/usr/include/trilinos/Teko_LU2x2Strategy.hpp is in libtrilinos-teko-dev 12.4.2-2.
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// Teko: A package for block and physics based preconditioning
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#ifndef __Teko_LU2x2Strategy_hpp__
#define __Teko_LU2x2Strategy_hpp__
#include "Teuchos_RCP.hpp"
#include "Thyra_LinearOpBase.hpp"
#include "Teko_Utilities.hpp"
#include "Teko_InverseFactory.hpp"
#include "Teko_BlockPreconditionerFactory.hpp"
namespace Teko {
/** @brief Abstract strategy for computing inv(F) and inv(S) in the
* LU2x2PreconditionerFactory.
*
* This should be paired with a LU2x2PreconditionerFactory,
* it build the \f$A_{00}^{-1}\f$ and \f$S\f$ opreators. Building an approximate
* inverse of this system
*
* \f$
* A = \left[
* \begin{array}{cc}
* A_{00} & A_{01} \\
* A_{10} & A_{11}
* \end{array}
* \right]
* \f$
*
* using a 2x2 block LDU decomposition gives
*
* \f$
* A = \left[
* \begin{array}{cc}
* I & 0 \\
* A_{10} A_{00}^{-1} & I
* \end{array}
* \right]
* \left[
* \begin{array}{cc}
* A_{00} & 0 \\
* 0 & -S
* \end{array}
* \right]
* \left[
* \begin{array}{cc}
* I & A_{00}^{-1} A_{01} \\
* 0 & I
* \end{array}
* \right]
* \f$
*
* where the Shur complement is \f$ S = -A_{11} + A_{10} A_{00}^{-1} A_{01} \f$
* To invert \f$ A \f$, \f$ A_{00}^{-1} \f$ and \f$ S^{-1} \f$ are required. The idea
* of this strategy is to give those operators.
*/
class LU2x2Strategy {
public:
virtual ~LU2x2Strategy() {}
/** returns the first (approximate) inverse of \f$A_{00}\f$ */
virtual const Teko::LinearOp
getHatInvA00(const Teko::BlockedLinearOp & A,BlockPreconditionerState & state) const = 0;
/** returns the scond (approximate) inverse of \f$A_{00}\f$ */
virtual const Teko::LinearOp
getTildeInvA00(const Teko::BlockedLinearOp & A,BlockPreconditionerState & state) const = 0;
/** returns an (approximate) inverse of \f$S = -A_{11} + A_{10} A_{00}^{-1} A_{01}\f$ */
virtual const Teko::LinearOp
getInvS(const Teko::BlockedLinearOp & A,BlockPreconditionerState & state) const = 0;
/** \brief This function builds the internals of the state from a parameter list.
*
* This function builds the internals of the LU 2x2 state
* from a parameter list. Furthermore, it allows a
* developer to easily add a factory to the build system.
*
* \param[in] settings Parameter list to use as the internal settings
* \param[in] invLib Inverse library to use for building inverse factory objects
*
* \note The default implementation does nothing.
*/
virtual void initializeFromParameterList(const Teuchos::ParameterList & settings,
const InverseLibrary & invLib)
{ }
/** \brief Request the additional parameters this preconditioner factory
* needs.
*
* Request the additonal parameters needed by this preconditioner factory.
* The parameter list will have a set of fields that can be filled with
* the requested values. These fields include all requirements, even those
* of the sub-solvers if there are any. Once correctly filled the object
* can be updated by calling the updateRequestedParameters with the filled
* parameter list.
*
* \returns A parameter list with the requested parameters.
*
* \note The default implementation returns Teuchos::null.
*/
virtual Teuchos::RCP<Teuchos::ParameterList> getRequestedParameters() const
{ return Teuchos::null; }
/** \brief Update this object with the fields from a parameter list.
*
* Update the requested fields using a parameter list. This method is
* expected to pair with the getRequestedParameters method (i.e. the fields
* requested are going to be update using this method).
*
* \param[in] pl Parameter list containing the requested parameters.
*
* \returns If the method succeeded (found all its required parameters) this
* method returns true, otherwise it returns false.
*
* \note The default implementation returns true (it does nothing!).
*/
virtual bool updateRequestedParameters(const Teuchos::ParameterList & pl)
{ return true; }
//! This method sets the request handler for this object
void setRequestHandler(const Teuchos::RCP<RequestHandler> & rh)
{ requestHandler_ = rh; }
//! This method gets the request handler uses by this object
Teuchos::RCP<RequestHandler> getRequestHandler() const
{ return requestHandler_; }
private:
Teuchos::RCP<RequestHandler> requestHandler_;
};
/** @brief A simple strategy for use with LU2x2PreconditionerFactory, that
* offers static objects for inv(F) and inv(S)
*
* This is a simple startegy for a LU2x2PreconditionerFactory
* it simply returns statically set RCP pointers to the passed in
* inv(F) and inv(Schur) operators. Note this will not permit
* efficient implementations when the preconditioner has to be rebuilt
*/
class StaticLU2x2Strategy : public LU2x2Strategy {
public:
/** @brief Constructor that takes the static \f$A_{00}^{-1}\f$ and \f$S^{-1}\f$ objects
*
* Constructor that takes the static \f$A_{00}^{-1}\f$ and \f$S^{-1}\f$ objects.
*
* @param[in] hInvA00 Inverse of \f$\hat{A}_{00}\f$ in the source matrix.
* @param[in] tInvA00 Inverse of \f$\tilde{A}_{00}\f$ in the source matrix.
* @param[in] invS Inverse of the Schur complement of the source matrix.
*/
StaticLU2x2Strategy(const Teko::LinearOp & hInvA00,
const Teko::LinearOp & tInvA00,
const Teko::LinearOp & invS)
: hatInvA00_(hInvA00), tildeInvA00_(tInvA00), invS_(invS)
{}
virtual ~StaticLU2x2Strategy() {}
/** @name Methods inherited from LU2x2Strategy. */
//@{
/** returns a static (approximate) inverse of F */
virtual const Teko::LinearOp
getHatInvA00(const Teko::BlockedLinearOp & A,BlockPreconditionerState & state) const
{ return hatInvA00_; }
/** returns a static (approximate) inverse of F */
virtual const Teko::LinearOp
getTildeInvA00(const Teko::BlockedLinearOp & A,BlockPreconditionerState & state) const
{ return tildeInvA00_; }
/** returns a static (approximate) inverse of S = -D + L*inv(F)*U */
virtual const Teko::LinearOp
getInvS(const Teko::BlockedLinearOp & A,BlockPreconditionerState & state) const
{ return invS_; }
//@}
protected:
const Teko::LinearOp hatInvA00_; /**< Stored value of \f$\hat{A}_{00}^{-1}\f$ */
const Teko::LinearOp tildeInvA00_; /**< Stored value of \f$\tilde{A}_{00}^{-1}\f$ */
const Teko::LinearOp invS_; /**< Stored value of \f$S^{-1}\f$ */
private:
// hide me!
StaticLU2x2Strategy() {}
};
} // end namespace Teko
#endif
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