#include <FixedPointSolve.h>

Inheritance diagram for FixedPointSolve:

Public Types
enum	MooseFixedPointConvergenceReason { MooseFixedPointConvergenceReason::UNSOLVED = 0, MooseFixedPointConvergenceReason::CONVERGED_NONLINEAR = 1, MooseFixedPointConvergenceReason::CONVERGED_ABS = 2, MooseFixedPointConvergenceReason::CONVERGED_RELATIVE = 3, MooseFixedPointConvergenceReason::CONVERGED_PP = 4, MooseFixedPointConvergenceReason::REACH_MAX_ITS = 5, MooseFixedPointConvergenceReason::CONVERGED_OBJECT = 6, MooseFixedPointConvergenceReason::DIVERGED_MAX_ITS = -1, MooseFixedPointConvergenceReason::DIVERGED_NONLINEAR = -2, MooseFixedPointConvergenceReason::DIVERGED_FAILED_MULTIAPP = -3, MooseFixedPointConvergenceReason::DIVERGED_OBJECT = -4 }
	Enumeration for fixed point convergence reasons. More...

using	DataFileParameterType = DataFileName
	The parameter type this interface expects for a data file name. More...

Public Member Functions
	FixedPointSolve (Executioner &ex)

virtual	~FixedPointSolve ()=default

virtual void	initialSetup () override
	Method that should be executed once, before any solve calls. More...

virtual bool	solve () override
	Iteratively solves the FEProblem. More...

unsigned int	numFixedPointIts () const
	Get the number of fixed point iterations performed Because this returns the number of fixed point iterations, rather than the current iteration count (which starts at 0), increment by 1. More...

unsigned int	numPicardIts () const
	Deprecated getter for the number of fixed point iterations. More...

MooseFixedPointConvergenceReason	checkConvergence () const
	Check the solver status. More...

bool	XFEMRepeatStep () const
	This function checks the _xfem_repeat_step flag set by solve. More...

void	setFixedPointStatus (MooseFixedPointConvergenceReason status)
	Set fixed point status. More...

void	clearFixedPointStatus ()
	Clear fixed point status. More...

bool	hasFixedPointIteration ()
	Whether or not this has fixed point iterations. More...

void	setMultiAppRelaxationFactor (Real factor)
	Set relaxation factor for the current solve as a SubApp. More...

void	setMultiAppTransformedVariables (const std::vector< std::string > &vars)
	Set relaxation variables for the current solve as a SubApp. More...

virtual void	setMultiAppTransformedPostprocessors (const std::vector< PostprocessorName > &pps)
	Set relaxation postprocessors for the current solve as a SubApp. More...

virtual void	allocateStorage (const bool primary)=0
	Allocate storage for the fixed point algorithm. More...

bool	autoAdvance () const
	Whether sub-applications are automatically advanced no matter what happens during their solves. More...

void	failStep ()
	Mark the current solve as failed due to external conditions. More...

virtual void	printFixedPointConvergenceHistory (Real initial_norm, const std::vector< Real > &timestep_begin_norms, const std::vector< Real > &timestep_end_norms) const =0
	Print the convergence history of the coupling, at every fixed point iteration. More...

virtual void	setInnerSolve (SolveObject &solve)
	Set the inner solve object wrapped by this object. More...

virtual bool	enabled () const
	Return the enabled status of the object. More...

std::shared_ptr< MooseObject >	getSharedPtr ()
	Get another shared pointer to this object that has the same ownership group. More...

std::shared_ptr< const MooseObject >	getSharedPtr () const

MooseApp &	getMooseApp () const
	Get the MooseApp this class is associated with. More...

const std::string &	type () const
	Get the type of this class. More...

const std::string &	name () const
	Get the name of the class. More...

std::string	typeAndName () const
	Get the class's combined type and name; useful in error handling. More...

MooseObjectParameterName	uniqueParameterName (const std::string &parameter_name) const

MooseObjectName	uniqueName () const

const InputParameters &	parameters () const
	Get the parameters of the object. More...

const hit::Node *	getHitNode () const

bool	hasBase () const

const std::string &	getBase () const

template<typename T >
const T &	getParam (const std::string &name) const
	Retrieve a parameter for the object. More...

template<typename T1 , typename T2 >
std::vector< std::pair< T1, T2 > >	getParam (const std::string &param1, const std::string &param2) const
	Retrieve two parameters and provide pair of parameters for the object. More...

template<typename T >
const T *	queryParam (const std::string &name) const
	Query a parameter for the object. More...

template<typename T >
const T &	getRenamedParam (const std::string &old_name, const std::string &new_name) const
	Retrieve a renamed parameter for the object. More...

template<typename T >
T	getCheckedPointerParam (const std::string &name, const std::string &error_string="") const
	Verifies that the requested parameter exists and is not NULL and returns it to the caller. More...

bool	isParamValid (const std::string &name) const
	Test if the supplied parameter is valid. More...

bool	isParamSetByUser (const std::string &name) const
	Test if the supplied parameter is set by a user, as opposed to not set or set to default. More...

void	connectControllableParams (const std::string &parameter, const std::string &object_type, const std::string &object_name, const std::string &object_parameter) const
	Connect controllable parameter of this action with the controllable parameters of the objects added by this action. More...

template<typename... Args>
void	paramError (const std::string &param, Args... args) const
	Emits an error prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message. More...

template<typename... Args>
void	paramWarning (const std::string &param, Args... args) const
	Emits a warning prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message. More...

template<typename... Args>
void	paramInfo (const std::string &param, Args... args) const
	Emits an informational message prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message. More...

std::string	messagePrefix (const bool hit_prefix=true) const

std::string	errorPrefix (const std::string &) const
	Deprecated message prefix; the error type is no longer used. More...

template<typename... Args>
void	mooseError (Args &&... args) const
	Emits an error prefixed with object name and type and optionally a file path to the top-level block parameter if available. More...

template<typename... Args>
void	mooseDocumentedError (const std::string &repo_name, const unsigned int issue_num, Args &&... args) const

template<typename... Args>
void	mooseErrorNonPrefixed (Args &&... args) const
	Emits an error without the prefixing included in mooseError(). More...

template<typename... Args>
void	mooseWarning (Args &&... args) const
	Emits a warning prefixed with object name and type. More...

template<typename... Args>
void	mooseWarningNonPrefixed (Args &&... args) const
	Emits a warning without the prefixing included in mooseWarning(). More...

template<typename... Args>
void	mooseDeprecated (Args &&... args) const

template<typename... Args>
void	mooseInfo (Args &&... args) const

void	callMooseError (std::string msg, const bool with_prefix, const hit::Node *node=nullptr) const
	External method for calling moose error with added object context. More...

const Parallel::Communicator &	comm () const

processor_id_type	n_processors () const

processor_id_type	processor_id () const

std::string	getDataFileName (const std::string &param) const
	Deprecated method. More...

std::string	getDataFileNameByName (const std::string &relative_path) const
	Deprecated method. More...

std::string	getDataFilePath (const std::string &relative_path) const
	Returns the path of a data file for a given relative file path. More...

PerfGraph &	perfGraph ()
	Get the PerfGraph. More...

bool	isDefaultPostprocessorValue (const std::string &param_name, const unsigned int index=0) const
	Determine whether or not the Postprocessor is a default value. More...

bool	hasPostprocessor (const std::string &param_name, const unsigned int index=0) const
	Determine if the Postprocessor data exists. More...

bool	hasPostprocessorByName (const PostprocessorName &name) const
	Determine if the Postprocessor data exists. More...

std::size_t	coupledPostprocessors (const std::string &param_name) const
	Returns number of Postprocessors coupled under parameter name. More...

const PostprocessorName &	getPostprocessorName (const std::string &param_name, const unsigned int index=0) const
	Get the name of a postprocessor. More...


const PostprocessorValue &	getPostprocessorValue (const std::string &param_name, const unsigned int index=0) const
	doco-normal-methods-begin Retrieve the value of a Postprocessor or one of it's old or older values More...

const PostprocessorValue &	getPostprocessorValueOld (const std::string &param_name, const unsigned int index=0) const

const PostprocessorValue &	getPostprocessorValueOlder (const std::string &param_name, const unsigned int index=0) const


virtual const PostprocessorValue &	getPostprocessorValueByName (const PostprocessorName &name) const
	Retrieve the value of the Postprocessor. More...

const PostprocessorValue &	getPostprocessorValueOldByName (const PostprocessorName &name) const

const PostprocessorValue &	getPostprocessorValueOlderByName (const PostprocessorName &name) const

Static Public Member Functions
static InputParameters	fixedPointDefaultConvergenceParams ()

static InputParameters	validParams ()

static void	callMooseError (MooseApp const app, const InputParameters &params, std::string msg, const bool with_prefix, const hit::Node node)
	External method for calling moose error with added object context. More...

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

Static Public Attributes
static const std::string	type_param = "_type"
	The name of the parameter that contains the object type. More...

static const std::string	name_param = "_object_name"
	The name of the parameter that contains the object name. More...

static const std::string	unique_name_param = "_unique_name"
	The name of the parameter that contains the unique object name. More...

static const std::string	app_param = "_moose_app"
	The name of the parameter that contains the MooseApp. More...

static const std::string	moose_base_param = "_moose_base"
	The name of the parameter that contains the moose system base. More...

Protected Member Functions
bool	performingRelaxation (const bool primary) const
	Returns true if there is relaxation. More...

virtual void	saveVariableValues (const bool primary)=0
	Saves the current values of the variables, and update the old(er) vectors. More...

virtual void	savePostprocessorValues (const bool primary)=0
	Saves the current values of the postprocessors, and update the old(er) vectors. More...

virtual bool	useFixedPointAlgorithmUpdateInsteadOfPicard (const bool primary)=0
	Use the fixed point algorithm transform instead of simply using the Picard update This routine can be used to alternate Picard iterations and fixed point algorithm updates based on the values of the variables before and after a solve / a Picard iteration. More...

virtual bool	solveStep (const std::set< dof_id_type > &transformed_dofs)
	Perform one fixed point iteration or a full solve. More...

virtual void	saveAllValues (const bool primary)
	Save both the variable and postprocessor values. More...

virtual void	transformPostprocessors (const bool primary)=0
	Use the fixed point algorithm to transform the postprocessors. More...

virtual void	transformVariables (const std::set< dof_id_type > &transformed_dofs, const bool primary)=0
	Use the fixed point algorithm to transform the variables. More...

bool	examineFixedPointConvergence (bool &converged)
	Examine the various convergence metrics. More...

void	printFixedPointConvergenceReason ()
	Print information about the fixed point convergence. More...

PerfID	registerTimedSection (const std::string &section_name, const unsigned int level) const
	Call to register a named section for timing. More...

PerfID	registerTimedSection (const std::string &section_name, const unsigned int level, const std::string &live_message, const bool print_dots=true) const
	Call to register a named section for timing. More...

std::string	timedSectionName (const std::string &section_name) const

virtual void	addPostprocessorDependencyHelper (const PostprocessorName &) const
	Helper for deriving classes to override to add dependencies when a Postprocessor is requested. More...

Protected Attributes
const bool	_has_fixed_point_its
	Whether or not we activate fixed point iteration. More...

const Real	_relax_factor
	Relaxation factor for fixed point Iteration. More...

std::vector< std::string >	_transformed_vars
	The variables (transferred or not) that are going to be relaxed. More...

const std::vector< PostprocessorName >	_transformed_pps
	The postprocessors (transferred or not) that are going to be relaxed. More...

std::vector< std::vector< PostprocessorValue > >	_transformed_pps_values
	Previous values of the relaxed postprocessors. More...

Real	_secondary_relaxation_factor
	Relaxation factor outside of fixed point iteration (used as a subapp) More...

std::vector< std::string >	_secondary_transformed_variables
	Variables to be relaxed outside of fixed point iteration (used as a subapp) More...

std::vector< PostprocessorName >	_secondary_transformed_pps
	Postprocessors to be relaxed outside of fixed point iteration (used as a subapp) More...

std::vector< std::vector< PostprocessorValue > >	_secondary_transformed_pps_values
	Previous values of the postprocessors relaxed outside of the fixed point iteration (used as a subapp) More...

Executioner &	_executioner
	Executioner used to construct this. More...

FEProblemBase &	_problem
	Reference to FEProblem. More...

DisplacedProblem *	_displaced_problem
	Displaced problem. More...

MooseMesh &	_mesh
	Mesh. More...

MooseMesh *	_displaced_mesh
	Displaced mesh. More...

SystemBase &	_solver_sys
	Reference to a system for creating vectors as needed for the solve, etc. More...

AuxiliarySystem &	_aux
	Reference to auxiliary system for faster access. More...

SolveObject *	_inner_solve
	SolveObject wrapped by this solve object. More...

const bool &	_enabled
	Reference to the "enable" InputParameters, used by Controls for toggling on/off MooseObjects. More...

MooseApp &	_app
	The MOOSE application this is associated with. More...

Factory &	_factory
	The Factory associated with the MooseApp. More...

ActionFactory &	_action_factory
	Builds Actions. More...

const std::string &	_type
	The type of this class. More...

const std::string &	_name
	The name of this class. More...

const InputParameters &	_pars
	The object's parameters. More...

const Parallel::Communicator &	_communicator

MooseApp &	_pg_moose_app
	The MooseApp that owns the PerfGraph. More...

const std::string	_prefix
	A prefix to use for all sections. More...


unsigned int	_fixed_point_it

unsigned int	_main_fixed_point_it
	fixed point iteration counter for the main app More...

MooseFixedPointConvergenceReason	_fixed_point_status
	Status of fixed point solve. More...

Private Attributes
const unsigned int	_max_xfem_update
	Maximum number of xfem updates per step. More...

const bool	_update_xfem_at_timestep_begin
	Controls whether xfem should update the mesh at the beginning of the time step. More...

unsigned int	_xfem_update_count
	Counter for number of xfem updates that have been performed in the current step. More...

bool	_xfem_repeat_step
	Whether step should be repeated due to xfem modifying the mesh. More...

Real	_old_entering_time
	Time of previous fixed point solve as a subapp. More...

bool	_fail_step
	force the current step to fail, triggering are repeat with a cut dt More...

const bool	_auto_advance_set_by_user
	Whether the user has set the auto_advance parameter for handling advancement of sub-applications in multi-app contexts. More...

const bool	_auto_advance_user_value
	The value of auto_advance set by the user for handling advancement of sub-applications in multi-app contexts. More...

Detailed Description

Definition at line 17 of file FixedPointSolve.h.

Member Typedef Documentation

◆ DataFileParameterType

using DataFileInterface::DataFileParameterType = DataFileName

inherited

The parameter type this interface expects for a data file name.

Definition at line 27 of file DataFileInterface.h.

Member Enumeration Documentation

◆ MooseFixedPointConvergenceReason

enum FixedPointSolve::MooseFixedPointConvergenceReason

strong

Enumeration for fixed point convergence reasons.

Enumerator
UNSOLVED
CONVERGED_NONLINEAR	Not solved yet.
CONVERGED_ABS	Main app nonlinear solve converged, FP unassessed.
CONVERGED_RELATIVE	FP converged by absolute residual tolerance.
CONVERGED_PP	FP converged by relative residual tolerance.
REACH_MAX_ITS	FP converged by absolute or relative PP tolerance.
CONVERGED_OBJECT	FP converged by hitting max iterations and accepting.
DIVERGED_MAX_ITS	FP converged according to Convergence object.
DIVERGED_NONLINEAR	FP diverged by hitting max iterations.
DIVERGED_FAILED_MULTIAPP	Main app nonlinear solve diverged.
DIVERGED_OBJECT	Multiapp solve diverged.

Definition at line 36 of file FixedPointSolve.h.

   {
     UNSOLVED = 0,                  
     CONVERGED_NONLINEAR = 1,       
     CONVERGED_ABS = 2,             
     CONVERGED_RELATIVE = 3,        
     CONVERGED_PP = 4,              
     REACH_MAX_ITS = 5,             
     CONVERGED_OBJECT = 6,          
     DIVERGED_MAX_ITS = -1,         
     DIVERGED_NONLINEAR = -2,       
     DIVERGED_FAILED_MULTIAPP = -3, 
     DIVERGED_OBJECT = -4           
   };

Constructor & Destructor Documentation

◆ FixedPointSolve()

FixedPointSolve::FixedPointSolve ( Executioner & ex )

Definition at line 148 of file FixedPointSolve.C.

   : SolveObject(ex),
     _has_fixed_point_its(getParam<unsigned int>("fixed_point_max_its") > 1 ||
                          isParamSetByUser("multiapp_fixed_point_convergence")),
     _relax_factor(getParam<Real>("relaxation_factor")),
     _transformed_vars(getParam<std::vector<std::string>>("transformed_variables")),
     _transformed_pps(getParam<std::vector<PostprocessorName>>("transformed_postprocessors")),
     // this value will be set by MultiApp
     _secondary_relaxation_factor(1.0),
     _fixed_point_it(0),
     _fixed_point_status(MooseFixedPointConvergenceReason::UNSOLVED),
     _max_xfem_update(getParam<unsigned int>("max_xfem_update")),
     _update_xfem_at_timestep_begin(getParam<bool>("update_xfem_at_timestep_begin")),
     _xfem_update_count(0),
     _xfem_repeat_step(false),
     _old_entering_time(_problem.time() - 1),
     _fail_step(false),
     _auto_advance_set_by_user(isParamValid("auto_advance")),
     _auto_advance_user_value(_auto_advance_set_by_user ? getParam<bool>("auto_advance") : true)
 {
   // Handle deprecated parameters
   if (!parameters().isParamSetByAddParam("relaxed_variables"))
     _transformed_vars = getParam<std::vector<std::string>>("relaxed_variables");
 
   if (_transformed_vars.size() > 0 && _transformed_pps.size() > 0)
     mooseWarning(
         "Both variable and postprocessor transformation are active. If the two share dofs, the "
         "transformation will not be correct.");
 
   if (!_app.isUltimateMaster())
   {
     _secondary_relaxation_factor = _app.fixedPointConfig().sub_relaxation_factor;
     _secondary_transformed_variables = _app.fixedPointConfig().sub_transformed_vars;
     _secondary_transformed_pps = _app.fixedPointConfig().sub_transformed_pps;
   }
 
   if (isParamValid("multiapp_fixed_point_convergence"))
     _problem.setMultiAppFixedPointConvergenceName(
         getParam<ConvergenceName>("multiapp_fixed_point_convergence"));
   else
     _problem.setNeedToAddDefaultMultiAppFixedPointConvergence();
 }

◆ ~FixedPointSolve()

virtual FixedPointSolve::~FixedPointSolve ( )

virtualdefault

Member Function Documentation

◆ addPostprocessorDependencyHelper()

virtual void PostprocessorInterface::addPostprocessorDependencyHelper ( const PostprocessorName & ) const

inlineprotectedvirtualinherited

Helper for deriving classes to override to add dependencies when a Postprocessor is requested.

Reimplemented in AuxKernelTempl< ComputeValueType >, AuxKernelTempl< RT >, AuxKernelTempl< RealVectorValue >, AuxKernelTempl< Real >, UserObject, and InitialConditionBase.

Definition at line 141 of file PostprocessorInterface.h.

Referenced by PostprocessorInterface::getPostprocessorValueByNameInternal().

141 {}

◆ allocateStorage()

virtual void FixedPointSolve::allocateStorage ( const bool primary )

pure virtual

Allocate storage for the fixed point algorithm.

This creates the system vector of old (older, pre/post solve) variable values and the array of old (older, pre/post solve) postprocessor values.

Parameters

primary Whether this routine is to allocate storage for the primary transformed quantities (as main app) or the secondary ones (as a subapp)

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by initialSetup().

◆ autoAdvance()

bool FixedPointSolve::autoAdvance ( ) const

Whether sub-applications are automatically advanced no matter what happens during their solves.

Definition at line 551 of file FixedPointSolve.C.

Referenced by solve(), and solveStep().

 {
   bool auto_advance = !(_has_fixed_point_its && _problem.isTransient());
 
   if (dynamic_cast<EigenExecutionerBase *>(&_executioner) && _has_fixed_point_its)
     auto_advance = true;
 
   if (_auto_advance_set_by_user)
     auto_advance = _auto_advance_user_value;
 
   return auto_advance;
 }

◆ callMooseError() [1/2]

void MooseBase::callMooseError	(	std::string	msg,
		const bool	with_prefix,
		const hit::Node *	node = `nullptr`
	)		const

inherited

External method for calling moose error with added object context.

Parameters

msg	The message
with_prefix	If true, add the prefix from messagePrefix(), which is the object information (type, name, etc)
node	Optional hit node to add file path context as a prefix

Definition at line 102 of file MooseBase.C.

Referenced by InputParameters::callMooseError(), MooseBase::mooseDocumentedError(), MooseBase::mooseError(), and MooseBase::mooseErrorNonPrefixed().

 {
   callMooseError(&_app, _pars, msg, with_prefix, node);
 }

◆ callMooseError() [2/2]

void MooseBase::callMooseError	(	MooseApp *const	app,
		const InputParameters &	params,
		std::string	msg,
		const bool	with_prefix,
		const hit::Node *	node
	)

staticinherited

External method for calling moose error with added object context.

Needed so that objects without the MooseBase context (InputParameters) can call errors with context

Parameters

app	The app pointer (if available); adds multiapp context and clears the console
params	The parameters, needed to obtain object information
msg	The message
with_prefix	If true, add the prefix from messagePrefix(), which is the object information (type, name, etc)
node	Optional hit node to add file path context as a prefix

Definition at line 110 of file MooseBase.C.

 {
   if (!node)
     node = MooseBase::getHitNode(params);
 
   std::string multiapp_prefix = "";
   if (app)
   {
     if (!app->isUltimateMaster())
       multiapp_prefix = app->name();
     app->getOutputWarehouse().mooseConsole();
   }
 
   if (with_prefix)
     // False here because the hit context will get processed by the node
     msg = messagePrefix(params, false) + msg;
 
   moose::internal::mooseErrorRaw(msg, multiapp_prefix, node);
 }

◆ checkConvergence()

MooseFixedPointConvergenceReason FixedPointSolve::checkConvergence ( ) const

inline

Check the solver status.

Definition at line 69 of file FixedPointSolve.h.

69 { return _fixed_point_status; }

FixedPointSolve::_fixed_point_status

MooseFixedPointConvergenceReason _fixed_point_status

Status of fixed point solve.

Definition: FixedPointSolve.h:228

◆ clearFixedPointStatus()

void FixedPointSolve::clearFixedPointStatus ( )

inline

Clear fixed point status.

Definition at line 81 of file FixedPointSolve.h.

81 { _fixed_point_status = MooseFixedPointConvergenceReason::UNSOLVED; }

FixedPointSolve::MooseFixedPointConvergenceReason::UNSOLVED

FixedPointSolve::_fixed_point_status

MooseFixedPointConvergenceReason _fixed_point_status

Status of fixed point solve.

Definition: FixedPointSolve.h:228

◆ connectControllableParams()

void MooseBase::connectControllableParams	(	const std::string &	parameter,
		const std::string &	object_type,
		const std::string &	object_name,
		const std::string &	object_parameter
	)		const

inherited

Connect controllable parameter of this action with the controllable parameters of the objects added by this action.

Parameters

parameter	Name of the controllable parameter of this action
object_type	Type of the object added by this action.
object_name	Name of the object added by this action.
object_parameter	Name of the parameter of the object.

Definition at line 74 of file MooseBase.C.

 {
   auto & factory = _app.getFactory();
   auto & ip_warehouse = _app.getInputParameterWarehouse();
 
   MooseObjectParameterName primary_name(uniqueName(), parameter);
   const auto base_type = factory.getValidParams(object_type).getBase();
   MooseObjectParameterName secondary_name(base_type, object_name, object_parameter);
   ip_warehouse.addControllableParameterConnection(primary_name, secondary_name);
 
   const auto & tags = _pars.get<std::vector<std::string>>("control_tags");
   for (const auto & tag : tags)
   {
     if (!tag.empty())
     {
       // Only adds the parameter with the different control tags if the derived class
       // properly registers the parameter to its own syntax
       MooseObjectParameterName tagged_name(tag, name(), parameter);
       ip_warehouse.addControllableParameterConnection(
           tagged_name, secondary_name, /*error_on_empty=*/false);
     }
   }
 }

◆ coupledPostprocessors()

std::size_t PostprocessorInterface::coupledPostprocessors ( const std::string & param_name ) const

inherited

Returns number of Postprocessors coupled under parameter name.

Parameters

param_name The name of the Postprocessor parameter

Returns: Number of coupled post-processors, 1 if it's a single

Definition at line 129 of file PostprocessorInterface.C.

Referenced by FunctionValuePostprocessor::FunctionValuePostprocessor().

 {
   checkParam(param_name);
 
   if (_ppi_params.isType<PostprocessorName>(param_name))
     return 1;
   return _ppi_params.get<std::vector<PostprocessorName>>(param_name).size();
 }

◆ enabled()

virtual bool MooseObject::enabled ( ) const

inlinevirtualinherited

Return the enabled status of the object.

Reimplemented in EigenKernel.

Definition at line 39 of file MooseObject.h.

Referenced by EigenKernel::enabled().

39 { return _enabled; }

MooseObject::_enabled

const bool & _enabled

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

Definition: MooseObject.h:50

◆ errorPrefix()

std::string MooseBase::errorPrefix ( const std::string & ) const

inlineinherited

Deprecated message prefix; the error type is no longer used.

Definition at line 260 of file MooseBase.h.

260 { return messagePrefix(); }

MooseBase::messagePrefix

std::string messagePrefix(const bool hit_prefix=true) const

Definition: MooseBase.h:252

◆ examineFixedPointConvergence()

bool FixedPointSolve::examineFixedPointConvergence ( bool & converged )

protected

Examine the various convergence metrics.

Definition at line 486 of file FixedPointSolve.C.

Referenced by solve().

 {
   _problem.execute(EXEC_MULTIAPP_FIXED_POINT_CONVERGENCE);
 
   auto & convergence = _problem.getConvergence(_problem.getMultiAppFixedPointConvergenceName());
   const auto status = convergence.checkConvergence(_fixed_point_it);
   switch (status)
   {
     case Convergence::MooseConvergenceStatus::CONVERGED:
       converged = true;
       return true;
     case Convergence::MooseConvergenceStatus::DIVERGED:
       converged = false;
       return true;
     case Convergence::MooseConvergenceStatus::ITERATING:
       converged = false;
       return false;
     default:
       mooseError("Should not reach here");
   }
 }

◆ failStep()

void FixedPointSolve::failStep ( )

inline

Mark the current solve as failed due to external conditions.

Definition at line 115 of file FixedPointSolve.h.

Referenced by Terminator::execute().

115 { _fail_step = true; }

FixedPointSolve::_fail_step

bool _fail_step

force the current step to fail, triggering are repeat with a cut dt

Definition: FixedPointSolve.h:245

◆ fixedPointDefaultConvergenceParams()

InputParameters FixedPointSolve::fixedPointDefaultConvergenceParams ( )

static

Definition at line 25 of file FixedPointSolve.C.

Referenced by AddDefaultConvergenceAction::checkUnusedMultiAppFixedPointConvergenceParameters(), DefaultMultiAppFixedPointConvergence::validParams(), and validParams().

 {
   InputParameters params = emptyInputParameters();
 
   params.addParam<unsigned int>(
       "fixed_point_min_its", 1, "Specifies the minimum number of fixed point iterations.");
   params.addParam<unsigned int>(
       "fixed_point_max_its", 1, "Specifies the maximum number of fixed point iterations.");
   params.addParam<bool>("disable_fixed_point_residual_norm_check",
                         false,
                         "Disable the residual norm evaluation thus the three parameters "
                         "fixed_point_rel_tol, fixed_point_abs_tol and fixed_point_force_norms.");
   params.addParam<bool>(
       "fixed_point_force_norms",
       false,
       "Force the evaluation of both the TIMESTEP_BEGIN and TIMESTEP_END norms regardless of the "
       "existence of active MultiApps with those execute_on flags, default: false.");
   params.addParam<bool>(
       "accept_on_max_fixed_point_iteration",
       false,
       "True to treat reaching the maximum number of fixed point iterations as converged.");
   params.addRangeCheckedParam<Real>("fixed_point_rel_tol",
                                     1e-8,
                                     "fixed_point_rel_tol>0",
                                     "The relative nonlinear residual drop to shoot for "
                                     "during fixed point iterations. This check is "
                                     "performed based on the main app's nonlinear "
                                     "residual.");
   params.addRangeCheckedParam<Real>("fixed_point_abs_tol",
                                     1e-50,
                                     "fixed_point_abs_tol>0",
                                     "The absolute nonlinear residual to shoot for "
                                     "during fixed point iterations. This check is "
                                     "performed based on the main app's nonlinear "
                                     "residual.");
 
   params.addParam<PostprocessorName>("custom_pp",
                                      "Postprocessor for custom fixed point convergence check.");
   params.addParam<bool>("direct_pp_value",
                         false,
                         "True to use direct postprocessor value "
                         "(scaled by value on first iteration). "
                         "False (default) to use difference in postprocessor "
                         "value between fixed point iterations.");
   params.addRangeCheckedParam<Real>("custom_rel_tol",
                                     1e-8,
                                     "custom_rel_tol>0",
                                     "The relative nonlinear residual drop to shoot for "
                                     "during fixed point iterations. This check is "
                                     "performed based on the postprocessor defined by "
                                     "custom_pp residual.");
   params.addRangeCheckedParam<Real>("custom_abs_tol",
                                     1e-50,
                                     "custom_abs_tol>0",
                                     "The absolute nonlinear residual to shoot for "
                                     "during fixed point iterations. This check is "
                                     "performed based on postprocessor defined by "
                                     "the custom_pp residual.");
 
   params.addParamNamesToGroup(
       "fixed_point_min_its fixed_point_max_its disable_fixed_point_residual_norm_check "
       "accept_on_max_fixed_point_iteration fixed_point_rel_tol fixed_point_abs_tol "
       "fixed_point_force_norms custom_pp direct_pp_value custom_abs_tol custom_rel_tol",
       "Fixed point iterations");
 
   return params;
 }

◆ getBase()

const std::string& MooseBase::getBase ( ) const

inlineinherited

Returns: The registered base for this object (set via InputParameters::registerBase())

Definition at line 143 of file MooseBase.h.

Referenced by Factory::copyConstruct(), and MooseBase::uniqueParameterName().

143 { return _pars.getBase(); }

MooseBase::_pars

const InputParameters & _pars

The object's parameters.

Definition: MooseBase.h:362

InputParameters::getBase

const std::string & getBase() const

Definition: InputParameters.C:497

◆ getCheckedPointerParam()

template<typename T >

T MooseBase::getCheckedPointerParam	(	const std::string &	name,
		const std::string &	error_string = `""`
	)		const

inherited

Verifies that the requested parameter exists and is not NULL and returns it to the caller.

The template parameter must be a pointer or an error will be thrown.

Definition at line 428 of file MooseBase.h.

 {
   return _pars.getCheckedPointerParam<T>(name, error_string);
 }

◆ getDataFileName()

std::string DataFileInterface::getDataFileName ( const std::string & param ) const

inherited

Deprecated method.

The data file paths are now automatically set within the InputParameters object, so using getParam<DataFileName>("param_name") is now sufficient.

Definition at line 21 of file DataFileInterface.C.

 {
   _parent.mooseDeprecated("getDataFileName() is deprecated. The file path is now directly set "
                           "within the InputParameters.\nUse getParam<DataFileName>(\"",
                           param,
                           "\") instead.");
   return _parent.getParam<DataFileName>(param);
 }

◆ getDataFileNameByName()

std::string DataFileInterface::getDataFileNameByName ( const std::string & relative_path ) const

inherited

Deprecated method.

Use getDataFilePath() instead.

Definition at line 31 of file DataFileInterface.C.

 {
   _parent.mooseDeprecated("getDataFileNameByName() is deprecated. Use getDataFilePath(\"",
                           relative_path,
                           "\") instead.");
   return getDataFilePath(relative_path);
 }

◆ getDataFilePath()

std::string DataFileInterface::getDataFilePath ( const std::string & relative_path ) const

inherited

Returns the path of a data file for a given relative file path.

This can be used for hardcoded datafile names and will search the same locations as getDataFileName

Definition at line 40 of file DataFileInterface.C.

Referenced by DataFileInterface::getDataFileNameByName().

 {
   // This should only ever be used with relative paths. There is no point to
   // use this search path with an absolute path.
   if (std::filesystem::path(relative_path).is_absolute())
     _parent.mooseWarning("While using getDataFilePath(\"",
                          relative_path,
                          "\"): This API should not be used for absolute paths.");
 
   // Throw on error so that if getPath() fails, we can throw an error
   // with the context of _parent.mooseError()
   const auto throw_on_error_before = Moose::_throw_on_error;
   Moose::_throw_on_error = true;
   std::optional<std::string> error;
 
   // This will search the data paths for this relative path
   Moose::DataFileUtils::Path found_path;
   try
   {
     found_path = Moose::DataFileUtils::getPath(relative_path);
   }
   catch (std::exception & e)
   {
     error = e.what();
   }
 
   Moose::_throw_on_error = throw_on_error_before;
   if (error)
     _parent.mooseError(*error);
 
   mooseAssert(found_path.context == Moose::DataFileUtils::Context::DATA,
               "Should only ever obtain data");
   mooseAssert(found_path.data_name, "Should be set");
 
   const std::string msg =
       "Using data file '" + found_path.path + "' from " + *found_path.data_name + " data";
   _parent.mooseInfo(msg);
 
   return found_path.path;
 }

◆ getHitNode()

const hit::Node* MooseBase::getHitNode ( ) const

inlineinherited

Returns: The block-level hit node for this object, if any

Definition at line 132 of file MooseBase.h.

Referenced by FEProblemBase::addAnyRedistributers(), MooseBase::callMooseError(), MooseBase::getHitNode(), and MooseBase::messagePrefix().

132 { return getHitNode(_pars); }

MooseBase::_pars

const InputParameters & _pars

The object's parameters.

Definition: MooseBase.h:362

MooseBase::getHitNode

const hit::Node * getHitNode() const

Definition: MooseBase.h:132

◆ getMooseApp()

MooseApp& MooseBase::getMooseApp ( ) const

inlineinherited

Get the MooseApp this class is associated with.

Definition at line 83 of file MooseBase.h.

Referenced by ChainControlSetupAction::act(), AddDefaultConvergenceAction::addDefaultMultiAppFixedPointConvergence(), AddDefaultConvergenceAction::addDefaultNonlinearConvergence(), AddDefaultConvergenceAction::addDefaultSteadyStateConvergence(), FEProblemBase::advanceState(), ParsedChainControl::buildFunction(), ReporterTransferInterface::checkHasReporterValue(), AddDefaultConvergenceAction::checkUnusedMultiAppFixedPointConvergenceParameters(), AddDefaultConvergenceAction::checkUnusedNonlinearConvergenceParameters(), AddDefaultConvergenceAction::checkUnusedSteadyStateConvergenceParameters(), Coupleable::checkWritableVar(), ComponentPhysicsInterface::ComponentPhysicsInterface(), Coupleable::Coupleable(), MortarData::createMortarInterface(), EigenProblem::doFreeNonlinearPowerIterations(), Terminator::execute(), FEProblemSolve::FEProblemSolve(), SolutionInvalidInterface::flagInvalidSolutionInternal(), ChainControl::getChainControlDataSystem(), DefaultConvergenceBase::getSharedExecutionerParam(), ChainControlDataPostprocessor::initialSetup(), MaterialPropertyInterface::MaterialPropertyInterface(), MooseVariableDataFV< OutputType >::MooseVariableDataFV(), ProgressOutput::output(), PetscOutputInterface::petscLinearOutput(), PetscOutputInterface::petscNonlinearOutput(), PetscOutputInterface::PetscOutputInterface(), PostprocessorInterface::postprocessorsAdded(), MultiApp::preTransfer(), Reporter::Reporter(), ReporterInterface::reportersAdded(), MultiApp::restore(), and VectorPostprocessorInterface::vectorPostprocessorsAdded().

83 { return _app; }

MooseBase::_app

MooseApp & _app

The MOOSE application this is associated with.

Definition: MooseBase.h:353

◆ getParam() [1/2]

template<typename T >

const T & MooseBase::getParam ( const std::string & name ) const

inherited

Retrieve a parameter for the object.

Parameters

name	The name of the parameter

Returns: The value of the parameter

Definition at line 384 of file MooseBase.h.

 {
   return InputParameters::getParamHelper<T>(name, _pars);
 }

◆ getParam() [2/2]

template<typename T1 , typename T2 >

std::vector< std::pair< T1, T2 > > MooseBase::getParam	(	const std::string &	param1,
		const std::string &	param2
	)		const

inherited

Retrieve two parameters and provide pair of parameters for the object.

Parameters

param1	The name of first parameter
param2	The name of second parameter

Returns: Vector of pairs of first and second parameters

Definition at line 421 of file MooseBase.h.

 {
   return _pars.get<T1, T2>(param1, param2);
 }

◆ getPostprocessorName()

const PostprocessorName & PostprocessorInterface::getPostprocessorName	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Get the name of a postprocessor.

This can only be used if the postprocessor parameter does not have a default value set (see isDefaultPostprocessorValue()), in which case the "name" is actually the default value.

Parameters

param_name	The name of the Postprocessor parameter
index	The index of the Postprocessor

Returns: The name of the given Postprocessor

Definition at line 185 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

 {
   return getPostprocessorNameInternal(param_name, index, /* allow_default_value = */ false);
 }

◆ getPostprocessorValue()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValue	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

doco-normal-methods-begin Retrieve the value of a Postprocessor or one of it's old or older values

Parameters

param_name	The name of the Postprocessor parameter (see below)
index	The index of the Postprocessor

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 36 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel(), FunctionValuePostprocessor::FunctionValuePostprocessor(), LinearCombinationPostprocessor::LinearCombinationPostprocessor(), and ParsedPostprocessor::ParsedPostprocessor().

 {
   return getPostprocessorValueInternal(param_name, index, /* t_index = */ 0);
 }

◆ getPostprocessorValueByName()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueByName ( const PostprocessorName & name ) const

virtualinherited

Retrieve the value of the Postprocessor.

Parameters

name	Postprocessor 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 57 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel(), PIDTransientControl::execute(), IterationAdaptiveDT::IterationAdaptiveDT(), LibtorchNeuralNetControl::LibtorchNeuralNetControl(), ParsedODEKernel::ParsedODEKernel(), SecantSolve::savePostprocessorValues(), SteffensenSolve::savePostprocessorValues(), PicardSolve::savePostprocessorValues(), WebServerControl::startServer(), Terminator::Terminator(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), PicardSolve::transformPostprocessors(), and VectorOfPostprocessors::VectorOfPostprocessors().

 {
   return getPostprocessorValueByNameInternal(name, /* t_index = */ 0);
 }

◆ getPostprocessorValueOld()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOld	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Definition at line 43 of file PostprocessorInterface.C.

 {
   return getPostprocessorValueInternal(param_name, index, /* t_index = */ 1);
 }

◆ getPostprocessorValueOldByName()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOldByName ( const PostprocessorName & name ) const

inherited

Definition at line 63 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

 {
   return getPostprocessorValueByNameInternal(name, /* t_index = */ 1);
 }

◆ getPostprocessorValueOlder()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOlder	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Definition at line 50 of file PostprocessorInterface.C.

 {
   return getPostprocessorValueInternal(param_name, index, /* t_index = */ 2);
 }

◆ getPostprocessorValueOlderByName()

const PostprocessorValue & PostprocessorInterface::getPostprocessorValueOlderByName ( const PostprocessorName & name ) const

inherited

Definition at line 69 of file PostprocessorInterface.C.

 {
   return getPostprocessorValueByNameInternal(name, /* t_index = */ 2);
 }

◆ getRenamedParam()

template<typename T >

const T & MooseBase::getRenamedParam	(	const std::string &	old_name,
		const std::string &	new_name
	)		const

inherited

Retrieve a renamed parameter for the object.

This helper makes sure we check both names before erroring, and that only one parameter is passed to avoid silent errors

Parameters

old_name	the old name for the parameter
new_name	the new name for the parameter

Definition at line 398 of file MooseBase.h.

 {
   // Most important: accept new parameter
   if (isParamSetByUser(new_name) && !isParamValid(old_name))
     return getParam<T>(new_name);
   // Second most: accept old parameter
   if (isParamValid(old_name) && !isParamSetByUser(new_name))
     return getParam<T>(old_name);
   // Third most: accept default for new parameter
   if (isParamValid(new_name) && !isParamValid(old_name))
     return getParam<T>(new_name);
   // Refuse: no default, no value passed
   if (!isParamValid(old_name) && !isParamValid(new_name))
     mooseError("parameter '" + new_name +
                "' is being retrieved without being set.\nDid you misspell it?");
   // Refuse: both old and new parameters set by user
   else
     mooseError("Parameter '" + new_name + "' may not be provided alongside former parameter '" +
                old_name + "'");
 }

◆ getSharedPtr() [1/2]

std::shared_ptr< MooseObject > MooseObject::getSharedPtr ( )

inherited

Get another shared pointer to this object that has the same ownership group.

Wrapper around shared_from_this().

Definition at line 61 of file MooseObject.C.

Referenced by MFEMProblem::addBoundaryCondition(), MFEMProblem::addKernel(), and MFEMProblem::addMFEMSolver().

 {
   try
   {
     return shared_from_this();
   }
   catch (std::bad_weak_ptr &)
   {
     mooseError(not_shared_error);
   }
 }

◆ getSharedPtr() [2/2]

std::shared_ptr< const MooseObject > MooseObject::getSharedPtr ( ) const

inherited

Definition at line 74 of file MooseObject.C.

 {
   try
   {
     return shared_from_this();
   }
   catch (std::bad_weak_ptr &)
   {
     mooseError(not_shared_error);
   }
 }

◆ hasBase()

bool MooseBase::hasBase ( ) const

inlineinherited

Returns: Whether or not this object has a registered base (set via InputParameters::registerBase())

Definition at line 138 of file MooseBase.h.

138 { return _pars.hasBase(); }

MooseBase::_pars

const InputParameters & _pars

The object's parameters.

Definition: MooseBase.h:362

InputParameters::hasBase

bool hasBase() const

Definition: InputParameters.C:491

◆ hasFixedPointIteration()

bool FixedPointSolve::hasFixedPointIteration ( )

inline

Whether or not this has fixed point iterations.

Definition at line 84 of file FixedPointSolve.h.

84 { return _has_fixed_point_its; }

FixedPointSolve::_has_fixed_point_its

const bool _has_fixed_point_its

Whether or not we activate fixed point iteration.

Definition: FixedPointSolve.h:202

◆ hasPostprocessor()

bool PostprocessorInterface::hasPostprocessor	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Determine if the Postprocessor data exists.

Parameters

param_name	The name of the Postprocessor parameter
index	The index of the Postprocessor

Returns: True if the Postprocessor exists

See also: hasPostprocessorByName getPostprocessorValue

Definition at line 107 of file PostprocessorInterface.C.

 {
   if (!postprocessorsAdded())
     _ppi_moose_object.mooseError(
         "Cannot call hasPostprocessor() until all Postprocessors have been constructed.");
 
   return hasPostprocessorByName(getPostprocessorNameInternal(param_name, index));
 }

◆ hasPostprocessorByName()

bool PostprocessorInterface::hasPostprocessorByName ( const PostprocessorName & name ) const

inherited

Determine if the Postprocessor data exists.

Parameters

name	The name of the Postprocessor

Returns: True if the Postprocessor exists

See also: hasPostprocessor getPostprocessorValueByName

Definition at line 118 of file PostprocessorInterface.C.

Referenced by PostprocessorInterface::getPostprocessorValueByNameInternal(), PostprocessorInterface::getPostprocessorValueInternal(), PostprocessorInterface::hasPostprocessor(), AdvancedOutput::initShowHideLists(), TableOutput::outputReporters(), Exodus::outputReporters(), and WebServerControl::startServer().

 {
   if (!postprocessorsAdded())
     _ppi_moose_object.mooseError(
         "Cannot call hasPostprocessorByName() until all Postprocessors have been constructed.");
 
   return _ppi_feproblem.getReporterData().hasReporterValue<PostprocessorValue>(
       PostprocessorReporterName(name));
 }

◆ initialSetup()

void FixedPointSolve::initialSetup ( )

overridevirtual

Method that should be executed once, before any solve calls.

Reimplemented from SolveObject.

Reimplemented in SteffensenSolve.

Definition at line 192 of file FixedPointSolve.C.

Referenced by SteffensenSolve::initialSetup().

 {
   SolveObject::initialSetup();
 
   allocateStorage(true);
 
   if (_has_fixed_point_its)
   {
     auto & conv = _problem.getConvergence(_problem.getMultiAppFixedPointConvergenceName());
     conv.checkIterationType(ConvergenceIterationTypes::MULTIAPP_FIXED_POINT);
   }
 }

◆ isDefaultPostprocessorValue()

bool PostprocessorInterface::isDefaultPostprocessorValue	(	const std::string &	param_name,
		const unsigned int	index = `0`
	)		const

inherited

Determine whether or not the Postprocessor is a default value.

A default value is when the value is either the value set by addParam, or is a user-set value in input instead of a name to a postprocessor.

Parameters

param_name	The name of the Postprocessor parameter
index	The index of the postprocessor

Returns: True if the Postprocessor is a default value, false if the Postprocessor is the name of a Postprocessor

Definition at line 75 of file PostprocessorInterface.C.

Referenced by EigenKernel::EigenKernel().

 {
   return isDefaultPostprocessorValueByName(getPostprocessorNameInternal(param_name, index));
 }

◆ isParamSetByUser()

bool MooseBase::isParamSetByUser ( const std::string & name ) const

inlineinherited

Test if the supplied parameter is set by a user, as opposed to not set or set to default.

Parameters

name	The name of the parameter to test

Definition at line 201 of file MooseBase.h.

Referenced by SetupDebugAction::act(), ADConservativeAdvectionBC::ADConservativeAdvectionBC(), DiffusionCG::addFEBCs(), DiffusionPhysicsBase::addInitialConditions(), MFEMMesh::buildMesh(), LibtorchNeuralNetControl::conditionalParameterError(), MooseApp::copyInputs(), DiffusionPhysicsBase::DiffusionPhysicsBase(), ElementSubdomainModifierBase::ElementSubdomainModifierBase(), MooseApp::errorCheck(), MooseBase::getRenamedParam(), DefaultConvergenceBase::getSharedExecutionerParam(), AddVariableAction::init(), PhysicsBase::initializePhysics(), ElementSubdomainModifierBase::initialSetup(), MatrixSymmetryCheck::MatrixSymmetryCheck(), MeshDiagnosticsGenerator::MeshDiagnosticsGenerator(), MultiAppGeneralFieldTransfer::MultiAppGeneralFieldTransfer(), SolutionInvalidityOutput::output(), Output::Output(), MultiAppGeneralFieldTransfer::outputValueConflicts(), PetscExternalPartitioner::partition(), PiecewiseTabularBase::PiecewiseTabularBase(), MooseMesh::prepare(), SolutionUserObjectBase::readXda(), PhysicsBase::reportPotentiallyMissedParameters(), MooseApp::runInputFile(), MooseApp::runInputs(), MFEMSolverBase::setPreconditioner(), SetupMeshAction::setupMesh(), MooseApp::setupOptions(), SideSetsFromBoundingBoxGenerator::SideSetsFromBoundingBoxGenerator(), TimedSubdomainModifier::TimedSubdomainModifier(), and XYDelaunayGenerator::XYDelaunayGenerator().

   {
     return _pars.isParamSetByUser(name);
   }

◆ isParamValid()

bool MooseBase::isParamValid ( const std::string & name ) const

inlineinherited

Test if the supplied parameter is valid.

Parameters

name	The name of the parameter to test

Definition at line 195 of file MooseBase.h.

195 { return _pars.isParamValid(name); }

MooseBase::_pars

const InputParameters & _pars

The object's parameters.

Definition: MooseBase.h:362

MooseBase::name

const std::string & name() const

Get the name of the class.

Definition: MooseBase.h:99

InputParameters::isParamValid

bool isParamValid(const std::string &name) const

This method returns parameters that have been initialized in one fashion or another, i.e.

Definition: InputParameters.C:386

◆ messagePrefix()

std::string MooseBase::messagePrefix ( const bool hit_prefix = true ) const

inlineinherited

Returns: A prefix to be used in messages that contain the input file location associated with this object (if any) and the name and type of the object.

Definition at line 252 of file MooseBase.h.

Referenced by MooseBase::callMooseError(), MooseBase::errorPrefix(), MooseBase::mooseDeprecated(), MooseBase::mooseInfo(), and MooseBase::mooseWarning().

   {
     return messagePrefix(_pars, hit_prefix);
   }

◆ mooseDeprecated()

template<typename... Args>

void MooseBase::mooseDeprecated ( Args &&... args ) const

inlineinherited

Definition at line 310 of file MooseBase.h.

Referenced by FEProblemBase::addAuxArrayVariable(), FEProblemBase::addAuxScalarVariable(), FEProblemBase::addAuxVariable(), FEProblemBase::advanceMultiApps(), MultiApp::appProblem(), MooseMesh::buildSideList(), ChangeOverTimestepPostprocessor::ChangeOverTimestepPostprocessor(), AddVariableAction::determineType(), EigenProblem::EigenProblem(), Eigenvalue::Eigenvalue(), MooseMesh::elem(), UserForcingFunction::f(), FaceFaceConstraint::FaceFaceConstraint(), FunctionDT::FunctionDT(), RandomICBase::generateRandom(), MooseMesh::getBoundariesToElems(), DataFileInterface::getDataFileName(), DataFileInterface::getDataFileNameByName(), Control::getExecuteOptions(), FEProblemBase::getNonlinearSystem(), MooseApp::getRecoverFileBase(), FEProblemBase::getUserObjects(), FEProblemBase::hasPostprocessor(), MooseApp::hasRecoverFileBase(), MatDiffusionBase< Real >::MatDiffusionBase(), MultiAppNearestNodeTransfer::MultiAppNearestNodeTransfer(), MultiAppShapeEvaluationTransfer::MultiAppShapeEvaluationTransfer(), MultiAppUserObjectTransfer::MultiAppUserObjectTransfer(), NodalScalarKernel::NodalScalarKernel(), MooseMesh::node(), numPicardIts(), RelationshipManager::operator>=(), PercentChangePostprocessor::PercentChangePostprocessor(), ReferenceResidualConvergence::ReferenceResidualConvergence(), Residual::Residual(), MooseMesh::setBoundaryToNormalMap(), Exodus::setOutputDimension(), MooseApp::setupOptions(), UserForcingFunction::UserForcingFunction(), and VariableResidual::VariableResidual().

   {
     moose::internal::mooseDeprecatedStream(
         _console, false, true, messagePrefix(true), std::forward<Args>(args)...);
   }

◆ mooseDocumentedError()

template<typename... Args>

void MooseBase::mooseDocumentedError	(	const std::string &	repo_name,
		const unsigned int	issue_num,
		Args &&...	args
	)		const

inlineinherited

Definition at line 273 of file MooseBase.h.

Referenced by ArrayDGLowerDKernel::ArrayDGLowerDKernel(), ArrayHFEMDirichletBC::ArrayHFEMDirichletBC(), ArrayLowerDIntegratedBC::ArrayLowerDIntegratedBC(), DGLowerDKernel::DGLowerDKernel(), HFEMDirichletBC::HFEMDirichletBC(), and LowerDIntegratedBC::LowerDIntegratedBC().

   {
     callMooseError(moose::internal::formatMooseDocumentedError(
                        repo_name, issue_num, argumentsToString(std::forward<Args>(args)...)),
                    /* with_prefix = */ true);
   }

◆ mooseError()

template<typename... Args>

void MooseBase::mooseError ( Args &&... args ) const

inlineinherited

Emits an error prefixed with object name and type and optionally a file path to the top-level block parameter if available.

Definition at line 267 of file MooseBase.h.

   {
     callMooseError(argumentsToString(std::forward<Args>(args)...), /* with_prefix = */ true);
   }

◆ mooseErrorNonPrefixed()

template<typename... Args>

void MooseBase::mooseErrorNonPrefixed ( Args &&... args ) const

inlineinherited

Emits an error without the prefixing included in mooseError().

Definition at line 286 of file MooseBase.h.

   {
     callMooseError(argumentsToString(std::forward<Args>(args)...), /* with_prefix = */ false);
   }

◆ mooseInfo()

template<typename... Args>

void MooseBase::mooseInfo ( Args &&... args ) const

inlineinherited

Definition at line 317 of file MooseBase.h.

Referenced by SetupRecoverFileBaseAction::act(), AStableDirk4::AStableDirk4(), MeshDiagnosticsGenerator::checkNonConformalMeshFromAdaptivity(), MultiAppGeneralFieldNearestLocationTransfer::evaluateInterpValuesNearestNode(), PIDTransientControl::execute(), Executioner::Executioner(), ExplicitRK2::ExplicitRK2(), ExplicitTVDRK2::ExplicitTVDRK2(), DataFileInterface::getDataFilePath(), MFEMScalarFESpace::getFECName(), MultiAppTransfer::getPointInTargetAppFrame(), ImplicitMidpoint::ImplicitMidpoint(), ParsedDownSelectionPositions::initialize(), PropertyReadFile::initialize(), MultiAppGeneralFieldTransfer::initialSetup(), InversePowerMethod::InversePowerMethod(), LStableDirk2::LStableDirk2(), LStableDirk3::LStableDirk3(), LStableDirk4::LStableDirk4(), PNGOutput::makeMeshFunc(), NonlinearEigen::NonlinearEigen(), SolutionInvalidityOutput::output(), MultiAppGeneralFieldTransfer::outputValueConflicts(), MooseBase::paramInfo(), ProjectionAux::ProjectionAux(), ReferenceResidualConvergence::ReferenceResidualConvergence(), MFEMDataCollection::registerFields(), FEProblemBase::setRestartFile(), MooseApp::setupOptions(), SolutionUserObjectBase::SolutionUserObjectBase(), SymmetryTransformGenerator::SymmetryTransformGenerator(), TransientBase::takeStep(), and TransientBase::TransientBase().

   {
     moose::internal::mooseInfoStream(_console, messagePrefix(true), std::forward<Args>(args)...);
   }

◆ mooseWarning()

template<typename... Args>

void MooseBase::mooseWarning ( Args &&... args ) const

inlineinherited

Emits a warning prefixed with object name and type.

Definition at line 295 of file MooseBase.h.

Referenced by CopyMeshPartitioner::_do_partition(), AddKernelAction::act(), MeshOnlyAction::act(), AddFunctionAction::act(), MaterialOutputAction::act(), CommonOutputAction::act(), MFEMProblem::addFunction(), MooseMesh::addPeriodicVariable(), DiracKernelBase::addPoint(), BoundaryMarker::BoundaryMarker(), DistributedRectilinearMeshGenerator::buildCube(), MultiAppVariableValueSamplePostprocessorTransfer::cacheElemToPostprocessorData(), CartesianMeshGenerator::CartesianMeshGenerator(), CheckOutputAction::checkConsoleOutput(), MultiAppTransfer::checkMultiAppExecuteOn(), MeshDiagnosticsGenerator::checkNonMatchingEdges(), ActionComponent::checkRequiredTasks(), PhysicsBase::checkRequiredTasks(), SampledOutput::cloneMesh(), MultiAppGeneralFieldTransfer::closestToPosition(), VariableValueElementSubdomainModifier::computeSubdomainID(), GapValueAux::computeValue(), MultiApp::createApp(), DebugResidualAux::DebugResidualAux(), MeshDiagnosticsGenerator::diagnosticsLog(), CartesianGridDivision::divisionIndex(), CylindricalGridDivision::divisionIndex(), SphericalGridDivision::divisionIndex(), ElementMaterialSampler::ElementMaterialSampler(), Postprocessor::evaluateDotWarning(), MeshDivisionFunctorReductionVectorPostprocessor::execute(), ElementQualityChecker::finalize(), FiniteDifferencePreconditioner::FiniteDifferencePreconditioner(), FixedPointSolve(), SubdomainPerElementGenerator::generate(), StitchMeshGenerator::generate(), ParsedGenerateSideset::generate(), MultiAppTransfer::getAppInfo(), FunctorBinnedValuesDivision::getBinIndex(), DataFileInterface::getDataFilePath(), PointSamplerBase::getLocalElemContainingPoint(), FEProblemBase::getMaterial(), LineValueSampler::getValue(), Terminator::handleMessage(), IndicatorMarker::IndicatorMarker(), CartesianGridDivision::initialize(), CylindricalGridDivision::initialize(), SphericalGridDivision::initialize(), ElementGroupCentroidPositions::initialize(), MultiAppGeneralFieldNearestLocationTransfer::initialSetup(), BoundsBase::initialSetup(), ReferenceResidualConvergence::initialSetup(), MultiAppGeneralFieldTransfer::initialSetup(), FEProblemBase::initialSetup(), AdvancedOutput::initPostprocessorOrVectorPostprocessorLists(), MaterialBase::initStatefulProperties(), LeastSquaresFit::LeastSquaresFit(), IterationAdaptiveDT::limitDTToPostprocessorValue(), MooseApp::loadLibraryAndDependencies(), FEProblemBase::mesh(), MultiAppGeneralFieldTransfer::MultiAppGeneralFieldTransfer(), NewmarkBeta::NewmarkBeta(), NodalPatchRecovery::NodalPatchRecovery(), NonlocalIntegratedBC::NonlocalIntegratedBC(), NonlocalKernel::NonlocalKernel(), Output::Output(), MultiAppGeneralFieldTransfer::outputValueConflicts(), MooseBase::paramWarning(), PiecewiseConstantFromCSV::PiecewiseConstantFromCSV(), Executioner::problem(), PropertyReadFile::readData(), TestSourceStepper::rejectStep(), PhysicsBase::reportPotentiallyMissedParameters(), MaterialBase::resetQpProperties(), SecondTimeDerivativeAux::SecondTimeDerivativeAux(), MooseMesh::setCoordSystem(), SidesetAroundSubdomainUpdater::SidesetAroundSubdomainUpdater(), FEProblemBase::sizeZeroes(), TransientMultiApp::solveStep(), Tecplot::Tecplot(), TimeDerivativeAux::TimeDerivativeAux(), Checkpoint::updateCheckpointFiles(), SampledOutput::updateSample(), PiecewiseConstantFromCSV::value(), and VariableCondensationPreconditioner::VariableCondensationPreconditioner().

   {
     moose::internal::mooseWarningStream(_console, messagePrefix(true), std::forward<Args>(args)...);
   }

◆ mooseWarningNonPrefixed()

template<typename... Args>

void MooseBase::mooseWarningNonPrefixed ( Args &&... args ) const

inlineinherited

Emits a warning without the prefixing included in mooseWarning().

Definition at line 304 of file MooseBase.h.

   {
     moose::internal::mooseWarningStream(_console, std::forward<Args>(args)...);
   }

◆ name()

const std::string& MooseBase::name ( ) const

inlineinherited

Get the name of the class.

Returns: The name of the class

Definition at line 99 of file MooseBase.h.

   {
     mooseAssert(_name.size(), "Empty name");
     return _name;
   }

◆ numFixedPointIts()

unsigned int FixedPointSolve::numFixedPointIts ( ) const

inline

Get the number of fixed point iterations performed Because this returns the number of fixed point iterations, rather than the current iteration count (which starts at 0), increment by 1.

Returns: Number of fixed point iterations performed

Definition at line 58 of file FixedPointSolve.h.

Referenced by FixedPointIterationAdaptiveDT::acceptStep(), IterationInfo::execute(), PIDTransientControl::execute(), ChangeOverFixedPointPostprocessor::finalize(), NumFixedPointIterations::getValue(), and DefaultMultiAppFixedPointConvergence::preExecute().

58 { return _fixed_point_it + 1; }

FixedPointSolve::_fixed_point_it

unsigned int _fixed_point_it

Definition: FixedPointSolve.h:224

◆ numPicardIts()

unsigned int FixedPointSolve::numPicardIts ( ) const

inline

Deprecated getter for the number of fixed point iterations.

Definition at line 61 of file FixedPointSolve.h.

   {
     mooseDeprecated("numPicards() is deprecated. Please use numFixedPointIts() instead.");
 
     return _fixed_point_it + 1;
   }

◆ paramError()

template<typename... Args>

void MooseBase::paramError	(	const std::string &	param,
		Args...	args
	)		const

inherited

Emits an error prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message.

If this object's parameters were not created directly by the Parser, then this function falls back to the normal behavior of mooseError - only printing a message using the given args.

Definition at line 435 of file MooseBase.h.

 {
   _pars.paramError(param, std::forward<Args>(args)...);
 }

◆ parameters()

const InputParameters& MooseBase::parameters ( ) const

inlineinherited

Get the parameters of the object.

Returns: The parameters of the object

Definition at line 127 of file MooseBase.h.

127 { return _pars; }

MooseBase::_pars

const InputParameters & _pars

The object's parameters.

Definition: MooseBase.h:362

◆ paramInfo()

template<typename... Args>

void MooseBase::paramInfo	(	const std::string &	param,
		Args...	args
	)		const

inherited

Emits an informational message prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message.

If this object's parameters were not created directly by the Parser, then this function falls back to the normal behavior of mooseInfo - only printing a message using the given args.

Definition at line 449 of file MooseBase.h.

Referenced by GridPartitioner::_do_partition(), ComboMarker::ComboMarker(), Control::Control(), FunctorIC::FunctorIC(), and TransientMultiApp::TransientMultiApp().

 {
   mooseInfo(_pars.paramMessage(param, std::forward<Args>(args)...));
 }

◆ paramWarning()

template<typename... Args>

void MooseBase::paramWarning	(	const std::string &	param,
		Args...	args
	)		const

inherited

Emits a warning prefixed with the file and line number of the given param (from the input file) along with the full parameter path+name followed by the given args as the message.

If this object's parameters were not created directly by the Parser, then this function falls back to the normal behavior of mooseWarning - only printing a message using the given args.

Definition at line 442 of file MooseBase.h.

Referenced by GridPartitioner::_do_partition(), MultiAppTransfer::checkParentAppUserObjectExecuteOn(), EigenProblem::checkProblemIntegrity(), CombinerGenerator::copyIntoMesh(), DefaultMultiAppFixedPointConvergence::DefaultMultiAppFixedPointConvergence(), MultiAppNearestNodeTransfer::execute(), FEProblemSolve::FEProblemSolve(), UniqueExtraIDMeshGenerator::generate(), PlaneIDMeshGenerator::generate(), Terminator::initialSetup(), SampledOutput::initSample(), MooseMesh::MooseMesh(), FEProblemBase::setPreserveMatrixSparsityPattern(), and Terminator::Terminator().

 {
   mooseWarning(_pars.paramMessage(param, std::forward<Args>(args)...));
 }

◆ perfGraph()

PerfGraph & PerfGraphInterface::perfGraph ( )

inherited

Get the PerfGraph.

Definition at line 78 of file PerfGraphInterface.C.

Referenced by CommonOutputAction::act(), PerfGraphData::finalize(), and PerfGraphOutput::output().

 {
   return _pg_moose_app.perfGraph();
 }

◆ performingRelaxation()

bool FixedPointSolve::performingRelaxation ( const bool primary ) const

protected

Returns true if there is relaxation.

Parameters

primary True if this is the parent app; false if this is a child app.

Definition at line 565 of file FixedPointSolve.C.

Referenced by PicardSolve::allocateStorage(), PicardSolve::savePostprocessorValues(), PicardSolve::saveVariableValues(), and PicardSolve::useFixedPointAlgorithmUpdateInsteadOfPicard().

 {
   if (primary)
     return !MooseUtils::absoluteFuzzyEqual(_relax_factor, 1.0);
   else
     return !MooseUtils::absoluteFuzzyEqual(_secondary_relaxation_factor, 1.0);
 }

◆ printFixedPointConvergenceHistory()

virtual void FixedPointSolve::printFixedPointConvergenceHistory	(	Real	initial_norm,
		const std::vector< Real > &	timestep_begin_norms,
		const std::vector< Real > &	timestep_end_norms
	)		const

pure virtual

Print the convergence history of the coupling, at every fixed point iteration.

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by DefaultMultiAppFixedPointConvergence::checkConvergence().

◆ printFixedPointConvergenceReason()

void FixedPointSolve::printFixedPointConvergenceReason ( )

protected

Print information about the fixed point convergence.

Definition at line 509 of file FixedPointSolve.C.

Referenced by solve().

 {
   _console << "Fixed point convergence reason: ";
   switch (_fixed_point_status)
   {
     case MooseFixedPointConvergenceReason::CONVERGED_ABS:
       _console << "CONVERGED_ABS";
       break;
     case MooseFixedPointConvergenceReason::CONVERGED_RELATIVE:
       _console << "CONVERGED_RELATIVE";
       break;
     case MooseFixedPointConvergenceReason::CONVERGED_PP:
       _console << "CONVERGED_PP";
       break;
     case MooseFixedPointConvergenceReason::REACH_MAX_ITS:
       _console << "REACH_MAX_ITS";
       break;
     case MooseFixedPointConvergenceReason::CONVERGED_OBJECT:
       _console << "CONVERGED_OBJECT (see Convergence object)";
       break;
     case MooseFixedPointConvergenceReason::DIVERGED_MAX_ITS:
       _console << "DIVERGED_MAX_ITS";
       break;
     case MooseFixedPointConvergenceReason::DIVERGED_NONLINEAR:
       _console << "DIVERGED_NONLINEAR";
       break;
     case MooseFixedPointConvergenceReason::DIVERGED_FAILED_MULTIAPP:
       _console << "DIVERGED_FAILED_MULTIAPP";
       break;
     case MooseFixedPointConvergenceReason::DIVERGED_OBJECT:
       _console << "DIVERGED_OBJECT (see Convergence object)";
       break;
     default:
       // UNSOLVED and CONVERGED_NONLINEAR should not be hit when coupling
       // iteration is not on here
       mooseError("Internal error: wrong fixed point status!");
       break;
   }
   _console << std::endl;
 }

◆ queryParam()

template<typename T >

const T * MooseBase::queryParam ( const std::string & name ) const

inherited

Query a parameter for the object.

If the parameter is not valid, nullptr will be returned

Parameters

name	The name of the parameter

Returns: A pointer to the parameter value, if it exists

Definition at line 391 of file MooseBase.h.

 {
   return isParamValid(name) ? &getParam<T>(name) : nullptr;
 }

◆ registerTimedSection() [1/2]

PerfID PerfGraphInterface::registerTimedSection	(	const std::string &	section_name,
		const unsigned int	level
	)		const

protectedinherited

Call to register a named section for timing.

Parameters

section_name	The name of the code section to be timed
level	The importance of the timer - lower is more important (0 will always come out)

Returns: The ID of the section - use when starting timing

Definition at line 53 of file PerfGraphInterface.C.

 {
   const auto timed_section_name = timedSectionName(section_name);
   if (!moose::internal::getPerfGraphRegistry().sectionExists(timed_section_name))
     return moose::internal::getPerfGraphRegistry().registerSection(timed_section_name, level);
   else
     return moose::internal::getPerfGraphRegistry().sectionID(timed_section_name);
 }

◆ registerTimedSection() [2/2]

PerfID PerfGraphInterface::registerTimedSection	(	const std::string &	section_name,
		const unsigned int	level,
		const std::string &	live_message,
		const bool	print_dots = `true`
	)		const

protectedinherited

Call to register a named section for timing.

Parameters

section_name	The name of the code section to be timed
level	The importance of the timer - lower is more important (0 will always come out)
live_message	The message to be printed to the screen during execution
print_dots	Whether or not progress dots should be printed for this section

Returns: The ID of the section - use when starting timing

Definition at line 64 of file PerfGraphInterface.C.

 {
   const auto timed_section_name = timedSectionName(section_name);
   if (!moose::internal::getPerfGraphRegistry().sectionExists(timed_section_name))
     return moose::internal::getPerfGraphRegistry().registerSection(
         timedSectionName(section_name), level, live_message, print_dots);
   else
     return moose::internal::getPerfGraphRegistry().sectionID(timed_section_name);
 }

◆ saveAllValues()

void FixedPointSolve::saveAllValues ( const bool primary )

protectedvirtual

Save both the variable and postprocessor values.

Definition at line 367 of file FixedPointSolve.C.

Referenced by solveStep().

 {
   saveVariableValues(primary);
   savePostprocessorValues(primary);
 }

◆ savePostprocessorValues()

virtual void FixedPointSolve::savePostprocessorValues ( const bool primary )

protectedpure virtual

Saves the current values of the postprocessors, and update the old(er) vectors.

Parameters

primary Whether this routine is to save the variables for the primary transformed quantities (as main app) or the secondary ones (as a subapp)

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by saveAllValues(), and solve().

◆ saveVariableValues()

virtual void FixedPointSolve::saveVariableValues ( const bool primary )

protectedpure virtual

Saves the current values of the variables, and update the old(er) vectors.

Parameters

primary Whether this routine is to save the variables for the primary transformed quantities (as main app) or the secondary ones (as a subapp)

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by saveAllValues(), and solve().

◆ setFixedPointStatus()

void FixedPointSolve::setFixedPointStatus ( MooseFixedPointConvergenceReason status )

inline

Set fixed point status.

Definition at line 75 of file FixedPointSolve.h.

Referenced by DefaultMultiAppFixedPointConvergence::checkConvergence().

   {
     _fixed_point_status = status;
   }

◆ setInnerSolve()

virtual void SolveObject::setInnerSolve ( SolveObject & solve )

inlinevirtualinherited

Set the inner solve object wrapped by this object.

Reimplemented in FEProblemSolve.

Definition at line 41 of file SolveObject.h.

41 { _inner_solve = &solve; }

SolveObject::_inner_solve

SolveObject * _inner_solve

SolveObject wrapped by this solve object.

Definition: SolveObject.h:59

SolveObject::solve

virtual bool solve()=0

Solve routine provided by this object.

◆ setMultiAppRelaxationFactor()

void FixedPointSolve::setMultiAppRelaxationFactor ( Real factor )

inline

Set relaxation factor for the current solve as a SubApp.

Definition at line 87 of file FixedPointSolve.h.

87 { _secondary_relaxation_factor = factor; }

FixedPointSolve::_secondary_relaxation_factor

Real _secondary_relaxation_factor

Relaxation factor outside of fixed point iteration (used as a subapp)

Definition: FixedPointSolve.h:214

◆ setMultiAppTransformedPostprocessors()

virtual void FixedPointSolve::setMultiAppTransformedPostprocessors ( const std::vector< PostprocessorName > & pps )

inlinevirtual

Set relaxation postprocessors for the current solve as a SubApp.

Definition at line 96 of file FixedPointSolve.h.

   {
     _secondary_transformed_pps = pps;
   }

◆ setMultiAppTransformedVariables()

void FixedPointSolve::setMultiAppTransformedVariables ( const std::vector< std::string > & vars )

inline

Set relaxation variables for the current solve as a SubApp.

Definition at line 90 of file FixedPointSolve.h.

   {
     _secondary_transformed_variables = vars;
   }

◆ solve()

bool FixedPointSolve::solve ( )

overridevirtual

Iteratively solves the FEProblem.

Returns: True if solver is converged.

Implements SolveObject.

Definition at line 206 of file FixedPointSolve.C.

 {
   TIME_SECTION("PicardSolve", 1);
 
   Real current_dt = _problem.dt();
 
   bool converged = true;
 
   // need to back up multi-apps even when not doing fixed point iteration for recovering from failed
   // multiapp solve
   _problem.backupMultiApps(EXEC_MULTIAPP_FIXED_POINT_BEGIN);
   _problem.backupMultiApps(EXEC_TIMESTEP_BEGIN);
   _problem.backupMultiApps(EXEC_TIMESTEP_END);
   _problem.backupMultiApps(EXEC_MULTIAPP_FIXED_POINT_END);
 
   // Prepare to relax variables as a main app
   std::set<dof_id_type> transformed_dofs;
   if ((_relax_factor != 1.0 || !dynamic_cast<PicardSolve *>(this)) && _transformed_vars.size() > 0)
   {
     // Snag all of the local dof indices for all of these variables
     AllLocalDofIndicesThread aldit(_problem, _transformed_vars);
     libMesh::ConstElemRange & elem_range = *_problem.mesh().getActiveLocalElementRange();
     Threads::parallel_reduce(elem_range, aldit);
 
     transformed_dofs = aldit.getDofIndices();
   }
 
   // Prepare to relax variables as a subapp
   std::set<dof_id_type> secondary_transformed_dofs;
   if (_secondary_relaxation_factor != 1.0 || !dynamic_cast<PicardSolve *>(this))
   {
     if (_secondary_transformed_variables.size() > 0)
     {
       // Snag all of the local dof indices for all of these variables
       AllLocalDofIndicesThread aldit(_problem, _secondary_transformed_variables);
       libMesh::ConstElemRange & elem_range = *_problem.mesh().getActiveLocalElementRange();
       Threads::parallel_reduce(elem_range, aldit);
 
       secondary_transformed_dofs = aldit.getDofIndices();
     }
 
     // To detect a new time step
     if (_old_entering_time == _problem.time() &&
         _fixed_point_status != MooseFixedPointConvergenceReason::UNSOLVED)
     {
       // Keep track of the iteration number of the main app
       _main_fixed_point_it++;
 
       // Save variable values before the solve. Solving will provide new values
       if (!_app.isUltimateMaster())
         saveVariableValues(/*is parent app of this iteration=*/false);
     }
     else
       _main_fixed_point_it = 0;
   }
 
   if (_has_fixed_point_its)
   {
     auto & convergence = _problem.getConvergence(_problem.getMultiAppFixedPointConvergenceName());
     convergence.initialize();
   }
 
   _fixed_point_it = 0;
   while (true)
   {
     if (_has_fixed_point_its)
     {
       if (_fixed_point_it != 0)
       {
         // For every iteration other than the first, we need to restore the state of the MultiApps
         _problem.restoreMultiApps(EXEC_TIMESTEP_BEGIN);
         _problem.restoreMultiApps(EXEC_TIMESTEP_END);
       }
 
       _console << COLOR_MAGENTA << "Beginning fixed point iteration " << _fixed_point_it
                << COLOR_DEFAULT << std::endl
                << std::endl;
     }
 
     // Solve a single application for one time step
     const bool solve_converged = solveStep(transformed_dofs);
 
     if (solve_converged)
     {
       if (_has_fixed_point_its)
       {
         _problem.outputStep(EXEC_MULTIAPP_FIXED_POINT_ITERATION_END);
 
         // Examine convergence metrics & properties and set the convergence reason
         bool break_out = examineFixedPointConvergence(converged);
 
         if (break_out)
         {
           // Except DefaultMultiAppFixedPointConvergence, convergence objects will not
           // update _fixed_point_status, so we give those cases generic values:
           if (_fixed_point_status == MooseFixedPointConvergenceReason::CONVERGED_NONLINEAR)
           {
             if (converged)
               _fixed_point_status = MooseFixedPointConvergenceReason::CONVERGED_OBJECT;
             else
               _fixed_point_status = MooseFixedPointConvergenceReason::DIVERGED_OBJECT;
           }
 
           break;
         }
       }
     }
     else
     {
       // If the last solve didn't converge then we need to exit this step completely (even in the
       // case of coupling). So we can retry...
       converged = false;
       break;
     }
 
     _problem.dt() =
         current_dt; // _dt might be smaller than this at this point for multistep methods
 
     _fixed_point_it++;
 
     if (!_has_fixed_point_its)
       break;
   }
 
   if (converged)
   {
     // Fixed point iteration loop ends right above
     _problem.execute(EXEC_MULTIAPP_FIXED_POINT_END);
     _problem.execTransfers(EXEC_MULTIAPP_FIXED_POINT_END);
     if (!_problem.execMultiApps(EXEC_MULTIAPP_FIXED_POINT_END, autoAdvance()))
     {
       _fixed_point_status = MooseFixedPointConvergenceReason::DIVERGED_FAILED_MULTIAPP;
       return false;
     }
     _problem.outputStep(EXEC_MULTIAPP_FIXED_POINT_END);
   }
 
   // Save postprocessors after the solve and their potential timestep_end execution
   // The postprocessors could be overwritten at timestep_begin, which is why they are saved
   // after the solve. They could also be saved right after the transfers.
   if (_old_entering_time == _problem.time())
     savePostprocessorValues(false);
 
   if (converged)
   {
     // Update the subapp using the fixed point algorithm
     if (_secondary_transformed_variables.size() > 0 &&
         useFixedPointAlgorithmUpdateInsteadOfPicard(false) && _old_entering_time == _problem.time())
       transformVariables(secondary_transformed_dofs, false);
 
     // Update the entering time, used to detect failed solves
     _old_entering_time = _problem.time();
   }
 
   if (_has_fixed_point_its)
     printFixedPointConvergenceReason();
 
   return converged;
 }

◆ solveStep()

bool FixedPointSolve::solveStep ( const std::set< dof_id_type > & transformed_dofs )

protectedvirtual

Perform one fixed point iteration or a full solve.

Parameters

transformed_dofs DoFs targetted by the fixed point algorithm

Returns: True if both nonlinear solve and the execution of multiapps are successful.

Note: this function also set _xfem_repeat_step flag for XFEM. It tracks _xfem_update_count state. FIXME: The proper design will be to let XFEM use Picard iteration to control the execution.

Definition at line 374 of file FixedPointSolve.C.

Referenced by solve().

 {
   bool auto_advance = autoAdvance();
 
   _executioner.preSolve();
   _problem.execTransfers(EXEC_TIMESTEP_BEGIN);
 
   if (_fixed_point_it == 0)
   {
     _problem.execute(EXEC_MULTIAPP_FIXED_POINT_BEGIN);
     _problem.execTransfers(EXEC_MULTIAPP_FIXED_POINT_BEGIN);
     if (!_problem.execMultiApps(EXEC_MULTIAPP_FIXED_POINT_BEGIN, autoAdvance()))
     {
       _fixed_point_status = MooseFixedPointConvergenceReason::DIVERGED_FAILED_MULTIAPP;
       return false;
     }
     _problem.outputStep(EXEC_MULTIAPP_FIXED_POINT_BEGIN);
   }
 
   if (!_problem.execMultiApps(EXEC_TIMESTEP_BEGIN, auto_advance))
   {
     _fixed_point_status = MooseFixedPointConvergenceReason::DIVERGED_FAILED_MULTIAPP;
     return false;
   }
 
   if (_problem.haveXFEM() && _update_xfem_at_timestep_begin)
     _problem.updateMeshXFEM();
 
   _problem.execute(EXEC_TIMESTEP_BEGIN);
 
   // Transform the fixed point postprocessors before solving, but after the timestep_begin transfers
   // have been received
   if (_transformed_pps.size() > 0 && useFixedPointAlgorithmUpdateInsteadOfPicard(true))
     transformPostprocessors(true);
   if (_secondary_transformed_pps.size() > 0 && useFixedPointAlgorithmUpdateInsteadOfPicard(false) &&
       _problem.time() == _old_entering_time)
     transformPostprocessors(false);
 
   if (_has_fixed_point_its)
   {
     auto & convergence = _problem.getConvergence(_problem.getMultiAppFixedPointConvergenceName());
     convergence.preExecute();
   }
 
   // Perform output for timestep begin
   _problem.outputStep(EXEC_TIMESTEP_BEGIN);
 
   // Update warehouse active objects
   _problem.updateActiveObjects();
 
   // Save the current values of variables and postprocessors, before the solve
   saveAllValues(true);
 
   // Save the previous fixed point iteration solution and aux variables
   _solver_sys.copyPreviousFixedPointSolutions();
   _aux.copyPreviousFixedPointSolutions();
 
   if (_has_fixed_point_its)
     _console << COLOR_MAGENTA << "\nMain app solve:" << COLOR_DEFAULT << std::endl;
   if (!_inner_solve->solve())
   {
     _fixed_point_status = MooseFixedPointConvergenceReason::DIVERGED_NONLINEAR;
 
     // Perform the output of the current, failed time step (this only occurs if desired)
     _problem.outputStep(EXEC_FAILED);
     return false;
   }
   else
     _fixed_point_status = MooseFixedPointConvergenceReason::CONVERGED_NONLINEAR;
 
   // Use the fixed point algorithm if the conditions (availability of values, etc) are met
   if (_transformed_vars.size() > 0 && useFixedPointAlgorithmUpdateInsteadOfPicard(true))
     transformVariables(transformed_dofs, true);
 
   if (_problem.haveXFEM() && (_xfem_update_count < _max_xfem_update) && _problem.updateMeshXFEM())
   {
     _console << "\nXFEM modified mesh, repeating step" << std::endl;
     _xfem_repeat_step = true;
     ++_xfem_update_count;
   }
   else
   {
     if (_problem.haveXFEM())
     {
       _xfem_repeat_step = false;
       _xfem_update_count = 0;
       _console << "\nXFEM did not modify mesh, continuing" << std::endl;
     }
 
     _problem.onTimestepEnd();
     _problem.execute(EXEC_TIMESTEP_END);
 
     _problem.execTransfers(EXEC_TIMESTEP_END);
     if (!_problem.execMultiApps(EXEC_TIMESTEP_END, auto_advance))
     {
       _fixed_point_status = MooseFixedPointConvergenceReason::DIVERGED_FAILED_MULTIAPP;
       return false;
     }
   }
 
   if (_fail_step)
   {
     _fail_step = false;
     return false;
   }
 
   _executioner.postSolve();
 
   return true;
 }

◆ timedSectionName()

std::string PerfGraphInterface::timedSectionName ( const std::string & section_name ) const

protectedinherited

Returns: The name of the timed section with the name section_name.

Optionally adds a prefix if one is defined.

Definition at line 47 of file PerfGraphInterface.C.

Referenced by PerfGraphInterface::registerTimedSection().

 {
   return _prefix.empty() ? "" : (_prefix + "::") + section_name;
 }

◆ transformPostprocessors()

virtual void FixedPointSolve::transformPostprocessors ( const bool primary )

protectedpure virtual

Use the fixed point algorithm to transform the postprocessors.

If this routine is not called, the next value of the postprocessors will just be from the unrelaxed Picard fixed point algorithm.

Parameters

primary Whether this routine is to save the variables for the primary transformed quantities (as main app) or the secondary ones (as a subapp)

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by solveStep().

◆ transformVariables()

virtual void FixedPointSolve::transformVariables	(	const std::set< dof_id_type > &	transformed_dofs,
		const bool	primary
	)

protectedpure virtual

Use the fixed point algorithm to transform the variables.

If this routine is not called, the next value of the variables will just be from the unrelaxed Picard fixed point algorithm.

Parameters

transformed_dofs	The dofs that will be affected by the algorithm
primary	Whether this routine is to save the variables for the primary transformed quantities (as main app) or the secondary ones (as a subapp)

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by solve(), and solveStep().

◆ type()

const std::string& MooseBase::type ( ) const

inlineinherited

Get the type of this class.

Returns: the name of the type of this class

Definition at line 89 of file MooseBase.h.

   {
     mooseAssert(_type.size(), "Empty type");
     return _type;
   }

◆ typeAndName()

std::string MooseBase::typeAndName ( ) const

inherited

Get the class's combined type and name; useful in error handling.

Returns: The type and name of this class in the form '<type()> "<name()>"'.

Definition at line 54 of file MooseBase.C.

Referenced by FEProblemBase::addPostprocessor(), MaterialPropertyStorage::addProperty(), FEProblemBase::addReporter(), FEProblemBase::addVectorPostprocessor(), MeshGeneratorSystem::dataDrivenError(), ReporterContext< std::vector< T > >::finalize(), and ReporterData::getReporterInfo().

 {
   return type() + std::string(" \"") + name() + std::string("\"");
 }

◆ uniqueName()

MooseObjectName MooseBase::uniqueName ( ) const

inherited

Returns: The unique name for accessing input parameters of this object in the InputParameterWarehouse

Definition at line 66 of file MooseBase.C.

Referenced by MooseBase::connectControllableParams(), and Action::uniqueActionName().

 {
   if (!_pars.have_parameter<std::string>(unique_name_param))
     mooseError("uniqueName(): Object does not have a unique name");
   return MooseObjectName(_pars.get<std::string>(unique_name_param));
 }

◆ uniqueParameterName()

MooseObjectParameterName MooseBase::uniqueParameterName ( const std::string & parameter_name ) const

inherited

Returns: The unique parameter name of a valid parameter of this object for accessing parameter controls

Definition at line 60 of file MooseBase.C.

 {
   return MooseObjectParameterName(getBase(), name(), parameter_name);
 }

◆ useFixedPointAlgorithmUpdateInsteadOfPicard()

virtual bool FixedPointSolve::useFixedPointAlgorithmUpdateInsteadOfPicard ( const bool primary )

protectedpure virtual

Use the fixed point algorithm transform instead of simply using the Picard update This routine can be used to alternate Picard iterations and fixed point algorithm updates based on the values of the variables before and after a solve / a Picard iteration.

Parameters

primary Whether this routine is used for the primary transformed quantities (as main app) or the secondary ones (as a subapp)

Implemented in PicardSolve, SteffensenSolve, and SecantSolve.

Referenced by solve(), and solveStep().

◆ validParams()

InputParameters FixedPointSolve::validParams ( )

static

Definition at line 94 of file FixedPointSolve.C.

Referenced by SecantSolve::validParams(), SteffensenSolve::validParams(), PicardSolve::validParams(), and Executioner::validParams().

 {
   InputParameters params = emptyInputParameters();
   params += FixedPointSolve::fixedPointDefaultConvergenceParams();
 
   params.addParam<ConvergenceName>(
       "multiapp_fixed_point_convergence",
       "Name of the Convergence object to use to assess convergence of the "
       "MultiApp fixed point solve. If not provided, a default Convergence "
       "will be constructed internally from the executioner parameters.");
 
   // Parameters for relaxing the fixed point process
   params.addRangeCheckedParam<Real>("relaxation_factor",
                                     1.0,
                                     "relaxation_factor>0 & relaxation_factor<2",
                                     "Fraction of newly computed value to keep."
                                     "Set between 0 and 2.");
   params.addParam<std::vector<std::string>>(
       "transformed_variables",
       std::vector<std::string>(),
       "List of main app variables to transform during fixed point iterations");
   params.addParam<std::vector<PostprocessorName>>(
       "transformed_postprocessors",
       std::vector<PostprocessorName>(),
       "List of main app postprocessors to transform during fixed point iterations");
   params.addDeprecatedParam<std::vector<std::string>>(
       "relaxed_variables",
       std::vector<std::string>(),
       "List of main app variables to relax during fixed point iterations",
       "Relaxed variables is deprecated, use transformed_variables instead.");
 
   params.addParam<bool>("auto_advance",
                         "Whether to automatically advance sub-applications regardless of whether "
                         "their solve converges, for transient executioners only.");
 
   params.addParamNamesToGroup(
       "multiapp_fixed_point_convergence "
       "relaxation_factor transformed_variables transformed_postprocessors auto_advance",
       "Fixed point iterations");
 
   params.addParam<unsigned int>(
       "max_xfem_update",
       std::numeric_limits<unsigned int>::max(),
       "Maximum number of times to update XFEM crack topology in a step due to evolving cracks");
   params.addParam<bool>("update_xfem_at_timestep_begin",
                         false,
                         "Should XFEM update the mesh at the beginning of the timestep");
 
   params.addParamNamesToGroup("max_xfem_update update_xfem_at_timestep_begin",
                               "XFEM fixed point iterations");
 
   return params;
 }

◆ XFEMRepeatStep()

bool FixedPointSolve::XFEMRepeatStep ( ) const

inline

This function checks the _xfem_repeat_step flag set by solve.

Definition at line 72 of file FixedPointSolve.h.

72 { return _xfem_repeat_step; }

FixedPointSolve::_xfem_repeat_step

bool _xfem_repeat_step

Whether step should be repeated due to xfem modifying the mesh.

Definition: FixedPointSolve.h:239

Member Data Documentation

◆ _action_factory

ActionFactory& ParallelParamObject::_action_factory

protectedinherited

Builds Actions.

Definition at line 40 of file ParallelParamObject.h.

Referenced by AddActionComponentAction::act(), CreateMeshSetupActionsForComponents::act(), ActionComponent::checkRequiredTasks(), PhysicsBase::checkRequiredTasks(), CommonOutputAction::create(), AddVariableAction::createInitialConditionAction(), DynamicObjectRegistrationAction::DynamicObjectRegistrationAction(), CreateExecutionerAction::setupAutoPreconditioning(), and ReadExecutorParamsAction::setupAutoPreconditioning().

◆ _app

MooseApp& MooseBase::_app

protectedinherited

The MOOSE application this is associated with.

Definition at line 353 of file MooseBase.h.

◆ _auto_advance_set_by_user

const bool FixedPointSolve::_auto_advance_set_by_user

private

Whether the user has set the auto_advance parameter for handling advancement of sub-applications in multi-app contexts.

Definition at line 249 of file FixedPointSolve.h.

Referenced by autoAdvance().

◆ _auto_advance_user_value

const bool FixedPointSolve::_auto_advance_user_value

private

The value of auto_advance set by the user for handling advancement of sub-applications in multi-app contexts.

Definition at line 253 of file FixedPointSolve.h.

Referenced by autoAdvance().

◆ _aux

AuxiliarySystem& SolveObject::_aux

protectedinherited

Reference to auxiliary system for faster access.

Definition at line 57 of file SolveObject.h.

Referenced by solveStep().

◆ _console

const ConsoleStream ConsoleStreamInterface::_console

inherited

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

Definition at line 31 of file ConsoleStreamInterface.h.

◆ _displaced_mesh

MooseMesh* SolveObject::_displaced_mesh

protectedinherited

Displaced mesh.

Definition at line 53 of file SolveObject.h.

const unsigned int FixedPointSolve::_max_xfem_update

private

Maximum number of xfem updates per step.

Definition at line 232 of file FixedPointSolve.h.

Referenced by solveStep().

◆ _mesh

MooseMesh& SolveObject::_mesh

protectedinherited

Mesh.

Definition at line 51 of file SolveObject.h.

◆ _name

const std::string& MooseBase::_name

protectedinherited

The name of this class.

Definition at line 359 of file MooseBase.h.

◆ _old_entering_time

Real FixedPointSolve::_old_entering_time

private

Time of previous fixed point solve as a subapp.

Definition at line 242 of file FixedPointSolve.h.

Referenced by solve(), and solveStep().

◆ _pars

const InputParameters& MooseBase::_pars

protectedinherited

The object's parameters.

Definition at line 362 of file MooseBase.h.

Referenced by AddFVICAction::act(), AddICAction::act(), CreateProblemAction::act(), CreateProblemDefaultAction::act(), SetupMeshAction::act(), ComposeTimeStepperAction::act(), SetupDebugAction::act(), AddAuxKernelAction::act(), AddPeriodicBCAction::act(), CommonOutputAction::act(), FunctorMaterial::addFunctorPropertyByBlocks(), BreakMeshByBlockGeneratorBase::BreakMeshByBlockGeneratorBase(), PiecewiseTabularBase::buildFromFile(), PNGOutput::calculateRescalingValues(), MooseBase::callMooseError(), MooseBase::connectControllableParams(), Console::Console(), MooseApp::copyInputs(), MaterialBase::declareADProperty(), MaterialBase::declareProperty(), FEProblemSolve::FEProblemSolve(), FunctionMaterialBase< is_ad >::FunctionMaterialBase(), FileMeshGenerator::generate(), MooseBase::getBase(), MooseBase::getCheckedPointerParam(), MaterialBase::getGenericZeroMaterialProperty(), MooseBase::getHitNode(), MeshGenerator::getMeshGeneratorNameFromParam(), MeshGenerator::getMeshGeneratorNamesFromParam(), MooseBase::getParam(), MooseBase::hasBase(), MeshGenerator::hasGenerateData(), AddVariableAction::init(), AdvancedOutput::initExecutionTypes(), Console::initialSetup(), MooseBase::isParamSetByUser(), MooseBase::isParamValid(), MultiApp::keepSolutionDuringRestore(), MooseBase::messagePrefix(), MooseBase::MooseBase(), MooseApp::outputMachineReadableData(), MooseBase::paramError(), GlobalParamsAction::parameters(), MooseBase::parameters(), MooseBase::paramInfo(), MooseBase::paramWarning(), MooseMesh::prepare(), Eigenvalue::prepareSolverOptions(), MooseMesh::setCoordSystem(), MooseMesh::setPartitionerHelper(), SetupMeshAction::setupMesh(), TransientBase::setupTimeIntegrator(), MooseApp::showInputs(), and MooseBase::uniqueName().

◆ _pg_moose_app

MooseApp& PerfGraphInterface::_pg_moose_app

protectedinherited

The MooseApp that owns the PerfGraph.

Definition at line 124 of file PerfGraphInterface.h.

Referenced by PerfGraphInterface::perfGraph().

◆ _prefix

const std::string PerfGraphInterface::_prefix

protectedinherited

A prefix to use for all sections.

Definition at line 127 of file PerfGraphInterface.h.

Referenced by PerfGraphInterface::timedSectionName().

◆ _problem

FEProblemBase& SolveObject::_problem

protectedinherited

◆ _relax_factor

const Real FixedPointSolve::_relax_factor

protected

Relaxation factor for fixed point Iteration.

Definition at line 205 of file FixedPointSolve.h.

Referenced by performingRelaxation(), solve(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), PicardSolve::transformPostprocessors(), SecantSolve::transformVariables(), SteffensenSolve::transformVariables(), and PicardSolve::transformVariables().

◆ _secondary_relaxation_factor

Real FixedPointSolve::_secondary_relaxation_factor

protected

Relaxation factor outside of fixed point iteration (used as a subapp)

Definition at line 214 of file FixedPointSolve.h.

Referenced by FixedPointSolve(), performingRelaxation(), setMultiAppRelaxationFactor(), solve(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), PicardSolve::transformPostprocessors(), SecantSolve::transformVariables(), SteffensenSolve::transformVariables(), and PicardSolve::transformVariables().

◆ _secondary_transformed_pps

std::vector<PostprocessorName> FixedPointSolve::_secondary_transformed_pps

protected

Postprocessors to be relaxed outside of fixed point iteration (used as a subapp)

Definition at line 218 of file FixedPointSolve.h.

Referenced by SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), FixedPointSolve(), SecantSolve::savePostprocessorValues(), SteffensenSolve::savePostprocessorValues(), PicardSolve::savePostprocessorValues(), SecantSolve::SecantSolve(), setMultiAppTransformedPostprocessors(), solveStep(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), and PicardSolve::transformPostprocessors().

◆ _secondary_transformed_pps_values

std::vector<std::vector<PostprocessorValue> > FixedPointSolve::_secondary_transformed_pps_values

protected

Previous values of the postprocessors relaxed outside of the fixed point iteration (used as a subapp)

Definition at line 220 of file FixedPointSolve.h.

Referenced by SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), SecantSolve::savePostprocessorValues(), SteffensenSolve::savePostprocessorValues(), PicardSolve::savePostprocessorValues(), SecantSolve::SecantSolve(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), and PicardSolve::transformPostprocessors().

◆ _secondary_transformed_variables

std::vector<std::string> FixedPointSolve::_secondary_transformed_variables

protected

Variables to be relaxed outside of fixed point iteration (used as a subapp)

Definition at line 216 of file FixedPointSolve.h.

Referenced by FixedPointSolve(), setMultiAppTransformedVariables(), and solve().

◆ _solver_sys

SystemBase& SolveObject::_solver_sys

protectedinherited

Reference to a system for creating vectors as needed for the solve, etc.

Definition at line 55 of file SolveObject.h.

Referenced by SecantSolve::allocateStorage(), SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), SecantSolve::saveVariableValues(), SteffensenSolve::saveVariableValues(), PicardSolve::saveVariableValues(), solveStep(), SecantSolve::transformVariables(), SteffensenSolve::transformVariables(), and PicardSolve::transformVariables().

◆ _transformed_pps

const std::vector<PostprocessorName> FixedPointSolve::_transformed_pps

protected

The postprocessors (transferred or not) that are going to be relaxed.

Definition at line 209 of file FixedPointSolve.h.

Referenced by SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), FixedPointSolve(), SecantSolve::savePostprocessorValues(), SteffensenSolve::savePostprocessorValues(), PicardSolve::savePostprocessorValues(), SecantSolve::SecantSolve(), solveStep(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), and PicardSolve::transformPostprocessors().

◆ _transformed_pps_values

std::vector<std::vector<PostprocessorValue> > FixedPointSolve::_transformed_pps_values

protected

Previous values of the relaxed postprocessors.

Definition at line 211 of file FixedPointSolve.h.

Referenced by SteffensenSolve::allocateStorage(), PicardSolve::allocateStorage(), SecantSolve::savePostprocessorValues(), SteffensenSolve::savePostprocessorValues(), PicardSolve::savePostprocessorValues(), SecantSolve::SecantSolve(), SecantSolve::transformPostprocessors(), SteffensenSolve::transformPostprocessors(), and PicardSolve::transformPostprocessors().

◆ _transformed_vars

std::vector<std::string> FixedPointSolve::_transformed_vars

protected

The variables (transferred or not) that are going to be relaxed.

Definition at line 207 of file FixedPointSolve.h.

Referenced by FixedPointSolve(), solve(), and solveStep().

◆ _type

const std::string& MooseBase::_type

protectedinherited

The type of this class.

Definition at line 356 of file MooseBase.h.

Referenced by ExplicitTimeIntegrator::ExplicitTimeIntegrator(), FEProblemSolve::FEProblemSolve(), FillBetweenSidesetsGenerator::generate(), FillBetweenCurvesGenerator::generate(), FillBetweenPointVectorsGenerator::generate(), ExplicitTimeIntegrator::init(), FEProblemBase::init(), MooseBase::MooseBase(), MooseStaticCondensationPreconditioner::MooseStaticCondensationPreconditioner(), PhysicsBasedPreconditioner::PhysicsBasedPreconditioner(), FEProblemBase::solverTypeString(), and MooseBase::type().

◆ _update_xfem_at_timestep_begin

const bool FixedPointSolve::_update_xfem_at_timestep_begin

private

Controls whether xfem should update the mesh at the beginning of the time step.

Definition at line 234 of file FixedPointSolve.h.

Referenced by solveStep().

◆ _xfem_repeat_step

bool FixedPointSolve::_xfem_repeat_step

private

Whether step should be repeated due to xfem modifying the mesh.

Definition at line 239 of file FixedPointSolve.h.

Referenced by solveStep(), and XFEMRepeatStep().

◆ _xfem_update_count

unsigned int FixedPointSolve::_xfem_update_count

private

Counter for number of xfem updates that have been performed in the current step.

Definition at line 237 of file FixedPointSolve.h.

Referenced by solveStep().

◆ app_param

const std::string MooseBase::app_param = "_moose_app"

staticinherited

The name of the parameter that contains the MooseApp.

Definition at line 59 of file MooseBase.h.

Referenced by FEProblemBase::addAnyRedistributers(), MeshGenerator::addMeshSubgenerator(), InputParameters::callMooseError(), ActionFactory::create(), Factory::getValidParams(), ActionFactory::getValidParams(), AutomaticMortarGeneration::initOutput(), SetupMeshAction::modifyParamsForUseSplit(), and MortarNodalGeometryOutput::validParams().

◆ moose_base_param

const std::string MooseBase::moose_base_param = "_moose_base"

staticinherited

The name of the parameter that contains the moose system base.

Definition at line 61 of file MooseBase.h.

Referenced by InputParameters::getBase(), InputParameters::hasBase(), and InputParameters::registerBase().

◆ name_param

const std::string MooseBase::name_param = "_object_name"

staticinherited

The name of the parameter that contains the object name.

Definition at line 55 of file MooseBase.h.

Referenced by InputParameterWarehouse::addInputParameters(), MooseObjectUnitTest::buildObjects(), ActionFactory::create(), AppFactory::create(), InputParameters::getObjectName(), AutomaticMortarGeneration::initOutput(), InputParameters::isMooseBaseObject(), MooseMesh::prepare(), CouplingFunctorCheckAction::validParams(), and MooseBase::validParams().

◆ type_param

const std::string MooseBase::type_param = "_type"

staticinherited

The name of the parameter that contains the object type.

Definition at line 53 of file MooseBase.h.

Referenced by ActionFactory::create(), AppFactory::create(), InputParameters::getObjectType(), Factory::initialize(), InputParameters::isMooseBaseObject(), MooseBase::validParams(), and MortarNodalGeometryOutput::validParams().

◆ unique_name_param

const std::string MooseBase::unique_name_param = "_unique_name"

staticinherited

The name of the parameter that contains the unique object name.

Definition at line 57 of file MooseBase.h.

Referenced by InputParameterWarehouse::addInputParameters(), AppFactory::create(), InputParameterWarehouse::removeInputParameters(), MooseBase::uniqueName(), and MooseBase::validParams().

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

include/executioners/FixedPointSolve.h
src/executioners/FixedPointSolve.C

Public Types

Public Member Functions

Static Public Member Functions

Public Attributes

Static Public Attributes

Protected Member Functions

Protected Attributes

Private Attributes

Detailed Description

Member Typedef Documentation

◆ DataFileParameterType

Member Enumeration Documentation

◆ MooseFixedPointConvergenceReason

Constructor & Destructor Documentation

◆ FixedPointSolve()

◆ ~FixedPointSolve()

Member Function Documentation

◆ addPostprocessorDependencyHelper()

◆ allocateStorage()

◆ autoAdvance()

◆ callMooseError() [1/2]

◆ callMooseError() [2/2]

◆ checkConvergence()

◆ clearFixedPointStatus()

◆ connectControllableParams()

◆ coupledPostprocessors()

◆ enabled()

◆ errorPrefix()

◆ examineFixedPointConvergence()

◆ failStep()

◆ fixedPointDefaultConvergenceParams()

◆ getBase()

◆ getCheckedPointerParam()

◆ getDataFileName()

◆ getDataFileNameByName()

◆ getDataFilePath()

◆ getHitNode()

◆ getMooseApp()

◆ getParam() [1/2]

◆ getParam() [2/2]

◆ getPostprocessorName()

◆ getPostprocessorValue()

◆ getPostprocessorValueByName()

◆ getPostprocessorValueOld()

◆ getPostprocessorValueOldByName()

◆ getPostprocessorValueOlder()

◆ getPostprocessorValueOlderByName()

◆ getRenamedParam()

◆ getSharedPtr() [1/2]

◆ getSharedPtr() [2/2]

◆ hasBase()

◆ hasFixedPointIteration()

◆ hasPostprocessor()

◆ hasPostprocessorByName()

◆ initialSetup()

◆ isDefaultPostprocessorValue()

◆ isParamSetByUser()

◆ isParamValid()

◆ messagePrefix()

◆ mooseDeprecated()

◆ mooseDocumentedError()

◆ mooseError()

◆ mooseErrorNonPrefixed()

◆ mooseInfo()

◆ mooseWarning()

◆ mooseWarningNonPrefixed()

◆ name()

◆ numFixedPointIts()

◆ numPicardIts()

◆ paramError()

◆ parameters()

◆ paramInfo()

◆ paramWarning()

◆ perfGraph()

◆ performingRelaxation()

◆ printFixedPointConvergenceHistory()

◆ printFixedPointConvergenceReason()

◆ queryParam()

◆ registerTimedSection() [1/2]

◆ registerTimedSection() [2/2]