PorousFlowWaterNCG::PorousFlowWaterNCG(const InputParameters & parameters)
: PorousFlowFluidStateMultiComponentBase(parameters),
_water_fp(getUserObject<SinglePhaseFluidProperties>("water_fp")),
_ncg_fp(getUserObject<SinglePhaseFluidProperties>("gas_fp")),
_Mh2o(_water_fp.molarMass()),
_Mncg(_ncg_fp.molarMass()),
_water_triple_temperature(_water_fp.triplePointTemperature()),
_water_critical_temperature(_water_fp.criticalTemperature())
{
// Check that the correct FluidProperties UserObjects have been provided
if (_water_fp.fluidName() != "water")
paramError("water_fp", "A valid water FluidProperties UserObject must be provided in water_fp");
// Set the number of phases and components, and their indexes
_num_phases = 2;
_num_components = 2;
_gas_phase_number = 1 - _aqueous_phase_number;
_gas_fluid_component = 1 - _aqueous_fluid_component;
// Check that _aqueous_phase_number is <= total number of phases
if (_aqueous_phase_number >= _num_phases)
paramError("liquid_phase_number",
"This value is larger than the possible number of phases ",
_num_phases);
// Check that _aqueous_fluid_component is <= total number of fluid components
if (_aqueous_fluid_component >= _num_components)
paramError("liquid_fluid_component",
"This value is larger than the possible number of fluid components",
_num_components);
}
ComputeInterfaceStress::ComputeInterfaceStress(const InputParameters & parameters)
: Material(parameters),
_nvar(coupledComponents("v")),
_grad_v(_nvar),
_op_range(getParam<std::vector<Real>>("op_range")),
_stress(getParam<std::vector<Real>>("stress")),
_planar_stress(
declareProperty<RankTwoTensor>(getParam<MaterialPropertyName>("planar_stress_name")))
{
if (_stress.size() == 1)
_stress.assign(_nvar, _stress[0]);
if (_stress.size() != _nvar)
paramError("stress", "Supply either one single stress or one per order parameter");
if (_op_range.size() == 1)
_op_range.assign(_nvar, _op_range[0]);
if (_op_range.size() != _nvar)
paramError("op_range", "Supply either one single op_range or one per order parameter");
for (MooseIndex(_grad_v) i = 0; i < _nvar; ++i)
{
_grad_v[i] = &coupledGradient("v", i);
_stress[i] /= _op_range[i];
}
}
TwoPhaseFluidProperties::TwoPhaseFluidProperties(const InputParameters & parameters)
: FluidProperties(parameters),
_liquid_name(isParamValid("fp_liquid") ? getParam<UserObjectName>("fp_liquid")
: UserObjectName(name() + ":liquid")),
_vapor_name(isParamValid("fp_vapor") ? getParam<UserObjectName>("fp_vapor")
: UserObjectName(name() + ":vapor"))
{
// If the single-phase fluid properties user object names are not provided, it
// is implied that these objects will be created by a derived class. In this
// case, we need to check that these user objects do not already exist.
if (!isParamValid("fp_liquid"))
if (_fe_problem.hasUserObject(_liquid_name))
paramError("fp_liquid",
"The two-phase fluid properties object '" + name() + "' is ",
"trying to create a single-phase fluid properties object with ",
"name '",
_liquid_name,
"', but a single-phase fluid properties ",
"object with this name already exists.");
if (!isParamValid("fp_vapor"))
if (_fe_problem.hasUserObject(_vapor_name))
paramError("fp_vapor",
"The two-phase fluid properties object '" + name() + "' is ",
"trying to create a single-phase fluid properties object with ",
"name '",
_vapor_name,
"', but a single-phase fluid properties ",
"object with this name already exists.");
}
GlobalDisplacementAux::GlobalDisplacementAux(const InputParameters & parameters)
: AuxKernel(parameters),
_scalar_global_strain(coupledScalarValue("scalar_global_strain")),
_component(getParam<unsigned int>("component")),
_output_global_disp(getParam<bool>("output_global_displacement")),
_pst(getUserObject<GlobalStrainUserObjectInterface>("global_strain_uo")),
_periodic_dir(_pst.getPeriodicDirections()),
_dim(_mesh.dimension()),
_ndisp(coupledComponents("displacements")),
_disp(_ndisp)
{
if (!isNodal())
paramError("variable", "GlobalDisplacementAux must be used on a nodal auxiliary variable");
if (_component >= _dim)
paramError("component",
"The component ",
_component,
" does not exist for ",
_dim,
" dimensional problems");
for (unsigned int i = 0; i < _ndisp; ++i)
_disp[i] = &coupledValue("displacements", i);
}
Kernel::Kernel(const InputParameters & parameters)
: KernelBase(parameters),
MooseVariableInterface<Real>(this, false),
_var(*mooseVariable()),
_test(_var.phi()),
_grad_test(_var.gradPhi()),
_phi(_assembly.phi(_var)),
_grad_phi(_assembly.gradPhi(_var)),
_u(_is_implicit ? _var.sln() : _var.slnOld()),
_grad_u(_is_implicit ? _var.gradSln() : _var.gradSlnOld()),
_u_dot(_var.uDot()),
_du_dot_du(_var.duDotDu())
{
addMooseVariableDependency(mooseVariable());
_save_in.resize(_save_in_strings.size());
_diag_save_in.resize(_diag_save_in_strings.size());
for (unsigned int i = 0; i < _save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _save_in_strings[i]);
if (_fe_problem.getNonlinearSystemBase().hasVariable(_save_in_strings[i]))
paramError("save_in", "cannot use solution variable as save-in variable");
if (var->feType() != _var.feType())
paramError(
"save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_save_in[i] = var;
var->sys().addVariableToZeroOnResidual(_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_save_in = _save_in.size() > 0;
for (unsigned int i = 0; i < _diag_save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _diag_save_in_strings[i]);
if (_fe_problem.getNonlinearSystemBase().hasVariable(_diag_save_in_strings[i]))
paramError("diag_save_in", "cannot use solution variable as diag save-in variable");
if (var->feType() != _var.feType())
paramError(
"diag_save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_diag_save_in[i] = var;
var->sys().addVariableToZeroOnJacobian(_diag_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_diag_save_in = _diag_save_in.size() > 0;
}
ADIntegratedBCTempl<T, compute_stage>::ADIntegratedBCTempl(const InputParameters & parameters)
: IntegratedBCBase(parameters),
MooseVariableInterface<T>(this,
false,
"variable",
Moose::VarKindType::VAR_NONLINEAR,
std::is_same<T, Real>::value ? Moose::VarFieldType::VAR_FIELD_STANDARD
: Moose::VarFieldType::VAR_FIELD_VECTOR),
_var(*this->mooseVariable()),
_normals(_assembly.adNormals<compute_stage>()),
_ad_q_points(_assembly.adQPointsFace<compute_stage>()),
_test(_var.phiFace()),
_grad_test(_var.template adGradPhiFace<compute_stage>()),
_u(_var.template adSln<compute_stage>()),
_grad_u(_var.template adGradSln<compute_stage>()),
_ad_JxW(_assembly.adJxWFace<compute_stage>())
{
addMooseVariableDependency(this->mooseVariable());
_save_in.resize(_save_in_strings.size());
_diag_save_in.resize(_diag_save_in_strings.size());
for (unsigned int i = 0; i < _save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_save_in[i] = var;
var->sys().addVariableToZeroOnResidual(_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_save_in = _save_in.size() > 0;
for (unsigned int i = 0; i < _diag_save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _diag_save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"diag_save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_diag_save_in[i] = var;
var->sys().addVariableToZeroOnJacobian(_diag_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_diag_save_in = _diag_save_in.size() > 0;
}
IntegratedBC::IntegratedBC(const InputParameters & parameters)
: IntegratedBCBase(parameters),
MooseVariableInterface<Real>(this,
false,
"variable",
Moose::VarKindType::VAR_NONLINEAR,
Moose::VarFieldType::VAR_FIELD_STANDARD),
_var(*mooseVariable()),
_normals(_var.normals()),
_phi(_assembly.phiFace(_var)),
_grad_phi(_assembly.gradPhiFace(_var)),
_test(_var.phiFace()),
_grad_test(_var.gradPhiFace()),
_u(_is_implicit ? _var.sln() : _var.slnOld()),
_grad_u(_is_implicit ? _var.gradSln() : _var.gradSlnOld())
{
addMooseVariableDependency(mooseVariable());
_save_in.resize(_save_in_strings.size());
_diag_save_in.resize(_diag_save_in_strings.size());
for (unsigned int i = 0; i < _save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_save_in[i] = var;
var->sys().addVariableToZeroOnResidual(_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_save_in = _save_in.size() > 0;
for (unsigned int i = 0; i < _diag_save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _diag_save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"diag_save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_diag_save_in[i] = var;
var->sys().addVariableToZeroOnJacobian(_diag_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_diag_save_in = _diag_save_in.size() > 0;
}
NodalBC::NodalBC(const InputParameters & parameters)
: NodalBCBase(parameters),
MooseVariableInterface<Real>(this,
true,
"variable",
Moose::VarKindType::VAR_NONLINEAR,
Moose::VarFieldType::VAR_FIELD_STANDARD),
_var(*mooseVariable()),
_current_node(_var.node()),
_u(_var.dofValues())
{
addMooseVariableDependency(mooseVariable());
_save_in.resize(_save_in_strings.size());
_diag_save_in.resize(_diag_save_in_strings.size());
for (unsigned int i = 0; i < _save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_save_in[i] = var;
var->sys().addVariableToZeroOnResidual(_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_save_in = _save_in.size() > 0;
for (unsigned int i = 0; i < _diag_save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _diag_save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"diag_save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_diag_save_in[i] = var;
var->sys().addVariableToZeroOnJacobian(_diag_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_diag_save_in = _diag_save_in.size() > 0;
}
PorousFlowNearestQp::PorousFlowNearestQp(const InputParameters & parameters)
: PorousFlowMaterial(parameters),
_nearest_qp(declareProperty<unsigned>("PorousFlow_nearestqp_nodal"))
{
if (getParam<bool>("nodal_material") == false)
paramError("nodal_material", "This must be a nodal material!");
}
void
PolycrystalUserObjectBase::assignOpsToGrains()
{
mooseAssert(_is_master, "This routine should only be called on the master rank");
Moose::perf_log.push("assignOpsToGrains()", "PolycrystalICTools");
// Use a simple backtracking coloring algorithm
if (_coloring_algorithm == "bt")
{
paramInfo("coloring_algorithm",
"The backtracking algorithm has exponential complexity. If you are using very few "
"order parameters, or you have several hundred grains or more, you should use one of "
"the PETSc coloring algorithms such as \"jp\".");
if (!colorGraph(0))
paramError("op_num",
"Unable to find a valid grain to op coloring, Make sure you have created enough "
"variables to hold a valid polycrystal initial condition (no grains represented "
"by the same variable should be allowed to touch, ~8 for 2D, ~25 for 3D)?");
}
else // PETSc Coloring algorithms
{
#ifdef LIBMESH_HAVE_PETSC
const std::string & ca_str = _coloring_algorithm;
Real * am_data = _adjacency_matrix->get_values().data();
try
{
Moose::PetscSupport::colorAdjacencyMatrix(
am_data, _feature_count, _vars.size(), _grain_to_op, ca_str.c_str());
}
catch (std::runtime_error & e)
{
paramError("op_num",
"Unable to find a valid grain to op coloring, Make sure you have created enough "
"variables to hold a valid polycrystal initial condition (no grains represented "
"by the same variable should be allowed to touch, ~8 for 2D, ~25 for 3D)?");
}
#else
mooseError("Selected coloring algorithm requires PETSc");
#endif
}
Moose::perf_log.pop("assignOpsToGrains()", "PolycrystalICTools");
}
PorousFlowHeatEnergy::PorousFlowHeatEnergy(const InputParameters & parameters)
: ElementIntegralPostprocessor(parameters),
_dictator(getUserObject<PorousFlowDictator>("PorousFlowDictator")),
_num_phases(_dictator.numPhases()),
_fluid_present(_num_phases > 0),
_include_porous_skeleton(getParam<bool>("include_porous_skeleton")),
_phase_index(getParam<std::vector<unsigned int>>("phase")),
_porosity(getMaterialProperty<Real>("PorousFlow_porosity_nodal")),
_rock_energy_nodal(getMaterialProperty<Real>("PorousFlow_matrix_internal_energy_nodal")),
_fluid_density(_fluid_present ? &getMaterialProperty<std::vector<Real>>(
"PorousFlow_fluid_phase_density_nodal")
: nullptr),
_fluid_saturation_nodal(
_fluid_present ? &getMaterialProperty<std::vector<Real>>("PorousFlow_saturation_nodal")
: nullptr),
_energy_nodal(_fluid_present ? &getMaterialProperty<std::vector<Real>>(
"PorousFlow_fluid_phase_internal_energy_nodal")
: nullptr),
_var(getParam<unsigned>("kernel_variable_number") < _dictator.numVariables()
? _dictator.getCoupledStandardMooseVars()[getParam<unsigned>("kernel_variable_number")]
: nullptr)
{
if (!_phase_index.empty())
{
// Check that the phase indices entered are not greater than the number of phases
const unsigned int max_phase_num = *std::max_element(_phase_index.begin(), _phase_index.end());
if (max_phase_num > _num_phases - 1)
paramError("phase",
"The Dictator proclaims that the phase index ",
max_phase_num,
" is greater than the largest phase index possible, which is ",
_num_phases - 1);
}
// Check that kernel_variable_number is OK
if (getParam<unsigned>("kernel_variable_number") >= _dictator.numVariables())
paramError("kernel_variable_number",
"The Dictator pronounces that the number of PorousFlow variables is ",
_dictator.numVariables(),
", however you have used ",
getParam<unsigned>("kernel_variable_number"),
". This is an error");
}
void
BimodalInverseSuperellipsoidsIC::initialSetup()
{
if (_size_variation_type == 2 && _size_variation > 0.0)
paramError("size_variation",
"If size_variation > 0.0, you must pass in a size_variation_type in "
"BimodalInverseSuperellipsoidsIC");
BimodalSuperellipsoidsIC::initialSetup();
}
MultiAppNearestNodeTransfer::MultiAppNearestNodeTransfer(const InputParameters & parameters)
: MultiAppFieldTransfer(parameters),
_fixed_meshes(getParam<bool>("fixed_meshes")),
_node_map(declareRestartableData<std::map<dof_id_type, Node *>>("node_map")),
_distance_map(declareRestartableData<std::map<dof_id_type, Real>>("distance_map")),
_neighbors_cached(declareRestartableData<bool>("neighbors_cached", false)),
_cached_froms(declareRestartableData<std::vector<std::vector<unsigned int>>>("cached_froms")),
_cached_dof_ids(
declareRestartableData<std::vector<std::vector<dof_id_type>>>("cached_dof_ids")),
_cached_from_inds(
declareRestartableData<std::map<dof_id_type, unsigned int>>("cached_from_ids")),
_cached_qp_inds(declareRestartableData<std::map<dof_id_type, unsigned int>>("cached_qp_inds"))
{
if (_to_var_names.size() != 1)
paramError("variable", " Support single to-variable only");
if (_from_var_names.size() != 1)
paramError("source_variable", " Support single from-variable only");
}
AdvectionBC::AdvectionBC(const InputParameters & parameters)
: IntegratedBC(parameters), _dim(_mesh.dimension()), _outflow(getParam<bool>("outflow"))
{
// check if # components matches mesh's dim
if (_dim != coupledComponents("velocity_vector"))
paramError("velocity_vector",
"Number of components of velocity_vector must match mesh dimension");
_velocity.resize(_dim);
for (unsigned int j = 0; j < _dim; ++j)
_velocity[j] = &coupledValue("velocity_vector", j);
}
ACGrGrMulti::ACGrGrMulti(const InputParameters & parameters)
: ACGrGrBase(parameters),
_gamma_names(getParam<std::vector<MaterialPropertyName>>("gamma_names")),
_num_j(_gamma_names.size()),
_prop_gammas(_num_j)
{
// check passed in parameter vectors
if (_num_j != coupledComponents("v"))
paramError("gamma_names",
"Need to pass in as many gamma_names as coupled variables in v in ACGrGrMulti");
for (unsigned int n = 0; n < _num_j; ++n)
_prop_gammas[n] = &getMaterialPropertyByName<Real>(_gamma_names[n]);
}
NodalEqualValueConstraint::NodalEqualValueConstraint(const InputParameters & parameters)
: NodalScalarKernel(parameters)
{
if (_node_ids.size() != 2)
paramError("boundary", "invalid number of nodes: want 2, got ", _node_ids.size());
unsigned int n = coupledComponents("var");
_value.resize(n);
_val_number.resize(n);
for (unsigned int k = 0; k < n; k++)
{
_value[k] = &coupledValue("var", k);
_val_number[k] = coupled("var", k);
}
}
SmoothCircleBaseIC::SmoothCircleBaseIC(const InputParameters & parameters)
: InitialCondition(parameters),
_mesh(_fe_problem.mesh()),
_invalue(parameters.get<Real>("invalue")),
_outvalue(parameters.get<Real>("outvalue")),
_int_width(parameters.get<Real>("int_width")),
_3D_spheres(parameters.get<bool>("3D_spheres")),
_zero_gradient(parameters.get<bool>("zero_gradient")),
_num_dim(_3D_spheres ? 3 : 2),
_profile(getParam<MooseEnum>("profile").getEnum<ProfileType>())
{
_random.seed(_tid, getParam<unsigned int>("rand_seed"));
if (_int_width <= 0.0 && _profile == ProfileType::TANH)
paramError("int_width",
"Interface width has to be strictly positive for the hyperbolic tangent profile");
}
void
MultiAppCopyTransfer::transfer(FEProblemBase & to_problem, FEProblemBase & from_problem)
{
// Populate the to/from variables needed to perform the transfer
MooseVariableFE & to_var = to_problem.getVariable(0, _to_var_name);
MeshBase & to_mesh = to_problem.mesh().getMesh();
MooseVariableFE & from_var = from_problem.getVariable(0, _from_var_name);
MeshBase & from_mesh = from_problem.mesh().getMesh();
// Check integrity
if (to_var.feType() != from_var.feType())
paramError("variable",
"'variable' and 'source_variable' must be the same type (order and family): ",
libMesh::Utility::enum_to_string<FEFamily>(to_var.feType().family),
moose::internal::incompatVarMsg(to_var, from_var));
if ((to_mesh.n_nodes() != from_mesh.n_nodes()) || (to_mesh.n_elem() != from_mesh.n_elem()))
mooseError("The meshes must be identical to utilize MultiAppCopyTransfer.");
// Transfer node dofs
MeshBase::const_node_iterator node_it = to_mesh.local_nodes_begin();
MeshBase::const_node_iterator node_end = to_mesh.local_nodes_end();
for (; node_it != node_end; ++node_it)
transferDofObject(*node_it, from_mesh.node_ptr((*node_it)->id()), to_var, from_var);
// Transfer elem dofs
MeshBase::const_element_iterator elem_it = to_mesh.local_elements_begin();
MeshBase::const_element_iterator elem_end = to_mesh.local_elements_end();
Elem * to_elem;
Elem * from_elem;
for (; elem_it != elem_end; ++elem_it)
{
to_elem = *elem_it;
from_elem = from_mesh.elem_ptr(to_elem->id());
mooseAssert(to_elem->type() == from_elem->type(), "The elements must be the same type.");
transferDofObject(to_elem, from_elem, to_var, from_var);
}
to_var.sys().solution().close();
to_var.sys().update();
}
PorousFlowVolumetricStrain::PorousFlowVolumetricStrain(const InputParameters & parameters)
: PorousFlowMaterialVectorBase(parameters),
_consistent(getParam<bool>("consistent_with_displaced_mesh")),
_ndisp(coupledComponents("displacements")),
_disp(3),
_disp_var_num(3),
_grad_disp(3),
_grad_disp_old(3),
_vol_strain_rate_qp(declareProperty<Real>("PorousFlow_volumetric_strain_rate_qp")),
_dvol_strain_rate_qp_dvar(
declareProperty<std::vector<RealGradient>>("dPorousFlow_volumetric_strain_rate_qp_dvar")),
_vol_total_strain_qp(declareProperty<Real>("PorousFlow_total_volumetric_strain_qp")),
_dvol_total_strain_qp_dvar(
declareProperty<std::vector<RealGradient>>("dPorousFlow_total_volumetric_strain_qp_dvar"))
{
if (_ndisp != _mesh.dimension())
paramError("displacements", "The number of variables supplied must match the mesh dimension.");
// fetch coupled variables and gradients (as stateful properties if necessary)
for (unsigned int i = 0; i < _ndisp; ++i)
{
_disp[i] = &coupledValue("displacements", i);
_disp_var_num[i] = coupled("displacements", i);
_grad_disp[i] = &coupledGradient("displacements", i);
_grad_disp_old[i] = &coupledGradientOld("displacements", i);
}
// set unused dimensions to zero
for (unsigned i = _ndisp; i < 3; ++i)
{
_disp[i] = &_zero;
_disp_var_num[i] = 0;
while (_dictator.isPorousFlowVariable(_disp_var_num[i]))
_disp_var_num[i]++; // increment until disp_var_num[i] is not a porflow var
_grad_disp[i] = &_grad_zero;
_grad_disp_old[i] = &_grad_zero;
}
if (_nodal_material == true)
mooseError("PorousFlowVolumetricStrain classes are only defined for at_nodes = false");
}
NodalKernel::NodalKernel(const InputParameters & parameters)
: MooseObject(parameters),
BlockRestrictable(this),
BoundaryRestrictable(this, true), // true for applying to nodesets
SetupInterface(this),
FunctionInterface(this),
UserObjectInterface(this),
TransientInterface(this),
PostprocessorInterface(this),
GeometricSearchInterface(this),
Restartable(this, "BCs"),
MeshChangedInterface(parameters),
RandomInterface(parameters,
*parameters.getCheckedPointerParam<FEProblemBase *>("_fe_problem_base"),
parameters.get<THREAD_ID>("_tid"),
true),
CoupleableMooseVariableDependencyIntermediateInterface(this, true),
MooseVariableInterface<Real>(this,
true,
"variable",
Moose::VarKindType::VAR_NONLINEAR,
Moose::VarFieldType::VAR_FIELD_STANDARD),
TaggingInterface(this),
_subproblem(*getCheckedPointerParam<SubProblem *>("_subproblem")),
_fe_problem(*getCheckedPointerParam<FEProblemBase *>("_fe_problem_base")),
_sys(*getCheckedPointerParam<SystemBase *>("_sys")),
_tid(parameters.get<THREAD_ID>("_tid")),
_assembly(_subproblem.assembly(_tid)),
_var(*mooseVariable()),
_mesh(_subproblem.mesh()),
_current_node(_var.node()),
_u(_var.dofValues()),
_save_in_strings(parameters.get<std::vector<AuxVariableName>>("save_in")),
_diag_save_in_strings(parameters.get<std::vector<AuxVariableName>>("diag_save_in"))
{
_save_in.resize(_save_in_strings.size());
_diag_save_in.resize(_diag_save_in_strings.size());
for (unsigned int i = 0; i < _save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_save_in[i] = var;
var->sys().addVariableToZeroOnResidual(_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_save_in = _save_in.size() > 0;
for (unsigned int i = 0; i < _diag_save_in_strings.size(); i++)
{
MooseVariable * var = &_subproblem.getStandardVariable(_tid, _diag_save_in_strings[i]);
if (var->feType() != _var.feType())
paramError(
"diag_save_in",
"saved-in auxiliary variable is incompatible with the object's nonlinear variable: ",
moose::internal::incompatVarMsg(*var, _var));
_diag_save_in[i] = var;
var->sys().addVariableToZeroOnJacobian(_diag_save_in_strings[i]);
addMooseVariableDependency(var);
}
_has_diag_save_in = _diag_save_in.size() > 0;
}
