src/ot/cvmesh.c

#ifndef lint
static const char RCSid[] = "$Id$";
#endif
/*
 *  Radiance triangle mesh conversion routines
 */

#include "copyright.h"
#include "standard.h"
#include "cvmesh.h"
#include "otypes.h"
#include "face.h"

/*
 * We need to divide faces into triangles and record auxiliary information
 * if given (surface normal and uv coordinates).  We do this by extending
 * the face structure linked to the OBJREC os member and putting our
 * auxiliary after it -- a bit sly, but it works.
 */

/* Auxiliary data for triangle */
typedef struct {
        int             fl;             /* flags of what we're storing */
        OBJECT          obj;            /* mesh triangle ID */
        FVECT           vn[3];          /* normals */
        FLOAT           vc[3][2];       /* uv coords. */
} TRIDATA;

#define tdsize(fl)      ((fl)&MT_UV ? sizeof(TRIDATA) : \
                                (fl)&MT_N ? sizeof(TRIDATA)-2*sizeof(FLOAT) : \
                                sizeof(int)+sizeof(OBJECT))

#define  OMARGIN        (10*FTINY)      /* margin around global cube */

MESH    *ourmesh = NULL;                /* our global mesh data structure */

FVECT   meshbounds[2];                  /* mesh bounding box */


MESH *
cvinit(nm)                      /* initialize empty mesh */
char    *nm;
{
                                /* free old mesh, first */
        if (ourmesh != NULL) {
                freemesh(ourmesh);
                ourmesh = NULL;
                freeobjects(0, nobjects);
                donesets();
        }
        if (nm == NULL)
                return(NULL);
        ourmesh = (MESH *)calloc(1, sizeof(MESH));
        if (ourmesh == NULL)
                goto nomem;
        ourmesh->name = savestr(nm);
        ourmesh->nref = 1;
        ourmesh->ldflags = 0;
        ourmesh->mcube.cutree = EMPTY;
        ourmesh->uvlim[0][0] = ourmesh->uvlim[0][1] = FHUGE;
        ourmesh->uvlim[1][0] = ourmesh->uvlim[1][1] = -FHUGE;
        meshbounds[0][0] = meshbounds[0][1] = meshbounds[0][2] = FHUGE;
        meshbounds[1][0] = meshbounds[1][1] = meshbounds[1][2] = -FHUGE;
        return(ourmesh);
nomem:
        error(SYSTEM, "out of memory in cvinit");
        return(NULL);
}


int
cvpoly(mo, n, vp, vn, vc)       /* convert a polygon to extended triangles */
OBJECT  mo;
int     n;
FVECT   *vp;
FVECT   *vn;
FLOAT   (*vc)[2];
{
        int     tcnt = 0;
        int     flags;
        FLOAT   *tn[3], *tc[3];
        int     *ord;
        int     i, j;

        if (n < 3)              /* degenerate face */
                return(0);
        flags = MT_V;
        if (vn != NULL) {
                tn[0] = vn[0]; tn[1] = vn[1]; tn[2] = vn[2];
                flags |= MT_N;
        } else {
                tn[0] = tn[1] = tn[2] = NULL;
        }
        if (vc != NULL) {
                tc[0] = vc[0]; tc[1] = vc[1]; tc[2] = vc[2];
                flags |= MT_UV;
        } else {
                tc[0] = tc[1] = tc[2] = NULL;
        }
        if (n == 3)             /* output single triangle */
                return(cvtri(mo, vp[0], vp[1], vp[2],
                                tn[0], tn[1], tn[2],
                                tc[0], tc[1], tc[2]));

                                /* decimate polygon (assumes convex) */
        ord = (int *)malloc(n*sizeof(int));
        if (ord == NULL)
                error(SYSTEM, "out of memory in cvpoly");
        for (i = n; i--; )
                ord[i] = i;
        while (n >= 3) {
                if (flags & MT_N)
                        for (i = 3; i--; )
                                tn[i] = vn[ord[i]];
                if (flags & MT_UV)
                        for (i = 3; i--; )
                                tc[i] = vc[ord[i]];
                tcnt += cvtri(mo, vp[ord[0]], vp[ord[1]], vp[ord[2]],
                                tn[0], tn[1], tn[2],
                                tc[0], tc[1], tc[2]);
                        /* remove vertex and rotate */
                n--;
                j = ord[0];
                for (i = 0; i < n-1; i++)
                        ord[i] = ord[i+2];
                ord[i] = j;
        }
        free((void *)ord);
        return(tcnt);
}


static void
add2bounds(vp, vc)              /* add point and uv coordinate to bounds */
FVECT   vp;
FLOAT   vc[2];
{
        register int    j;

        for (j = 3; j--; ) {
                if (vp[j] < meshbounds[0][j])
                        meshbounds[0][j] = vp[j];
                if (vp[j] > meshbounds[1][j])
                        meshbounds[1][j] = vp[j];
        }
        if (vc == NULL)
                return;
        for (j = 2; j--; ) {
                if (vc[j] < ourmesh->uvlim[0][j])
                        ourmesh->uvlim[0][j] = vc[j];
                if (vc[j] > ourmesh->uvlim[1][j])
                        ourmesh->uvlim[1][j] = vc[j];
        }
}


int                             /* create an extended triangle */
cvtri(mo, vp1, vp2, vp3, vn1, vn2, vn3, vc1, vc2, vc3)
OBJECT  mo;
FVECT   vp1, vp2, vp3;
FVECT   vn1, vn2, vn3;
FLOAT   vc1[2], vc2[2], vc3[2];
{
        static OBJECT   fobj = OVOID;
        char            buf[32];
        int             flags;
        TRIDATA         *ts;
        FACE            *f;
        OBJREC          *fop;
        int             j;
        
        flags = MT_V;
        if (vn1 != NULL && vn2 != NULL && vn3 != NULL)
                flags |= MT_N;
        if (vc1 != NULL && vc2 != NULL && vc3 != NULL)
                flags |= MT_UV;
        if (fobj == OVOID) {    /* create new triangle object */
                fobj = newobject();
                if (fobj == OVOID)
                        goto nomem;
                fop = objptr(fobj);
                fop->omod = mo;
                fop->otype = OBJ_FACE;
                sprintf(buf, "t%d", fobj);
                fop->oname = savqstr(buf);
                fop->oargs.nfargs = 9;
                fop->oargs.farg = (FLOAT *)malloc(9*sizeof(FLOAT));
                if (fop->oargs.farg == NULL)
                        goto nomem;
        } else {                /* else reuse failed one */
                fop = objptr(fobj);
                if (fop->otype != OBJ_FACE || fop->oargs.nfargs != 9)
                        error(CONSISTENCY, "code error 1 in cvtri");
        }
        for (j = 3; j--; ) {
                fop->oargs.farg[j] = vp1[j];
                fop->oargs.farg[3+j] = vp2[j];
                fop->oargs.farg[6+j] = vp3[j];
        }
                                /* create face record */
        f = getface(fop);
        if (f->area == 0.) {
                free_os(fop);
                return(0);
        }
        if (fop->os != (char *)f)
                error(CONSISTENCY, "code error 2 in cvtri");
                                /* follow with auxliary data */
        f = (FACE *)realloc((void *)f, sizeof(FACE)+tdsize(flags));
        if (f == NULL)
                goto nomem;
        fop->os = (char *)f;
        ts = (TRIDATA *)(f+1);
        ts->fl = flags;
        ts->obj = OVOID;
        if (flags & MT_N)
                for (j = 3; j--; ) {
                        ts->vn[0][j] = vn1[j];
                        ts->vn[1][j] = vn2[j];
                        ts->vn[2][j] = vn3[j];
                }
        if (flags & MT_UV)
                for (j = 2; j--; ) {
                        ts->vc[0][j] = vc1[j];
                        ts->vc[1][j] = vc2[j];
                        ts->vc[2][j] = vc3[j];
                }
        else
                vc1 = vc2 = vc3 = NULL;
                                /* update bounds */
        add2bounds(vp1, vc1);
        add2bounds(vp2, vc2);
        add2bounds(vp3, vc3);
        fobj = OVOID;           /* we used this one */
        return(1);
nomem:
        error(SYSTEM, "out of memory in cvtri");
        return(0);
}


static OBJECT
cvmeshtri(obj)                  /* add an extended triangle to our mesh */
OBJECT  obj;
{
        OBJREC          *o = objptr(obj);
        TRIDATA         *ts;
        MESHVERT        vert[3];
        int             i, j;
        
        if (o->otype != OBJ_FACE)
                error(CONSISTENCY, "non-face in mesh");
        if (o->oargs.nfargs != 9)
                error(CONSISTENCY, "non-triangle in mesh");
        if (o->os == NULL)
                error(CONSISTENCY, "missing face record in cvmeshtri");
        ts = (TRIDATA *)((FACE *)o->os + 1);
        if (ts->obj != OVOID)   /* already added? */
                return(ts->obj);
        vert[0].fl = vert[1].fl = vert[2].fl = ts->fl;
        for (i = 3; i--; )
                for (j = 3; j--; )
                        vert[i].v[j] = o->oargs.farg[3*i+j];
        if (ts->fl & MT_N)
                for (i = 3; i--; )
                        for (j = 3; j--; )
                                vert[i].n[j] = ts->vn[i][j];
        if (ts->fl & MT_UV)
                for (i = 3; i--; )
                        for (j = 2; j--; )
                                vert[i].uv[j] = ts->vc[i][j];
        ts->obj = addmeshtri(ourmesh, vert, o->omod);
        if (ts->obj == OVOID)
                error(INTERNAL, "addmeshtri failed");
        return(ts->obj);
}


void
cvmeshbounds()                  /* set mesh boundaries */
{
        int     i;

        if (ourmesh == NULL)
                return;
                                /* fix coordinate bounds */
        for (i = 0; i < 3; i++) {
                if (meshbounds[0][i] >= meshbounds[1][i])
                        error(USER, "no polygons in mesh");
                meshbounds[0][i] -= OMARGIN;
                meshbounds[1][i] += OMARGIN;
                if (meshbounds[1][i]-meshbounds[0][i] > ourmesh->mcube.cusize)
                        ourmesh->mcube.cusize = meshbounds[1][i] -
                                                meshbounds[0][i];
        }
        for (i = 0; i < 3; i++)
                ourmesh->mcube.cuorg[i] = (meshbounds[1][i]+meshbounds[0][i] -
                                                ourmesh->mcube.cusize)*.5;
        if (ourmesh->uvlim[0][0] > ourmesh->uvlim[1][0]) {
                ourmesh->uvlim[0][0] = ourmesh->uvlim[0][1] = 0.;
                ourmesh->uvlim[1][0] = ourmesh->uvlim[1][1] = 0.;
        } else {
                for (i = 0; i < 2; i++) {
                        double  marg;
                        marg = 1e-6*(ourmesh->uvlim[1][i] -
                                        ourmesh->uvlim[0][i]);
                        ourmesh->uvlim[0][i] -= marg;
                        ourmesh->uvlim[1][i] += marg;
                }
        }
        ourmesh->ldflags |= IO_BOUNDS;
}


static OCTREE
cvmeshoct(ot)                   /* convert triangles in subtree */
OCTREE  ot;
{
        int     i;

        if (isempty(ot))
                return(EMPTY);

        if (isfull(ot)) {
                OBJECT  oset1[MAXSET+1];
                OBJECT  oset2[MAXSET+1];
                objset(oset1, ot);
                oset2[0] = 0;
                for (i = oset1[0]; i > 0; i--)
                        insertelem(oset2, cvmeshtri(oset1[i]));
                return(fullnode(oset2));
        }

        for (i = 8; i--; )
                octkid(ot, i) = cvmeshoct(octkid(ot, i));
        return(ot);
}


MESH *
cvmesh()                        /* convert mesh and octree leaf nodes */
{
        if (ourmesh == NULL)
                return(NULL);
                                /* convert triangles in octree nodes */
        ourmesh->mcube.cutree = cvmeshoct(ourmesh->mcube.cutree);
        ourmesh->ldflags |= IO_SCENE|IO_TREE;

        return(ourmesh);
}
Revision:	2.3
Committed:	Fri Mar 14 21:27:46 2003 UTC (22 years, 7 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad3R5
Changes since 2.2:	+37 -31 lines
Log Message:	Added -a option to obj2mesh to incorporate materials in mesh
#	User	Rev	Content
1	greg	2.1	#ifndef lint
2			static const char RCSid[] = "$Id$";
3			#endif
4			/*
5			* Radiance triangle mesh conversion routines
6			*/
7
8			#include "copyright.h"
9			#include "standard.h"
10			#include "cvmesh.h"
11			#include "otypes.h"
12			#include "face.h"
13
14			/*
15			* We need to divide faces into triangles and record auxiliary information
16			* if given (surface normal and uv coordinates). We do this by extending
17			* the face structure linked to the OBJREC os member and putting our
18			* auxiliary after it -- a bit sly, but it works.
19			*/
20
21			/* Auxiliary data for triangle */
22			typedef struct {
23			int fl; /* flags of what we're storing */
24			OBJECT obj; /* mesh triangle ID */
25			FVECT vn[3]; /* normals */
26			FLOAT vc[3][2]; /* uv coords. */
27			} TRIDATA;
28
29			#define tdsize(fl) ((fl)&MT_UV ? sizeof(TRIDATA) : \
30			(fl)&MT_N ? sizeof(TRIDATA)-2*sizeof(FLOAT) : \
31			sizeof(int)+sizeof(OBJECT))
32
33			#define OMARGIN (10FTINY) / margin around global cube */
34
35			MESH ourmesh = NULL; / our global mesh data structure */
36
37			FVECT meshbounds[2]; /* mesh bounding box */
38
39
40			MESH *
41			cvinit(nm) /* initialize empty mesh */
42			char *nm;
43			{
44			/* free old mesh, first */
45			if (ourmesh != NULL) {
46			freemesh(ourmesh);
47			ourmesh = NULL;
48			freeobjects(0, nobjects);
49			donesets();
50			}
51			if (nm == NULL)
52			return(NULL);
53			ourmesh = (MESH *)calloc(1, sizeof(MESH));
54			if (ourmesh == NULL)
55			goto nomem;
56			ourmesh->name = savestr(nm);
57			ourmesh->nref = 1;
58			ourmesh->ldflags = 0;
59			ourmesh->mcube.cutree = EMPTY;
60	greg	2.2	ourmesh->uvlim[0][0] = ourmesh->uvlim[0][1] = FHUGE;
61			ourmesh->uvlim[1][0] = ourmesh->uvlim[1][1] = -FHUGE;
62	greg	2.1	meshbounds[0][0] = meshbounds[0][1] = meshbounds[0][2] = FHUGE;
63			meshbounds[1][0] = meshbounds[1][1] = meshbounds[1][2] = -FHUGE;
64			return(ourmesh);
65			nomem:
66			error(SYSTEM, "out of memory in cvinit");
67			return(NULL);
68			}
69
70
71			int
72	greg	2.3	cvpoly(mo, n, vp, vn, vc) /* convert a polygon to extended triangles */
73			OBJECT mo;
74	greg	2.1	int n;
75			FVECT *vp;
76			FVECT *vn;
77			FLOAT (*vc)[2];
78			{
79			int tcnt = 0;
80			int flags;
81			FLOAT tn[3], tc[3];
82			int *ord;
83			int i, j;
84
85			if (n < 3) /* degenerate face */
86			return(0);
87			flags = MT_V;
88			if (vn != NULL) {
89			tn[0] = vn[0]; tn[1] = vn[1]; tn[2] = vn[2];
90			flags \|= MT_N;
91			} else {
92			tn[0] = tn[1] = tn[2] = NULL;
93			}
94			if (vc != NULL) {
95			tc[0] = vc[0]; tc[1] = vc[1]; tc[2] = vc[2];
96			flags \|= MT_UV;
97			} else {
98			tc[0] = tc[1] = tc[2] = NULL;
99			}
100			if (n == 3) /* output single triangle */
101	greg	2.3	return(cvtri(mo, vp[0], vp[1], vp[2],
102	greg	2.1	tn[0], tn[1], tn[2],
103			tc[0], tc[1], tc[2]));
104
105			/* decimate polygon (assumes convex) */
106			ord = (int )malloc(nsizeof(int));
107			if (ord == NULL)
108			error(SYSTEM, "out of memory in cvpoly");
109			for (i = n; i--; )
110			ord[i] = i;
111			while (n >= 3) {
112			if (flags & MT_N)
113			for (i = 3; i--; )
114			tn[i] = vn[ord[i]];
115			if (flags & MT_UV)
116			for (i = 3; i--; )
117			tc[i] = vc[ord[i]];
118	greg	2.3	tcnt += cvtri(mo, vp[ord[0]], vp[ord[1]], vp[ord[2]],
119	greg	2.1	tn[0], tn[1], tn[2],
120			tc[0], tc[1], tc[2]);
121			/* remove vertex and rotate */
122			n--;
123			j = ord[0];
124			for (i = 0; i < n-1; i++)
125			ord[i] = ord[i+2];
126			ord[i] = j;
127			}
128			free((void *)ord);
129			return(tcnt);
130			}
131
132
133			static void
134			add2bounds(vp, vc) /* add point and uv coordinate to bounds */
135			FVECT vp;
136			FLOAT vc[2];
137			{
138			register int j;
139
140			for (j = 3; j--; ) {
141			if (vp[j] < meshbounds[0][j])
142			meshbounds[0][j] = vp[j];
143			if (vp[j] > meshbounds[1][j])
144			meshbounds[1][j] = vp[j];
145			}
146			if (vc == NULL)
147			return;
148			for (j = 2; j--; ) {
149			if (vc[j] < ourmesh->uvlim[0][j])
150			ourmesh->uvlim[0][j] = vc[j];
151			if (vc[j] > ourmesh->uvlim[1][j])
152			ourmesh->uvlim[1][j] = vc[j];
153			}
154			}
155
156
157			int /* create an extended triangle */
158	greg	2.3	cvtri(mo, vp1, vp2, vp3, vn1, vn2, vn3, vc1, vc2, vc3)
159			OBJECT mo;
160	greg	2.1	FVECT vp1, vp2, vp3;
161			FVECT vn1, vn2, vn3;
162			FLOAT vc1[2], vc2[2], vc3[2];
163			{
164	greg	2.3	static OBJECT fobj = OVOID;
165			char buf[32];
166			int flags;
167			TRIDATA *ts;
168			FACE *f;
169			OBJREC *fop;
170			int j;
171	greg	2.1
172			flags = MT_V;
173			if (vn1 != NULL && vn2 != NULL && vn3 != NULL)
174			flags \|= MT_N;
175			if (vc1 != NULL && vc2 != NULL && vc3 != NULL)
176			flags \|= MT_UV;
177	greg	2.3	if (fobj == OVOID) { /* create new triangle object */
178			fobj = newobject();
179			if (fobj == OVOID)
180			goto nomem;
181			fop = objptr(fobj);
182			fop->omod = mo;
183			fop->otype = OBJ_FACE;
184			sprintf(buf, "t%d", fobj);
185			fop->oname = savqstr(buf);
186			fop->oargs.nfargs = 9;
187			fop->oargs.farg = (FLOAT )malloc(9sizeof(FLOAT));
188			if (fop->oargs.farg == NULL)
189			goto nomem;
190			} else { /* else reuse failed one */
191			fop = objptr(fobj);
192			if (fop->otype != OBJ_FACE \|\| fop->oargs.nfargs != 9)
193			error(CONSISTENCY, "code error 1 in cvtri");
194			}
195	greg	2.1	for (j = 3; j--; ) {
196			fop->oargs.farg[j] = vp1[j];
197			fop->oargs.farg[3+j] = vp2[j];
198			fop->oargs.farg[6+j] = vp3[j];
199			}
200			/* create face record */
201	greg	2.3	f = getface(fop);
202			if (f->area == 0.) {
203			free_os(fop);
204	greg	2.1	return(0);
205			}
206			if (fop->os != (char *)f)
207	greg	2.3	error(CONSISTENCY, "code error 2 in cvtri");
208	greg	2.1	/* follow with auxliary data */
209			f = (FACE )realloc((void )f, sizeof(FACE)+tdsize(flags));
210			if (f == NULL)
211			goto nomem;
212			fop->os = (char *)f;
213			ts = (TRIDATA *)(f+1);
214			ts->fl = flags;
215			ts->obj = OVOID;
216			if (flags & MT_N)
217			for (j = 3; j--; ) {
218			ts->vn[0][j] = vn1[j];
219			ts->vn[1][j] = vn2[j];
220			ts->vn[2][j] = vn3[j];
221			}
222			if (flags & MT_UV)
223			for (j = 2; j--; ) {
224			ts->vc[0][j] = vc1[j];
225			ts->vc[1][j] = vc2[j];
226			ts->vc[2][j] = vc3[j];
227			}
228			else
229			vc1 = vc2 = vc3 = NULL;
230			/* update bounds */
231			add2bounds(vp1, vc1);
232			add2bounds(vp2, vc2);
233			add2bounds(vp3, vc3);
234	greg	2.3	fobj = OVOID; /* we used this one */
235	greg	2.1	return(1);
236			nomem:
237			error(SYSTEM, "out of memory in cvtri");
238			return(0);
239			}
240
241
242			static OBJECT
243			cvmeshtri(obj) /* add an extended triangle to our mesh */
244			OBJECT obj;
245			{
246			OBJREC *o = objptr(obj);
247			TRIDATA *ts;
248			MESHVERT vert[3];
249			int i, j;
250
251			if (o->otype != OBJ_FACE)
252			error(CONSISTENCY, "non-face in mesh");
253			if (o->oargs.nfargs != 9)
254			error(CONSISTENCY, "non-triangle in mesh");
255			if (o->os == NULL)
256			error(CONSISTENCY, "missing face record in cvmeshtri");
257			ts = (TRIDATA )((FACE )o->os + 1);
258			if (ts->obj != OVOID) /* already added? */
259			return(ts->obj);
260			vert[0].fl = vert[1].fl = vert[2].fl = ts->fl;
261			for (i = 3; i--; )
262			for (j = 3; j--; )
263			vert[i].v[j] = o->oargs.farg[3*i+j];
264			if (ts->fl & MT_N)
265			for (i = 3; i--; )
266			for (j = 3; j--; )
267			vert[i].n[j] = ts->vn[i][j];
268			if (ts->fl & MT_UV)
269			for (i = 3; i--; )
270			for (j = 2; j--; )
271			vert[i].uv[j] = ts->vc[i][j];
272	greg	2.3	ts->obj = addmeshtri(ourmesh, vert, o->omod);
273	greg	2.1	if (ts->obj == OVOID)
274			error(INTERNAL, "addmeshtri failed");
275			return(ts->obj);
276			}
277
278
279			void
280			cvmeshbounds() /* set mesh boundaries */
281			{
282			int i;
283
284			if (ourmesh == NULL)
285			return;
286			/* fix coordinate bounds */
287			for (i = 0; i < 3; i++) {
288			if (meshbounds[0][i] >= meshbounds[1][i])
289			error(USER, "no polygons in mesh");
290			meshbounds[0][i] -= OMARGIN;
291			meshbounds[1][i] += OMARGIN;
292			if (meshbounds[1][i]-meshbounds[0][i] > ourmesh->mcube.cusize)
293			ourmesh->mcube.cusize = meshbounds[1][i] -
294			meshbounds[0][i];
295			}
296			for (i = 0; i < 3; i++)
297			ourmesh->mcube.cuorg[i] = (meshbounds[1][i]+meshbounds[0][i] -
298			ourmesh->mcube.cusize)*.5;
299	greg	2.2	if (ourmesh->uvlim[0][0] > ourmesh->uvlim[1][0]) {
300	greg	2.1	ourmesh->uvlim[0][0] = ourmesh->uvlim[0][1] = 0.;
301			ourmesh->uvlim[1][0] = ourmesh->uvlim[1][1] = 0.;
302			} else {
303			for (i = 0; i < 2; i++) {
304			double marg;
305			marg = 1e-6*(ourmesh->uvlim[1][i] -
306			ourmesh->uvlim[0][i]);
307			ourmesh->uvlim[0][i] -= marg;
308			ourmesh->uvlim[1][i] += marg;
309			}
310			}
311			ourmesh->ldflags \|= IO_BOUNDS;
312			}
313
314
315			static OCTREE
316			cvmeshoct(ot) /* convert triangles in subtree */
317			OCTREE ot;
318			{
319			int i;
320
321			if (isempty(ot))
322			return(EMPTY);
323
324			if (isfull(ot)) {
325			OBJECT oset1[MAXSET+1];
326			OBJECT oset2[MAXSET+1];
327			objset(oset1, ot);
328			oset2[0] = 0;
329			for (i = oset1[0]; i > 0; i--)
330			insertelem(oset2, cvmeshtri(oset1[i]));
331			return(fullnode(oset2));
332			}
333
334			for (i = 8; i--; )
335			octkid(ot, i) = cvmeshoct(octkid(ot, i));
336			return(ot);
337			}
338
339
340			MESH *
341			cvmesh() /* convert mesh and octree leaf nodes */
342			{
343			if (ourmesh == NULL)
344			return(NULL);
345			/* convert triangles in octree nodes */
346			ourmesh->mcube.cutree = cvmeshoct(ourmesh->mcube.cutree);
347			ourmesh->ldflags \|= IO_SCENE\|IO_TREE;
348
349			return(ourmesh);
350			}