a[i]*u[i][1] + u[i][0]);
                        c1[2] = lvect[2] - crad;
                } else {
                        c1[0] = cl[0]; c1[1] = cl[1]; c1[2] = cl[2];
                }
                if (a[i] > 0.) {
                        printf("\n%s sphere %s.tc%d\n", pmtype, pname, i+1);
                        printf("0\n0\n4 %18.12g %18.12g %18.12g %18.12g\n",
                                c1[0], c1[1], c1[2], crad);
                }
                printf("\n%s cylinder %s.te%d\n", pmtype, pname, i+1);
                printf("0\n0\n7\n");
                printf("\t%18.12g\t%18.12g\t%18.12g\n", c0[0], c0[1], c0[2]);
                printf("\t%18.12g\t%18.12g\t%18.12g\n", c1[0], c1[1], c1[2]);
                printf("\t%18.12g\n", crad);
                c0[0] = c1[0]; c0[1] = c1[1]; c0[2] = c1[2];
        }
}


printsides(round)               /* print prism sides */
int  round;
{
        register int  i;

        for (i = 0; i < nverts-1; i++)
                if (round)
                        rside(i, i+1);
                else
                        side(i, i+1);
        if (!iscomplete)
                if (round)
                        rside(nverts-1, 0);
                else
                        side(nverts-1, 0);
}


side(n0, n1)                    /* print single side */
register int  n0, n1;
{
        printf("\n%s polygon %s.%d\n", pmtype, pname, n0+1);
        printf("0\n0\n12\n");
        printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n0][0],
                        vert[n0][1], 0.0);
        printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n0][0]+lvect[0],
                        vert[n0][1]+lvect[1], lvect[2]);
        printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n1][0]+lvect[0],
                        vert[n1][1]+lvect[1], lvect[2]);
        printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n1][0],
                        vert[n1][1], 0.0);
}


rside(n0, n1)                   /* print side with rounded edge */
register int  n0, n1;
{
        double  s, c, t[3];

                                        /* compute tanget offset vector */
        s = (lvect[1]*u[n1][0] - lvect[0]*u[n1][1])/llen;
        if (s < -FTINY || s > FTINY) {
                c = sqrt(1. - s*s);
                t[0] = (c - 1.)*u[n1][1];
                t[1] = (1. - c)*u[n1][0];
                t[2] = s;
        } else
                t[0] = t[1] = t[2] = 0.;
                                        /* output side */
        printf("\n%s polygon %s.%d\n", pmtype, pname, n0+1);
        printf("0\n0\n12\n");
        printf("\t%18.12g\t%18.12g\t%18.12g\n",
                        vert[n0][0] + crad*(t[0] - a[n0]*u[n1][0]),
                        vert[n0][1] + crad*(t[1] - a[n0]*u[n1][1]),
                        crad*(t[2] + 1.));
        printf("\t%18.12g\t%18.12g\t%18.12g\n",
                        vert[n0][0] + lvect[0] + crad*(t[0] - a[n0]*u[n1][0]),
                        vert[n0][1] + lvect[1] + crad*(t[1] - a[n0]*u[n1][1]),
                        lvect[2] + crad*(t[2] - 1.));
        printf("\t%18.12g\t%18.12g\t%18.12g\n",
                        vert[n1][0] + lvect[0] + crad*(t[0] + a[n1]*u[n1][0]),
                        vert[n1][1] + lvect[1] + crad*(t[1] + a[n1]*u[n1][1]),
                        lvect[2] + crad*(t[2] - 1.));
        printf("\t%18.12g\t%18.12g\t%18.12g\n",
                        vert[n1][0] + crad*(t[0] + a[n1]*u[n1][0]),
                        vert[n1][1] + crad*(t[1] + a[n1]*u[n1][1]),
                        crad*(t[2] + 1.));
                                        /* output joining edge */
        if (a[n1] < 0.)
                return;
        printf("\n%s cylinder %s.e%d\n", pmtype, pname, n0+1);
        printf("0\n0\n7\n");
        printf("\t%18.12g\t%18.12g\t%18.12g\n",
                vert[n1][0] + crad*(a[n1]*u[n1][0] - u[n1][1]),
                vert[n1][1] + crad*(a[n1]*u[n1][1] + u[n1][0]),
                crad);
        printf("\t%18.12g\t%18.12g\t%18.12g\n",
                vert[n1][0] + lvect[0] + crad*(a[n1]*u[n1][0] - u[n1][1]),
                vert[n1][1] + lvect[1] + crad*(a[n1]*u[n1][1] + u[n1][0]),
                lvect[2] - crad);
        printf("\t%18.12g\n", crad);
}


printhead(ac, av)               /* print command header */
register int  ac;
register char  **av;
{
        putchar('#');
        while (ac--) {
                putchar(' ');
                fputs(*av++, stdout);
        }
        putchar('\n');
}
Revision:	2.6
Committed:	Tue Mar 19 16:30:56 1996 UTC (29 years, 7 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.5:	+227 -44 lines
Log Message:	added -r option for smoothed edges
#	User	Rev	Content
1	greg	2.6	/* Copyright (c) 1996 Regents of the University of California */
2	greg	1.1
3			#ifndef lint
4			static char SCCSid[] = "$SunId$ LBL";
5			#endif
6
7			/*
8			* genprism.c - generate a prism.
9			* 2D vertices in the xy plane are given on the
10			* command line or from a file. Their order together
11			* with the extrude direction will determine surface
12			* orientation.
13			*/
14
15			#include <stdio.h>
16
17	greg	2.3	#include <math.h>
18
19	greg	1.1	#include <ctype.h>
20
21			#define MAXVERT 1024 /* maximum # vertices */
22	greg	2.2
23	greg	2.6	#define FTINY 1e-6
24
25	greg	2.4	#ifdef DCL_ATOF
26			extern double atof();
27			#endif
28
29	greg	1.1	char pmtype; / material type */
30			char pname; / name */
31
32			double lvect[3] = {0.0, 0.0, 1.0};
33	greg	2.6	double llen = 1.0;
34	greg	1.1
35			double vert[MAXVERT][2];
36			int nverts = 0;
37
38	greg	2.6	double u[MAXVERT][2]; /* edge unit vectors */
39			double a[MAXVERT]; /* corner trim sizes */
40
41	greg	1.1	int do_ends = 1; /* include end caps */
42			int iscomplete = 0; /* polygon is already completed */
43	greg	2.6	double crad = 0.0; /* radius for corners */
44	greg	1.1
45	greg	2.6	#define rounding (crad > FTINY)
46	greg	1.1
47	greg	2.6
48	greg	1.1	main(argc, argv)
49			int argc;
50			char **argv;
51			{
52			int an;
53
54			if (argc < 4)
55			goto userr;
56
57			pmtype = argv[1];
58			pname = argv[2];
59
60			if (!strcmp(argv[3], "-")) {
61			readverts(NULL);
62			an = 4;
63			} else if (isdigit(argv[3][0])) {
64			nverts = atoi(argv[3]);
65			if (argc-3 < 2*nverts)
66			goto userr;
67			for (an = 0; an < nverts; an++) {
68			vert[an][0] = atof(argv[2*an+4]);
69			vert[an][1] = atof(argv[2*an+5]);
70			}
71			an = 2*nverts+4;
72			} else {
73			readverts(argv[3]);
74			an = 4;
75			}
76			if (nverts < 3) {
77			fprintf(stderr, "%s: not enough vertices\n", argv[0]);
78			exit(1);
79			}
80
81			for ( ; an < argc; an++) {
82			if (argv[an][0] != '-')
83			goto userr;
84			switch (argv[an][1]) {
85			case 'l': /* length vector */
86			lvect[0] = atof(argv[++an]);
87			lvect[1] = atof(argv[++an]);
88			lvect[2] = atof(argv[++an]);
89	greg	2.6	llen = sqrt(lvect[0]lvect[0] + lvect[1]lvect[1] +
90			lvect[2]*lvect[2]);
91			if (llen <= FTINY) {
92			fprintf(stderr, "%s: zero extrusion vector\n",
93			argv[0]);
94			exit(1);
95			}
96	greg	1.1	break;
97	greg	2.6	case 'r': /* radius */
98			crad = atof(argv[++an]);
99			break;
100	greg	1.1	case 'e': /* ends */
101			do_ends = !do_ends;
102			break;
103			case 'c': /* complete */
104			iscomplete = !iscomplete;
105			break;
106			default:
107			goto userr;
108			}
109			}
110	greg	2.6	if (rounding) {
111			if (crad > fabs(lvect[2])) {
112			fprintf(stderr, "%s: rounding greater than height\n",
113			argv[0]);
114			exit(1);
115			}
116			compute_rounding();
117			}
118	greg	1.1	printhead(argc, argv);
119
120			if (do_ends)
121	greg	2.6	if (rounding)
122			printrends();
123			else
124			printends();
125	greg	1.1
126	greg	2.6	printsides(rounding);
127
128			exit(0);
129	greg	1.1	userr:
130			fprintf(stderr, "Usage: %s material name ", argv[0]);
131			fprintf(stderr, "{ - \| vfile \| N v1 v2 .. vN } ");
132	greg	2.6	fprintf(stderr, "[-l lvect][-r radius][-c][-e]\n");
133	greg	1.1	exit(1);
134			}
135
136
137			readverts(fname) /* read vertices from a file */
138	greg	1.2	char *fname;
139	greg	1.1	{
140			FILE *fp;
141
142	greg	2.6	if (fname == NULL)
143	greg	1.1	fp = stdin;
144	greg	2.6	else if ((fp = fopen(fname, "r")) == NULL) {
145	greg	1.1	fprintf(stderr, "%s: cannot open\n", fname);
146			exit(1);
147			}
148			while (fscanf(fp, "%lf %lf", &vert[nverts][0], &vert[nverts][1]) == 2)
149	greg	2.6	nverts++;
150			fclose(fp);
151			}
152
153
154			compute_rounding() /* compute vectors for rounding operations */
155			{
156			register int i;
157			register double v0, v1;
158			double l;
159
160			v0 = vert[nverts-1];
161			for (i = 0; i < nverts; i++) { /* compute u[] /
162			v1 = vert[i];
163			u[i][0] = v0[0] - v1[0];
164			u[i][1] = v0[1] - v1[1];
165			l = sqrt(u[i][0]u[i][0] + u[i][1]u[i][1]);
166			if (l <= FTINY) {
167			fprintf(stderr, "Degenerate side in prism\n");
168	greg	2.5	exit(1);
169			}
170	greg	2.6	u[i][0] /= l;
171			u[i][1] /= l;
172			v0 = v1;
173			}
174			v1 = u[0];
175			for (i = nverts; i--; ) { /* compute a[] /
176			v0 = u[i];
177			l = v0[0]v1[0] + v0[1]v1[1];
178			if (1+l <= FTINY) {
179			fprintf(stderr, "Overlapping sides in prism\n");
180			exit(1);
181			}
182			if (1-l <= 0.)
183			a[i] = 0.;
184			else {
185			a[i] = sqrt((1-l)/(1+l));
186			if ((v1[0]v0[1]-v1[1]v0[0] > 0.) != (lvect[2] > 0.))
187			a[i] = -a[i];
188			}
189			v1 = v0;
190			}
191	greg	1.1	}
192
193
194			printends() /* print ends of prism */
195			{
196			register int i;
197	greg	2.6	/* bottom face */
198			printf("\n%s polygon %s.b\n", pmtype, pname);
199			printf("0\n0\n%d\n", nverts*3);
200			for (i = 0; i < nverts; i++)
201			printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[i][0],
202			vert[i][1], 0.0);
203			/* top face */
204			printf("\n%s polygon %s.t\n", pmtype, pname);
205			printf("0\n0\n%d\n", nverts*3);
206			for (i = nverts; i--; )
207			printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[i][0]+lvect[0],
208			vert[i][1]+lvect[1], lvect[2]);
209			}
210	greg	1.1
211	greg	2.6
212			printrends() /* print ends of prism with rounding */
213			{
214			register int i;
215			double c0[3], c1[3], cl[3];
216			/* bottom face */
217	greg	1.1	printf("\n%s polygon %s.b\n", pmtype, pname);
218			printf("0\n0\n%d\n", nverts*3);
219			for (i = 0; i < nverts; i++) {
220			printf("\t%18.12g\t%18.12g\t%18.12g\n",
221	greg	2.6	vert[i][0] + crad(a[i]u[i][0] - u[i][1]),
222			vert[i][1] + crad(a[i]u[i][1] + u[i][0]),
223			0.0);
224	greg	1.1	}
225	greg	2.6	/* bottom corners and edges */
226			c0[0] = cl[0] = vert[nverts-1][0] +
227			crad(a[nverts-1]u[nverts-1][0] - u[nverts-1][1]);
228			c0[1] = cl[1] = vert[nverts-1][1] +
229			crad(a[nverts-1]u[nverts-1][1] + u[nverts-1][0]);
230			c0[2] = cl[2] = crad;
231			for (i = 0; i < nverts; i++) {
232			if (i < nverts-1) {
233			c1[0] = vert[i][0] + crad(a[i]u[i][0] - u[i][1]);
234			c1[1] = vert[i][1] + crad(a[i]u[i][1] + u[i][0]);
235			c1[2] = crad;
236			} else {
237			c1[0] = cl[0]; c1[1] = cl[1]; c1[2] = cl[2];
238			}
239			if (a[i] > 0.) {
240			printf("\n%s sphere %s.bc%d\n", pmtype, pname, i+1);
241			printf("0\n0\n4 %18.12g %18.12g %18.12g %18.12g\n",
242			c1[0], c1[1], c1[2], crad);
243			}
244			printf("\n%s cylinder %s.be%d\n", pmtype, pname, i+1);
245			printf("0\n0\n7\n");
246			printf("\t%18.12g\t%18.12g\t%18.12g\n", c0[0], c0[1], c0[2]);
247			printf("\t%18.12g\t%18.12g\t%18.12g\n", c1[0], c1[1], c1[2]);
248			printf("\t%18.12g\n", crad);
249			c0[0] = c1[0]; c0[1] = c1[1]; c0[2] = c1[2];
250			}
251			/* top face */
252			printf("\n%s polygon %s.t\n", pmtype, pname);
253	greg	1.1	printf("0\n0\n%d\n", nverts*3);
254	greg	2.6	for (i = nverts; i--; ) {
255	greg	1.1	printf("\t%18.12g\t%18.12g\t%18.12g\n",
256	greg	2.6	vert[i][0] + lvect[0] + crad(a[i]u[i][0] - u[i][1]),
257			vert[i][1] + lvect[1] + crad(a[i]u[i][1] + u[i][0]),
258			lvect[2]);
259	greg	1.1	}
260	greg	2.6	/* top corners and edges */
261			c0[0] = cl[0] = vert[nverts-1][0] + lvect[0] +
262			crad(a[nverts-1]u[nverts-1][0] - u[nverts-1][1]);
263			c0[1] = cl[1] = vert[nverts-1][1] + lvect[1] +
264			crad(a[nverts-1]u[nverts-1][1] + u[nverts-1][0]);
265			c0[2] = cl[2] = lvect[2] - crad;
266			for (i = 0; i < nverts; i++) {
267			if (i < nverts-1) {
268			c1[0] = vert[i][0] + lvect[0] +
269			crad(a[i]u[i][0] - u[i][1]);
270			c1[1] = vert[i][1] + lvect[1] +
271			crad(a[i]u[i][1] + u[i][0]);
272			c1[2] = lvect[2] - crad;
273			} else {
274			c1[0] = cl[0]; c1[1] = cl[1]; c1[2] = cl[2];
275			}
276			if (a[i] > 0.) {
277			printf("\n%s sphere %s.tc%d\n", pmtype, pname, i+1);
278			printf("0\n0\n4 %18.12g %18.12g %18.12g %18.12g\n",
279			c1[0], c1[1], c1[2], crad);
280			}
281			printf("\n%s cylinder %s.te%d\n", pmtype, pname, i+1);
282			printf("0\n0\n7\n");
283			printf("\t%18.12g\t%18.12g\t%18.12g\n", c0[0], c0[1], c0[2]);
284			printf("\t%18.12g\t%18.12g\t%18.12g\n", c1[0], c1[1], c1[2]);
285			printf("\t%18.12g\n", crad);
286			c0[0] = c1[0]; c0[1] = c1[1]; c0[2] = c1[2];
287			}
288	greg	1.1	}
289
290
291	greg	2.6	printsides(round) /* print prism sides */
292			int round;
293	greg	1.1	{
294			register int i;
295
296			for (i = 0; i < nverts-1; i++)
297	greg	2.6	if (round)
298			rside(i, i+1);
299			else
300			side(i, i+1);
301	greg	1.1	if (!iscomplete)
302	greg	2.6	if (round)
303			rside(nverts-1, 0);
304			else
305			side(nverts-1, 0);
306	greg	1.1	}
307
308
309	greg	2.6	side(n0, n1) /* print single side */
310			register int n0, n1;
311	greg	1.1	{
312	greg	2.6	printf("\n%s polygon %s.%d\n", pmtype, pname, n0+1);
313	greg	1.1	printf("0\n0\n12\n");
314	greg	2.6	printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n0][0],
315			vert[n0][1], 0.0);
316			printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n0][0]+lvect[0],
317			vert[n0][1]+lvect[1], lvect[2]);
318			printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n1][0]+lvect[0],
319			vert[n1][1]+lvect[1], lvect[2]);
320			printf("\t%18.12g\t%18.12g\t%18.12g\n", vert[n1][0],
321			vert[n1][1], 0.0);
322			}
323
324
325			rside(n0, n1) /* print side with rounded edge */
326			register int n0, n1;
327			{
328			double s, c, t[3];
329
330			/* compute tanget offset vector */
331			s = (lvect[1]u[n1][0] - lvect[0]u[n1][1])/llen;
332			if (s < -FTINY \|\| s > FTINY) {
333			c = sqrt(1. - s*s);
334			t[0] = (c - 1.)*u[n1][1];
335			t[1] = (1. - c)*u[n1][0];
336			t[2] = s;
337			} else
338			t[0] = t[1] = t[2] = 0.;
339			/* output side */
340			printf("\n%s polygon %s.%d\n", pmtype, pname, n0+1);
341			printf("0\n0\n12\n");
342	greg	1.1	printf("\t%18.12g\t%18.12g\t%18.12g\n",
343	greg	2.6	vert[n0][0] + crad(t[0] - a[n0]u[n1][0]),
344			vert[n0][1] + crad(t[1] - a[n0]u[n1][1]),
345			crad*(t[2] + 1.));
346	greg	1.1	printf("\t%18.12g\t%18.12g\t%18.12g\n",
347	greg	2.6	vert[n0][0] + lvect[0] + crad(t[0] - a[n0]u[n1][0]),
348			vert[n0][1] + lvect[1] + crad(t[1] - a[n0]u[n1][1]),
349			lvect[2] + crad*(t[2] - 1.));
350	greg	1.1	printf("\t%18.12g\t%18.12g\t%18.12g\n",
351	greg	2.6	vert[n1][0] + lvect[0] + crad(t[0] + a[n1]u[n1][0]),
352			vert[n1][1] + lvect[1] + crad(t[1] + a[n1]u[n1][1]),
353			lvect[2] + crad*(t[2] - 1.));
354	greg	1.1	printf("\t%18.12g\t%18.12g\t%18.12g\n",
355	greg	2.6	vert[n1][0] + crad(t[0] + a[n1]u[n1][0]),
356			vert[n1][1] + crad(t[1] + a[n1]u[n1][1]),
357			crad*(t[2] + 1.));
358			/* output joining edge */
359			if (a[n1] < 0.)
360			return;
361			printf("\n%s cylinder %s.e%d\n", pmtype, pname, n0+1);
362			printf("0\n0\n7\n");
363			printf("\t%18.12g\t%18.12g\t%18.12g\n",
364			vert[n1][0] + crad(a[n1]u[n1][0] - u[n1][1]),
365			vert[n1][1] + crad(a[n1]u[n1][1] + u[n1][0]),
366			crad);
367			printf("\t%18.12g\t%18.12g\t%18.12g\n",
368			vert[n1][0] + lvect[0] + crad(a[n1]u[n1][0] - u[n1][1]),
369			vert[n1][1] + lvect[1] + crad(a[n1]u[n1][1] + u[n1][0]),
370			lvect[2] - crad);
371			printf("\t%18.12g\n", crad);
372	greg	1.1	}
373
374
375			printhead(ac, av) /* print command header */
376			register int ac;
377			register char **av;
378			{
379			putchar('#');
380			while (ac--) {
381			putchar(' ');
382			fputs(*av++, stdout);
383			}
384			putchar('\n');
385			}