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FunctionProcessor.hpp
Connectivity.cpp 6.47 KiB
#include <mesh/Connectivity.hpp>
#include <mesh/ConnectivityDescriptor.hpp>
#include <utils/Messenger.hpp>
#include <map>
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(), PUGS_LAMBDA(CellId j) { cell_type[j] = descriptor.cell_type_vector[j]; });
m_cell_type = cell_type;
}
m_cell_number = WeakCellValue<int>(*this, convert_to_array(descriptor.cell_number_vector));
Array node_number_array = convert_to_array(descriptor.node_number_vector);
m_node_number = WeakNodeValue<int>(*this, node_number_array);
{
WeakCellValue<int> cell_global_index(*this);
int first_index = 0;
parallel_for(
this->numberOfCells(), PUGS_LAMBDA(CellId j) { cell_global_index[j] = first_index + j; });
m_cell_global_index = cell_global_index;
}
m_cell_owner = WeakCellValue<int>(*this, convert_to_array(descriptor.cell_owner_vector));
{
const int rank = parallel::rank();
WeakCellValue<bool> cell_is_owned(*this);
parallel_for(
this->numberOfCells(), PUGS_LAMBDA(CellId j) { cell_is_owned[j] = (m_cell_owner[j] == rank); });
m_cell_is_owned = cell_is_owned;
}
Array node_owner_array = convert_to_array(descriptor.node_owner_vector);
m_node_owner = WeakNodeValue<int>{*this, node_owner_array};
Array<bool> node_is_owned_array(this->numberOfNodes());
{
const int rank = parallel::rank();
WeakNodeValue<bool> node_is_owned(*this, node_is_owned_array);
parallel_for(
this->numberOfNodes(), PUGS_LAMBDA(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) {
// faces are similar to nodes
m_face_number = WeakFaceValue<int>(*this, node_number_array);
m_face_owner = WeakFaceValue<int>(*this, node_owner_array);
m_face_is_owned = WeakFaceValue<bool>(*this, node_is_owned_array);
// edges are similar to nodes
m_edge_number = WeakEdgeValue<int>(*this, node_number_array);
m_edge_owner = WeakEdgeValue<int>(*this, node_owner_array);
m_edge_is_owned = WeakEdgeValue<bool>(*this, node_is_owned_array);
} else {
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;
}
Array face_number_array = convert_to_array(descriptor.face_number_vector);
m_face_number = WeakFaceValue<int>(*this, face_number_array);
Array face_owner_array = convert_to_array(descriptor.face_owner_vector);
m_face_owner = WeakFaceValue<int>(*this, face_owner_array);
Array<bool> face_is_owned_array(this->numberOfFaces());
{
const int rank = parallel::rank();
WeakFaceValue<bool> face_is_owned(*this, face_is_owned_array);
parallel_for(
this->numberOfFaces(), PUGS_LAMBDA(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) {
// edges are similar to faces
m_edge_number = WeakEdgeValue<int>(*this, face_number_array);
m_edge_owner = WeakEdgeValue<int>(*this, face_owner_array);
m_edge_is_owned = WeakEdgeValue<bool>(*this, face_is_owned_array);
} else {
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;
}
m_edge_number = WeakEdgeValue<int>(*this, convert_to_array(descriptor.edge_number_vector));
m_edge_owner = WeakEdgeValue<int>(*this, convert_to_array(descriptor.edge_owner_vector));
{
const int rank = parallel::rank();
WeakEdgeValue<bool> edge_is_owned(*this);
parallel_for(
this->numberOfEdges(), PUGS_LAMBDA(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 Connectivity<1>::Connectivity();
template Connectivity<2>::Connectivity();
template Connectivity<3>::Connectivity();
template void Connectivity<1>::_buildFrom(const ConnectivityDescriptor&);
template void Connectivity<2>::_buildFrom(const ConnectivityDescriptor&);
template void Connectivity<3>::_buildFrom(const ConnectivityDescriptor&);