libtrilinos-teko-dev 12.12.1-5 / usr / include / trilinos / Teko_LSCSIMPLECStrategy.hpp

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#ifndef __Teko_LSCSIMPLECStrategy_hpp__
#define __Teko_LSCSIMPLECStrategy_hpp__

#include "Teko_LSCStrategy.hpp"

namespace Teko {
namespace NS {

class LSCPrecondState; // forward declration

/** \brief A strategy that takes a single inverse factory and
  *        uses that for all inverses. If no mass matrix is 
  *        passed in the diagonal of the 1,1 block is used.
  *
  * A strategy that takes a single inverse factory and uses that
  * for all inverses. Optionally the mass matrix can be passed
  * in, if it is the diagonal is extracted and that is used to
  * form the inverse approximation.
  */
class LSCSIMPLECStrategy : public LSCStrategy {
public:
   //! \name Constructors
   //@{
   LSCSIMPLECStrategy();
   //@}

   virtual ~LSCSIMPLECStrategy() {}

   //! Functions inherited from LSCStrategy
   //@{

   /** This informs the strategy object to build the state associated
     * with this operator.
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     */
   virtual void buildState(BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Get the inverse of \f$B Q_u^{-1} B^T\f$. 
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     *
     * \returns An (approximate) inverse of \f$B Q_u^{-1} B^T\f$.
     */
   virtual LinearOp getInvBQBt(const BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Get the inverse of \f$B H B^T - \gamma C\f$. 
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     *
     * \returns An (approximate) inverse of \f$B H B^T - \gamma C\f$.
     */
   virtual LinearOp getInvBHBt(const BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Get the inverse of the \f$F\f$ block.
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     *
     * \returns An (approximate) inverse of \f$F\f$.
     */
   virtual LinearOp getInvF(const BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Get the inverse for stabilizing the whole schur complement approximation.
     * Returns \f$\alpha D^{-1}\f$.
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     *
     * \returns The operator to stabilize the whole Schur complement.
     */
   virtual LinearOp getOuterStabilization(const BlockedLinearOp & A,BlockPreconditionerState & state) const
   { return Teuchos::null; }

   virtual LinearOp getInnerStabilization(const BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Get the inverse mass matrix.
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     *
     * \returns The inverse of the mass matrix \f$Q_u\f$.
     */
   virtual LinearOp getInvMass(const BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Get the \f$H\f$ scaling matrix.
     *
     * \param[in] A The linear operator to be preconditioned by LSC.
     * \param[in] state State object for storying reusable information about
     *                  the operator A.
     *
     * \returns The \f$H\f$ scaling matrix.
     */
   virtual LinearOp getHScaling(const BlockedLinearOp & A,BlockPreconditionerState & state) const;

   /** Should the approximation of the inverse use a full LDU decomposition, or
     * is a upper triangular approximation sufficient.
     *
     * \returns True if the full LDU decomposition should be used, otherwise
     *          only an upper triangular version is used.
     */
   virtual bool useFullLDU() const { return useFullLDU_; }

   //! Initialize from a parameter list
   virtual void initializeFromParameterList(const Teuchos::ParameterList & pl,
                                            const InverseLibrary & invLib); 

   //! Initialize the state object using this blocked linear operator
   virtual void initializeState(const BlockedLinearOp & A,LSCPrecondState * state) const;

   /** Compute the inverses required for the LSC Schur complement
     *
     * \note This method assumes that the BQBt and BHBt operators have
     *       been constructed.
     */
   void computeInverses(const BlockedLinearOp & A,LSCPrecondState * state) const;

   //! Set to true to use the Full LDU decomposition, false otherwise
   virtual void setUseFullLDU(bool val) { useFullLDU_ = val; }

   virtual void setSymmetric(bool isSymmetric) { }

protected:
   // how to invert the matrices
   Teuchos::RCP<InverseFactory> invFactoryF_;
   Teuchos::RCP<InverseFactory> invFactoryS_;

   // flags for handling various options
   bool useFullLDU_;
   DiagonalType scaleType_; 

private:
   LSCSIMPLECStrategy(const LSCSIMPLECStrategy &);
};

} // end namespace NS
} // end namespace Teko

#endif