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	/**
	* file solvers.cc
	*
	* @author Till Junge <till.junge@epfl.ch>
	*
	* @date 20 Dec 2017
	*
	* @brief implementation of solver functions
	*
	* @section LICENSE
	*
	* Copyright © 2017 Till Junge
	*
	* µSpectre is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License as
	* published by the Free Software Foundation, either version 3, or (at
	* your option) any later version.
	*
	* µSpectre 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
	* General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with GNU Emacs; see the file COPYING. If not, write to the
	* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
	* Boston, MA 02111-1307, USA.
	*/

	#include "solver/solvers.hh"
	#include "solver/solver_cg.hh"
	#include "common/iterators.hh"

	#include <iomanip>
	#include <cmath>

	namespace muSpectre {

	template <Dim_t DimS, Dim_t DimM>
	std::vector<OptimizeResult>
	de_geus (SystemBase<DimS, DimM> & sys, const GradIncrements<DimM> & delFs,
	const Real cg_tol, const Real newton_tol, Uint maxiter,
	Dim_t verbose) {

	using Field_t = typename MaterialBase<DimS, DimM>::StrainField_t;
	auto solver_fields{std::make_unique<GlobalFieldCollection<DimS, DimM>>()};
	solver_fields->initialise(sys.get_resolutions());

	// Corresponds to symbol δF or δε
	auto & incrF{make_field<Field_t>("δF", *solver_fields)};

	// Corresponds to symbol ΔF or Δε
	auto & DeltaF{make_field<Field_t>("ΔF", *solver_fields)};

	// field to store the rhs for cg calculations
	auto & rhs{make_field<Field_t>("rhs", *solver_fields)};

	SolverCG<DimS, DimM> cg(sys.get_resolutions(),
	cg_tol, maxiter, verbose-1>0);
	cg.initialise();


	if (maxiter == 0) {
	maxiter = sys.size()DimMDimM*10;
	}

	size_t count_width{};
	const auto form{sys.get_formulation()};
	std::string strain_symb{};
	if (verbose > 0) {
	//setup of algorithm 5.2 in Nocedal, Numerical Optimization (p. 111)
	std::cout << "de Geus for ";
	switch (form) {
	case Formulation::small_strain: {
	strain_symb = "ε";
	std::cout << "small";
	break;
	}
	case Formulation::finite_strain: {
	strain_symb = "F";
	std::cout << "finite";
	break;
	}
	default:
	throw SolverError("unknown formulation");
	break;
	}
	std::cout << " strain with" << std::endl
	<< "newton_tol = " << newton_tol << ", cg_tol = "
	<< cg_tol << " maxiter = " << maxiter << " and Δ"
	<< strain_symb << " =" <<std::endl;
	for (auto&& tup: akantu::enumerate(delFs)) {
	auto && counter{std::get<0>(tup)};
	auto && grad{std::get<1>(tup)};
	std::cout << "Step " << counter + 1 << ":" << std::endl
	<< grad << std::endl;
	}
	count_width = size_t(std::log10(maxiter))+1;
	}

	// initialise F = I or ε = 0
	auto & F{sys.get_strain()};
	switch (form) {
	case Formulation::finite_strain: {
	F.get_map() = Matrices::I2<DimM>();
	break;
	}
	case Formulation::small_strain: {
	F.get_map() = Matrices::I2<DimM>().Zero();
	for (const auto & delF: delFs) {
	if (!check_symmetry(delF)) {
	throw SolverError("all Δε must be symmetric!");
	}
	}
	break;
	}
	default:
	throw SolverError("Unknown formulation");
	break;
	}

	// initialise return value
	std::vector<OptimizeResult> ret_val{};

	// initialise materials
	constexpr bool need_tangent{true};
	sys.initialise_materials(need_tangent);

	Grad_t<DimM> previous_grad{Grad_t<DimM>::Zero()};
	for (const auto & delF: delFs) { //incremental loop

	Real incrNorm{2*newton_tol}, gradNorm{1};
	auto convergence_test = [&incrNorm, &gradNorm, &newton_tol] () {
	return incrNorm/gradNorm <= newton_tol;
	};
	Uint newt_iter{0};
	for (;
	(newt_iter < maxiter) && (!convergence_test() \|\|
	(newt_iter==1));
	++newt_iter) {

	// obtain material response
	auto res_tup{sys.evaluate_stress_tangent(F)};
	auto & P{std::get<0>(res_tup)};
	auto & K{std::get<1>(res_tup)};

	auto tangent_effect = [&sys, &K] (const Field_t & dF, Field_t & dP) {
	sys.directional_stiffness(K, dF, dP);
	};


	if (newt_iter == 0) {
	DeltaF.get_map() = -(delF-previous_grad); // neg sign because rhs
	tangent_effect(DeltaF, rhs);
	cg.solve(tangent_effect, rhs, incrF);
	F.eigen() -= DeltaF.eigen();
	} else {
	rhs.eigen() = -P.eigen();
	sys.project(rhs);
	cg.solve(tangent_effect, rhs, incrF);
	}

	F.eigen() += incrF.eigen();

	incrNorm = incrF.eigen().matrix().norm();
	gradNorm = F.eigen().matrix().norm();
	if (verbose>0) {
	std::cout << "at Newton step " << std::setw(count_width) << newt_iter
	<< ", \|δ" << strain_symb << "\|/\|Δ" << strain_symb
	<< "\| = " << std::setw(17) << incrNorm/gradNorm
	<< ", tol = " << newton_tol << std::endl;
	if (verbose-1>1) {
	std::cout << "<" << strain_symb << "> =" << std::endl
	<< F.get_map().mean() << std::endl;
	}
	}
	}
	// update previous gradient
	previous_grad = delF;

	ret_val.push_back(OptimizeResult{F.eigen(), sys.get_stress().eigen(),
	convergence_test(), Int(convergence_test()),
	"message not yet implemented",
	newt_iter, cg.get_counter()});


	//!store history variables here

	}

	return ret_val;

	}

	template std::vector<OptimizeResult>
	de_geus (SystemBase<twoD, twoD> & sys, const GradIncrements<twoD>& delF0,
	const Real cg_tol, const Real newton_tol, Uint maxiter,
	Dim_t verbose);

	// template typename SystemBase<twoD, threeD>::StrainField_t &
	// de_geus (SystemBase<twoD, threeD> & sys, const GradIncrements<threeD>& delF0,
	// const Real cg_tol, const Real newton_tol, Uint maxiter,
	// Dim_t verbose);

	template std::vector<OptimizeResult>
	de_geus (SystemBase<threeD, threeD> & sys, const GradIncrements<threeD>& delF0,
	const Real cg_tol, const Real newton_tol, Uint maxiter,
	Dim_t verbose);

	/* ---------------------------------------------------------------------- */
	template <Dim_t DimS, Dim_t DimM>
	std::vector<OptimizeResult>
	newton_cg (SystemBase<DimS, DimM> & sys, const GradIncrements<DimM> & delFs,
	const Real cg_tol, const Real newton_tol, Uint maxiter,
	Dim_t verbose) {
	using Field_t = typename MaterialBase<DimS, DimM>::StrainField_t;
	auto solver_fields{std::make_unique<GlobalFieldCollection<DimS, DimM>>()};
	solver_fields->initialise(sys.get_resolutions());

	// Corresponds to symbol δF or δε
	auto & incrF{make_field<Field_t>("δF", *solver_fields)};

	// field to store the rhs for cg calculations
	auto & rhs{make_field<Field_t>("rhs", *solver_fields)};

	SolverCG<DimS, DimM> cg(sys.get_resolutions(),
	cg_tol, maxiter, verbose-1>0);
	cg.initialise();


	if (maxiter == 0) {
	maxiter = sys.size()DimMDimM*10;
	}

	size_t count_width{};
	const auto form{sys.get_formulation()};
	std::string strain_symb{};
	if (verbose > 0) {
	//setup of algorithm 5.2 in Nocedal, Numerical Optimization (p. 111)
	std::cout << "Newton-CG for ";
	switch (form) {
	case Formulation::small_strain: {
	strain_symb = "ε";
	std::cout << "small";
	break;
	}
	case Formulation::finite_strain: {
	strain_symb = "Fy";
	std::cout << "finite";
	break;
	}
	default:
	throw SolverError("unknown formulation");
	break;
	}
	std::cout << " strain with" << std::endl
	<< "newton_tol = " << newton_tol << ", cg_tol = "
	<< cg_tol << " maxiter = " << maxiter << " and Δ"
	<< strain_symb << " =" <<std::endl;
	for (auto&& tup: akantu::enumerate(delFs)) {
	auto && counter{std::get<0>(tup)};
	auto && grad{std::get<1>(tup)};
	std::cout << "Step " << counter + 1 << ":" << std::endl
	<< grad << std::endl;
	}
	count_width = size_t(std::log10(maxiter))+1;
	}

	// initialise F = I or ε = 0
	auto & F{sys.get_strain()};
	switch (sys.get_formulation()) {
	case Formulation::finite_strain: {
	F.get_map() = Matrices::I2<DimM>();
	break;
	}
	case Formulation::small_strain: {
	F.get_map() = Matrices::I2<DimM>().Zero();
	for (const auto & delF: delFs) {
	if (!check_symmetry(delF)) {
	throw SolverError("all Δε must be symmetric!");
	}
	}
	break;
	}
	default:
	throw SolverError("Unknown formulation");
	break;
	}

	// initialise return value
	std::vector<OptimizeResult> ret_val{};

	// initialise materials
	constexpr bool need_tangent{true};
	sys.initialise_materials(need_tangent);

	Grad_t<DimM> previous_grad{Grad_t<DimM>::Zero()};
	for (const auto & delF: delFs) { //incremental loop
	// apply macroscopic strain increment
	for (auto && grad: F.get_map()) {
	grad += delF - previous_grad;
	}

	Real incrNorm{2*newton_tol}, gradNorm{1};
	auto convergence_test = [&incrNorm, &gradNorm, &newton_tol] () {
	return incrNorm/gradNorm <= newton_tol;
	};
	Uint newt_iter{0};

	for (;
	newt_iter < maxiter && !convergence_test();
	++newt_iter) {

	// obtain material response
	auto res_tup{sys.evaluate_stress_tangent(F)};
	auto & P{std::get<0>(res_tup)};
	auto & K{std::get<1>(res_tup)};

	auto tangent_effect = [&sys, &K] (const Field_t & dF, Field_t & dP) {
	sys.directional_stiffness(K, dF, dP);
	};

	rhs.eigen() = -P.eigen();
	sys.project(rhs);
	cg.solve(tangent_effect, rhs, incrF);

	F.eigen() += incrF.eigen();

	incrNorm = incrF.eigen().matrix().norm();
	gradNorm = F.eigen().matrix().norm();
	if (verbose > 0) {
	std::cout << "at Newton step " << std::setw(count_width) << newt_iter
	<< ", \|δ" << strain_symb << "\|/\|Δ" << strain_symb
	<< "\| = " << std::setw(17) << incrNorm/gradNorm
	<< ", tol = " << newton_tol << std::endl;

	if (verbose-1>1) {
	std::cout << "<" << strain_symb << "> =" << std::endl
	<< F.get_map().mean() << std::endl;
	}
	}

	}
	// update previous gradient
	previous_grad = delF;

	ret_val.push_back(OptimizeResult{F.eigen(), sys.get_stress().eigen(),
	convergence_test(), Int(convergence_test()),
	"message not yet implemented",
	newt_iter, cg.get_counter()});

	//store history variables here

	}

	return ret_val;

	}

	template std::vector<OptimizeResult>
	newton_cg (SystemBase<twoD, twoD> & sys, const GradIncrements<twoD>& delF0,
	const Real cg_tol, const Real newton_tol, Uint maxiter,
	Dim_t verbose);

	// template typename SystemBase<twoD, threeD>::StrainField_t &
	// newton_cg (SystemBase<twoD, threeD> & sys, const GradIncrements<threeD>& delF0,
	// const Real cg_tol, const Real newton_tol, Uint maxiter,
	// Dim_t verbose);

	template std::vector<OptimizeResult>
	newton_cg (SystemBase<threeD, threeD> & sys, const GradIncrements<threeD>& delF0,
	const Real cg_tol, const Real newton_tol, Uint maxiter,
	Dim_t verbose);


	/* ---------------------------------------------------------------------- */
	bool check_symmetry(const Eigen::Ref<const Eigen::ArrayXXd>& eps,
	Real rel_tol){
	return rel_tol >= (eps-eps.transpose()).matrix().norm()/eps.matrix().norm();
	}


	} // muSpectre

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