// Copyright (c) 2002,2011 Utrecht University (The Netherlands).
// All rights reserved.
//
// This file is part of CGAL (www.cgal.org).
//
// $URL: https://github.com/CGAL/cgal/blob/v5.2/Spatial_searching/include/CGAL/Point_container.h $
// $Id: Point_container.h 0779373 2020-03-26T13:31:46+01:00 Sébastien Loriot
// SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-Commercial
//
//
// Author(s) : Hans Tangelder (<hanst@cs.uu.nl>)
// custom point container
#ifndef CGAL_POINT_CONTAINER_H
#define CGAL_POINT_CONTAINER_H
#include <CGAL/license/Spatial_searching.h>
#include <list>
#include <vector>
#include <functional>
#include <algorithm>
#include <CGAL/Kd_tree_rectangle.h>
#include <CGAL/internal/Get_dimension_tag.h>
#include <boost/optional.hpp>
namespace CGAL {
template <class Traits>
class Point_container {
private:
typedef typename Traits::Point_d Point_d;
typedef std::vector<const Point_d*> Point_vector;
public:
typedef typename Traits::FT FT;
typedef typename Point_vector::iterator iterator;
typedef typename Point_vector::const_iterator const_iterator;
typedef typename internal::Get_dimension_tag<Traits>::Dimension D;
private:
Traits traits;
// the iterator range of the Point_container
boost::optional<iterator> m_b ;
boost::optional<iterator> m_e ;
int built_coord; // a coordinate for which the pointer list is built
Kd_tree_rectangle<FT,D> bbox; // bounding box, i.e. rectangle of node
Kd_tree_rectangle<FT,D> tbox; // tight bounding box,
// i.e. minimal enclosing bounding
// box of points
public:
inline const Kd_tree_rectangle<FT,D>&
bounding_box() const
{
return bbox;
}
inline const Kd_tree_rectangle<FT,D>&
tight_bounding_box() const
{
return tbox;
}
inline int
dimension() const
{
return bbox.dimension();
}
inline int
built_coordinate() const
{
return built_coord;
}
// coordinate of the maximal span
inline int
max_span_coord() const
{
return bbox.max_span_coord();
}
// coordinate of the maximal tight span
inline int
max_tight_span_coord() const
{
return tbox.max_span_coord();
}
inline FT
max_span_lower() const
{
return bbox.min_coord(max_span_coord());
}
inline FT
max_tight_span_lower() const
{
return tbox.min_coord(max_tight_span_coord());
}
inline FT
max_span_upper() const
{
return bbox.max_coord(max_span_coord());
}
inline FT
max_tight_span_upper() const
{
return tbox.max_coord(max_tight_span_coord());
}
inline FT
max_spread() const
{
return max_span_upper() - max_span_lower();
}
inline FT
max_tight_spread() const
{
return max_tight_span_upper() - max_tight_span_lower();
}
int
max_tight_span_coord_balanced(FT Aspect_ratio) const
{
int cut_dim(-1);
FT max_spread_points(FT(-1));
FT max_length = max_spread(); // length of longest side of box
int dim = dimension();
for (int d=0; d<dim; d++) {
FT length=bbox.max_coord(d)-bbox.min_coord(d);
if (FT(2)*max_length/length <= Aspect_ratio) {
FT spread=tbox.max_coord(d)-tbox.min_coord(d);
if (spread > max_spread_points) {
max_spread_points = spread;
cut_dim = d;
}
}
}
// CGAL_assertion(cut_dim >= 0);
return cut_dim;
}
FT
max_span_upper_without_dim(int d) const
{
FT max_span(FT(0));
int dim=dimension();
for (int i=0; i<dim; i++) {
FT span = bbox.max_coord(i)-bbox.min_coord(i);
if (d != i && span > max_span) max_span=span;
}
return max_span;
}
FT
balanced_fair(int d, FT Aspect_ratio)
{
FT small_piece = max_span_upper_without_dim(d) / Aspect_ratio;
FT low_cut = bbox.min_coord(d) + small_piece; // lowest legal cut;
FT high_cut = bbox.max_coord(d) - small_piece; //highest legal cut;
// CGAL_assertion (high_cut >= low_cut);
FT split_value = median(d);
if (split_value < low_cut) split_value = low_cut;
if (split_value > high_cut) split_value = high_cut;
return split_value;
}
FT
balanced_sliding_fair(int d, FT Aspect_ratio)
{
FT small_piece = max_span_upper_without_dim(d) / Aspect_ratio;
FT low_cut = bbox.min_coord(d) + small_piece; // lowest legal cut;
FT high_cut = bbox.max_coord(d) - small_piece; //highest legal cut;
// CGAL_assertion (high_cut >= low_cut);
FT split_value = median(d);
FT max_span_lower = tbox.min_coord(d);
FT max_span_upper = tbox.max_coord(d);
if (split_value < low_cut) split_value= max_span_lower;
if (split_value > high_cut) split_value = max_span_upper;
return split_value;
}
// points
inline std::size_t
size() const
{
return *m_e - *m_b;
}
inline const_iterator
begin() const {
return *m_b;
}
inline const_iterator
end() const
{
return *m_e;
}
inline iterator
begin()
{
return *m_b;
}
inline iterator
end()
{
return *m_e;
}
inline bool
empty() const
{
return !m_b || !m_e || (*m_b == *m_e ) ;
}
// building the container from a sequence of Point_d*
Point_container(const int d, iterator begin, iterator end,const Traits& traits_) :
traits(traits_),m_b(begin), m_e(end), bbox(d, begin, end,traits.construct_cartesian_const_iterator_d_object()), tbox(bbox)
{
built_coord = max_span_coord();
}
void
set_range(iterator begin, iterator end)
{
m_b = begin;
m_e = end;
}
// building an empty container
Point_container(const int d,const Traits& traits_) :
traits(traits_),bbox(d), tbox(d)
{}
template <class Traits2>
struct Cmp {
typedef typename Traits2::FT FT;
typedef typename Traits2::Point_d Point_d;
typedef std::vector<const Point_d*> Point_vector;
int split_coord;
FT value;
const typename Traits2::Construct_cartesian_const_iterator_d& construct_it;
Cmp(int s, FT c,const typename Traits2::Construct_cartesian_const_iterator_d& cst_it)
: split_coord(s), value(c), construct_it(cst_it)
{}
bool
operator()(const Point_d* pt) const
{
typename Traits2::Cartesian_const_iterator_d ptit;
ptit = construct_it(*pt);
return *(ptit+split_coord) < value;
}
};
template <class Traits2>
struct Between {
typedef typename Traits2::FT FT;
typedef typename Traits2::Point_d Point_d;
typedef std::vector<const Point_d*> Point_vector;
int split_coord;
FT low, high;
const typename Traits2::Construct_cartesian_const_iterator_d& construct_it;
Between(int s, FT l, FT h,const typename Traits2::Construct_cartesian_const_iterator_d& cst_it)
: split_coord(s), low(l), high(h), construct_it(cst_it)
{}
bool
operator()(const Point_d* pt) const
{
typename Traits2::Cartesian_const_iterator_d ptit;
ptit = construct_it(*pt);
if(! ( *(ptit+split_coord) <= high ) ){
// std::cerr << "Point " << *pt << " exceeds " << high << " in dimension " << split_coord << std::endl;
return false;
}
if(! ( *(ptit+split_coord) >= low ) ){
//std::cerr << "Point " << *pt << " below " << low << " in dimension " << split_coord << std::endl;
return false;
}
return true;
}
};
void recompute_tight_bounding_box()
{
tbox.template update_from_point_pointers<typename Traits::Construct_cartesian_const_iterator_d>(begin(), end(),traits.construct_cartesian_const_iterator_d_object());
}
bool
is_valid() const
{
if(empty()) return true;
bool b = true;
for (int i = 0; i < dimension(); i++){
CGAL_assertion( b = (b && (bbox.min_coord(i) <= tbox.min_coord(i))));
CGAL_assertion( b = (b && (bbox.max_coord(i) >= tbox.max_coord(i))));
typename Traits::Construct_cartesian_const_iterator_d construct_it=traits.construct_cartesian_const_iterator_d_object();
Between<Traits> between(i,tbox.min_coord(i), tbox.max_coord(i), construct_it);
for(const_iterator it = begin(); it != end(); it++){
b = (b && between(*it));
}
}
return b;
}
// note that splitting is restricted to the built coordinate
template <class Separator>
void split(Point_container<Traits>& c, Separator& sep,
bool sliding=false)
{
CGAL_assertion(dimension()==c.dimension());
CGAL_assertion(is_valid());
c.bbox=bbox;
const int split_coord = sep.cutting_dimension();
FT cutting_value = sep.cutting_value();
built_coord=split_coord;
c.built_coord=split_coord;
typename Traits::Construct_cartesian_const_iterator_d construct_it=traits.construct_cartesian_const_iterator_d_object();
Cmp<Traits> cmp(split_coord, cutting_value,construct_it);
iterator it = std::partition(begin(), end(), cmp);
// now [begin,it) are lower and [it,end) are upper
if (sliding) { // avoid empty lists
if (it == begin()) {
iterator minelt = std::min_element(begin(),end(),comp_coord_val<Traits,int>(split_coord,construct_it));
if(minelt != it){
std::iter_swap(minelt,it);
}
cutting_value = *(construct_it(**it)+split_coord);
sep.set_cutting_value(cutting_value);
it++;
}
if (it == end()) {
iterator maxelt = std::max_element(begin(),end(),comp_coord_val<Traits,int>(split_coord,construct_it));
it--;
if(maxelt != it){
std::iter_swap(maxelt,it);
}
cutting_value = *(construct_it(**it)+split_coord);
sep.set_cutting_value(cutting_value);
}
}
c.set_range(begin(), it);
set_range(it, end());
// adjusting boxes
bbox.set_lower_bound(split_coord, cutting_value);
tbox. template update_from_point_pointers<typename Traits::Construct_cartesian_const_iterator_d>(begin(),end(),construct_it);
c.bbox.set_upper_bound(split_coord, cutting_value);
c.tbox. template update_from_point_pointers<typename Traits::Construct_cartesian_const_iterator_d>(c.begin(),c.end(),construct_it);
CGAL_assertion(is_valid());
CGAL_assertion(c.is_valid());
}
template <class Traits2, class Value>
struct comp_coord_val {
private:
Value coord;
const typename Traits2::Construct_cartesian_const_iterator_d& construct_it;
typedef typename Traits2::Point_d Point_d;
public:
comp_coord_val (const Value& coordinate,const typename Traits2::Construct_cartesian_const_iterator_d& cst_it)
: coord(coordinate), construct_it(cst_it)
{}
bool
operator()(const Point_d *a, const Point_d *b) const
{
typename Traits2::Cartesian_const_iterator_d ait = construct_it(*a),
bit = construct_it(*b);
return *(ait+coord) < *(bit+coord);
}
};
FT
median(const int split_coord)
{
typename Traits::Construct_cartesian_const_iterator_d construct_it=traits.construct_cartesian_const_iterator_d_object();
iterator mid = begin() + (end() - begin())/2;
std::nth_element(begin(), mid, end(),comp_coord_val<Traits,int>(split_coord,construct_it));
typename Traits::Cartesian_const_iterator_d mpit = construct_it((*(*mid)));
FT val1 = *(mpit+split_coord);
mid++;
mpit = construct_it((*(*mid)));
FT val2 = *(mpit+split_coord);
return (val1+val2)/FT(2);
}
private:
explicit Point_container()
{} // disable default constructor
};
template <class Point>
std::ostream&
operator<< (std::ostream& s, Point_container<Point>& c)
{
s << "Points container of size " << c.size() << "\n cell:";
s << c.bounding_box();
s << "\n minimal box enclosing points:"; s << c.tight_bounding_box();
return s;
}
} // namespace CGAL
#endif // CGAL_POINT_CONTAINER_H