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mesh_segment_intersector_tmpl.hh
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mesh_segment_intersector_tmpl.hh
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/**
* @file mesh_segment_intersector_tmpl.hh
*
* @author Lucas Frerot <lucas.frerot@epfl.ch>
* @author Clement Roux <clement.roux@epfl.ch>
* @author Marco Vocialta <marco.vocialta@epfl.ch>
*
* @date creation: Wed Apr 29 2015
* @date last modification: Thu Jan 14 2016
*
* @brief Computation of mesh intersection with segments
*
* @section LICENSE
*
* Copyright (©) 2015 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/>.
*
*/
/* -------------------------------------------------------------------------- */
#ifndef __AKANTU_MESH_SEGMENT_INTERSECTOR_TMPL_HH__
#define __AKANTU_MESH_SEGMENT_INTERSECTOR_TMPL_HH__
#include "aka_common.hh"
#include "mesh_geom_common.hh"
#include "tree_type_helper.hh"
__BEGIN_AKANTU__
template<UInt dim, ElementType type>
MeshSegmentIntersector<dim, type>::MeshSegmentIntersector(Mesh & mesh, Mesh & result_mesh):
parent_type(mesh),
result_mesh(result_mesh),
current_physical_name()
{
this->intersection_points = new Array<Real>(0,dim);
this->constructData();
}
template<UInt dim, ElementType type>
MeshSegmentIntersector<dim, type>::~MeshSegmentIntersector()
{}
template<UInt dim, ElementType type>
void MeshSegmentIntersector<dim, type>::computeIntersectionQuery(const K::Segment_3 & query) {
AKANTU_DEBUG_IN();
result_mesh.addConnectivityType(_segment_2, _not_ghost);
result_mesh.addConnectivityType(_segment_2, _ghost);
std::list<result_type> result_list;
std::set<std::pair<K::Segment_3, UInt>, segmentPairsLess> segment_set;
this->factory.getTree().all_intersections(query, std::back_inserter(result_list));
this->computeSegments(result_list, segment_set, query);
// Arrays for storing nodes and connectivity
Array<Real> & nodes = result_mesh.getNodes();
Array<UInt> & connectivity = result_mesh.getConnectivity(_segment_2);
// Arrays for storing associated element and physical name
bool valid_elemental_data = true;
Array<Element> * associated_element = NULL;
Array<std::string> * associated_physical_name = NULL;
try {
associated_element = &result_mesh.getData<Element>("associated_element", _segment_2);
associated_physical_name = &result_mesh.getData<std::string>("physical_names", _segment_2);
} catch (debug::Exception & e) {
valid_elemental_data = false;
}
std::set<pair_type, segmentPairsLess>::iterator
it = segment_set.begin(),
end = segment_set.end();
// Loop over the segment pairs
for (; it != end ; ++it) {
if (!it->first.is_degenerate()) {
Vector<UInt> segment_connectivity(2);
segment_connectivity(0) = result_mesh.getNbNodes();
segment_connectivity(1) = result_mesh.getNbNodes() + 1;
connectivity.push_back(segment_connectivity);
// Copy nodes
Vector<Real> source(dim), target(dim);
for (UInt j = 0 ; j < dim ; j++) {
source(j) = it->first.source()[j];
target(j) = it->first.target()[j];
}
nodes.push_back(source);
nodes.push_back(target);
// Copy associated element info
if (valid_elemental_data) {
associated_element->push_back(Element(type, it->second));
associated_physical_name->push_back(current_physical_name);
}
}
}
AKANTU_DEBUG_OUT();
}
template<UInt dim, ElementType type>
void MeshSegmentIntersector<dim, type>:: computeMeshQueryIntersectionPoint(const K::Segment_3 & query,
UInt nb_old_nodes) {
AKANTU_DEBUG_ERROR("The method: computeMeshQueryIntersectionPoint has not been implemented in class MeshSegmentIntersector!");
}
template<UInt dim, ElementType type>
void MeshSegmentIntersector<dim, type>::buildResultFromQueryList(const std::list<K::Segment_3> & query_list) {
AKANTU_DEBUG_IN();
this->computeIntersectionQueryList(query_list);
AKANTU_DEBUG_OUT();
}
template<UInt dim, ElementType type>
void MeshSegmentIntersector<dim, type>::computeSegments(const std::list<result_type> & intersections,
std::set<pair_type, segmentPairsLess> & segments,
const K::Segment_3 & query) {
AKANTU_DEBUG_IN();
/*
* Number of intersections = 0 means
*
* - query is completely outside mesh
* - query is completely inside primitive
*
* We try to determine the case and still construct the segment list
*/
if (intersections.size() == 0) {
// We look at all the primitives intersected by two rays
// If there is one primitive in common, then query is inside
// that primitive
K::Ray_3 ray1(query.source(), query.target());
K::Ray_3 ray2(query.target(), query.source());
std::set<UInt> ray1_results, ray2_results;
this->factory.getTree().all_intersected_primitives(ray1, std::inserter(ray1_results, ray1_results.begin()));
this->factory.getTree().all_intersected_primitives(ray2, std::inserter(ray2_results, ray2_results.begin()));
bool inside_primitive = false;
UInt primitive_id = 0;
std::set<UInt>::iterator
ray2_it = ray2_results.begin(),
ray2_end = ray2_results.end();
// Test if first list contains an element of second list
for (; ray2_it != ray2_end && !inside_primitive ; ++ray2_it) {
if (ray1_results.find(*ray2_it) != ray1_results.end()) {
inside_primitive = true;
primitive_id = *ray2_it;
}
}
if (inside_primitive) {
segments.insert(std::make_pair(query, primitive_id));
}
}
else {
typename std::list<result_type>::const_iterator
it = intersections.begin(),
end = intersections.end();
for(; it != end ; ++it) {
UInt el = (*it)->second;
// Result of intersection is a segment
if (const K::Segment_3 * segment = boost::get<K::Segment_3>(&((*it)->first))) {
// Check if the segment was alread created
segments.insert(std::make_pair(*segment, el));
}
// Result of intersection is a point
else if (const K::Point_3 * point = boost::get<K::Point_3>(&((*it)->first))) {
// We only want to treat points differently if we're in 3D with Tetra4 elements
// This should be optimized by compilator
if (dim == 3 && type == _tetrahedron_4) {
UInt nb_nodes_per_element = Mesh::getNbNodesPerElement(type);
TreeTypeHelper<Triangle<K>, K>::container_type facets;
const Array<Real> & nodes = this->mesh.getNodes();
Array<UInt>::const_vector_iterator
connectivity_vec = this->mesh.getConnectivity(type).begin(nb_nodes_per_element);
const Vector<UInt> & el_connectivity = connectivity_vec[el];
Matrix<Real> node_coordinates(dim, nb_nodes_per_element);
for (UInt i = 0 ; i < nb_nodes_per_element ; i++)
for (UInt j = 0 ; j < dim ; j++)
node_coordinates(j, i) = nodes(el_connectivity(i), j);
this->factory.addPrimitive(node_coordinates, el, facets);
// Local tree
TreeTypeHelper<Triangle<K>, K>::tree * local_tree =
new TreeTypeHelper<Triangle<K>, K>::tree(facets.begin(), facets.end());
// Compute local intersections (with current element)
std::list<result_type> local_intersections;
local_tree->all_intersections(query, std::back_inserter(local_intersections));
bool out_point_found = false;
typename std::list<result_type>::const_iterator
local_it = local_intersections.begin(),
local_end = local_intersections.end();
for (; local_it != local_end ; ++local_it) {
if (const K::Point_3 * local_point = boost::get<K::Point_3>(&((*local_it)->first))) {
if (!comparePoints(*point, *local_point)) {
K::Segment_3 seg(*point, *local_point);
segments.insert(std::make_pair(seg, el));
out_point_found = true;
}
}
}
if (!out_point_found) {
TreeTypeHelper<Triangle<K>, K>::point_type
a(node_coordinates(0, 0), node_coordinates(1, 0), node_coordinates(2, 0)),
b(node_coordinates(0, 1), node_coordinates(1, 1), node_coordinates(2, 1)),
c(node_coordinates(0, 2), node_coordinates(1, 2), node_coordinates(2, 2)),
d(node_coordinates(0, 3), node_coordinates(1, 3), node_coordinates(2, 3));
K::Tetrahedron_3 tetra(a, b, c, d);
const K::Point_3 * inside_point = NULL;
if (tetra.has_on_bounded_side(query.source()) && !tetra.has_on_boundary(query.source()))
inside_point = &query.source();
else if (tetra.has_on_bounded_side(query.target()) && !tetra.has_on_boundary(query.target()))
inside_point = &query.target();
if (inside_point) {
K::Segment_3 seg(*inside_point, *point);
segments.insert(std::make_pair(seg, el));
}
}
delete local_tree;
}
}
}
}
AKANTU_DEBUG_OUT();
}
__END_AKANTU__
#endif // __AKANTU_MESH_SEGMENT_INTERSECTOR_TMPL_HH__

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