resolution.cc
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Created: Sun, Nov 10, 01:02

resolution.cc
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	/**
	* @file resolution.cc
	*
	* @author Mohit Pundir <mohit.pundir@epfl.ch>
	*
	* @date creation: Thu Jan 17 2019
	* @date last modification: Wed Apr 07 2021
	*
	* @brief Implementation of common part of the contact resolution class
	*
	*
	* @section LICENSE
	*
	* Copyright (©) 2018-2021 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 "resolution.hh"
	#include "contact_mechanics_model.hh"
	#include "sparse_matrix.hh"
	/* -------------------------------------------------------------------------- */

	namespace akantu {

	/* -------------------------------------------------------------------------- */
	Resolution::Resolution(ContactMechanicsModel & model, const ID & id)
	: Parsable(ParserType::_contact_resolution, id), id(id),
	fem(model.getFEEngine()), model(model) {

	AKANTU_DEBUG_IN();

	spatial_dimension = model.getMesh().getSpatialDimension();
	this->initialize();

	AKANTU_DEBUG_OUT();
	}

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

	/* -------------------------------------------------------------------------- */
	void Resolution::initialize() {
	registerParam("name", name, std::string(), _pat_parsable \| _pat_readable);
	registerParam("mu", mu, Real(0.), _pat_parsable \| _pat_modifiable,
	"Friction Coefficient");
	registerParam("is_master_deformable", is_master_deformable, bool(false),
	_pat_parsable \| _pat_readable, "Is master surface deformable");
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::printself(std::ostream & stream, int indent) const {
	std::string space(indent, AKANTU_INDENT);
	std::string type = getID().substr(getID().find_last_of(':') + 1);

	stream << space << "Contact Resolution " << type << " [" << std::endl;
	Parsable::printself(stream, indent);
	stream << space << "]" << std::endl;
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::assembleInternalForces(GhostType /ghost_type/) {
	AKANTU_DEBUG_IN();

	this->assembleInternalForces();

	AKANTU_DEBUG_OUT();
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::assembleInternalForces() {
	AKANTU_DEBUG_IN();

	for (const auto & element : model.getContactElements()) {

	auto nb_nodes = element.getNbNodes();

	Vector<Real> local_fn(nb_nodes * spatial_dimension);
	computeNormalForce(element, local_fn);

	Vector<Real> local_ft(nb_nodes * spatial_dimension);
	computeTangentialForce(element, local_ft);

	Vector<Real> local_fc(nb_nodes * spatial_dimension);
	local_fc = local_fn + local_ft;

	assembleLocalToGlobalArray(element, local_fn, model.getNormalForce());
	assembleLocalToGlobalArray(element, local_ft, model.getTangentialForce());
	assembleLocalToGlobalArray(element, local_fc, model.getInternalForce());
	}

	AKANTU_DEBUG_OUT();
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::assembleLocalToGlobalArray(const ContactElement & element,
	Vector<Real> & local,
	Array<Real> & global) {

	auto get_connectivity = [&](auto & slave, auto & master) {
	Vector<UInt> master_conn =
	const_cast<const Mesh &>(model.getMesh()).getConnectivity(master);
	Vector<UInt> elem_conn(master_conn.size() + 1);

	elem_conn[0] = slave;
	for (UInt i = 1; i < elem_conn.size(); ++i) {
	elem_conn[i] = master_conn[i - 1];
	}

	return elem_conn;
	};

	auto & surface_selector = model.getContactDetector().getSurfaceSelector();
	auto & slave_list = surface_selector.getSlaveList();
	auto & master_list = surface_selector.getMasterList();

	auto connectivity = get_connectivity(element.slave, element.master);

	UInt nb_dofs = global.getNbComponent();
	UInt nb_nodes = is_master_deformable ? connectivity.size() : 1;
	Real alpha = is_master_deformable ? 0.5 : 1.;

	for (UInt i : arange(nb_nodes)) {
	UInt n = connectivity[i];

	auto slave_result = std::find(slave_list.begin(), slave_list.end(), n);
	auto master_result = std::find(master_list.begin(), master_list.end(), n);

	for (UInt j : arange(nb_dofs)) {
	UInt offset_node = n * nb_dofs + j;
	global[offset_node] += alpha * local[i * nb_dofs + j];
	}
	}
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::assembleStiffnessMatrix(GhostType /ghost_type/) {
	AKANTU_DEBUG_IN();

	auto & global_stiffness =
	const_cast<SparseMatrix &>(model.getDOFManager().getMatrix("K"));

	for (const auto & element : model.getContactElements()) {

	auto nb_nodes = element.getNbNodes();

	Matrix<Real> local_kn(nb_nodes * spatial_dimension,
	nb_nodes * spatial_dimension);
	computeNormalModuli(element, local_kn);
	assembleLocalToGlobalMatrix(element, local_kn, global_stiffness);

	Matrix<Real> local_kt(nb_nodes * spatial_dimension,
	nb_nodes * spatial_dimension);
	computeTangentialModuli(element, local_kt);
	assembleLocalToGlobalMatrix(element, local_kt, global_stiffness);
	}

	AKANTU_DEBUG_OUT();
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::assembleLocalToGlobalMatrix(const ContactElement & element,
	const Matrix<Real> & local,
	SparseMatrix & global) {

	auto get_connectivity = [&](auto & slave, auto & master) {
	Vector<UInt> master_conn =
	const_cast<const Mesh &>(model.getMesh()).getConnectivity(master);
	Vector<UInt> elem_conn(master_conn.size() + 1);

	elem_conn[0] = slave;
	for (UInt i = 1; i < elem_conn.size(); ++i) {
	elem_conn[i] = master_conn[i - 1];
	}

	return elem_conn;
	};

	auto connectivity = get_connectivity(element.slave, element.master);

	auto nb_dofs = spatial_dimension;
	UInt nb_nodes = is_master_deformable ? connectivity.size() : 1;
	UInt total_nb_dofs = nb_dofs * nb_nodes;

	std::vector<UInt> equations;
	for (UInt i : arange(connectivity.size())) {
	UInt conn = connectivity[i];
	for (UInt j : arange(nb_dofs)) {
	equations.push_back(conn * nb_dofs + j);
	}
	}

	for (UInt i : arange(total_nb_dofs)) {
	UInt row = equations[i];
	for (UInt j : arange(total_nb_dofs)) {
	UInt col = equations[j];
	global.add(row, col, local(i, j));
	}
	}
	}

	/* -------------------------------------------------------------------------- */
	void Resolution::beforeSolveStep() {}

	/* -------------------------------------------------------------------------- */
	void Resolution::afterSolveStep(__attribute__((unused)) bool converged) {}

	} // namespace akantu

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