src/common/rglsurf.c

#ifndef lint
static const char       RCSid[] = "$Id$";
#endif
/*
 * Convert Radiance -> OpenGL surfaces.
 */

#include "copyright.h"

#include "radogl.h"

#ifndef NSLICES
#define NSLICES         18              /* number of quadric slices */
#endif
#ifndef NSTACKS
#define NSTACKS         10              /* number of quadric stacks */
#endif

MATREC  *curmat = NULL;                 /* current material */

static int      curpolysize = 0;        /* outputting triangles/quads */

static GLUquadricObj    *gluqo;         /* shared quadric object */
static GLUtesselator    *gluto;         /* shared tessallation object */

static char     *glu_rout = "unk";      /* active GLU routine */

#define NOPOLY()        if (curpolysize) {glEnd(); curpolysize = 0;} else


void
setmaterial(mp, cent, ispoly)   /* prepare for new material */
register MATREC *mp;
FVECT   cent;
int     ispoly;
{
        if (mp != curmat && domats) {
                NOPOLY();
                domatobj(curmat = mp, cent);
        } else if (!ispoly)
                NOPOLY();
}


double
polyarea(cent, norm, n, v)      /* compute polygon area & normal */
FVECT   cent, norm;     /* returned center and normal */
int     n;              /* number of vertices */
register FVECT  v[];    /* vertex list */
{
        FVECT   v1, v2, v3;
        double  d;
        register int    i;

        norm[0] = norm[1] = norm[2] = 0.;
        v1[0] = v[1][0] - v[0][0];
        v1[1] = v[1][1] - v[0][1];
        v1[2] = v[1][2] - v[0][2];
        for (i = 2; i < n; i++) {
                v2[0] = v[i][0] - v[0][0];
                v2[1] = v[i][1] - v[0][1];
                v2[2] = v[i][2] - v[0][2];
                fcross(v3, v1, v2);
                norm[0] += v3[0];
                norm[1] += v3[1];
                norm[2] += v3[2];
                VCOPY(v1, v2);
        }
        if (cent != NULL) {                     /* compute center also */
                cent[0] = cent[1] = cent[2] = 0.;
                for (i = n; i--; ) {
                        cent[0] += v[i][0];
                        cent[1] += v[i][1];
                        cent[2] += v[i][2];
                }
                d = 1./n;
                cent[0] *= d; cent[1] *= d; cent[2] *= d;
        }
        return(normalize(norm)*.5);
}


static void
glu_error(en)                   /* report an error as a warning */
GLenum  en;
{
        sprintf(errmsg, "GLU error %s: %s", glu_rout, gluErrorString(en));
        error(WARNING, errmsg);
}


static void
myCombine(coords, vertex_data, weight, dataOut)
register GLdouble       coords[3];
GLdouble        *vertex_data[4];
GLfloat weight[4];
GLdouble        **dataOut;
{
        register GLdouble       *newvert;

        newvert = (GLdouble *)malloc(3*sizeof(GLdouble));
        if (newvert == NULL)
                error(SYSTEM, "out of memory in myCombine");
        VCOPY(newvert, coords);         /* no data, just coordinates */
        *dataOut = newvert;
}


static
newtess()                       /* allocate GLU tessellation object */
{
        if ((gluto = gluNewTess()) == NULL)
                error(INTERNAL, "gluNewTess failed");
        gluTessCallback(gluto, GLU_TESS_BEGIN, glBegin);
        gluTessCallback(gluto, GLU_TESS_VERTEX, glVertex3dv);
        gluTessCallback(gluto, GLU_TESS_END, glEnd);
        gluTessCallback(gluto, GLU_TESS_COMBINE, myCombine);
        gluTessCallback(gluto, GLU_TESS_ERROR, glu_error);
        gluTessProperty(gluto, GLU_TESS_WINDING_RULE, GLU_TESS_WINDING_NONZERO);
}


static
newquadric()                    /* allocate GLU quadric structure */
{
        if ((gluqo = gluNewQuadric()) == NULL)
                error(INTERNAL, "gluNewQuadric failed");
        gluQuadricDrawStyle(gluqo, GLU_FILL);
        gluQuadricCallback(gluqo, GLU_ERROR, glu_error);
}


int
o_face(o)                       /* convert a face */
register OBJREC *o;
{
        double  area;
        FVECT   norm, cent;
        register int    i;

        if (o->oargs.nfargs < 9 | o->oargs.nfargs % 3)
                objerror(o, USER, "bad # real arguments");
        area = polyarea(cent, norm, o->oargs.nfargs/3, (FVECT *)o->oargs.farg);
        if (area <= FTINY)
                return(0);
        if (dolights)                                   /* check for source */
                doflatsrc((MATREC *)o->os, cent, norm, area);
        setmaterial((MATREC *)o->os, cent, 1);          /* set material */
        if (o->oargs.nfargs/3 != curpolysize) {
                if (curpolysize) glEnd();
                curpolysize = o->oargs.nfargs/3;
                if (curpolysize == 3)
                        glBegin(GL_TRIANGLES);
                else if (curpolysize == 4)
                        glBegin(GL_QUADS);
        }
        glNormal3d((GLdouble)norm[0], (GLdouble)norm[1], (GLdouble)norm[2]);
        if (curpolysize > 4) {
                if (gluto == NULL) newtess();
                glu_rout = "tessellating polygon";
                gluTessNormal(gluto, (GLdouble)norm[0],
                                (GLdouble)norm[1], (GLdouble)norm[2]);
                gluTessBeginPolygon(gluto, NULL);
                gluTessBeginContour(gluto);
#ifdef SMLFLT
                error(INTERNAL, "bad code segment in o_face");
#endif
                for (i = 0; i < curpolysize; i++)
                        gluTessVertex(gluto, (GLdouble *)(o->oargs.farg+3*i),
                                        (void *)(o->oargs.farg+3*i));
                gluTessEndContour(gluto);
                gluTessEndPolygon(gluto);
                curpolysize = 0;
        } else {
                for (i = 0; i < curpolysize; i++)
                        glVertex3d((GLdouble)o->oargs.farg[3*i],
                                        (GLdouble)o->oargs.farg[3*i+1],
                                        (GLdouble)o->oargs.farg[3*i+2]);
        }
        return(0);
}


void
surfclean()                     /* clean up surface routines */
{
        setmaterial(NULL, NULL, 0);
        if (gluqo != NULL) {
                gluDeleteQuadric(gluqo);
                gluqo = NULL;
        }
        if (gluto != NULL) {
                gluDeleteTess(gluto);
                gluto = NULL;
        }
        rgl_checkerr("in surfclean");
}


int
o_sphere(o)                     /* convert a sphere */
register OBJREC *o;
{
                                        /* check arguments */
        if (o->oargs.nfargs != 4)
                objerror(o, USER, "bad # real arguments");
        if (o->oargs.farg[3] < -FTINY) {
                o->otype = o->otype==OBJ_SPHERE ? OBJ_BUBBLE : OBJ_SPHERE;
                o->oargs.farg[3] = -o->oargs.farg[3];
        } else if (o->oargs.farg[3] <= FTINY)
                return(0);
        if (dolights)
                dosphsrc((MATREC *)o->os, o->oargs.farg,
                                PI*o->oargs.farg[3]*o->oargs.farg[3]);
        setmaterial((MATREC *)o->os, o->oargs.farg, 0);
        if (gluqo == NULL) newquadric();
        glu_rout = "making sphere";
        gluQuadricOrientation(gluqo,
                        o->otype==OBJ_BUBBLE ? GLU_INSIDE : GLU_OUTSIDE);
        gluQuadricNormals(gluqo, GLU_SMOOTH);
        glMatrixMode(GL_MODELVIEW);
        glPushMatrix();
        glTranslated((GLdouble)o->oargs.farg[0], (GLdouble)o->oargs.farg[1],
                        (GLdouble)o->oargs.farg[2]);
        gluSphere(gluqo, (GLdouble)o->oargs.farg[3], NSLICES, NSTACKS);
        glPopMatrix();
        return(0);
}


int
o_cone(o)                       /* convert a cone or cylinder */
register OBJREC *o;
{
        double  x1, y1, h, d;
        FVECT   cent;
        register int    iscyl;

        iscyl = o->otype==OBJ_CYLINDER | o->otype==OBJ_TUBE;
        if (o->oargs.nfargs != (iscyl ? 7 : 8))
                objerror(o, USER, "bad # real arguments");
        if (o->oargs.farg[6] < -FTINY) {
                o->oargs.farg[6] = -o->oargs.farg[6];
                if (iscyl)
                        o->otype = o->otype==OBJ_CYLINDER ?
                                        OBJ_TUBE : OBJ_CYLINDER;
                else {
                        if ((o->oargs.farg[7] = -o->oargs.farg[7]) < -FTINY)
                                objerror(o, USER, "illegal radii");
                        o->otype = o->otype==OBJ_CONE ? OBJ_CUP : OBJ_CONE;
                }
        } else if (!iscyl && o->oargs.farg[7] < -FTINY)
                objerror(o, USER, "illegal radii");
        if (o->oargs.farg[6] <= FTINY && (iscyl || o->oargs.farg[7] <= FTINY))
                return;
        if (!iscyl) {
                if (o->oargs.farg[6] < 0.)      /* complains for tiny neg's */
                        o->oargs.farg[6] = 0.;
                if (o->oargs.farg[7] < 0.)
                        o->oargs.farg[7] = 0.;
        }
        cent[0] = .5*(o->oargs.farg[0] + o->oargs.farg[3]);
        cent[1] = .5*(o->oargs.farg[1] + o->oargs.farg[4]);
        cent[2] = .5*(o->oargs.farg[2] + o->oargs.farg[5]);
        setmaterial((MATREC *)o->os, cent, 0);
        if (gluqo == NULL) newquadric();
        glu_rout = "making cylinder";
        gluQuadricOrientation(gluqo, o->otype==OBJ_CUP | o->otype==OBJ_TUBE ?
                        GLU_INSIDE : GLU_OUTSIDE);
        gluQuadricNormals(gluqo, GLU_SMOOTH);
        glMatrixMode(GL_MODELVIEW);
        glPushMatrix();
                                        /* do base translation */
        glTranslated((GLdouble)o->oargs.farg[0], (GLdouble)o->oargs.farg[1],
                        (GLdouble)o->oargs.farg[2]);
                                        /* compute height & rotation angle */
        h = sqrt(dist2(o->oargs.farg,o->oargs.farg+3));
        if (h <= FTINY)
                return;
        x1 = o->oargs.farg[1] - o->oargs.farg[4];
        y1 = o->oargs.farg[3] - o->oargs.farg[0];
        /* z1 = 0; */
        d = 180./PI * asin(sqrt(x1*x1 + y1*y1) / h);
        if (o->oargs.farg[5] < o->oargs.farg[2])
                d = 180. - d;
        if (d > FTINY)
                glRotated(d, (GLdouble)x1, (GLdouble)y1, 0.);
        gluCylinder(gluqo, o->oargs.farg[6], o->oargs.farg[iscyl ? 6 : 7],
                        h, NSLICES, 1);
        glPopMatrix();
        return(0);
}


int
o_ring(o)                       /* convert a ring */
register OBJREC *o;
{
        double  x1, y1, d;

        if (o->oargs.nfargs != 8)
                objerror(o, USER, "bad # real arguments");
        if (o->oargs.farg[7] < o->oargs.farg[6]) {
                register double d = o->oargs.farg[7];
                o->oargs.farg[7] = o->oargs.farg[6];
                o->oargs.farg[6] = d;
        }
        if (o->oargs.farg[6] < -FTINY)
                objerror(o, USER, "negative radius");
        if (o->oargs.farg[6] < 0.)              /* complains for tiny neg's */
                o->oargs.farg[6] = 0.;
        if (o->oargs.farg[7] - o->oargs.farg[6] <= FTINY)
                return;
        if (dolights)
                doflatsrc((MATREC *)o->os, o->oargs.farg, o->oargs.farg+3, 
                                PI*(o->oargs.farg[7]*o->oargs.farg[7] -
                                        o->oargs.farg[6]*o->oargs.farg[6]));
        setmaterial((MATREC *)o->os, o->oargs.farg, 0);
        if (gluqo == NULL) newquadric();
        glu_rout = "making disk";
        gluQuadricOrientation(gluqo, GLU_OUTSIDE);
        gluQuadricNormals(gluqo, GLU_FLAT);
        glMatrixMode(GL_MODELVIEW);
        glPushMatrix();
        glTranslated((GLdouble)o->oargs.farg[0], (GLdouble)o->oargs.farg[1],
                        (GLdouble)o->oargs.farg[2]);
                                        /* compute rotation angle */
        d = VLEN(o->oargs.farg+3);
        if (d <= FTINY)
                return;
        x1 = -o->oargs.farg[4];
        y1 = o->oargs.farg[3];
        /* z1 = 0; */
        d = 180./PI * asin(sqrt(x1*x1 + y1*y1) / d);
        if (o->oargs.farg[5] < 0.)
                d = 180. - d;
        if (d > FTINY)
                glRotated(d, (GLdouble)x1, (GLdouble)y1, 0.);
        gluDisk(gluqo, o->oargs.farg[6], o->oargs.farg[7], NSLICES, 1);
        glPopMatrix();
        return(0);
}
Revision:	3.7
Committed:	Wed Apr 23 02:28:06 2003 UTC (21 years ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 3.6:	+6 -2 lines
Log Message:	Added check for mesh primitive and warning when encountered
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id$";
3	#endif
4	/*
5	* Convert Radiance -> OpenGL surfaces.
6	*/
7
8	#include "copyright.h"
9
10	#include "radogl.h"
11
12	#ifndef NSLICES
13	#define NSLICES 18 /* number of quadric slices */
14	#endif
15	#ifndef NSTACKS
16	#define NSTACKS 10 /* number of quadric stacks */
17	#endif
18
19	MATREC curmat = NULL; / current material */
20
21	static int curpolysize = 0; /* outputting triangles/quads */
22
23	static GLUquadricObj gluqo; / shared quadric object */
24	static GLUtesselator gluto; / shared tessallation object */
25
26	static char glu_rout = "unk"; / active GLU routine */
27
28	#define NOPOLY() if (curpolysize) {glEnd(); curpolysize = 0;} else
29
30
31	void
32	setmaterial(mp, cent, ispoly) /* prepare for new material */
33	register MATREC *mp;
34	FVECT cent;
35	int ispoly;
36	{
37	if (mp != curmat && domats) {
38	NOPOLY();
39	domatobj(curmat = mp, cent);
40	} else if (!ispoly)
41	NOPOLY();
42	}
43
44
45	double
46	polyarea(cent, norm, n, v) /* compute polygon area & normal */
47	FVECT cent, norm; /* returned center and normal */
48	int n; /* number of vertices */
49	register FVECT v[]; /* vertex list */
50	{
51	FVECT v1, v2, v3;
52	double d;
53	register int i;
54
55	norm[0] = norm[1] = norm[2] = 0.;
56	v1[0] = v[1][0] - v[0][0];
57	v1[1] = v[1][1] - v[0][1];
58	v1[2] = v[1][2] - v[0][2];
59	for (i = 2; i < n; i++) {
60	v2[0] = v[i][0] - v[0][0];
61	v2[1] = v[i][1] - v[0][1];
62	v2[2] = v[i][2] - v[0][2];
63	fcross(v3, v1, v2);
64	norm[0] += v3[0];
65	norm[1] += v3[1];
66	norm[2] += v3[2];
67	VCOPY(v1, v2);
68	}
69	if (cent != NULL) { /* compute center also */
70	cent[0] = cent[1] = cent[2] = 0.;
71	for (i = n; i--; ) {
72	cent[0] += v[i][0];
73	cent[1] += v[i][1];
74	cent[2] += v[i][2];
75	}
76	d = 1./n;
77	cent[0] = d; cent[1] = d; cent[2] *= d;
78	}
79	return(normalize(norm)*.5);
80	}
81
82
83	static void
84	glu_error(en) /* report an error as a warning */
85	GLenum en;
86	{
87	sprintf(errmsg, "GLU error %s: %s", glu_rout, gluErrorString(en));
88	error(WARNING, errmsg);
89	}
90
91
92	static void
93	myCombine(coords, vertex_data, weight, dataOut)
94	register GLdouble coords[3];
95	GLdouble *vertex_data[4];
96	GLfloat weight[4];
97	GLdouble **dataOut;
98	{
99	register GLdouble *newvert;
100
101	newvert = (GLdouble )malloc(3sizeof(GLdouble));
102	if (newvert == NULL)
103	error(SYSTEM, "out of memory in myCombine");
104	VCOPY(newvert, coords); /* no data, just coordinates */
105	*dataOut = newvert;
106	}
107
108
109	static
110	newtess() /* allocate GLU tessellation object */
111	{
112	if ((gluto = gluNewTess()) == NULL)
113	error(INTERNAL, "gluNewTess failed");
114	gluTessCallback(gluto, GLU_TESS_BEGIN, glBegin);
115	gluTessCallback(gluto, GLU_TESS_VERTEX, glVertex3dv);
116	gluTessCallback(gluto, GLU_TESS_END, glEnd);
117	gluTessCallback(gluto, GLU_TESS_COMBINE, myCombine);
118	gluTessCallback(gluto, GLU_TESS_ERROR, glu_error);
119	gluTessProperty(gluto, GLU_TESS_WINDING_RULE, GLU_TESS_WINDING_NONZERO);
120	}
121
122
123	static
124	newquadric() /* allocate GLU quadric structure */
125	{
126	if ((gluqo = gluNewQuadric()) == NULL)
127	error(INTERNAL, "gluNewQuadric failed");
128	gluQuadricDrawStyle(gluqo, GLU_FILL);
129	gluQuadricCallback(gluqo, GLU_ERROR, glu_error);
130	}
131
132
133	int
134	o_face(o) /* convert a face */
135	register OBJREC *o;
136	{
137	double area;
138	FVECT norm, cent;
139	register int i;
140
141	if (o->oargs.nfargs < 9 \| o->oargs.nfargs % 3)
142	objerror(o, USER, "bad # real arguments");
143	area = polyarea(cent, norm, o->oargs.nfargs/3, (FVECT *)o->oargs.farg);
144	if (area <= FTINY)
145	return(0);
146	if (dolights) /* check for source */
147	doflatsrc((MATREC *)o->os, cent, norm, area);
148	setmaterial((MATREC )o->os, cent, 1); / set material */
149	if (o->oargs.nfargs/3 != curpolysize) {
150	if (curpolysize) glEnd();
151	curpolysize = o->oargs.nfargs/3;
152	if (curpolysize == 3)
153	glBegin(GL_TRIANGLES);
154	else if (curpolysize == 4)
155	glBegin(GL_QUADS);
156	}
157	glNormal3d((GLdouble)norm[0], (GLdouble)norm[1], (GLdouble)norm[2]);
158	if (curpolysize > 4) {
159	if (gluto == NULL) newtess();
160	glu_rout = "tessellating polygon";
161	gluTessNormal(gluto, (GLdouble)norm[0],
162	(GLdouble)norm[1], (GLdouble)norm[2]);
163	gluTessBeginPolygon(gluto, NULL);
164	gluTessBeginContour(gluto);
165	#ifdef SMLFLT
166	error(INTERNAL, "bad code segment in o_face");
167	#endif
168	for (i = 0; i < curpolysize; i++)
169	gluTessVertex(gluto, (GLdouble )(o->oargs.farg+3i),
170	(void )(o->oargs.farg+3i));
171	gluTessEndContour(gluto);
172	gluTessEndPolygon(gluto);
173	curpolysize = 0;
174	} else {
175	for (i = 0; i < curpolysize; i++)
176	glVertex3d((GLdouble)o->oargs.farg[3*i],
177	(GLdouble)o->oargs.farg[3*i+1],
178	(GLdouble)o->oargs.farg[3*i+2]);
179	}
180	return(0);
181	}
182
183
184	void
185	surfclean() /* clean up surface routines */
186	{
187	setmaterial(NULL, NULL, 0);
188	if (gluqo != NULL) {
189	gluDeleteQuadric(gluqo);
190	gluqo = NULL;
191	}
192	if (gluto != NULL) {
193	gluDeleteTess(gluto);
194	gluto = NULL;
195	}
196	rgl_checkerr("in surfclean");
197	}
198
199
200	int
201	o_sphere(o) /* convert a sphere */
202	register OBJREC *o;
203	{
204	/* check arguments */
205	if (o->oargs.nfargs != 4)
206	objerror(o, USER, "bad # real arguments");
207	if (o->oargs.farg[3] < -FTINY) {
208	o->otype = o->otype==OBJ_SPHERE ? OBJ_BUBBLE : OBJ_SPHERE;
209	o->oargs.farg[3] = -o->oargs.farg[3];
210	} else if (o->oargs.farg[3] <= FTINY)
211	return(0);
212	if (dolights)
213	dosphsrc((MATREC *)o->os, o->oargs.farg,
214	PIo->oargs.farg[3]o->oargs.farg[3]);
215	setmaterial((MATREC *)o->os, o->oargs.farg, 0);
216	if (gluqo == NULL) newquadric();
217	glu_rout = "making sphere";
218	gluQuadricOrientation(gluqo,
219	o->otype==OBJ_BUBBLE ? GLU_INSIDE : GLU_OUTSIDE);
220	gluQuadricNormals(gluqo, GLU_SMOOTH);
221	glMatrixMode(GL_MODELVIEW);
222	glPushMatrix();
223	glTranslated((GLdouble)o->oargs.farg[0], (GLdouble)o->oargs.farg[1],
224	(GLdouble)o->oargs.farg[2]);
225	gluSphere(gluqo, (GLdouble)o->oargs.farg[3], NSLICES, NSTACKS);
226	glPopMatrix();
227	return(0);
228	}
229
230
231	int
232	o_cone(o) /* convert a cone or cylinder */
233	register OBJREC *o;
234	{
235	double x1, y1, h, d;
236	FVECT cent;
237	register int iscyl;
238
239	iscyl = o->otype==OBJ_CYLINDER \| o->otype==OBJ_TUBE;
240	if (o->oargs.nfargs != (iscyl ? 7 : 8))
241	objerror(o, USER, "bad # real arguments");
242	if (o->oargs.farg[6] < -FTINY) {
243	o->oargs.farg[6] = -o->oargs.farg[6];
244	if (iscyl)
245	o->otype = o->otype==OBJ_CYLINDER ?
246	OBJ_TUBE : OBJ_CYLINDER;
247	else {
248	if ((o->oargs.farg[7] = -o->oargs.farg[7]) < -FTINY)
249	objerror(o, USER, "illegal radii");
250	o->otype = o->otype==OBJ_CONE ? OBJ_CUP : OBJ_CONE;
251	}
252	} else if (!iscyl && o->oargs.farg[7] < -FTINY)
253	objerror(o, USER, "illegal radii");
254	if (o->oargs.farg[6] <= FTINY && (iscyl \|\| o->oargs.farg[7] <= FTINY))
255	return;
256	if (!iscyl) {
257	if (o->oargs.farg[6] < 0.) /* complains for tiny neg's */
258	o->oargs.farg[6] = 0.;
259	if (o->oargs.farg[7] < 0.)
260	o->oargs.farg[7] = 0.;
261	}
262	cent[0] = .5*(o->oargs.farg[0] + o->oargs.farg[3]);
263	cent[1] = .5*(o->oargs.farg[1] + o->oargs.farg[4]);
264	cent[2] = .5*(o->oargs.farg[2] + o->oargs.farg[5]);
265	setmaterial((MATREC *)o->os, cent, 0);
266	if (gluqo == NULL) newquadric();
267	glu_rout = "making cylinder";
268	gluQuadricOrientation(gluqo, o->otype==OBJ_CUP \| o->otype==OBJ_TUBE ?
269	GLU_INSIDE : GLU_OUTSIDE);
270	gluQuadricNormals(gluqo, GLU_SMOOTH);
271	glMatrixMode(GL_MODELVIEW);
272	glPushMatrix();
273	/* do base translation */
274	glTranslated((GLdouble)o->oargs.farg[0], (GLdouble)o->oargs.farg[1],
275	(GLdouble)o->oargs.farg[2]);
276	/* compute height & rotation angle */
277	h = sqrt(dist2(o->oargs.farg,o->oargs.farg+3));
278	if (h <= FTINY)
279	return;
280	x1 = o->oargs.farg[1] - o->oargs.farg[4];
281	y1 = o->oargs.farg[3] - o->oargs.farg[0];
282	/* z1 = 0; */
283	d = 180./PI * asin(sqrt(x1x1 + y1y1) / h);
284	if (o->oargs.farg[5] < o->oargs.farg[2])
285	d = 180. - d;
286	if (d > FTINY)
287	glRotated(d, (GLdouble)x1, (GLdouble)y1, 0.);
288	gluCylinder(gluqo, o->oargs.farg[6], o->oargs.farg[iscyl ? 6 : 7],
289	h, NSLICES, 1);
290	glPopMatrix();
291	return(0);
292	}
293
294
295	int
296	o_ring(o) /* convert a ring */
297	register OBJREC *o;
298	{
299	double x1, y1, d;
300
301	if (o->oargs.nfargs != 8)
302	objerror(o, USER, "bad # real arguments");
303	if (o->oargs.farg[7] < o->oargs.farg[6]) {
304	register double d = o->oargs.farg[7];
305	o->oargs.farg[7] = o->oargs.farg[6];
306	o->oargs.farg[6] = d;
307	}
308	if (o->oargs.farg[6] < -FTINY)
309	objerror(o, USER, "negative radius");
310	if (o->oargs.farg[6] < 0.) /* complains for tiny neg's */
311	o->oargs.farg[6] = 0.;
312	if (o->oargs.farg[7] - o->oargs.farg[6] <= FTINY)
313	return;
314	if (dolights)
315	doflatsrc((MATREC *)o->os, o->oargs.farg, o->oargs.farg+3,
316	PI(o->oargs.farg[7]o->oargs.farg[7] -
317	o->oargs.farg[6]*o->oargs.farg[6]));
318	setmaterial((MATREC *)o->os, o->oargs.farg, 0);
319	if (gluqo == NULL) newquadric();
320	glu_rout = "making disk";
321	gluQuadricOrientation(gluqo, GLU_OUTSIDE);
322	gluQuadricNormals(gluqo, GLU_FLAT);
323	glMatrixMode(GL_MODELVIEW);
324	glPushMatrix();
325	glTranslated((GLdouble)o->oargs.farg[0], (GLdouble)o->oargs.farg[1],
326	(GLdouble)o->oargs.farg[2]);
327	/* compute rotation angle */
328	d = VLEN(o->oargs.farg+3);
329	if (d <= FTINY)
330	return;
331	x1 = -o->oargs.farg[4];
332	y1 = o->oargs.farg[3];
333	/* z1 = 0; */
334	d = 180./PI * asin(sqrt(x1x1 + y1y1) / d);
335	if (o->oargs.farg[5] < 0.)
336	d = 180. - d;
337	if (d > FTINY)
338	glRotated(d, (GLdouble)x1, (GLdouble)y1, 0.);
339	gluDisk(gluqo, o->oargs.farg[6], o->oargs.farg[7], NSLICES, 1);
340	glPopMatrix();
341	return(0);
342	}