MFEM
v4.6.0
Finite element discretization library
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Solve the H(div) saddle-point system using MINRES with matrix-free block-diagonal preconditioning. More...
#include <hdiv_linear_solver.hpp>
Public Types | |
enum | Mode { GRAD_DIV, DARCY } |
Which type of saddle-point problem is being solved? More... | |
Public Types inherited from mfem::Operator | |
enum | DiagonalPolicy { DIAG_ZERO, DIAG_ONE, DIAG_KEEP } |
Defines operator diagonal policy upon elimination of rows and/or columns. More... | |
enum | Type { ANY_TYPE, MFEM_SPARSEMAT, Hypre_ParCSR, PETSC_MATAIJ, PETSC_MATIS, PETSC_MATSHELL, PETSC_MATNEST, PETSC_MATHYPRE, PETSC_MATGENERIC, Complex_Operator, MFEM_ComplexSparseMat, Complex_Hypre_ParCSR, Complex_DenseMat, MFEM_Block_Matrix, MFEM_Block_Operator } |
Enumeration defining IDs for some classes derived from Operator. More... | |
Public Member Functions | |
HdivSaddlePointSolver (ParMesh &mesh_, ParFiniteElementSpace &fes_rt_, ParFiniteElementSpace &fes_l2_, Coefficient &L_coeff_, Coefficient &R_coeff_, const Array< int > &ess_rt_dofs_, Mode mode_) | |
Creates a solver for the H(div) saddle-point system. More... | |
HdivSaddlePointSolver (ParMesh &mesh_, ParFiniteElementSpace &fes_rt_, ParFiniteElementSpace &fes_l2_, Coefficient &R_coeff_, const Array< int > &ess_rt_dofs_) | |
Creates a linear solver for the case when the L2 diagonal block is zero (for Darcy problems). More... | |
void | Setup () |
Build the linear operator and solver. Must be called when the coefficients change. More... | |
void | SetBC (const Vector &x_rt) |
Sets the Dirichlet boundary conditions at the RT essential DOFs. More... | |
void | Mult (const Vector &b, Vector &x) const override |
Solve the linear system for L2 (scalar) and RT (flux) unknowns. More... | |
void | SetOperator (const Operator &op) override |
No-op. More... | |
int | GetNumIterations () const |
Get the number of MINRES iterations. More... | |
void | EliminateBC (Vector &) const |
Eliminates the BCs (called internally, not public interface). More... | |
const Array< int > & | GetOffsets () const |
Return the offsets of the block system. More... | |
MINRESSolver & | GetMINRES () |
Returns the internal MINRES solver. More... | |
Public Member Functions inherited from mfem::Solver | |
Solver (int s=0, bool iter_mode=false) | |
Initialize a square Solver with size s. More... | |
Solver (int h, int w, bool iter_mode=false) | |
Initialize a Solver with height h and width w. More... | |
Public Member Functions inherited from mfem::Operator | |
void | InitTVectors (const Operator *Po, const Operator *Ri, const Operator *Pi, Vector &x, Vector &b, Vector &X, Vector &B) const |
Initializes memory for true vectors of linear system. More... | |
Operator (int s=0) | |
Construct a square Operator with given size s (default 0). More... | |
Operator (int h, int w) | |
Construct an Operator with the given height (output size) and width (input size). More... | |
int | Height () const |
Get the height (size of output) of the Operator. Synonym with NumRows(). More... | |
int | NumRows () const |
Get the number of rows (size of output) of the Operator. Synonym with Height(). More... | |
int | Width () const |
Get the width (size of input) of the Operator. Synonym with NumCols(). More... | |
int | NumCols () const |
Get the number of columns (size of input) of the Operator. Synonym with Width(). More... | |
virtual MemoryClass | GetMemoryClass () const |
Return the MemoryClass preferred by the Operator. More... | |
virtual void | MultTranspose (const Vector &x, Vector &y) const |
Action of the transpose operator: y=A^t(x) . The default behavior in class Operator is to generate an error. More... | |
virtual void | AddMult (const Vector &x, Vector &y, const double a=1.0) const |
Operator application: y+=A(x) (default) or y+=a*A(x) . More... | |
virtual void | AddMultTranspose (const Vector &x, Vector &y, const double a=1.0) const |
Operator transpose application: y+=A^t(x) (default) or y+=a*A^t(x) . More... | |
virtual void | ArrayMult (const Array< const Vector *> &X, Array< Vector *> &Y) const |
Operator application on a matrix: Y=A(X) . More... | |
virtual void | ArrayMultTranspose (const Array< const Vector *> &X, Array< Vector *> &Y) const |
Action of the transpose operator on a matrix: Y=A^t(X) . More... | |
virtual void | ArrayAddMult (const Array< const Vector *> &X, Array< Vector *> &Y, const double a=1.0) const |
Operator application on a matrix: Y+=A(X) (default) or Y+=a*A(X) . More... | |
virtual void | ArrayAddMultTranspose (const Array< const Vector *> &X, Array< Vector *> &Y, const double a=1.0) const |
Operator transpose application on a matrix: Y+=A^t(X) (default) or Y+=a*A^t(X) . More... | |
virtual Operator & | GetGradient (const Vector &x) const |
Evaluate the gradient operator at the point x. The default behavior in class Operator is to generate an error. More... | |
virtual void | AssembleDiagonal (Vector &diag) const |
Computes the diagonal entries into diag. Typically, this operation only makes sense for linear Operators. In some cases, only an approximation of the diagonal is computed. More... | |
virtual const Operator * | GetProlongation () const |
Prolongation operator from linear algebra (linear system) vectors, to input vectors for the operator. NULL means identity. More... | |
virtual const Operator * | GetRestriction () const |
Restriction operator from input vectors for the operator to linear algebra (linear system) vectors. NULL means identity. More... | |
virtual const Operator * | GetOutputProlongation () const |
Prolongation operator from linear algebra (linear system) vectors, to output vectors for the operator. NULL means identity. More... | |
virtual const Operator * | GetOutputRestrictionTranspose () const |
Transpose of GetOutputRestriction, directly available in this form to facilitate matrix-free RAP-type operators. More... | |
virtual const Operator * | GetOutputRestriction () const |
Restriction operator from output vectors for the operator to linear algebra (linear system) vectors. NULL means identity. More... | |
void | FormLinearSystem (const Array< int > &ess_tdof_list, Vector &x, Vector &b, Operator *&A, Vector &X, Vector &B, int copy_interior=0) |
Form a constrained linear system using a matrix-free approach. More... | |
void | FormRectangularLinearSystem (const Array< int > &trial_tdof_list, const Array< int > &test_tdof_list, Vector &x, Vector &b, Operator *&A, Vector &X, Vector &B) |
Form a column-constrained linear system using a matrix-free approach. More... | |
virtual void | RecoverFEMSolution (const Vector &X, const Vector &b, Vector &x) |
Reconstruct a solution vector x (e.g. a GridFunction) from the solution X of a constrained linear system obtained from Operator::FormLinearSystem() or Operator::FormRectangularLinearSystem(). More... | |
void | FormSystemOperator (const Array< int > &ess_tdof_list, Operator *&A) |
Return in A a parallel (on truedofs) version of this square operator. More... | |
void | FormRectangularSystemOperator (const Array< int > &trial_tdof_list, const Array< int > &test_tdof_list, Operator *&A) |
Return in A a parallel (on truedofs) version of this rectangular operator (including constraints). More... | |
void | FormDiscreteOperator (Operator *&A) |
Return in A a parallel (on truedofs) version of this rectangular operator. More... | |
void | PrintMatlab (std::ostream &out, int n, int m=0) const |
Prints operator with input size n and output size m in Matlab format. More... | |
virtual void | PrintMatlab (std::ostream &out) const |
Prints operator in Matlab format. More... | |
virtual | ~Operator () |
Virtual destructor. More... | |
Type | GetType () const |
Return the type ID of the Operator class. More... | |
Additional Inherited Members | |
Public Attributes inherited from mfem::Solver | |
bool | iterative_mode |
If true, use the second argument of Mult() as an initial guess. More... | |
Protected Member Functions inherited from mfem::Operator | |
void | FormConstrainedSystemOperator (const Array< int > &ess_tdof_list, ConstrainedOperator *&Aout) |
see FormSystemOperator() More... | |
void | FormRectangularConstrainedSystemOperator (const Array< int > &trial_tdof_list, const Array< int > &test_tdof_list, RectangularConstrainedOperator *&Aout) |
see FormRectangularSystemOperator() More... | |
Operator * | SetupRAP (const Operator *Pi, const Operator *Po) |
Returns RAP Operator of this, using input/output Prolongation matrices Pi corresponds to "P", Po corresponds to "Rt". More... | |
Protected Attributes inherited from mfem::Operator | |
int | height |
Dimension of the output / number of rows in the matrix. More... | |
int | width |
Dimension of the input / number of columns in the matrix. More... | |
Solve the H(div) saddle-point system using MINRES with matrix-free block-diagonal preconditioning.
See HdivSaddlePointSolver::HdivSaddlePointSolver for the problem description.
Definition at line 27 of file hdiv_linear_solver.hpp.
Which type of saddle-point problem is being solved?
Enumerator | |
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GRAD_DIV | Grad-div problem. |
DARCY | Darcy/mixed Poisson problem. |
Definition at line 31 of file hdiv_linear_solver.hpp.
mfem::HdivSaddlePointSolver::HdivSaddlePointSolver | ( | ParMesh & | mesh_, |
ParFiniteElementSpace & | fes_rt_, | ||
ParFiniteElementSpace & | fes_l2_, | ||
Coefficient & | L_coeff_, | ||
Coefficient & | R_coeff_, | ||
const Array< int > & | ess_rt_dofs_, | ||
Mode | mode_ | ||
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Creates a solver for the H(div) saddle-point system.
The associated matrix is given by
[ L B ] [ B^T -R ]
where L is the L2 mass matrix, R is the RT mass matrix, and B is the divergence form (VectorFEDivergenceIntegrator).
Essential boundary conditions in the RT space are given by ess_rt_dofs_. (Rows and columns are eliminated from R and columns are eliminated from B).
The L block has coefficient L_coeff_ and the R block has coefficient R_coeff_.
The parameter mode_ determines whether the block system corresponds to a grad-div problem or a Darcy problem. Specifically, if mode_ is Mode::GRAD_DIV, then the B and B^T blocks are also scaled by L_coeff_, and if mode_ is Mode::DARCY, then the B and B^T blocks are unweighted.
Mode::GRAD_DIV corresponds to the grad-div problem
alpha u - grad ( beta div ( u )) = f,
where alpha is R_coeff_ and beta is L_coeff_.
Mode::DARCY corresponds to the Darcy-type problem
alpha p - div ( beta grad ( p )) = f,
where alpha is L_coeff and beta is R_coeff_. In this case, the coefficient alpha is allowed to be zero.
Definition at line 65 of file hdiv_linear_solver.cpp.
mfem::HdivSaddlePointSolver::HdivSaddlePointSolver | ( | ParMesh & | mesh_, |
ParFiniteElementSpace & | fes_rt_, | ||
ParFiniteElementSpace & | fes_l2_, | ||
Coefficient & | R_coeff_, | ||
const Array< int > & | ess_rt_dofs_ | ||
) |
Creates a linear solver for the case when the L2 diagonal block is zero (for Darcy problems).
Equivalent to passing ConstantCoefficient(0.0) as L_coeff_ and Mode::DARCY as mode_ to the primary constructor (see above).
Definition at line 155 of file hdiv_linear_solver.cpp.
void mfem::HdivSaddlePointSolver::EliminateBC | ( | Vector & | b | ) | const |
Eliminates the BCs (called internally, not public interface).
Definition at line 277 of file hdiv_linear_solver.cpp.
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Returns the internal MINRES solver.
Definition at line 170 of file hdiv_linear_solver.hpp.
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Get the number of MINRES iterations.
Definition at line 164 of file hdiv_linear_solver.hpp.
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Return the offsets of the block system.
Definition at line 168 of file hdiv_linear_solver.hpp.
Solve the linear system for L2 (scalar) and RT (flux) unknowns.
If the problem has essential boundary conditions (i.e. if ess_rt_dofs is not empty), then SetBC() must be called before Mult().
Implements mfem::Operator.
Definition at line 330 of file hdiv_linear_solver.cpp.
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Sets the Dirichlet boundary conditions at the RT essential DOFs.
Definition at line 155 of file hdiv_linear_solver.hpp.
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void mfem::HdivSaddlePointSolver::Setup | ( | ) |
Build the linear operator and solver. Must be called when the coefficients change.
Definition at line 162 of file hdiv_linear_solver.cpp.