#include <MaxVarNDofsPerElem.h>

Inheritance diagram for MaxVarNDofsPerElem:

Public Member Functions
	MaxVarNDofsPerElem (FEProblemBase &feproblem, SolverSystem &sys)

	MaxVarNDofsPerElem (MaxVarNDofsPerElem &x, Threads::split split)

virtual	~MaxVarNDofsPerElem ()

virtual void	onElement (const Elem *elem)
	Assembly of the element (not including surface assembly) More...

void	join (const MaxVarNDofsPerElem &)

dof_id_type	max ()

virtual void	caughtMooseException (MooseException &e) override
	Called if a MooseException is caught anywhere during the computation. More...

virtual bool	keepGoing () override
	Whether or not the loop should continue. More...

virtual void	preElement (const Elem *elem) override
	Called before the element assembly. More...

virtual void	preInternalSide (const Elem *elem, unsigned int side) override
	Called before evaluations on an element internal side. More...

virtual void	preBoundary (const Elem elem, unsigned int side, BoundaryID bnd_id, const Elem lower_d_elem=nullptr) override
	Called before the boundary assembly. More...

virtual void	neighborSubdomainChanged () override
	Called every time the neighbor subdomain changes (i.e. More...

virtual void	operator() (const ConstElemRange &range, bool bypass_threading=false)

virtual void	pre ()
	Called before the element range loop. More...

virtual void	post ()
	Called after the element range loop. More...

virtual void	postElement (const Elem *elem)
	Called after the element assembly is done (including surface assembling) More...

virtual void	onBoundary (const Elem elem, unsigned int side, BoundaryID bnd_id, const Elem lower_d_elem=nullptr)
	Called when doing boundary assembling. More...

virtual void	postInternalSide (const Elem *elem, unsigned int side)
	Called after evaluations on an element internal side. More...

virtual void	onInternalSide (const Elem *elem, unsigned int side)
	Called when doing internal edge assembling. More...

virtual void	onExternalSide (const Elem *elem, unsigned int side)
	Called when iterating over external sides (no side neighbor) More...

virtual void	onInterface (const Elem *elem, unsigned int side, BoundaryID bnd_id)
	Called when doing interface assembling. More...

virtual void	subdomainChanged ()
	Called every time the current subdomain changes (i.e. More...

Protected Member Functions
void	prepareElement (const Elem *elem)

void	clearVarsAndMaterials ()

void	printExecutionOrdering (const std::vector< T * > &objs, const bool print_header=true, const std::string &line_prefix="[DBG]") const
	Routine to output the ordering of objects within a vector of pointers to these objects. More...

void	printExecutionOrdering (const std::vector< std::shared_ptr< T >> &objs_ptrs, const bool print_header=true, const std::string &line_prefix="[DBG]") const

virtual void	printGeneralExecutionInformation () const
	Print information about the loop ordering. More...

virtual void	printBlockExecutionInformation () const
	Print information about the particular ordering of objects on each block. More...

virtual void	printBoundaryExecutionInformation (const unsigned int) const
	Print information about the particular ordering of objects on each boundary. More...

void	resetExecPrintedSets () const
	Resets the set of blocks and boundaries visited. More...

virtual bool	shouldComputeInternalSide (const Elem &elem, const Elem &neighbor) const
	Whether to compute the internal side for the provided element-neighbor pair. More...

Protected Attributes
SolverSystem &	_system
	The nonlinear system. More...

size_t	_max
	Maximum number of dofs for any one variable on any one element. More...

const DofMap &	_dof_map
	DOF map. More...

std::vector< dof_id_type >	_dof_indices
	Reusable storage. More...

FEProblemBase &	_fe_problem

MooseMesh &	_mesh

THREAD_ID	_tid

SubdomainID	_subdomain
	The subdomain for the current element. More...

SubdomainID	_old_subdomain
	The subdomain for the last element. More...

SubdomainID	_neighbor_subdomain
	The subdomain for the current neighbor. More...

SubdomainID	_old_neighbor_subdomain
	The subdomain for the last neighbor. More...

std::set< SubdomainID >	_blocks_exec_printed
	Keep track of which blocks were visited. More...

std::set< BoundaryID >	_boundaries_exec_printed
	Keep track of which boundaries were visited. More...

Detailed Description

Definition at line 18 of file MaxVarNDofsPerElem.h.

Constructor & Destructor Documentation

◆ MaxVarNDofsPerElem() [1/2]

MaxVarNDofsPerElem::MaxVarNDofsPerElem	(	FEProblemBase &	feproblem,
		SolverSystem &	sys
	)

Definition at line 18 of file MaxVarNDofsPerElem.C.

   : ThreadedElementLoop<ConstElemRange>(feproblem),
     _system(sys),
     _max(0),
     _dof_map(_system.dofMap())
 {
 }

◆ MaxVarNDofsPerElem() [2/2]

MaxVarNDofsPerElem::MaxVarNDofsPerElem	(	MaxVarNDofsPerElem &	x,
		Threads::split	split
	)

Definition at line 27 of file MaxVarNDofsPerElem.C.

   : ThreadedElementLoop<ConstElemRange>(x, split), _system(x._system), _max(0), _dof_map(x._dof_map)
 {
 }

◆ ~MaxVarNDofsPerElem()

MaxVarNDofsPerElem::~MaxVarNDofsPerElem ( )

virtual

Definition at line 32 of file MaxVarNDofsPerElem.C.

32 {}

Member Function Documentation

◆ caughtMooseException()

void ThreadedElementLoop< ConstElemRange >::caughtMooseException ( MooseException & e )

overridevirtualinherited

Called if a MooseException is caught anywhere during the computation.

The single input parameter taken is a MooseException object.

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 105 of file ThreadedElementLoop.h.

Referenced by ComputeJacobianForScalingThread::operator()().

 {
   Threads::spin_mutex::scoped_lock lock(threaded_element_mutex);
 
   std::string what(e.what());
   _fe_problem.setException(what);
 }

◆ clearVarsAndMaterials()

void ThreadedElementLoop< ConstElemRange >::clearVarsAndMaterials ( )

protectedinherited

Definition at line 195 of file ThreadedElementLoop.h.

Referenced by NonlinearThread::post().

 {
   _fe_problem.clearActiveElementalMooseVariables(this->_tid);
   _fe_problem.clearActiveMaterialProperties(this->_tid);
 }

◆ join()

void MaxVarNDofsPerElem::join ( const MaxVarNDofsPerElem & y )

Definition at line 46 of file MaxVarNDofsPerElem.C.

 {
   _max = std::max(_max, y._max);
 }

◆ keepGoing()

virtual bool ThreadedElementLoop< ConstElemRange >::keepGoing ( )

inlineoverridevirtualinherited

Whether or not the loop should continue.

Returns: true to keep going, false to stop.

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 45 of file ThreadedElementLoop.h.

Referenced by ComputeJacobianForScalingThread::operator()().

45 { return !_fe_problem.hasException(); }

ThreadedElementLoop< ConstElemRange >::_fe_problem

FEProblemBase & _fe_problem

Definition: ThreadedElementLoop.h:62

FEProblemBase::hasException

virtual bool hasException()

Whether or not an exception has occurred.

Definition: FEProblemBase.h:508

◆ max()

dof_id_type MaxVarNDofsPerElem::max ( )

inline

Definition at line 32 of file MaxVarNDofsPerElem.h.

Referenced by FEProblemBase::initialSetup().

32 { return _max; }

MaxVarNDofsPerElem::_max

size_t _max

Maximum number of dofs for any one variable on any one element.

Definition: MaxVarNDofsPerElem.h:39

◆ neighborSubdomainChanged()

void ThreadedElementLoop< ConstElemRange >::neighborSubdomainChanged ( )

overridevirtualinherited

Called every time the neighbor subdomain changes (i.e.

the subdomain of this neighbor is not the same as the subdomain of the last neighbor). Beware of over-using this! You might think that you can do some expensive stuff in here and get away with it... but there are applications that have TONS of subdomains....

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 139 of file ThreadedElementLoop.h.

 {
   _fe_problem.neighborSubdomainSetup(ThreadedElementLoopBase<RangeType>::_neighbor_subdomain,
                                      ThreadedElementLoopBase<RangeType>::_tid);
 }

◆ onBoundary()

void ThreadedElementLoopBase< ConstElemRange >::onBoundary	(	const Elem *	elem,
		unsigned int	side,
		BoundaryID	bnd_id,
		const Elem *	lower_d_elem = `nullptr`
	)

virtualinherited

Called when doing boundary assembling.

Parameters

elem	- The element we are checking is on the boundary.
side	- The side of the element in question.
bnd_id	- ID of the boundary we are at
lower_d_elem	- Lower dimensional element (e.g. Mortar)

Reimplemented in ComputeUserObjectsThread, NonlinearThread, ComputeIndicatorThread, ComputeMaterialsObjectThread, and ComputeMarkerThread.

Definition at line 376 of file ThreadedElementLoopBase.h.

380 {

381 }

◆ onElement()

void MaxVarNDofsPerElem::onElement ( const Elem * elem )

virtual

Assembly of the element (not including surface assembly)

Parameters

elem	- active element

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 35 of file MaxVarNDofsPerElem.C.

 {
   for (unsigned int var = 0; var < _system.nVariables(); var++)
   {
     _dof_map.dof_indices(elem, _dof_indices, var);
 
     _max = std::max(_max, _dof_indices.size());
   }
 }

◆ onExternalSide()

void ThreadedElementLoopBase< ConstElemRange >::onExternalSide	(	const Elem *	elem,
		unsigned int	side
	)

virtualinherited

Called when iterating over external sides (no side neighbor)

Parameters

elem	- Element we are on
side	- local side number of the element 'elem'

Reimplemented in ComputeUserObjectsThread.

Definition at line 403 of file ThreadedElementLoopBase.h.

404 {

405 }

◆ onInterface()

void ThreadedElementLoopBase< ConstElemRange >::onInterface	(	const Elem *	elem,
		unsigned int	side,
		BoundaryID	bnd_id
	)

virtualinherited

Called when doing interface assembling.

Parameters

elem	- Element we are on
side	- local side number of the element 'elem'
bnd_id	- ID of the interface we are at

Reimplemented in ComputeUserObjectsThread, NonlinearThread, and ComputeMaterialsObjectThread.

Definition at line 409 of file ThreadedElementLoopBase.h.

412 {

413 }

◆ onInternalSide()

void ThreadedElementLoopBase< ConstElemRange >::onInternalSide	(	const Elem *	elem,
		unsigned int	side
	)

virtualinherited

Called when doing internal edge assembling.

Parameters

elem	- Element we are on
side	- local side number of the element 'elem'

Reimplemented in ComputeUserObjectsThread, NonlinearThread, ComputeIndicatorThread, ComputeMaterialsObjectThread, and ComputeMarkerThread.

Definition at line 397 of file ThreadedElementLoopBase.h.

398 {

399 }

◆ operator()()

void ThreadedElementLoopBase< ConstElemRange >::operator()	(	const ConstElemRange &	range,
		bool	bypass_threading = `false`
	)

virtualinherited

Reimplemented in NonlinearThread, and ComputeJacobianForScalingThread.

Definition at line 226 of file ThreadedElementLoopBase.h.

 {
   try
   {
     try
     {
       ParallelUniqueId puid;
       _tid = bypass_threading ? 0 : puid.id;
 
       pre();
       printGeneralExecutionInformation();
 
       _subdomain = Moose::INVALID_BLOCK_ID;
       _neighbor_subdomain = Moose::INVALID_BLOCK_ID;
       typename RangeType::const_iterator el = range.begin();
       for (el = range.begin(); el != range.end(); ++el)
       {
         if (!keepGoing())
           break;
 
         const Elem * elem = *el;
 
         preElement(elem);
 
         _old_subdomain = _subdomain;
         _subdomain = elem->subdomain_id();
         if (_subdomain != _old_subdomain)
         {
           subdomainChanged();
           printBlockExecutionInformation();
         }
 
         onElement(elem);
 
         if (_mesh.interiorLowerDBlocks().count(elem->subdomain_id()) > 0 ||
             _mesh.boundaryLowerDBlocks().count(elem->subdomain_id()) > 0)
         {
           postElement(elem);
           continue;
         }
 
         for (unsigned int side = 0; side < elem->n_sides(); side++)
         {
           std::vector<BoundaryID> boundary_ids = _mesh.getBoundaryIDs(elem, side);
           const Elem * lower_d_elem = _mesh.getLowerDElem(elem, side);
 
           if (boundary_ids.size() > 0)
             for (std::vector<BoundaryID>::iterator it = boundary_ids.begin();
                  it != boundary_ids.end();
                  ++it)
             {
               preBoundary(elem, side, *it, lower_d_elem);
               printBoundaryExecutionInformation(*it);
               onBoundary(elem, side, *it, lower_d_elem);
             }
 
           const Elem * neighbor = elem->neighbor_ptr(side);
           if (neighbor)
           {
             preInternalSide(elem, side);
 
             _old_neighbor_subdomain = _neighbor_subdomain;
             _neighbor_subdomain = neighbor->subdomain_id();
             if (_neighbor_subdomain != _old_neighbor_subdomain)
               neighborSubdomainChanged();
 
             if (shouldComputeInternalSide(*elem, *neighbor))
               onInternalSide(elem, side);
 
             if (boundary_ids.size() > 0)
               for (std::vector<BoundaryID>::iterator it = boundary_ids.begin();
                    it != boundary_ids.end();
                    ++it)
                 onInterface(elem, side, *it);
 
             postInternalSide(elem, side);
           }
           else
             onExternalSide(elem, side);
         } // sides
 
         postElement(elem);
       } // range
 
       post();
       resetExecPrintedSets();
     }
     catch (MetaPhysicL::LogicError & e)
     {
       moose::translateMetaPhysicLError(e);
     }
     catch (std::exception & e)
     {
       // Continue if we find a libMesh degenerate map exception, but
       // just re-throw for any real error
       if (!strstr(e.what(), "Jacobian") && !strstr(e.what(), "singular") &&
           !strstr(e.what(), "det != 0"))
         throw; // not "throw e;" - that destroys type info!
 
       mooseException("We caught a libMesh degeneracy exception in ThreadedElementLoopBase:\n",
                      e.what());
     }
   }
   catch (MooseException & e)
   {
     caughtMooseException(e);
   }
 }

◆ post()

void ThreadedElementLoopBase< ConstElemRange >::post ( )

virtualinherited

Called after the element range loop.

Reimplemented in ComputeUserObjectsThread, NonlinearThread, ComputeIndicatorThread, ComputeElemAuxVarsThread< AuxKernelType >, ComputeMarkerThread, and ComputeMaterialsObjectThread.

Definition at line 343 of file ThreadedElementLoopBase.h.

344 {

345 }

◆ postElement()

void ThreadedElementLoopBase< ConstElemRange >::postElement ( const Elem * elem )

virtualinherited

Called after the element assembly is done (including surface assembling)

Parameters

elem	- active element

Reimplemented in ComputeJacobianBlocksThread, NonlinearThread, ComputeIndicatorThread, ComputeJacobianThread, and ComputeMarkerThread.

Definition at line 361 of file ThreadedElementLoopBase.h.

362 {

363 }

◆ postInternalSide()

void ThreadedElementLoopBase< ConstElemRange >::postInternalSide	(	const Elem *	elem,
		unsigned int	side
	)

virtualinherited

Called after evaluations on an element internal side.

Parameters

elem	- Element we are on
side	- local side number of the element 'elem'

Reimplemented in ComputeJacobianBlocksThread.

Definition at line 391 of file ThreadedElementLoopBase.h.

392 {

393 }

◆ pre()

void ThreadedElementLoopBase< ConstElemRange >::pre ( )

virtualinherited

Called before the element range loop.

Definition at line 337 of file ThreadedElementLoopBase.h.

Referenced by ComputeJacobianForScalingThread::operator()().

338 {

339 }

◆ preBoundary()

void ThreadedElementLoop< ConstElemRange >::preBoundary	(	const Elem *	elem,
		unsigned int	side,
		BoundaryID	bnd_id,
		const Elem *	lower_d_elem = `nullptr`
	)

overridevirtualinherited

Called before the boundary assembly.

Parameters

elem	- The element we are checking is on the boundary.
side	- The side of the element in question.
bnd_id	- ID of the boundary we are at
lower_d_elem	- Lower dimensional element (e.g. Mortar)

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 129 of file ThreadedElementLoop.h.

 {
   _fe_problem.setCurrentBoundaryID(bnd_id, ThreadedElementLoopBase<RangeType>::_tid);
 }

◆ preElement()

void ThreadedElementLoop< ConstElemRange >::preElement ( const Elem * elem )

overridevirtualinherited

Called before the element assembly.

Parameters

elem	- active element

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 115 of file ThreadedElementLoop.h.

Referenced by ComputeJacobianForScalingThread::operator()().

 {
   _fe_problem.setCurrentSubdomainID(el, ThreadedElementLoopBase<RangeType>::_tid);
 }

◆ preInternalSide()

void ThreadedElementLoop< ConstElemRange >::preInternalSide	(	const Elem *	elem,
		unsigned int	side
	)

overridevirtualinherited

Called before evaluations on an element internal side.

Parameters

elem	- Element we are on
side	- local side number of the element 'elem'

Reimplemented from ThreadedElementLoopBase< ConstElemRange >.

Definition at line 122 of file ThreadedElementLoop.h.

 {
   _fe_problem.setNeighborSubdomainID(el, side, ThreadedElementLoopBase<RangeType>::_tid);
 }

◆ prepareElement()

void ThreadedElementLoop< ConstElemRange >::prepareElement ( const Elem * elem )

protectedinherited

Definition at line 186 of file ThreadedElementLoop.h.

Referenced by NonlinearThread::onElement().

 {
   _fe_problem.prepare(elem, this->_tid);
   _fe_problem.reinitElem(elem, this->_tid);
   _fe_problem.reinitMaterials(this->_subdomain, this->_tid);
 }

◆ printBlockExecutionInformation()

virtual void ThreadedElementLoopBase< ConstElemRange >::printBlockExecutionInformation ( ) const

inlineprotectedvirtualinherited

Print information about the particular ordering of objects on each block.

Reimplemented in NonlinearThread, ComputeUserObjectsThread, ComputeIndicatorThread, ComputeElemAuxVarsThread< AuxKernelType >, and ComputeMarkerThread.

Definition at line 184 of file ThreadedElementLoopBase.h.

184 {}

◆ printBoundaryExecutionInformation()

virtual void ThreadedElementLoopBase< ConstElemRange >::printBoundaryExecutionInformation ( const unsigned int ) const

inlineprotectedvirtualinherited

Print information about the particular ordering of objects on each boundary.

Reimplemented in NonlinearThread.

Definition at line 187 of file ThreadedElementLoopBase.h.

187 {}

◆ printExecutionOrdering() [1/2]

void ThreadedElementLoop< ConstElemRange >::printExecutionOrdering	(	const std::vector< T *> &	objs,
		const bool	print_header = `true`,
		const std::string &	line_prefix = `"[DBG]"`
	)		const

protectedinherited

Routine to output the ordering of objects within a vector of pointers to these objects.

These objects must implement the name() routine, and it must return a string or compatible type.

Template Parameters

T	the object type

Parameters

objs	the vector with all the objects (should be pointers)
objects_type	the name of the type of objects. Defaults to the CPP object name
print_header	whether to print a header about the timing of execution and the type of objects

Definition at line 148 of file ThreadedElementLoop.h.

 {
   if (!objs.size())
     return;
 
   auto & console = _fe_problem.console();
   const auto objects_type = MooseUtils::prettyCppType(objs[0]);
   std::vector<MooseObject *> moose_objs;
   for (auto obj_ptr : objs)
     moose_objs.push_back(dynamic_cast<MooseObject *>(obj_ptr));
   const auto names = ConsoleUtils::mooseObjectVectorToString(moose_objs);
 
   // Print string with a DBG prefix and with sufficient line breaks
   std::string message = print_header ? "Executing " + objects_type + " on " +
                                            _fe_problem.getCurrentExecuteOnFlag().name() + "\n"
                                      : "";
   message += (print_header ? "Order of execution:\n" : "") + names;
   console << ConsoleUtils::formatString(message, line_prefix) << std::endl;
 }

◆ printExecutionOrdering() [2/2]

void ThreadedElementLoop< ConstElemRange >::printExecutionOrdering	(	const std::vector< std::shared_ptr< T >> &	objs_ptrs,
		const bool	print_header = `true`,
		const std::string &	line_prefix = `"[DBG]"`
	)		const

protectedinherited

Definition at line 173 of file ThreadedElementLoop.h.

 {
   std::vector<T *> regular_ptrs;
   for (auto shared_ptr : objs_ptrs)
     regular_ptrs.push_back(shared_ptr.get());
   printExecutionOrdering<T>(regular_ptrs, print_header, line_prefix);
 }

◆ printGeneralExecutionInformation()

virtual void ThreadedElementLoopBase< ConstElemRange >::printGeneralExecutionInformation ( ) const

inlineprotectedvirtualinherited

Print information about the loop ordering.

Reimplemented in NonlinearThread, ComputeUserObjectsThread, ComputeIndicatorThread, ComputeElemAuxVarsThread< AuxKernelType >, ComputeMarkerThread, and ComputeElemDampingThread.

Definition at line 181 of file ThreadedElementLoopBase.h.

181 {}

◆ resetExecPrintedSets()

void ThreadedElementLoopBase< ConstElemRange >::resetExecPrintedSets ( ) const

protectedinherited

Resets the set of blocks and boundaries visited.

Definition at line 454 of file ThreadedElementLoopBase.h.

 {
   _blocks_exec_printed.clear();
   _boundaries_exec_printed.clear();
 }

◆ shouldComputeInternalSide()

bool ThreadedElementLoopBase< ConstElemRange >::shouldComputeInternalSide	(	const Elem &	elem,
		const Elem &	neighbor
	)		const

protectedvirtualinherited

Whether to compute the internal side for the provided element-neighbor pair.

Typically this will return true if the element id is less than the neighbor id when the elements are equal level, or when the element is more refined than the neighbor, and then false otherwise. One type of loop where the logic will be different is when projecting stateful material properties

Reimplemented in NonlinearThread, and FlagElementsThread.

Definition at line 429 of file ThreadedElementLoopBase.h.

 {
   auto level = [this](const auto & elem_arg)
   {
     if (_mesh.doingPRefinement())
       return elem_arg.p_level();
     else
       return elem_arg.level();
   };
   const auto elem_id = elem.id(), neighbor_id = neighbor.id();
   const auto elem_level = level(elem), neighbor_level = level(neighbor);
 
   // When looping over elements and then sides, we need to make sure that we do not duplicate
   // effort, e.g. if a face is shared by element 1 and element 2, then we do not want to do compute
   // work both when we are visiting element 1 *and* then later when visiting element 2. Our rule is
   // to only compute when we are visiting the element that has the lower element id when element and
   // neighbor are of the same adaptivity level, and then if they are not of the same level, then
   // we only compute when we are visiting the finer element
   return (neighbor.active() && (neighbor_level == elem_level) && (elem_id < neighbor_id)) ||
          (neighbor_level < elem_level);
 }

◆ subdomainChanged()

void ThreadedElementLoopBase< ConstElemRange >::subdomainChanged ( )

virtualinherited

Called every time the current subdomain changes (i.e.

the subdomain of this element is not the same as the subdomain of the last element). Beware of over-using this! You might think that you can do some expensive stuff in here and get away with it... but there are applications that have TONS of subdomains....

Reimplemented in ComputeUserObjectsThread, NonlinearThread, ComputeIndicatorThread, ComputeMaterialsObjectThread, ComputeElemAuxVarsThread< AuxKernelType >, and ComputeMarkerThread.

Definition at line 417 of file ThreadedElementLoopBase.h.

418 {

419 }