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update orient_polygon_soup to always produce a polyhedron 

with self-intersection at singular vertices/edges
This commit is contained in:
Sébastien Loriot 2015-01-29 12:27:43 +01:00
parent b4bd141980
commit 24fcc4a2fe
12 changed files with 557 additions and 156 deletions
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438
Operations_on_polyhedra/include/CGAL/orient_polygon_soup.h
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@ -14,21 +14,22 @@
//
// $URL$
// $Id$
//
//
// Author(s) : Laurent Rineau and Ilker O. Yaz
//
// Author(s) : Laurent Rineau and Sebastien Loriot
#ifndef CGAL_ORIENT_POLYGON_SOUP
#define CGAL_ORIENT_POLYGON_SOUP
#include <boost/foreach.hpp>
#include <set>
#include <map>
#include <stack>
#include <algorithm>
#include <iostream>
#include <CGAL/array.h>
namespace CGAL {
namespace internal {
@ -36,193 +37,368 @@ namespace internal {
template<class Point_3, class Polygon_3>
class Polygon_soup_orienter
{
typedef typename std::iterator_traits<typename Polygon_3::iterator>::value_type Index;
typedef std::vector<Point_3> Points;
typedef std::map<std::pair<Index, Index>, std::set<std::size_t> > Edges_map;
typedef cpp11::array<Index, 2> Edge;
typedef std::vector<Polygon_3> Polygons;
typedef std::set<Edge> Edges;
typedef typename Polygons::size_type size_type;
/// Index types
typedef typename std::iterator_traits<
typename Polygon_3::iterator >::value_type V_ID;
typedef typename std::vector<Polygon_3>::size_type P_ID;
// typedef int CC_ID;
typedef std::pair<V_ID, V_ID> V_ID_pair;
/// Container types
typedef std::vector<Point_3> Points;
typedef std::vector<Polygon_3> Polygons;
typedef std::map<V_ID_pair, std::set<P_ID> > Edge_map;
typedef typename Edge_map::iterator Edge_map_iterator;
typedef std::set<V_ID_pair> Marked_edges;
const Points& points;
Polygons& polygons;
/// Data members
Points& points; //< the set of input points
Polygons& polygons; //< the set of input polygons
Edge_map edges; //< the set of edges of the input polygons
Marked_edges marked_edges; //< the set of singular edges or edges incident
//< to non-compatible orientation polygons
Edges_map edges;
Edges non_manifold_edges;
/// for each polygon referenced by its position in `polygons`, indicates
/// the connected component it belongs too after orientation.
// std::vector< CC_ID > polygon_cc_id;
/// for each vertex, indicates the list of polygon containing it
std::vector< std::vector<P_ID> > incident_polygons_per_vertex;
private:
Edge canonical_edge(Index i, Index j)
/// Utility functions
V_ID_pair canonical_edge(V_ID i, V_ID j)
{
return i<j ? CGAL::make_array(i,j):CGAL::make_array(j,i);
return i<j ? V_ID_pair(i,j):V_ID_pair(j,i);
}
void fill_edges() {
// Fill edges
edges.clear();
for(size_type i = 0; i < polygons.size(); ++i)
{
const size_type size = polygons[i].size();
for(size_type j = 0; j < size; ++j) {
const Index& i0 = polygons[i][j];
const Index& i1 = polygons[i][ j+1 < size ? j+1: 0];
edges[std::make_pair(i0, i1)].insert(i);
}
}
bool is_edge_marked(V_ID i, V_ID j)
{
return marked_edges.count(canonical_edge(i,j));
}
// Fill non-manifold edges
non_manifold_edges.clear();
for(size_type i = 0; i < polygons.size(); ++i)
{
const size_type size = polygons[i].size();
for(size_type j = 0; j < size; ++j) {
const Index& i0 = polygons[i][j];
const Index& i1 = polygons[i][ j+1 < size ? j+1: 0];
void set_edge_marked(V_ID i, V_ID j)
{
marked_edges.insert(canonical_edge(i,j));
}
if( edges[std::make_pair(i0, i1)].size() +
edges[std::make_pair(i1, i0)].size() > 2 )
{
non_manifold_edges.insert(canonical_edge(i0,i1));
}
}
}
cpp11::array<V_ID,3>
get_neighbor_vertices(V_ID v_id, P_ID polygon_index)
{
std::size_t nbv = polygons[polygon_index].size(), pvid=0;
for (; pvid!=nbv; ++pvid)
if (v_id==polygons[polygon_index][pvid]) break;
CGAL_assertion( pvid!=nbv );
V_ID prev = polygons[polygon_index][ (pvid+nbv-1)%nbv ];
V_ID next = polygons[polygon_index][ (pvid+1)%nbv ];
return make_array(prev,v_id,next);
}
std::pair<V_ID,P_ID>
next_cw_vertex_around_source(V_ID src, V_ID tgt)
{
typedef std::pair<V_ID,P_ID> VID_and_PID;
if ( is_edge_marked(src,tgt) ) return VID_and_PID(src,300612);
Edge_map_iterator em_it=edges.find(V_ID_pair(tgt, src));
if ( em_it==edges.end() ) return VID_and_PID(src,300612);// the vertex is on the border
CGAL_assertion(em_it->second.size()==1);
P_ID p_id = *(em_it->second.begin());
return VID_and_PID(get_neighbor_vertices(src, p_id)[2], p_id);
}
std::pair<V_ID,P_ID>
next_ccw_vertex_around_target(V_ID src, V_ID tgt)
{
typedef std::pair<V_ID,P_ID> VID_and_PID;
if ( is_edge_marked(src,tgt) ) return VID_and_PID(tgt,300612);
Edge_map_iterator em_it=edges.find(V_ID_pair(tgt, src));
if ( em_it==edges.end() ) return VID_and_PID(tgt,300612);// the vertex is on the border
CGAL_assertion(em_it->second.size()==1);
P_ID p_id = *(em_it->second.begin());
return VID_and_PID(get_neighbor_vertices(tgt, p_id)[0], p_id);
}
void inverse_orientation(const std::size_t index) {
std::reverse(polygons[index].begin(), polygons[index].end());
}
public:
Polygon_soup_orienter(const Points& points, Polygons& polygons)
: points(points), polygons(polygons)
void replace_vertex_index_in_polygon(
std::size_t polygon_id,
V_ID old_index,
V_ID new_index)
{
fill_edges();
BOOST_FOREACH(V_ID& i, polygons[polygon_id])
if( i==old_index )
i=new_index;
}
bool orient()
/// Functions filling containers
void fill_edge_map() {
// Fill edges
edges.clear();
for(P_ID i = 0; i < polygons.size(); ++i)
{
const P_ID size = polygons[i].size();
for(P_ID j = 0; j < size; ++j) {
V_ID i0 = polygons[i][j];
V_ID i1 = polygons[i][ (j+1)%size];
edges[V_ID_pair(i0, i1)].insert(i);
}
}
// Fill non-manifold edges
marked_edges.clear();
for(P_ID i = 0; i < polygons.size(); ++i)
{
const P_ID size = polygons[i].size();
for(P_ID j = 0; j < size; ++j) {
V_ID i0 = polygons[i][j];
V_ID i1 = polygons[i][ (j+1)%size ];
std::size_t nb_edges = 0;
Edge_map_iterator em_it = edges.find( V_ID_pair(i0, i1) );
if ( em_it!=edges.end() ) nb_edges += em_it->second.size();
em_it = edges.find( V_ID_pair(i1, i0) );
if ( em_it!=edges.end() ) nb_edges += em_it->second.size();
if( nb_edges > 2 ) set_edge_marked(i0,i1);
}
}
}
void fill_incident_polygons_per_vertex()
{
incident_polygons_per_vertex.resize(points.size());
P_ID nb_polygons=polygons.size();
for(P_ID ip=0; ip<nb_polygons; ++ip)
{
BOOST_FOREACH(V_ID iv, polygons[ip])
incident_polygons_per_vertex[iv].push_back(ip);
}
}
public:
Polygon_soup_orienter(Points& points, Polygons& polygons)
: points(points), polygons(polygons)
{
fill_edge_map();
}
/// We try to orient polygon consistently by walking in the dual graph, from
/// a not yet re-oriented polygon.
/// We have an edge between two polygons if they share an edge, and this edge
/// is shared by exactly two polygons. While walking along an edge, we reorient
/// the polygon we walked in if its orientation is not compatible with the one
/// we come from.
/// If the polygon was already marked as oriented, then we cut the dual edge
/// in the graph and the primal edge is marked.
/// At the same time, we assign an id to each polygon in the same connected
/// componenet of the dual graph.
void orient()
{
std::vector<bool> oriented;
std::stack<std::size_t> stack;
using std::make_pair;
// polygon_cc_id.resize(polygons.size(), -1);
// no polygon is oriented
// We first consider all polygons as non-oriented
oriented.resize(polygons.size());
size_type polygon_index = 0;
bool success = true;
P_ID polygon_index = 0;
while (polygon_index != polygons.size())
// CC_ID current_cc_index=-1;
while (polygon_index != polygons.size())
{
// We look for the first polygon not already oriented
while ( polygon_index != polygons.size() && oriented[polygon_index] ) {
++polygon_index;
}
if(polygon_index == polygons.size()) break;
// ++ current_cc_index; // visit a new connected component
// we visit the connected component by crossing edges manifold edges
oriented[polygon_index] = true;
stack.push(polygon_index);
while(! stack.empty() )
{
const size_type to_be_oriented_index = stack.top();
const P_ID to_be_oriented_index = stack.top();
stack.pop();
const size_type size = polygons[to_be_oriented_index].size();
for(size_type ih = 0 ; ih < size ; ++ih) {
size_type ihp1 = ih+1;
if(ihp1>=size) ihp1 = 0;
const Index& i1 = polygons[to_be_oriented_index][ih];
const Index& i2 = polygons[to_be_oriented_index][ihp1];
if(non_manifold_edges.count(canonical_edge(i1,i2)) > 0) {
continue;
}
// CGAL_assertion(polygon_cc_id[to_be_oriented_index]==-1);
// polygon_cc_id[to_be_oriented_index]=current_cc_index;
const P_ID size = polygons[to_be_oriented_index].size();
for(P_ID ih = 0 ; ih < size ; ++ih) {
P_ID ihp1 = (ih+1)%size;
const V_ID i1 = polygons[to_be_oriented_index][ih];
const V_ID i2 = polygons[to_be_oriented_index][ihp1];
if( is_edge_marked(i1,i2) ) continue;
// edge (i1,i2)
typename Edges_map::iterator it_same_orient = edges.find(make_pair(i1, i2));
Edge_map_iterator it_same_orient = edges.find(V_ID_pair(i1, i2));
// edges (i2,i1)
typename Edges_map::iterator it_other_orient = edges.find(make_pair(i2, i1));
Edge_map_iterator it_other_orient = edges.find(V_ID_pair(i2, i1));
CGAL_assertion(it_same_orient != edges.end());
if(it_same_orient->second.size() > 1) {
if((it_other_orient != edges.end() && it_other_orient->second.size() > 0) ||
it_same_orient->second.size() > 2) {
// three polygons at the edge
success = false; // non-orientable
}
{
// one neighbor polyhedron, opposite orientation
size_type index = *(it_same_orient->second.begin());
if(index == to_be_oriented_index)
index = *(++it_same_orient->second.begin());
if(oriented[index]) {
// "neighbor polygon #%1 is already oriented, but in opposite orientation").arg(index);
success = false; // non-orientable
continue; // next edge
}
CGAL_assertion(it_other_orient == edges.end() ||
it_other_orient->second.size()==1);
// reverse the orientation
const size_type size = polygons[index].size();
for(size_type j = 0; j < size; ++j) {
const Index& i0 = polygons[index][j];
const Index& i1 = polygons[index][ j+1 < size ? j+1: 0];
CGAL_assertion_code(const bool r = )
edges[std::make_pair(i0, i1)].erase(index)
CGAL_assertion_code(!= 0);
CGAL_assertion(r);
}
inverse_orientation(index);
for(size_type j = 0; j < size; ++j) {
const Index& i0 = polygons[index][j];
const Index& i1 = polygons[index][ j+1 < size ? j+1: 0];
edges[std::make_pair(i0, i1)].insert(index);
}
// "inverse the orientation of polygon #%1\n").arg(index);
if (it_same_orient->second.size() > 1)
{
CGAL_assertion(it_other_orient == edges.end());
// one neighbor but with the same orientation
P_ID index = *(it_same_orient->second.begin());
if(index == to_be_oriented_index)
index = *(++it_same_orient->second.begin());
if(oriented[index])
{
// polygon already oriented but its orientation is not compatible ---> mark the edge and continue
set_edge_marked(i1,i2);
continue; // next edge
}
// reverse the orientation
const P_ID size = polygons[index].size();
for(P_ID j = 0; j < size; ++j) {
V_ID i0 = polygons[index][j];
V_ID i1 = polygons[index][(j+1)%size];
Edge_map_iterator em_it = edges.find(V_ID_pair(i0, i1));
CGAL_assertion_code(const bool r = )
em_it->second.erase(index)
CGAL_assertion_code(!= 0);
CGAL_assertion(r);
if ( em_it->second.empty() ) edges.erase(em_it);
}
inverse_orientation(index);
for(P_ID j = 0; j < size; ++j) {
V_ID i0 = polygons[index][j];
V_ID i1 = polygons[index][(j+1)%size];
edges[V_ID_pair(i0, i1)].insert(index);
}
// "inverse the orientation of polygon #index
oriented[index] = true;
stack.push(index);
}
else{
if( it_other_orient != edges.end() ){
CGAL_assertion(it_same_orient->second.size() == 1);
CGAL_assertion(it_other_orient->second.size() == 1);
// one polygon, same orientation
const P_ID index = *(it_other_orient->second.begin());
if(oriented[index]) continue; //nothing todo already processed and correctly oriented
oriented[index] = true;
// "keep the orientation of polygon #index
stack.push(index);
}
}
else if(it_other_orient != edges.end() && it_other_orient->second.size() == 1) {
// one polygon, same orientation
const size_type index = *(it_other_orient->second.begin());
if(oriented[index])
continue;
oriented[index] = true;
// "keep the orientation of polygon #%1\n").arg(index);
stack.push(index);
}
else {
if(it_same_orient->second.size() != 1 ||
(it_other_orient != edges.end() && it_other_orient->second.size() > 0))
{
success = false; // non-orientable
}
}
} // end for on all edges of one
} // end for on all edges of one
} // end while loop on the polygons of the connected component
} // end while loop on all non-oriented polygons remaining
} // end while loop on all non-oriented polygons remaining
}
return success;
/// A vertex is said to be singular if its link is neither a cycle nor a chain,
/// but several cycles and chains.
/// For each such vertex v, we consider each set of polygons incident to v
/// and sharing a non-marked edge incident to v. A copy of v is assigned to
/// each but one set of incident polygons.
void duplicate_singular_vertices()
{
fill_incident_polygons_per_vertex();
std::vector< std::pair<V_ID, std::vector<P_ID> > > vertices_to_duplicate;
V_ID nbv = static_cast<V_ID>( points.size() );
for (V_ID v_id = 0; v_id < nbv; ++v_id)
{
const std::vector< P_ID >& incident_polygons = incident_polygons_per_vertex[v_id];
if ( incident_polygons.empty() ) continue; //isolated vertex
std::set<P_ID> visited_polygons;
bool first_pass = true;
BOOST_FOREACH(P_ID p_id, incident_polygons)
{
if ( !visited_polygons.insert(p_id).second ) continue; // already visited
if (!first_pass)
{
vertices_to_duplicate.push_back(std::pair<V_ID, std::vector<P_ID> >());
vertices_to_duplicate.back().first=v_id;
}
const cpp11::array<V_ID,3>& neighbors = get_neighbor_vertices(v_id,p_id);
V_ID next = neighbors[2];
if( !first_pass)
vertices_to_duplicate.back().second.push_back(p_id);
do{
P_ID other_p_id;
cpp11::tie(next, other_p_id) = next_cw_vertex_around_source(v_id, next);
if (next==v_id) break;
visited_polygons.insert(other_p_id);
if( !first_pass)
vertices_to_duplicate.back().second.push_back(other_p_id);
}
while(next!=neighbors[0]);
if (next==v_id){
/// turn the otherway round
next = neighbors[0];
do{
P_ID other_p_id;
cpp11::tie(next, other_p_id) = next_ccw_vertex_around_target(next, v_id);
if (next==v_id) break;
visited_polygons.insert(other_p_id);
if( !first_pass)
vertices_to_duplicate.back().second.push_back(other_p_id);
}
while(true);
}
first_pass=false;
}
}
/// now duplicate the vertices
typedef std::pair<V_ID, std::vector<P_ID> > V_ID_and_Polygon_ids;
BOOST_FOREACH(const V_ID_and_Polygon_ids& vid_and_pids, vertices_to_duplicate)
{
V_ID new_index = static_cast<V_ID>(points.size());
points.push_back( points[vid_and_pids.first] );
BOOST_FOREACH(P_ID polygon_id, vid_and_pids.second)
replace_vertex_index_in_polygon(polygon_id, vid_and_pids.first, new_index);
}
}
};
} // namespace internal
/**
* Tries to consistently orient a soup of polygons in 3D space.
* If a consistent orientation has been found, `true` is returned.
* In any case `polygons` is updated.
/**
* Tries to consistently orient a soup of polygons in 3D space.
* If it is not possible to produce a combinatorial manifold surface, some points will be
* duplicated. These points are either an endpoint of edges incident to more than
* two polygons, or an endpoint of an edge between two polygons with incompatible orientations
* (during the re-orientation process), or a point shared by at least two polygons that do not
* share an edge this point is incident to.
* @tparam Point_3 the point type
* @tparam Polygon_3 the Polygon type, being a container of indices
*
* @param points points of the soup of polygons.
* @param[in, out] polygons each element in the vector describes a polygon using the index of the points in the vector.
* @param[in,out] points points of the soup of polygons. Some points might be pushed back to resolve
* non-manifold or non-orientability issues.
* @param[in, out] polygons each element in the vector describes a polygon using the index of the points in `points`.
*
* @return true if a consistent orientation has been found
* @return return false if some points where duplicated, thus producing a self-intersecting polyhedron
*
* \TODO code: there is no check for duplicate points, yet it can be implemented as separate filter function
*/
*/
template <class Point_3, class Polygon_3>
bool orient_polygon_soup(const std::vector<Point_3>& points,
bool orient_polygon_soup(std::vector<Point_3>& points,
std::vector< Polygon_3 >& polygons)
{
std::size_t inital_nb_pts = points.size();
internal::Polygon_soup_orienter<Point_3, Polygon_3> orienter(points, polygons);
return orienter.orient();
orienter.orient();
orienter.duplicate_singular_vertices();
return inital_nb_pts==points.size();
}
}// namespace CGAL

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3 3 2 7
3 7 2 6
3 4 0 3
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3 6 4 7
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4 3 2 6 5
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4 6 7 12 13
4 10 11 12 13
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#include <CGAL/Polyhedron_3.h>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/orient_polygon_soup.h>
#include <CGAL/polygon_soup_to_polyhedron_3.h>
#include <CGAL/IO/OFF_reader.h>
#include <string>
#include <fstream>
#include <iostream>
typedef CGAL::Simple_cartesian<double> K;
typedef CGAL::Polyhedron_3<K> Polyhedron;
void test(std::string fname, std::size_t expected_duplicated_vertices)
{
std::vector<K::Point_3> points;
std::vector< std::vector<std::size_t> > polygons;
std::ifstream input(fname.c_str());
if (!input)
{
std::cerr << "Cannot open file " << fname << "\n";
exit(EXIT_FAILURE);
}
if (!CGAL::read_OFF(input, points, polygons))
{
std::cerr << "Error parsing the OFF file " << fname << "\n";
exit(EXIT_FAILURE);
}
std::size_t initial_nb_points = points.size();
CGAL::orient_polygon_soup(points, polygons);
assert(expected_duplicated_vertices == points.size()-initial_nb_points);
Polyhedron P;
CGAL::polygon_soup_to_polyhedron_3(P, points, polygons);
assert(P.is_valid());
std::cout << fname << " OK\n";
}
int main()
{
test("data_polygon_soup/bad_cube.off", 4);
test("data_polygon_soup/isolated_singular_vertex_one_cc.off", 1);
test("data_polygon_soup/isolated_vertices.off", 1);
test("data_polygon_soup/nm_vertex_and_edge.off", 6);
test("data_polygon_soup/one_duplicated_edge.off", 6);
test("data_polygon_soup/one_duplicated_edge_sharing_vertex.off", 8);
test("data_polygon_soup/partial_overlap.off", 4);
test("data_polygon_soup/incompatible_orientation.off", 2);
}

41
Polyhedron/demo/Polyhedron/Polyhedron_demo_orient_soup_plugin.cpp
View File

@ -88,28 +88,27 @@ void Polyhedron_demo_orient_soup_plugin::orient()
// qDebug() << tr("I have the item %1\n").arg(item->name());
QApplication::setOverrideCursor(Qt::WaitCursor);
if(!item->orient()) {
messages->warning(tr("The polygon soup \"%1\" is not orientable.")
.arg(item->name()));
// QMessageBox::information(mw, tr("Not orientable"),
// tr("The polygon soup \"%1\" is not orientable.")
// .arg(item->name()));
scene->itemChanged(item);
} else {
Scene_polyhedron_item* poly_item = new Scene_polyhedron_item();
if(item->exportAsPolyhedron(poly_item->polyhedron())) {
poly_item->setName(item->name());
poly_item->setColor(item->color());
poly_item->setRenderingMode(item->renderingMode());
poly_item->setVisible(item->visible());
poly_item->changed();
poly_item->setProperty("source filename", item->property("source filename"));
scene->replaceItem(index, poly_item);
delete item;
} else {
scene->itemChanged(item);
}
QMessageBox::information(mw, tr("Not orientable without self-intersections"),
tr("The polygon soup \"%1\" is not directly orientable."
" Some vertices have been duplicated and some self-intersections"
" have been created.")
.arg(item->name()));
}
Scene_polyhedron_item* poly_item = new Scene_polyhedron_item();
if(item->exportAsPolyhedron(poly_item->polyhedron())) {
poly_item->setName(item->name());
poly_item->setColor(item->color());
poly_item->setRenderingMode(item->renderingMode());
poly_item->setVisible(item->visible());
poly_item->changed();
poly_item->setProperty("source filename", item->property("source filename"));
scene->replaceItem(index, poly_item);
delete item;
} else {
scene->itemChanged(item);
}
QApplication::restoreOverrideCursor();
}
else{

7
Polyhedron/demo/Polyhedron/Scene_polygon_soup_item.cpp
View File

@ -155,11 +155,10 @@ void Scene_polygon_soup_item::inside_out()
bool
Scene_polygon_soup_item::orient()
{
if(isEmpty() || this->oriented)
if(isEmpty() || oriented)
return true; // nothing to do
oriented = CGAL::orient_polygon_soup(soup->points, soup->polygons);
return oriented;
oriented=true;
return CGAL::orient_polygon_soup(soup->points, soup->polygons);
}