MFEM
v4.5.2
Finite element discretization library
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#include <operator.hpp>
Public Member Functions | |
TimeDependentAdjointOperator (int dim, int adjdim, double t=0., Type type=EXPLICIT) | |
The TimedependentAdjointOperator extends the TimeDependentOperator class to use features in SUNDIALS CVODESSolver for computing quadratures and solving adjoint problems. More... | |
virtual | ~TimeDependentAdjointOperator () |
Destructor. More... | |
virtual void | QuadratureIntegration (const Vector &y, Vector &qdot) const |
Provide the operator integration of a quadrature equation. More... | |
virtual void | AdjointRateMult (const Vector &y, Vector &yB, Vector &yBdot) const =0 |
Perform the action of the operator: yBdot = k = f(y,@2 yB, t), where. More... | |
virtual void | QuadratureSensitivityMult (const Vector &y, const Vector &yB, Vector &qBdot) const |
Provides the sensitivity of the quadrature w.r.t to primal and adjoint solutions. More... | |
virtual int | SUNImplicitSetupB (const double t, const Vector &x, const Vector &xB, const Vector &fxB, int jokB, int *jcurB, double gammaB) |
Setup the ODE linear system \( A(x,t) = (I - gamma J) \) or \( A = (M - gamma J) \), where \( J(x,t) = \frac{df}{dt(x,t)} \). More... | |
virtual int | SUNImplicitSolveB (Vector &x, const Vector &b, double tol) |
Solve the ODE linear system \( A(x,xB,t) xB = b \) as setup by the method SUNImplicitSetup(). More... | |
int | GetAdjointHeight () |
Returns the size of the adjoint problem state space. More... | |
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... | |
EvalMode | GetEvalMode () const |
Return the current evaluation mode. See SetEvalMode() for details. More... | |
virtual void | SetEvalMode (const EvalMode new_eval_mode) |
Set the evaluation mode of the time-dependent operator. More... | |
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 &k, 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 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 Operator & | GetImplicitGradient (const Vector &x, const Vector &k, double shift) const |
Return an Operator representing (dF/dk shift + dF/dx) at the given x, k, and the currently set 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 int | SUNImplicitSetup (const Vector &x, const Vector &fx, int jok, int *jcur, double gamma) |
Setup the ODE linear system \( A(x,t) = (I - gamma J) \) or \( A = (M - gamma J) \), where \( J(x,t) = \frac{df}{dt(x,t)} \). More... | |
virtual int | SUNImplicitSolve (const Vector &b, Vector &x, double tol) |
Solve the ODE linear system \( A x = b \) as setup by the method SUNImplicitSetup(). More... | |
virtual int | SUNMassSetup () |
Setup the mass matrix in the ODE system \( M y' = f(y,t) \) . More... | |
virtual int | SUNMassSolve (const Vector &b, Vector &x, double tol) |
Solve the mass matrix linear system \( M x = b \) as setup by the method SUNMassSetup(). More... | |
virtual int | SUNMassMult (const Vector &x, Vector &v) |
Compute the mass matrix-vector product \( v = M x \) . More... | |
virtual | ~TimeDependentOperator () |
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... | |
Protected Attributes | |
int | adjoint_height |
Protected Attributes inherited from mfem::TimeDependentOperator | |
double | t |
Current time. More... | |
Type | type |
Describes the form of the TimeDependentOperator. More... | |
EvalMode | eval_mode |
Current evaluation mode. 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... | |
TimeDependentAdjointOperator is a TimeDependentOperator with Adjoint rate equations to be used with CVODESSolver.
Definition at line 505 of file operator.hpp.
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inline |
The TimedependentAdjointOperator extends the TimeDependentOperator class to use features in SUNDIALS CVODESSolver for computing quadratures and solving adjoint problems.
To solve adjoint problems one needs to implement the AdjointRateMult method to tell CVODES what the adjoint rate equation is.
QuadratureIntegration (optional) can be used to compute values over the forward problem
QuadratureSensitivityMult (optional) can be used to find the sensitivity of the quadrature using the adjoint solution in part.
SUNImplicitSetupB (optional) can be used to setup custom solvers for the newton solve for the adjoint problem.
SUNImplicitSolveB (optional) actually uses the solvers from SUNImplicitSetupB to solve the adjoint problem.
See SUNDIALS user manuals for specifics.
[in] | dim | Dimension of the forward operator |
[in] | adjdim | Dimension of the adjoint operator. Typically it is the same size as dim. However, SUNDIALS allows users to specify the size if one wants to perform custom operations. |
[in] | t | Starting time to set |
[in] | type | The TimeDependentOperator type |
Definition at line 538 of file operator.hpp.
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inlinevirtual |
Destructor.
Definition at line 545 of file operator.hpp.
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pure virtual |
Perform the action of the operator: yBdot = k = f(y,@2 yB, t), where.
[in] | y | The primal solution at time t |
[in] | yB | The adjoint solution at time t |
[out] | yBdot | the rate at time t |
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Returns the size of the adjoint problem state space.
Definition at line 621 of file operator.hpp.
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inlinevirtual |
Provide the operator integration of a quadrature equation.
[in] | y | The current value at time t |
[out] | qdot | The current quadrature rate value at t |
Definition at line 553 of file operator.hpp.
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inlinevirtual |
Provides the sensitivity of the quadrature w.r.t to primal and adjoint solutions.
[in] | y | the value of the primal solution at time t |
[in] | yB | the value of the adjoint solution at time t |
[out] | qBdot | the value of the sensitivity of the quadrature rate at time t |
Definition at line 574 of file operator.hpp.
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inlinevirtual |
Setup the ODE linear system \( A(x,t) = (I - gamma J) \) or \( A = (M - gamma J) \), where \( J(x,t) = \frac{df}{dt(x,t)} \).
[in] | t | The current time |
[in] | x | The state at which \(A(x,xB,t)\) should be evaluated. |
[in] | xB | The state at which \(A(x,xB,t)\) should be evaluated. |
[in] | fxB | The current value of the ODE rhs function, \(f(x,t)\). |
[in] | jokB | Flag indicating if the Jacobian should be updated. |
[out] | jcurB | Flag to signal if the Jacobian was updated. |
[in] | gammaB | The scaled time step value. |
If not re-implemented, this method simply generates an error.
Presently, this method is used by SUNDIALS ODE solvers, for more details, see the SUNDIALS User Guides.
Definition at line 593 of file operator.hpp.
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inlinevirtual |
Solve the ODE linear system \( A(x,xB,t) xB = b \) as setup by the method SUNImplicitSetup().
[in] | b | The linear system right-hand side. |
[in,out] | x | On input, the initial guess. On output, the solution. |
[in] | tol | Linear solve tolerance. |
If not re-implemented, this method simply generates an error.
Presently, this method is used by SUNDIALS ODE solvers, for more details, see the SUNDIALS User Guides.
Definition at line 613 of file operator.hpp.
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protected |
Definition at line 624 of file operator.hpp.