https://gitlab.opengeosys.org/ogs/ogs.git
Tip revision: 2c4697de7bcd9643d3fbde1992f5e8844e12804f authored by Norbert Grunwald on 14 September 2021, 10:22:34 UTC
[T/TH2M] updated reference files include aeraulic_flow and heat_flux
[T/TH2M] updated reference files include aeraulic_flow and heat_flux
Tip revision: 2c4697d
NodePartitionedMesh.h
/*!
\file
\author Wenqing Wang
\date 2014.06
\brief Definition of mesh class for partitioned mesh (by node) for parallel
computing within the framework of domain decomposition (DDC).
\copyright
Copyright (c) 2012-2021, OpenGeoSys Community (http://www.opengeosys.org)
Distributed under a Modified BSD License.
See accompanying file LICENSE.txt or
http://www.opengeosys.org/project/license
*/
#pragma once
#include <algorithm>
#include <string>
#include <vector>
#include "Mesh.h"
#include "Node.h"
namespace MeshLib
{
/// A subdomain mesh.
class NodePartitionedMesh : public Mesh
{
public:
// Copy a global mesh for the case of the thread number is one,
// i.e the global mesh is not partitioned.
// \param mesh The global mesh
explicit NodePartitionedMesh(const Mesh& mesh)
: Mesh(mesh),
_global_node_ids(mesh.getNumberOfNodes()),
_n_global_base_nodes(mesh.getNumberOfBaseNodes()),
_n_global_nodes(mesh.getNumberOfNodes()),
_n_active_base_nodes(mesh.getNumberOfBaseNodes()),
_n_active_nodes(mesh.getNumberOfNodes()),
_is_single_thread(true)
{
for (std::size_t i = 0; i < _nodes.size(); i++)
{
_global_node_ids[i] = _nodes[i]->getID();
}
}
/*!
\brief Constructor
\param name Name assigned to the mesh.
\param nodes Vector for nodes, which storage looks like:
||--active base nodes--|--ghost base nodes--|
--active extra nodes--|--ghost extra nodes--||
(extra nodes: nodes for high order interpolations)
\param glb_node_ids Global IDs of nodes of a partition.
\param elements Vector for elements. Ghost elements are stored
after regular (non-ghost) elements.
\param properties Mesh property.
\param n_global_base_nodes Number of the base nodes of the global mesh.
\param n_global_nodes Number of all nodes of the global mesh.
\param n_base_nodes Number of the base nodes.
\param n_active_base_nodes Number of the active base nodes.
\param n_active_nodes Number of all active nodes.
*/
NodePartitionedMesh(const std::string& name,
const std::vector<Node*>& nodes,
const std::vector<std::size_t>& glb_node_ids,
const std::vector<Element*>& elements,
Properties properties,
const std::size_t n_global_base_nodes,
const std::size_t n_global_nodes,
const std::size_t n_base_nodes,
const std::size_t n_active_base_nodes,
const std::size_t n_active_nodes)
: Mesh(name, nodes, elements, properties, n_base_nodes),
_global_node_ids(glb_node_ids),
_n_global_base_nodes(n_global_base_nodes),
_n_global_nodes(n_global_nodes),
_n_active_base_nodes(n_active_base_nodes),
_n_active_nodes(n_active_nodes),
_is_single_thread(false)
{
}
/// Get the number of nodes of the global mesh for linear elements.
std::size_t getNumberOfGlobalBaseNodes() const
{
return _n_global_base_nodes;
}
/// Get the number of all nodes of the global mesh.
std::size_t getNumberOfGlobalNodes() const { return _n_global_nodes; }
/// Get the global node ID of a node with its local ID.
std::size_t getGlobalNodeID(const std::size_t node_id) const
{
return _global_node_ids[node_id];
}
/// Get the number of the active nodes of the partition for linear elements.
std::size_t getNumberOfActiveBaseNodes() const
{
return _n_active_base_nodes;
}
/// Get the number of all active nodes of the partition.
std::size_t getNumberOfActiveNodes() const { return _n_active_nodes; }
/// Check whether a node with ID of node_id is a ghost node
bool isGhostNode(const std::size_t node_id) const
{
if (node_id < _n_active_base_nodes)
return false;
else if (node_id >= _n_base_nodes && node_id < getLargestActiveNodeID())
return false;
else
return true;
}
/// Get the largest ID of active nodes for higher order elements in a
/// partition.
std::size_t getLargestActiveNodeID() const
{
return _n_base_nodes + _n_active_nodes - _n_active_base_nodes;
}
// TODO I guess that is a simplified version of computeSparsityPattern()
/// Get the maximum number of connected nodes to node.
std::size_t getMaximumNConnectedNodesToNode() const
{
auto const& nodes_connections =
MeshLib::calculateNodesConnectedByElements(*this);
auto const max_connections = std::max_element(
nodes_connections.cbegin(), nodes_connections.cend(),
[](auto const& connections_node_a, auto const& connections_node_b) {
return (connections_node_a.size() < connections_node_b.size());
});
// Return the number of connected nodes +1 for the node itself.
return max_connections->size() + 1;
}
bool isForSingleThread() const { return _is_single_thread; }
private:
/// Global IDs of nodes of a partition
std::vector<std::size_t> _global_node_ids;
/// Number of the nodes of the global mesh linear interpolations.
std::size_t _n_global_base_nodes;
/// Number of all nodes of the global mesh.
std::size_t _n_global_nodes;
/// Number of the active nodes for linear interpolations
std::size_t _n_active_base_nodes;
/// Number of the all active nodes.
std::size_t _n_active_nodes;
const bool _is_single_thread;
};
} // namespace MeshLib