/* GTS - Library for the manipulation of triangulated surfaces * Copyright (C) 1999 Stéphane Popinet * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ #include #include #include "gts.h" static void prepend_triangle_bbox (GtsTriangle * t, GSList ** bboxes) { *bboxes = g_slist_prepend (*bboxes, gts_bbox_triangle (gts_bbox_class (), t)); } static gboolean segment_is_ok (GtsSegment * s) { g_return_val_if_fail (s != NULL, FALSE); g_return_val_if_fail (s->v1 != s->v2, FALSE); g_assert (GTS_OBJECT (s)->reserved == NULL); return TRUE; } static gboolean vertex_is_ok (GtsVertex * v) { g_return_val_if_fail (v != NULL, FALSE); g_return_val_if_fail (GTS_OBJECT (v)->reserved == NULL, FALSE); g_assert (GTS_OBJECT (v)->reserved == NULL); return TRUE; } static gboolean triangle_is_ok (GtsTriangle * t) { g_return_val_if_fail (t != NULL, FALSE); g_return_val_if_fail (t->e1 != NULL, FALSE); g_return_val_if_fail (t->e2 != NULL, FALSE); g_return_val_if_fail (t->e3 != NULL, FALSE); g_return_val_if_fail (t->e1 != t->e2 && t->e1 != t->e3 && t->e2 != t->e3, FALSE); g_assert (gts_segments_touch (GTS_SEGMENT (t->e1), GTS_SEGMENT (t->e2))); g_return_val_if_fail (gts_segments_touch (GTS_SEGMENT (t->e1), GTS_SEGMENT (t->e3)), FALSE); g_return_val_if_fail (gts_segments_touch (GTS_SEGMENT (t->e2), GTS_SEGMENT (t->e3)), FALSE); g_return_val_if_fail (GTS_SEGMENT (t->e1)->v1 != GTS_SEGMENT (t->e1)->v2, FALSE); g_return_val_if_fail (GTS_SEGMENT (t->e2)->v1 != GTS_SEGMENT (t->e2)->v2, FALSE); g_return_val_if_fail (GTS_SEGMENT (t->e3)->v1 != GTS_SEGMENT (t->e3)->v2, FALSE); g_return_val_if_fail (GTS_OBJECT (t)->reserved == NULL, FALSE); return TRUE; } static void write_segment (GtsSegment * s, FILE * fp) { fprintf (fp, "# %p %p:%s->%p:%s\n" "VECT 1 2 0 2 0 %g %g %g %g %g %g\n", s, s->v1, GTS_NVERTEX (s->v1)->name, s->v2, GTS_NVERTEX (s->v2)->name, GTS_POINT (s->v1)->x, GTS_POINT (s->v1)->y, GTS_POINT (s->v1)->z, GTS_POINT (s->v2)->x, GTS_POINT (s->v2)->y, GTS_POINT (s->v2)->z); } int main (int argc, char * argv[]) { GtsSurface * s1, * s2; GtsSurfaceInter * si; GNode * tree1, * tree2; gboolean is_open1, is_open2; GSList * bboxes; FILE * fptr; GtsFile * fp; if (argc != 3) { fprintf (stderr, "%s: check set operations between surfaces\n" "usage: %s FILE1 FILE2\n", argv[0], argv[0]); return 1; } /* open first file */ if ((fptr = fopen (argv[1], "rt")) == NULL) { fprintf (stderr, "%s: can not open file `%s'\n", argv[0], argv[1]); return 1; } /* reads in first surface file */ s1 = gts_surface_new (gts_surface_class (), GTS_FACE_CLASS (gts_nface_class ()), GTS_EDGE_CLASS (gts_nedge_class ()), GTS_VERTEX_CLASS (gts_nvertex_class ())); fp = gts_file_new (fptr); if (gts_surface_read (s1, fp)) { fprintf (stderr, "set: `%s' is not a valid GTS surface file\n", argv[1]); fprintf (stderr, "%s:%d:%d: %s\n", argv[1], fp->line, fp->pos, fp->error); return 1; } gts_file_destroy (fp); fclose (fptr); /* open second file */ if ((fptr = fopen (argv[2], "rt")) == NULL) { fprintf (stderr, "%s: can not open file `%s'\n", argv[0], argv[2]); return 1; } /* reads in second surface file */ s2 = gts_surface_new (gts_surface_class (), GTS_FACE_CLASS (gts_nface_class ()), GTS_EDGE_CLASS (gts_nedge_class ()), GTS_VERTEX_CLASS (gts_nvertex_class ())); fp = gts_file_new (fptr); if (gts_surface_read (s2, fp)) { fprintf (stderr, "set: `%s' is not a valid GTS surface file\n", argv[2]); fprintf (stderr, "%s:%d:%d: %s\n", argv[2], fp->line, fp->pos, fp->error); return 1; } gts_file_destroy (fp); fclose (fptr); /* display summary information about both surfaces */ #if 0 gts_surface_print_stats (s1, stderr); gts_surface_print_stats (s2, stderr); #endif /* check surfaces */ g_assert (gts_surface_is_orientable (s1)); g_assert (gts_surface_is_orientable (s2)); g_assert (!gts_surface_is_self_intersecting (s1)); g_assert (!gts_surface_is_self_intersecting (s2)); /* build bounding boxes for first surface */ bboxes = NULL; gts_surface_foreach_face (s1, (GtsFunc) prepend_triangle_bbox, &bboxes); /* build bounding box tree for first surface */ tree1 = gts_bb_tree_new (bboxes); /* free list of bboxes */ g_slist_free (bboxes); is_open1 = gts_surface_volume (s1) < 0. ? TRUE : FALSE; /* build bounding boxes for second surface */ bboxes = NULL; gts_surface_foreach_face (s2, (GtsFunc) prepend_triangle_bbox, &bboxes); /* build bounding box tree for second surface */ tree2 = gts_bb_tree_new (bboxes); /* free list of bboxes */ g_slist_free (bboxes); is_open2 = gts_surface_volume (s2) < 0. ? TRUE : FALSE; #if 1 { GtsSurface * s = gts_surface_new (gts_surface_class (), gts_face_class (), gts_edge_class (), gts_vertex_class ()); gboolean closed = TRUE; si = gts_surface_inter_new (gts_surface_inter_class (), s1, s2, tree1, tree2, is_open1, is_open2); gts_surface_merge (s, si->s1); gts_surface_merge (s, si->s2); gts_surface_print_stats (s, stderr); #if 1 printf ("(geometry \"inter\" { = LIST {\n"); g_slist_foreach (si->edges, (GFunc) write_segment, stdout); printf ("}})\n" "(normalization \"inter\" none)\n"); printf ("(geometry \"s1\" { =\n"); gts_surface_write_oogl (si->s1, stdout); printf ("})\n" "(normalization \"s1\" none)\n"); printf ("(geometry \"s2\" { =\n"); gts_surface_write_oogl (si->s2, stdout); printf ("})\n" "(normalization \"s2\" none)\n"); #else #if 1 { GtsGraph * g; g = gts_segments_graph_new (gts_graph_class (), si->edges); gts_graph_write_dot (g, stdout); gts_object_destroy (GTS_OBJECT (g)); } #else { GtsGraph * g = gts_surface_graph_new (gts_graph_class (), s); gts_graph_write_dot (g, stdout); gts_object_destroy (GTS_OBJECT (g)); } #endif #endif gts_object_destroy (GTS_OBJECT (s)); #if 1 gts_surface_foreach_face (s1, (GtsFunc) triangle_is_ok, NULL); gts_surface_foreach_edge (s1, (GtsFunc) segment_is_ok, NULL); gts_surface_foreach_edge (s1, (GtsFunc) vertex_is_ok, NULL); gts_surface_foreach_face (s2, (GtsFunc) triangle_is_ok, NULL); gts_surface_foreach_edge (s2, (GtsFunc) segment_is_ok, NULL); gts_surface_foreach_edge (s2, (GtsFunc) vertex_is_ok, NULL); gts_surface_foreach_face (si->s1, (GtsFunc) triangle_is_ok, NULL); gts_surface_foreach_edge (si->s1, (GtsFunc) segment_is_ok, NULL); gts_surface_foreach_edge (si->s1, (GtsFunc) vertex_is_ok, NULL); gts_surface_foreach_face (si->s2, (GtsFunc) triangle_is_ok, NULL); gts_surface_foreach_edge (si->s2, (GtsFunc) segment_is_ok, NULL); gts_surface_foreach_edge (si->s2, (GtsFunc) vertex_is_ok, NULL); #endif g_assert (gts_surface_inter_check (si, &closed)); } #else si = gts_surface_inter_new (gts_surface_inter_class (), s1, s2, tree1, tree2); #endif /* destroy surfaces and intersection */ gts_object_destroy (GTS_OBJECT (s1)); gts_object_destroy (GTS_OBJECT (s2)); gts_object_destroy (GTS_OBJECT (si)); /* destroy bounding box trees (including bounding boxes) */ gts_bb_tree_destroy (tree1, TRUE); gts_bb_tree_destroy (tree2, TRUE); /* free GTS memory (for memory profiling) */ gts_finalize (); return 0; }