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// Boost.Geometry (aka GGL, Generic Geometry Library)
// Copyright (c) 2007-2015 Barend Gehrels, Amsterdam, the Netherlands.
// This file was modified by Oracle on 2013-2022.
// Modifications copyright (c) 2013-2022 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
// 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_RELATE_TURNS_HPP
#define BOOST_GEOMETRY_ALGORITHMS_DETAIL_RELATE_TURNS_HPP
#include <boost/geometry/algorithms/detail/overlay/do_reverse.hpp>
#include <boost/geometry/algorithms/detail/overlay/get_turns.hpp>
#include <boost/geometry/algorithms/detail/overlay/get_turn_info.hpp>
#include <boost/geometry/geometries/helper_geometry.hpp>
#include <boost/geometry/policies/robustness/get_rescale_policy.hpp>
#include <boost/geometry/policies/robustness/segment_ratio_type.hpp>
#include <boost/geometry/strategies/cartesian/point_in_point.hpp>
#include <boost/geometry/strategies/spherical/point_in_point.hpp>
#include <boost/geometry/strategies/distance.hpp>
namespace boost { namespace geometry {
#ifndef DOXYGEN_NO_DETAIL
namespace detail { namespace relate { namespace turns {
template <bool IncludeDegenerate = false>
struct assign_policy
: overlay::assign_null_policy
{
static bool const include_degenerate = IncludeDegenerate;
};
// turn retriever, calling get_turns
template
<
typename Geometry1,
typename Geometry2,
typename GetTurnPolicy = detail::get_turns::get_turn_info_type
<
Geometry1, Geometry2, assign_policy<>
>
>
struct get_turns
{
using turn_point_type = typename helper_geometry
<
typename geometry::point_type<Geometry1>::type
>::type;
template <typename Strategy>
struct robust_policy_type
: geometry::rescale_overlay_policy_type
<
Geometry1,
Geometry2,
typename Strategy::cs_tag
>
{};
template
<
typename Strategy,
typename RobustPolicy = typename robust_policy_type<Strategy>::type
>
struct turn_info_type
{
using ratio_type = typename segment_ratio_type<turn_point_type, RobustPolicy>::type;
using type = overlay::turn_info
<
turn_point_type,
ratio_type,
typename detail::get_turns::turn_operation_type
<
Geometry1, Geometry2, turn_point_type, ratio_type
>::type
>;
};
template <typename Turns, typename InterruptPolicy, typename Strategy>
static inline void apply(Turns & turns,
Geometry1 const& geometry1,
Geometry2 const& geometry2,
InterruptPolicy & interrupt_policy,
Strategy const& strategy)
{
typedef typename robust_policy_type<Strategy>::type robust_policy_t;
robust_policy_t robust_policy
= geometry::get_rescale_policy<robust_policy_t>(
geometry1, geometry2, strategy);
apply(turns, geometry1, geometry2, interrupt_policy, strategy, robust_policy);
}
template <typename Turns, typename InterruptPolicy, typename Strategy, typename RobustPolicy>
static inline void apply(Turns & turns,
Geometry1 const& geometry1,
Geometry2 const& geometry2,
InterruptPolicy & interrupt_policy,
Strategy const& strategy,
RobustPolicy const& robust_policy)
{
static const bool reverse1 = detail::overlay::do_reverse
<
geometry::point_order<Geometry1>::value
>::value;
static const bool reverse2 = detail::overlay::do_reverse
<
geometry::point_order<Geometry2>::value
>::value;
dispatch::get_turns
<
typename geometry::tag<Geometry1>::type,
typename geometry::tag<Geometry2>::type,
Geometry1,
Geometry2,
reverse1,
reverse2,
GetTurnPolicy
>::apply(0, geometry1, 1, geometry2,
strategy, robust_policy,
turns, interrupt_policy);
}
};
// TURNS SORTING AND SEARCHING
template <int N = 0, int U = 1, int I = 2, int B = 3, int C = 4, int O = 0>
struct op_to_int
{
template <typename Operation>
inline int operator()(Operation const& op) const
{
switch(op.operation)
{
case detail::overlay::operation_none : return N;
case detail::overlay::operation_union : return U;
case detail::overlay::operation_intersection : return I;
case detail::overlay::operation_blocked : return B;
case detail::overlay::operation_continue : return C;
case detail::overlay::operation_opposite : return O;
}
return -1;
}
};
template <std::size_t OpId, typename OpToInt>
struct less_op_xxx_linear
{
template <typename Turn>
inline bool operator()(Turn const& left, Turn const& right) const
{
static OpToInt op_to_int;
return op_to_int(left.operations[OpId]) < op_to_int(right.operations[OpId]);
}
};
template <std::size_t OpId>
struct less_op_linear_linear
: less_op_xxx_linear< OpId, op_to_int<0,2,3,1,4,0> > // xuic
{};
template <std::size_t OpId>
struct less_op_linear_areal_single
{
template <typename Turn>
inline bool operator()(Turn const& left, Turn const& right) const
{
static const std::size_t other_op_id = (OpId + 1) % 2;
static turns::op_to_int<0,2,3,1,4,0> op_to_int_xuic;
static turns::op_to_int<0,3,2,1,4,0> op_to_int_xiuc;
segment_identifier const& left_other_seg_id = left.operations[other_op_id].seg_id;
segment_identifier const& right_other_seg_id = right.operations[other_op_id].seg_id;
typedef typename Turn::turn_operation_type operation_type;
operation_type const& left_operation = left.operations[OpId];
operation_type const& right_operation = right.operations[OpId];
if ( left_other_seg_id.ring_index == right_other_seg_id.ring_index )
{
return op_to_int_xuic(left_operation)
< op_to_int_xuic(right_operation);
}
else
{
return op_to_int_xiuc(left_operation)
< op_to_int_xiuc(right_operation);
}
}
};
template <std::size_t OpId>
struct less_op_areal_linear
: less_op_xxx_linear< OpId, op_to_int<0,1,0,0,2,0> >
{};
template <std::size_t OpId>
struct less_op_areal_areal
{
template <typename Turn>
inline bool operator()(Turn const& left, Turn const& right) const
{
static const std::size_t other_op_id = (OpId + 1) % 2;
static op_to_int<0, 1, 2, 3, 4, 0> op_to_int_uixc;
static op_to_int<0, 2, 1, 3, 4, 0> op_to_int_iuxc;
segment_identifier const& left_other_seg_id = left.operations[other_op_id].seg_id;
segment_identifier const& right_other_seg_id = right.operations[other_op_id].seg_id;
typedef typename Turn::turn_operation_type operation_type;
operation_type const& left_operation = left.operations[OpId];
operation_type const& right_operation = right.operations[OpId];
if ( left_other_seg_id.multi_index == right_other_seg_id.multi_index )
{
if ( left_other_seg_id.ring_index == right_other_seg_id.ring_index )
{
return op_to_int_uixc(left_operation) < op_to_int_uixc(right_operation);
}
else
{
if ( left_other_seg_id.ring_index == -1 )
{
if ( left_operation.operation == overlay::operation_union )
return false;
else if ( left_operation.operation == overlay::operation_intersection )
return true;
}
else if ( right_other_seg_id.ring_index == -1 )
{
if ( right_operation.operation == overlay::operation_union )
return true;
else if ( right_operation.operation == overlay::operation_intersection )
return false;
}
return op_to_int_iuxc(left_operation) < op_to_int_iuxc(right_operation);
}
}
else
{
return op_to_int_uixc(left_operation) < op_to_int_uixc(right_operation);
}
}
};
template <std::size_t OpId>
struct less_other_multi_index
{
static const std::size_t other_op_id = (OpId + 1) % 2;
template <typename Turn>
inline bool operator()(Turn const& left, Turn const& right) const
{
return left.operations[other_op_id].seg_id.multi_index
< right.operations[other_op_id].seg_id.multi_index;
}
};
// sort turns by G1 - source_index == 0 by:
// seg_id -> distance and coordinates -> operation
template <std::size_t OpId, typename LessOp, typename Strategy>
struct less
{
BOOST_STATIC_ASSERT(OpId < 2);
template <typename Turn>
static inline bool use_fraction(Turn const& left, Turn const& right)
{
using eq_pp_strategy_type = decltype(std::declval<Strategy>().relate(
detail::dummy_point(), detail::dummy_point()));
static LessOp less_op;
// NOTE: Assuming fraction is more permissive and faster than
// comparison of points with strategy.
return geometry::math::equals(left.operations[OpId].fraction,
right.operations[OpId].fraction)
&& eq_pp_strategy_type::apply(left.point, right.point)
?
less_op(left, right)
:
(left.operations[OpId].fraction < right.operations[OpId].fraction)
;
}
template <typename Turn>
inline bool operator()(Turn const& left, Turn const& right) const
{
segment_identifier const& sl = left.operations[OpId].seg_id;
segment_identifier const& sr = right.operations[OpId].seg_id;
return sl < sr || ( sl == sr && use_fraction(left, right) );
}
};
}}} // namespace detail::relate::turns
#endif // DOXYGEN_NO_DETAIL
}} // namespace boost::geometry
#endif // BOOST_GEOMETRY_ALGORITHMS_DETAIL_RELATE_TURNS_HPP
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