TetrahedralMesh.cpp

00001 /*
00002 
00003 Copyright (C) University of Oxford, 2005-2011
00004 
00005 University of Oxford means the Chancellor, Masters and Scholars of the
00006 University of Oxford, having an administrative office at Wellington
00007 Square, Oxford OX1 2JD, UK.
00008 
00009 This file is part of Chaste.
00010 
00011 Chaste is free software: you can redistribute it and/or modify it
00012 under the terms of the GNU Lesser General Public License as published
00013 by the Free Software Foundation, either version 2.1 of the License, or
00014 (at your option) any later version.
00015 
00016 Chaste is distributed in the hope that it will be useful, but WITHOUT
00017 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
00018 FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Lesser General Public
00019 License for more details. The offer of Chaste under the terms of the
00020 License is subject to the License being interpreted in accordance with
00021 English Law and subject to any action against the University of Oxford
00022 being under the jurisdiction of the English Courts.
00023 
00024 You should have received a copy of the GNU Lesser General Public License
00025 along with Chaste. If not, see <http://www.gnu.org/licenses/>.
00026 
00027 */
00028 
00029 #include "TetrahedralMesh.hpp"
00030 
00031 #include <iostream>
00032 #include <cassert>
00033 #include <sstream>
00034 #include <map>
00035 
00036 #include "BoundaryElement.hpp"
00037 #include "Element.hpp"
00038 #include "Exception.hpp"
00039 #include "Node.hpp"
00040 #include "OutputFileHandler.hpp"
00041 #include "PetscTools.hpp"
00042 #include "RandomNumberGenerator.hpp"
00043 
00044 //Jonathan Shewchuk's triangle and Hang Si's tetgen
00045 #define REAL double
00046 #define VOID void
00047 #include "triangle.h"
00048 #include "tetgen.h"
00049 #undef REAL
00050 #undef VOID
00051 
00053 //   IMPLEMENTATION
00055 
00056 
00057 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00058 TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::TetrahedralMesh()
00059 {
00060     Clear();
00061 }
00062 
00063 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00064 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ConstructFromMeshReader(
00065     AbstractMeshReader<ELEMENT_DIM, SPACE_DIM>& rMeshReader)
00066 {
00067     this->mMeshFileBaseName = rMeshReader.GetMeshFileBaseName();
00068 
00069     // Record number of corner nodes
00070     unsigned num_nodes = rMeshReader.GetNumNodes();
00071 
00072     // Reserve memory for nodes, so we don't have problems with pointers stored in
00073     // elements becoming invalid.
00074     this->mNodes.reserve(num_nodes);
00075 
00076     rMeshReader.Reset();
00077 
00078     //typename std::map<std::pair<unsigned,unsigned>,unsigned>::const_iterator iterator;
00079     //std::map<std::pair<unsigned,unsigned>,unsigned> internal_nodes_map;
00080 
00081     // Add nodes
00082     std::vector<double> coords;
00083     for (unsigned i=0; i < num_nodes; i++)
00084     {
00085         coords = rMeshReader.GetNextNode();
00086         Node<SPACE_DIM>* p_node =  new Node<SPACE_DIM>(i, coords, false);
00087 
00088         for (unsigned i = 0; i < rMeshReader.GetNodeAttributes().size(); i++)
00089         {
00090             double attribute = rMeshReader.GetNodeAttributes()[i];
00091             p_node->AddNodeAttribute(attribute);
00092         }
00093 
00094         this->mNodes.push_back(p_node);
00095     }
00096 
00097     //unsigned new_node_index = mNumCornerNodes;
00098 
00099     rMeshReader.Reset();
00100     // Add elements
00101     //new_node_index = mNumCornerNodes;
00102     this->mElements.reserve(rMeshReader.GetNumElements());
00103 
00104     for (unsigned element_index=0; element_index < (unsigned) rMeshReader.GetNumElements(); element_index++)
00105     {
00106         ElementData element_data = rMeshReader.GetNextElementData();
00107         std::vector<Node<SPACE_DIM>*> nodes;
00108 
00109         // NOTE: currently just reading element vertices from mesh reader - even if it
00110         // does contain information about internal nodes (ie for quadratics) this is
00111         // ignored here and used elsewhere: ie don't do this:
00112         //   unsigned nodes_size = node_indices.size();
00113 
00114         for (unsigned j=0; j<ELEMENT_DIM+1; j++) // num vertices=ELEMENT_DIM+1, may not be equal to nodes_size.
00115         {
00116             assert(element_data.NodeIndices[j] <  this->mNodes.size());
00117             nodes.push_back(this->mNodes[element_data.NodeIndices[j]]);
00118         }
00119 
00120         Element<ELEMENT_DIM,SPACE_DIM>* p_element = new Element<ELEMENT_DIM,SPACE_DIM>(element_index, nodes);
00121         this->mElements.push_back(p_element);
00122 
00123         if (rMeshReader.GetNumElementAttributes() > 0)
00124         {
00125             assert(rMeshReader.GetNumElementAttributes() == 1);
00126             unsigned attribute_value = element_data.AttributeValue;
00127             p_element->SetRegion(attribute_value);
00128         }
00129     }
00130 
00131     // Add boundary elements and nodes
00132     for (unsigned face_index=0; face_index<(unsigned)rMeshReader.GetNumFaces(); face_index++)
00133     {
00134         ElementData face_data = rMeshReader.GetNextFaceData();
00135         std::vector<unsigned> node_indices = face_data.NodeIndices;
00136 
00137         // NOTE: as above just read boundary element *vertices* from mesh reader - even if
00138         // it is a quadratic mesh with internal elements, the extra nodes are ignored here
00139         // and used elsewhere: ie, we don't do this:
00140         //   unsigned nodes_size = node_indices.size();
00141 
00142         std::vector<Node<SPACE_DIM>*> nodes;
00143         for (unsigned node_index=0; node_index<ELEMENT_DIM; node_index++) // node_index from 0 to DIM-1, not 0 to node.size()-1
00144         {
00145             assert(node_indices[node_index] < this->mNodes.size());
00146             // Add Node pointer to list for creating an element
00147             nodes.push_back(this->mNodes[node_indices[node_index]]);
00148         }
00149 
00150         // This is a boundary face
00151         // Ensure all its nodes are marked as boundary nodes
00152 
00153         assert(nodes.size()==ELEMENT_DIM); // just taken vertices of boundary node from
00154         for (unsigned j=0; j<nodes.size(); j++)
00155         {
00156             if (!nodes[j]->IsBoundaryNode())
00157             {
00158                 nodes[j]->SetAsBoundaryNode();
00159                 this->mBoundaryNodes.push_back(nodes[j]);
00160             }
00161             //Register the index that this bounday element will have
00162             //with the node
00163             nodes[j]->AddBoundaryElement(face_index);
00164         }
00165 
00166         // The added elements will be deleted in our destructor
00167         BoundaryElement<ELEMENT_DIM-1,SPACE_DIM>* p_boundary_element = new BoundaryElement<ELEMENT_DIM-1,SPACE_DIM>(face_index, nodes);
00168         this->mBoundaryElements.push_back(p_boundary_element);
00169 
00170         if (rMeshReader.GetNumFaceAttributes() > 0)
00171         {
00172             assert(rMeshReader.GetNumFaceAttributes() == 1);
00173             unsigned attribute_value = face_data.AttributeValue;
00174             p_boundary_element->SetRegion(attribute_value);
00175         }
00176     }
00177 
00178     RefreshJacobianCachedData();
00179     rMeshReader.Reset();
00180 }
00181 
00182 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00183 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ReadNodesPerProcessorFile(const std::string& rNodesPerProcessorFile)
00184 {
00185     std::vector<unsigned> nodes_per_processor_vec;
00186 
00187     std::ifstream file_stream(rNodesPerProcessorFile.c_str());
00188     if (file_stream.is_open())
00189     {
00190         while (file_stream)
00191         {
00192             unsigned nodes_per_processor;
00193             file_stream >> nodes_per_processor;
00194 
00195             if (file_stream)
00196             {
00197                 nodes_per_processor_vec.push_back(nodes_per_processor);
00198             }
00199         }
00200     }
00201     else
00202     {
00203         EXCEPTION("Unable to read nodes per processor file " + rNodesPerProcessorFile);
00204     }
00205 
00206     unsigned sum = 0;
00207     for (unsigned i=0; i<nodes_per_processor_vec.size(); i++)
00208     {
00209         sum += nodes_per_processor_vec[i];
00210     }
00211 
00212     if (sum != this->GetNumNodes())
00213     {
00214         std::stringstream string_stream;
00215         string_stream << "Sum of nodes per processor, " << sum
00216                      << ", not equal to number of nodes in mesh, " << this->GetNumNodes();
00217         EXCEPTION(string_stream.str());
00218     }
00219 
00220     unsigned num_owned=nodes_per_processor_vec[PetscTools::GetMyRank()];
00221 
00222     if (nodes_per_processor_vec.size() != PetscTools::GetNumProcs())
00223     {
00224         EXCEPTION("Number of processes doesn't match the size of the nodes-per-processor file");
00225     }
00226     delete this->mpDistributedVectorFactory;
00227     this->mpDistributedVectorFactory=new DistributedVectorFactory(this->GetNumNodes(), num_owned);
00228 }
00229 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00230 bool TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::CheckIsConforming()
00231 {
00232     /* Each face of each element is a set of node indices
00233      * We form a set of these in order to get their parity:
00234      *   all faces which appear once are inserted into the set
00235      *   all faces which appear twice are inserted and then removed from the set
00236      *   we're assuming that faces never appear more than twice
00237      */
00238     std::set< std::set<unsigned> > odd_parity_faces;
00239 
00240     for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00241          iter != this->GetElementIteratorEnd();
00242          ++iter)
00243     {
00244         for (unsigned face_index=0; face_index<=ELEMENT_DIM; face_index++)
00245         {
00246             std::set<unsigned> face_info;
00247             for (unsigned node_index=0; node_index<=ELEMENT_DIM; node_index++)
00248             {
00249                 //Leave one index out each time
00250                 if (node_index != face_index)
00251                 {
00252                     face_info.insert(iter->GetNodeGlobalIndex(node_index));
00253                 }
00254             }
00255             //Face is now formed - attempt to find it
00256             std::set< std::set<unsigned> >::iterator find_face=odd_parity_faces.find(face_info);
00257             if( find_face != odd_parity_faces.end())
00258             {
00259                 //Face was in set, so it now has even parity.
00260                 //Remove it via the iterator
00261                 odd_parity_faces.erase(find_face);
00262             }
00263             else
00264             {
00265                 //Face is not in set so it now has odd parity.  Insert it
00266                 odd_parity_faces.insert(face_info);
00267             }
00268 
00269         }
00270     }
00271     /* At this point the odd parity faces should be the same as the
00272      * boundary elements.  We could check this explicitly or we
00273      * could just count them.
00274      */
00275     return( odd_parity_faces.size() == this->GetNumBoundaryElements());
00276 }
00277 
00278 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00279 double TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetVolume()
00280 {
00281     double mesh_volume = 0.0;
00282 
00283     for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00284          iter != this->GetElementIteratorEnd();
00285          ++iter)
00286     {
00287         mesh_volume += iter->GetVolume(mElementJacobianDeterminants[iter->GetIndex()]);
00288     }
00289 
00290     return mesh_volume;
00291 }
00292 
00293 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00294 double TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetSurfaceArea()
00295 {
00296     //ELEMENT_DIM-1 is the dimension of the boundary element
00297     assert(ELEMENT_DIM >= 1);
00298     const unsigned bound_element_dim = ELEMENT_DIM-1;
00299     assert(bound_element_dim < 3);
00300     if ( bound_element_dim == 0)
00301     {
00302         return 0.0;
00303     }
00304 
00305     double mesh_surface = 0.0;
00306     typename TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::BoundaryElementIterator it = this->GetBoundaryElementIteratorBegin();
00307 
00308     while (it != this->GetBoundaryElementIteratorEnd())
00309     {
00310         mesh_surface += mBoundaryElementJacobianDeterminants[(*it)->GetIndex()];
00311         it++;
00312     }
00313 
00314     if ( bound_element_dim == 2)
00315     {
00316         mesh_surface /= 2.0;
00317     }
00318 
00319     return mesh_surface;
00320 }
00321 
00322 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00323 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::PermuteNodes()
00324 {
00325     //Make a permutation vector of the identity
00326     RandomNumberGenerator* p_rng = RandomNumberGenerator::Instance();
00327     std::vector<unsigned> perm;
00328     p_rng->Shuffle(this->mNodes.size(), perm);
00329     //Call the non-random version
00330     PermuteNodes(perm);
00331 }
00332 
00333 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00334 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::PermuteNodes(const std::vector<unsigned>& perm)
00335 {
00336     // Let's not do this if there are any deleted nodes
00337     assert( this->GetNumAllNodes() == this->GetNumNodes());
00338 
00339     assert(perm.size() == this->mNodes.size());
00340 
00341     // Copy the node pointers
00342     std::vector< Node<SPACE_DIM>* > copy_m_nodes;
00343     copy_m_nodes.assign(this->mNodes.begin(), this->mNodes.end());
00344 
00345     for (unsigned original_index=0; original_index<this->mNodes.size(); original_index++)
00346     {
00347         assert(perm[original_index] < this->mNodes.size());
00348         //perm[original_index] holds the new assigned index of that node
00349         this->mNodes[ perm[original_index] ] = copy_m_nodes[original_index];
00350     }
00351 
00352     // Update indices
00353     for (unsigned index=0; index<this->mNodes.size(); index++)
00354     {
00355         this->mNodes[index]->SetIndex(index);
00356     }
00357     //Copy the permutation vector into the mesh
00358     this->mNodesPermutation = perm;
00359 }
00360 
00361 
00362 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00363 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetContainingElementIndex(const ChastePoint<SPACE_DIM>& rTestPoint,
00364                                                                             bool strict,
00365                                                                             std::set<unsigned> testElements,
00366                                                                             bool onlyTryWithTestElements)
00367 {
00368     for (std::set<unsigned>::iterator iter=testElements.begin(); iter!=testElements.end(); iter++)
00369     {
00370         assert(*iter<this->GetNumElements());
00371         if (this->mElements[*iter]->IncludesPoint(rTestPoint, strict))
00372         {
00373             assert(!this->mElements[*iter]->IsDeleted());
00374             return *iter;
00375         }
00376     }
00377 
00378     if(!onlyTryWithTestElements)
00379     {
00380         for (unsigned i=0; i<this->mElements.size(); i++)
00381         {
00382             if (this->mElements[i]->IncludesPoint(rTestPoint, strict))
00383             {
00384                 assert(!this->mElements[i]->IsDeleted());
00385                 return i;
00386             }
00387         }
00388     }
00389 
00390     // If it's in none of the elements, then throw
00391     std::stringstream ss;
00392     ss << "Point [";
00393     for(unsigned j=0; (int)j<(int)SPACE_DIM-1; j++)
00394     {
00395         ss << rTestPoint[j] << ",";
00396     }
00397     ss << rTestPoint[SPACE_DIM-1] << "] is not in ";
00398     if(!onlyTryWithTestElements)
00399     {
00400         ss << "mesh - all elements tested";
00401     }
00402     else
00403     {
00404         ss << "set of elements given";
00405     }
00406     EXCEPTION(ss.str());
00407 }
00408 
00409 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00410 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetContainingElementIndexWithInitialGuess(const ChastePoint<SPACE_DIM>& rTestPoint, unsigned startingElementGuess, bool strict)
00411 {
00412     assert(startingElementGuess<this->GetNumElements());
00413 
00414     // let m=startingElementGuess, N=num_elem-1
00415     // We search from in this order: m, m+1, m+2, .. , N, 0, 1, .., m-1.
00416 
00417     unsigned i = startingElementGuess;
00418     bool reached_end = false;
00419 
00420     while(!reached_end)
00421     {
00422         if (this->mElements[i]->IncludesPoint(rTestPoint, strict))
00423         {
00424             assert(!this->mElements[i]->IsDeleted());
00425             return i;
00426         }
00427 
00428         // increment
00429         i++;
00430         if(i==this->GetNumElements())
00431         {
00432             i=0;
00433         }
00434 
00435         // back to the beginning yet?
00436         if(i==startingElementGuess)
00437         {
00438             reached_end = true;
00439         }
00440     }
00441 
00442     // If it's in none of the elements, then throw
00443     std::stringstream ss;
00444     ss << "Point [";
00445     for(unsigned j=0; (int)j<(int)SPACE_DIM-1; j++)
00446     {
00447         ss << rTestPoint[j] << ",";
00448     }
00449     ss << rTestPoint[SPACE_DIM-1] << "] is not in mesh - all elements tested";
00450     EXCEPTION(ss.str());
00451 }
00452 
00453 
00454 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00455 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetNearestElementIndex(const ChastePoint<SPACE_DIM>& rTestPoint)
00456 {
00457     double max_min_weight = -INFINITY;
00458     unsigned closest_index = 0;
00459     for (unsigned i=0; i<this->mElements.size(); i++)
00460     {
00461         c_vector<double, ELEMENT_DIM+1> weight=this->mElements[i]->CalculateInterpolationWeights(rTestPoint);
00462         double neg_weight_sum=0.0;
00463         for (unsigned j=0; j<=ELEMENT_DIM; j++)
00464         {
00465             if (weight[j] < 0.0)
00466             {
00467                 neg_weight_sum += weight[j];
00468             }
00469         }
00470         if (neg_weight_sum > max_min_weight)
00471         {
00472             max_min_weight = neg_weight_sum;
00473             closest_index = i;
00474         }
00475 
00476     }
00477     assert(!this->mElements[closest_index]->IsDeleted());
00478     return closest_index;
00479 }
00480 
00481 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00482 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetNearestElementIndexFromTestElements(const ChastePoint<SPACE_DIM>& rTestPoint,
00483                                                                                          std::set<unsigned> testElements)
00484 {
00485     assert(testElements.size()>0);
00486 
00487     double max_min_weight = -INFINITY;
00488     unsigned closest_index = 0;
00489     for(std::set<unsigned>::iterator iter = testElements.begin();
00490         iter != testElements.end();
00491         iter++)
00492     {
00493         c_vector<double, ELEMENT_DIM+1> weight=this->mElements[*iter]->CalculateInterpolationWeights(rTestPoint);
00494         double neg_weight_sum=0.0;
00495         for (unsigned j=0; j<=ELEMENT_DIM; j++)
00496         {
00497             if (weight[j] < 0.0)
00498             {
00499                 neg_weight_sum += weight[j];
00500             }
00501         }
00502         if (neg_weight_sum > max_min_weight)
00503         {
00504             max_min_weight = neg_weight_sum;
00505             closest_index = *iter;
00506         }
00507 
00508     }
00509     assert(!this->mElements[closest_index]->IsDeleted());
00510     return closest_index;
00511 }
00512 
00513 
00514 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00515 std::vector<unsigned> TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetContainingElementIndices(const ChastePoint<SPACE_DIM> &rTestPoint)
00516 {
00517     std::vector<unsigned> element_indices;
00518     for (unsigned i=0; i<this->mElements.size(); i++)
00519     {
00520         if (this->mElements[i]->IncludesPoint(rTestPoint))
00521         {
00522             assert(!this->mElements[i]->IsDeleted());
00523             element_indices.push_back(i);
00524         }
00525     }
00526     return element_indices;
00527 }
00528 
00529 
00530 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00531 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::Clear()
00532 {
00533     // three loops, just like the destructor. note we don't delete boundary nodes.
00534     for (unsigned i=0; i<this->mBoundaryElements.size(); i++)
00535     {
00536         delete this->mBoundaryElements[i];
00537     }
00538     for (unsigned i=0; i<this->mElements.size(); i++)
00539     {
00540         delete this->mElements[i];
00541     }
00542     for (unsigned i=0; i<this->mNodes.size(); i++)
00543     {
00544         delete this->mNodes[i];
00545     }
00546 
00547     this->mNodes.clear();
00548     this->mElements.clear();
00549     this->mBoundaryElements.clear();
00550     this->mBoundaryNodes.clear();
00551 }
00552 
00553 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00554 std::set<unsigned> TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::CalculateBoundaryOfFlaggedRegion()
00555 {
00556     // A set of nodes which lie on the face, size 3 in 2D, size 4 in 3D
00557     typedef std::set<unsigned> FaceNodes;
00558 
00559     // Face maps to true the first time it is encountered, and false subsequent
00560     // times. Thus, faces mapping to true at the end are boundary faces
00561     std::map<FaceNodes,bool> face_on_boundary;
00562 
00563     // Loop over all elements
00564     for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00565          iter != this->GetElementIteratorEnd();
00566          ++iter)
00567     {
00568         if (iter->IsFlagged())
00569         {
00570             // To get faces, initially start with all nodes
00571             std::set<unsigned> all_nodes;
00572             for (unsigned i=0; i<ELEMENT_DIM+1; i++)
00573             {
00574                 all_nodes.insert(iter->GetNodeGlobalIndex(i));
00575             }
00576 
00577             // Remove one node in turn to obtain each face
00578             for (unsigned i=0; i<ELEMENT_DIM+1; i++)
00579             {
00580                 FaceNodes face_nodes = all_nodes;
00581                 face_nodes.erase(iter->GetNodeGlobalIndex(i));
00582 
00583                 // Search the map of faces to see if it contains this face
00584                 std::map<FaceNodes,bool>::iterator it = face_on_boundary.find(face_nodes);
00585 
00586                 if (it == face_on_boundary.end())
00587                 {
00588                     // Face not found, add and assume on boundary
00589                     face_on_boundary[face_nodes]=true;
00590                 }
00591                 else
00592                 {
00593                     // Face found in map, so not on boundary
00594                     it->second = false;
00595                 }
00596             }
00597         }
00598     }
00599 
00600     // Boundary nodes to be returned
00601     std::set<unsigned> boundary_of_flagged_region;
00602 
00603     // Get all faces in the map
00604     std::map<FaceNodes,bool>::iterator it=face_on_boundary.begin();
00605     while (it!=face_on_boundary.end())
00606     {
00607         // If the face maps to true it is on the boundary
00608         if (it->second==true)
00609         {
00610             // Get all nodes in the face and put in set to be returned
00611             boundary_of_flagged_region.insert(it->first.begin(),it->first.end());
00612         }
00613         it++;
00614     }
00615 
00616     return boundary_of_flagged_region;
00617 }
00618 
00619 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00620 double TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetAngleBetweenNodes(unsigned indexA, unsigned indexB)
00621 {
00622     assert(SPACE_DIM == 2);
00623     assert(SPACE_DIM == ELEMENT_DIM);
00624 
00625     double x_diff = this->mNodes[indexB]->rGetLocation()[0] - this->mNodes[indexA]->rGetLocation()[0];
00626     double y_diff = this->mNodes[indexB]->rGetLocation()[1] - this->mNodes[indexA]->rGetLocation()[1];
00627 
00628     if (x_diff==0)
00629     {
00630         if (y_diff>0)
00631         {
00632             return M_PI/2.0;
00633         }
00634         else if (y_diff<0)
00635         {
00636             return -M_PI/2.0;
00637         }
00638         else
00639         {
00640             EXCEPTION("Tried to compute polar angle of (0,0)");
00641         }
00642     }
00643 
00644     double angle = atan2(y_diff,x_diff);
00645     return angle;
00646 }
00647 
00648 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00649 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::UnflagAllElements()
00650 {
00651     for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00652          iter != this->GetElementIteratorEnd();
00653          ++iter)
00654     {
00655         iter->Unflag();
00656     }
00657 }
00658 
00659 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00660 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::FlagElementsNotContainingNodes(std::set<unsigned> nodesList)
00661 {
00662     for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00663          iter != this->GetElementIteratorEnd();
00664          ++iter)
00665     {
00666         bool found_node = false;
00667 
00668         for (unsigned i=0; i<iter->GetNumNodes(); i++)
00669         {
00670             unsigned node_index = iter->GetNodeGlobalIndex(i);
00671 
00672             std::set<unsigned>::iterator set_iter = nodesList.find(node_index);
00673             if (set_iter != nodesList.end())
00674             {
00675                 found_node = true;
00676             }
00677         }
00678 
00679         if (!found_node)
00680         {
00681             iter->Flag();
00682         }
00683     }
00684 }
00685 
00686 
00688 //                          edge iterator class                             //
00690 
00691 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00692 Node<SPACE_DIM>* TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator::GetNodeA()
00693 {
00694     assert((*this) != mrMesh.EdgesEnd());
00695     Element<ELEMENT_DIM,SPACE_DIM>* p_element = mrMesh.GetElement(mElemIndex);
00696     return p_element->GetNode(mNodeALocalIndex);
00697 }
00698 
00699 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00700 Node<SPACE_DIM>* TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator::GetNodeB()
00701 {
00702     assert((*this) != mrMesh.EdgesEnd());
00703     Element<ELEMENT_DIM,SPACE_DIM>* p_element = mrMesh.GetElement(mElemIndex);
00704     return p_element->GetNode(mNodeBLocalIndex);
00705 }
00706 
00707 
00708 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00709 bool TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator::operator!=(const TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator& rOther)
00710 {
00711     return (mElemIndex != rOther.mElemIndex ||
00712             mNodeALocalIndex != rOther.mNodeALocalIndex ||
00713             mNodeBLocalIndex != rOther.mNodeBLocalIndex);
00714 }
00715 
00716 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00717 typename TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator& TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator::operator++()
00718 {
00719     bool already_seen_this_edge;
00720 
00721     unsigned num_elements = mrMesh.GetNumAllElements();
00722     std::pair<unsigned, unsigned> current_node_pair;
00723     do
00724     {
00725         // Advance to the next edge in the mesh.
00726         // Node indices are incremented modulo #nodes_per_elem
00727         mNodeBLocalIndex = (mNodeBLocalIndex + 1) % (ELEMENT_DIM+1);
00728         if (mNodeBLocalIndex == mNodeALocalIndex)
00729         {
00730             mNodeALocalIndex = (mNodeALocalIndex + 1) % (ELEMENT_DIM+1);
00731             mNodeBLocalIndex = (mNodeALocalIndex + 1) % (ELEMENT_DIM+1);
00732         }
00733 
00734         if (mNodeALocalIndex == 0 && mNodeBLocalIndex == 1) // advance to next element...
00735         {
00736             
00737             // ...skipping deleted ones
00738             do
00739             {
00740                 mElemIndex++;
00741             }
00742             while (mElemIndex!=num_elements && mrMesh.GetElement(mElemIndex)->IsDeleted());
00743         }
00744          
00745         if (mElemIndex != num_elements)
00746         {
00747             Element<ELEMENT_DIM, SPACE_DIM>* p_element = mrMesh.GetElement(mElemIndex);
00748             unsigned node_a_global_index = p_element->GetNodeGlobalIndex(mNodeALocalIndex);
00749             unsigned node_b_global_index = p_element->GetNodeGlobalIndex(mNodeBLocalIndex);
00750             if (node_b_global_index < node_a_global_index)
00751             {
00752                 //Swap them over
00753                 unsigned temp = node_a_global_index;
00754                 node_a_global_index = node_b_global_index;
00755                 node_b_global_index = temp;
00756             }
00757 
00758             // Check we haven't seen it before
00759             current_node_pair = std::pair<unsigned, unsigned>(node_a_global_index, node_b_global_index);
00760             already_seen_this_edge = (mEdgesVisited.count(current_node_pair) != 0);
00761         }
00762         else
00763         {
00764             already_seen_this_edge = false;
00765         }
00766     }
00767     while (already_seen_this_edge);
00768     mEdgesVisited.insert(current_node_pair);
00769 
00770     return (*this);
00771 }
00772 
00773 
00774 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00775 TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator::EdgeIterator(TetrahedralMesh& rMesh, unsigned elemIndex)
00776     : mrMesh(rMesh),
00777       mElemIndex(elemIndex),
00778       mNodeALocalIndex(0),
00779       mNodeBLocalIndex(1)
00780 {
00781     if (elemIndex==mrMesh.GetNumAllElements())
00782     {
00783         return;
00784     }
00785 
00786     mEdgesVisited.clear();
00787 
00788     // add the current node pair to the store
00789 
00790     unsigned node_a_global_index = mrMesh.GetElement(mElemIndex)->GetNodeGlobalIndex(mNodeALocalIndex);
00791     unsigned node_b_global_index = mrMesh.GetElement(mElemIndex)->GetNodeGlobalIndex(mNodeBLocalIndex);
00792     if (node_b_global_index < node_a_global_index)
00793     {
00794         //Swap them over
00795         unsigned temp = node_a_global_index;
00796         node_a_global_index = node_b_global_index;
00797         node_b_global_index = temp;
00798     }
00799 
00800     // Check we haven't seen it before
00801     std::pair<unsigned, unsigned> current_node_pair=std::pair<unsigned, unsigned>(node_a_global_index, node_b_global_index);
00802 
00803     mEdgesVisited.insert(current_node_pair);
00804 }
00805 
00806 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00807 typename TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgesBegin()
00808 {
00809     unsigned first_element_index=0;
00810     while (first_element_index!=this->GetNumAllElements() && this->GetElement(first_element_index)->IsDeleted())
00811     {
00812         first_element_index++;
00813     }
00814     return EdgeIterator(*this, first_element_index);
00815 }
00816 
00817 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00818 typename TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgeIterator TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::EdgesEnd()
00819 {
00820     return EdgeIterator(*this, this->GetNumAllElements());
00821 }
00822 
00823 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00824 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::RefreshMesh()
00825 {
00826     RefreshJacobianCachedData();
00827 }
00828 
00829 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00830 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::SolveNodeMapping(unsigned index) const
00831 {
00832     assert(index < this->mNodes.size() );
00833     return index;
00834 }
00835 
00836 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00837 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::SolveElementMapping(unsigned index) const
00838 {
00839     assert(index < this->mElements.size() );
00840     return index;
00841 }
00842 
00843 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00844 unsigned TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::SolveBoundaryElementMapping(unsigned index) const
00845 {
00846     assert(index < this->mBoundaryElements.size() );
00847     return index;
00848 }
00849 
00850 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00851 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::RefreshJacobianCachedData()
00852 {
00853     unsigned num_elements = this->GetNumAllElements();
00854     unsigned num_boundary_elements = this->GetNumAllBoundaryElements();
00855 
00856     // Make sure we have enough space
00857     this->mElementJacobians.resize(num_elements);
00858     this->mElementInverseJacobians.resize(num_elements);
00859 
00860     if (ELEMENT_DIM < SPACE_DIM)
00861     {
00862         this->mElementWeightedDirections.resize(num_elements);
00863     }
00864 
00865     this->mBoundaryElementWeightedDirections.resize(num_boundary_elements);
00866 
00867     this->mElementJacobianDeterminants.resize(num_elements);
00868     this->mBoundaryElementJacobianDeterminants.resize(num_boundary_elements);
00869 
00870     // Update caches
00871     for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00872          iter != this->GetElementIteratorEnd();
00873          ++iter)
00874     {
00875         unsigned index = iter->GetIndex();
00876         iter->CalculateInverseJacobian(this->mElementJacobians[index], this->mElementJacobianDeterminants[index], this->mElementInverseJacobians[index]);
00877     }
00878 
00879     if (ELEMENT_DIM < SPACE_DIM)
00880     {
00881         for (typename AbstractTetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ElementIterator iter = this->GetElementIteratorBegin();
00882              iter != this->GetElementIteratorEnd();
00883              ++iter)
00884         {
00885              unsigned index = iter->GetIndex();
00886              iter->CalculateWeightedDirection(this->mElementWeightedDirections[index], this->mElementJacobianDeterminants[index]);
00887         }
00888     }
00889 
00890     for ( typename TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::BoundaryElementIterator itb = this->GetBoundaryElementIteratorBegin();
00891           itb != this->GetBoundaryElementIteratorEnd();
00892           itb++)
00893     {
00894         unsigned index = (*itb)->GetIndex();
00895         (*itb)->CalculateWeightedDirection(this->mBoundaryElementWeightedDirections[index], this->mBoundaryElementJacobianDeterminants[index]);
00896     }
00897 }
00898 
00899 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00900 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetJacobianForElement(unsigned elementIndex, c_matrix<double, SPACE_DIM, SPACE_DIM>& rJacobian, double& rJacobianDeterminant) const
00901 {
00902     assert(ELEMENT_DIM <= SPACE_DIM);
00903     assert(elementIndex < this->mElementJacobians.size());
00904     rJacobian = this->mElementJacobians[elementIndex];
00905     rJacobianDeterminant = this->mElementJacobianDeterminants[elementIndex];
00906 }
00907 
00908 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00909 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetInverseJacobianForElement(unsigned elementIndex, c_matrix<double, SPACE_DIM, ELEMENT_DIM>& rJacobian, double& rJacobianDeterminant, c_matrix<double, ELEMENT_DIM, SPACE_DIM>& rInverseJacobian) const
00910 {
00911     assert(ELEMENT_DIM <= SPACE_DIM);
00912     assert(elementIndex < this->mElementInverseJacobians.size());
00913     rInverseJacobian = this->mElementInverseJacobians[elementIndex];
00914     rJacobian = this->mElementJacobians[elementIndex];
00915     rJacobianDeterminant = this->mElementJacobianDeterminants[elementIndex];
00916 }
00917 
00918 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00919 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetWeightedDirectionForElement(unsigned elementIndex, c_vector<double, SPACE_DIM>& rWeightedDirection, double& rJacobianDeterminant) const
00920 {
00921     assert(ELEMENT_DIM < SPACE_DIM);
00922     assert(elementIndex < this->mElementWeightedDirections.size());
00923     rWeightedDirection = this->mElementWeightedDirections[elementIndex];
00924     rJacobianDeterminant = this->mElementJacobianDeterminants[elementIndex];
00925 }
00926 
00927 template<unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00928 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::GetWeightedDirectionForBoundaryElement(unsigned elementIndex, c_vector<double, SPACE_DIM>& rWeightedDirection, double& rJacobianDeterminant) const
00929 {
00930     assert(elementIndex < this->mBoundaryElementWeightedDirections.size());
00931     rWeightedDirection = this->mBoundaryElementWeightedDirections[elementIndex];
00932     rJacobianDeterminant = this->mBoundaryElementJacobianDeterminants[elementIndex];
00933 }
00934 
00935 
00936 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00937 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::InitialiseTriangulateIo(triangulateio& mesherIo)
00938 {
00939         mesherIo.numberofpoints = 0;
00940         mesherIo.pointlist = NULL;
00941         mesherIo.numberofpointattributes = 0;
00942         mesherIo.pointattributelist = (double *) NULL;
00943         mesherIo.pointmarkerlist = (int *) NULL;
00944         mesherIo.numberofsegments = 0;
00945         mesherIo.numberofholes = 0;
00946         mesherIo.numberofregions = 0;
00947         mesherIo.trianglelist = (int *) NULL;
00948         mesherIo.triangleattributelist = (double *) NULL;
00949         mesherIo.numberoftriangleattributes = 0;
00950         mesherIo.edgelist = (int *) NULL;
00951         mesherIo.edgemarkerlist = (int *) NULL;
00952 }
00953 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00954 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::FreeTriangulateIo(triangulateio& mesherIo)
00955 {
00956     if (mesherIo.numberofpoints != 0)
00957     {
00958         mesherIo.numberofpoints=0;
00959         free(mesherIo.pointlist);
00960     }
00961             
00962     //These (and the above) should actually be safe since we explicity set to NULL above
00963     free(mesherIo.pointattributelist);
00964     free(mesherIo.pointmarkerlist);
00965     free(mesherIo.trianglelist);
00966     free(mesherIo.triangleattributelist);
00967     free(mesherIo.edgelist);
00968     free(mesherIo.edgemarkerlist);
00969 }    
00970 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
00971 template <class MESHER_IO>
00972 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ExportToMesher(NodeMap& map, MESHER_IO& mesherInput, int *elementList)
00973 {
00974     if (SPACE_DIM == 2)
00975     {
00976         mesherInput.pointlist = (double *) malloc(this->GetNumNodes() * SPACE_DIM * sizeof(double));
00977     }
00978     else
00979     {
00980         mesherInput.pointlist =  new double[this->GetNumNodes() * SPACE_DIM];
00981     }
00982 
00983     mesherInput.numberofpoints = this->GetNumNodes();
00984     unsigned new_index = 0;
00985     for (unsigned i=0; i<this->GetNumAllNodes(); i++)
00986     {
00987         if (this->mNodes[i]->IsDeleted())
00988         {
00989             map.SetDeleted(i);
00990         }
00991         else
00992         {
00993             map.SetNewIndex(i, new_index);
00994             for (unsigned j=0; j<SPACE_DIM; j++)
00995             {
00996                 mesherInput.pointlist[SPACE_DIM*new_index + j] = this->mNodes[i]->rGetLocation()[j];
00997             }
00998             new_index++;
00999         }
01000     }
01001     if(elementList != NULL)
01002     {
01003         unsigned element_index=0u;
01004         //Assume there is enough space for this
01005         mesherInput.numberofcorners=ELEMENT_DIM+1;
01006         for (typename TetrahedralMesh<ELEMENT_DIM,SPACE_DIM>::ElementIterator elem_iter = this->GetElementIteratorBegin();
01007              elem_iter != this->GetElementIteratorEnd();
01008              ++elem_iter)
01009         {         
01010             
01011             for (unsigned j=0; j<=ELEMENT_DIM; j++)
01012             {
01013                 elementList[element_index*(ELEMENT_DIM+1) + j] = (*elem_iter).GetNodeGlobalIndex(j);
01014                 //PRINT_3_VARIABLES((*elem_iter).GetNodeGlobalIndex(j), element_index*(ELEMENT_DIM+1) + j, elementList[element_index*(ELEMENT_DIM+1) + j]);
01015             }
01016             element_index++;
01017         }
01018     }        
01019 }
01020 
01021 template <unsigned ELEMENT_DIM, unsigned SPACE_DIM>
01022 template <class MESHER_IO>
01023 void TetrahedralMesh<ELEMENT_DIM, SPACE_DIM>::ImportFromMesher(MESHER_IO& mesherOutput, unsigned numberOfElements, int *elementList, unsigned numberOfFaces, int *faceList, int *edgeMarkerList)
01024 {
01025     unsigned nodes_per_element = mesherOutput.numberofcorners;
01026     
01027     assert( nodes_per_element == ELEMENT_DIM+1 || nodes_per_element == (ELEMENT_DIM+1)*(ELEMENT_DIM+2)/2 );
01028 
01029     Clear();
01030     // Construct the nodes
01031     for (unsigned node_index=0; node_index<(unsigned)mesherOutput.numberofpoints; node_index++)
01032     {
01033         this->mNodes.push_back(new Node<SPACE_DIM>(node_index, &mesherOutput.pointlist[node_index * SPACE_DIM], false));
01034     }
01035 
01036     // Construct the elements
01037     this->mElements.reserve(numberOfElements);
01038 
01039     unsigned real_element_index=0;
01040     for (unsigned element_index=0; element_index<numberOfElements; element_index++)
01041     {
01042         std::vector<Node<SPACE_DIM>*> nodes;
01043         for (unsigned j=0; j<ELEMENT_DIM+1; j++)
01044         {
01045             unsigned global_node_index = elementList[element_index*(nodes_per_element) + j];
01046             assert(global_node_index < this->mNodes.size());
01047             nodes.push_back(this->mNodes[global_node_index]);
01048             
01049         }
01050         //For some reason, tetgen in library mode makes its initial Delauney with
01051         //very thin slivers.  Hence we expect to ignore some of the elements!
01052         Element<ELEMENT_DIM, SPACE_DIM>* p_element;
01053         try
01054         {
01055             p_element = new Element<ELEMENT_DIM, SPACE_DIM>(real_element_index, nodes);
01056             //Shouldn't throw after this point
01057             this->mElements.push_back(p_element);
01058             
01059             //Add the internals to quadratics
01060             for (unsigned j=ELEMENT_DIM+1; j<nodes_per_element; j++)
01061             {
01062                 unsigned global_node_index = elementList[element_index*nodes_per_element + j];
01063                 assert(global_node_index < this->mNodes.size());
01064                 this->mElements[real_element_index]->AddNode( this->mNodes[global_node_index] );
01065                 this->mNodes[global_node_index]->AddElement(real_element_index);
01066                 this->mNodes[global_node_index]->MarkAsInternal();
01067             }
01068             real_element_index++;
01069         }
01070         catch (Exception &e)
01071         {
01072             //Tetgen is feeding us lies
01073             assert(SPACE_DIM == 3);
01074             
01075             // #1670: To run large MeshBased Simulations comment out the line above
01076             // To find out the error message uncomment this:
01077             //std::cout<<e.GetMessage() << std::endl;
01078         }
01079     }
01080 
01081     // Construct the BoundaryElements (and mark boundary nodes)
01082     unsigned next_boundary_element_index = 0;
01083     for (unsigned boundary_element_index=0; boundary_element_index<numberOfFaces; boundary_element_index++)
01084     {
01085         //Tetgen produces only boundary faces (set edgeMarkerList to NULL)
01086         //Triangle marks which edges are on the boundary
01087         if (edgeMarkerList == NULL || edgeMarkerList[boundary_element_index] == 1)
01088         {
01089             std::vector<Node<SPACE_DIM>*> nodes;
01090             for (unsigned j=0; j<ELEMENT_DIM; j++)
01091             {
01092                 unsigned global_node_index = faceList[boundary_element_index*ELEMENT_DIM + j];
01093                 assert(global_node_index < this->mNodes.size());
01094                 nodes.push_back(this->mNodes[global_node_index]);
01095                 if (!nodes[j]->IsBoundaryNode())
01096                 {
01097                     nodes[j]->SetAsBoundaryNode();
01098                     this->mBoundaryNodes.push_back(nodes[j]);
01099                 }
01100             }
01101             //For some reason, tetgen in library mode makes its initial Delauney with
01102             //very thin slivers.  Hence we expect to ignore some of the faces!
01103             BoundaryElement<ELEMENT_DIM-1, SPACE_DIM>* p_b_element;
01104             try
01105             {
01106                 p_b_element = new BoundaryElement<ELEMENT_DIM-1, SPACE_DIM>(next_boundary_element_index, nodes);
01107                 this->mBoundaryElements.push_back(p_b_element);
01108                 next_boundary_element_index++;
01109             }
01110             catch (Exception &e)
01111             {
01112                 //Tetgen is feeding us lies  //Watch this space for coverage
01113                 assert(SPACE_DIM == 3);
01114             }
01115         }
01116     }
01117     
01118     this->RefreshJacobianCachedData();    
01119 }
01120 
01121 
01122 
01124 // Explicit instantiation
01126 
01127 template class TetrahedralMesh<1,1>;
01128 template class TetrahedralMesh<1,2>;
01129 template class TetrahedralMesh<1,3>;
01130 template class TetrahedralMesh<2,2>;
01131 template class TetrahedralMesh<2,3>;
01132 template class TetrahedralMesh<3,3>;
01133 
01138 template void TetrahedralMesh<2,2>::ExportToMesher<triangulateio>(NodeMap&, triangulateio&, int*);
01139 template void TetrahedralMesh<2,2>::ImportFromMesher<triangulateio>(triangulateio&, unsigned, int *, unsigned, int *, int *);
01140 
01141 template void TetrahedralMesh<3,3>::ExportToMesher<tetgen::tetgenio>(NodeMap&, tetgen::tetgenio&, int*);
01142 template void TetrahedralMesh<3,3>::ImportFromMesher<tetgen::tetgenio>(tetgen::tetgenio&, unsigned, int *, unsigned, int *, int *);
01143 
01144 //The following don't ever need to be instantiated, but are needed to keep some compilers happy
01145 template void TetrahedralMesh<1,2>::ExportToMesher<triangulateio>(NodeMap&, triangulateio&, int*);
01146 template void TetrahedralMesh<1,2>::ImportFromMesher<triangulateio>(triangulateio&, unsigned, int *, unsigned, int *, int *);
01147 
01148 template void TetrahedralMesh<1,3>::ExportToMesher<tetgen::tetgenio>(NodeMap&, tetgen::tetgenio&, int*);
01149 template void TetrahedralMesh<1,3>::ImportFromMesher<tetgen::tetgenio>(tetgen::tetgenio&, unsigned, int *, unsigned, int *, int *);
01150 template void TetrahedralMesh<2,3>::ExportToMesher<tetgen::tetgenio>(NodeMap&, tetgen::tetgenio&, int*);
01151 template void TetrahedralMesh<2,3>::ImportFromMesher<tetgen::tetgenio>(tetgen::tetgenio&, unsigned, int *, unsigned, int *, int *);
01152 
01153 
01154 //Intel compilation with IPO thinks that it's missing some bizarre instantiations
01155 template void TetrahedralMesh<3u, 3u>::ImportFromMesher<triangulateio>(triangulateio&, unsigned int, int*, unsigned int, int*, int*);
01156 template void TetrahedralMesh<1u, 1u>::ImportFromMesher<triangulateio>(triangulateio&, unsigned int, int*, unsigned int, int*, int*);
01157 template void TetrahedralMesh<1u, 1u>::ImportFromMesher<tetgen::tetgenio>(tetgen::tetgenio&, unsigned int, int*, unsigned int, int*, int*);
01158 template void TetrahedralMesh<2u, 2u>::ImportFromMesher<tetgen::tetgenio>(tetgen::tetgenio&, unsigned int, int*, unsigned int, int*, int*);
01159 template void TetrahedralMesh<1u, 1u>::ExportToMesher<tetgen::tetgenio>(NodeMap&, tetgen::tetgenio&, int*);
01160 
01161 // Intel v11 compilation thinks that it's missing even more bizarre instantiations
01162 //template void TetrahedralMesh<2,2>::ExportToMesher<tetgen::tetgenio>(NodeMap&, tetgen::tetgenio&, int*);
01163 //template void TetrahedralMesh<3,3>::ExportToMesher<triangulateio>(NodeMap&, triangulateio&, int*);
01164 //template void TetrahedralMesh<1,3>::ExportToMesher<triangulateio>(NodeMap&, triangulateio&, int*);
01165 //template void TetrahedralMesh<1,1>::ExportToMesher<triangulateio>(NodeMap&, triangulateio&, int*);
01166 //template void TetrahedralMesh<1,2>::ExportToMesher<tetgen::tetgenio>(NodeMap&, tetgen::tetgenio&, int*);
01167 //template void TetrahedralMesh<2,3>::ExportToMesher<triangulateio>(NodeMap&, triangulateio&, int*);
01168 //template void TetrahedralMesh<1,3>::ImportFromMesher<triangulateio>(triangulateio&, unsigned, int *, unsigned, int *, int *);
01169 //template void TetrahedralMesh<2,3>::ImportFromMesher<triangulateio>(triangulateio&, unsigned, int *, unsigned, int *, int *);
01170 //template void TetrahedralMesh<1,2>::ImportFromMesher<tetgen::tetgenio>(tetgen::tetgenio&, unsigned, int *, unsigned, int *, int *);
01176 // Serialization for Boost >= 1.36
01177 #define CHASTE_SERIALIZATION_CPP
01178 #include "SerializationExportWrapper.hpp"
01179 EXPORT_TEMPLATE_CLASS_ALL_DIMS(TetrahedralMesh)
Generated on Tue May 31 14:31:48 2011 for Chaste by  doxygen 1.5.5