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33 results

ScalarNodalScheme.cpp

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  • Connectivity.cpp 5.88 KiB
    #include <Connectivity.hpp>
    #include <map>
    
    #include <Messenger.hpp>
    
    #include <ConnectivityDescriptor.hpp>
    
    template<size_t Dimension>
    Connectivity<Dimension>::Connectivity() {}
    
    template<size_t Dimension>
    void Connectivity<Dimension>::
    _buildFrom(const ConnectivityDescriptor& descriptor)
    {
      Assert(descriptor.cell_to_node_vector.size() == descriptor.cell_type_vector.size());
      Assert(descriptor.cell_number_vector.size() == descriptor.cell_type_vector.size());
      if constexpr (Dimension>1) {
        Assert(descriptor.cell_to_face_vector.size() == descriptor.cell_type_vector.size());
        Assert(descriptor.face_to_node_vector.size() == descriptor.face_number_vector.size());
        Assert(descriptor.face_owner_vector.size() == descriptor.face_number_vector.size());
      }
    
      auto& cell_to_node_matrix
          = m_item_to_item_matrix[itemTId(ItemType::cell)][itemTId(ItemType::node)];
      cell_to_node_matrix = descriptor.cell_to_node_vector;
    
      {
        WeakCellValue<CellType> cell_type(*this);
        parallel_for(this->numberOfCells(), PASTIS_LAMBDA(const CellId& j){
            cell_type[j] = descriptor.cell_type_vector[j];
          });
        m_cell_type = cell_type;
      }
    
      {
        WeakCellValue<int> cell_number(*this);
        cell_number = convert_to_array(descriptor.cell_number_vector);
        m_cell_number = cell_number;
      }
    
      {
        WeakNodeValue<int> node_number(*this);
        node_number = convert_to_array(descriptor.node_number_vector);
        m_node_number = node_number;
      }
    
      {
        WeakCellValue<int> cell_global_index(*this);
        int first_index = 0;
        parallel_for(this->numberOfCells(), PASTIS_LAMBDA(const CellId& j) {
          cell_global_index[j] = first_index+j;
          });
        m_cell_global_index = cell_global_index;
      }
    
      {
        WeakCellValue<int> cell_owner(*this);
        cell_owner = convert_to_array(descriptor.cell_owner_vector);
        m_cell_owner = cell_owner;
      }
    
      {
        const int rank = parallel::rank();
        WeakCellValue<bool> cell_is_owned(*this);
        parallel_for(this->numberOfCells(), PASTIS_LAMBDA(const CellId& j) {
            cell_is_owned[j] = (m_cell_owner[j] == rank);
          });
        m_cell_is_owned = cell_is_owned;
      }
    
      {
        WeakNodeValue<int> node_owner(*this);
        node_owner = convert_to_array(descriptor.node_owner_vector);
        m_node_owner = node_owner;
      }
    
      {
        const int rank = parallel::rank();
        WeakNodeValue<bool> node_is_owned(*this);
        parallel_for(this->numberOfNodes(), PASTIS_LAMBDA(const NodeId& r) {
            node_is_owned[r] = (m_node_owner[r] == rank);
          });
        m_node_is_owned = node_is_owned;
      }
    
      m_ref_node_list_vector = descriptor.template refItemListVector<ItemType::node>();
      m_ref_cell_list_vector = descriptor.template refItemListVector<ItemType::cell>();
    
      if constexpr (Dimension>1) {
        m_item_to_item_matrix[itemTId(ItemType::face)][itemTId(ItemType::node)] = descriptor.face_to_node_vector;
    
        m_item_to_item_matrix[itemTId(ItemType::cell)][itemTId(ItemType::face)] = descriptor.cell_to_face_vector;
    
        {
          FaceValuePerCell<bool> cell_face_is_reversed(*this);
          for (CellId j=0; j<descriptor.cell_face_is_reversed_vector.size(); ++j) {
            const auto& face_cells_vector = descriptor.cell_face_is_reversed_vector[j];
            for (unsigned short lj=0; lj<face_cells_vector.size(); ++lj) {
              cell_face_is_reversed(j,lj) = face_cells_vector[lj];
            }
          }
          m_cell_face_is_reversed = cell_face_is_reversed;
        }
    
        {
          WeakFaceValue<int> face_number(*this);
          face_number = convert_to_array(descriptor.face_number_vector);
          m_face_number = face_number;
        }
    
        {
          WeakFaceValue<int> face_owner(*this);
          face_owner = convert_to_array(descriptor.face_owner_vector);
          m_face_owner = face_owner;
        }
    
        {
          const int rank = parallel::rank();
          WeakFaceValue<bool> face_is_owned(*this);
          parallel_for(this->numberOfFaces(), PASTIS_LAMBDA(const FaceId& l) {
              face_is_owned[l] = (m_face_owner[l] == rank);
            });
          m_face_is_owned = face_is_owned;
        }
    
        m_ref_face_list_vector = descriptor.template refItemListVector<ItemType::face>();
    
        if constexpr (Dimension>2) {
          m_item_to_item_matrix[itemTId(ItemType::edge)][itemTId(ItemType::node)] = descriptor.edge_to_node_vector;
    
          m_item_to_item_matrix[itemTId(ItemType::face)][itemTId(ItemType::edge)] = descriptor.face_to_edge_vector;
    
          m_item_to_item_matrix[itemTId(ItemType::cell)][itemTId(ItemType::edge)] = descriptor.cell_to_edge_vector;
    
          {
            EdgeValuePerFace<bool> face_edge_is_reversed(*this);
            for (FaceId l=0; l<descriptor.face_edge_is_reversed_vector.size(); ++l) {
              const auto& edge_faces_vector = descriptor.face_edge_is_reversed_vector[l];
              for (unsigned short el=0; el<edge_faces_vector.size(); ++el) {
                face_edge_is_reversed(l,el) = edge_faces_vector[el];
              }
            }
            m_face_edge_is_reversed = face_edge_is_reversed;
          }
    
          {
            WeakEdgeValue<int> edge_number(*this);
            edge_number = convert_to_array(descriptor.edge_number_vector);
            m_edge_number = edge_number;
          }
    
          {
            WeakEdgeValue<int> edge_owner(*this);
            edge_owner = convert_to_array(descriptor.edge_owner_vector);
            m_edge_owner = edge_owner;
          }
    
          {
            const int rank = parallel::rank();
            WeakEdgeValue<bool> edge_is_owned(*this);
            parallel_for(this->numberOfEdges(), PASTIS_LAMBDA(const EdgeId& e) {
                edge_is_owned[e] = (m_edge_owner[e] == rank);
              });
            m_edge_is_owned = edge_is_owned;
          }
    
          m_ref_edge_list_vector = descriptor.template refItemListVector<ItemType::edge>();
        }
      }
    }
    
    template Connectivity1D::Connectivity();
    template Connectivity2D::Connectivity();
    template Connectivity3D::Connectivity();
    
    template void Connectivity1D::_buildFrom(const ConnectivityDescriptor&);
    template void Connectivity2D::_buildFrom(const ConnectivityDescriptor&);
    template void Connectivity3D::_buildFrom(const ConnectivityDescriptor&);