// Boost.Geometry (aka GGL, Generic Geometry Library)
// Copyright (c) 2007-2013 Barend Gehrels, Amsterdam, the Netherlands.
// Copyright (c) 2008-2013 Bruno Lalande, Paris, France.
// Copyright (c) 2009-2013 Mateusz Loskot, London, UK.
// Copyright (c) 2013-2017 Adam Wulkiewicz, Lodz, Poland.
// This file was modified by Oracle on 2017-2021.
// Modifications copyright (c) 2017-2021 Oracle and/or its affiliates.
// Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle
// Use, modification and distribution is subject to the Boost Software License,
// Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
// http://www.boost.org/LICENSE_1_0.txt)
#ifndef BOOST_GEOMETRY_ALGORITHMS_DETAIL_EXTREME_POINTS_HPP
#define BOOST_GEOMETRY_ALGORITHMS_DETAIL_EXTREME_POINTS_HPP
#include <cstddef>
#include <boost/range/begin.hpp>
#include <boost/range/end.hpp>
#include <boost/range/size.hpp>
#include <boost/range/value_type.hpp>
#include <boost/geometry/algorithms/detail/assign_box_corners.hpp>
#include <boost/geometry/algorithms/detail/interior_iterator.hpp>
#include <boost/geometry/arithmetic/arithmetic.hpp>
#include <boost/geometry/core/cs.hpp>
#include <boost/geometry/core/point_order.hpp>
#include <boost/geometry/core/point_type.hpp>
#include <boost/geometry/core/ring_type.hpp>
#include <boost/geometry/core/tags.hpp>
#include <boost/geometry/geometries/concepts/check.hpp>
#include <boost/geometry/iterators/ever_circling_iterator.hpp>
#include <boost/geometry/strategies/side.hpp>
#include <boost/geometry/util/math.hpp>
namespace boost { namespace geometry
{
#ifndef DOXYGEN_NO_DETAIL
namespace detail { namespace extreme_points
{
template <std::size_t Dimension>
struct compare
{
template <typename Point>
inline bool operator()(Point const& lhs, Point const& rhs)
{
return geometry::get<Dimension>(lhs) < geometry::get<Dimension>(rhs);
}
};
template <std::size_t Dimension, typename PointType, typename CoordinateType>
inline void move_along_vector(PointType& point, PointType const& extreme, CoordinateType const& base_value)
{
// Moves a point along the vector (point, extreme) in the direction of the extreme point
// This adapts the possibly uneven legs of the triangle (or trapezium-like shape)
// _____extreme _____
// / \ / \ .
// /base \ => / \ point .
// \ point .
//
// For so-called intruders, it can be used to adapt both legs to the level of "base"
// For the base, it can be used to adapt both legs to the level of the max-value of the intruders
// If there are 2 or more extreme values, use the one close to 'point' to have a correct vector
CoordinateType const value = geometry::get<Dimension>(point);
//if (geometry::math::equals(value, base_value))
if (value >= base_value)
{
return;
}
PointType vector = point;
subtract_point(vector, extreme);
CoordinateType const diff = geometry::get<Dimension>(vector);
// diff should never be zero
// because of the way our triangle/trapezium is build.
// We just return if it would be the case.
if (geometry::math::equals(diff, 0))
{
return;
}
CoordinateType const base_diff = base_value - geometry::get<Dimension>(extreme);
multiply_value(vector, base_diff);
divide_value(vector, diff);
// The real move:
point = extreme;
add_point(point, vector);
}
template <std::size_t Dimension, typename Range, typename CoordinateType>
inline void move_along_vector(Range& range, CoordinateType const& base_value)
{
if (range.size() >= 3)
{
move_along_vector<Dimension>(range.front(), *(range.begin() + 1), base_value);
move_along_vector<Dimension>(range.back(), *(range.rbegin() + 1), base_value);
}
}
template<typename Ring, std::size_t Dimension>
struct extreme_points_on_ring
{
typedef typename geometry::coordinate_type<Ring>::type coordinate_type;
typedef typename boost::range_iterator<Ring const>::type range_iterator;
typedef typename geometry::point_type<Ring>::type point_type;
template <typename CirclingIterator, typename Points>
static inline bool extend(CirclingIterator& it,
std::size_t n,
coordinate_type max_coordinate_value,
Points& points, int direction)
{
std::size_t safe_index = 0;
do
{
it += direction;
points.push_back(*it);
if (safe_index++ >= n)
{
// E.g.: ring is completely horizontal or vertical (= invalid, but we don't want to have an infinite loop)
return false;
}
} while (geometry::math::equals(geometry::get<Dimension>(*it), max_coordinate_value));
return true;
}
// Overload without adding to poinst
template <typename CirclingIterator>
static inline bool extend(CirclingIterator& it,
std::size_t n,
coordinate_type max_coordinate_value,
int direction)
{
std::size_t safe_index = 0;
do
{
it += direction;
if (safe_index++ >= n)
{
// E.g.: ring is completely horizontal or vertical (= invalid, but we don't want to have an infinite loop)
return false;
}
} while (geometry::math::equals(geometry::get<Dimension>(*it), max_coordinate_value));
return true;
}
template <typename CirclingIterator>
static inline bool extent_both_sides(Ring const& ring,
point_type extreme,
CirclingIterator& left,
CirclingIterator& right)
{
std::size_t const n = boost::size(ring);
coordinate_type const max_coordinate_value = geometry::get<Dimension>(extreme);
if (! extend(left, n, max_coordinate_value, -1))
{
return false;
}
if (! extend(right, n, max_coordinate_value, +1))
{
return false;
}
return true;
}
template <typename Collection, typename CirclingIterator>
static inline bool collect(Ring const& ring,
point_type extreme,
Collection& points,
CirclingIterator& left,
CirclingIterator& right)
{
std::size_t const n = boost::size(ring);
coordinate_type const max_coordinate_value = geometry::get<Dimension>(extreme);
// Collects first left, which is reversed (if more than one point) then adds the top itself, then right
if (! extend(left, n, max_coordinate_value, points, -1))
{
return false;
}
std::reverse(points.begin(), points.end());
points.push_back(extreme);
if (! extend(right, n, max_coordinate_value, points, +1))
{
return false;
}
return true;
}
template <typename Extremes, typename Intruders, typename CirclingIterator, typename SideStrategy>
static inline void get_intruders(Ring const& ring, CirclingIterator left, CirclingIterator right,
Extremes const& extremes,
Intruders& intruders,
SideStrategy const& strategy)
{
if (boost::size(extremes) < 3)
{
return;
}
coordinate_type const min_value = geometry::get<Dimension>(*std::min_element(boost::begin(extremes), boost::end(extremes), compare<Dimension>()));
// Also select left/right (if Dimension=1)
coordinate_type const other_min = geometry::get<1 - Dimension>(*std::min_element(boost::begin(extremes), boost::end(extremes), compare<1 - Dimension>()));
coordinate_type const other_max = geometry::get<1 - Dimension>(*std::max_element(boost::begin(extremes), boost::end(extremes), compare<1 - Dimension>()));
std::size_t defensive_check_index = 0; // in case we skip over left/right check, collect modifies right too
std::size_t const n = boost::size(ring);
while (left != right && defensive_check_index < n)
{
coordinate_type const coordinate = geometry::get<Dimension>(*right);
coordinate_type const other_coordinate = geometry::get<1 - Dimension>(*right);
if (coordinate > min_value && other_coordinate > other_min && other_coordinate < other_max)
{
int const factor = geometry::point_order<Ring>::value == geometry::clockwise ? 1 : -1;
int const first_side = strategy.apply(*right, extremes.front(), *(extremes.begin() + 1)) * factor;
int const last_side = strategy.apply(*right, *(extremes.rbegin() + 1), extremes.back()) * factor;
// If not lying left from any of the extemes side
if (first_side != 1 && last_side != 1)
{
//std::cout << "first " << first_side << " last " << last_side << std::endl;
// we start at this intrusion until it is handled, and don't affect our initial left iterator
CirclingIterator left_intrusion_it = right;
typename boost::range_value<Intruders>::type intruder;
collect(ring, *right, intruder, left_intrusion_it, right);
// Also moves these to base-level, makes sorting possible which can be done in case of self-tangencies
// (we might postpone this action, it is often not necessary. However it is not time-consuming)
move_along_vector<Dimension>(intruder, min_value);
intruders.push_back(intruder);
--right;
}
}
++right;
defensive_check_index++;
}
}
template <typename Extremes, typename Intruders, typename SideStrategy>
static inline void get_intruders(Ring const& ring,
Extremes const& extremes,
Intruders& intruders,
SideStrategy const& strategy)
{
std::size_t const n = boost::size(ring);
if (n >= 3)
{
geometry::ever_circling_range_iterator<Ring const> left(ring);
geometry::ever_circling_range_iterator<Ring const> right(ring);
++right;
get_intruders(ring, left, right, extremes, intruders, strategy);
}
}
template <typename Iterator, typename SideStrategy>
static inline bool right_turn(Ring const& ring, Iterator it, SideStrategy const& strategy)
{
typename std::iterator_traits<Iterator>::difference_type const index
= std::distance(boost::begin(ring), it);
geometry::ever_circling_range_iterator<Ring const> left(ring);
geometry::ever_circling_range_iterator<Ring const> right(ring);
left += index;
right += index;
if (! extent_both_sides(ring, *it, left, right))
{
return false;
}
int const factor = geometry::point_order<Ring>::value == geometry::clockwise ? 1 : -1;
int const first_side = strategy.apply(*(right - 1), *right, *left) * factor;
int const last_side = strategy.apply(*left, *(left + 1), *right) * factor;
//std::cout << "Candidate at " << geometry::wkt(*it) << " first=" << first_side << " last=" << last_side << std::endl;
// Turn should not be left (actually, it should be right because extent removes horizontal/collinear cases)
return first_side != 1 && last_side != 1;
}
// Gets the extreme segments (top point plus neighbouring points), plus intruders, if any, on the same ring
template <typename Extremes, typename Intruders, typename SideStrategy>
static inline bool apply(Ring const& ring,
Extremes& extremes,
Intruders& intruders,
SideStrategy const& strategy)
{
std::size_t const n = boost::size(ring);
if (n < 3)
{
return false;
}
// Get all maxima, usually one. In case of self-tangencies, or self-crossings,
// the max might be is not valid. A valid max should make a right turn
range_iterator max_it = boost::begin(ring);
compare<Dimension> smaller;
for (range_iterator it = max_it + 1; it != boost::end(ring); ++it)
{
if (smaller(*max_it, *it) && right_turn(ring, it, strategy))
{
max_it = it;
}
}
if (max_it == boost::end(ring))
{
return false;
}
typename std::iterator_traits<range_iterator>::difference_type const
index = std::distance(boost::begin(ring), max_it);
//std::cout << "Extreme point lies at " << index << " having " << geometry::wkt(*max_it) << std::endl;
geometry::ever_circling_range_iterator<Ring const> left(ring);
geometry::ever_circling_range_iterator<Ring const> right(ring);
left += index;
right += index;
// Collect all points (often 3) in a temporary vector
std::vector<point_type> points;
points.reserve(3);
if (! collect(ring, *max_it, points, left, right))
{
return false;
}
//std::cout << "Built vector of " << points.size() << std::endl;
coordinate_type const front_value = geometry::get<Dimension>(points.front());
coordinate_type const back_value = geometry::get<Dimension>(points.back());
coordinate_type const base_value = (std::max)(front_value, back_value);
if (front_value < back_value)
{
move_along_vector<Dimension>(points.front(), *(points.begin() + 1), base_value);
}
else
{
move_along_vector<Dimension>(points.back(), *(points.rbegin() + 1), base_value);
}
std::copy(points.begin(), points.end(), std::back_inserter(extremes));
get_intruders(ring, left, right, extremes, intruders, strategy);
return true;
}
};
}} // namespace detail::extreme_points
#endif // DOXYGEN_NO_DETAIL
#ifndef DOXYGEN_NO_DISPATCH
namespace dispatch
{
template
<
typename Geometry,
std::size_t Dimension,
typename GeometryTag = typename tag<Geometry>::type
>
struct extreme_points
{};
template<typename Ring, std::size_t Dimension>
struct extreme_points<Ring, Dimension, ring_tag>
: detail::extreme_points::extreme_points_on_ring<Ring, Dimension>
{};
template<typename Polygon, std::size_t Dimension>
struct extreme_points<Polygon, Dimension, polygon_tag>
{
template <typename Extremes, typename Intruders, typename SideStrategy>
static inline bool apply(Polygon const& polygon, Extremes& extremes, Intruders& intruders,
SideStrategy const& strategy)
{
typedef typename geometry::ring_type<Polygon>::type ring_type;
typedef detail::extreme_points::extreme_points_on_ring
<
ring_type, Dimension
> ring_implementation;
if (! ring_implementation::apply(geometry::exterior_ring(polygon),
extremes, intruders, strategy))
{
return false;
}
// For a polygon, its interior rings can contain intruders
typename interior_return_type<Polygon const>::type
rings = interior_rings(polygon);
for (typename detail::interior_iterator<Polygon const>::type
it = boost::begin(rings); it != boost::end(rings); ++it)
{
ring_implementation::get_intruders(*it, extremes, intruders, strategy);
}
return true;
}
};
template<typename Box>
struct extreme_points<Box, 1, box_tag>
{
template <typename Extremes, typename Intruders, typename SideStrategy>
static inline bool apply(Box const& box, Extremes& extremes, Intruders& ,
SideStrategy const& )
{
extremes.resize(4);
geometry::detail::assign_box_corners_oriented<false>(box, extremes);
// ll,ul,ur,lr, contains too exactly the right info
return true;
}
};
template<typename Box>
struct extreme_points<Box, 0, box_tag>
{
template <typename Extremes, typename Intruders, typename SideStrategy>
static inline bool apply(Box const& box, Extremes& extremes, Intruders& ,
SideStrategy const& )
{
extremes.resize(4);
geometry::detail::assign_box_corners_oriented<false>(box, extremes);
// ll,ul,ur,lr, rotate one to start with UL and end with LL
std::rotate(extremes.begin(), extremes.begin() + 1, extremes.end());
return true;
}
};
template<typename MultiPolygon, std::size_t Dimension>
struct extreme_points<MultiPolygon, Dimension, multi_polygon_tag>
{
template <typename Extremes, typename Intruders, typename SideStrategy>
static inline bool apply(MultiPolygon const& multi, Extremes& extremes,
Intruders& intruders, SideStrategy const& strategy)
{
// Get one for the very first polygon, that is (for the moment) enough.
// It is not guaranteed the "extreme" then, but for the current purpose
// (point_on_surface) it can just be this point.
if (boost::size(multi) >= 1)
{
return extreme_points
<
typename boost::range_value<MultiPolygon const>::type,
Dimension,
polygon_tag
>::apply(*boost::begin(multi), extremes, intruders, strategy);
}
return false;
}
};
} // namespace dispatch
#endif // DOXYGEN_NO_DISPATCH
/*!
\brief Returns extreme points (for Edge=1 in dimension 1, so the top,
for Edge=0 in dimension 0, the right side)
\note We could specify a strategy (less/greater) to get bottom/left side too. However, until now we don't need that.
*/
template
<
std::size_t Edge,
typename Geometry,
typename Extremes,
typename Intruders,
typename SideStrategy
>
inline bool extreme_points(Geometry const& geometry,
Extremes& extremes,
Intruders& intruders,
SideStrategy const& strategy)
{
concepts::check<Geometry const>();
// Extremes is not required to follow a geometry concept (but it should support an output iterator),
// but its elements should fulfil the point-concept
concepts::check<typename boost::range_value<Extremes>::type>();
// Intruders should contain collections which value type is point-concept
// Extremes might be anything (supporting an output iterator), but its elements should fulfil the point-concept
concepts::check
<
typename boost::range_value
<
typename boost::range_value<Intruders>::type
>::type
const
>();
return dispatch::extreme_points
<
Geometry,
Edge
>::apply(geometry, extremes, intruders, strategy);
}
template
<
std::size_t Edge,
typename Geometry,
typename Extremes,
typename Intruders
>
inline bool extreme_points(Geometry const& geometry,
Extremes& extremes,
Intruders& intruders)
{
typedef typename strategy::side::services::default_strategy
<
typename cs_tag<Geometry>::type
>::type strategy_type;
return geometry::extreme_points<Edge>(geometry,extremes, intruders, strategy_type());
}
}} // namespace boost::geometry
#endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_EXTREME_POINTS_HPP