/usr/include/trilinos/ROL_KelleySachsModel.hpp is in libtrilinos-rol-dev 12.10.1-3.
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// ************************************************************************
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// Rapid Optimization Library (ROL) Package
// Copyright (2014) Sandia Corporation
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// @HEADER
#ifndef ROL_KELLEYSACHSMODEL_HPP
#define ROL_KELLEYSACHSMODEL_HPP
#include "ROL_TrustRegionModel.hpp"
#include "ROL_BoundConstraint.hpp"
/** @ingroup func_group
\class ROL::KelleySachsModel
\brief Provides the interface to evaluate projected trust-region model
functions from the Kelley-Sachs bound constrained trust-region algorithm.
-----
*/
namespace ROL {
template<class Real>
class KelleySachsModel : public TrustRegionModel<Real> {
private:
Teuchos::RCP<BoundConstraint<Real> > bnd_;
Teuchos::RCP<Secant<Real> > secant_;
Teuchos::RCP<Vector<Real> > dual_, prim_;
const bool useSecantPrecond_;
const bool useSecantHessVec_;
Real eps_;
public:
KelleySachsModel(Objective<Real> &obj, BoundConstraint<Real> &bnd,
const Vector<Real> &x, const Vector<Real> &g, const Real eps)
: TrustRegionModel<Real>::TrustRegionModel(obj,x,g,false),
secant_(Teuchos::null), useSecantPrecond_(false), useSecantHessVec_(false), eps_(eps) {
bnd_ = Teuchos::rcpFromRef(bnd);
prim_ = x.clone();
dual_ = g.clone();
}
KelleySachsModel(Objective<Real> &obj, BoundConstraint<Real> &bnd,
const Vector<Real> &x, const Vector<Real> &g, const Real eps,
const Teuchos::RCP<Secant<Real> > &secant,
const bool useSecantPrecond, const bool useSecantHessVec)
: TrustRegionModel<Real>::TrustRegionModel(obj,x,g,false),
secant_(secant), useSecantPrecond_(useSecantPrecond), useSecantHessVec_(useSecantHessVec), eps_(eps) {
bnd_ = Teuchos::rcpFromRef(bnd);
prim_ = x.clone();
dual_ = g.clone();
}
Real value( const Vector<Real> &s, Real &tol ) {
const Teuchos::RCP<const Vector<Real> > gc = TrustRegionModel<Real>::getGradient();
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
hessVec(*dual_,s,s,tol);
dual_->scale(static_cast<Real>(0.5));
// Remove active components of gradient
prim_->set(gc->dual());
bnd_->pruneActive(*prim_,*gc,*xc,eps_);
// Add reduced gradient to reduced hessian in direction s
dual_->plus(prim_->dual());
return dual_->dot(s.dual());
}
void gradient( Vector<Real> &g, const Vector<Real> &s, Real &tol ) {
const Teuchos::RCP<const Vector<Real> > gc = TrustRegionModel<Real>::getGradient();
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
// Apply (reduced) hessian to direction s
hessVec(g,s,s,tol);
// Remove active components of gradient
prim_->set(TrustRegionModel<Real>::getGradient()->dual());
bnd_->pruneActive(*prim_,*gc,*xc,eps_);
// Add reduced gradient to reduced hessian in direction s
g.plus(prim_->dual());
}
void hessVec( Vector<Real> &Hv, const Vector<Real> &v, const Vector<Real> &s, Real &tol ) {
const Teuchos::RCP<const Vector<Real> > gc = TrustRegionModel<Real>::getGradient();
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
// Set vnew to v
prim_->set(v);
// Remove elements of vnew corresponding to binding set
bnd_->pruneActive(*prim_,*gc,*xc,eps_);
// Apply full Hessian to reduced vector
if ( useSecantHessVec_ ) {
secant_->applyB(Hv,*prim_);
}
else {
TrustRegionModel<Real>::getObjective()->hessVec(Hv,*prim_,*xc,tol);
}
// Remove elements of Hv corresponding to binding set
bnd_->pruneActive(Hv,*gc,*xc,eps_);
// Set vnew to v
prim_->set(v);
// Remove Elements of vnew corresponding to complement of binding set
bnd_->pruneInactive(*prim_,*gc,*xc,eps_);
dual_->set(prim_->dual());
bnd_->pruneInactive(*dual_,*gc,*xc,eps_);
// Fill complement of binding set elements in Hp with v
Hv.plus(*dual_);
}
void invHessVec( Vector<Real> &Hv, const Vector<Real> &v, const Vector<Real> &s, Real &tol ) {
const Teuchos::RCP<const Vector<Real> > gc = TrustRegionModel<Real>::getGradient();
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
// Set vnew to v
dual_->set(v);
// Remove elements of vnew corresponding to binding set
bnd_->pruneActive(*dual_,*gc,*xc,eps_);
// Apply full Hessian to reduced vector
if ( useSecantHessVec_ ) {
secant_->applyH(Hv,*dual_);
}
else {
TrustRegionModel<Real>::getObjective()->invHessVec(Hv,*dual_,*xc,tol);
}
// Remove elements of Hv corresponding to binding set
bnd_->pruneActive(Hv,*gc,*xc,eps_);
// Set vnew to v
dual_->set(v);
// Remove Elements of vnew corresponding to complement of binding set
bnd_->pruneInactive(*dual_,*gc,*xc,eps_);
prim_->set(dual_->dual());
bnd_->pruneInactive(*prim_,*gc,*xc,eps_);
// Fill complement of binding set elements in Hv with v
Hv.plus(*prim_);
}
void precond( Vector<Real> &Mv, const Vector<Real> &v, const Vector<Real> &x, Real &tol ) {
const Teuchos::RCP<const Vector<Real> > gc = TrustRegionModel<Real>::getGradient();
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
// Set vnew to v
dual_->set(v);
// Remove elements of vnew corresponding to binding set
bnd_->pruneActive(*dual_,*gc,*xc,eps_);
// Apply full Hessian to reduced vector
if ( useSecantPrecond_ ) {
secant_->applyH(Mv,*dual_);
}
else {
TrustRegionModel<Real>::getObjective()->precond(Mv,*dual_,*xc,tol);
}
// Remove elements of Mv corresponding to binding set
bnd_->pruneActive(Mv,*gc,*xc,eps_);
// Set vnew to v
dual_->set(v);
// Remove Elements of vnew corresponding to complement of binding set
bnd_->pruneInactive(*dual_,*gc,*xc,eps_);
prim_->set(dual_->dual());
bnd_->pruneInactive(*prim_,*gc,*xc,eps_);
// Fill complement of binding set elements in Mv with v
Mv.plus(*prim_);
}
void dualTransform( Vector<Real> &tv, const Vector<Real> &v ) {
// Compute T(v) = P_I(v) where P_I is the projection onto the inactive indices
const Teuchos::RCP<const Vector<Real> > gc = TrustRegionModel<Real>::getGradient();
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
tv.set(v);
bnd_->pruneActive(tv,*gc,*xc,eps_);
}
void primalTransform( Vector<Real> &tv, const Vector<Real> &v ) {
// Compute T(v) = P( x + v ) - x where P is the projection onto the feasible set
const Teuchos::RCP<const Vector<Real> > xc = TrustRegionModel<Real>::getIterate();
tv.set(*xc);
tv.plus(v);
bnd_->project(tv);
tv.axpy(static_cast<Real>(-1),*xc);
}
const Teuchos::RCP<BoundConstraint<Real> > getBoundConstraint(void) const {
return bnd_;
}
};
} // namespace ROL
#endif
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