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RandomIC Class Reference

RandomIC just returns a Random value. More...

#include <RandomIC.h>

Inheritance diagram for RandomIC:
[legend]

Public Types

enum  TEST_TYPE { ALL, ANY }
 A flag changing the behavior of hasBoundary. More...
 

Public Member Functions

 RandomIC (const InputParameters &parameters)
 Constructor. More...
 
virtual Real value (const Point &p) override
 The value of the variable at a point. More...
 
MooseVariablevariable ()
 
const std::set< std::string > & getDependObjects () const
 
virtual void compute ()
 
virtual RealGradient gradient (const Point &)
 The gradient of the variable at a point. More...
 
virtual void initialSetup ()
 Gets called at the beginning of the simulation before this object is asked to do its job. More...
 
virtual const std::set< std::string > & getRequestedItems () override
 Return a set containing the names of items requested by the object. More...
 
virtual const std::set< std::string > & getSuppliedItems () override
 Return a set containing the names of items owned by the object. More...
 
template<typename T >
const T & getUserObject (const std::string &name)
 
template<typename T >
const T & getUserObjectByName (const UserObjectName &name)
 
template<class T >
const T & getUserObjectByName (const std::string &name)
 Get an user object with a given name. More...
 
const UserObjectgetUserObjectBase (const std::string &name)
 
const std::string & name () const
 Get the name of the object. More...
 
const InputParametersparameters () const
 Get the parameters of the object. More...
 
template<typename T >
const T & getParam (const std::string &name) const
 Retrieve a parameter for the object. More...
 
bool isParamValid (const std::string &name) const
 Test if the supplied parameter is valid. More...
 
MooseAppgetMooseApp ()
 Get the MooseApp this object is associated with. More...
 
virtual bool enabled ()
 Return the enabled status of the object. More...
 
template<typename... Args>
void mooseError (Args &&...args) const
 
template<typename... Args>
void mooseWarning (Args &&...args) const
 
template<typename... Args>
void mooseDeprecated (Args &&...args) const
 
template<typename... Args>
void mooseInfo (Args &&...args) const
 
const std::vector< SubdomainName > & blocks () const
 Return the block names for this object. More...
 
unsigned int numBlocks () const
 Return the number of blocks for this object. More...
 
virtual const std::set< SubdomainID > & blockIDs () const
 Return the block subdomain ids for this object. More...
 
bool hasBlocks (const SubdomainName &name) const
 Test if the supplied block name is valid for this object. More...
 
bool hasBlocks (const std::vector< SubdomainName > &names) const
 Test if the supplied vector of block names are valid for this object. More...
 
bool hasBlocks (const SubdomainID &id) const
 Test if the supplied block ids are valid for this object. More...
 
bool hasBlocks (const std::vector< SubdomainID > &ids) const
 Test if the supplied vector block ids are valid for this object. More...
 
bool hasBlocks (const std::set< SubdomainID > &ids) const
 Test if the supplied set of block ids are valid for this object. More...
 
bool isBlockSubset (const std::set< SubdomainID > &ids) const
 Test if the class block ids are a subset of the supplied objects. More...
 
bool isBlockSubset (const std::vector< SubdomainID > &ids) const
 Test if the class block ids are a subset of the supplied objects. More...
 
template<typename T >
bool hasBlockMaterialProperty (const std::string &prop_name)
 Check if a material property is valid for all blocks of this object. More...
 
const std::set< SubdomainID > & meshBlockIDs () const
 Return all of the SubdomainIDs for the mesh. More...
 
virtual bool blockRestricted () const
 Returns true if this object has been restricted to a boundary. More...
 
void checkVariable (const MooseVariable &variable) const
 Helper for checking that the ids for this object are in agreement with the variables on the supplied variable. More...
 
const std::map< std::string, std::vector< MooseVariable * > > & getCoupledVars ()
 Get the list of coupled variables. More...
 
const std::vector< MooseVariable * > & getCoupledMooseVars () const
 Get the list of coupled variables. More...
 
FunctiongetFunction (const std::string &name)
 Get a function with a given name. More...
 
FunctiongetFunctionByName (const FunctionName &name)
 Get a function with a given name. More...
 
const UserObjectgetUserObjectBaseByName (const std::string &name)
 Get an user object with a given name. More...
 
virtual const std::set< BoundaryID > & boundaryIDs () const
 Return the boundary IDs for this object. More...
 
const std::vector< BoundaryName > & boundaryNames () const
 Return the boundary names for this object. More...
 
unsigned int numBoundaryIDs () const
 Return the number of boundaries for this object. More...
 
bool hasBoundary (const BoundaryName &name) const
 Test if the supplied boundary name is valid for this object. More...
 
bool hasBoundary (const std::vector< BoundaryName > &names) const
 Test if the supplied vector of boundary names are valid for this object. More...
 
bool hasBoundary (const BoundaryID &id) const
 Test if the supplied boundary ids are valid for this object. More...
 
bool hasBoundary (const std::vector< BoundaryID > &ids, TEST_TYPE type=ALL) const
 Test if the supplied vector boundary ids are valid for this object. More...
 
bool hasBoundary (const std::set< BoundaryID > &ids, TEST_TYPE type=ALL) const
 Test if the supplied set of boundary ids are valid for this object. More...
 
bool isBoundarySubset (const std::set< BoundaryID > &ids) const
 Test if the class boundary ids are a subset of the supplied objects. More...
 
bool isBoundarySubset (const std::vector< BoundaryID > &ids) const
 
template<typename T >
bool hasBoundaryMaterialProperty (const std::string &prop_name) const
 Check if a material property is valid for all boundaries of this object. More...
 
virtual bool boundaryRestricted () const
 Returns true if this object has been restricted to a boundary. More...
 
const std::set< BoundaryID > & meshBoundaryIDs () const
 Returns the set of all boundary ids for the entire mesh. More...
 

Static Public Member Functions

static bool restricted (const std::set< BoundaryID > &ids)
 Helper for determining if the object is boundary restricted. More...
 
template<typename T >
static void sort (typename std::vector< T > &vector)
 Given a vector, sort using the getRequested/SuppliedItems sets. More...
 
template<typename T >
static void cyclicDependencyError (CyclicDependencyException< T > &e, const std::string &header)
 A helper method for cyclic errors. More...
 

Public Attributes

const ConsoleStream _console
 An instance of helper class to write streams to the Console objects. More...
 

Protected Member Functions

virtual bool hasBlockMaterialPropertyHelper (const std::string &prop_name)
 A helper method to allow the Material object to specialize the behavior of hasBlockMaterialProperty. More...
 
void initializeBlockRestrictable (const MooseObject *moose_object)
 An initialization routine needed for dual constructors. More...
 
Moose::CoordinateSystemType getBlockCoordSystem ()
 Check if the blocks this object operates on all have the same coordinate system, and if so return it. More...
 
virtual bool isCoupled (const std::string &var_name, unsigned int i=0)
 Returns true if a variables has been coupled as name. More...
 
unsigned int coupledComponents (const std::string &var_name)
 Number of coupled components. More...
 
virtual void coupledCallback (const std::string &var_name, bool is_old)
 
virtual unsigned int coupled (const std::string &var_name, unsigned int comp=0)
 Returns the index for a coupled variable by name. More...
 
virtual const VariableValuecoupledValue (const std::string &var_name, unsigned int comp=0)
 Returns value of a coupled variable. More...
 
virtual VariableValuewritableCoupledValue (const std::string &var_name, unsigned int comp=0)
 Returns a writable reference to a coupled variable. More...
 
virtual const VariableValuecoupledValueOld (const std::string &var_name, unsigned int comp=0)
 Returns an old value from previous time step of a coupled variable. More...
 
virtual const VariableValuecoupledValueOlder (const std::string &var_name, unsigned int comp=0)
 Returns an old value from two time steps previous of a coupled variable. More...
 
virtual const VariableValuecoupledValuePreviousNL (const std::string &var_name, unsigned int comp=0)
 Returns value of previous Newton iterate of a coupled variable. More...
 
virtual const VariableGradientcoupledGradient (const std::string &var_name, unsigned int comp=0)
 Returns gradient of a coupled variable. More...
 
virtual const VariableGradientcoupledGradientOld (const std::string &var_name, unsigned int comp=0)
 Returns an old gradient from previous time step of a coupled variable. More...
 
virtual const VariableGradientcoupledGradientOlder (const std::string &var_name, unsigned int comp=0)
 Returns an old gradient from two time steps previous of a coupled variable. More...
 
virtual const VariableGradientcoupledGradientPreviousNL (const std::string &var_name, unsigned int comp=0)
 Returns gradient of a coupled variable for previous Newton iterate. More...
 
virtual const VariableSecondcoupledSecond (const std::string &var_name, unsigned int comp=0)
 Returns second derivative of a coupled variable. More...
 
virtual const VariableSecondcoupledSecondOld (const std::string &var_name, unsigned int comp=0)
 Returns an old second derivative from previous time step of a coupled variable. More...
 
virtual const VariableSecondcoupledSecondOlder (const std::string &var_name, unsigned int comp=0)
 Returns an old second derivative from two time steps previous of a coupled variable. More...
 
virtual const VariableSecondcoupledSecondPreviousNL (const std::string &var_name, unsigned int comp=0)
 Returns second derivative of a coupled variable for the previous Newton iterate. More...
 
virtual const VariableValuecoupledDot (const std::string &var_name, unsigned int comp=0)
 Time derivative of a coupled variable. More...
 
virtual const VariableValuecoupledDotDu (const std::string &var_name, unsigned int comp=0)
 Time derivative of a coupled variable with respect to the coefficients. More...
 
virtual const VariableValuecoupledNodalValue (const std::string &var_name, unsigned int comp=0)
 Returns nodal values of a coupled variable. More...
 
virtual const VariableValuecoupledNodalValueOld (const std::string &var_name, unsigned int comp=0)
 Returns an old nodal value from previous time step of a coupled variable. More...
 
virtual const VariableValuecoupledNodalValueOlder (const std::string &var_name, unsigned int comp=0)
 Returns an old nodal value from two time steps previous of a coupled variable. More...
 
virtual const VariableValuecoupledNodalValuePreviousNL (const std::string &var_name, unsigned int comp=0)
 Returns nodal values of a coupled variable for previous Newton iterate. More...
 
virtual const VariableValuecoupledNodalDot (const std::string &var_name, unsigned int comp=0)
 Nodal values of time derivative of a coupled variable. More...
 
virtual const DenseVector< Number > & coupledSolutionDoFs (const std::string &var_name, unsigned int comp=0)
 Returns DoFs in the current solution vector of a coupled variable for the local element. More...
 
virtual const DenseVector< Number > & coupledSolutionDoFsOld (const std::string &var_name, unsigned int comp=0)
 Returns DoFs in the old solution vector of a coupled variable for the local element. More...
 
virtual const DenseVector< Number > & coupledSolutionDoFsOlder (const std::string &var_name, unsigned int comp=0)
 Returns DoFs in the older solution vector of a coupled variable for the local element. More...
 
MooseVariablegetVar (const std::string &var_name, unsigned int comp)
 Extract pointer to a coupled variable. More...
 
void validateExecutionerType (const std::string &name) const
 Checks to make sure that the current Executioner has set "_it_transient" when old/older values are coupled in. More...
 
bool hasBoundaryMaterialPropertyHelper (const std::string &prop_name) const
 A helper method to avoid circular #include problems. More...
 
template<typename T >
T & declareRestartableData (std::string data_name)
 Declare a piece of data as "restartable". More...
 
template<typename T >
T & declareRestartableData (std::string data_name, const T &init_value)
 Declare a piece of data as "restartable" and initialize it. More...
 
template<typename T >
T & declareRestartableDataWithContext (std::string data_name, void *context)
 Declare a piece of data as "restartable". More...
 
template<typename T >
T & declareRestartableDataWithContext (std::string data_name, const T &init_value, void *context)
 Declare a piece of data as "restartable" and initialize it. More...
 

Protected Attributes

Real _min
 
Real _max
 
Real _range
 
FEProblemBase_fe_problem
 
SystemBase_sys
 
THREAD_ID _tid
 
Assembly_assembly
 
Real & _t
 Time. More...
 
const Moose::CoordinateSystemType_coord_sys
 The coordinate system type for this problem, references the value in Assembly. More...
 
MooseVariable_var
 The variable that this initial condition is acting upon. More...
 
const Elem *& _current_elem
 The current element we are on will retrieving values at specific points in the domain. More...
 
const Node * _current_node
 The current node if the point we are evaluating at also happens to be a node. More...
 
unsigned int _qp
 The current quadrature point, contains the "nth" node number when visiting nodes. More...
 
std::set< std::string > _depend_vars
 
std::set< std::string > _supplied_vars
 
std::set< std::string > _depend_uo
 Depend UserObjects. More...
 
const bool _ignore_uo_dependency
 If set, UOs retrieved by this IC will not be executed before this IC. More...
 
MooseApp_app
 The MooseApp this object is associated with. More...
 
const InputParameters_pars
 Parameters of this object, references the InputParameters stored in the InputParametersWarehouse. More...
 
const std::string & _name
 The name of this object, reference to value stored in InputParameters. More...
 
const bool & _enabled
 Reference to the "enable" InputParaemters, used by Controls for toggling on/off MooseObjects. More...
 
std::shared_ptr< MaterialData_blk_material_data
 Pointer to the MaterialData class for this object. More...
 
const InputParameters_c_parameters
 
FEProblemBase_c_fe_problem
 
std::map< std::string, std::vector< MooseVariable * > > _coupled_vars
 Coupled vars whose values we provide. More...
 
std::vector< MooseVariable * > _coupled_moose_vars
 Vector of coupled variables. More...
 
bool _c_nodal
 True if we provide coupling to nodal values. More...
 
bool _c_is_implicit
 True if implicit value is required. More...
 
const InputParameters_coupleable_params
 Local InputParameters. More...
 
std::map< std::string, VariableValue * > _default_value
 Will hold the default value for optional coupled variables. More...
 
VariableValue _default_value_zero
 This will always be zero because the default values for optionally coupled variables is always constant and this is used for time derivative info. More...
 
VariableGradient _default_gradient
 This will always be zero because the default values for optionally coupled variables is always constant. More...
 
VariableSecond _default_second
 This will always be zero because the default values for optionally coupled variables is always constant. More...
 
bool _coupleable_neighbor
 Whether or not this object is a "neighbor" object: ie all of it's coupled values should be neighbor values. More...
 
FEProblemBase_zi_feproblem
 
THREAD_ID _zi_tid
 
const Real & _real_zero
 
const VariableValue_zero
 
const VariableGradient_grad_zero
 
const VariableSecond_second_zero
 
const VariablePhiSecond_second_phi_zero
 

Detailed Description

RandomIC just returns a Random value.

Definition at line 40 of file RandomIC.h.

Member Enumeration Documentation

A flag changing the behavior of hasBoundary.

Enumerator
ALL 
ANY 

Definition at line 40 of file BoundaryRestrictable.h.

Constructor & Destructor Documentation

RandomIC::RandomIC ( const InputParameters parameters)

Constructor.

Parameters
parametersThe parameters object holding data for the class to use.

Definition at line 31 of file RandomIC.C.

32  : InitialCondition(parameters),
33  _min(getParam<Real>("min")),
34  _max(getParam<Real>("max")),
35  _range(_max - _min)
36 {
37  mooseAssert(_range > 0.0, "Min > Max for RandomIC!");
38  MooseRandom::seed(getParam<unsigned int>("seed"));
39 }
Real _max
Definition: RandomIC.h:54
static void seed(unsigned int seed)
The method seeds the random number generator.
Definition: MooseRandom.h:49
InitialCondition(const InputParameters &parameters)
Constructor.
Real _range
Definition: RandomIC.h:55
Real _min
Definition: RandomIC.h:53

Member Function Documentation

const std::set< SubdomainID > & BlockRestrictable::blockIDs ( ) const
virtualinherited

Return the block subdomain ids for this object.

Returns
a set of SudomainIDs that are valid for this object

Definition at line 168 of file BlockRestrictable.C.

Referenced by BlockRestrictable::getBlockCoordSystem(), Material::getZeroMaterialProperty(), BlockRestrictable::hasBlockMaterialPropertyHelper(), Material::registerPropName(), and BlockRestrictable::~BlockRestrictable().

169 {
170  return _blk_ids;
171 }
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
bool BlockRestrictable::blockRestricted ( ) const
virtualinherited

Returns true if this object has been restricted to a boundary.

See also
MooseObject

Definition at line 156 of file BlockRestrictable.C.

Referenced by BlockRestrictable::checkVariable(), BlockRestrictable::getBlockCoordSystem(), BlockRestrictable::hasBlockMaterialPropertyHelper(), and BlockRestrictable::~BlockRestrictable().

157 {
158  return _blk_ids.find(Moose::ANY_BLOCK_ID) == _blk_ids.end();
159 }
const SubdomainID ANY_BLOCK_ID
Definition: MooseTypes.h:117
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
const std::vector< SubdomainName > & BlockRestrictable::blocks ( ) const
inherited

Return the block names for this object.

Note, if the 'blocks' input parameter was not utilized this will return an empty vector.

Returns
vector of SubdomainNames that are valid for this object

Definition at line 162 of file BlockRestrictable.C.

Referenced by BlockRestrictable::~BlockRestrictable().

163 {
164  return _blocks;
165 }
std::vector< SubdomainName > _blocks
Vector the block names supplied by the user via the input file.
const std::set< BoundaryID > & BoundaryRestrictable::boundaryIDs ( ) const
virtualinherited

Return the boundary IDs for this object.

Returns
A set of all boundary ids for which the object is restricted

Definition at line 153 of file BoundaryRestrictable.C.

Referenced by NonlinearSystemBase::addBoundaryCondition(), NonlinearSystemBase::addInterfaceKernel(), AutoPositionsMultiApp::fillPositions(), Material::getZeroMaterialProperty(), BoundaryRestrictable::hasBoundaryMaterialPropertyHelper(), and Material::registerPropName().

154 {
155  return _bnd_ids;
156 }
std::set< BoundaryID > _bnd_ids
Set of the boundary ids.
const std::vector< BoundaryName > & BoundaryRestrictable::boundaryNames ( ) const
inherited

Return the boundary names for this object.

Returns
A set of all boundary names for which the object is restricted

Definition at line 159 of file BoundaryRestrictable.C.

Referenced by NearestNodeDistanceAux::NearestNodeDistanceAux(), and NearestNodeValueAux::NearestNodeValueAux().

160 {
161  return _boundary_names;
162 }
std::vector< BoundaryName > _boundary_names
Vector the the boundary names.
bool BoundaryRestrictable::boundaryRestricted ( ) const
virtualinherited

Returns true if this object has been restricted to a boundary.

See also
MooseObject

Reimplemented in NodalNormalsPreprocessor.

Definition at line 171 of file BoundaryRestrictable.C.

Referenced by DerivativeMaterialInterface< T >::haveMaterialProperty().

172 {
174 }
static bool restricted(const std::set< BoundaryID > &ids)
Helper for determining if the object is boundary restricted.
std::set< BoundaryID > _bnd_ids
Set of the boundary ids.
void BlockRestrictable::checkVariable ( const MooseVariable variable) const
inherited

Helper for checking that the ids for this object are in agreement with the variables on the supplied variable.

Parameters
variableThe variable to check against.

Definition at line 308 of file BlockRestrictable.C.

Referenced by BlockRestrictable::~BlockRestrictable().

309 {
310  if (!isBlockSubset(variable.activeSubdomains()))
311  {
312  std::string var_ids = Moose::stringify(variable.activeSubdomains(), ", ");
313  std::string obj_ids = Moose::stringify(blockRestricted() ? _blk_ids : meshBlockIDs(), ", ");
314  mooseError("The 'block' parameter of the object '",
315  _blk_name,
316  "' must be a subset of the 'block' parameter of the variable '",
317  variable.name(),
318  "':\n Object '",
319  _blk_name,
320  "': ",
321  obj_ids,
322  "\n Variable '",
323  variable.name(),
324  "': ",
325  var_ids);
326  }
327 }
bool isBlockSubset(const std::set< SubdomainID > &ids) const
Test if the class block ids are a subset of the supplied objects.
const std::set< SubdomainID > & meshBlockIDs() const
Return all of the SubdomainIDs for the mesh.
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
const std::string & name() const
Get the variable name.
const std::set< SubdomainID > & activeSubdomains() const
std::string stringify(const T &t)
conversion to string
Definition: Conversion.h:66
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
const std::string & _blk_name
Name of the object.
virtual bool blockRestricted() const
Returns true if this object has been restricted to a boundary.
void InitialCondition::compute ( )
virtualinherited

Definition at line 106 of file InitialCondition.C.

Referenced by InitialCondition::getDependObjects().

107 {
108  // -- NOTE ----
109  // The following code is a copy from libMesh project_vector.C plus it adds some features, so we
110  // can couple variable values
111  // and we also do not call any callbacks, but we use our initial condition system directly.
112  // ------------
113 
114  // The element matrix and RHS for projections.
115  // Note that Ke is always real-valued, whereas Fe may be complex valued if complex number support
116  // is enabled
117  DenseMatrix<Real> Ke;
118  DenseVector<Number> Fe;
119  // The new element coefficients
120  DenseVector<Number> Ue;
121 
122  const FEType & fe_type = _var.feType();
123 
124  // The dimension of the current element
125  const unsigned int dim = _current_elem->dim();
126  // The element type
127  const ElemType elem_type = _current_elem->type();
128  // The number of nodes on the new element
129  const unsigned int n_nodes = _current_elem->n_nodes();
130  // The global DOF indices
131  std::vector<dof_id_type> dof_indices;
132  // Side/edge DOF indices
133  std::vector<unsigned int> side_dofs;
134 
135  // Get FE objects of the appropriate type
136  // We cannot use the FE object in Assembly, since the following code is messing with the
137  // quadrature rules
138  // for projections and would screw it up. However, if we implement projections from one mesh to
139  // another,
140  // this code should use that implementation.
141  std::unique_ptr<FEBase> fe(FEBase::build(dim, fe_type));
142 
143  // Prepare variables for projection
144  std::unique_ptr<QBase> qrule(fe_type.default_quadrature_rule(dim));
145  std::unique_ptr<QBase> qedgerule(fe_type.default_quadrature_rule(1));
146  std::unique_ptr<QBase> qsiderule(fe_type.default_quadrature_rule(dim - 1));
147 
148  // The values of the shape functions at the quadrature points
149  const std::vector<std::vector<Real>> & phi = fe->get_phi();
150 
151  // The gradients of the shape functions at the quadrature points on the child element.
152  const std::vector<std::vector<RealGradient>> * dphi = NULL;
153 
154  const FEContinuity cont = fe->get_continuity();
155 
156  if (cont == C_ONE)
157  {
158  const std::vector<std::vector<RealGradient>> & ref_dphi = fe->get_dphi();
159  dphi = &ref_dphi;
160  }
161 
162  // The Jacobian * quadrature weight at the quadrature points
163  const std::vector<Real> & JxW = fe->get_JxW();
164  // The XYZ locations of the quadrature points
165  const std::vector<Point> & xyz_values = fe->get_xyz();
166 
167  // Update the DOF indices for this element based on the current mesh
168  _var.prepareIC();
169  dof_indices = _var.dofIndices();
170 
171  // The number of DOFs on the element
172  const unsigned int n_dofs = dof_indices.size();
173  if (n_dofs == 0)
174  return;
175 
176  // Fixed vs. free DoFs on edge/face projections
177  std::vector<char> dof_is_fixed(n_dofs, false); // bools
178  std::vector<int> free_dof(n_dofs, 0);
179 
180  // Zero the interpolated values
181  Ue.resize(n_dofs);
182  Ue.zero();
183 
184  // In general, we need a series of
185  // projections to ensure a unique and continuous
186  // solution. We start by interpolating nodes, then
187  // hold those fixed and project edges, then
188  // hold those fixed and project faces, then
189  // hold those fixed and project interiors
190 
191  // Interpolate node values first
192  unsigned int current_dof = 0;
193  for (unsigned int n = 0; n != n_nodes; ++n)
194  {
195  // FIXME: this should go through the DofMap,
196  // not duplicate dof_indices code badly!
197  const unsigned int nc = FEInterface::n_dofs_at_node(dim, fe_type, elem_type, n);
198  if (!_current_elem->is_vertex(n))
199  {
200  current_dof += nc;
201  continue;
202  }
203  if (cont == DISCONTINUOUS)
204  {
205  libmesh_assert(nc == 0);
206  }
207  // Assume that C_ZERO elements have a single nodal
208  // value shape function
209  else if (cont == C_ZERO)
210  {
211  libmesh_assert(nc == 1);
212  _qp = n;
213  _current_node = _current_elem->node_ptr(n);
214  Ue(current_dof) = value(*_current_node);
215  dof_is_fixed[current_dof] = true;
216  current_dof++;
217  }
218  // The hermite element vertex shape functions are weird
219  else if (fe_type.family == HERMITE)
220  {
221  _qp = n;
222  _current_node = _current_elem->node_ptr(n);
223  Ue(current_dof) = value(*_current_node);
224  dof_is_fixed[current_dof] = true;
225  current_dof++;
226  Gradient grad = gradient(*_current_node);
227  // x derivative
228  Ue(current_dof) = grad(0);
229  dof_is_fixed[current_dof] = true;
230  current_dof++;
231  if (dim > 1)
232  {
233  // We'll finite difference mixed derivatives
234  Point nxminus = _current_elem->point(n), nxplus = _current_elem->point(n);
235  nxminus(0) -= TOLERANCE;
236  nxplus(0) += TOLERANCE;
237  Gradient gxminus = gradient(nxminus);
238  Gradient gxplus = gradient(nxplus);
239  // y derivative
240  Ue(current_dof) = grad(1);
241  dof_is_fixed[current_dof] = true;
242  current_dof++;
243  // xy derivative
244  Ue(current_dof) = (gxplus(1) - gxminus(1)) / 2. / TOLERANCE;
245  dof_is_fixed[current_dof] = true;
246  current_dof++;
247 
248  if (dim > 2)
249  {
250  // z derivative
251  Ue(current_dof) = grad(2);
252  dof_is_fixed[current_dof] = true;
253  current_dof++;
254  // xz derivative
255  Ue(current_dof) = (gxplus(2) - gxminus(2)) / 2. / TOLERANCE;
256  dof_is_fixed[current_dof] = true;
257  current_dof++;
258  // We need new points for yz
259  Point nyminus = _current_elem->point(n), nyplus = _current_elem->point(n);
260  nyminus(1) -= TOLERANCE;
261  nyplus(1) += TOLERANCE;
262  Gradient gyminus = gradient(nyminus);
263  Gradient gyplus = gradient(nyplus);
264  // xz derivative
265  Ue(current_dof) = (gyplus(2) - gyminus(2)) / 2. / TOLERANCE;
266  dof_is_fixed[current_dof] = true;
267  current_dof++;
268  // Getting a 2nd order xyz is more tedious
269  Point nxmym = _current_elem->point(n), nxmyp = _current_elem->point(n),
270  nxpym = _current_elem->point(n), nxpyp = _current_elem->point(n);
271  nxmym(0) -= TOLERANCE;
272  nxmym(1) -= TOLERANCE;
273  nxmyp(0) -= TOLERANCE;
274  nxmyp(1) += TOLERANCE;
275  nxpym(0) += TOLERANCE;
276  nxpym(1) -= TOLERANCE;
277  nxpyp(0) += TOLERANCE;
278  nxpyp(1) += TOLERANCE;
279  Gradient gxmym = gradient(nxmym);
280  Gradient gxmyp = gradient(nxmyp);
281  Gradient gxpym = gradient(nxpym);
282  Gradient gxpyp = gradient(nxpyp);
283  Number gxzplus = (gxpyp(2) - gxmyp(2)) / 2. / TOLERANCE;
284  Number gxzminus = (gxpym(2) - gxmym(2)) / 2. / TOLERANCE;
285  // xyz derivative
286  Ue(current_dof) = (gxzplus - gxzminus) / 2. / TOLERANCE;
287  dof_is_fixed[current_dof] = true;
288  current_dof++;
289  }
290  }
291  }
292  // Assume that other C_ONE elements have a single nodal
293  // value shape function and nodal gradient component
294  // shape functions
295  else if (cont == C_ONE)
296  {
297  libmesh_assert(nc == 1 + dim);
298  _current_node = _current_elem->node_ptr(n);
299  Ue(current_dof) = value(*_current_node);
300  dof_is_fixed[current_dof] = true;
301  current_dof++;
302  Gradient grad = gradient(*_current_node);
303  for (unsigned int i = 0; i != dim; ++i)
304  {
305  Ue(current_dof) = grad(i);
306  dof_is_fixed[current_dof] = true;
307  current_dof++;
308  }
309  }
310  else
311  libmesh_error();
312  } // loop over nodes
313 
314  // From here on out we won't be sampling at nodes anymore
315  _current_node = NULL;
316 
317  // In 3D, project any edge values next
318  if (dim > 2 && cont != DISCONTINUOUS)
319  for (unsigned int e = 0; e != _current_elem->n_edges(); ++e)
320  {
321  FEInterface::dofs_on_edge(_current_elem, dim, fe_type, e, side_dofs);
322 
323  // Some edge dofs are on nodes and already
324  // fixed, others are free to calculate
325  unsigned int free_dofs = 0;
326  for (unsigned int i = 0; i != side_dofs.size(); ++i)
327  if (!dof_is_fixed[side_dofs[i]])
328  free_dof[free_dofs++] = i;
329 
330  // There may be nothing to project
331  if (!free_dofs)
332  continue;
333 
334  Ke.resize(free_dofs, free_dofs);
335  Ke.zero();
336  Fe.resize(free_dofs);
337  Fe.zero();
338  // The new edge coefficients
339  DenseVector<Number> Uedge(free_dofs);
340 
341  // Initialize FE data on the edge
342  fe->attach_quadrature_rule(qedgerule.get());
343  fe->edge_reinit(_current_elem, e);
344  const unsigned int n_qp = qedgerule->n_points();
345 
346  // Loop over the quadrature points
347  for (unsigned int qp = 0; qp < n_qp; qp++)
348  {
349  // solution at the quadrature point
350  Number fineval = value(xyz_values[qp]);
351  // solution grad at the quadrature point
352  Gradient finegrad;
353  if (cont == C_ONE)
354  finegrad = gradient(xyz_values[qp]);
355 
356  // Form edge projection matrix
357  for (unsigned int sidei = 0, freei = 0; sidei != side_dofs.size(); ++sidei)
358  {
359  unsigned int i = side_dofs[sidei];
360  // fixed DoFs aren't test functions
361  if (dof_is_fixed[i])
362  continue;
363  for (unsigned int sidej = 0, freej = 0; sidej != side_dofs.size(); ++sidej)
364  {
365  unsigned int j = side_dofs[sidej];
366  if (dof_is_fixed[j])
367  Fe(freei) -= phi[i][qp] * phi[j][qp] * JxW[qp] * Ue(j);
368  else
369  Ke(freei, freej) += phi[i][qp] * phi[j][qp] * JxW[qp];
370  if (cont == C_ONE)
371  {
372  if (dof_is_fixed[j])
373  Fe(freei) -= ((*dphi)[i][qp] * (*dphi)[j][qp]) * JxW[qp] * Ue(j);
374  else
375  Ke(freei, freej) += ((*dphi)[i][qp] * (*dphi)[j][qp]) * JxW[qp];
376  }
377  if (!dof_is_fixed[j])
378  freej++;
379  }
380  Fe(freei) += phi[i][qp] * fineval * JxW[qp];
381  if (cont == C_ONE)
382  Fe(freei) += (finegrad * (*dphi)[i][qp]) * JxW[qp];
383  freei++;
384  }
385  }
386 
387  Ke.cholesky_solve(Fe, Uedge);
388 
389  // Transfer new edge solutions to element
390  for (unsigned int i = 0; i != free_dofs; ++i)
391  {
392  Number & ui = Ue(side_dofs[free_dof[i]]);
393  libmesh_assert(std::abs(ui) < TOLERANCE || std::abs(ui - Uedge(i)) < TOLERANCE);
394  ui = Uedge(i);
395  dof_is_fixed[side_dofs[free_dof[i]]] = true;
396  }
397  }
398 
399  // Project any side values (edges in 2D, faces in 3D)
400  if (dim > 1 && cont != DISCONTINUOUS)
401  for (unsigned int s = 0; s != _current_elem->n_sides(); ++s)
402  {
403  FEInterface::dofs_on_side(_current_elem, dim, fe_type, s, side_dofs);
404 
405  // Some side dofs are on nodes/edges and already
406  // fixed, others are free to calculate
407  unsigned int free_dofs = 0;
408  for (unsigned int i = 0; i != side_dofs.size(); ++i)
409  if (!dof_is_fixed[side_dofs[i]])
410  free_dof[free_dofs++] = i;
411 
412  // There may be nothing to project
413  if (!free_dofs)
414  continue;
415 
416  Ke.resize(free_dofs, free_dofs);
417  Ke.zero();
418  Fe.resize(free_dofs);
419  Fe.zero();
420  // The new side coefficients
421  DenseVector<Number> Uside(free_dofs);
422 
423  // Initialize FE data on the side
424  fe->attach_quadrature_rule(qsiderule.get());
425  fe->reinit(_current_elem, s);
426  const unsigned int n_qp = qsiderule->n_points();
427 
428  // Loop over the quadrature points
429  for (unsigned int qp = 0; qp < n_qp; qp++)
430  {
431  // solution at the quadrature point
432  Number fineval = value(xyz_values[qp]);
433  // solution grad at the quadrature point
434  Gradient finegrad;
435  if (cont == C_ONE)
436  finegrad = gradient(xyz_values[qp]);
437 
438  // Form side projection matrix
439  for (unsigned int sidei = 0, freei = 0; sidei != side_dofs.size(); ++sidei)
440  {
441  unsigned int i = side_dofs[sidei];
442  // fixed DoFs aren't test functions
443  if (dof_is_fixed[i])
444  continue;
445  for (unsigned int sidej = 0, freej = 0; sidej != side_dofs.size(); ++sidej)
446  {
447  unsigned int j = side_dofs[sidej];
448  if (dof_is_fixed[j])
449  Fe(freei) -= phi[i][qp] * phi[j][qp] * JxW[qp] * Ue(j);
450  else
451  Ke(freei, freej) += phi[i][qp] * phi[j][qp] * JxW[qp];
452  if (cont == C_ONE)
453  {
454  if (dof_is_fixed[j])
455  Fe(freei) -= ((*dphi)[i][qp] * (*dphi)[j][qp]) * JxW[qp] * Ue(j);
456  else
457  Ke(freei, freej) += ((*dphi)[i][qp] * (*dphi)[j][qp]) * JxW[qp];
458  }
459  if (!dof_is_fixed[j])
460  freej++;
461  }
462  Fe(freei) += (fineval * phi[i][qp]) * JxW[qp];
463  if (cont == C_ONE)
464  Fe(freei) += (finegrad * (*dphi)[i][qp]) * JxW[qp];
465  freei++;
466  }
467  }
468 
469  Ke.cholesky_solve(Fe, Uside);
470 
471  // Transfer new side solutions to element
472  for (unsigned int i = 0; i != free_dofs; ++i)
473  {
474  Number & ui = Ue(side_dofs[free_dof[i]]);
475  libmesh_assert(std::abs(ui) < TOLERANCE || std::abs(ui - Uside(i)) < TOLERANCE);
476  ui = Uside(i);
477  dof_is_fixed[side_dofs[free_dof[i]]] = true;
478  }
479  }
480 
481  // Project the interior values, finally
482 
483  // Some interior dofs are on nodes/edges/sides and
484  // already fixed, others are free to calculate
485  unsigned int free_dofs = 0;
486  for (unsigned int i = 0; i != n_dofs; ++i)
487  if (!dof_is_fixed[i])
488  free_dof[free_dofs++] = i;
489 
490  // There may be nothing to project
491  if (free_dofs)
492  {
493  Ke.resize(free_dofs, free_dofs);
494  Ke.zero();
495  Fe.resize(free_dofs);
496  Fe.zero();
497  // The new interior coefficients
498  DenseVector<Number> Uint(free_dofs);
499 
500  // Initialize FE data
501  fe->attach_quadrature_rule(qrule.get());
502  fe->reinit(_current_elem);
503  const unsigned int n_qp = qrule->n_points();
504 
505  // Loop over the quadrature points
506  for (unsigned int qp = 0; qp < n_qp; qp++)
507  {
508  // solution at the quadrature point
509  Number fineval = value(xyz_values[qp]);
510  // solution grad at the quadrature point
511  Gradient finegrad;
512  if (cont == C_ONE)
513  finegrad = gradient(xyz_values[qp]);
514 
515  // Form interior projection matrix
516  for (unsigned int i = 0, freei = 0; i != n_dofs; ++i)
517  {
518  // fixed DoFs aren't test functions
519  if (dof_is_fixed[i])
520  continue;
521  for (unsigned int j = 0, freej = 0; j != n_dofs; ++j)
522  {
523  if (dof_is_fixed[j])
524  Fe(freei) -= phi[i][qp] * phi[j][qp] * JxW[qp] * Ue(j);
525  else
526  Ke(freei, freej) += phi[i][qp] * phi[j][qp] * JxW[qp];
527  if (cont == C_ONE)
528  {
529  if (dof_is_fixed[j])
530  Fe(freei) -= ((*dphi)[i][qp] * (*dphi)[j][qp]) * JxW[qp] * Ue(j);
531  else
532  Ke(freei, freej) += ((*dphi)[i][qp] * (*dphi)[j][qp]) * JxW[qp];
533  }
534  if (!dof_is_fixed[j])
535  freej++;
536  }
537  Fe(freei) += phi[i][qp] * fineval * JxW[qp];
538  if (cont == C_ONE)
539  Fe(freei) += (finegrad * (*dphi)[i][qp]) * JxW[qp];
540  freei++;
541  }
542  }
543  Ke.cholesky_solve(Fe, Uint);
544 
545  // Transfer new interior solutions to element
546  for (unsigned int i = 0; i != free_dofs; ++i)
547  {
548  Number & ui = Ue(free_dof[i]);
549  libmesh_assert(std::abs(ui) < TOLERANCE || std::abs(ui - Uint(i)) < TOLERANCE);
550  ui = Uint(i);
551  dof_is_fixed[free_dof[i]] = true;
552  }
553  } // if there are free interior dofs
554 
555  // Make sure every DoF got reached!
556  for (unsigned int i = 0; i != n_dofs; ++i)
557  libmesh_assert(dof_is_fixed[i]);
558 
559  NumericVector<Number> & solution = _var.sys().solution();
560 
561  // 'first' and 'last' are no longer used, see note about subdomain-restricted variables below
562  // const dof_id_type
563  // first = solution.first_local_index(),
564  // last = solution.last_local_index();
565 
566  // Lock the new_vector since it is shared among threads.
567  {
568  Threads::spin_mutex::scoped_lock lock(Threads::spin_mtx);
569 
570  for (unsigned int i = 0; i < n_dofs; i++)
571  // We may be projecting a new zero value onto
572  // an old nonzero approximation - RHS
573  // if (Ue(i) != 0.)
574 
575  // This is commented out because of subdomain restricted variables.
576  // It can be the case that if a subdomain restricted variable's boundary
577  // aligns perfectly with a processor boundary that the variable will get
578  // no value. To counteract this we're going to let every processor set a
579  // value at every node and then let PETSc figure it out.
580  // Later we can choose to do something different / better.
581  // if ((dof_indices[i] >= first) && (dof_indices[i] < last))
582  {
583  solution.set(dof_indices[i], Ue(i));
584  }
585  _var.setNodalValue(Ue);
586  }
587 }
const FEType & feType() const
Get the type of finite element object.
const Elem *& _current_elem
The current element we are on will retrieving values at specific points in the domain.
void setNodalValue(Number value, unsigned int idx=0)
Set the nodal value for this variable to keep everything up to date.
unsigned int _qp
The current quadrature point, contains the "nth" node number when visiting nodes. ...
MooseVariable & _var
The variable that this initial condition is acting upon.
std::vector< dof_id_type > & dofIndices()
PetscInt n
const Node * _current_node
The current node if the point we are evaluating at also happens to be a node.
virtual NumericVector< Number > & solution()=0
virtual Real value(const Point &p)=0
The value of the variable at a point.
SystemBase & sys()
Get the system this variable is part of.
virtual RealGradient gradient(const Point &)
The gradient of the variable at a point.
unsigned int Coupleable::coupled ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns the index for a coupled variable by name.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Index of coupled variable, if this is an optionally coupled variable that wasn't provided this will return a unique "invalid" index.

Reimplemented in ShapeUserObject< ElementUserObject >, and ShapeUserObject< SideUserObject >.

Definition at line 136 of file Coupleable.C.

Referenced by NodalEqualValueConstraint::NodalEqualValueConstraint().

137 {
138  if (!isCoupled(var_name))
139  return _optional_var_index[var_name];
140 
141  MooseVariable * var = getVar(var_name, comp);
142  switch (var->kind())
143  {
145  return var->number();
147  return std::numeric_limits<unsigned int>::max() - var->number();
148  }
149  mooseError("Unknown variable kind. Corrupted binary?");
150 }
Class for stuff related to variables.
Definition: MooseVariable.h:43
Moose::VarKindType kind() const
Kind of the variable (Nonlinear, Auxiliary, ...)
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
unsigned int number() const
Get variable number coming from libMesh.
std::map< std::string, unsigned int > _optional_var_index
Unique indices for optionally coupled vars that weren&#39;t provided.
Definition: Coupleable.h:378
void Coupleable::coupledCallback ( const std::string &  var_name,
bool  is_old 
)
protectedvirtualinherited
unsigned int Coupleable::coupledComponents ( const std::string &  var_name)
protectedinherited

Number of coupled components.

Parameters
var_nameName of the variable
Returns
number of components this variable has (usually 1)

Definition at line 111 of file Coupleable.C.

Referenced by NodalEqualValueConstraint::NodalEqualValueConstraint(), SphericalAverage::SphericalAverage(), and VolumeHistogram::VolumeHistogram().

112 {
113  return _coupled_vars[var_name].size();
114 }
std::map< std::string, std::vector< MooseVariable * > > _coupled_vars
Coupled vars whose values we provide.
Definition: Coupleable.h:321
const VariableValue & Coupleable::coupledDot ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Time derivative of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the time derivative of the coupled variable
See also
Kernel::dot

Reimplemented in AuxKernel.

Definition at line 296 of file Coupleable.C.

Referenced by AuxKernel::coupledDot().

297 {
298  if (!isCoupled(var_name)) // Return default 0
299  return _default_value_zero;
300 
301  MooseVariable * var = getVar(var_name, comp);
302 
304  {
305  if (_c_nodal)
306  return var->nodalSlnDot();
307  else
308  return var->uDot();
309  }
310  else
311  {
312  if (_c_nodal)
313  return var->nodalSlnDotNeighbor();
314  else
315  return var->uDotNeighbor();
316  }
317 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
const VariableValue & uDotNeighbor()
VariableValue _default_value_zero
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:339
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const VariableValue & nodalSlnDot()
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & uDot()
const VariableValue & nodalSlnDotNeighbor()
const VariableValue & Coupleable::coupledDotDu ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Time derivative of a coupled variable with respect to the coefficients.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the time derivative of the coupled variable with respect to the coefficients
See also
Kernel:dotDu

Reimplemented in AuxKernel.

Definition at line 320 of file Coupleable.C.

Referenced by AuxKernel::coupledDotDu().

321 {
322  if (!isCoupled(var_name)) // Return default 0
323  return _default_value_zero;
324 
325  MooseVariable * var = getVar(var_name, comp);
326 
328  {
329  if (_c_nodal)
330  return var->nodalSlnDuDotDu();
331  else
332  return var->duDotDu();
333  }
334  else
335  {
336  if (_c_nodal)
337  return var->nodalSlnDuDotDu();
338  else
339  return var->duDotDu();
340  }
341 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
VariableValue _default_value_zero
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:339
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
const VariableValue & duDotDu()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & nodalSlnDuDotDu()
const VariableGradient & Coupleable::coupledGradient ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns gradient of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableGradient containing the gradient of the coupled variable
See also
Kernel::gradient

Definition at line 344 of file Coupleable.C.

345 {
346  if (!isCoupled(var_name)) // Return default 0
347  return _default_gradient;
348 
349  coupledCallback(var_name, false);
350  if (_c_nodal)
351  mooseError("Nodal variables do not have gradients");
352 
353  MooseVariable * var = getVar(var_name, comp);
354 
356  return (_c_is_implicit) ? var->gradSln() : var->gradSlnOld();
357  else
358  return (_c_is_implicit) ? var->gradSlnNeighbor() : var->gradSlnOldNeighbor();
359 }
const VariableGradient & gradSlnNeighbor()
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
const VariableGradient & gradSlnOld()
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
const VariableGradient & gradSlnOldNeighbor()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableGradient _default_gradient
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:342
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableGradient & gradSln()
const VariableGradient & Coupleable::coupledGradientOld ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old gradient from previous time step of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableGradient containing the old gradient of the coupled variable
See also
Kernel::gradientOld

Definition at line 362 of file Coupleable.C.

363 {
364  if (!isCoupled(var_name)) // Return default 0
365  return _default_gradient;
366 
367  coupledCallback(var_name, true);
368  if (_c_nodal)
369  mooseError("Nodal variables do not have gradients");
370 
371  validateExecutionerType(var_name);
372  MooseVariable * var = getVar(var_name, comp);
373 
375  return (_c_is_implicit) ? var->gradSlnOld() : var->gradSlnOlder();
376  else
377  return (_c_is_implicit) ? var->gradSlnOldNeighbor() : var->gradSlnOlderNeighbor();
378 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
const VariableGradient & gradSlnOld()
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
const VariableGradient & gradSlnOldNeighbor()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableGradient _default_gradient
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:342
const VariableGradient & gradSlnOlderNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableGradient & gradSlnOlder()
const VariableGradient & Coupleable::coupledGradientOlder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old gradient from two time steps previous of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableGradient containing the older gradient of the coupled variable
See also
Kernel::gradientOlder

Definition at line 381 of file Coupleable.C.

382 {
383  if (!isCoupled(var_name)) // Return default 0
384  return _default_gradient;
385 
386  coupledCallback(var_name, true);
387  if (_c_nodal)
388  mooseError("Nodal variables do not have gradients");
389 
390  validateExecutionerType(var_name);
391  MooseVariable * var = getVar(var_name, comp);
392 
393  if (_c_is_implicit)
394  {
396  return var->gradSlnOlder();
397  else
398  return var->gradSlnOlderNeighbor();
399  }
400  else
401  mooseError("Older values not available for explicit schemes");
402 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableGradient _default_gradient
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:342
const VariableGradient & gradSlnOlderNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableGradient & gradSlnOlder()
const VariableGradient & Coupleable::coupledGradientPreviousNL ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns gradient of a coupled variable for previous Newton iterate.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableGradient containing the gradient of the coupled variable

Definition at line 405 of file Coupleable.C.

406 {
407  if (!isCoupled(var_name)) // Return default 0
408  return _default_gradient;
409 
411  coupledCallback(var_name, true);
412  if (_c_nodal)
413  mooseError("Nodal variables do not have gradients");
414 
415  MooseVariable * var = getVar(var_name, comp);
416 
418  return var->gradSlnPreviousNL();
419  else
420  return var->gradSlnPreviousNLNeighbor();
421 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const VariableGradient & gradSlnPreviousNLNeighbor()
FEProblemBase & _c_fe_problem
Definition: Coupleable.h:318
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableGradient _default_gradient
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:342
const VariableGradient & gradSlnPreviousNL()
void needsPreviousNewtonIteration(bool state)
Set a flag that indicated that user required values for the previous Newton iterate.
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & Coupleable::coupledNodalDot ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Nodal values of time derivative of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the nodal values of time derivative of the coupled variable

Definition at line 568 of file Coupleable.C.

569 {
570  if (!isCoupled(var_name)) // Return default 0
571  return _default_value_zero;
572 
573  coupledCallback(var_name, false);
574  MooseVariable * var = getVar(var_name, comp);
575 
577  return var->nodalValueDot();
578  else
579  return var->nodalValueDotNeighbor();
580 }
Class for stuff related to variables.
Definition: MooseVariable.h:43
VariableValue _default_value_zero
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:339
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const VariableValue & nodalValueDotNeighbor()
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & nodalValueDot()
const VariableValue & Coupleable::coupledNodalValue ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns nodal values of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue for the coupled variable

Definition at line 501 of file Coupleable.C.

502 {
503  if (!isCoupled(var_name))
504  return *getDefaultValue(var_name);
505 
506  coupledCallback(var_name, false);
507  MooseVariable * var = getVar(var_name, comp);
508 
510  return (_c_is_implicit) ? var->nodalValue() : var->nodalValueOld();
511  else
512  return (_c_is_implicit) ? var->nodalValueNeighbor() : var->nodalValueOldNeighbor();
513 }
const VariableValue & nodalValue()
Class for stuff related to variables.
Definition: MooseVariable.h:43
const VariableValue & nodalValueNeighbor()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
const VariableValue & nodalValueOldNeighbor()
const VariableValue & nodalValueOld()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & Coupleable::coupledNodalValueOld ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old nodal value from previous time step of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the old value of the coupled variable

Definition at line 516 of file Coupleable.C.

517 {
518  if (!isCoupled(var_name))
519  return *getDefaultValue(var_name);
520 
521  validateExecutionerType(var_name);
522  coupledCallback(var_name, true);
523  MooseVariable * var = getVar(var_name, comp);
524 
526  return (_c_is_implicit) ? var->nodalValueOld() : var->nodalValueOlder();
527  else
529 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
Class for stuff related to variables.
Definition: MooseVariable.h:43
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
const VariableValue & nodalValueOldNeighbor()
const VariableValue & nodalValueOld()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & nodalValueOlderNeighbor()
const VariableValue & nodalValueOlder()
const VariableValue & Coupleable::coupledNodalValueOlder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old nodal value from two time steps previous of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the older value of the coupled variable

Definition at line 532 of file Coupleable.C.

533 {
534  if (!isCoupled(var_name))
535  return *getDefaultValue(var_name);
536 
537  validateExecutionerType(var_name);
538  coupledCallback(var_name, true);
539  MooseVariable * var = getVar(var_name, comp);
540  if (_c_is_implicit)
541  {
543  return var->nodalValueOlder();
544  else
545  return var->nodalValueOlderNeighbor();
546  }
547  else
548  mooseError("Older values not available for explicit schemes");
549 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & nodalValueOlderNeighbor()
const VariableValue & nodalValueOlder()
const VariableValue & Coupleable::coupledNodalValuePreviousNL ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns nodal values of a coupled variable for previous Newton iterate.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue for the coupled variable

Definition at line 552 of file Coupleable.C.

553 {
554  if (!isCoupled(var_name))
555  return *getDefaultValue(var_name);
556 
558  coupledCallback(var_name, true);
559  MooseVariable * var = getVar(var_name, comp);
560 
562  return var->nodalValuePreviousNL();
563  else
564  return var->nodalValuePreviousNLNeighbor();
565 }
Class for stuff related to variables.
Definition: MooseVariable.h:43
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
const VariableValue & nodalValuePreviousNL()
FEProblemBase & _c_fe_problem
Definition: Coupleable.h:318
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
void needsPreviousNewtonIteration(bool state)
Set a flag that indicated that user required values for the previous Newton iterate.
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & nodalValuePreviousNLNeighbor()
const VariableSecond & Coupleable::coupledSecond ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns second derivative of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableSecond containing the second derivative of the coupled variable
See also
Kernel::second

Definition at line 424 of file Coupleable.C.

425 {
426  if (!isCoupled(var_name)) // Return default 0
427  return _default_second;
428 
429  coupledCallback(var_name, false);
430  if (_c_nodal)
431  mooseError("Nodal variables do not have second derivatives");
432 
433  MooseVariable * var = getVar(var_name, comp);
434 
436  return (_c_is_implicit) ? var->secondSln() : var->secondSlnOlder();
437  else
438  return (_c_is_implicit) ? var->secondSlnNeighbor() : var->secondSlnOlderNeighbor();
439 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
const VariableSecond & secondSln()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const VariableSecond & secondSlnOlder()
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableSecond _default_second
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:345
const VariableSecond & secondSlnOlderNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableSecond & secondSlnNeighbor()
const VariableSecond & Coupleable::coupledSecondOld ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old second derivative from previous time step of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableSecond containing the old second derivative of the coupled variable
See also
Kernel::secondOld

Definition at line 442 of file Coupleable.C.

443 {
444  if (!isCoupled(var_name)) // Return default 0
445  return _default_second;
446 
447  coupledCallback(var_name, true);
448  if (_c_nodal)
449  mooseError("Nodal variables do not have second derivatives");
450 
451  validateExecutionerType(var_name);
452  MooseVariable * var = getVar(var_name, comp);
454  return (_c_is_implicit) ? var->secondSlnOld() : var->secondSlnOlder();
455  else
457 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
const VariableSecond & secondSlnOldNeighbor()
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const VariableSecond & secondSlnOld()
const VariableSecond & secondSlnOlder()
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableSecond _default_second
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:345
const VariableSecond & secondSlnOlderNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableSecond & Coupleable::coupledSecondOlder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old second derivative from two time steps previous of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableSecond containing the older second derivative of the coupled variable
See also
Kernel::secondOlder

Definition at line 460 of file Coupleable.C.

461 {
462  if (!isCoupled(var_name)) // Return default 0
463  return _default_second;
464 
465  coupledCallback(var_name, true);
466  if (_c_nodal)
467  mooseError("Nodal variables do not have second derivatives");
468 
469  validateExecutionerType(var_name);
470  MooseVariable * var = getVar(var_name, comp);
471  if (_c_is_implicit)
472  {
474  return var->secondSlnOlder();
475  else
476  return var->secondSlnOlderNeighbor();
477  }
478  else
479  mooseError("Older values not available for explicit schemes");
480 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const VariableSecond & secondSlnOlder()
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableSecond _default_second
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:345
const VariableSecond & secondSlnOlderNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableSecond & Coupleable::coupledSecondPreviousNL ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns second derivative of a coupled variable for the previous Newton iterate.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableSecond containing the second derivative of the coupled variable

Definition at line 483 of file Coupleable.C.

484 {
485  if (!isCoupled(var_name)) // Return default 0
486  return _default_second;
487 
489  coupledCallback(var_name, true);
490  if (_c_nodal)
491  mooseError("Nodal variables do not have second derivatives");
492 
493  MooseVariable * var = getVar(var_name, comp);
495  return var->secondSlnPreviousNL();
496  else
497  return var->secondSlnPreviousNLNeighbor();
498 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
const VariableSecond & secondSlnPreviousNL()
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
FEProblemBase & _c_fe_problem
Definition: Coupleable.h:318
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
VariableSecond _default_second
This will always be zero because the default values for optionally coupled variables is always consta...
Definition: Coupleable.h:345
void needsPreviousNewtonIteration(bool state)
Set a flag that indicated that user required values for the previous Newton iterate.
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableSecond & secondSlnPreviousNLNeighbor()
const DenseVector< Number > & Coupleable::coupledSolutionDoFs ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns DoFs in the current solution vector of a coupled variable for the local element.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a DenseVector for the DoFs of the coupled variable

Definition at line 583 of file Coupleable.C.

584 {
585  // default coupling is not available for elemental solutions
586  if (!isCoupled(var_name))
587  mooseError("invalid variable name for coupledSolutionDoFs");
588 
589  if (_c_nodal)
590  mooseError("nodal objects should not call coupledSolutionDoFs");
591 
592  coupledCallback(var_name, false);
593  MooseVariable * var = getVar(var_name, comp);
594 
596  return (_c_is_implicit) ? var->solutionDoFs() : var->solutionDoFsOld();
597  else
599 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
const DenseVector< Number > & solutionDoFsOld()
Class for stuff related to variables.
Definition: MooseVariable.h:43
const DenseVector< Number > & solutionDoFsNeighbor()
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
const DenseVector< Number > & solutionDoFs()
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const DenseVector< Number > & solutionDoFsOldNeighbor()
const DenseVector< Number > & Coupleable::coupledSolutionDoFsOld ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns DoFs in the old solution vector of a coupled variable for the local element.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a DenseVector for the old DoFs of the coupled variable

Definition at line 602 of file Coupleable.C.

603 {
604  // default coupling is not available for elemental solutions
605  if (!isCoupled(var_name))
606  mooseError("invalid variable name for coupledSolutionDoFsOld");
607 
608  if (_c_nodal)
609  mooseError("nodal objects should not call coupledSolutionDoFsOld");
610 
611  validateExecutionerType(var_name);
612  coupledCallback(var_name, true);
613  MooseVariable * var = getVar(var_name, comp);
614 
616  return (_c_is_implicit) ? var->solutionDoFsOld() : var->solutionDoFsOlder();
617  else
619 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
const DenseVector< Number > & solutionDoFsOld()
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
const DenseVector< Number > & solutionDoFsOlder()
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const DenseVector< Number > & solutionDoFsOlderNeighbor()
const DenseVector< Number > & solutionDoFsOldNeighbor()
const DenseVector< Number > & Coupleable::coupledSolutionDoFsOlder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns DoFs in the older solution vector of a coupled variable for the local element.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a DenseVector for the older DoFs of the coupled variable

Definition at line 622 of file Coupleable.C.

623 {
624  // default coupling is not available for elemental solutions
625  if (!isCoupled(var_name))
626  mooseError("invalid variable name for coupledSolutionDoFsOlder");
627 
628  if (_c_nodal)
629  mooseError("nodal objects should not call coupledSolutionDoFsOlder");
630 
631  validateExecutionerType(var_name);
632  coupledCallback(var_name, true);
633  MooseVariable * var = getVar(var_name, comp);
634  if (_c_is_implicit)
635  {
637  return var->solutionDoFsOlder();
638  else
639  return var->solutionDoFsOlderNeighbor();
640  }
641  else
642  mooseError("Older values not available for explicit schemes");
643 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
const DenseVector< Number > & solutionDoFsOlder()
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const DenseVector< Number > & solutionDoFsOlderNeighbor()
const VariableValue & Coupleable::coupledValue ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns value of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue for the coupled variable
See also
Kernel::value

Definition at line 167 of file Coupleable.C.

Referenced by NodalEqualValueConstraint::NodalEqualValueConstraint(), ParsedAux::ParsedAux(), SphericalAverage::SphericalAverage(), VariableTimeIntegrationAux::VariableTimeIntegrationAux(), and Coupleable::writableCoupledValue().

168 {
169  if (!isCoupled(var_name))
170  return *getDefaultValue(var_name);
171 
172  coupledCallback(var_name, false);
173  MooseVariable * var = getVar(var_name, comp);
174 
176  {
177  if (_c_nodal)
178  return (_c_is_implicit) ? var->nodalSln() : var->nodalSlnOld();
179  else
180  return (_c_is_implicit) ? var->sln() : var->slnOld();
181  }
182  else
183  {
184  if (_c_nodal)
185  return (_c_is_implicit) ? var->nodalSlnNeighbor() : var->nodalSlnOldNeighbor();
186  else
187  return (_c_is_implicit) ? var->slnNeighbor() : var->slnOldNeighbor();
188  }
189 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
const VariableValue & nodalSlnNeighbor()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
const VariableValue & nodalSlnOldNeighbor()
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
const VariableValue & slnOld()
const VariableValue & nodalSlnOld()
const VariableValue & slnOldNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & nodalSln()
const VariableValue & sln()
const VariableValue & slnNeighbor()
const VariableValue & Coupleable::coupledValueOld ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old value from previous time step of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the old value of the coupled variable
See also
Kernel::valueOld

Definition at line 198 of file Coupleable.C.

Referenced by VariableTimeIntegrationAux::VariableTimeIntegrationAux().

199 {
200  if (!isCoupled(var_name))
201  return *getDefaultValue(var_name);
202 
203  validateExecutionerType(var_name);
204  coupledCallback(var_name, true);
205  MooseVariable * var = getVar(var_name, comp);
206 
208  {
209  if (_c_nodal)
210  return (_c_is_implicit) ? var->nodalSlnOld() : var->nodalSlnOlder();
211  else
212  return (_c_is_implicit) ? var->slnOld() : var->slnOlder();
213  }
214  else
215  {
216  if (_c_nodal)
217  return (_c_is_implicit) ? var->nodalSlnOldNeighbor() : var->nodalSlnOlderNeighbor();
218  else
219  return (_c_is_implicit) ? var->slnOldNeighbor() : var->slnOlderNeighbor();
220  }
221 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
const VariableValue & slnOlder()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
const VariableValue & nodalSlnOldNeighbor()
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
const VariableValue & slnOld()
const VariableValue & nodalSlnOlderNeighbor()
const VariableValue & nodalSlnOld()
const VariableValue & slnOlderNeighbor()
const VariableValue & nodalSlnOlder()
const VariableValue & slnOldNeighbor()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & Coupleable::coupledValueOlder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns an old value from two time steps previous of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the older value of the coupled variable
See also
Kernel::valueOlder

Definition at line 224 of file Coupleable.C.

Referenced by VariableTimeIntegrationAux::VariableTimeIntegrationAux().

225 {
226  if (!isCoupled(var_name))
227  return *getDefaultValue(var_name);
228 
229  validateExecutionerType(var_name);
230  coupledCallback(var_name, true);
231  MooseVariable * var = getVar(var_name, comp);
232 
234  {
235  if (_c_nodal)
236  {
237  if (_c_is_implicit)
238  return var->nodalSlnOlder();
239  else
240  mooseError("Older values not available for explicit schemes");
241  }
242  else
243  {
244  if (_c_is_implicit)
245  return var->slnOlder();
246  else
247  mooseError("Older values not available for explicit schemes");
248  }
249  }
250  else
251  {
252  if (_c_nodal)
253  {
254  if (_c_is_implicit)
255  return var->nodalSlnOlderNeighbor();
256  else
257  mooseError("Older values not available for explicit schemes");
258  }
259  else
260  {
261  if (_c_is_implicit)
262  return var->slnOlderNeighbor();
263  else
264  mooseError("Older values not available for explicit schemes");
265  }
266  }
267 }
void validateExecutionerType(const std::string &name) const
Checks to make sure that the current Executioner has set "_it_transient" when old/older values are co...
Definition: Coupleable.C:646
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
const VariableValue & slnOlder()
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
bool _c_is_implicit
True if implicit value is required.
Definition: Coupleable.h:330
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
const VariableValue & nodalSlnOlderNeighbor()
const VariableValue & slnOlderNeighbor()
const VariableValue & nodalSlnOlder()
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & Coupleable::coupledValuePreviousNL ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns value of previous Newton iterate of a coupled variable.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue containing the older value of the coupled variable

Definition at line 270 of file Coupleable.C.

271 {
272  if (!isCoupled(var_name))
273  return *getDefaultValue(var_name);
274 
276  coupledCallback(var_name, true);
277  MooseVariable * var = getVar(var_name, comp);
278 
280  {
281  if (_c_nodal)
282  return var->nodalSlnPreviousNL();
283  else
284  return var->slnPreviousNL();
285  }
286  else
287  {
288  if (_c_nodal)
289  return var->nodalSlnPreviousNLNeighbor();
290  else
291  return var->slnPreviousNLNeighbor();
292  }
293 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
Class for stuff related to variables.
Definition: MooseVariable.h:43
const VariableValue & nodalSlnPreviousNL()
const VariableValue & slnPreviousNLNeighbor()
MooseVariable * getVar(const std::string &var_name, unsigned int comp)
Extract pointer to a coupled variable.
Definition: Coupleable.C:117
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
Definition: Coupleable.C:153
FEProblemBase & _c_fe_problem
Definition: Coupleable.h:318
virtual bool isCoupled(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled as name.
Definition: Coupleable.C:91
virtual void coupledCallback(const std::string &var_name, bool is_old)
Definition: Coupleable.C:86
const VariableValue & nodalSlnPreviousNLNeighbor()
void needsPreviousNewtonIteration(bool state)
Set a flag that indicated that user required values for the previous Newton iterate.
bool _coupleable_neighbor
Whether or not this object is a "neighbor" object: ie all of it&#39;s coupled values should be neighbor v...
Definition: Coupleable.h:363
const VariableValue & slnPreviousNL()
template<typename T >
void DependencyResolverInterface::cyclicDependencyError ( CyclicDependencyException< T > &  e,
const std::string &  header 
)
staticinherited

A helper method for cyclic errors.

Definition at line 100 of file DependencyResolverInterface.h.

Referenced by DependencyResolverInterface::DependencyResolverInterface().

102 {
103  std::ostringstream oss;
104 
105  oss << header << ":\n";
106  const typename std::multimap<T, T> & depends = e.getCyclicDependencies();
107  for (typename std::multimap<T, T>::const_iterator it = depends.begin(); it != depends.end(); ++it)
108  oss << (static_cast<T>(it->first))->name() << " -> " << (static_cast<T>(it->second))->name()
109  << "\n";
110  mooseError(oss.str());
111 }
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
const std::multimap< T, T > & getCyclicDependencies() const
template<typename T >
T & Restartable::declareRestartableData ( std::string  data_name)
protectedinherited

Declare a piece of data as "restartable".

This means that in the event of a restart this piece of data will be restored back to its previous value.

NOTE: This returns a reference! Make sure you store it in a reference!

Parameters
data_nameThe name of the data (usually just use the same name as the member variable)

Definition at line 224 of file Restartable.h.

225 {
226  return declareRestartableDataWithContext<T>(data_name, NULL);
227 }
template<typename T >
T & Restartable::declareRestartableData ( std::string  data_name,
const T &  init_value 
)
protectedinherited

Declare a piece of data as "restartable" and initialize it.

This means that in the event of a restart this piece of data will be restored back to its previous value.

NOTE: This returns a reference! Make sure you store it in a reference!

Parameters
data_nameThe name of the data (usually just use the same name as the member variable)
init_valueThe initial value of the data

Definition at line 231 of file Restartable.h.

232 {
233  return declareRestartableDataWithContext<T>(data_name, init_value, NULL);
234 }
template<typename T >
T & Restartable::declareRestartableDataWithContext ( std::string  data_name,
void *  context 
)
protectedinherited

Declare a piece of data as "restartable".

This means that in the event of a restart this piece of data will be restored back to its previous value.

NOTE: This returns a reference! Make sure you store it in a reference!

Parameters
data_nameThe name of the data (usually just use the same name as the member variable)
contextContext pointer that will be passed to the load and store functions

Definition at line 238 of file Restartable.h.

239 {
241  mooseError("No valid SubProblem found for ", _restartable_system_name, "/", _restartable_name);
242 
243  std::string full_name = _restartable_system_name + "/" + _restartable_name + "/" + data_name;
244  RestartableData<T> * data_ptr = new RestartableData<T>(full_name, context);
245 
247 
248  return data_ptr->get();
249 }
std::string _restartable_system_name
The system name this object is in.
Definition: Restartable.h:202
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
std::string _restartable_name
The name of the object.
Definition: Restartable.h:196
void registerRestartableDataOnSubProblem(std::string name, RestartableDataValue *data, THREAD_ID tid)
Helper function so we don&#39;t have to include SubProblem in the header.
Definition: Restartable.C:49
Concrete definition of a parameter value for a specified type.
SubProblem * _restartable_subproblem
Pointer to the SubProblem class.
Definition: Restartable.h:208
THREAD_ID _restartable_tid
The thread ID for this object.
Definition: Restartable.h:205
template<typename T >
T & Restartable::declareRestartableDataWithContext ( std::string  data_name,
const T &  init_value,
void *  context 
)
protectedinherited

Declare a piece of data as "restartable" and initialize it.

This means that in the event of a restart this piece of data will be restored back to its previous value.

NOTE: This returns a reference! Make sure you store it in a reference!

Parameters
data_nameThe name of the data (usually just use the same name as the member variable)
init_valueThe initial value of the data
contextContext pointer that will be passed to the load and store functions

Definition at line 253 of file Restartable.h.

256 {
258  mooseError("No valid SubProblem found for ", _restartable_system_name, "/", _restartable_name);
259 
260  std::string full_name = _restartable_system_name + "/" + _restartable_name + "/" + data_name;
261  RestartableData<T> * data_ptr = new RestartableData<T>(full_name, context);
262 
263  data_ptr->set() = init_value;
264 
266 
267  return data_ptr->get();
268 }
std::string _restartable_system_name
The system name this object is in.
Definition: Restartable.h:202
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
std::string _restartable_name
The name of the object.
Definition: Restartable.h:196
void registerRestartableDataOnSubProblem(std::string name, RestartableDataValue *data, THREAD_ID tid)
Helper function so we don&#39;t have to include SubProblem in the header.
Definition: Restartable.C:49
Concrete definition of a parameter value for a specified type.
SubProblem * _restartable_subproblem
Pointer to the SubProblem class.
Definition: Restartable.h:208
THREAD_ID _restartable_tid
The thread ID for this object.
Definition: Restartable.h:205
virtual bool MooseObject::enabled ( )
inlinevirtualinherited

Return the enabled status of the object.

Reimplemented in EigenKernel.

Definition at line 77 of file MooseObject.h.

Referenced by EigenKernel::enabled().

77 { return _enabled; }
const bool & _enabled
Reference to the "enable" InputParaemters, used by Controls for toggling on/off MooseObjects.
Definition: MooseObject.h:117
Moose::CoordinateSystemType BlockRestrictable::getBlockCoordSystem ( )
protectedinherited

Check if the blocks this object operates on all have the same coordinate system, and if so return it.

Definition at line 286 of file BlockRestrictable.C.

287 {
288  if (!_blk_mesh)
289  mooseError("No mesh available in BlockRestrictable::checkCoordSystem()");
290  if (!_blk_feproblem)
291  mooseError("No problem available in BlockRestrictable::checkCoordSystem()");
292 
293  const auto & subdomains = blockRestricted() ? blockIDs() : meshBlockIDs();
294 
295  if (subdomains.empty())
296  mooseError("No subdomains found in the problem.");
297 
298  // make sure all subdomains are using the same coordinate system
299  auto coord_system = _blk_feproblem->getCoordSystem(*subdomains.begin());
300  for (auto subdomain : subdomains)
301  if (_blk_feproblem->getCoordSystem(subdomain) != coord_system)
302  mooseError("This object requires all subdomains to have the same coordinate system.");
303 
304  return coord_system;
305 }
virtual const std::set< SubdomainID > & blockIDs() const
Return the block subdomain ids for this object.
const std::set< SubdomainID > & meshBlockIDs() const
Return all of the SubdomainIDs for the mesh.
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
FEProblemBase * _blk_feproblem
Pointer to FEProblemBase.
virtual Moose::CoordinateSystemType getCoordSystem(SubdomainID sid) override
MooseMesh * _blk_mesh
Pointer to Mesh.
virtual bool blockRestricted() const
Returns true if this object has been restricted to a boundary.
const std::vector<MooseVariable *>& Coupleable::getCoupledMooseVars ( ) const
inlineinherited
const std::map<std::string, std::vector<MooseVariable *> >& Coupleable::getCoupledVars ( )
inlineinherited

Get the list of coupled variables.

Returns
The list of coupled variables

Definition at line 54 of file Coupleable.h.

Referenced by AuxKernel::AuxKernel(), and InitialCondition::InitialCondition().

55  {
56  return _coupled_vars;
57  }
std::map< std::string, std::vector< MooseVariable * > > _coupled_vars
Coupled vars whose values we provide.
Definition: Coupleable.h:321
const std::set<std::string>& InitialCondition::getDependObjects ( ) const
inlineinherited

Definition at line 69 of file InitialCondition.h.

69 { return _depend_uo; }
std::set< std::string > _depend_uo
Depend UserObjects.
Function & FunctionInterface::getFunction ( const std::string &  name)
inherited

Get a function with a given name.

Parameters
nameThe name of the parameter key of the function to retrieve
Returns
The function with name associated with the parameter 'name'

Definition at line 35 of file FunctionInterface.C.

36 {
37  return _fni_feproblem.getFunction(_fni_params.get<FunctionName>(name), _fni_tid);
38 }
virtual Function & getFunction(const std::string &name, THREAD_ID tid=0)
FEProblemBase & _fni_feproblem
Reference to FEProblemBase instance.
const InputParameters & _fni_params
Parameters of the object with this interface.
THREAD_ID _fni_tid
Thread ID.
Function & FunctionInterface::getFunctionByName ( const FunctionName &  name)
inherited

Get a function with a given name.

Parameters
nameThe name of the function to retrieve
Returns
The function with name 'name'

Definition at line 41 of file FunctionInterface.C.

Referenced by CompositeFunction::CompositeFunction(), FunctionScalarAux::FunctionScalarAux(), FunctionScalarIC::FunctionScalarIC(), GenericFunctionMaterial::GenericFunctionMaterial(), LinearCombinationFunction::LinearCombinationFunction(), and LineFunctionSampler::LineFunctionSampler().

42 {
43  return _fni_feproblem.getFunction(name, _fni_tid);
44 }
virtual Function & getFunction(const std::string &name, THREAD_ID tid=0)
FEProblemBase & _fni_feproblem
Reference to FEProblemBase instance.
THREAD_ID _fni_tid
Thread ID.
MooseApp& MooseObject::getMooseApp ( )
inlineinherited

Get the MooseApp this object is associated with.

Definition at line 72 of file MooseObject.h.

Referenced by RestartableDataIO::createBackup(), RestartableDataIO::deserializeRestartableData(), Resurrector::restartRestartableData(), and RestartableDataIO::restoreBackup().

72 { return _app; }
MooseApp & _app
The MooseApp this object is associated with.
Definition: MooseObject.h:108
template<typename T >
const T & MooseObject::getParam ( const std::string &  name) const
inherited

Retrieve a parameter for the object.

Parameters
nameThe name of the parameter
Returns
The value of the parameter

Definition at line 122 of file MooseObject.h.

Referenced by FEProblemBase::addMaterial(), ConstraintWarehouse::addObject(), BicubicSplineFunction::BicubicSplineFunction(), Piecewise::buildFromXandY(), EigenKernel::EigenKernel(), FieldSplitPreconditioner::FieldSplitPreconditioner(), FiniteDifferencePreconditioner::FiniteDifferencePreconditioner(), GenericConstantRankTwoTensor::GenericConstantRankTwoTensor(), TimeSequenceStepper::init(), BlockRestrictable::initializeBlockRestrictable(), BoundaryRestrictable::initializeBoundaryRestrictable(), Console::initialSetup(), AdvancedOutput::initialSetup(), SideSetsBetweenSubdomains::modify(), AddExtraNodeset::modify(), MeshExtruder::modify(), SideSetsAroundSubdomain::modify(), RenameBlock::modify(), MooseObject::parameters(), ParsedAddSideset::ParsedAddSideset(), ParsedAux::ParsedAux(), ParsedODEKernel::ParsedODEKernel(), ParsedSubdomainMeshModifier::ParsedSubdomainMeshModifier(), PhysicsBasedPreconditioner::PhysicsBasedPreconditioner(), SingleMatrixPreconditioner::SingleMatrixPreconditioner(), TimePeriod::TimePeriod(), and VectorOfPostprocessors::VectorOfPostprocessors().

123 {
124  return InputParameters::getParamHelper(name, _pars, static_cast<T *>(0));
125 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
static const T & getParamHelper(const std::string &name, const InputParameters &pars, const T *the_type)
const InputParameters & _pars
Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.
Definition: MooseObject.h:111
const std::set< std::string > & InitialCondition::getRequestedItems ( )
overridevirtualinherited

Return a set containing the names of items requested by the object.

Implements DependencyResolverInterface.

Definition at line 86 of file InitialCondition.C.

Referenced by InitialCondition::initialSetup().

87 {
88  return _depend_vars;
89 }
std::set< std::string > _depend_vars
const std::set< std::string > & InitialCondition::getSuppliedItems ( )
overridevirtualinherited

Return a set containing the names of items owned by the object.

Implements DependencyResolverInterface.

Definition at line 92 of file InitialCondition.C.

Referenced by InitialCondition::initialSetup().

93 {
94  return _supplied_vars;
95 }
std::set< std::string > _supplied_vars
template<typename T >
const T & InitialCondition::getUserObject ( const std::string &  name)
inherited

Definition at line 151 of file InitialCondition.h.

Referenced by InitialCondition::initialSetup().

152 {
154  _depend_uo.insert(_pars.get<UserObjectName>(name));
155  return UserObjectInterface::getUserObject<T>(name);
156 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
std::set< std::string > _depend_uo
Depend UserObjects.
const InputParameters & _pars
Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.
Definition: MooseObject.h:111
const bool _ignore_uo_dependency
If set, UOs retrieved by this IC will not be executed before this IC.
const UserObject & InitialCondition::getUserObjectBase ( const std::string &  name)
inherited

Definition at line 98 of file InitialCondition.C.

Referenced by InitialCondition::initialSetup().

99 {
101  _depend_uo.insert(_pars.get<UserObjectName>(name));
103 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
std::set< std::string > _depend_uo
Depend UserObjects.
const InputParameters & _pars
Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.
Definition: MooseObject.h:111
const bool _ignore_uo_dependency
If set, UOs retrieved by this IC will not be executed before this IC.
const UserObject & getUserObjectBase(const std::string &name)
Get an user object with a given parameter name.
const UserObject & UserObjectInterface::getUserObjectBaseByName ( const std::string &  name)
inherited

Get an user object with a given name.

Parameters
nameThe name of the user object to retrieve
Returns
The user object with the name

Definition at line 34 of file UserObjectInterface.C.

Referenced by UserObjectInterface::getUserObjectByName().

35 {
36  return _uoi_feproblem.getUserObjectBase(name);
37 }
FEProblemBase & _uoi_feproblem
Reference to the FEProblemBase instance.
const UserObject & getUserObjectBase(const std::string &name)
Get the user object by its name.
template<class T >
const T & UserObjectInterface::getUserObjectByName ( const std::string &  name)
inherited

Get an user object with a given name.

Parameters
nameThe name of the user object to retrieve
Returns
The user object with the name

Definition at line 93 of file UserObjectInterface.h.

94 {
95  unsigned int tid = isDiscreteUserObject(getUserObjectBaseByName(name)) ? _uoi_tid : 0;
96  return _uoi_feproblem.getUserObject<T>(name, tid);
97 }
bool isDiscreteUserObject(const UserObject &uo) const
Check if the user object is a DiscreteElementUserObject.
const UserObject & getUserObjectBaseByName(const std::string &name)
Get an user object with a given name.
FEProblemBase & _uoi_feproblem
Reference to the FEProblemBase instance.
THREAD_ID _uoi_tid
Thread ID.
const T & getUserObject(const std::string &name, unsigned int tid=0)
Get the user object by its name.
template<typename T >
const T & InitialCondition::getUserObjectByName ( const UserObjectName &  name)
inherited

Definition at line 160 of file InitialCondition.h.

Referenced by InitialCondition::initialSetup().

161 {
163  _depend_uo.insert(name);
164  return UserObjectInterface::getUserObjectByName<T>(name);
165 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
std::set< std::string > _depend_uo
Depend UserObjects.
const bool _ignore_uo_dependency
If set, UOs retrieved by this IC will not be executed before this IC.
MooseVariable * Coupleable::getVar ( const std::string &  var_name,
unsigned int  comp 
)
protectedinherited

Extract pointer to a coupled variable.

Parameters
var_nameName of parameter desired
compComponent number of multiple coupled variables
Returns
Pointer to the desired variable

Definition at line 117 of file Coupleable.C.

Referenced by ShapeUserObject< T >::coupled(), Coupleable::coupled(), AuxKernel::coupledDot(), Coupleable::coupledDot(), AuxKernel::coupledDotDu(), Coupleable::coupledDotDu(), Coupleable::coupledGradient(), Coupleable::coupledGradientOld(), Coupleable::coupledGradientOlder(), Coupleable::coupledGradientPreviousNL(), NeighborCoupleable::coupledNeighborGradient(), NeighborCoupleable::coupledNeighborGradientOld(), NeighborCoupleable::coupledNeighborGradientOlder(), NeighborCoupleable::coupledNeighborSecond(), NeighborCoupleable::coupledNeighborSolutionDoFs(), NeighborCoupleable::coupledNeighborSolutionDoFsOld(), NeighborCoupleable::coupledNeighborSolutionDoFsOlder(), NeighborCoupleable::coupledNeighborValue(), NeighborCoupleable::coupledNeighborValueOld(), NeighborCoupleable::coupledNeighborValueOlder(), Coupleable::coupledNodalDot(), Coupleable::coupledNodalValue(), Coupleable::coupledNodalValueOld(), Coupleable::coupledNodalValueOlder(), Coupleable::coupledNodalValuePreviousNL(), Coupleable::coupledSecond(), Coupleable::coupledSecondOld(), Coupleable::coupledSecondOlder(), Coupleable::coupledSecondPreviousNL(), Coupleable::coupledSolutionDoFs(), Coupleable::coupledSolutionDoFsOld(), Coupleable::coupledSolutionDoFsOlder(), Coupleable::coupledValue(), Coupleable::coupledValueOld(), Coupleable::coupledValueOlder(), Coupleable::coupledValuePreviousNL(), ParsedAux::ParsedAux(), PiecewiseLinearInterpolationMaterial::PiecewiseLinearInterpolationMaterial(), and SphericalAverage::SphericalAverage().

118 {
119  if (_coupled_vars.find(var_name) != _coupled_vars.end())
120  {
121  if (comp < _coupled_vars[var_name].size())
122  {
123  // Error check - don't couple elemental to nodal
124  if (!(_coupled_vars[var_name][comp])->isNodal() && _c_nodal)
125  mooseError("You cannot couple an elemental variable to a nodal variable");
126  return _coupled_vars[var_name][comp];
127  }
128  else
129  mooseError("Trying to get a non-existent component of variable '" + var_name + "'");
130  }
131  else
132  mooseError("Trying to get a non-existent variable '" + var_name + "'");
133 }
bool _c_nodal
True if we provide coupling to nodal values.
Definition: Coupleable.h:327
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
std::map< std::string, std::vector< MooseVariable * > > _coupled_vars
Coupled vars whose values we provide.
Definition: Coupleable.h:321
virtual RealGradient InitialCondition::gradient ( const Point &  )
inlinevirtualinherited

The gradient of the variable at a point.

This is optional. Note that if you are using C1 continuous elements you will want to use an initial condition that defines this!

Reimplemented in FunctionIC.

Definition at line 86 of file InitialCondition.h.

Referenced by InitialCondition::compute().

86 { return RealGradient(); };
RealVectorValue RealGradient
Definition: Assembly.h:43
template<typename T >
bool BlockRestrictable::hasBlockMaterialProperty ( const std::string &  prop_name)
inherited

Check if a material property is valid for all blocks of this object.

This method returns true if the supplied property name has been declared in a Material object on the block ids for this object.

Template Parameters
TThe type of material property
Parameters
prop_namethe name of the property to query
Returns
true if the property exists for all block ids of the object, otherwise false
See also
Material::hasBlockMaterialProperty

Definition at line 254 of file BlockRestrictable.h.

Referenced by BlockRestrictable::~BlockRestrictable().

255 {
256  mooseAssert(_blk_material_data != NULL, "MaterialData pointer is not defined");
257  return hasBlockMaterialPropertyHelper(prop_name) &&
258  _blk_material_data->haveProperty<T>(prop_name);
259 }
std::shared_ptr< MaterialData > _blk_material_data
Pointer to the MaterialData class for this object.
virtual bool hasBlockMaterialPropertyHelper(const std::string &prop_name)
A helper method to allow the Material object to specialize the behavior of hasBlockMaterialProperty.
bool BlockRestrictable::hasBlockMaterialPropertyHelper ( const std::string &  prop_name)
protectedvirtualinherited

A helper method to allow the Material object to specialize the behavior of hasBlockMaterialProperty.

It also avoid circular #include problems.

See also
hasBlockMaterialProperty

Definition at line 250 of file BlockRestrictable.C.

Referenced by BlockRestrictable::hasBlockMaterialProperty().

251 {
252 
253  // Reference to MaterialWarehouse for testing and retrieving block ids
255 
256  // Complete set of ids that this object is active
257  const std::set<SubdomainID> & ids = blockRestricted() ? blockIDs() : meshBlockIDs();
258 
259  // Loop over each id for this object
260  for (const auto & id : ids)
261  {
262  // Storage of material properties that have been DECLARED on this id
263  std::set<std::string> declared_props;
264 
265  // If block materials exist, populated the set of properties that were declared
266  if (warehouse.hasActiveBlockObjects(id))
267  {
268  const std::vector<std::shared_ptr<Material>> & mats = warehouse.getActiveBlockObjects(id);
269  for (const auto & mat : mats)
270  {
271  const std::set<std::string> & mat_props = mat->getSuppliedItems();
272  declared_props.insert(mat_props.begin(), mat_props.end());
273  }
274  }
275 
276  // If the supplied property is not in the list of properties on the current id, return false
277  if (declared_props.find(prop_name) == declared_props.end())
278  return false;
279  }
280 
281  // If you get here the supplied property is defined on all blocks
282  return true;
283 }
virtual const std::set< SubdomainID > & blockIDs() const
Return the block subdomain ids for this object.
const std::set< SubdomainID > & meshBlockIDs() const
Return all of the SubdomainIDs for the mesh.
FEProblemBase * _blk_feproblem
Pointer to FEProblemBase.
Material objects are special in that they have additional objects created automatically (see FEProble...
const std::map< SubdomainID, std::vector< std::shared_ptr< T > > > & getActiveBlockObjects(THREAD_ID tid=0) const
const MaterialWarehouse & getMaterialWarehouse()
bool hasActiveBlockObjects(THREAD_ID tid=0) const
virtual bool blockRestricted() const
Returns true if this object has been restricted to a boundary.
bool BlockRestrictable::hasBlocks ( const SubdomainName &  name) const
inherited

Test if the supplied block name is valid for this object.

Parameters
nameA SubdomainName to check
Returns
True if the given id is valid for this object

Definition at line 180 of file BlockRestrictable.C.

Referenced by LineMaterialSamplerBase< T >::execute(), BlockRestrictable::hasBlocks(), and BlockRestrictable::~BlockRestrictable().

181 {
182  // Create a vector and utilize the getSubdomainIDs function, which
183  // handles the ANY_BLOCK_ID (getSubdomainID does not)
184  std::vector<SubdomainName> names(1);
185  names[0] = name;
186  return hasBlocks(_blk_mesh->getSubdomainIDs(names));
187 }
bool hasBlocks(const SubdomainName &name) const
Test if the supplied block name is valid for this object.
std::vector< SubdomainID > getSubdomainIDs(const std::vector< SubdomainName > &subdomain_name) const
Get the associated subdomainIDs for the subdomain names that are passed in.
Definition: MooseMesh.C:1051
MooseMesh * _blk_mesh
Pointer to Mesh.
bool BlockRestrictable::hasBlocks ( const std::vector< SubdomainName > &  names) const
inherited

Test if the supplied vector of block names are valid for this object.

Parameters
namesA vector of SubdomainNames to check
Returns
True if the given ids are valid for this object

Definition at line 190 of file BlockRestrictable.C.

191 {
192  return hasBlocks(_blk_mesh->getSubdomainIDs(names));
193 }
bool hasBlocks(const SubdomainName &name) const
Test if the supplied block name is valid for this object.
std::vector< SubdomainID > getSubdomainIDs(const std::vector< SubdomainName > &subdomain_name) const
Get the associated subdomainIDs for the subdomain names that are passed in.
Definition: MooseMesh.C:1051
MooseMesh * _blk_mesh
Pointer to Mesh.
bool BlockRestrictable::hasBlocks ( const SubdomainID id) const
inherited

Test if the supplied block ids are valid for this object.

Parameters
idA SubdomainID to check
Returns
True if the given id is valid for this object

Definition at line 196 of file BlockRestrictable.C.

197 {
198  if (_blk_ids.empty() || _blk_ids.find(Moose::ANY_BLOCK_ID) != _blk_ids.end())
199  return true;
200  else
201  return _blk_ids.find(id) != _blk_ids.end();
202 }
const SubdomainID ANY_BLOCK_ID
Definition: MooseTypes.h:117
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
bool BlockRestrictable::hasBlocks ( const std::vector< SubdomainID > &  ids) const
inherited

Test if the supplied vector block ids are valid for this object.

Parameters
idsA vector of SubdomainIDs ids to check
Returns
True if the all of the given ids are found within the ids for this object

Definition at line 205 of file BlockRestrictable.C.

206 {
207  std::set<SubdomainID> ids_set(ids.begin(), ids.end());
208  return hasBlocks(ids_set);
209 }
bool hasBlocks(const SubdomainName &name) const
Test if the supplied block name is valid for this object.
bool BlockRestrictable::hasBlocks ( const std::set< SubdomainID > &  ids) const
inherited

Test if the supplied set of block ids are valid for this object.

Parameters
idsA std::set of SubdomainIDs to check
Returns
True if the all of the given ids are found within the ids for this object
See also
isSubset

Definition at line 212 of file BlockRestrictable.C.

213 {
214  if (_blk_ids.empty() || _blk_ids.find(Moose::ANY_BLOCK_ID) != _blk_ids.end())
215  return true;
216  else
217  return std::includes(_blk_ids.begin(), _blk_ids.end(), ids.begin(), ids.end());
218 }
const SubdomainID ANY_BLOCK_ID
Definition: MooseTypes.h:117
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
bool BoundaryRestrictable::hasBoundary ( const BoundaryName &  name) const
inherited

Test if the supplied boundary name is valid for this object.

Parameters
nameA BoundaryName to check
Returns
True if the given id is valid for this object

Definition at line 183 of file BoundaryRestrictable.C.

Referenced by NodalNormalsPreprocessor::execute(), BoundaryRestrictable::hasBoundary(), and BoundaryRestrictable::hasBoundaryMaterialPropertyHelper().

184 {
185  // Create a vector and utilize the getBoundaryIDs function, which
186  // handles the ANY_BOUNDARY_ID (getBoundaryID does not)
187  return hasBoundary(_bnd_mesh->getBoundaryIDs({name}));
188 }
std::vector< BoundaryID > getBoundaryIDs(const Elem *const elem, const unsigned short int side) const
Returns a vector of boundary IDs for the requested element on the requested side. ...
Definition: MooseMesh.C:1990
MooseMesh * _bnd_mesh
Point to mesh.
bool hasBoundary(const BoundaryName &name) const
Test if the supplied boundary name is valid for this object.
bool BoundaryRestrictable::hasBoundary ( const std::vector< BoundaryName > &  names) const
inherited

Test if the supplied vector of boundary names are valid for this object.

Parameters
namesA vector of BoundaryNames to check
Returns
True if the given ids are valid for this object

Definition at line 191 of file BoundaryRestrictable.C.

192 {
193  return hasBoundary(_bnd_mesh->getBoundaryIDs(names));
194 }
std::vector< BoundaryID > getBoundaryIDs(const Elem *const elem, const unsigned short int side) const
Returns a vector of boundary IDs for the requested element on the requested side. ...
Definition: MooseMesh.C:1990
MooseMesh * _bnd_mesh
Point to mesh.
bool hasBoundary(const BoundaryName &name) const
Test if the supplied boundary name is valid for this object.
bool BoundaryRestrictable::hasBoundary ( const BoundaryID id) const
inherited

Test if the supplied boundary ids are valid for this object.

Parameters
idA BoundaryID to check
Returns
True if the given id is valid for this object

Definition at line 197 of file BoundaryRestrictable.C.

198 {
199  if (_bnd_ids.empty() || _bnd_ids.find(Moose::ANY_BOUNDARY_ID) != _bnd_ids.end())
200  return true;
201  else
202  return _bnd_ids.find(id) != _bnd_ids.end();
203 }
std::set< BoundaryID > _bnd_ids
Set of the boundary ids.
const BoundaryID ANY_BOUNDARY_ID
Definition: MooseTypes.h:119
bool BoundaryRestrictable::hasBoundary ( const std::vector< BoundaryID > &  ids,
TEST_TYPE  type = ALL 
) const
inherited

Test if the supplied vector boundary ids are valid for this object.

Parameters
idsA vector of BoundaryIDs ids to check
typeA flag for the type of matching to perform: ALL requires that all supplied ids must match those of the object; ANY requires that any one of the supplied ids must match those of the object
Returns
True if the all of the given ids are found within the ids for this object

Definition at line 206 of file BoundaryRestrictable.C.

207 {
208  std::set<BoundaryID> ids_set(ids.begin(), ids.end());
209  return hasBoundary(ids_set, type);
210 }
bool hasBoundary(const BoundaryName &name) const
Test if the supplied boundary name is valid for this object.
MatType type
bool BoundaryRestrictable::hasBoundary ( const std::set< BoundaryID > &  ids,
TEST_TYPE  type = ALL 
) const
inherited

Test if the supplied set of boundary ids are valid for this object.

Parameters
idsA std::set of BoundaryIDs to check
typeA flag for the type of matching to perform: ALL requires that all supplied ids must match those of the object; ANY requires that any one of the supplied ids must match those of the object
Returns
True if the all of the given ids are found within the ids for this object
See also
isSubset

Definition at line 213 of file BoundaryRestrictable.C.

214 {
215  // An empty input is assumed to be ANY_BOUNDARY_ID
216  if (ids.empty() || ids.find(Moose::ANY_BOUNDARY_ID) != ids.end())
217  return true;
218 
219  // All supplied IDs must match those of the object
220  else if (type == ALL)
221  {
222  if (_bnd_ids.find(Moose::ANY_BOUNDARY_ID) != _bnd_ids.end())
223  return true;
224  else
225  return std::includes(_bnd_ids.begin(), _bnd_ids.end(), ids.begin(), ids.end());
226  }
227  // Any of the supplied IDs must match those of the object
228  else
229  {
230  // Loop through the supplied ids
231  for (const auto & id : ids)
232  {
233  // Test the current supplied id
234  bool test = hasBoundary(id);
235 
236  // If the id exists in the stored ids, then return true, otherwise
237  if (test)
238  return true;
239  }
240  return false;
241  }
242 }
std::set< BoundaryID > _bnd_ids
Set of the boundary ids.
bool hasBoundary(const BoundaryName &name) const
Test if the supplied boundary name is valid for this object.
MatType type
const BoundaryID ANY_BOUNDARY_ID
Definition: MooseTypes.h:119
template<typename T >
bool BoundaryRestrictable::hasBoundaryMaterialProperty ( const std::string &  prop_name) const
inherited

Check if a material property is valid for all boundaries of this object.

This method returns true if the supplied property name has been declared in a Material object on the boundary ids for this object.

Template Parameters
TThe type of material property
Parameters
prop_namethe name of the property to query
Returns
true if the property exists for all boundary ids of the object, otherwise false

Definition at line 228 of file BoundaryRestrictable.h.

229 {
230  // If you get here the supplied property is defined on all boundaries, but is still subject
231  // existence in the MateialData class
232  return hasBoundaryMaterialPropertyHelper(prop_name) &&
233  _bnd_material_data->haveProperty<T>(prop_name);
234 }
bool hasBoundaryMaterialPropertyHelper(const std::string &prop_name) const
A helper method to avoid circular #include problems.
std::shared_ptr< MaterialData > _bnd_material_data
Pointer to MaterialData for boundary (.
bool BoundaryRestrictable::hasBoundaryMaterialPropertyHelper ( const std::string &  prop_name) const
protectedinherited

A helper method to avoid circular #include problems.

See also
hasBoundaryMaterialProperty

Definition at line 274 of file BoundaryRestrictable.C.

Referenced by BoundaryRestrictable::hasBoundaryMaterialProperty().

275 {
276  // Reference to MaterialWarehouse for testing and retrieving boundary ids
278 
279  // Complete set of BoundaryIDs that this object is defined
280  const std::set<BoundaryID> & ids =
282 
283  // Loop over each BoundaryID for this object
284  for (const auto & id : ids)
285  {
286  // Storage of material properties that have been DECLARED on this BoundaryID
287  std::set<std::string> declared_props;
288 
289  // If boundary materials exist, populated the set of properties that were declared
290  if (warehouse.hasActiveBoundaryObjects(id))
291  {
292  const std::vector<std::shared_ptr<Material>> & mats = warehouse.getActiveBoundaryObjects(id);
293  for (const auto & mat : mats)
294  {
295  const std::set<std::string> & mat_props = mat->getSuppliedItems();
296  declared_props.insert(mat_props.begin(), mat_props.end());
297  }
298  }
299 
300  // If the supplied property is not in the list of properties on the current id, return false
301  if (declared_props.find(prop_name) == declared_props.end())
302  return false;
303  }
304 
305  // If you get here the supplied property is defined on all boundaries
306  return true;
307 }
virtual const std::set< BoundaryID > & boundaryIDs() const
Return the boundary IDs for this object.
const std::map< BoundaryID, std::vector< std::shared_ptr< T > > > & getActiveBoundaryObjects(THREAD_ID tid=0) const
Material objects are special in that they have additional objects created automatically (see FEProble...
const std::set< BoundaryID > & meshBoundaryIDs() const
Returns the set of all boundary ids for the entire mesh.
bool hasActiveBoundaryObjects(THREAD_ID tid=0) const
bool hasBoundary(const BoundaryName &name) const
Test if the supplied boundary name is valid for this object.
const MaterialWarehouse & getMaterialWarehouse()
FEProblemBase * _bnd_feproblem
Pointer to FEProblemBase.
const BoundaryID ANY_BOUNDARY_ID
Definition: MooseTypes.h:119
void BlockRestrictable::initializeBlockRestrictable ( const MooseObject moose_object)
protectedinherited

An initialization routine needed for dual constructors.

Definition at line 78 of file BlockRestrictable.C.

Referenced by BlockRestrictable::BlockRestrictable().

79 {
80  // If the mesh pointer is not defined, but FEProblemBase is, get it from there
81  if (_blk_feproblem != NULL && _blk_mesh == NULL)
83 
84  // Check that the mesh pointer was defined, it is required for this class to operate
85  if (_blk_mesh == NULL)
86  mooseError("The input parameters must contain a pointer to FEProblem via '_fe_problem' or a "
87  "pointer to the MooseMesh via '_mesh'");
88 
89  // Populate the MaterialData pointer
90  if (_blk_feproblem != NULL)
92 
93  // The 'block' input is defined
94  if (moose_object->isParamValid("block"))
95  {
96  // Extract the blocks from the input
97  _blocks = moose_object->getParam<std::vector<SubdomainName>>("block");
98 
99  // Get the IDs from the supplied names
100  std::vector<SubdomainID> vec_ids = _blk_mesh->getSubdomainIDs(_blocks);
101 
102  // Store the IDs, handling ANY_BLOCK_ID if supplied
103  if (std::find(_blocks.begin(), _blocks.end(), "ANY_BLOCK_ID") != _blocks.end())
105  else
106  _blk_ids.insert(vec_ids.begin(), vec_ids.end());
107  }
108 
109  // When 'blocks' is not set and there is a "variable", use the blocks from the variable
110  else if (moose_object->isParamValid("variable"))
111  {
112  std::string variable_name = moose_object->parameters().getMooseType("variable");
113  if (!variable_name.empty())
115  }
116 
117  // Produce error if the object is not allowed to be both block and boundary restricted
118  if (!_blk_dual_restrictable && !_boundary_ids.empty() && !_boundary_ids.empty())
119  if (!_boundary_ids.empty() && _boundary_ids.find(Moose::ANY_BOUNDARY_ID) == _boundary_ids.end())
120  mooseError("Attempted to restrict the object '",
121  _blk_name,
122  "' to a block, but the object is already restricted by boundary");
123 
124  // If no blocks were defined above, specify that it is valid on all blocks
125  if (_blk_ids.empty())
126  {
128  _blocks = {"ANY_BLOCK_ID"};
129  }
130 
131  // If this object is block restricted, check that defined blocks exist on the mesh
132  if (_blk_ids.find(Moose::ANY_BLOCK_ID) == _blk_ids.end())
133  {
134  const std::set<SubdomainID> & valid_ids = _blk_mesh->meshSubdomains();
135  std::vector<SubdomainID> diff;
136 
137  std::set_difference(_blk_ids.begin(),
138  _blk_ids.end(),
139  valid_ids.begin(),
140  valid_ids.end(),
141  std::back_inserter(diff));
142 
143  if (!diff.empty())
144  {
145  std::ostringstream msg;
146  msg << "The object '" << _blk_name
147  << "' contains the following block ids that do not exist on the mesh:";
148  for (const auto & id : diff)
149  msg << " " << id;
150  mooseError(msg.str());
151  }
152  }
153 }
const bool _blk_dual_restrictable
Flag for allowing dual restriction.
const std::set< SubdomainID > & meshSubdomains() const
Returns a read-only reference to the set of subdomains currently present in the Mesh.
Definition: MooseMesh.C:2157
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
FEProblemBase * _blk_feproblem
Pointer to FEProblemBase.
const std::set< SubdomainID > & activeSubdomains() const
std::shared_ptr< MaterialData > _blk_material_data
Pointer to the MaterialData class for this object.
THREAD_ID _blk_tid
Thread id for this object.
std::vector< SubdomainName > _blocks
Vector the block names supplied by the user via the input file.
bool isParamValid(const std::string &name) const
Test if the supplied parameter is valid.
Definition: MooseObject.h:67
const T & getParam(const std::string &name) const
Retrieve a parameter for the object.
Definition: MooseObject.h:122
std::string getMooseType(const std::string &name) const
Utility functions for retrieving one of the MooseTypes variables into the common "string" base class...
std::shared_ptr< MaterialData > getMaterialData(Moose::MaterialDataType type, THREAD_ID tid=0)
const SubdomainID ANY_BLOCK_ID
Definition: MooseTypes.h:117
const InputParameters & parameters() const
Get the parameters of the object.
Definition: MooseObject.h:53
virtual MooseMesh & mesh() override
const std::set< BoundaryID > & _boundary_ids
Reference to the boundary_ids, defaults to an empty set if not provided.
std::vector< SubdomainID > getSubdomainIDs(const std::vector< SubdomainName > &subdomain_name) const
Get the associated subdomainIDs for the subdomain names that are passed in.
Definition: MooseMesh.C:1051
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
virtual MooseVariable & getVariable(THREAD_ID tid, const std::string &var_name) override
Returns the variable reference for requested variable which may be in any system. ...
const std::string & _blk_name
Name of the object.
MooseMesh * _blk_mesh
Pointer to Mesh.
const BoundaryID ANY_BOUNDARY_ID
Definition: MooseTypes.h:119
virtual void InitialCondition::initialSetup ( )
inlinevirtualinherited

Gets called at the beginning of the simulation before this object is asked to do its job.

Note: This method is normally inherited from SetupInterface. However in this case it makes no sense to inherit the other virtuals available in that class so we are adding this virtual directly to this class with out the extra inheritance.

Definition at line 94 of file InitialCondition.h.

94 {}
bool BlockRestrictable::isBlockSubset ( const std::set< SubdomainID > &  ids) const
inherited

Test if the class block ids are a subset of the supplied objects.

Parameters
idsA std::set of Subdomains to check
Returns
True if all of the block ids for this class are found within the given ids (opposite of hasBlocks)
See also
hasBlocks

Definition at line 221 of file BlockRestrictable.C.

Referenced by BlockRestrictable::checkVariable(), BlockRestrictable::isBlockSubset(), and BlockRestrictable::~BlockRestrictable().

222 {
223  // An empty input is assumed to be ANY_BLOCK_ID
224  if (ids.empty() || ids.find(Moose::ANY_BLOCK_ID) != ids.end())
225  return true;
226 
227  if (_blk_ids.find(Moose::ANY_BLOCK_ID) != _blk_ids.end())
228  return std::includes(ids.begin(),
229  ids.end(),
230  _blk_mesh->meshSubdomains().begin(),
231  _blk_mesh->meshSubdomains().end());
232  else
233  return std::includes(ids.begin(), ids.end(), _blk_ids.begin(), _blk_ids.end());
234 }
const std::set< SubdomainID > & meshSubdomains() const
Returns a read-only reference to the set of subdomains currently present in the Mesh.
Definition: MooseMesh.C:2157
const SubdomainID ANY_BLOCK_ID
Definition: MooseTypes.h:117
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
MooseMesh * _blk_mesh
Pointer to Mesh.
bool BlockRestrictable::isBlockSubset ( const std::vector< SubdomainID > &  ids) const
inherited

Test if the class block ids are a subset of the supplied objects.

Parameters
idsA std::vector of Subdomains to check
Returns
True if all of the block ids for this class are found within the given ids (opposite of hasBlocks)
See also
hasBlocks

Definition at line 237 of file BlockRestrictable.C.

238 {
239  std::set<SubdomainID> ids_set(ids.begin(), ids.end());
240  return isBlockSubset(ids_set);
241 }
bool isBlockSubset(const std::set< SubdomainID > &ids) const
Test if the class block ids are a subset of the supplied objects.
bool BoundaryRestrictable::isBoundarySubset ( const std::set< BoundaryID > &  ids) const
inherited

Test if the class boundary ids are a subset of the supplied objects.

Parameters
idsA std::set of boundaries to check
Returns
True if all of the boundary ids for this class are found within the given ids (opposite of hasBoundary)
See also
hasBoundary

Definition at line 245 of file BoundaryRestrictable.C.

Referenced by BoundaryRestrictable::isBoundarySubset().

246 {
247  // An empty input is assumed to be ANY_BOUNDARY_ID
248  if (ids.empty() || ids.find(Moose::ANY_BOUNDARY_ID) != ids.end())
249  return true;
250 
251  if (_bnd_ids.find(Moose::ANY_BOUNDARY_ID) != _bnd_ids.end())
252  return std::includes(ids.begin(),
253  ids.end(),
254  _bnd_mesh->meshBoundaryIds().begin(),
255  _bnd_mesh->meshBoundaryIds().end());
256  else
257  return std::includes(ids.begin(), ids.end(), _bnd_ids.begin(), _bnd_ids.end());
258 }
const std::set< BoundaryID > & meshBoundaryIds() const
Returns a read-only reference to the set of boundary IDs currently present in the Mesh...
Definition: MooseMesh.C:2163
MooseMesh * _bnd_mesh
Point to mesh.
std::set< BoundaryID > _bnd_ids
Set of the boundary ids.
const BoundaryID ANY_BOUNDARY_ID
Definition: MooseTypes.h:119
bool BoundaryRestrictable::isBoundarySubset ( const std::vector< BoundaryID > &  ids) const
inherited

Definition at line 261 of file BoundaryRestrictable.C.

262 {
263  std::set<BoundaryID> ids_set(ids.begin(), ids.end());
264  return isBoundarySubset(ids_set);
265 }
bool isBoundarySubset(const std::set< BoundaryID > &ids) const
Test if the class boundary ids are a subset of the supplied objects.
bool Coupleable::isCoupled ( const std::string &  var_name,
unsigned int  i = 0 
)
protectedvirtualinherited

Returns true if a variables has been coupled as name.

Parameters
var_nameThe name the kernel wants to refer to the variable as.
iBy default 0, in general the index to test in a vector of MooseVariable pointers.
Returns
True if a coupled variable has the supplied name

Definition at line 91 of file Coupleable.C.

Referenced by Coupleable::coupled(), Coupleable::coupledDot(), Coupleable::coupledDotDu(), Coupleable::coupledGradient(), Coupleable::coupledGradientOld(), Coupleable::coupledGradientOlder(), Coupleable::coupledGradientPreviousNL(), Coupleable::coupledNodalDot(), Coupleable::coupledNodalValue(), Coupleable::coupledNodalValueOld(), Coupleable::coupledNodalValueOlder(), Coupleable::coupledNodalValuePreviousNL(), Coupleable::coupledSecond(), Coupleable::coupledSecondOld(), Coupleable::coupledSecondOlder(), Coupleable::coupledSecondPreviousNL(), Coupleable::coupledSolutionDoFs(), Coupleable::coupledSolutionDoFsOld(), Coupleable::coupledSolutionDoFsOlder(), Coupleable::coupledValue(), Coupleable::coupledValueOld(), Coupleable::coupledValueOlder(), and Coupleable::coupledValuePreviousNL().

92 {
93  std::map<std::string, std::vector<MooseVariable *>>::iterator it = _coupled_vars.find(var_name);
94  if (it != _coupled_vars.end())
95  return (i < it->second.size());
96  else
97  {
98  // Make sure the user originally requested this value in the InputParameter syntax
99  if (!_coupleable_params.hasCoupledValue(var_name))
100  mooseError("The coupled variable \"",
101  var_name,
102  "\" was never added to this objects's "
103  "InputParameters, please double-check your "
104  "spelling");
105 
106  return false;
107  }
108 }
bool hasCoupledValue(const std::string &coupling_name) const
Return whether or not the coupled variable exists.
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
std::map< std::string, std::vector< MooseVariable * > > _coupled_vars
Coupled vars whose values we provide.
Definition: Coupleable.h:321
const InputParameters & _coupleable_params
Local InputParameters.
Definition: Coupleable.h:333
bool MooseObject::isParamValid ( const std::string &  name) const
inlineinherited

Test if the supplied parameter is valid.

Parameters
nameThe name of the parameter to test

Definition at line 67 of file MooseObject.h.

Referenced by BicubicSplineFunction::BicubicSplineFunction(), Piecewise::buildFromFile(), Piecewise::buildFromXandY(), GeneratedMesh::buildMesh(), LibmeshPartitioner::clone(), OversampleOutput::cloneMesh(), CSVReader::CSVReader(), MultiAppNearestNodeTransfer::execute(), FileOutput::FileOutput(), MultiApp::fillPositions(), MultiAppNearestNodeTransfer::getLocalNodes(), MultiAppNearestNodeTransfer::getNearestNode(), IterationAdaptiveDT::init(), EigenExecutionerBase::init(), MooseMesh::init(), AdvancedOutput::initExecutionTypes(), BlockRestrictable::initializeBlockRestrictable(), BoundaryRestrictable::initializeBoundaryRestrictable(), SolutionAux::initialSetup(), MooseParsedVectorFunction::initialSetup(), Console::initialSetup(), Receiver::initialSetup(), SolutionFunction::initialSetup(), MooseParsedGradFunction::initialSetup(), MooseParsedFunction::initialSetup(), AdvancedOutput::initialSetup(), AdvancedOutput::initPostprocessorOrVectorPostprocessorLists(), IterationAdaptiveDT::IterationAdaptiveDT(), LeastSquaresFit::LeastSquaresFit(), LibmeshPartitioner::LibmeshPartitioner(), BreakBoundaryOnSubdomain::modify(), MeshExtruder::modify(), MeshSideSet::modify(), AssignElementSubdomainID::modify(), RenameBlock::modify(), ParsedSubdomainMeshModifier::modify(), SubdomainBoundingBox::modify(), EigenExecutionerBase::normalizeSolution(), Output::Output(), Exodus::outputSetup(), PetscOutput::PetscOutput(), Piecewise::Piecewise(), SolutionUserObject::readExodusII(), RenameBlock::RenameBlock(), Piecewise::setData(), SolutionUserObject::SolutionUserObject(), and TimePeriod::TimePeriod().

67 { return _pars.isParamValid(name); }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
bool isParamValid(const std::string &name) const
This method returns parameters that have been initialized in one fashion or another, i.e.
const InputParameters & _pars
Parameters of this object, references the InputParameters stored in the InputParametersWarehouse.
Definition: MooseObject.h:111
const std::set< SubdomainID > & BlockRestrictable::meshBlockIDs ( ) const
inherited

Return all of the SubdomainIDs for the mesh.

Returns
A set of all subdomians for the entire mesh

Definition at line 244 of file BlockRestrictable.C.

Referenced by BlockRestrictable::checkVariable(), BlockRestrictable::getBlockCoordSystem(), BlockRestrictable::hasBlockMaterialPropertyHelper(), and BlockRestrictable::~BlockRestrictable().

245 {
246  return _blk_mesh->meshSubdomains();
247 }
const std::set< SubdomainID > & meshSubdomains() const
Returns a read-only reference to the set of subdomains currently present in the Mesh.
Definition: MooseMesh.C:2157
MooseMesh * _blk_mesh
Pointer to Mesh.
const std::set< BoundaryID > & BoundaryRestrictable::meshBoundaryIDs ( ) const
inherited

Returns the set of all boundary ids for the entire mesh.

Returns
A const reference the the boundary ids for the entire mesh

Definition at line 268 of file BoundaryRestrictable.C.

Referenced by BoundaryRestrictable::hasBoundaryMaterialPropertyHelper().

269 {
270  return _bnd_mesh->getBoundaryIDs();
271 }
std::vector< BoundaryID > getBoundaryIDs(const Elem *const elem, const unsigned short int side) const
Returns a vector of boundary IDs for the requested element on the requested side. ...
Definition: MooseMesh.C:1990
MooseMesh * _bnd_mesh
Point to mesh.
template<typename... Args>
void MooseObject::mooseDeprecated ( Args &&...  args) const
inlineinherited
template<typename... Args>
void MooseObject::mooseError ( Args &&...  args) const
inlineinherited

Definition at line 80 of file MooseObject.h.

Referenced by FEProblemBase::addInitialCondition(), DiracKernel::addPointWithValidId(), FEProblemBase::addPostprocessor(), MooseMesh::addQuadratureNode(), FEProblemBase::addVectorPostprocessor(), Output::advancedExecuteOn(), AnnularMesh::AnnularMesh(), MultiApp::appPostprocessorValue(), MultiApp::appProblem(), MultiApp::appProblemBase(), MultiApp::appUserObjectBase(), Function::average(), Axisymmetric2D3DSolutionFunction::Axisymmetric2D3DSolutionFunction(), BicubicSplineFunction::BicubicSplineFunction(), BoundingValueElementDamper::BoundingValueElementDamper(), BoundingValueNodalDamper::BoundingValueNodalDamper(), BoundsAux::BoundsAux(), MooseMesh::buildCoarseningMap(), Piecewise::buildFromFile(), Piecewise::buildFromXandY(), Piecewise::buildFromXY(), TiledMesh::buildMesh(), GeneratedMesh::buildMesh(), ImageMesh::buildMesh3D(), MooseMesh::buildRefinementMap(), EigenExecutionerBase::chebyshev(), FEProblemBase::checkCoordinateSystems(), FEProblemBase::checkDependMaterialsHelper(), FEProblemBase::checkDisplacementOrders(), Material::checkExecutionStage(), Steady::checkIntegrity(), EigenExecutionerBase::checkIntegrity(), SubProblem::checkMatProps(), FEProblemBase::checkProblemIntegrity(), Material::checkStatefulSanity(), FEProblemBase::checkUserObjects(), LibmeshPartitioner::clone(), CompositeFunction::CompositeFunction(), ElementLpNormAux::compute(), ElementH1ErrorFunctionAux::compute(), TimeSequenceStepperBase::computeFailedDT(), IterationAdaptiveDT::computeFailedDT(), TimeStepper::computeFailedDT(), FEProblemBase::computeResidual(), Material::computeSubdomainProperties(), PenetrationAux::computeValue(), TimeStepper::constrainStep(), AuxKernel::coupledDot(), AuxKernel::coupledDotDu(), DebugResidualAux::DebugResidualAux(), BicubicSplineFunction::derivative(), DGKernel::DGKernel(), SolutionUserObject::discontinuousPointValue(), SolutionUserObject::discontinuousPointValueGradient(), FEProblemBase::duplicateVariableCheck(), EigenProblem::EigenProblem(), Eigenvalues::Eigenvalues(), ElementalVariableValue::ElementalVariableValue(), MooseMesh::errorIfDistributedMesh(), SolutionUserObject::evalMeshFunction(), SolutionUserObject::evalMeshFunctionGradient(), SolutionUserObject::evalMultiValuedMeshFunction(), SolutionUserObject::evalMultiValuedMeshFunctionGradient(), PerflogDumper::execute(), NodalValueSampler::execute(), MultiAppPostprocessorTransfer::execute(), DiscreteElementUserObject::execute(), MultiAppPostprocessorInterpolationTransfer::execute(), MultiAppVariableValueSamplePostprocessorTransfer::execute(), MultiAppNearestNodeTransfer::execute(), PointValue::execute(), MultiAppPostprocessorToAuxScalarTransfer::execute(), MultiAppScalarToAuxScalarTransfer::execute(), MultiAppVariableValueSampleTransfer::execute(), FindValueOnLine::execute(), MultiAppInterpolationTransfer::execute(), TimeExtremeValue::execute(), LeastSquaresFit::execute(), FEProblemBase::executeControls(), FileOutput::FileOutput(), MultiApp::fillPositions(), VerifyElementUniqueID::finalize(), VerifyNodalUniqueID::finalize(), DiscreteElementUserObject::finalize(), MemoryUsage::finalize(), PointSamplerBase::finalize(), Transfer::find_sys(), FiniteDifferencePreconditioner::FiniteDifferencePreconditioner(), FunctionDT::FunctionDT(), FunctionScalarAux::FunctionScalarAux(), FunctionScalarIC::FunctionScalarIC(), GapValueAux::GapValueAux(), GeneratedMesh::GeneratedMesh(), GenericConstantMaterial::GenericConstantMaterial(), GenericFunctionMaterial::GenericFunctionMaterial(), MooseMesh::getBoundaryID(), MultiApp::getBoundingBox(), MooseMesh::getCoarseningMap(), FEProblemBase::getCoordSystem(), PiecewiseConstant::getDirection(), FEProblemBase::getDistribution(), MultiApp::getExecutioner(), FEProblemBase::getFunction(), SolutionUserObject::getLocalVarIndex(), AuxKernel::getMaterialProperty(), AuxKernel::getMaterialPropertyOld(), AuxKernel::getMaterialPropertyOlder(), GeneratedMesh::getMaxInDimension(), AnnularMesh::getMaxInDimension(), FEProblemBase::getMaxQps(), FEProblemBase::getMaxShapeFunctions(), GeneratedMesh::getMinInDimension(), AnnularMesh::getMinInDimension(), MooseMesh::getMortarInterface(), MooseMesh::getMortarInterfaceByName(), MooseMesh::getNodeBlockIds(), MooseMesh::getNodeList(), FEProblemBase::getNonlinearSystem(), MooseMesh::getPairedBoundaryMapping(), ImageMesh::GetPixelInfo(), MaterialStdVectorAux::getRealValue(), MooseMesh::getRefinementMap(), FEProblemBase::getSampler(), DisplacedProblem::getScalarVariable(), FEProblemBase::getScalarVariable(), MooseMesh::getSubdomainBoundaryIds(), MooseMesh::getSubdomainID(), DisplacedProblem::getSystem(), FEProblemBase::getSystem(), FEProblemBase::getUserObjectBase(), NumVars::getValue(), PerformanceData::getValue(), Residual::getValue(), FindValueOnLine::getValueAtPoint(), DisplacedProblem::getVariable(), FEProblemBase::getVariable(), MultiApp::globalAppToLocal(), MooseParsedVectorFunction::gradient(), AdvancedOutput::hasOutputHelper(), CSVTimeSequenceStepper::init(), IterationAdaptiveDT::init(), EigenExecutionerBase::init(), MooseMesh::init(), FEProblemBase::init(), NumPicardIterations::initialize(), FullSolveMultiApp::initialSetup(), SolutionAux::initialSetup(), Axisymmetric2D3DSolutionFunction::initialSetup(), Exodus::initialSetup(), SolutionFunction::initialSetup(), SolutionUserObject::initialSetup(), FEProblemBase::initialSetup(), AdvancedOutput::initOutputList(), AdvancedOutput::initShowHideLists(), Material::initStatefulProperties(), Function::integral(), IntegratedBC::IntegratedBC(), InterfaceKernel::InterfaceKernel(), EigenExecutionerBase::inversePowerIteration(), InversePowerMethod::InversePowerMethod(), IterationAdaptiveDT::IterationAdaptiveDT(), KernelBase::KernelBase(), LeastSquaresFit::LeastSquaresFit(), LibmeshPartitioner::LibmeshPartitioner(), LinearCombinationFunction::LinearCombinationFunction(), LinearCombinationPostprocessor::LinearCombinationPostprocessor(), LinearNodalConstraint::LinearNodalConstraint(), LineMaterialSamplerBase< T >::LineMaterialSamplerBase(), MaterialRealTensorValueAux::MaterialRealTensorValueAux(), MaterialRealVectorValueAux::MaterialRealVectorValueAux(), MaterialStdVectorRealGradientAux::MaterialStdVectorRealGradientAux(), MaterialVectorPostprocessor::MaterialVectorPostprocessor(), SubProblem::meshChanged(), MeshExtruder::MeshExtruder(), SideSetsFromNormals::modify(), SideSetsFromPoints::modify(), AddExtraNodeset::modify(), MeshExtruder::modify(), AssignElementSubdomainID::modify(), AddAllSideSetsByNormals::modify(), ElementDeleterBase::modify(), ParsedSubdomainMeshModifier::modify(), RenameBlock::modify(), ImageSubdomain::modify(), BoundingBoxNodeSet::modify(), OrientedSubdomainBoundingBox::modify(), AddSideSetsFromBoundingBox::modify(), SubdomainBoundingBox::modify(), MultiAppMeshFunctionTransfer::MultiAppMeshFunctionTransfer(), MultiAppPostprocessorTransfer::MultiAppPostprocessorTransfer(), NearestNodeDistanceAux::NearestNodeDistanceAux(), NearestNodeValueAux::NearestNodeValueAux(), NodalBC::NodalBC(), NodalConstraint::NodalConstraint(), NodalEqualValueConstraint::NodalEqualValueConstraint(), NodalKernel::NodalKernel(), NodalVariableValue::NodalVariableValue(), NumDOFs::NumDOFs(), NumNonlinearIterations::NumNonlinearIterations(), VTKOutput::output(), XDA::output(), AdvancedOutput::outputElementalVariables(), AdvancedOutput::outputInput(), AdvancedOutput::outputNodalVariables(), AdvancedOutput::outputPostprocessors(), AdvancedOutput::outputScalarVariables(), AdvancedOutput::outputSystemInformation(), Console::outputVectorPostprocessors(), AdvancedOutput::outputVectorPostprocessors(), PiecewiseBilinear::parse(), ParsedAddSideset::ParsedAddSideset(), ParsedAux::ParsedAux(), ParsedODEKernel::ParsedODEKernel(), ParsedSubdomainMeshModifier::ParsedSubdomainMeshModifier(), PatternedMesh::PatternedMesh(), PhysicsBasedPreconditioner::PhysicsBasedPreconditioner(), Piecewise::Piecewise(), PiecewiseBilinear::PiecewiseBilinear(), PiecewiseLinearInterpolationMaterial::PiecewiseLinearInterpolationMaterial(), PiecewiseMultilinear::PiecewiseMultilinear(), SolutionUserObject::pointValueGradientWrapper(), SolutionUserObject::pointValueWrapper(), LStableDirk2::postStep(), LStableDirk3::postStep(), ImplicitMidpoint::postStep(), ExplicitTVDRK2::postStep(), AStableDirk4::postStep(), LStableDirk4::postStep(), ExplicitRK2::postStep(), Predictor::Predictor(), SolutionUserObject::readExodusII(), SolutionUserObject::readXda(), RelativeSolutionDifferenceNorm::RelativeSolutionDifferenceNorm(), RenameBlock::RenameBlock(), ScalarComponentIC::ScalarComponentIC(), BicubicSplineFunction::secondDerivative(), FEProblemBase::setCoordSystem(), Piecewise::setData(), EigenProblem::setEigenproblemType(), Sampler::setNumberOfRequiedRandomSeeds(), Split::setup(), TransientMultiApp::setupApp(), TimeSequenceStepperBase::setupSequence(), Transient::setupTimeIntegrator(), SideSetsFromNormals::SideSetsFromNormals(), SideSetsFromPoints::SideSetsFromPoints(), SolutionUserObject::SolutionUserObject(), FullSolveMultiApp::solveStep(), UserObject::spatialValue(), SphericalAverage::SphericalAverage(), StitchedMesh::StitchedMesh(), NodalUserObject::subdomainSetup(), GeneralUserObject::subdomainSetup(), Constraint::subdomainSetup(), Console::systemInfoFlags(), Terminator::Terminator(), TestSetupPostprocessorDataActionFunction::TestSetupPostprocessorDataActionFunction(), DiscreteElementUserObject::threadJoin(), GeneralUserObject::threadJoin(), Function::timeDerivative(), TimeExtremeValue::TimeExtremeValue(), TimePeriod::TimePeriod(), MultiAppCopyTransfer::transfer(), MultiAppMeshFunctionTransfer::transferVariable(), Transient::Transient(), TransientMultiApp::TransientMultiApp(), EqualValueBoundaryConstraint::updateConstrainedNodes(), SolutionUserObject::updateExodusBracketingTimeIndices(), Axisymmetric2D3DSolutionFunction::value(), ValueRangeMarker::ValueRangeMarker(), ValueThresholdMarker::ValueThresholdMarker(), MultiAppTransfer::variableIntegrityCheck(), VariableResidual::VariableResidual(), VariableTimeIntegrationAux::VariableTimeIntegrationAux(), VectorOfPostprocessors::VectorOfPostprocessors(), VectorPostprocessorFunction::VectorPostprocessorFunction(), MooseParsedGradFunction::vectorValue(), MooseParsedFunction::vectorValue(), and VolumeHistogram::VolumeHistogram().

81  {
82  std::ostringstream oss;
83  moose::internal::mooseStreamAll(oss, std::forward<Args>(args)...);
84  std::string msg = oss.str();
85  callMooseErrorRaw(msg, &_app);
86  }
void mooseStreamAll(std::ostringstream &ss)
Definition: MooseError.C:78
void callMooseErrorRaw(std::string &msg, MooseApp *app)
Definition: MooseObject.C:45
MooseApp & _app
The MooseApp this object is associated with.
Definition: MooseObject.h:108
template<typename... Args>
void MooseObject::mooseInfo ( Args &&...  args) const
inlineinherited

Definition at line 101 of file MooseObject.h.

102  {
103  moose::internal::mooseInfoStream(_console, std::forward<Args>(args)...);
104  }
void mooseInfoStream(S &oss, Args &&...args)
Definition: MooseError.h:145
const ConsoleStream _console
An instance of helper class to write streams to the Console objects.
template<typename... Args>
void MooseObject::mooseWarning ( Args &&...  args) const
inlineinherited
const std::string& MooseObject::name ( ) const
inlineinherited

Get the name of the object.

Returns
The name of the object

Definition at line 47 of file MooseObject.h.

Referenced by FEProblemBase::addDistribution(), FEProblemBase::addFunction(), FEProblemBase::addIndicator(), FEProblemBase::addInitialCondition(), FEProblemBase::addMarker(), FEProblemBase::addMaterial(), MooseMesh::addMortarInterface(), FEProblemBase::addMultiApp(), FEProblemBase::addPredictor(), FEProblemBase::addSampler(), FEProblemBase::addTransfer(), FEProblemBase::addUserObject(), Output::advancedExecuteOn(), MultiApp::appPostprocessorValue(), MultiApp::appProblem(), MultiApp::appProblemBase(), MultiApp::appUserObjectBase(), AStableDirk4::AStableDirk4(), Function::average(), FEProblemBase::checkDependMaterialsHelper(), Damper::checkMinDamping(), Material::checkStatefulSanity(), CompositeFunction::CompositeFunction(), Material::computeSubdomainProperties(), AuxKernel::coupledCallback(), AuxKernel::coupledDot(), AuxKernel::coupledDotDu(), MultiApp::createApp(), DGKernel::DGKernel(), AB2PredictorCorrector::estimateTimeError(), SolutionUserObject::evalMeshFunction(), SolutionUserObject::evalMeshFunctionGradient(), SolutionUserObject::evalMultiValuedMeshFunction(), SolutionUserObject::evalMultiValuedMeshFunctionGradient(), MultiAppPostprocessorTransfer::execute(), MultiAppPostprocessorInterpolationTransfer::execute(), MultiAppVariableValueSamplePostprocessorTransfer::execute(), MultiAppNearestNodeTransfer::execute(), PointValue::execute(), MultiAppPostprocessorToAuxScalarTransfer::execute(), MultiAppScalarToAuxScalarTransfer::execute(), MultiAppVariableValueSampleTransfer::execute(), MultiAppMeshFunctionTransfer::execute(), MultiAppInterpolationTransfer::execute(), MultiAppUserObjectTransfer::execute(), MultiAppProjectionTransfer::execute(), MultiAppCopyTransfer::execute(), FileOutput::FileOutput(), MultiApp::fillPositions(), PointSamplerBase::finalize(), GeneralUserObject::GeneralUserObject(), MultiApp::getBoundingBox(), Control::getControllableParameterHelper(), Control::getControllableValue(), AuxKernel::getDependObjects(), MultiApp::getExecutioner(), OutputWarehouse::getFileNumbers(), SolutionUserObject::getLocalVarIndex(), AuxKernel::getMaterialProperty(), SubProblem::getMaterialPropertyBlockNames(), SubProblem::getMaterialPropertyBoundaryNames(), AuxKernel::getMaterialPropertyOld(), AuxKernel::getMaterialPropertyOlder(), OutputWarehouse::getOutput(), Transient::getTimeStepperName(), InitialCondition::getUserObject(), AuxKernel::getUserObject(), InitialCondition::getUserObjectByName(), AuxKernel::getUserObjectByName(), AdvancedOutput::hasOutputHelper(), FEProblemBase::init(), CSVReader::initialize(), MultiAppProjectionTransfer::initialSetup(), InitialCondition::initialSetup(), SolutionUserObject::initialSetup(), AdvancedOutput::initOutputList(), AdvancedOutput::initPostprocessorOrVectorPostprocessorLists(), Material::initStatefulProperties(), Function::integral(), IntegratedBC::IntegratedBC(), InterfaceKernel::InterfaceKernel(), KernelBase::KernelBase(), LinearCombinationFunction::LinearCombinationFunction(), Marker::Marker(), MaterialDerivativeTestKernelBase< T >::MaterialDerivativeTestKernelBase(), MaterialVectorPostprocessor::MaterialVectorPostprocessor(), ElementDeleterBase::modify(), NodalBC::NodalBC(), NodalEqualValueConstraint::NodalEqualValueConstraint(), NodalKernel::NodalKernel(), NodalValueSampler::NodalValueSampler(), NodalVariableValue::NodalVariableValue(), DOFMapOutput::output(), AdvancedOutput::outputElementalVariables(), AdvancedOutput::outputInput(), AdvancedOutput::outputNodalVariables(), ConsoleUtils::outputOutputInformation(), Nemesis::outputPostprocessors(), Exodus::outputPostprocessors(), AdvancedOutput::outputPostprocessors(), AdvancedOutput::outputScalarVariables(), AdvancedOutput::outputSystemInformation(), AdvancedOutput::outputVectorPostprocessors(), MooseObject::parameters(), Executioner::parentOutputPositionChanged(), ParsedAddSideset::ParsedAddSideset(), ParsedAux::ParsedAux(), ParsedODEKernel::ParsedODEKernel(), ParsedSubdomainMeshModifier::ParsedSubdomainMeshModifier(), PointSamplerBase::PointSamplerBase(), SubProblem::registerRecoverableData(), SubProblem::registerRestartableData(), Material::resetQpProperties(), Sampler::Sampler(), ScalarComponentIC::ScalarComponentIC(), MooseMesh::setBoundaryName(), Control::setControllableValue(), OutputWarehouse::setFileNumbers(), MooseMesh::setSubdomainName(), Split::setup(), TransientMultiApp::setupApp(), SideValueSampler::SideValueSampler(), TransientMultiApp::solveStep(), UserObject::spatialValue(), SphericalAverage::SphericalAverage(), StitchedMesh::StitchedMesh(), Function::timeDerivative(), TransientMultiApp::TransientMultiApp(), MultiAppTransfer::variableIntegrityCheck(), VariableResidual::VariableResidual(), and AdvancedOutput::wantOutput().

47 { return _name; }
const std::string & _name
The name of this object, reference to value stored in InputParameters.
Definition: MooseObject.h:114
unsigned int BlockRestrictable::numBlocks ( ) const
inherited

Return the number of blocks for this object.

Returns
The number of subdomains

Definition at line 174 of file BlockRestrictable.C.

Referenced by BlockRestrictable::~BlockRestrictable().

175 {
176  return (unsigned int)_blk_ids.size();
177 }
std::set< SubdomainID > _blk_ids
Set of block ids supplied by the user via the input file (for error reporting)
unsigned int BoundaryRestrictable::numBoundaryIDs ( ) const
inherited

Return the number of boundaries for this object.

Returns
The number of boundary ids

Definition at line 165 of file BoundaryRestrictable.C.

166 {
167  return (unsigned int)_bnd_ids.size();
168 }
std::set< BoundaryID > _bnd_ids
Set of the boundary ids.
const InputParameters& MooseObject::parameters ( ) const
inlineinherited
bool BoundaryRestrictable::restricted ( const std::set< BoundaryID > &  ids)
staticinherited

Helper for determining if the object is boundary restricted.

This is needed for the MaterialPropertyInterface.

Definition at line 177 of file BoundaryRestrictable.C.

Referenced by BoundaryRestrictable::boundaryRestricted().

178 {
179  return ids.find(Moose::ANY_BOUNDARY_ID) == ids.end();
180 }
const BoundaryID ANY_BOUNDARY_ID
Definition: MooseTypes.h:119
template<typename T >
void DependencyResolverInterface::sort ( typename std::vector< T > &  vector)
staticinherited

Given a vector, sort using the getRequested/SuppliedItems sets.

Definition at line 63 of file DependencyResolverInterface.h.

Referenced by DependencyResolverInterface::DependencyResolverInterface().

64 {
65  DependencyResolver<T> resolver;
66 
67  typename std::vector<T>::iterator start = vector.begin();
68  typename std::vector<T>::iterator end = vector.end();
69 
70  for (typename std::vector<T>::iterator iter = start; iter != end; ++iter)
71  {
72  const std::set<std::string> & requested_items = (*iter)->getRequestedItems();
73 
74  for (typename std::vector<T>::iterator iter2 = start; iter2 != end; ++iter2)
75  {
76  if (iter == iter2)
77  continue;
78 
79  const std::set<std::string> & supplied_items = (*iter2)->getSuppliedItems();
80 
81  std::set<std::string> intersect;
82  std::set_intersection(requested_items.begin(),
83  requested_items.end(),
84  supplied_items.begin(),
85  supplied_items.end(),
86  std::inserter(intersect, intersect.end()));
87 
88  // If the intersection isn't empty then there is a dependency here
89  if (!intersect.empty())
90  resolver.insertDependency(*iter, *iter2);
91  }
92  }
93 
94  // Sort based on dependencies
95  std::stable_sort(start, end, resolver);
96 }
void insertDependency(const T &key, const T &value)
Insert a dependency pair - the first value or the "key" depends on the second value or the "value"...
void Coupleable::validateExecutionerType ( const std::string &  name) const
protectedinherited

Checks to make sure that the current Executioner has set "_it_transient" when old/older values are coupled in.

Parameters
namethe name of the variable

Definition at line 646 of file Coupleable.C.

Referenced by Coupleable::coupledGradientOld(), Coupleable::coupledGradientOlder(), NeighborCoupleable::coupledNeighborGradientOld(), NeighborCoupleable::coupledNeighborGradientOlder(), NeighborCoupleable::coupledNeighborValueOld(), NeighborCoupleable::coupledNeighborValueOlder(), Coupleable::coupledNodalValueOld(), Coupleable::coupledNodalValueOlder(), Coupleable::coupledSecondOld(), Coupleable::coupledSecondOlder(), Coupleable::coupledSolutionDoFsOld(), Coupleable::coupledSolutionDoFsOlder(), Coupleable::coupledValueOld(), and Coupleable::coupledValueOlder().

647 {
648  if (!_c_fe_problem.isTransient())
649  mooseError("You may not couple in old or older values of \"",
650  name,
651  "\" when using a \"Steady\" executioner.");
652 }
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
FEProblemBase & _c_fe_problem
Definition: Coupleable.h:318
virtual bool isTransient() const override
Real RandomIC::value ( const Point &  p)
overridevirtual

The value of the variable at a point.

This must be overridden by derived classes.

Implements InitialCondition.

Definition at line 42 of file RandomIC.C.

43 {
44  // Random number between 0 and 1
45  Real rand_num = MooseRandom::rand();
46 
47  // Between 0 and range
48  rand_num *= _range;
49 
50  // Between min and max
51  rand_num += _min;
52 
53  return rand_num;
54 }
static double rand()
This method returns the next random number (double format) from the generator.
Definition: MooseRandom.h:55
Real _range
Definition: RandomIC.h:55
Real _min
Definition: RandomIC.h:53
MooseVariable& InitialCondition::variable ( )
inlineinherited

Definition at line 67 of file InitialCondition.h.

67 { return _var; }
MooseVariable & _var
The variable that this initial condition is acting upon.
VariableValue & Coupleable::writableCoupledValue ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns a writable reference to a coupled variable.

Note: you should not have to use this very often (use coupledValue() instead) but there are situations, such as writing to multiple AuxVariables from a single AuxKernel, where it is required.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Reference to a VariableValue for the coupled variable
See also
Kernel::value

Definition at line 192 of file Coupleable.C.

193 {
194  return const_cast<VariableValue &>(coupledValue(var_name, comp));
195 }
virtual const VariableValue & coupledValue(const std::string &var_name, unsigned int comp=0)
Returns value of a coupled variable.
Definition: Coupleable.C:167

Member Data Documentation

MooseApp& MooseObject::_app
protectedinherited

The MooseApp this object is associated with.

Definition at line 108 of file MooseObject.h.

Referenced by AB2PredictorCorrector::AB2PredictorCorrector(), Executioner::addAttributeReporter(), FEProblemBase::addMaterial(), FEProblemBase::addMultiApp(), FEProblemBase::allowOutput(), AStableDirk4::AStableDirk4(), FileMesh::buildMesh(), FEProblemBase::checkNonlinearConvergence(), OversampleOutput::cloneMesh(), FEProblemBase::computeJacobian(), FEProblemBase::computeResidualType(), Console::Console(), TimeStepper::constrainStep(), MultiApp::createApp(), EigenExecutionerBase::EigenExecutionerBase(), EigenKernel::EigenKernel(), InversePowerMethod::execute(), NonlinearEigen::execute(), Transient::execute(), Steady::execute(), FileOutput::FileOutput(), FEProblemBase::forceOutput(), MooseObject::getMooseApp(), InversePowerMethod::init(), NonlinearEigen::init(), Transient::init(), Steady::init(), MooseMesh::init(), NumPicardIterations::initialize(), TimePeriod::initialSetup(), Console::initialSetup(), MultiApp::initialSetup(), FEProblemBase::initialSetup(), AdvancedOutput::initOutputList(), FEProblemBase::initPetscOutput(), AdvancedOutput::initPostprocessorOrVectorPostprocessorLists(), InversePowerMethod::InversePowerMethod(), MooseObject::mooseError(), MooseMesh::MooseMesh(), NonlinearEigen::NonlinearEigen(), Tecplot::output(), Exodus::output(), Nemesis::output(), ControlOutput::outputActiveObjects(), ControlOutput::outputChangedControls(), ControlOutput::outputControls(), Exodus::outputEmptyTimestep(), Console::outputInput(), Exodus::outputInput(), Exodus::outputNodalVariables(), OversampleOutput::outputStep(), Output::outputStep(), FEProblemBase::outputStep(), Console::outputSystemInformation(), MultiApp::parentOutputPositionChanged(), PerformanceData::PerformanceData(), PetscOutput::petscLinearOutput(), PetscOutput::petscNonlinearOutput(), SubProblem::registerRecoverableData(), SubProblem::registerRestartableData(), FEProblemBase::setRestartFile(), TransientMultiApp::setupApp(), TimeSequenceStepperBase::setupSequence(), Transient::setupTimeIntegrator(), TransientMultiApp::solveStep(), FEProblemBase::subdomainSetup(), TimeExtremeValue::TimeExtremeValue(), TimePeriod::TimePeriod(), FEProblemBase::timestepSetup(), Transient::Transient(), and Console::write().

Assembly& InitialCondition::_assembly
protectedinherited

Definition at line 112 of file InitialCondition.h.

std::shared_ptr<MaterialData> BlockRestrictable::_blk_material_data
protectedinherited

Pointer to the MaterialData class for this object.

Definition at line 203 of file BlockRestrictable.h.

Referenced by BlockRestrictable::hasBlockMaterialProperty(), and BlockRestrictable::initializeBlockRestrictable().

FEProblemBase& Coupleable::_c_fe_problem
protectedinherited
bool Coupleable::_c_is_implicit
protectedinherited
bool Coupleable::_c_nodal
protectedinherited
const InputParameters& Coupleable::_c_parameters
protectedinherited

Definition at line 315 of file Coupleable.h.

Referenced by Coupleable::Coupleable().

const ConsoleStream ConsoleStreamInterface::_console
inherited

An instance of helper class to write streams to the Console objects.

Definition at line 37 of file ConsoleStreamInterface.h.

Referenced by IterationAdaptiveDT::acceptStep(), CreateProblemAction::act(), SetupRecoverFileBaseAction::act(), Adaptivity::adaptMesh(), FEProblemBase::adaptMesh(), FEProblemBase::advanceMultiApps(), SimplePredictor::apply(), FEProblemBase::backupMultiApps(), FEProblemBase::checkProblemIntegrity(), IterationAdaptiveDT::computeAdaptiveDT(), Transient::computeConstrainedDT(), NonlinearSystemBase::computeDamping(), IterationAdaptiveDT::computeDT(), IterationAdaptiveDT::computeFailedDT(), IterationAdaptiveDT::computeInterpolationDT(), FEProblemBase::computeResidualType(), IterationAdaptiveDT::constrainStep(), TimeStepper::constrainStep(), AB2PredictorCorrector::converged(), FEProblemBase::execMultiApps(), FEProblemBase::execMultiAppTransfers(), MultiAppPostprocessorTransfer::execute(), MultiAppPostprocessorInterpolationTransfer::execute(), MultiAppVariableValueSamplePostprocessorTransfer::execute(), MultiAppNearestNodeTransfer::execute(), MultiAppPostprocessorToAuxScalarTransfer::execute(), MultiAppScalarToAuxScalarTransfer::execute(), MultiAppVariableValueSampleTransfer::execute(), MultiAppUserObjectTransfer::execute(), MultiAppInterpolationTransfer::execute(), MultiAppMeshFunctionTransfer::execute(), MultiAppProjectionTransfer::execute(), MultiAppCopyTransfer::execute(), Steady::execute(), MultiAppDTKUserObjectTransfer::execute(), ActionWarehouse::executeActionsWithAction(), ActionWarehouse::executeAllActions(), MultiApp::globalAppToLocal(), InversePowerMethod::init(), NonlinearEigen::init(), Steady::init(), FEProblemBase::initialAdaptMesh(), FEProblemBase::initialSetup(), EigenExecutionerBase::inversePowerIteration(), Transient::keepGoing(), IterationAdaptiveDT::limitDTByFunction(), IterationAdaptiveDT::limitDTToPostprocessorValue(), EigenExecutionerBase::makeBXConsistent(), Console::meshChanged(), MooseObject::mooseDeprecated(), MooseObject::mooseInfo(), MooseObject::mooseWarning(), DOFMapOutput::output(), VariableResidualNormsDebugOutput::output(), Console::output(), ControlOutput::outputActiveObjects(), ControlOutput::outputChangedControls(), ControlOutput::outputControls(), Console::outputInput(), Console::outputPostprocessors(), Console::outputScalarVariables(), Console::outputSystemInformation(), FEProblemBase::possiblyRebuildGeomSearchPatches(), EigenExecutionerBase::postExecute(), ActionWarehouse::printActionDependencySets(), EigenExecutionerBase::printEigenvalue(), MaterialPropertyDebugOutput::printMaterialMap(), SolutionTimeAdaptiveDT::rejectStep(), DT2::rejectStep(), FEProblemBase::restoreMultiApps(), SimplePredictor::shouldApply(), NonlinearSystem::solve(), LStableDirk2::solve(), LStableDirk3::solve(), ImplicitMidpoint::solve(), ExplicitTVDRK2::solve(), AStableDirk4::solve(), LStableDirk4::solve(), ExplicitRK2::solve(), TransientMultiApp::solveStep(), Transient::solveStep(), DT2::step(), AB2PredictorCorrector::step(), NonlinearEigen::takeStep(), FEProblemBase::useFECache(), Console::writeTimestepInformation(), Console::writeVariableNorms(), and FEProblemBase::~FEProblemBase().

const Moose::CoordinateSystemType& InitialCondition::_coord_sys
protectedinherited

The coordinate system type for this problem, references the value in Assembly.

Definition at line 118 of file InitialCondition.h.

bool Coupleable::_coupleable_neighbor
protectedinherited
const InputParameters& Coupleable::_coupleable_params
protectedinherited

Local InputParameters.

Definition at line 333 of file Coupleable.h.

Referenced by Coupleable::getDefaultValue(), and Coupleable::isCoupled().

std::vector<MooseVariable *> Coupleable::_coupled_moose_vars
protectedinherited
std::map<std::string, std::vector<MooseVariable *> > Coupleable::_coupled_vars
protectedinherited

Coupled vars whose values we provide.

Definition at line 321 of file Coupleable.h.

Referenced by Coupleable::Coupleable(), Coupleable::coupledComponents(), Coupleable::getVar(), and Coupleable::isCoupled().

const Elem*& InitialCondition::_current_elem
protectedinherited

The current element we are on will retrieving values at specific points in the domain.

Note that this IS valid even for nodes shared among several elements.

Definition at line 128 of file InitialCondition.h.

Referenced by InitialCondition::compute().

const Node* InitialCondition::_current_node
protectedinherited

The current node if the point we are evaluating at also happens to be a node.

Otherwise the pointer will be NULL.

Definition at line 134 of file InitialCondition.h.

Referenced by InitialCondition::compute().

VariableGradient Coupleable::_default_gradient
protectedinherited

This will always be zero because the default values for optionally coupled variables is always constant.

Definition at line 342 of file Coupleable.h.

Referenced by Coupleable::Coupleable(), Coupleable::coupledGradient(), Coupleable::coupledGradientOld(), Coupleable::coupledGradientOlder(), Coupleable::coupledGradientPreviousNL(), and Coupleable::~Coupleable().

VariableSecond Coupleable::_default_second
protectedinherited

This will always be zero because the default values for optionally coupled variables is always constant.

Definition at line 345 of file Coupleable.h.

Referenced by Coupleable::Coupleable(), Coupleable::coupledSecond(), Coupleable::coupledSecondOld(), Coupleable::coupledSecondOlder(), Coupleable::coupledSecondPreviousNL(), and Coupleable::~Coupleable().

std::map<std::string, VariableValue *> Coupleable::_default_value
protectedinherited

Will hold the default value for optional coupled variables.

Definition at line 336 of file Coupleable.h.

Referenced by Coupleable::getDefaultValue(), and Coupleable::~Coupleable().

VariableValue Coupleable::_default_value_zero
protectedinherited

This will always be zero because the default values for optionally coupled variables is always constant and this is used for time derivative info.

Definition at line 339 of file Coupleable.h.

Referenced by Coupleable::Coupleable(), Coupleable::coupledDot(), Coupleable::coupledDotDu(), Coupleable::coupledNodalDot(), and Coupleable::~Coupleable().

std::set<std::string> InitialCondition::_depend_uo
protectedinherited
std::set<std::string> InitialCondition::_depend_vars
protectedinherited
const bool& MooseObject::_enabled
protectedinherited

Reference to the "enable" InputParaemters, used by Controls for toggling on/off MooseObjects.

Definition at line 117 of file MooseObject.h.

Referenced by MooseObject::enabled().

FEProblemBase& InitialCondition::_fe_problem
protectedinherited

Definition at line 108 of file InitialCondition.h.

const VariableGradient& ZeroInterface::_grad_zero
protectedinherited

Definition at line 45 of file ZeroInterface.h.

const bool InitialCondition::_ignore_uo_dependency
protectedinherited

If set, UOs retrieved by this IC will not be executed before this IC.

Definition at line 146 of file InitialCondition.h.

Referenced by InitialCondition::getUserObject(), InitialCondition::getUserObjectBase(), and InitialCondition::getUserObjectByName().

Real RandomIC::_max
protected

Definition at line 54 of file RandomIC.h.

Real RandomIC::_min
protected

Definition at line 53 of file RandomIC.h.

Referenced by value().

const std::string& MooseObject::_name
protectedinherited
const InputParameters& MooseObject::_pars
protectedinherited
unsigned int InitialCondition::_qp
protectedinherited

The current quadrature point, contains the "nth" node number when visiting nodes.

Definition at line 137 of file InitialCondition.h.

Referenced by InitialCondition::compute().

Real RandomIC::_range
protected

Definition at line 55 of file RandomIC.h.

Referenced by RandomIC(), and value().

const Real& ZeroInterface::_real_zero
protectedinherited

Definition at line 43 of file ZeroInterface.h.

const VariablePhiSecond& ZeroInterface::_second_phi_zero
protectedinherited

Definition at line 47 of file ZeroInterface.h.

const VariableSecond& ZeroInterface::_second_zero
protectedinherited

Definition at line 46 of file ZeroInterface.h.

std::set<std::string> InitialCondition::_supplied_vars
protectedinherited
SystemBase& InitialCondition::_sys
protectedinherited

Definition at line 109 of file InitialCondition.h.

Real& InitialCondition::_t
protectedinherited

Time.

Definition at line 115 of file InitialCondition.h.

Referenced by FunctionIC::gradient(), and FunctionIC::value().

THREAD_ID InitialCondition::_tid
protectedinherited

Definition at line 110 of file InitialCondition.h.

MooseVariable& InitialCondition::_var
protectedinherited

The variable that this initial condition is acting upon.

Definition at line 121 of file InitialCondition.h.

Referenced by InitialCondition::compute(), and InitialCondition::variable().

const VariableValue& ZeroInterface::_zero
protectedinherited

Definition at line 44 of file ZeroInterface.h.

FEProblemBase& ZeroInterface::_zi_feproblem
protectedinherited

Definition at line 41 of file ZeroInterface.h.

THREAD_ID ZeroInterface::_zi_tid
protectedinherited

Definition at line 42 of file ZeroInterface.h.


The documentation for this class was generated from the following files: