model_solver.cc
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model_solver.cc
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	/**
	* @file model_solver.cc
	*
	* @author Mohit Pundir <mohit.pundir@epfl.ch>
	* @author Nicolas Richart <nicolas.richart@epfl.ch>
	*
	* @date creation: Tue Aug 18 2015
	* @date last modification: Tue Mar 30 2021
	*
	* @brief Implementation of ModelSolver
	*
	*
	* @section LICENSE
	*
	* Copyright (©) 2015-2021 EPFL (Ecole Polytechnique Fédérale de Lausanne)
	* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
	*
	* Akantu 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 3 of the License, or (at your option) any
	* later version.
	*
	* Akantu 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 Akantu. If not, see <http://www.gnu.org/licenses/>.
	*
	*/

	/* -------------------------------------------------------------------------- */
	#include "model_solver.hh"
	#include "dof_manager.hh"
	#include "dof_manager_default.hh"
	#include "mesh.hh"
	#include "non_linear_solver.hh"
	#include "time_step_solver.hh"

	#if defined(AKANTU_USE_PETSC)
	#include "dof_manager_petsc.hh"
	#endif

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

	namespace akantu {

	/* -------------------------------------------------------------------------- */
	template <typename T> static T getOptionToType(const std::string & opt_str) {
	std::stringstream sstr(opt_str);
	T opt;
	sstr >> opt;

	return opt;
	}

	/* -------------------------------------------------------------------------- */
	ModelSolver::ModelSolver(Mesh & mesh, const ModelType & type, const ID & id)
	: Parsable(ParserType::_model, id), model_type(type), parent_id(id),
	mesh(mesh) {}

	/* -------------------------------------------------------------------------- */
	ModelSolver::ModelSolver(Mesh & mesh, const ModelType & type, const ID & id,
	std::shared_ptr<DOFManager> dof_manager)
	: ModelSolver(mesh, type, id) {
	if (not dof_manager) {
	this->initDOFManager();
	} else {
	this->dof_manager = dof_manager;
	this->setDOFManager(*this->dof_manager);
	}
	}

	/* -------------------------------------------------------------------------- */
	ModelSolver::~ModelSolver() = default;

	/* -------------------------------------------------------------------------- */
	std::tuple<ParserSection, bool> ModelSolver::getParserSection() {
	auto sub_sections = getStaticParser().getSubSections(ParserType::_model);

	auto it = std::find_if(
	sub_sections.begin(), sub_sections.end(), [&](auto && section) {
	auto type = getOptionToType<ModelType>(section.getName());
	// default id should be the model type if not defined
	std::string name = section.getParameter("name", this->parent_id);
	return type == model_type and name == this->parent_id;
	});

	if (it == sub_sections.end()) {
	return std::make_tuple(ParserSection(), true);
	}

	return std::make_tuple(*it, false);
	}

	/* -------------------------------------------------------------------------- */
	std::shared_ptr<DOFManager> ModelSolver::initDOFManager() {
	// default without external solver activated at compilation same as mumps that
	// is the historical solver but with only the lumped solver
	ID solver_type = "default";

	#if defined(AKANTU_USE_MUMPS)
	solver_type = "default";
	#elif defined(AKANTU_USE_PETSC)
	solver_type = "petsc";
	#endif

	ParserSection section;
	bool is_empty;
	std::tie(section, is_empty) = this->getParserSection();

	if (not is_empty) {
	solver_type = section.getOption(solver_type);
	return this->initDOFManager(section, solver_type);
	}
	return this->initDOFManager(solver_type);
	}

	/* -------------------------------------------------------------------------- */
	std::shared_ptr<DOFManager>
	ModelSolver::initDOFManager(const ID & solver_type) {
	if (dof_manager) {
	AKANTU_EXCEPTION("The DOF manager for this model is already initialized !");
	}

	try {
	this->dof_manager = DOFManagerFactory::getInstance().allocate(
	solver_type, mesh, this->parent_id + ":dof_manager_" + solver_type);
	} catch (...) {
	AKANTU_EXCEPTION(
	"To use the solver "
	<< solver_type
	<< " you will have to code it. This is an unknown solver type.");
	}

	this->setDOFManager(*this->dof_manager);
	return this->dof_manager;
	}

	/* -------------------------------------------------------------------------- */
	std::shared_ptr<DOFManager>
	ModelSolver::initDOFManager(const ParserSection & section,
	const ID & solver_type) {
	this->initDOFManager(solver_type);
	auto sub_sections = section.getSubSections(ParserType::_time_step_solver);

	// parsing the time step solvers
	for (auto && section : sub_sections) {
	ID type = section.getName();
	ID solver_id = section.getParameter("name", type);

	auto tss_type = getOptionToType<TimeStepSolverType>(type);
	auto tss_options = this->getDefaultSolverOptions(tss_type);

	auto sub_solvers_sect =
	section.getSubSections(ParserType::_non_linear_solver);
	auto nb_non_linear_solver_section =
	section.getNbSubSections(ParserType::_non_linear_solver);

	auto nls_type = tss_options.non_linear_solver_type;

	if (nb_non_linear_solver_section == 1) {
	auto && nls_section = *(sub_solvers_sect.first);
	nls_type = getOptionToType<NonLinearSolverType>(nls_section.getName());
	} else if (nb_non_linear_solver_section > 0) {
	AKANTU_EXCEPTION("More than one non linear solver are provided for the "
	"time step solver "
	<< solver_id);
	}

	this->getNewSolver(solver_id, tss_type, nls_type);
	if (nb_non_linear_solver_section == 1) {
	const auto & nls_section = *(sub_solvers_sect.first);
	this->dof_manager->getNonLinearSolver(solver_id).parseSection(
	nls_section);
	}

	auto sub_integrator_sections =
	section.getSubSections(ParserType::_integration_scheme);

	for (auto && is_section : sub_integrator_sections) {
	const auto & dof_type_str = is_section.getName();
	ID dof_id;
	try {
	ID tmp = is_section.getParameter("name");
	dof_id = tmp;
	} catch (...) {
	AKANTU_EXCEPTION("No degree of freedom name specified for the "
	"integration scheme of type "
	<< dof_type_str);
	}

	auto it_type = getOptionToType<IntegrationSchemeType>(dof_type_str);

	IntegrationScheme::SolutionType s_type = is_section.getParameter(
	"solution_type", tss_options.solution_type[dof_id]);
	this->setIntegrationScheme(solver_id, dof_id, it_type, s_type);
	}

	for (auto & is_type : tss_options.integration_scheme_type) {
	if (!this->hasIntegrationScheme(solver_id, is_type.first)) {
	this->setIntegrationScheme(solver_id, is_type.first, is_type.second,
	tss_options.solution_type[is_type.first]);
	}
	}
	}

	if (section.hasParameter("default_solver")) {
	ID default_solver = section.getParameter("default_solver");
	if (this->hasSolver(default_solver)) {
	this->setDefaultSolver(default_solver);
	} else {
	AKANTU_EXCEPTION(
	"The solver \""
	<< default_solver
	<< "\" was not created, it cannot be set as default solver");
	}
	}

	return this->dof_manager;
	}

	/* -------------------------------------------------------------------------- */
	TimeStepSolver & ModelSolver::getSolver(const ID & solver_id) {
	ID tmp_solver_id = solver_id;
	if (tmp_solver_id.empty()) {
	tmp_solver_id = this->default_solver_id;
	}

	TimeStepSolver & tss = this->dof_manager->getTimeStepSolver(tmp_solver_id);
	return tss;
	}

	/* -------------------------------------------------------------------------- */
	const TimeStepSolver & ModelSolver::getSolver(const ID & solver_id) const {
	ID tmp_solver_id = solver_id;
	if (solver_id.empty()) {
	tmp_solver_id = this->default_solver_id;
	}

	const TimeStepSolver & tss =
	this->dof_manager->getTimeStepSolver(tmp_solver_id);
	return tss;
	}

	/* -------------------------------------------------------------------------- */
	TimeStepSolver & ModelSolver::getTimeStepSolver(const ID & solver_id) {
	return this->getSolver(solver_id);
	}

	/* -------------------------------------------------------------------------- */
	const TimeStepSolver &
	ModelSolver::getTimeStepSolver(const ID & solver_id) const {
	return this->getSolver(solver_id);
	}

	/* -------------------------------------------------------------------------- */
	NonLinearSolver & ModelSolver::getNonLinearSolver(const ID & solver_id) {
	return this->getSolver(solver_id).getNonLinearSolver();
	}
	/* -------------------------------------------------------------------------- */
	const NonLinearSolver &
	ModelSolver::getNonLinearSolver(const ID & solver_id) const {
	return this->getSolver(solver_id).getNonLinearSolver();
	}

	/* -------------------------------------------------------------------------- */
	bool ModelSolver::hasSolver(const ID & solver_id) const {
	ID tmp_solver_id = solver_id;
	if (solver_id.empty()) {
	tmp_solver_id = this->default_solver_id;
	}

	if (not this->dof_manager) {
	AKANTU_EXCEPTION("No DOF manager was initialized");
	}
	return this->dof_manager->hasTimeStepSolver(tmp_solver_id);
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::setDefaultSolver(const ID & solver_id) {
	AKANTU_DEBUG_ASSERT(
	this->hasSolver(solver_id),
	"Cannot set the default solver to a solver that does not exists");
	this->default_solver_id = solver_id;
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::solveStep(SolverCallback & callback, const ID & solver_id) {
	AKANTU_DEBUG_IN();

	TimeStepSolver & tss = this->getSolver(solver_id);
	// make one non linear solve
	tss.solveStep(callback);

	AKANTU_DEBUG_OUT();
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::solveStep(const ID & solver_id) {
	solveStep(*this, solver_id);
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::getNewSolver(const ID & solver_id,
	TimeStepSolverType time_step_solver_type,
	NonLinearSolverType non_linear_solver_type) {
	if (this->default_solver_id.empty()) {
	this->default_solver_id = solver_id;
	}

	if (non_linear_solver_type == NonLinearSolverType::_auto) {
	switch (time_step_solver_type) {
	case TimeStepSolverType::_dynamic:
	case TimeStepSolverType::_static:
	non_linear_solver_type = NonLinearSolverType::_newton_raphson;
	break;
	case TimeStepSolverType::_dynamic_lumped:
	non_linear_solver_type = NonLinearSolverType::_lumped;
	break;
	case TimeStepSolverType::_not_defined:
	AKANTU_EXCEPTION(time_step_solver_type
	<< " is not a valid time step solver type");
	break;
	}
	}

	this->initSolver(time_step_solver_type, non_linear_solver_type);

	NonLinearSolver & nls = this->dof_manager->getNewNonLinearSolver(
	solver_id, non_linear_solver_type);

	this->dof_manager->getNewTimeStepSolver(solver_id, time_step_solver_type, nls,
	*this);
	}

	/* -------------------------------------------------------------------------- */
	Real ModelSolver::getTimeStep(const ID & solver_id) const {
	const TimeStepSolver & tss = this->getSolver(solver_id);

	return tss.getTimeStep();
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::setTimeStep(Real time_step, const ID & solver_id) {
	TimeStepSolver & tss = this->getSolver(solver_id);

	return tss.setTimeStep(time_step);
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::setIntegrationScheme(
	const ID & solver_id, const ID & dof_id,
	const IntegrationSchemeType & integration_scheme_type,
	IntegrationScheme::SolutionType solution_type) {
	TimeStepSolver & tss = this->dof_manager->getTimeStepSolver(solver_id);

	tss.setIntegrationScheme(dof_id, integration_scheme_type, solution_type);
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::setIntegrationScheme(
	const ID & solver_id, const ID & dof_id,
	std::unique_ptr<IntegrationScheme> & integration_scheme,
	IntegrationScheme::SolutionType solution_type) {
	TimeStepSolver & tss = this->dof_manager->getTimeStepSolver(solver_id);

	tss.setIntegrationScheme(dof_id, integration_scheme, solution_type);
	}

	/* -------------------------------------------------------------------------- */
	bool ModelSolver::hasDefaultSolver() const {
	return (not this->default_solver_id.empty());
	}

	/* -------------------------------------------------------------------------- */
	bool ModelSolver::hasIntegrationScheme(const ID & solver_id,
	const ID & dof_id) const {
	TimeStepSolver & tss = this->dof_manager->getTimeStepSolver(solver_id);
	return tss.hasIntegrationScheme(dof_id);
	}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::predictor() {}

	/* -------------------------------------------------------------------------- */
	void ModelSolver::corrector() {}

	/* -------------------------------------------------------------------------- */
	TimeStepSolverType ModelSolver::getDefaultSolverType() const {
	return TimeStepSolverType::_dynamic_lumped;
	}

	/* -------------------------------------------------------------------------- */
	ModelSolverOptions
	ModelSolver::getDefaultSolverOptions(__attribute__((unused))
	const TimeStepSolverType & type) const {
	ModelSolverOptions options;
	options.non_linear_solver_type = NonLinearSolverType::_auto;
	return options;
	}

	} // namespace akantu

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