libtrilinos-thyra-dev 12.4.2-2 / usr / include / trilinos / Thyra_PreconditionerFactoryBase_decl.hpp

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#ifndef THYRA_PRECONDITIONER_FACTORY_BASE_DECL_HPP
#define THYRA_PRECONDITIONER_FACTORY_BASE_DECL_HPP

#include "Thyra_PreconditionerBase.hpp"
#include "Thyra_LinearOpSourceBase.hpp"
#include "Teuchos_Describable.hpp"
#include "Teuchos_ParameterListAcceptor.hpp"
#include "Teuchos_VerboseObject.hpp"


namespace Thyra {


/** \brief Factory interface for creating preconditioner objects from
 * <tt>LinearOpBase</tt> objects.
 *
 * \ingroup Thyra_Op_Solve_fundamental_interfaces_code_grp
 *
 * ToDo: Finish documentation!
 */
template<class Scalar>
class PreconditionerFactoryBase
  : virtual public Teuchos::Describable,
    virtual public Teuchos::ParameterListAcceptor,
    virtual public Teuchos::VerboseObject<PreconditionerFactoryBase<Scalar> >
{
public:

  /** @name Pure virtual public functions that must be overridden in subclasses */
  //@{

  /** \brief Check that a <tt>LinearOpBase</tt> object is compatible with
   * <tt>*this</tt> factory object.
   */
  virtual bool isCompatible(const LinearOpSourceBase<Scalar> &fwdOpSrc) const = 0;

  /** \brief Create an (uninitialized) <tt>LinearOpBase</tt> object to be
   * initalized as the preconditioner later in
   * <tt>this->initializePrecOp()</tt>.
   *
   * Note that on output <tt>return->domain().get()==NULL</tt> may be true
   * which means that the operator is not fully initialized.  In fact, the
   * output operator object is not guaranteed to be fully initialized until
   * after it is passed through <tt>this->initializePrecOp()</tt>.
   */
  virtual RCP<PreconditionerBase<Scalar> > createPrec() const = 0;

  /** \brief Initialize a pre-created <tt>LinearOpBase</tt> preconditioner
   * object given a "compatible" <tt>LinearOpBase</tt> object.
   *
   * \param fwdOpSrc [in] The forward linear operator that will be used to
   * create the output <tt>LinearOpBase</tt> preconditioner object.  Note that
   * this object is remembered by the <tt>*Op</tt> object on output.
   *
   * \param prec [in/out] The output <tt>PreconditionerBase</tt>
   * preconditioner object.  This object must have be created first by
   * <tt>this->createPrec()</tt>.  The object may have also already been
   * passed through this function several times.  Note that subclasses should
   * always first strip off the transpose and scaling by calling
   * <tt>unwrap()</tt> before attempting to dynamic cast the object.
   *
   * \param supportSolveUse [in] Determines if <tt>apply()</tt> and/or
   * <tt>applyTranspose()</tt> will be called on the initialized
   * preconditioner operators.  This allows <tt>*this</tt> factory object
   * determine how to best initialize the <tt>*prec</tt> object.  Default
   * <tt>supportSolveUse=SUPPORT_SOLVE_UNSPECIFIED</tt>
   *
   * <b>Preconditions:</b><ul>
   *
   * <li><tt>fwdOpSrc.get()!=NULL</tt>
   *
   * <li><tt>this->isCompatible(*fwdOpSrc)==true</tt>
   *
   * <li><tt>prec!=NULL</tt>
   *
   * <li><tt>*prec</tt> must have been created by <tt>this->createPrec()</tt>
   * prior to calling this function.
   *
   * <li>[<tt>supportSolveUse==SUPPORT_SOLVE_FORWARD_ONLY<tt>]
   * <tt>this->applySupportsConj(conj)==true</tt> for any value of
   * <tt>conj</tt>
   *
   * <li>[<tt>supportSolveUse==SUPPORT_SOLVE_TRANSPOSE_ONLY<tt>]
   * <tt>this->applyTransposeSupportsConj(conj)==true</tt> for any value of
   * <tt>conj</tt>
   *
   * <li>[<tt>supportSolveUse==SUPPORT_SOLVE_FORWARD_AND_TRANSPOSE<tt>]
   * <tt>this->applySupportsConj(conj)==true &&
   * this->applyTransposeSupportsConj(conj)==true</tt> for any value of
   * <tt>conj</tt>
   *
   * </ul>
   *
   * <b>Postconditions:</b><ul>
   *
   * <li>Throws <tt>CatastrophicSolveFailure</tt> if the preconditioner could
   * not be created successfully (e.g. due to a factorization failure or some
   * other cause).
   *
   * <li><tt>precOp->range()->isCompatible(*fwdOpSrc->domain())==true</tt>
   *
   * <li><tt>precOp->domain()->isCompatible(*fwdOpSrc->range())==true</tt>
   *
   * <li><t>precOp->applySupportsConj(conj)==this->applySupportsConj(conj)</tt>
   *
   * <li><t>precOp->applyTransposeSupportsConj(conj) ==
   * this->applyTransposeSupportsConj(conj)</tt>
   *
   * <li><tt>fwdOpSrc.count()</tt> after output is greater than
   * <tt>fwdOpSrc.count()</tt> just before this call and therefore the client
   * can assume that the <tt>*fwdOpSrc</tt> object will be remembered by the
   * <tt>*prec</tt> object.  The client must be careful not to modify the
   * <tt>*fwdOpSrc</tt> object or else the <tt>*precOp</tt> object may also be
   * modified and become invalid.
   *
   * </ul>
   */
  virtual void initializePrec(
    const RCP<const LinearOpSourceBase<Scalar> > &fwdOpSrc,
    PreconditionerBase<Scalar> *precOp,
    const ESupportSolveUse supportSolveUse = SUPPORT_SOLVE_UNSPECIFIED
    ) const = 0;

  /** \brief Uninitialize a <tt>LinearOpBase</tt> preconditioner object and
   * return its remembered forward linear operator.
   *
   * \param prec [in/out] On input, <tt>*precOp</tt> is an initialized or
   * uninitialized object and on output is uninitialized.  Note that
   * "uninitialized" does not mean that <tt>precOp</tt> is completely
   * stateless.  It may still remember some aspect of the matrix
   * <tt>fwdOpSrc</tt> that will allow for a more efficient initialization
   * next time through <tt>this->initializePrecOp()</tt>.
   *
   * \param fwdOpSrc [in/out] If <tt>fwdOpSrc!=NULL</tt> on input, then on
   * output this is set to same forward operator passed into
   * <tt>this->initializePrecOp()</tt>.
   *
   * \param ESupportSolveUse [in/out] If <tt>precOpType!=NULL</tt> on input,
   * then on output this is set to same option value passed to
   * <tt>this->initializePrecOp()</tt>.
   *
   * <b>Preconditions:</b><ul>
   *
   * <li><tt>*precOp</tt> must have been created by
   * <tt>this->createPrecOp()</tt> prior to calling this function.
   *
   * <li><tt>precOp</tt> may or may not have been passed through a call to
   * <tt>this->initializePrecOp()</tt>.
   *
   * </ul>
   *
   * <b>Postconditions:</b><ul>
   *
   * <li>If <tt>*precOp</tt> on input was initialized through a call to
   * <tt>this->initializePrecOp()</tt> then <tt>return.get()!=NULL</tt>.
   *
   * <li>If <tt>*precOp</tt> was uninitialized on input and
   * <tt>fwdOpSrc!=NULL</tt> then <tt>fwdOpSrc->get()==NULL</tt> on output.
   *
   * <li>On output, <tt>*precOp</tt> can be considered to be uninitialized and
   * it is safe to modify the forward operator object <tt>*(*fwdOpSrc)</tt>
   * returned in <tt>fwdOpSrc</tt>.  The default is <tt>fwdOpSrc==NULL</tt> in
   * which case the forward operator will not be returned in
   * <tt>*fwdOpSrc</tt>.
   *
   * </ul>
   *
   * This function should be called before the forward operator passed in to
   * <tt>this->initializePrecOp()</tt> is modified.  Otherwise, <tt>*this</tt>
   * could be left in an inconsistent state.  However, this is not required.
   */
  virtual void uninitializePrec(
    PreconditionerBase<Scalar> *prec,
    RCP<const LinearOpSourceBase<Scalar> > *fwdOpSrc = NULL,
    ESupportSolveUse *supportSolveUse = NULL
    ) const = 0;
  
  //@}

  /** @name Virtual public functions with default implementations */
  //@{

  /** \brief Return if <tt>precOp->apply()</tt> supports the argument
   * <tt>conj</tt>.
   *
   * The default implementation returns <tt>true</tt> for real valued scalar
   * types or when <tt>conj==NONCONJ_ELE</tt> for complex valued types.
   */
  virtual bool applySupportsConj(EConj conj) const;

  /** \brief Return if <tt>precOp->solveTranspose()</tt> supports the argument
   * <tt>conj</tt>.
   *
   * The default implementation returns <tt>false</tt>.
   */
  virtual bool applyTransposeSupportsConj(EConj conj) const;

  //@}

private:
  
  // Not defined and not to be called
  PreconditionerFactoryBase<Scalar>&
  operator=(const PreconditionerFactoryBase<Scalar>&);

};


} // namespace Thyra


#endif // THYRA_PRECONDITIONER_FACTORY_BASE_DECL_HPP