OGS
HTProcess.cpp
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1
11#include "HTProcess.h"
12
13#include <cassert>
14
15#include "MonolithicHTFEM.h"
16#include "NumLib/DOF/DOFTableUtil.h"
17#include "NumLib/DOF/LocalToGlobalIndexMap.h"
18#include "ProcessLib/CoupledSolutionsForStaggeredScheme.h"
19#include "ProcessLib/SurfaceFlux/SurfaceFluxData.h"
20#include "ProcessLib/Utils/CreateLocalAssemblers.h"
21#include "StaggeredHTFEM.h"
22
23namespace ProcessLib
24{
25namespace HT
26{
27HTProcess::HTProcess(
28 std::string name,
29 MeshLib::Mesh& mesh,
30 std::unique_ptr<ProcessLib::AbstractJacobianAssembler>&& jacobian_assembler,
31 std::vector<std::unique_ptr<ParameterLib::ParameterBase>> const& parameters,
32 unsigned const integration_order,
33 std::vector<std::vector<std::reference_wrapper<ProcessVariable>>>&&
34 process_variables,
35 HTProcessData&& process_data,
36 SecondaryVariableCollection&& secondary_variables,
37 bool const use_monolithic_scheme,
38 std::unique_ptr<ProcessLib::SurfaceFluxData>&& surfaceflux)
39 : Process(std::move(name), mesh, std::move(jacobian_assembler), parameters,
40 integration_order, std::move(process_variables),
41 std::move(secondary_variables), use_monolithic_scheme),
42 _process_data(std::move(process_data)),
43 _surfaceflux(std::move(surfaceflux))
44{
45}
46
47void HTProcess::initializeConcreteProcess(
48 NumLib::LocalToGlobalIndexMap const& dof_table,
49 MeshLib::Mesh const& mesh,
50 unsigned const integration_order)
51{
52 int const mesh_space_dimension = _process_data.mesh_space_dimension;
53
54 if (_use_monolithic_scheme)
55 {
56 ProcessLib::createLocalAssemblers<MonolithicHTFEM>(
57 mesh_space_dimension, mesh.getElements(), dof_table,
58 _local_assemblers, NumLib::IntegrationOrder{integration_order},
59 mesh.isAxiallySymmetric(), _process_data);
60 }
61 else
62 {
63 ProcessLib::createLocalAssemblers<StaggeredHTFEM>(
64 mesh_space_dimension, mesh.getElements(), dof_table,
65 _local_assemblers, NumLib::IntegrationOrder{integration_order},
66 mesh.isAxiallySymmetric(), _process_data);
67 }
68
69 _secondary_variables.addSecondaryVariable(
70 "darcy_velocity",
71 makeExtrapolator(mesh_space_dimension, getExtrapolator(),
72 _local_assemblers,
73 &HTLocalAssemblerInterface::getIntPtDarcyVelocity));
74}
75
76void HTProcess::assembleConcreteProcess(
77 const double t, double const dt, std::vector<GlobalVector*> const& x,
78 std::vector<GlobalVector*> const& x_prev, int const process_id,
79 GlobalMatrix& M, GlobalMatrix& K, GlobalVector& b)
80{
81 std::vector<NumLib::LocalToGlobalIndexMap const*> dof_tables;
82 if (_use_monolithic_scheme)
83 {
84 DBUG("Assemble HTProcess.");
85 dof_tables.emplace_back(_local_to_global_index_map.get());
86 }
87 else
88 {
89 if (process_id == _process_data.heat_transport_process_id)
90 {
91 DBUG(
92 "Assemble the equations of heat transport process within "
93 "HTProcess.");
94 }
95 else
96 {
97 DBUG(
98 "Assemble the equations of single phase fully saturated "
99 "fluid flow process within HTProcess.");
100 }
101 dof_tables.emplace_back(_local_to_global_index_map.get());
102 dof_tables.emplace_back(_local_to_global_index_map.get());
103 }
104
105 ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
106 // Call global assembler for each local assembly item.
107 GlobalExecutor::executeSelectedMemberDereferenced(
108 _global_assembler, &VectorMatrixAssembler::assemble, _local_assemblers,
109 pv.getActiveElementIDs(), dof_tables, t, dt, x, x_prev, process_id, M,
110 K, b);
111}
112
113void HTProcess::assembleWithJacobianConcreteProcess(
114 const double t, double const dt, std::vector<GlobalVector*> const& x,
115 std::vector<GlobalVector*> const& x_prev, int const process_id,
116 GlobalMatrix& M, GlobalMatrix& K, GlobalVector& b, GlobalMatrix& Jac)
117{
118 DBUG("AssembleWithJacobian HTProcess.");
119
120 std::vector<NumLib::LocalToGlobalIndexMap const*> dof_tables;
121 if (!_use_monolithic_scheme)
122 {
123 dof_tables.emplace_back(_local_to_global_index_map.get());
124 }
125 else
126 {
127 dof_tables.emplace_back(_local_to_global_index_map.get());
128 dof_tables.emplace_back(_local_to_global_index_map.get());
129 }
130
131 // Call global assembler for each local assembly item.
132 ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
133 GlobalExecutor::executeSelectedMemberDereferenced(
134 _global_assembler, &VectorMatrixAssembler::assembleWithJacobian,
135 _local_assemblers, pv.getActiveElementIDs(), dof_tables, t, dt, x,
136 x_prev, process_id, M, K, b, Jac);
137}
138
139std::tuple<NumLib::LocalToGlobalIndexMap*, bool>
140HTProcess::getDOFTableForExtrapolatorData() const
141{
142 if (!_use_monolithic_scheme)
143 {
144 // For single-variable-single-component processes reuse the existing DOF
145 // table.
146 const bool manage_storage = false;
147 return std::make_tuple(_local_to_global_index_map.get(),
148 manage_storage);
149 }
150
151 // Otherwise construct a new DOF table.
152 std::vector<MeshLib::MeshSubset> all_mesh_subsets_single_component{
153 *_mesh_subset_all_nodes};
154
155 const bool manage_storage = true;
156 return std::make_tuple(new NumLib::LocalToGlobalIndexMap(
157 std::move(all_mesh_subsets_single_component),
158 // by location order is needed for output
159 NumLib::ComponentOrder::BY_LOCATION),
160 manage_storage);
161}
162
163Eigen::Vector3d HTProcess::getFlux(std::size_t element_id,
164 MathLib::Point3d const& p,
165 double const t,
166 std::vector<GlobalVector*> const& x) const
167{
168 // fetch local_x from primary variable
169 std::vector<GlobalIndexType> indices_cache;
170 auto const r_c_indices = NumLib::getRowColumnIndices(
171 element_id, *_local_to_global_index_map, indices_cache);
172 std::vector<std::vector<GlobalIndexType>> indices_of_all_coupled_processes{
173 x.size(), r_c_indices.rows};
174 auto const local_x =
175 getCoupledLocalSolutions(x, indices_of_all_coupled_processes);
176
177 return _local_assemblers[element_id]->getFlux(p, t, local_x);
178}
179
180// this is almost a copy of the implementation in the GroundwaterFlow
181void HTProcess::postTimestepConcreteProcess(
182 std::vector<GlobalVector*> const& x,
183 std::vector<GlobalVector*> const& /*x_prev*/,
184 const double t,
185 const double /*delta_t*/,
186 int const process_id)
187{
188 // For the monolithic scheme, process_id is always zero.
189 if (_use_monolithic_scheme && process_id != 0)
190 {
191 OGS_FATAL(
192 "The condition of process_id = 0 must be satisfied for monolithic "
193 "HTProcess, which is a single process.");
194 }
195 if (!_use_monolithic_scheme &&
196 process_id != _process_data.hydraulic_process_id)
197 {
198 DBUG("This is the thermal part of the staggered HTProcess.");
199 return;
200 }
201 if (!_surfaceflux) // computing the surfaceflux is optional
202 {
203 return;
204 }
205
206 ProcessLib::ProcessVariable const& pv = getProcessVariables(process_id)[0];
207
208 _surfaceflux->integrate(x, t, *this, process_id, _integration_order, _mesh,
209 pv.getActiveElementIDs());
210}
211} // namespace HT
212} // namespace ProcessLib
OGS_FATAL
#define OGS_FATAL(...)
Definition Error.h:26
DBUG
void DBUG(fmt::format_string< Args... > fmt, Args &&... args)
Definition Logging.h:30
MathLib::EigenVector
Global vector based on Eigen vector.
Definition EigenVector.h:25
MeshLib::Mesh::isAxiallySymmetric
bool isAxiallySymmetric() const
Definition Mesh.h:137
MeshLib::Mesh::getElements
std::vector< Element * > const & getElements() const
Get the element-vector for the mesh.
Definition Mesh.h:109
ProcessLib::HT::HTLocalAssemblerInterface::getIntPtDarcyVelocity
virtual std::vector< double > const & getIntPtDarcyVelocity(const double, std::vector< GlobalVector * > const &x, std::vector< NumLib::LocalToGlobalIndexMap const * > const &, std::vector< double > &) const =0
ProcessLib::HT::HTProcess::initializeConcreteProcess
void initializeConcreteProcess(NumLib::LocalToGlobalIndexMap const &dof_table, MeshLib::Mesh const &mesh, unsigned const integration_order) override
Process specific initialization called by initialize().
Definition HTProcess.cpp:47
ProcessLib::HT::HTProcess::getDOFTableForExtrapolatorData
std::tuple< NumLib::LocalToGlobalIndexMap *, bool > getDOFTableForExtrapolatorData() const override
Definition HTProcess.cpp:140
ProcessLib::HT::HTProcess::HTProcess
HTProcess(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, HTProcessData &&process_data, SecondaryVariableCollection &&secondary_variables, bool const use_monolithic_scheme, std::unique_ptr< ProcessLib::SurfaceFluxData > &&surfaceflux)
Definition HTProcess.cpp:27
ProcessLib::HT::HTProcess::_surfaceflux
std::unique_ptr< ProcessLib::SurfaceFluxData > _surfaceflux
Definition HTProcess.h:114
ProcessLib::HT::HTProcess::getFlux
Eigen::Vector3d getFlux(std::size_t element_id, MathLib::Point3d const &p, double const t, std::vector< GlobalVector * > const &x) const override
Definition HTProcess.cpp:163
ProcessLib::HT::HTProcess::_process_data
HTProcessData _process_data
Definition HTProcess.h:110
ProcessLib::HT::HTProcess::assembleConcreteProcess
void assembleConcreteProcess(const double t, double const dt, std::vector< GlobalVector * > const &x, std::vector< GlobalVector * > const &x_prev, int const process_id, GlobalMatrix &M, GlobalMatrix &K, GlobalVector &b) override
Definition HTProcess.cpp:76
ProcessLib::HT::HTProcess::postTimestepConcreteProcess
void postTimestepConcreteProcess(std::vector< GlobalVector * > const &x, std::vector< GlobalVector * > const &x_prev, const double t, const double delta_t, int const process_id) override
Definition HTProcess.cpp:181
ProcessLib::HT::HTProcess::assembleWithJacobianConcreteProcess
void assembleWithJacobianConcreteProcess(const double t, double const dt, std::vector< GlobalVector * > const &x, std::vector< GlobalVector * > const &x_prev, int const process_id, GlobalMatrix &M, GlobalMatrix &K, GlobalVector &b, GlobalMatrix &Jac) override
Definition HTProcess.cpp:113
ProcessLib::HT::HTProcess::_local_assemblers
std::vector< std::unique_ptr< HTLocalAssemblerInterface > > _local_assemblers
Definition HTProcess.h:112
ProcessLib::ProcessVariable::getActiveElementIDs
std::vector< std::size_t > const & getActiveElementIDs() const
Definition ProcessVariable.h:87
ProcessLib::Process::_mesh_subset_all_nodes
std::unique_ptr< MeshLib::MeshSubset const > _mesh_subset_all_nodes
Definition Process.h:358
ProcessLib::Process::_mesh
MeshLib::Mesh & _mesh
Definition Process.h:357
ProcessLib::Process::_secondary_variables
SecondaryVariableCollection _secondary_variables
Definition Process.h:362
ProcessLib::Process::getProcessVariables
std::vector< std::reference_wrapper< ProcessVariable > > const & getProcessVariables(const int process_id) const
Definition Process.h:155
ProcessLib::Process::_global_assembler
VectorMatrixAssembler _global_assembler
Definition Process.h:367
ProcessLib::Process::_integration_order
unsigned const _integration_order
Definition Process.h:374
ProcessLib::Process::_local_to_global_index_map
std::unique_ptr< NumLib::LocalToGlobalIndexMap > _local_to_global_index_map
Definition Process.h:360
ProcessLib::Process::getExtrapolator
NumLib::Extrapolator & getExtrapolator() const
Definition Process.h:199
ProcessLib::Process::_use_monolithic_scheme
const bool _use_monolithic_scheme
Definition Process.h:369
ProcessLib::SecondaryVariableCollection
Handles configuration of several secondary variables from the project file.
Definition SecondaryVariable.h:115
ProcessLib::SecondaryVariableCollection::addSecondaryVariable
void addSecondaryVariable(std::string const &internal_name, SecondaryVariableFunctions &&fcts)
Definition SecondaryVariable.cpp:25
ProcessLib::VectorMatrixAssembler::assembleWithJacobian
void assembleWithJacobian(std::size_t const mesh_item_id, LocalAssemblerInterface &local_assembler, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_tables, const double t, double const dt, std::vector< GlobalVector * > const &x, std::vector< GlobalVector * > const &x_prev, int const process_id, GlobalMatrix &M, GlobalMatrix &K, GlobalVector &b, GlobalMatrix &Jac)
Definition VectorMatrixAssembler.cpp:106
ProcessLib::VectorMatrixAssembler::assemble
void assemble(std::size_t const mesh_item_id, LocalAssemblerInterface &local_assembler, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_tables, double const t, double const dt, std::vector< GlobalVector * > const &x, std::vector< GlobalVector * > const &x_prev, int const process_id, GlobalMatrix &M, GlobalMatrix &K, GlobalVector &b)
Definition VectorMatrixAssembler.cpp:39
NumLib::getRowColumnIndices
NumLib::LocalToGlobalIndexMap::RowColumnIndices getRowColumnIndices(std::size_t const id, NumLib::LocalToGlobalIndexMap const &dof_table, std::vector< GlobalIndexType > &indices)
Definition DOFTableUtil.cpp:146
NumLib::ComponentOrder::BY_LOCATION
@ BY_LOCATION
Ordering data by spatial location.
ProcessLib::getCoupledLocalSolutions
std::vector< double > getCoupledLocalSolutions(std::vector< GlobalVector * > const &global_solutions, std::vector< std::vector< GlobalIndexType > > const &indices)
Definition CoupledSolutionsForStaggeredScheme.cpp:21
ProcessLib::makeExtrapolator
SecondaryVariableFunctions makeExtrapolator(const unsigned num_components, NumLib::Extrapolator &extrapolator, LocalAssemblerCollection const &local_assemblers, typename NumLib::ExtrapolatableLocalAssemblerCollection< LocalAssemblerCollection >::IntegrationPointValuesMethod integration_point_values_method)
Definition SecondaryVariable.h:164
NumLib::SerialExecutor::executeSelectedMemberDereferenced
static void executeSelectedMemberDereferenced(Object &object, Method method, Container const &container, std::vector< std::size_t > const &active_container_ids, Args &&... args)
Definition SerialExecutor.h:98