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// Copyright (c) 2013 Technical University Braunschweig (Germany).
// All rights reserved.
//
// This file is part of CGAL (www.cgal.org).
// You can redistribute it and/or modify it under the terms of the GNU
// General Public License as published by the Free Software Foundation,
// either version 3 of the License, or (at your option) any later version.
//
// Licensees holding a valid commercial license may use this file in
// accordance with the commercial license agreement provided with the software.
//
// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
//
// $URL$
// $Id$
// SPDX-License-Identifier: GPL-3.0+
//
//
// Author(s): Kan Huang <huangkandiy@gmail.com>
//
#ifndef CGAL_ROTATIONAL_SWEEP_VISIBILITY_2_H
#define CGAL_ROTATIONAL_SWEEP_VISIBILITY_2_H
#include <CGAL/license/Visibility_2.h>
#include <CGAL/Visibility_2/visibility_utils.h>
#include <CGAL/Arrangement_2.h>
#include <CGAL/bounding_box.h>
#include <CGAL/assertions.h>
#include <CGAL/Kernel/global_functions_2.h>
#include <boost/unordered_map.hpp>
#include <iterator>
namespace CGAL {
template<class Arrangement_2_ , class RegularizationCategory = CGAL::Tag_true >
class Rotational_sweep_visibility_2 {
public:
typedef Arrangement_2_ Arrangement_2;
typedef typename Arrangement_2::Traits_2 Traits_2;
typedef typename Arrangement_2::Geometry_traits_2 Geometry_traits_2;
typedef typename Arrangement_2::Vertex_const_handle Vertex_const_handle;
typedef typename Arrangement_2::Vertex_handle Vertex_handle;
typedef typename Arrangement_2::Halfedge_const_handle Halfedge_const_handle;
typedef typename Arrangement_2::Halfedge_handle Halfedge_handle;
typedef typename Arrangement_2::
Ccb_halfedge_const_circulator Ccb_halfedge_const_circulator;
typedef typename Arrangement_2::Face_const_handle Face_const_handle;
typedef typename Arrangement_2::Face_handle Face_handle;
typedef typename Geometry_traits_2::Kernel K;
typedef typename Geometry_traits_2::Point_2 Point_2;
typedef typename Geometry_traits_2::Ray_2 Ray_2;
typedef typename Geometry_traits_2::Segment_2 Segment_2;
typedef typename Geometry_traits_2::Line_2 Line_2;
typedef typename Geometry_traits_2::Vector_2 Vector_2;
typedef typename Geometry_traits_2::Direction_2 Direction_2;
typedef typename Geometry_traits_2::FT Number_type;
typedef typename Geometry_traits_2::Object_2 Object_2;
typedef RegularizationCategory Regularization_category;
typedef CGAL::Tag_true Supports_general_polygon_category;
typedef CGAL::Tag_true Supports_simple_polygon_category;
private:
typedef std::vector<Point_2> Points;
typedef Vertex_const_handle VH;
typedef std::vector<VH> VHs;
typedef Halfedge_const_handle EH;
typedef std::vector<EH> EHs;
class Less_edge: public CGAL::cpp98::binary_function<EH, EH, bool> {
const Geometry_traits_2* geom_traits;
public:
Less_edge() {}
Less_edge(const Geometry_traits_2* traits):geom_traits(traits) {}
bool operator() (const EH e1, const EH e2) const {
if (e1 == e2)
return false;
else {
return &(*e1)<&(*e2);
}
// if (e1->source() == e2->source())
// return Visibility_2::compare_xy_2(geom_traits,
// e1->target()->point(), e2->target()->point()) == SMALLER;
// else
// return Visibility_2::compare_xy_2(geom_traits,
// e1->source()->point(), e2->source()->point()) == SMALLER;
}
};
class Less_vertex: public CGAL::cpp98::binary_function<VH, VH, bool> {
const Geometry_traits_2* geom_traits;
public:
Less_vertex() {}
Less_vertex(const Geometry_traits_2* traits):geom_traits(traits) {}
bool operator() (const VH v1, const VH v2) const {
if (v1 == v2)
return false;
else
// I know this is dirty but it speeds up by 25%. Michael
return &(*v1)<&(*v2);
// return Visibility_2::
// compare_xy_2(geom_traits, v1->point(), v2->point()) == SMALLER;
}
};
class Closer_edge: public CGAL::cpp98::binary_function<EH, EH, bool> {
const Geometry_traits_2* geom_traits;
Point_2 q;
public:
Closer_edge() {}
Closer_edge(const Geometry_traits_2* traits, const Point_2& q) :
geom_traits(traits), q(q) {}
int vtype(const Point_2& c, const Point_2& p) const {
switch(Visibility_2::orientation_2(geom_traits, q, c, p)) {
case COLLINEAR:
if (Visibility_2::less_distance_to_point_2(geom_traits, q, c, p))
return 0;
else
return 3;
case RIGHT_TURN:
return 1;
case LEFT_TURN:
return 2;
default: CGAL_assume(false);
}
return -1;
}
bool operator() (const EH& e1, const EH& e2) const {
if (e1 == e2)
return false;
const Point_2& s1=e1->source()->point(),
t1=e1->target()->point(),
s2=e2->source()->point(),
t2=e2->target()->point();
if (e1->source() == e2->source()) {
int vt1 = vtype(s1, t1),
vt2 = vtype(s1, t2);
if (vt1 != vt2)
return vt1 > vt2;
else
return (Visibility_2::orientation_2(geom_traits, s1, t2, t1)==
Visibility_2::orientation_2(geom_traits, s1, t2, q));
}
if (e1->target() == e2->source()) {
// const Point_2& p1 = s1,
// p2 = t2,
// c = s2;
int vt1 = vtype(t1, s1),
vt2 = vtype(t1, t2);
if (vt1 != vt2)
return vt1 > vt2;
else
return (Visibility_2::orientation_2(geom_traits, s2, t2, s1)==
Visibility_2::orientation_2(geom_traits, s2, t2, q));
}
if (e1->source() == e2->target()) {
// const Point_2& p1 = t1,
// p2 = s2,
// c = s1;
int vt1 = vtype(s1, t1),
vt2 = vtype(s1, s2);
if (vt1 != vt2)
return vt1 > vt2;
else return (Visibility_2::orientation_2(geom_traits, s1, s2, t1)==
Visibility_2::orientation_2(geom_traits, s1, s2, q));
}
if (e1->target() == e2->target()) {
// const Point_2& p1 = s1,
// p2 = s2,
// c = t1;
int vt1 = vtype(t1, s1),
vt2 = vtype(t1, s2);
if (vt1 != vt2)
return vt1 > vt2;
else return (Visibility_2::orientation_2(geom_traits, t1, s2, s1)==
Visibility_2::orientation_2(geom_traits, t1, s2, q));
}
Orientation e1q = Visibility_2::orientation_2(geom_traits, s1, t1, q);
switch (e1q)
{
case COLLINEAR:
if (Visibility_2::collinear(geom_traits, q, s2, t2)) {
//q is collinear with e1 and e2.
return (Visibility_2::less_distance_to_point_2(geom_traits, q, s1, s2)
|| Visibility_2::less_distance_to_point_2(geom_traits, q, t1, t2));
}
else {
//q is collinear with e1 not with e2.
if (Visibility_2::collinear(geom_traits, s2, t2, s1))
return (Visibility_2::orientation_2(geom_traits, s2, t2, q)
== Visibility_2::orientation_2(geom_traits, s2, t2, t1));
else
return (Visibility_2::orientation_2(geom_traits, s2, t2, q)
== Visibility_2::orientation_2(geom_traits, s2, t2, s1));
}
break;
case RIGHT_TURN:
switch (Visibility_2::orientation_2(geom_traits, s1, t1, s2)) {
case COLLINEAR:
return Visibility_2::orientation_2(geom_traits, s1, t1, t2)!=e1q;
case RIGHT_TURN:
if (Visibility_2::orientation_2(geom_traits, s1, t1, t2) == LEFT_TURN)
return Visibility_2::orientation_2(geom_traits, s2, t2, q)
== Visibility_2::orientation_2(geom_traits, s2, t2, s1);
else
return false;
case LEFT_TURN:
if(Visibility_2::orientation_2(geom_traits, s1, t1, t2) == RIGHT_TURN)
return Visibility_2::orientation_2(geom_traits, s2, t2, q)
== Visibility_2::orientation_2(geom_traits, s2, t2, s1);
else
return true;
default: CGAL_assume(false);
}
break;
case LEFT_TURN:
switch (Visibility_2::orientation_2(geom_traits, s1, t1, s2)) {
case COLLINEAR:
return Visibility_2::orientation_2(geom_traits, s1, t1, t2)!=e1q;
case LEFT_TURN:
if(Visibility_2::orientation_2(geom_traits, s1, t1, t2) == RIGHT_TURN)
return Visibility_2::orientation_2(geom_traits, s2, t2, q)
== Visibility_2::orientation_2(geom_traits, s2, t2, s1);
else
return false;
case RIGHT_TURN:
if (Visibility_2::orientation_2(geom_traits, s1, t1, t2) == LEFT_TURN)
return Visibility_2::orientation_2(geom_traits, s2, t2, q)
== Visibility_2::orientation_2(geom_traits, s2, t2, s1);
else
return true;
default: CGAL_assume(false);
}
}
CGAL_assume(false);
return false;
}
};
const Arrangement_2 *p_arr;
const Geometry_traits_2 *geom_traits;
mutable Point_2 q; //query point
mutable Points polygon; //visibility polygon
mutable std::map<VH, EHs, Less_vertex> incident_edges;
mutable std::map<EH, int, Less_edge> edx; //index of active edges in
//the heap
mutable std::set<EH, Closer_edge> active_edges; //a set of edges that
//intersect the current
//vision ray.
mutable VHs vs; //angular sorted vertices
mutable EHs bad_edges; //edges that pass the query point
mutable VH cone_end1; //an end of visibility cone
mutable VH cone_end2; //another end of visibility cone
mutable typename Points::size_type cone_end1_idx;
//index of cone_end1->point() in
//visibility polygon
mutable typename Points::size_type cone_end2_idx;
//index of cone_end2->point() in
//visibility polygon
mutable bool is_vertex_query;
mutable bool is_edge_query;
mutable bool is_face_query;
mutable bool is_big_cone; //whether the angle of
//visibility_cone is greater than pi.
public:
Rotational_sweep_visibility_2(): p_arr(NULL), geom_traits(NULL) {}
Rotational_sweep_visibility_2(const Arrangement_2& arr): p_arr(&arr) {
geom_traits = p_arr->geometry_traits();
}
const std::string name() const { return std::string("R_visibility_2"); }
template <typename VARR>
typename VARR::Face_handle
compute_visibility(
const Point_2& q, const Halfedge_const_handle e, VARR& arr_out) const
{
arr_out.clear();
bad_edges.clear();
this->q = q;
if (Visibility_2::compare_xy_2(geom_traits, q, e->target()->point())==EQUAL)
{
is_vertex_query = true;
is_edge_query = false;
is_face_query = false;
cone_end1 = e->source();
cone_end2 = e->next()->target();
is_big_cone = CGAL::right_turn(cone_end1->point(), q, cone_end2->point());
typename Arrangement_2::
Halfedge_around_vertex_const_circulator first, curr;
first = curr = e->target()->incident_halfedges();
do {
if (curr->face() == e->face())
bad_edges.push_back(curr);
else if (curr->twin()->face() == e->face())
bad_edges.push_back(curr->twin());
} while (++curr != first);
}
else {
is_vertex_query = false;
is_edge_query = true;
is_face_query = false;
cone_end1 = e->source();
cone_end2 = e->target();
bad_edges.push_back(e);
is_big_cone = false;
}
visibility_region_impl(e->face(), q);
//decide which inside of the visibility butterfly is needed.
typename Points::size_type small_idx, big_idx;
if ( cone_end1_idx < cone_end2_idx ) {
small_idx = cone_end1_idx;
big_idx = cone_end2_idx;
}
else {
small_idx = cone_end2_idx;
big_idx = cone_end1_idx;
}
typename Points::size_type next_idx = small_idx + 1;
bool is_between;
//indicate whether the shape between small_idx and big_idx is the visibility
//region required.
if (CGAL::right_turn(cone_end1->point(), q, cone_end2->point())) {
is_between = false;
while (next_idx != big_idx) {
if (CGAL::left_turn(cone_end1->point(), q, polygon[next_idx]) ||
CGAL::left_turn(q, cone_end2->point(), polygon[next_idx]))
{
is_between = true;
break;
}
next_idx++;
}
}
else {
is_between = true;
while (next_idx != big_idx) {
if (CGAL::right_turn(cone_end1->point(), q, polygon[next_idx]) ||
CGAL::right_turn(q, cone_end2->point(), polygon[next_idx]))
{
is_between = false;
break;
}
next_idx++;
}
}
typename Points::iterator first = polygon.begin();
std::advance(first, small_idx);
typename Points::iterator last = polygon.begin();
std::advance(last, big_idx);
if (is_between) {
Points polygon_out(first, last+1);
if (is_vertex_query)
polygon_out.push_back(q);
Visibility_2::report_while_handling_needles<Rotational_sweep_visibility_2>
(geom_traits, q, polygon_out, arr_out);
}
else {
Points polygon_out(polygon.begin(), first+1);
if (is_vertex_query) polygon_out.push_back(q);
for (typename Points::size_type i = big_idx; i != polygon.size(); i++) {
polygon_out.push_back(polygon[i]);
}
Visibility_2::report_while_handling_needles<Rotational_sweep_visibility_2>
(geom_traits, q, polygon_out, arr_out);
}
Visibility_2::conditional_regularize(arr_out, Regularization_category());
if (arr_out.faces_begin()->is_unbounded())
return ++arr_out.faces_begin();
else
return arr_out.faces_begin();
}
template <typename VARR>
typename VARR::Face_handle
compute_visibility(
const Point_2& q, const Face_const_handle f, VARR& arr_out) const
{
arr_out.clear();
this->q = q;
is_vertex_query = false;
is_edge_query = false;
is_face_query = true;
visibility_region_impl(f, q);
Visibility_2::report_while_handling_needles<Rotational_sweep_visibility_2>
(geom_traits, q, polygon, arr_out);
Visibility_2::conditional_regularize(arr_out, Regularization_category());
if (arr_out.faces_begin()->is_unbounded())
return ++arr_out.faces_begin();
else
return arr_out.faces_begin();
}
bool is_attached() const {
return (p_arr != NULL);
}
void attach(const Arrangement_2& arr) {
p_arr = &arr;
geom_traits = p_arr->geometry_traits();
}
void detach() {
p_arr = NULL;
geom_traits = NULL;
}
const Arrangement_2& arrangement_2() const {
return *p_arr;
}
private:
//get the neighbor of v along edge e
VH get_neighbor(const EH e, const VH v) const {
if (e->source() == v)
return e->target();
else
return e->source();
}
//check whether ray(q->dp) intersects segment(p1, p2)
bool do_intersect_ray(const Point_2& q,
const Point_2& dp,
const Point_2& p1,
const Point_2& p2) const
{
return (CGAL::orientation(q, dp, p1) != CGAL::orientation(q, dp, p2) &&
CGAL::orientation(q, p1, dp) == CGAL::orientation(q, p1, p2));
}
//arrange vertices that on a same vision ray in a 'funnel' order
void funnel(typename VHs::size_type i, typename VHs::size_type j) const {
VHs right, left;
//whether the edges incident to a vertex block the left side and right side
//of current vision ray.
bool block_left(false), block_right(false);
VH former = vs[i], nb;
for (typename VHs::size_type l=i; l<j; l++) {
bool left_v(false), right_v(false), has_predecessor(false);
EHs& edges = incident_edges[vs[l]];
for (typename EHs::size_type k=0; k<edges.size(); k++) {
nb = get_neighbor(edges[k], vs[l]);
if ( nb == former ) {
has_predecessor = true;
break;
}
if (CGAL::left_turn(q, vs[l]->point(), nb->point()))
left_v = true;
else
right_v = CGAL::right_turn(q, vs[l]->point(), nb->point());
}
if (has_predecessor) {
//if the current vertex connects to the vertex before by an edge,
//the vertex before can help it to block.
block_left = block_left || left_v;
block_right = block_right || right_v;
}
else {
block_left = left_v;
block_right = right_v;
}
if (block_left && block_right) {
//when both sides are blocked,
//there is no need to change the vertex after.
right.push_back(vs[l]);
break;
}
else {
if (block_left)
left.push_back(vs[l]);
else
right.push_back(vs[l]);
}
former = vs[l];
}
for (typename VHs::size_type l=0; l!=right.size(); l++)
vs[i+l] = right[l];
for (typename VHs::size_type l=0; l!=left.size(); l++)
vs[i+l+right.size()] = left[left.size()-1-l];
}
void visibility_region_impl(const Face_const_handle f, const Point_2& q) const
{
vs.clear();
polygon.clear();
active_edges = std::set<EH, Closer_edge>(Closer_edge(geom_traits, q));
incident_edges = std::map<VH, EHs, Less_vertex>(Less_vertex(geom_traits));
edx = std::map<EH, int, Less_edge>(Less_edge(geom_traits));
EHs relevant_edges; //edges that can affect the visibility of query point.
Arrangement_2 bbox;
if (is_face_query)
input_face(f);
else
input_face(f, relevant_edges, bbox);
//the following code is the initiation of vision ray.
//the direction of the initial ray is between the direction from q to last
//vertex in vs and positive x-axis. By choosing this direction, we make sure
//that all plane is swept and there is not needle at the beginning of
//sweeping.
Vector_2 dir;
if (Direction_2(-1, 0) < Direction_2(Vector_2(q, vs.back()->point())))
dir = Vector_2(1, 0) + Vector_2(q, vs.back()->point());
else
dir = Vector_2(0, -1);
Point_2 dp = q + dir;
//initiation of active_edges. for face queries,
//all edges on the boundary can affect visibility.
//for non-face queries, only relevant_edges has to be considered.
if (is_face_query) {
Ccb_halfedge_const_circulator curr = f->outer_ccb();
Ccb_halfedge_const_circulator circ = curr;
do {
if (do_intersect_ray(
q, dp, curr->target()->point(), curr->source()->point()))
active_edges.insert(curr);
} while (++curr != circ);
typename Arrangement_2::Hole_const_iterator hi;
for (hi = f->holes_begin(); hi != f->holes_end(); ++hi) {
Ccb_halfedge_const_circulator curr = circ = *hi;
do {
if (do_intersect_ray(
q, dp, curr->target()->point(), curr->source()->point()))
active_edges.insert(curr);
} while (++curr != circ);
}
}
else {
for (typename EHs::size_type i=0; i!=relevant_edges.size(); i++)
if (do_intersect_ray(q, dp, relevant_edges[i]->source()->point(),
relevant_edges[i]->target()->point()))
active_edges.insert(relevant_edges[i]);
}
//angular sweep begins
// std::cout<<active_edges.size()<<std::endl;
for (typename VHs::size_type i=0; i!=vs.size(); i++) {
VH vh = vs[i];
EH closest_e = *active_edges.begin();
EHs& edges = incident_edges[vh];
EHs insert_ehs, remove_ehs;
for (typename EHs::size_type j=0; j!=edges.size(); j++) {
EH& e = edges[j];
if (active_edges.find(e) == active_edges.end())
insert_ehs.push_back(e);
else
remove_ehs.push_back(e);
}
typename EHs::size_type insert_cnt = insert_ehs.size();
typename EHs::size_type remove_cnt = remove_ehs.size();
if (insert_cnt == 1 && remove_cnt == 1) {
const EH& ctemp_eh = *active_edges.find(remove_ehs.front());
EH& temp_eh = const_cast<EH&>(ctemp_eh);
temp_eh = insert_ehs.front();
}
else {
for (typename EHs::size_type j=0; j!=remove_cnt; j++)
active_edges.erase(remove_ehs[j]);
for (typename EHs::size_type j=0; j!=insert_cnt; j++)
active_edges.insert(insert_ehs[j]);
}
if (closest_e != *active_edges.begin()) {
//when the closest edge changed
if (is_face_query) {
if (remove_cnt > 0 && insert_cnt > 0) {
//some edges are added and some are deleted,
//which means the vertex swept is part of visibility polygon.
update_visibility(vh->point());
}
if (remove_cnt == 0 && insert_cnt > 0) {
//only add some edges, means the view ray is blocked by new edges.
//therefore first add the intersection of view ray and
//former closet edge, then add the vertice swept.
update_visibility(ray_seg_intersection(q,
vh->point(),
closest_e->target()->point(),
closest_e->source()->point())
);
update_visibility(vh->point());
}
if (remove_cnt > 0 && insert_cnt == 0) {
//only delete some edges, means some block is moved and the view ray
//can reach the segments after the block.
update_visibility(vh->point());
update_visibility(
ray_seg_intersection(q,
vh->point(),
(*active_edges.begin())->target()->point(),
(*active_edges.begin())->source()->point()
)
);
}
}
else {
//extra work here for edge/vertex query is the index of cone_end1 and
//cone_end2 will be recorded.
if (remove_cnt > 0 && insert_cnt > 0) {
//some edges are added and some are deleted,
//which means the vertice swept is part of visibility polygon.
if (update_visibility(vh->point())) {
if (vh == cone_end1)
cone_end1_idx = polygon.size()-1;
else if (vh == cone_end2)
cone_end2_idx = polygon.size()-1;
}
}
if (remove_cnt == 0 && insert_cnt > 0) {
//only add some edges, means the view ray is blocked by new edges.
//therefore first add the intersection of view ray and former closet
//edge, then add the vertice swept.
update_visibility(ray_seg_intersection(q,
vh->point(),
closest_e->target()->point(),
closest_e->source()->point())
);
if (update_visibility(vh->point())) {
if (vh == cone_end1)
cone_end1_idx = polygon.size()-1;
else if (vh == cone_end2)
cone_end2_idx = polygon.size()-1;
}
}
if (remove_cnt > 0 && insert_cnt == 0) {
//only delete some edges, means some block is removed and the vision
//ray can reach the segments after the block.
if (update_visibility(vh->point())) {
if (vh == cone_end1)
cone_end1_idx = polygon.size()-1;
else if (vh == cone_end2)
cone_end2_idx = polygon.size()-1;
}
update_visibility(
ray_seg_intersection(q,
vh->point(),
(*active_edges.begin())->target()->point(),
(*active_edges.begin())->source()->point())
);
}
}
}
}
}
void print_edge(const EH e) const {
std::cout << e->source()->point() <<"->"<< e->target()->point() <<std::endl;
}
//compute the intersection of ray(q->dp) and segment(s, t)
//if they are collinear then return the endpoint which is closer to q.
Point_2 ray_seg_intersection(
const Point_2& q, const Point_2& dp, // the ray
const Point_2& s, const Point_2& t) // the segment
const
{
if (CGAL::collinear(q, dp, s)) {
if (CGAL::collinear(q, dp, t)) {
if (CGAL::compare_distance_to_point(q, s, t)==CGAL::SMALLER)
return s;
else
return t;
}
else
return s;
}
Ray_2 ray(q,dp);
Segment_2 seg(s,t);
CGAL::Object result = CGAL::intersection(ray, seg);
return *(CGAL::object_cast<Point_2>(&result));
}
//check if p has been discovered before, if not update the visibility polygon
bool update_visibility(const Point_2& p) const {
if (polygon.empty()) {
polygon.push_back(p);
return true;
}
else if (Visibility_2::compare_xy_2(geom_traits, polygon.back(), p)
!= EQUAL)
{
polygon.push_back(p);
return true;
}
return false;
}
//functor to decide which vertex is swept earlier by the rotational sweeping
//ray
class Is_swept_earlier:public CGAL::cpp98::binary_function<VH, VH, bool> {
const Point_2& q;
const Geometry_traits_2* geom_traits;
public:
Is_swept_earlier(const Point_2& q, const Geometry_traits_2* traits) :
q(q), geom_traits(traits) {}
bool operator() (const VH v1, const VH v2) const {
const Point_2& p1 = v1->point();
const Point_2& p2 = v2->point();
int qua1 = quadrant(q, p1);
int qua2 = quadrant(q, p2);
if (qua1 < qua2)
return true;
if (qua1 > qua2)
return false;
if (collinear(q, p1, p2))
return (CGAL::compare_distance_to_point(q, p1, p2) == CGAL::SMALLER);
else
return CGAL::right_turn(p1, q, p2);
}
//return the quadrant of p with respect to o.
int quadrant(const Point_2& o, const Point_2& p) const {
typename Geometry_traits_2::Compare_x_2 compare_x =
geom_traits->compare_x_2_object();
typename Geometry_traits_2::Compare_y_2 compare_y =
geom_traits->compare_y_2_object();
Comparison_result dx = compare_x(p, o);
Comparison_result dy = compare_y(p, o);
if (dx==LARGER && dy!=SMALLER)
return 1;
if (dx!=LARGER && dy==LARGER)
return 2;
if (dx==SMALLER && dy!=LARGER)
return 3;
if (dx!=SMALLER && dy==SMALLER)
return 4;
return 0;
}
};
//when the query point is in face, every edge is good.
void input_neighbor_f( const Halfedge_const_handle e) const {
VH v = e->target();
if (!incident_edges.count(v))
vs.push_back(v);
incident_edges[v].push_back(e);
incident_edges[v].push_back(e->next());
}
//check if p is in the visibility cone
bool is_in_cone(const Point_2& p) const{
if (is_big_cone)
return (!CGAL::right_turn(cone_end1->point(), q, p)) ||
(!CGAL::left_turn(cone_end2->point(), q, p));
else
return (!CGAL::right_turn(cone_end1->point(), q, p)) &&
(!CGAL::left_turn(cone_end2->point(), q, p));
}
//for vertex and edge query: the visibility is limited in a cone.
void input_edge(const Halfedge_const_handle e,
EHs& good_edges) const {
for (typename EHs::size_type i = 0; i < bad_edges.size(); i++)
if (e == bad_edges[i])
return;
VH v1 = e->target();
VH v2 = e->source();
//an edge will affect visibility only if it has an endpoint in the
//visibility cone or it crosses the boundary of the cone.
if (is_in_cone(v1->point()) || is_in_cone(v2->point()) ||
do_intersect_ray(q, cone_end1->point(), v1->point(), v2->point()))
{
good_edges.push_back(e);
if (!incident_edges.count(v1))
vs.push_back(v1);
incident_edges[v1].push_back(e);
if (!incident_edges.count(v2))
vs.push_back(v2);
incident_edges[v2].push_back(e);
}
}
//for face query: traverse the face to get all edges
//and sort vertices in counter-clockwise order.
void input_face (Face_const_handle fh) const
{
Ccb_halfedge_const_circulator curr = fh->outer_ccb();
Ccb_halfedge_const_circulator circ = curr;
do {
CGAL_assertion(curr->face() == fh);
input_neighbor_f(curr);
} while (++curr != circ);
typename Arrangement_2::Hole_const_iterator hi;
for (hi = fh->holes_begin(); hi != fh->holes_end(); ++hi) {
Ccb_halfedge_const_circulator curr = *hi, circ = *hi;
do {
CGAL_assertion(curr->face() == fh);
input_neighbor_f(curr);
} while (++curr != circ);
}
std::sort(vs.begin(), vs.end(), Is_swept_earlier(q, geom_traits));
for (typename VHs::size_type i=0; i!=vs.size(); i++) {
typename VHs::size_type j = i+1;
while (j != vs.size()) {
if (!CGAL::collinear(q, vs[i]->point(), vs[j]->point()))
break;
j++;
}
if (j-i>1)
funnel(i, j);
i = j-1;
}
}
//for vertex or edge query: traverse the face to get all edges
//and sort vertices in counter-clockwise order.
void input_face (Face_const_handle fh,
EHs& good_edges,
Arrangement_2& bbox) const
{
Ccb_halfedge_const_circulator curr = fh->outer_ccb();
Ccb_halfedge_const_circulator circ = curr;
do {
CGAL_assertion(curr->face() == fh);
input_edge(curr, good_edges);
} while (++curr != circ);
typename Arrangement_2::Hole_const_iterator hi;
for (hi = fh->holes_begin(); hi != fh->holes_end(); ++hi) {
Ccb_halfedge_const_circulator curr = circ = *hi;
do {
CGAL_assertion(curr->face() == fh);
input_edge(curr, good_edges);
} while (++curr != circ);
}
//create a box that cover all vertices such that during the sweeping,
//the vision ray will always intersect at least an edge.
//this box doesn't intersect any relevant_edge.
Points points;
for (typename VHs::size_type i=0; i<vs.size(); i++) {
points.push_back(vs[i]->point());
}
points.push_back(q);
//first get the bounding box of all relevant points.
typename Geometry_traits_2::Iso_rectangle_2 bb =
bounding_box(points.begin(), points.end());
Number_type xmin, xmax, ymin, ymax;
typename Geometry_traits_2::Compute_x_2 compute_x =
geom_traits->compute_x_2_object();
typename Geometry_traits_2::Compute_y_2 compute_y =
geom_traits->compute_y_2_object();
//make the box a little bigger than bb so that it won't intersect any
//relevant_edge.
xmin = compute_x((bb.min)())-1;
ymin = compute_y((bb.min)())-1;
xmax = compute_x((bb.max)())+1;
ymax = compute_y((bb.max)())+1;
Point_2 box[4] = {Point_2(xmin, ymin), Point_2(xmax, ymin),
Point_2(xmax, ymax), Point_2(xmin, ymax)};
Halfedge_handle e1 = bbox.insert_in_face_interior(Segment_2(box[0], box[1]),
bbox.unbounded_face());
Halfedge_handle e2 = bbox.insert_from_left_vertex(Segment_2(box[1], box[2]),
e1->target());
Halfedge_handle e3 = bbox.insert_from_right_vertex(Segment_2(box[2],box[3]),
e2->target());
bbox.insert_at_vertices(Segment_2(box[0], box[3]),
e1->source(), e3->target());
circ = curr = e1->face()->outer_ccb();
do {
VH v = curr->target();
vs.push_back(v);
incident_edges[v].push_back(curr);
incident_edges[v].push_back(curr->next());
good_edges.push_back(curr);
} while(++curr != circ);
std::sort(vs.begin(), vs.end(), Is_swept_earlier(q, geom_traits));
for (typename VHs::size_type i=0; i!=vs.size(); i++) {
typename VHs::size_type j = i+1;
while (j != vs.size()) {
if (!CGAL::collinear(q, vs[i]->point(), vs[j]->point()))
break;
j++;
}
if (j-i>1)
funnel(i, j);
i = j-1;
}
}
};
} // end namespace CGAL
#endif
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