MFEM
v3.4
Finite element discretization library
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#include <ex18.hpp>
Public Member Functions | |
FE_Evolution (FiniteElementSpace &_vfes, Operator &_A, SparseMatrix &_Aflux) | |
virtual void | Mult (const Vector &x, Vector &y) const |
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time. More... | |
virtual | ~FE_Evolution () |
FE_Evolution (SparseMatrix &_M, SparseMatrix &_K, const Vector &_b) | |
virtual void | Mult (const Vector &x, Vector &y) const |
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time. More... | |
virtual | ~FE_Evolution () |
FE_Evolution (HypreParMatrix &_M, HypreParMatrix &_K, const Vector &_b) | |
virtual void | Mult (const Vector &x, Vector &y) const |
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time. More... | |
virtual | ~FE_Evolution () |
FE_Evolution (HypreParMatrix &_M, HypreParMatrix &_K, const Vector &_b, bool M_in_lhs) | |
virtual void | ExplicitMult (const Vector &x, Vector &y) const |
Perform the action of the explicit part of the operator, G: y = G(x, t) where t is the current time. More... | |
virtual void | ImplicitMult (const Vector &x, const Vector &xp, Vector &y) const |
Perform the action of the implicit part of the operator, F: y = F(x, k, t) where t is the current time. More... | |
virtual void | Mult (const Vector &x, Vector &y) const |
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time. More... | |
virtual Operator & | GetExplicitGradient (const Vector &x) const |
Return an Operator representing dG/dx at the given point x and the currently set time. More... | |
virtual Operator & | GetImplicitGradient (const Vector &x, const Vector &xp, double shift) const |
Return an Operator representing (dF/dk shift + dF/dx) at the given x, k, and the currently set time. More... | |
virtual | ~FE_Evolution () |
FE_Evolution (SparseMatrix &_M, SparseMatrix &_K, const Vector &_b) | |
virtual void | Mult (const Vector &x, Vector &y) const |
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time. More... | |
virtual | ~FE_Evolution () |
FE_Evolution (HypreParMatrix &_M, HypreParMatrix &_K, const Vector &_b) | |
virtual void | Mult (const Vector &x, Vector &y) const |
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time. More... | |
virtual | ~FE_Evolution () |
Public Member Functions inherited from mfem::TimeDependentOperator | |
TimeDependentOperator (int n=0, double t_=0.0, Type type_=EXPLICIT) | |
Construct a "square" TimeDependentOperator y = f(x,t), where x and y have the same dimension n. More... | |
TimeDependentOperator (int h, int w, double t_=0.0, Type type_=EXPLICIT) | |
Construct a TimeDependentOperator y = f(x,t), where x and y have dimensions w and h, respectively. More... | |
virtual double | GetTime () const |
Read the currently set time. More... | |
virtual void | SetTime (const double _t) |
Set the current time. More... | |
bool | isExplicit () const |
True if type is EXPLICIT. More... | |
bool | isImplicit () const |
True if type is IMPLICIT or HOMOGENEOUS. More... | |
bool | isHomogeneous () const |
True if type is HOMOGENEOUS. More... | |
virtual void | ImplicitSolve (const double dt, const Vector &x, Vector &k) |
Solve the equation: k = f(x + dt k, t), for the unknown k at the current time t. More... | |
virtual | ~TimeDependentOperator () |
Public Member Functions inherited from mfem::Operator | |
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 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 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 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... | |
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... | |
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(). More... | |
void | PrintMatlab (std::ostream &out, int n=0, int m=0) const |
Prints operator with input size n and output size m 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 Types inherited from mfem::TimeDependentOperator | |
enum | Type { EXPLICIT, IMPLICIT, HOMOGENEOUS } |
Public Types inherited from mfem::Operator | |
enum | Type { ANY_TYPE, MFEM_SPARSEMAT, Hypre_ParCSR, PETSC_MATAIJ, PETSC_MATIS, PETSC_MATSHELL, PETSC_MATNEST, PETSC_MATHYPRE, PETSC_MATGENERIC } |
Enumeration defining IDs for some classes derived from Operator. More... | |
Protected Attributes inherited from mfem::TimeDependentOperator | |
double | t |
Current time. More... | |
Type | type |
Describes the form of the TimeDependentOperator. 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... | |
A time-dependent operator for the right-hand side of the ODE. The DG weak form of du/dt = -v.grad(u) is M du/dt = K u + b, where M and K are the mass and advection matrices, and b describes the flow on the boundary. This can be written as a general ODE, du/dt = M^{-1} (K u + b), and this class is used to evaluate the right-hand side.
A time-dependent operator for the ODE as F(u,du/dt,t) = G(u,t) The DG weak form of du/dt = -v.grad(u) is M du/dt = K u + b, where M and K are the mass and advection matrices, and b describes the flow on the boundary. This can be also written as a general ODE with the right-hand side only as du/dt = M^{-1} (K u + b). This class is used to evaluate the right-hand side and the left-hand side.
FE_Evolution::FE_Evolution | ( | FiniteElementSpace & | _vfes, |
Operator & | _A, | ||
SparseMatrix & | _Aflux | ||
) |
FE_Evolution::FE_Evolution | ( | SparseMatrix & | _M, |
SparseMatrix & | _K, | ||
const Vector & | _b | ||
) |
FE_Evolution::FE_Evolution | ( | HypreParMatrix & | _M, |
HypreParMatrix & | _K, | ||
const Vector & | _b | ||
) |
FE_Evolution::FE_Evolution | ( | HypreParMatrix & | _M, |
HypreParMatrix & | _K, | ||
const Vector & | _b, | ||
bool | M_in_lhs | ||
) |
FE_Evolution::FE_Evolution | ( | SparseMatrix & | _M, |
SparseMatrix & | _K, | ||
const Vector & | _b | ||
) |
FE_Evolution::FE_Evolution | ( | HypreParMatrix & | _M, |
HypreParMatrix & | _K, | ||
const Vector & | _b | ||
) |
Perform the action of the explicit part of the operator, G: y = G(x, t) where t is the current time.
Presently, this method is used by some PETSc ODE solvers, for more details, see the PETSc Manual.
Reimplemented from mfem::TimeDependentOperator.
Return an Operator representing dG/dx at the given point x and the currently set time.
Presently, this method is used by some PETSc ODE solvers, for more details, see the PETSc Manual.
Reimplemented from mfem::TimeDependentOperator.
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virtual |
Return an Operator representing (dF/dk shift + dF/dx) at the given x, k, and the currently set time.
Presently, this method is used by some PETSc ODE solvers, for more details, see the PETSc Manual.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the implicit part of the operator, F: y = F(x, k, t) where t is the current time.
Presently, this method is used by some PETSc ODE solvers, for more details, see the PETSc Manual.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time.
Reimplemented from mfem::TimeDependentOperator.
Perform the action of the operator: y = k = f(x, t), where k solves the algebraic equation F(x, k, t) = G(x, t) and t is the current time.
Reimplemented from mfem::TimeDependentOperator.