Class MultiblockCoarsenAlgorithm<DIM> encapsulates the AMR communication pattern to coarsen data from a finer level to any coarser level in a multiblock domain. Most often, data is coarsened from the interiors of source patch components on the source patch level into interiors of patch components on the destination level. If the coarsening operators require ghost cells on a source component, then sufficient ghost cell storage must be provided by the source patch data component, and those ghost cells must be filled before calling the data coarsening routines. More...

#include <MultiblockCoarsenAlgorithm.h>

Inheritance diagram for SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >:

[legend]

Public Member Functions
	MultiblockCoarsenAlgorithm (tbox::Pointer< hier::MultiblockPatchHierarchy< DIM > > multiblock, bool fill_coarse_data=false)

virtual	~MultiblockCoarsenAlgorithm ()

void	registerCoarsen (const int dst, const int src, const tbox::Pointer< xfer::CoarsenOperator< DIM > > opcoarsen, const hier::IntVector< DIM > &gcw_to_coarsen=hier::IntVector< DIM >(0))

tbox::Pointer< MultiblockCoarsenSchedule< DIM > >	createSchedule (tbox::Pointer< hier::MultiblockPatchLevel< DIM > > crse_level, tbox::Pointer< hier::MultiblockPatchLevel< DIM > > fine_level, MultiblockCoarsenPatchStrategy< DIM > patch_strategy=((MultiblockCoarsenPatchStrategy< DIM > ) NULL), MultiblockRefinePatchStrategy< DIM > refine_strategy=((MultiblockRefinePatchStrategy< DIM > ) NULL)) const

Private Member Functions
	MultiblockCoarsenAlgorithm (const MultiblockCoarsenAlgorithm< DIM > &)

void	operator= (const MultiblockCoarsenAlgorithm< DIM > &)

Private Attributes
tbox::Pointer< xfer::CoarsenClasses< DIM > >	d_coarsen_classes

tbox::Pointer< hier::MultiblockPatchHierarchy< DIM > >	d_multiblock

bool	d_fill_coarse_data

Detailed Description

template<int DIM>
class SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >

Communication algorithms generally consist of three parts: an algorithm, a schedule, and a patch strategy. The algorithm describes the communication between patch data items but is independent of the configuration of the AMR hierarchy. Patch data items and their associated coarsening operators are registered with the algorithm. To generate the communication dependencies for a particular hierarchy configuration, the algorithm generates a schedule based on the current hierarchy configuration. This schedule then performs the communication based on the registered data types and their associated operators. User-defined pre-processing and post-processing are provided through the abstract patch strategy class. The source patch data space is used during processing to store temporary data. Thus, the user-defined coarsening operators should operate on the source space by using the patch data with those indices.

Note that each coarsen schedule created by a coarsen algorithm remains valid as long as the patches involved in the communication process do not change as long as the patches involved in the communication process do not change; thus, they can be used for multiple data communication cycles.

Typical usage of a coarsen algorithm to perform data coarsening on an AMR hierarchy involves four steps:

Construct a coarsen algorithm object.
Register coarsen operations with the coarsen algorithm. Using the registerCoarsen() methods(s), one provides source and destination patch data information, as well as spatial coarsening operators as needed.
After all operations are registered with the algorithm, one creates a communication schedule using the createSchedule() method. This method identifies the source (fine) and destination (coarse) patch levels for data coarsening. Note that when creating a communication schedule, a concrete instance of a MultiblockCoarsenPatchStrategy<DIM> object may be required to supply user-defined spatial data coarsening operations.
Invoke the coarsenData() method in the communication schedule to perform the data transfers.

See also: xfer::MultiblockCoarsenSchedule; xfer::CoarsenSchedule; xfer::CoarsenPatchStrategy; xfer::CoarsenClasses

Constructor & Destructor Documentation

◆ MultiblockCoarsenAlgorithm() [1/2]

template<int DIM>

SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::MultiblockCoarsenAlgorithm	(	tbox::Pointer< hier::MultiblockPatchHierarchy< DIM > >	multiblock,
		bool	fill_coarse_data = `false`
	)

Construct a coarsening algorithm and initialize its basic state. Coarsening operations must be registered with this algorithm before it can do anything useful. See the registerCoarsen() routine for details

Parameters

multiblock pointer to the multiblock patch hierarchy on which this coarsen algorithm with operate.

fill_coarse_data boolean flag indicating whether coarse level data is needed for the data coarsening operations. By default this argument is false. If a true value is provided, then source data will be filled on a temporary coarse patch level (i.e., copied from the actual coarse level source data) for use in coarsening operations registered with this algorithm. This option should only be used by those who specifically require this behavior and who know how to properly process the patch data on coarse and fine patch levels during the coarsening process.

◆ ~MultiblockCoarsenAlgorithm()

template<int DIM>

virtual SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::~MultiblockCoarsenAlgorithm ( )

virtual

The virtual destructor for the algorithm releases all internal storage.

◆ MultiblockCoarsenAlgorithm() [2/2]

template<int DIM>

SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::MultiblockCoarsenAlgorithm ( const MultiblockCoarsenAlgorithm< DIM > & )

private

Member Function Documentation

◆ registerCoarsen()

template<int DIM>

void SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::registerCoarsen	(	const int	dst,
		const int	src,
		const tbox::Pointer< xfer::CoarsenOperator< DIM > >	opcoarsen,
		const hier::IntVector< DIM > &	gcw_to_coarsen = `hier::IntVector< DIM >(0)`
	)

Register a coarsening operation with the coarsening algorithm. Data from the interiors of the source component on a source (fine) patch level will be coarsened into the source component of a temporary (coarse) patch level and then copied into the destination component on the destination (coarse) patch level. If the coarsening operator requires data in ghost cells outside of the patch interiors (i.e., a non-zero stencil width), then those ghost cells must exist in the source patch data component and the ghost cells must be filled with valid data on the source level before a call to invoke the communication schedule. Note that the source and destination components may be the same in any case.

Some special circumstances require that data be coarsened from the ghost cell regions of a finer level and the resulting coarsened data should be copied to the destination patch level. When this is the case, the optional integer vector argument should be set to the cell width, in the destination (coarser) level index space, of the region around the fine level where this coarsening should occur. For example, if the coarser level needs data in a region two (coarse) cells wide around the boundary of the finer level, then the gcw_to_coarsen should be set to a vector with all entries set to two. Moreover, if the refinement ratio
between coarse and fine levels is four in this case, then the source patch data is required to have at least eight ghost cells.

Parameters

dst	Patch data index filled on destination level.
src	Patch data index coarsened from the source level.
opcoarsen	Pointer to coarsening operator. This may be a null pointer.

In this case, coarsening must be handled by the coarsen patch strategy member functions. See the comments for MultiblockCoarsenPatchStrategy<DIM>::preprocessCoarsen() and MultiblockCoarsenPatchStrategy<DIM>::postprocessCoarsen().

Parameters

gcw_to_coarsen Integer vector ghost cell width when data should be coarsened from ghost cell regions of the source (finer) level into the destination (coarser) level. By default, it is the vector of zeros indicating that data should be coarsened from from patch interiors on the source level. If this argument is used, its value should be the cell width, in the destination (coarser) level index space, of the region around the fine level where this coarsening should occur. This argument should only be provided by those who specifically require this special behavior and know how to properly process the patch data on coarse and fine patch levels during the coarsening process.

◆ createSchedule()

template<int DIM>

tbox::Pointer< MultiblockCoarsenSchedule<DIM> > SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::createSchedule	(	tbox::Pointer< hier::MultiblockPatchLevel< DIM > >	crse_level,
		tbox::Pointer< hier::MultiblockPatchLevel< DIM > >	fine_level,
		MultiblockCoarsenPatchStrategy< DIM > *	patch_strategy = `((MultiblockCoarsenPatchStrategy< DIM > *) NULL)`,
		MultiblockRefinePatchStrategy< DIM > *	refine_strategy = `((MultiblockRefinePatchStrategy< DIM > *) NULL)`
	)		const

Create a communication schedule to coarsen data from finer patch levels. This communication schedule may then be executed to perform the data transfers. This schedule creation procedure assumes that the coarse level represents a ragion of coarser index space than the fine level. To avoid potentially erroneous behavior, the coarse level domain should cover the domain of the fine level.

Neither patch level can be null and when assertion checking is active, passing a null level pointer will produce an unrecoverable exception.

Note that the schedule remains valid as long as the patches on the levels do not change; thus, it can be used for multiple data communication cycles.

Returns: Pointer to coarsen schedule that performs the data transfers.

Parameters

crse_level	Pointer to coarse (destination) level.
fine_level	Pointer to fine (source) level.
patch_strategy	Pointer to a coarsen patch strategy that provides user-defined coarsen operations. If this patch strategy is null (default state), then no user-defined coarsen operations will be performed.
refine_strategy	Pointer to a refine patch strategy that provides user-defined refinement operations for specific cases where a user-defined coarsening scheme requires data to be filled on the coarse level prior to the execution of the coarsening operation. Default is NULL.

◆ operator=()

template<int DIM>

void SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::operator= ( const MultiblockCoarsenAlgorithm< DIM > & )

private

Member Data Documentation

◆ d_coarsen_classes

template<int DIM>

tbox::Pointer< xfer::CoarsenClasses<DIM> > SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::d_coarsen_classes

private

◆ d_multiblock

template<int DIM>

tbox::Pointer< hier::MultiblockPatchHierarchy<DIM> > SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::d_multiblock

private

◆ d_fill_coarse_data

template<int DIM>

bool SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >::d_fill_coarse_data

private

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

/samrai/include/MultiblockCoarsenAlgorithm.h

Public Member Functions

Private Member Functions

Private Attributes

Detailed Description

template<int DIM> class SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >

Constructor & Destructor Documentation

◆ MultiblockCoarsenAlgorithm() [1/2]

◆ ~MultiblockCoarsenAlgorithm()

◆ MultiblockCoarsenAlgorithm() [2/2]

Member Function Documentation

◆ registerCoarsen()

◆ createSchedule()

◆ operator=()

Member Data Documentation

◆ d_coarsen_classes

◆ d_multiblock

◆ d_fill_coarse_data

template<int DIM>
class SAMRAI::xfer::MultiblockCoarsenAlgorithm< DIM >