/usr/include/trilinos/Rythmos_StepperHelpers_def.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_STEPPER_HELPERS_DEF_HPP
#define RYTHMOS_STEPPER_HELPERS_DEF_HPP
#include "Rythmos_StepperHelpers_decl.hpp"
#include "Rythmos_InterpolationBufferHelpers.hpp"
#include "Rythmos_InterpolatorBaseHelpers.hpp"
#include "Teuchos_Assert.hpp"
#include "Thyra_AssertOp.hpp"
#include "Thyra_VectorStdOps.hpp"
namespace Rythmos {
using Teuchos::ConstNonconstObjectContainer;
template<class Scalar>
void assertValidModel(
const StepperBase<Scalar>& stepper,
const Thyra::ModelEvaluator<Scalar>& model
)
{
typedef Thyra::ModelEvaluatorBase MEB;
TEUCHOS_ASSERT(stepper.acceptsModel());
const MEB::InArgs<Scalar> inArgs = model.createInArgs();
const MEB::OutArgs<Scalar> outArgs = model.createOutArgs();
//TEUCHOS_ASSERT(inArgs.supports(MEB::IN_ARG_t));
TEUCHOS_ASSERT(inArgs.supports(MEB::IN_ARG_x));
TEUCHOS_ASSERT(outArgs.supports(MEB::OUT_ARG_f));
if (stepper.isImplicit()) { // implicit stepper
TEUCHOS_ASSERT( inArgs.supports(MEB::IN_ARG_x_dot) );
TEUCHOS_ASSERT( inArgs.supports(MEB::IN_ARG_alpha) );
TEUCHOS_ASSERT( inArgs.supports(MEB::IN_ARG_beta) );
TEUCHOS_ASSERT( outArgs.supports(MEB::OUT_ARG_W) );
}
//else { // explicit stepper
// TEUCHOS_ASSERT( !inArgs.supports(MEB::IN_ARG_x_dot) );
// TEUCHOS_ASSERT( !inArgs.supports(MEB::IN_ARG_alpha) );
// TEUCHOS_ASSERT( !inArgs.supports(MEB::IN_ARG_beta) );
// TEUCHOS_ASSERT( !outArgs.supports(MEB::OUT_ARG_W) );
//}
}
template<class Scalar>
bool setDefaultInitialConditionFromNominalValues(
const Thyra::ModelEvaluator<Scalar>& model,
const Ptr<StepperBase<Scalar> >& stepper
)
{
typedef ScalarTraits<Scalar> ST;
typedef Thyra::ModelEvaluatorBase MEB;
if (isInitialized(*stepper))
return false; // Already has an initial condition
MEB::InArgs<Scalar> initCond = model.getNominalValues();
if (!is_null(initCond.get_x())) {
// IC has x, we will assume that initCont.get_t() is the valid start time.
// Therefore, we just need to check that x_dot is also set or we will
// create a zero x_dot
#ifdef HAVE_RYTHMOS_DEBUG
THYRA_ASSERT_VEC_SPACES( "setInitialConditionIfExists(...)",
*model.get_x_space(), *initCond.get_x()->space() );
#endif
if (initCond.supports(MEB::IN_ARG_x_dot)) {
if (is_null(initCond.get_x_dot())) {
const RCP<Thyra::VectorBase<Scalar> > x_dot =
createMember(model.get_x_space());
assign(x_dot.ptr(), ST::zero());
}
else {
#ifdef HAVE_RYTHMOS_DEBUG
THYRA_ASSERT_VEC_SPACES( "setInitialConditionIfExists(...)",
*model.get_x_space(), *initCond.get_x_dot()->space() );
#endif
}
}
stepper->setInitialCondition(initCond);
return true;
}
// The model has not nominal values for which to set the initial
// conditions so wo don't do anything! The stepper will still have not
return false;
}
template<class Scalar>
void restart( StepperBase<Scalar> *stepper )
{
#ifdef HAVE_RYTHMOS_DEBUG
TEUCHOS_TEST_FOR_EXCEPT(0==stepper);
#endif // HAVE_RYTHMOS_DEBUG
typedef Thyra::ModelEvaluatorBase MEB;
const Rythmos::StepStatus<double>
stepStatus = stepper->getStepStatus();
const RCP<const Thyra::ModelEvaluator<Scalar> >
model = stepper->getModel();
// First, copy all of the model's state, including parameter values etc.
MEB::InArgs<double> initialCondition = model->createInArgs();
initialCondition.setArgs(model->getNominalValues());
// Set the current values of the state and time
RCP<const Thyra::VectorBase<double> > x, x_dot;
Rythmos::get_x_and_x_dot(*stepper,stepStatus.time,&x,&x_dot);
initialCondition.set_x(x);
initialCondition.set_x_dot(x_dot);
initialCondition.set_t(stepStatus.time);
// Set the new initial condition back on the stepper. This will effectively
// reset the stepper to think that it is starting over again (which it is).
stepper->setInitialCondition(initialCondition);
}
template<class Scalar>
void eval_model_explicit(
const Thyra::ModelEvaluator<Scalar> &model,
Thyra::ModelEvaluatorBase::InArgs<Scalar> &basePoint,
const VectorBase<Scalar>& x_in,
const typename Thyra::ModelEvaluatorBase::InArgs<Scalar>::ScalarMag &t_in,
const Ptr<VectorBase<Scalar> >& f_out,
const Scalar scaled_dt,
const Scalar stage_point
)
{
typedef Thyra::ModelEvaluatorBase MEB;
MEB::InArgs<Scalar> inArgs = model.createInArgs();
MEB::OutArgs<Scalar> outArgs = model.createOutArgs();
inArgs.setArgs(basePoint);
inArgs.set_x(Teuchos::rcp(&x_in,false));
if (inArgs.supports(MEB::IN_ARG_t)) {
inArgs.set_t(t_in);
}
// For model evaluators whose state function f(x, x_dot, t) describes
// an implicit ODE, and which accept an optional x_dot input argument,
// make sure the latter is set to null in order to request the evaluation
// of a state function corresponding to the explicit ODE formulation
// x_dot = f(x, t)
if (inArgs.supports(MEB::IN_ARG_x_dot)) {
inArgs.set_x_dot(Teuchos::null);
}
if (inArgs.supports(MEB::IN_ARG_step_size)) {
inArgs.set_step_size(scaled_dt);
}
if (inArgs.supports(MEB::IN_ARG_stage_number)) {
inArgs.set_stage_number(stage_point);
}
outArgs.set_f(Teuchos::rcp(&*f_out,false));
model.evalModel(inArgs,outArgs);
//inArgs.set_x_dot(Teuchos::null);
}
#ifdef HAVE_THYRA_ME_POLYNOMIAL
template<class Scalar>
void eval_model_explicit_poly(
const Thyra::ModelEvaluator<Scalar> &model,
Thyra::ModelEvaluatorBase::InArgs<Scalar> &basePoint,
const Teuchos::Polynomial< VectorBase<Scalar> > &x_poly,
const typename Thyra::ModelEvaluatorBase::InArgs<Scalar>::ScalarMag &t,
const Ptr<Teuchos::Polynomial<VectorBase<Scalar> > >& f_poly
)
{
typedef Thyra::ModelEvaluatorBase MEB;
MEB::InArgs<Scalar> inArgs = model.createInArgs();
MEB::OutArgs<Scalar> outArgs = model.createOutArgs();
inArgs.setArgs(basePoint);
inArgs.set_x_poly(Teuchos::rcp(&x_poly,false));
if (inArgs.supports(MEB::IN_ARG_t)) {
inArgs.set_t(t);
}
outArgs.set_f_poly(Teuchos::rcp(&*f_poly,false));
model.evalModel(inArgs,outArgs);
}
#endif // HAVE_THYRA_ME_POLYNOMIAL
template<class Scalar>
void defaultGetPoints(
const Scalar& t_old, // required inArg
const Ptr<const VectorBase<Scalar> >& x_old, // optional inArg
const Ptr<const VectorBase<Scalar> >& xdot_old, // optional inArg
const Scalar& t, // required inArg
const Ptr<const VectorBase<Scalar> >& x, // optional inArg
const Ptr<const VectorBase<Scalar> >& xdot, // optional inArg
const Array<Scalar>& time_vec, // required inArg
const Ptr<Array<Teuchos::RCP<const Thyra::VectorBase<Scalar> > > >& x_vec, // optional outArg
const Ptr<Array<Teuchos::RCP<const Thyra::VectorBase<Scalar> > > >& xdot_vec, // optional outArg
const Ptr<Array<typename Teuchos::ScalarTraits<Scalar>::magnitudeType> >& accuracy_vec, // optional outArg
const Ptr<InterpolatorBase<Scalar> > interpolator // optional inArg (note: not const)
)
{
typedef Teuchos::ScalarTraits<Scalar> ST;
assertTimePointsAreSorted(time_vec);
TimeRange<Scalar> tr(t_old, t);
TEUCHOS_ASSERT( tr.isValid() );
if (!is_null(x_vec)) {
x_vec->clear();
}
if (!is_null(xdot_vec)) {
xdot_vec->clear();
}
if (!is_null(accuracy_vec)) {
accuracy_vec->clear();
}
typename Array<Scalar>::const_iterator time_it = time_vec.begin();
RCP<const VectorBase<Scalar> > tmpVec;
RCP<const VectorBase<Scalar> > tmpVecDot;
for (; time_it != time_vec.end() ; time_it++) {
Scalar time = *time_it;
asssertInTimeRange(tr, time);
Scalar accuracy = ST::zero();
if (compareTimeValues(time,t_old)==0) {
if (!is_null(x_old)) {
tmpVec = x_old->clone_v();
}
if (!is_null(xdot_old)) {
tmpVecDot = xdot_old->clone_v();
}
} else if (compareTimeValues(time,t)==0) {
if (!is_null(x)) {
tmpVec = x->clone_v();
}
if (!is_null(xdot)) {
tmpVecDot = xdot->clone_v();
}
} else {
TEUCHOS_TEST_FOR_EXCEPTION(
is_null(interpolator), std::logic_error,
"Error, getPoints: This stepper only supports time values on the boundaries!\n"
);
// At this point, we know time != t_old, time != t, interpolator != null,
// and time in [t_old,t], therefore, time in (t_old,t).
// t_old != t at this point because otherwise it would have been caught above.
// Now use the interpolator to pass out the interior points
typename DataStore<Scalar>::DataStoreVector_t ds_nodes;
typename DataStore<Scalar>::DataStoreVector_t ds_out;
{
// t_old
DataStore<Scalar> ds;
ds.time = t_old;
ds.x = rcp(x_old.get(),false);
ds.xdot = rcp(xdot_old.get(),false);
ds_nodes.push_back(ds);
}
{
// t
DataStore<Scalar> ds;
ds.time = t;
ds.x = rcp(x.get(),false);
ds.xdot = rcp(xdot.get(),false);
ds_nodes.push_back(ds);
}
Array<Scalar> time_vec_in;
time_vec_in.push_back(time);
interpolate<Scalar>(*interpolator,rcp(&ds_nodes,false),time_vec_in,&ds_out);
Array<Scalar> time_vec_out;
Array<RCP<const VectorBase<Scalar> > > x_vec_out;
Array<RCP<const VectorBase<Scalar> > > xdot_vec_out;
Array<typename Teuchos::ScalarTraits<Scalar>::magnitudeType> accuracy_vec_out;
dataStoreVectorToVector(ds_out,&time_vec_out,&x_vec_out,&xdot_vec_out,&accuracy_vec_out);
TEUCHOS_ASSERT( time_vec_out.length()==1 );
tmpVec = x_vec_out[0];
tmpVecDot = xdot_vec_out[0];
accuracy = accuracy_vec_out[0];
}
if (!is_null(x_vec)) {
x_vec->push_back(tmpVec);
}
if (!is_null(xdot_vec)) {
xdot_vec->push_back(tmpVecDot);
}
if (!is_null(accuracy_vec)) {
accuracy_vec->push_back(accuracy);
}
tmpVec = Teuchos::null;
tmpVecDot = Teuchos::null;
}
}
template<class Scalar>
void setStepperModel(
const Ptr<StepperBase<Scalar> >& stepper,
const RCP<const Thyra::ModelEvaluator<Scalar> >& model
)
{
stepper->setModel(model);
}
template<class Scalar>
void setStepperModel(
const Ptr<StepperBase<Scalar> >& stepper,
const RCP<Thyra::ModelEvaluator<Scalar> >& model
)
{
stepper->setNonconstModel(model);
}
template<class Scalar>
void setStepperModel(
const Ptr<StepperBase<Scalar> >& stepper,
ConstNonconstObjectContainer<Thyra::ModelEvaluator<Scalar> >& model
)
{
if (model.isConst()) {
stepper->setModel(model.getConstObj());
}
else {
stepper->setNonconstModel(model.getNonconstObj());
}
}
//
// Explicit Instantiation macro
//
// Must be expanded from within the Rythmos namespace!
//
#ifdef HAVE_THYRA_ME_POLYNOMIAL
#define RYTHMOS_STEPPER_HELPERS_POLY_INSTANT(SCALAR) \
template void eval_model_explicit_poly( \
const Thyra::ModelEvaluator< SCALAR > &model, \
Thyra::ModelEvaluatorBase::InArgs< SCALAR > &basePoint, \
const Teuchos::Polynomial< VectorBase< SCALAR > > &x_poly, \
const Thyra::ModelEvaluatorBase::InArgs< SCALAR >::ScalarMag &t, \
const Ptr<Teuchos::Polynomial<VectorBase< SCALAR > > >& f_poly \
);
#else // HAVE_THYRA_ME_POLYNOMIAL
#define RYTHMOS_STEPPER_HELPERS_POLY_INSTANT(SCALAR)
#endif // HAVE_THYRA_ME_POLYNOMIAL
#define RYTHMOS_STEPPER_HELPERS_INSTANT(SCALAR) \
\
template void assertValidModel( \
const StepperBase< SCALAR >& stepper, \
const Thyra::ModelEvaluator< SCALAR >& model \
); \
template bool setDefaultInitialConditionFromNominalValues( \
const Thyra::ModelEvaluator< SCALAR >& model, \
const Ptr<StepperBase< SCALAR > >& stepper \
); \
template void restart( StepperBase< SCALAR > *stepper ); \
\
template void eval_model_explicit( \
const Thyra::ModelEvaluator< SCALAR > &model, \
Thyra::ModelEvaluatorBase::InArgs< SCALAR > &basePoint, \
const VectorBase< SCALAR >& x_in, \
const Thyra::ModelEvaluatorBase::InArgs< SCALAR >::ScalarMag &t_in, \
const Ptr<VectorBase< SCALAR > >& f_out, \
const SCALAR scaled_dt, \
const SCALAR stage_point\
); \
\
RYTHMOS_STEPPER_HELPERS_POLY_INSTANT(SCALAR) \
\
template void defaultGetPoints( \
const SCALAR & t_old, \
const Ptr<const VectorBase< SCALAR > >& x_old, \
const Ptr<const VectorBase< SCALAR > >& xdot_old, \
const SCALAR & t, \
const Ptr<const VectorBase< SCALAR > >& x, \
const Ptr<const VectorBase< SCALAR > >& xdot, \
const Array< SCALAR >& time_vec, \
const Ptr<Array<Teuchos::RCP<const Thyra::VectorBase< SCALAR > > > >& x_vec, \
const Ptr<Array<Teuchos::RCP<const Thyra::VectorBase< SCALAR > > > >& xdot_vec, \
const Ptr<Array<Teuchos::ScalarTraits< SCALAR >::magnitudeType> >& accuracy_vec, \
const Ptr<InterpolatorBase< SCALAR > > interpolator \
); \
\
template void setStepperModel( \
const Ptr<StepperBase< SCALAR > >& stepper, \
const RCP<const Thyra::ModelEvaluator< SCALAR > >& model \
); \
\
template void setStepperModel( \
const Ptr<StepperBase< SCALAR > >& stepper, \
const RCP<Thyra::ModelEvaluator< SCALAR > >& model \
); \
\
template void setStepperModel( \
const Ptr<StepperBase< SCALAR > >& stepper, \
Teuchos::ConstNonconstObjectContainer<Thyra::ModelEvaluator< SCALAR > >& model \
);
} // namespace Rythmos
#endif // RYTHMOS_STEPPER_HELPERS_DEF_HPP
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