Exemple #1
0
MeshPtr MeshTools::timeSliceMesh(MeshPtr spaceTimeMesh, double t,
                                 map<GlobalIndexType, GlobalIndexType> &sliceCellIDToSpaceTimeCellID, int H1OrderForSlice) {
  MeshTopologyPtr meshTopo = spaceTimeMesh->getTopology();
  set<IndexType> cellIDsToCheck = meshTopo->getRootCellIndices();
  set<IndexType> activeCellIDsForTime;
  
  set<IndexType> allActiveCellIDs = meshTopo->getActiveCellIndices();
  
  int spaceDim = meshTopo->getSpaceDim() - 1;  // # of true spatial dimensions
  
  MeshTopologyPtr sliceTopo = Teuchos::rcp( new MeshTopology(spaceDim) );
  set<IndexType> rootCellIDs = meshTopo->getRootCellIndices();
  for (set<IndexType>::iterator rootCellIt = rootCellIDs.begin(); rootCellIt != rootCellIDs.end(); rootCellIt++) {
    IndexType rootCellID = *rootCellIt;
    FieldContainer<double> physicalNodes = spaceTimeMesh->physicalCellNodesForCell(rootCellID);
    if (cellMatches(physicalNodes, t)) { // cell and some subset of its descendents should be included in slice mesh
      vector< vector< double > > sliceNodes = timeSliceForCell(physicalNodes, t);
      CellTopoPtrLegacy cellTopo = getBottomTopology(meshTopo, rootCellID);
      CellPtr sliceCell = sliceTopo->addCell(cellTopo, sliceNodes);
      sliceCellIDToSpaceTimeCellID[sliceCell->cellIndex()] = rootCellID;
    }
  }
  
  MeshPtr sliceMesh = Teuchos::rcp( new Mesh(sliceTopo, spaceTimeMesh->bilinearForm(), H1OrderForSlice, spaceDim) );
  
  // process refinements.  For now, we assume isotropic refinements, which means that each refinement in spacetime induces a refinement in the spatial slice
  set<IndexType> sliceCellIDsToCheckForRefinement = sliceTopo->getActiveCellIndices();
  while (sliceCellIDsToCheckForRefinement.size() > 0) {
    set<IndexType>::iterator cellIt = sliceCellIDsToCheckForRefinement.begin();
    IndexType sliceCellID = *cellIt;
    sliceCellIDsToCheckForRefinement.erase(cellIt);
    
    CellPtr sliceCell = sliceTopo->getCell(sliceCellID);
    CellPtr spaceTimeCell = meshTopo->getCell(sliceCellIDToSpaceTimeCellID[sliceCellID]);
    if (spaceTimeCell->isParent()) {
      set<GlobalIndexType> cellsToRefine;
      cellsToRefine.insert(sliceCellID);
      sliceMesh->hRefine(cellsToRefine, RefinementPattern::regularRefinementPattern(sliceCell->topology()->getKey()));
      vector<IndexType> spaceTimeChildren = spaceTimeCell->getChildIndices();
      for (int childOrdinal=0; childOrdinal<spaceTimeChildren.size(); childOrdinal++) {
        IndexType childID = spaceTimeChildren[childOrdinal];
        FieldContainer<double> childNodes = meshTopo->physicalCellNodesForCell(childID);
        if (cellMatches(childNodes, t)) {
          vector< vector<double> > childSlice = timeSliceForCell(childNodes, t);
          CellPtr childSliceCell = sliceTopo->findCellWithVertices(childSlice);
          sliceCellIDToSpaceTimeCellID[childSliceCell->cellIndex()] = childID;
          sliceCellIDsToCheckForRefinement.insert(childSliceCell->cellIndex());
        }
      }
    }
  }
  
  return sliceMesh;
}
Exemple #2
0
MeshPtr MeshTools::timeSliceMesh(MeshPtr spaceTimeMesh, double t,
                                 map<GlobalIndexType, GlobalIndexType> &sliceCellIDToSpaceTimeCellID, int H1OrderForSlice)
{
  MeshTopology* meshTopo = dynamic_cast<MeshTopology*>(spaceTimeMesh->getTopology().get());
  TEUCHOS_TEST_FOR_EXCEPTION(!meshTopo, std::invalid_argument, "timeSliceMesh() called with spaceTimeMesh that appears to be pure MeshTopologyView.  This is not supported.");
  set<IndexType> cellIDsToCheck = meshTopo->getRootCellIndices();
  set<IndexType> activeCellIDsForTime;

  set<IndexType> allActiveCellIDs = meshTopo->getActiveCellIndices();

  int spaceDim = meshTopo->getDimension() - 1;  // # of true spatial dimensions

  MeshTopologyPtr sliceTopo = Teuchos::rcp( new MeshTopology(spaceDim) );
  set<IndexType> rootCellIDs = meshTopo->getRootCellIndices();
  for (set<IndexType>::iterator rootCellIt = rootCellIDs.begin(); rootCellIt != rootCellIDs.end(); rootCellIt++)
  {
    IndexType rootCellID = *rootCellIt;
    FieldContainer<double> physicalNodes = spaceTimeMesh->physicalCellNodesForCell(rootCellID);
    if (cellMatches(physicalNodes, t))   // cell and some subset of its descendents should be included in slice mesh
    {
      vector< vector< double > > sliceNodes = timeSliceForCell(physicalNodes, t);
      CellTopoPtr cellTopo = getBottomTopology(meshTopo, rootCellID);
      GlobalIndexType newCellID = sliceTopo->cellCount();
      CellPtr sliceCell = sliceTopo->addCell(newCellID, cellTopo, sliceNodes); // for consistency, this is only valid if run on every MPI rank.
      sliceCellIDToSpaceTimeCellID[sliceCell->cellIndex()] = rootCellID;
    }
  }

  MeshPtr sliceMesh = Teuchos::rcp( new Mesh(sliceTopo, spaceTimeMesh->bilinearForm(), H1OrderForSlice, spaceDim) );

  // process refinements.  For now, we assume isotropic refinements, which means that each refinement in spacetime induces a refinement in the spatial slice
  set<IndexType> sliceCellIDsToCheckForRefinement = sliceTopo->getActiveCellIndices();
  while (sliceCellIDsToCheckForRefinement.size() > 0)
  {
    set<IndexType>::iterator cellIt = sliceCellIDsToCheckForRefinement.begin();
    IndexType sliceCellID = *cellIt;
    sliceCellIDsToCheckForRefinement.erase(cellIt);

    CellPtr sliceCell = sliceTopo->getCell(sliceCellID);
    CellPtr spaceTimeCell = meshTopo->getCell(sliceCellIDToSpaceTimeCellID[sliceCellID]);
    if (spaceTimeCell->isParent(spaceTimeMesh->getTopology()))
    {
      set<GlobalIndexType> cellsToRefine;
      cellsToRefine.insert(sliceCellID);
      sliceMesh->hRefine(cellsToRefine, RefinementPattern::regularRefinementPattern(sliceCell->topology()));
      vector<IndexType> spaceTimeChildren = spaceTimeCell->getChildIndices(spaceTimeMesh->getTopology());
      for (int childOrdinal=0; childOrdinal<spaceTimeChildren.size(); childOrdinal++)
      {
        IndexType childID = spaceTimeChildren[childOrdinal];
        FieldContainer<double> childNodes = meshTopo->physicalCellNodesForCell(childID);
        if (cellMatches(childNodes, t))
        {
          vector< vector<double> > childSlice = timeSliceForCell(childNodes, t);
          CellPtr childSliceCell = sliceTopo->findCellWithVertices(childSlice);
          sliceCellIDToSpaceTimeCellID[childSliceCell->cellIndex()] = childID;
          sliceCellIDsToCheckForRefinement.insert(childSliceCell->cellIndex());
        }
      }
    }
  }

  MeshPartitionPolicyPtr partitionPolicy = MeshPartitionPolicy::inducedPartitionPolicy(sliceMesh, spaceTimeMesh, sliceCellIDToSpaceTimeCellID);

  sliceMesh->setPartitionPolicy(partitionPolicy);

  return sliceMesh;
}
bool MeshTestUtility::determineRefTestPointsForNeighbors(MeshTopologyViewPtr meshTopo, CellPtr fineCell, unsigned int sideOrdinal,
    FieldContainer<double> &fineSideRefPoints, FieldContainer<double> &fineCellRefPoints,
    FieldContainer<double> &coarseSideRefPoints, FieldContainer<double> &coarseCellRefPoints)
{
  unsigned spaceDim = meshTopo->getDimension();
  unsigned sideDim = spaceDim - 1;

  if (spaceDim == 1)
  {
    fineSideRefPoints.resize(0,0);
    coarseSideRefPoints.resize(0,0);
    fineCellRefPoints.resize(1,1);
    coarseCellRefPoints.resize(1,1);

    FieldContainer<double> lineRefNodes(2,1);
    CellTopoPtr line = CellTopology::line();

    CamelliaCellTools::refCellNodesForTopology(lineRefNodes, line);

    fineCellRefPoints[0] = lineRefNodes[sideOrdinal];
    unsigned neighborSideOrdinal = fineCell->getNeighborInfo(sideOrdinal, meshTopo).second;
    if (neighborSideOrdinal != -1)
    {
      coarseCellRefPoints[0] = lineRefNodes[neighborSideOrdinal];
      return true;
    }
    else
    {
      return false;
    }
  }
  pair<GlobalIndexType, unsigned> neighborInfo = fineCell->getNeighborInfo(sideOrdinal, meshTopo);
  if (neighborInfo.first == -1)
  {
    // boundary
    return false;
  }
  CellPtr neighborCell = meshTopo->getCell(neighborInfo.first);
  if (neighborCell->isParent(meshTopo))
  {
    return false; // fineCell isn't the finer of the two...
  }

  CellTopoPtr fineSideTopo = fineCell->topology()->getSubcell(sideDim, sideOrdinal);

  CubatureFactory cubFactory;
  int cubDegree = 4; // fairly arbitrary choice: enough to get a decent number of test points...
  Teuchos::RCP<Cubature<double> > fineSideTopoCub = cubFactory.create(fineSideTopo, cubDegree);

  int numCubPoints = fineSideTopoCub->getNumPoints();

  FieldContainer<double> cubPoints(numCubPoints, sideDim);
  FieldContainer<double> cubWeights(numCubPoints); // we neglect these...

  fineSideTopoCub->getCubature(cubPoints, cubWeights);

  FieldContainer<double> sideRefCellNodes(fineSideTopo->getNodeCount(),sideDim);
  CamelliaCellTools::refCellNodesForTopology(sideRefCellNodes, fineSideTopo);

  int numTestPoints = numCubPoints + fineSideTopo->getNodeCount();

  FieldContainer<double> testPoints(numTestPoints, sideDim);
  for (int ptOrdinal=0; ptOrdinal<testPoints.dimension(0); ptOrdinal++)
  {
    if (ptOrdinal<fineSideTopo->getNodeCount())
    {
      for (int d=0; d<sideDim; d++)
      {
        testPoints(ptOrdinal,d) = sideRefCellNodes(ptOrdinal,d);
      }
    }
    else
    {
      for (int d=0; d<sideDim; d++)
      {
        testPoints(ptOrdinal,d) = cubPoints(ptOrdinal-fineSideTopo->getNodeCount(),d);
      }
    }
  }

  fineSideRefPoints = testPoints;
  fineCellRefPoints.resize(numTestPoints, spaceDim);

  CamelliaCellTools::mapToReferenceSubcell(fineCellRefPoints, testPoints, sideDim, sideOrdinal, fineCell->topology());

  CellTopoPtr coarseSideTopo = neighborCell->topology()->getSubcell(sideDim, neighborInfo.second);

  unsigned fineSideAncestorPermutation = fineCell->ancestralPermutationForSubcell(sideDim, sideOrdinal, meshTopo);
  unsigned coarseSidePermutation = neighborCell->subcellPermutation(sideDim, neighborInfo.second);

  unsigned coarseSideAncestorPermutationInverse = CamelliaCellTools::permutationInverse(coarseSideTopo, coarseSidePermutation);

  unsigned composedPermutation = CamelliaCellTools::permutationComposition(coarseSideTopo, coarseSideAncestorPermutationInverse, fineSideAncestorPermutation); // goes from coarse ordering to fine.

  RefinementBranch fineRefBranch = fineCell->refinementBranchForSide(sideOrdinal, meshTopo);

  FieldContainer<double> fineSideNodes(fineSideTopo->getNodeCount(), sideDim);  // relative to the ancestral cell whose neighbor is compatible
  if (fineRefBranch.size() == 0)
  {
    CamelliaCellTools::refCellNodesForTopology(fineSideNodes, coarseSideTopo, composedPermutation);
  }
  else
  {
    FieldContainer<double> ancestralSideNodes(coarseSideTopo->getNodeCount(), sideDim);
    CamelliaCellTools::refCellNodesForTopology(ancestralSideNodes, coarseSideTopo, composedPermutation);

    RefinementBranch fineSideRefBranch = RefinementPattern::sideRefinementBranch(fineRefBranch, sideOrdinal);
    fineSideNodes = RefinementPattern::descendantNodes(fineSideRefBranch, ancestralSideNodes);
  }

  BasisCachePtr sideTopoCache = Teuchos::rcp( new BasisCache(fineSideTopo, 1, false) );
  sideTopoCache->setRefCellPoints(testPoints);

  // add cell dimension
  fineSideNodes.resize(1,fineSideNodes.dimension(0), fineSideNodes.dimension(1));
  sideTopoCache->setPhysicalCellNodes(fineSideNodes, vector<GlobalIndexType>(), false);
  coarseSideRefPoints = sideTopoCache->getPhysicalCubaturePoints();

  // strip off the cell dimension:
  coarseSideRefPoints.resize(coarseSideRefPoints.dimension(1),coarseSideRefPoints.dimension(2));

  coarseCellRefPoints.resize(numTestPoints,spaceDim);
  CamelliaCellTools::mapToReferenceSubcell(coarseCellRefPoints, coarseSideRefPoints, sideDim, neighborInfo.second, neighborCell->topology());

  return true; // containers filled....
}