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cgma
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00001 /* 00002 * 00003 * 00004 * Copyright (C) 2004 Sandia Corporation. Under the terms of Contract DE-AC04-94AL85000 00005 * with Sandia Corporation, the U.S. Government retains certain rights in this software. 00006 * 00007 * This file is part of facetbool--contact via [email protected] 00008 * 00009 * This library is free software; you can redistribute it and/or 00010 * modify it under the terms of the GNU Lesser General Public 00011 * License as published by the Free Software Foundation; either 00012 * version 2.1 of the License, or (at your option) any later version. 00013 * 00014 * This library is distributed in the hope that it will be useful, 00015 * but WITHOUT ANY WARRANTY; without even the implied warranty of 00016 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 00017 * Lesser General Public License for more details. 00018 * 00019 * You should have received a copy of the GNU Lesser General Public 00020 * License along with this library; if not, write to the Free Software 00021 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA 00022 * 00023 * 00024 * 00025 */ 00026 00027 #include <math.h> 00028 #include <algorithm> 00029 #include "FBRetriangulate.hpp" 00030 #include "FBTiler.hpp" 00031 #include "CubitMessage.hpp" 00032 00033 #ifdef KEEP_BOYD10_KEEP 00034 bool edgecf_less(const FB_Edge* efirst, const FB_Edge* esecond) 00035 { 00036 if ( efirst->quadrant < esecond->quadrant ) return true; 00037 if ( efirst->quadrant > esecond->quadrant ) return false; 00038 00039 if ( efirst->slope < esecond->slope ) return true; 00040 else return false; 00041 00042 } 00043 #endif 00044 00045 FBRetriangulate::FBRetriangulate(std::vector<FB_Coord *>& my_verts, 00046 std::vector<FB_Triangle *>& my_tris, 00047 std::vector<int>& my_newfacets, 00048 std::vector<int>& my_newfacetsindex) 00049 { 00050 verts = my_verts; 00051 tris = &my_tris; 00052 newfacets = &my_newfacets; 00053 newfacetsindex = &my_newfacetsindex; 00054 p_dir=0; 00055 s_dir=0; 00056 } 00057 00058 FBRetriangulate::FBRetriangulate(std::vector<FB_Coord *>& my_verts, 00059 std::vector<FB_Triangle *>& my_tris, 00060 std::vector<int>& my_newfacets) 00061 { 00062 verts = my_verts; 00063 tris = &my_tris; 00064 newfacets = &my_newfacets; 00065 newfacetsindex = 0; 00066 p_dir=0; 00067 s_dir=0; 00068 } 00069 00070 FBRetriangulate::~FBRetriangulate() 00071 { 00072 00073 } 00074 00075 CubitStatus FBRetriangulate::retriangulate_this_tri(int sequence, std::vector<FB_Edge*> &orphaned_edges) 00076 { 00077 CubitStatus status; 00078 double xspan, yspan, zspan; 00079 std::vector<FB_Triangle *>::iterator itt; 00080 00081 itt = tris->begin(); 00082 itt += sequence; 00083 my_tri = *itt; 00084 status = CUBIT_SUCCESS; 00085 00086 // tri = &itt; 00087 xspan = my_tri->boundingbox.xmax - my_tri->boundingbox.xmin; 00088 yspan = my_tri->boundingbox.ymax - my_tri->boundingbox.ymin; 00089 zspan = my_tri->boundingbox.zmax - my_tri->boundingbox.zmin; 00090 if ( ( fabs(my_tri->c) >= fabs(my_tri->a) ) && 00091 ( fabs(my_tri->c) >= fabs(my_tri->b) ) ) { 00092 p_dir = 1; 00093 s_dir = 0; 00094 if ( xspan > yspan ) { 00095 p_dir = 0; 00096 s_dir = 1; 00097 } 00098 } 00099 else if ( fabs(my_tri->b) >= fabs(my_tri->a) ) { 00100 p_dir = 2; 00101 s_dir = 0; 00102 if ( xspan > zspan ) { 00103 p_dir = 0; 00104 s_dir = 2; 00105 } 00106 } 00107 else { 00108 p_dir = 1; 00109 s_dir = 2; 00110 if ( zspan > yspan ) { 00111 p_dir = 2; 00112 s_dir = 1; 00113 } 00114 } 00115 00116 if ( p_dir == 0 ) { 00117 if ( s_dir == 1 ) { 00118 if ( my_tri->c > 0.0 ) 00119 winding = CCW; 00120 else 00121 winding = CW; 00122 } 00123 else if (s_dir == 2 ) { 00124 if ( my_tri->b > 0.0 ) 00125 winding = CW; 00126 else 00127 winding = CCW; 00128 } 00129 } 00130 else if ( p_dir == 1 ) { 00131 if ( s_dir == 0 ) { 00132 if ( my_tri->c > 0.0 ) 00133 winding = CW; 00134 else 00135 winding = CCW; 00136 } 00137 else if (s_dir == 2 ) { 00138 if ( my_tri->a > 0.0 ) 00139 winding = CW; 00140 else 00141 winding = CCW; 00142 } 00143 } 00144 else if ( p_dir == 2 ) { 00145 if ( s_dir == 0 ) { 00146 if ( my_tri->b > 0.0 ) 00147 winding = CCW; 00148 else 00149 winding = CW; 00150 } 00151 else if (s_dir == 1 ) { 00152 if ( my_tri->a > 0.0 ) 00153 winding = CCW; 00154 else 00155 winding = CW; 00156 } 00157 } 00158 else{ 00159 PRINT_ERROR("Unexpected result.\n"); 00160 return CUBIT_FAILURE; 00161 } 00162 00163 //if ( winding == CCW ) winding = CW; 00164 //else winding = CCW; 00165 classify_edges(); 00166 00167 // Add edges around the perimeter of the triangle to its edge list. 00168 status = add_bdry_edges(orphaned_edges); 00169 make_vert_list(); 00170 00171 // Add internal edges where there is a local min or max 00172 status = remove_min_max(); 00173 00174 // Get the vertex chains that will be retriangulated. 00175 00176 bool chain_status = true; 00177 sort_vertstufflist_edges(); 00178 std::vector<int> *chainlist = new std::vector<int>; 00179 // std::vector<FB_Triangle* > new_tris; 00180 unsigned int i, nfsize; 00181 nfsize = newfacets->size(); 00182 while (chain_status == true ) { 00183 chain_status = get_a_chain(chainlist); 00184 if ( chain_status == false ) break; 00185 FBTiler *tiler = new FBTiler(verts,p_dir,s_dir,sequence, 00186 my_tri->a,my_tri->b,my_tri->c,newfacets); 00187 status = tiler->Tile_Poly(chainlist); 00188 delete tiler; 00189 chainlist->clear(); 00190 00191 } 00192 00193 delete chainlist; 00194 unsigned int number_new; 00195 int e0index, e1index, e2index; 00196 00197 number_new = newfacets->size() - nfsize; 00198 if ( number_new > 0 ) { 00199 std::vector<int>::iterator itp; 00200 itp = newfacets->begin(); 00201 itp += nfsize; 00202 for ( i = 0; i < number_new; i += 3 ) { 00203 FB_Triangle *new_tri; 00204 e0index = e1index = e2index = 0; 00205 get_edge_indices(*itp,*(itp+1),*(itp+2),sequence, 00206 e0index, e1index, e2index); 00207 new_tri = new FB_Triangle(*itp,*(itp+1),*(itp+2), 00208 sequence,my_tri->cubitsurfaceindex, 00209 e0index, e1index, e2index); 00210 tris->push_back(new_tri); 00211 itp += 3; 00212 } 00213 if ( newfacetsindex ) newfacetsindex->push_back(nfsize); 00214 } 00215 for ( i = 0; i < vertstufflist.size(); i++ ) { 00216 delete vertstufflist[i]; 00217 } 00218 00219 vertstufflist.clear(); 00220 00221 return status; 00222 00223 } 00224 00225 CubitStatus FBRetriangulate::remove_min_max() 00226 { 00227 CubitStatus status; 00228 FB_Edge *edge; 00229 std::vector<FB_Edge*>::iterator dpe; 00230 bool goes_down, goes_up; 00231 VertexStuff *vstuff; 00232 unsigned int i; 00233 int this_vert, that_vert; 00234 double this_vert_p_dir_coord, that_vert_p_dir_coord; 00235 00236 status = CUBIT_SUCCESS; 00237 00238 for ( i = 0; i < vertstufflist.size(); i++ ) { 00239 vstuff = vertstufflist[i]; 00240 if ( vstuff->v0type != INTERIOR_VERT ) continue; 00241 goes_down = goes_up = false; 00242 this_vert = vstuff->v0; 00243 this_vert_p_dir_coord = verts[this_vert]->coord[p_dir]; 00244 dpe = vstuff->edge_list.begin(); 00245 while ( dpe != vstuff->edge_list.end() ) { 00246 edge = *dpe; 00247 dpe++; 00248 if ( edge->v0 == this_vert ) that_vert = edge->v1; 00249 else that_vert = edge->v0; 00250 that_vert_p_dir_coord = verts[that_vert]->coord[p_dir]; 00251 if ( that_vert_p_dir_coord < this_vert_p_dir_coord ) 00252 goes_down = true; 00253 else if ( that_vert_p_dir_coord > this_vert_p_dir_coord ) 00254 goes_up = true; 00255 else { 00256 double this_vert_s_dir_coord, that_vert_s_dir_coord; 00257 this_vert_s_dir_coord = verts[this_vert]->coord[s_dir]; 00258 that_vert_s_dir_coord = verts[that_vert]->coord[s_dir]; 00259 if ( this_vert_s_dir_coord < that_vert_s_dir_coord ) 00260 goes_up = true; 00261 else goes_down = true; 00262 } 00263 } 00264 00265 if ( goes_down == false ) { 00266 add_edge_down(this_vert,i); 00267 } else if ( goes_up == false ) { 00268 add_edge_up(this_vert,i); 00269 } 00270 } 00271 00272 return status; 00273 00274 } 00275 00276 CubitStatus FBRetriangulate::add_bdry_edges(std::vector<FB_Edge*> &orphaned_edges) 00277 { 00278 // For each triangle edge, make a list of pairs of edge points and 00279 // vertex numbers that touch the edge. Then sort the list by distance 00280 // from the start of the edge. (This was what we really put in the 00281 // pair, not the point itself.) Finally, go through this sorted list 00282 // and add edges to the edge_list. If the edge_list is empty, we 00283 // still must add in the triangle edge itself. 00284 00285 CubitStatus status; 00286 FB_Edge *edge; 00287 std::list< std::pair<double,int> > edge0_list, edge1_list, edge2_list; 00288 std::list< std::pair<double,int> >::iterator dp; 00289 std::vector<FB_Edge*>::iterator dpe, dpe_orig; 00290 double vx0, vy0, vz0, vx1, vy1, vz1, vx2, vy2, vz2, dist; 00291 std::pair<double,int> mypair; 00292 00293 status = CUBIT_SUCCESS; 00294 00295 vx0 = verts[my_tri->v0]->coord[0]; 00296 vy0 = verts[my_tri->v0]->coord[1]; 00297 vz0 = verts[my_tri->v0]->coord[2]; 00298 vx1 = verts[my_tri->v1]->coord[0]; 00299 vy1 = verts[my_tri->v1]->coord[1]; 00300 vz1 = verts[my_tri->v1]->coord[2]; 00301 vx2 = verts[my_tri->v2]->coord[0]; 00302 vy2 = verts[my_tri->v2]->coord[1]; 00303 vz2 = verts[my_tri->v2]->coord[2]; 00304 00305 dpe = my_tri->edge_list.begin(); 00306 while ( dpe != my_tri->edge_list.end() ) { 00307 edge = *dpe; 00308 dpe++; 00309 if ( (edge->v0_type == INTERIOR_VERT) && 00310 (edge->v1_type == INTERIOR_VERT) ) 00311 continue; 00312 if ( edge->v0_type == EDGE_0 ) { 00313 dist = get_dist(vx0,vy0,vz0,verts[edge->v0]->coord[0], 00314 verts[edge->v0]->coord[1],verts[edge->v0]->coord[2]); 00315 edge0_list.push_back(std::pair<double,int>(dist,edge->v0)); 00316 } else if ( edge->v0_type == EDGE_1 ) { 00317 dist = get_dist(vx1,vy1,vz1,verts[edge->v0]->coord[0], 00318 verts[edge->v0]->coord[1],verts[edge->v0]->coord[2]); 00319 edge1_list.push_back(std::pair<double,int>(dist,edge->v0)); 00320 } else if ( edge->v0_type == EDGE_2 ) { 00321 dist = get_dist(vx2,vy2,vz2,verts[edge->v0]->coord[0], 00322 verts[edge->v0]->coord[1],verts[edge->v0]->coord[2]); 00323 edge2_list.push_back(std::pair<double,int>(dist,edge->v0)); 00324 } 00325 if ( edge->v1_type == EDGE_0 ) { 00326 dist = get_dist(vx0,vy0,vz0,verts[edge->v1]->coord[0], 00327 verts[edge->v1]->coord[1],verts[edge->v1]->coord[2]); 00328 edge0_list.push_back(std::pair<double,int>(dist,edge->v1)); 00329 } else if ( edge->v1_type == EDGE_1 ) { 00330 dist = get_dist(vx1,vy1,vz1,verts[edge->v1]->coord[0], 00331 verts[edge->v1]->coord[1],verts[edge->v1]->coord[2]); 00332 edge1_list.push_back(std::pair<double,int>(dist,edge->v1)); 00333 } else if ( edge->v1_type == EDGE_2 ) { 00334 dist = get_dist(vx2,vy2,vz2,verts[edge->v1]->coord[0], 00335 verts[edge->v1]->coord[1],verts[edge->v1]->coord[2]); 00336 edge2_list.push_back(std::pair<double,int>(dist,edge->v1)); 00337 } 00338 } 00339 00340 edge0_list.sort(); 00341 edge1_list.sort(); 00342 edge2_list.sort(); 00343 00344 // Now we have to remove all BDRY_EDGEs because they will be made anew 00345 // in what follows. Erasing elements from a vector is inefficient, but 00346 // this shouldn't happen often. 00347 dpe = my_tri->edge_list.begin(); 00348 dpe_orig = my_tri->edge_list.end(); 00349 00350 while ( dpe != dpe_orig ) { 00351 edge = *dpe; 00352 if ( edge->edge_type == BDRY_EDGE ) { 00353 dpe = my_tri->edge_list.erase(dpe); 00354 orphaned_edges.push_back(edge); 00355 dpe_orig = my_tri->edge_list.end(); 00356 } else { 00357 dpe++; 00358 } 00359 } 00360 int newv0, newv1, newv0_type, newv1_type; 00361 newv0_type = newv1_type = EDGE_0; 00362 newv0 = my_tri->v0; 00363 dp = edge0_list.begin(); 00364 while ( dp != edge0_list.end() ) { 00365 mypair = *dp; 00366 newv1 = mypair.second; 00367 // It is possible to get the same vert more than once in the list. 00368 // After sorting, they will be adjacent. The following if statement 00369 // causes duplicate verts to be used only once. 00370 if ( newv0 != newv1 ) { 00371 add_this_bdry_edge(newv0,newv1,newv0_type,newv1_type); 00372 newv0 = newv1; 00373 } 00374 dp++; 00375 } 00376 newv1 = my_tri->v1; 00377 if ( newv0 != newv1 ) 00378 add_this_bdry_edge(newv0,newv1,newv0_type,newv1_type); 00379 00380 newv0_type = newv1_type = EDGE_1; 00381 newv0 = my_tri->v1; 00382 dp = edge1_list.begin(); 00383 while ( dp != edge1_list.end() ) { 00384 mypair = *dp; 00385 newv1 = mypair.second; 00386 if ( newv0 != newv1 ) { 00387 add_this_bdry_edge(newv0,newv1,newv0_type,newv1_type); 00388 newv0 = newv1; 00389 } 00390 dp++; 00391 } 00392 newv1 = my_tri->v2; 00393 if ( newv0 != newv1 ) 00394 add_this_bdry_edge(newv0,newv1,newv0_type,newv1_type); 00395 00396 newv0_type = newv1_type = EDGE_2; 00397 newv0 = my_tri->v2; 00398 dp = edge2_list.begin(); 00399 while ( dp != edge2_list.end() ) { 00400 mypair = *dp; 00401 newv1 = mypair.second; 00402 if ( newv0 != newv1 ) { 00403 add_this_bdry_edge(newv0,newv1,newv0_type,newv1_type); 00404 newv0 = newv1; 00405 } 00406 dp++; 00407 } 00408 newv1 = my_tri->v0; 00409 if ( newv0 != newv1 ) 00410 add_this_bdry_edge(newv0,newv1,newv0_type,newv1_type); 00411 00412 return status; 00413 00414 } 00415 00416 void FBRetriangulate::add_this_bdry_edge(int v0, int v1, int v0_type, 00417 int v1_type) 00418 { 00419 // Add an edge if it doesn't already exist. 00420 std::vector<FB_Edge*>::iterator dpe; 00421 bool ifoundit; 00422 FB_Edge *edge, *new_edge; 00423 00424 ifoundit = false; 00425 dpe = my_tri->edge_list.begin(); 00426 while ( dpe != my_tri->edge_list.end() ) { 00427 edge = *dpe; 00428 if ( ( ((int)edge->v0 == v0) && ((int)edge->v1 == v1) ) || 00429 ( ((int)edge->v0 == v1) && ((int)edge->v1 == v0) ) ) { 00430 ifoundit = true; 00431 break; 00432 } 00433 dpe++; 00434 } 00435 if ( ifoundit == false ) { 00436 new_edge = new FB_Edge(v0,v1,v0_type,v1_type,true); 00437 new_edge->edge_type = BDRY_EDGE; 00438 my_tri->edge_list.push_back(new_edge); 00439 } 00440 } 00441 00442 void FBRetriangulate::make_vert_list() 00443 { 00444 unsigned int i; 00445 int v0, v1; 00446 FB_Edge *edge; 00447 VertexStuff *vstuff; 00448 std::vector<FB_Edge*>::iterator dpe; 00449 bool foundv0, foundv1; 00450 00451 dpe = my_tri->edge_list.begin(); 00452 while ( dpe != my_tri->edge_list.end() ) { 00453 edge = *dpe; 00454 dpe++; 00455 v0 = edge->v0; 00456 v1 = edge->v1; 00457 foundv0 = foundv1 = false; 00458 00459 for ( i = 0; i < vertstufflist.size(); i++ ) { 00460 if ( vertstufflist[i]->v0 == v0 ) { 00461 vertstufflist[i]->edge_list.push_back(edge); 00462 foundv0 = true; 00463 } 00464 if ( vertstufflist[i]->v0 == v1 ) { 00465 vertstufflist[i]->edge_list.push_back(edge); 00466 foundv1 = true; 00467 } 00468 } 00469 if ( foundv0 == false ) { 00470 vstuff = new VertexStuff(v0, edge->v0_type,verts[v0]->coord[p_dir], 00471 verts[v0]->coord[s_dir]); 00472 vstuff->edge_list.push_back(edge); 00473 vertstufflist.push_back(vstuff); 00474 } 00475 if ( foundv1 == false ) { 00476 vstuff = new VertexStuff(v1, edge->v1_type,verts[v1]->coord[p_dir], 00477 verts[v1]->coord[s_dir]); 00478 vstuff->edge_list.push_back(edge); 00479 vertstufflist.push_back(vstuff); 00480 } 00481 00482 } 00483 00484 std::vector<VertexStuff* >::iterator vitbegin, vitend; 00485 vitbegin = vertstufflist.begin(); 00486 vitend = vertstufflist.end(); 00487 00488 std::sort(vitbegin,vitend,vertstuffcompfn_less()); 00489 00490 } 00491 00492 void FBRetriangulate::add_edge_up(int v0, int seq) 00493 { 00494 unsigned int i, k; 00495 int v1, v0test, v1test, v0type, v1type; 00496 bool foundit, crossed; 00497 FB_Edge *edge; 00498 std::vector<FB_Edge*>::iterator dpe; 00499 00500 v1 = 0; //To keep compiler from warning that v1 might be used uninitialized. 00501 v1type = 0; 00502 v0type = vertstufflist[seq]->v0type; 00503 for ( k = seq+1; k < vertstufflist.size(); k++ ) { 00504 foundit = true; 00505 v1 = vertstufflist[k]->v0; 00506 if ( fabs(verts[v1]->coord[p_dir]-verts[v0]->coord[p_dir]) < EPSILON ) 00507 continue; 00508 v1type = vertstufflist[k]->v0type; 00509 // v0 to v1 is the putative new edge. Test whether it crosses any 00510 // existing internal edge. Any such internal edge that it crosses 00511 // has to have an endpoint higher than v1. If v1 is the next-to-top 00512 // vertex, use it. 00513 if ( k == vertstufflist.size() - 1 ) { 00514 foundit = true; 00515 add_tri_edge(v0,v1,v0type,v1type); 00516 return; 00517 } 00518 for ( i = k+1; i < vertstufflist.size()-1; i++ ) { 00519 dpe = vertstufflist[i]->edge_list.begin(); 00520 00521 while ( dpe != vertstufflist[i]->edge_list.end() ) { 00522 edge = *dpe; 00523 dpe++; 00524 if ( (edge->v0_type != INTERIOR_VERT) && 00525 (edge->v1_type != INTERIOR_VERT) ) 00526 continue; 00527 v0test = edge->v0; 00528 v1test = edge->v1; 00529 if ( (v0test == v1) || (v1test == v1) ) continue; 00530 crossed = test_for_crossing(v0,v1,v0test,v1test); 00531 if ( crossed == true ) { 00532 foundit = false; 00533 break; 00534 } 00535 } 00536 if ( foundit == false ) break; 00537 } // end of "for (i ...." 00538 if ( foundit == true ) break; 00539 } 00540 add_tri_edge(v0,v1,v0type,v1type); 00541 } 00542 00543 void FBRetriangulate::add_edge_down(int v0, int seq) 00544 { 00545 int i, k; 00546 int v1, v0test, v1test, v0type, v1type; 00547 bool foundit, crossed; 00548 FB_Edge *edge; 00549 std::vector<FB_Edge*>::iterator dpe; 00550 00551 v1 = 0; //To keep compiler from warning that v1 might be used uninitialized. 00552 v1type = 0; 00553 v0type = vertstufflist[seq]->v0type; 00554 for ( k = seq-1; k > -1; k-- ) { 00555 foundit = true; 00556 v1 = vertstufflist[k]->v0; 00557 if ( fabs(verts[v1]->coord[p_dir]-verts[v0]->coord[p_dir]) < EPSILON ) continue; 00558 v1type = vertstufflist[k]->v0type; 00559 // v0 to v1 is the putative new edge. Test whether it crosses 00560 // any existing internal edge. Any such internal edge that it 00561 // crosses has to have an endpoint higher than v1. If v1 is the 00562 // next-to-top vertex, use it. 00563 if ( k == 0 ) { 00564 foundit = true; 00565 add_tri_edge(v0,v1,v0type,v1type); 00566 return; 00567 } 00568 for ( i = k-1; i > 0; i-- ) { 00569 dpe = vertstufflist[i]->edge_list.begin(); 00570 00571 while ( dpe != vertstufflist[i]->edge_list.end() ) { 00572 edge = *dpe; 00573 dpe++; 00574 if ( (edge->v0_type != INTERIOR_VERT) && 00575 (edge->v1_type != INTERIOR_VERT) ) 00576 continue; 00577 v0test = edge->v0; 00578 v1test = edge->v1; 00579 if ( (v0test == v1) || (v1test == v1) ) continue; 00580 crossed = test_for_crossing(v0,v1,v0test,v1test); 00581 if ( crossed == true ) { 00582 foundit = false; 00583 break; 00584 } 00585 } 00586 if ( foundit == false ) break; 00587 } // end of "for (i ...." 00588 if ( foundit == true ) break; 00589 } 00590 add_tri_edge(v0,v1,v0type,v1type); 00591 } 00592 00593 bool FBRetriangulate::test_for_crossing(int v0, int v1, int v2, int v3) 00594 { 00595 double x0, y0, x1, y1, x2, y2, x3, y3, dxa, dya, dxb, dyb, p01x, p01y; 00596 double product, dasq, dbsq, prodsq; 00597 double s, t; 00598 00599 x0 = verts[v0]->coord[p_dir]; y0 = verts[v0]->coord[s_dir]; 00600 x1 = verts[v1]->coord[p_dir]; y1 = verts[v1]->coord[s_dir]; 00601 x2 = verts[v2]->coord[p_dir]; y2 = verts[v2]->coord[s_dir]; 00602 x3 = verts[v3]->coord[p_dir]; y3 = verts[v3]->coord[s_dir]; 00603 dxa = x1 - x0; dya = y1 - y0; 00604 dxb = x3 - x2; dyb = y3 - y2; 00605 00606 product = dxa*dyb - dya*dxb; 00607 dasq = dxa*dxa + dya*dya; 00608 dbsq = dxb*dxb + dyb*dyb; 00609 prodsq = product*product; 00610 00611 if ( prodsq > EPSILON2*dasq*dbsq ) { 00612 p01x = x2 - x0; 00613 p01y = y2 - y0; 00614 s = (p01x*dyb - p01y*dxb)/product; 00615 if ( (s < 0.0) || (s > 1.0) ) return false; 00616 00617 t = (p01x*dya - p01y*dxa)/product; 00618 if ( (t < 0.0) || (t > 1.0) ) return false; 00619 00620 } 00621 00622 return true; 00623 } 00624 00625 void FBRetriangulate::add_tri_edge(int v0, int v1, int v0_type, int v1_type) 00626 { 00627 FB_Edge *edge; 00628 unsigned int i; 00629 00630 edge = new FB_Edge(v0,v1,v0_type,v1_type,false); 00631 edge->edge_type = INTERIOR_EDGE; 00632 my_tri->edge_list.push_back(edge); 00633 for ( i = 0; i < vertstufflist.size(); i++ ) { 00634 if ( vertstufflist[i]->v0 == v0 ) { 00635 vertstufflist[i]->edge_list.push_back(edge); 00636 } 00637 if ( vertstufflist[i]->v0 == v1 ) { 00638 vertstufflist[i]->edge_list.push_back(edge); 00639 v1_type = vertstufflist[i]->v0type; 00640 } 00641 } 00642 00643 } 00644 00645 bool FBRetriangulate::get_a_chain(std::vector<int> *chainlist) 00646 { 00647 bool status; 00648 int vthis, vprev, vstart; 00649 int direction; 00650 FB_Edge *edge; 00651 std::vector<FB_Edge*>::iterator dpe; 00652 status = false; 00653 dpe = my_tri->edge_list.begin(); 00654 // to keep compiler from warning that edge might be used uninitialized 00655 edge = 0; 00656 00657 while ( dpe != my_tri->edge_list.end() ) { 00658 edge = *dpe; 00659 dpe++; 00660 // Skip edges that are not interior edges. 00661 // if ( edge->v0_type == edge->v1_type ) continue; 00662 if ( edge->edge_type == BDRY_EDGE ) continue; 00663 if ( edge->num_times < 2 ) { 00664 if ( (edge->edge_type == BDRY_EDGE) && (edge->num_times == 1) ) 00665 continue; 00666 status = true; 00667 edge->num_times++; 00668 break; 00669 } 00670 } 00671 if ( status == true ) { 00672 if ( edge->num_times == 1 ) { 00673 vthis = edge->v1; 00674 vprev = edge->v0; 00675 direction = 1; 00676 } else { 00677 vthis = edge->v0; 00678 vprev = edge->v1; 00679 direction = 1; 00680 } 00681 vstart = vprev; 00682 chainlist->push_back(vthis); 00683 00684 while ( vthis != vstart ) { 00685 get_next_vert_in_chain(vthis,vprev,direction); 00686 chainlist->push_back(vthis); 00687 } 00688 } 00689 00690 if ( status == false ) { // There were no interior edges. 00691 // So just go around the perimeter. 00692 dpe = my_tri->edge_list.begin(); 00693 edge = *dpe; 00694 if ( edge->num_times != 0 ) { 00695 status = false; 00696 return status; 00697 } 00698 edge->num_times = 1; 00699 vthis = edge->v0; 00700 vprev = edge->v1; 00701 direction = 1; 00702 vstart = vprev; 00703 chainlist->push_back(vthis); 00704 00705 while ( vthis != vstart ) { 00706 get_next_vert_in_chain(vthis,vprev,direction); 00707 chainlist->push_back(vthis); 00708 } 00709 status = true; 00710 } 00711 00712 return status; 00713 00714 } 00715 00716 void FBRetriangulate::get_next_vert_in_chain(int& vthis, 00717 int& vprev, int direction) 00718 // Right now, direction always equals 1. 00719 { 00720 unsigned int i; 00721 FB_Edge *edge; 00722 std::vector<FB_Edge*>::iterator dpe, dpebegin, dpeend; 00723 00724 for ( i = 0; i < vertstufflist.size(); i++ ) { 00725 if ( vertstufflist[i]->v0 == (int)vthis ) break; 00726 } 00727 dpe = dpebegin = vertstufflist[i]->edge_list.begin(); 00728 dpeend = vertstufflist[i]->edge_list.end(); 00729 while ( dpe != dpeend ) { 00730 edge = *dpe; 00731 if ( (edge->v0 == vprev) || (edge->v1 == vprev) ) break; 00732 dpe++; 00733 } 00734 if ( direction == 1 ) { 00735 if ( dpe == dpebegin ) 00736 dpe = vertstufflist[i]->edge_list.end(); 00737 dpe--; 00738 } else { 00739 dpe++; 00740 if ( dpe == dpeend ) 00741 dpe = dpebegin; 00742 } 00743 edge = *dpe; 00744 vprev = vthis; 00745 if ( vthis == edge->v1 ) { 00746 // Swap the edge verts. We do this so that next time we see this 00747 // edge we will know that it was oriented to point in the direction 00748 // of the previous loop. Thus we will know to proceed in the 00749 // opposite direction next time. 00750 // (see edge->num_times test in get_a_chain().) 00751 unsigned int vtemp; 00752 vtemp = edge->v0; 00753 edge->v0 = edge->v1; 00754 edge->v1 = vtemp; 00755 vtemp = edge->v0_type; 00756 edge->v0_type = edge->v1_type; 00757 edge->v1_type = vtemp; 00758 } 00759 vthis = edge->v1; 00760 edge->num_times++; 00761 00762 } 00763 00764 void FBRetriangulate::sort_vertstufflist_edges() 00765 { 00766 // For each vertex that has more than 2 edges, sort the edges in CCW order. 00767 unsigned int i; 00768 FB_Edge *edge; 00769 std::vector<FB_Edge*>::iterator dpe, dpebegin, dpeend; 00770 double x0, y0, x1, y1, slope; 00771 int v0; 00772 unsigned int quadrant; 00773 00774 quadrant = 0; // Initialize so compiler won't warn. 00775 00776 for ( i = 0; i < vertstufflist.size(); i++ ) { 00777 if ( vertstufflist[i]->edge_list.size() > 2 ) { 00778 v0 = vertstufflist[i]->v0; 00779 x0 = verts[v0]->coord[p_dir]; 00780 y0 = verts[v0]->coord[s_dir]; 00781 dpe = vertstufflist[i]->edge_list.begin(); 00782 while ( dpe != vertstufflist[i]->edge_list.end() ) { 00783 edge = *dpe; 00784 dpe++; 00785 if ( edge->v0 == v0 ) { 00786 x1 = verts[edge->v1]->coord[p_dir]; 00787 y1 = verts[edge->v1]->coord[s_dir]; 00788 } else { 00789 x1 = verts[edge->v0]->coord[p_dir]; 00790 y1 = verts[edge->v0]->coord[s_dir]; 00791 } 00792 if ( fabs(x1-x0) < EPSILON ) { 00793 if ( y1 > y0 ) { 00794 slope = CUBIT_DBL_MAX; 00795 quadrant = 1; 00796 } else { 00797 slope = -CUBIT_DBL_MAX; 00798 quadrant = 4; 00799 } 00800 } else { 00801 slope = (y1-y0)/(x1-x0); 00802 if ( (x1 >= x0) && (y1 >= y0) ) quadrant = 1; 00803 else if ( (x1 < x0) && (y1 > y0) ) quadrant = 2; 00804 else if ( (x1 <= x0) && (y1 <= y0) ) quadrant = 3; 00805 else if ( (x1 > x0) && (y1 < y0) ) quadrant = 4; 00806 } 00807 edge->slope = slope; 00808 edge->quadrant = quadrant; 00809 } 00810 // Now sort the edge list by the value of quadrant or slope. 00811 // vertstufflist[i]->edge_list.sort(edgecompfn_less()); 00812 // vertstufflist[i]->edge_list.sort(edgecf_less); 00813 dpebegin = vertstufflist[i]->edge_list.begin(); 00814 dpeend = vertstufflist[i]->edge_list.end(); 00815 // if ( winding == CW ) 00816 std::sort(dpebegin,dpeend,edgecompfn_less()); 00817 // else 00818 // std::sort(dpebegin,dpeend,edgecompfn_more()); 00819 00820 } 00821 00822 dpe = vertstufflist[i]->edge_list.begin(); 00823 while ( dpe != vertstufflist[i]->edge_list.end() ) { 00824 edge = *dpe; 00825 dpe++; 00826 } 00827 00828 00829 } 00830 } 00831 00832 void FBRetriangulate::classify_edges() 00833 { 00834 // Flag boundary edges as such. 00835 FB_Edge *edge; 00836 std::vector<FB_Edge*>::iterator dpe; 00837 int type; 00838 00839 dpe = my_tri->edge_list.begin(); 00840 while ( dpe != my_tri->edge_list.end() ) { 00841 edge = *dpe; 00842 00843 if ( (edge->v0_type != INTERIOR_VERT) && 00844 (edge->v1_type != INTERIOR_VERT) ) { 00845 if ( edge->v0_type == edge->v1_type ) 00846 edge->edge_type = BDRY_EDGE; 00847 else { 00848 type = UNKNOWN; 00849 switch( edge->v0_type ) { 00850 case VERTEX_0: 00851 if ( edge->v1_type != EDGE_1 ) { 00852 type = BDRY_EDGE; 00853 if ( edge->edge_type == INTERSECTION_EDGE) { 00854 if ( edge->v1_type == VERTEX_1 ) 00855 my_tri->cubitedge0index = INTERSECTION_EDGE; 00856 else if ( edge->v1_type == VERTEX_2 ) 00857 my_tri->cubitedge2index = INTERSECTION_EDGE; 00858 } 00859 } 00860 break; 00861 case VERTEX_1: 00862 if ( edge->v1_type != EDGE_2 ) { 00863 type = BDRY_EDGE; 00864 if ( edge->edge_type == INTERSECTION_EDGE) { 00865 if ( edge->v1_type == VERTEX_2 ) 00866 my_tri->cubitedge1index = INTERSECTION_EDGE; 00867 else if ( edge->v1_type == VERTEX_0 ) 00868 my_tri->cubitedge0index = INTERSECTION_EDGE; 00869 } 00870 } 00871 break; 00872 case VERTEX_2: 00873 if ( edge->v1_type != EDGE_0 ) { 00874 type = BDRY_EDGE; 00875 if ( edge->edge_type == INTERSECTION_EDGE) { 00876 if ( edge->v1_type == VERTEX_1 ) 00877 my_tri->cubitedge1index = INTERSECTION_EDGE; 00878 else if ( edge->v1_type == VERTEX_0 ) 00879 my_tri->cubitedge2index = INTERSECTION_EDGE; 00880 } 00881 } 00882 break; 00883 case EDGE_0: 00884 if ( (edge->v1_type == VERTEX_0) || 00885 (edge->v1_type == VERTEX_1) ) { 00886 type = BDRY_EDGE; 00887 if ( edge->edge_type == INTERSECTION_EDGE) 00888 my_tri->cubitedge0index = INTERSECTION_EDGE; 00889 } 00890 break; 00891 case EDGE_1: 00892 if ( (edge->v1_type == VERTEX_1) || 00893 (edge->v1_type == VERTEX_2) ) { 00894 type = BDRY_EDGE; 00895 if ( edge->edge_type == INTERSECTION_EDGE) 00896 my_tri->cubitedge1index = INTERSECTION_EDGE; 00897 } 00898 break; 00899 case EDGE_2: 00900 if ( (edge->v1_type == VERTEX_2) || 00901 (edge->v1_type == VERTEX_0) ) { 00902 type = BDRY_EDGE; 00903 if ( edge->edge_type == INTERSECTION_EDGE) 00904 my_tri->cubitedge2index = INTERSECTION_EDGE; 00905 } 00906 break; 00907 } 00908 if ( type == BDRY_EDGE ) edge->edge_type = BDRY_EDGE; 00909 } 00910 } // else edge->edge_type = INTERIOR_EDGE; 00911 dpe++; 00912 } 00913 00914 } 00915 00916 void FBRetriangulate::get_edge_indices(int v0, int v1, int v2, int parent, 00917 int &e0index, int &e1index, 00918 int &e2index) 00919 { 00920 std::vector<FB_Edge*>::iterator itt; 00921 std::vector<FB_Triangle*>::iterator itp; 00922 FB_Edge *edge; 00923 int e_v0, e_v1, e_type, e_v0type, e_v1type; 00924 00925 itp = tris->begin(); 00926 itp += parent; 00927 itt = (*itp)->edge_list.begin(); 00928 while ( itt != (*itp)->edge_list.end() ) { 00929 edge = *itt; 00930 e_v0 = edge->v0; 00931 e_v1 = edge->v1; 00932 e_v0type = edge->v0_type; 00933 e_v1type = edge->v1_type; 00934 e_type = edge->edge_type; 00935 if ( ( (e_v0 == v0) && (e_v1 == v1) ) || 00936 ( (e_v0 == v1) && (e_v1 == v0) ) ) { 00937 if ( e_type == INTERSECTION_EDGE ) 00938 e0index = INTERSECTION_EDGE; 00939 else if ( e_type == INTERIOR_EDGE ) 00940 e0index = 0; 00941 else if ( (e_v0type == EDGE_0) || (e_v1type == EDGE_0) ) 00942 e0index = (*itp)->cubitedge0index; 00943 else if ( (e_v0type == EDGE_1) || (e_v1type == EDGE_1) ) 00944 e0index = (*itp)->cubitedge1index; 00945 else if ( (e_v0type == EDGE_2) || (e_v1type == EDGE_2) ) 00946 e0index = (*itp)->cubitedge2index; 00947 else if ( ( (e_v0type == VERTEX_0) || (e_v0type == VERTEX_1) ) & 00948 ( (e_v1type == VERTEX_0) || (e_v1type == VERTEX_1) ) ) 00949 e0index = (*itp)->cubitedge0index; 00950 else if ( ( (e_v0type == VERTEX_1) || (e_v0type == VERTEX_2) ) & 00951 ( (e_v1type == VERTEX_1) || (e_v1type == VERTEX_2) ) ) 00952 e1index = (*itp)->cubitedge1index; 00953 else if ( ( (e_v0type == VERTEX_2) || (e_v0type == VERTEX_0) ) & 00954 ( (e_v1type == VERTEX_2) || (e_v1type == VERTEX_0) ) ) 00955 e2index = (*itp)->cubitedge2index; 00956 } 00957 else if ( ( (e_v0 == v1) && (e_v1 == v2) ) || 00958 ( (e_v0 == v2) && (e_v1 == v1) ) ) { 00959 if ( e_type == INTERSECTION_EDGE ) 00960 e1index = INTERSECTION_EDGE; 00961 else if ( e_type == INTERIOR_EDGE ) 00962 e1index = 0; 00963 else if ( (e_v0type == EDGE_0) || (e_v1type == EDGE_0) ) 00964 e1index = (*itp)->cubitedge0index; 00965 else if ( (e_v0type == EDGE_1) || (e_v1type == EDGE_1) ) 00966 e1index = (*itp)->cubitedge1index; 00967 else if ( (e_v0type == EDGE_2) || (e_v1type == EDGE_2) ) 00968 e1index = (*itp)->cubitedge2index; 00969 else if ( ( (e_v0type == VERTEX_0) || (e_v0type == VERTEX_1) ) & 00970 ( (e_v1type == VERTEX_0) || (e_v1type == VERTEX_1) ) ) 00971 e0index = (*itp)->cubitedge0index; 00972 else if ( ( (e_v0type == VERTEX_1) || (e_v0type == VERTEX_2) ) & 00973 ( (e_v1type == VERTEX_1) || (e_v1type == VERTEX_2) ) ) 00974 e1index = (*itp)->cubitedge1index; 00975 else if ( ( (e_v0type == VERTEX_2) || (e_v0type == VERTEX_0) ) & 00976 ( (e_v1type == VERTEX_2) || (e_v1type == VERTEX_0) ) ) 00977 e2index = (*itp)->cubitedge2index; 00978 } 00979 else if ( ( (e_v0 == v2) && (e_v1 == v0) ) || 00980 ( (e_v0 == v0) && (e_v1 == v2) ) ) { 00981 if ( e_type == INTERSECTION_EDGE ) 00982 e2index = INTERSECTION_EDGE; 00983 else if ( e_type == INTERIOR_EDGE ) 00984 e2index = 0; 00985 else if ( (e_v0type == EDGE_0) || (e_v1type == EDGE_0) ) 00986 e2index = (*itp)->cubitedge0index; 00987 else if ( (e_v0type == EDGE_1) || (e_v1type == EDGE_1) ) 00988 e2index = (*itp)->cubitedge1index; 00989 else if ( (e_v0type == EDGE_2) || (e_v1type == EDGE_2) ) 00990 e2index = (*itp)->cubitedge2index; 00991 else if ( ( (e_v0type == VERTEX_0) || (e_v0type == VERTEX_1) ) & 00992 ( (e_v1type == VERTEX_0) || (e_v1type == VERTEX_1) ) ) 00993 e0index = (*itp)->cubitedge0index; 00994 else if ( ( (e_v0type == VERTEX_1) || (e_v0type == VERTEX_2) ) & 00995 ( (e_v1type == VERTEX_1) || (e_v1type == VERTEX_2) ) ) 00996 e1index = (*itp)->cubitedge1index; 00997 else if ( ( (e_v0type == VERTEX_2) || (e_v0type == VERTEX_0) ) & 00998 ( (e_v1type == VERTEX_2) || (e_v1type == VERTEX_0) ) ) 00999 e2index = (*itp)->cubitedge2index; 01000 } 01001 01002 itt++; 01003 } 01004 01005 } 01006 01007
1.7.6.1 
