py_mesh.cc
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	/**
	* Copyright (©) 2019-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)
	* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
	*
	* This file is part of Akantu
	*
	* 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 "aka_config.hh"
	/* -------------------------------------------------------------------------- */
	#include "py_aka_array.hh"
	/* -------------------------------------------------------------------------- */
	#include <element_type_map.hh>
	#include <fe_engine.hh>
	#include <mesh.hh>
	#include <mesh_accessor.hh>
	#include <mesh_utils.hh>
	/* -------------------------------------------------------------------------- */
	#include <pybind11/pybind11.h>
	#include <pybind11/stl.h>
	/* -------------------------------------------------------------------------- */
	namespace py = pybind11;
	/* -------------------------------------------------------------------------- */

	namespace akantu {

	namespace {
	/* ------------------------------------------------------------------------ */
	template <typename T>
	auto register_element_type_map_array(py::module & mod,
	const std::string & name) {
	return py::class_<ElementTypeMapArray<T>,
	std::shared_ptr<ElementTypeMapArray<T>>>(
	mod, ("ElementTypeMapArray" + name).c_str())
	.def(py::init<const ID &, const ID &>(),
	py::arg("id") = "by_element_type_array",
	py::arg("parent_id") = "no_parent")
	.def(
	"__call__",
	[](ElementTypeMapArray<T> & self, ElementType type,
	GhostType ghost_type) -> decltype(auto) {
	return self(type, ghost_type);
	},
	py::arg("type"), py::arg("ghost_type") = _not_ghost,
	py::return_value_policy::reference, py::keep_alive<0, 1>())
	.def(
	"elementTypes",
	[](ElementTypeMapArray<T> & self, Int _dim, GhostType _ghost_type,
	ElementKind _kind) -> std::vector<ElementType> {
	auto types = self.elementTypes(_dim, _ghost_type, _kind);
	std::vector<ElementType> _types;
	for (auto && t : types) {
	_types.push_back(t);
	}
	return _types;
	},
	py::arg("dim") = _all_dimensions,
	py::arg("ghost_type") = _not_ghost, py::arg("kind") = _ek_regular)
	.def(
	"initialize",
	[](ElementTypeMapArray<T> & self, const Mesh & mesh,
	GhostType ghost_type, Int nb_component, Int spatial_dimension,
	ElementKind element_kind, bool with_nb_element,
	bool with_nb_nodes_per_element, T default_value,
	bool do_not_default) {
	self.initialize(
	mesh, _ghost_type = ghost_type, _nb_component = nb_component,
	_spatial_dimension =
	(spatial_dimension == -2 ? mesh.getSpatialDimension()
	: spatial_dimension),
	_element_kind = element_kind,
	_with_nb_element = with_nb_element,
	_with_nb_nodes_per_element = with_nb_nodes_per_element,
	_default_value = default_value,
	_do_not_default = do_not_default);
	},
	py::arg("mesh"), py::kw_only(), py::arg("ghost_type") = _casper,
	py::arg("nb_component") = 1, py::arg("spatial_dimension") = -2,
	py::arg("element_kind") = _ek_not_defined,
	py::arg("with_nb_element") = false,
	py::arg("with_nb_nodes_per_element") = false,
	py::arg("default_value") = T{}, py::arg("do_not_default") = false)
	.def(
	"initialize",
	[](ElementTypeMapArray<T> & self, const FEEngine & fe_engine,
	GhostType ghost_type, Int nb_component, Int spatial_dimension,
	ElementKind element_kind, bool with_nb_element,
	bool with_nb_nodes_per_element, T default_value,
	bool do_not_default) {
	self.initialize(
	fe_engine, _ghost_type = ghost_type,
	_nb_component = nb_component,
	_spatial_dimension =
	(spatial_dimension == -2
	? fe_engine.getMesh().getSpatialDimension()
	: spatial_dimension),
	_element_kind = element_kind,
	_with_nb_element = with_nb_element,
	_with_nb_nodes_per_element = with_nb_nodes_per_element,
	_default_value = default_value,
	_do_not_default = do_not_default);
	},
	py::arg("mesh"), py::kw_only(), py::arg("ghost_type") = _casper,
	py::arg("nb_component") = 1, py::arg("spatial_dimension") = -2,
	py::arg("element_kind") = _ek_not_defined,
	py::arg("with_nb_element") = false,
	py::arg("with_nb_nodes_per_element") = false,
	py::arg("default_value") = T{}, py::arg("do_not_default") = false)
	.def(
	"initialize",
	[](ElementTypeMapArray<T> & self, const FEEngine & fe_engine,
	GhostType ghost_type, Int nb_component, Int spatial_dimension,
	ElementKind element_kind, bool with_nb_element,
	bool with_nb_nodes_per_element, T default_value,
	bool do_not_default) {
	self.initialize(
	fe_engine, _ghost_type = ghost_type,
	_nb_component = nb_component,
	_spatial_dimension =
	(spatial_dimension == -2
	? fe_engine.getMesh().getSpatialDimension()
	: spatial_dimension),
	_element_kind = element_kind,
	_with_nb_element = with_nb_element,
	_with_nb_nodes_per_element = with_nb_nodes_per_element,
	_default_value = default_value,
	_do_not_default = do_not_default);
	},
	py::arg("fe_engine"), py::arg("ghost_type") = _casper,
	py::arg("nb_component") = 1, py::arg("spatial_dimension") = -2,
	py::arg("element_kind") = _ek_not_defined,
	py::arg("with_nb_element") = false,
	py::arg("with_nb_nodes_per_element") = false,
	py::arg("default_value") = T{}, py::arg("do_not_default") = false)
	.def("getID", &ElementTypeMapArray<T>::getID);
	}
	} // namespace
	/* -------------------------------------------------------------------------- */
	void register_mesh(py::module & mod) {
	py::class_<Mesh::PeriodicSlaves>(mod, "PeriodicSlaves")
	.def(
	"__iter__",
	[](Mesh::PeriodicSlaves & _this) {
	return py::make_iterator(_this.begin(), _this.end());
	},
	py::keep_alive<0, 1>());

	py::class_<MeshData>(mod, "MeshData")
	.def(
	"getElementalDataUInt",
	[](MeshData & _this, const ID & name) -> decltype(auto) {
	return _this.getElementalData<UInt>(name);
	},
	py::return_value_policy::reference)
	.def(
	"getElementalDataReal",
	[](MeshData & _this, const ID & name) -> decltype(auto) {
	return _this.getElementalData<Real>(name);
	},
	py::return_value_policy::reference);

	py::class_<Mesh, GroupManager, Dumpable, MeshData>(mod, "Mesh",
	py::multiple_inheritance())
	.def(py::init<Int, const ID &>(), py::arg("spatial_dimension"),
	py::arg("id") = "mesh")
	.def("read", &Mesh::read, py::arg("filename"),
	py::arg("mesh_io_type") = _miot_auto, "read the mesh from a file")
	.def(
	"getNodes",
	[](Mesh & self) -> decltype(auto) { return self.getNodes(); },
	py::return_value_policy::reference)
	.def("getNbNodes", &Mesh::getNbNodes)
	.def(
	"getConnectivity",
	[](Mesh & self, ElementType type) -> decltype(auto) {
	return self.getConnectivity(type);
	},
	py::return_value_policy::reference)
	.def(
	"getConnectivities",
	[](Mesh & self) -> decltype(auto) {
	return self.getConnectivities();
	},
	py::return_value_policy::reference)
	.def(
	"addConnectivityType",
	[](Mesh & self, ElementType type, GhostType ghost_type) -> void {
	self.addConnectivityType(type, ghost_type);
	},
	py::arg("type"), py::arg("ghost_type") = _not_ghost)
	.def("distribute", [](Mesh & self) { self.distribute(); })
	.def("isDistributed",
	[](const Mesh & self) { return self.isDistributed(); })
	.def("fillNodesToElements", &Mesh::fillNodesToElements,
	py::arg("dimension") = _all_dimensions)
	.def("getAssociatedElements",
	[](Mesh & self, const Idx & node, py::list list) {
	Array<Element> elements;
	self.getAssociatedElements(node, elements);
	for (auto && element : elements) {
	list.append(element);
	}
	})
	.def("makePeriodic",
	[](Mesh & self, const SpatialDirection & direction) {
	self.makePeriodic(direction);
	})
	.def(
	"getNbElement",
	[](Mesh & self, const Int spatial_dimension, GhostType ghost_type,
	ElementKind kind) {
	return self.getNbElement(spatial_dimension, ghost_type, kind);
	},
	py::kw_only(), py::arg("spatial_dimension") = _all_dimensions,
	py::arg("ghost_type") = _not_ghost, py::arg("kind") = _ek_not_defined)
	.def(
	"getNbElement",
	[](Mesh & self, ElementType type, GhostType ghost_type) {
	return self.getNbElement(type, ghost_type);
	},
	py::kw_only(), py::arg("type"), py::arg("ghost_type") = _not_ghost)
	.def_static(
	"getSpatialDimension",
	[](ElementType & type) { return Mesh::getSpatialDimension(type); })
	.def(
	"getDataReal",
	[](Mesh & _this, const ID & name, ElementType type,
	GhostType ghost_type) -> decltype(auto) {
	return _this.getData<Real>(name, type, ghost_type);
	},
	py::arg("name"), py::arg("type"), py::arg("ghost_type") = _not_ghost,
	py::return_value_policy::reference)
	.def(
	"hasDataReal",
	[](Mesh & _this, const ID & name, ElementType type,
	GhostType ghost_type) -> bool {
	return _this.hasData<Real>(name, type, ghost_type);
	},
	py::arg("name"), py::arg("type"), py::arg("ghost_type") = _not_ghost)
	.def("isPeriodic", [](const Mesh & _this) { return _this.isPeriodic(); })
	.def("getPeriodicMaster", &Mesh::getPeriodicMaster)
	.def("getPeriodicSlaves", &Mesh::getPeriodicSlaves)
	.def("isPeriodicSlave", &Mesh::isPeriodicSlave)
	.def("isPeriodicMaster", &Mesh::isPeriodicMaster)
	.def(
	"getMeshFacets",
	[](const Mesh & self) -> const Mesh & {
	return self.getMeshFacets();
	},
	py::return_value_policy::reference)
	.def("getUpperBounds", &Mesh::getUpperBounds)
	.def("getLowerBounds", &Mesh::getLowerBounds)
	.def("initMeshFacets", &Mesh::initMeshFacets,
	py::arg("id") = "mesh_facets", py::return_value_policy::reference);

	/* ------------------------------------------------------------------------ */
	py::class_<MeshUtils>(mod, "MeshUtils")
	.def_static("buildFacets", &MeshUtils::buildFacets);

	py::class_<MeshAccessor>(mod, "MeshAccessor")
	.def(py::init<Mesh &>(), py::arg("mesh"))
	.def(
	"resizeConnectivity",
	[](MeshAccessor & self, Int new_size, ElementType type, GhostType gt)
	-> void { self.resizeConnectivity(new_size, type, gt); },
	py::arg("new_size"), py::arg("type"),
	py::arg("ghost_type") = _not_ghost)
	.def(
	"resizeNodes",
	[](MeshAccessor & self, Int new_size) -> void {
	self.resizeNodes(new_size);
	},
	py::arg("new_size"))
	.def("makeReady", &MeshAccessor::makeReady);

	register_element_type_map_array<Real>(mod, "Real");
	register_element_type_map_array<UInt>(mod, "UInt");
	register_element_type_map_array<Int>(mod, "Int");
	register_element_type_map_array<bool>(mod, "bool");
	}
	} // namespace akantu

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