1 // Copyright (C) 2007-2016 CEA/DEN, EDF R&D
3 // This library is free software; you can redistribute it and/or
4 // modify it under the terms of the GNU Lesser General Public
5 // License as published by the Free Software Foundation; either
6 // version 2.1 of the License, or (at your option) any later version.
8 // This library is distributed in the hope that it will be useful,
9 // but WITHOUT ANY WARRANTY; without even the implied warranty of
10 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
11 // Lesser General Public License for more details.
13 // You should have received a copy of the GNU Lesser General Public
14 // License along with this library; if not, write to the Free Software
15 // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
17 // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
19 // Author : Anthony Geay (CEA/DEN)
21 #include "MEDCouplingUMesh.hxx"
22 #include "MEDCoupling1GTUMesh.hxx"
23 #include "MEDCouplingFieldDouble.hxx"
24 #include "CellModel.hxx"
25 #include "VolSurfUser.txx"
26 #include "InterpolationUtils.hxx"
27 #include "PointLocatorAlgos.txx"
29 #include "BBTreeDst.txx"
30 #include "DirectedBoundingBox.hxx"
31 #include "InterpKernelGeo2DEdgeArcCircle.hxx"
32 #include "InterpKernelAutoPtr.hxx"
33 #include "InterpKernelGeo2DNode.hxx"
34 #include "InterpKernelGeo2DEdgeLin.hxx"
35 #include "InterpKernelGeo2DEdgeArcCircle.hxx"
36 #include "InterpKernelGeo2DQuadraticPolygon.hxx"
37 #include "TranslationRotationMatrix.hxx"
38 #include "VectorUtils.hxx"
39 #include "MEDCouplingSkyLineArray.hxx"
49 using namespace MEDCoupling;
53 int InternalAddPoint(const INTERP_KERNEL::Edge *e, int id, const double *coo, int startId, int endId, DataArrayDouble& addCoo, int& nodesCnter)
59 int ret(nodesCnter++);
61 e->getMiddleOfPoints(coo+2*startId,coo+2*endId,newPt);
62 addCoo.insertAtTheEnd(newPt,newPt+2);
67 int InternalAddPointOriented(const INTERP_KERNEL::Edge *e, int id, const double *coo, int startId, int endId, DataArrayDouble& addCoo, int& nodesCnter)
73 int ret(nodesCnter++);
75 e->getMiddleOfPointsOriented(coo+2*startId,coo+2*endId,newPt);
76 addCoo.insertAtTheEnd(newPt,newPt+2);
82 void EnterTheResultOf2DCellFirst(const INTERP_KERNEL::Edge *e, int start, int stp, int nbOfEdges, bool linOrArc, const double *coords, const int *connBg, int offset, DataArrayInt *newConnOfCell, DataArrayDouble *appendedCoords, std::vector<int>& middles)
85 int trueStart(start>=0?start:nbOfEdges+start);
86 tmp[0]=linOrArc?(int)INTERP_KERNEL::NORM_QPOLYG:(int)INTERP_KERNEL::NORM_POLYGON; tmp[1]=connBg[trueStart]; tmp[2]=connBg[stp];
87 newConnOfCell->insertAtTheEnd(tmp,tmp+3);
92 int tmp2(0),tmp3(appendedCoords->getNumberOfTuples()/2);
93 InternalAddPointOriented(e,-1,coords,tmp[1],tmp[2],*appendedCoords,tmp2);
94 middles.push_back(tmp3+offset);
97 middles.push_back(connBg[trueStart+nbOfEdges]);
101 void EnterTheResultOf2DCellMiddle(const INTERP_KERNEL::Edge *e, int start, int stp, int nbOfEdges, bool linOrArc, const double *coords, const int *connBg, int offset, DataArrayInt *newConnOfCell, DataArrayDouble *appendedCoords, std::vector<int>& middles)
103 int tmpSrt(newConnOfCell->back()),tmpEnd(connBg[stp]);
104 newConnOfCell->pushBackSilent(tmpEnd);
109 int tmp2(0),tmp3(appendedCoords->getNumberOfTuples()/2);
110 InternalAddPointOriented(e,-1,coords,tmpSrt,tmpEnd,*appendedCoords,tmp2);
111 middles.push_back(tmp3+offset);
114 middles.push_back(connBg[start+nbOfEdges]);
118 void EnterTheResultOf2DCellEnd(const INTERP_KERNEL::Edge *e, int start, int stp, int nbOfEdges, bool linOrArc, const double *coords, const int *connBg, int offset, DataArrayInt *newConnOfCell, DataArrayDouble *appendedCoords, std::vector<int>& middles)
120 // only the quadratic point to deal with:
123 if(stp-start>1) // if we are covering more than one segment we need to create a new mid point
125 int tmpSrt(connBg[start]),tmpEnd(connBg[stp % nbOfEdges]); // % to handle last seg.
126 int tmp2(0),tmp3(appendedCoords->getNumberOfTuples()/2);
127 InternalAddPointOriented(e,-1,coords,tmpSrt,tmpEnd,*appendedCoords,tmp2);
128 middles.push_back(tmp3+offset);
131 middles.push_back(connBg[start+nbOfEdges]);
135 void IKGeo2DInternalMapper2(INTERP_KERNEL::Node *n, const std::map<MCAuto<INTERP_KERNEL::Node>,int>& m, int forbVal0, int forbVal1, std::vector<int>& isect)
137 MCAuto<INTERP_KERNEL::Node> nTmp(n); nTmp->incrRef();
138 std::map<MCAuto<INTERP_KERNEL::Node>,int>::const_iterator it(m.find(nTmp));
140 throw INTERP_KERNEL::Exception("Internal error in remapping !");
142 if(v==forbVal0 || v==forbVal1)
144 if(std::find(isect.begin(),isect.end(),v)==isect.end())
148 bool IKGeo2DInternalMapper(const INTERP_KERNEL::ComposedEdge& c, const std::map<MCAuto<INTERP_KERNEL::Node>,int>& m, int forbVal0, int forbVal1, std::vector<int>& isect)
153 bool presenceOfOn(false);
154 for(int i=0;i<sz;i++)
156 INTERP_KERNEL::ElementaryEdge *e(c[i]);
157 if(e->getLoc()!=INTERP_KERNEL::FULL_ON_1)
159 IKGeo2DInternalMapper2(e->getStartNode(),m,forbVal0,forbVal1,isect);
160 IKGeo2DInternalMapper2(e->getEndNode(),m,forbVal0,forbVal1,isect);
166 namespace MEDCoupling
169 INTERP_KERNEL::Edge *MEDCouplingUMeshBuildQPFromEdge2(INTERP_KERNEL::NormalizedCellType typ, const int *bg, const double *coords2D, std::map< MCAuto<INTERP_KERNEL::Node>,int>& m)
171 INTERP_KERNEL::Edge *ret(0);
172 MCAuto<INTERP_KERNEL::Node> n0(new INTERP_KERNEL::Node(coords2D[2*bg[0]],coords2D[2*bg[0]+1])),n1(new INTERP_KERNEL::Node(coords2D[2*bg[1]],coords2D[2*bg[1]+1]));
173 m[n0]=bg[0]; m[n1]=bg[1];
176 case INTERP_KERNEL::NORM_SEG2:
178 ret=new INTERP_KERNEL::EdgeLin(n0,n1);
181 case INTERP_KERNEL::NORM_SEG3:
183 INTERP_KERNEL::Node *n2(new INTERP_KERNEL::Node(coords2D[2*bg[2]],coords2D[2*bg[2]+1])); m[n2]=bg[2];
184 INTERP_KERNEL::EdgeLin *e1(new INTERP_KERNEL::EdgeLin(n0,n2)),*e2(new INTERP_KERNEL::EdgeLin(n2,n1));
185 INTERP_KERNEL::SegSegIntersector inters(*e1,*e2);
186 // is the SEG3 degenerated, and thus can be reduced to a SEG2?
187 bool colinearity(inters.areColinears());
188 delete e1; delete e2;
190 { ret=new INTERP_KERNEL::EdgeLin(n0,n1); }
192 { ret=new INTERP_KERNEL::EdgeArcCircle(n0,n2,n1); }
196 throw INTERP_KERNEL::Exception("MEDCouplingUMeshBuildQPFromEdge2 : Expecting a mesh with spaceDim==2 and meshDim==1 !");
201 INTERP_KERNEL::Edge *MEDCouplingUMeshBuildQPFromEdge(INTERP_KERNEL::NormalizedCellType typ, std::map<int, std::pair<INTERP_KERNEL::Node *,bool> >& mapp2, const int *bg)
203 INTERP_KERNEL::Edge *ret=0;
206 case INTERP_KERNEL::NORM_SEG2:
208 ret=new INTERP_KERNEL::EdgeLin(mapp2[bg[0]].first,mapp2[bg[1]].first);
211 case INTERP_KERNEL::NORM_SEG3:
213 INTERP_KERNEL::EdgeLin *e1=new INTERP_KERNEL::EdgeLin(mapp2[bg[0]].first,mapp2[bg[2]].first);
214 INTERP_KERNEL::EdgeLin *e2=new INTERP_KERNEL::EdgeLin(mapp2[bg[2]].first,mapp2[bg[1]].first);
215 INTERP_KERNEL::SegSegIntersector inters(*e1,*e2);
216 // is the SEG3 degenerated, and thus can be reduced to a SEG2?
217 bool colinearity=inters.areColinears();
218 delete e1; delete e2;
220 ret=new INTERP_KERNEL::EdgeLin(mapp2[bg[0]].first,mapp2[bg[1]].first);
222 ret=new INTERP_KERNEL::EdgeArcCircle(mapp2[bg[0]].first,mapp2[bg[2]].first,mapp2[bg[1]].first);
223 mapp2[bg[2]].second=false;
227 throw INTERP_KERNEL::Exception("MEDCouplingUMeshBuildQPFromEdge : Expecting a mesh with spaceDim==2 and meshDim==1 !");
233 * This method creates a sub mesh in Geometric2D DS. The sub mesh is composed by the sub set of cells in 'candidates' taken from
234 * the global mesh 'mDesc'.
235 * The input mesh 'mDesc' must be so that mDim==1 and spaceDim==2.
236 * 'mapp' returns a mapping between local numbering in submesh (represented by a Node*) and the global node numbering in 'mDesc'.
238 INTERP_KERNEL::QuadraticPolygon *MEDCouplingUMeshBuildQPFromMesh(const MEDCouplingUMesh *mDesc, const std::vector<int>& candidates,
239 std::map<INTERP_KERNEL::Node *,int>& mapp)
242 std::map<int, std::pair<INTERP_KERNEL::Node *,bool> > mapp2;//bool is for a flag specifying if node is boundary (true) or only a middle for SEG3.
243 const double *coo=mDesc->getCoords()->getConstPointer();
244 const int *c=mDesc->getNodalConnectivity()->getConstPointer();
245 const int *cI=mDesc->getNodalConnectivityIndex()->getConstPointer();
247 for(std::vector<int>::const_iterator it=candidates.begin();it!=candidates.end();it++)
248 s.insert(c+cI[*it]+1,c+cI[(*it)+1]);
249 for(std::set<int>::const_iterator it2=s.begin();it2!=s.end();it2++)
251 INTERP_KERNEL::Node *n=new INTERP_KERNEL::Node(coo[2*(*it2)],coo[2*(*it2)+1]);
252 mapp2[*it2]=std::pair<INTERP_KERNEL::Node *,bool>(n,true);
254 INTERP_KERNEL::QuadraticPolygon *ret=new INTERP_KERNEL::QuadraticPolygon;
255 for(std::vector<int>::const_iterator it=candidates.begin();it!=candidates.end();it++)
257 INTERP_KERNEL::NormalizedCellType typ=(INTERP_KERNEL::NormalizedCellType)c[cI[*it]];
258 ret->pushBack(MEDCouplingUMeshBuildQPFromEdge(typ,mapp2,c+cI[*it]+1));
260 for(std::map<int, std::pair<INTERP_KERNEL::Node *,bool> >::const_iterator it2=mapp2.begin();it2!=mapp2.end();it2++)
262 if((*it2).second.second)
263 mapp[(*it2).second.first]=(*it2).first;
264 ((*it2).second.first)->decrRef();
269 INTERP_KERNEL::Node *MEDCouplingUMeshBuildQPNode(int nodeId, const double *coo1, int offset1, const double *coo2, int offset2, const std::vector<double>& addCoo)
273 int locId=nodeId-offset2;
274 return new INTERP_KERNEL::Node(addCoo[2*locId],addCoo[2*locId+1]);
278 int locId=nodeId-offset1;
279 return new INTERP_KERNEL::Node(coo2[2*locId],coo2[2*locId+1]);
281 return new INTERP_KERNEL::Node(coo1[2*nodeId],coo1[2*nodeId+1]);
285 * Construct a mapping between set of Nodes and the standard MEDCoupling connectivity format (c, cI).
287 void MEDCouplingUMeshBuildQPFromMesh3(const double *coo1, int offset1, const double *coo2, int offset2, const std::vector<double>& addCoo,
288 const int *desc1Bg, const int *desc1End, const std::vector<std::vector<int> >& intesctEdges1,
289 /*output*/std::map<INTERP_KERNEL::Node *,int>& mapp, std::map<int,INTERP_KERNEL::Node *>& mappRev)
291 for(const int *desc1=desc1Bg;desc1!=desc1End;desc1++)
293 int eltId1=abs(*desc1)-1;
294 for(std::vector<int>::const_iterator it1=intesctEdges1[eltId1].begin();it1!=intesctEdges1[eltId1].end();it1++)
296 std::map<int,INTERP_KERNEL::Node *>::const_iterator it=mappRev.find(*it1);
297 if(it==mappRev.end())
299 INTERP_KERNEL::Node *node=MEDCouplingUMeshBuildQPNode(*it1,coo1,offset1,coo2,offset2,addCoo);
311 * Returns true if a colinearization has been found in the given cell. If false is returned the content pushed in \a newConnOfCell is equal to [ \a connBg , \a connEnd ) .
312 * \a appendedCoords is a DataArrayDouble instance with number of components equal to one (even if the items are pushed by pair).
314 bool MEDCouplingUMesh::Colinearize2DCell(const double *coords, const int *connBg, const int *connEnd, int offset, DataArrayInt *newConnOfCell, DataArrayDouble *appendedCoords)
316 std::size_t sz(std::distance(connBg,connEnd));
317 if(sz<3)//3 because 2+1(for the cell type) and 2 is the minimal number of edges of 2D cell.
318 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::Colinearize2DCell : the input cell has invalid format !");
320 INTERP_KERNEL::AutoPtr<int> tmpConn(new int[sz]);
321 const INTERP_KERNEL::CellModel& cm(INTERP_KERNEL::CellModel::GetCellModel((INTERP_KERNEL::NormalizedCellType)connBg[0]));
322 unsigned nbs(cm.getNumberOfSons2(connBg+1,sz));
323 unsigned nbOfHit(0); // number of fusions operated
324 int posBaseElt(0),posEndElt(0),nbOfTurn(0);
325 const unsigned int maxNbOfHit = cm.isQuadratic() ? nbs-2 : nbs-3; // a quad cell is authorized to end up with only two edges, a linear one has to keep 3 at least
326 INTERP_KERNEL::NormalizedCellType typeOfSon;
327 std::vector<int> middles;
329 for(;(nbOfTurn+nbOfHit)<nbs;nbOfTurn++)
331 cm.fillSonCellNodalConnectivity2(posBaseElt,connBg+1,sz,tmpConn,typeOfSon);
332 std::map<MCAuto<INTERP_KERNEL::Node>,int> m;
333 INTERP_KERNEL::Edge *e(MEDCouplingUMeshBuildQPFromEdge2(typeOfSon,tmpConn,coords,m));
334 posEndElt = posBaseElt+1;
336 // Look backward first: are the final edges of the cells colinear with the first ones?
337 // This initializes posBaseElt.
340 for(unsigned i=1;i<nbs && nbOfHit<maxNbOfHit;i++) // 2nd condition is to avoid ending with a cell with one single edge
342 cm.fillSonCellNodalConnectivity2(nbs-i,connBg+1,sz,tmpConn,typeOfSon);
343 INTERP_KERNEL::Edge *eCand(MEDCouplingUMeshBuildQPFromEdge2(typeOfSon,tmpConn,coords,m));
344 INTERP_KERNEL::EdgeIntersector *eint(INTERP_KERNEL::Edge::BuildIntersectorWith(e,eCand));
345 bool isColinear=eint->areColinears();
359 const unsigned fwdStart = (nbOfTurn == 0 ? 0 : posBaseElt); // the first element to be inspected going forward
360 for(unsigned j=fwdStart+1;j<nbs && nbOfHit<maxNbOfHit;j++) // 2nd condition is to avoid ending with a cell with one single edge
362 cm.fillSonCellNodalConnectivity2((int)j,connBg+1,sz,tmpConn,typeOfSon); // get edge #j's connectivity
363 INTERP_KERNEL::Edge *eCand(MEDCouplingUMeshBuildQPFromEdge2(typeOfSon,tmpConn,coords,m));
364 INTERP_KERNEL::EdgeIntersector *eint(INTERP_KERNEL::Edge::BuildIntersectorWith(e,eCand));
365 bool isColinear(eint->areColinears());
377 //push [posBaseElt,posEndElt) in newConnOfCell using e
378 // The if clauses below are (voluntary) not mutually exclusive: on a quad cell with 2 edges, the end of the connectivity is also its beginning!
380 // at the beginning of the connectivity (insert type)
381 EnterTheResultOf2DCellFirst(e,posBaseElt,posEndElt,(int)nbs,cm.isQuadratic(),coords,connBg+1,offset,newConnOfCell,appendedCoords,middles);
382 else if((nbOfHit+nbOfTurn) != (nbs-1))
384 EnterTheResultOf2DCellMiddle(e,posBaseElt,posEndElt,(int)nbs,cm.isQuadratic(),coords,connBg+1,offset,newConnOfCell,appendedCoords,middles);
385 if ((nbOfHit+nbOfTurn) == (nbs-1))
386 // at the end (only quad points to deal with)
387 EnterTheResultOf2DCellEnd(e,posBaseElt,posEndElt,(int)nbs,cm.isQuadratic(),coords,connBg+1,offset,newConnOfCell,appendedCoords,middles);
388 posBaseElt=posEndElt;
392 newConnOfCell->insertAtTheEnd(middles.begin(),middles.end());
398 bool IsColinearOfACellOf(const std::vector< std::vector<int> >& intersectEdge1, const std::vector<int>& candidates, int start, int stop, int& retVal)
400 if(candidates.empty())
402 for(std::vector<int>::const_iterator it=candidates.begin();it!=candidates.end();it++)
404 const std::vector<int>& pool(intersectEdge1[*it]);
405 int tmp[2]; tmp[0]=start; tmp[1]=stop;
406 if(std::search(pool.begin(),pool.end(),tmp,tmp+2)!=pool.end())
411 tmp[0]=stop; tmp[1]=start;
412 if(std::search(pool.begin(),pool.end(),tmp,tmp+2)!=pool.end())
422 * This method performs the 2nd step of Partition of 2D mesh.
423 * This method has 4 inputs :
424 * - a mesh 'm1' with meshDim==1 and a SpaceDim==2
425 * - a mesh 'm2' with meshDim==1 and a SpaceDim==2
426 * - subDiv of size 'm2->getNumberOfCells()' that lists for each seg cell in 'm2' the splitting node ids randomly sorted.
427 * The aim of this method is to sort the splitting nodes, if any, and to put them in 'intersectEdge' output parameter based on edges of mesh 'm2'
428 * Nodes end up lying consecutively on a cutted edge.
429 * \param m1 is expected to be a mesh of meshDimension equal to 1 and spaceDim equal to 2. No check of that is performed by this method.
430 * (Only present for its coords in case of 'subDiv' shares some nodes of 'm1')
431 * \param m2 is expected to be a mesh of meshDimension equal to 1 and spaceDim equal to 2. No check of that is performed by this method.
432 * \param addCoo input parameter with additional nodes linked to intersection of the 2 meshes.
433 * \param[out] intersectEdge the same content as subDiv, but correctly oriented.
435 void MEDCouplingUMesh::BuildIntersectEdges(const MEDCouplingUMesh *m1, const MEDCouplingUMesh *m2,
436 const std::vector<double>& addCoo,
437 const std::vector< std::vector<int> >& subDiv, std::vector< std::vector<int> >& intersectEdge)
439 int offset1=m1->getNumberOfNodes();
440 int ncell=m2->getNumberOfCells();
441 const int *c=m2->getNodalConnectivity()->begin();
442 const int *cI=m2->getNodalConnectivityIndex()->begin();
443 const double *coo=m2->getCoords()->begin();
444 const double *cooBis=m1->getCoords()->begin();
445 int offset2=offset1+m2->getNumberOfNodes();
446 intersectEdge.resize(ncell);
447 for(int i=0;i<ncell;i++,cI++)
449 const std::vector<int>& divs=subDiv[i];
450 int nnode=cI[1]-cI[0]-1;
451 std::map<int, std::pair<INTERP_KERNEL::Node *,bool> > mapp2;
452 std::map<INTERP_KERNEL::Node *, int> mapp22;
453 for(int j=0;j<nnode;j++)
455 INTERP_KERNEL::Node *nn=new INTERP_KERNEL::Node(coo[2*c[(*cI)+j+1]],coo[2*c[(*cI)+j+1]+1]);
456 int nnid=c[(*cI)+j+1];
457 mapp2[nnid]=std::pair<INTERP_KERNEL::Node *,bool>(nn,true);
458 mapp22[nn]=nnid+offset1;
460 INTERP_KERNEL::Edge *e=MEDCouplingUMeshBuildQPFromEdge((INTERP_KERNEL::NormalizedCellType)c[*cI],mapp2,c+(*cI)+1);
461 for(std::map<int, std::pair<INTERP_KERNEL::Node *,bool> >::const_iterator it=mapp2.begin();it!=mapp2.end();it++)
462 ((*it).second.first)->decrRef();
463 std::vector<INTERP_KERNEL::Node *> addNodes(divs.size());
464 std::map<INTERP_KERNEL::Node *,int> mapp3;
465 for(std::size_t j=0;j<divs.size();j++)
468 INTERP_KERNEL::Node *tmp=0;
470 tmp=new INTERP_KERNEL::Node(cooBis[2*id],cooBis[2*id+1]);
472 tmp=new INTERP_KERNEL::Node(coo[2*(id-offset1)],coo[2*(id-offset1)+1]);//if it happens, bad news mesh 'm2' is non conform.
474 tmp=new INTERP_KERNEL::Node(addCoo[2*(id-offset2)],addCoo[2*(id-offset2)+1]);
478 e->sortIdsAbs(addNodes,mapp22,mapp3,intersectEdge[i]);
479 for(std::vector<INTERP_KERNEL::Node *>::const_iterator it=addNodes.begin();it!=addNodes.end();it++)
485 MEDCouplingUMesh *BuildMesh1DCutFrom(const MEDCouplingUMesh *mesh1D, const std::vector< std::vector<int> >& intersectEdge2, const DataArrayDouble *coords1, const std::vector<double>& addCoo, const std::map<int,int>& mergedNodes, const std::vector< std::vector<int> >& colinear2, const std::vector< std::vector<int> >& intersectEdge1,
486 MCAuto<DataArrayInt>& idsInRetColinear, MCAuto<DataArrayInt>& idsInMesh1DForIdsInRetColinear)
488 idsInRetColinear=DataArrayInt::New(); idsInRetColinear->alloc(0,1);
489 idsInMesh1DForIdsInRetColinear=DataArrayInt::New(); idsInMesh1DForIdsInRetColinear->alloc(0,1);
490 int nCells(mesh1D->getNumberOfCells());
491 if(nCells!=(int)intersectEdge2.size())
492 throw INTERP_KERNEL::Exception("BuildMesh1DCutFrom : internal error # 1 !");
493 const DataArrayDouble *coo2(mesh1D->getCoords());
494 const int *c(mesh1D->getNodalConnectivity()->begin()),*ci(mesh1D->getNodalConnectivityIndex()->begin());
495 const double *coo2Ptr(coo2->begin());
496 int offset1(coords1->getNumberOfTuples());
497 int offset2(offset1+coo2->getNumberOfTuples());
498 int offset3(offset2+addCoo.size()/2);
499 std::vector<double> addCooQuad;
500 MCAuto<DataArrayInt> cOut(DataArrayInt::New()),ciOut(DataArrayInt::New()); cOut->alloc(0,1); ciOut->alloc(1,1); ciOut->setIJ(0,0,0);
501 int tmp[4],cicnt(0),kk(0);
502 for(int i=0;i<nCells;i++)
504 std::map<MCAuto<INTERP_KERNEL::Node>,int> m;
505 INTERP_KERNEL::Edge *e(MEDCouplingUMeshBuildQPFromEdge2((INTERP_KERNEL::NormalizedCellType)c[ci[i]],c+ci[i]+1,coo2Ptr,m));
506 const std::vector<int>& subEdges(intersectEdge2[i]);
507 int nbSubEdge(subEdges.size()/2);
508 for(int j=0;j<nbSubEdge;j++,kk++)
510 MCAuto<INTERP_KERNEL::Node> n1(MEDCouplingUMeshBuildQPNode(subEdges[2*j],coords1->begin(),offset1,coo2Ptr,offset2,addCoo)),n2(MEDCouplingUMeshBuildQPNode(subEdges[2*j+1],coords1->begin(),offset1,coo2Ptr,offset2,addCoo));
511 MCAuto<INTERP_KERNEL::Edge> e2(e->buildEdgeLyingOnMe(n1,n2));
512 INTERP_KERNEL::Edge *e2Ptr(e2);
513 std::map<int,int>::const_iterator itm;
514 if(dynamic_cast<INTERP_KERNEL::EdgeArcCircle *>(e2Ptr))
516 tmp[0]=INTERP_KERNEL::NORM_SEG3;
517 itm=mergedNodes.find(subEdges[2*j]);
518 tmp[1]=itm!=mergedNodes.end()?(*itm).second:subEdges[2*j];
519 itm=mergedNodes.find(subEdges[2*j+1]);
520 tmp[2]=itm!=mergedNodes.end()?(*itm).second:subEdges[2*j+1];
521 tmp[3]=offset3+(int)addCooQuad.size()/2;
523 e2->getBarycenter(tmp2); addCooQuad.insert(addCooQuad.end(),tmp2,tmp2+2);
525 cOut->insertAtTheEnd(tmp,tmp+4);
526 ciOut->pushBackSilent(cicnt);
530 tmp[0]=INTERP_KERNEL::NORM_SEG2;
531 itm=mergedNodes.find(subEdges[2*j]);
532 tmp[1]=itm!=mergedNodes.end()?(*itm).second:subEdges[2*j];
533 itm=mergedNodes.find(subEdges[2*j+1]);
534 tmp[2]=itm!=mergedNodes.end()?(*itm).second:subEdges[2*j+1];
536 cOut->insertAtTheEnd(tmp,tmp+3);
537 ciOut->pushBackSilent(cicnt);
540 if(IsColinearOfACellOf(intersectEdge1,colinear2[i],tmp[1],tmp[2],tmp00))
542 idsInRetColinear->pushBackSilent(kk);
543 idsInMesh1DForIdsInRetColinear->pushBackSilent(tmp00);
548 MCAuto<MEDCouplingUMesh> ret(MEDCouplingUMesh::New(mesh1D->getName(),1));
549 ret->setConnectivity(cOut,ciOut,true);
550 MCAuto<DataArrayDouble> arr3(DataArrayDouble::New());
551 arr3->useArray(&addCoo[0],false,C_DEALLOC,(int)addCoo.size()/2,2);
552 MCAuto<DataArrayDouble> arr4(DataArrayDouble::New()); arr4->useArray(&addCooQuad[0],false,C_DEALLOC,(int)addCooQuad.size()/2,2);
553 std::vector<const DataArrayDouble *> coordss(4);
554 coordss[0]=coords1; coordss[1]=mesh1D->getCoords(); coordss[2]=arr3; coordss[3]=arr4;
555 MCAuto<DataArrayDouble> arr(DataArrayDouble::Aggregate(coordss));
560 MEDCouplingUMesh *BuildRefined2DCellLinear(const DataArrayDouble *coords, const int *descBg, const int *descEnd, const std::vector< std::vector<int> >& intersectEdge1)
562 std::vector<int> allEdges;
563 for(const int *it2(descBg);it2!=descEnd;it2++)
565 const std::vector<int>& edge1(intersectEdge1[std::abs(*it2)-1]);
567 allEdges.insert(allEdges.end(),edge1.begin(),edge1.end());
569 allEdges.insert(allEdges.end(),edge1.rbegin(),edge1.rend());
571 std::size_t nb(allEdges.size());
573 throw INTERP_KERNEL::Exception("BuildRefined2DCellLinear : internal error 1 !");
574 std::size_t nbOfEdgesOf2DCellSplit(nb/2);
575 MCAuto<MEDCouplingUMesh> ret(MEDCouplingUMesh::New("",2));
576 ret->setCoords(coords);
577 ret->allocateCells(1);
578 std::vector<int> connOut(nbOfEdgesOf2DCellSplit);
579 for(std::size_t kk=0;kk<nbOfEdgesOf2DCellSplit;kk++)
580 connOut[kk]=allEdges[2*kk];
581 ret->insertNextCell(INTERP_KERNEL::NORM_POLYGON,connOut.size(),&connOut[0]);
585 MEDCouplingUMesh *BuildRefined2DCellQuadratic(const DataArrayDouble *coords, const MEDCouplingUMesh *mesh2D, int cellIdInMesh2D, const int *descBg, const int *descEnd, const std::vector< std::vector<int> >& intersectEdge1)
587 const int *c(mesh2D->getNodalConnectivity()->begin()),*ci(mesh2D->getNodalConnectivityIndex()->begin());
588 const INTERP_KERNEL::CellModel& cm(INTERP_KERNEL::CellModel::GetCellModel((INTERP_KERNEL::NormalizedCellType)c[ci[cellIdInMesh2D]]));
590 unsigned sz(cm.getNumberOfSons2(c+ci[cellIdInMesh2D]+1,ci[cellIdInMesh2D+1]-ci[cellIdInMesh2D]-1));
591 if(sz!=std::distance(descBg,descEnd))
592 throw INTERP_KERNEL::Exception("BuildRefined2DCellQuadratic : internal error 1 !");
593 INTERP_KERNEL::AutoPtr<int> tmpPtr(new int[ci[cellIdInMesh2D+1]-ci[cellIdInMesh2D]]);
594 std::vector<int> allEdges,centers;
595 const double *coordsPtr(coords->begin());
596 MCAuto<DataArrayDouble> addCoo(DataArrayDouble::New()); addCoo->alloc(0,1);
597 int offset(coords->getNumberOfTuples());
598 for(const int *it2(descBg);it2!=descEnd;it2++,ii++)
600 INTERP_KERNEL::NormalizedCellType typeOfSon;
601 cm.fillSonCellNodalConnectivity2(ii,c+ci[cellIdInMesh2D]+1,ci[cellIdInMesh2D+1]-ci[cellIdInMesh2D]-1,tmpPtr,typeOfSon);
602 const std::vector<int>& edge1(intersectEdge1[std::abs(*it2)-1]);
604 allEdges.insert(allEdges.end(),edge1.begin(),edge1.end());
606 allEdges.insert(allEdges.end(),edge1.rbegin(),edge1.rend());
608 centers.push_back(tmpPtr[2]);//special case where no subsplit of edge -> reuse the original center.
610 {//the current edge has been subsplit -> create corresponding centers.
611 std::size_t nbOfCentersToAppend(edge1.size()/2);
612 std::map< MCAuto<INTERP_KERNEL::Node>,int> m;
613 MCAuto<INTERP_KERNEL::Edge> ee(MEDCouplingUMeshBuildQPFromEdge2(typeOfSon,tmpPtr,coordsPtr,m));
614 std::vector<int>::const_iterator it3(allEdges.end()-edge1.size());
615 for(std::size_t k=0;k<nbOfCentersToAppend;k++)
618 const double *aa(coordsPtr+2*(*it3++));
619 const double *bb(coordsPtr+2*(*it3++));
620 ee->getMiddleOfPoints(aa,bb,tmpp);
621 addCoo->insertAtTheEnd(tmpp,tmpp+2);
622 centers.push_back(offset+k);
626 std::size_t nb(allEdges.size());
628 throw INTERP_KERNEL::Exception("BuildRefined2DCellQuadratic : internal error 2 !");
629 std::size_t nbOfEdgesOf2DCellSplit(nb/2);
630 MCAuto<MEDCouplingUMesh> ret(MEDCouplingUMesh::New("",2));
632 ret->setCoords(coords);
635 addCoo->rearrange(2);
636 addCoo=DataArrayDouble::Aggregate(coords,addCoo);
637 ret->setCoords(addCoo);
639 ret->allocateCells(1);
640 std::vector<int> connOut(nbOfEdgesOf2DCellSplit);
641 for(std::size_t kk=0;kk<nbOfEdgesOf2DCellSplit;kk++)
642 connOut[kk]=allEdges[2*kk];
643 connOut.insert(connOut.end(),centers.begin(),centers.end());
644 ret->insertNextCell(INTERP_KERNEL::NORM_QPOLYG,connOut.size(),&connOut[0]);
649 * This method creates a refinement of a cell in \a mesh2D. Those cell is defined by descending connectivity and the sorted subdivided nodal connectivity
652 * \param [in] mesh2D - The origin 2D mesh. \b Warning \b coords are not those of \a mesh2D. But mesh2D->getCoords()==coords[:mesh2D->getNumberOfNodes()]
654 MEDCouplingUMesh *BuildRefined2DCell(const DataArrayDouble *coords, const MEDCouplingUMesh *mesh2D, int cellIdInMesh2D, const int *descBg, const int *descEnd, const std::vector< std::vector<int> >& intersectEdge1)
656 const INTERP_KERNEL::CellModel& cm(INTERP_KERNEL::CellModel::GetCellModel(mesh2D->getTypeOfCell(cellIdInMesh2D)));
657 if(!cm.isQuadratic())
658 return BuildRefined2DCellLinear(coords,descBg,descEnd,intersectEdge1);
660 return BuildRefined2DCellQuadratic(coords,mesh2D,cellIdInMesh2D,descBg,descEnd,intersectEdge1);
663 void AddCellInMesh2D(MEDCouplingUMesh *mesh2D, const std::vector<int>& conn, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& edges)
666 for(std::vector< MCAuto<INTERP_KERNEL::Edge> >::const_iterator it=edges.begin();it!=edges.end();it++)
668 const INTERP_KERNEL::Edge *ee(*it);
669 if(dynamic_cast<const INTERP_KERNEL::EdgeArcCircle *>(ee))
673 mesh2D->insertNextCell(INTERP_KERNEL::NORM_POLYGON,conn.size(),&conn[0]);
676 const double *coo(mesh2D->getCoords()->begin());
677 std::size_t sz(conn.size());
678 std::vector<double> addCoo;
679 std::vector<int> conn2(conn);
680 int offset(mesh2D->getNumberOfNodes());
681 for(std::size_t i=0;i<sz;i++)
684 edges[(i+1)%sz]->getMiddleOfPoints(coo+2*conn[i],coo+2*conn[(i+1)%sz],tmp);// tony a chier i+1 -> i
685 addCoo.insert(addCoo.end(),tmp,tmp+2);
686 conn2.push_back(offset+(int)i);
688 mesh2D->getCoords()->rearrange(1);
689 mesh2D->getCoords()->pushBackValsSilent(&addCoo[0],&addCoo[0]+addCoo.size());
690 mesh2D->getCoords()->rearrange(2);
691 mesh2D->insertNextCell(INTERP_KERNEL::NORM_QPOLYG,conn2.size(),&conn2[0]);
696 * \b WARNING edges in out1 coming from \a splitMesh1D are \b NOT oriented because only used for equation of curve.
698 * This method cuts in 2 parts the input 2D cell given using boundaries description (\a edge1Bis and \a edge1BisPtr) using
699 * a set of edges defined in \a splitMesh1D.
701 void BuildMesh2DCutInternal2(const MEDCouplingUMesh *splitMesh1D, const std::vector<int>& edge1Bis, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& edge1BisPtr,
702 std::vector< std::vector<int> >& out0, std::vector< std::vector< MCAuto<INTERP_KERNEL::Edge> > >& out1)
704 std::size_t nb(edge1Bis.size()/2);
705 std::size_t nbOfEdgesOf2DCellSplit(nb/2);
706 int iEnd(splitMesh1D->getNumberOfCells());
708 throw INTERP_KERNEL::Exception("BuildMesh2DCutInternal2 : internal error ! input 1D mesh must have at least one cell !");
710 const int *cSplitPtr(splitMesh1D->getNodalConnectivity()->begin()),*ciSplitPtr(splitMesh1D->getNodalConnectivityIndex()->begin());
711 for(ii=0;ii<nb && edge1Bis[2*ii]!=cSplitPtr[ciSplitPtr[0]+1];ii++);
712 for(jj=ii;jj<nb && edge1Bis[2*jj+1]!=cSplitPtr[ciSplitPtr[iEnd-1]+2];jj++);
715 {//the edges splitMesh1D[iStart:iEnd] does not fully cut the current 2D cell -> single output cell
716 out0.resize(1); out1.resize(1);
717 std::vector<int>& connOut(out0[0]);
718 connOut.resize(nbOfEdgesOf2DCellSplit);
719 std::vector< MCAuto<INTERP_KERNEL::Edge> >& edgesPtr(out1[0]);
720 edgesPtr.resize(nbOfEdgesOf2DCellSplit);
721 for(std::size_t kk=0;kk<nbOfEdgesOf2DCellSplit;kk++)
723 connOut[kk]=edge1Bis[2*kk];
724 edgesPtr[kk]=edge1BisPtr[2*kk];
729 // [i,iEnd[ contains the
730 out0.resize(2); out1.resize(2);
731 std::vector<int>& connOutLeft(out0[0]);
732 std::vector<int>& connOutRight(out0[1]);//connOutLeft should end with edge1Bis[2*ii] and connOutRight should end with edge1Bis[2*jj+1]
733 std::vector< MCAuto<INTERP_KERNEL::Edge> >& eleft(out1[0]);
734 std::vector< MCAuto<INTERP_KERNEL::Edge> >& eright(out1[1]);
735 for(std::size_t k=ii;k<jj+1;k++)
736 { connOutLeft.push_back(edge1Bis[2*k+1]); eleft.push_back(edge1BisPtr[2*k+1]); }
737 std::vector< MCAuto<INTERP_KERNEL::Edge> > ees(iEnd);
738 for(int ik=0;ik<iEnd;ik++)
740 std::map< MCAuto<INTERP_KERNEL::Node>,int> m;
741 MCAuto<INTERP_KERNEL::Edge> ee(MEDCouplingUMeshBuildQPFromEdge2((INTERP_KERNEL::NormalizedCellType)cSplitPtr[ciSplitPtr[ik]],cSplitPtr+ciSplitPtr[ik]+1,splitMesh1D->getCoords()->begin(),m));
744 for(int ik=iEnd-1;ik>=0;ik--)
745 connOutLeft.push_back(cSplitPtr[ciSplitPtr[ik]+1]);
746 for(std::size_t k=jj+1;k<nbOfEdgesOf2DCellSplit+ii;k++)
747 { connOutRight.push_back(edge1Bis[2*k+1]); eright.push_back(edge1BisPtr[2*k+1]); }
748 eleft.insert(eleft.end(),ees.rbegin(),ees.rend());
749 for(int ik=0;ik<iEnd;ik++)
750 connOutRight.push_back(cSplitPtr[ciSplitPtr[ik]+2]);
751 eright.insert(eright.end(),ees.begin(),ees.end());
759 CellInfo(const std::vector<int>& edges, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& edgesPtr);
761 std::vector<int> _edges;
762 std::vector< MCAuto<INTERP_KERNEL::Edge> > _edges_ptr;
765 CellInfo::CellInfo(const std::vector<int>& edges, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& edgesPtr)
767 std::size_t nbe(edges.size());
768 std::vector<int> edges2(2*nbe); std::vector< MCAuto<INTERP_KERNEL::Edge> > edgesPtr2(2*nbe);
769 for(std::size_t i=0;i<nbe;i++)
771 edges2[2*i]=edges[i]; edges2[2*i+1]=edges[(i+1)%nbe];
772 edgesPtr2[2*i]=edgesPtr[(i+1)%nbe]; edgesPtr2[2*i+1]=edgesPtr[(i+1)%nbe];//tony a chier
774 _edges.resize(4*nbe); _edges_ptr.resize(4*nbe);
775 std::copy(edges2.begin(),edges2.end(),_edges.begin()); std::copy(edges2.begin(),edges2.end(),_edges.begin()+2*nbe);
776 std::copy(edgesPtr2.begin(),edgesPtr2.end(),_edges_ptr.begin()); std::copy(edgesPtr2.begin(),edgesPtr2.end(),_edges_ptr.begin()+2*nbe);
782 EdgeInfo(int istart, int iend, const MCAuto<MEDCouplingUMesh>& mesh):_istart(istart),_iend(iend),_mesh(mesh),_left(-7),_right(-7) { }
783 EdgeInfo(int istart, int iend, int pos, const MCAuto<INTERP_KERNEL::Edge>& edge):_istart(istart),_iend(iend),_edge(edge),_left(pos),_right(pos+1) { }
784 bool isInMyRange(int pos) const { return pos>=_istart && pos<_iend; }
785 void somethingHappendAt(int pos, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newLeft, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newRight);
786 void feedEdgeInfoAt(double eps, const MEDCouplingUMesh *mesh2D, int offset, int neighbors[2]) const;
790 MCAuto<MEDCouplingUMesh> _mesh;
791 MCAuto<INTERP_KERNEL::Edge> _edge;
796 void EdgeInfo::somethingHappendAt(int pos, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newLeft, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newRight)
798 const MEDCouplingUMesh *mesh(_mesh);
804 { _left++; _right++; return ; }
807 bool isLeft(std::find(newLeft.begin(),newLeft.end(),_edge)!=newLeft.end()),isRight(std::find(newRight.begin(),newRight.end(),_edge)!=newRight.end());
808 if((isLeft && isRight) || (!isLeft && !isRight))
809 throw INTERP_KERNEL::Exception("EdgeInfo::somethingHappendAt : internal error # 1 !");
820 bool isLeft(std::find(newLeft.begin(),newLeft.end(),_edge)!=newLeft.end()),isRight(std::find(newRight.begin(),newRight.end(),_edge)!=newRight.end());
821 if((isLeft && isRight) || (!isLeft && !isRight))
822 throw INTERP_KERNEL::Exception("EdgeInfo::somethingHappendAt : internal error # 2 !");
837 void EdgeInfo::feedEdgeInfoAt(double eps, const MEDCouplingUMesh *mesh2D, int offset, int neighbors[2]) const
839 const MEDCouplingUMesh *mesh(_mesh);
842 neighbors[0]=offset+_left; neighbors[1]=offset+_right;
845 {// not fully splitting cell case
846 if(mesh2D->getNumberOfCells()==1)
847 {//little optimization. 1 cell no need to find in which cell mesh is !
848 neighbors[0]=offset; neighbors[1]=offset;
853 MCAuto<DataArrayDouble> barys(mesh->computeCellCenterOfMass());
854 int cellId(mesh2D->getCellContainingPoint(barys->begin(),eps));
856 throw INTERP_KERNEL::Exception("EdgeInfo::feedEdgeInfoAt : internal error !");
857 neighbors[0]=offset+cellId; neighbors[1]=offset+cellId;
862 class VectorOfCellInfo
865 VectorOfCellInfo(const std::vector<int>& edges, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& edgesPtr);
866 std::size_t size() const { return _pool.size(); }
867 int getPositionOf(double eps, const MEDCouplingUMesh *mesh) const;
868 void setMeshAt(std::size_t pos, const MCAuto<MEDCouplingUMesh>& mesh, int istart, int iend, const MCAuto<MEDCouplingUMesh>& mesh1DInCase, const std::vector< std::vector<int> >& edges, const std::vector< std::vector< MCAuto<INTERP_KERNEL::Edge> > >& edgePtrs);
869 const std::vector<int>& getConnOf(int pos) const { return get(pos)._edges; }
870 const std::vector< MCAuto<INTERP_KERNEL::Edge> >& getEdgePtrOf(int pos) const { return get(pos)._edges_ptr; }
871 MCAuto<MEDCouplingUMesh> getZeMesh() const { return _ze_mesh; }
872 void feedEdgeInfoAt(double eps, int pos, int offset, int neighbors[2]) const;
874 int getZePosOfEdgeGivenItsGlobalId(int pos) const;
875 void updateEdgeInfo(int pos, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newLeft, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newRight);
876 const CellInfo& get(int pos) const;
877 CellInfo& get(int pos);
879 std::vector<CellInfo> _pool;
880 MCAuto<MEDCouplingUMesh> _ze_mesh;
881 std::vector<EdgeInfo> _edge_info;
884 VectorOfCellInfo::VectorOfCellInfo(const std::vector<int>& edges, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& edgesPtr):_pool(1)
886 _pool[0]._edges=edges;
887 _pool[0]._edges_ptr=edgesPtr;
890 int VectorOfCellInfo::getPositionOf(double eps, const MEDCouplingUMesh *mesh) const
893 throw INTERP_KERNEL::Exception("VectorOfCellSplitter::getPositionOf : empty !");
896 const MEDCouplingUMesh *zeMesh(_ze_mesh);
898 throw INTERP_KERNEL::Exception("VectorOfCellSplitter::getPositionOf : null aggregated mesh !");
899 MCAuto<DataArrayDouble> barys(mesh->computeCellCenterOfMass());
900 return zeMesh->getCellContainingPoint(barys->begin(),eps);
903 void VectorOfCellInfo::setMeshAt(std::size_t pos, const MCAuto<MEDCouplingUMesh>& mesh, int istart, int iend, const MCAuto<MEDCouplingUMesh>& mesh1DInCase, const std::vector< std::vector<int> >& edges, const std::vector< std::vector< MCAuto<INTERP_KERNEL::Edge> > >& edgePtrs)
905 get(pos);//to check pos
906 bool isFast(pos==0 && _pool.size()==1);
907 std::size_t sz(edges.size());
908 // dealing with edges
910 _edge_info.push_back(EdgeInfo(istart,iend,mesh1DInCase));
912 _edge_info.push_back(EdgeInfo(istart,iend,pos,edgePtrs[0].back()));
914 std::vector<CellInfo> pool(_pool.size()-1+sz);
915 for(std::size_t i=0;i<pos;i++)
917 for(std::size_t j=0;j<sz;j++)
918 pool[pos+j]=CellInfo(edges[j],edgePtrs[j]);
919 for(int i=pos+1;i<(int)_pool.size();i++)
920 pool[i+sz-1]=_pool[i];
924 updateEdgeInfo(pos,edgePtrs[0],edgePtrs[1]);
932 std::vector< MCAuto<MEDCouplingUMesh> > ms;
935 MCAuto<MEDCouplingUMesh> elt(static_cast<MEDCouplingUMesh *>(_ze_mesh->buildPartOfMySelfSlice(0,pos,true)));
939 if(pos<_ze_mesh->getNumberOfCells()-1)
941 MCAuto<MEDCouplingUMesh> elt(static_cast<MEDCouplingUMesh *>(_ze_mesh->buildPartOfMySelfSlice(pos+1,_ze_mesh->getNumberOfCells(),true)));
944 std::vector< const MEDCouplingUMesh *> ms2(ms.size());
945 for(std::size_t j=0;j<ms2.size();j++)
947 _ze_mesh=MEDCouplingUMesh::MergeUMeshesOnSameCoords(ms2);
950 void VectorOfCellInfo::feedEdgeInfoAt(double eps, int pos, int offset, int neighbors[2]) const
952 _edge_info[getZePosOfEdgeGivenItsGlobalId(pos)].feedEdgeInfoAt(eps,_ze_mesh,offset,neighbors);
955 int VectorOfCellInfo::getZePosOfEdgeGivenItsGlobalId(int pos) const
958 throw INTERP_KERNEL::Exception("VectorOfCellInfo::getZePosOfEdgeGivenItsGlobalId : invalid id ! Must be >=0 !");
960 for(std::vector<EdgeInfo>::const_iterator it=_edge_info.begin();it!=_edge_info.end();it++,ret++)
962 if((*it).isInMyRange(pos))
965 throw INTERP_KERNEL::Exception("VectorOfCellInfo::getZePosOfEdgeGivenItsGlobalId : invalid id !");
968 void VectorOfCellInfo::updateEdgeInfo(int pos, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newLeft, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& newRight)
971 if(_edge_info.empty())
973 std::size_t sz(_edge_info.size()-1);
974 for(std::size_t i=0;i<sz;i++)
975 _edge_info[i].somethingHappendAt(pos,newLeft,newRight);
978 const CellInfo& VectorOfCellInfo::get(int pos) const
980 if(pos<0 || pos>=(int)_pool.size())
981 throw INTERP_KERNEL::Exception("VectorOfCellSplitter::get const : invalid pos !");
985 CellInfo& VectorOfCellInfo::get(int pos)
987 if(pos<0 || pos>=(int)_pool.size())
988 throw INTERP_KERNEL::Exception("VectorOfCellSplitter::get : invalid pos !");
994 * - a \b closed set of edges ( \a allEdges and \a allEdgesPtr ) that defines the split descending 2D cell.
995 * - \a splitMesh1D a split 2D curve mesh contained into 2D cell defined above.
997 * This method returns the 2D mesh and feeds \a idsLeftRight using offset.
999 * Algorithm : \a splitMesh1D is cut into contiguous parts. Each contiguous parts will build incrementally the output 2D cells.
1001 * \param [in] allEdges a list of pairs (beginNode, endNode). Represents all edges (already cut) in the single 2D cell being handled here. Linked with \a allEdgesPtr to get the equation of edge.
1003 MEDCouplingUMesh *BuildMesh2DCutInternal(double eps, MEDCouplingUMesh *splitMesh1D, const std::vector<int>& allEdges, const std::vector< MCAuto<INTERP_KERNEL::Edge> >& allEdgesPtr, int offset,
1004 MCAuto<DataArrayInt>& idsLeftRight)
1006 int nbCellsInSplitMesh1D(splitMesh1D->getNumberOfCells());
1007 if(nbCellsInSplitMesh1D==0)
1008 throw INTERP_KERNEL::Exception("BuildMesh2DCutInternal : internal error ! input 1D mesh must have at least one cell !");
1009 const int *cSplitPtr(splitMesh1D->getNodalConnectivity()->begin()),*ciSplitPtr(splitMesh1D->getNodalConnectivityIndex()->begin());
1010 std::size_t nb(allEdges.size()),jj;
1012 throw INTERP_KERNEL::Exception("BuildMesh2DCutFrom : internal error 2 !");
1013 std::vector<int> edge1Bis(nb*2);
1014 std::vector< MCAuto<INTERP_KERNEL::Edge> > edge1BisPtr(nb*2);
1015 std::copy(allEdges.begin(),allEdges.end(),edge1Bis.begin());
1016 std::copy(allEdges.begin(),allEdges.end(),edge1Bis.begin()+nb);
1017 std::copy(allEdgesPtr.begin(),allEdgesPtr.end(),edge1BisPtr.begin());
1018 std::copy(allEdgesPtr.begin(),allEdgesPtr.end(),edge1BisPtr.begin()+nb);
1020 idsLeftRight=DataArrayInt::New(); idsLeftRight->alloc(nbCellsInSplitMesh1D*2); idsLeftRight->fillWithValue(-2); idsLeftRight->rearrange(2);
1021 int *idsLeftRightPtr(idsLeftRight->getPointer());
1022 VectorOfCellInfo pool(edge1Bis,edge1BisPtr);
1024 // Compute contiguous parts of splitMesh1D. We can not make the full assumption that segments are consecutive in the connectivity
1025 // (even if the user correctly called orderConsecutiveCells1D()). Indeed the tool might be a closed line whose junction point is in
1026 // splitMesh1D. There can be only one such a point, and if this happens this is necessarily at the start
1027 // of the connectivity.
1028 MCAuto <DataArrayInt> renumb(DataArrayInt::New());
1029 renumb->alloc(nbCellsInSplitMesh1D,1);
1030 const int * renumbP(renumb->begin());
1032 int i, first=cSplitPtr[1];
1033 // Follow 1D line backward as long as it is connected:
1034 for (i=nbCellsInSplitMesh1D-1; cSplitPtr[ciSplitPtr[i]+2] == first; i--)
1035 first=cSplitPtr[ciSplitPtr[i]+1];
1036 if (i < nbCellsInSplitMesh1D-1)
1038 // Build circular permutation to shift consecutive edges together
1040 renumb->applyModulus(nbCellsInSplitMesh1D);
1041 splitMesh1D->renumberCells(renumbP, false);
1042 cSplitPtr = splitMesh1D->getNodalConnectivity()->begin();
1043 ciSplitPtr = splitMesh1D->getNodalConnectivityIndex()->begin();
1049 for(int iStart=0;iStart<nbCellsInSplitMesh1D;)
1050 {// split [0:nbCellsInSplitMesh1D) in contiguous parts [iStart:iEnd)
1052 for(;iEnd<nbCellsInSplitMesh1D;)
1054 for(jj=0;jj<nb && edge1Bis[2*jj+1]!=cSplitPtr[ciSplitPtr[iEnd]+2];jj++);
1060 if(iEnd<nbCellsInSplitMesh1D)
1063 MCAuto<MEDCouplingUMesh> partOfSplitMesh1D(static_cast<MEDCouplingUMesh *>(splitMesh1D->buildPartOfMySelfSlice(iStart,iEnd,1,true)));
1064 int pos(pool.getPositionOf(eps,partOfSplitMesh1D));
1066 MCAuto<MEDCouplingUMesh>retTmp(MEDCouplingUMesh::New("",2));
1067 retTmp->setCoords(splitMesh1D->getCoords());
1068 retTmp->allocateCells();
1070 std::vector< std::vector<int> > out0;
1071 std::vector< std::vector< MCAuto<INTERP_KERNEL::Edge> > > out1;
1073 BuildMesh2DCutInternal2(partOfSplitMesh1D,pool.getConnOf(pos),pool.getEdgePtrOf(pos),out0,out1);
1074 for(std::size_t cnt=0;cnt<out0.size();cnt++)
1075 AddCellInMesh2D(retTmp,out0[cnt],out1[cnt]);
1076 pool.setMeshAt(pos,retTmp,iStart,iEnd,partOfSplitMesh1D,out0,out1);
1080 for(int mm=0;mm<nbCellsInSplitMesh1D;mm++)
1081 pool.feedEdgeInfoAt(eps,renumbP[mm],offset,idsLeftRightPtr+2*mm);
1083 return pool.getZeMesh().retn();
1087 * splitMesh1D is an input parameter but might have its cells renumbered.
1089 MEDCouplingUMesh *BuildMesh2DCutFrom(double eps, int cellIdInMesh2D, const MEDCouplingUMesh *mesh2DDesc, MEDCouplingUMesh *splitMesh1D,
1090 const int *descBg, const int *descEnd, const std::vector< std::vector<int> >& intersectEdge1, int offset,
1091 MCAuto<DataArrayInt>& idsLeftRight)
1093 const int *cdescPtr(mesh2DDesc->getNodalConnectivity()->begin()),*cidescPtr(mesh2DDesc->getNodalConnectivityIndex()->begin());
1095 std::vector<int> allEdges;
1096 std::vector< MCAuto<INTERP_KERNEL::Edge> > allEdgesPtr; // for each sub edge in splitMesh2D the uncut Edge object of the original mesh2D
1097 for(const int *it(descBg);it!=descEnd;it++) // for all edges in the descending connectivity of the 2D mesh in relative Fortran mode
1099 int edgeId(std::abs(*it)-1);
1100 std::map< MCAuto<INTERP_KERNEL::Node>,int> m;
1101 MCAuto<INTERP_KERNEL::Edge> ee(MEDCouplingUMeshBuildQPFromEdge2((INTERP_KERNEL::NormalizedCellType)cdescPtr[cidescPtr[edgeId]],cdescPtr+cidescPtr[edgeId]+1,mesh2DDesc->getCoords()->begin(),m));
1102 const std::vector<int>& edge1(intersectEdge1[edgeId]);
1104 allEdges.insert(allEdges.end(),edge1.begin(),edge1.end());
1106 allEdges.insert(allEdges.end(),edge1.rbegin(),edge1.rend());
1107 std::size_t sz(edge1.size());
1108 for(std::size_t cnt=0;cnt<sz;cnt++)
1109 allEdgesPtr.push_back(ee);
1112 return BuildMesh2DCutInternal(eps,splitMesh1D,allEdges,allEdgesPtr,offset,idsLeftRight);
1115 bool AreEdgeEqual(const double *coo2D, const INTERP_KERNEL::CellModel& typ1, const int *conn1, const INTERP_KERNEL::CellModel& typ2, const int *conn2, double eps)
1117 if(!typ1.isQuadratic() && !typ2.isQuadratic())
1118 {//easy case comparison not
1119 return conn1[0]==conn2[0] && conn1[1]==conn2[1];
1121 else if(typ1.isQuadratic() && typ2.isQuadratic())
1123 bool status0(conn1[0]==conn2[0] && conn1[1]==conn2[1]);
1126 if(conn1[2]==conn2[2])
1128 const double *a(coo2D+2*conn1[2]),*b(coo2D+2*conn2[2]);
1129 double dist(sqrt((a[0]-b[0])*(a[0]-b[0])+(a[1]-b[1])*(a[1]-b[1])));
1133 {//only one is quadratic
1134 bool status0(conn1[0]==conn2[0] && conn1[1]==conn2[1]);
1137 const double *a(0),*bb(0),*be(0);
1138 if(typ1.isQuadratic())
1140 a=coo2D+2*conn1[2]; bb=coo2D+2*conn2[0]; be=coo2D+2*conn2[1];
1144 a=coo2D+2*conn2[2]; bb=coo2D+2*conn1[0]; be=coo2D+2*conn1[1];
1146 double b[2]; b[0]=(be[0]+bb[0])/2.; b[1]=(be[1]+bb[1])/2.;
1147 double dist(sqrt((a[0]-b[0])*(a[0]-b[0])+(a[1]-b[1])*(a[1]-b[1])));
1153 * This method returns among the cellIds [ \a candidatesIn2DBg , \a candidatesIn2DEnd ) in \a mesh2DSplit those exactly sharing \a cellIdInMesh1DSplitRelative in \a mesh1DSplit.
1154 * \a mesh2DSplit and \a mesh1DSplit are expected to share the coordinates array.
1156 * \param [in] cellIdInMesh1DSplitRelative is in Fortran mode using sign to specify direction.
1158 int FindRightCandidateAmong(const MEDCouplingUMesh *mesh2DSplit, const int *candidatesIn2DBg, const int *candidatesIn2DEnd, const MEDCouplingUMesh *mesh1DSplit, int cellIdInMesh1DSplitRelative, double eps)
1160 if(candidatesIn2DEnd==candidatesIn2DBg)
1161 throw INTERP_KERNEL::Exception("FindRightCandidateAmong : internal error 1 !");
1162 const double *coo(mesh2DSplit->getCoords()->begin());
1163 if(std::distance(candidatesIn2DBg,candidatesIn2DEnd)==1)
1164 return *candidatesIn2DBg;
1165 int edgeId(std::abs(cellIdInMesh1DSplitRelative)-1);
1166 MCAuto<MEDCouplingUMesh> cur1D(static_cast<MEDCouplingUMesh *>(mesh1DSplit->buildPartOfMySelf(&edgeId,&edgeId+1,true)));
1167 if(cellIdInMesh1DSplitRelative<0)
1168 cur1D->changeOrientationOfCells();
1169 const int *c1D(cur1D->getNodalConnectivity()->begin());
1170 const INTERP_KERNEL::CellModel& ref1DType(INTERP_KERNEL::CellModel::GetCellModel((INTERP_KERNEL::NormalizedCellType)c1D[0]));
1171 for(const int *it=candidatesIn2DBg;it!=candidatesIn2DEnd;it++)
1173 MCAuto<MEDCouplingUMesh> cur2D(static_cast<MEDCouplingUMesh *>(mesh2DSplit->buildPartOfMySelf(it,it+1,true)));
1174 const int *c(cur2D->getNodalConnectivity()->begin()),*ci(cur2D->getNodalConnectivityIndex()->begin());
1175 const INTERP_KERNEL::CellModel &cm(INTERP_KERNEL::CellModel::GetCellModel((INTERP_KERNEL::NormalizedCellType)c[ci[0]]));
1176 unsigned sz(cm.getNumberOfSons2(c+ci[0]+1,ci[1]-ci[0]-1));
1177 INTERP_KERNEL::AutoPtr<int> tmpPtr(new int[ci[1]-ci[0]]);
1178 for(unsigned it2=0;it2<sz;it2++)
1180 INTERP_KERNEL::NormalizedCellType typeOfSon;
1181 cm.fillSonCellNodalConnectivity2(it2,c+ci[0]+1,ci[1]-ci[0]-1,tmpPtr,typeOfSon);
1182 const INTERP_KERNEL::CellModel &curCM(INTERP_KERNEL::CellModel::GetCellModel(typeOfSon));
1183 if(AreEdgeEqual(coo,ref1DType,c1D+1,curCM,tmpPtr,eps))
1187 throw INTERP_KERNEL::Exception("FindRightCandidateAmong : internal error 2 ! Unable to find the edge among split cell !");
1191 * \param [out] intersectEdge1 - for each cell in \a m1Desc returns the result of the split. The result is given using pair of int given resp start and stop.
1192 * So for all edge \a i in \a m1Desc \a intersectEdge1[i] is of length 2*n where n is the number of sub edges.
1193 * And for each j in [1,n) intersect[i][2*(j-1)+1]==intersect[i][2*j].
1194 * \param [out] subDiv2 - for each cell in \a m2Desc returns nodes that split it using convention \a m1Desc first, then \a m2Desc, then addCoo
1195 * \param [out] colinear2 - for each cell in \a m2Desc returns the edges in \a m1Desc that are colinear to it.
1196 * \param [out] addCoo - nodes to be append at the end
1197 * \param [out] mergedNodes - gives all pair of nodes of \a m2Desc that have same location than some nodes in \a m1Desc. key is id in \a m2Desc offseted and value is id in \a m1Desc.
1199 void MEDCouplingUMesh::Intersect1DMeshes(const MEDCouplingUMesh *m1Desc, const MEDCouplingUMesh *m2Desc, double eps,
1200 std::vector< std::vector<int> >& intersectEdge1, std::vector< std::vector<int> >& colinear2, std::vector< std::vector<int> >& subDiv2, std::vector<double>& addCoo, std::map<int,int>& mergedNodes)
1202 static const int SPACEDIM=2;
1203 INTERP_KERNEL::QuadraticPlanarPrecision prec(eps);
1204 INTERP_KERNEL::QuadraticPlanarArcDetectionPrecision arcPrec(eps);
1205 const int *c1(m1Desc->getNodalConnectivity()->begin()),*ci1(m1Desc->getNodalConnectivityIndex()->begin());
1206 // Build BB tree of all edges in the tool mesh (second mesh)
1207 MCAuto<DataArrayDouble> bbox1Arr(m1Desc->getBoundingBoxForBBTree(eps)),bbox2Arr(m2Desc->getBoundingBoxForBBTree(eps));
1208 const double *bbox1(bbox1Arr->begin()),*bbox2(bbox2Arr->begin());
1209 int nDescCell1(m1Desc->getNumberOfCells()),nDescCell2(m2Desc->getNumberOfCells());
1210 intersectEdge1.resize(nDescCell1);
1211 colinear2.resize(nDescCell2);
1212 subDiv2.resize(nDescCell2);
1213 BBTree<SPACEDIM,int> myTree(bbox2,0,0,m2Desc->getNumberOfCells(),-eps);
1215 std::vector<int> candidates1(1);
1216 int offset1(m1Desc->getNumberOfNodes());
1217 int offset2(offset1+m2Desc->getNumberOfNodes());
1218 for(int i=0;i<nDescCell1;i++) // for all edges in the first mesh
1220 std::vector<int> candidates2; // edges of mesh2 candidate for intersection
1221 myTree.getIntersectingElems(bbox1+i*2*SPACEDIM,candidates2);
1222 if(!candidates2.empty()) // candidates2 holds edges from the second mesh potentially intersecting current edge i in mesh1
1224 std::map<INTERP_KERNEL::Node *,int> map1,map2;
1225 // pol2 is not necessarily a closed polygon: just a set of (quadratic) edges (same as candidates2) in the Geometric DS format
1226 INTERP_KERNEL::QuadraticPolygon *pol2=MEDCouplingUMeshBuildQPFromMesh(m2Desc,candidates2,map2);
1228 INTERP_KERNEL::QuadraticPolygon *pol1=MEDCouplingUMeshBuildQPFromMesh(m1Desc,candidates1,map1);
1229 // This following part is to avoid that some removed nodes (for example due to a merge between pol1 and pol2) are replaced by a newly created one
1230 // This trick guarantees that Node * are discriminant (i.e. form a unique identifier)
1231 std::set<INTERP_KERNEL::Node *> nodes;
1232 pol1->getAllNodes(nodes); pol2->getAllNodes(nodes);
1233 std::size_t szz(nodes.size());
1234 std::vector< MCAuto<INTERP_KERNEL::Node> > nodesSafe(szz);
1235 std::set<INTERP_KERNEL::Node *>::const_iterator itt(nodes.begin());
1236 for(std::size_t iii=0;iii<szz;iii++,itt++)
1237 { (*itt)->incrRef(); nodesSafe[iii]=*itt; }
1238 // end of protection
1239 // Performs edge cutting:
1240 pol1->splitAbs(*pol2,map1,map2,offset1,offset2,candidates2,intersectEdge1[i],i,colinear2,subDiv2,addCoo,mergedNodes);
1245 // Copy the edge (take only the two first points, ie discard quadratic point at this stage)
1246 intersectEdge1[i].insert(intersectEdge1[i].end(),c1+ci1[i]+1,c1+ci1[i]+3);
1252 * This method is private and is the first step of Partition of 2D mesh (spaceDim==2 and meshDim==2).
1253 * It builds the descending connectivity of the two meshes, and then using a binary tree
1254 * it computes the edge intersections. This results in new points being created : they're stored in addCoo.
1255 * Documentation about parameters colinear2 and subDiv2 can be found in method QuadraticPolygon::splitAbs().
1257 void MEDCouplingUMesh::IntersectDescending2DMeshes(const MEDCouplingUMesh *m1, const MEDCouplingUMesh *m2, double eps,
1258 std::vector< std::vector<int> >& intersectEdge1, std::vector< std::vector<int> >& colinear2, std::vector< std::vector<int> >& subDiv2,
1259 MEDCouplingUMesh *& m1Desc, DataArrayInt *&desc1, DataArrayInt *&descIndx1, DataArrayInt *&revDesc1, DataArrayInt *&revDescIndx1,
1260 std::vector<double>& addCoo,
1261 MEDCouplingUMesh *& m2Desc, DataArrayInt *&desc2, DataArrayInt *&descIndx2, DataArrayInt *&revDesc2, DataArrayInt *&revDescIndx2)
1263 // Build desc connectivity
1264 desc1=DataArrayInt::New(); descIndx1=DataArrayInt::New(); revDesc1=DataArrayInt::New(); revDescIndx1=DataArrayInt::New();
1265 desc2=DataArrayInt::New();
1266 descIndx2=DataArrayInt::New();
1267 revDesc2=DataArrayInt::New();
1268 revDescIndx2=DataArrayInt::New();
1269 MCAuto<DataArrayInt> dd1(desc1),dd2(descIndx1),dd3(revDesc1),dd4(revDescIndx1);
1270 MCAuto<DataArrayInt> dd5(desc2),dd6(descIndx2),dd7(revDesc2),dd8(revDescIndx2);
1271 m1Desc=m1->buildDescendingConnectivity2(desc1,descIndx1,revDesc1,revDescIndx1);
1272 m2Desc=m2->buildDescendingConnectivity2(desc2,descIndx2,revDesc2,revDescIndx2);
1273 MCAuto<MEDCouplingUMesh> dd9(m1Desc),dd10(m2Desc);
1274 std::map<int,int> notUsedMap;
1275 Intersect1DMeshes(m1Desc,m2Desc,eps,intersectEdge1,colinear2,subDiv2,addCoo,notUsedMap);
1276 m1Desc->incrRef(); desc1->incrRef(); descIndx1->incrRef(); revDesc1->incrRef(); revDescIndx1->incrRef();
1277 m2Desc->incrRef(); desc2->incrRef(); descIndx2->incrRef(); revDesc2->incrRef(); revDescIndx2->incrRef();
1281 * Private. Third step of the partitioning algorithm (Intersect2DMeshes): reconstruct full 2D cells from the
1282 * (newly created) nodes corresponding to the edge intersections.
1284 * @param[out] cr, crI connectivity of the resulting mesh
1285 * @param[out] cNb1, cNb2 correspondence arrays giving for the merged mesh the initial cells IDs in m1 / m2
1286 * TODO: describe input parameters
1288 void MEDCouplingUMesh::BuildIntersecting2DCellsFromEdges(double eps, const MEDCouplingUMesh *m1, const int *desc1, const int *descIndx1,
1289 const std::vector<std::vector<int> >& intesctEdges1, const std::vector< std::vector<int> >& colinear2,
1290 const MEDCouplingUMesh *m2, const int *desc2, const int *descIndx2, const std::vector<std::vector<int> >& intesctEdges2,
1291 const std::vector<double>& addCoords,
1292 std::vector<double>& addCoordsQuadratic, std::vector<int>& cr, std::vector<int>& crI, std::vector<int>& cNb1, std::vector<int>& cNb2)
1294 static const int SPACEDIM=2;
1295 const double *coo1(m1->getCoords()->begin());
1296 const int *conn1(m1->getNodalConnectivity()->begin()),*connI1(m1->getNodalConnectivityIndex()->begin());
1297 int offset1(m1->getNumberOfNodes());
1298 const double *coo2(m2->getCoords()->begin());
1299 const int *conn2(m2->getNodalConnectivity()->begin()),*connI2(m2->getNodalConnectivityIndex()->begin());
1300 int offset2(offset1+m2->getNumberOfNodes());
1301 int offset3(offset2+((int)addCoords.size())/2);
1302 MCAuto<DataArrayDouble> bbox1Arr(m1->getBoundingBoxForBBTree(eps)),bbox2Arr(m2->getBoundingBoxForBBTree(eps));
1303 const double *bbox1(bbox1Arr->begin()),*bbox2(bbox2Arr->begin());
1304 // Here a BBTree on 2D-cells, not on segments:
1305 BBTree<SPACEDIM,int> myTree(bbox2,0,0,m2->getNumberOfCells(),eps);
1306 int ncell1(m1->getNumberOfCells());
1308 for(int i=0;i<ncell1;i++)
1310 std::vector<int> candidates2;
1311 myTree.getIntersectingElems(bbox1+i*2*SPACEDIM,candidates2);
1312 std::map<INTERP_KERNEL::Node *,int> mapp;
1313 std::map<int,INTERP_KERNEL::Node *> mappRev;
1314 INTERP_KERNEL::QuadraticPolygon pol1;
1315 INTERP_KERNEL::NormalizedCellType typ=(INTERP_KERNEL::NormalizedCellType)conn1[connI1[i]];
1316 const INTERP_KERNEL::CellModel& cm=INTERP_KERNEL::CellModel::GetCellModel(typ);
1317 // Populate mapp and mappRev with nodes from the current cell (i) from mesh1 - this also builds the Node* objects:
1318 MEDCouplingUMeshBuildQPFromMesh3(coo1,offset1,coo2,offset2,addCoords,desc1+descIndx1[i],desc1+descIndx1[i+1],intesctEdges1,/* output */mapp,mappRev);
1319 // pol1 is the full cell from mesh2, in QP format, with all the additional intersecting nodes.
1320 pol1.buildFromCrudeDataArray(mappRev,cm.isQuadratic(),conn1+connI1[i]+1,coo1,
1321 desc1+descIndx1[i],desc1+descIndx1[i+1],intesctEdges1);
1323 std::set<INTERP_KERNEL::Edge *> edges1;// store all edges of pol1 that are NOT consumed by intersect cells. If any after iteration over candidates2 -> a part of pol1 should appear in result
1324 std::set<INTERP_KERNEL::Edge *> edgesBoundary2;// store all edges that are on boundary of (pol2 intersect pol1) minus edges on pol1.
1325 INTERP_KERNEL::IteratorOnComposedEdge it1(&pol1);
1326 for(it1.first();!it1.finished();it1.next())
1327 edges1.insert(it1.current()->getPtr());
1329 std::map<int,std::vector<INTERP_KERNEL::ElementaryEdge *> > edgesIn2ForShare; // common edges
1330 std::vector<INTERP_KERNEL::QuadraticPolygon> pol2s(candidates2.size());
1332 for(std::vector<int>::const_iterator it2=candidates2.begin();it2!=candidates2.end();it2++,ii++)
1334 INTERP_KERNEL::NormalizedCellType typ2=(INTERP_KERNEL::NormalizedCellType)conn2[connI2[*it2]];
1335 const INTERP_KERNEL::CellModel& cm2=INTERP_KERNEL::CellModel::GetCellModel(typ2);
1336 // Complete mapping with elements coming from the current cell it2 in mesh2:
1337 MEDCouplingUMeshBuildQPFromMesh3(coo1,offset1,coo2,offset2,addCoords,desc2+descIndx2[*it2],desc2+descIndx2[*it2+1],intesctEdges2,/* output */mapp,mappRev);
1338 // pol2 is the new QP in the final merged result.
1339 pol2s[ii].buildFromCrudeDataArray2(mappRev,cm2.isQuadratic(),conn2+connI2[*it2]+1,coo2,desc2+descIndx2[*it2],desc2+descIndx2[*it2+1],intesctEdges2,
1340 pol1,desc1+descIndx1[i],desc1+descIndx1[i+1],intesctEdges1,colinear2, /* output */ edgesIn2ForShare);
1343 for(std::vector<int>::const_iterator it2=candidates2.begin();it2!=candidates2.end();it2++,ii++)
1345 INTERP_KERNEL::ComposedEdge::InitLocationsWithOther(pol1,pol2s[ii]);
1346 pol2s[ii].updateLocOfEdgeFromCrudeDataArray2(desc2+descIndx2[*it2],desc2+descIndx2[*it2+1],intesctEdges2,pol1,desc1+descIndx1[i],desc1+descIndx1[i+1],intesctEdges1,colinear2);
1347 //MEDCouplingUMeshAssignOnLoc(pol1,pol2,desc1+descIndx1[i],desc1+descIndx1[i+1],intesctEdges1,desc2+descIndx2[*it2],desc2+descIndx2[*it2+1],intesctEdges2,colinear2);
1348 pol1.buildPartitionsAbs(pol2s[ii],edges1,edgesBoundary2,mapp,i,*it2,offset3,addCoordsQuadratic,cr,crI,cNb1,cNb2);
1350 // Deals with remaining (non-consumed) edges from m1: these are the edges that were never touched
1351 // by m2 but that we still want to keep in the final result.
1356 INTERP_KERNEL::QuadraticPolygon::ComputeResidual(pol1,edges1,edgesBoundary2,mapp,offset3,i,addCoordsQuadratic,cr,crI,cNb1,cNb2);
1358 catch(INTERP_KERNEL::Exception& e)
1360 std::ostringstream oss; oss << "Error when computing residual of cell #" << i << " in source/m1 mesh ! Maybe the neighbours of this cell in mesh are not well connected !\n" << "The deep reason is the following : " << e.what();
1361 throw INTERP_KERNEL::Exception(oss.str());
1364 for(std::map<int,INTERP_KERNEL::Node *>::const_iterator it=mappRev.begin();it!=mappRev.end();it++)
1365 (*it).second->decrRef();
1369 void InsertNodeInConnIfNecessary(int nodeIdToInsert, std::vector<int>& conn, const double *coords, double eps)
1371 std::vector<int>::iterator it(std::find(conn.begin(),conn.end(),nodeIdToInsert));
1374 std::size_t sz(conn.size());
1375 std::size_t found(std::numeric_limits<std::size_t>::max());
1376 for(std::size_t i=0;i<sz;i++)
1378 int pt0(conn[i]),pt1(conn[(i+1)%sz]);
1379 double v1[3]={coords[3*pt1+0]-coords[3*pt0+0],coords[3*pt1+1]-coords[3*pt0+1],coords[3*pt1+2]-coords[3*pt0+2]},v2[3]={coords[3*nodeIdToInsert+0]-coords[3*pt0+0],coords[3*nodeIdToInsert+1]-coords[3*pt0+1],coords[3*nodeIdToInsert+2]-coords[3*pt0+2]};
1380 double normm(sqrt(v1[0]*v1[0]+v1[1]*v1[1]+v1[2]*v1[2]));
1381 std::transform(v1,v1+3,v1,std::bind2nd(std::multiplies<double>(),1./normm));
1382 std::transform(v2,v2+3,v2,std::bind2nd(std::multiplies<double>(),1./normm));
1384 v3[0]=v1[1]*v2[2]-v1[2]*v2[1]; v3[1]=v1[2]*v2[0]-v1[0]*v2[2]; v3[2]=v1[0]*v2[1]-v1[1]*v2[0];
1385 double normm2(sqrt(v3[0]*v3[0]+v3[1]*v3[1]+v3[2]*v3[2])),dotTest(v1[0]*v2[0]+v1[1]*v2[1]+v1[2]*v2[2]);
1387 if(dotTest>eps && dotTest<1.-eps)
1393 if(found==std::numeric_limits<std::size_t>::max())
1394 throw INTERP_KERNEL::Exception("InsertNodeInConnIfNecessary : not found point !");
1395 conn.insert(conn.begin()+(found+1)%sz,nodeIdToInsert);
1398 void SplitIntoToPart(const std::vector<int>& conn, int pt0, int pt1, std::vector<int>& part0, std::vector<int>& part1)
1400 std::size_t sz(conn.size());
1401 std::vector<int> *curPart(&part0);
1402 for(std::size_t i=0;i<sz;i++)
1404 int nextt(conn[(i+1)%sz]);
1405 (*curPart).push_back(nextt);
1406 if(nextt==pt0 || nextt==pt1)
1412 (*curPart).push_back(nextt);
1418 * this method method splits cur cells 3D Surf in sub cells 3DSurf using the previous subsplit. This method is the last one used to clip.
1420 void MEDCouplingUMesh::buildSubCellsFromCut(const std::vector< std::pair<int,int> >& cut3DSurf,
1421 const int *desc, const int *descIndx, const double *coords, double eps,
1422 std::vector<std::vector<int> >& res) const
1424 checkFullyDefined();
1425 if(getMeshDimension()!=3 || getSpaceDimension()!=3)
1426 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::buildSubCellsFromCut works on umeshes with meshdim equal to 3 and spaceDim equal to 3 too!");
1427 const int *nodal3D(_nodal_connec->begin()),*nodalIndx3D(_nodal_connec_index->begin());
1428 int nbOfCells(getNumberOfCells());
1430 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::buildSubCellsFromCut works only with single cell presently !");
1431 for(int i=0;i<nbOfCells;i++)
1433 int offset(descIndx[i]),nbOfFaces(descIndx[i+1]-offset);
1434 for(int j=0;j<nbOfFaces;j++)
1436 const std::pair<int,int>& p=cut3DSurf[desc[offset+j]];
1437 const INTERP_KERNEL::CellModel& cm(INTERP_KERNEL::CellModel::GetCellModel((INTERP_KERNEL::NormalizedCellType)nodal3D[nodalIndx3D[i]]));
1438 int sz=nodalIndx3D[i+1]-nodalIndx3D[i]-1;
1439 INTERP_KERNEL::AutoPtr<int> tmp(new int[sz]);
1440 INTERP_KERNEL::NormalizedCellType cmsId;
1441 unsigned nbOfNodesSon(cm.fillSonCellNodalConnectivity2(j,nodal3D+nodalIndx3D[i]+1,sz,tmp,cmsId));
1442 std::vector<int> elt((int *)tmp,(int *)tmp+nbOfNodesSon);
1443 if(p.first!=-1 && p.second!=-1)
1447 InsertNodeInConnIfNecessary(p.first,elt,coords,eps);
1448 InsertNodeInConnIfNecessary(p.second,elt,coords,eps);
1449 std::vector<int> elt1,elt2;
1450 SplitIntoToPart(elt,p.first,p.second,elt1,elt2);
1451 res.push_back(elt1);
1452 res.push_back(elt2);
1464 * It is the linear part of MEDCouplingUMesh::split2DCells. Here no additional nodes will be added in \b this. So coordinates pointer remain unchanged (is not even touch).
1466 * \sa MEDCouplingUMesh::split2DCells
1468 void MEDCouplingUMesh::split2DCellsLinear(const DataArrayInt *desc, const DataArrayInt *descI, const DataArrayInt *subNodesInSeg, const DataArrayInt *subNodesInSegI)
1470 checkConnectivityFullyDefined();
1471 int ncells(getNumberOfCells()),lgthToReach(getNodalConnectivityArrayLen()+subNodesInSeg->getNumberOfTuples());
1472 MCAuto<DataArrayInt> c(DataArrayInt::New()); c->alloc((std::size_t)lgthToReach);
1473 const int *subPtr(subNodesInSeg->begin()),*subIPtr(subNodesInSegI->begin()),*descPtr(desc->begin()),*descIPtr(descI->begin()),*oldConn(getNodalConnectivity()->begin());
1474 int *cPtr(c->getPointer()),*ciPtr(getNodalConnectivityIndex()->getPointer());
1475 int prevPosOfCi(ciPtr[0]);
1476 for(int i=0;i<ncells;i++,ciPtr++,descIPtr++)
1478 int offset(descIPtr[0]),sz(descIPtr[1]-descIPtr[0]),deltaSz(0);
1479 *cPtr++=(int)INTERP_KERNEL::NORM_POLYGON; *cPtr++=oldConn[prevPosOfCi+1];
1480 for(int j=0;j<sz;j++)
1482 int offset2(subIPtr[descPtr[offset+j]]),sz2(subIPtr[descPtr[offset+j]+1]-subIPtr[descPtr[offset+j]]);
1483 for(int k=0;k<sz2;k++)
1484 *cPtr++=subPtr[offset2+k];
1486 *cPtr++=oldConn[prevPosOfCi+j+2];
1489 prevPosOfCi=ciPtr[1];
1490 ciPtr[1]=ciPtr[0]+1+sz+deltaSz;//sz==old nb of nodes because (nb of subedges=nb of nodes for polygons)
1493 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::split2DCellsLinear : Some of edges to be split are orphan !");
1494 _nodal_connec->decrRef();
1495 _nodal_connec=c.retn(); _types.clear(); _types.insert(INTERP_KERNEL::NORM_POLYGON);
1500 * It is the quadratic part of MEDCouplingUMesh::split2DCells. Here some additional nodes can be added at the end of coordinates array object.
1502 * \return int - the number of new nodes created.
1503 * \sa MEDCouplingUMesh::split2DCells
1505 int MEDCouplingUMesh::split2DCellsQuadratic(const DataArrayInt *desc, const DataArrayInt *descI, const DataArrayInt *subNodesInSeg, const DataArrayInt *subNodesInSegI, const DataArrayInt *mid, const DataArrayInt *midI)
1507 checkConsistencyLight();
1508 int ncells(getNumberOfCells()),lgthToReach(getNodalConnectivityArrayLen()+2*subNodesInSeg->getNumberOfTuples()),nodesCnt(getNumberOfNodes());
1509 MCAuto<DataArrayInt> c(DataArrayInt::New()); c->alloc((std::size_t)lgthToReach);
1510 MCAuto<DataArrayDouble> addCoo(DataArrayDouble::New()); addCoo->alloc(0,1);
1511 const int *subPtr(subNodesInSeg->begin()),*subIPtr(subNodesInSegI->begin()),*descPtr(desc->begin()),*descIPtr(descI->begin()),*oldConn(getNodalConnectivity()->begin());
1512 const int *midPtr(mid->begin()),*midIPtr(midI->begin());
1513 const double *oldCoordsPtr(getCoords()->begin());
1514 int *cPtr(c->getPointer()),*ciPtr(getNodalConnectivityIndex()->getPointer());
1515 int prevPosOfCi(ciPtr[0]);
1516 for(int i=0;i<ncells;i++,ciPtr++,descIPtr++)
1518 int offset(descIPtr[0]),sz(descIPtr[1]-descIPtr[0]),deltaSz(sz);
1519 for(int j=0;j<sz;j++)
1520 { int sz2(subIPtr[descPtr[offset+j]+1]-subIPtr[descPtr[offset+j]]); deltaSz+=sz2; }
1521 *cPtr++=(int)INTERP_KERNEL::NORM_QPOLYG; cPtr[0]=oldConn[prevPosOfCi+1];
1522 for(int j=0;j<sz;j++)//loop over subedges of oldConn
1524 int offset2(subIPtr[descPtr[offset+j]]),sz2(subIPtr[descPtr[offset+j]+1]-subIPtr[descPtr[offset+j]]),offset3(midIPtr[descPtr[offset+j]]);
1528 cPtr[1]=oldConn[prevPosOfCi+2+j];
1529 cPtr[deltaSz]=oldConn[prevPosOfCi+1+j+sz]; cPtr++;
1532 std::vector<INTERP_KERNEL::Node *> ns(3);
1533 ns[0]=new INTERP_KERNEL::Node(oldCoordsPtr[2*oldConn[prevPosOfCi+1+j]],oldCoordsPtr[2*oldConn[prevPosOfCi+1+j]+1]);
1534 ns[1]=new INTERP_KERNEL::Node(oldCoordsPtr[2*oldConn[prevPosOfCi+1+(1+j)%sz]],oldCoordsPtr[2*oldConn[prevPosOfCi+1+(1+j)%sz]+1]);
1535 ns[2]=new INTERP_KERNEL::Node(oldCoordsPtr[2*oldConn[prevPosOfCi+1+sz+j]],oldCoordsPtr[2*oldConn[prevPosOfCi+1+sz+j]+1]);
1536 MCAuto<INTERP_KERNEL::Edge> e(INTERP_KERNEL::QuadraticPolygon::BuildArcCircleEdge(ns));
1537 for(int k=0;k<sz2;k++)//loop over subsplit of current subedge
1539 cPtr[1]=subPtr[offset2+k];
1540 cPtr[deltaSz]=InternalAddPoint(e,midPtr[offset3+k],oldCoordsPtr,cPtr[0],cPtr[1],*addCoo,nodesCnt); cPtr++;
1542 int tmpEnd(oldConn[prevPosOfCi+1+(j+1)%sz]);
1545 cPtr[deltaSz]=InternalAddPoint(e,midPtr[offset3+sz2],oldCoordsPtr,cPtr[0],tmpEnd,*addCoo,nodesCnt); cPtr++;
1547 prevPosOfCi=ciPtr[1]; cPtr+=deltaSz;
1548 ciPtr[1]=ciPtr[0]+1+2*deltaSz;//sz==old nb of nodes because (nb of subedges=nb of nodes for polygons)
1551 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::split2DCellsQuadratic : Some of edges to be split are orphan !");
1552 _nodal_connec->decrRef();
1553 _nodal_connec=c.retn(); _types.clear(); _types.insert(INTERP_KERNEL::NORM_QPOLYG);
1554 addCoo->rearrange(2);
1555 MCAuto<DataArrayDouble> coo(DataArrayDouble::Aggregate(getCoords(),addCoo));//info are copied from getCoords() by using Aggregate
1557 return addCoo->getNumberOfTuples();
1564 * Partitions the first given 2D mesh using the second given 2D mesh as a tool, and
1565 * returns a result mesh constituted by polygons.
1566 * Thus the final result contains all nodes from m1 plus new nodes. However it doesn't necessarily contains
1567 * all nodes from m2.
1568 * The meshes should be in 2D space. In
1569 * addition, returns two arrays mapping cells of the result mesh to cells of the input
1571 * \param [in] m1 - the first input mesh which is a partitioned object. The mesh must be so that each point in the space covered by \a m1
1572 * must be covered exactly by one entity, \b no \b more. If it is not the case, some tools are available to heal the mesh (conformize2D, mergeNodes)
1573 * \param [in] m2 - the second input mesh which is a partition tool. The mesh must be so that each point in the space covered by \a m2
1574 * must be covered exactly by one entity, \b no \b more. If it is not the case, some tools are available to heal the mesh (conformize2D, mergeNodes)
1575 * \param [in] eps - precision used to detect coincident mesh entities.
1576 * \param [out] cellNb1 - a new instance of DataArrayInt holding for each result
1577 * cell an id of the cell of \a m1 it comes from. The caller is to delete
1578 * this array using decrRef() as it is no more needed.
1579 * \param [out] cellNb2 - a new instance of DataArrayInt holding for each result
1580 * cell an id of the cell of \a m2 it comes from. -1 value means that a
1581 * result cell comes from a cell (or part of cell) of \a m1 not overlapped by
1582 * any cell of \a m2. The caller is to delete this array using decrRef() as
1583 * it is no more needed.
1584 * \return MEDCouplingUMesh * - the result 2D mesh which is a new instance of
1585 * MEDCouplingUMesh. The caller is to delete this mesh using decrRef() as it
1586 * is no more needed.
1587 * \throw If the coordinates array is not set in any of the meshes.
1588 * \throw If the nodal connectivity of cells is not defined in any of the meshes.
1589 * \throw If any of the meshes is not a 2D mesh in 2D space.
1591 * \sa conformize2D, mergeNodes
1593 MEDCouplingUMesh *MEDCouplingUMesh::Intersect2DMeshes(const MEDCouplingUMesh *m1, const MEDCouplingUMesh *m2,
1594 double eps, DataArrayInt *&cellNb1, DataArrayInt *&cellNb2)
1597 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::Intersect2DMeshes : input meshes must be not NULL !");
1598 m1->checkFullyDefined();
1599 m2->checkFullyDefined();
1600 INTERP_KERNEL::QuadraticPlanarPrecision prec(eps);
1601 INTERP_KERNEL::QuadraticPlanarArcDetectionPrecision arcPrec(eps);
1602 if(m1->getMeshDimension()!=2 || m1->getSpaceDimension()!=2 || m2->getMeshDimension()!=2 || m2->getSpaceDimension()!=2)
1603 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::Intersect2DMeshes works on umeshes m1 AND m2 with meshdim equal to 2 and spaceDim equal to 2 too!");
1605 // Step 1: compute all edge intersections (new nodes)
1606 std::vector< std::vector<int> > intersectEdge1, colinear2, subDiv2;
1607 MEDCouplingUMesh *m1Desc=0,*m2Desc=0; // descending connec. meshes
1608 DataArrayInt *desc1=0,*descIndx1=0,*revDesc1=0,*revDescIndx1=0,*desc2=0,*descIndx2=0,*revDesc2=0,*revDescIndx2=0;
1609 std::vector<double> addCoo,addCoordsQuadratic; // coordinates of newly created nodes
1610 IntersectDescending2DMeshes(m1,m2,eps,intersectEdge1,colinear2, subDiv2,
1611 m1Desc,desc1,descIndx1,revDesc1,revDescIndx1,
1612 addCoo, m2Desc,desc2,descIndx2,revDesc2,revDescIndx2);
1613 revDesc1->decrRef(); revDescIndx1->decrRef(); revDesc2->decrRef(); revDescIndx2->decrRef();
1614 MCAuto<DataArrayInt> dd1(desc1),dd2(descIndx1),dd3(desc2),dd4(descIndx2);
1615 MCAuto<MEDCouplingUMesh> dd5(m1Desc),dd6(m2Desc);
1617 // Step 2: re-order newly created nodes according to the ordering found in m2
1618 std::vector< std::vector<int> > intersectEdge2;
1619 BuildIntersectEdges(m1Desc,m2Desc,addCoo,subDiv2,intersectEdge2);
1620 subDiv2.clear(); dd5=0; dd6=0;
1623 std::vector<int> cr,crI; //no DataArrayInt because interface with Geometric2D
1624 std::vector<int> cNb1,cNb2; //no DataArrayInt because interface with Geometric2D
1625 BuildIntersecting2DCellsFromEdges(eps,m1,desc1->begin(),descIndx1->begin(),intersectEdge1,colinear2,m2,desc2->begin(),descIndx2->begin(),intersectEdge2,addCoo,
1626 /* outputs -> */addCoordsQuadratic,cr,crI,cNb1,cNb2);
1628 // Step 4: Prepare final result:
1629 MCAuto<DataArrayDouble> addCooDa(DataArrayDouble::New());
1630 addCooDa->alloc((int)(addCoo.size())/2,2);
1631 std::copy(addCoo.begin(),addCoo.end(),addCooDa->getPointer());
1632 MCAuto<DataArrayDouble> addCoordsQuadraticDa(DataArrayDouble::New());
1633 addCoordsQuadraticDa->alloc((int)(addCoordsQuadratic.size())/2,2);
1634 std::copy(addCoordsQuadratic.begin(),addCoordsQuadratic.end(),addCoordsQuadraticDa->getPointer());
1635 std::vector<const DataArrayDouble *> coordss(4);
1636 coordss[0]=m1->getCoords(); coordss[1]=m2->getCoords(); coordss[2]=addCooDa; coordss[3]=addCoordsQuadraticDa;
1637 MCAuto<DataArrayDouble> coo(DataArrayDouble::Aggregate(coordss));
1638 MCAuto<MEDCouplingUMesh> ret(MEDCouplingUMesh::New("Intersect2D",2));
1639 MCAuto<DataArrayInt> conn(DataArrayInt::New()); conn->alloc((int)cr.size(),1); std::copy(cr.begin(),cr.end(),conn->getPointer());
1640 MCAuto<DataArrayInt> connI(DataArrayInt::New()); connI->alloc((int)crI.size(),1); std::copy(crI.begin(),crI.end(),connI->getPointer());
1641 MCAuto<DataArrayInt> c1(DataArrayInt::New()); c1->alloc((int)cNb1.size(),1); std::copy(cNb1.begin(),cNb1.end(),c1->getPointer());
1642 MCAuto<DataArrayInt> c2(DataArrayInt::New()); c2->alloc((int)cNb2.size(),1); std::copy(cNb2.begin(),cNb2.end(),c2->getPointer());
1643 ret->setConnectivity(conn,connI,true);
1644 ret->setCoords(coo);
1645 cellNb1=c1.retn(); cellNb2=c2.retn();
1650 * Partitions the first given 2D mesh using the second given 1D mesh as a tool.
1651 * Thus the final result contains the aggregation of nodes of \a mesh2D, then nodes of \a mesh1D, then new nodes that are the result of the intersection
1652 * and finally, in case of quadratic polygon the centers of edges new nodes.
1653 * The meshes should be in 2D space. In addition, returns two arrays mapping cells of the resulting mesh to cells of the input.
1655 * \param [in] mesh2D - the 2D mesh (spacedim=meshdim=2) to be intersected using \a mesh1D tool. The mesh must be so that each point in the space covered by \a mesh2D
1656 * must be covered exactly by one entity, \b no \b more. If it is not the case, some tools are available to heal the mesh (conformize2D, mergeNodes)
1657 * \param [in] mesh1D - the 1D mesh (spacedim=2 meshdim=1) the is the tool that will be used to intersect \a mesh2D. \a mesh1D must be ordered consecutively. If it is not the case
1658 * you can invoke orderConsecutiveCells1D on \a mesh1D.
1659 * \param [in] eps - precision used to perform intersections and localization operations.
1660 * \param [out] splitMesh2D - the result of the split of \a mesh2D mesh.
1661 * \param [out] splitMesh1D - the result of the split of \a mesh1D mesh.
1662 * \param [out] cellIdInMesh2D - the array that gives for each cell id \a i in \a splitMesh2D the id in \a mesh2D it comes from.
1663 * So this array has a number of tuples equal to the number of cells of \a splitMesh2D and a number of component equal to 1.
1664 * \param [out] cellIdInMesh1D - the array of pair that gives for each cell id \a i in \a splitMesh1D the cell in \a splitMesh2D on the left for the 1st component
1665 * and the cell in \a splitMesh2D on the right for the 2nt component. -1 means no cell.
1666 * So this array has a number of tuples equal to the number of cells of \a splitMesh1D and a number of components equal to 2.
1668 * \sa Intersect2DMeshes, orderConsecutiveCells1D, conformize2D, mergeNodes
1670 void MEDCouplingUMesh::Intersect2DMeshWith1DLine(const MEDCouplingUMesh *mesh2D, const MEDCouplingUMesh *mesh1D, double eps, MEDCouplingUMesh *&splitMesh2D, MEDCouplingUMesh *&splitMesh1D, DataArrayInt *&cellIdInMesh2D, DataArrayInt *&cellIdInMesh1D)
1672 if(!mesh2D || !mesh1D)
1673 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::Intersect2DMeshWith1DLine : input meshes must be not NULL !");
1674 mesh2D->checkFullyDefined();
1675 mesh1D->checkFullyDefined();
1676 const std::vector<std::string>& compNames(mesh2D->getCoords()->getInfoOnComponents());
1677 if(mesh2D->getMeshDimension()!=2 || mesh2D->getSpaceDimension()!=2 || mesh1D->getMeshDimension()!=1 || mesh1D->getSpaceDimension()!=2)
1678 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::Intersect2DMeshWith1DLine works with mesh2D with spacedim=meshdim=2 and mesh1D with meshdim=1 spaceDim=2 !");
1679 // Step 1: compute all edge intersections (new nodes)
1680 std::vector< std::vector<int> > intersectEdge1, colinear2, subDiv2;
1681 std::vector<double> addCoo,addCoordsQuadratic; // coordinates of newly created nodes
1682 INTERP_KERNEL::QuadraticPlanarPrecision prec(eps);
1683 INTERP_KERNEL::QuadraticPlanarArcDetectionPrecision arcPrec(eps);
1685 // Build desc connectivity
1686 DataArrayInt *desc1(DataArrayInt::New()),*descIndx1(DataArrayInt::New()),*revDesc1(DataArrayInt::New()),*revDescIndx1(DataArrayInt::New());
1687 MCAuto<DataArrayInt> dd1(desc1),dd2(descIndx1),dd3(revDesc1),dd4(revDescIndx1);
1688 MCAuto<MEDCouplingUMesh> m1Desc(mesh2D->buildDescendingConnectivity2(desc1,descIndx1,revDesc1,revDescIndx1));
1689 std::map<int,int> mergedNodes;
1690 Intersect1DMeshes(m1Desc,mesh1D,eps,intersectEdge1,colinear2,subDiv2,addCoo,mergedNodes);
1691 // use mergeNodes to fix intersectEdge1
1692 for(std::vector< std::vector<int> >::iterator it0=intersectEdge1.begin();it0!=intersectEdge1.end();it0++)
1694 std::size_t n((*it0).size()/2);
1695 int eltStart((*it0)[0]),eltEnd((*it0)[2*n-1]);
1696 std::map<int,int>::const_iterator it1;
1697 it1=mergedNodes.find(eltStart);
1698 if(it1!=mergedNodes.end())
1699 (*it0)[0]=(*it1).second;
1700 it1=mergedNodes.find(eltEnd);
1701 if(it1!=mergedNodes.end())
1702 (*it0)[2*n-1]=(*it1).second;
1705 MCAuto<DataArrayDouble> addCooDa(DataArrayDouble::New());
1706 addCooDa->useArray(&addCoo[0],false,C_DEALLOC,(int)addCoo.size()/2,2);
1707 // Step 2: re-order newly created nodes according to the ordering found in m2
1708 std::vector< std::vector<int> > intersectEdge2;
1709 BuildIntersectEdges(m1Desc,mesh1D,addCoo,subDiv2,intersectEdge2);
1711 // Step 3: compute splitMesh1D
1712 MCAuto<DataArrayInt> idsInRet1Colinear,idsInDescMesh2DForIdsInRetColinear;
1713 MCAuto<DataArrayInt> ret2(DataArrayInt::New()); ret2->alloc(0,1);
1714 MCAuto<MEDCouplingUMesh> ret1(BuildMesh1DCutFrom(mesh1D,intersectEdge2,mesh2D->getCoords(),addCoo,mergedNodes,colinear2,intersectEdge1,
1715 idsInRet1Colinear,idsInDescMesh2DForIdsInRetColinear));
1716 MCAuto<DataArrayInt> ret3(DataArrayInt::New()); ret3->alloc(ret1->getNumberOfCells()*2,1); ret3->fillWithValue(std::numeric_limits<int>::max()); ret3->rearrange(2);
1717 MCAuto<DataArrayInt> idsInRet1NotColinear(idsInRet1Colinear->buildComplement(ret1->getNumberOfCells()));
1718 // deal with cells in mesh2D that are not cut but only some of their edges are
1719 MCAuto<DataArrayInt> idsInDesc2DToBeRefined(idsInDescMesh2DForIdsInRetColinear->deepCopy());
1720 idsInDesc2DToBeRefined->abs(); idsInDesc2DToBeRefined->applyLin(1,-1);
1721 idsInDesc2DToBeRefined=idsInDesc2DToBeRefined->buildUnique();
1722 MCAuto<DataArrayInt> out0s;//ids in mesh2D that are impacted by the fact that some edges of \a mesh1D are part of the edges of those cells
1723 if(!idsInDesc2DToBeRefined->empty())
1725 DataArrayInt *out0(0),*outi0(0);
1726 MEDCouplingUMesh::ExtractFromIndexedArrays(idsInDesc2DToBeRefined->begin(),idsInDesc2DToBeRefined->end(),dd3,dd4,out0,outi0);
1727 MCAuto<DataArrayInt> outi0s(outi0);
1729 out0s=out0s->buildUnique();
1733 MCAuto<MEDCouplingUMesh> ret1NonCol(static_cast<MEDCouplingUMesh *>(ret1->buildPartOfMySelf(idsInRet1NotColinear->begin(),idsInRet1NotColinear->end())));
1734 MCAuto<DataArrayDouble> baryRet1(ret1NonCol->computeCellCenterOfMass());
1735 MCAuto<DataArrayInt> elts,eltsIndex;
1736 mesh2D->getCellsContainingPoints(baryRet1->begin(),baryRet1->getNumberOfTuples(),eps,elts,eltsIndex);
1737 MCAuto<DataArrayInt> eltsIndex2(DataArrayInt::New()); eltsIndex2->alloc(0,1);
1738 if (eltsIndex->getNumberOfTuples() > 1)
1739 eltsIndex2 = eltsIndex->deltaShiftIndex();
1740 MCAuto<DataArrayInt> eltsIndex3(eltsIndex2->findIdsEqual(1));
1741 if(eltsIndex2->count(0)+eltsIndex3->getNumberOfTuples()!=ret1NonCol->getNumberOfCells())
1742 throw INTERP_KERNEL::Exception("Intersect2DMeshWith1DLine : internal error 1 !");
1743 MCAuto<DataArrayInt> cellsToBeModified(elts->buildUnique());
1744 MCAuto<DataArrayInt> untouchedCells(cellsToBeModified->buildComplement(mesh2D->getNumberOfCells()));
1745 if((DataArrayInt *)out0s)
1746 untouchedCells=untouchedCells->buildSubstraction(out0s);//if some edges in ret1 are colinear to descending mesh of mesh2D remove cells from untouched one
1747 std::vector< MCAuto<MEDCouplingUMesh> > outMesh2DSplit;
1748 // OK all is ready to insert in ret2 mesh
1749 if(!untouchedCells->empty())
1750 {// the most easy part, cells in mesh2D not impacted at all
1751 outMesh2DSplit.push_back(static_cast<MEDCouplingUMesh *>(mesh2D->buildPartOfMySelf(untouchedCells->begin(),untouchedCells->end())));
1752 outMesh2DSplit.back()->setCoords(ret1->getCoords());
1753 ret2->pushBackValsSilent(untouchedCells->begin(),untouchedCells->end());
1755 if((DataArrayInt *)out0s)
1756 {// here dealing with cells in out0s but not in cellsToBeModified
1757 MCAuto<DataArrayInt> fewModifiedCells(out0s->buildSubstraction(cellsToBeModified));
1758 const int *rdptr(dd3->begin()),*rdiptr(dd4->begin()),*dptr(dd1->begin()),*diptr(dd2->begin());
1759 for(const int *it=fewModifiedCells->begin();it!=fewModifiedCells->end();it++)
1761 outMesh2DSplit.push_back(BuildRefined2DCell(ret1->getCoords(),mesh2D,*it,dptr+diptr[*it],dptr+diptr[*it+1],intersectEdge1));
1762 ret1->setCoords(outMesh2DSplit.back()->getCoords());
1764 int offset(ret2->getNumberOfTuples());
1765 ret2->pushBackValsSilent(fewModifiedCells->begin(),fewModifiedCells->end());
1766 MCAuto<DataArrayInt> partOfRet3(DataArrayInt::New()); partOfRet3->alloc(2*idsInRet1Colinear->getNumberOfTuples(),1);
1767 partOfRet3->fillWithValue(std::numeric_limits<int>::max()); partOfRet3->rearrange(2);
1768 int kk(0),*ret3ptr(partOfRet3->getPointer());
1769 for(const int *it=idsInDescMesh2DForIdsInRetColinear->begin();it!=idsInDescMesh2DForIdsInRetColinear->end();it++,kk++)
1771 int faceId(std::abs(*it)-1);
1772 for(const int *it2=rdptr+rdiptr[faceId];it2!=rdptr+rdiptr[faceId+1];it2++)
1774 int tmp(fewModifiedCells->findIdFirstEqual(*it2));
1777 if(std::find(dptr+diptr[*it2],dptr+diptr[*it2+1],-(*it))!=dptr+diptr[*it2+1])
1778 ret3ptr[2*kk]=tmp+offset;
1779 if(std::find(dptr+diptr[*it2],dptr+diptr[*it2+1],(*it))!=dptr+diptr[*it2+1])
1780 ret3ptr[2*kk+1]=tmp+offset;
1783 {//the current edge is shared by a 2D cell that will be split just after
1784 if(std::find(dptr+diptr[*it2],dptr+diptr[*it2+1],-(*it))!=dptr+diptr[*it2+1])
1785 ret3ptr[2*kk]=-(*it2+1);
1786 if(std::find(dptr+diptr[*it2],dptr+diptr[*it2+1],(*it))!=dptr+diptr[*it2+1])
1787 ret3ptr[2*kk+1]=-(*it2+1);
1791 m1Desc->setCoords(ret1->getCoords());
1792 ret1NonCol->setCoords(ret1->getCoords());
1793 ret3->setPartOfValues3(partOfRet3,idsInRet1Colinear->begin(),idsInRet1Colinear->end(),0,2,1,true);
1794 if(!outMesh2DSplit.empty())
1796 DataArrayDouble *da(outMesh2DSplit.back()->getCoords());
1797 for(std::vector< MCAuto<MEDCouplingUMesh> >::iterator itt=outMesh2DSplit.begin();itt!=outMesh2DSplit.end();itt++)
1798 (*itt)->setCoords(da);
1801 cellsToBeModified=cellsToBeModified->buildUniqueNotSorted();
1802 for(const int *it=cellsToBeModified->begin();it!=cellsToBeModified->end();it++)
1804 MCAuto<DataArrayInt> idsNonColPerCell(elts->findIdsEqual(*it));
1805 idsNonColPerCell->transformWithIndArr(eltsIndex3->begin(),eltsIndex3->end());
1806 MCAuto<DataArrayInt> idsNonColPerCell2(idsInRet1NotColinear->selectByTupleId(idsNonColPerCell->begin(),idsNonColPerCell->end()));
1807 MCAuto<MEDCouplingUMesh> partOfMesh1CuttingCur2DCell(static_cast<MEDCouplingUMesh *>(ret1NonCol->buildPartOfMySelf(idsNonColPerCell->begin(),idsNonColPerCell->end())));
1808 MCAuto<DataArrayInt> partOfRet3;
1809 MCAuto<MEDCouplingUMesh> splitOfOneCell(BuildMesh2DCutFrom(eps,*it,m1Desc,partOfMesh1CuttingCur2DCell,dd1->begin()+dd2->getIJ(*it,0),dd1->begin()+dd2->getIJ((*it)+1,0),intersectEdge1,ret2->getNumberOfTuples(),partOfRet3));
1810 ret3->setPartOfValues3(partOfRet3,idsNonColPerCell2->begin(),idsNonColPerCell2->end(),0,2,1,true);
1811 outMesh2DSplit.push_back(splitOfOneCell);
1812 for(std::size_t i=0;i<splitOfOneCell->getNumberOfCells();i++)
1813 ret2->pushBackSilent(*it);
1816 std::size_t nbOfMeshes(outMesh2DSplit.size());
1817 std::vector<const MEDCouplingUMesh *> tmp(nbOfMeshes);
1818 for(std::size_t i=0;i<nbOfMeshes;i++)
1819 tmp[i]=outMesh2DSplit[i];
1821 ret1->getCoords()->setInfoOnComponents(compNames);
1822 MCAuto<MEDCouplingUMesh> ret2D(MEDCouplingUMesh::MergeUMeshesOnSameCoords(tmp));
1823 // To finish - filter ret3 - std::numeric_limits<int>::max() -> -1 - negate values must be resolved.
1825 MCAuto<DataArrayInt> edgesToDealWith(ret3->findIdsStrictlyNegative());
1826 for(const int *it=edgesToDealWith->begin();it!=edgesToDealWith->end();it++)
1828 int old2DCellId(-ret3->getIJ(*it,0)-1);
1829 MCAuto<DataArrayInt> candidates(ret2->findIdsEqual(old2DCellId));
1830 ret3->setIJ(*it,0,FindRightCandidateAmong(ret2D,candidates->begin(),candidates->end(),ret1,*it%2==0?-((*it)/2+1):(*it)/2+1,eps));// div by 2 because 2 components natively in ret3
1832 ret3->changeValue(std::numeric_limits<int>::max(),-1);
1835 splitMesh1D=ret1.retn();
1836 splitMesh2D=ret2D.retn();
1837 cellIdInMesh2D=ret2.retn();
1838 cellIdInMesh1D=ret3.retn();
1842 * \b WARNING this method is \b potentially \b non \b const (if returned array is empty).
1843 * \b WARNING this method lead to have a non geometric type sorted mesh (for MED file users) !
1844 * This method performs a conformization of \b this. So if a edge in \a this can be split into entire edges in \a this this method
1845 * will suppress such edges to use sub edges in \a this. So this method does not add nodes in \a this if merged edges are both linear (INTERP_KERNEL::NORM_SEG2).
1846 * In the other cases new nodes can be created. If any are created, they will be appended at the end of the coordinates object before the invocation of this method.
1848 * Whatever the returned value, this method does not alter the order of cells in \a this neither the orientation of cells.
1849 * The modified cells, if any, are systematically declared as NORM_POLYGON or NORM_QPOLYG depending on the initial quadraticness of geometric type.
1851 * This method expects that \b this has a meshDim equal 2 and spaceDim equal to 2 too.
1852 * This method expects that all nodes in \a this are not closer than \a eps.
1853 * If it is not the case you can invoke MEDCouplingUMesh::mergeNodes before calling this method.
1855 * \param [in] eps the relative error to detect merged edges.
1856 * \return DataArrayInt * - The list of cellIds in \a this that have been subdivided. If empty, nothing changed in \a this (as if it were a const method). The array is a newly allocated array
1857 * that the user is expected to deal with.
1859 * \throw If \a this is not coherent.
1860 * \throw If \a this has not spaceDim equal to 2.
1861 * \throw If \a this has not meshDim equal to 2.
1862 * \sa MEDCouplingUMesh::mergeNodes, MEDCouplingUMesh::split2DCells
1864 DataArrayInt *MEDCouplingUMesh::conformize2D(double eps)
1866 static const int SPACEDIM=2;
1867 checkConsistencyLight();
1868 if(getSpaceDimension()!=2 || getMeshDimension()!=2)
1869 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::conformize2D : This method only works for meshes with spaceDim=2 and meshDim=2 !");
1870 MCAuto<DataArrayInt> desc1(DataArrayInt::New()),descIndx1(DataArrayInt::New()),revDesc1(DataArrayInt::New()),revDescIndx1(DataArrayInt::New());
1871 MCAuto<MEDCouplingUMesh> mDesc(buildDescendingConnectivity(desc1,descIndx1,revDesc1,revDescIndx1));
1872 const int *c(mDesc->getNodalConnectivity()->begin()),*ci(mDesc->getNodalConnectivityIndex()->begin()),*rd(revDesc1->begin()),*rdi(revDescIndx1->begin());
1873 MCAuto<DataArrayDouble> bboxArr(mDesc->getBoundingBoxForBBTree(eps));
1874 const double *bbox(bboxArr->begin()),*coords(getCoords()->begin());
1875 int nCell(getNumberOfCells()),nDescCell(mDesc->getNumberOfCells());
1876 std::vector< std::vector<int> > intersectEdge(nDescCell),overlapEdge(nDescCell);
1877 std::vector<double> addCoo;
1878 BBTree<SPACEDIM,int> myTree(bbox,0,0,nDescCell,-eps);
1879 INTERP_KERNEL::QuadraticPlanarPrecision prec(eps);
1880 INTERP_KERNEL::QuadraticPlanarArcDetectionPrecision arcPrec(eps);
1881 for(int i=0;i<nDescCell;i++)
1883 std::vector<int> candidates;
1884 myTree.getIntersectingElems(bbox+i*2*SPACEDIM,candidates);
1885 for(std::vector<int>::const_iterator it=candidates.begin();it!=candidates.end();it++)
1888 std::map<MCAuto<INTERP_KERNEL::Node>,int> m;
1889 INTERP_KERNEL::Edge *e1(MEDCouplingUMeshBuildQPFromEdge2((INTERP_KERNEL::NormalizedCellType)c[ci[i]],c+ci[i]+1,coords,m)),
1890 *e2(MEDCouplingUMeshBuildQPFromEdge2((INTERP_KERNEL::NormalizedCellType)c[ci[*it]],c+ci[*it]+1,coords,m));
1891 INTERP_KERNEL::MergePoints merge;
1892 INTERP_KERNEL::QuadraticPolygon c1,c2;
1893 e1->intersectWith(e2,merge,c1,c2);
1894 e1->decrRef(); e2->decrRef();
1895 if(IKGeo2DInternalMapper(c1,m,c[ci[i]+1],c[ci[i]+2],intersectEdge[i]))
1896 overlapEdge[i].push_back(*it);
1897 if(IKGeo2DInternalMapper(c2,m,c[ci[*it]+1],c[ci[*it]+2],intersectEdge[*it]))
1898 overlapEdge[*it].push_back(i);
1901 // splitting done. sort intersect point in intersectEdge.
1902 std::vector< std::vector<int> > middle(nDescCell);
1903 int nbOf2DCellsToBeSplit(0);
1904 bool middleNeedsToBeUsed(false);
1905 std::vector<bool> cells2DToTreat(nDescCell,false);
1906 for(int i=0;i<nDescCell;i++)
1908 std::vector<int>& isect(intersectEdge[i]);
1909 int sz((int)isect.size());
1912 std::map<MCAuto<INTERP_KERNEL::Node>,int> m;
1913 INTERP_KERNEL::Edge *e(MEDCouplingUMeshBuildQPFromEdge2((INTERP_KERNEL::NormalizedCellType)c[ci[i]],c+ci[i]+1,coords,m));
1914 e->sortSubNodesAbs(coords,isect);
1919 int idx0(rdi[i]),idx1(rdi[i+1]);
1921 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::conformize2D : internal error #0 !");
1922 if(!cells2DToTreat[rd[idx0]])
1924 cells2DToTreat[rd[idx0]]=true;
1925 nbOf2DCellsToBeSplit++;
1927 // try to reuse at most eventual 'middle' of SEG3
1928 std::vector<int>& mid(middle[i]);
1929 mid.resize(sz+1,-1);
1930 if((INTERP_KERNEL::NormalizedCellType)c[ci[i]]==INTERP_KERNEL::NORM_SEG3)
1932 middleNeedsToBeUsed=true;
1933 const std::vector<int>& candidates(overlapEdge[i]);
1934 std::vector<int> trueCandidates;
1935 for(std::vector<int>::const_iterator itc=candidates.begin();itc!=candidates.end();itc++)
1936 if((INTERP_KERNEL::NormalizedCellType)c[ci[*itc]]==INTERP_KERNEL::NORM_SEG3)
1937 trueCandidates.push_back(*itc);
1938 int stNode(c[ci[i]+1]),endNode(isect[0]);
1939 for(int j=0;j<sz+1;j++)
1941 for(std::vector<int>::const_iterator itc=trueCandidates.begin();itc!=trueCandidates.end();itc++)
1943 int tmpSt(c[ci[*itc]+1]),tmpEnd(c[ci[*itc]+2]);
1944 if((tmpSt==stNode && tmpEnd==endNode) || (tmpSt==endNode && tmpEnd==stNode))
1945 { mid[j]=*itc; break; }
1948 endNode=j<sz-1?isect[j+1]:c[ci[i]+2];
1953 MCAuto<DataArrayInt> ret(DataArrayInt::New()),notRet(DataArrayInt::New()); ret->alloc(nbOf2DCellsToBeSplit,1);
1954 if(nbOf2DCellsToBeSplit==0)
1957 int *retPtr(ret->getPointer());
1958 for(int i=0;i<nCell;i++)
1959 if(cells2DToTreat[i])
1962 MCAuto<DataArrayInt> mSafe,nSafe,oSafe,pSafe,qSafe,rSafe;
1963 DataArrayInt *m(0),*n(0),*o(0),*p(0),*q(0),*r(0);
1964 MEDCouplingUMesh::ExtractFromIndexedArrays(ret->begin(),ret->end(),desc1,descIndx1,m,n); mSafe=m; nSafe=n;
1965 DataArrayInt::PutIntoToSkylineFrmt(intersectEdge,o,p); oSafe=o; pSafe=p;
1966 if(middleNeedsToBeUsed)
1967 { DataArrayInt::PutIntoToSkylineFrmt(middle,q,r); qSafe=q; rSafe=r; }
1968 MCAuto<MEDCouplingUMesh> modif(static_cast<MEDCouplingUMesh *>(buildPartOfMySelf(ret->begin(),ret->end(),true)));
1969 int nbOfNodesCreated(modif->split2DCells(mSafe,nSafe,oSafe,pSafe,qSafe,rSafe));
1970 setCoords(modif->getCoords());//if nbOfNodesCreated==0 modif and this have the same coordinates pointer so this line has no effect. But for quadratic cases this line is important.
1971 setPartOfMySelf(ret->begin(),ret->end(),*modif);
1973 bool areNodesMerged; int newNbOfNodes;
1974 if(nbOfNodesCreated!=0)
1975 MCAuto<DataArrayInt> tmp(mergeNodes(eps,areNodesMerged,newNbOfNodes));
1981 * This non const method works on 2D mesh. This method scans every cell in \a this and look if each edge constituting this cell is not mergeable with neighbors edges of that cell.
1982 * If yes, the cell is "repaired" to minimize at most its number of edges. So this method do not change the overall shape of cells in \a this (with eps precision).
1983 * This method do not take care of shared edges between cells, so this method can lead to a non conform mesh (\a this). If a conform mesh is required you're expected
1984 * to invoke MEDCouplingUMesh::mergeNodes and MEDCouplingUMesh::conformize2D right after this call.
1985 * This method works on any 2D geometric types of cell (even static one). If a cell is touched its type becomes dynamic automatically. For 2D "repaired" quadratic cells
1986 * new nodes for center of merged edges is are systematically created and appended at the end of the previously existing nodes.
1988 * If the returned array is empty it means that nothing has changed in \a this (as if it were a const method). If the array is not empty the connectivity of \a this is modified
1989 * using new instance, idem for coordinates.
1991 * If \a this is constituted by only linear 2D cells, this method is close to the computation of the convex hull of each cells in \a this.
1993 * \return DataArrayInt * - The list of cellIds in \a this that have at least one edge colinearized.
1995 * \throw If \a this is not coherent.
1996 * \throw If \a this has not spaceDim equal to 2.
1997 * \throw If \a this has not meshDim equal to 2.
1999 * \sa MEDCouplingUMesh::conformize2D, MEDCouplingUMesh::mergeNodes, MEDCouplingUMesh::convexEnvelop2D.
2001 DataArrayInt *MEDCouplingUMesh::colinearize2D(double eps)
2003 MCAuto<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
2004 checkConsistencyLight();
2005 if(getSpaceDimension()!=2 || getMeshDimension()!=2)
2006 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::colinearize2D : This method only works for meshes with spaceDim=2 and meshDim=2 !");
2007 INTERP_KERNEL::QuadraticPlanarPrecision prec(eps);
2008 INTERP_KERNEL::QuadraticPlanarArcDetectionPrecision arcPrec(eps);
2009 int nbOfCells(getNumberOfCells()),nbOfNodes(getNumberOfNodes());
2010 const int *cptr(_nodal_connec->begin()),*ciptr(_nodal_connec_index->begin());
2011 MCAuto<DataArrayInt> newc(DataArrayInt::New()),newci(DataArrayInt::New()); newci->alloc(nbOfCells+1,1); newc->alloc(0,1); newci->setIJ(0,0,0);
2012 MCAuto<DataArrayDouble> appendedCoords(DataArrayDouble::New()); appendedCoords->alloc(0,1);//1 not 2 it is not a bug.
2013 const double *coords(_coords->begin());
2014 int *newciptr(newci->getPointer());
2015 for(int i=0;i<nbOfCells;i++,newciptr++,ciptr++)
2017 if(Colinearize2DCell(coords,cptr+ciptr[0],cptr+ciptr[1],nbOfNodes,newc,appendedCoords))
2018 ret->pushBackSilent(i);
2019 newciptr[1]=newc->getNumberOfTuples();
2024 if(!appendedCoords->empty())
2026 appendedCoords->rearrange(2);
2027 MCAuto<DataArrayDouble> newCoords(DataArrayDouble::Aggregate(getCoords(),appendedCoords));//treat info on components
2029 setCoords(newCoords);
2032 setConnectivity(newc,newci,true);
2038 * c, cI describe a wire mesh in 3D space, in local numbering
2039 * startNode, endNode in global numbering
2040 *\return true if the segment is indeed split
2042 bool MEDCouplingUMesh::OrderPointsAlongLine(const double * coo, int startNode, int endNode,
2043 const int * c, const int * cI, const int *idsBg, const int *endBg,
2044 std::vector<int> & pointIds, std::vector<int> & hitSegs)
2046 using namespace std;
2048 const int SPACEDIM=3;
2049 typedef pair<double, int> PairDI;
2051 for (const int * it = idsBg; it != endBg; ++it)
2053 assert(c[cI[*it]] == INTERP_KERNEL::NORM_SEG2);
2054 int start = c[cI[*it]+1], end = c[cI[*it]+2];
2055 x.insert(make_pair(coo[start*SPACEDIM], start)); // take only X coords
2056 x.insert(make_pair(coo[end*SPACEDIM], end));
2059 vector<PairDI> xx(x.begin(), x.end());
2060 sort(xx.begin(),xx.end());
2061 pointIds.reserve(xx.size());
2063 // Keep what is inside [startNode, endNode]:
2065 for (vector<PairDI>::const_iterator it=xx.begin(); it != xx.end(); ++it)
2067 const int idx = (*it).second;
2070 if (idx == startNode) go = 1;
2071 if (idx == endNode) go = 2;
2072 if (go) pointIds.push_back(idx);
2075 pointIds.push_back(idx);
2076 if (idx == endNode || idx == startNode)
2080 // vector<int> pointIds2(pointIds.size()+2);
2081 // copy(pointIds.begin(), pointIds.end(), pointIds2.data()+1);
2082 // pointIds2[0] = startNode;
2083 // pointIds2[pointIds2.size()-1] = endNode;
2086 reverse(pointIds.begin(), pointIds.end());
2088 // Now identify smaller segments that are not sub-divided - those won't need any further treatment:
2089 for (const int * it = idsBg; it != endBg; ++it)
2091 int start = c[cI[*it]+1], end = c[cI[*it]+2];
2092 vector<int>::const_iterator itStart = find(pointIds.begin(), pointIds.end(), start);
2093 if (itStart == pointIds.end()) continue;
2094 vector<int>::const_iterator itEnd = find(pointIds.begin(), pointIds.end(), end);
2095 if (itEnd == pointIds.end()) continue;
2096 if (abs(distance(itEnd, itStart)) != 1) continue;
2097 hitSegs.push_back(*it); // segment is undivided.
2100 return (pointIds.size() > 2); // something else apart start and end node
2103 void MEDCouplingUMesh::ReplaceEdgeInFace(const int * sIdxConn, const int * sIdxConnE, int startNode, int endNode,
2104 const std::vector<int>& insidePoints, std::vector<int>& modifiedFace)
2106 using namespace std;
2107 int dst = distance(sIdxConn, sIdxConnE);
2108 modifiedFace.reserve(dst + insidePoints.size()-2);
2109 modifiedFace.resize(dst);
2110 copy(sIdxConn, sIdxConnE, modifiedFace.data());
2112 vector<int>::iterator shortEnd = modifiedFace.begin()+dst;
2113 vector<int>::iterator startPos = find(modifiedFace.begin(), shortEnd , startNode);
2114 if (startPos == shortEnd)
2115 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::ReplaceEdgeInFace: internal error, should never happen!");
2116 vector<int>::iterator endPos = find(modifiedFace.begin(),shortEnd, endNode);
2117 if (endPos == shortEnd)
2118 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::ReplaceEdgeInFace: internal error, should never happen!");
2119 int d = distance(startPos, endPos);
2120 if (d == 1 || d == (1-dst)) // don't use modulo, for neg numbers, result is implementation defined ...
2121 modifiedFace.insert(++startPos, ++insidePoints.begin(), --insidePoints.end()); // insidePoints also contains start and end node. Those don't need to be inserted.
2123 modifiedFace.insert(++endPos, ++insidePoints.rbegin(), --insidePoints.rend());
2130 * \b WARNING this method is \b potentially \b non \b const (if returned array is not empty).
2131 * \b WARNING this method lead to have a non geometric type sorted mesh (for MED file users) !
2132 * This method performs a conformization of \b this.
2134 * Only polyhedron cells are supported. You can call convertAllToPoly()
2136 * This method expects that \b this has a meshDim equal 3 and spaceDim equal to 3 too.
2137 * This method expects that all nodes in \a this are not closer than \a eps.
2138 * If it is not the case you can invoke MEDCouplingUMesh::mergeNodes before calling this method.
2140 * \param [in] eps the relative error to detect merged edges.
2141 * \return DataArrayInt * - The list of cellIds in \a this that have been subdivided. If empty, nothing changed in \a this (as if it were a const method). The array is a newly allocated array
2142 * that the user is expected to deal with.
2144 * \throw If \a this is not coherent.
2145 * \throw If \a this has not spaceDim equal to 3.
2146 * \throw If \a this has not meshDim equal to 3.
2147 * \sa MEDCouplingUMesh::mergeNodes, MEDCouplingUMesh::conformize2D, MEDCouplingUMesh::convertAllToPoly()
2149 DataArrayInt *MEDCouplingUMesh::conformize3D(double eps)
2151 using namespace std;
2153 static const int SPACEDIM=3;
2154 checkConsistencyLight();
2155 if(getSpaceDimension()!=3 || getMeshDimension()!=3)
2156 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::conformize3D : This method only works for meshes with spaceDim=3 and meshDim=3!");
2157 if(_types.size() != 1 || *(_types.begin()) != INTERP_KERNEL::NORM_POLYHED)
2158 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::conformize3D : This method only works for polyhedrons! Call convertAllToPoly first.");
2160 MCAuto<MEDCouplingSkyLineArray> connSla(MEDCouplingSkyLineArray::BuildFromPolyhedronConn(getNodalConnectivity(), getNodalConnectivityIndex()));
2161 const double * coo(_coords->begin());
2162 MCAuto<DataArrayInt> ret(DataArrayInt::New()); ret->alloc(0,1);
2165 /*************************
2167 *************************/
2168 MCAuto<DataArrayInt> descDNU(DataArrayInt::New()),descIDNU(DataArrayInt::New()),revDesc(DataArrayInt::New()),revDescI(DataArrayInt::New());
2169 MCAuto<MEDCouplingUMesh> mDesc(buildDescendingConnectivity(descDNU,descIDNU,revDesc,revDescI));
2170 const int *revDescIP(revDescI->getConstPointer()), *revDescP(revDesc->getConstPointer());
2171 const int *cDesc(mDesc->getNodalConnectivity()->begin()),*cIDesc(mDesc->getNodalConnectivityIndex()->begin());
2172 MCAuto<MEDCouplingSkyLineArray> connSlaDesc(MEDCouplingSkyLineArray::New(mDesc->getNodalConnectivityIndex(), mDesc->getNodalConnectivity()));
2175 MCAuto<DataArrayDouble> bboxArr(mDesc->getBoundingBoxForBBTree(eps));
2176 const double *bbox(bboxArr->begin()); getCoords()->begin();
2177 int nDescCell(mDesc->getNumberOfCells());
2178 BBTree<SPACEDIM,int> myTree(bbox,0,0,nDescCell,-eps);
2179 // Surfaces - handle biggest first
2180 MCAuto<MEDCouplingFieldDouble> surfF = mDesc->getMeasureField(true);
2181 DataArrayDouble * surfs = surfF->getArray();
2183 MCAuto<MEDCouplingFieldDouble> normalsF = mDesc->buildOrthogonalField();
2184 DataArrayDouble * normals = normalsF->getArray();
2185 const double * normalsP = normals->getConstPointer();
2187 // Sort faces by decreasing surface:
2188 vector< pair<double,int> > S;
2189 for(std::size_t i=0;i < surfs->getNumberOfTuples();i++)
2191 pair<double,int> p = make_pair(surfs->begin()[i], i);
2194 sort(S.rbegin(),S.rend()); // reverse sort
2195 vector<bool> hit(nDescCell);
2196 fill(hit.begin(), hit.end(), false);
2197 vector<int> hitPoly; // the final result: which 3D cells have been modified.
2199 for( vector<pair<double,int> >::const_iterator it = S.begin(); it != S.end(); it++)
2201 int faceIdx = (*it).second;
2202 if (hit[faceIdx]) continue;
2204 vector<int> candidates, cands2;
2205 myTree.getIntersectingElems(bbox+faceIdx*2*SPACEDIM,candidates);
2206 // Keep only candidates whose normal matches the normal of current face
2207 for(vector<int>::const_iterator it2=candidates.begin();it2!=candidates.end();it2++)
2209 bool col = INTERP_KERNEL::isColinear3D(normalsP + faceIdx*SPACEDIM, normalsP + *(it2)*SPACEDIM, eps);
2210 if (*it2 != faceIdx && col)
2211 cands2.push_back(*it2);
2216 // Now rotate, and match barycenters -- this is where we will bring Intersect2DMeshes later
2217 INTERP_KERNEL::TranslationRotationMatrix rotation;
2218 INTERP_KERNEL::TranslationRotationMatrix::Rotate3DTriangle(coo+SPACEDIM*(cDesc[cIDesc[faceIdx]+1]),
2219 coo+SPACEDIM*(cDesc[cIDesc[faceIdx]+2]),
2220 coo+SPACEDIM*(cDesc[cIDesc[faceIdx]+3]), rotation);
2222 MCAuto<MEDCouplingUMesh> mPartRef(mDesc->buildPartOfMySelfSlice(faceIdx, faceIdx+1,1,false)); // false=zipCoords is called
2223 MCAuto<MEDCouplingUMesh> mPartCand(mDesc->buildPartOfMySelf(&cands2[0], &cands2[0]+cands2.size(), false)); // false=zipCoords is called
2224 double * cooPartRef(mPartRef->_coords->getPointer());
2225 double * cooPartCand(mPartCand->_coords->getPointer());
2226 for (std::size_t ii = 0; ii < mPartRef->_coords->getNumberOfTuples(); ii++)
2227 rotation.transform_vector(cooPartRef+SPACEDIM*ii);
2228 for (std::size_t ii = 0; ii < mPartCand->_coords->getNumberOfTuples(); ii++)
2229 rotation.transform_vector(cooPartCand+SPACEDIM*ii);
2231 // Localize faces in 2D thanks to barycenters
2232 MCAuto<DataArrayDouble> baryPart = mPartCand->computeCellCenterOfMass();
2233 vector<int> compo; compo.push_back(2);
2234 MCAuto<DataArrayDouble> baryPartZ = baryPart->keepSelectedComponents(compo);
2235 MCAuto<DataArrayInt> idsGoodPlane = baryPartZ->findIdsInRange(-eps, +eps);
2236 if (!idsGoodPlane->getNumberOfTuples())
2239 baryPart = baryPart->selectByTupleId(*idsGoodPlane);
2241 compo[0] = 0; compo.push_back(1);
2242 MCAuto<DataArrayDouble> baryPartXY = baryPart->keepSelectedComponents(compo);
2243 mPartRef->changeSpaceDimension(2,0.0);
2244 MCAuto<DataArrayInt> cc(DataArrayInt::New()), ccI(DataArrayInt::New());
2245 mPartRef->getCellsContainingPoints(baryPartXY->begin(), baryPartXY->getNumberOfTuples(), eps, cc, ccI);
2247 if (!cc->getNumberOfTuples())
2249 MCAuto<DataArrayInt> dsi = ccI->deltaShiftIndex();
2252 MCAuto<DataArrayInt> tmp = dsi->findIdsInRange(0, 2);
2253 if (tmp->getNumberOfTuples() != dsi->getNumberOfTuples())
2256 oss << "MEDCouplingUMesh::conformize3D: Non expected non-conformity. Only simple (=partition-like) non-conformities are handled. Face #" << faceIdx << " violates this condition!";
2257 throw INTERP_KERNEL::Exception(oss.str());
2261 MCAuto<DataArrayInt> ids = dsi->findIdsEqual(1);
2263 if (!ids->getNumberOfTuples())
2266 double checkSurf=0.0;
2267 const int * idsGoodPlaneP(idsGoodPlane->begin());
2268 for (const int * ii = ids->begin(); ii != ids->end(); ii++)
2270 int faceIdx2 = cands2[idsGoodPlaneP[*ii]];
2271 hit[faceIdx2] = true;
2272 checkSurf += surfs->begin()[faceIdx2];
2274 if (fabs(checkSurf - surfs->begin()[faceIdx]) > eps)
2277 oss << "MEDCouplingUMesh::conformize3D: Non expected non-conformity. Only simple (=partition-like) non-conformities are handled. Face #" << faceIdx << " violates this condition!";
2278 throw INTERP_KERNEL::Exception(oss.str());
2281 // For all polyhedrons using this face, replace connectivity:
2282 vector<int> polyIndices, packsIds, facePack;
2283 for (int ii=revDescIP[faceIdx]; ii < revDescIP[faceIdx+1]; ii++)
2284 polyIndices.push_back(revDescP[ii]);
2285 ret->pushBackValsSilent(polyIndices.data(),polyIndices.data()+polyIndices.size());
2287 // Current face connectivity
2288 const int * sIdxConn = cDesc + cIDesc[faceIdx] + 1;
2289 const int * sIdxConnE = cDesc + cIDesc[faceIdx+1];
2290 connSla->findPackIds(polyIndices, sIdxConn, sIdxConnE, packsIds);
2291 // Deletion of old faces
2293 for (vector<int>::const_iterator it2=polyIndices.begin(); it2!=polyIndices.end(); ++it2, ++jj)
2295 if (packsIds[jj] == -1)
2296 // The below should never happen - if a face is used several times, with a different layout of the nodes
2297 // it means that it is already conform, so it is *not* hit by the algorithm. The algorithm only hits
2298 // faces which are actually used only once, by a single cell. This is different for edges below.
2299 throw INTERP_KERNEL::Exception("MEDCouplingUMesh::conformize3D: Could not find face in connectivity! Internal error.");
2301 connSla->deletePack(*it2, packsIds[jj]);
2303 // Insertion of new faces:
2304 for (const int * ii = ids->begin(); ii != ids->end(); ii++)
2306 // Build pack from the face to insert:
2307 int faceIdx2 = cands2[idsGoodPlane->getIJ(*ii,0)];
2309 const int * facePack2 = connSlaDesc->getSimplePackSafePtr(faceIdx2, facePack2Sz); // contains the type!
2310 // Insert it in all hit polyhedrons:
2311 for (vector<int>::const_iterator it2=polyIndices.begin(); it2!=polyIndices.end(); ++it2)
2312 connSla->pushBackPack(*it2, facePack2+1, facePack2+facePack2Sz); // without the type
2317 // Set back modified connectivity
2318 MCAuto<DataArrayInt> cAuto; cAuto.takeRef(_nodal_connec);
2319 MCAuto<DataArrayInt> cIAuto; cIAuto.takeRef(_nodal_connec_index);
2320 connSla->convertToPolyhedronConn(cAuto, cIAuto);
2323 /************************
2325 ************************/
2326 // Now we have a face-conform mesh.
2328 // Recompute descending
2329 MCAuto<DataArrayInt> desc(DataArrayInt::New()),descI(DataArrayInt::New()),revDesc(DataArrayInt::New()),revDescI(DataArrayInt::New());
2330 // Rebuild desc connectivity with orientation this time!!
2331 MCAuto<MEDCouplingUMesh> mDesc(buildDescendingConnectivity2(desc,descI,revDesc,revDescI));
2332 const int *revDescIP(revDescI->getConstPointer()), *revDescP(revDesc->getConstPointer());
2333 const int *descIP(descI->getConstPointer()), *descP(desc->getConstPointer());
2334 const int *cDesc(mDesc->getNodalConnectivity()->begin()),*cIDesc(mDesc->getNodalConnectivityIndex()->begin());
2335 MCAuto<DataArrayInt> ciDeepC(mDesc->getNodalConnectivityIndex()->deepCopy());
2336 MCAuto<DataArrayInt> cDeepC(mDesc->getNodalConnectivity()->deepCopy());
2337 MCAuto<MEDCouplingSkyLineArray> connSlaDesc(MEDCouplingSkyLineArray::New(ciDeepC, cDeepC));
2338 MCAuto<DataArrayInt> desc2(DataArrayInt::New()),descI2(DataArrayInt::New()),revDesc2(DataArrayInt::New()),revDescI2(DataArrayInt::New());
2339 MCAuto<MEDCouplingUMesh> mDesc2 = mDesc->buildDescendingConnectivity(desc2,descI2,revDesc2,revDescI2);
2340 // std::cout << "writing!\n";
2341 // mDesc->writeVTK("/tmp/toto_desc_confInter.vtu");
2342 // mDesc2->writeVTK("/tmp/toto_desc2_confInter.vtu");
2343 const int *revDescIP2(revDescI2->getConstPointer()), *revDescP2(revDesc2->getConstPointer());
2344 const int *cDesc2(mDesc2->getNodalConnectivity()->begin()),*cIDesc2(mDesc2->getNodalConnectivityIndex()->begin());
2345 MCAuto<DataArrayDouble> bboxArr(mDesc2->getBoundingBoxForBBTree(eps));
2346 const double *bbox2(bboxArr->begin());
2347 int nDesc2Cell=mDesc2->getNumberOfCells();
2348 BBTree<SPACEDIM,int> myTree2(bbox2,0,0,nDesc2Cell,-eps);
2350 // Edges - handle longest first
2351 MCAuto<MEDCouplingFieldDouble> lenF = mDesc2->getMeasureField(true);
2352 DataArrayDouble * lens = lenF->getArray();
2354 // Sort edges by decreasing length:
2355 vector<pair<double,int> > S;
2356 for(std::size_t i=0;i < lens->getNumberOfTuples();i++)
2358 pair<double,int> p = make_pair(lens->getIJ(i, 0), i);
2361 sort(S.rbegin(),S.rend()); // reverse sort
2363 vector<bool> hit(nDesc2Cell);
2364 fill(hit.begin(), hit.end(), false);
2366 for( vector<pair<double,int> >::const_iterator it = S.begin(); it != S.end(); it++)
2368 int eIdx = (*it).second;
2372 vector<int> candidates, cands2;
2373 myTree2.getIntersectingElems(bbox2+eIdx*2*SPACEDIM,candidates);
2374 // Keep only candidates colinear with current edge
2376 unsigned start = cDesc2[cIDesc2[eIdx]+1], end = cDesc2[cIDesc2[eIdx]+2];
2377 for (int i3=0; i3 < 3; i3++) // TODO: use fillSonCellNodalConnectivity2 or similar?
2378 vCurr[i3] = coo[start*SPACEDIM+i3] - coo[end*SPACEDIM+i3];
2379 for(vector<int>::const_iterator it2=candidates.begin();it2!=candidates.end();it2++)
2382 unsigned start2 = cDesc2[cIDesc2[*it2]+1], end2 = cDesc2[cIDesc2[*it2]+2];
2383 for (int i3=0; i3 < 3; i3++)
2384 vOther[i3] = coo[start2*SPACEDIM+i3] - coo[end2*SPACEDIM+i3];
2385 bool col = INTERP_KERNEL::isColinear3D(vCurr, vOther, eps);
2386 // Warning: different from faces: we need to keep eIdx in the final list of candidates because we need
2387 // to have its nodes inside the sub mesh mPartCand below (needed in OrderPointsAlongLine())
2389 cands2.push_back(*it2);
2391 if (cands2.size() == 1 && cands2[0] == eIdx) // see warning above
2394 // Now rotate edges to bring them on Ox
2395 int startNode = cDesc2[cIDesc2[eIdx]+1];
2396 int endNode = cDesc2[cIDesc2[eIdx]+2];
2397 INTERP_KERNEL::TranslationRotationMatrix rotation;
2398 INTERP_KERNEL::TranslationRotationMatrix::Rotate3DBipoint(coo+SPACEDIM*startNode, coo+SPACEDIM*endNode, rotation);
2399 MCAuto<MEDCouplingUMesh> mPartRef(mDesc2->buildPartOfMySelfSlice(eIdx, eIdx+1,1,false)); // false=zipCoords is called
2400 MCAuto<MEDCouplingUMesh> mPartCand(mDesc2->buildPartOfMySelf(&cands2[0], &cands2[0]+cands2.size(), true)); // true=zipCoords is called
2401 MCAuto<DataArrayInt> nodeMap(mPartCand->zipCoordsTraducer());
2404 MCAuto<DataArrayInt> tmp(nodeMap->findIdsNotEqual(-1));
2405 nbElemsNotM1 = tmp->getNbOfElems();
2407 MCAuto<DataArrayInt> nodeMapInv = nodeMap->invertArrayO2N2N2O(nbElemsNotM1);
2408 double * cooPartRef(mPartRef->_coords->getPointer());
2409 double * cooPartCand(mPartCand->_coords->getPointer());
2410 for (std::size_t ii = 0; ii < mPartRef->_coords->getNumberOfTuples(); ii++)
2411 rotation.transform_vector(cooPartRef+SPACEDIM*ii);
2412 for (std::size_t ii = 0; ii < mPartCand->_coords->getNumberOfTuples(); ii++)
2413 rotation.transform_vector(cooPartCand+SPACEDIM*ii);
2416 // Eliminate all edges for which y or z is not null
2417 MCAuto<DataArrayDouble> baryPart = mPartCand->computeCellCenterOfMass();
2418 vector<int> compo; compo.push_back(1);
2419 MCAuto<DataArrayDouble> baryPartY = baryPart->keepSelectedComponents(compo);
2421 MCAuto<DataArrayDouble> baryPartZ = baryPart->keepSelectedComponents(compo);
2422 MCAuto<DataArrayInt> idsGoodLine1 = baryPartY->findIdsInRange(-eps, +eps);
2423 MCAuto<DataArrayInt> idsGoodLine2 = baryPartZ->findIdsInRange(-eps, +eps);
2424 MCAuto<DataArrayInt> idsGoodLine = idsGoodLine1->buildIntersection(idsGoodLine2);
2425 if (!idsGoodLine->getNumberOfTuples())
2428 // Now the ordering along the Ox axis:
2429 std::vector<int> insidePoints, hitSegs;
2430 bool isSplit = OrderPointsAlongLine(mPartCand->_coords->getConstPointer(), nodeMap->begin()[startNode], nodeMap->begin()[endNode],
2431 mPartCand->getNodalConnectivity()->begin(), mPartCand->getNodalConnectivityIndex()->begin(),
2432 idsGoodLine->begin(), idsGoodLine->end(),
2433 /*out*/insidePoints, hitSegs);
2434 // Optim: smaller segments completely included in eIdx and not split won't need any further treatment:
2435 for (vector<int>::const_iterator its=hitSegs.begin(); its != hitSegs.end(); ++its)
2436 hit[cands2[*its]] = true;
2438 if (!isSplit) // current segment remains in one piece
2441 // Get original node IDs in global coords array
2442 for (std::vector<int>::iterator iit = insidePoints.begin(); iit!=insidePoints.end(); ++iit)
2443 *iit = nodeMapInv->begin()[*iit];
2445 vector<int> polyIndices, packsIds, facePack;
2446 // For each face implying this edge
2447 for (int ii=revDescIP2[eIdx]; ii < revDescIP2[eIdx+1]; ii++)
2449 int faceIdx = revDescP2[ii];
2450 // each cell where this face is involved connectivity will be modified:
2451 ret->pushBackValsSilent(revDescP + revDescIP[faceIdx], revDescP + revDescIP[faceIdx+1]);
2453 // Current face connectivity
2454 const int * sIdxConn = cDesc + cIDesc[faceIdx] + 1;
2455 const int * sIdxConnE = cDesc + cIDesc[faceIdx+1];
2457 vector<int> modifiedFace;
2458 ReplaceEdgeInFace(sIdxConn, sIdxConnE, startNode, endNode, insidePoints, /*out*/modifiedFace);
2459 modifiedFace.insert(modifiedFace.begin(), INTERP_KERNEL::NORM_POLYGON);
2460 connSlaDesc->replaceSimplePack(faceIdx, modifiedFace.data(), modifiedFace.data()+modifiedFace.size());
2464 // Rebuild 3D connectivity from descending:
2465 MCAuto<MEDCouplingSkyLineArray> newConn(MEDCouplingSkyLineArray::New());
2466 MCAuto<DataArrayInt> superIdx(DataArrayInt::New()); superIdx->alloc(getNumberOfCells()+1); superIdx->fillWithValue(0);
2467 MCAuto<DataArrayInt> idx(DataArrayInt::New()); idx->alloc(1); idx->fillWithValue(0);
2468 MCAuto<DataArrayInt> vals(DataArrayInt::New()); vals->alloc(0);
2469 newConn->set3(superIdx, idx, vals);
2470 for(std::size_t ii = 0; ii < getNumberOfCells(); ii++)
2471 for (int jj=descIP[ii]; jj < descIP[ii+1]; jj++)
2473 int sz, faceIdx = abs(descP[jj])-1;
2474 bool orient = descP[jj]>0;
2475 const int * p = connSlaDesc->getSimplePackSafePtr(faceIdx, sz);
2477 newConn->pushBackPack(ii, p+1, p+sz); // +1 to skip type
2480 vector<int> rev(sz-1);
2481 for (int kk=0; kk<sz-1; kk++) rev[kk]=*(p+sz-kk-1);
2482 newConn->pushBackPack(ii, rev.data(), rev.data()+sz-1);
2486 newConn->convertToPolyhedronConn(cAuto, cIAuto);
2489 ret = ret->buildUniqueNotSorted();