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vn-verdnaturachat/ios/Pods/boost-for-react-native/boost/container/detail/flat_tree.hpp

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////////////////////////////////////////////////////////////////////////////////
//
// (C) Copyright Ion Gaztanaga 2005-2015. Distributed under 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)
//
// See http://www.boost.org/libs/container for documentation.
//
////////////////////////////////////////////////////////////////////////////////
#ifndef BOOST_CONTAINER_FLAT_TREE_HPP
#define BOOST_CONTAINER_FLAT_TREE_HPP
#ifndef BOOST_CONFIG_HPP
# include <boost/config.hpp>
#endif
#if defined(BOOST_HAS_PRAGMA_ONCE)
# pragma once
#endif
#include <boost/container/detail/config_begin.hpp>
#include <boost/container/detail/workaround.hpp>
#include <boost/container/container_fwd.hpp>
#include <boost/move/utility_core.hpp>
#include <boost/container/detail/pair.hpp>
#include <boost/container/vector.hpp>
#include <boost/container/detail/value_init.hpp>
#include <boost/container/detail/destroyers.hpp>
#include <boost/container/detail/algorithm.hpp> //algo_equal(), algo_lexicographical_compare
#include <boost/container/detail/iterator.hpp>
#include <boost/container/detail/is_sorted.hpp>
#include <boost/container/allocator_traits.hpp>
#ifdef BOOST_CONTAINER_VECTOR_ITERATOR_IS_POINTER
#include <boost/intrusive/pointer_traits.hpp>
#endif
#include <boost/container/detail/type_traits.hpp>
#include <boost/container/detail/iterators.hpp>
#include <boost/move/make_unique.hpp>
#include <boost/move/adl_move_swap.hpp>
#if defined(BOOST_NO_CXX11_VARIADIC_TEMPLATES)
#include <boost/move/detail/fwd_macros.hpp>
#endif
#include <boost/intrusive/detail/minimal_pair_header.hpp> //pair
#include <boost/move/iterator.hpp>
namespace boost {
namespace container {
namespace container_detail {
template<class Compare, class Value, class KeyOfValue>
class flat_tree_value_compare
: private Compare
{
typedef Value first_argument_type;
typedef Value second_argument_type;
typedef bool return_type;
public:
flat_tree_value_compare()
: Compare()
{}
flat_tree_value_compare(const Compare &pred)
: Compare(pred)
{}
bool operator()(const Value& lhs, const Value& rhs) const
{
KeyOfValue key_extract;
return Compare::operator()(key_extract(lhs), key_extract(rhs));
}
const Compare &get_comp() const
{ return *this; }
Compare &get_comp()
{ return *this; }
};
template<class Pointer>
struct get_flat_tree_iterators
{
#ifdef BOOST_CONTAINER_VECTOR_ITERATOR_IS_POINTER
typedef Pointer iterator;
typedef typename boost::intrusive::
pointer_traits<Pointer>::element_type iterator_element_type;
typedef typename boost::intrusive::
pointer_traits<Pointer>:: template
rebind_pointer<const iterator_element_type>::type const_iterator;
#else //BOOST_CONTAINER_VECTOR_ITERATOR_IS_POINTER
typedef typename boost::container::container_detail::
vec_iterator<Pointer, false> iterator;
typedef typename boost::container::container_detail::
vec_iterator<Pointer, true > const_iterator;
#endif //BOOST_CONTAINER_VECTOR_ITERATOR_IS_POINTER
typedef boost::container::reverse_iterator<iterator> reverse_iterator;
typedef boost::container::reverse_iterator<const_iterator> const_reverse_iterator;
};
template <class Value, class KeyOfValue,
class Compare, class Allocator>
class flat_tree
{
typedef boost::container::vector<Value, Allocator> vector_t;
typedef Allocator allocator_t;
typedef allocator_traits<Allocator> allocator_traits_type;
public:
typedef flat_tree_value_compare<Compare, Value, KeyOfValue> value_compare;
private:
struct Data
//Inherit from value_compare to do EBO
: public value_compare
{
BOOST_COPYABLE_AND_MOVABLE(Data)
public:
Data()
: value_compare(), m_vect()
{}
explicit Data(const Data &d)
: value_compare(static_cast<const value_compare&>(d)), m_vect(d.m_vect)
{}
Data(BOOST_RV_REF(Data) d)
: value_compare(boost::move(static_cast<value_compare&>(d))), m_vect(boost::move(d.m_vect))
{}
Data(const Data &d, const Allocator &a)
: value_compare(static_cast<const value_compare&>(d)), m_vect(d.m_vect, a)
{}
Data(BOOST_RV_REF(Data) d, const Allocator &a)
: value_compare(boost::move(static_cast<value_compare&>(d))), m_vect(boost::move(d.m_vect), a)
{}
explicit Data(const Compare &comp)
: value_compare(comp), m_vect()
{}
Data(const Compare &comp, const allocator_t &alloc)
: value_compare(comp), m_vect(alloc)
{}
explicit Data(const allocator_t &alloc)
: value_compare(), m_vect(alloc)
{}
Data& operator=(BOOST_COPY_ASSIGN_REF(Data) d)
{
this->value_compare::operator=(d);
m_vect = d.m_vect;
return *this;
}
Data& operator=(BOOST_RV_REF(Data) d)
{
this->value_compare::operator=(boost::move(static_cast<value_compare &>(d)));
m_vect = boost::move(d.m_vect);
return *this;
}
void swap(Data &d)
{
value_compare& mycomp = *this, & othercomp = d;
boost::adl_move_swap(mycomp, othercomp);
this->m_vect.swap(d.m_vect);
}
vector_t m_vect;
};
Data m_data;
BOOST_COPYABLE_AND_MOVABLE(flat_tree)
public:
typedef typename vector_t::value_type value_type;
typedef typename vector_t::pointer pointer;
typedef typename vector_t::const_pointer const_pointer;
typedef typename vector_t::reference reference;
typedef typename vector_t::const_reference const_reference;
typedef typename KeyOfValue::type key_type;
typedef Compare key_compare;
typedef typename vector_t::allocator_type allocator_type;
typedef typename vector_t::size_type size_type;
typedef typename vector_t::difference_type difference_type;
typedef typename vector_t::iterator iterator;
typedef typename vector_t::const_iterator const_iterator;
typedef typename vector_t::reverse_iterator reverse_iterator;
typedef typename vector_t::const_reverse_iterator const_reverse_iterator;
//!Standard extension
typedef allocator_type stored_allocator_type;
private:
typedef allocator_traits<stored_allocator_type> stored_allocator_traits;
public:
BOOST_CONTAINER_FORCEINLINE flat_tree()
: m_data()
{ }
BOOST_CONTAINER_FORCEINLINE explicit flat_tree(const Compare& comp)
: m_data(comp)
{ }
BOOST_CONTAINER_FORCEINLINE flat_tree(const Compare& comp, const allocator_type& a)
: m_data(comp, a)
{ }
BOOST_CONTAINER_FORCEINLINE explicit flat_tree(const allocator_type& a)
: m_data(a)
{ }
BOOST_CONTAINER_FORCEINLINE flat_tree(const flat_tree& x)
: m_data(x.m_data)
{ }
BOOST_CONTAINER_FORCEINLINE flat_tree(BOOST_RV_REF(flat_tree) x)
BOOST_NOEXCEPT_IF(boost::container::container_detail::is_nothrow_move_constructible<Compare>::value)
: m_data(boost::move(x.m_data))
{ }
BOOST_CONTAINER_FORCEINLINE flat_tree(const flat_tree& x, const allocator_type &a)
: m_data(x.m_data, a)
{ }
BOOST_CONTAINER_FORCEINLINE flat_tree(BOOST_RV_REF(flat_tree) x, const allocator_type &a)
: m_data(boost::move(x.m_data), a)
{ }
template <class InputIterator>
flat_tree( ordered_range_t, InputIterator first, InputIterator last
, const Compare& comp = Compare()
, const allocator_type& a = allocator_type())
: m_data(comp, a)
{
this->m_data.m_vect.insert(this->m_data.m_vect.end(), first, last);
BOOST_ASSERT((is_sorted)(this->m_data.m_vect.cbegin(), this->m_data.m_vect.cend(), this->priv_value_comp()));
}
template <class InputIterator>
flat_tree( ordered_unique_range_t, InputIterator first, InputIterator last
, const Compare& comp = Compare()
, const allocator_type& a = allocator_type())
: m_data(comp, a)
{
this->m_data.m_vect.insert(this->m_data.m_vect.end(), first, last);
BOOST_ASSERT((is_sorted_and_unique)(this->m_data.m_vect.cbegin(), this->m_data.m_vect.cend(), this->priv_value_comp()));
}
template <class InputIterator>
flat_tree( bool unique_insertion
, InputIterator first, InputIterator last
, const Compare& comp = Compare()
, const allocator_type& a = allocator_type())
: m_data(comp, a)
{
//Use cend() as hint to achieve linear time for
//ordered ranges as required by the standard
//for the constructor
//Call end() every iteration as reallocation might have invalidated iterators
if(unique_insertion){
for ( ; first != last; ++first){
this->insert_unique(this->cend(), *first);
}
}
else{
for ( ; first != last; ++first){
this->insert_equal(this->cend(), *first);
}
}
}
BOOST_CONTAINER_FORCEINLINE ~flat_tree()
{}
BOOST_CONTAINER_FORCEINLINE flat_tree& operator=(BOOST_COPY_ASSIGN_REF(flat_tree) x)
{ m_data = x.m_data; return *this; }
BOOST_CONTAINER_FORCEINLINE flat_tree& operator=(BOOST_RV_REF(flat_tree) x)
BOOST_NOEXCEPT_IF( (allocator_traits_type::propagate_on_container_move_assignment::value ||
allocator_traits_type::is_always_equal::value) &&
boost::container::container_detail::is_nothrow_move_assignable<Compare>::value)
{ m_data = boost::move(x.m_data); return *this; }
BOOST_CONTAINER_FORCEINLINE const value_compare &priv_value_comp() const
{ return static_cast<const value_compare &>(this->m_data); }
BOOST_CONTAINER_FORCEINLINE value_compare &priv_value_comp()
{ return static_cast<value_compare &>(this->m_data); }
BOOST_CONTAINER_FORCEINLINE const key_compare &priv_key_comp() const
{ return this->priv_value_comp().get_comp(); }
BOOST_CONTAINER_FORCEINLINE key_compare &priv_key_comp()
{ return this->priv_value_comp().get_comp(); }
public:
// accessors:
BOOST_CONTAINER_FORCEINLINE Compare key_comp() const
{ return this->m_data.get_comp(); }
BOOST_CONTAINER_FORCEINLINE value_compare value_comp() const
{ return this->m_data; }
BOOST_CONTAINER_FORCEINLINE allocator_type get_allocator() const
{ return this->m_data.m_vect.get_allocator(); }
BOOST_CONTAINER_FORCEINLINE const stored_allocator_type &get_stored_allocator() const
{ return this->m_data.m_vect.get_stored_allocator(); }
BOOST_CONTAINER_FORCEINLINE stored_allocator_type &get_stored_allocator()
{ return this->m_data.m_vect.get_stored_allocator(); }
BOOST_CONTAINER_FORCEINLINE iterator begin()
{ return this->m_data.m_vect.begin(); }
BOOST_CONTAINER_FORCEINLINE const_iterator begin() const
{ return this->cbegin(); }
BOOST_CONTAINER_FORCEINLINE const_iterator cbegin() const
{ return this->m_data.m_vect.begin(); }
BOOST_CONTAINER_FORCEINLINE iterator end()
{ return this->m_data.m_vect.end(); }
BOOST_CONTAINER_FORCEINLINE const_iterator end() const
{ return this->cend(); }
BOOST_CONTAINER_FORCEINLINE const_iterator cend() const
{ return this->m_data.m_vect.end(); }
BOOST_CONTAINER_FORCEINLINE reverse_iterator rbegin()
{ return reverse_iterator(this->end()); }
BOOST_CONTAINER_FORCEINLINE const_reverse_iterator rbegin() const
{ return this->crbegin(); }
BOOST_CONTAINER_FORCEINLINE const_reverse_iterator crbegin() const
{ return const_reverse_iterator(this->cend()); }
BOOST_CONTAINER_FORCEINLINE reverse_iterator rend()
{ return reverse_iterator(this->begin()); }
BOOST_CONTAINER_FORCEINLINE const_reverse_iterator rend() const
{ return this->crend(); }
BOOST_CONTAINER_FORCEINLINE const_reverse_iterator crend() const
{ return const_reverse_iterator(this->cbegin()); }
BOOST_CONTAINER_FORCEINLINE bool empty() const
{ return this->m_data.m_vect.empty(); }
BOOST_CONTAINER_FORCEINLINE size_type size() const
{ return this->m_data.m_vect.size(); }
BOOST_CONTAINER_FORCEINLINE size_type max_size() const
{ return this->m_data.m_vect.max_size(); }
BOOST_CONTAINER_FORCEINLINE void swap(flat_tree& other)
BOOST_NOEXCEPT_IF( allocator_traits_type::is_always_equal::value
&& boost::container::container_detail::is_nothrow_swappable<Compare>::value )
{ this->m_data.swap(other.m_data); }
public:
// insert/erase
std::pair<iterator,bool> insert_unique(const value_type& val)
{
std::pair<iterator,bool> ret;
insert_commit_data data;
ret.second = this->priv_insert_unique_prepare(KeyOfValue()(val), data);
ret.first = ret.second ? this->priv_insert_commit(data, val)
: iterator(vector_iterator_get_ptr(data.position));
return ret;
}
std::pair<iterator,bool> insert_unique(BOOST_RV_REF(value_type) val)
{
std::pair<iterator,bool> ret;
insert_commit_data data;
ret.second = this->priv_insert_unique_prepare(KeyOfValue()(val), data);
ret.first = ret.second ? this->priv_insert_commit(data, boost::move(val))
: iterator(vector_iterator_get_ptr(data.position));
return ret;
}
iterator insert_equal(const value_type& val)
{
iterator i = this->upper_bound(KeyOfValue()(val));
i = this->m_data.m_vect.insert(i, val);
return i;
}
iterator insert_equal(BOOST_RV_REF(value_type) mval)
{
iterator i = this->upper_bound(KeyOfValue()(mval));
i = this->m_data.m_vect.insert(i, boost::move(mval));
return i;
}
iterator insert_unique(const_iterator hint, const value_type& val)
{
BOOST_ASSERT(this->priv_in_range_or_end(hint));
insert_commit_data data;
return this->priv_insert_unique_prepare(hint, KeyOfValue()(val), data)
? this->priv_insert_commit(data, val)
: iterator(vector_iterator_get_ptr(data.position));
}
iterator insert_unique(const_iterator hint, BOOST_RV_REF(value_type) val)
{
BOOST_ASSERT(this->priv_in_range_or_end(hint));
insert_commit_data data;
return this->priv_insert_unique_prepare(hint, KeyOfValue()(val), data)
? this->priv_insert_commit(data, boost::move(val))
: iterator(vector_iterator_get_ptr(data.position));
}
iterator insert_equal(const_iterator hint, const value_type& val)
{
BOOST_ASSERT(this->priv_in_range_or_end(hint));
insert_commit_data data;
this->priv_insert_equal_prepare(hint, val, data);
return this->priv_insert_commit(data, val);
}
iterator insert_equal(const_iterator hint, BOOST_RV_REF(value_type) mval)
{
BOOST_ASSERT(this->priv_in_range_or_end(hint));
insert_commit_data data;
this->priv_insert_equal_prepare(hint, mval, data);
return this->priv_insert_commit(data, boost::move(mval));
}
template <class InIt>
void insert_unique(InIt first, InIt last)
{
for ( ; first != last; ++first){
this->insert_unique(*first);
}
}
template <class InIt>
void insert_equal(InIt first, InIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::enable_if_c
< container_detail::is_input_iterator<InIt>::value
>::type * = 0
#endif
)
{ this->priv_insert_equal_loop(first, last); }
template <class InIt>
void insert_equal(InIt first, InIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::enable_if_c
< !container_detail::is_input_iterator<InIt>::value
>::type * = 0
#endif
)
{
const size_type len = static_cast<size_type>(boost::container::iterator_distance(first, last));
this->reserve(this->size()+len);
this->priv_insert_equal_loop(first, last);
}
//Ordered
template <class InIt>
void insert_equal(ordered_range_t, InIt first, InIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::enable_if_c
< container_detail::is_input_iterator<InIt>::value
>::type * = 0
#endif
)
{ this->priv_insert_equal_loop_ordered(first, last); }
template <class FwdIt>
void insert_equal(ordered_range_t, FwdIt first, FwdIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::enable_if_c
< !container_detail::is_input_iterator<FwdIt>::value &&
container_detail::is_forward_iterator<FwdIt>::value
>::type * = 0
#endif
)
{
const size_type len = static_cast<size_type>(boost::container::iterator_distance(first, last));
this->reserve(this->size()+len);
this->priv_insert_equal_loop_ordered(first, last);
}
template <class BidirIt>
void insert_equal(ordered_range_t, BidirIt first, BidirIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::disable_if_or
< void
, container_detail::is_input_iterator<BidirIt>
, container_detail::is_forward_iterator<BidirIt>
>::type * = 0
#endif
)
{ this->m_data.m_vect.merge(first, last, static_cast<const value_compare &>(this->m_data)); }
template <class InIt>
void insert_unique(ordered_unique_range_t, InIt first, InIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::enable_if_or
< void
, container_detail::is_input_iterator<InIt>
, container_detail::is_forward_iterator<InIt>
>::type * = 0
#endif
)
{
const_iterator pos(this->cend());
for ( ; first != last; ++first){
pos = this->insert_unique(pos, *first);
++pos;
}
}
template <class BidirIt>
void insert_unique(ordered_unique_range_t, BidirIt first, BidirIt last
#if !defined(BOOST_CONTAINER_DOXYGEN_INVOKED)
, typename container_detail::enable_if_c
< !(container_detail::is_input_iterator<BidirIt>::value ||
container_detail::is_forward_iterator<BidirIt>::value)
>::type * = 0
#endif
)
{ this->m_data.m_vect.merge_unique(first, last, static_cast<const value_compare &>(this->m_data)); }
#if !defined(BOOST_NO_CXX11_VARIADIC_TEMPLATES)
template <class... Args>
std::pair<iterator, bool> emplace_unique(BOOST_FWD_REF(Args)... args)
{
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));
stored_allocator_type &a = this->get_stored_allocator();
stored_allocator_traits::construct(a, &val, ::boost::forward<Args>(args)... );
value_destructor<stored_allocator_type> d(a, val);
return this->insert_unique(::boost::move(val));
}
template <class... Args>
iterator emplace_hint_unique(const_iterator hint, BOOST_FWD_REF(Args)... args)
{
//hint checked in insert_unique
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));
stored_allocator_type &a = this->get_stored_allocator();
stored_allocator_traits::construct(a, &val, ::boost::forward<Args>(args)... );
value_destructor<stored_allocator_type> d(a, val);
return this->insert_unique(hint, ::boost::move(val));
}
template <class... Args>
iterator emplace_equal(BOOST_FWD_REF(Args)... args)
{
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));
stored_allocator_type &a = this->get_stored_allocator();
stored_allocator_traits::construct(a, &val, ::boost::forward<Args>(args)... );
value_destructor<stored_allocator_type> d(a, val);
return this->insert_equal(::boost::move(val));
}
template <class... Args>
iterator emplace_hint_equal(const_iterator hint, BOOST_FWD_REF(Args)... args)
{
//hint checked in insert_equal
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));
stored_allocator_type &a = this->get_stored_allocator();
stored_allocator_traits::construct(a, &val, ::boost::forward<Args>(args)... );
value_destructor<stored_allocator_type> d(a, val);
return this->insert_equal(hint, ::boost::move(val));
}
template <class KeyType, class... Args>
BOOST_CONTAINER_FORCEINLINE std::pair<iterator, bool> try_emplace
(const_iterator hint, BOOST_FWD_REF(KeyType) key, BOOST_FWD_REF(Args)... args)
{
std::pair<iterator,bool> ret;
insert_commit_data data;
const key_type & k = key;
ret.second = hint == const_iterator()
? this->priv_insert_unique_prepare(k, data)
: this->priv_insert_unique_prepare(hint, k, data);
if(!ret.second){
ret.first = this->nth(data.position - this->cbegin());
}
else{
typedef typename emplace_functor_type<try_emplace_t, KeyType, Args...>::type func_t;
typedef emplace_iterator<value_type, func_t, difference_type> it_t;
func_t func(try_emplace_t(), ::boost::forward<KeyType>(key), ::boost::forward<Args>(args)...);
ret.first = this->m_data.m_vect.insert(data.position, it_t(func), it_t());
}
return ret;
}
#else // !defined(BOOST_NO_CXX11_VARIADIC_TEMPLATES)
#define BOOST_CONTAINER_FLAT_TREE_EMPLACE_CODE(N) \
BOOST_MOVE_TMPL_LT##N BOOST_MOVE_CLASS##N BOOST_MOVE_GT##N \
std::pair<iterator, bool> emplace_unique(BOOST_MOVE_UREF##N)\
{\
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;\
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));\
stored_allocator_type &a = this->get_stored_allocator();\
stored_allocator_traits::construct(a, &val BOOST_MOVE_I##N BOOST_MOVE_FWD##N);\
value_destructor<stored_allocator_type> d(a, val);\
return this->insert_unique(::boost::move(val));\
}\
\
BOOST_MOVE_TMPL_LT##N BOOST_MOVE_CLASS##N BOOST_MOVE_GT##N \
iterator emplace_hint_unique(const_iterator hint BOOST_MOVE_I##N BOOST_MOVE_UREF##N)\
{\
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;\
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));\
stored_allocator_type &a = this->get_stored_allocator();\
stored_allocator_traits::construct(a, &val BOOST_MOVE_I##N BOOST_MOVE_FWD##N);\
value_destructor<stored_allocator_type> d(a, val);\
return this->insert_unique(hint, ::boost::move(val));\
}\
\
BOOST_MOVE_TMPL_LT##N BOOST_MOVE_CLASS##N BOOST_MOVE_GT##N \
iterator emplace_equal(BOOST_MOVE_UREF##N)\
{\
typename aligned_storage<sizeof(value_type), alignment_of<value_type>::value>::type v;\
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));\
stored_allocator_type &a = this->get_stored_allocator();\
stored_allocator_traits::construct(a, &val BOOST_MOVE_I##N BOOST_MOVE_FWD##N);\
value_destructor<stored_allocator_type> d(a, val);\
return this->insert_equal(::boost::move(val));\
}\
\
BOOST_MOVE_TMPL_LT##N BOOST_MOVE_CLASS##N BOOST_MOVE_GT##N \
iterator emplace_hint_equal(const_iterator hint BOOST_MOVE_I##N BOOST_MOVE_UREF##N)\
{\
typename aligned_storage <sizeof(value_type), alignment_of<value_type>::value>::type v;\
value_type &val = *static_cast<value_type *>(static_cast<void *>(&v));\
stored_allocator_type &a = this->get_stored_allocator();\
stored_allocator_traits::construct(a, &val BOOST_MOVE_I##N BOOST_MOVE_FWD##N);\
value_destructor<stored_allocator_type> d(a, val);\
return this->insert_equal(hint, ::boost::move(val));\
}\
template <class KeyType BOOST_MOVE_I##N BOOST_MOVE_CLASS##N>\
BOOST_CONTAINER_FORCEINLINE std::pair<iterator, bool>\
try_emplace(const_iterator hint, BOOST_FWD_REF(KeyType) key BOOST_MOVE_I##N BOOST_MOVE_UREF##N)\
{\
std::pair<iterator,bool> ret;\
insert_commit_data data;\
const key_type & k = key;\
ret.second = hint == const_iterator()\
? this->priv_insert_unique_prepare(k, data)\
: this->priv_insert_unique_prepare(hint, k, data);\
\
if(!ret.second){\
ret.first = this->nth(data.position - this->cbegin());\
}\
else{\
typedef typename emplace_functor_type<try_emplace_t, KeyType BOOST_MOVE_I##N BOOST_MOVE_TARG##N>::type func_t;\
typedef emplace_iterator<value_type, func_t, difference_type> it_t;\
func_t func(try_emplace_t(), ::boost::forward<KeyType>(key) BOOST_MOVE_I##N BOOST_MOVE_FWD##N);\
ret.first = this->m_data.m_vect.insert(data.position, it_t(func), it_t());\
}\
return ret;\
}\
//
BOOST_MOVE_ITERATE_0TO7(BOOST_CONTAINER_FLAT_TREE_EMPLACE_CODE)
#undef BOOST_CONTAINER_FLAT_TREE_EMPLACE_CODE
#endif // !defined(BOOST_NO_CXX11_VARIADIC_TEMPLATES)
template<class KeyType, class M>
std::pair<iterator, bool> insert_or_assign(const_iterator hint, BOOST_FWD_REF(KeyType) key, BOOST_FWD_REF(M) obj)
{
const key_type& k = key;
std::pair<iterator,bool> ret;
insert_commit_data data;
ret.second = hint == const_iterator()
? this->priv_insert_unique_prepare(k, data)
: this->priv_insert_unique_prepare(hint, k, data);
if(!ret.second){
ret.first = this->nth(data.position - this->cbegin());
ret.first->second = boost::forward<M>(obj);
}
else{
typedef typename emplace_functor_type<KeyType, M>::type func_t;
typedef emplace_iterator<value_type, func_t, difference_type> it_t;
func_t func(boost::forward<KeyType>(key), boost::forward<M>(obj));
ret.first = this->m_data.m_vect.insert(data.position, it_t(func), it_t());
}
return ret;
}
BOOST_CONTAINER_FORCEINLINE iterator erase(const_iterator position)
{ return this->m_data.m_vect.erase(position); }
size_type erase(const key_type& k)
{
std::pair<iterator,iterator > itp = this->equal_range(k);
size_type ret = static_cast<size_type>(itp.second-itp.first);
if (ret){
this->m_data.m_vect.erase(itp.first, itp.second);
}
return ret;
}
BOOST_CONTAINER_FORCEINLINE iterator erase(const_iterator first, const_iterator last)
{ return this->m_data.m_vect.erase(first, last); }
BOOST_CONTAINER_FORCEINLINE void clear()
{ this->m_data.m_vect.clear(); }
//! <b>Effects</b>: Tries to deallocate the excess of memory created
// with previous allocations. The size of the vector is unchanged
//!
//! <b>Throws</b>: If memory allocation throws, or T's copy constructor throws.
//!
//! <b>Complexity</b>: Linear to size().
BOOST_CONTAINER_FORCEINLINE void shrink_to_fit()
{ this->m_data.m_vect.shrink_to_fit(); }
BOOST_CONTAINER_FORCEINLINE iterator nth(size_type n) BOOST_NOEXCEPT_OR_NOTHROW
{ return this->m_data.m_vect.nth(n); }
BOOST_CONTAINER_FORCEINLINE const_iterator nth(size_type n) const BOOST_NOEXCEPT_OR_NOTHROW
{ return this->m_data.m_vect.nth(n); }
BOOST_CONTAINER_FORCEINLINE size_type index_of(iterator p) BOOST_NOEXCEPT_OR_NOTHROW
{ return this->m_data.m_vect.index_of(p); }
BOOST_CONTAINER_FORCEINLINE size_type index_of(const_iterator p) const BOOST_NOEXCEPT_OR_NOTHROW
{ return this->m_data.m_vect.index_of(p); }
// set operations:
iterator find(const key_type& k)
{
iterator i = this->lower_bound(k);
iterator end_it = this->end();
if (i != end_it && this->m_data.get_comp()(k, KeyOfValue()(*i))){
i = end_it;
}
return i;
}
const_iterator find(const key_type& k) const
{
const_iterator i = this->lower_bound(k);
const_iterator end_it = this->cend();
if (i != end_it && this->m_data.get_comp()(k, KeyOfValue()(*i))){
i = end_it;
}
return i;
}
// set operations:
size_type count(const key_type& k) const
{
std::pair<const_iterator, const_iterator> p = this->equal_range(k);
size_type n = p.second - p.first;
return n;
}
template<class C2>
void merge_unique(flat_tree<Value, KeyOfValue, C2, Allocator>& source)
{
this->insert( boost::make_move_iterator(source.begin())
, boost::make_move_iterator(source.end()));
}
template<class C2>
void merge_equal(flat_tree<Value, KeyOfValue, C2, Allocator>& source)
{
this->insert( boost::make_move_iterator(source.begin())
, boost::make_move_iterator(source.end()));
}
void merge_unique(flat_tree& source)
{
this->m_data.m_vect.merge_unique
( boost::make_move_iterator(source.begin())
, boost::make_move_iterator(source.end())
, static_cast<const value_compare &>(this->m_data));
}
void merge_equal(flat_tree& source)
{
this->m_data.m_vect.merge
( boost::make_move_iterator(source.begin())
, boost::make_move_iterator(source.end())
, static_cast<const value_compare &>(this->m_data));
}
BOOST_CONTAINER_FORCEINLINE iterator lower_bound(const key_type& k)
{ return this->priv_lower_bound(this->begin(), this->end(), k); }
BOOST_CONTAINER_FORCEINLINE const_iterator lower_bound(const key_type& k) const
{ return this->priv_lower_bound(this->cbegin(), this->cend(), k); }
BOOST_CONTAINER_FORCEINLINE iterator upper_bound(const key_type& k)
{ return this->priv_upper_bound(this->begin(), this->end(), k); }
BOOST_CONTAINER_FORCEINLINE const_iterator upper_bound(const key_type& k) const
{ return this->priv_upper_bound(this->cbegin(), this->cend(), k); }
BOOST_CONTAINER_FORCEINLINE std::pair<iterator,iterator> equal_range(const key_type& k)
{ return this->priv_equal_range(this->begin(), this->end(), k); }
BOOST_CONTAINER_FORCEINLINE std::pair<const_iterator, const_iterator> equal_range(const key_type& k) const
{ return this->priv_equal_range(this->cbegin(), this->cend(), k); }
BOOST_CONTAINER_FORCEINLINE std::pair<iterator, iterator> lower_bound_range(const key_type& k)
{ return this->priv_lower_bound_range(this->begin(), this->end(), k); }
BOOST_CONTAINER_FORCEINLINE std::pair<const_iterator, const_iterator> lower_bound_range(const key_type& k) const
{ return this->priv_lower_bound_range(this->cbegin(), this->cend(), k); }
BOOST_CONTAINER_FORCEINLINE size_type capacity() const
{ return this->m_data.m_vect.capacity(); }
BOOST_CONTAINER_FORCEINLINE void reserve(size_type cnt)
{ this->m_data.m_vect.reserve(cnt); }
BOOST_CONTAINER_FORCEINLINE friend bool operator==(const flat_tree& x, const flat_tree& y)
{
return x.size() == y.size() && ::boost::container::algo_equal(x.begin(), x.end(), y.begin());
}
BOOST_CONTAINER_FORCEINLINE friend bool operator<(const flat_tree& x, const flat_tree& y)
{
return ::boost::container::algo_lexicographical_compare(x.begin(), x.end(), y.begin(), y.end());
}
BOOST_CONTAINER_FORCEINLINE friend bool operator!=(const flat_tree& x, const flat_tree& y)
{ return !(x == y); }
BOOST_CONTAINER_FORCEINLINE friend bool operator>(const flat_tree& x, const flat_tree& y)
{ return y < x; }
BOOST_CONTAINER_FORCEINLINE friend bool operator<=(const flat_tree& x, const flat_tree& y)
{ return !(y < x); }
BOOST_CONTAINER_FORCEINLINE friend bool operator>=(const flat_tree& x, const flat_tree& y)
{ return !(x < y); }
BOOST_CONTAINER_FORCEINLINE friend void swap(flat_tree& x, flat_tree& y)
{ x.swap(y); }
private:
BOOST_CONTAINER_FORCEINLINE bool priv_in_range_or_end(const_iterator pos) const
{
return (this->begin() <= pos) && (pos <= this->end());
}
struct insert_commit_data
{
const_iterator position;
};
// insert/erase
void priv_insert_equal_prepare
(const_iterator pos, const value_type& val, insert_commit_data &data)
{
// N1780
// To insert val at pos:
// if pos == end || val <= *pos
// if pos == begin || val >= *(pos-1)
// insert val before pos
// else
// insert val before upper_bound(val)
// else
// insert val before lower_bound(val)
const value_compare &val_cmp = this->m_data;
if(pos == this->cend() || !val_cmp(*pos, val)){
if (pos == this->cbegin() || !val_cmp(val, pos[-1])){
data.position = pos;
}
else{
data.position =
this->priv_upper_bound(this->cbegin(), pos, KeyOfValue()(val));
}
}
else{
data.position =
this->priv_lower_bound(pos, this->cend(), KeyOfValue()(val));
}
}
bool priv_insert_unique_prepare
(const_iterator b, const_iterator e, const key_type& k, insert_commit_data &commit_data)
{
const key_compare &key_cmp = this->priv_key_comp();
commit_data.position = this->priv_lower_bound(b, e, k);
return commit_data.position == e || key_cmp(k, KeyOfValue()(*commit_data.position));
}
BOOST_CONTAINER_FORCEINLINE bool priv_insert_unique_prepare
(const key_type& k, insert_commit_data &commit_data)
{ return this->priv_insert_unique_prepare(this->cbegin(), this->cend(), k, commit_data); }
bool priv_insert_unique_prepare
(const_iterator pos, const key_type& k, insert_commit_data &commit_data)
{
//N1780. Props to Howard Hinnant!
//To insert k at pos:
//if pos == end || k <= *pos
// if pos == begin || k >= *(pos-1)
// insert k before pos
// else
// insert k before upper_bound(k)
//else if pos+1 == end || k <= *(pos+1)
// insert k after pos
//else
// insert k before lower_bound(k)
const key_compare &key_cmp = this->priv_key_comp();
const const_iterator cend_it = this->cend();
if(pos == cend_it || key_cmp(k, KeyOfValue()(*pos))){ //Check if k should go before end
const const_iterator cbeg = this->cbegin();
commit_data.position = pos;
if(pos == cbeg){ //If container is empty then insert it in the beginning
return true;
}
const_iterator prev(pos);
--prev;
if(key_cmp(KeyOfValue()(*prev), k)){ //If previous element was less, then it should go between prev and pos
return true;
}
else if(!key_cmp(k, KeyOfValue()(*prev))){ //If previous was equal then insertion should fail
commit_data.position = prev;
return false;
}
else{ //Previous was bigger so insertion hint was pointless, dispatch to hintless insertion
//but reduce the search between beg and prev as prev is bigger than k
return this->priv_insert_unique_prepare(cbeg, prev, k, commit_data);
}
}
else{
//The hint is before the insertion position, so insert it
//in the remaining range [pos, end)
return this->priv_insert_unique_prepare(pos, cend_it, k, commit_data);
}
}
template<class Convertible>
BOOST_CONTAINER_FORCEINLINE iterator priv_insert_commit
(insert_commit_data &commit_data, BOOST_FWD_REF(Convertible) convertible)
{
return this->m_data.m_vect.insert
( commit_data.position
, boost::forward<Convertible>(convertible));
}
template <class RanIt>
RanIt priv_lower_bound(RanIt first, const RanIt last,
const key_type & key) const
{
const Compare &key_cmp = this->m_data.get_comp();
KeyOfValue key_extract;
size_type len = static_cast<size_type>(last - first);
RanIt middle;
while (len) {
size_type step = len >> 1;
middle = first;
middle += step;
if (key_cmp(key_extract(*middle), key)) {
first = ++middle;
len -= step + 1;
}
else{
len = step;
}
}
return first;
}
template <class RanIt>
RanIt priv_upper_bound
(RanIt first, const RanIt last,const key_type & key) const
{
const Compare &key_cmp = this->m_data.get_comp();
KeyOfValue key_extract;
size_type len = static_cast<size_type>(last - first);
RanIt middle;
while (len) {
size_type step = len >> 1;
middle = first;
middle += step;
if (key_cmp(key, key_extract(*middle))) {
len = step;
}
else{
first = ++middle;
len -= step + 1;
}
}
return first;
}
template <class RanIt>
std::pair<RanIt, RanIt>
priv_equal_range(RanIt first, RanIt last, const key_type& key) const
{
const Compare &key_cmp = this->m_data.get_comp();
KeyOfValue key_extract;
size_type len = static_cast<size_type>(last - first);
RanIt middle;
while (len) {
size_type step = len >> 1;
middle = first;
middle += step;
if (key_cmp(key_extract(*middle), key)){
first = ++middle;
len -= step + 1;
}
else if (key_cmp(key, key_extract(*middle))){
len = step;
}
else {
//Middle is equal to key
last = first;
last += len;
RanIt const first_ret = this->priv_lower_bound(first, middle, key);
return std::pair<RanIt, RanIt>
( first_ret, this->priv_upper_bound(++middle, last, key));
}
}
return std::pair<RanIt, RanIt>(first, first);
}
template<class RanIt>
std::pair<RanIt, RanIt> priv_lower_bound_range(RanIt first, RanIt last, const key_type& k) const
{
const Compare &key_cmp = this->m_data.get_comp();
KeyOfValue key_extract;
RanIt lb(this->priv_lower_bound(first, last, k)), ub(lb);
if(lb != last && static_cast<difference_type>(!key_cmp(k, key_extract(*lb)))){
++ub;
}
return std::pair<RanIt, RanIt>(lb, ub);
}
template<class InIt>
void priv_insert_equal_loop(InIt first, InIt last)
{
for ( ; first != last; ++first){
this->insert_equal(*first);
}
}
template<class InIt>
void priv_insert_equal_loop_ordered(InIt first, InIt last)
{
const_iterator pos(this->cend());
for ( ; first != last; ++first){
//If ordered, then try hint version
//to achieve constant-time complexity per insertion
//in some cases
pos = this->insert_equal(pos, *first);
++pos;
}
}
};
} //namespace container_detail {
} //namespace container {
//!has_trivial_destructor_after_move<> == true_type
//!specialization for optimizations
template <class T, class KeyOfValue,
class Compare, class Allocator>
struct has_trivial_destructor_after_move<boost::container::container_detail::flat_tree<T, KeyOfValue, Compare, Allocator> >
{
typedef typename ::boost::container::allocator_traits<Allocator>::pointer pointer;
static const bool value = ::boost::has_trivial_destructor_after_move<Allocator>::value &&
::boost::has_trivial_destructor_after_move<pointer>::value;
};
} //namespace boost {
#include <boost/container/detail/config_end.hpp>
#endif // BOOST_CONTAINER_FLAT_TREE_HPP
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