micpsolverold.hpp
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Created: Mon, Nov 4, 18:04

micpsolverold.hpp
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	/*-------------------------------------------------------

	- Module : micpsolver
	- File : micpsolver.hpp
	- Author : Fabien Georget

	Copyright (c) 2014, Fabien Georget, Princeton University

	---------------------------------------------------------*/

	#ifndef SPECMIC_MICPSOLVER_MICPSOLVEROLD_HPP
	#define SPECMIC_MICPSOLVER_MICPSOLVEROLD_HPP

	#include <memory>
	#include <Eigen/Dense>
	#include "micpsolver_structs.hpp"
	#include "ncp_function.hpp"

	//! \file micpsolver.hpp The MiCP solver

	namespace specmicp {
	namespace micpsolver {

	//! \brief Call a NCP-function
	//!
	//! @tparam ncp_t the NCP function to use
	//! @param a first argument
	//! @param b second argument
	//! @param t parameter of the NCP function
	//!
	template <NCPfunction ncp_t>
	inline double ncp_function(double a, double b, double t);

	//! \brief Reformulate the jacobian using the NCP-function ncp_t
	//!
	//! @tparam ncp_t the NCP-function to use
	//! @param[in] neq number of equation
	//! @param[in] neq_free number of free variables
	//! @param[in] x the variables
	//! @param[in] r the residuals
	//! @param[in,out] jacobian the jacobian to reformulate
	//! @param[in,out] r_reformulated the reformulated residuals
	//! @param[in] t parameter of the NCP function
	template <NCPfunction ncp_t>
	inline void reformulate_jacobian_helper(
	int neq,
	int neq_free,
	const Eigen::VectorXd& x,
	const Eigen::VectorXd& r,
	Eigen::MatrixXd& jacobian,
	Eigen::VectorXd& r_reformulated,
	double t
	);

	//! \brief reformulate the result of the Newton system
	template <NCPfunction ncp_t>
	inline void reformulate_result(
	int neq,
	int neq_free,
	Eigen::VectorXd& x,
	const Eigen::VectorXd& orig_r,
	Eigen::VectorXd& grad_phi,
	Eigen::VectorXd& update
	);

	//! \brief The MiCP Solver
	//!
	//! Solve
	//! - \f$ G(u, v) = 0\f$
	//! - \f$ 0 \leq v \perp H(u,v) \geq 0 \f$
	//!
	//! \tparam Program a subclass of MiCPProg
	//!
	//! References :
	//! - \cite Munson2001
	//! - \cite Facchinei2003
	//!
	template <class Program, NCPfunction ncp_t>
	class MiCPSolverOLD {

	public:
	//! \brief Constructor
	//!
	//! @param prog smart pointer toward an instance of a Program to solve
	MiCPSolverOLD(std::shared_ptr<Program> prog):
	m_program(prog),
	m_residuals(prog->total_variables()),
	m_phi_residuals(Eigen::VectorXd::Zero(prog->total_variables())),
	m_jacobian(prog->total_variables(),prog ->total_variables()),
	m_max_taken(false),
	m_consec_max(0)
	{
	}

	//! \brief Return a const reference to the options used by the algorithm
	const MiCPSolverOptions& get_options() const {return m_options;}
	//! \brief Return a reference to the options used by the algorithm
	MiCPSolverOptions& get_options() {return m_options;}
	//! \brief Set the options
	void set_options(const MiCPSolverOptions& options) {m_options = options;}

	//! \brief Return the number of equations
	int get_neq() const {return m_program->total_variables();}
	//! \brief Return the number of equations corresponding to the free variables (size of G)
	int get_neq_free() const {return m_program->nb_free_variables();}

	// Merit function
	// ##############

	//! \brief Reformulation for lower bounded variable
	double phi_lower_bounded(const double& x, const double& r, const double& l) const {
	return ncp_function<ncp_t>(x-l, r, get_options().penalization_factor);}
	//! \brief Reformulation for a free variable
	double phi_free(const double& r) const {
	return r;
	}

	//! \brief Compute the norm of the update
	template <int p>
	double norm_update(const Eigen::VectorXd& update,
	const Eigen::VectorXd& solution) const {
	return (update.array().abs()/(solution.array().max(1))
	).matrix().template lpNorm<p>();
	}
	// Residuals and jacobian
	// ----------------------

	//! \brief Compute the residuals, store it in r
	//!
	//! @param[in] x the variables
	//! @param[out] r vector to store the residuals (must be of the same size as x)
	void compute_residuals(const Eigen::VectorXd& x, Eigen::VectorXd& r)
	{
	m_program->get_residuals(x, r);
	get_perf().nb_call_residuals += 1;
	}
	//! \brief Compute the residuals, use internal storage
	//!
	//! @param[in] x the variables
	void compute_residuals(const Eigen::VectorXd& x)
	{
	return compute_residuals(x, m_residuals);
	get_perf().nb_call_jacobian += 1;
	}
	//! \brief Compute the jacobian
	//!
	//! Assumes that the residual have been computed before
	//!
	//! @param[in] x the variables
	void compute_jacobian(Eigen::VectorXd& x)
	{
	m_program->get_jacobian(x, m_jacobian);
	}
	//! \brief Reformulation of the residuals
	//!
	//! Reformulate the problem - assumes that r, the residual, has been computed before
	//!
	//! @param[in] x the variables
	//! @param[in] r the residuals
	//! @param[out] r_phi a vector of size neq, which will contain the reformulated residuals
	void reformulate_residuals(const Eigen::VectorXd& x,
	const Eigen::VectorXd& r,
	Eigen::VectorXd& r_phi);
	//! \brief Reformulation of the residuals inplace
	//!
	//! @param[in] x the variables
	//! @param[in,out] r the residual, will contain the reformulated residuals
	void reformulate_residuals_inplace(const Eigen::VectorXd& x,
	Eigen::VectorXd &r);
	//! \brief Reformulation of the jacobian
	//!
	//! r is the original vector of residuals (not reformulated)
	void reformulate_jacobian(const Eigen::VectorXd& x
	)
	{
	reformulate_jacobian_helper<ncp_t>(get_neq(), get_neq_free(),
	x, m_residuals,
	m_jacobian,
	m_phi_residuals,
	get_options().penalization_factor);
	}

	//! \brief Compute the factors to scale the jacobian
	//!
	//! @param[in] jacobian the jacobian to scale (from the reformulated problem)
	//! @param[in] residual the residuals corresponding to the jacobian
	//! @param[out] rscaler scaling factors of the rows
	//! @param[out] cscaler scaling factors of the columns
	void scaling_jacobian(const Eigen::MatrixXd& jacobian,
	const Eigen::VectorXd& residual,
	Eigen::VectorXd& rscaler,
	Eigen::VectorXd& cscaler);

	// Algorithm
	// #########

	//! \brief Solver the program using x as initial guess
	//!
	//! @param[in,out] x the initial guess, as output contains the solution (from the last iteration)
	MiCPSolverReturnCode solve(Eigen::VectorXd& x);

	//! \brief Setup the residuals
	//!
	//! @param[in] x the current solution
	void setup_residuals(const Eigen::VectorXd& x) {
	compute_residuals(x);
	reformulate_residuals(x, m_residuals, m_phi_residuals);
	}

	//! \brief Setup the jacobian
	//!
	//! @param[in] x the current solution
	void setup_jacobian(Eigen::VectorXd& x) {
	compute_jacobian(x);
	reformulate_jacobian(x);
	m_grad_phi = m_jacobian.transpose() * m_phi_residuals;
	}

	//! \brief Check for convergence
	//!
	//! @param nb_iterations the number of iterations
	//! @param update the update taken at the previous iteration
	//! @param solution the current solution
	//! @return a MiCPSolverReturnCode describing the state of the algorithm
	MiCPSolverReturnCode check_convergence(int nb_iterations,
	Eigen::VectorXd& update,
	Eigen::VectorXd& solution);

	//! \brief Solve the Newton system
	//!
	//! Assume that the Newton system has been formed
	//!
	//! \param[out] update the update to apply to the solution
	MiCPSolverReturnCode search_direction_calculation(Eigen::VectorXd& update);

	//! \brief Solve the Newton system - does not scale the jacobian
	//!
	//! Assume that the Newton system has been formed
	//!
	//! \param[out] update the update to apply to the solution
	MiCPSolverReturnCode search_direction_calculation_no_scaling(Eigen::VectorXd& update);
	//! \brief Linesearch
	//!
	//! Nonmonotone linesearch
	//!
	//! References :
	//! - \cite Dennis1983
	//! - \cite Munson2001
	//!
	int linesearch(Eigen::VectorXd& update, Eigen::VectorXd& x);

	//! \brief Crashing
	//!
	//! This function improves, if possible, the initial guess
	//! Reference :
	//! - \cite Munson2001
	void crashing(Eigen::VectorXd& x);

	//! \brief Project variables on the feasible set
	void projection(Eigen::VectorXd& x);

	//! \brief Return a const reference to an instance of MiCPPerformance
	const MiCPPerformance& get_performance() {return m_perf;}

	protected:
	//! \brief Return a reference to an instance of MiCPPerformance
	MiCPPerformance& get_perf() {return m_perf;}

	private:

	//! \brief Return the step corrected step length if it is too long
	double is_step_too_long(Eigen::VectorXd& update);

	std::shared_ptr<Program> m_program; //!< Smart pointer of a program

	MiCPSolverOptions m_options; //!< The options
	MiCPPerformance m_perf; //!< The performance

	// Residuals and jacobian
	Eigen::VectorXd m_residuals; //!< The residuals
	Eigen::VectorXd m_phi_residuals; //!< The reformulated residuals
	Eigen::VectorXd m_grad_phi; //!< The gradient of the reformulated residuals
	Eigen::MatrixXd m_jacobian; //!< The jacobian

	std::vector<double> m_max_merits; //!< Contains the m best value of the merit function

	bool m_max_taken; //!< True if the 'length' of the step was equal or bigger than the maximum step length
	int m_consec_max; //!< The number of consecutive step were the step length was equal or bigger than the maximum step length

	bool m_gradient_step_taken; //!< True if the update was computed using the gradient

	};

	} // end namespace micpsolver
	} // end namespace specmicp

	// ###############//
	// Implementation //
	// ###############//
	#include "micpsolverold.inl"

	#endif // SPECMIC_MICPSOLVER_MICPSOLVER_HPP

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