Beispiel #1
0
PetscErrorCode DMView_Cartesian_Ascii(const ALE::Obj<ALE::CartesianMesh>& mesh, PetscViewer viewer)
{
    PetscViewerFormat format;
    PetscErrorCode    ierr;

    PetscFunctionBegin;
    ierr = PetscViewerGetFormat(viewer, &format);
    CHKERRQ(ierr);
    if (format == PETSC_VIEWER_ASCII_VTK) {
#if 0
        ierr = VTKViewer::writeHeader(viewer);
        CHKERRQ(ierr);
        ierr = VTKViewer::writeVertices(mesh, viewer);
        CHKERRQ(ierr);
        ierr = VTKViewer::writeElements(mesh, viewer);
        CHKERRQ(ierr);
#endif
    } else {
        int dim = mesh->getDimension();

        ierr = PetscViewerASCIIPrintf(viewer, "Mesh in %d dimensions:\n", dim);
        CHKERRQ(ierr);
        /* FIX: Need to globalize */
        ierr = PetscViewerASCIIPrintf(viewer, "  %d vertices\n", mesh->getSieve()->getNumVertices());
        CHKERRQ(ierr);
        ierr = PetscViewerASCIIPrintf(viewer, "  %d cells\n",    mesh->getSieve()->getNumCells());
        CHKERRQ(ierr);
    }
    ierr = PetscViewerFlush(viewer);
    CHKERRQ(ierr);
    PetscFunctionReturn(0);
}
Beispiel #2
0
PetscErrorCode OutputVTK(ALE::Obj<ALE::Mesh> mesh, Options *options, std::string outname)
{
  PetscViewer    viewer;
  PetscErrorCode ierr;

  PetscFunctionBegin;
  if (options->outputVTK) {
    ALE::LogStage stage = ALE::LogStageRegister("VTKOutput");
    ALE::LogStagePush(stage);
    ierr = PetscPrintf(mesh->comm(), "Creating VTK mesh files\n");CHKERRQ(ierr);
    ierr = PetscViewerCreate(mesh->comm(), &viewer);CHKERRQ(ierr);
    ierr = PetscViewerSetType(viewer, PETSC_VIEWER_ASCII);CHKERRQ(ierr);
    ierr = PetscViewerSetFormat(viewer, PETSC_VIEWER_ASCII_VTK);CHKERRQ(ierr);
    ierr = PetscViewerFileSetName(viewer, outname.c_str());CHKERRQ(ierr);
    ierr = VTKViewer::writeHeader(viewer);CHKERRQ(ierr);
    ierr = VTKViewer::writeVertices(mesh, viewer);
    ierr = VTKViewer::writeElements(mesh, viewer);
//    ierr = VTKViewer::writeHierarchyVertices(mesh, viewer, options->zScale);CHKERRQ(ierr);
//    ierr = VTKViewer::writeHierarchyElements(mesh, viewer);CHKERRQ(ierr);
    ierr = PetscViewerDestroy(viewer);CHKERRQ(ierr);
    //const ALE::Mesh::topology_type::sheaf_type& patches = mesh->getTopology()->getPatches();
    ALE::LogStagePop(stage);
  }
  PetscFunctionReturn(0);
}
Beispiel #3
0
PetscErrorCode DMCoarsen_Cartesian(DM mesh, MPI_Comm comm, DM *coarseMesh)
{
    ALE::Obj<ALE::CartesianMesh> oldMesh;
    PetscErrorCode               ierr;

    PetscFunctionBegin;
    if (comm == MPI_COMM_NULL) comm = ((PetscObject)mesh)->comm;
    ierr = DMCartesianGetMesh(mesh, oldMesh);
    CHKERRQ(ierr);
    ierr = DMCartesianCreate(comm, coarseMesh);
    CHKERRQ(ierr);
#if 0
    ALE::Obj<ALE::Mesh> newMesh = ALE::Generator::refineMesh(oldMesh, refinementLimit, false);
    ierr = MeshCartesianSetMesh(*coarseMesh, newMesh);
    CHKERRQ(ierr);
    const ALE::Obj<ALE::CartesianMesh::real_section_type>& s = newMesh->getRealSection("default");

    newMesh->setDiscretization(oldMesh->getDiscretization());
    newMesh->setBoundaryCondition(oldMesh->getBoundaryCondition());
    newMesh->setupField(s);
#else
    SETERRQ(PETSC_COMM_SELF,PETSC_ERR_SUP, "Not yet implemented");
#endif
    PetscFunctionReturn(0);
}
Beispiel #4
0
PetscErrorCode DMMeshConvertOverlapToSF(DM dm, PetscSF *sf)
{
    ALE::Obj<PETSC_MESH_TYPE> mesh;
    PetscInt                  *local;
    PetscSFNode               *remote;
    PetscInt                  numPoints;
    PetscErrorCode            ierr;

    PetscFunctionBegin;
    ierr = PetscSFCreate(((PetscObject) dm)->comm, sf);
    CHKERRQ(ierr);
    ierr = DMMeshGetMesh(dm, mesh);
    CHKERRQ(ierr);
    {
        /* The local points have degree 1
             We use the recv overlap
        */
        ALE::Obj<PETSC_MESH_TYPE::recv_overlap_type> overlap = mesh->getRecvOverlap();

        numPoints = overlap->getNumPoints();
        ierr      = PetscMalloc(numPoints * sizeof(PetscInt), &local);
        CHKERRQ(ierr);
        ierr      = PetscMalloc(numPoints * sizeof(PetscSFNode), &remote);
        CHKERRQ(ierr);
        for (PetscInt r = 0, i = 0; r < overlap->getNumRanks(); ++r) {
            const PetscInt                                                      rank   = overlap->getRank(r);
            const PETSC_MESH_TYPE::recv_overlap_type::supportSequence::iterator cBegin = overlap->supportBegin(rank);
            const PETSC_MESH_TYPE::recv_overlap_type::supportSequence::iterator cEnd   = overlap->supportEnd(rank);

            for (PETSC_MESH_TYPE::recv_overlap_type::supportSequence::iterator c_iter = cBegin; c_iter != cEnd; ++c_iter, ++i) {
                local[i]        = *c_iter;
                remote[i].rank  = rank;
                remote[i].index = c_iter.color();
            }
        }
        ierr = PetscSFSetGraph(*sf, numPoints, numPoints, local, PETSC_OWN_POINTER, remote, PETSC_OWN_POINTER);
        CHKERRQ(ierr);
        ierr = PetscSFView(*sf, NULL);
        CHKERRQ(ierr);
    }
    PetscFunctionReturn(0);
}
Beispiel #5
0
PetscErrorCode DMCartesianGetSectionReal(DM dm, const char name[], SectionReal *section)
{
    ALE::Obj<ALE::CartesianMesh> m;
    PetscErrorCode      ierr;

    PetscFunctionBegin;
    ierr = DMCartesianGetMesh(dm, m);
    CHKERRQ(ierr);
    ierr = SectionRealCreate(m->comm(), section);
    CHKERRQ(ierr);
    ierr = PetscObjectSetName((PetscObject) *section, name);
    CHKERRQ(ierr);
#if 0
    ierr = SectionRealSetSection(*section, m->getRealSection(std::string(name)));
    CHKERRQ(ierr);
    ierr = SectionRealSetBundle(*section, m);
    CHKERRQ(ierr);
#endif
    PetscFunctionReturn(0);
}
Beispiel #6
0
void viewConesAndSupports(const ALE::Obj<BiGraphInt3>& bg, const char *name)
{

  // View the cones for all base points
  std::cout << name << " cones:" << std::endl;
  BiGraphInt3::traits::baseSequence base = bg->base();
  for (BiGraphInt3::traits::baseSequence::traits::iterator i = base.begin(); i != base.end(); i++) {
    BiGraphInt3::traits::coneSequence cone = bg->cone(*i);
    std::cout << *i << ": ";
    cone.view(std::cout, true);
  }

  // View the supports for all cap points
  std::cout << name << " supports:" << std::endl;
  BiGraphInt3::traits::capSequence cap = bg->cap();
  for (BiGraphInt3::traits::capSequence::traits::iterator i = cap.begin(); i != cap.end(); i++) {
    BiGraphInt3::traits::supportSequence supp = bg->support(*i);
    std::cout << *i << ": ";
    supp.view(std::cout, true);
  }
} /* viewConesAndSupports() */
Beispiel #7
0
PetscErrorCode CreateSieve(MPI_Comm comm, int debug)
{
  PetscErrorCode ierr;

  PetscFunctionBegin;
  ALE::Obj<sieve_type> sieve = sieve_type(comm, debug);
  ierr = PetscPrintf(comm, "Creating a 'Hat' Sieve of global size %d: 3 base nodes and 1 cap node per process\n",
                     3*sieve->commSize()+1);CHKERRQ(ierr);
  for (int i = 0; i < 3; i++) {
    sieve_type::point_type p(sieve->commRank(), 0), b(-1,2*sieve->commRank()+i);
    sieve->addArrow(p,b);
  }
  sieve->view(std::cout, "Hat");
  PetscFunctionReturn(0);
}
Beispiel #8
0
PetscErrorCode PETSCDM_DLLEXPORT MeshRefineSingularity_Fichera(ALE::Obj<ALE::Mesh> mesh, MPI_Comm comm, double * singularity, double factor, ALE::Obj<ALE::Mesh> * refinedMesh, PetscTruth interpolate = PETSC_FALSE)
{
  ALE::Obj<ALE::Mesh> oldMesh = mesh;
  double              oldLimit;
  PetscErrorCode      ierr;

  PetscFunctionBegin;
  //ierr = MeshGetMesh(mesh, oldMesh);CHKERRQ(ierr);
  //ierr = MeshCreate(comm, refinedMesh);CHKERRQ(ierr);
  int dim = oldMesh->getDimension();
  oldLimit = oldMesh->getMaxVolume();
  //double oldLimInv = 1./oldLimit;
  double curLimit, tmpLimit;
  double minLimit = oldLimit/16384.;             //arbitrary;
  const ALE::Obj<ALE::Mesh::real_section_type>& coordinates = oldMesh->getRealSection("coordinates");
  const ALE::Obj<ALE::Mesh::real_section_type>& volume_limits = oldMesh->getRealSection("volume_limits");
  volume_limits->setFiberDimension(oldMesh->heightStratum(0), 1);
  oldMesh->allocate(volume_limits);
  const ALE::Obj<ALE::Mesh::label_sequence>& cells = oldMesh->heightStratum(0);
  ALE::Mesh::label_sequence::iterator c_iter = cells->begin();
  ALE::Mesh::label_sequence::iterator c_iter_end = cells->end();
  double centerCoords[dim];
  while (c_iter != c_iter_end) {
    const double * coords = oldMesh->restrictClosure(coordinates, *c_iter);
    for (int i = 0; i < dim; i++) {
      centerCoords[i] = 0;
      for (int j = 0; j < dim+1; j++) {
        centerCoords[i] += coords[j*dim+i];
      }
      centerCoords[i] = centerCoords[i]/(dim+1);
      //PetscPrintf(oldMesh->comm(), "%f, ", centerCoords[i]);
    }
    //PetscPrintf(oldMesh->comm(), "\n");
    double dist = 0.;
    double cornerdist = 0.;
    //HERE'S THE DIFFERENCE: if centercoords is less than the singularity coordinate for each direction, include that direction in the distance
    /*
    for (int i = 0; i < dim; i++) {
      if (centerCoords[i] <= singularity[i]) {
        dist += (centerCoords[i] - singularity[i])*(centerCoords[i] - singularity[i]);
      }
    }
    */
    //determine: the per-dimension distance: cases
    if (dim > 2) {
      for (int i = 0; i < dim; i++) {
	cornerdist = 0.;
	if (centerCoords[i] > singularity[i]) {
	  for (int j = 0; j < dim; j++) {
	    if (j != i) cornerdist += (centerCoords[j] - singularity[j])*(centerCoords[j] - singularity[j]);
	  }
	  if (cornerdist < dist || dist == 0.) dist = cornerdist; 
	}
      }
    }
    //patch up AROUND the corner by minimizing between the distance from the relevant axis and the singular vertex
    double singdist = 0.;
    for (int i = 0; i < dim; i++) {
      singdist += (centerCoords[i] - singularity[i])*(centerCoords[i] - singularity[i]);
    }
    if (singdist < dist || dist == 0.) dist = singdist;
    if (dist > 0.) {
      dist = sqrt(dist);
      double mu = pow(dist, factor);
      //PetscPrintf(oldMesh->comm(), "%f, %f\n", mu, dist);
      tmpLimit = oldLimit*pow(mu, dim);
      if (tmpLimit > minLimit) {
        curLimit = tmpLimit;
      } else curLimit = minLimit;
    } else curLimit = minLimit;
    //PetscPrintf(oldMesh->comm(), "%f, %f\n", dist, tmpLimit);
    volume_limits->updatePoint(*c_iter, &curLimit);
    c_iter++;
  }

  ALE::Obj<ALE::Mesh> newMesh = ALE::Generator::refineMesh(oldMesh, volume_limits, interpolate);
  //ierr = MeshSetMesh(*refinedMesh, newMesh);CHKERRQ(ierr);
  *refinedMesh = newMesh;
  const ALE::Obj<ALE::Mesh::real_section_type>& s = newMesh->getRealSection("default");
  const Obj<std::set<std::string> >& discs = oldMesh->getDiscretizations();

  for(std::set<std::string>::const_iterator f_iter = discs->begin(); f_iter != discs->end(); ++f_iter) {
    newMesh->setDiscretization(*f_iter, oldMesh->getDiscretization(*f_iter));
  }
  newMesh->setupField(s);
  //  PetscPrintf(newMesh->comm(), "refined\n");
  PetscFunctionReturn(0);
}
Beispiel #9
0
EXTERN_C_BEGIN
#undef __FUNCT__
#define __FUNCT__ "DMConvert_DA_Mesh"
PetscErrorCode DMConvert_DA_Mesh(DM dm, const DMType newtype, DM *dmNew)
{
  PetscSection   section;
  DM             cda;
  DMDALocalInfo  info;
  Vec            coordinates;
  PetscInt      *cone, *coneO;
  PetscInt       dim, M, N, P, numCells, numGlobalCells, numCorners, numVertices, c = 0, v = 0;
  PetscInt       ye, ze;
  PetscInt       debug = 0;
  PetscErrorCode ierr;

  PetscFunctionBegin;
  ierr = PetscOptionsGetInt(PETSC_NULL, "-dm_mesh_debug", &debug, PETSC_NULL);CHKERRQ(ierr);
  ierr = DMDAGetInfo(dm, &dim, &M, &N, &P, 0,0,0,0,0,0,0,0,0);CHKERRQ(ierr);
  ierr = DMDAGetLocalInfo(dm, &info);CHKERRQ(ierr);
  if (info.sw  > 1) SETERRQ(((PetscObject) dm)->comm, PETSC_ERR_SUP, "Currently, only DMDAs with unti stencil width can be converted to DMMeshes.");
  /* In order to get a partition of cells, rather than vertices, we give each process the cells between vertices it owns
     and also higher numbered ghost vertices (vertices to the right and up) */
  numCorners  = 1 << dim;
  numCells    = ((info.gxm+info.gxs - info.xs) - 1);
  if (dim > 1) {numCells *= ((info.gym+info.gys - info.ys) - 1);}
  if (dim > 2) {numCells *= ((info.gzm+info.gzs - info.zs) - 1);}
  numVertices = (info.gxm+info.gxs - info.xs);
  if (dim > 1) {numVertices *= (info.gym+info.gys - info.ys);}
  if (dim > 2) {numVertices *= (info.gzm+info.gzs - info.zs);}
  numGlobalCells = M-1;
  if (dim > 1) {numGlobalCells *= N-1;}
  if (dim > 2) {numGlobalCells *= P-1;}

  ALE::Obj<PETSC_MESH_TYPE>             mesh  = new PETSC_MESH_TYPE(((PetscObject) dm)->comm, info.dim, debug);
  ALE::Obj<PETSC_MESH_TYPE::sieve_type> sieve = new PETSC_MESH_TYPE::sieve_type(((PetscObject) dm)->comm, 0, numCells+numVertices, debug);
  PETSC_MESH_TYPE::renumbering_type     renumbering;

  mesh->setSieve(sieve);
  /* Number each cell for the vertex in the lower left corner */
  if (dim < 3) {ze = 1; P = 1;} else {ze = info.gzs+info.gzm-1;}
  if (dim < 2) {ye = 1; N = 1;} else {ye = info.gys+info.gym-1;}
  for(PetscInt k = info.zs; k < ze; ++k) {
    for(PetscInt j = info.ys; j < ye; ++j) {
      for(PetscInt i = info.xs; i < info.gxs+info.gxm-1; ++i, ++c) {
        PetscInt globalC = (k*(N-1) + j)*(M-1) + i;

        renumbering[globalC] = c;
        sieve->setConeSize(c, numCorners);
      }
    }
  }
  if (c != numCells) {SETERRQ2(((PetscObject) dm)->comm, PETSC_ERR_PLIB, "Error in generated cell numbering, %d should be %d", c, numCells);}
  /* Get vertex renumbering */
  for(PetscInt k = info.zs; k < info.gzs+info.gzm; ++k) {
    for(PetscInt j = info.ys; j < info.gys+info.gym; ++j) {
      for(PetscInt i = info.xs; i < info.gxs+info.gxm; ++i, ++v) {
        PetscInt globalV = (k*N + j)*M + i + numGlobalCells;

        renumbering[globalV] = v+numCells;
      }
    }
  }
  if (v != numVertices) {SETERRQ2(((PetscObject) dm)->comm, PETSC_ERR_PLIB, "Error in generated vertex numbering, %d should be %d", v, numVertices);}
  /* Calculate support sizes */
  for(PetscInt k = info.zs; k < ze; ++k, ++c) {
    for(PetscInt j = info.ys; j < ye; ++j) {
      for(PetscInt i = info.xs; i < info.gxs+info.gxm-1; ++i) {
        for(PetscInt kp = k; kp <= k+(dim>2); ++kp) {
          for(PetscInt jp = j; jp <= j+(dim>1); ++jp) {
            for(PetscInt ip = i; ip <= i+1; ++ip) {
              PetscInt globalV = (kp*N + jp)*M + ip + numGlobalCells;

              sieve->addSupportSize(renumbering[globalV], 1);
            }
          }
        }
      }
    }
  }
  sieve->allocate();
  ierr = PetscMalloc2(numCorners,PetscInt,&cone,numCorners,PetscInt,&coneO);CHKERRQ(ierr);
  for(PetscInt v = 0; v < numCorners; ++v) {
    coneO[v] = 1;
  }
  for(PetscInt k = info.zs; k < ze; ++k) {
    for(PetscInt j = info.ys; j < ye; ++j) {
      for(PetscInt i = info.xs; i < info.gxs+info.gxm-1; ++i) {
        PetscInt globalC = (k*(N-1) + j)*(M-1) + i;
        PetscInt v       = 0;

        cone[v++] = renumbering[(k*N + j)*M + i+0 + numGlobalCells];
        cone[v++] = renumbering[(k*N + j)*M + i+1 + numGlobalCells];
        if (dim > 1) {
          cone[v++] = renumbering[(k*N + j+1)*M + i+0 + numGlobalCells];
          cone[v++] = renumbering[(k*N + j+1)*M + i+1 + numGlobalCells];
        }
        if (dim > 2) {
          cone[v++] = renumbering[((k+1)*N + j+0)*M + i+0 + numGlobalCells];
          cone[v++] = renumbering[((k+1)*N + j+0)*M + i+1 + numGlobalCells];
          cone[v++] = renumbering[((k+1)*N + j+1)*M + i+0 + numGlobalCells];
          cone[v++] = renumbering[((k+1)*N + j+1)*M + i+1 + numGlobalCells];
        }
        sieve->setCone(cone, renumbering[globalC]);
        sieve->setConeOrientation(coneO, renumbering[globalC]);
      }
    }
  }
  ierr = PetscFree2(cone,coneO);CHKERRQ(ierr);
  sieve->symmetrize();
  mesh->stratify();
  /* Create boundary marker */
  {
    const Obj<PETSC_MESH_TYPE::label_type>& boundary = mesh->createLabel("marker");

    for(PetscInt k = info.zs; k < info.gzs+info.gzm; ++k) {
      for(PetscInt j = info.ys; j < info.gys+info.gym; ++j) {
        if (info.xs == 0) {
          PetscInt globalV = (k*N + j)*M + info.xs + numGlobalCells;

          mesh->setValue(boundary, renumbering[globalV], 1);
        }
        if (info.gxs+info.gxm-1 == M-1) {
          PetscInt globalV = (k*N + j)*M + info.gxs+info.gxm-1 + numGlobalCells;

          mesh->setValue(boundary, renumbering[globalV], 1);
        }
      }
    }
    if (dim > 1) {
      for(PetscInt k = info.zs; k < info.gzs+info.gzm; ++k) {
        for(PetscInt i = info.xs; i < info.gxs+info.gxm; ++i) {
          if (info.ys == 0) {
            PetscInt globalV = (k*N + info.ys)*M + i + numGlobalCells;

            mesh->setValue(boundary, renumbering[globalV], 1);
          }
          if (info.gys+info.gym-1 == N-1) {
            PetscInt globalV = (k*N + info.gys+info.gym-1)*M + i + numGlobalCells;

            mesh->setValue(boundary, renumbering[globalV], 1);
          }
        }
      }
    }
    if (dim > 2) {
      for(PetscInt j = info.ys; j < info.gys+info.gym; ++j) {
        for(PetscInt i = info.xs; i < info.gxs+info.gxm; ++i) {
          if (info.zs == 0) {
            PetscInt globalV = (info.zs*N + j)*M + i + numGlobalCells;

            mesh->setValue(boundary, renumbering[globalV], 1);
          }
          if (info.gzs+info.gzm-1 == P-1) {
            PetscInt globalV = ((info.gzs+info.gzm-1)*N + j)*M + i + numGlobalCells;

            mesh->setValue(boundary, renumbering[globalV], 1);
          }
        }
      }
    }
  }
  /* Create new DM */
  ierr = DMMeshCreate(((PetscObject) dm)->comm, dmNew);CHKERRQ(ierr);
  ierr = DMMeshSetMesh(*dmNew, mesh);CHKERRQ(ierr);
  /* Set coordinates */
  ierr = PetscSectionCreate(((PetscObject) dm)->comm, &section);CHKERRQ(ierr);
  ierr = PetscSectionSetChart(section, numCells, numCells+numVertices);CHKERRQ(ierr);
  for(PetscInt v = numCells; v < numCells+numVertices; ++v) {
    ierr = PetscSectionSetDof(section, v, dim);CHKERRQ(ierr);
  }
  ierr = PetscSectionSetUp(section);CHKERRQ(ierr);
  ierr = DMMeshSetCoordinateSection(*dmNew, section);CHKERRQ(ierr);
  ierr = DMDAGetCoordinateDA(dm, &cda);CHKERRQ(ierr);
  ierr = DMDAGetGhostedCoordinates(dm, &coordinates);CHKERRQ(ierr);
  {
    Obj<PETSC_MESH_TYPE::real_section_type> coordSection = mesh->getRealSection("coordinates");

    switch(dim) {
    case 1:
    {
      PetscScalar **coords;

      ierr = DMDAVecGetArrayDOF(cda, coordinates, &coords);CHKERRQ(ierr);
      for(PetscInt i = info.xs; i < info.gxs+info.gxm; ++i) {
        PetscInt globalV = i + numGlobalCells;

        coordSection->updatePoint(renumbering[globalV], coords[i]);
      }
      ierr = DMDAVecRestoreArrayDOF(cda, coordinates, &coords);CHKERRQ(ierr);
      break;
    }
    case 2:
    {
      PetscScalar ***coords;

      ierr = DMDAVecGetArrayDOF(cda, coordinates, &coords);CHKERRQ(ierr);
      for(PetscInt j = info.ys; j < info.gys+info.gym; ++j) {
        for(PetscInt i = info.xs; i < info.gxs+info.gxm; ++i) {
          PetscInt globalV = j*M + i + numGlobalCells;

          coordSection->updatePoint(renumbering[globalV], coords[j][i]);
        }
      }
      ierr = DMDAVecRestoreArrayDOF(cda, coordinates, &coords);CHKERRQ(ierr);
      break;
    }
    case 3:
    {
      PetscScalar ****coords;

      ierr = DMDAVecGetArrayDOF(cda, coordinates, &coords);CHKERRQ(ierr);
      for(PetscInt k = info.zs; k < info.gzs+info.gzm; ++k, ++v) {
        for(PetscInt j = info.ys; j < info.gys+info.gym; ++j) {
          for(PetscInt i = info.xs; i < info.gxs+info.gxm; ++i) {
            PetscInt globalV = (k*N + j)*M + i + numGlobalCells;

            coordSection->updatePoint(renumbering[globalV], coords[k][j][i]);
          }
        }
      }
      ierr = DMDAVecRestoreArrayDOF(cda, coordinates, &coords);CHKERRQ(ierr);
      break;
    }
    default:
      SETERRQ1(((PetscObject) dm)->comm, PETSC_ERR_ARG_OUTOFRANGE, "Invalid DMDA dimension %d", dim);
    }
  }
  /* Get overlap for interdomain communication */
  {
    typedef PETSC_MESH_TYPE::point_type point_type;
    PETSc::Log::Event("CreateOverlap").begin();
    ALE::Obj<PETSC_MESH_TYPE::send_overlap_type> sendParallelMeshOverlap = mesh->getSendOverlap();
    ALE::Obj<PETSC_MESH_TYPE::recv_overlap_type> recvParallelMeshOverlap = mesh->getRecvOverlap();
    //   Can I figure this out in a nicer way?
    ALE::SetFromMap<std::map<point_type,point_type> > globalPoints(renumbering);

    ALE::OverlapBuilder<>::constructOverlap(globalPoints, renumbering, sendParallelMeshOverlap, recvParallelMeshOverlap);
    if (debug) {
      sendParallelMeshOverlap->view("Send Overlap");
      recvParallelMeshOverlap->view("Recieve Overlap");
    }
    mesh->setCalculatedOverlap(true);
    PETSc::Log::Event("CreateOverlap").end();
  }
  PetscFunctionReturn(0);
}
Beispiel #10
0
PetscErrorCode testBiGraphDiv2()
{
  PetscInt       debug;
  PetscBool      flag;
  PetscErrorCode ierr;

  PetscFunctionBegin;
  debug = 0;
  ierr  = PetscOptionsGetInt(NULL, "-debug", &debug, &flag);CHKERRQ(ierr);
  ALE::Obj<BiGraphInt3> bg = BiGraphInt3(PETSC_COMM_SELF, debug);

  // Add arrows from the first 10 integers to the first 20 integers, coloring the arrows for 0 (even target) or 1 (odd target)
  for (int i = 0; i < 10; i++) {
    bg->addArrow(2*i+0, i, 0);
    bg->addArrow(2*i+1, i, 1);
  }

  // View
  bg->view(std::cout, "bigraph/2");

  // View cones and supports
  viewConesAndSupports(bg, "bigraph/2");

  // Take and view the cone of the whole base
  ALE::Obj<BiGraphInt3::traits::coneSet> cone = bg->cone(bg->base());
  std::cout << "Total cone of bigraph/2" << std::endl;
  std::cout << "[";
  for (BiGraphInt3::traits::coneSet::iterator i = cone->begin(); i != cone->end(); i++) {
    std::cout << " " << *i;
  }
  std::cout << " ]" << std::endl;

  // Take and view the support of the whole cap
  ALE::Obj<BiGraphInt3::traits::supportSet> supp = bg->support(bg->cap());
  std::cout << "Total support of bigraph/2" << std::endl;
  std::cout << "[";
  for (BiGraphInt3::traits::supportSet::iterator i = supp->begin(); i != supp->end(); i++) {
    std::cout << *i;
  }
  std::cout << "]";


  // Change each arrow color to its negative
  BiGraphInt3::baseSequence base = bg->base();
  for (BiGraphInt3::baseSequence::iterator i = base.begin(); i != base.end(); i++) {
    BiGraphInt3::coneSequence cone = bg->cone(*i);
    for (BiGraphInt3::coneSequence::iterator j = cone.begin(); j != cone.end(); j++) {
      bg->setColor(*j,*i,-(j.color()));
    }
  }
  // View
  bg->view(std::cout, "bigraph/2 after negation");

  // Remove the arrow from 4 to 2 with color 0
  BiGraphInt3::traits::arrow_type a(4,2,0), b(4,3,0);
  bg->removeArrow(a);
  bg->removeArrow(b);
  // View
  ostringstream txt;
  txt << "bigraph/2 after removal of arrows " << a << " and " << b;
  bg->view(std::cout, txt.str().c_str());

  // Remove first cone
  {
    BiGraphInt3::baseSequence base = bg->base();
    bg->clearCone(*(base.begin()));
  }

  // View
  bg->view(std::cout, "bigraph/2 after removal of the first cone");

  // Remove first support
  {
    BiGraphInt3::capSequence cap = bg->cap();
    bg->clearSupport(*(cap.begin()));
  }

  // View
  bg->view(std::cout, "bigraph/2 after removal of the first support");

  // Now restrict the base to the [0,8[ interval
  try {
    {
      ALE::Obj<int_set> base = int_set();
      for (int i = 0; i < 8; i++) {
        base->insert(i);
      }
      bg->restrictBase(base);
    }
  }
  catch(ALE::Exception e) {
    std::cout << "Caught exception: " << e.message() << std::endl;
  }

  // View
  bg->view(std::cout, "bigraph/2 after restricting base to [0,8[");

  // Now exclude [0,5[ from the base
  try {
    {
      ALE::Obj<int_set> ebase = int_set();
      for (int i = 0; i < 5; i++) {
        ebase->insert(i);
      }
      bg->excludeBase(ebase);
    }
  }
  catch(ALE::Exception e) {
    std::cout << "Caught exception: " << e.message() << std::endl;
  }

  // View
  bg->view(std::cout, "bigraph/2 after excluding [0,5[ from base");
  PetscFunctionReturn(0);
} /* testBiGraphDiv2() */
Beispiel #11
0
PetscErrorCode DMCreateInterpolation_Cartesian(DM fineMesh, DM coarseMesh, Mat *interpolation, Vec *scaling)
{
    ALE::Obj<ALE::CartesianMesh> coarse;
    ALE::Obj<ALE::CartesianMesh> fine;
    Mat                          P;
    PetscErrorCode               ierr;

    PetscFunctionBegin;
    ierr = DMCartesianGetMesh(fineMesh,   fine);
    CHKERRQ(ierr);
    ierr = DMCartesianGetMesh(coarseMesh, coarse);
    CHKERRQ(ierr);
#if 0
    const ALE::Obj<ALE::Mesh::real_section_type>& coarseCoordinates = coarse->getRealSection("coordinates");
    const ALE::Obj<ALE::Mesh::real_section_type>& fineCoordinates   = fine->getRealSection("coordinates");
    const ALE::Obj<ALE::Mesh::label_sequence>&    vertices          = fine->depthStratum(0);
    const ALE::Obj<ALE::Mesh::real_section_type>& sCoarse           = coarse->getRealSection("default");
    const ALE::Obj<ALE::Mesh::real_section_type>& sFine             = fine->getRealSection("default");
    const ALE::Obj<ALE::Mesh::order_type>&        coarseOrder = coarse->getFactory()->getGlobalOrder(coarse, "default", sCoarse);
    const ALE::Obj<ALE::Mesh::order_type>&        fineOrder   = fine->getFactory()->getGlobalOrder(fine, "default", sFine);
    const int dim = coarse->getDimension();
    double *v0, *J, *invJ, detJ, *refCoords, *values;
#endif

    ierr = MatCreate(fine->comm(), &P);
    CHKERRQ(ierr);
#if 0
    ierr = MatSetSizes(P, sFine->size(), sCoarse->size(), PETSC_DETERMINE, PETSC_DETERMINE);
    CHKERRQ(ierr);
    ierr = MatSetFromOptions(P);
    CHKERRQ(ierr);
    ierr = PetscMalloc5(dim,double,&v0,dim*dim,double,&J,dim*dim,double,&invJ,dim,double,&refCoords,dim+1,double,&values);
    CHKERRQ(ierr);
    for(ALE::Mesh::label_sequence::iterator v_iter = vertices->begin(); v_iter != vertices->end(); ++v_iter) {
        const ALE::Mesh::real_section_type::value_type *coords     = fineCoordinates->restrictPoint(*v_iter);
        const ALE::Mesh::point_type                     coarseCell = coarse->locatePoint(coords);

        coarse->computeElementGeometry(coarseCoordinates, coarseCell, v0, J, invJ, detJ);
        for(int d = 0; d < dim; ++d) {
            refCoords[d] = 0.0;
            for(int e = 0; e < dim; ++e) {
                refCoords[d] += invJ[d*dim+e]*(coords[e] - v0[e]);
            }
            refCoords[d] -= 1.0;
        }
        values[0] = 1.0/3.0 - (refCoords[0] + refCoords[1])/3.0;
        values[1] = 0.5*(refCoords[0] + 1.0);
        values[2] = 0.5*(refCoords[1] + 1.0);
        ierr = updateOperatorGeneral(P, fine, sFine, fineOrder, *v_iter, sCoarse, coarseOrder, coarseCell, values, INSERT_VALUES);
        CHKERRQ(ierr);
    }
    ierr = PetscFree5(v0,J,invJ,refCoords,values);
    CHKERRQ(ierr);
#endif
    ierr = MatAssemblyBegin(P, MAT_FINAL_ASSEMBLY);
    CHKERRQ(ierr);
    ierr = MatAssemblyEnd(P, MAT_FINAL_ASSEMBLY);
    CHKERRQ(ierr);
    *interpolation = P;
    PetscFunctionReturn(0);
}