Tetrahedron.cc 8.61 KB
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#include "Tetrahedron.h"
#include "DOFAdmin.h"
#include "Mesh.h"
#include "CoarseningManager.h"
#include "FixVec.h"
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#include "ElementDofIterator.h"
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namespace AMDiS {

  const unsigned char Tetrahedron::nChildEdge[3][2][2] = {{{5,4},{4,5}},
							  {{5,4},{5,4}},
							  {{5,4},{5,4}}};
  const unsigned char Tetrahedron::nChildFace[3][2][2] = {{{1,2},{2,1}},
							  {{1,2},{1,2}},
							  {{1,2},{1,2}}};
  const int Tetrahedron::childVertex[3][2][4] = {{{0,2,3,4},{1,3,2,4}},
						 {{0,2,3,4},{1,2,3,4}},
						 {{0,2,3,4},{1,2,3,4}}};
  const int Tetrahedron::childEdge[3][2][6] = {{{1,2,0,5,5,4},{4,3,0,5,5,4}},
					       {{1,2,0,5,4,5},{3,4,0,5,4,5}},
					       {{1,2,0,5,4,5},{3,4,0,5,4,5}}};
  const unsigned char Tetrahedron::adjacentChild[2][2] = {{0,1}, {1,0}};

  const signed char Tetrahedron::childOrientation[3][2] = {{1,1}, 
							   {1,-1}, 
							   {1,-1}};

  const unsigned char Tetrahedron::edgeOfDOFs[4][4] =  {{255,0,1,2},
							{0,255,3,4},
							{1,3,255,5},
							{2,4,5,255}};

  const int Tetrahedron::vertexOfEdge[6][2] = {{0,1},
					       {0,2},
					       {0,3},
					       {1,2},
					       {1,3},
					       {2,3}};
  const int Tetrahedron::vertexOfFace[4][3] = {{1,2,3},
					       {0,2,3},
					       {0,1,3},
					       {0,1,2}};


  const int Tetrahedron::sideOfChild[3][2][4] = {{{-1, 3, 1, 2},  // type 0
						  {3, -1, 2, 1}},
						 {{-1, 3, 1, 2},  // type 1
						  {3, -1, 1, 2}},
						 {{-1, 3, 1, 2},  // type 2
						  {3, -1, 1, 2}}};

  const int Tetrahedron::vertexOfParent[3][2][4] = {{{0, 2, 3, -1},  // type 0
						     {1, 3, 2, -1}},
						    {{0, 2, 3, -1},  // type 1
						     {1, 2, 3, -1}},
						    {{0, 2, 3, -1},  // type 2
						     {1, 2, 3, -1}}};

  const int Tetrahedron::edgeOfFace[4][3] = {{5, 4, 3},  // face 0
					     {5, 2, 1},  // face 1
					     {4, 2, 0},  // face 2
					     {3, 1, 0}}; // face 3

  bool Tetrahedron::hasSide(Element* sideElem) const
  {
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    FUNCNAME("Tetrahedron::hasSide()");
    TEST_EXIT_DBG(sideElem->isTriangle())("called for sideElem-type != Triangle\n");
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    ERROR_EXIT("not yet\n");
    return false;
  }

  int Tetrahedron::getVertexOfPosition(GeoIndex position,
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				       int positionIndex,
				       int vertexIndex) const 
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  {
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    FUNCNAME("Triangle::getVertexOfPosition()");
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    switch(position) {
    case VERTEX:
      return positionIndex;
      break;
    case EDGE:
      return vertexOfEdge[positionIndex][vertexIndex];
      break;
    case FACE:
      return vertexOfFace[positionIndex][vertexIndex];
      break;
    case CENTER:
      return vertexIndex;
      break;
    default:
      ERROR_EXIT("invalid position\n");
      return 0;
    }
  }

  const FixVec<int, WORLD>&
  Tetrahedron::sortFaceIndices(int face, FixVec<int,WORLD> *vec) const
  {
    static MatrixOfFixVecs<FixVec<int,WORLD> > *sorted_3d = NULL;
    FixVec<int,WORLD> *val = NULL;
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    const int *vof = vertexOfFace[face];
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    if (NULL == sorted_3d) {
      sorted_3d = new MatrixOfFixVecs<FixVec<int,WORLD> >(3, 4, 7, NO_INIT);
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      (*sorted_3d)[0][0][0]=(*sorted_3d)[0][0][1]=
	(*sorted_3d)[0][0][2]=(*sorted_3d)[1][0][0]=
	(*sorted_3d)[1][0][1]=(*sorted_3d)[1][0][2]=
	(*sorted_3d)[1][1][0]=(*sorted_3d)[1][2][1]=
	(*sorted_3d)[1][3][0]=(*sorted_3d)[1][4][2]=
	(*sorted_3d)[1][5][1]=(*sorted_3d)[1][6][2]=
	(*sorted_3d)[2][0][0]=(*sorted_3d)[2][0][1]=
	(*sorted_3d)[2][0][2]=(*sorted_3d)[2][1][0]=
	(*sorted_3d)[2][2][1]=(*sorted_3d)[2][3][0]=
	(*sorted_3d)[2][4][2]=(*sorted_3d)[2][5][1]=
	(*sorted_3d)[2][6][2]=(*sorted_3d)[3][0][0]=
	(*sorted_3d)[3][0][1]=(*sorted_3d)[3][0][2]=
	(*sorted_3d)[3][1][0]=(*sorted_3d)[3][2][1]=
	(*sorted_3d)[3][3][0]=(*sorted_3d)[3][4][2]=
	(*sorted_3d)[3][5][1]=(*sorted_3d)[3][6][2]=0;

      (*sorted_3d)[0][1][0]=(*sorted_3d)[0][2][1]=
	(*sorted_3d)[0][3][0]=(*sorted_3d)[0][4][2]=
	(*sorted_3d)[0][5][1]=(*sorted_3d)[0][6][2]=
	(*sorted_3d)[2][1][2]=(*sorted_3d)[2][2][0]=
	(*sorted_3d)[2][3][1]=(*sorted_3d)[2][4][1]=
	(*sorted_3d)[2][5][2]=(*sorted_3d)[2][6][0]=
	(*sorted_3d)[3][1][2]=(*sorted_3d)[3][2][0]=
	(*sorted_3d)[3][3][1]=(*sorted_3d)[3][4][1]=
	(*sorted_3d)[3][5][2]=(*sorted_3d)[3][6][0]=1;

      (*sorted_3d)[0][1][2]=(*sorted_3d)[0][2][0]=
	(*sorted_3d)[0][3][1]=(*sorted_3d)[0][4][1]=
	(*sorted_3d)[0][5][2]=(*sorted_3d)[0][6][0]=
	(*sorted_3d)[1][1][2]=(*sorted_3d)[1][2][0]=
	(*sorted_3d)[1][3][1]=(*sorted_3d)[1][4][1]=
	(*sorted_3d)[1][5][2]=(*sorted_3d)[1][6][0]=
	(*sorted_3d)[3][1][1]=(*sorted_3d)[3][2][2]=
	(*sorted_3d)[3][3][2]=(*sorted_3d)[3][4][0]=
	(*sorted_3d)[3][5][0]=(*sorted_3d)[3][6][1]=2;

      (*sorted_3d)[0][1][1]=(*sorted_3d)[0][2][2]=
	(*sorted_3d)[0][3][2]=(*sorted_3d)[0][4][0]=
	(*sorted_3d)[0][5][0]=(*sorted_3d)[0][6][1]=
	(*sorted_3d)[1][1][1]=(*sorted_3d)[1][2][2]=
	(*sorted_3d)[1][3][2]=(*sorted_3d)[1][4][0]=
	(*sorted_3d)[1][5][0]=(*sorted_3d)[1][6][1]=
	(*sorted_3d)[2][1][1]=(*sorted_3d)[2][2][2]=
	(*sorted_3d)[2][3][2]=(*sorted_3d)[2][4][0]=
	(*sorted_3d)[2][5][0]=(*sorted_3d)[2][6][1]=3;
    }

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    int no = 0;
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    if (dof[vof[0]][0] < dof[vof[1]][0])
      no++;
    if (dof[vof[1]][0] < dof[vof[2]][0])
      no += 2;
    if (dof[vof[2]][0] < dof[vof[0]][0])
      no += 4;

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    if (!(no >= 1  &&  no <= 6))
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      ERROR_EXIT("can not sort face indices of element %d at face %d\n", 
		 getIndex(), face);

    if (vec) {
      val = vec;
      *val = (*sorted_3d)[face][no];
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    } else {
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      val = &((*sorted_3d)[face][no]);
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    }
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    return(*(const_cast<const FixVec<int,WORLD>* >(val)));
  }

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  void Tetrahedron::getVertexDofs(FiniteElemSpace* feSpace, 
				  int ith, int elType,
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				  DofContainer& dofs, 
				  bool reverseMode,
				  bool parentVertices) const
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  {
    FUNCNAME("Tetrahedron::getVertexDofs()");
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    bool p = false;
//     if (MPI::COMM_WORLD.Get_rank() == 0)
//       p = true;

    if (p)
      MSG("GET-VD: idx=%d ith=%d type=%d\n", this->getIndex(), ith, elType);

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    if (parentVertices) {
      switch (ith) {
      case 0:
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	dofs.push_back(dof[1]); dofs.push_back(dof[2]); dofs.push_back(dof[3]);
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	break;
      case 1:
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	dofs.push_back(dof[0]); dofs.push_back(dof[2]); dofs.push_back(dof[3]);
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	break;
      case 2:
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	dofs.push_back(dof[0]); dofs.push_back(dof[1]); dofs.push_back(dof[3]);
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	break;
      case 3:
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	dofs.push_back(dof[0]); dofs.push_back(dof[1]); dofs.push_back(dof[2]);
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	break;
      default:
	ERROR_EXIT("Should never happen!\n");
      }
    }

    switch (ith) {
    case 0:
      {
	if (sideOfChild[elType][0][ith] != -1) {
	  std::cout << "ERROR 1 WITH elType = " << elType << "!\n";
	  exit(0);
	}

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	if (child[1]) 
	  child[1]->getVertexDofs(feSpace, 
				  sideOfChild[elType][1][ith], 
				  (elType + 1) % 3,
				  dofs, 
				  reverseMode);
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      }
      break;
    case 1:
      {
	if (sideOfChild[elType][1][ith] != -1) {
	  std::cout << "ERROR 2 WITH elType = " << elType << "!\n";
	  exit(0);
	}

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	if (child[0]) 
	  child[0]->getVertexDofs(feSpace, 
				  sideOfChild[elType][0][ith], 
				  (elType + 1) % 3,
				  dofs,
				  reverseMode);
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      }
      break;

    case 2:
    case 3:
      {
	if (child[0]) {
	  int c1 = sideOfChild[elType][0][ith];
	  int c2 = sideOfChild[elType][1][ith];

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	  if (p)
	    MSG("GO TO CHILD WITH SIDE %d %d\n", c1, c2);

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	  if (c1 == -1 || c2 == -1) {
	    std::cout << "ERROR 3 WITH elType = " << elType << std::endl;
	    exit(0);
	  }

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	  if (reverseMode) {
	    child[1]->getVertexDofs(feSpace, c2, (elType + 1) % 3, dofs, false);
	    dofs.push_back(child[0]->getDOF(3));
	    child[0]->getVertexDofs(feSpace, c1, (elType + 1) % 3, dofs, false);
	  } else {
	    child[0]->getVertexDofs(feSpace, c1, (elType + 1) % 3, dofs, false);
	    dofs.push_back(child[0]->getDOF(3));
	    child[1]->getVertexDofs(feSpace, c2, (elType + 1) % 3, dofs, false);
	  }
	} else {
	  if (p)
	    MSG("NO CHILD\n");
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	}
      }
      break;
    default:
      ERROR_EXIT("Should never happen!\n");
    }
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  }

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  void Tetrahedron::getNonVertexDofs(FiniteElemSpace* feSpace,
				     int ith, int elType,
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				     DofContainer& dofs) const
  {
    FUNCNAME("Tetrahedron::getNonVertexDofs()");
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    if (child[0]) {
      int childFace0 = sideOfChild[elType][0][ith];
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      int childFace1 = sideOfChild[elType][1][ith];
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      TEST_EXIT(childFace0 != -1 || childFace1 != -1)
	("No new face for child elements!\n");

      if (childFace0 != -1) 
	child[0]->getNonVertexDofs(feSpace, childFace0, (elType + 1) % 3, dofs);

      if (childFace1 != -1) 
	child[1]->getNonVertexDofs(feSpace, childFace1, (elType + 1) % 3, dofs);
    } else { 
      ElementDofIterator elDofIter(feSpace, true);
      elDofIter.reset(this);
      do {
	if (elDofIter.getCurrentPos() == 2 && 
	    elDofIter.getCurrentElementPos() == ith)
	  dofs.push_back(elDofIter.getDofPtr());		
      } while(elDofIter.next());      
    }
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  }

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}