/usr/include/trilinos/Rythmos_ImplicitBDFStepperRampingStepControl_decl.hpp is in libtrilinos-rythmos-dev 12.12.1-5.
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// ***********************************************************************
//
// Rythmos Package
// Copyright (2006) Sandia Corporation
//
// Under terms of Contract DE-AC04-94AL85000, there is a non-exclusive
// license for use of this work by or on behalf of the U.S. Government.
//
// This library is free software; you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as
// published by the Free Software Foundation; either version 2.1 of the
// License, or (at your option) any later version.
//
// This library is distributed in the hope that it will be useful, but
// WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
// Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public
// License along with this library; if not, write to the Free Software
// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301
// USA
// Questions? Contact Todd S. Coffey (tscoffe@sandia.gov)
//
// ***********************************************************************
//@HEADER
#ifndef Rythmos_IMPLICITBDF_STEPPER_RAMPING_STEP_CONTROL_DECL_H
#define Rythmos_IMPLICITBDF_STEPPER_RAMPING_STEP_CONTROL_DECL_H
#include "Rythmos_ErrWtVecCalcAcceptingStepControlStrategyBase.hpp"
#include "Rythmos_ImplicitBDFStepperStepControl.hpp" // for BDFactionFlag definition
namespace Rythmos {
/** \brief . */
//enum BDFactionFlag { ACTION_UNSET, ACTION_LOWER, ACTION_MAINTAIN, ACTION_RAISE };
/** \brief Ramping Step Control Strategy object for ImplicitBDFStpper
*
* This object is a special step control strategy to manage the
* startup of simulations form an inconsistent state or to startup a
* simulation for an order of accuracy study. The strategy follows
* the pattern:
*
* 1. An initial startup phase with constant initial time step
* (failures can reduce the time step) at 1st order.
*
* 2. A second phase with constant time step that increases the order
* to max order.
*
* 3. A ramping phase that runs at max order and increases the time
* step up to the max time step. LTE control during the ramping phase
* is optional.
*
* 4. Time integration phase that runs at max step size and max order.
//
// Order of calls: setRequestedStepSize() nextStepSize() optional:
// nextStepOrder() setCorrection acceptStep completeStep or
// rejectStep repeat
//
// 08/16/07 tscoffe: This order of operations must be enforced through
// preconditions or I need to re-think how to set up the interface for this
// strategy object.
*/
template<class Scalar>
class ImplicitBDFStepperRampingStepControl
: virtual public ErrWtVecCalcAcceptingStepControlStrategyBase<Scalar>
{
public:
typedef typename Teuchos::ScalarTraits<Scalar>::magnitudeType ScalarMag;
ImplicitBDFStepperRampingStepControl();
/** \name Overridden from StepControlStrategyBase */
//@{
/** \brief . */
void setRequestedStepSize(const StepperBase<Scalar>& stepper,
const Scalar& stepSize, const StepSizeType& stepSizeType);
/** \brief . */
void nextStepSize(const StepperBase<Scalar>& stepper, Scalar* stepSize,
StepSizeType* stepSizeType, int* order);
/** \brief . */
void setCorrection(
const StepperBase<Scalar>& stepper
,const RCP<const Thyra::VectorBase<Scalar> >& soln
,const RCP<const Thyra::VectorBase<Scalar> >& ee
,int solveStatus
);
/** \brief . */
bool acceptStep(const StepperBase<Scalar>& stepper, Scalar* LETValue);
/** \brief . */
void completeStep(const StepperBase<Scalar>& stepper);
/** \brief . */
AttemptedStepStatusFlag rejectStep(const StepperBase<Scalar>& stepper);
/** \brief . */
StepControlStrategyState getCurrentState();
/** \brief . */
int getMinOrder() const;
/** \brief . */
int getMaxOrder() const;
/** \brief . */
void setStepControlData(const StepperBase<Scalar>& stepper);
/** \brief . */
bool supportsCloning() const;
/** \brief . */
RCP<StepControlStrategyBase<Scalar> > cloneStepControlStrategyAlgorithm() const;
//@}
/** \name Overridden from ErrWtVecCalcAcceptingStepControlStrategyBase */
//@{
/** \brief . */
void setErrWtVecCalc(const RCP<ErrWtVecCalcBase<Scalar> >& errWtVecCalc);
/** \brief . */
RCP<const ErrWtVecCalcBase<Scalar> > getErrWtVecCalc() const;
//@}
/** \name Overridden from Teuchos::Describable */
//@{
/** \brief . */
void describe(
Teuchos::FancyOStream &out,
const Teuchos::EVerbosityLevel verbLevel
) const;
//@}
/** \name Overridden from ParameterListAcceptor */
//@{
/** \brief . */
void setParameterList(RCP<Teuchos::ParameterList> const& paramList);
/** \brief . */
RCP<Teuchos::ParameterList> getNonconstParameterList();
/** \brief . */
RCP<Teuchos::ParameterList> unsetParameterList();
/** \brief . */
RCP<const Teuchos::ParameterList> getValidParameters() const;
//@}
/** \brief . */
void initialize(const StepperBase<Scalar>& stepper);
/** \name Accessor functions (used for testing) */
//@{
int numberOfSteps() const;
int numberOfFailedSteps() const;
Scalar currentStepSize() const;
int currentOrder() const;
//@}
private:
Scalar wRMSNorm_(
const Thyra::VectorBase<Scalar>& weight,
const Thyra::VectorBase<Scalar>& vector
) const;
void setStepControlState_(StepControlStrategyState state);
void updateCoeffs_();
//* returns true if the objects verbosity level is equal to or greater than level in verbLevel */
bool doOutput_(Teuchos::EVerbosityLevel verbLevel);
protected:
StepControlStrategyState stepControlState_;
RCP<ErrWtVecCalcBase<Scalar> > errWtVecCalc_;
RCP<Teuchos::ParameterList> parameterList_;
StepSizeType stepSizeType_;
Scalar requestedStepSize_;
Scalar currentStepSize_;
int currentOrder_;
Scalar nextStepSize_;
int nextOrder_;
int numberOfSteps_;
int totalNumberOfFailedSteps_;
int countOfConstantStepsAfterFailure_;
int newtonConvergenceStatus_;
Scalar time_;
Scalar stopTime_;
RCP<const Thyra::VectorBase<Scalar> > ee_; // Newton update
RCP<Thyra::VectorBase<Scalar> > errWtVec_; // error weight vector
RCP<Thyra::VectorBase<Scalar> > delta_;
ScalarMag relErrTol_; // relative error tolerance
ScalarMag absErrTol_; // absolute error tolerance
// Validated parameters
int numConstantSteps_;
Scalar initialStepSize_;
Scalar maxStepSize_;
Scalar minStepSize_;
Scalar stepSizeIncreaseFactor_;
Scalar stepSizeDecreaseFactor_;
int minOrder_;
int maxOrder_;
bool useLETToDetermineConvergence_;
bool restrictStepSizeByNumberOfNonlinearIterations_;
int numberOfNonlinearIterationsForStepSizeRestriction_;
std::vector<Scalar> breakPoints_; // from user params (stor for reset)
std::list<Scalar> currentBreakPoints_; // break points left
// Garbage to clean up for LET
Array<Scalar> alpha_; // $\alpha_j(n)=h_n/\psi_j(n)$ coefficient used in local error test
// note: $h_n$ = current step size, n = current time step
Array<Scalar> sigma_; // $\sigma_j(n) = \frac{h_n^j(j-1)!}{\psi_1(n)*\cdots *\psi_j(n)}$
Array<Scalar> gamma_; // $\gamma_j(n)=\sum_{l=1}^{j-1}1/\psi_l(n)$ coefficient used to
// calculate time derivative of history array for predictor
Array<Scalar> beta_; // coefficients used to evaluate predictor from history array
Array<Scalar> psi_; // $\psi_j(n) = t_n-t_{n-j}$ intermediary variable used to
// compute $\beta_j(n)$
Scalar alpha_s_; // $\alpha_s$ fixed-leading coefficient of this BDF method
Scalar alpha_0_; // $-\sum_{j=1}^k \alpha_j(n)$ coefficient used in local error test
Scalar cj_ ; // $-\alpha_s/h_n$ coefficient used in local error test
Scalar ck_ ; // local error coefficient gamma[0] = 0;
Scalar ck_enorm_; // ck * enorm
};
} // namespace Rythmos
#endif // Rythmos_IMPLICITBDF_STEPPER_STEP_CONTROL_DECL_H
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