libcarla/include/system/boost/geometry/algorithms/detail/equals/interface.hpp

// 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 2014-2022.
// Modifications copyright (c) 2014-2022 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_DETAIL_EQUALS_INTERFACE_HPP
#define BOOST_GEOMETRY_ALGORITHMS_DETAIL_EQUALS_INTERFACE_HPP


#include <cstddef>

#include <boost/geometry/core/coordinate_dimension.hpp>
#include <boost/geometry/core/reverse_dispatch.hpp>
#include <boost/geometry/core/tag.hpp>
#include <boost/geometry/core/tag_cast.hpp>

#include <boost/geometry/geometries/adapted/boost_variant.hpp>
#include <boost/geometry/geometries/concepts/check.hpp>

#include <boost/geometry/algorithms/not_implemented.hpp>

#include <boost/geometry/strategies/default_strategy.hpp>
#include <boost/geometry/strategies/detail.hpp>
#include <boost/geometry/strategies/relate/services.hpp>


namespace boost { namespace geometry
{

#ifndef DOXYGEN_NO_DISPATCH
namespace dispatch
{

template
<
    typename Geometry1,
    typename Geometry2,
    typename Tag1 = typename tag<Geometry1>::type,
    typename Tag2 = typename tag<Geometry2>::type,
    typename CastedTag1 = typename tag_cast<Tag1, pointlike_tag, linear_tag, areal_tag>::type,
    typename CastedTag2 = typename tag_cast<Tag2, pointlike_tag, linear_tag, areal_tag>::type,
    std::size_t DimensionCount = dimension<Geometry1>::type::value,
    bool Reverse = reverse_dispatch<Geometry1, Geometry2>::type::value
>
struct equals: not_implemented<Tag1, Tag2>
{};


// If reversal is needed, perform it
template
<
    typename Geometry1, typename Geometry2,
    typename Tag1, typename Tag2,
    typename CastedTag1, typename CastedTag2,
    std::size_t DimensionCount
>
struct equals<Geometry1, Geometry2, Tag1, Tag2, CastedTag1, CastedTag2, DimensionCount, true>
    : equals<Geometry2, Geometry1, Tag2, Tag1, CastedTag2, CastedTag1, DimensionCount, false>
{
    template <typename Strategy>
    static inline bool apply(Geometry1 const& g1, Geometry2 const& g2, Strategy const& strategy)
    {
        return equals
            <
                Geometry2, Geometry1,
                Tag2, Tag1,
                CastedTag2, CastedTag1,
                DimensionCount,
                false
            >::apply(g2, g1, strategy);
    }
};


} // namespace dispatch
#endif // DOXYGEN_NO_DISPATCH


namespace resolve_strategy
{

template
<
    typename Strategy,
    bool IsUmbrella = strategies::detail::is_umbrella_strategy<Strategy>::value
>
struct equals
{
    template <typename Geometry1, typename Geometry2>
    static inline bool apply(Geometry1 const& geometry1,
                             Geometry2 const& geometry2,
                             Strategy const& strategy)
    {
        return dispatch::equals
            <
                Geometry1, Geometry2
            >::apply(geometry1, geometry2, strategy);
    }
};

template <typename Strategy>
struct equals<Strategy, false>
{
    template <typename Geometry1, typename Geometry2>
    static inline bool apply(Geometry1 const& geometry1,
                             Geometry2 const& geometry2,
                             Strategy const& strategy)
    {
        using strategies::relate::services::strategy_converter;

        return dispatch::equals
            <
                Geometry1, Geometry2
            >::apply(geometry1, geometry2,
                     strategy_converter<Strategy>::get(strategy));
    }
};

template <>
struct equals<default_strategy, false>
{
    template <typename Geometry1, typename Geometry2>
    static inline bool apply(Geometry1 const& geometry1,
                             Geometry2 const& geometry2,
                             default_strategy)
    {
        typedef typename strategies::relate::services::default_strategy
            <
                Geometry1,
                Geometry2
            >::type strategy_type;

        return dispatch::equals
            <
                Geometry1, Geometry2
            >::apply(geometry1, geometry2, strategy_type());
    }
};

} // namespace resolve_strategy


namespace resolve_dynamic {

template
<
    typename Geometry1, typename Geometry2,
    typename Tag1 = typename geometry::tag<Geometry1>::type,
    typename Tag2 = typename geometry::tag<Geometry2>::type
>
struct equals
{
    template <typename Strategy>
    static inline bool apply(Geometry1 const& geometry1,
                             Geometry2 const& geometry2,
                             Strategy const& strategy)
    {
        concepts::check_concepts_and_equal_dimensions
            <
                Geometry1 const,
                Geometry2 const
            >();

        return resolve_strategy::equals
            <
                Strategy
            >::apply(geometry1, geometry2, strategy);
    }
};

template <typename Geometry1, typename Geometry2, typename Tag2>
struct equals<Geometry1, Geometry2, dynamic_geometry_tag, Tag2>
{
    template <typename Strategy>
    static inline bool apply(Geometry1 const& geometry1, Geometry2 const& geometry2,
                             Strategy const& strategy)
    {
        bool result = false;
        traits::visit<Geometry1>::apply([&](auto const& g1)
        {
            result = equals
                <
                    util::remove_cref_t<decltype(g1)>,
                    Geometry2
                >::apply(g1, geometry2, strategy);
        }, geometry1);
        return result;
    }
};

template <typename Geometry1, typename Geometry2, typename Tag1>
struct equals<Geometry1, Geometry2, Tag1, dynamic_geometry_tag>
{
    template <typename Strategy>
    static inline bool apply(Geometry1 const& geometry1, Geometry2 const& geometry2,
                             Strategy const& strategy)
    {
        bool result = false;
        traits::visit<Geometry2>::apply([&](auto const& g2)
        {
            result = equals
                <
                    Geometry1,
                    util::remove_cref_t<decltype(g2)>
                >::apply(geometry1, g2, strategy);
        }, geometry2);
        return result;
    }
};

template <typename Geometry1, typename Geometry2>
struct equals<Geometry1, Geometry2, dynamic_geometry_tag, dynamic_geometry_tag>
{
    template <typename Strategy>
    static inline bool apply(Geometry1 const& geometry1, Geometry2 const& geometry2,
                             Strategy const& strategy)
    {
        bool result = false;
        traits::visit<Geometry1, Geometry2>::apply([&](auto const& g1, auto const& g2)
        {
            result = equals
                <
                    util::remove_cref_t<decltype(g1)>,
                    util::remove_cref_t<decltype(g2)>
                >::apply(g1, g2, strategy);
        }, geometry1, geometry2);
        return result;
    }
};

} // namespace resolve_dynamic


/*!
\brief \brief_check{are spatially equal}
\details \details_check12{equals, is spatially equal}. Spatially equal means
    that the same point set is included. A box can therefore be spatially equal
    to a ring or a polygon, or a linestring can be spatially equal to a
    multi-linestring or a segment. This only works theoretically, not all
    combinations are implemented yet.
\ingroup equals
\tparam Geometry1 \tparam_geometry
\tparam Geometry2 \tparam_geometry
\tparam Strategy \tparam_strategy{Equals}
\param geometry1 \param_geometry
\param geometry2 \param_geometry
\param strategy \param_strategy{equals}
\return \return_check2{are spatially equal}

\qbk{distinguish,with strategy}
\qbk{[include reference/algorithms/equals.qbk]}
 */
template <typename Geometry1, typename Geometry2, typename Strategy>
inline bool equals(Geometry1 const& geometry1,
                   Geometry2 const& geometry2,
                   Strategy const& strategy)
{
    return resolve_dynamic::equals
        <
            Geometry1, Geometry2
        >::apply(geometry1, geometry2, strategy);
}


/*!
\brief \brief_check{are spatially equal}
\details \details_check12{equals, is spatially equal}. Spatially equal means
    that the same point set is included. A box can therefore be spatially equal
    to a ring or a polygon, or a linestring can be spatially equal to a
    multi-linestring or a segment. This only works theoretically, not all
    combinations are implemented yet.
\ingroup equals
\tparam Geometry1 \tparam_geometry
\tparam Geometry2 \tparam_geometry
\param geometry1 \param_geometry
\param geometry2 \param_geometry
\return \return_check2{are spatially equal}

\qbk{[include reference/algorithms/equals.qbk]}
 */
template <typename Geometry1, typename Geometry2>
inline bool equals(Geometry1 const& geometry1, Geometry2 const& geometry2)
{
    return resolve_dynamic::equals
        <
            Geometry1, Geometry2
        >::apply(geometry1, geometry2, default_strategy());
}


}} // namespace boost::geometry


#endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_EQUALS_INTERFACE_HPP