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// Boost.Geometry Index
//
// R-tree R*-tree insert algorithm implementation
//
// Copyright (c) 2011-2014 Adam Wulkiewicz, Lodz, Poland.
//
// 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_INDEX_DETAIL_RTREE_RSTAR_INSERT_HPP
#define BOOST_GEOMETRY_INDEX_DETAIL_RTREE_RSTAR_INSERT_HPP
#include <boost/geometry/index/detail/algorithms/content.hpp>
namespace boost { namespace geometry { namespace index {
namespace detail { namespace rtree { namespace visitors {
namespace rstar {
template <typename Value, typename Options, typename Translator, typename Box, typename Allocators>
class remove_elements_to_reinsert
{
public:
typedef typename rtree::node<Value, typename Options::parameters_type, Box, Allocators, typename Options::node_tag>::type node;
typedef typename rtree::internal_node<Value, typename Options::parameters_type, Box, Allocators, typename Options::node_tag>::type internal_node;
typedef typename rtree::leaf<Value, typename Options::parameters_type, Box, Allocators, typename Options::node_tag>::type leaf;
typedef typename Options::parameters_type parameters_type;
//typedef typename Allocators::internal_node_pointer internal_node_pointer;
typedef internal_node * internal_node_pointer;
template <typename ResultElements, typename Node>
static inline void apply(ResultElements & result_elements,
Node & n,
internal_node_pointer parent,
size_t current_child_index,
parameters_type const& parameters,
Translator const& translator,
Allocators & allocators)
{
typedef typename rtree::elements_type<Node>::type elements_type;
typedef typename elements_type::value_type element_type;
typedef typename geometry::point_type<Box>::type point_type;
// TODO: awulkiew - change second point_type to the point type of the Indexable?
typedef typename
geometry::default_comparable_distance_result<point_type>::type
comparable_distance_type;
elements_type & elements = rtree::elements(n);
const size_t elements_count = parameters.get_max_elements() + 1;
const size_t reinserted_elements_count = (::std::min)(parameters.get_reinserted_elements(), elements_count - parameters.get_min_elements());
BOOST_GEOMETRY_INDEX_ASSERT(parent, "node shouldn't be the root node");
BOOST_GEOMETRY_INDEX_ASSERT(elements.size() == elements_count, "unexpected elements number");
BOOST_GEOMETRY_INDEX_ASSERT(0 < reinserted_elements_count, "wrong value of elements to reinsert");
// calculate current node's center
point_type node_center;
geometry::centroid(rtree::elements(*parent)[current_child_index].first, node_center);
// fill the container of centers' distances of children from current node's center
typedef typename index::detail::rtree::container_from_elements_type<
elements_type,
std::pair<comparable_distance_type, element_type>
>::type sorted_elements_type;
sorted_elements_type sorted_elements;
// If constructor is used instead of resize() MS implementation leaks here
sorted_elements.reserve(elements_count); // MAY THROW, STRONG (V, E: alloc, copy)
for ( typename elements_type::const_iterator it = elements.begin() ;
it != elements.end() ; ++it )
{
point_type element_center;
geometry::centroid( rtree::element_indexable(*it, translator), element_center);
sorted_elements.push_back(std::make_pair(
geometry::comparable_distance(node_center, element_center),
*it)); // MAY THROW (V, E: copy)
}
// sort elements by distances from center
std::partial_sort(
sorted_elements.begin(),
sorted_elements.begin() + reinserted_elements_count,
sorted_elements.end(),
distances_dsc<comparable_distance_type, element_type>); // MAY THROW, BASIC (V, E: copy)
// copy elements which will be reinserted
result_elements.clear();
result_elements.reserve(reinserted_elements_count); // MAY THROW, STRONG (V, E: alloc, copy)
for ( typename sorted_elements_type::const_iterator it = sorted_elements.begin() ;
it != sorted_elements.begin() + reinserted_elements_count ; ++it )
{
result_elements.push_back(it->second); // MAY THROW (V, E: copy)
}
BOOST_TRY
{
// copy remaining elements to the current node
elements.clear();
elements.reserve(elements_count - reinserted_elements_count); // SHOULDN'T THROW (new_size <= old size)
for ( typename sorted_elements_type::const_iterator it = sorted_elements.begin() + reinserted_elements_count;
it != sorted_elements.end() ; ++it )
{
elements.push_back(it->second); // MAY THROW (V, E: copy)
}
}
BOOST_CATCH(...)
{
elements.clear();
for ( typename sorted_elements_type::iterator it = sorted_elements.begin() ;
it != sorted_elements.end() ; ++it )
{
destroy_element<Value, Options, Translator, Box, Allocators>::apply(it->second, allocators);
}
BOOST_RETHROW // RETHROW
}
BOOST_CATCH_END
::boost::ignore_unused_variable_warning(parameters);
}
private:
template <typename Distance, typename El>
static inline bool distances_asc(
std::pair<Distance, El> const& d1,
std::pair<Distance, El> const& d2)
{
return d1.first < d2.first;
}
template <typename Distance, typename El>
static inline bool distances_dsc(
std::pair<Distance, El> const& d1,
std::pair<Distance, El> const& d2)
{
return d1.first > d2.first;
}
};
template <size_t InsertIndex, typename Element, typename Value, typename Options, typename Box, typename Allocators>
struct level_insert_elements_type
{
typedef typename rtree::elements_type<
typename rtree::internal_node<Value, typename Options::parameters_type, Box, Allocators, typename Options::node_tag>::type
>::type type;
};
template <typename Value, typename Options, typename Box, typename Allocators>
struct level_insert_elements_type<0, Value, Value, Options, Box, Allocators>
{
typedef typename rtree::elements_type<
typename rtree::leaf<Value, typename Options::parameters_type, Box, Allocators, typename Options::node_tag>::type
>::type type;
};
template <size_t InsertIndex, typename Element, typename Value, typename Options, typename Translator, typename Box, typename Allocators>
struct level_insert_base
: public detail::insert<Element, Value, Options, Translator, Box, Allocators>
{
typedef detail::insert<Element, Value, Options, Translator, Box, Allocators> base;
typedef typename base::node node;
typedef typename base::internal_node internal_node;
typedef typename base::leaf leaf;
typedef typename level_insert_elements_type<InsertIndex, Element, Value, Options, Box, Allocators>::type elements_type;
typedef typename index::detail::rtree::container_from_elements_type<
elements_type,
typename elements_type::value_type
>::type result_elements_type;
typedef typename Options::parameters_type parameters_type;
typedef typename Allocators::node_pointer node_pointer;
typedef typename Allocators::size_type size_type;
inline level_insert_base(node_pointer & root,
size_type & leafs_level,
Element const& element,
parameters_type const& parameters,
Translator const& translator,
Allocators & allocators,
size_type relative_level)
: base(root, leafs_level, element, parameters, translator, allocators, relative_level)
, result_relative_level(0)
{}
template <typename Node>
inline void handle_possible_reinsert_or_split_of_root(Node &n)
{
BOOST_GEOMETRY_INDEX_ASSERT(result_elements.empty(), "reinsert should be handled only once for level");
result_relative_level = base::m_leafs_level - base::m_traverse_data.current_level;
// overflow
if ( base::m_parameters.get_max_elements() < rtree::elements(n).size() )
{
// node isn't root node
if ( !base::m_traverse_data.current_is_root() )
{
// NOTE: exception-safety
// After an exception result_elements may contain garbage, don't use it
rstar::remove_elements_to_reinsert<Value, Options, Translator, Box, Allocators>::apply(
result_elements, n,
base::m_traverse_data.parent, base::m_traverse_data.current_child_index,
base::m_parameters, base::m_translator, base::m_allocators); // MAY THROW, BASIC (V, E: alloc, copy)
}
// node is root node
else
{
BOOST_GEOMETRY_INDEX_ASSERT(&n == &rtree::get<Node>(*base::m_root_node), "node should be the root node");
base::split(n); // MAY THROW (V, E: alloc, copy, N: alloc)
}
}
}
template <typename Node>
inline void handle_possible_split(Node &n) const
{
// overflow
if ( base::m_parameters.get_max_elements() < rtree::elements(n).size() )
{
base::split(n); // MAY THROW (V, E: alloc, copy, N: alloc)
}
}
template <typename Node>
inline void recalculate_aabb_if_necessary(Node &n) const
{
if ( !result_elements.empty() && !base::m_traverse_data.current_is_root() )
{
// calulate node's new box
base::m_traverse_data.current_element().first =
elements_box<Box>(rtree::elements(n).begin(), rtree::elements(n).end(), base::m_translator);
}
}
size_type result_relative_level;
result_elements_type result_elements;
};
template <size_t InsertIndex, typename Element, typename Value, typename Options, typename Translator, typename Box, typename Allocators>
struct level_insert
: public level_insert_base<InsertIndex, Element, Value, Options, Translator, Box, Allocators>
{
typedef level_insert_base<InsertIndex, Element, Value, Options, Translator, Box, Allocators> base;
typedef typename base::node node;
typedef typename base::internal_node internal_node;
typedef typename base::leaf leaf;
typedef typename Options::parameters_type parameters_type;
typedef typename Allocators::node_pointer node_pointer;
typedef typename Allocators::size_type size_type;
inline level_insert(node_pointer & root,
size_type & leafs_level,
Element const& element,
parameters_type const& parameters,
Translator const& translator,
Allocators & allocators,
size_type relative_level)
: base(root, leafs_level, element, parameters, translator, allocators, relative_level)
{}
inline void operator()(internal_node & n)
{
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level < base::m_leafs_level, "unexpected level");
if ( base::m_traverse_data.current_level < base::m_level )
{
// next traversing step
base::traverse(*this, n); // MAY THROW (E: alloc, copy, N: alloc)
// further insert
if ( 0 < InsertIndex )
{
BOOST_GEOMETRY_INDEX_ASSERT(0 < base::m_level, "illegal level value, level shouldn't be the root level for 0 < InsertIndex");
if ( base::m_traverse_data.current_level == base::m_level - 1 )
{
base::handle_possible_reinsert_or_split_of_root(n); // MAY THROW (E: alloc, copy, N: alloc)
}
}
}
else
{
BOOST_GEOMETRY_INDEX_ASSERT(base::m_level == base::m_traverse_data.current_level, "unexpected level");
BOOST_TRY
{
// push new child node
rtree::elements(n).push_back(base::m_element); // MAY THROW, STRONG (E: alloc, copy)
}
BOOST_CATCH(...)
{
// NOTE: exception-safety
// if the insert fails above, the element won't be stored in the tree, so delete it
rtree::visitors::destroy<Value, Options, Translator, Box, Allocators> del_v(base::m_element.second, base::m_allocators);
rtree::apply_visitor(del_v, *base::m_element.second);
BOOST_RETHROW // RETHROW
}
BOOST_CATCH_END
// first insert
if ( 0 == InsertIndex )
{
base::handle_possible_reinsert_or_split_of_root(n); // MAY THROW (E: alloc, copy, N: alloc)
}
// not the first insert
else
{
base::handle_possible_split(n); // MAY THROW (E: alloc, N: alloc)
}
}
base::recalculate_aabb_if_necessary(n);
}
inline void operator()(leaf &)
{
BOOST_GEOMETRY_INDEX_ASSERT(false, "this visitor can't be used for a leaf");
}
};
template <size_t InsertIndex, typename Value, typename Options, typename Translator, typename Box, typename Allocators>
struct level_insert<InsertIndex, Value, Value, Options, Translator, Box, Allocators>
: public level_insert_base<InsertIndex, Value, Value, Options, Translator, Box, Allocators>
{
typedef level_insert_base<InsertIndex, Value, Value, Options, Translator, Box, Allocators> base;
typedef typename base::node node;
typedef typename base::internal_node internal_node;
typedef typename base::leaf leaf;
typedef typename Options::parameters_type parameters_type;
typedef typename Allocators::node_pointer node_pointer;
typedef typename Allocators::size_type size_type;
inline level_insert(node_pointer & root,
size_type & leafs_level,
Value const& v,
parameters_type const& parameters,
Translator const& translator,
Allocators & allocators,
size_type relative_level)
: base(root, leafs_level, v, parameters, translator, allocators, relative_level)
{}
inline void operator()(internal_node & n)
{
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level < base::m_leafs_level, "unexpected level");
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level < base::m_level, "unexpected level");
// next traversing step
base::traverse(*this, n); // MAY THROW (V, E: alloc, copy, N: alloc)
BOOST_GEOMETRY_INDEX_ASSERT(0 < base::m_level, "illegal level value, level shouldn't be the root level for 0 < InsertIndex");
if ( base::m_traverse_data.current_level == base::m_level - 1 )
{
base::handle_possible_reinsert_or_split_of_root(n); // MAY THROW (E: alloc, copy, N: alloc)
}
base::recalculate_aabb_if_necessary(n);
}
inline void operator()(leaf & n)
{
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level == base::m_leafs_level,
"unexpected level");
BOOST_GEOMETRY_INDEX_ASSERT(base::m_level == base::m_traverse_data.current_level ||
base::m_level == (std::numeric_limits<size_t>::max)(),
"unexpected level");
rtree::elements(n).push_back(base::m_element); // MAY THROW, STRONG (V: alloc, copy)
base::handle_possible_split(n); // MAY THROW (V: alloc, copy, N: alloc)
}
};
template <typename Value, typename Options, typename Translator, typename Box, typename Allocators>
struct level_insert<0, Value, Value, Options, Translator, Box, Allocators>
: public level_insert_base<0, Value, Value, Options, Translator, Box, Allocators>
{
typedef level_insert_base<0, Value, Value, Options, Translator, Box, Allocators> base;
typedef typename base::node node;
typedef typename base::internal_node internal_node;
typedef typename base::leaf leaf;
typedef typename Options::parameters_type parameters_type;
typedef typename Allocators::node_pointer node_pointer;
typedef typename Allocators::size_type size_type;
inline level_insert(node_pointer & root,
size_type & leafs_level,
Value const& v,
parameters_type const& parameters,
Translator const& translator,
Allocators & allocators,
size_type relative_level)
: base(root, leafs_level, v, parameters, translator, allocators, relative_level)
{}
inline void operator()(internal_node & n)
{
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level < base::m_leafs_level,
"unexpected level");
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level < base::m_level,
"unexpected level");
// next traversing step
base::traverse(*this, n); // MAY THROW (V: alloc, copy, N: alloc)
base::recalculate_aabb_if_necessary(n);
}
inline void operator()(leaf & n)
{
BOOST_GEOMETRY_INDEX_ASSERT(base::m_traverse_data.current_level == base::m_leafs_level,
"unexpected level");
BOOST_GEOMETRY_INDEX_ASSERT(base::m_level == base::m_traverse_data.current_level ||
base::m_level == (std::numeric_limits<size_t>::max)(),
"unexpected level");
rtree::elements(n).push_back(base::m_element); // MAY THROW, STRONG (V: alloc, copy)
base::handle_possible_reinsert_or_split_of_root(n); // MAY THROW (V: alloc, copy, N: alloc)
base::recalculate_aabb_if_necessary(n);
}
};
} // namespace rstar
// R*-tree insert visitor
// After passing the Element to insert visitor the Element is managed by the tree
// I.e. one should not delete the node passed to the insert visitor after exception is thrown
// because this visitor may delete it
template <typename Element, typename Value, typename Options, typename Translator, typename Box, typename Allocators>
class insert<Element, Value, Options, Translator, Box, Allocators, insert_reinsert_tag>
: public rtree::visitor<Value, typename Options::parameters_type, Box, Allocators, typename Options::node_tag, false>::type
{
typedef typename Options::parameters_type parameters_type;
typedef typename rtree::node<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type node;
typedef typename rtree::internal_node<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type internal_node;
typedef typename rtree::leaf<Value, parameters_type, Box, Allocators, typename Options::node_tag>::type leaf;
typedef typename Allocators::node_pointer node_pointer;
typedef typename Allocators::size_type size_type;
public:
inline insert(node_pointer & root,
size_type & leafs_level,
Element const& element,
parameters_type const& parameters,
Translator const& translator,
Allocators & allocators,
size_type relative_level = 0)
: m_root(root), m_leafs_level(leafs_level), m_element(element)
, m_parameters(parameters), m_translator(translator)
, m_relative_level(relative_level), m_allocators(allocators)
{}
inline void operator()(internal_node & BOOST_GEOMETRY_INDEX_ASSERT_UNUSED_PARAM(n))
{
BOOST_GEOMETRY_INDEX_ASSERT(&n == &rtree::get<internal_node>(*m_root), "current node should be the root");
// Distinguish between situation when reinserts are required and use adequate visitor, otherwise use default one
if ( m_parameters.get_reinserted_elements() > 0 )
{
rstar::level_insert<0, Element, Value, Options, Translator, Box, Allocators> lins_v(
m_root, m_leafs_level, m_element, m_parameters, m_translator, m_allocators, m_relative_level);
rtree::apply_visitor(lins_v, *m_root); // MAY THROW (V, E: alloc, copy, N: alloc)
if ( !lins_v.result_elements.empty() )
{
recursive_reinsert(lins_v.result_elements, lins_v.result_relative_level); // MAY THROW (V, E: alloc, copy, N: alloc)
}
}
else
{
visitors::insert<Element, Value, Options, Translator, Box, Allocators, insert_default_tag> ins_v(
m_root, m_leafs_level, m_element, m_parameters, m_translator, m_allocators, m_relative_level);
rtree::apply_visitor(ins_v, *m_root);
}
}
inline void operator()(leaf & BOOST_GEOMETRY_INDEX_ASSERT_UNUSED_PARAM(n))
{
BOOST_GEOMETRY_INDEX_ASSERT(&n == &rtree::get<leaf>(*m_root), "current node should be the root");
// Distinguish between situation when reinserts are required and use adequate visitor, otherwise use default one
if ( m_parameters.get_reinserted_elements() > 0 )
{
rstar::level_insert<0, Element, Value, Options, Translator, Box, Allocators> lins_v(
m_root, m_leafs_level, m_element, m_parameters, m_translator, m_allocators, m_relative_level);
rtree::apply_visitor(lins_v, *m_root); // MAY THROW (V, E: alloc, copy, N: alloc)
// we're in the root, so root should be split and there should be no elements to reinsert
BOOST_GEOMETRY_INDEX_ASSERT(lins_v.result_elements.empty(), "unexpected state");
}
else
{
visitors::insert<Element, Value, Options, Translator, Box, Allocators, insert_default_tag> ins_v(
m_root, m_leafs_level, m_element, m_parameters, m_translator, m_allocators, m_relative_level);
rtree::apply_visitor(ins_v, *m_root);
}
}
private:
template <typename Elements>
inline void recursive_reinsert(Elements & elements, size_t relative_level)
{
typedef typename Elements::value_type element_type;
// reinsert children starting from the minimum distance
typename Elements::reverse_iterator it = elements.rbegin();
for ( ; it != elements.rend() ; ++it)
{
rstar::level_insert<1, element_type, Value, Options, Translator, Box, Allocators> lins_v(
m_root, m_leafs_level, *it, m_parameters, m_translator, m_allocators, relative_level);
BOOST_TRY
{
rtree::apply_visitor(lins_v, *m_root); // MAY THROW (V, E: alloc, copy, N: alloc)
}
BOOST_CATCH(...)
{
++it;
for ( ; it != elements.rend() ; ++it)
rtree::destroy_element<Value, Options, Translator, Box, Allocators>::apply(*it, m_allocators);
BOOST_RETHROW // RETHROW
}
BOOST_CATCH_END
BOOST_GEOMETRY_INDEX_ASSERT(relative_level + 1 == lins_v.result_relative_level, "unexpected level");
// non-root relative level
if ( lins_v.result_relative_level < m_leafs_level && !lins_v.result_elements.empty())
{
recursive_reinsert(lins_v.result_elements, lins_v.result_relative_level); // MAY THROW (V, E: alloc, copy, N: alloc)
}
}
}
node_pointer & m_root;
size_type & m_leafs_level;
Element const& m_element;
parameters_type const& m_parameters;
Translator const& m_translator;
size_type m_relative_level;
Allocators & m_allocators;
};
}}} // namespace detail::rtree::visitors
}}} // namespace boost::geometry::index
#endif // BOOST_GEOMETRY_INDEX_DETAIL_RTREE_RSTAR_INSERT_HPP
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