From 4b64cf486f5c999fd8167758cae27839f3b50848 Mon Sep 17 00:00:00 2001 From: Harpreet Date: Sat, 3 Sep 2016 00:34:27 +0530 Subject: Structure updated and intqpipopt files added --- build/Bonmin/include/coin/IpNLP.hpp | 243 ------------------------------------ 1 file changed, 243 deletions(-) delete mode 100644 build/Bonmin/include/coin/IpNLP.hpp (limited to 'build/Bonmin/include/coin/IpNLP.hpp') diff --git a/build/Bonmin/include/coin/IpNLP.hpp b/build/Bonmin/include/coin/IpNLP.hpp deleted file mode 100644 index 1063c01..0000000 --- a/build/Bonmin/include/coin/IpNLP.hpp +++ /dev/null @@ -1,243 +0,0 @@ -// Copyright (C) 2004, 2006 International Business Machines and others. -// All Rights Reserved. -// This code is published under the Eclipse Public License. -// -// $Id: IpNLP.hpp 2269 2013-05-05 11:32:40Z stefan $ -// -// Authors: Carl Laird, Andreas Waechter IBM 2004-08-13 - -#ifndef __IPNLP_HPP__ -#define __IPNLP_HPP__ - -#include "IpUtils.hpp" -#include "IpVector.hpp" -#include "IpSmartPtr.hpp" -#include "IpMatrix.hpp" -#include "IpSymMatrix.hpp" -#include "IpOptionsList.hpp" -#include "IpAlgTypes.hpp" -#include "IpReturnCodes.hpp" - -namespace Ipopt -{ - // forward declarations - class IpoptData; - class IpoptCalculatedQuantities; - class IteratesVector; - - /** Brief Class Description. - * Detailed Class Description. - */ - class NLP : public ReferencedObject - { - public: - /**@name Constructors/Destructors */ - //@{ - /** Default constructor */ - NLP() - {} - - /** Default destructor */ - virtual ~NLP() - {} - //@} - - /** Exceptions */ - //@{ - DECLARE_STD_EXCEPTION(USER_SCALING_NOT_IMPLEMENTED); - DECLARE_STD_EXCEPTION(INVALID_NLP); - //@} - - /** @name NLP Initialization (overload in - * derived classes).*/ - //@{ - /** Overload if you want the chance to process options or parameters that - * may be specific to the NLP */ - virtual bool ProcessOptions(const OptionsList& options, - const std::string& prefix) - { - return true; - } - - /** Method for creating the derived vector / matrix types. The - * Hess_lagrangian_space pointer can be NULL if a quasi-Newton - * options is chosen. */ - virtual bool GetSpaces(SmartPtr& x_space, - SmartPtr& c_space, - SmartPtr& d_space, - SmartPtr& x_l_space, - SmartPtr& px_l_space, - SmartPtr& x_u_space, - SmartPtr& px_u_space, - SmartPtr& d_l_space, - SmartPtr& pd_l_space, - SmartPtr& d_u_space, - SmartPtr& pd_u_space, - SmartPtr& Jac_c_space, - SmartPtr& Jac_d_space, - SmartPtr& Hess_lagrangian_space)=0; - - /** Method for obtaining the bounds information */ - virtual bool GetBoundsInformation(const Matrix& Px_L, - Vector& x_L, - const Matrix& Px_U, - Vector& x_U, - const Matrix& Pd_L, - Vector& d_L, - const Matrix& Pd_U, - Vector& d_U)=0; - - /** Method for obtaining the starting point for all the - * iterates. ToDo it might not make sense to ask for initial - * values for v_L and v_U? */ - virtual bool GetStartingPoint( - SmartPtr x, - bool need_x, - SmartPtr y_c, - bool need_y_c, - SmartPtr y_d, - bool need_y_d, - SmartPtr z_L, - bool need_z_L, - SmartPtr z_U, - bool need_z_U - )=0; - - /** Method for obtaining an entire iterate as a warmstart point. - * The incoming IteratesVector has to be filled. The default - * dummy implementation returns false. */ - virtual bool GetWarmStartIterate(IteratesVector& warm_start_iterate) - { - return false; - } - //@} - - /** @name NLP evaluation routines (overload - * in derived classes. */ - //@{ - virtual bool Eval_f(const Vector& x, Number& f) = 0; - - virtual bool Eval_grad_f(const Vector& x, Vector& g_f) = 0; - - virtual bool Eval_c(const Vector& x, Vector& c) = 0; - - virtual bool Eval_jac_c(const Vector& x, Matrix& jac_c) = 0; - - virtual bool Eval_d(const Vector& x, Vector& d) = 0; - - virtual bool Eval_jac_d(const Vector& x, Matrix& jac_d) = 0; - - virtual bool Eval_h(const Vector& x, - Number obj_factor, - const Vector& yc, - const Vector& yd, - SymMatrix& h) = 0; - //@} - - /** @name NLP solution routines. Have default dummy - * implementations that can be overloaded. */ - //@{ - /** This method is called at the very end of the optimization. It - * provides the final iterate to the user, so that it can be - * stored as the solution. The status flag indicates the outcome - * of the optimization, where SolverReturn is defined in - * IpAlgTypes.hpp. */ - virtual void FinalizeSolution(SolverReturn status, - const Vector& x, const Vector& z_L, - const Vector& z_U, - const Vector& c, const Vector& d, - const Vector& y_c, const Vector& y_d, - Number obj_value, - const IpoptData* ip_data, - IpoptCalculatedQuantities* ip_cq) - {} - - /** This method is called once per iteration, after the iteration - * summary output has been printed. It provides the current - * information to the user to do with it anything she wants. It - * also allows the user to ask for a premature termination of the - * optimization by returning false, in which case Ipopt will - * terminate with a corresponding return status. The basic - * information provided in the argument list has the quantities - * values printed in the iteration summary line. If more - * information is required, a user can obtain it from the IpData - * and IpCalculatedQuantities objects. However, note that the - * provided quantities are all for the problem that Ipopt sees, - * i.e., the quantities might be scaled, fixed variables might be - * sorted out, etc. The status indicates things like whether the - * algorithm is in the restoration phase... In the restoration - * phase, the dual variables are probably not not changing. */ - virtual bool IntermediateCallBack(AlgorithmMode mode, - Index iter, Number obj_value, - Number inf_pr, Number inf_du, - Number mu, Number d_norm, - Number regularization_size, - Number alpha_du, Number alpha_pr, - Index ls_trials, - const IpoptData* ip_data, - IpoptCalculatedQuantities* ip_cq) - { - return true; - } - //@} - - /** Routines to get the scaling parameters. These do not need to - * be overloaded unless the options are set for User scaling - */ - //@{ - virtual void GetScalingParameters( - const SmartPtr x_space, - const SmartPtr c_space, - const SmartPtr d_space, - Number& obj_scaling, - SmartPtr& x_scaling, - SmartPtr& c_scaling, - SmartPtr& d_scaling) const - { - THROW_EXCEPTION(USER_SCALING_NOT_IMPLEMENTED, - "You have set options for user provided scaling, but have" - " not implemented GetScalingParameters in the NLP interface"); - } - //@} - - /** Method for obtaining the subspace in which the limited-memory - * Hessian approximation should be done. This is only called if - * the limited-memory Hessian approximation is chosen. Since the - * Hessian is zero in the space of all variables that appear in - * the problem functions only linearly, this allows the user to - * provide a VectorSpace for all nonlinear variables, and an - * ExpansionMatrix to lift from this VectorSpace to the - * VectorSpace of the primal variables x. If the returned values - * are NULL, it is assumed that the Hessian is to be approximated - * in the space of all x variables. The default instantiation of - * this method returns NULL, and a user only has to overwrite - * this method if the approximation is to be done only in a - * subspace. */ - virtual void - GetQuasiNewtonApproximationSpaces(SmartPtr& approx_space, - SmartPtr& P_approx) - { - approx_space = NULL; - P_approx = NULL; - } - - private: - /**@name Default Compiler Generated Methods - * (Hidden to avoid implicit creation/calling). - * These methods are not implemented and - * we do not want the compiler to implement - * them for us, so we declare them private - * and do not define them. This ensures that - * they will not be implicitly created/called. */ - //@{ - /** Copy Constructor */ - NLP(const NLP&); - - /** Overloaded Equals Operator */ - void operator=(const NLP&); - //@} - }; - -} // namespace Ipopt - -#endif -- cgit