src/common/readmesh.c

#ifndef lint
static const char RCSid[] = "$Id$";
#endif
/*
 *  Routines for reading a compiled mesh from a file
 */

#include  "standard.h"
#include  "octree.h"
#include  "object.h"
#include  "mesh.h"

static char     *meshfn;        /* input file name */
static FILE     *meshfp;        /* mesh file pointer */
static int      objsize;        /* sizeof(OBJECT) from writer */


static void
mesherror(etyp, msg)                    /* mesh read error */
int  etyp;
char  *msg;
{
        char  msgbuf[128];

        sprintf(msgbuf, "(%s): %s", meshfn, msg);
        error(etyp, msgbuf);
}


static long
mgetint(siz)                            /* get a siz-byte integer */
int  siz;
{
        register long  r;

        r = getint(siz, meshfp);
        if (feof(meshfp))
                mesherror(USER, "truncated mesh file");
        return(r);
}


static double
mgetflt()                               /* get a floating point number */
{
        double  r;

        r = getflt(meshfp);
        if (feof(meshfp))
                mesherror(USER, "truncated mesh file");
        return(r);
}
        

static OCTREE
getfullnode()                           /* get a set, return fullnode */
{
        OBJECT  set[MAXSET+1];
        register int  i;

        if ((set[0] = mgetint(objsize)) > MAXSET)
                mesherror(USER, "bad set in getfullnode");
        for (i = 1; i <= set[0]; i++)
                set[i] = mgetint(objsize);
        return(fullnode(set));
}       


static OCTREE
gettree()                               /* get a pre-ordered octree */
{
        register OCTREE  ot;
        register int  i;
        
        switch (getc(meshfp)) {
        case OT_EMPTY:
                return(EMPTY);
        case OT_FULL:
                return(getfullnode());
        case OT_TREE:
                if ((ot = octalloc()) == EMPTY)
                        mesherror(SYSTEM, "out of tree space in readmesh");
                for (i = 0; i < 8; i++)
                        octkid(ot, i) = gettree();
                return(ot);
        case EOF:
                mesherror(USER, "truncated mesh octree");
        default:
                mesherror(USER, "damaged mesh octree");
        }
}


static void
skiptree()                              /* skip octree on input */
{
        register int  i;
        
        switch (getc(meshfp)) {
        case OT_EMPTY:
                return;
        case OT_FULL:
                for (i = mgetint(objsize)*objsize; i-- > 0; )
                        if (getc(meshfp) == EOF)
                                mesherror(USER, "truncated mesh octree");
                return;
        case OT_TREE:
                for (i = 0; i < 8; i++)
                        skiptree();
                return;
        case EOF:
                mesherror(USER, "truncated mesh octree");
        default:
                mesherror(USER, "damaged mesh octree");
        }
}


static void
getpatch(pp)                            /* load a mesh patch */
register MESHPATCH      *pp;
{
        int     flags;
        int     i, j;
                                        /* vertex flags */
        flags = mgetint(1);
        if (!(flags & MT_V) || flags & ~(MT_V|MT_N|MT_UV))
                mesherror(USER, "bad patch flags");
                                        /* allocate vertices */
        pp->nverts = mgetint(2);
        if (pp->nverts <= 0 || pp->nverts > 256)
                mesherror(USER, "bad number of patch vertices");
        pp->xyz = (uint4 (*)[3])malloc(pp->nverts*3*sizeof(uint4));
        if (pp->xyz == NULL)
                goto nomem;
        if (flags & MT_N) {
                pp->norm = (int4 *)calloc(pp->nverts, sizeof(int4));
                if (pp->norm == NULL)
                        goto nomem;
        } else
                pp->norm = NULL;
        if (flags & MT_UV) {
                pp->uv = (uint4 (*)[2])calloc(pp->nverts, 2*sizeof(uint4));
                if (pp->uv == NULL)
                        goto nomem;
        } else
                pp->uv = NULL;
                                        /* vertex xyz locations */
        for (i = 0; i < pp->nverts; i++)
                for (j = 0; j < 3; j++)
                        pp->xyz[i][j] = mgetint(4);
                                        /* vertex normals */
        if (flags & MT_N)
                for (i = 0; i < pp->nverts; i++)
                        pp->norm[i] = mgetint(4);
                                        /* uv coordinates */
        if (flags & MT_UV)
                for (i = 0; i < pp->nverts; i++)
                        for (j = 0; j < 2; j++)
                                pp->uv[i][j] = mgetint(4);
                                        /* local triangles */
        pp->ntris = mgetint(2);
        if (pp->ntris < 0 || pp->ntris > 512)
                mesherror(USER, "bad number of local triangles");
        if (pp->ntris) {
                pp->tri = (struct PTri *)malloc(pp->ntris *
                                                sizeof(struct PTri));
                if (pp->tri == NULL)
                        goto nomem;
                for (i = 0; i < pp->ntris; i++) {
                        pp->tri[i].v1 = mgetint(1);
                        pp->tri[i].v2 = mgetint(1);
                        pp->tri[i].v3 = mgetint(1);
                }
        } else
                pp->tri = NULL;
                                        /* joiner triangles */
        pp->nj1tris = mgetint(2);
        if (pp->nj1tris < 0 || pp->nj1tris > 512)
                mesherror(USER, "bad number of joiner triangles");
        if (pp->nj1tris) {
                pp->j1tri = (struct PJoin1 *)malloc(pp->nj1tris *
                                                sizeof(struct PJoin1));
                if (pp->j1tri == NULL)
                        goto nomem;
                for (i = 0; i < pp->nj1tris; i++) {
                        pp->j1tri[i].v1j = mgetint(4);
                        pp->j1tri[i].v2 = mgetint(1);
                        pp->j1tri[i].v3 = mgetint(1);
                }
        } else
                pp->j1tri = NULL;
                                        /* double joiner triangles */
        pp->nj2tris = mgetint(2);
        if (pp->nj2tris < 0 || pp->nj2tris > 256)
                mesherror(USER, "bad number of double joiner triangles");
        if (pp->nj2tris) {
                pp->j2tri = (struct PJoin2 *)malloc(pp->nj2tris *
                                                sizeof(struct PJoin2));
                if (pp->j2tri == NULL)
                        goto nomem;
                for (i = 0; i < pp->nj2tris; i++) {
                        pp->j2tri[i].v1j = mgetint(4);
                        pp->j2tri[i].v2j = mgetint(4);
                        pp->j2tri[i].v3 = mgetint(1);
                }
        } else
                pp->j2tri = NULL;
        return;
nomem:
        error(SYSTEM, "out of mesh memory in getpatch");
}


void
readmesh(mp, path, flags)               /* read in mesh structures */
MESH    *mp;
char    *path;
int     flags;
{
        char    sbuf[64];
        int     i;
                                        /* check what's loaded */
        flags &= (IO_INFO|IO_BOUNDS|IO_TREE|IO_SCENE) & ~mp->ldflags;
                                        /* open input file */
        if (path == NULL) {
                meshfn = "standard input";
                meshfp = stdin;
        } else if ((meshfp = fopen(meshfn=path, "r")) == NULL) {
                sprintf(errmsg, "cannot open mesh file \"%s\"", path);
                error(SYSTEM, errmsg);
        }
#ifdef MSDOS
        setmode(fileno(meshfp), O_BINARY);
#endif
                                        /* read header */
        checkheader(meshfp, MESHFMT, flags&IO_INFO ? stdout : (FILE *)NULL);
                                        /* read format number */
        objsize = getint(2, meshfp) - MESHMAGIC;
        if (objsize <= 0 || objsize > MAXOBJSIZ || objsize > sizeof(long))
                mesherror(USER, "incompatible mesh format");
                                        /* read boundaries */
        if (flags & IO_BOUNDS) {
                for (i = 0; i < 3; i++)
                        mp->mcube.cuorg[i] = atof(getstr(sbuf, meshfp));
                mp->mcube.cusize = atof(getstr(sbuf, meshfp));
                for (i = 0; i < 2; i++) {
                        mp->uvlim[0][i] = mgetflt();
                        mp->uvlim[1][i] = mgetflt();
                }
        } else {
                for (i = 0; i < 4; i++)
                        getstr(sbuf, meshfp);
                for (i = 0; i < 4; i++)
                        mgetflt();
        }
                                        /* read the octree */
        if (flags & IO_TREE)
                mp->mcube.cutree = gettree();
        else if (flags & IO_SCENE)
                skiptree();
                                        /* read the patches */
        if (flags & IO_SCENE) {
                mp->npatches = mgetint(4);
                mp->patch = (MESHPATCH *)calloc(mp->npatches,
                                        sizeof(MESHPATCH));
                if (mp->patch == NULL)
                        mesherror(SYSTEM, "out of patch memory");
                for (i = 0; i < mp->npatches; i++)
                        getpatch(&mp->patch[i]);
        }
                                        /* clean up */
        fclose(meshfp);
        mp->ldflags |= flags;
}
Revision:	2.1
Committed:	Tue Mar 11 17:08:55 2003 UTC (21 years, 1 month ago) by greg
Content type:	text/plain
Branch:	MAIN
Log Message:	First working version of new "mesh" primitive, obj2mesh converter
#	User	Rev	Content
1	greg	2.1	#ifndef lint
2			static const char RCSid[] = "$Id$";
3			#endif
4			/*
5			* Routines for reading a compiled mesh from a file
6			*/
7
8			#include "standard.h"
9			#include "octree.h"
10			#include "object.h"
11			#include "mesh.h"
12
13			static char meshfn; / input file name */
14			static FILE meshfp; / mesh file pointer */
15			static int objsize; /* sizeof(OBJECT) from writer */
16
17
18			static void
19			mesherror(etyp, msg) /* mesh read error */
20			int etyp;
21			char *msg;
22			{
23			char msgbuf[128];
24
25			sprintf(msgbuf, "(%s): %s", meshfn, msg);
26			error(etyp, msgbuf);
27			}
28
29
30			static long
31			mgetint(siz) /* get a siz-byte integer */
32			int siz;
33			{
34			register long r;
35
36			r = getint(siz, meshfp);
37			if (feof(meshfp))
38			mesherror(USER, "truncated mesh file");
39			return(r);
40			}
41
42
43			static double
44			mgetflt() /* get a floating point number */
45			{
46			double r;
47
48			r = getflt(meshfp);
49			if (feof(meshfp))
50			mesherror(USER, "truncated mesh file");
51			return(r);
52			}
53
54
55			static OCTREE
56			getfullnode() /* get a set, return fullnode */
57			{
58			OBJECT set[MAXSET+1];
59			register int i;
60
61			if ((set[0] = mgetint(objsize)) > MAXSET)
62			mesherror(USER, "bad set in getfullnode");
63			for (i = 1; i <= set[0]; i++)
64			set[i] = mgetint(objsize);
65			return(fullnode(set));
66			}
67
68
69			static OCTREE
70			gettree() /* get a pre-ordered octree */
71			{
72			register OCTREE ot;
73			register int i;
74
75			switch (getc(meshfp)) {
76			case OT_EMPTY:
77			return(EMPTY);
78			case OT_FULL:
79			return(getfullnode());
80			case OT_TREE:
81			if ((ot = octalloc()) == EMPTY)
82			mesherror(SYSTEM, "out of tree space in readmesh");
83			for (i = 0; i < 8; i++)
84			octkid(ot, i) = gettree();
85			return(ot);
86			case EOF:
87			mesherror(USER, "truncated mesh octree");
88			default:
89			mesherror(USER, "damaged mesh octree");
90			}
91			}
92
93
94			static void
95			skiptree() /* skip octree on input */
96			{
97			register int i;
98
99			switch (getc(meshfp)) {
100			case OT_EMPTY:
101			return;
102			case OT_FULL:
103			for (i = mgetint(objsize)*objsize; i-- > 0; )
104			if (getc(meshfp) == EOF)
105			mesherror(USER, "truncated mesh octree");
106			return;
107			case OT_TREE:
108			for (i = 0; i < 8; i++)
109			skiptree();
110			return;
111			case EOF:
112			mesherror(USER, "truncated mesh octree");
113			default:
114			mesherror(USER, "damaged mesh octree");
115			}
116			}
117
118
119			static void
120			getpatch(pp) /* load a mesh patch */
121			register MESHPATCH *pp;
122			{
123			int flags;
124			int i, j;
125			/* vertex flags */
126			flags = mgetint(1);
127			if (!(flags & MT_V) \|\| flags & ~(MT_V\|MT_N\|MT_UV))
128			mesherror(USER, "bad patch flags");
129			/* allocate vertices */
130			pp->nverts = mgetint(2);
131			if (pp->nverts <= 0 \|\| pp->nverts > 256)
132			mesherror(USER, "bad number of patch vertices");
133			pp->xyz = (uint4 ()[3])malloc(pp->nverts3*sizeof(uint4));
134			if (pp->xyz == NULL)
135			goto nomem;
136			if (flags & MT_N) {
137			pp->norm = (int4 *)calloc(pp->nverts, sizeof(int4));
138			if (pp->norm == NULL)
139			goto nomem;
140			} else
141			pp->norm = NULL;
142			if (flags & MT_UV) {
143			pp->uv = (uint4 ()[2])calloc(pp->nverts, 2sizeof(uint4));
144			if (pp->uv == NULL)
145			goto nomem;
146			} else
147			pp->uv = NULL;
148			/* vertex xyz locations */
149			for (i = 0; i < pp->nverts; i++)
150			for (j = 0; j < 3; j++)
151			pp->xyz[i][j] = mgetint(4);
152			/* vertex normals */
153			if (flags & MT_N)
154			for (i = 0; i < pp->nverts; i++)
155			pp->norm[i] = mgetint(4);
156			/* uv coordinates */
157			if (flags & MT_UV)
158			for (i = 0; i < pp->nverts; i++)
159			for (j = 0; j < 2; j++)
160			pp->uv[i][j] = mgetint(4);
161			/* local triangles */
162			pp->ntris = mgetint(2);
163			if (pp->ntris < 0 \|\| pp->ntris > 512)
164			mesherror(USER, "bad number of local triangles");
165			if (pp->ntris) {
166			pp->tri = (struct PTri )malloc(pp->ntris
167			sizeof(struct PTri));
168			if (pp->tri == NULL)
169			goto nomem;
170			for (i = 0; i < pp->ntris; i++) {
171			pp->tri[i].v1 = mgetint(1);
172			pp->tri[i].v2 = mgetint(1);
173			pp->tri[i].v3 = mgetint(1);
174			}
175			} else
176			pp->tri = NULL;
177			/* joiner triangles */
178			pp->nj1tris = mgetint(2);
179			if (pp->nj1tris < 0 \|\| pp->nj1tris > 512)
180			mesherror(USER, "bad number of joiner triangles");
181			if (pp->nj1tris) {
182			pp->j1tri = (struct PJoin1 )malloc(pp->nj1tris
183			sizeof(struct PJoin1));
184			if (pp->j1tri == NULL)
185			goto nomem;
186			for (i = 0; i < pp->nj1tris; i++) {
187			pp->j1tri[i].v1j = mgetint(4);
188			pp->j1tri[i].v2 = mgetint(1);
189			pp->j1tri[i].v3 = mgetint(1);
190			}
191			} else
192			pp->j1tri = NULL;
193			/* double joiner triangles */
194			pp->nj2tris = mgetint(2);
195			if (pp->nj2tris < 0 \|\| pp->nj2tris > 256)
196			mesherror(USER, "bad number of double joiner triangles");
197			if (pp->nj2tris) {
198			pp->j2tri = (struct PJoin2 )malloc(pp->nj2tris
199			sizeof(struct PJoin2));
200			if (pp->j2tri == NULL)
201			goto nomem;
202			for (i = 0; i < pp->nj2tris; i++) {
203			pp->j2tri[i].v1j = mgetint(4);
204			pp->j2tri[i].v2j = mgetint(4);
205			pp->j2tri[i].v3 = mgetint(1);
206			}
207			} else
208			pp->j2tri = NULL;
209			return;
210			nomem:
211			error(SYSTEM, "out of mesh memory in getpatch");
212			}
213
214
215			void
216			readmesh(mp, path, flags) /* read in mesh structures */
217			MESH *mp;
218			char *path;
219			int flags;
220			{
221			char sbuf[64];
222			int i;
223			/* check what's loaded */
224			flags &= (IO_INFO\|IO_BOUNDS\|IO_TREE\|IO_SCENE) & ~mp->ldflags;
225			/* open input file */
226			if (path == NULL) {
227			meshfn = "standard input";
228			meshfp = stdin;
229			} else if ((meshfp = fopen(meshfn=path, "r")) == NULL) {
230			sprintf(errmsg, "cannot open mesh file \"%s\"", path);
231			error(SYSTEM, errmsg);
232			}
233			#ifdef MSDOS
234			setmode(fileno(meshfp), O_BINARY);
235			#endif
236			/* read header */
237			checkheader(meshfp, MESHFMT, flags&IO_INFO ? stdout : (FILE *)NULL);
238			/* read format number */
239			objsize = getint(2, meshfp) - MESHMAGIC;
240			if (objsize <= 0 \|\| objsize > MAXOBJSIZ \|\| objsize > sizeof(long))
241			mesherror(USER, "incompatible mesh format");
242			/* read boundaries */
243			if (flags & IO_BOUNDS) {
244			for (i = 0; i < 3; i++)
245			mp->mcube.cuorg[i] = atof(getstr(sbuf, meshfp));
246			mp->mcube.cusize = atof(getstr(sbuf, meshfp));
247			for (i = 0; i < 2; i++) {
248			mp->uvlim[0][i] = mgetflt();
249			mp->uvlim[1][i] = mgetflt();
250			}
251			} else {
252			for (i = 0; i < 4; i++)
253			getstr(sbuf, meshfp);
254			for (i = 0; i < 4; i++)
255			mgetflt();
256			}
257			/* read the octree */
258			if (flags & IO_TREE)
259			mp->mcube.cutree = gettree();
260			else if (flags & IO_SCENE)
261			skiptree();
262			/* read the patches */
263			if (flags & IO_SCENE) {
264			mp->npatches = mgetint(4);
265			mp->patch = (MESHPATCH *)calloc(mp->npatches,
266			sizeof(MESHPATCH));
267			if (mp->patch == NULL)
268			mesherror(SYSTEM, "out of patch memory");
269			for (i = 0; i < mp->npatches; i++)
270			getpatch(&mp->patch[i]);
271			}
272			/* clean up */
273			fclose(meshfp);
274			mp->ldflags \|= flags;
275			}