// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2007-2012 Barend Gehrels, Amsterdam, the Netherlands. // Copyright (c) 2008-2012 Bruno Lalande, Paris, France. // Copyright (c) 2009-2012 Mateusz Loskot, London, UK. // Copyright (c) 2014 Samuel Debionne, Grenoble, France. // This file was modified by Oracle on 2020. // Modifications copyright (c) 2020 Oracle and/or its affiliates. // Contributed and/or modified by Adam Wulkiewicz, 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_ASSIGN_HPP #define BOOST_GEOMETRY_ALGORITHMS_ASSIGN_HPP #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace boost { namespace geometry { /*! \brief Assign a range of points to a linestring, ring or polygon \note The point-type of the range might be different from the point-type of the geometry \ingroup assign \tparam Geometry \tparam_geometry \tparam Range \tparam_range_point \param geometry \param_geometry \param range \param_range_point \qbk{ [heading Notes] [note Assign automatically clears the geometry before assigning (use append if you don't want that)] [heading Example] [assign_points] [assign_points_output] [heading See also] \* [link geometry.reference.algorithms.append append] } */ template inline void assign_points(Geometry& geometry, Range const& range) { concepts::check(); clear(geometry); geometry::append(geometry, range, -1, 0); } /*! \brief assign to a box inverse infinite \details The assign_inverse function initialize a 2D or 3D box with large coordinates, the min corner is very large, the max corner is very small. This is a convenient starting point to collect the minimum bounding box of a geometry. \ingroup assign \tparam Geometry \tparam_geometry \param geometry \param_geometry \qbk{ [heading Example] [assign_inverse] [assign_inverse_output] [heading See also] \* [link geometry.reference.algorithms.make.make_inverse make_inverse] } */ template inline void assign_inverse(Geometry& geometry) { concepts::check(); dispatch::assign_inverse < typename tag::type, Geometry >::apply(geometry); } /*! \brief assign zero values to a box, point \ingroup assign \details The assign_zero function initializes a 2D or 3D point or box with coordinates of zero \tparam Geometry \tparam_geometry \param geometry \param_geometry */ template inline void assign_zero(Geometry& geometry) { concepts::check(); dispatch::assign_zero < typename tag::type, Geometry >::apply(geometry); } /*! \brief Assign two coordinates to a geometry (usually a 2D point) \ingroup assign \tparam Geometry \tparam_geometry \tparam Type \tparam_numeric to specify the coordinates \param geometry \param_geometry \param c1 \param_x \param c2 \param_y \qbk{distinguish, 2 coordinate values} \qbk{ [heading Example] [assign_2d_point] [assign_2d_point_output] [heading See also] \* [link geometry.reference.algorithms.make.make_2_2_coordinate_values make] } */ template inline void assign_values(Geometry& geometry, Type const& c1, Type const& c2) { concepts::check(); dispatch::assign < typename tag::type, Geometry, geometry::dimension::type::value >::apply(geometry, c1, c2); } /*! \brief Assign three values to a geometry (usually a 3D point) \ingroup assign \tparam Geometry \tparam_geometry \tparam Type \tparam_numeric to specify the coordinates \param geometry \param_geometry \param c1 \param_x \param c2 \param_y \param c3 \param_z \qbk{distinguish, 3 coordinate values} \qbk{ [heading Example] [assign_3d_point] [assign_3d_point_output] [heading See also] \* [link geometry.reference.algorithms.make.make_3_3_coordinate_values make] } */ template inline void assign_values(Geometry& geometry, Type const& c1, Type const& c2, Type const& c3) { concepts::check(); dispatch::assign < typename tag::type, Geometry, geometry::dimension::type::value >::apply(geometry, c1, c2, c3); } /*! \brief Assign four values to a geometry (usually a box or segment) \ingroup assign \tparam Geometry \tparam_geometry \tparam Type \tparam_numeric to specify the coordinates \param geometry \param_geometry \param c1 First coordinate (usually x1) \param c2 Second coordinate (usually y1) \param c3 Third coordinate (usually x2) \param c4 Fourth coordinate (usually y2) \qbk{distinguish, 4 coordinate values} */ template inline void assign_values(Geometry& geometry, Type const& c1, Type const& c2, Type const& c3, Type const& c4) { concepts::check(); dispatch::assign < typename tag::type, Geometry, geometry::dimension::type::value >::apply(geometry, c1, c2, c3, c4); } namespace resolve_variant { template struct assign { static inline void apply(Geometry1& geometry1, const Geometry2& geometry2) { concepts::check(); concepts::check(); concepts::check_concepts_and_equal_dimensions(); static bool const same_point_order = point_order::value == point_order::value; BOOST_GEOMETRY_STATIC_ASSERT( same_point_order, "Assign is not supported for different point orders.", Geometry1, Geometry2); static bool const same_closure = closure::value == closure::value; BOOST_GEOMETRY_STATIC_ASSERT( same_closure, "Assign is not supported for different closures.", Geometry1, Geometry2); dispatch::convert::apply(geometry2, geometry1); } }; template struct assign, Geometry2> { struct visitor: static_visitor { Geometry2 const& m_geometry2; visitor(Geometry2 const& geometry2) : m_geometry2(geometry2) {} template result_type operator()(Geometry1& geometry1) const { return assign < Geometry1, Geometry2 >::apply (geometry1, m_geometry2); } }; static inline void apply(variant& geometry1, Geometry2 const& geometry2) { return boost::apply_visitor(visitor(geometry2), geometry1); } }; template struct assign > { struct visitor: static_visitor { Geometry1& m_geometry1; visitor(Geometry1 const& geometry1) : m_geometry1(geometry1) {} template result_type operator()(Geometry2 const& geometry2) const { return assign < Geometry1, Geometry2 >::apply (m_geometry1, geometry2); } }; static inline void apply(Geometry1& geometry1, variant const& geometry2) { return boost::apply_visitor(visitor(geometry1), geometry2); } }; template struct assign, variant > { struct visitor: static_visitor { template result_type operator()( Geometry1& geometry1, Geometry2 const& geometry2) const { return assign < Geometry1, Geometry2 >::apply (geometry1, geometry2); } }; static inline void apply(variant& geometry1, variant const& geometry2) { return boost::apply_visitor(visitor(), geometry1, geometry2); } }; } // namespace resolve_variant /*! \brief Assigns one geometry to another geometry \details The assign algorithm assigns one geometry, e.g. a BOX, to another geometry, e.g. a RING. This only works if it is possible and applicable. \ingroup assign \tparam Geometry1 \tparam_geometry \tparam Geometry2 \tparam_geometry \param geometry1 \param_geometry (target) \param geometry2 \param_geometry (source) \qbk{ [heading Example] [assign] [assign_output] [heading See also] \* [link geometry.reference.algorithms.convert convert] } */ template inline void assign(Geometry1& geometry1, Geometry2 const& geometry2) { resolve_variant::assign::apply(geometry1, geometry2); } }} // namespace boost::geometry #endif // BOOST_GEOMETRY_ALGORITHMS_ASSIGN_HPP