int Key_K_CB( Togl *togl, int argc, const char *argv[] ) { if( dh == DRAW_HIERARCHY ) { if( which_pieces.Length() != 1 ) { // Go up the hierarchy int i; SWIFT_Array<SWIFT_BV*> new_which_pieces( which_pieces.Length() ); SWIFT_BV* parent; new_which_pieces.Set_Length( 0 ); parent = NULL; for( i = 0; i < which_pieces.Length(); i++ ) { if( uleaves && which_pieces[i]->Is_Leaf() && which_pieces[i]->Level() < level ) { new_which_pieces.Add( which_pieces[i] ); } else if( parent != which_pieces[i]->Parent() ) { parent = which_pieces[i]->Parent(); new_which_pieces.Add( parent ); } } level--; // Include the new leaves at this level if uleaves is false if( !uleaves ) { for( i = 0; i < num_leaves; i++ ) { if( leaves[i]->Level() == level ) { new_which_pieces.Add_Grow( leaves[i], 10 ); } } } which_pieces.Destroy(); which_pieces = new_which_pieces; new_which_pieces.Nullify(); } } else { // Show next convex piece and set text field char temp[80]; if( which_cps.Length() == 0 ) { which_cps.Set_Length( 1 ); which_cps[0] = 0; } else { which_cps[0] = (which_cps[0] == which_cps.Max_Length()-1 ? 0 : which_cps[0]+1); which_cps.Set_Length( 1 ); } sprintf( temp, "set which_cps %d", which_cps[0] ); Tcl_Eval( Togl_Interp( togl ), temp ); } Togl_PostRedisplay( togl ); return TCL_OK; }
int Key_J_CB( Togl *togl, int argc, const char *argv[] ) { if( dh == DRAW_HIERARCHY ) { int i, j; bool advanced = false; SWIFT_Array<SWIFT_BV*> new_which_pieces( 100 ); new_which_pieces.Set_Length( 0 ); for( i = 0; i < which_pieces.Length(); i++ ) { if( uleaves && which_pieces[i]->Is_Leaf() ) { // Keep this leaf new_which_pieces.Add_Grow( which_pieces[i], 10 ); } else { for( j = 0; j < which_pieces[i]->Num_Children(); j++ ) { new_which_pieces.Add_Grow( which_pieces[i]->Children()[j], 10 ); advanced = true; } } } if( advanced ) { level++; which_pieces.Destroy(); which_pieces = new_which_pieces; new_which_pieces.Nullify(); } } else { // Show previous convex piece and set text field char temp[80]; if( which_cps.Length() == 0 ) { which_cps.Set_Length( 1 ); which_cps[0] = 0; } else { which_cps[0] = (which_cps[0] == 0 ? which_cps.Max_Length()-1 : which_cps[0]-1); which_cps.Set_Length( 1 ); } sprintf( temp, "set which_cps %d", which_cps[0] ); Tcl_Eval( Togl_Interp( togl ), temp ); } Togl_PostRedisplay( togl ); return TCL_OK; }
void Compute_Leaves( SWIFT_BV* piece ) { int i; if( piece == mesh->Root() ) { leaves.Destroy(); leaves.Create( num_leaves ); leaves.Set_Length( 0 ); } if( piece->Is_Leaf() ) { leaves.Add( piece ); } else { for( i = 0; i < piece->Num_Children(); i++ ) { Compute_Leaves( piece->Children()[i] ); } } }
int Convex_Pieces_CB( Togl *togl, int argc, const char *argv[] ) { if( argv[2][0] == 'A' || argv[2][0] == 'a' ) { // Want to draw all pieces int i; which_cps.Set_Length( which_cps.Max_Length() ); for( i = 0; i < which_cps.Length(); i++ ) { which_cps[i] = i; } } else { // Parse the string to determine which ones to draw long upper, lower; const char* str = argv[2]; char* endp; int i; SWIFT_Array<int> which_cps_back = which_cps; which_cps.Set_Length( 0 ); while( *str != '\0' && which_cps.Length() != which_cps.Max_Length() ) { if( isdigit( *str ) ) { // Read the next segment lower = strtol( str, &endp, 10 ); str = endp; if( lower < 0 ) { lower = 0; } if( lower >= which_cps.Max_Length() ) { lower = which_cps.Max_Length()-1; } upper = lower; if( *str == '-' ) { str++; if( isdigit( *str ) ) { upper = strtol( str, &endp, 10 ); str = endp; if( upper < 0 ) { upper = 0; } if( upper >= which_cps.Max_Length() ) { upper = which_cps.Max_Length()-1; } if( upper < lower ) { int j = lower; lower = upper; upper = j; } } else { cerr << "Error: Expecting number after '-'" << endl; which_cps = which_cps_back; break; } } // Save the segment for( i = lower; i <= upper && which_cps.Length() != which_cps.Max_Length(); i++ ) { which_cps.Add( i ); } // Done this segment if( *str == ',' ) { str++; } else { // Assume that we found the end of the list break; } } else { break; } } } Togl_PostRedisplay( t ); return TCL_OK; }
int Decompose_DFS( SWIFT_Tri_Mesh* m, SWIFT_Array<int>& piece_ids, SWIFT_Array< SWIFT_Array<int> >& mfs, SWIFT_Array< SWIFT_Array<SWIFT_Tri_Face> >& vfs, bool random ) { // Start performing DFS on the dual graph maintaining a convex hull along // the way. cerr << endl << "Starting "; if( random ) { cerr << "randomized "; } cerr << "DFS decomposition" << endl; const unsigned int max_faces_in_a_chull = (m->Num_Vertices() - 2) << 1; int i, j, k, l, p; int created_faces = 0; int top, id; // The faces stack SWIFT_Array<SWIFT_Tri_Face*> sfs; // Keeps track of all the faces that were marked as failed so that they can // be unmarked efficiently. SWIFT_Array<SWIFT_Tri_Face*> mark_failed; // The current convex hull SWIFT_Array<SWIFT_Tri_Face> chull; // Pointers to faces indicating whether the face on the convex hull is a // model face or a virtual face (entry is NULL) SWIFT_Array<SWIFT_Tri_Face*> cfs; // Which faces on the original model are allowed to be added SWIFT_Array<bool> fallowed; // Which vertices exist on the convex hull SWIFT_Array<bool> cvs; // Ids of vertices belonging to the convex hull SWIFT_Array<int> cvs_idx; // Ids of faces that are added at each iteration SWIFT_Array<int> addedfs; // The model face ids that belong to a single convex hull SWIFT_Array<int> temp_mfs_1d; // The model face ids that belong to each convex hull SWIFT_Array< SWIFT_Array<int> > temp_mfs_2d; sfs.Create( m->Num_Faces() ); mark_failed.Create( m->Num_Faces() ); chull.Create( max_faces_in_a_chull ); cfs.Create( max_faces_in_a_chull ); fallowed.Create( m->Num_Faces() ); cvs.Create( m->Num_Vertices() ); cvs_idx.Create( m->Num_Vertices() ); addedfs.Create( m->Num_Faces() ); temp_mfs_1d.Create( m->Num_Faces() ); temp_mfs_2d.Create( m->Num_Faces() ); vfs.Create( m->Num_Faces() ); piece_ids.Create( m->Num_Faces() ); Prepare_Mesh_For_Decomposition( m ); for( i = 0; i < m->Num_Faces(); i++ ) { fallowed[i] = true; } for( i = 0; i < m->Num_Vertices(); i++ ) { cvs[i] = false; } cvs_idx.Set_Length( 0 ); id = 0; for( p = 0; p < m->Num_Faces(); ) { // Try to advance p for( ; p < m->Num_Faces() && m->Faces()[p].Marked(); p++ ); if( p == m->Num_Faces() ) break; if( random ) { // Find a random i in the range [p,m->Num_Faces()-1] while( m->Faces()[i = (int) ((SWIFT_Real)(m->Num_Faces()-p) * drand48()) + p].Marked() ); } else { i = p; } top = 0; sfs[0] = m->Faces()(i); mark_failed.Set_Length( 0 ); temp_mfs_1d.Set_Length( 0 ); Create_First_Face( m->Faces()(i), chull, cfs ); // Unset all the vertex membership flags for( j = 0; j < cvs_idx.Length(); j++ ) { cvs[cvs_idx[j]] = false; } cvs_idx.Set_Length( 0 ); // Mark the first three vertices as added to the hull cvs_idx.Add( m->Vertex_Id( m->Faces()[i].Edge1().Origin() ) ); cvs_idx.Add( m->Vertex_Id( m->Faces()[i].Edge2().Origin() ) ); cvs_idx.Add( m->Vertex_Id( m->Faces()[i].Edge3().Origin() ) ); cvs[cvs_idx[0]] = true; cvs[cvs_idx[1]] = true; cvs[cvs_idx[2]] = true; // Add the first face piece_ids[i] = id; m->Faces()[i].Mark(); temp_mfs_1d.Add( i ); l = 1; addedfs.Set_Length( 1 ); addedfs[0] = i; fallowed[i] = false; while( top != -1 ) { if( sfs[top]->Edge1().Marked() && sfs[top]->Edge1().Twin()->Adj_Face()->Unmarked() ) { if( Add_To_Convex_Hull( m, chull, cfs, fallowed, cvs, addedfs, sfs[top]->Edge1().Twin()->Adj_Face(), sfs[top]->Edge1P(), sfs[top]->Edge1().Twin()->Prev()->Origin() ) ) { cvs_idx.Add( m->Vertex_Id( sfs[top]->Edge1().Twin()->Prev()->Origin() ) ); sfs[top+1] = sfs[top]->Edge1().Twin()->Adj_Face(); top++; // Mark all the faces that were added to the chull for( j = l; j < addedfs.Length(); j++ ) { fallowed[addedfs[j]] = false; if( m->Faces()[addedfs[j]].Unmarked() ) { m->Faces()[addedfs[j]].Mark(); piece_ids[addedfs[j]] = id; temp_mfs_1d.Add( addedfs[j] ); } } l = addedfs.Length(); continue; } else { mark_failed.Add( sfs[top]->Edge1().Twin()->Adj_Face() ); sfs[top]->Edge1().Twin()->Adj_Face()->Mark(); fallowed[m->Face_Id(sfs[top]->Edge1().Twin()->Adj_Face())] = false; } } if( sfs[top]->Edge2().Marked() && sfs[top]->Edge2().Twin()->Adj_Face()->Unmarked() ) { if( Add_To_Convex_Hull( m, chull, cfs, fallowed, cvs, addedfs, sfs[top]->Edge2().Twin()->Adj_Face(), sfs[top]->Edge2P(), sfs[top]->Edge2().Twin()->Prev()->Origin() ) ) { cvs_idx.Add( m->Vertex_Id( sfs[top]->Edge2().Twin()->Prev()->Origin() ) ); sfs[top+1] = sfs[top]->Edge2().Twin()->Adj_Face(); top++; // Mark all the faces that were added to the chull for( j = l; j < addedfs.Length(); j++ ) { fallowed[addedfs[j]] = false; if( m->Faces()[addedfs[j]].Unmarked() ) { m->Faces()[addedfs[j]].Mark(); piece_ids[addedfs[j]] = id; temp_mfs_1d.Add( addedfs[j] ); } } l = addedfs.Length(); continue; } else { mark_failed.Add( sfs[top]->Edge2().Twin()->Adj_Face() ); sfs[top]->Edge2().Twin()->Adj_Face()->Mark(); fallowed[m->Face_Id(sfs[top]->Edge2().Twin()->Adj_Face())] = false; } } if( sfs[top]->Edge3().Marked() && sfs[top]->Edge3().Twin()->Adj_Face()->Unmarked() ) { if( Add_To_Convex_Hull( m, chull, cfs, fallowed, cvs, addedfs, sfs[top]->Edge3().Twin()->Adj_Face(), sfs[top]->Edge3P(), sfs[top]->Edge3().Twin()->Prev()->Origin() ) ) { cvs_idx.Add( m->Vertex_Id( sfs[top]->Edge3().Twin()->Prev()->Origin() ) ); sfs[top+1] = sfs[top]->Edge3().Twin()->Adj_Face(); top++; // Mark all the faces that were added to the chull for( j = l; j < addedfs.Length(); j++ ) { fallowed[addedfs[j]] = false; if( m->Faces()[addedfs[j]].Unmarked() ) { m->Faces()[addedfs[j]].Mark(); piece_ids[addedfs[j]] = id; temp_mfs_1d.Add( addedfs[j] ); } } l = addedfs.Length(); continue; } else { mark_failed.Add( sfs[top]->Edge3().Twin()->Adj_Face() ); sfs[top]->Edge3().Twin()->Adj_Face()->Mark(); fallowed[m->Face_Id(sfs[top]->Edge3().Twin()->Adj_Face())] = false; } } top--; } // Unmark all the failed faces. for( j = 0; j < mark_failed.Length(); j++ ) { mark_failed[j]->Unmark(); fallowed[m->Face_Id( mark_failed[j] )] = true; } // Copy the virtual faces for this piece for( j = 0, k = 0; j < chull.Length(); j++ ) { if( chull[j].Unmarked() && cfs[j] == NULL ) { k++; } } created_faces += k; vfs[id].Create( k ); for( j = 0, k = 0; j < chull.Length(); j++ ) { if( chull[j].Unmarked() && cfs[j] == NULL ) { vfs[id][k].Set_Normal_N( chull[j].Normal() ); vfs[id][k].Set_Distance( chull[j].Distance() ); vfs[id][k].Edge1().Set_Direction_N( chull[j].Edge1().Direction() ); vfs[id][k].Edge2().Set_Direction_N( chull[j].Edge2().Direction() ); vfs[id][k].Edge3().Set_Direction_N( chull[j].Edge3().Direction() ); vfs[id][k].Edge1().Set_Length( chull[j].Edge1().Length() ); vfs[id][k].Edge2().Set_Length( chull[j].Edge2().Length() ); vfs[id][k].Edge3().Set_Length( chull[j].Edge3().Length() ); vfs[id][k].Edge1().Set_Origin( chull[j].Edge1().Origin() ); vfs[id][k].Edge2().Set_Origin( chull[j].Edge2().Origin() ); vfs[id][k].Edge3().Set_Origin( chull[j].Edge3().Origin() ); vfs[id][k].Edge1().Set_Twin( chull[j].Edge1().Twin() ); vfs[id][k].Edge2().Set_Twin( chull[j].Edge2().Twin() ); vfs[id][k].Edge3().Set_Twin( chull[j].Edge3().Twin() ); chull[j].Edge1().Twin()->Set_Twin( vfs[id][k].Edge1P() ); chull[j].Edge2().Twin()->Set_Twin( vfs[id][k].Edge2P() ); chull[j].Edge3().Twin()->Set_Twin( vfs[id][k].Edge3P() ); k++; } } // Copy the model faces for this piece temp_mfs_2d[id].Copy_Length( temp_mfs_1d ); id++; if( !random ) { p++; } } temp_mfs_2d.Set_Length( id ); vfs.Set_Length( id ); // Unmark all the faces and edges for( i = 0; i < m->Num_Faces(); i++ ) { m->Faces()[i].Unmark(); m->Faces()[i].Edge1().Unmark(); m->Faces()[i].Edge2().Unmark(); m->Faces()[i].Edge3().Unmark(); } // Copy the mfs mfs.Copy_Length( temp_mfs_2d ); for( i = 0; i < temp_mfs_2d.Length(); i++ ) { temp_mfs_2d[i].Nullify(); } cerr << "Created " << id << " pieces" << endl; cerr << "Original faces = " << m->Num_Faces() << endl; cerr << "Created virtual faces = " << created_faces << endl << endl; return id; }
int Decompose_Cresting_BFS( SWIFT_Tri_Mesh* m, SWIFT_Array<int>& piece_ids, SWIFT_Array< SWIFT_Array<int> >& mfs, SWIFT_Array< SWIFT_Array<SWIFT_Tri_Face> >& vfs ) { // Start performing BFS on the dual graph maintaining a convex hull along // the way. cerr << endl << "Starting cresting BFS decomposition" << endl; const unsigned int max_faces_in_a_chull = (m->Num_Vertices() - 2) << 1; int i, j, k, l; int created_faces = 0; int front, id; bool add_children; SWIFT_Tri_Edge* e; SWIFT_Tri_Vertex* v; SWIFT_Array<SWIFT_Tri_Face*> qfs; // The queue SWIFT_Array<SWIFT_Tri_Face*> qfs_parents; SWIFT_Array<int> qmap; SWIFT_Array<int> qmap_idx; SWIFT_Array<SWIFT_Tri_Face*> mark_failed; SWIFT_Array<SWIFT_Tri_Face> chull; SWIFT_Array<SWIFT_Tri_Face*> cfs; SWIFT_Array<bool> fallowed; SWIFT_Array<bool> cvs; SWIFT_Array<int> cvs_idx; SWIFT_Array<int> addedfs; SWIFT_Array<int> temp_mfs_1d; SWIFT_Array< SWIFT_Array<int> > temp_mfs_2d; // The priority queue SWIFT_Array<int> lengths( m->Num_Faces() ); SWIFT_Array<int> bmap( m->Num_Faces() ); SWIFT_Array<int> fmap( m->Num_Faces() ); qfs.Create( m->Num_Faces() ); qfs_parents.Create( m->Num_Faces() ); qmap.Create( m->Num_Faces() ); qmap_idx.Create( m->Num_Faces() ); mark_failed.Create( m->Num_Faces() ); chull.Create( max_faces_in_a_chull ); cfs.Create( max_faces_in_a_chull ); fallowed.Create( m->Num_Faces() ); cvs.Create( m->Num_Vertices() ); cvs_idx.Create( m->Num_Vertices() ); addedfs.Create( m->Num_Faces() ); temp_mfs_1d.Create( m->Num_Faces() ); temp_mfs_2d.Create( m->Num_Faces() ); vfs.Create( m->Num_Faces() ); piece_ids.Create( m->Num_Faces() ); Prepare_Mesh_For_Decomposition( m ); cvs_idx.Set_Length( 0 ); qmap_idx.Set_Length( 0 ); for( i = 0; i < m->Num_Vertices(); i++ ) { cvs[i] = false; } for( i = 0; i < m->Num_Faces(); i++ ) { fallowed[i] = true; piece_ids[i] = -1; qmap[i] = -1; bmap[i] = fmap[i] = i; if( m->Faces()[i].Edge1().Unmarked() || m->Faces()[i].Edge2().Unmarked() || m->Faces()[i].Edge3().Unmarked() ) { lengths[i] = 0; qmap_idx.Add( i ); } else { lengths[i] = -1; } } id = 0; // Calculate distances for each face and create priority queue if( !qmap_idx.Empty() ) { // This is a convex object for( i = 0; i < qmap_idx.Max_Length(); i++ ) { if( m->Faces()[qmap_idx[i]].Edge1().Twin() != NULL ) { k = m->Face_Id( m->Faces()[qmap_idx[i]].Edge1().Twin()->Adj_Face() ); if( lengths[k] == -1 ) { lengths[k] = lengths[qmap_idx[i]]+1; qmap_idx.Add( k ); } } if( m->Faces()[qmap_idx[i]].Edge2().Twin() != NULL ) { k = m->Face_Id( m->Faces()[qmap_idx[i]].Edge2().Twin()->Adj_Face() ); if( lengths[k] == -1 ) { lengths[k] = lengths[qmap_idx[i]]+1; qmap_idx.Add( k ); } } if( m->Faces()[qmap_idx[i]].Edge3().Twin() != NULL ) { k = m->Face_Id( m->Faces()[qmap_idx[i]].Edge3().Twin()->Adj_Face() ); if( lengths[k] == -1 ) { lengths[k] = lengths[qmap_idx[i]]+1; qmap_idx.Add( k ); } } } Build_Heap( lengths, bmap, fmap ); } qmap_idx.Set_Length( 0 ); // Process the priority queue by doing BFS while( !lengths.Empty() ) { i = bmap[0]; // Unset all the qmappings for( j = 0; j < qmap_idx.Length(); j++ ) { qmap[qmap_idx[j]] = -1; } qmap_idx.Set_Length( 0 ); qfs.Set_Length( 0 ); qfs_parents.Set_Length( 0 ); front = 0; if( m->Faces()[i].Edge1().Marked() && m->Faces()[i].Edge1().Twin()->Adj_Face()->Unmarked() ) { j = m->Face_Id( m->Faces()[i].Edge1().Twin()->Adj_Face() ); qmap_idx.Add( j ); qmap[j] = qfs.Length(); qfs.Add( m->Faces()(j) ); m->Faces()(j)->Mark(); qfs_parents.Add( m->Faces()(i) ); } if( m->Faces()[i].Edge2().Marked() && m->Faces()[i].Edge2().Twin()->Adj_Face()->Unmarked() ) { j = m->Face_Id( m->Faces()[i].Edge2().Twin()->Adj_Face() ); qmap_idx.Add( j ); qmap[j] = qfs.Length(); qfs.Add( m->Faces()(j) ); m->Faces()(j)->Mark(); qfs_parents.Add( m->Faces()(i) ); } if( m->Faces()[i].Edge3().Marked() && m->Faces()[i].Edge3().Twin()->Adj_Face()->Unmarked() ) { j = m->Face_Id( m->Faces()[i].Edge3().Twin()->Adj_Face() ); qmap_idx.Add( j ); qmap[j] = qfs.Length(); qfs.Add( m->Faces()(j) ); m->Faces()(j)->Mark(); qfs_parents.Add( m->Faces()(i) ); } mark_failed.Set_Length( 0 ); temp_mfs_1d.Set_Length( 0 ); Create_First_Face( m->Faces()(i), chull, cfs ); // Unset all the vertex membership flags for( j = 0; j < cvs_idx.Length(); j++ ) { cvs[cvs_idx[j]] = false; } cvs_idx.Set_Length( 0 ); // Mark the first three vertices as added to the hull cvs_idx.Add( m->Vertex_Id( m->Faces()[i].Edge1().Origin() ) ); cvs_idx.Add( m->Vertex_Id( m->Faces()[i].Edge2().Origin() ) ); cvs_idx.Add( m->Vertex_Id( m->Faces()[i].Edge3().Origin() ) ); cvs[cvs_idx[0]] = true; cvs[cvs_idx[1]] = true; cvs[cvs_idx[2]] = true; // Add the first face piece_ids[i] = id; m->Faces()[i].Mark(); temp_mfs_1d.Add( i ); l = 1; addedfs.Set_Length( 1 ); addedfs[0] = i; fallowed[i] = false; // The strategy here is a bit different from that of DFS. Whatever // is at the front of the queue is tested for validity and if so, it // is added and the unmarked neighbors are placed at the end of the // queue. while( front < qfs.Length() ) { if( qmap[ m->Face_Id( qfs[front] ) ] >= 0 ) { if( qfs[front]->Edge1().Twin() != NULL && qfs_parents[front] == qfs[front]->Edge1().Twin()->Adj_Face() ) { e = qfs[front]->Edge1().Twin(); v = qfs[front]->Edge3().Origin(); } else if( qfs[front]->Edge2().Twin() != NULL && qfs_parents[front] == qfs[front]->Edge2().Twin()->Adj_Face() ) { e = qfs[front]->Edge2().Twin(); v = qfs[front]->Edge1().Origin(); } else { e = qfs[front]->Edge3().Twin(); v = qfs[front]->Edge2().Origin(); } add_children = Add_To_Convex_Hull( m, chull, cfs, fallowed, cvs, addedfs, qfs[front], e, v ); if( add_children ) { // Add the face to the current piece cvs_idx.Add( m->Vertex_Id( v ) ); // Mark all the faces that were added to the chull for( j = l; j < addedfs.Length(); j++ ) { fallowed[addedfs[j]] = false; if( piece_ids[addedfs[j]] == -1 ) { // Remove faces that were added if they exist in q if( qmap[addedfs[j]] == -1 ) { qmap_idx.Add( addedfs[j] ); } qmap[addedfs[j]] = -2; piece_ids[addedfs[j]] = id; temp_mfs_1d.Add( addedfs[j] ); Delete_From_Heap( lengths, bmap, fmap, fmap[addedfs[j]] ); } } l = addedfs.Length(); } } else { add_children = true; } if( add_children ) { // Expand the front by adding unmarked neighbors to the queue if( qfs[front]->Edge1().Marked() && qfs[front]->Edge1().Twin()->Adj_Face()->Unmarked() ) { j = m->Face_Id( qfs[front]->Edge1().Twin()->Adj_Face() ); if( qmap[j] == -2 ) { qmap[j] = -1; } else { qmap[j] = qfs.Length(); qmap_idx.Add( j ); } qfs.Add( m->Faces()(j) ); m->Faces()(j)->Mark(); qfs_parents.Add( qfs[front] ); } if( qfs[front]->Edge2().Marked() && qfs[front]->Edge2().Twin()->Adj_Face()->Unmarked() ) { j = m->Face_Id( qfs[front]->Edge2().Twin()->Adj_Face() ); if( qmap[j] == -2 ) { qmap[j] = -1; } else { qmap[j] = qfs.Length(); qmap_idx.Add( j ); } qfs.Add( m->Faces()(j) ); m->Faces()(j)->Mark(); qfs_parents.Add( qfs[front] ); } if( qfs[front]->Edge3().Marked() && qfs[front]->Edge3().Twin()->Adj_Face()->Unmarked() ) { j = m->Face_Id( qfs[front]->Edge3().Twin()->Adj_Face() ); if( qmap[j] == -2 ) { qmap[j] = -1; } else { qmap[j] = qfs.Length(); qmap_idx.Add( j ); } qfs.Add( m->Faces()(j) ); m->Faces()(j)->Mark(); qfs_parents.Add( qfs[front] ); } } else { mark_failed.Add( qfs[front] ); } front++; } // Unmark all the failed faces. for( j = 0; j < mark_failed.Length(); j++ ) { mark_failed[j]->Unmark(); } // Copy the virtual faces for this piece for( j = 0, k = 0; j < chull.Length(); j++ ) { if( chull[j].Unmarked() && cfs[j] == NULL ) { k++; } } created_faces += k; vfs[id].Create( k ); for( j = 0, k = 0; j < chull.Length(); j++ ) { if( chull[j].Unmarked() && cfs[j] == NULL ) { vfs[id][k].Set_Normal_N( chull[j].Normal() ); vfs[id][k].Set_Distance( chull[j].Distance() ); vfs[id][k].Edge1().Set_Direction_N( chull[j].Edge1().Direction() ); vfs[id][k].Edge2().Set_Direction_N( chull[j].Edge2().Direction() ); vfs[id][k].Edge3().Set_Direction_N( chull[j].Edge3().Direction() ); vfs[id][k].Edge1().Set_Length( chull[j].Edge1().Length() ); vfs[id][k].Edge2().Set_Length( chull[j].Edge2().Length() ); vfs[id][k].Edge3().Set_Length( chull[j].Edge3().Length() ); vfs[id][k].Edge1().Set_Origin( chull[j].Edge1().Origin() ); vfs[id][k].Edge2().Set_Origin( chull[j].Edge2().Origin() ); vfs[id][k].Edge3().Set_Origin( chull[j].Edge3().Origin() ); vfs[id][k].Edge1().Set_Twin( chull[j].Edge1().Twin() ); vfs[id][k].Edge2().Set_Twin( chull[j].Edge2().Twin() ); vfs[id][k].Edge3().Set_Twin( chull[j].Edge3().Twin() ); chull[j].Edge1().Twin()->Set_Twin( vfs[id][k].Edge1P() ); chull[j].Edge2().Twin()->Set_Twin( vfs[id][k].Edge2P() ); chull[j].Edge3().Twin()->Set_Twin( vfs[id][k].Edge3P() ); k++; } } // Copy the model faces for this piece temp_mfs_2d[id].Copy_Length( temp_mfs_1d ); id++; // Remove this face from the priority queue Delete_From_Heap( lengths, bmap, fmap, fmap[i] ); } temp_mfs_2d.Set_Length( id ); vfs.Set_Length( id ); // Unmark all the faces and edges for( i = 0; i < m->Num_Faces(); i++ ) { m->Faces()[i].Unmark(); m->Faces()[i].Edge1().Unmark(); m->Faces()[i].Edge2().Unmark(); m->Faces()[i].Edge3().Unmark(); } // Copy the mfs mfs.Copy_Length( temp_mfs_2d ); for( i = 0; i < temp_mfs_2d.Length(); i++ ) { temp_mfs_2d[i].Nullify(); } cerr << "Created " << id << " pieces" << endl; cerr << "Original faces = " << m->Num_Faces() << endl; cerr << "Created virtual faces = " << created_faces << endl << endl; return id; }