Пример #1
0
/**
 *			B U _ P T B L
 *
 *  This version maintained for source compatibility with existing NMG code.
 */
int
bu_ptbl(struct bu_ptbl *b, int func, long int *p)
{
    if (func == BU_PTBL_INIT) {
	bu_ptbl_init(b, 64, "bu_ptbl() buffer[]");
	return 0;
    } else if (func == BU_PTBL_RST) {
	bu_ptbl_reset(b);
	return 0;
    } else if (func == BU_PTBL_INS) {
	return bu_ptbl_ins(b, p);
    } else if (func == BU_PTBL_LOC) {
	return bu_ptbl_locate(b, p);
    } else if ( func == BU_PTBL_ZERO ) {
	bu_ptbl_zero(b, p);
	return( 0 );
    } else if (func == BU_PTBL_INS_UNIQUE) {
	return bu_ptbl_ins_unique(b, p);
    } else if (func == BU_PTBL_RM) {
	return bu_ptbl_rm(b, p);
    } else if (func == BU_PTBL_CAT) {
	bu_ptbl_cat( b, (const struct bu_ptbl *)p );
	return(0);
    } else if (func == BU_PTBL_FREE) {
	bu_ptbl_free(b);
	return (0);
    } else {
	BU_CK_PTBL(b);
	bu_log("bu_ptbl(%8x) Unknown table function %d\n", b, func);
	bu_bomb("bu_ptbl");
    }
    return(-1);/* this is here to keep lint happy */
}
Пример #2
0
void
diff_free_result(struct diff_result *result)
{
    unsigned int i = 0;
    if (result->obj_name) {
	bu_free(result->obj_name, "free name copy in diff result");
    }
    BU_PUT(result->diff_tol, struct bn_tol);
    for (i = 0; i < BU_PTBL_LEN(result->param_diffs); i++) {
	struct diff_avp *avp = (struct diff_avp *)BU_PTBL_GET(result->param_diffs, i);
	diff_free_avp(avp);
	BU_PUT(avp, struct diff_avp);
    }
    bu_ptbl_free(result->param_diffs);
    BU_PUT(result->param_diffs, struct bu_ptbl);
    for (i = 0; i < BU_PTBL_LEN(result->attr_diffs); i++) {
	struct diff_avp *avp = (struct diff_avp *)BU_PTBL_GET(result->attr_diffs, i);
	diff_free_avp(avp);
	BU_PUT(avp, struct diff_avp);
    }
    bu_ptbl_free(result->attr_diffs);
    BU_PUT(result->attr_diffs, struct bu_ptbl);
}
Пример #3
0
/**
 * R T _ F R E E _ S O L T A B
 *
 * Decrement use count on soltab structure.  If no longer needed,
 * release associated storage, and free the structure.
 *
 * This routine semaphore protects against other copies of itself
 * running in parallel, and against other routines (such as
 * rt_find_identical_solid()) which might also be modifying the linked
 * list heads.
 *
 * Called by -
 *	db_free_tree()
 *	rt_clean()
 *	rt_gettrees()
 *	rt_kill_deal_solid_refs()
 */
void
rt_free_soltab(struct soltab *stp)
{
    int	hash;

    RT_CK_SOLTAB(stp);
    if ( stp->st_id < 0 )
	bu_bomb("rt_free_soltab:  bad st_id");

    hash = db_dirhash(stp->st_dp->d_namep);

    ACQUIRE_SEMAPHORE_TREE(hash);		/* start critical section */
    if ( --(stp->st_uses) > 0 )  {
	RELEASE_SEMAPHORE_TREE(hash);
	return;
    }
    BU_LIST_DEQUEUE( &(stp->l2) );		/* remove from st_dp->d_use_hd list */
    BU_LIST_DEQUEUE( &(stp->l) );		/* uses rti_solidheads[] */

    RELEASE_SEMAPHORE_TREE(hash);		/* end critical section */

    if ( stp->st_aradius > 0 )  {
	stp->st_meth->ft_free( stp );
	stp->st_aradius = 0;
    }
    if ( stp->st_matp )  bu_free( (char *)stp->st_matp, "st_matp");
    stp->st_matp = (matp_t)0;	/* Sanity */

    bu_ptbl_free(&stp->st_regions);

    stp->st_dp = DIR_NULL;		/* Sanity */

    if ( stp->st_path.magic )  {
	RT_CK_FULL_PATH( &stp->st_path );
	db_free_full_path( &stp->st_path );
    }

    bu_free( (char *)stp, "struct soltab" );
}
Пример #4
0
static void
nmg_to_psurf(struct nmgregion *r, FILE *fp_psurf)
/* NMG region to be converted. */
/* Jack format file to write vertex list to. */
{
    int			i;
    int			*map;	/* map from v->index to Jack vert # */
    struct bu_ptbl		vtab;	/* vertex table */

    map = (int *)bu_calloc(r->m_p->maxindex, sizeof(int), "Jack vert map");

    /* Built list of vertex structs */
    nmg_vertex_tabulate( &vtab, &r->l.magic );

    /* FIXME: What to do if 0 vertices?  */

    /* Print list of unique vertices and convert from mm to cm. */
    for (i = 0; i < BU_PTBL_END(&vtab); i++)  {
	struct vertex			*v;
	struct vertex_g	*vg;
	v = (struct vertex *)BU_PTBL_GET(&vtab, i);
	NMG_CK_VERTEX(v);
	vg = v->vg_p;
	NMG_CK_VERTEX_G(vg);
	NMG_INDEX_ASSIGN( map, v, i+1 );  /* map[v->index] = i+1 */
	fprintf(fp_psurf, "%f\t%f\t%f\n",
		vg->coord[X] / 10.,
		vg->coord[Y] / 10.,
		vg->coord[Z] / 10.);
    }
    fprintf(fp_psurf, ";;\n");

    jack_faces(r, fp_psurf, map);

    bu_ptbl_free(&vtab);
    bu_free( (char *)map, "Jack vert map" );
}
Пример #5
0
int
ged_nmg_collapse(struct ged *gedp, int argc, const char *argv[])
{
    char *new_name;
    struct model *m;
    struct rt_db_internal intern;
    struct directory *dp;
    struct bu_ptbl faces;
    struct face *fp;
    size_t count;
    fastf_t tol_coll;
    fastf_t min_angle;
    static const char *usage = "nmg_prim new_prim max_err_dist [min_angle]";

    GED_CHECK_DATABASE_OPEN(gedp, GED_ERROR);
    GED_CHECK_READ_ONLY(gedp, GED_ERROR);
    GED_CHECK_ARGC_GT_0(gedp, argc, GED_ERROR);

    /* initialize result */
    bu_vls_trunc(gedp->ged_result_str, 0);

    /* must be wanting help */
    if (argc == 1) {
	bu_vls_printf(gedp->ged_result_str, "Usage: %s %s", argv[0], usage);
	return GED_HELP;
    }

    if (argc < 4) {
	bu_vls_printf(gedp->ged_result_str, "Usage: %s %s", argv[0], usage);
	return GED_ERROR;
    }

    if (strchr(argv[2], '/')) {
	bu_vls_printf(gedp->ged_result_str, "Do not use '/' in solid names: %s\n", argv[2]);
	return GED_ERROR;
    }

    new_name = (char *)argv[2];

    if (db_lookup(gedp->ged_wdbp->dbip, new_name, LOOKUP_QUIET) != RT_DIR_NULL) {
	bu_vls_printf(gedp->ged_result_str, "%s already exists\n", new_name);
	return GED_ERROR;
    }

    if ((dp=db_lookup(gedp->ged_wdbp->dbip, argv[1], LOOKUP_NOISY)) == RT_DIR_NULL)
	return GED_ERROR;

    if (dp->d_flags & RT_DIR_COMB) {
	bu_vls_printf(gedp->ged_result_str, "%s is a combination, only NMG primitives are allowed here\n", argv[1]);
	return GED_ERROR;
    }

    if (rt_db_get_internal(&intern, dp, gedp->ged_wdbp->dbip, (matp_t)NULL, &rt_uniresource) < 0) {
	bu_vls_printf(gedp->ged_result_str, "Failed to get internal form of %s!!!!\n", argv[1]);
	return GED_ERROR;
    }

    if (intern.idb_type != ID_NMG) {
	bu_vls_printf(gedp->ged_result_str, "%s is not an NMG solid!!!!\n", argv[1]);
	rt_db_free_internal(&intern);
	return GED_ERROR;
    }

    tol_coll = atof(argv[3]) * gedp->ged_wdbp->dbip->dbi_local2base;
    if (tol_coll <= 0.0) {
	bu_vls_printf(gedp->ged_result_str, "tolerance distance too small\n");
	return GED_ERROR;
    }

    if (argc == 5) {
	min_angle = atof(argv[4]);
	if (min_angle < 0.0) {
	    bu_vls_printf(gedp->ged_result_str, "Minimum angle cannot be less than zero\n");
	    return GED_ERROR;
	}
    } else
	min_angle = 0.0;

    m = (struct model *)intern.idb_ptr;
    NMG_CK_MODEL(m);

    /* check that all faces are planar */
    nmg_face_tabulate(&faces, &m->magic);
    for (BU_PTBL_FOR(fp, (struct face *), &faces)) {
	if (fp->g.magic_p != NULL && *(fp->g.magic_p) != NMG_FACE_G_PLANE_MAGIC) {
	    bu_log("\tnot planar\n");
	    bu_ptbl_free(&faces);
	    bu_vls_printf(gedp->ged_result_str,
			  "nmg_collapse can only be applied to NMG primitives with planar faces\n");
	    return GED_ERROR;
	}
    }
    bu_ptbl_free(&faces);

    /* triangulate model */
    nmg_triangulate_model(m, &gedp->ged_wdbp->wdb_tol);

    count = (size_t)nmg_edge_collapse(m, &gedp->ged_wdbp->wdb_tol, tol_coll, min_angle);

    dp=db_diradd(gedp->ged_wdbp->dbip, new_name, RT_DIR_PHONY_ADDR, 0, RT_DIR_SOLID, (void *)&intern.idb_type);
    if (dp == RT_DIR_NULL) {
	bu_vls_printf(gedp->ged_result_str, "Cannot add %s to directory\n", new_name);
	rt_db_free_internal(&intern);
	return GED_ERROR;
    }

    if (rt_db_put_internal(dp, gedp->ged_wdbp->dbip, &intern, &rt_uniresource) < 0) {
	rt_db_free_internal(&intern);
	bu_vls_printf(gedp->ged_result_str, "Database write error, aborting.\n");
	return GED_ERROR;
    }

    rt_db_free_internal(&intern);

    bu_vls_printf(gedp->ged_result_str, "%zu edges collapsed\n", count);

    return GED_OK;
}
Пример #6
0
static void
nmg_to_obj(struct nmgregion *r, struct db_full_path *pathp, int region_id, int aircode, int los, int material_id)
{
    struct model *m;
    struct shell *s;
    struct vertex *v;
    struct bu_ptbl verts;
    struct bu_ptbl norms;
    char *region_name;
    int numverts = 0;		/* Number of vertices to output */
    int numtri   = 0;		/* Number of triangles to output */
    int i;

    NMG_CK_REGION( r );
    RT_CK_FULL_PATH(pathp);

    region_name = db_path_to_string( pathp );

#if 0
    printf("Attempting to process region %s\n", region_name);
    fflush(stdout);
#endif

    m = r->m_p;
    NMG_CK_MODEL( m );

    /* triangulate model */
    nmg_triangulate_model( m, &tol );

    /* list all vertices in result */
    nmg_vertex_tabulate( &verts, &r->l.magic );

    /* Get number of vertices */
    numverts = BU_PTBL_END (&verts);

    /* get list of vertexuse normals */
    if ( do_normals )
	nmg_vertexuse_normal_tabulate( &norms, &r->l.magic );

/* XXX Check vertices, shells faces first? Do not want to punt mid-stream */
/* BEGIN CHECK SECTION */
/* Check vertices */

    for ( i=0; i<numverts; i++ )
    {
	v = (struct vertex *)BU_PTBL_GET( &verts, i );
	NMG_CK_VERTEX( v );
    }

/* Check triangles */
    for ( BU_LIST_FOR( s, shell, &r->s_hd ) )
    {
	struct faceuse *fu;

	NMG_CK_SHELL( s );

	for ( BU_LIST_FOR( fu, faceuse, &s->fu_hd ) )
	{
	    struct loopuse *lu;

	    NMG_CK_FACEUSE( fu );

	    if ( fu->orientation != OT_SAME )
		continue;

	    for ( BU_LIST_FOR( lu, loopuse, &fu->lu_hd ) )
	    {
		struct edgeuse *eu;
		int vert_count=0;

		NMG_CK_LOOPUSE( lu );

		if ( BU_LIST_FIRST_MAGIC( &lu->down_hd ) != NMG_EDGEUSE_MAGIC )
		    continue;

		/* check vertex numbers for each triangle */
		for ( BU_LIST_FOR( eu, edgeuse, &lu->down_hd ) )
		{
		    NMG_CK_EDGEUSE( eu );

		    v = eu->vu_p->v_p;
		    NMG_CK_VERTEX( v );

		    vert_count++;
		    i = bu_ptbl_locate( &verts, (long *)v );
		    if ( i < 0 )
		    {
			/*XXX*/				bu_ptbl_free( &verts);
			/*XXX*/				bu_free( region_name, "region name" );
			bu_log( "Vertex from eu x%x is not in nmgregion x%x\n", eu, r );
			bu_exit(1, "ERROR: Can't find vertex in list!");
		    }
		}
		if ( vert_count > 3 )
		{
		    /*XXX*/			bu_ptbl_free( &verts);
		    /*XXX*/			bu_free( region_name, "region name" );
		    bu_log( "lu x%x has %d vertices!\n", lu, vert_count );
		    bu_exit(1, "ERROR: LU is not a triangle\n");
		}
		else if ( vert_count < 3 )
		    continue;
		numtri++;
	    }
	}
    }

/* END CHECK SECTION */
/* Write pertinent info for this region */

    if ( usemtl )
	fprintf( fp, "usemtl %d_%d_%d\n", aircode, los, material_id );

    fprintf( fp, "g %s", pathp->fp_names[0]->d_namep );
    for ( i=1; i<pathp->fp_len; i++ )
	fprintf( fp, "/%s", pathp->fp_names[i]->d_namep );
    fprintf( fp, "\n" );

    /* Write vertices */
    for ( i=0; i<numverts; i++ )
    {
	v = (struct vertex *)BU_PTBL_GET( &verts, i );
	NMG_CK_VERTEX( v );
	if (inches)
	    fprintf( fp, "v %f %f %f\n", V3ARGSIN( v->vg_p->coord ));
	else
	    fprintf( fp, "v %f %f %f\n", V3ARGS( v->vg_p->coord ));
    }

    /* Write vertexuse normals */
    if ( do_normals )
    {
	for ( i=0; i<BU_PTBL_END( &norms ); i++ )
	{
	    struct vertexuse_a_plane *va;

	    va = (struct vertexuse_a_plane *)BU_PTBL_GET( &norms, i );
	    NMG_CK_VERTEXUSE_A_PLANE( va );
	    if (inches)
		fprintf( fp, "vn %f %f %f\n", V3ARGSIN( va->N ));
	    else
		fprintf( fp, "vn %f %f %f\n", V3ARGS( va->N ));
	}
    }

    /* output triangles */
    for ( BU_LIST_FOR( s, shell, &r->s_hd ) )
    {
	struct faceuse *fu;

	NMG_CK_SHELL( s );

	for ( BU_LIST_FOR( fu, faceuse, &s->fu_hd ) )
	{
	    struct loopuse *lu;

	    NMG_CK_FACEUSE( fu );

	    if ( fu->orientation != OT_SAME )
		continue;

	    for ( BU_LIST_FOR( lu, loopuse, &fu->lu_hd ) )
	    {
		struct edgeuse *eu;
		int vert_count=0;
		int use_normals=1;

		NMG_CK_LOOPUSE( lu );

		if ( BU_LIST_FIRST_MAGIC( &lu->down_hd ) != NMG_EDGEUSE_MAGIC )
		    continue;

		/* Each vertexuse of the face must have a normal in order
		 * to use the normals in Wavefront
		 */
		if ( do_normals )
		{
		    for ( BU_LIST_FOR( eu, edgeuse, &lu->down_hd ) )
		    {
			NMG_CK_EDGEUSE( eu );

			if ( !eu->vu_p->a.magic_p )
			{
			    use_normals = 0;
			    break;
			}

			if ( *eu->vu_p->a.magic_p != NMG_VERTEXUSE_A_PLANE_MAGIC )
			{
			    use_normals = 0;
			    break;
			}
		    }
		}
		else
		    use_normals = 0;

		fprintf( fp, "f" );

		/* list vertex numbers for each triangle */
		for ( BU_LIST_FOR( eu, edgeuse, &lu->down_hd ) )
		{
		    NMG_CK_EDGEUSE( eu );

		    v = eu->vu_p->v_p;
		    NMG_CK_VERTEX( v );

		    vert_count++;
		    i = bu_ptbl_locate( &verts, (long *)v );
		    if ( i < 0 )
		    {
			bu_ptbl_free( &verts);
			bu_log( "Vertex from eu x%x is not in nmgregion x%x\n", eu, r );
			/*XXX*/				bu_free( region_name, "region name" );
			/*XXX*/				bu_exit(1, "Can't find vertex in list!\n");
		    }

		    if ( use_normals )
		    {
			int j;

			j = bu_ptbl_locate( &norms, (long *)eu->vu_p->a.magic_p );
			fprintf( fp, " %ld//%ld", i+1+vert_offset, j+1+norm_offset );
		    }
		    else
			fprintf( fp, " %ld", i+1+vert_offset );
		}

		fprintf( fp, "\n" );

		if ( vert_count > 3 )
		{
		    bu_ptbl_free( &verts);
		    bu_free( region_name, "region name" );
		    bu_log( "lu x%x has %d vertices!\n", lu, vert_count );
		    bu_exit(1, "ERROR: LU is not a triangle\n" );
		}
	    }
	}
    }
Пример #7
0
int
main(int argc, char **argv)
{
    int i = 0;
    int diff_state = 0;
    struct bu_ptbl results;
    struct db_i *dbip1 = DBI_NULL;
    struct db_i *dbip2 = DBI_NULL;
    /*struct bu_vls diff_log = BU_VLS_INIT_ZERO;*/
    struct bn_tol *diff_tol;
    BU_GET(diff_tol, struct bn_tol);
    diff_tol->dist = BN_TOL_DIST;

    BU_PTBL_INIT(&results);

    if (argc != 3) {
	bu_log("Error - please specify two .g files\n");
	bu_exit(EXIT_FAILURE, NULL);
    }

    if (!bu_file_exists(argv[1], NULL)) {
	bu_exit(1, "Cannot stat file %s\n", argv[1]);
    }

    if (!bu_file_exists(argv[2], NULL)) {
	bu_exit(1, "Cannot stat file %s\n", argv[2]);
    }

    if ((dbip1 = db_open(argv[1], DB_OPEN_READONLY)) == DBI_NULL) {
	bu_exit(1, "Cannot open geometry database file %s\n", argv[1]);
    }
    RT_CK_DBI(dbip1);
    if (db_dirbuild(dbip1) < 0) {
	db_close(dbip1);
	bu_exit(1, "db_dirbuild failed on geometry database file %s\n", argv[1]);
    }

    /* Reset the material head so we don't get warnings when the global
     * is overwritten.  This will go away when material_head ceases to
     * be a librt global.*/
    rt_new_material_head(MATER_NULL);

    if ((dbip2 = db_open(argv[2], DB_OPEN_READONLY)) == DBI_NULL) {
	bu_exit(1, "Cannot open geometry database file %s\n", argv[2]);
    }
    RT_CK_DBI(dbip2);
    if (db_dirbuild(dbip2) < 0) {
	db_close(dbip1);
	db_close(dbip2);
	bu_exit(1, "db_dirbuild failed on geometry database file %s\n", argv[1]);
    }


    diff_state = db_diff(dbip1, dbip2, diff_tol, DB_COMPARE_ALL, &results);
    if (diff_state == DIFF_UNCHANGED) {
	bu_log("No differences found.\n");
    } else {
	print_diff_summary(&results);
    }

    for (i = 0; i < (int)BU_PTBL_LEN(&results); i++) {
	struct diff_result *result = (struct diff_result *)BU_PTBL_GET(&results, i);
	diff_free_result(result);
    }

    bu_ptbl_free(&results);
    BU_PUT(diff_tol, struct bn_tol);

    db_close(dbip1);
    db_close(dbip2);
    return 0;
}
Пример #8
0
static int
selection_command(
	struct ged *gedp,
	struct rt_db_internal *ip,
	int argc,
	const char *argv[])
{
    int i;
    struct rt_selection_set *selection_set;
    struct bu_ptbl *selections;
    struct rt_selection *new_selection;
    struct rt_selection_query query;
    const char *cmd, *solid_name, *selection_name;

    /*  0         1          2         3
     * brep <solid_name> selection subcommand
     */
    if (argc < 4) {
	return -1;
    }

    solid_name = argv[1];
    cmd = argv[3];

    if (BU_STR_EQUAL(cmd, "append")) {
	/* append to named selection - selection is created if it doesn't exist */
	void (*free_selection)(struct rt_selection *);

	/*        4         5      6      7     8    9    10
	 * selection_name startx starty startz dirx diry dirz
	 */
	if (argc != 11) {
	    bu_log("wrong args for selection append");
	    return -1;
	}
	selection_name = argv[4];

	/* find matching selections */
	query.start[X] = atof(argv[5]);
	query.start[Y] = atof(argv[6]);
	query.start[Z] = atof(argv[7]);
	query.dir[X] = atof(argv[8]);
	query.dir[Y] = atof(argv[9]);
	query.dir[Z] = atof(argv[10]);
	query.sorting = RT_SORT_CLOSEST_TO_START;

	selection_set = ip->idb_meth->ft_find_selections(ip, &query);
	if (!selection_set) {
	    bu_log("no matching selections");
	    return -1;
	}

	/* could be multiple options, just grabbing the first and
	 * freeing the rest
	 */
	selections = &selection_set->selections;
	new_selection = (struct rt_selection *)BU_PTBL_GET(selections, 0);

	free_selection = selection_set->free_selection;
	for (i = BU_PTBL_LEN(selections) - 1; i > 0; --i) {
	    long *s = BU_PTBL_GET(selections, i);
	    free_selection((struct rt_selection *)s);
	    bu_ptbl_rm(selections, s);
	}
	bu_ptbl_free(selections);
	BU_FREE(selection_set, struct rt_selection_set);

	/* get existing/new selections set in gedp */
	selection_set = ged_get_selection_set(gedp, solid_name, selection_name);
	selection_set->free_selection = free_selection;
	selections = &selection_set->selections;

	/* TODO: Need to implement append by passing new and
	 * existing selection to an rt_brep_evaluate_selection.
	 * For now, new selection simply replaces old one.
	 */
	for (i = BU_PTBL_LEN(selections) - 1; i >= 0; --i) {
	    long *s = BU_PTBL_GET(selections, i);
	    free_selection((struct rt_selection *)s);
	    bu_ptbl_rm(selections, s);
	}
	bu_ptbl_ins(selections, (long *)new_selection);
    } else if (BU_STR_EQUAL(cmd, "translate")) {
	struct rt_selection_operation operation;

	/*        4       5  6  7
	 * selection_name dx dy dz
	 */
	if (argc != 8) {
	    return -1;
	}
	selection_name = argv[4];

	selection_set = ged_get_selection_set(gedp, solid_name, selection_name);
	selections = &selection_set->selections;

	if (BU_PTBL_LEN(selections) < 1) {
	    return -1;
	}

	for (i = 0; i < (int)BU_PTBL_LEN(selections); ++i) {
	    int ret;
	    operation.type = RT_SELECTION_TRANSLATION;
	    operation.parameters.tran.dx = atof(argv[5]);
	    operation.parameters.tran.dy = atof(argv[6]);
	    operation.parameters.tran.dz = atof(argv[7]);

	    ret = ip->idb_meth->ft_process_selection(ip, gedp->ged_wdbp->dbip,
		    (struct rt_selection *)BU_PTBL_GET(selections, i), &operation);

	    if (ret != 0) {
		return ret;
	    }
	}
    }

    return 0;
}
Пример #9
0
void
db_close(register struct db_i *dbip)
{
    register int i;
    register struct directory *dp, *nextdp;

    if (!dbip)
	return;

    RT_CK_DBI(dbip);
    if (RT_G_DEBUG&DEBUG_DB) bu_log("db_close(%s) %p uses=%d\n",
				    dbip->dbi_filename, (void *)dbip, dbip->dbi_uses);

    bu_semaphore_acquire(BU_SEM_LISTS);
    if ((--dbip->dbi_uses) > 0) {
	bu_semaphore_release(BU_SEM_LISTS);
	/* others are still using this database */
	return;
    }
    bu_semaphore_release(BU_SEM_LISTS);

    /* ready to free the database -- use count is now zero */

    /* free up any mapped files */
    if (dbip->dbi_mf) {
	/*
	 * We're using an instance of a memory mapped file.
	 * We have two choices:
	 * Either dissociate from the memory mapped file
	 * by clearing dbi_mf->apbuf, or
	 * keeping our already-scanned dbip ready for
	 * further use, with our dbi_uses counter at 0.
	 * For speed of re-open, at the price of some address space,
	 * the second choice is taken.
	 */
	bu_close_mapped_file(dbip->dbi_mf);
	bu_free_mapped_files(0);
	dbip->dbi_mf = (struct bu_mapped_file *)NULL;
    }

    /* try to ensure/encourage that the file is written out */
    db_sync(dbip);

    if (dbip->dbi_fp) {
	fclose(dbip->dbi_fp);
    }

    if (dbip->dbi_title)
	bu_free(dbip->dbi_title, "dbi_title");
    if (dbip->dbi_filename)
	bu_free(dbip->dbi_filename, "dbi_filename");

    db_free_anim(dbip);
    rt_color_free();		/* Free MaterHead list */

    /* Release map of database holes */
    rt_mempurge(&(dbip->dbi_freep));
    rt_memclose();

    dbip->dbi_inmem = NULL;		/* sanity */

    bu_ptbl_free(&dbip->dbi_clients);

    /* Free all directory entries */
    for (i = 0; i < RT_DBNHASH; i++) {
	for (dp = dbip->dbi_Head[i]; dp != RT_DIR_NULL;) {
	    RT_CK_DIR(dp);
	    nextdp = dp->d_forw;
	    RT_DIR_FREE_NAMEP(dp);	/* frees d_namep */

	    if ((dp->d_flags & RT_DIR_INMEM) && (dp->d_un.ptr != NULL)) {
		bu_free(dp->d_un.ptr, "db_close d_un.ptr");
		dp->d_un.ptr = NULL;
		dp->d_len    = 0;
	    }

	    /* Put 'dp' back on the freelist */
	    dp->d_forw = rt_uniresource.re_directory_hd;
	    rt_uniresource.re_directory_hd = dp;

	    /* null'ing the forward pointer here is a huge
	     * memory leak as it causes the loss of all
	     * nodes on the freelist except the first.
	     * (so don't do it)
	     */

	    dp = nextdp;
	}
	dbip->dbi_Head[i] = RT_DIR_NULL;	/* sanity*/
    }

    if (dbip->dbi_filepath != NULL) {
	bu_free_argv(2, dbip->dbi_filepath);
	dbip->dbi_filepath = NULL; /* sanity */
    }

    bu_free((char *)dbip, "struct db_i");
}
Пример #10
0
static void
nmg_to_dxf(struct nmgregion *r, const struct db_full_path *pathp, int UNUSED(region_id), int UNUSED(material_id), float color[3])
{
    struct model *m;
    struct shell *s;
    struct vertex *v;
    struct bu_ptbl verts;
    char *region_name;
    int region_polys=0;
    int tri_count=0;
    int color_num;
    int do_triangulate=0;

    NMG_CK_REGION(r);
    RT_CK_FULL_PATH(pathp);

    region_name = db_path_to_string(pathp);

    m = r->m_p;
    NMG_CK_MODEL(m);

    /* Count triangles */
    for (BU_LIST_FOR(s, shell, &r->s_hd)) {
	struct faceuse *fu;

	NMG_CK_SHELL(s);

	for (BU_LIST_FOR(fu, faceuse, &s->fu_hd)) {
	    struct loopuse *lu;
	    int vert_count=0;

	    NMG_CK_FACEUSE(fu);

	    if (fu->orientation != OT_SAME)
		continue;

	    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		struct edgeuse *eu;

		if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC)
		    continue;

		for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
		    vert_count++;
		}

		if (vert_count > 3) {
		    do_triangulate = 1;
		    goto triangulate;
		}

		tri_count++;
	    }
	}
    }

 triangulate:
    if (do_triangulate) {
	/* triangulate model */
	nmg_triangulate_model(m, &tol);

	/* Count triangles */
	tri_count = 0;
	for (BU_LIST_FOR(s, shell, &r->s_hd)) {
	    struct faceuse *fu;

	    for (BU_LIST_FOR(fu, faceuse, &s->fu_hd)) {
		struct loopuse *lu;

		if (fu->orientation != OT_SAME)
		    continue;

		for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		    if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC)
			continue;

		    tri_count++;
		}
	    }
	}
    }

    nmg_vertex_tabulate(&verts, &r->l.magic);

    color_num = find_closest_color(color);

    if (polyface_mesh) {
	size_t i;


	fprintf(fp, "0\nPOLYLINE\n8\n%s\n62\n%d\n70\n64\n71\n%lu\n72\n%d\n",
		 region_name, color_num, (unsigned long)BU_PTBL_LEN(&verts), tri_count);
	for (i = 0; i < BU_PTBL_LEN(&verts); i++) {
	    fprintf(fp, "0\nVERTEX\n8\n%s\n", region_name);
	    v = (struct vertex *)BU_PTBL_GET(&verts, i);
	    NMG_CK_VERTEX(v);
	    if (inches) {
		fprintf(fp, "10\n%f\n20\n%f\n30\n%f\n70\n192\n", V3ARGSIN(v->vg_p->coord));
	    } else {
		fprintf(fp, "10\n%f\n20\n%f\n30\n%f\n70\n192\n", V3ARGS(v->vg_p->coord));
	    }
	}
    }

    /* Check triangles */
    for (BU_LIST_FOR(s, shell, &r->s_hd)) {
	struct faceuse *fu;

	NMG_CK_SHELL(s);

	for (BU_LIST_FOR(fu, faceuse, &s->fu_hd)) {
	    struct loopuse *lu;

	    NMG_CK_FACEUSE(fu);

	    if (fu->orientation != OT_SAME)
		continue;

	    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		struct edgeuse *eu;
		int vert_count=0;

		NMG_CK_LOOPUSE(lu);

		if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC)
		    continue;

		if (polyface_mesh) {
		    fprintf(fp, "0\nVERTEX\n8\n%s\n70\n128\n10\n0.0\n20\n0.0\n30\n0.0\n",
			     region_name);
		} else {
		    fprintf(fp, "0\n3DFACE\n8\n%s\n62\n%d\n", region_name, color_num);
		}

		/* check vertex numbers for each triangle */
		for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
		    NMG_CK_EDGEUSE(eu);

		    vert_count++;

		    v = eu->vu_p->v_p;
		    NMG_CK_VERTEX(v);

		    if (polyface_mesh) {
			fprintf(fp, "%d\n%d\n",
				 vert_count+70, bu_ptbl_locate(&verts, (long *)v) + 1);
		    } else {
			if (inches) {
			    fprintf(fp, "%d\n%f\n%d\n%f\n%d\n%f\n",
				     10 + vert_count - 1,
				     v->vg_p->coord[X] / 25.4,
				     20 + vert_count - 1,
				     v->vg_p->coord[Y] / 25.4,
				     30 + vert_count -1,
				     v->vg_p->coord[Z] / 25.4);
			} else {
			    fprintf(fp, "%d\n%f\n%d\n%f\n%d\n%f\n",
				     10 + vert_count - 1,
				     v->vg_p->coord[X],
				     20 + vert_count - 1,
				     v->vg_p->coord[Y],
				     30 + vert_count -1,
				     v->vg_p->coord[Z]);
			}
		    }
		}
		if (vert_count > 3) {
		    bu_free(region_name, "region name");
		    bu_log("lu %p has %d vertices!\n", (void *)lu, vert_count);
		    bu_exit(1, "ERROR: LU is not a triangle\n");
		} else if (vert_count < 3) {
		    continue;
		} else {
		    /* repeat the last vertex for the benefit of codes
		     * that interpret the dxf specification for
		     * 3DFACES as requiring a fourth vertex even when
		     * only three are input.
		     */
		    if (!polyface_mesh) {
			vert_count++;
			if (inches) {
			    fprintf(fp, "%d\n%f\n%d\n%f\n%d\n%f\n",
				     10 + vert_count - 1,
				     v->vg_p->coord[X] / 25.4,
				     20 + vert_count - 1,
				     v->vg_p->coord[Y] / 25.4,
				     30 + vert_count -1,
				     v->vg_p->coord[Z] / 25.4);
			} else {
			    fprintf(fp, "%d\n%f\n%d\n%f\n%d\n%f\n",
				     10 + vert_count - 1,
				     v->vg_p->coord[X],
				     20 + vert_count - 1,
				     v->vg_p->coord[Y],
				     30 + vert_count -1,
				     v->vg_p->coord[Z]);
			}
		    }
		}

		tot_polygons++;
		region_polys++;
	    }
	}
    }

    bu_ptbl_free(&verts);
    bu_free(region_name, "region name");

    if (polyface_mesh) {
	fprintf(fp, "0\nSEQEND\n");
    }

}
Пример #11
0
int
ged_draw_guts(struct ged *gedp, int argc, const char *argv[], int kind)
{
    size_t i;
    int drawtrees_retval;
    int flag_A_attr=0;
    int flag_o_nonunique=1;
    int last_opt=0;
    struct bu_vls vls = BU_VLS_INIT_ZERO;
    static const char *usage = "<[-R -C#/#/# -s] objects> | <-o -A attribute name/value pairs>";

/* #define DEBUG_TIMING 1 */

#ifdef DEBUG_TIMING
    int64_t elapsedtime;
#endif

    GED_CHECK_DATABASE_OPEN(gedp, GED_ERROR);
    GED_CHECK_DRAWABLE(gedp, GED_ERROR);
    GED_CHECK_ARGC_GT_0(gedp, argc, GED_ERROR);

    /* initialize result */
    bu_vls_trunc(gedp->ged_result_str, 0);

    /* must be wanting help */
    if (argc == 1) {
	bu_vls_printf(gedp->ged_result_str, "Usage: %s %s", argv[0], usage);
	return GED_HELP;
    }

#ifdef DEBUG_TIMING
    elapsedtime = bu_gettime();
#endif

    /* skip past cmd */
    --argc;
    ++argv;

    /* check args for "-A" (attributes) and "-o" */
    for (i = 0; i < (size_t)argc; i++) {
	char *ptr_A=NULL;
	char *ptr_o=NULL;
	char *c;

	if (*argv[i] != '-') {
	    /* Done checking options. If our display is non-empty,
	     * add -R to keep current view.
	     */
	    if (BU_LIST_NON_EMPTY(gedp->ged_gdp->gd_headDisplay)) {
		bu_vls_strcat(&vls, " -R");
	    }
	    break;
	}

	ptr_A=strchr(argv[i], 'A');
	if (ptr_A)
	    flag_A_attr = 1;

	ptr_o=strchr(argv[i], 'o');
	if (ptr_o)
	    flag_o_nonunique = 2;

	last_opt = i;

	if (!ptr_A && !ptr_o) {
	    bu_vls_putc(&vls, ' ');
	    bu_vls_strcat(&vls, argv[i]);
	    continue;
	}

	if (strlen(argv[i]) == ((size_t)1 + (ptr_A != NULL) + (ptr_o != NULL))) {
	    /* argv[i] is just a "-A" or "-o" */
	    continue;
	}

	/* copy args other than "-A" or "-o" */
	bu_vls_putc(&vls, ' ');
	c = (char *)argv[i];
	while (*c != '\0') {
	    if (*c != 'A' && *c != 'o') {
		bu_vls_putc(&vls, *c);
	    }
	    c++;
	}
    }

    if (flag_A_attr) {
	/* args are attribute name/value pairs */
	struct bu_attribute_value_set avs;
	int max_count=0;
	int remaining_args=0;
	int new_argc=0;
	char **new_argv=NULL;
	struct bu_ptbl *tbl;

	remaining_args = argc - last_opt - 1;
	if (remaining_args < 2 || remaining_args%2) {
	    bu_vls_printf(gedp->ged_result_str, "Error: must have even number of arguments (name/value pairs)\n");
	    bu_vls_free(&vls);
	    return GED_ERROR;
	}

	bu_avs_init(&avs, (argc - last_opt)/2, "ged_draw_guts avs");
	i = 0;
	while (i < (size_t)argc) {
	    if (*argv[i] == '-') {
		i++;
		continue;
	    }

	    /* this is a name/value pair */
	    if (flag_o_nonunique == 2) {
		bu_avs_add_nonunique(&avs, argv[i], argv[i+1]);
	    } else {
		bu_avs_add(&avs, argv[i], argv[i+1]);
	    }
	    i += 2;
	}

	tbl = db_lookup_by_attr(gedp->ged_wdbp->dbip, RT_DIR_REGION | RT_DIR_SOLID | RT_DIR_COMB, &avs, flag_o_nonunique);
	bu_avs_free(&avs);
	if (!tbl) {
	    bu_log("Error: db_lookup_by_attr() failed!!\n");
	    bu_vls_free(&vls);
	    return TCL_ERROR;
	}
	if (BU_PTBL_LEN(tbl) < 1) {
	    /* nothing matched, just return */
	    bu_vls_free(&vls);
	    return TCL_OK;
	}
	for (i = 0; i < BU_PTBL_LEN(tbl); i++) {
	    struct directory *dp;

	    dp = (struct directory *)BU_PTBL_GET(tbl, i);
	    bu_vls_putc(&vls, ' ');
	    bu_vls_strcat(&vls, dp->d_namep);
	}

	max_count = BU_PTBL_LEN(tbl) + last_opt + 1;
	bu_ptbl_free(tbl);
	bu_free((char *)tbl, "ged_draw_guts ptbl");
	new_argv = (char **)bu_calloc(max_count+1, sizeof(char *), "ged_draw_guts new_argv");
	new_argc = bu_argv_from_string(new_argv, max_count, bu_vls_addr(&vls));

	/* First, delete any mention of these objects.
	 * Silently skip any leading options (which start with minus signs).
	 */
	for (i = 0; i < (size_t)new_argc; ++i) {
	    /* Skip any options */
	    if (new_argv[i][0] == '-') {
		/* If this option requires an argument which was
		 * provided separately (e.g. '-C 0/255/0' instead of
		 * '-C0/255/0'), skip the argument too.
		 */
		if (strlen(argv[i]) == 2 && strchr("mxCP", argv[i][1])) {
		    i++;
		}
		continue;
	    }

	    dl_erasePathFromDisplay(gedp->ged_gdp->gd_headDisplay, gedp->ged_wdbp->dbip, gedp->ged_free_vlist_callback, new_argv[i], 0, gedp->freesolid);
	}

	drawtrees_retval = _ged_drawtrees(gedp, new_argc, (const char **)new_argv, kind, (struct _ged_client_data *)0);
	bu_vls_free(&vls);
	bu_free((char *)new_argv, "ged_draw_guts new_argv");
	if (drawtrees_retval) {
	    return GED_ERROR;
	}
    } else {
	int empty_display;
	bu_vls_free(&vls);

	empty_display = 1;
	if (BU_LIST_NON_EMPTY(gedp->ged_gdp->gd_headDisplay)) {
	    empty_display = 0;
	}

	/* First, delete any mention of these objects.
	 * Silently skip any leading options (which start with minus signs).
	 */
	for (i = 0; i < (size_t)argc; ++i) {
	    /* Skip any options */
	    if (argv[i][0] == '-') {
		/* If this option requires an argument which was
		 * provided separately (e.g. '-C 0/255/0' instead of
		 * '-C0/255/0'), skip the argument too.
		 */
		if (strlen(argv[i]) == 2 && strchr("mxCP", argv[i][1])) {
		    i++;
		}
		continue;
	    }

	    dl_erasePathFromDisplay(gedp->ged_gdp->gd_headDisplay, gedp->ged_wdbp->dbip, gedp->ged_free_vlist_callback, argv[i], 0, gedp->freesolid);
	}

	/* if our display is non-empty add -R to keep current view */
	if (!empty_display) {
	    int new_argc;
	    char **new_argv;

	    new_argc = argc + 1;
	    new_argv = (char **)bu_malloc(new_argc * sizeof(char *), "ged_draw_guts new_argv");

	    new_argv[0] = bu_strdup("-R");
	    for (i = 0; i < (size_t)argc; ++i) {
		new_argv[i + 1] = bu_strdup(argv[i]);
	    }

	    drawtrees_retval = _ged_drawtrees(gedp, new_argc, (const char **)new_argv, kind, (struct _ged_client_data *)0);

	    for (i = 0; i < (size_t)new_argc; ++i) {
		bu_free(new_argv[i], "ged_draw_guts new_argv[i] - bu_strdup(argv[i])");
	    }
	    bu_free(new_argv, "ged_draw_guts new_argv");
	} else {
	    drawtrees_retval = _ged_drawtrees(gedp, argc, argv, kind, (struct _ged_client_data *)0);
	}
	if (drawtrees_retval) {
	    return GED_ERROR;
	}
    }

#ifdef DEBUG_TIMING
    elapsedtime = bu_gettime() - elapsedtime;
    {
	int seconds = elapsedtime / 1000000;
	int minutes = seconds / 60;
	int hours = minutes / 60;

	minutes = minutes % 60;
	seconds = seconds %60;

	bu_vls_printf(gedp->ged_result_str, "Elapsed time: %02d:%02d:%02d\n", hours, minutes, seconds);
    }
#endif

    return GED_OK;
}
/* 0 = no difference within tolerance, 1 = difference >= tolerance */
int
analyze_raydiff(/* TODO - decide what to return.  Probably some sort of left, common, right segment sets.  See what rtcheck does... */
	struct db_i *dbip, const char *obj1, const char *obj2, struct bn_tol *tol)
{
    int ret;
    int count = 0;
    struct rt_i *rtip;
    int ncpus = bu_avail_cpus();
    point_t min, mid, max;
    struct rt_pattern_data *xdata, *ydata, *zdata;
    fastf_t *rays;
    struct raydiff_container *state;

    if (!dbip || !obj1 || !obj2 || !tol) return 0;

    rtip = rt_new_rti(dbip);
    if (rt_gettree(rtip, obj1) < 0) return -1;
    if (rt_gettree(rtip, obj2) < 0) return -1;
    rt_prep_parallel(rtip, 1);


    /* Now we've got the bounding box - set up the grids */
    VMOVE(min, rtip->mdl_min);
    VMOVE(max, rtip->mdl_max);
    VSET(mid, (max[0] - min[0])/2, (max[1] - min[1])/2, (max[2] - min[2])/2);

    BU_GET(xdata, struct rt_pattern_data);
    VSET(xdata->center_pt, min[0] - 0.1 * min[0], mid[1], mid[2]);
    VSET(xdata->center_dir, 1, 0, 0);
    xdata->vn = 2;
    xdata->pn = 2;
    xdata->n_vec = (vect_t *)bu_calloc(xdata->vn + 1, sizeof(vect_t), "vects array");
    xdata->n_p = (fastf_t *)bu_calloc(xdata->pn + 1, sizeof(fastf_t), "params array");
    xdata->n_p[0] = 50; /* TODO - get tolerances from caller */
    xdata->n_p[1] = 50;
    VSET(xdata->n_vec[0], 0, max[1], 0);
    VSET(xdata->n_vec[1], 0, 0, max[2]);
    ret = rt_pattern(xdata, RT_PATTERN_RECT_ORTHOGRID);
    bu_free(xdata->n_vec, "x vec inputs");
    bu_free(xdata->n_p, "x p inputs");
    if (ret < 0) return -1;


    BU_GET(ydata, struct rt_pattern_data);
    VSET(ydata->center_pt, mid[0], min[1] - 0.1 * min[1], mid[2]);
    VSET(ydata->center_dir, 0, 1, 0);
    ydata->vn = 2;
    ydata->pn = 2;
    ydata->n_vec = (vect_t *)bu_calloc(ydata->vn + 1, sizeof(vect_t), "vects array");
    ydata->n_p = (fastf_t *)bu_calloc(ydata->pn + 1, sizeof(fastf_t), "params array");
    ydata->n_p[0] = 50; /* TODO - get tolerances from caller */
    ydata->n_p[1] = 50;
    VSET(ydata->n_vec[0], max[0], 0, 0);
    VSET(ydata->n_vec[1], 0, 0, max[2]);
    ret = rt_pattern(ydata, RT_PATTERN_RECT_ORTHOGRID);
    bu_free(ydata->n_vec, "y vec inputs");
    bu_free(ydata->n_p, "y p inputs");
    if (ret < 0) return -1;

    BU_GET(zdata, struct rt_pattern_data);
    VSET(zdata->center_pt, mid[0], mid[1], min[2] - 0.1 * min[2]);
    VSET(zdata->center_dir, 0, 0, 1);
    zdata->vn = 2;
    zdata->pn = 2;
    zdata->n_vec = (vect_t *)bu_calloc(zdata->vn + 1, sizeof(vect_t), "vects array");
    zdata->n_p = (fastf_t *)bu_calloc(zdata->pn + 1, sizeof(fastf_t), "params array");
    zdata->n_p[0] = 50; /* TODO - get tolerances from caller */
    zdata->n_p[1] = 50;
    VSET(zdata->n_vec[0], max[0], 0, 0);
    VSET(zdata->n_vec[1], 0, max[1], 0);
    ret = rt_pattern(zdata, RT_PATTERN_RECT_ORTHOGRID);
    bu_free(zdata->n_vec, "x vec inputs");
    bu_free(zdata->n_p, "x p inputs");
    if (ret < 0) return -1;

    /* Consolidate the grids into a single ray array */
    {
	size_t i, j;
	rays = (fastf_t *)bu_calloc((xdata->ray_cnt + ydata->ray_cnt + zdata->ray_cnt + 1) * 6, sizeof(fastf_t), "rays");
	count = 0;
	for (i = 0; i < xdata->ray_cnt; i++) {
	    for (j = 0; j < 6; j++) {
		rays[6*count+j] = xdata->rays[6*i + j];
	    }
	    count++;
	}
	for (i = 0; i < ydata->ray_cnt; i++) {
	    for (j = 0; j < 6; j++) {
		rays[6*count+j] = ydata->rays[6*i + j];
	    }
	    count++;
	}
	for (i = 0; i < zdata->ray_cnt; i++) {
	    for (j = 0; j < 6; j++) {
		rays[6*count+j] = zdata->rays[6*i+j];
	    }
	    count++;
	}

    }
    bu_free(xdata->rays, "x rays");
    bu_free(ydata->rays, "y rays");
    bu_free(zdata->rays, "z rays");
    BU_PUT(xdata, struct rt_pattern_data);
    BU_PUT(ydata, struct rt_pattern_data);
    BU_PUT(zdata, struct rt_pattern_data);

    bu_log("ray cnt: %d\n", count);

    {
	int i, j;
	ncpus = 2;
	state = (struct raydiff_container *)bu_calloc(ncpus+1, sizeof(struct raydiff_container), "resources");
	for (i = 0; i < ncpus+1; i++) {
	    state[i].rtip = rtip;
	    state[i].tol = 0.5;
	    state[i].ncpus = ncpus;
	    state[i].left_name = bu_strdup(obj1);
	    state[i].right_name = bu_strdup(obj2);
	    BU_GET(state[i].resp, struct resource);
	    rt_init_resource(state[i].resp, i, state->rtip);
	    BU_GET(state[i].left, struct bu_ptbl);
	    bu_ptbl_init(state[i].left, 64, "left solid hits");
	    BU_GET(state[i].both, struct bu_ptbl);
	    bu_ptbl_init(state[i].both, 64, "hits on both solids");
	    BU_GET(state[i].right, struct bu_ptbl);
	    bu_ptbl_init(state[i].right, 64, "right solid hits");
	    state[i].rays_cnt = count;
	    state[i].rays = rays;
	}
	bu_parallel(raydiff_gen_worker, ncpus, (void *)state);

	/* Collect and print all of the results */
	for (i = 0; i < ncpus+1; i++) {
	    for (j = 0; j < (int)BU_PTBL_LEN(state[i].left); j++) {
		struct diff_seg *dseg = (struct diff_seg *)BU_PTBL_GET(state[i].left, j);
		bu_log("Result: LEFT diff vol (%s): %g %g %g -> %g %g %g\n", obj1, V3ARGS(dseg->in_pt), V3ARGS(dseg->out_pt));
	    }
	    for (j = 0; j < (int)BU_PTBL_LEN(state[i].both); j++) {
		struct diff_seg *dseg = (struct diff_seg *)BU_PTBL_GET(state[i].both, j);
		bu_log("Result: BOTH): %g %g %g -> %g %g %g\n", V3ARGS(dseg->in_pt), V3ARGS(dseg->out_pt));
	    }
	    for (j = 0; j < (int)BU_PTBL_LEN(state[i].right); j++) {
		struct diff_seg *dseg = (struct diff_seg *)BU_PTBL_GET(state[i].right, j);
		bu_log("Result: RIGHT diff vol (%s): %g %g %g -> %g %g %g\n", obj2, V3ARGS(dseg->in_pt), V3ARGS(dseg->out_pt));
	    }
	}

	/* Free results */
	for (i = 0; i < ncpus+1; i++) {
	    for (j = 0; j < (int)BU_PTBL_LEN(state[i].left); j++) {
		struct diff_seg *dseg = (struct diff_seg *)BU_PTBL_GET(state[i].left, j);
		BU_PUT(dseg, struct diff_seg);
	    }
	    bu_ptbl_free(state[i].left);
	    BU_PUT(state[i].left, struct diff_seg);
	    for (j = 0; j < (int)BU_PTBL_LEN(state[i].both); j++) {
		struct diff_seg *dseg = (struct diff_seg *)BU_PTBL_GET(state[i].both, j);
		BU_PUT(dseg, struct diff_seg);
	    }
	    bu_ptbl_free(state[i].both);
	    BU_PUT(state[i].both, struct diff_seg);
	    for (j = 0; j < (int)BU_PTBL_LEN(state[i].right); j++) {
		struct diff_seg *dseg = (struct diff_seg *)BU_PTBL_GET(state[i].right, j);
		BU_PUT(dseg, struct diff_seg);
	    }
	    bu_ptbl_free(state[i].right);
	    BU_PUT(state[i].right, struct diff_seg);

	    bu_free((void *)state[i].left_name, "left name");
	    bu_free((void *)state[i].right_name, "right name");
	    BU_PUT(state[i].resp, struct resource);
	}
	bu_free(state, "free state containers");
    }
    return 0;
}
HIDDEN int
nmg_brep_face(ON_Brep **b, const struct faceuse *fu, const struct bn_tol *tol, long *brepi) {
    const struct face_g_plane *fg = fu->f_p->g.plane_p;
    struct bu_ptbl vert_table;
    struct vertex **pt;
    int ret = 0;
    int pnt_cnt = 0;
    int pnt_index = 0;
    vect_t u_axis, v_axis;
    point_t obr_center;
    point_t *points_3d = NULL;
    point_t *points_obr = NULL;
    struct loopuse *lu;
    struct edgeuse *eu;

    /* Find out how many points we have, set up any uninitialized ON_Brep vertex
     * structures, and prepare a map of NMG index values to the point array indices */
    nmg_tabulate_face_g_verts(&vert_table, fg);

    for (BU_PTBL_FOR(pt, (struct vertex **), &vert_table)) {
	if (brepi[(*pt)->vg_p->index] == -INT_MAX) {
	    ON_BrepVertex& vert = (*b)->NewVertex((*pt)->vg_p->coord, SMALL_FASTF);
	    brepi[(*pt)->vg_p->index] = vert.m_vertex_index;
	}
	pnt_cnt++;
    }

    /* Prepare the 3D obr input array */
    points_3d = (point_t *)bu_calloc(pnt_cnt + 1, sizeof(point_t), "nmg points");
    for (BU_PTBL_FOR(pt, (struct vertex **), &vert_table)) {
	VSET(points_3d[pnt_index], (*pt)->vg_p->coord[0],(*pt)->vg_p->coord[1],(*pt)->vg_p->coord[2]);
	pnt_index++;
    }
    bu_ptbl_free(&vert_table);


    /* Calculate the 3D coplanar oriented bounding rectangle (obr) */
    ret += bg_3d_coplanar_obr(&obr_center, &u_axis, &v_axis, (const point_t *)points_3d, pnt_cnt);
    if (ret) {
	bu_log("Failed to get oriented bounding rectangle for NMG faceuse #%lu\n", fu->index);
	return -1;
    }
    bu_free(points_3d, "done with obr 3d point inputs");

    /* Use the obr to define the 3D corner points of the NURBS surface */
    points_obr = (point_t *)bu_calloc(3 + 1, sizeof(point_t), "points_3d");
    VADD3(points_obr[2], obr_center, u_axis, v_axis);
    VSCALE(u_axis, u_axis, -1);
    VADD3(points_obr[3], obr_center, u_axis, v_axis);
    VSCALE(v_axis, v_axis, -1);
    VADD3(points_obr[0], obr_center, u_axis, v_axis);
    VSCALE(u_axis, u_axis, -1);
    VADD3(points_obr[1], obr_center, u_axis, v_axis);

    /* We need to orient our surface correctly according to the NMG - using
     * the openNURBS FlipFace function later does not seem to work very
     * well. If an outer loop is found in the NMG with a cw orientation,
     * factor that in in addition to the fu->f_p->flip flag. */
    int ccw = 0;
    vect_t vtmp, uv1, uv2, vnormal;
    point_t center;
    VADD2(center, points_obr[0], points_obr[1]);
    VADD2(center, center, points_obr[2]);
    VADD2(center, center, points_obr[3]);
    VSCALE(center, center, 0.25);
    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
	if (lu->orientation == OT_SAME && nmg_loop_is_ccw(lu, fg->N, tol) == -1) ccw = -1;
    }
    if (ccw != -1) {
	VSET(vnormal, fg->N[0], fg->N[1], fg->N[2]);
    } else {
	VSET(vnormal, -fg->N[0], -fg->N[1], -fg->N[2]);
    }
    if (fu->f_p->flip)
	VSET(vnormal, -vnormal[0], -vnormal[1], -vnormal[2]);
    VSUB2(uv1, points_obr[0], center);
    VSUB2(uv2, points_obr[1], center);
    VCROSS(vtmp, uv1, uv2);
    if (VDOT(vtmp, vnormal) < 0) {
	VMOVE(vtmp, points_obr[0]);
	VMOVE(points_obr[0], points_obr[1]);
	VMOVE(points_obr[1], vtmp);
	VMOVE(vtmp, points_obr[3]);
	VMOVE(points_obr[3], points_obr[2]);
	VMOVE(points_obr[2], vtmp);
    }

    /* Now that we've got our points correctly oriented for
     * the NURBS surface, proceed to create it. */
    ON_3dPoint p1 = ON_3dPoint(points_obr[0]);
    ON_3dPoint p2 = ON_3dPoint(points_obr[1]);
    ON_3dPoint p3 = ON_3dPoint(points_obr[2]);
    ON_3dPoint p4 = ON_3dPoint(points_obr[3]);

    (*b)->m_S.Append(sideSurface(p1, p2, p3, p4));
    ON_Surface *surf = (*(*b)->m_S.Last());
    int surfindex = (*b)->m_S.Count();
    ON_BrepFace& face = (*b)->NewFace(surfindex - 1);

    // With the surface and the face defined, make
    // trimming loops and create faces.  To generate UV
    // coordinates for each from and to for the
    // edgecurves, the UV origin is defined to be v1,
    // v1->v2 is defined as the U domain, and v1->v4 is
    // defined as the V domain.
    VSUB2(u_axis, points_obr[2], points_obr[1]);
    VSUB2(v_axis, points_obr[0], points_obr[1]);
    fastf_t u_axis_dist = MAGNITUDE(u_axis);
    fastf_t v_axis_dist = MAGNITUDE(v_axis);

    /* Now that we have the surface and the face, add the loops */
    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
	if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC) continue; // loop is a single vertex
	// Check if this is an inner or outer loop
	ON_BrepLoop::TYPE looptype = (lu->orientation == OT_SAME) ? ON_BrepLoop::outer : ON_BrepLoop::inner;
	ON_BrepLoop& loop = (*b)->NewLoop(looptype, face);
	for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
	    vect_t ev1, ev2;
	    struct vertex_g *vg1 = eu->vu_p->v_p->vg_p;
	    struct vertex_g *vg2 = eu->eumate_p->vu_p->v_p->vg_p;
	    NMG_CK_VERTEX_G(vg1);
	    NMG_CK_VERTEX_G(vg2);
	    VMOVE(ev1, vg1->coord);
	    VMOVE(ev2, vg2->coord);
	    // Add edge if not already added
	    if (brepi[eu->e_p->index] == -INT_MAX) {
		/* always add edges with the small vertex index as from */
		int vert1 = (vg1->index <= vg2->index) ? brepi[vg1->index] : brepi[vg2->index];
		int vert2 = (vg1->index > vg2->index) ? brepi[vg1->index] : brepi[vg2->index];
		// Create and add 3D curve
		ON_Curve* c3d = new ON_LineCurve((*b)->m_V[vert1].Point(), (*b)->m_V[vert2].Point());
		c3d->SetDomain(0.0, 1.0);
		(*b)->m_C3.Append(c3d);
		// Create and add 3D edge
		ON_BrepEdge& e = (*b)->NewEdge((*b)->m_V[vert1], (*b)->m_V[vert2] , (*b)->m_C3.Count() - 1);
		e.m_tolerance = 0.0;
		brepi[eu->e_p->index] = e.m_edge_index;
	    }
	    // Regardless of whether the edge existed as an object, it needs to be added to the trimming loop
	    ON_3dPoint vg1pt(vg1->coord);
	    int orientation = ((vg1pt != (*b)->m_V[(*b)->m_E[(int)brepi[eu->e_p->index]].m_vi[0]].Point())) ? 1 : 0;
	    // Make a 2d trimming curve, create a trim, and add the trim to the loop
	    vect_t vect1, vect2, u_component, v_component;
	    double u0, u1, v0, v1;
	    ON_2dPoint from_uv, to_uv;
	    VSUB2(vect1, ev1, points_obr[0]);
	    VSUB2(vect2, ev2, points_obr[0]);
	    surf->GetDomain(0, &u0, &u1);
	    surf->GetDomain(1, &v0, &v1);
	    VPROJECT(vect1, u_axis, u_component, v_component);
	    from_uv.y = u0 + MAGNITUDE(u_component)/u_axis_dist*(u1-u0);
	    from_uv.x = v0 + MAGNITUDE(v_component)/v_axis_dist*(v1-v0);
	    VPROJECT(vect2, u_axis, u_component, v_component);
	    to_uv.y = u0 + MAGNITUDE(u_component)/u_axis_dist*(u1-u0);
	    to_uv.x = v0 + MAGNITUDE(v_component)/v_axis_dist*(v1-v0);
	    ON_Curve* c2d =  new ON_LineCurve(from_uv, to_uv);
	    c2d->SetDomain(0.0, 1.0);
	    int c2i = (*b)->m_C2.Count();
	    (*b)->m_C2.Append(c2d);
	    ON_BrepTrim& trim = (*b)->NewTrim((*b)->m_E[(int)brepi[eu->e_p->index]], orientation, loop, c2i);
	    trim.m_type = ON_BrepTrim::mated;
	    trim.m_tolerance[0] = 0.0;
	    trim.m_tolerance[1] = 0.0;
	}
    }

    bu_free(points_obr, "Done with obr");

    return 0;
}
Пример #14
0
static void
nmg_to_acad(struct nmgregion *r, const struct db_full_path *pathp, int region_id)
{
    struct model *m;
    struct shell *s;
    struct vertex *v;
    struct bu_ptbl verts;
    char *region_name;
    int numverts = 0;		/* Number of vertices to output */
    int numtri   = 0;		/* Number of triangles to output */
    int tricount = 0;		/* Triangle number */
    int i;

    NMG_CK_REGION(r);
    RT_CK_FULL_PATH(pathp);

    region_name = db_path_to_string(pathp);

    m = r->m_p;
    NMG_CK_MODEL(m);

    /* triangulate model */
    nmg_triangulate_model(m, &tol);


    /* list all vertices in result */
    nmg_vertex_tabulate(&verts, &r->l.magic);

    /* Get number of vertices */

    numverts = BU_PTBL_END (&verts);

/* BEGIN CHECK SECTION */

/* Check vertices */

    for (i=0; i<numverts; i++) {
	v = (struct vertex *)BU_PTBL_GET(&verts, i);
	NMG_CK_VERTEX(v);
    }

/* Check triangles */
    for (BU_LIST_FOR(s, shell, &r->s_hd)) {
	struct faceuse *fu;

	NMG_CK_SHELL(s);

	for (BU_LIST_FOR(fu, faceuse, &s->fu_hd)) {
	    struct loopuse *lu;

	    NMG_CK_FACEUSE(fu);

	    if (fu->orientation != OT_SAME)
		continue;

	    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		struct edgeuse *eu;
		int vert_count=0;

		NMG_CK_LOOPUSE(lu);

		if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC)
		    continue;

		/* check vertex numbers for each triangle */
		for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
		    NMG_CK_EDGEUSE(eu);

		    v = eu->vu_p->v_p;
		    NMG_CK_VERTEX(v);

		    vert_count++;
		    i = bu_ptbl_locate(&verts, (long *)v);
		    if (i < 0) {
			bu_ptbl_free(&verts);
			bu_free(region_name, "region name");
			bu_log("Vertex from eu %p is not in nmgregion %p\n", (void *)eu, (void *)r);
			bu_exit(1, "ERROR: Triangle vertex was not located\n");
		    }
		}
		if (vert_count > 3) {
		    bu_ptbl_free(&verts);
		    bu_free(region_name, "region name");
		    bu_log("lu %p has too many (%d) vertices!\n", (void *)lu, vert_count);
		    bu_exit(1, "ERROR: LU is not a triangle\n");
		} else if (vert_count < 3)
		    continue;
		numtri++;
	    }
	}
    }

/* END CHECK SECTION */
/* Write pertinent info for this region */

    fprintf(fp, "%s\n", (region_name+1));
/* No mirror plane */
    fprintf(fp, "%d\n", 0);
/* Number of vertices */
    fprintf(fp, "%d\n", numverts);


    /* Write numverts, then vertices */

    for (i=0; i<numverts; i++) {
	v = (struct vertex *)BU_PTBL_GET(&verts, i);
	NMG_CK_VERTEX(v);
	if (inches)
	    fprintf(fp, "%f %f %f\n", V3ARGSIN(v->vg_p->coord));
	else
	    fprintf(fp, "%f %f %f\n", V3ARGS(v->vg_p->coord));
    }

/* Number of sub-parts (always 1 with BRL-CAD) */
    fprintf(fp, "%d\n", 1);
/* Write out name again */
    fprintf(fp, "%s\n", (region_name+1));
/* Number of triangles, number of vert/tri (3) */
    fprintf(fp, "%d       %d\n", numtri, 3);

    /* output triangles */
    for (BU_LIST_FOR(s, shell, &r->s_hd)) {
	struct faceuse *fu;

	NMG_CK_SHELL(s);

	for (BU_LIST_FOR(fu, faceuse, &s->fu_hd)) {
	    struct loopuse *lu;

	    NMG_CK_FACEUSE(fu);

	    if (fu->orientation != OT_SAME)
		continue;

	    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		struct edgeuse *eu;
		int vert_count=0;

		NMG_CK_LOOPUSE(lu);

		if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC)
		    continue;

		/* list vertex numbers for each triangle */
		for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
		    NMG_CK_EDGEUSE(eu);

		    v = eu->vu_p->v_p;
		    NMG_CK_VERTEX(v);

		    vert_count++;
		    i = bu_ptbl_locate(&verts, (long *)v);
		    if (i < 0) {
			bu_ptbl_free(&verts);
			bu_log("Vertex from eu %p is not in nmgregion %p\n", (void *)eu, (void *)r);
			bu_free(region_name, "region name");
			bu_exit(1, "ERROR: Can't find vertex in list!\n");
		    }

		    fprintf(fp, " %d", i+1);
		}

		/* Output other info. for triangle ICOAT, component#, facet# */
		/* Map Icoat from material table later */
		/* fprintf(fp, "%s icomp=%d material=%d:\n", (region_name+1), region_id);*/

		fprintf(fp, " %d    %d    %d\n", 0, region_id, ++tricount);

		if (vert_count > 3) {
		    bu_ptbl_free(&verts);
		    bu_free(region_name, "region name");
		    bu_log("lu %p has %d vertices!\n", (void *)lu, vert_count);
		    bu_exit(1, "ERROR: LU is not a triangle\n");
		} else if (vert_count < 3)
		    continue;
		tot_polygons++;
	    }
	}
    }
/* regions_converted++;
   printf("Processed region %s\n", region_name);
   printf("Regions attempted = %d Regions done = %d\n", regions_tried, regions_converted);
   fflush(stdout);
*/
    bu_ptbl_free(&verts);
    bu_free(region_name, "region name");
}
Пример #15
0
extern "C" void
rt_nmg_brep(ON_Brep **b, const struct rt_db_internal *ip, const struct bn_tol *tol)
{
    struct model *m;
    struct nmgregion *r;
    struct shell *s;
    struct faceuse *fu;
    struct loopuse *lu;
    struct edgeuse *eu;

    int edge_index;
    long* brepi;

    RT_CK_DB_INTERNAL(ip);
    m = (struct model *)ip->idb_ptr;
    NMG_CK_MODEL(m);

    brepi = static_cast<long*>(bu_malloc(m->maxindex * sizeof(long), "rt_nmg_brep: brepi[]"));
    for (int i = 0; i < m->maxindex; i++) brepi[i] = -INT_MAX;

    for (BU_LIST_FOR(r, nmgregion, &m->r_hd)) {
	for (BU_LIST_FOR(s, shell, &r->s_hd)) {
	    for (BU_LIST_FOR(fu, faceuse, &s->fu_hd)) {
		NMG_CK_FACEUSE(fu);
		if (fu->orientation != OT_SAME) continue;

		// Need to create ON_NurbsSurface based on plane of
		// face in order to have UV space in which to define
		// trimming loops.  Bounding points are NOT on the
		// face plane, so another approach must be used.
		//
		// General approach: For all loops in the faceuse,
		// collect all the vertices.  Find the center point of
		// all the vertices, and search for the point with the
		// greatest distance from that center point.  Once
		// found, cross the vector between the center point
		// and furthest point with the normal of the face and
		// scale the resulting vector to have the same length
		// as the vector to the furthest point.  Add the two
		// resulting vectors to find the first corner point.
		// Mirror the first corner point across the center to
		// find the second corner point.  Cross the two
		// vectors created by the first two corner points with
		// the face normal to get the vectors of the other two
		// corners, and scale the resulting vectors to the
		// same magnitude as the first two.  These four points
		// bound all vertices on the plane and form a suitable
		// staring point for a UV space, since all points on
		// all the edges are equal to or further than the
		// distance between the furthest vertex and the center
		// point.

		// ............. .............
		// .           .* .          .
		// .         .  .    .       .
		// .        .   .      .     .
		// .       .    .       *    .
		// .      .     .       .    .
		// .     .      .       .    .
		// .    .       .       .    .
		// .   *        *       .    .
		// .   .                .    .
		// .   .                .    .
		// .   .                .    .
		// .   *.               .    .
		// .     ...        ...*     .
		// .       .... ....         .
		// .           *             .
		// ...........................
		//


		const struct face_g_plane *fg = fu->f_p->g.plane_p;
		struct bu_ptbl vert_table;
		nmg_tabulate_face_g_verts(&vert_table, fg);
		point_t tmppt, center, max_pt;
		struct vertex **pt;

		VSET(tmppt, 0, 0, 0);
		VSET(max_pt, 0, 0, 0);

		int ptcnt = 0;
		for (BU_PTBL_FOR(pt, (struct vertex **), &vert_table)) {
		    tmppt[0] += (*pt)->vg_p->coord[0];
		    tmppt[1] += (*pt)->vg_p->coord[1];
		    tmppt[2] += (*pt)->vg_p->coord[2];
		    ptcnt++;
		    if (brepi[(*pt)->vg_p->index] == -INT_MAX) {
			ON_BrepVertex& vert = (*b)->NewVertex((*pt)->vg_p->coord, SMALL_FASTF);
			brepi[(*pt)->vg_p->index] = vert.m_vertex_index;
		    }
		}
		VSET(center, tmppt[0]/ptcnt, tmppt[1]/ptcnt, tmppt[2]/ptcnt);
		fastf_t max_dist = 0.0;
		fastf_t curr_dist;
		for (BU_PTBL_FOR(pt, (struct vertex **), &vert_table)) {
		    tmppt[0] = (*pt)->vg_p->coord[0];
		    tmppt[1] = (*pt)->vg_p->coord[1];
		    tmppt[2] = (*pt)->vg_p->coord[2];
		    curr_dist = DIST_PT_PT(center, tmppt);
		    if (curr_dist > max_dist) {
			max_dist = curr_dist;
			VMOVE(max_pt, tmppt);
		    }
		}
		bu_ptbl_free(&vert_table);
		int ccw = 0;
		vect_t vtmp, uv1, uv2, uv3, uv4, vnormal;
		// If an outer loop is found in the nmg with a cw
		// orientation, use a flipped normal to form the NURBS
		// surface
		for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		    if (lu->orientation == OT_SAME && nmg_loop_is_ccw(lu, fg->N, tol) == -1) ccw = -1;
		}
		if (ccw != -1) {
		    VSET(vnormal, fg->N[0], fg->N[1], fg->N[2]);
		} else {
		    VSET(vnormal, -fg->N[0], -fg->N[1], -fg->N[2]);
		}
		VSUB2(uv1, max_pt, center);
		VCROSS(vtmp, uv1, vnormal);
		VADD2(uv1, uv1, vtmp);
		VCROSS(uv2, uv1, vnormal);
		VREVERSE(uv3, uv1);
		VCROSS(uv4, uv3, vnormal);
		VADD2(uv1, uv1, center);
		VADD2(uv2, uv2, center);
		VADD2(uv3, uv3, center);
		VADD2(uv4, uv4, center);

		ON_3dPoint p1 = ON_3dPoint(uv1);
		ON_3dPoint p2 = ON_3dPoint(uv2);
		ON_3dPoint p3 = ON_3dPoint(uv3);
		ON_3dPoint p4 = ON_3dPoint(uv4);

		(*b)->m_S.Append(sideSurface(p1, p4, p3, p2));
		ON_Surface *surf = (*(*b)->m_S.Last());
		int surfindex = (*b)->m_S.Count();

		// Now that we have the surface, define the face
		ON_BrepFace& face = (*b)->NewFace(surfindex - 1);

		// With the surface and the face defined, make
		// trimming loops and create faces.  To generate UV
		// coordinates for each from and to for the
		// edgecurves, the UV origin is defined to be v1,
		// v1->v2 is defined as the U domain, and v1->v4 is
		// defined as the V domain.
		vect_t u_axis, v_axis;
		VSUB2(u_axis, uv2, uv1);
		VSUB2(v_axis, uv4, uv1);
		fastf_t u_axis_dist = MAGNITUDE(u_axis);
		fastf_t v_axis_dist = MAGNITUDE(v_axis);

		// Now that the surface context is set up, add the loops.
		for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		    int edges=0;
		    if (BU_LIST_FIRST_MAGIC(&lu->down_hd) != NMG_EDGEUSE_MAGIC) continue; // loop is a single vertex
		    ON_BrepLoop::TYPE looptype;
		    // Check if this is an inner or outer loop
		    if (lu->orientation == OT_SAME) {
			looptype = ON_BrepLoop::outer;
		    } else {
			looptype = ON_BrepLoop::inner;
		    }
		    ON_BrepLoop& loop = (*b)->NewLoop(looptype, face);
		    for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
			++edges;
			vect_t ev1, ev2;
			struct vertex_g *vg1, *vg2;
			vg1 = eu->vu_p->v_p->vg_p;
			NMG_CK_VERTEX_G(vg1);
			int vert1 = brepi[vg1->index];
			VMOVE(ev1, vg1->coord);
			vg2 = eu->eumate_p->vu_p->v_p->vg_p;
			NMG_CK_VERTEX_G(vg2);
			int vert2 = brepi[vg2->index];
			VMOVE(ev2, vg2->coord);
			// Add edge if not already added
			if (brepi[eu->e_p->index] == -INT_MAX) {
			    /* always add edges with the small vertex index as from */
			    if (vg1->index > vg2->index) {
				int tmpvert = vert1;
				vert1 = vert2;
				vert2 = tmpvert;
			    }
			    // Create and add 3D curve
			    ON_Curve* c3d = new ON_LineCurve((*b)->m_V[vert1].Point(), (*b)->m_V[vert2].Point());
			    c3d->SetDomain(0.0, 1.0);
			    (*b)->m_C3.Append(c3d);
			    // Create and add 3D edge
			    ON_BrepEdge& e = (*b)->NewEdge((*b)->m_V[vert1], (*b)->m_V[vert2] , (*b)->m_C3.Count() - 1);
			    e.m_tolerance = 0.0;
			    brepi[eu->e_p->index] = e.m_edge_index;
			}
			// Regardless of whether the edge existed as
			// an object, it needs to be added to the
			// trimming loop
			vect_t u_component, v_component;
			ON_3dPoint vg1pt(vg1->coord);
			int orientation = 0;
			edge_index = brepi[eu->e_p->index];
			if (vg1pt !=  (*b)->m_V[(*b)->m_E[edge_index].m_vi[0]].Point()) {
			    orientation = 1;
			}
			// Now, make 2d trimming curves
			vect_t vect1, vect2;
			VSUB2(vect1, ev1, uv1);
			VSUB2(vect2, ev2, uv1);
			ON_2dPoint from_uv, to_uv;
			double u0, u1, v0, v1;
			surf->GetDomain(0, &u0, &u1);
			surf->GetDomain(1, &v0, &v1);

			VPROJECT(vect1, u_axis, u_component, v_component);
			from_uv.y = u0 + MAGNITUDE(u_component)/u_axis_dist*(u1-u0);
			from_uv.x = v0 + MAGNITUDE(v_component)/v_axis_dist*(v1-v0);
			VPROJECT(vect2, u_axis, u_component, v_component);
			to_uv.y = u0 + MAGNITUDE(u_component)/u_axis_dist*(u1-u0);
			to_uv.x = v0 + MAGNITUDE(v_component)/v_axis_dist*(v1-v0);
			ON_3dPoint S1, S2;
			ON_3dVector Su, Sv;
			surf->Ev1Der(from_uv.x, from_uv.y, S1, Su, Sv);
			surf->Ev1Der(to_uv.x, to_uv.y, S2, Su, Sv);
			ON_Curve* c2d =  new ON_LineCurve(from_uv, to_uv);
			c2d->SetDomain(0.0, 1.0);
			int c2i = (*b)->m_C2.Count();
			(*b)->m_C2.Append(c2d);
			edge_index = brepi[eu->e_p->index];
			ON_BrepTrim& trim = (*b)->NewTrim((*b)->m_E[edge_index], orientation, loop, c2i);
			trim.m_type = ON_BrepTrim::mated;
			trim.m_tolerance[0] = 0.0;
			trim.m_tolerance[1] = 0.0;
		    }
		}
	    }
	    (*b)->SetTrimIsoFlags();
	}
    }

    bu_free(brepi, "rt_nmg_brep: brepi[]");
}
Пример #16
0
HIDDEN int
move_all_func(struct ged *gedp, int nflag, const char *old_name, const char *new_name)
{
    int i;
    struct ged_display_list *gdlp;
    struct directory *dp;
    struct rt_db_internal intern;
    struct rt_comb_internal *comb;
    struct bu_ptbl stack;

    /* rename the record itself */
    if ((dp = db_lookup(gedp->ged_wdbp->dbip, old_name, LOOKUP_NOISY)) == RT_DIR_NULL)
	return GED_ERROR;

    if (db_lookup(gedp->ged_wdbp->dbip, new_name, LOOKUP_QUIET) != RT_DIR_NULL) {
	bu_vls_printf(gedp->ged_result_str, "%s: already exists", new_name);
	return GED_ERROR;
    }

    /* if this was a sketch, we need to look for all the extrude
     * objects that might use it.
     *
     * This has to be done here, before we rename the (possible) sketch object
     * because the extrude will do a rt_db_get on the sketch when we call
     * rt_db_get_internal on it.
     */
    if (dp->d_major_type == DB5_MAJORTYPE_BRLCAD && \
	dp->d_minor_type == DB5_MINORTYPE_BRLCAD_SKETCH) {

	struct directory *dirp;

	for (i = 0; i < RT_DBNHASH; i++) {
	    for (dirp = gedp->ged_wdbp->dbip->dbi_Head[i]; dirp != RT_DIR_NULL; dirp = dirp->d_forw) {

		if (dirp->d_major_type == DB5_MAJORTYPE_BRLCAD && \
		    dirp->d_minor_type == DB5_MINORTYPE_BRLCAD_EXTRUDE) {
		    struct rt_extrude_internal *extrude;

		    if (rt_db_get_internal(&intern, dirp, gedp->ged_wdbp->dbip, (fastf_t *)NULL, &rt_uniresource) < 0) {
			bu_log("Can't get extrude %s?\n", dirp->d_namep);
			continue;
		    }
		    extrude = (struct rt_extrude_internal *)intern.idb_ptr;
		    RT_EXTRUDE_CK_MAGIC(extrude);

		    if (BU_STR_EQUAL(extrude->sketch_name, old_name)) {
			if (nflag) {
			    bu_vls_printf(gedp->ged_result_str, "%s ", dirp->d_namep);
			    rt_db_free_internal(&intern);
			} else {
			    bu_free(extrude->sketch_name, "sketch name");
			    extrude->sketch_name = bu_strdup(new_name);

			    if (rt_db_put_internal(dirp, gedp->ged_wdbp->dbip, &intern, &rt_uniresource) < 0) {
				bu_log("oops\n");
			    }
			}
		    } else
			rt_db_free_internal(&intern);
		}
	    }
	}
    }

    if (!nflag) {
	/* Change object name in the directory. */
	if (db_rename(gedp->ged_wdbp->dbip, dp, new_name) < 0) {
	    bu_vls_printf(gedp->ged_result_str, "error in rename to %s, aborting", new_name);
	    return GED_ERROR;
	}

	/* Change name in the file */
	if (rt_db_get_internal(&intern, dp, gedp->ged_wdbp->dbip, (fastf_t *)NULL, &rt_uniresource) < 0) {
	    bu_vls_printf(gedp->ged_result_str, "Database read error, aborting");
	    return GED_ERROR;
	}

	if (rt_db_put_internal(dp, gedp->ged_wdbp->dbip, &intern, &rt_uniresource) < 0) {
	    bu_vls_printf(gedp->ged_result_str, "Database write error, aborting");
	    return GED_ERROR;
	}
    }

    bu_ptbl_init(&stack, 64, "combination stack for wdb_mvall_cmd");


    /* Examine all COMB nodes */
    for (i = 0; i < RT_DBNHASH; i++) {
	for (dp = gedp->ged_wdbp->dbip->dbi_Head[i]; dp != RT_DIR_NULL; dp = dp->d_forw) {
	    if (nflag) {
		union tree *comb_leaf;
		int done=0;

		if (!(dp->d_flags & RT_DIR_COMB)) continue;
		if (rt_db_get_internal(&intern, dp, gedp->ged_wdbp->dbip, (fastf_t *)NULL, &rt_uniresource) < 0) continue;
		comb = (struct rt_comb_internal *)intern.idb_ptr;
		bu_ptbl_reset(&stack);
		/* visit each leaf in the combination */
		comb_leaf = comb->tree;
		if (comb_leaf) {
		    while (!done) {
			while (comb_leaf->tr_op != OP_DB_LEAF) {
			    bu_ptbl_ins(&stack, (long *)comb_leaf);
			    comb_leaf = comb_leaf->tr_b.tb_left;
			}

			if (BU_STR_EQUAL(comb_leaf->tr_l.tl_name, old_name)) {
			    bu_vls_printf(gedp->ged_result_str, "%s ", dp->d_namep);
			}

			if (BU_PTBL_END(&stack) < 1) {
			    done = 1;
			    break;
			}
			comb_leaf = (union tree *)BU_PTBL_GET(&stack, BU_PTBL_END(&stack)-1);
			if (comb_leaf->tr_op != OP_DB_LEAF) {
			    bu_ptbl_rm(&stack, (long *)comb_leaf);
			    comb_leaf = comb_leaf->tr_b.tb_right;
			}
		    }
		}
		rt_db_free_internal(&intern);
	    } else {
		int comb_mvall_status = db_comb_mvall(dp, gedp->ged_wdbp->dbip, old_name, new_name, &stack);
		if (!comb_mvall_status) continue;
		if (comb_mvall_status == 2) {
		    bu_ptbl_free(&stack);
		    bu_vls_printf(gedp->ged_result_str, "Database write error, aborting");
		    return GED_ERROR;
		}
	    }
	}
    }

    bu_ptbl_free(&stack);

    if (!nflag) {
	/* Change object name anywhere in the display list path. */
	for (BU_LIST_FOR(gdlp, ged_display_list, gedp->ged_gdp->gd_headDisplay)) {
	    int first = 1;
	    int found = 0;
	    struct bu_vls new_path = BU_VLS_INIT_ZERO;
	    char *dupstr = strdup(bu_vls_addr(&gdlp->gdl_path));
	    char *tok = strtok(dupstr, "/");

	    while (tok) {
		if (BU_STR_EQUAL(tok, old_name)) {
		    found = 1;

		    if (first) {
			first = 0;
			bu_vls_printf(&new_path, "%s", new_name);
		    } else
			bu_vls_printf(&new_path, "/%s", new_name);
		} else {
		    if (first) {
			first = 0;
			bu_vls_printf(&new_path, "%s", tok);
		    } else
			bu_vls_printf(&new_path, "/%s", tok);
		}

		tok = strtok((char *)NULL, "/");
	    }

	    if (found) {
		bu_vls_free(&gdlp->gdl_path);
		bu_vls_printf(&gdlp->gdl_path, "%s", bu_vls_addr(&new_path));
	    }

	    free((void *)dupstr);
	    bu_vls_free(&new_path);
	}
    }

    return GED_OK;
}
Пример #17
0
static size_t
show_dangling_edges(struct ged *gedp, const uint32_t *magic_p, const char *name, int out_type)
{
    FILE *plotfp = NULL;
    const char *manifolds = NULL;
    const struct edgeuse *eur;
    int done;
    point_t pt1, pt2;
    size_t i, cnt;
    struct bn_vlblock *vbp = NULL;
    struct bu_list *vhead = NULL;
    struct bu_ptbl faces;
    struct bu_vls plot_file_name = BU_VLS_INIT_ZERO;
    struct edgeuse *eu = NULL;
    struct face *fp = NULL;
    struct faceuse *fu, *fu1, *fu2;
    struct faceuse *newfu = NULL;
    struct loopuse *lu = NULL;

    /* out_type: 0 = none, 1 = show, 2 = plot */
    if (out_type < 0 || out_type > 2) {
	bu_log("Internal error, open edge test failed.\n");
	return 0;
    }

    if (out_type == 1) {
	vbp = rt_vlblock_init();
	vhead = rt_vlblock_find(vbp, 0xFF, 0xFF, 0x00);
    }

    bu_ptbl_init(&faces, 64, "faces buffer");
    nmg_face_tabulate(&faces, magic_p);

    cnt = 0;
    for (i = 0; i < (size_t)BU_PTBL_END(&faces) ; i++) {
	fp = (struct face *)BU_PTBL_GET(&faces, i);
	NMG_CK_FACE(fp);
	fu = fu1 = fp->fu_p;
	NMG_CK_FACEUSE(fu1);
	fu2 = fp->fu_p->fumate_p;
	NMG_CK_FACEUSE(fu2);
	done = 0;
	while (!done) {
	    NMG_CK_FACEUSE(fu);
	    for (BU_LIST_FOR(lu, loopuse, &fu->lu_hd)) {
		NMG_CK_LOOPUSE(lu);
		if (BU_LIST_FIRST_MAGIC(&lu->down_hd) == NMG_EDGEUSE_MAGIC) {
		    for (BU_LIST_FOR(eu, edgeuse, &lu->down_hd)) {
			NMG_CK_EDGEUSE(eu);
			eur = nmg_radial_face_edge_in_shell(eu);
			newfu = eur->up.lu_p->up.fu_p;
			while (manifolds &&
			       NMG_MANIFOLDS(manifolds, newfu) &
			       NMG_2MANIFOLD &&
			       eur != eu->eumate_p) {
			    eur = nmg_radial_face_edge_in_shell(eur->eumate_p);
			    newfu = eur->up.lu_p->up.fu_p;
			}
			if (eur == eu->eumate_p) {
			    VMOVE(pt1, eu->vu_p->v_p->vg_p->coord);
			    VMOVE(pt2, eu->eumate_p->vu_p->v_p->vg_p->coord);
			    if (out_type == 1) {
				BN_ADD_VLIST(vbp->free_vlist_hd, vhead, pt1, BN_VLIST_LINE_MOVE);
				BN_ADD_VLIST(vbp->free_vlist_hd, vhead, pt2, BN_VLIST_LINE_DRAW);
			    } else if (out_type == 2) {
				if (!plotfp) {
				    bu_vls_sprintf(&plot_file_name, "%s.%p.pl", name, (void *)magic_p);
				    if ((plotfp = fopen(bu_vls_addr(&plot_file_name), "wb")) == (FILE *)NULL) {
					bu_vls_free(&plot_file_name);
					bu_log("Error, unable to create plot file (%s), open edge test failed.\n",
					       bu_vls_addr(&plot_file_name));
					return 0;
				    }
				}
				pdv_3line(plotfp, pt1, pt2);
			    }
			    cnt++;
			}
		    }
		}
	    }
	    if (fu == fu1) fu = fu2;
	    if (fu == fu2) done = 1;
	};

    }

    if (out_type == 1) {
	/* Add overlay */
	_ged_cvt_vlblock_to_solids(gedp, vbp, (char *)name, 0);
	rt_vlblock_free(vbp);
	bu_log("Showing open edges...\n");
    } else if (out_type == 2) {
	if (plotfp) {
	    (void)fclose(plotfp);
	    bu_log("Wrote plot file (%s)\n", bu_vls_addr(&plot_file_name));
	    bu_vls_free(&plot_file_name);
	}
    }
    bu_ptbl_free(&faces);

    return cnt;
}