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MFEM
v4.4.0
Finite element discretization library
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MFEM
v4.4.0
Finite element discretization library
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Abstract base class BilinearFormIntegrator. More...
#include <bilininteg.hpp>
Public Member Functions | |
| virtual void | AssemblePA (const FiniteElementSpace &fes) |
| Method defining partial assembly. More... | |
| virtual void | AssemblePA (const FiniteElementSpace &trial_fes, const FiniteElementSpace &test_fes) |
| virtual void | AssemblePAInteriorFaces (const FiniteElementSpace &fes) |
| virtual void | AssemblePABoundaryFaces (const FiniteElementSpace &fes) |
| virtual void | AssembleDiagonalPA (Vector &diag) |
| Assemble diagonal and add it to Vector diag. More... | |
| virtual void | AssembleDiagonalPA_ADAt (const Vector &D, Vector &diag) |
| Assemble diagonal of ADA^T (A is this integrator) and add it to diag. More... | |
| virtual void | AddMultPA (const Vector &x, Vector &y) const |
| Method for partially assembled action. More... | |
| virtual void | AddMultTransposePA (const Vector &x, Vector &y) const |
| Method for partially assembled transposed action. More... | |
| virtual void | AssembleEA (const FiniteElementSpace &fes, Vector &emat, const bool add=true) |
| Method defining element assembly. More... | |
| virtual void | AssembleMF (const FiniteElementSpace &fes) |
| Method defining matrix-free assembly. More... | |
| virtual void | AddMultMF (const Vector &x, Vector &y) const |
| virtual void | AddMultTransposeMF (const Vector &x, Vector &y) const |
| virtual void | AssembleDiagonalMF (Vector &diag) |
| Assemble diagonal and add it to Vector diag. More... | |
| virtual void | AssembleEAInteriorFaces (const FiniteElementSpace &fes, Vector &ea_data_int, Vector &ea_data_ext, const bool add=true) |
| virtual void | AssembleEABoundaryFaces (const FiniteElementSpace &fes, Vector &ea_data_bdr, const bool add=true) |
| virtual void | AssembleElementMatrix (const FiniteElement &el, ElementTransformation &Trans, DenseMatrix &elmat) |
| Given a particular Finite Element computes the element matrix elmat. More... | |
| virtual void | AssembleElementMatrix2 (const FiniteElement &trial_fe, const FiniteElement &test_fe, ElementTransformation &Trans, DenseMatrix &elmat) |
| virtual void | AssembleFaceMatrix (const FiniteElement &el1, const FiniteElement &el2, FaceElementTransformations &Trans, DenseMatrix &elmat) |
| virtual void | AssembleFaceMatrix (const FiniteElement &trial_face_fe, const FiniteElement &test_fe1, const FiniteElement &test_fe2, FaceElementTransformations &Trans, DenseMatrix &elmat) |
| virtual void | AssembleElementVector (const FiniteElement &el, ElementTransformation &Tr, const Vector &elfun, Vector &elvect) |
| Perform the local action of the BilinearFormIntegrator. Note that the default implementation in the base class is general but not efficient. More... | |
| virtual void | AssembleFaceVector (const FiniteElement &el1, const FiniteElement &el2, FaceElementTransformations &Tr, const Vector &elfun, Vector &elvect) |
| Perform the local action of the BilinearFormIntegrator resulting from a face integral term. Note that the default implementation in the base class is general but not efficient. More... | |
| virtual void | AssembleElementGrad (const FiniteElement &el, ElementTransformation &Tr, const Vector &elfun, DenseMatrix &elmat) |
| Assemble the local gradient matrix. More... | |
| virtual void | AssembleFaceGrad (const FiniteElement &el1, const FiniteElement &el2, FaceElementTransformations &Tr, const Vector &elfun, DenseMatrix &elmat) |
| Assemble the local action of the gradient of the NonlinearFormIntegrator resulting from a face integral term. More... | |
| virtual void | ComputeElementFlux (const FiniteElement &el, ElementTransformation &Trans, Vector &u, const FiniteElement &fluxelem, Vector &flux, bool with_coef=true) |
| Virtual method required for Zienkiewicz-Zhu type error estimators. More... | |
| virtual double | ComputeFluxEnergy (const FiniteElement &fluxelem, ElementTransformation &Trans, Vector &flux, Vector *d_energy=NULL) |
| Virtual method required for Zienkiewicz-Zhu type error estimators. More... | |
| virtual | ~BilinearFormIntegrator () |
 Public Member Functions inherited from mfem::NonlinearFormIntegrator | |
| virtual void | SetIntRule (const IntegrationRule *ir) |
| Prescribe a fixed IntegrationRule to use (when ir != NULL) or let the integrator choose (when ir == NULL). More... | |
| void | SetIntegrationRule (const IntegrationRule &ir) |
| Prescribe a fixed IntegrationRule to use. More... | |
| void | SetPAMemoryType (MemoryType mt) |
| const IntegrationRule * | GetIntegrationRule () const |
| Get the integration rule of the integrator (possibly NULL). More... | |
| virtual double | GetElementEnergy (const FiniteElement &el, ElementTransformation &Tr, const Vector &elfun) |
| Compute the local energy. More... | |
| virtual void | AssembleGradPA (const Vector &x, const FiniteElementSpace &fes) |
| Prepare the integrator for partial assembly (PA) gradient evaluations on the given FE space fes at the state x. More... | |
| virtual double | GetLocalStateEnergyPA (const Vector &x) const |
| Compute the local (to the MPI rank) energy with partial assembly. More... | |
| virtual void | AddMultGradPA (const Vector &x, Vector &y) const |
| Method for partially assembled gradient action. More... | |
| virtual void | AssembleGradDiagonalPA (Vector &diag) const |
| Method for computing the diagonal of the gradient with partial assembly. More... | |
| virtual bool | SupportsCeed () const |
| Indicates whether this integrator can use a Ceed backend. More... | |
| ceed::Operator & | GetCeedOp () |
| virtual | ~NonlinearFormIntegrator () |
Protected Member Functions | |
| BilinearFormIntegrator (const IntegrationRule *ir=NULL) | |
| Protected Member Functions inherited from mfem::NonlinearFormIntegrator | |
| NonlinearFormIntegrator (const IntegrationRule *ir=NULL) | |
Additional Inherited Members | |
| Protected Attributes inherited from mfem::NonlinearFormIntegrator | |
| const IntegrationRule * | IntRule |
| ceed::Operator * | ceedOp |
| MemoryType | pa_mt = MemoryType::DEFAULT |
Abstract base class BilinearFormIntegrator.
Definition at line 34 of file bilininteg.hpp.
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Definition at line 37 of file bilininteg.hpp.
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Definition at line 247 of file bilininteg.hpp.
Perform the action of integrator on the input x and add the result to the output y. Both x and y are E-vectors, i.e. they represent the element-wise discontinuous version of the FE space.
This method can be called only after the method AssembleMF() has been called.
Reimplemented from mfem::NonlinearFormIntegrator.
Reimplemented in mfem::VectorDiffusionIntegrator, mfem::VectorMassIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, and mfem::SumIntegrator.
Definition at line 105 of file bilininteg.cpp.
Method for partially assembled action.
Perform the action of integrator on the input x and add the result to the output y. Both x and y are E-vectors, i.e. they represent the element-wise discontinuous version of the FE space.
This method can be called only after the method AssemblePA() has been called.
Reimplemented from mfem::NonlinearFormIntegrator.
Reimplemented in mfem::IdentityInterpolator, mfem::GradientInterpolator, mfem::DGTraceIntegrator, mfem::VectorDiffusionIntegrator, mfem::DivDivIntegrator, mfem::VectorDivergenceIntegrator, mfem::VectorFEMassIntegrator, mfem::CurlCurlIntegrator, mfem::VectorFEDivergenceIntegrator, mfem::VectorMassIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, mfem::GradientIntegrator, mfem::MixedVectorWeakCurlIntegrator, mfem::MixedVectorCurlIntegrator, mfem::MixedVectorGradientIntegrator, mfem::MixedScalarCurlIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 87 of file bilininteg.cpp.
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Perform the transpose action of integrator on the input x and add the result to the output y. Both x and y are E-vectors, i.e. they represent the element-wise discontinuous version of the FE space.
This method can be called only after the method AssemblePA() has been called.
Reimplemented in mfem::SumIntegrator.
Definition at line 111 of file bilininteg.cpp.
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Method for partially assembled transposed action.
Perform the transpose action of integrator on the input x and add the result to the output y. Both x and y are E-vectors, i.e. they represent the element-wise discontinuous version of the FE space.
This method can be called only after the method AssemblePA() has been called.
Reimplemented in mfem::IdentityInterpolator, mfem::GradientInterpolator, mfem::DGTraceIntegrator, mfem::VectorDivergenceIntegrator, mfem::VectorFEDivergenceIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, mfem::GradientIntegrator, mfem::MixedVectorGradientIntegrator, mfem::MixedScalarCurlIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 93 of file bilininteg.cpp.
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Assemble diagonal and add it to Vector diag.
Reimplemented in mfem::VectorDiffusionIntegrator, mfem::VectorMassIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, and mfem::SumIntegrator.
Definition at line 117 of file bilininteg.cpp.
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Assemble diagonal and add it to Vector diag.
Reimplemented in mfem::VectorDiffusionIntegrator, mfem::DivDivIntegrator, mfem::VectorFEMassIntegrator, mfem::CurlCurlIntegrator, mfem::VectorMassIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, and mfem::SumIntegrator.
Definition at line 48 of file bilininteg.cpp.
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Assemble diagonal of ADA^T (A is this integrator) and add it to diag.
Reimplemented in mfem::VectorFEDivergenceIntegrator.
Definition at line 81 of file bilininteg.cpp.
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Method defining element assembly.
The result of the element assembly is added to the emat Vector if add is true. Otherwise, if add is false, we set emat.
Reimplemented in mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 54 of file bilininteg.cpp.
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Reimplemented in mfem::DGTraceIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 72 of file bilininteg.cpp.
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Reimplemented in mfem::DGTraceIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 62 of file bilininteg.cpp.
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Assemble the local gradient matrix.
Reimplemented from mfem::NonlinearFormIntegrator.
Definition at line 177 of file bilininteg.hpp.
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Given a particular Finite Element computes the element matrix elmat.
Reimplemented in mfem::ElasticityIntegrator, mfem::VectorDiffusionIntegrator, mfem::DivDivIntegrator, mfem::VectorFEMassIntegrator, mfem::VectorCurlCurlIntegrator, mfem::CurlCurlIntegrator, mfem::DerivativeIntegrator, mfem::VectorFECurlIntegrator, mfem::VectorFEWeakDivergenceIntegrator, mfem::VectorFEDivergenceIntegrator, mfem::VectorMassIntegrator, mfem::GroupConvectionIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, mfem::MixedScalarVectorIntegrator, mfem::MixedVectorIntegrator, mfem::MixedScalarIntegrator, mfem::SumIntegrator, mfem::InverseIntegrator, mfem::LumpedIntegrator, and mfem::TransposeIntegrator.
Definition at line 123 of file bilininteg.cpp.
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Compute the local matrix representation of a bilinear form a(u,v) defined on different trial (given by u) and test (given by v) spaces. The rows in the local matrix correspond to the test dofs and the columns – to the trial dofs.
Reimplemented in mfem::VectorInnerProductInterpolator, mfem::VectorCrossProductInterpolator, mfem::ScalarCrossProductInterpolator, mfem::VectorScalarProductInterpolator, mfem::ScalarVectorProductInterpolator, mfem::ScalarProductInterpolator, mfem::NormalInterpolator, mfem::DivergenceInterpolator, mfem::CurlInterpolator, mfem::IdentityInterpolator, mfem::GradientInterpolator, mfem::VectorDivergenceIntegrator, mfem::VectorFEMassIntegrator, mfem::DerivativeIntegrator, mfem::VectorFECurlIntegrator, mfem::VectorFEWeakDivergenceIntegrator, mfem::VectorFEDivergenceIntegrator, mfem::VectorMassIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, mfem::GradientIntegrator, mfem::MixedScalarVectorIntegrator, mfem::MixedVectorIntegrator, mfem::MixedScalarIntegrator, mfem::SumIntegrator, mfem::TransposeIntegrator, and DomainIntegrator.
Definition at line 131 of file bilininteg.cpp.
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Perform the local action of the BilinearFormIntegrator. Note that the default implementation in the base class is general but not efficient.
Reimplemented from mfem::NonlinearFormIntegrator.
Reimplemented in mfem::VectorDiffusionIntegrator, and mfem::DiffusionIntegrator.
Definition at line 156 of file bilininteg.cpp.
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Assemble the local action of the gradient of the NonlinearFormIntegrator resulting from a face integral term.
Reimplemented from mfem::NonlinearFormIntegrator.
Definition at line 182 of file bilininteg.hpp.
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Reimplemented in mfem::DGElasticityIntegrator, mfem::DGDiffusionBR2Integrator, mfem::DGDiffusionIntegrator, mfem::DGTraceIntegrator, mfem::BoundaryMassIntegrator, mfem::SumIntegrator, mfem::TransposeIntegrator, mfem::SBM2NeumannIntegrator, and mfem::SBM2DirichletIntegrator.
Definition at line 139 of file bilininteg.cpp.
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Abstract method used for assembling TraceFaceIntegrators in a MixedBilinearForm.
Reimplemented in mfem::NormalTraceJumpIntegrator, mfem::TraceJumpIntegrator, and mfem::SumIntegrator.
Definition at line 147 of file bilininteg.cpp.
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Perform the local action of the BilinearFormIntegrator resulting from a face integral term. Note that the default implementation in the base class is general but not efficient.
Reimplemented from mfem::NonlinearFormIntegrator.
Definition at line 167 of file bilininteg.cpp.
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Method defining matrix-free assembly.
Used with BilinearFormIntegrators that have different spaces.The result of fully matrix-free assembly is stored internally so that it can be used later in the methods AddMultMF() and AddMultTransposeMF().
Reimplemented from mfem::NonlinearFormIntegrator.
Reimplemented in mfem::VectorDiffusionIntegrator, mfem::VectorMassIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, and mfem::SumIntegrator.
Definition at line 99 of file bilininteg.cpp.
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Method defining partial assembly.
The result of the partial assembly is stored internally so that it can be used later in the methods AddMultPA() and AddMultTransposePA().
Reimplemented from mfem::NonlinearFormIntegrator.
Reimplemented in mfem::VectorDiffusionIntegrator, mfem::DivDivIntegrator, mfem::VectorFEMassIntegrator, mfem::CurlCurlIntegrator, mfem::VectorMassIntegrator, mfem::ConvectionIntegrator, mfem::MassIntegrator, mfem::DiffusionIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 23 of file bilininteg.cpp.
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Used with BilinearFormIntegrators that have different spaces.
Reimplemented from mfem::NonlinearFormIntegrator.
Reimplemented in mfem::IdentityInterpolator, mfem::GradientInterpolator, mfem::VectorDivergenceIntegrator, mfem::VectorFEMassIntegrator, mfem::VectorFEDivergenceIntegrator, mfem::GradientIntegrator, mfem::MixedVectorWeakCurlIntegrator, mfem::MixedVectorCurlIntegrator, mfem::MixedVectorGradientIntegrator, and mfem::MixedScalarCurlIntegrator.
Definition at line 29 of file bilininteg.cpp.
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Reimplemented in mfem::DGTraceIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 42 of file bilininteg.cpp.
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Reimplemented in mfem::DGTraceIntegrator, mfem::SumIntegrator, and mfem::TransposeIntegrator.
Definition at line 36 of file bilininteg.cpp.
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Virtual method required for Zienkiewicz-Zhu type error estimators.
The purpose of the method is to compute a local "flux" finite element function given a local finite element solution. The "flux" function has to be computed in terms of its coefficients (represented by the Vector flux) which multiply the basis functions defined by the FiniteElement fluxelem. Typically, the "flux" function will have more than one component and consequently flux should be store the coefficients of all components: first all coefficient for component 0, then all coefficients for component 1, etc. What the "flux" function represents depends on the specific integrator. For example, in the case of DiffusionIntegrator, the flux is the gradient of the solution multiplied by the diffusion coefficient.
| [in] | el | FiniteElement of the solution. |
| [in] | Trans | The ElementTransformation describing the physical position of the mesh element. |
| [in] | u | Solution coefficients representing the expansion of the solution function in the basis of el. |
| [in] | fluxelem | FiniteElement of the "flux". |
| [out] | flux | "Flux" coefficients representing the expansion of the "flux" function in the basis of fluxelem. The size of flux as a Vector has to be set by this method, e.g. using Vector::SetSize(). |
| [in] | with_coef | If zero (the default value is 1) the implementation of the method may choose not to scale the "flux" function by any coefficients describing the integrator. |
Reimplemented in mfem::ElasticityIntegrator, mfem::CurlCurlIntegrator, and mfem::DiffusionIntegrator.
Definition at line 217 of file bilininteg.hpp.
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Virtual method required for Zienkiewicz-Zhu type error estimators.
The purpose of this method is to compute a local number that measures the energy of a given "flux" function (see ComputeElementFlux() for a description of the "flux" function). Typically, the energy of a "flux" function should be equal to a_local(u,u), if the "flux" is defined from a solution u; here a_local(.,.) denotes the element-local bilinear form represented by the integrator.
| [in] | fluxelem | FiniteElement of the "flux". |
| [in] | Trans | The ElementTransformation describing the physical position of the mesh element. |
| [in] | flux | "Flux" coefficients representing the expansion of the "flux" function in the basis of fluxelem. |
| [out] | d_energy | If not NULL, the given Vector should be set to represent directional energy split that can be used for anisotropic error estimation. |
Reimplemented in mfem::ElasticityIntegrator, mfem::CurlCurlIntegrator, and mfem::DiffusionIntegrator.
Definition at line 242 of file bilininteg.hpp.
1.8.5
