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// Boost.Geometry (aka GGL, Generic Geometry Library)
// Copyright (c) 2014-2015 Barend Gehrels, Amsterdam, the Netherlands.
// Copyright (c) 2014-2015 Bruno Lalande, Paris, France.
// Copyright (c) 2014-2015 Mateusz Loskot, London, UK.
// Copyright (c) 2014-2015 Adam Wulkiewicz, Lodz, Poland.
// This file was modified by Oracle on 2015, 2019.
// Modifications copyright (c) 2015, 2019, Oracle and/or its affiliates.
// Contributed and/or modified by Menelaos Karavelas, on behalf of Oracle
// 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_POLICIES_ROBUSTNESS_GET_RESCALE_POLICY_HPP
#define BOOST_GEOMETRY_POLICIES_ROBUSTNESS_GET_RESCALE_POLICY_HPP
#include <cstddef>
#include <boost/mpl/assert.hpp>
#include <boost/type_traits/is_floating_point.hpp>
#include <boost/type_traits/is_same.hpp>
#include <boost/geometry/core/assert.hpp>
#include <boost/geometry/core/config.hpp>
#include <boost/geometry/core/tag_cast.hpp>
#include <boost/geometry/algorithms/envelope.hpp>
#include <boost/geometry/algorithms/expand.hpp>
#include <boost/geometry/algorithms/is_empty.hpp>
#include <boost/geometry/algorithms/detail/recalculate.hpp>
#include <boost/geometry/algorithms/detail/get_max_size.hpp>
#include <boost/geometry/policies/robustness/robust_type.hpp>
#include <boost/geometry/geometries/point.hpp>
#include <boost/geometry/geometries/box.hpp>
#include <boost/geometry/policies/robustness/no_rescale_policy.hpp>
#include <boost/geometry/policies/robustness/rescale_policy.hpp>
#include <boost/geometry/util/promote_floating_point.hpp>
namespace boost { namespace geometry
{
#ifndef DOXYGEN_NO_DETAIL
namespace detail { namespace get_rescale_policy
{
template
<
typename Box,
typename Point,
typename RobustPoint,
typename Factor
>
inline void scale_box_to_integer_range(Box const& box,
Point& min_point,
RobustPoint& min_robust_point,
Factor& factor)
{
// Scale box to integer-range
typedef typename promote_floating_point
<
typename geometry::coordinate_type<Point>::type
>::type num_type;
num_type const diff = boost::numeric_cast<num_type>(detail::get_max_size(box));
num_type const range = 10000000.0; // Define a large range to get precise integer coordinates
num_type const half = 0.5;
if (math::equals(diff, num_type())
|| diff >= range
|| ! boost::math::isfinite(diff))
{
factor = 1;
}
else
{
factor = boost::numeric_cast<num_type>(
boost::numeric_cast<boost::long_long_type>(half + range / diff));
BOOST_GEOMETRY_ASSERT(factor >= 1);
}
// Assign input/output minimal points
detail::assign_point_from_index<0>(box, min_point);
num_type const two = 2;
boost::long_long_type const min_coordinate
= boost::numeric_cast<boost::long_long_type>(-range / two);
assign_values(min_robust_point, min_coordinate, min_coordinate);
}
template
<
typename Point, typename RobustPoint, typename Geometry,
typename Factor, typename EnvelopeStrategy
>
static inline void init_rescale_policy(Geometry const& geometry,
Point& min_point,
RobustPoint& min_robust_point,
Factor& factor,
EnvelopeStrategy const& strategy)
{
if (geometry::is_empty(geometry))
{
return;
}
// Get bounding box
model::box<Point> env = geometry::return_envelope
<
model::box<Point>
>(geometry, strategy);
scale_box_to_integer_range(env, min_point, min_robust_point, factor);
}
// NOTE: Actually it should take 2 separate strategies, one for each geometry
// in case one of them was e.g. a Box
template
<
typename Point, typename RobustPoint, typename Geometry1, typename Geometry2,
typename Factor, typename EnvelopeStrategy1, typename EnvelopeStrategy2
>
static inline void init_rescale_policy(Geometry1 const& geometry1,
Geometry2 const& geometry2,
Point& min_point,
RobustPoint& min_robust_point,
Factor& factor,
EnvelopeStrategy1 const& strategy1,
EnvelopeStrategy2 const& strategy2)
{
// Get bounding boxes (when at least one of the geometries is not empty)
bool const is_empty1 = geometry::is_empty(geometry1);
bool const is_empty2 = geometry::is_empty(geometry2);
if (is_empty1 && is_empty2)
{
return;
}
model::box<Point> env;
if (is_empty1)
{
geometry::envelope(geometry2, env, strategy2);
}
else if (is_empty2)
{
geometry::envelope(geometry1, env, strategy1);
}
else
{
// The following approach (envelope + expand) may not give the
// optimal MBR when then two geometries are in the spherical
// equatorial or geographic coordinate systems.
// TODO: implement envelope for two (or possibly more geometries)
geometry::envelope(geometry1, env, strategy1);
model::box<Point> env2 = geometry::return_envelope
<
model::box<Point>
>(geometry2, strategy2);
geometry::expand(env, env2, strategy1.get_box_expand_strategy());
}
scale_box_to_integer_range(env, min_point, min_robust_point, factor);
}
template
<
typename Point,
bool IsFloatingPoint
>
struct rescale_policy_type
{
typedef no_rescale_policy type;
};
// We rescale only all FP types
template
<
typename Point
>
struct rescale_policy_type<Point, true>
{
typedef typename geometry::coordinate_type<Point>::type coordinate_type;
typedef model::point
<
typename detail::robust_type<coordinate_type>::type,
geometry::dimension<Point>::value,
typename geometry::coordinate_system<Point>::type
> robust_point_type;
typedef typename promote_floating_point<coordinate_type>::type factor_type;
typedef detail::robust_policy<Point, robust_point_type, factor_type> type;
};
template <typename Policy>
struct get_rescale_policy
{
template <typename Geometry, typename EnvelopeStrategy>
static inline Policy apply(Geometry const& geometry,
EnvelopeStrategy const& strategy)
{
typedef typename point_type<Geometry>::type point_type;
typedef typename geometry::coordinate_type<Geometry>::type coordinate_type;
typedef typename promote_floating_point<coordinate_type>::type factor_type;
typedef model::point
<
typename detail::robust_type<coordinate_type>::type,
geometry::dimension<point_type>::value,
typename geometry::coordinate_system<point_type>::type
> robust_point_type;
point_type min_point;
robust_point_type min_robust_point;
factor_type factor;
init_rescale_policy(geometry, min_point, min_robust_point,
factor, strategy);
return Policy(min_point, min_robust_point, factor);
}
template <typename Geometry1, typename Geometry2, typename EnvelopeStrategy1, typename EnvelopeStrategy2>
static inline Policy apply(Geometry1 const& geometry1, Geometry2 const& geometry2,
EnvelopeStrategy1 const& strategy1,
EnvelopeStrategy2 const& strategy2)
{
typedef typename point_type<Geometry1>::type point_type;
typedef typename geometry::coordinate_type<Geometry1>::type coordinate_type;
typedef typename promote_floating_point<coordinate_type>::type factor_type;
typedef model::point
<
typename detail::robust_type<coordinate_type>::type,
geometry::dimension<point_type>::value,
typename geometry::coordinate_system<point_type>::type
> robust_point_type;
point_type min_point;
robust_point_type min_robust_point;
factor_type factor;
init_rescale_policy(geometry1, geometry2, min_point, min_robust_point,
factor, strategy1, strategy2);
return Policy(min_point, min_robust_point, factor);
}
};
// Specialization for no-rescaling
template <>
struct get_rescale_policy<no_rescale_policy>
{
template <typename Geometry, typename EnvelopeStrategy>
static inline no_rescale_policy apply(Geometry const& , EnvelopeStrategy const&)
{
return no_rescale_policy();
}
template <typename Geometry1, typename Geometry2, typename EnvelopeStrategy1, typename EnvelopeStrategy2>
static inline no_rescale_policy apply(Geometry1 const& , Geometry2 const& ,
EnvelopeStrategy1 const& , EnvelopeStrategy2 const& )
{
return no_rescale_policy();
}
};
}} // namespace detail::get_rescale_policy
#endif // DOXYGEN_NO_DETAIL
template
<
typename Point,
typename CSTag = typename geometry::cs_tag<Point>::type
>
struct rescale_policy_type
: public detail::get_rescale_policy::rescale_policy_type
<
Point,
#if defined(BOOST_GEOMETRY_USE_RESCALING)
boost::is_floating_point
<
typename geometry::coordinate_type<Point>::type
>::type::value
&&
boost::is_same
<
CSTag,
geometry::cartesian_tag
>::value
#else
false
#endif
>
{
static const bool is_point
= boost::is_same
<
typename geometry::tag<Point>::type,
geometry::point_tag
>::type::value;
BOOST_MPL_ASSERT_MSG((is_point),
INVALID_INPUT_GEOMETRY,
(typename geometry::tag<Point>::type));
};
template
<
typename Geometry1,
typename Geometry2,
typename CSTag = typename geometry::cs_tag<Geometry1>::type,
typename Tag1 = typename tag_cast
<
typename tag<Geometry1>::type,
box_tag,
pointlike_tag,
linear_tag,
areal_tag
>::type,
typename Tag2 = typename tag_cast
<
typename tag<Geometry2>::type,
box_tag,
pointlike_tag,
linear_tag,
areal_tag
>::type
>
struct rescale_overlay_policy_type
// Default: no rescaling
: public detail::get_rescale_policy::rescale_policy_type
<
typename geometry::point_type<Geometry1>::type,
false
>
{};
// Areal/areal: get rescale policy based on coordinate type
template
<
typename Geometry1,
typename Geometry2,
typename CSTag
>
struct rescale_overlay_policy_type<Geometry1, Geometry2, CSTag, areal_tag, areal_tag>
: public rescale_policy_type
<
typename geometry::point_type<Geometry1>::type,
CSTag
>
{};
#ifndef DOXYGEN_NO_DETAIL
namespace detail { namespace get_rescale_policy
{
// get envelope strategy compatible with relate strategy based on geometry tag
// and strategy cs_tag
template
<
typename Geometry,
typename Strategy,
typename Tag = typename geometry::tag<Geometry>::type,
typename CSTag = typename Strategy::cs_tag
>
struct get_envelope_strategy
{
typedef typename Strategy::envelope_strategy_type type;
static inline type apply(Strategy const& strategy)
{
return strategy.get_envelope_strategy();
}
};
template <typename Geometry, typename Strategy, typename CSTag>
struct get_envelope_strategy<Geometry, Strategy, box_tag, CSTag>
{
typedef typename Strategy::envelope_box_strategy_type type;
static inline type apply(Strategy const& )
{
return type();
}
};
// NOTE: within::xxx_point_point shouldn't have a getter for envelope strategy
// so dispatch by CStag. In the future strategies should probably be redesigned.
template <typename Geometry, typename Strategy>
struct get_envelope_strategy<Geometry, Strategy, point_tag, cartesian_tag>
{
typedef strategy::envelope::cartesian_point type;
static inline type apply(Strategy const& )
{
return type();
}
};
template <typename Geometry, typename Strategy>
struct get_envelope_strategy<Geometry, Strategy, point_tag, spherical_tag>
{
typedef strategy::envelope::spherical_point type;
static inline type apply(Strategy const& )
{
return type();
}
};
template <typename Geometry, typename Strategy>
struct get_envelope_strategy<Geometry, Strategy, multi_point_tag, cartesian_tag>
{
typedef strategy::envelope::cartesian_point type;
static inline type apply(Strategy const& )
{
return type();
}
};
template <typename Geometry, typename Strategy>
struct get_envelope_strategy<Geometry, Strategy, multi_point_tag, spherical_tag>
{
typedef strategy::envelope::spherical_point type;
static inline type apply(Strategy const& )
{
return type();
}
};
// utility for backward-compatibility either treating the argument as geometry
// or envelope strategy for get_rescale_policy
template
<
typename Geometry2OrStrategy,
typename Tag = typename geometry::tag<Geometry2OrStrategy>::type
>
struct get_rescale_policy_geometry_or_strategy
{
template <typename Policy, typename Geometry>
static inline Policy apply(Geometry const& geometry, Geometry2OrStrategy const& geometry2)
{
typename geometry::strategy::envelope::services::default_strategy
<
typename geometry::tag<Geometry>::type,
typename geometry::cs_tag<Geometry>::type
>::type strategy1;
typename geometry::strategy::envelope::services::default_strategy
<
typename geometry::tag<Geometry2OrStrategy>::type,
typename geometry::cs_tag<Geometry2OrStrategy>::type
>::type strategy2;
return detail::get_rescale_policy::get_rescale_policy
<
Policy
>::apply(geometry, geometry2, strategy1, strategy2);
}
};
template <typename Strategy>
struct get_rescale_policy_geometry_or_strategy<Strategy, void>
{
template <typename Policy, typename Geometry>
static inline Policy apply(Geometry const& geometry, Strategy const& strategy)
{
return detail::get_rescale_policy::get_rescale_policy
<
Policy
>::apply(geometry,
get_envelope_strategy
<
Geometry, Strategy
>::apply(strategy));
}
};
}} // namespace detail::get_rescale_policy
#endif // DOXYGEN_NO_DETAIL
template <typename Policy, typename Geometry>
inline Policy get_rescale_policy(Geometry const& geometry)
{
typename geometry::strategy::envelope::services::default_strategy
<
typename geometry::tag<Geometry>::type,
typename geometry::cs_tag<Geometry>::type
>::type strategy;
return detail::get_rescale_policy::get_rescale_policy<Policy>::apply(geometry, strategy);
}
template <typename Policy, typename Geometry, typename Geometry2OrStrategy>
inline Policy get_rescale_policy(Geometry const& geometry, Geometry2OrStrategy const& geometry2_or_strategy)
{
// if the second argument is a geometry use default strategy
// otherwise assume it's envelope strategy for the first argument
return detail::get_rescale_policy::get_rescale_policy_geometry_or_strategy
<
Geometry2OrStrategy
> ::template apply<Policy, Geometry>(geometry, geometry2_or_strategy);
}
template <typename Policy, typename Geometry1, typename Geometry2, typename IntersectionStrategy>
inline Policy get_rescale_policy(Geometry1 const& geometry1, Geometry2 const& geometry2,
IntersectionStrategy const& strategy)
{
return detail::get_rescale_policy::get_rescale_policy
<
Policy
>::apply(geometry1, geometry2,
detail::get_rescale_policy::get_envelope_strategy
<
Geometry1, IntersectionStrategy
>::apply(strategy),
detail::get_rescale_policy::get_envelope_strategy
<
Geometry2, IntersectionStrategy
>::apply(strategy));
}
}} // namespace boost::geometry
#endif // BOOST_GEOMETRY_POLICIES_ROBUSTNESS_GET_RESCALE_POLICY_HPP
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