Intrepid2
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Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions > Class Template Reference

Basis defining integrated Legendre basis on the line, a polynomial subspace of H(grad) on the line. More...

#include <Intrepid2_IntegratedLegendreBasis_HGRAD_TET.hpp>

Inheritance diagram for Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >:
Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >

Public Types

using BasisBase = Basis< DeviceType, OutputScalar, PointScalar >
 
using OrdinalTypeArray1DHost = Kokkos::View< ordinal_type *, typename ExecutionSpace::array_layout, Kokkos::HostSpace >
 View type for 1d host array.
 
using OrdinalTypeArray2DHost = Kokkos::View< ordinal_type **, typename ExecutionSpace::array_layout, Kokkos::HostSpace >
 View type for 2d host array.
 
using OutputViewType = Kokkos::DynRankView< OutputValueType, Kokkos::LayoutStride, DeviceType >
 View type for basis value output.
 
using PointViewType = Kokkos::DynRankView< PointValueType, Kokkos::LayoutStride, DeviceType >
 View type for input points.
 
using ScalarViewType = Kokkos::DynRankView< scalarType, Kokkos::LayoutStride, DeviceType >
 View type for scalars.
 
using ExecutionSpace = typename DeviceType::execution_space
 (Kokkos) Execution space for basis.
 
- Public Types inherited from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >
using DeviceType = Device
 (Kokkos) Device type on which Basis is templated. Does not necessarily return true for Kokkos::is_device (may be Kokkos::Serial, for example).
 
using ExecutionSpace = typename DeviceType::execution_space
 (Kokkos) Execution space for basis.
 
using OutputValueType = outputValueType
 Output value type for basis; default is double.
 
using PointValueType = pointValueType
 Point value type for basis; default is double.
 
using OrdinalViewType = Kokkos::View< ordinal_type, DeviceType >
 View type for ordinal.
 
using EBasisViewType = Kokkos::View< EBasis, DeviceType >
 View for basis type.
 
using ECoordinatesViewType = Kokkos::View< ECoordinates, DeviceType >
 View for coordinate system type.
 
using OrdinalTypeArray1DHost = Kokkos::View< ordinal_type *, typename ExecutionSpace::array_layout, Kokkos::HostSpace >
 View type for 1d host array.
 
using OrdinalTypeArray2DHost = Kokkos::View< ordinal_type **, typename ExecutionSpace::array_layout, Kokkos::HostSpace >
 View type for 2d host array.
 
using OrdinalTypeArray3DHost = Kokkos::View< ordinal_type ***, typename ExecutionSpace::array_layout, Kokkos::HostSpace >
 View type for 3d host array.
 
using OrdinalTypeArrayStride1DHost = Kokkos::View< ordinal_type *, Kokkos::LayoutStride, Kokkos::HostSpace >
 View type for 1d host array.
 
using OrdinalTypeArray1D = Kokkos::View< ordinal_type *, DeviceType >
 View type for 1d device array.
 
using OrdinalTypeArray2D = Kokkos::View< ordinal_type **, DeviceType >
 View type for 2d device array.
 
using OrdinalTypeArray3D = Kokkos::View< ordinal_type ***, DeviceType >
 View type for 3d device array.
 
using OrdinalTypeArrayStride1D = Kokkos::View< ordinal_type *, Kokkos::LayoutStride, DeviceType >
 View type for 1d device array.
 
typedef ScalarTraits
< pointValueType >
::scalar_type 
scalarType
 Scalar type for point values.
 
using OutputViewType = Kokkos::DynRankView< OutputValueType, Kokkos::LayoutStride, DeviceType >
 View type for basis value output.
 
using PointViewType = Kokkos::DynRankView< PointValueType, Kokkos::LayoutStride, DeviceType >
 View type for input points.
 
using ScalarViewType = Kokkos::DynRankView< scalarType, Kokkos::LayoutStride, DeviceType >
 View type for scalars.
 

Public Member Functions

 IntegratedLegendreBasis_HGRAD_TET (int polyOrder, const EPointType pointType=POINTTYPE_DEFAULT)
 Constructor. More...
 
const char * getName () const override
 Returns basis name. More...
 
virtual bool requireOrientation () const override
 True if orientation is required.
 
virtual void getValues (OutputViewType outputValues, const PointViewType inputPoints, const EOperator operatorType=OPERATOR_VALUE) const override
 Evaluation of a FEM basis on a reference cell. More...
 
BasisPtr< DeviceType,
OutputScalar, PointScalar > 
getSubCellRefBasis (const ordinal_type subCellDim, const ordinal_type subCellOrd) const override
 returns the basis associated to a subCell. More...
 
virtual BasisPtr< typename
Kokkos::HostSpace::device_type,
OutputScalar, PointScalar > 
getHostBasis () const override
 Creates and returns a Basis object whose DeviceType template argument is Kokkos::HostSpace::device_type, but is otherwise identical to this. More...
 
- Public Member Functions inherited from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >
OutputValueType getDummyOutputValue ()
 Dummy array to receive input arguments.
 
PointValueType getDummyPointValue ()
 Dummy array to receive input arguments.
 
Kokkos::DynRankView
< OutputValueType, DeviceType
allocateOutputView (const int numPoints, const EOperator operatorType=OPERATOR_VALUE) const
 Allocate a View container suitable for passing to the getValues() variant that accepts Kokkos DynRankViews as arguments (as opposed to the Intrepid2 BasisValues and PointValues containers). More...
 
virtual BasisValues
< OutputValueType, DeviceType
allocateBasisValues (TensorPoints< PointValueType, DeviceType > points, const EOperator operatorType=OPERATOR_VALUE) const
 Allocate BasisValues container suitable for passing to the getValues() variant that takes a TensorPoints container as argument. More...
 
virtual void getScratchSpaceSize (ordinal_type &perTeamSpaceSize, ordinal_type &perThreadSpaceSize, const PointViewType inputPoints, const EOperator operatorType=OPERATOR_VALUE) const
 Return the size of the scratch space, in bytes, needed for using the team-level implementation of getValues. More...
 
virtual KOKKOS_INLINE_FUNCTION void getValues (OutputViewType, const PointViewType, const EOperator, const typename Kokkos::TeamPolicy< ExecutionSpace >::member_type &teamMember, const typename ExecutionSpace::scratch_memory_space &scratchStorage, const ordinal_type subcellDim=-1, const ordinal_type subcellOrdinal=-1) const
 Team-level evaluation of basis functions on a reference cell. More...
 
virtual void getValues (const ExecutionSpace &, OutputViewType, const PointViewType, const EOperator=OPERATOR_VALUE) const
 Evaluation of a FEM basis on a reference cell. More...
 
virtual void getValues (BasisValues< OutputValueType, DeviceType > outputValues, const TensorPoints< PointValueType, DeviceType > inputPoints, const EOperator operatorType=OPERATOR_VALUE) const
 Evaluation of a FEM basis on a reference cell, using point and output value containers that allow preservation of tensor-product structure. More...
 
virtual void getValues (OutputViewType, const PointViewType, const PointViewType, const EOperator=OPERATOR_VALUE) const
 Evaluation of an FVD basis evaluation on a physical cell. More...
 
virtual void getDofCoords (ScalarViewType) const
 Returns spatial locations (coordinates) of degrees of freedom on the reference cell.
 
virtual void getDofCoeffs (ScalarViewType) const
 Coefficients for computing degrees of freedom for Lagrangian basis If P is an element of the space spanned by the basis, := P(dofCoords(i)) dofCoeffs(i) are the nodal coefficients associated to basis function i. More...
 
OrdinalTypeArray1DHost getFieldOrdinalsForDegree (OrdinalTypeArray1DHost &degrees) const
 For hierarchical bases, returns the field ordinals that have at most the specified degree in each dimension. Assuming that these are less than or equal to the polynomial orders provided at Basis construction, the corresponding polynomials will form a superset of the Basis of the same type constructed with polynomial orders corresponding to the specified degrees. More...
 
std::vector< int > getFieldOrdinalsForDegree (std::vector< int > &degrees) const
 For hierarchical bases, returns the field ordinals that have at most the specified degree in each dimension. Assuming that these are less than or equal to the polynomial orders provided at Basis construction, the corresponding polynomials will form a superset of the Basis of the same type constructed with polynomial orders corresponding to the specified degrees. More...
 
OrdinalTypeArray1DHost getFieldOrdinalsForH1Degree (OrdinalTypeArray1DHost &degrees) const
 For hierarchical bases, returns the field ordinals that have at most the specified H^1 degree in each dimension. Assuming that these are less than or equal to the polynomial orders provided at Basis construction, the corresponding polynomials will form a superset of the Basis of the same type constructed with polynomial orders corresponding to the specified degrees. More...
 
std::vector< int > getFieldOrdinalsForH1Degree (std::vector< int > &degrees) const
 For hierarchical bases, returns the field ordinals that have at most the specified H^1 degree in each dimension. Assuming that these are less than or equal to the polynomial orders provided at Basis construction, the corresponding polynomials will form a superset of the Basis of the same type constructed with polynomial orders corresponding to the specified degrees. More...
 
OrdinalTypeArray1DHost getPolynomialDegreeOfField (int fieldOrdinal) const
 For hierarchical bases, returns the polynomial degree (which may have multiple values in higher spatial dimensions) for the specified basis ordinal as a host array. More...
 
OrdinalTypeArray1DHost getH1PolynomialDegreeOfField (int fieldOrdinal) const
 For hierarchical bases, returns the polynomial degree (which may have multiple values in higher spatial dimensions) for the specified basis ordinal as a host array. More...
 
std::vector< int > getPolynomialDegreeOfFieldAsVector (int fieldOrdinal) const
 For hierarchical bases, returns the polynomial degree (which may have multiple values in higher spatial dimensions) for the specified basis ordinal as a host array. More...
 
std::vector< int > getH1PolynomialDegreeOfFieldAsVector (int fieldOrdinal) const
 For hierarchical bases, returns the polynomial degree (which may have multiple values in higher spatial dimensions) for the specified basis ordinal as a host array. More...
 
int getPolynomialDegreeLength () const
 For hierarchical bases, returns the number of entries required to specify the polynomial degree of a basis function.
 
ordinal_type getCardinality () const
 Returns cardinality of the basis. More...
 
ordinal_type getDegree () const
 Returns the degree of the basis. More...
 
EFunctionSpace getFunctionSpace () const
 Returns the function space for the basis. More...
 
shards::CellTopology getBaseCellTopology () const
 Returns the base cell topology for which the basis is defined. See Shards documentation https://trilinos.org/packages/shards for definition of base cell topology. More...
 
EBasis getBasisType () const
 Returns the basis type. More...
 
ECoordinates getCoordinateSystem () const
 Returns the type of coordinate system for which the basis is defined. More...
 
ordinal_type getDofCount (const ordinal_type subcDim, const ordinal_type subcOrd) const
 DoF count for specified subcell. More...
 
ordinal_type getDofOrdinal (const ordinal_type subcDim, const ordinal_type subcOrd, const ordinal_type subcDofOrd) const
 DoF tag to ordinal lookup. More...
 
virtual int getNumTensorialExtrusions () const
 returns the number of tensorial extrusions relative to the cell topology returned by getBaseCellTopology(). Base class returns 0; overridden by TensorBasis.
 
const OrdinalTypeArray3DHost getAllDofOrdinal () const
 DoF tag to ordinal data structure.
 
const OrdinalTypeArrayStride1DHost getDofTag (const ordinal_type dofOrd) const
 DoF ordinal to DoF tag lookup. More...
 
const OrdinalTypeArray2DHost getAllDofTags () const
 Retrieves all DoF tags. More...
 
ordinal_type getDomainDimension () const
 Returns the spatial dimension of the domain of the basis; this is equal to getBaseCellTopology().getDimension() + getNumTensorialExtrusions(). More...
 

Protected Attributes

int polyOrder_
 
EPointType pointType_
 
- Protected Attributes inherited from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >
ordinal_type basisCardinality_
 Cardinality of the basis, i.e., the number of basis functions/degrees-of-freedom.
 
ordinal_type basisDegree_
 Degree of the largest complete polynomial space that can be represented by the basis.
 
unsigned basisCellTopologyKey_
 Identifier of the base topology of the cells for which the basis is defined. See the Shards package for definition of base cell topology. For TensorBasis subclasses, by default this the cell topology that is extruded (i.e., it is a lower-dimensional CellTopology than the space on which the tensor basis is defined). This allows tensor bases to be defined in higher dimensions than shards::CellTopology supports. TensorBasis subclasses can opt to use an equivalent shards CellTopology for base topology, as well as using Intrepid2's tagging for tensor bases in dimensions up to 3, by calling TensorBasis::setShardsTopologyAndTags().
 
EBasis basisType_
 Type of the basis.
 
ECoordinates basisCoordinates_
 The coordinate system for which the basis is defined.
 
EFunctionSpace functionSpace_
 The function space in which the basis is defined.
 
OrdinalTypeArray2DHost ordinalToTag_
 "true" if tagToOrdinal_ and ordinalToTag_ have been initialized More...
 
OrdinalTypeArray3DHost tagToOrdinal_
 DoF tag to ordinal lookup table. More...
 
Kokkos::DynRankView
< scalarType, DeviceType
dofCoords_
 Coordinates of degrees-of-freedom for basis functions defined in physical space.
 
Kokkos::DynRankView
< scalarType, DeviceType
dofCoeffs_
 Coefficients for computing degrees of freedom for Lagrangian basis If P is an element of the space spanned by the basis, := P(dofCoords_(i)) dofCoeffs_(i) are the nodal coefficients associated to basis functions i. More...
 
OrdinalTypeArray2DHost fieldOrdinalPolynomialDegree_
 Polynomial degree for each degree of freedom. Only defined for hierarchical bases right now. The number of entries per degree of freedom in this table depends on the basis type. For hypercubes, this will be the spatial dimension. We have not yet determined what this will be for simplices beyond 1D; there are not yet hierarchical simplicial bases beyond 1D in Intrepid2. More...
 
OrdinalTypeArray2DHost fieldOrdinalH1PolynomialDegree_
 H^1 polynomial degree for each degree of freedom. Only defined for hierarchical bases right now. The number of entries per degree of freedom in this table depends on the basis type. For hypercubes, this will be the spatial dimension. We have not yet determined what this will be for simplices beyond 1D; there are not yet hierarchical simplicial bases beyond 1D in Intrepid2. More...
 

Additional Inherited Members

- Protected Member Functions inherited from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >
void setOrdinalTagData (OrdinalTypeView3D &tagToOrdinal, OrdinalTypeView2D &ordinalToTag, const OrdinalTypeView1D tags, const ordinal_type basisCard, const ordinal_type tagSize, const ordinal_type posScDim, const ordinal_type posScOrd, const ordinal_type posDfOrd)
 Fills ordinalToTag_ and tagToOrdinal_ by basis-specific tag data. More...
 

Detailed Description

template<typename DeviceType, typename OutputScalar = double, typename PointScalar = double, bool defineVertexFunctions = true>
class Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >

Basis defining integrated Legendre basis on the line, a polynomial subspace of H(grad) on the line.

This is used in the construction of hierarchical bases on higher-dimensional topologies. For mathematical details of the construction, see:

Federico Fuentes, Brendan Keith, Leszek Demkowicz, Sriram Nagaraj. "Orientation embedded high order shape functions for the exact sequence elements of all shapes." Computers & Mathematics with Applications, Volume 70, Issue 4, 2015, Pages 353-458, ISSN 0898-1221. https://doi.org/10.1016/j.camwa.2015.04.027.

Note that the template argument defineVertexFunctions controls whether this basis is defined in a strictly hierarchical way. If defineVertexFunctions is false, then the first basis function is the constant 1.0, and this basis will be suitable for discontinuous discretizations. If defineVertexFunctions is true, then the first basis function will instead be 1.0-x-y, and the basis will be suitable for continuous discretizations.

Definition at line 578 of file Intrepid2_IntegratedLegendreBasis_HGRAD_TET.hpp.

Constructor & Destructor Documentation

template<typename DeviceType , typename OutputScalar = double, typename PointScalar = double, bool defineVertexFunctions = true>
Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >::IntegratedLegendreBasis_HGRAD_TET ( int  polyOrder,
const EPointType  pointType = POINTTYPE_DEFAULT 
)
inline

Member Function Documentation

template<typename DeviceType , typename OutputScalar = double, typename PointScalar = double, bool defineVertexFunctions = true>
virtual BasisPtr<typename Kokkos::HostSpace::device_type, OutputScalar, PointScalar> Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >::getHostBasis ( ) const
inlineoverridevirtual

Creates and returns a Basis object whose DeviceType template argument is Kokkos::HostSpace::device_type, but is otherwise identical to this.

Returns
Pointer to the new Basis object.

Reimplemented from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >.

Definition at line 869 of file Intrepid2_IntegratedLegendreBasis_HGRAD_TET.hpp.

template<typename DeviceType , typename OutputScalar = double, typename PointScalar = double, bool defineVertexFunctions = true>
const char* Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >::getName ( ) const
inlineoverridevirtual

Returns basis name.

Returns
the name of the basis

Reimplemented from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >.

Definition at line 791 of file Intrepid2_IntegratedLegendreBasis_HGRAD_TET.hpp.

template<typename DeviceType , typename OutputScalar = double, typename PointScalar = double, bool defineVertexFunctions = true>
BasisPtr<DeviceType,OutputScalar,PointScalar> Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >::getSubCellRefBasis ( const ordinal_type  subCellDim,
const ordinal_type  subCellOrd 
) const
inlineoverridevirtual

returns the basis associated to a subCell.

The bases of the subCell are the restriction to the subCell of the bases of the parent cell.

Parameters
[in]subCellDim- dimension of subCell
[in]subCellOrd- position of the subCell among of the subCells having the same dimension
Returns
pointer to the subCell basis of dimension subCellDim and position subCellOrd

Reimplemented from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >.

Definition at line 851 of file Intrepid2_IntegratedLegendreBasis_HGRAD_TET.hpp.

References Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >::basisDegree_.

template<typename DeviceType , typename OutputScalar = double, typename PointScalar = double, bool defineVertexFunctions = true>
virtual void Intrepid2::IntegratedLegendreBasis_HGRAD_TET< DeviceType, OutputScalar, PointScalar, defineVertexFunctions >::getValues ( OutputViewType  outputValues,
const PointViewType  inputPoints,
const EOperator  operatorType = OPERATOR_VALUE 
) const
inlineoverridevirtual

Evaluation of a FEM basis on a reference cell.

Returns values of operatorType acting on FEM basis functions for a set of points in the reference cell for which the basis is defined.

Parameters
outputValues[out] - variable rank array with the basis values
inputPoints[in] - rank-2 array (P,D) with the evaluation points
operatorType[in] - the operator acting on the basis functions
Remarks
For rank and dimension specifications of the output array see Section MD array template arguments for basis methods. Dimensions of ArrayScalar arguments are checked at runtime if HAVE_INTREPID2_DEBUG is defined.
A FEM basis spans a COMPLETE or INCOMPLETE polynomial space on the reference cell which is a smooth function space. Thus, all operator types that are meaningful for the approximated function space are admissible. When the order of the operator exceeds the degree of the basis, the output array is filled with the appropriate number of zeros.

Reimplemented from Intrepid2::Basis< DeviceType, OutputScalar, PointScalar >.

Definition at line 824 of file Intrepid2_IntegratedLegendreBasis_HGRAD_TET.hpp.


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