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Axisymmetric2D3DSolutionFunction Class Reference

Function for reading a 2D axisymmetric solution from file and mapping it to a 3D Cartesian system. More...

#include <Axisymmetric2D3DSolutionFunction.h>

Inheritance diagram for Axisymmetric2D3DSolutionFunction:
[legend]

Public Member Functions

 Axisymmetric2D3DSolutionFunction (const InputParameters &parameters)
 Constructor. More...
 
virtual Real value (Real t, const Point &p) override
 Override this to evaluate the scalar function at point (t,x,y,z), by default this returns zero, you must override it. More...
 
virtual void initialSetup () override
 Setup the function for use Gathers a pointer to the SolutionUserObject containing the solution that was read. More...
 
virtual RealVectorValue vectorValue (Real t, const Point &p)
 Override this to evaluate the vector function at a point (t,x,y,z), by default this returns a zero vector, you must override it. More...
 
virtual RealGradient gradient (Real t, const Point &p)
 Function objects can optionally provide a gradient at a point. More...
 
virtual Real timeDerivative (Real t, const Point &p)
 Get the time derivative of the function. More...
 
virtual Real integral ()
 
virtual Real average ()
 
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
 
virtual void timestepSetup ()
 Gets called at the beginning of the timestep before this object is asked to do its job. More...
 
virtual void jacobianSetup ()
 Gets called just before the Jacobian is computed and before this object is asked to do its job. More...
 
virtual void residualSetup ()
 Gets called just before the residual is computed and before this object is asked to do its job. More...
 
virtual void subdomainSetup ()
 Gets called when the subdomain changes (i.e. More...
 
virtual const std::vector< ExecFlagType > & execFlags () const
 Get the execution flag for the object. More...
 
ExecFlagType execBitFlags () const
 Build and return the execution flags as a bitfield. More...
 
bool isImplicit ()
 
bool hasPostprocessor (const std::string &name) const
 Determine if the Postprocessor exists. More...
 
bool hasPostprocessorByName (const PostprocessorName &name)
 Determine if the Postprocessor exists. More...
 
template<class T >
const T & getUserObject (const std::string &name)
 Get an user object with a given parameter name. More...
 
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)
 Get an user object with a given parameter name. More...
 
const UserObjectgetUserObjectBaseByName (const std::string &name)
 Get an user object with a given name. More...
 
virtual void meshChanged ()
 Called on this object when the mesh changes. More...
 
const std::vector< MooseVariableScalar * > & getCoupledMooseScalarVars ()
 Get the list of coupled scalar variables. More...
 
const PostprocessorValuegetPostprocessorValue (const std::string &name)
 Retrieve the value of a Postprocessor or one of it's old or older values. More...
 
const PostprocessorValuegetPostprocessorValueOld (const std::string &name)
 
const PostprocessorValuegetPostprocessorValueOlder (const std::string &name)
 
const PostprocessorValuegetPostprocessorValueByName (const PostprocessorName &name)
 Retrieve the value of the Postprocessor. More...
 
const PostprocessorValuegetPostprocessorValueOldByName (const PostprocessorName &name)
 
const PostprocessorValuegetPostprocessorValueOlderByName (const PostprocessorName &name)
 
const PostprocessorValuegetDefaultPostprocessorValue (const std::string &name)
 Return the default postprocessor value. More...
 

Static Public Member Functions

static MultiMooseEnum getExecuteOptions ()
 Returns the available options for the 'execute_on' input parameters. More...
 

Public Attributes

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

Protected Member Functions

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...
 
virtual bool isCoupledScalar (const std::string &var_name, unsigned int i=0)
 Returns true if a variables has been coupled_as name. More...
 
virtual unsigned int coupledScalarComponents (const std::string &var_name)
 Return the number of components to the coupled scalar variable. More...
 
virtual unsigned int coupledScalar (const std::string &var_name, unsigned int comp=0)
 Returns the index for a scalar coupled variable by name. More...
 
virtual Order coupledScalarOrder (const std::string &var_name, unsigned int comp=0)
 Returns the order for a scalar coupled variable by name. More...
 
virtual VariableValuecoupledScalarValue (const std::string &var_name, unsigned int comp=0)
 Returns value of a scalar coupled variable. More...
 
virtual VariableValuecoupledScalarValueOld (const std::string &var_name, unsigned int comp=0)
 Returns the old (previous time step) value of a scalar coupled variable. More...
 
virtual VariableValuecoupledScalarValueOlder (const std::string &var_name, unsigned int comp=0)
 Returns the older (two time steps previous) value of a scalar coupled variable. More...
 
virtual VariableValuecoupledScalarDot (const std::string &var_name, unsigned int comp=0)
 Returns the time derivative of a scalar coupled variable. More...
 
virtual VariableValuecoupledScalarDotDu (const std::string &var_name, unsigned int comp=0)
 Time derivative of a scalar coupled variable with respect to the coefficients. More...
 
VariableValuegetDefaultValue (const std::string &var_name)
 Helper method to return (and insert if necessary) the default value for an uncoupled variable. More...
 
MooseVariableScalargetScalarVar (const std::string &var_name, unsigned int comp)
 Extract pointer to a scalar coupled variable. More...
 

Protected Attributes

const SolutionUserObject_solution_object_ptr
 Pointer to SolutionUserObject containing the solution of interest. More...
 
const Real _scale_factor
 Factor to scale the solution by (default = 1) More...
 
const Real _add_factor
 Factor to add to the solution (default = 0) More...
 
const Real _axial_dim_ratio
 Ratio of axial dimension of 3d model to its counterpart in the 2d model. More...
 
const RealVectorValue _2d_axis_point1
 Two points that define the axis of rotation for the 2d model. More...
 
const RealVectorValue _2d_axis_point2
 
const RealVectorValue _3d_axis_point1
 Two points that define the axis of rotation for the 3d model. More...
 
const RealVectorValue _3d_axis_point2
 
const bool _has_component
 If the solution field is a vector, the desired component must be specified Has the component been specified? More...
 
const unsigned int _component
 The index of the component. More...
 
bool _default_axes
 Are the default axes of rotation being used? More...
 
std::vector< std::string > _var_names
 The variable names to extract from the file. More...
 
std::vector< unsigned int > _solution_object_var_indices
 The local SolutionUserObject indices for the variables extracted from the file. 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::vector< ExecFlagType_exec_flags
 execution flag (when is the object executed/evaluated) More...
 
const ExecFlagType_current_execute_flag
 Reference to FEProblemBase. More...
 
const InputParameters_ti_params
 
FEProblemBase_ti_feproblem
 
bool _is_implicit
 If the object is using implicit or explicit form. More...
 
Real & _t
 Time. More...
 
int & _t_step
 The number of the time step. More...
 
Real & _dt
 Time step size. More...
 
Real & _dt_old
 Size of the old time step. More...
 
bool _is_transient
 
FEProblemBase_mci_feproblem
 Reference to FEProblemBase instance. More...
 
const InputParameters_sc_parameters
 
FEProblemBase_sc_fe_problem
 
std::map< std::string, std::vector< MooseVariableScalar * > > _coupled_scalar_vars
 Coupled vars whose values we provide. More...
 
std::map< std::string, VariableValue * > _default_value
 Will hold the default value for optional coupled scalar variables. More...
 
std::vector< MooseVariableScalar * > _coupled_moose_scalar_vars
 Vector of coupled variables. More...
 
bool _sc_is_implicit
 True if implicit value is required. More...
 
const InputParameters_coupleable_params
 Local InputParameters. More...
 

Detailed Description

Function for reading a 2D axisymmetric solution from file and mapping it to a 3D Cartesian system.

This function extracts values from a solution read from a file via a SolutionUserObject. The appropriate transformations are applied to convert either scalar or vector functions from a 2D axisymmetric frame to a 3D Cartesian frame. It is possible to scale and add a constant to the solution.

Definition at line 34 of file Axisymmetric2D3DSolutionFunction.h.

Constructor & Destructor Documentation

Axisymmetric2D3DSolutionFunction::Axisymmetric2D3DSolutionFunction ( const InputParameters parameters)

Constructor.

Parameters
parametersThe input parameters for the function

Definition at line 70 of file Axisymmetric2D3DSolutionFunction.C.

72  : Function(parameters),
74  _scale_factor(getParam<Real>("scale_factor")),
75  _add_factor(getParam<Real>("add_factor")),
76  _axial_dim_ratio(getParam<Real>("axial_dimension_ratio")),
77  _2d_axis_point1(getParam<RealVectorValue>("2d_axis_point1")),
78  _2d_axis_point2(getParam<RealVectorValue>("2d_axis_point2")),
79  _3d_axis_point1(getParam<RealVectorValue>("3d_axis_point1")),
80  _3d_axis_point2(getParam<RealVectorValue>("3d_axis_point2")),
81  _has_component(isParamValid("component")),
82  _component(_has_component ? getParam<unsigned int>("component") : 99999),
83  _var_names(getParam<std::vector<std::string>>("from_variables"))
84 {
85  if (_has_component && _var_names.size() != 2)
86  mooseError("Must supply names of 2 variables in 'from_variables' if 'component' is specified");
87  else if (!_has_component && _var_names.size() == 2)
88  mooseError("Must supply 'component' if 2 variables specified in 'from_variables'");
89  else if (_var_names.size() > 2)
90  mooseError("If 'from_variables' is specified, it must have either 1 (scalar) or 2 (vector "
91  "components) variables");
92 
93  Point zero;
94  Point unit_vec_y;
95  unit_vec_y(1) = 1;
96  if (_2d_axis_point1 == zero && _2d_axis_point2 == unit_vec_y && _3d_axis_point1 == zero &&
97  _3d_axis_point2 == unit_vec_y)
98  _default_axes = true;
99  else
100  _default_axes = false;
101 
102  if (_3d_axis_point1.relative_fuzzy_equals(_3d_axis_point2))
103  mooseError("3d_axis_point1 and 3d_axis_point2 must be different points");
104  if (_2d_axis_point1.relative_fuzzy_equals(_2d_axis_point2))
105  mooseError("2d_axis_point1 and 2d_axis_point2 must be different points");
106 }
const Real _add_factor
Factor to add to the solution (default = 0)
const unsigned int _component
The index of the component.
const RealVectorValue _2d_axis_point1
Two points that define the axis of rotation for the 2d model.
const RealVectorValue _3d_axis_point1
Two points that define the axis of rotation for the 3d model.
Function(const InputParameters &parameters)
Class constructor.
Definition: Function.C:28
bool _default_axes
Are the default axes of rotation being used?
std::vector< std::string > _var_names
The variable names to extract from the file.
bool isParamValid(const std::string &name) const
Test if the supplied parameter is valid.
Definition: MooseObject.h:67
const SolutionUserObject * _solution_object_ptr
Pointer to SolutionUserObject containing the solution of interest.
const T & getParam(const std::string &name) const
Retrieve a parameter for the object.
Definition: MooseObject.h:122
const Real _axial_dim_ratio
Ratio of axial dimension of 3d model to its counterpart in the 2d model.
void mooseError(Args &&...args) const
Definition: MooseObject.h:80
const bool _has_component
If the solution field is a vector, the desired component must be specified Has the component been spe...
const Real _scale_factor
Factor to scale the solution by (default = 1)

Member Function Documentation

Real Function::average ( )
virtualinherited

Reimplemented in PiecewiseConstant, and PiecewiseLinear.

Definition at line 75 of file Function.C.

76 {
77  mooseError("Average method not defined for function ", name());
78  return 0;
79 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
void mooseError(Args &&...args) const
Definition: MooseObject.h:80
unsigned int ScalarCoupleable::coupledScalar ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns the index for a scalar coupled variable by name.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Index of coupled variable

Definition at line 99 of file ScalarCoupleable.C.

Referenced by ParsedODEKernel::ParsedODEKernel().

100 {
101  return getScalarVar(var_name, comp)->number();
102 }
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
unsigned int number() const
Get variable number coming from libMesh.
unsigned int ScalarCoupleable::coupledScalarComponents ( const std::string &  var_name)
protectedvirtualinherited

Return the number of components to the coupled scalar variable.

Parameters
var_nameThe of the coupled variable

Definition at line 189 of file ScalarCoupleable.C.

190 {
191  return _coupled_scalar_vars[var_name].size();
192 }
std::map< std::string, std::vector< MooseVariableScalar * > > _coupled_scalar_vars
Coupled vars whose values we provide.
VariableValue & ScalarCoupleable::coupledScalarDot ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns the time derivative of a scalar coupled variable.

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

Definition at line 161 of file ScalarCoupleable.C.

162 {
163  MooseVariableScalar * var = getScalarVar(var_name, comp);
164  return var->uDot();
165 }
VariableValue & uDot()
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
Class for scalar variables (they are different).
VariableValue & ScalarCoupleable::coupledScalarDotDu ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Time derivative of a scalar 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

Definition at line 168 of file ScalarCoupleable.C.

169 {
170  MooseVariableScalar * var = getScalarVar(var_name, comp);
171  return var->duDotDu();
172 }
VariableValue & duDotDu()
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
Class for scalar variables (they are different).
Order ScalarCoupleable::coupledScalarOrder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns the order for a scalar coupled variable by name.

Parameters
var_nameName of coupled variable
compComponent number for vector of coupled variables
Returns
Order of coupled variable

Definition at line 105 of file ScalarCoupleable.C.

106 {
107  if (!isCoupledScalar(var_name, comp))
109 
110  return getScalarVar(var_name, comp)->order();
111 }
virtual bool isCoupledScalar(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled_as name.
FEProblemBase & _sc_fe_problem
Order getMaxScalarOrder() const
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
Order order() const
Get the order of this variable Note: Order enum can be implicitly converted to unsigned int...
VariableValue & ScalarCoupleable::coupledScalarValue ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns value of a scalar 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 128 of file ScalarCoupleable.C.

Referenced by ParsedODEKernel::ParsedODEKernel().

129 {
130  if (!isCoupledScalar(var_name, comp))
131  return *getDefaultValue(var_name);
132 
133  MooseVariableScalar * var = getScalarVar(var_name, comp);
134  return (_sc_is_implicit) ? var->sln() : var->slnOld();
135 }
VariableValue & sln()
virtual bool isCoupledScalar(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled_as name.
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
bool _sc_is_implicit
True if implicit value is required.
Class for scalar variables (they are different).
VariableValue & slnOld()
VariableValue & ScalarCoupleable::coupledScalarValueOld ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns the old (previous time step) value of a scalar coupled variable.

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

Definition at line 138 of file ScalarCoupleable.C.

139 {
140  if (!isCoupledScalar(var_name, comp))
141  return *getDefaultValue(var_name);
142 
143  MooseVariableScalar * var = getScalarVar(var_name, comp);
144  return (_sc_is_implicit) ? var->slnOld() : var->slnOlder();
145 }
virtual bool isCoupledScalar(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled_as name.
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
bool _sc_is_implicit
True if implicit value is required.
Class for scalar variables (they are different).
VariableValue & slnOlder()
VariableValue & slnOld()
VariableValue & ScalarCoupleable::coupledScalarValueOlder ( const std::string &  var_name,
unsigned int  comp = 0 
)
protectedvirtualinherited

Returns the older (two time steps previous) value of a scalar coupled variable.

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

Definition at line 148 of file ScalarCoupleable.C.

149 {
150  if (!isCoupledScalar(var_name, comp))
151  return *getDefaultValue(var_name);
152 
153  MooseVariableScalar * var = getScalarVar(var_name, comp);
154  if (_sc_is_implicit)
155  return var->slnOlder();
156  else
157  mooseError("Older values not available for explicit schemes");
158 }
virtual bool isCoupledScalar(const std::string &var_name, unsigned int i=0)
Returns true if a variables has been coupled_as name.
void mooseError(Args &&...args)
Emit an error message with the given stringified, concatenated args and terminate the application...
Definition: MooseError.h:182
VariableValue * getDefaultValue(const std::string &var_name)
Helper method to return (and insert if necessary) the default value for an uncoupled variable...
MooseVariableScalar * getScalarVar(const std::string &var_name, unsigned int comp)
Extract pointer to a scalar coupled variable.
bool _sc_is_implicit
True if implicit value is required.
Class for scalar variables (they are different).
VariableValue & slnOlder()
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
ExecFlagType SetupInterface::execBitFlags ( ) const
inherited

Build and return the execution flags as a bitfield.

Definition at line 100 of file SetupInterface.C.

Referenced by EigenExecutionerBase::init().

101 {
102  unsigned int exec_bit_field = EXEC_NONE;
103  for (unsigned int i = 0; i < _exec_flags.size(); ++i)
104  exec_bit_field |= _exec_flags[i];
105 
106  return static_cast<ExecFlagType>(exec_bit_field);
107 }
std::vector< ExecFlagType > _exec_flags
execution flag (when is the object executed/evaluated)
ExecFlagType
Execution flags - when is the object executed/evaluated.
Definition: MooseTypes.h:90
const std::vector< ExecFlagType > & SetupInterface::execFlags ( ) const
virtualinherited

Get the execution flag for the object.

Reimplemented in MultiAppTransfer.

Definition at line 94 of file SetupInterface.C.

Referenced by ExecuteMooseObjectWarehouse< T >::addObjectMask(), and MultiAppTransfer::execFlags().

95 {
96  return _exec_flags;
97 }
std::vector< ExecFlagType > _exec_flags
execution flag (when is the object executed/evaluated)
const std::vector< MooseVariableScalar * > & ScalarCoupleable::getCoupledMooseScalarVars ( )
inherited

Get the list of coupled scalar variables.

Returns
The list of coupled variables

Definition at line 72 of file ScalarCoupleable.C.

Referenced by AuxScalarKernel::AuxScalarKernel(), and ScalarInitialCondition::ScalarInitialCondition().

73 {
75 }
std::vector< MooseVariableScalar * > _coupled_moose_scalar_vars
Vector of coupled variables.
const PostprocessorValue & PostprocessorInterface::getDefaultPostprocessorValue ( const std::string &  name)
inherited

Return the default postprocessor value.

Parameters
nameThe name of the postprocessor parameter
Returns
A const reference to the default value

Definition at line 92 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

93 {
95 }
const PostprocessorValue & getDefaultPostprocessorValue(const std::string &name, bool suppress_error=false) const
Get the default value for a postprocessor added with addPostprocessor.
const InputParameters & _ppi_params
PostprocessorInterface Parameters.
VariableValue * ScalarCoupleable::getDefaultValue ( const std::string &  var_name)
protectedinherited

Helper method to return (and insert if necessary) the default value for an uncoupled variable.

Parameters
var_namethe name of the variable for which to retrieve a default value
Returns
VariableValue * a pointer to the associated VarirableValue.

Definition at line 114 of file ScalarCoupleable.C.

Referenced by ScalarCoupleable::coupledScalarValue(), ScalarCoupleable::coupledScalarValueOld(), and ScalarCoupleable::coupledScalarValueOlder().

115 {
116  std::map<std::string, VariableValue *>::iterator default_value_it = _default_value.find(var_name);
117  if (default_value_it == _default_value.end())
118  {
121  default_value_it = _default_value.insert(std::make_pair(var_name, value)).first;
122  }
123 
124  return default_value_it->second;
125 }
MooseArray< Real > VariableValue
FEProblemBase & _sc_fe_problem
Order getMaxScalarOrder() const
const InputParameters & _coupleable_params
Local InputParameters.
std::map< std::string, VariableValue * > _default_value
Will hold the default value for optional coupled scalar variables.
Real defaultCoupledValue(const std::string &coupling_name) const
Get the default value for an optionally coupled variable.
MultiMooseEnum SetupInterface::getExecuteOptions ( )
staticinherited

Returns the available options for the 'execute_on' input parameters.

Returns
A MooseEnum with the available 'execute_on' options, the default is 'residual'

Definition at line 110 of file SetupInterface.C.

Referenced by AddNodalNormalsAction::act(), AdvancedOutput::addValidParams(), AdvancedOutput::initExecutionTypes(), OutputOnWarehouse::OutputOnWarehouse(), validParams< CommonOutputAction >(), validParams< Output >(), and validParams< SetupInterface >().

111 {
112  return MultiMooseEnum("none=0x00 initial=0x01 linear=0x02 nonlinear=0x04 timestep_end=0x08 "
113  "timestep_begin=0x10 final=0x20 custom=0x100",
114  "linear");
115 }
This is a "smart" enum class intended to replace many of the shortcomings in the C++ enum type It sho...
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 PostprocessorValue & PostprocessorInterface::getPostprocessorValue ( const std::string &  name)
inherited

Retrieve the value of a Postprocessor or one of it's old or older values.

Parameters
nameThe name of the Postprocessor parameter (see below)
Returns
A reference to the desired value

The name required by this method is the name that is hard-coded into your source code. For example, if you have a Kernel that requires a Postprocessor you may have an input file with "pp = my_pp", this function requires the "pp" name as input (see .../moose_test/functions/PostprocessorFunction.C)

see getPostprocessorValueByName getPostprocessorValueOldByName getPostprocessorValueOlderByName

Definition at line 29 of file PostprocessorInterface.C.

Referenced by GeneralUserObject::getPostprocessorValue(), and AuxKernel::getPostprocessorValue().

30 {
31  // Return the default if the Postprocessor does not exist and a default does, otherwise
32  // continue as usual
35  else
36  return _pi_feproblem.getPostprocessorValue(_ppi_params.get<PostprocessorName>(name));
37 }
bool hasPostprocessor(const std::string &name) const
Determine if the Postprocessor exists.
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
bool hasDefaultPostprocessorValue(const std::string &name) const
Returns true if a default PostprocessorValue is defined.
const PostprocessorValue & getDefaultPostprocessorValue(const std::string &name, bool suppress_error=false) const
Get the default value for a postprocessor added with addPostprocessor.
PostprocessorValue & getPostprocessorValue(const PostprocessorName &name)
Get a reference to the value associated with the postprocessor.
const InputParameters & _ppi_params
PostprocessorInterface Parameters.
const PostprocessorValue & PostprocessorInterface::getPostprocessorValueByName ( const PostprocessorName &  name)
inherited

Retrieve the value of the Postprocessor.

Parameters
namePostprocessor name (see below)
Returns
A reference to the desired value

The name required by this method is the name defined in the input file. For example, if you have a Kernel that requires a Postprocessor you may have an input file with "pp = my_pp", this method requires the "my_pp" name as input (see .../moose_test/functions/PostprocessorFunction.C)

see getPostprocessorValue getPostprocessorValueOld getPostprocessorValueOlder

Definition at line 62 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel(), GeneralUserObject::getPostprocessorValueByName(), AuxKernel::getPostprocessorValueByName(), and EigenExecutionerBase::inversePowerIteration().

63 {
65 }
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
PostprocessorValue & getPostprocessorValue(const PostprocessorName &name)
Get a reference to the value associated with the postprocessor.
const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOld ( const std::string &  name)
inherited

Definition at line 40 of file PostprocessorInterface.C.

41 {
42  // Return the default if the Postprocessor does not exist and a default does, otherwise
43  // continue as usual
46  else
47  return _pi_feproblem.getPostprocessorValueOld(_ppi_params.get<PostprocessorName>(name));
48 }
PostprocessorValue & getPostprocessorValueOld(const std::string &name)
Get the reference to the old value of a post-processor.
bool hasPostprocessor(const std::string &name) const
Determine if the Postprocessor exists.
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
bool hasDefaultPostprocessorValue(const std::string &name) const
Returns true if a default PostprocessorValue is defined.
const PostprocessorValue & getDefaultPostprocessorValue(const std::string &name, bool suppress_error=false) const
Get the default value for a postprocessor added with addPostprocessor.
const InputParameters & _ppi_params
PostprocessorInterface Parameters.
const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOldByName ( const PostprocessorName &  name)
inherited

Definition at line 68 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

69 {
71 }
PostprocessorValue & getPostprocessorValueOld(const std::string &name)
Get the reference to the old value of a post-processor.
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOlder ( const std::string &  name)
inherited

Definition at line 51 of file PostprocessorInterface.C.

52 {
53  // Return the default if the Postprocessor does not exist and a default does, otherwise
54  // continue as usual
57  else
58  return _pi_feproblem.getPostprocessorValueOlder(_ppi_params.get<PostprocessorName>(name));
59 }
bool hasPostprocessor(const std::string &name) const
Determine if the Postprocessor exists.
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
PostprocessorValue & getPostprocessorValueOlder(const std::string &name)
Get the reference to the older value of a post-processor.
bool hasDefaultPostprocessorValue(const std::string &name) const
Returns true if a default PostprocessorValue is defined.
const PostprocessorValue & getDefaultPostprocessorValue(const std::string &name, bool suppress_error=false) const
Get the default value for a postprocessor added with addPostprocessor.
const InputParameters & _ppi_params
PostprocessorInterface Parameters.
const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOlderByName ( const PostprocessorName &  name)
inherited

Definition at line 74 of file PostprocessorInterface.C.

75 {
77 }
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
PostprocessorValue & getPostprocessorValueOlder(const std::string &name)
Get the reference to the older value of a post-processor.
MooseVariableScalar * ScalarCoupleable::getScalarVar ( const std::string &  var_name,
unsigned int  comp 
)
protectedinherited

Extract pointer to a scalar coupled variable.

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

Definition at line 175 of file ScalarCoupleable.C.

Referenced by ScalarCoupleable::coupledScalar(), ScalarCoupleable::coupledScalarDot(), ScalarCoupleable::coupledScalarDotDu(), ScalarCoupleable::coupledScalarOrder(), ScalarCoupleable::coupledScalarValue(), ScalarCoupleable::coupledScalarValueOld(), ScalarCoupleable::coupledScalarValueOlder(), and ParsedODEKernel::ParsedODEKernel().

176 {
177  if (_coupled_scalar_vars.find(var_name) != _coupled_scalar_vars.end())
178  {
179  if (comp < _coupled_scalar_vars[var_name].size())
180  return _coupled_scalar_vars[var_name][comp];
181  else
182  mooseError("Trying to get a non-existent component of variable '" + var_name + "'");
183  }
184  else
185  mooseError("Trying to get a non-existent variable '" + var_name + "'");
186 }
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< MooseVariableScalar * > > _coupled_scalar_vars
Coupled vars whose values we provide.
template<class T >
const T & UserObjectInterface::getUserObject ( const std::string &  name)
inherited

Get an user object with a given parameter name.

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

Definition at line 85 of file UserObjectInterface.h.

86 {
87  unsigned int tid = isDiscreteUserObject(getUserObjectBase(name)) ? _uoi_tid : 0;
88  return _uoi_feproblem.getUserObject<T>(_uoi_params.get<UserObjectName>(name), tid);
89 }
bool isDiscreteUserObject(const UserObject &uo) const
Check if the user object is a DiscreteElementUserObject.
const InputParameters & _uoi_params
Parameters of the object with this interface.
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.
const UserObject & getUserObjectBase(const std::string &name)
Get an user object with a given parameter name.
const UserObject & UserObjectInterface::getUserObjectBase ( const std::string &  name)
inherited

Get an user object with a given parameter name.

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

Definition at line 28 of file UserObjectInterface.C.

Referenced by UserObjectInterface::getUserObject(), InitialCondition::getUserObjectBase(), and AuxKernel::getUserObjectBase().

29 {
30  return _uoi_feproblem.getUserObjectBase(_uoi_params.get<UserObjectName>(name));
31 }
const InputParameters & _uoi_params
Parameters of the object with this interface.
FEProblemBase & _uoi_feproblem
Reference to the FEProblemBase instance.
const UserObject & getUserObjectBase(const std::string &name)
Get the user object by its 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.
RealGradient Function::gradient ( Real  t,
const Point &  p 
)
virtualinherited

Function objects can optionally provide a gradient at a point.

By default this returns 0, you must override it.

Parameters
tThe time
pThe Point in space (x,y,z)
Returns
A gradient of the function evaluated at the time and location

Reimplemented in MooseParsedGradFunction, MooseParsedFunction, SolutionFunction, MooseParsedVectorFunction, BicubicSplineFunction, LinearCombinationFunction, and SplineFunction.

Definition at line 49 of file Function.C.

Referenced by ElementH1SemiError::computeQpIntegral(), ElementW1pError::computeQpIntegral(), ElementH1ErrorFunctionAux::computeValue(), and FunctionIC::gradient().

50 {
51  return RealGradient(0, 0, 0);
52 }
RealVectorValue RealGradient
Definition: Assembly.h:43
bool PostprocessorInterface::hasPostprocessor ( const std::string &  name) const
inherited

Determine if the Postprocessor exists.

Parameters
nameThe name of the Postprocessor parameter
Returns
True if the Postprocessor exists
See also
hasPostprocessorByName getPostprocessorValue

Definition at line 80 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel(), PostprocessorInterface::getPostprocessorValue(), PostprocessorInterface::getPostprocessorValueOld(), PostprocessorInterface::getPostprocessorValueOlder(), and TestSetupPostprocessorDataActionFunction::TestSetupPostprocessorDataActionFunction().

81 {
82  return _pi_feproblem.hasPostprocessor(_ppi_params.get<PostprocessorName>(name));
83 }
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
bool hasPostprocessor(const std::string &name)
Check existence of the postprocessor.
const InputParameters & _ppi_params
PostprocessorInterface Parameters.
bool PostprocessorInterface::hasPostprocessorByName ( const PostprocessorName &  name)
inherited

Determine if the Postprocessor exists.

Parameters
nameThe name of the Postprocessor
Returns
True if the Postprocessor exists
See also
hasPostprocessor getPostprocessorValueByName

Definition at line 86 of file PostprocessorInterface.C.

Referenced by VectorOfPostprocessors::VectorOfPostprocessors().

87 {
88  return _pi_feproblem.hasPostprocessor(name);
89 }
FEProblemBase & _pi_feproblem
Reference the the FEProblemBase class.
bool hasPostprocessor(const std::string &name)
Check existence of the postprocessor.
void Axisymmetric2D3DSolutionFunction::initialSetup ( )
overridevirtual

Setup the function for use Gathers a pointer to the SolutionUserObject containing the solution that was read.

A pointer is required because Functions are created prior to UserObjects, see Moose.C.

Reimplemented from SetupInterface.

Definition at line 109 of file Axisymmetric2D3DSolutionFunction.C.

110 {
111  // Get a pointer to the SolutionUserObject. A pointer is used because the UserObject is not
112  // available during the
113  // construction of the function
114  _solution_object_ptr = &getUserObject<SolutionUserObject>("solution");
115 
116  // If 'from_variable' is not specified, get the value from the SolutionUserObject
117  if (_var_names.size() == 0)
118  {
119  // Get all the variables from the SolutionUserObject
120  const std::vector<std::string> & vars = _solution_object_ptr->variableNames();
121 
122  // If there are more than one, throw an error
123  if (vars.size() > 1)
124  mooseError("If the SolutionUserObject contains multiple variables, the variable name must be "
125  "specified in the input file with 'from_variables'");
126 
127  // Define the variable
128  _var_names.push_back(vars[0]);
129  }
130  if (_2d_axis_point1(2) != 0)
131  mooseError("3rd component of 2d_axis_point1 must be zero");
132  if (_2d_axis_point2(2) != 0)
133  mooseError("3rd component of 2d_axis_point2 must be zero");
134 
136  for (unsigned int i = 0; i < _var_names.size(); ++i)
138 }
std::vector< unsigned int > _solution_object_var_indices
The local SolutionUserObject indices for the variables extracted from the file.
const RealVectorValue _2d_axis_point1
Two points that define the axis of rotation for the 2d model.
std::vector< std::string > _var_names
The variable names to extract from the file.
const SolutionUserObject * _solution_object_ptr
Pointer to SolutionUserObject containing the solution of interest.
void mooseError(Args &&...args) const
Definition: MooseObject.h:80
unsigned int getLocalVarIndex(const std::string &var_name) const
Returns the local index for a given variable name.
const std::vector< std::string > & variableNames() const
Real Function::integral ( )
virtualinherited

Reimplemented in PiecewiseConstant, and PiecewiseLinear.

Definition at line 68 of file Function.C.

69 {
70  mooseError("Integral method not defined for function ", name());
71  return 0;
72 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
void mooseError(Args &&...args) const
Definition: MooseObject.h:80
bool ScalarCoupleable::isCoupledScalar ( const std::string &  var_name,
unsigned int  i = 0 
)
protectedvirtualinherited

Returns true if a variables has been coupled_as name.

Parameters
var_nameThe of the coupled variable
iBy default 0, in general the index to test in a vector of MooseVariable pointers.

Definition at line 78 of file ScalarCoupleable.C.

Referenced by ScalarCoupleable::coupledScalarOrder(), ScalarCoupleable::coupledScalarValue(), ScalarCoupleable::coupledScalarValueOld(), and ScalarCoupleable::coupledScalarValueOlder().

79 {
80  std::map<std::string, std::vector<MooseVariableScalar *>>::iterator it =
81  _coupled_scalar_vars.find(var_name);
82  if (it != _coupled_scalar_vars.end())
83  return (i < it->second.size());
84  else
85  {
86  // Make sure the user originally requested this value in the InputParameter syntax
87  if (!_coupleable_params.hasCoupledValue(var_name))
88  mooseError("The coupled scalar variable \"",
89  var_name,
90  "\" was never added to this objects's "
91  "InputParameters, please double-check "
92  "your spelling");
93 
94  return false;
95  }
96 }
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
const InputParameters & _coupleable_params
Local InputParameters.
std::map< std::string, std::vector< MooseVariableScalar * > > _coupled_scalar_vars
Coupled vars whose values we provide.
bool TransientInterface::isImplicit ( )
inlineinherited

Definition at line 41 of file TransientInterface.h.

41 { return _is_implicit; }
bool _is_implicit
If the object is using implicit or explicit form.
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
void SetupInterface::jacobianSetup ( )
virtualinherited

Gets called just before the Jacobian is computed and before this object is asked to do its job.

Definition at line 79 of file SetupInterface.C.

80 {
81 }
virtual void MeshChangedInterface::meshChanged ( )
inlinevirtualinherited

Called on this object when the mesh changes.

Reimplemented in DiracKernel, Console, OversampleOutput, Exodus, Nemesis, GeometryBase, and EqualValueBoundaryConstraint.

Definition at line 43 of file MeshChangedInterface.h.

43 {}
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(), 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(), 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(), 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
const InputParameters& MooseObject::parameters ( ) const
inlineinherited
void SetupInterface::residualSetup ( )
virtualinherited

Gets called just before the residual is computed and before this object is asked to do its job.

Definition at line 84 of file SetupInterface.C.

85 {
86 }
void SetupInterface::subdomainSetup ( )
virtualinherited

Gets called when the subdomain changes (i.e.

in a Jacobian or residual loop) and before this object is asked to do its job

Reimplemented in Material, Constraint, GeneralUserObject, and NodalUserObject.

Definition at line 89 of file SetupInterface.C.

90 {
91 }
Real Function::timeDerivative ( Real  t,
const Point &  p 
)
virtualinherited

Get the time derivative of the function.

Parameters
tThe time
pThe point in space (x,y,z)
Returns
The time derivative of the function at the specified time and location

Reimplemented in MooseParsedFunction, PiecewiseConstant, and PiecewiseLinear.

Definition at line 55 of file Function.C.

56 {
57  mooseError("timeDerivative method not defined for function ", name());
58  return 0;
59 }
const std::string & name() const
Get the name of the object.
Definition: MooseObject.h:47
void mooseError(Args &&...args) const
Definition: MooseObject.h:80
void SetupInterface::timestepSetup ( )
virtualinherited

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

Reimplemented in SolutionUserObject, NumNonlinearIterations, and MemoryUsage.

Definition at line 74 of file SetupInterface.C.

75 {
76 }
Real Axisymmetric2D3DSolutionFunction::value ( Real  t,
const Point &  p 
)
overridevirtual

Override this to evaluate the scalar function at point (t,x,y,z), by default this returns zero, you must override it.

Parameters
tThe time
pThe Point in space (x,y,z)
Returns
A scalar of the function evaluated at the time and location

Reimplemented from Function.

Definition at line 141 of file Axisymmetric2D3DSolutionFunction.C.

142 {
143  Point xypoint;
144  Point r_dir_2d;
145  Point z_dir_2d;
146  Point r_dir_3d;
147  Point z_dir_3d;
148  bool r_gt_zero = false;
149 
150  if (_default_axes)
151  {
152  r_dir_2d(0) = 1;
153  z_dir_2d(1) = 1;
154  r_dir_3d = p;
155  r_dir_3d(1) = 0;
156  Real r = r_dir_3d.norm();
158  {
159  r_gt_zero = true;
160  r_dir_3d /= r;
161  }
162  z_dir_3d(1) = 1;
163  xypoint(0) = std::sqrt(p(0) * p(0) + p(2) * p(2));
164  xypoint(1) = p(1) / _axial_dim_ratio;
165  }
166  else
167  {
168  // Find the r, z coordinates of the point in the 3D model relative to the 3D axis
169  z_dir_3d = _3d_axis_point2 - _3d_axis_point1;
170  z_dir_3d /= z_dir_3d.norm();
171  Point v3dp1p(p - _3d_axis_point1);
172  Real z = z_dir_3d * v3dp1p;
173  Point axis_proj = _3d_axis_point1 + z * z_dir_3d; // projection of point onto axis
174  Point axis_proj_to_p = p - axis_proj;
175  Real r = axis_proj_to_p.norm();
177  {
178  r_gt_zero = true;
179  r_dir_3d = axis_proj_to_p / r;
180  }
181 
182  // Convert point in r, z coordinates into x, y coordinates
183  z_dir_2d = _2d_axis_point2 - _2d_axis_point1;
184  z_dir_2d /= z_dir_2d.norm();
185  Point out_of_plane_vec(0, 0, 1);
186  r_dir_2d = z_dir_2d.cross(out_of_plane_vec);
187  r_dir_2d /= r_dir_2d.norm(); // size should be 1, maybe this isn't necessary
188  xypoint = _2d_axis_point1 + z / _axial_dim_ratio * z_dir_2d + r * r_dir_2d;
189  }
190 
191  Real val;
192  if (_has_component)
193  {
194  Real val_x = _solution_object_ptr->pointValue(t, xypoint, _solution_object_var_indices[0]);
195  Real val_y = _solution_object_ptr->pointValue(t, xypoint, _solution_object_var_indices[1]);
196 
197  // val_vec_rz contains the value vector converted from x,y to r,z coordinates
198  Point val_vec_rz;
199  val_vec_rz(0) = r_dir_2d(0) * val_x + r_dir_2d(1) * val_y;
200  val_vec_rz(1) = z_dir_2d(0) * val_x + z_dir_2d(1) * val_y;
201  if (!r_gt_zero && !MooseUtils::absoluteFuzzyEqual(val_vec_rz(0), 0.0))
202  mooseError("In Axisymmetric2D3DSolutionFunction r=0 and r component of value vector != 0");
203  Point val_vec_3d = val_vec_rz(0) * r_dir_3d + val_vec_rz(1) * z_dir_3d;
204 
205  val = val_vec_3d(_component);
206  }
207  else
209 
210  return _scale_factor * val + _add_factor;
211 }
const Real _add_factor
Factor to add to the solution (default = 0)
std::vector< unsigned int > _solution_object_var_indices
The local SolutionUserObject indices for the variables extracted from the file.
const unsigned int _component
The index of the component.
const RealVectorValue _2d_axis_point1
Two points that define the axis of rotation for the 2d model.
const RealVectorValue _3d_axis_point1
Two points that define the axis of rotation for the 3d model.
Real pointValue(Real t, const Point &p, const unsigned int local_var_index) const
Returns a value at a specific location and variable (see SolutionFunction)
bool _default_axes
Are the default axes of rotation being used?
const SolutionUserObject * _solution_object_ptr
Pointer to SolutionUserObject containing the solution of interest.
const Real _axial_dim_ratio
Ratio of axial dimension of 3d model to its counterpart in the 2d model.
bool absoluteFuzzyGreaterThan(const libMesh::Real &var1, const libMesh::Real &var2, const libMesh::Real &tol=libMesh::TOLERANCE *libMesh::TOLERANCE)
Function to check whether a variable is greater than another variable within an absolute tolerance...
bool absoluteFuzzyEqual(const libMesh::Real &var1, const libMesh::Real &var2, const libMesh::Real &tol=libMesh::TOLERANCE *libMesh::TOLERANCE)
Function to check whether two variables are equal within an absolute tolerance.
void mooseError(Args &&...args) const
Definition: MooseObject.h:80
const bool _has_component
If the solution field is a vector, the desired component must be specified Has the component been spe...
const Real _scale_factor
Factor to scale the solution by (default = 1)
RealVectorValue Function::vectorValue ( Real  t,
const Point &  p 
)
virtualinherited

Override this to evaluate the vector function at a point (t,x,y,z), by default this returns a zero vector, you must override it.

Parameters
tThe time
pThe Point in space (x,y,z)
Returns
A vector of the function evaluated at the time and location

Reimplemented in MooseParsedFunction, MooseParsedGradFunction, MooseParsedVectorFunction, and LinearCombinationFunction.

Definition at line 62 of file Function.C.

63 {
64  return RealVectorValue(0, 0, 0);
65 }
VectorValue< Real > RealVectorValue
Definition: Assembly.h:40

Member Data Documentation

const RealVectorValue Axisymmetric2D3DSolutionFunction::_2d_axis_point1
protected

Two points that define the axis of rotation for the 2d model.

Definition at line 69 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by Axisymmetric2D3DSolutionFunction(), initialSetup(), and value().

const RealVectorValue Axisymmetric2D3DSolutionFunction::_2d_axis_point2
protected
const RealVectorValue Axisymmetric2D3DSolutionFunction::_3d_axis_point1
protected

Two points that define the axis of rotation for the 3d model.

Definition at line 73 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by Axisymmetric2D3DSolutionFunction(), and value().

const RealVectorValue Axisymmetric2D3DSolutionFunction::_3d_axis_point2
protected

Definition at line 74 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by Axisymmetric2D3DSolutionFunction(), and value().

const Real Axisymmetric2D3DSolutionFunction::_add_factor
protected

Factor to add to the solution (default = 0)

Definition at line 61 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by value().

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().

const Real Axisymmetric2D3DSolutionFunction::_axial_dim_ratio
protected

Ratio of axial dimension of 3d model to its counterpart in the 2d model.

This permits the axial dimension of the 3d model to be larger than that of the 2d model

Definition at line 66 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by value().

const unsigned int Axisymmetric2D3DSolutionFunction::_component
protected

The index of the component.

Definition at line 81 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by value().

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 InputParameters& ScalarCoupleable::_coupleable_params
protectedinherited
std::vector<MooseVariableScalar *> ScalarCoupleable::_coupled_moose_scalar_vars
protectedinherited

Vector of coupled variables.

Definition at line 144 of file ScalarCoupleable.h.

Referenced by ScalarCoupleable::getCoupledMooseScalarVars(), and ScalarCoupleable::ScalarCoupleable().

std::map<std::string, std::vector<MooseVariableScalar *> > ScalarCoupleable::_coupled_scalar_vars
protectedinherited
const ExecFlagType& SetupInterface::_current_execute_flag
protectedinherited

Reference to FEProblemBase.

Definition at line 85 of file SetupInterface.h.

bool Axisymmetric2D3DSolutionFunction::_default_axes
protected

Are the default axes of rotation being used?

Definition at line 84 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by Axisymmetric2D3DSolutionFunction(), and value().

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

Will hold the default value for optional coupled scalar variables.

Definition at line 141 of file ScalarCoupleable.h.

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

Real& TransientInterface::_dt
protectedinherited

Time step size.

Definition at line 63 of file TransientInterface.h.

Referenced by TotalVariableValue::execute(), and VariableTimeIntegrationAux::getIntegralValue().

Real& TransientInterface::_dt_old
protectedinherited

Size of the old time step.

Definition at line 66 of file TransientInterface.h.

Referenced by VariableTimeIntegrationAux::getIntegralValue().

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().

std::vector<ExecFlagType> SetupInterface::_exec_flags
protectedinherited

execution flag (when is the object executed/evaluated)

Definition at line 82 of file SetupInterface.h.

Referenced by SetupInterface::execBitFlags(), SetupInterface::execFlags(), and SetupInterface::SetupInterface().

const bool Axisymmetric2D3DSolutionFunction::_has_component
protected

If the solution field is a vector, the desired component must be specified Has the component been specified?

Definition at line 78 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by Axisymmetric2D3DSolutionFunction(), and value().

bool TransientInterface::_is_implicit
protectedinherited

If the object is using implicit or explicit form.

This does NOT mean time scheme, but which values are going to be used in the object - either from current time or old time. Note that even explicit schemes have implicit form (it is the time derivative "kernel")

Definition at line 54 of file TransientInterface.h.

Referenced by EigenKernel::computeJacobian(), EigenKernel::computeOffDiagJacobian(), EigenKernel::EigenKernel(), EigenKernel::enabled(), and TransientInterface::isImplicit().

bool TransientInterface::_is_transient
protectedinherited

Definition at line 69 of file TransientInterface.h.

FEProblemBase& MeshChangedInterface::_mci_feproblem
protectedinherited

Reference to FEProblemBase instance.

Definition at line 47 of file MeshChangedInterface.h.

Referenced by MeshChangedInterface::MeshChangedInterface().

const std::string& MooseObject::_name
protectedinherited
const InputParameters& MooseObject::_pars
protectedinherited
FEProblemBase& ScalarCoupleable::_sc_fe_problem
protectedinherited
bool ScalarCoupleable::_sc_is_implicit
protectedinherited
const InputParameters& ScalarCoupleable::_sc_parameters
protectedinherited

Definition at line 60 of file ScalarCoupleable.h.

Referenced by ScalarCoupleable::ScalarCoupleable().

const Real Axisymmetric2D3DSolutionFunction::_scale_factor
protected

Factor to scale the solution by (default = 1)

Definition at line 58 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by value().

const SolutionUserObject* Axisymmetric2D3DSolutionFunction::_solution_object_ptr
protected

Pointer to SolutionUserObject containing the solution of interest.

Definition at line 55 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by initialSetup(), and value().

std::vector<unsigned int> Axisymmetric2D3DSolutionFunction::_solution_object_var_indices
protected

The local SolutionUserObject indices for the variables extracted from the file.

Definition at line 90 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by initialSetup(), and value().

Real& TransientInterface::_t
protectedinherited
int& TransientInterface::_t_step
protectedinherited

The number of the time step.

Definition at line 60 of file TransientInterface.h.

FEProblemBase& TransientInterface::_ti_feproblem
protectedinherited

Definition at line 46 of file TransientInterface.h.

Referenced by SolutionFunction::SolutionFunction().

const InputParameters& TransientInterface::_ti_params
protectedinherited

Definition at line 44 of file TransientInterface.h.

std::vector<std::string> Axisymmetric2D3DSolutionFunction::_var_names
protected

The variable names to extract from the file.

Definition at line 87 of file Axisymmetric2D3DSolutionFunction.h.

Referenced by Axisymmetric2D3DSolutionFunction(), and initialSetup().


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