vn-verdnaturachat/ios/Pods/boost-for-react-native/boost/geometry/algorithms/centroid.hpp

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// Boost.Geometry (aka GGL, Generic Geometry Library)
// Copyright (c) 2007-2015 Barend Gehrels, Amsterdam, the Netherlands.
// Copyright (c) 2008-2015 Bruno Lalande, Paris, France.
// Copyright (c) 2009-2015 Mateusz Loskot, London, UK.
// Copyright (c) 2014-2015 Adam Wulkiewicz, Lodz, Poland.
// This file was modified by Oracle on 2014, 2015.
// Modifications copyright (c) 2014-2015 Oracle and/or its affiliates.
// Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle
// Contributed and/or modified by Menelaos Karavelas, on behalf of Oracle
// Parts of Boost.Geometry are redesigned from Geodan's Geographic Library
// (geolib/GGL), copyright (c) 1995-2010 Geodan, Amsterdam, the Netherlands.
// 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_CENTROID_HPP
#define BOOST_GEOMETRY_ALGORITHMS_CENTROID_HPP
#include <cstddef>
#include <boost/core/ignore_unused.hpp>
#include <boost/range.hpp>
#include <boost/variant/apply_visitor.hpp>
#include <boost/variant/static_visitor.hpp>
#include <boost/variant/variant_fwd.hpp>
#include <boost/geometry/core/closure.hpp>
#include <boost/geometry/core/cs.hpp>
#include <boost/geometry/core/coordinate_dimension.hpp>
#include <boost/geometry/core/exception.hpp>
#include <boost/geometry/core/exterior_ring.hpp>
#include <boost/geometry/core/interior_rings.hpp>
#include <boost/geometry/core/tag_cast.hpp>
#include <boost/geometry/core/tags.hpp>
#include <boost/geometry/core/point_type.hpp>
#include <boost/geometry/geometries/concepts/check.hpp>
#include <boost/geometry/algorithms/assign.hpp>
#include <boost/geometry/algorithms/convert.hpp>
#include <boost/geometry/algorithms/detail/interior_iterator.hpp>
#include <boost/geometry/algorithms/detail/point_on_border.hpp>
#include <boost/geometry/algorithms/not_implemented.hpp>
#include <boost/geometry/strategies/centroid.hpp>
#include <boost/geometry/strategies/concepts/centroid_concept.hpp>
#include <boost/geometry/strategies/default_strategy.hpp>
#include <boost/geometry/views/closeable_view.hpp>
#include <boost/geometry/util/for_each_coordinate.hpp>
#include <boost/geometry/util/select_coordinate_type.hpp>
#include <boost/geometry/algorithms/is_empty.hpp>
#include <boost/geometry/algorithms/detail/centroid/translating_transformer.hpp>
namespace boost { namespace geometry
{
#if ! defined(BOOST_GEOMETRY_CENTROID_NO_THROW)
/*!
\brief Centroid Exception
\ingroup centroid
\details The centroid_exception is thrown if the free centroid function is called with
geometries for which the centroid cannot be calculated. For example: a linestring
without points, a polygon without points, an empty multi-geometry.
\qbk{
[heading See also]
\* [link geometry.reference.algorithms.centroid the centroid function]
}
*/
class centroid_exception : public geometry::exception
{
public:
/*!
\brief The default constructor
*/
inline centroid_exception() {}
/*!
\brief Returns the explanatory string.
\return Pointer to a null-terminated string with explanatory information.
*/
virtual char const* what() const throw()
{
return "Boost.Geometry Centroid calculation exception";
}
};
#endif
#ifndef DOXYGEN_NO_DETAIL
namespace detail { namespace centroid
{
struct centroid_point
{
template<typename Point, typename PointCentroid, typename Strategy>
static inline void apply(Point const& point, PointCentroid& centroid,
Strategy const&)
{
geometry::convert(point, centroid);
}
};
template
<
typename Indexed,
typename Point,
std::size_t Dimension = 0,
std::size_t DimensionCount = dimension<Indexed>::type::value
>
struct centroid_indexed_calculator
{
typedef typename select_coordinate_type
<
Indexed, Point
>::type coordinate_type;
static inline void apply(Indexed const& indexed, Point& centroid)
{
coordinate_type const c1 = get<min_corner, Dimension>(indexed);
coordinate_type const c2 = get<max_corner, Dimension>(indexed);
coordinate_type m = c1 + c2;
coordinate_type const two = 2;
m /= two;
set<Dimension>(centroid, m);
centroid_indexed_calculator
<
Indexed, Point, Dimension + 1
>::apply(indexed, centroid);
}
};
template<typename Indexed, typename Point, std::size_t DimensionCount>
struct centroid_indexed_calculator<Indexed, Point, DimensionCount, DimensionCount>
{
static inline void apply(Indexed const& , Point& )
{
}
};
struct centroid_indexed
{
template<typename Indexed, typename Point, typename Strategy>
static inline void apply(Indexed const& indexed, Point& centroid,
Strategy const&)
{
centroid_indexed_calculator
<
Indexed, Point
>::apply(indexed, centroid);
}
};
// There is one thing where centroid is different from e.g. within.
// If the ring has only one point, it might make sense that
// that point is the centroid.
template<typename Point, typename Range>
inline bool range_ok(Range const& range, Point& centroid)
{
std::size_t const n = boost::size(range);
if (n > 1)
{
return true;
}
else if (n <= 0)
{
#if ! defined(BOOST_GEOMETRY_CENTROID_NO_THROW)
throw centroid_exception();
#else
return false;
#endif
}
else // if (n == 1)
{
// Take over the first point in a "coordinate neutral way"
geometry::convert(*boost::begin(range), centroid);
return false;
}
//return true; // unreachable
}
/*!
\brief Calculate the centroid of a Ring or a Linestring.
*/
template <closure_selector Closure>
struct centroid_range_state
{
template<typename Ring, typename PointTransformer, typename Strategy>
static inline void apply(Ring const& ring,
PointTransformer const& transformer,
Strategy const& strategy,
typename Strategy::state_type& state)
{
boost::ignore_unused(strategy);
typedef typename geometry::point_type<Ring const>::type point_type;
typedef typename closeable_view<Ring const, Closure>::type view_type;
typedef typename boost::range_iterator<view_type const>::type iterator_type;
view_type view(ring);
iterator_type it = boost::begin(view);
iterator_type end = boost::end(view);
if (it != end)
{
typename PointTransformer::result_type
previous_pt = transformer.apply(*it);
for ( ++it ; it != end ; ++it)
{
typename PointTransformer::result_type
pt = transformer.apply(*it);
strategy.apply(static_cast<point_type const&>(previous_pt),
static_cast<point_type const&>(pt),
state);
previous_pt = pt;
}
}
}
};
template <closure_selector Closure>
struct centroid_range
{
template<typename Range, typename Point, typename Strategy>
static inline bool apply(Range const& range, Point& centroid,
Strategy const& strategy)
{
if (range_ok(range, centroid))
{
// prepare translation transformer
translating_transformer<Range> transformer(*boost::begin(range));
typename Strategy::state_type state;
centroid_range_state<Closure>::apply(range, transformer,
strategy, state);
if ( strategy.result(state, centroid) )
{
// translate the result back
transformer.apply_reverse(centroid);
return true;
}
}
return false;
}
};
/*!
\brief Centroid of a polygon.
\note Because outer ring is clockwise, inners are counter clockwise,
triangle approach is OK and works for polygons with rings.
*/
struct centroid_polygon_state
{
template<typename Polygon, typename PointTransformer, typename Strategy>
static inline void apply(Polygon const& poly,
PointTransformer const& transformer,
Strategy const& strategy,
typename Strategy::state_type& state)
{
typedef typename ring_type<Polygon>::type ring_type;
typedef centroid_range_state<geometry::closure<ring_type>::value> per_ring;
per_ring::apply(exterior_ring(poly), transformer, strategy, state);
typename interior_return_type<Polygon const>::type
rings = interior_rings(poly);
for (typename detail::interior_iterator<Polygon const>::type
it = boost::begin(rings); it != boost::end(rings); ++it)
{
per_ring::apply(*it, transformer, strategy, state);
}
}
};
struct centroid_polygon
{
template<typename Polygon, typename Point, typename Strategy>
static inline bool apply(Polygon const& poly, Point& centroid,
Strategy const& strategy)
{
if (range_ok(exterior_ring(poly), centroid))
{
// prepare translation transformer
translating_transformer<Polygon>
transformer(*boost::begin(exterior_ring(poly)));
typename Strategy::state_type state;
centroid_polygon_state::apply(poly, transformer, strategy, state);
if ( strategy.result(state, centroid) )
{
// translate the result back
transformer.apply_reverse(centroid);
return true;
}
}
return false;
}
};
/*!
\brief Building block of a multi-point, to be used as Policy in the
more generec centroid_multi
*/
struct centroid_multi_point_state
{
template <typename Point, typename PointTransformer, typename Strategy>
static inline void apply(Point const& point,
PointTransformer const& transformer,
Strategy const& strategy,
typename Strategy::state_type& state)
{
boost::ignore_unused(strategy);
strategy.apply(static_cast<Point const&>(transformer.apply(point)),
state);
}
};
/*!
\brief Generic implementation which calls a policy to calculate the
centroid of the total of its single-geometries
\details The Policy is, in general, the single-version, with state. So
detail::centroid::centroid_polygon_state is used as a policy for this
detail::centroid::centroid_multi
*/
template <typename Policy>
struct centroid_multi
{
template <typename Multi, typename Point, typename Strategy>
static inline bool apply(Multi const& multi,
Point& centroid,
Strategy const& strategy)
{
#if ! defined(BOOST_GEOMETRY_CENTROID_NO_THROW)
// If there is nothing in any of the ranges, it is not possible
// to calculate the centroid
if (geometry::is_empty(multi))
{
throw centroid_exception();
}
#endif
// prepare translation transformer
translating_transformer<Multi> transformer(multi);
typename Strategy::state_type state;
for (typename boost::range_iterator<Multi const>::type
it = boost::begin(multi);
it != boost::end(multi);
++it)
{
Policy::apply(*it, transformer, strategy, state);
}
if ( strategy.result(state, centroid) )
{
// translate the result back
transformer.apply_reverse(centroid);
return true;
}
return false;
}
};
template <typename Algorithm>
struct centroid_linear_areal
{
template <typename Geometry, typename Point, typename Strategy>
static inline void apply(Geometry const& geom,
Point& centroid,
Strategy const& strategy)
{
if ( ! Algorithm::apply(geom, centroid, strategy) )
{
geometry::point_on_border(centroid, geom);
}
}
};
}} // namespace detail::centroid
#endif // DOXYGEN_NO_DETAIL
#ifndef DOXYGEN_NO_DISPATCH
namespace dispatch
{
template
<
typename Geometry,
typename Tag = typename tag<Geometry>::type
>
struct centroid: not_implemented<Tag>
{};
template <typename Geometry>
struct centroid<Geometry, point_tag>
: detail::centroid::centroid_point
{};
template <typename Box>
struct centroid<Box, box_tag>
: detail::centroid::centroid_indexed
{};
template <typename Segment>
struct centroid<Segment, segment_tag>
: detail::centroid::centroid_indexed
{};
template <typename Ring>
struct centroid<Ring, ring_tag>
: detail::centroid::centroid_linear_areal
<
detail::centroid::centroid_range<geometry::closure<Ring>::value>
>
{};
template <typename Linestring>
struct centroid<Linestring, linestring_tag>
: detail::centroid::centroid_linear_areal
<
detail::centroid::centroid_range<closed>
>
{};
template <typename Polygon>
struct centroid<Polygon, polygon_tag>
: detail::centroid::centroid_linear_areal
<
detail::centroid::centroid_polygon
>
{};
template <typename MultiLinestring>
struct centroid<MultiLinestring, multi_linestring_tag>
: detail::centroid::centroid_linear_areal
<
detail::centroid::centroid_multi
<
detail::centroid::centroid_range_state<closed>
>
>
{};
template <typename MultiPolygon>
struct centroid<MultiPolygon, multi_polygon_tag>
: detail::centroid::centroid_linear_areal
<
detail::centroid::centroid_multi
<
detail::centroid::centroid_polygon_state
>
>
{};
template <typename MultiPoint>
struct centroid<MultiPoint, multi_point_tag>
: detail::centroid::centroid_multi
<
detail::centroid::centroid_multi_point_state
>
{};
} // namespace dispatch
#endif // DOXYGEN_NO_DISPATCH
namespace resolve_strategy {
template <typename Geometry>
struct centroid
{
template <typename Point, typename Strategy>
static inline void apply(Geometry const& geometry, Point& out, Strategy const& strategy)
{
dispatch::centroid<Geometry>::apply(geometry, out, strategy);
}
template <typename Point>
static inline void apply(Geometry const& geometry, Point& out, default_strategy)
{
typedef typename strategy::centroid::services::default_strategy
<
typename cs_tag<Geometry>::type,
typename tag_cast
<
typename tag<Geometry>::type,
pointlike_tag,
linear_tag,
areal_tag
>::type,
dimension<Geometry>::type::value,
Point,
Geometry
>::type strategy_type;
dispatch::centroid<Geometry>::apply(geometry, out, strategy_type());
}
};
} // namespace resolve_strategy
namespace resolve_variant {
template <typename Geometry>
struct centroid
{
template <typename Point, typename Strategy>
static inline void apply(Geometry const& geometry, Point& out, Strategy const& strategy)
{
concepts::check_concepts_and_equal_dimensions<Point, Geometry const>();
resolve_strategy::centroid<Geometry>::apply(geometry, out, strategy);
}
};
template <BOOST_VARIANT_ENUM_PARAMS(typename T)>
struct centroid<boost::variant<BOOST_VARIANT_ENUM_PARAMS(T)> >
{
template <typename Point, typename Strategy>
struct visitor: boost::static_visitor<void>
{
Point& m_out;
Strategy const& m_strategy;
visitor(Point& out, Strategy const& strategy)
: m_out(out), m_strategy(strategy)
{}
template <typename Geometry>
void operator()(Geometry const& geometry) const
{
centroid<Geometry>::apply(geometry, m_out, m_strategy);
}
};
template <typename Point, typename Strategy>
static inline void
apply(boost::variant<BOOST_VARIANT_ENUM_PARAMS(T)> const& geometry,
Point& out,
Strategy const& strategy)
{
boost::apply_visitor(visitor<Point, Strategy>(out, strategy), geometry);
}
};
} // namespace resolve_variant
/*!
\brief \brief_calc{centroid} \brief_strategy
\ingroup centroid
\details \details_calc{centroid,geometric center (or: center of mass)}. \details_strategy_reasons
\tparam Geometry \tparam_geometry
\tparam Point \tparam_point
\tparam Strategy \tparam_strategy{Centroid}
\param geometry \param_geometry
\param c \param_point \param_set{centroid}
\param strategy \param_strategy{centroid}
\qbk{distinguish,with strategy}
\qbk{[include reference/algorithms/centroid.qbk]}
\qbk{[include reference/algorithms/centroid_strategies.qbk]}
}
*/
template<typename Geometry, typename Point, typename Strategy>
inline void centroid(Geometry const& geometry, Point& c,
Strategy const& strategy)
{
resolve_variant::centroid<Geometry>::apply(geometry, c, strategy);
}
/*!
\brief \brief_calc{centroid}
\ingroup centroid
\details \details_calc{centroid,geometric center (or: center of mass)}. \details_default_strategy
\tparam Geometry \tparam_geometry
\tparam Point \tparam_point
\param geometry \param_geometry
\param c The calculated centroid will be assigned to this point reference
\qbk{[include reference/algorithms/centroid.qbk]}
\qbk{
[heading Example]
[centroid]
[centroid_output]
}
*/
template<typename Geometry, typename Point>
inline void centroid(Geometry const& geometry, Point& c)
{
geometry::centroid(geometry, c, default_strategy());
}
/*!
\brief \brief_calc{centroid}
\ingroup centroid
\details \details_calc{centroid,geometric center (or: center of mass)}. \details_return{centroid}.
\tparam Point \tparam_point
\tparam Geometry \tparam_geometry
\param geometry \param_geometry
\return \return_calc{centroid}
\qbk{[include reference/algorithms/centroid.qbk]}
*/
template<typename Point, typename Geometry>
inline Point return_centroid(Geometry const& geometry)
{
Point c;
geometry::centroid(geometry, c);
return c;
}
/*!
\brief \brief_calc{centroid} \brief_strategy
\ingroup centroid
\details \details_calc{centroid,geometric center (or: center of mass)}. \details_return{centroid}. \details_strategy_reasons
\tparam Point \tparam_point
\tparam Geometry \tparam_geometry
\tparam Strategy \tparam_strategy{centroid}
\param geometry \param_geometry
\param strategy \param_strategy{centroid}
\return \return_calc{centroid}
\qbk{distinguish,with strategy}
\qbk{[include reference/algorithms/centroid.qbk]}
\qbk{[include reference/algorithms/centroid_strategies.qbk]}
*/
template<typename Point, typename Geometry, typename Strategy>
inline Point return_centroid(Geometry const& geometry, Strategy const& strategy)
{
Point c;
geometry::centroid(geometry, c, strategy);
return c;
}
}} // namespace boost::geometry
#endif // BOOST_GEOMETRY_ALGORITHMS_CENTROID_HPP