HeatConductionProcess.cpp

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#include "HeatConductionProcess.h"
 
#include <cassert>
 
#include "MathLib/LinAlg/FinalizeMatrixAssembly.h"
#include "MathLib/LinAlg/FinalizeVectorAssembly.h"
#include "NumLib/DOF/DOFTableUtil.h"
#include "ProcessLib/Utils/ComputeResiduum.h"
#include "ProcessLib/Utils/CreateLocalAssemblers.h"
 
namespace ProcessLib
{
namespace HeatConduction
{
HeatConductionProcess::HeatConductionProcess(
    std::string name,
    MeshLib::Mesh& mesh,
    std::unique_ptr<ProcessLib::AbstractJacobianAssembler>&& jacobian_assembler,
    std::vector<std::unique_ptr<ParameterLib::ParameterBase>> const& parameters,
    unsigned const integration_order,
    std::vector<std::vector<std::reference_wrapper<ProcessVariable>>>&&
        process_variables,
    HeatConductionProcessData&& process_data,
    SecondaryVariableCollection&& secondary_variables)
    : Process(std::move(name), mesh, std::move(jacobian_assembler), parameters,
              integration_order, std::move(process_variables),
              std::move(secondary_variables)),
      _process_data(std::move(process_data))
{
    _heat_flux = MeshLib::getOrCreateMeshProperty<double>(
        mesh, "HeatFlux", MeshLib::MeshItemType::Node, 1);
}
 
void HeatConductionProcess::initializeConcreteProcess(
    NumLib::LocalToGlobalIndexMap const& dof_table,
    MeshLib::Mesh const& mesh,
    unsigned const integration_order)
{
    const int process_id = 0;
    ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
    ProcessLib::createLocalAssemblers<LocalAssemblerData>(
        mesh.getDimension(), mesh.getElements(), dof_table,
        pv.getShapeFunctionOrder(), _local_assemblers,
        mesh.isAxiallySymmetric(), integration_order, _process_data);
 
    _secondary_variables.addSecondaryVariable(
        "heat_flux_x",
        makeExtrapolator(
            1, getExtrapolator(), _local_assemblers,
            &HeatConductionLocalAssemblerInterface::getIntPtHeatFluxX));
 
    if (mesh.getDimension() > 1)
    {
        _secondary_variables.addSecondaryVariable(
            "heat_flux_y",
            makeExtrapolator(
                1, getExtrapolator(), _local_assemblers,
                &HeatConductionLocalAssemblerInterface::getIntPtHeatFluxY));
    }
    if (mesh.getDimension() > 2)
    {
        _secondary_variables.addSecondaryVariable(
            "heat_flux_z",
            makeExtrapolator(
                1, getExtrapolator(), _local_assemblers,
                &HeatConductionLocalAssemblerInterface::getIntPtHeatFluxZ));
    }
}
 
void HeatConductionProcess::assembleConcreteProcess(
    const double t, double const dt, std::vector<GlobalVector*> const& x,
    std::vector<GlobalVector*> const& xdot, int const process_id,
    GlobalMatrix& M, GlobalMatrix& K, GlobalVector& b)
{
    DBUG("Assemble HeatConductionProcess.");
 
    ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
 
    std::vector<std::reference_wrapper<NumLib::LocalToGlobalIndexMap>>
        dof_table = {std::ref(*_local_to_global_index_map)};
    // Call global assembler for each local assembly item.
    GlobalExecutor::executeSelectedMemberDereferenced(
        _global_assembler, &VectorMatrixAssembler::assemble, _local_assemblers,
        pv.getActiveElementIDs(), dof_table, t, dt, x, xdot, process_id, M, K,
        b);
 
    MathLib::finalizeMatrixAssembly(M);
    MathLib::finalizeMatrixAssembly(K);
    MathLib::finalizeVectorAssembly(b);
 
    auto const residuum = computeResiduum(*x[0], *xdot[0], M, K, b);
    transformVariableFromGlobalVector(residuum, 0 /*variable id*/,
                                      *_local_to_global_index_map, *_heat_flux,
                                      std::negate<double>());
}
 
void HeatConductionProcess::assembleWithJacobianConcreteProcess(
    const double t, double const dt, std::vector<GlobalVector*> const& x,
    std::vector<GlobalVector*> const& xdot, const double dxdot_dx,
    const double dx_dx, int const process_id, GlobalMatrix& M, GlobalMatrix& K,
    GlobalVector& b, GlobalMatrix& Jac)
{
    DBUG("AssembleWithJacobian HeatConductionProcess.");
 
    ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
 
    std::vector<std::reference_wrapper<NumLib::LocalToGlobalIndexMap>>
        dof_table = {std::ref(*_local_to_global_index_map)};
    // Call global assembler for each local assembly item.
    GlobalExecutor::executeSelectedMemberDereferenced(
        _global_assembler, &VectorMatrixAssembler::assembleWithJacobian,
        _local_assemblers, pv.getActiveElementIDs(), dof_table, t, dt, x, xdot,
        dxdot_dx, dx_dx, process_id, M, K, b, Jac);
 
    transformVariableFromGlobalVector(b, 0 /*variable id*/,
                                      *_local_to_global_index_map, *_heat_flux,
                                      std::negate<double>());
}
 
void HeatConductionProcess::computeSecondaryVariableConcrete(
    double const t, double const dt, std::vector<GlobalVector*> const& x,
    GlobalVector const& x_dot, int const process_id)
{
    DBUG("Compute heat flux for HeatConductionProcess.");
 
    std::vector<NumLib::LocalToGlobalIndexMap const*> dof_tables;
    dof_tables.reserve(x.size());
    std::generate_n(std::back_inserter(dof_tables), x.size(),
                    [&]() { return _local_to_global_index_map.get(); });
 
    ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
    GlobalExecutor::executeSelectedMemberOnDereferenced(
        &HeatConductionLocalAssemblerInterface::computeSecondaryVariable,
        _local_assemblers, pv.getActiveElementIDs(), dof_tables, t, dt, x,
        x_dot, process_id);
}
 
}  // namespace HeatConduction
}  // namespace ProcessLib