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Start debugging 3D interpolation error on OCTA12 in target mesh
authorageay <ageay>
Fri, 2 Aug 2013 13:12:19 +0000 (13:12 +0000)
committerageay <ageay>
Fri, 2 Aug 2013 13:12:19 +0000 (13:12 +0000)
src/INTERP_KERNEL/CMakeLists.txt
src/INTERP_KERNEL/Polyhedron3D2DIntersectorP0P0.txx
src/INTERP_KERNEL/SplitterTetra.cxx [new file with mode: 0644]
src/INTERP_KERNEL/SplitterTetra.hxx
src/INTERP_KERNEL/SplitterTetra.txx

index 0c29d1e3b872d49fa38b2e4d5996a56cb47fcf72..7d2e4a4223ecd1ce10ce2b32beb618cb0ffd29ba 100644 (file)
@@ -38,6 +38,7 @@ SET(interpkernel_SOURCES
   InterpKernelCellSimplify.cxx
   InterpKernelMatrixTools.cxx
   VolSurfUser.cxx
+  SplitterTetra.cxx
   Bases/InterpKernelException.cxx
   Geometric2D/InterpKernelGeo2DAbstractEdge.cxx
   Geometric2D/InterpKernelGeo2DBounds.cxx
index ce3d1a10c4494f8d0a3e49b2b6cdf45726c4ae8c..4c1e4fb9ef159abfd532593ddef111c6a359342c 100644 (file)
@@ -81,7 +81,6 @@ namespace INTERP_KERNEL
    * 
    * @param targetCell in C mode.
    * @param srcCells in C mode.
-   *
    */
   template<class MyMeshType, class MyMatrixType>
   void Polyhedron3D2DIntersectorP0P0<MyMeshType,MyMatrixType>::intersectCells(ConnType targetCell,
@@ -111,7 +110,7 @@ namespace INTERP_KERNEL
           {
             // we could store mapping local -> global numbers too, but not sure it is worth it
             const int globalNodeNum = getGlobalNumberOfNode(i, OTT<ConnType,numPol>::indFC(*iterCellS), src_mesh);
-            polyNodes[i]=globalNodeNum;
+            polyNodes[i] = globalNodeNum;
             polyCoords[i] = const_cast<double*>(src_mesh.getCoordinatesPtr()+MyMeshType::MY_SPACEDIM*globalNodeNum);
           }
 
@@ -125,46 +124,43 @@ namespace INTERP_KERNEL
                                                     listOfTetraFacesTreated,
                                                     listOfTetraFacesColinear);
 
-        if(surface!=0.) {
-
-          matrix[targetCell].insert(std::make_pair(cellSrcIdx, surface));
-
-          bool isSrcFaceColinearWithFaceOfTetraTargetCell = false;
-          std::set<TriangleFaceKey>::iterator iter;
-          for (iter = listOfTetraFacesColinear.begin(); iter != listOfTetraFacesColinear.end(); ++iter)
-            {
-              if (listOfTetraFacesTreated.count(*iter) != 1)
-                {
-                  isSrcFaceColinearWithFaceOfTetraTargetCell = false;
-                  break;
-                }
-              else
-                {
-                  isSrcFaceColinearWithFaceOfTetraTargetCell = true;
-                }
-            }
-
-          if (isSrcFaceColinearWithFaceOfTetraTargetCell)
-            {
-              DuplicateFacesType::iterator intersectFacesIter = _intersect_faces.find(cellSrcIdx);
-              if (intersectFacesIter != _intersect_faces.end())
-                {
-                  intersectFacesIter->second.insert(targetCell);
-                }
-              else
-                {
-                  std::set<int> targetCellSet;
-                  targetCellSet.insert(targetCell);
-                  _intersect_faces.insert(std::make_pair(cellSrcIdx, targetCellSet));
-                }
-
-            }
-
-        }
-
-        delete[] polyNodes;
-        delete[] polyCoords;
-
+        if(surface!=0.)
+          {
+            
+            matrix[targetCell].insert(std::make_pair(cellSrcIdx, surface));
+            
+            bool isSrcFaceColinearWithFaceOfTetraTargetCell = false;
+            std::set<TriangleFaceKey>::iterator iter;
+            for (iter = listOfTetraFacesColinear.begin(); iter != listOfTetraFacesColinear.end(); ++iter)
+              {
+                if (listOfTetraFacesTreated.count(*iter) != 1)
+                  {
+                    isSrcFaceColinearWithFaceOfTetraTargetCell = false;
+                    break;
+                  }
+                else
+                  {
+                    isSrcFaceColinearWithFaceOfTetraTargetCell = true;
+                  }
+              }
+            
+            if (isSrcFaceColinearWithFaceOfTetraTargetCell)
+              {
+                DuplicateFacesType::iterator intersectFacesIter = _intersect_faces.find(cellSrcIdx);
+                if (intersectFacesIter != _intersect_faces.end())
+                  {
+                    intersectFacesIter->second.insert(targetCell);
+                  }
+                else
+                  {
+                    std::set<int> targetCellSet;
+                    targetCellSet.insert(targetCell);
+                    _intersect_faces.insert(std::make_pair(cellSrcIdx, targetCellSet));
+                  }
+              }
+          }
+        delete [] polyNodes;
+        delete [] polyCoords;
       }
     _split.releaseArrays();
   }
diff --git a/src/INTERP_KERNEL/SplitterTetra.cxx b/src/INTERP_KERNEL/SplitterTetra.cxx
new file mode 100644 (file)
index 0000000..b5e4999
--- /dev/null
@@ -0,0 +1,216 @@
+// Copyright (C) 2007-2013  CEA/DEN, EDF R&D
+//
+// This library is free software; you can redistribute it and/or
+// modify it under the terms of the GNU Lesser General Public
+// License as published by the Free Software Foundation; either
+// version 2.1 of the License.
+//
+// This library is distributed in the hope that it will be useful,
+// but WITHOUT ANY WARRANTY; without even the implied warranty of
+// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+// Lesser General Public License for more details.
+//
+// You should have received a copy of the GNU Lesser General Public
+// License along with this library; if not, write to the Free Software
+// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307 USA
+//
+// See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
+//
+// Author : Anthony Geay (CEA/DEN)
+
+#include "SplitterTetra.hxx"
+
+namespace INTERP_KERNEL
+{
+
+  void SplitHexa8IntoTetras(SplittingPolicy policy, const int *nodalConnBg, const int *nodalConnEnd, const double *coords,
+                            std::vector<int>& tetrasNodalConn, std::vector<double>& addCoords) throw(INTERP_KERNEL::Exception)
+  {
+    if(std::distance(nodalConnBg,nodalConnEnd)!=8)
+      throw INTERP_KERNEL::Exception("SplitHexa8IntoTetras : input hexa do not have 8 nodes !");
+    switch(policy)
+      {
+      case PLANAR_FACE_5:
+        {
+          tetrasNodalConn.resize(20);
+          int *conn(&tetrasNodalConn[0]);
+          conn[0]=nodalConnBg[SPLIT_NODES_5_WO[0]]; conn[1]=nodalConnBg[SPLIT_NODES_5_WO[1]]; conn[2]=nodalConnBg[SPLIT_NODES_5_WO[2]]; conn[3]=nodalConnBg[SPLIT_NODES_5_WO[3]];
+          conn[4]=nodalConnBg[SPLIT_NODES_5_WO[4]]; conn[5]=nodalConnBg[SPLIT_NODES_5_WO[5]]; conn[6]=nodalConnBg[SPLIT_NODES_5_WO[6]]; conn[7]=nodalConnBg[SPLIT_NODES_5_WO[7]];
+          conn[8]=nodalConnBg[SPLIT_NODES_5_WO[8]]; conn[9]=nodalConnBg[SPLIT_NODES_5_WO[9]]; conn[10]=nodalConnBg[SPLIT_NODES_5_WO[10]]; conn[11]=nodalConnBg[SPLIT_NODES_5_WO[11]];
+          conn[12]=nodalConnBg[SPLIT_NODES_5_WO[12]]; conn[13]=nodalConnBg[SPLIT_NODES_5_WO[13]]; conn[14]=nodalConnBg[SPLIT_NODES_5_WO[14]]; conn[15]=nodalConnBg[SPLIT_NODES_5_WO[15]];
+          conn[16]=nodalConnBg[SPLIT_NODES_5_WO[16]]; conn[17]=nodalConnBg[SPLIT_NODES_5_WO[17]]; conn[18]=nodalConnBg[SPLIT_NODES_5_WO[18]]; conn[19]=nodalConnBg[SPLIT_NODES_5_WO[19]];
+          return ;
+        }
+      case PLANAR_FACE_6:
+        {
+          tetrasNodalConn.resize(24);
+          int *conn(&tetrasNodalConn[0]);
+          conn[0]=nodalConnBg[SPLIT_NODES_6_WO[0]]; conn[1]=nodalConnBg[SPLIT_NODES_6_WO[1]]; conn[2]=nodalConnBg[SPLIT_NODES_6_WO[2]]; conn[3]=nodalConnBg[SPLIT_NODES_6_WO[3]];
+          conn[4]=nodalConnBg[SPLIT_NODES_6_WO[4]]; conn[5]=nodalConnBg[SPLIT_NODES_6_WO[5]]; conn[6]=nodalConnBg[SPLIT_NODES_6_WO[6]]; conn[7]=nodalConnBg[SPLIT_NODES_6_WO[7]];
+          conn[8]=nodalConnBg[SPLIT_NODES_6_WO[8]]; conn[9]=nodalConnBg[SPLIT_NODES_6_WO[9]]; conn[10]=nodalConnBg[SPLIT_NODES_6_WO[10]]; conn[11]=nodalConnBg[SPLIT_NODES_6_WO[11]];
+          conn[12]=nodalConnBg[SPLIT_NODES_6_WO[12]]; conn[13]=nodalConnBg[SPLIT_NODES_6_WO[13]]; conn[14]=nodalConnBg[SPLIT_NODES_6_WO[14]]; conn[15]=nodalConnBg[SPLIT_NODES_6_WO[15]];
+          conn[16]=nodalConnBg[SPLIT_NODES_6_WO[16]]; conn[17]=nodalConnBg[SPLIT_NODES_6_WO[17]]; conn[18]=nodalConnBg[SPLIT_NODES_6_WO[18]]; conn[19]=nodalConnBg[SPLIT_NODES_6_WO[19]];
+          conn[20]=nodalConnBg[SPLIT_NODES_6_WO[20]]; conn[21]=nodalConnBg[SPLIT_NODES_6_WO[21]]; conn[22]=nodalConnBg[SPLIT_NODES_6_WO[22]]; conn[23]=nodalConnBg[SPLIT_NODES_6_WO[23]];
+          return ;
+        }
+      case GENERAL_24:
+        {
+          addCoords.resize(7*3);
+          tetrasNodalConn.resize(24*4);
+          int *conn(&tetrasNodalConn[0]);
+          double *tmp(&addCoords[18]);
+          tmp[0]=0.; tmp[1]=0.; tmp[2]=0.;
+          double *tmp2(&addCoords[0]);
+          for(int i=0;i<6;i++,tmp2+=3)
+            {
+              tmp2[0]=0.; tmp2[1]=0.; tmp2[2]=0.;
+              for(int j=0;j<4;j++,conn+=4)
+                {
+                  tmp2[0]+=coords[3*nodalConnBg[GENERAL_24_SUB_NODES_WO[4*i+j]]+0];
+                  tmp2[1]+=coords[3*nodalConnBg[GENERAL_24_SUB_NODES_WO[4*i+j]]+1];
+                  tmp2[2]+=coords[3*nodalConnBg[GENERAL_24_SUB_NODES_WO[4*i+j]]+3];
+                  conn[0]=nodalConnBg[GENERAL_24_SUB_NODES_WO[4*i+j]];
+                  conn[1]=nodalConnBg[GENERAL_24_SUB_NODES_WO[4*i+(j+1)%4]];
+                  conn[2]=-(i+1); conn[3]=-7;
+                }
+              tmp2[0]/=4.; tmp2[1]/=4.; tmp2[2]/=4.;
+              tmp[0]+=tmp2[0]; tmp[1]+=tmp2[1]; tmp[2]+=tmp2[2];
+            }
+          tmp[0]/=6.; tmp[1]/=6.; tmp[2]/=6.;
+          return ;
+        }
+      case GENERAL_48:
+        {
+          addCoords.resize(19*3);
+          tetrasNodalConn.resize(48*4);
+          double *tmp2(&addCoords[0]),*tmp(&addCoords[0]);
+          for(int i=0;i<12;i++,tmp2+=3)
+            {
+              tmp2[0]=(coords[3*nodalConnBg[GENERAL_48_SUB_NODES[2*i]]+0]+coords[3*nodalConnBg[GENERAL_48_SUB_NODES[2*i+1]]+0])/2.;
+              tmp2[1]=(coords[3*nodalConnBg[GENERAL_48_SUB_NODES[2*i]]+1]+coords[3*nodalConnBg[GENERAL_48_SUB_NODES[2*i+1]]+1])/2.;
+              tmp2[2]=(coords[3*nodalConnBg[GENERAL_48_SUB_NODES[2*i]]+2]+coords[3*nodalConnBg[GENERAL_48_SUB_NODES[2*i+1]]+2])/2.;
+            }
+          for(int i=0;i<7;i++,tmp2+=3)
+            {
+              tmp2[0]=(tmp[3*nodalConnBg[(GENERAL_48_SUB_NODES[2*i+24]-8)]+0]+tmp[3*nodalConnBg[(GENERAL_48_SUB_NODES[2*i+25]-8)]+0])/2.;
+              tmp2[1]=(tmp[3*nodalConnBg[(GENERAL_48_SUB_NODES[2*i+24]-8)]+1]+tmp[3*nodalConnBg[(GENERAL_48_SUB_NODES[2*i+25]-8)]+1])/2.;
+              tmp2[2]=(tmp[3*nodalConnBg[(GENERAL_48_SUB_NODES[2*i+24]-8)]+2]+tmp[3*nodalConnBg[(GENERAL_48_SUB_NODES[2*i+25]-8)]+2])/2.;
+            }
+          int *conn(&tetrasNodalConn[0]);
+          std::vector<double> dummy;
+          for(int i=0;i<8;i++)
+            {
+              std::vector<int> c;
+              SplitHexa8IntoTetras(PLANAR_FACE_6,GENERAL_48_SUBZONES_2+i*8,GENERAL_48_SUBZONES_2+(i+1)*8,coords,c,dummy);
+              int *conn2(&c[0]);
+              for(int j=0;j<6;j++,conn+=4,conn2+=4)
+                {
+                  conn[0]=conn2[0]>=0?nodalConnBg[conn2[0]]:conn2[0];
+                  conn[1]=conn2[1]>=0?nodalConnBg[conn2[1]]:conn2[1];
+                  conn[2]=conn2[2]>=0?nodalConnBg[conn2[2]]:conn2[2];
+                  conn[3]=conn2[3]>=0?nodalConnBg[conn2[3]]:conn2[3];
+                }
+            }
+          return ;
+        }
+      default:
+        throw INTERP_KERNEL::Exception("SplitHexa8IntoTetras : invalid input policy ! Should be in [PLANAR_FACE_5,PLANAR_FACE_6,GENERAL_24,GENERAL_48] !");
+      }
+  }
+
+  void SplitIntoTetras(SplittingPolicy policy, NormalizedCellType gt, const int *nodalConnBg, const int *nodalConnEnd, const double *coords,
+                       std::vector<int>& tetrasNodalConn, std::vector<double>& addCoords) throw(INTERP_KERNEL::Exception)
+  {
+    switch(gt)
+      {
+      case NORM_TETRA4:
+        {
+          std::size_t sz(std::distance(nodalConnBg,nodalConnEnd));
+          if(sz!=4)
+            throw INTERP_KERNEL::Exception("SplitIntoTetras : input tetra do not have 4 nodes !");
+          tetrasNodalConn.insert(tetrasNodalConn.end(),nodalConnBg,nodalConnEnd);
+          return ;
+        }
+      case NORM_HEXA8:
+        {
+          SplitHexa8IntoTetras(policy,nodalConnBg,nodalConnEnd,coords,tetrasNodalConn,addCoords);
+          return ;
+        }
+      case NORM_PYRA5:
+        {
+          std::size_t sz(std::distance(nodalConnBg,nodalConnEnd));
+          if(sz!=5)
+            throw INTERP_KERNEL::Exception("SplitIntoTetras : input pyra5 do not have 5 nodes !");
+          tetrasNodalConn.resize(8);
+          int *conn(&tetrasNodalConn[0]);
+          conn[0]=nodalConnBg[0]; conn[1]=nodalConnBg[1]; conn[2]=nodalConnBg[2]; conn[3]=nodalConnBg[4];
+          conn[4]=nodalConnBg[0]; conn[5]=nodalConnBg[2]; conn[6]=nodalConnBg[3]; conn[7]=nodalConnBg[4];
+          return ;
+        }
+      case NORM_PENTA6:
+        {
+          std::size_t sz(std::distance(nodalConnBg,nodalConnEnd));
+          if(sz!=6)
+            throw INTERP_KERNEL::Exception("SplitIntoTetras : input penta6 do not have 6 nodes !");
+          tetrasNodalConn.resize(12);
+          int *conn(&tetrasNodalConn[0]);
+          conn[0]=nodalConnBg[0]; conn[1]=nodalConnBg[1]; conn[2]=nodalConnBg[2]; conn[3]=nodalConnBg[3];
+          conn[4]=nodalConnBg[3]; conn[5]=nodalConnBg[5]; conn[6]=nodalConnBg[4]; conn[7]=nodalConnBg[2];
+          conn[8]=nodalConnBg[4]; conn[9]=nodalConnBg[2]; conn[10]=nodalConnBg[1]; conn[11]=nodalConnBg[3];
+          return ;
+        }
+      case NORM_HEXGP12:
+        {
+          std::size_t sz(std::distance(nodalConnBg,nodalConnEnd));
+          if(sz!=12)
+            throw INTERP_KERNEL::Exception("SplitIntoTetras : input octa12 (hexagone prism) do not have 12 nodes !");
+          tetrasNodalConn.resize(48);
+          int *conn(&tetrasNodalConn[0]);
+          conn[0]=nodalConnBg[0]; conn[1]=nodalConnBg[1]; conn[2]=nodalConnBg[5]; conn[3]=nodalConnBg[6];
+          conn[4]=nodalConnBg[6]; conn[5]=nodalConnBg[11]; conn[6]=nodalConnBg[7]; conn[7]=nodalConnBg[5];
+          conn[8]=nodalConnBg[7]; conn[9]=nodalConnBg[5]; conn[10]=nodalConnBg[1]; conn[11]=nodalConnBg[6];
+          //
+          conn[12]=nodalConnBg[1]; conn[13]=nodalConnBg[4]; conn[14]=nodalConnBg[5]; conn[15]=nodalConnBg[7];
+          conn[16]=nodalConnBg[7]; conn[17]=nodalConnBg[11]; conn[18]=nodalConnBg[10]; conn[19]=nodalConnBg[5];
+          conn[20]=nodalConnBg[10]; conn[21]=nodalConnBg[5]; conn[22]=nodalConnBg[4]; conn[23]=nodalConnBg[7];
+          //
+          conn[24]=nodalConnBg[1]; conn[25]=nodalConnBg[2]; conn[26]=nodalConnBg[4]; conn[27]=nodalConnBg[7];
+          conn[28]=nodalConnBg[7]; conn[29]=nodalConnBg[10]; conn[30]=nodalConnBg[8]; conn[31]=nodalConnBg[4];
+          conn[32]=nodalConnBg[8]; conn[33]=nodalConnBg[4]; conn[34]=nodalConnBg[2]; conn[35]=nodalConnBg[7];
+          //
+          conn[36]=nodalConnBg[2]; conn[37]=nodalConnBg[3]; conn[38]=nodalConnBg[4]; conn[39]=nodalConnBg[8];
+          conn[40]=nodalConnBg[8]; conn[41]=nodalConnBg[10]; conn[42]=nodalConnBg[9]; conn[43]=nodalConnBg[4];
+          conn[44]=nodalConnBg[9]; conn[45]=nodalConnBg[4]; conn[46]=nodalConnBg[3]; conn[47]=nodalConnBg[8];
+          return ;
+        }
+      case NORM_POLYHED:
+        {
+          std::size_t nbOfFaces(std::count(nodalConnBg,nodalConnEnd,-1)+1);
+          std::size_t nbOfTetra(std::distance(nodalConnBg,nodalConnEnd)-nbOfFaces+1);
+          addCoords.resize((nbOfFaces+1)*3);
+          tetrasNodalConn.resize(nbOfTetra*4);
+          int *conn(&tetrasNodalConn[0]);
+          const int *work(nodalConnBg);
+          double *tmp(&addCoords[0]),*tmp2(&addCoords[3*nbOfFaces]);
+          tmp2[0]=0.; tmp2[1]=0.; tmp2[2]=0.;
+          for(std::size_t i=0;i<nbOfFaces;i++,tmp+=3)
+            {
+              tmp[0]=0.; tmp[1]=0.; tmp[2]=0.;
+              std::size_t nbOfNodesOfFace(std::distance(work,std::find(work,nodalConnEnd,-1)));
+              for(std::size_t j=0;j<nbOfNodesOfFace;j++,conn+=4)
+                {
+                  conn[0]=work[j]; conn[1]=work[(j+1)%nbOfNodesOfFace]; conn[2]=-((int)i+1); conn[3]=-((int)nbOfFaces+1);
+                  tmp[0]+=coords[3*work[j]+0]; tmp[1]+=coords[3*work[j]+1]; tmp[2]+=coords[3*work[j]+2];
+                }
+              tmp[0]/=(int)nbOfNodesOfFace; tmp[1]/=(int)nbOfNodesOfFace; tmp[2]/=(int)nbOfNodesOfFace;
+              tmp2[0]+=tmp[0]; tmp2[1]+=tmp[1]; tmp2[2]+=tmp[2];
+              work+=nbOfNodesOfFace+1;
+            }
+          tmp2[0]/=(int)nbOfFaces; tmp2[1]/=(int)nbOfFaces; tmp2[2]/=(int)nbOfFaces;
+          return ;
+        }
+      default:
+        throw INTERP_KERNEL::Exception("SplitIntoTetras : not managed such Geometric type ! Available geometric types are all 3D linear cells !");
+      }
+  }
+}
index 1c8b1e4b9d583507fdc45f618db0ee70a3c84fe7..9bf2cffb5f07078e1589007cc16dd083946f3362 100644 (file)
@@ -23,6 +23,7 @@
 #include "TransformedTriangle.hxx"
 #include "TetraAffineTransform.hxx"
 #include "InterpolationOptions.hxx"
+#include "InterpKernelException.hxx"
 #include "InterpKernelHashMap.hxx"
 #include "VectorUtils.hxx"
 
@@ -98,6 +99,17 @@ namespace INTERP_KERNEL
       2,3,6,7,// sub-node 13 (face)
       8,9,10,11// sub-node 14 (cell)
     };
+
+  static const int GENERAL_24_SUB_NODES_WO[28] = 
+    {
+      0,4,5,1,// sub-node 8  (face)
+      0,1,2,3,// sub-node 9  (face)
+      0,3,7,4,// sub-node 10 (face)
+      1,5,6,2,// sub-node 11 (face)
+      4,7,6,5,// sub-node 12 (face)
+      2,6,7,3,// sub-node 13 (face)
+      8,9,10,11// sub-node 14 (cell)
+    };
   
   static const int TETRA_EDGES_GENERAL_24[48] = 
     {
@@ -133,6 +145,65 @@ namespace INTERP_KERNEL
       3,2
     };
   
+  // Each sub-node is the barycenter of two other nodes.
+  // For the edges, these lie on the original mesh.
+  // For the faces, these are the edge sub-nodes.
+  // For the cell these are two face sub-nodes.
+  static const int GENERAL_48_SUB_NODES[38] = 
+    {
+      0,1,   // sub-node 8 (edge)
+      0,4,   // sub-node 9 (edge)
+      1,5,   // sub-node 10 (edge)
+      4,5,   // sub-node 11 (edge)
+      0,3,   // sub-node 12 (edge)
+      1,2,   // sub-node 13 (edge)
+      4,7,   // sub-node 14 (edge)
+      5,6,   // sub-node 15 (edge)
+      2,3,   // sub-node 16 (edge)
+      3,7,   // sub-node 17 (edge)
+      2,6,   // sub-node 18 (edge)
+      6,7,   // sub-node 19 (edge)
+      8,11,  // sub-node 20 (face)
+      12,13, // sub-node 21 (face)
+      9,17,  // sub-node 22 (face)
+      10,18, // sub-node 23 (face)
+      14,15, // sub-node 24 (face)
+      16,19, // sub-node 25 (face)
+      20,25  // sub-node 26 (cell)
+    };
+
+  // Define 8 hexahedral subzones as in Grandy, p449
+  // the values correspond to the nodes that correspond to nodes 1,2,3,4,5,6,7,8 in the subcell
+  // For the correspondance of the nodes, see the GENERAL_48_SUB_NODES table in calculateSubNodes
+  static const int GENERAL_48_SUBZONES[64] = 
+    {
+      0,8,21,12,9,20,26,22,
+      8,1,13,21,20,10,23,26,
+      12,21,16,3,22,26,25,17,
+      21,13,2,16,26,23,18,25,
+      9,20,26,22,4,11,24,14,
+      20,10,23,26,11,5,15,24,
+      22,26,25,17,14,24,19,7,
+      26,23,18,25,24,15,6,19
+    };
+
+  static const int GENERAL_48_SUBZONES_2[64] = 
+    {
+      0,-1,-14,-5,-2,-13,-19,-15,
+      -1,1,-6,-14,-13,-3,-16,-19,
+      -5,-14,-9,3,-15,-19,-18,-10,
+      -14,-6,2,-9,-19,-16,-11,-18,
+      -2,-13,-19,-15,4,-4,-17,-7,
+      -13,-3,-16,-19,-4,5,-8,-17,
+      -15,-19,-18,-10,-7,-17,-12,7,
+      -19,-16,-11,-18,-17,-8,6,-12};
+
+  void SplitHexa8IntoTetras(SplittingPolicy policy, const int *nodalConnBg, const int *nodalConnEnd, const double *coords,
+                            std::vector<int>& tetrasNodalConn, std::vector<double>& addCoords) throw(INTERP_KERNEL::Exception);
+  
+  void SplitIntoTetras(SplittingPolicy policy, NormalizedCellType gt, const int *nodalConnBg, const int *nodalConnEnd, const double *coords,
+                       std::vector<int>& tetrasNodalConn, std::vector<double>& addCoords) throw(INTERP_KERNEL::Exception);
+  
   /**
    * \brief Class representing a triangular face, used as key in caching hash map in SplitterTetra.
    *
@@ -280,7 +351,6 @@ namespace INTERP_KERNEL
 
 namespace INTERP_KERNEL
 {
-
   /** 
    * \brief Class calculating the volume of intersection between a tetrahedral target element and
    * source elements with triangular or quadratilateral faces.
index 9312b5fa6eb8d31dfc81259d5e712d3eab7825d2..38aab3c233bce06edbf49a475325afa7f9460575 100644 (file)
@@ -557,7 +557,6 @@ namespace INTERP_KERNEL
    * @param polyNodesNbr number of the nodes of the polygon source face
    * @param polyNodes numbers of the nodes of the polygon source face
    * @param polyCoords coordinates of the nodes of the polygon source face
-   * @param polyCoords coordinates of the nodes of the polygon source face
    * @param dimCaracteristic characteristic size of the meshes containing the triangles
    * @param precision precision for double float data used for comparison
    * @param listOfTetraFacesTreated list of tetra faces treated
@@ -1085,25 +1084,10 @@ namespace INTERP_KERNEL
    */
   template<class MyMeshTypeT, class MyMeshTypeS>
   void SplitterTetra2<MyMeshTypeT, MyMeshTypeS>::calculateGeneral48Tetra(typename std::vector< SplitterTetra<MyMeshTypeS>* >& tetra)
-  {
-    // Define 8 hexahedral subzones as in Grandy, p449
-    // the values correspond to the nodes that correspond to nodes 1,2,3,4,5,6,7,8 in the subcell
-    // For the correspondance of the nodes, see the GENERAL_48_SUB_NODES table in calculateSubNodes
-    static const int subZones[64] = 
-      {
-        0,8,21,12,9,20,26,22,
-        8,1,13,21,20,10,23,26,
-        12,21,16,3,22,26,25,17,
-        21,13,2,16,26,23,18,25,
-        9,20,26,22,4,11,24,14,
-        20,10,23,26,11,5,15,24,
-        22,26,25,17,14,24,19,7,
-        26,23,18,25,24,15,6,19
-      };
-    
+  { 
     for(int i = 0; i < 8; ++i)
       {
-        sixSplit(&subZones[8*i],tetra);
+        sixSplit(GENERAL_48_SUBZONES+8*i,tetra);
       }
   }
   
@@ -1238,33 +1222,6 @@ namespace INTERP_KERNEL
 
           case GENERAL_48:
             {
-              // Each sub-node is the barycenter of two other nodes.
-              // For the edges, these lie on the original mesh.
-              // For the faces, these are the edge sub-nodes.
-              // For the cell these are two face sub-nodes.
-              static const int GENERAL_48_SUB_NODES[38] = 
-                {
-                  0,1,   // sub-node 9 (edge)
-                  0,4,   // sub-node 10 (edge)
-                  1,5,   // sub-node 11 (edge)
-                  4,5,   // sub-node 12 (edge)
-                  0,3,   // sub-node 13 (edge)
-                  1,2,   // sub-node 14 (edge)
-                  4,7,   // sub-node 15 (edge)
-                  5,6,   // sub-node 16 (edge)
-                  2,3,   // sub-node 17 (edge)
-                  3,7,   // sub-node 18 (edge)
-                  2,6,   // sub-node 19 (edge)
-                  6,7,   // sub-node 20 (edge)
-                  8,11,  // sub-node 21 (face)
-                  12,13, // sub-node 22 (face)
-                  9,17,  // sub-node 23 (face)
-                  10,18, // sub-node 24 (face)
-                  14,15, // sub-node 25 (face)
-                  16,19, // sub-node 26 (face)
-                  20,25  // sub-node 27 (cell)
-                };
-
               for(int i = 0; i < 19; ++i)
                 {
                   double* barycenter = new double[3];