vn-verdnaturachat/ios/Pods/boost-for-react-native/boost/pending/container_traits.hpp

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// (C) Copyright Jeremy Siek 2004
// (C) Copyright Thomas Claveirole 2010
// (C) Copyright Ignacy Gawedzki 2010
// 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)
#ifndef BOOST_GRAPH_DETAIL_CONTAINER_TRAITS_H
#define BOOST_GRAPH_DETAIL_CONTAINER_TRAITS_H
// Sure would be nice to be able to forward declare these
// instead of pulling in all the headers. Too bad that
// is not legal. There ought to be a standard <stlfwd> header. -JGS
#include <boost/next_prior.hpp>
#include <algorithm> // for std::remove
#include <utility>
#include <vector>
#include <list>
#include <map>
#include <set>
#include <boost/unordered_set.hpp>
#include <boost/unordered_map.hpp>
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
#include <unordered_set>
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
#include <unordered_map>
#endif
#ifdef BOOST_NO_CXX11_RVALUE_REFERENCES
#define BOOST_PENDING_FWD_TYPE(type) const type&
#define BOOST_PENDING_FWD_VALUE(type, var) (var)
#else
#define BOOST_PENDING_FWD_TYPE(type) type&&
#define BOOST_PENDING_FWD_VALUE(type, var) (std::forward<type>((var)))
#endif
// The content of this file is in 'graph_detail' because otherwise
// there will be name clashes with
// sandbox/boost/sequence_algo/container_traits.hpp
// The 'detail' subnamespace will still cause problems.
namespace boost { namespace graph_detail {
//======================================================================
// Container Category Tags
//
// They use virtual inheritance because there are lots of
// inheritance diamonds.
struct container_tag { };
struct forward_container_tag : virtual public container_tag { };
struct reversible_container_tag : virtual public forward_container_tag { };
struct random_access_container_tag
: virtual public reversible_container_tag { };
struct sequence_tag : virtual public forward_container_tag { };
struct associative_container_tag : virtual public forward_container_tag { };
struct sorted_associative_container_tag
: virtual public associative_container_tag,
virtual public reversible_container_tag { };
struct front_insertion_sequence_tag : virtual public sequence_tag { };
struct back_insertion_sequence_tag : virtual public sequence_tag { };
struct unique_associative_container_tag
: virtual public associative_container_tag { };
struct multiple_associative_container_tag
: virtual public associative_container_tag { };
struct simple_associative_container_tag
: virtual public associative_container_tag { };
struct pair_associative_container_tag
: virtual public associative_container_tag { };
//======================================================================
// Iterator Stability Tags
//
// Do mutating operations such as insert/erase/resize invalidate all
// outstanding iterators?
struct stable_tag { };
struct unstable_tag { };
//======================================================================
// Container Traits Class and container_category() function
// don't use this unless there is partial specialization
template <class Container>
struct container_traits {
typedef typename Container::category category;
typedef typename Container::iterator_stability iterator_stability;
};
// Use this as a compile-time assertion that X is stable
inline void require_stable(stable_tag) { }
// std::vector
struct vector_tag :
virtual public random_access_container_tag,
virtual public back_insertion_sequence_tag { };
template <class T, class Alloc>
vector_tag container_category(const std::vector<T,Alloc>&)
{ return vector_tag(); }
template <class T, class Alloc>
unstable_tag iterator_stability(const std::vector<T,Alloc>&)
{ return unstable_tag(); }
template <class T, class Alloc>
struct container_traits< std::vector<T,Alloc> > {
typedef vector_tag category;
typedef unstable_tag iterator_stability;
};
// std::list
struct list_tag :
virtual public reversible_container_tag,
virtual public back_insertion_sequence_tag
// this causes problems for push_dispatch...
// virtual public front_insertion_sequence_tag
{ };
template <class T, class Alloc>
list_tag container_category(const std::list<T,Alloc>&)
{ return list_tag(); }
template <class T, class Alloc>
stable_tag iterator_stability(const std::list<T,Alloc>&)
{ return stable_tag(); }
template <class T, class Alloc>
struct container_traits< std::list<T,Alloc> > {
typedef list_tag category;
typedef stable_tag iterator_stability;
};
// std::set
struct set_tag :
virtual public sorted_associative_container_tag,
virtual public simple_associative_container_tag,
virtual public unique_associative_container_tag
{ };
template <class Key, class Cmp, class Alloc>
set_tag container_category(const std::set<Key,Cmp,Alloc>&)
{ return set_tag(); }
template <class Key, class Cmp, class Alloc>
stable_tag iterator_stability(const std::set<Key,Cmp,Alloc>&)
{ return stable_tag(); }
template <class Key, class Cmp, class Alloc>
struct container_traits< std::set<Key,Cmp,Alloc> > {
typedef set_tag category;
typedef stable_tag iterator_stability;
};
// std::multiset
struct multiset_tag :
virtual public sorted_associative_container_tag,
virtual public simple_associative_container_tag,
virtual public multiple_associative_container_tag
{ };
template <class Key, class Cmp, class Alloc>
multiset_tag container_category(const std::multiset<Key,Cmp,Alloc>&)
{ return multiset_tag(); }
template <class Key, class Cmp, class Alloc>
stable_tag iterator_stability(const std::multiset<Key,Cmp,Alloc>&)
{ return stable_tag(); }
template <class Key, class Cmp, class Alloc>
struct container_traits< std::multiset<Key,Cmp,Alloc> > {
typedef multiset_tag category;
typedef stable_tag iterator_stability;
};
// deque
// std::map
struct map_tag :
virtual public sorted_associative_container_tag,
virtual public pair_associative_container_tag,
virtual public unique_associative_container_tag
{ };
template <class Key, class T, class Cmp, class Alloc>
struct container_traits< std::map<Key,T,Cmp,Alloc> > {
typedef map_tag category;
typedef stable_tag iterator_stability;
};
template <class Key, class T, class Cmp, class Alloc>
map_tag container_category(const std::map<Key,T,Cmp,Alloc>&)
{ return map_tag(); }
template <class Key, class T, class Cmp, class Alloc>
stable_tag iterator_stability(const std::map<Key,T,Cmp,Alloc>&)
{ return stable_tag(); }
// std::multimap
struct multimap_tag :
virtual public sorted_associative_container_tag,
virtual public pair_associative_container_tag,
virtual public multiple_associative_container_tag
{ };
template <class Key, class T, class Cmp, class Alloc>
struct container_traits< std::multimap<Key,T,Cmp,Alloc> > {
typedef multimap_tag category;
typedef stable_tag iterator_stability;
};
template <class Key, class T, class Cmp, class Alloc>
multimap_tag container_category(const std::multimap<Key,T,Cmp,Alloc>&)
{ return multimap_tag(); }
template <class Key, class T, class Cmp, class Alloc>
stable_tag iterator_stability(const std::multimap<Key,T,Cmp,Alloc>&)
{ return stable_tag(); }
// hash_set, hash_map
struct unordered_set_tag :
virtual public simple_associative_container_tag,
virtual public unique_associative_container_tag
{ };
struct unordered_multiset_tag :
virtual public simple_associative_container_tag,
virtual public multiple_associative_container_tag
{ };
struct unordered_map_tag :
virtual public pair_associative_container_tag,
virtual public unique_associative_container_tag
{ };
struct unordered_multimap_tag :
virtual public pair_associative_container_tag,
virtual public multiple_associative_container_tag
{ };
template <class Key, class Eq, class Hash, class Alloc>
struct container_traits< boost::unordered_set<Key,Eq,Hash,Alloc> > {
typedef unordered_set_tag category;
typedef unstable_tag iterator_stability;
};
template <class Key, class T, class Eq, class Hash, class Alloc>
struct container_traits< boost::unordered_map<Key,T,Eq,Hash,Alloc> > {
typedef unordered_map_tag category;
typedef unstable_tag iterator_stability;
};
template <class Key, class Eq, class Hash, class Alloc>
struct container_traits< boost::unordered_multiset<Key,Eq,Hash,Alloc> > {
typedef unordered_multiset_tag category;
typedef unstable_tag iterator_stability;
};
template <class Key, class T, class Eq, class Hash, class Alloc>
struct container_traits< boost::unordered_multimap<Key,T,Eq,Hash,Alloc> > {
typedef unordered_multimap_tag category;
typedef unstable_tag iterator_stability;
};
template <class Key, class Eq, class Hash, class Alloc>
unordered_set_tag
container_category(const boost::unordered_set<Key,Eq,Hash,Alloc>&)
{ return unordered_set_tag(); }
template <class Key, class T, class Eq, class Hash, class Alloc>
unordered_map_tag
container_category(const boost::unordered_map<Key,T,Eq,Hash,Alloc>&)
{ return unordered_map_tag(); }
template <class Key, class Eq, class Hash, class Alloc>
unstable_tag iterator_stability(const boost::unordered_set<Key,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
template <class Key, class T, class Eq, class Hash, class Alloc>
unstable_tag iterator_stability(const boost::unordered_map<Key,T,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
template <class Key, class Eq, class Hash, class Alloc>
unordered_multiset_tag
container_category(const boost::unordered_multiset<Key,Eq,Hash,Alloc>&)
{ return unordered_multiset_tag(); }
template <class Key, class T, class Eq, class Hash, class Alloc>
unordered_multimap_tag
container_category(const boost::unordered_multimap<Key,T,Eq,Hash,Alloc>&)
{ return unordered_multimap_tag(); }
template <class Key, class Eq, class Hash, class Alloc>
unstable_tag
iterator_stability(const boost::unordered_multiset<Key,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
template <class Key, class T, class Eq, class Hash, class Alloc>
unstable_tag
iterator_stability(const boost::unordered_multimap<Key,T,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
template <class Key, class Eq, class Hash, class Alloc>
struct container_traits< std::unordered_set<Key,Eq,Hash,Alloc> > {
typedef unordered_set_tag category;
typedef unstable_tag iterator_stability;
};
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
template <class Key, class T, class Eq, class Hash, class Alloc>
struct container_traits< std::unordered_map<Key,T,Eq,Hash,Alloc> > {
typedef unordered_map_tag category;
typedef unstable_tag iterator_stability;
};
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
template <class Key, class Eq, class Hash, class Alloc>
struct container_traits< std::unordered_multiset<Key,Eq,Hash,Alloc> > {
typedef unordered_multiset_tag category;
typedef unstable_tag iterator_stability;
};
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
template <class Key, class T, class Eq, class Hash, class Alloc>
struct container_traits< std::unordered_multimap<Key,T,Eq,Hash,Alloc> > {
typedef unordered_multimap_tag category;
typedef unstable_tag iterator_stability;
};
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
template <class Key, class Eq, class Hash, class Alloc>
unordered_set_tag
container_category(const std::unordered_set<Key,Eq,Hash,Alloc>&)
{ return unordered_set_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
template <class Key, class T, class Eq, class Hash, class Alloc>
unordered_map_tag
container_category(const std::unordered_map<Key,T,Eq,Hash,Alloc>&)
{ return unordered_map_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
template <class Key, class Eq, class Hash, class Alloc>
unstable_tag iterator_stability(const std::unordered_set<Key,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
template <class Key, class T, class Eq, class Hash, class Alloc>
unstable_tag iterator_stability(const std::unordered_map<Key,T,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
template <class Key, class Eq, class Hash, class Alloc>
unordered_multiset_tag
container_category(const std::unordered_multiset<Key,Eq,Hash,Alloc>&)
{ return unordered_multiset_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
template <class Key, class T, class Eq, class Hash, class Alloc>
unordered_multimap_tag
container_category(const std::unordered_multimap<Key,T,Eq,Hash,Alloc>&)
{ return unordered_multimap_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_SET
template <class Key, class Eq, class Hash, class Alloc>
unstable_tag
iterator_stability(const std::unordered_multiset<Key,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
#endif
#ifndef BOOST_NO_CXX11_HDR_UNORDERED_MAP
template <class Key, class T, class Eq, class Hash, class Alloc>
unstable_tag
iterator_stability(const std::unordered_multimap<Key,T,Eq,Hash,Alloc>&)
{ return unstable_tag(); }
#endif
//===========================================================================
// Generalized Container Functions
// Erase
template <class Sequence, class T>
void erase_dispatch(Sequence& c, const T& x,
sequence_tag)
{
c.erase(std::remove(c.begin(), c.end(), x), c.end());
}
template <class AssociativeContainer, class T>
void erase_dispatch(AssociativeContainer& c, const T& x,
associative_container_tag)
{
c.erase(x);
}
template <class Container, class T>
void erase(Container& c, const T& x)
{
erase_dispatch(c, x, container_category(c));
}
// Erase If
template <class Sequence, class Predicate, class IteratorStability>
void erase_if_dispatch(Sequence& c, Predicate p,
sequence_tag, IteratorStability)
{
#if 0
c.erase(std::remove_if(c.begin(), c.end(), p), c.end());
#else
if (! c.empty())
c.erase(std::remove_if(c.begin(), c.end(), p), c.end());
#endif
}
template <class AssociativeContainer, class Predicate>
void erase_if_dispatch(AssociativeContainer& c, Predicate p,
associative_container_tag, stable_tag)
{
typename AssociativeContainer::iterator i, next;
for (i = next = c.begin(); next != c.end(); i = next) {
++next;
if (p(*i))
c.erase(i);
}
}
template <class AssociativeContainer, class Predicate>
void erase_if_dispatch(AssociativeContainer& c, Predicate p,
associative_container_tag, unstable_tag)
{
// This method is really slow, so hopefully we won't have any
// associative containers with unstable iterators!
// Is there a better way to do this?
typename AssociativeContainer::iterator i;
typename AssociativeContainer::size_type n = c.size();
while (n--)
for (i = c.begin(); i != c.end(); ++i)
if (p(*i)) {
c.erase(i);
break;
}
}
template <class Container, class Predicate>
void erase_if(Container& c, Predicate p)
{
erase_if_dispatch(c, p, container_category(c), iterator_stability(c));
}
// Push
template <class Container, class T>
std::pair<typename Container::iterator, bool>
push_dispatch(Container& c, BOOST_PENDING_FWD_TYPE(T) v, back_insertion_sequence_tag)
{
c.push_back(BOOST_PENDING_FWD_VALUE(T, v));
return std::make_pair(boost::prior(c.end()), true);
}
template <class Container, class T>
std::pair<typename Container::iterator, bool>
push_dispatch(Container& c, BOOST_PENDING_FWD_TYPE(T) v, front_insertion_sequence_tag)
{
c.push_front(BOOST_PENDING_FWD_VALUE(T, v));
return std::make_pair(c.begin(), true);
}
template <class AssociativeContainer, class T>
std::pair<typename AssociativeContainer::iterator, bool>
push_dispatch(AssociativeContainer& c, BOOST_PENDING_FWD_TYPE(T) v,
unique_associative_container_tag)
{
return c.insert(BOOST_PENDING_FWD_VALUE(T, v));
}
template <class AssociativeContainer, class T>
std::pair<typename AssociativeContainer::iterator, bool>
push_dispatch(AssociativeContainer& c, BOOST_PENDING_FWD_TYPE(T) v,
multiple_associative_container_tag)
{
return std::make_pair(c.insert(BOOST_PENDING_FWD_VALUE(T, v)), true);
}
template <class Container, class T>
std::pair<typename Container::iterator,bool>
push(Container& c, BOOST_PENDING_FWD_TYPE(T) v)
{
return push_dispatch(c, BOOST_PENDING_FWD_VALUE(T, v), container_category(c));
}
// Find
template <class Container, class Value>
typename Container::iterator
find_dispatch(Container& c,
const Value& value,
container_tag)
{
return std::find(c.begin(), c.end(), value);
}
template <class AssociativeContainer, class Value>
typename AssociativeContainer::iterator
find_dispatch(AssociativeContainer& c,
const Value& value,
associative_container_tag)
{
return c.find(value);
}
template <class Container, class Value>
typename Container::iterator
find(Container& c,
const Value& value)
{
return find_dispatch(c, value,
graph_detail::container_category(c));
}
// Find (const versions)
template <class Container, class Value>
typename Container::const_iterator
find_dispatch(const Container& c,
const Value& value,
container_tag)
{
return std::find(c.begin(), c.end(), value);
}
template <class AssociativeContainer, class Value>
typename AssociativeContainer::const_iterator
find_dispatch(const AssociativeContainer& c,
const Value& value,
associative_container_tag)
{
return c.find(value);
}
template <class Container, class Value>
typename Container::const_iterator
find(const Container& c,
const Value& value)
{
return find_dispatch(c, value,
graph_detail::container_category(c));
}
// Equal range
#if 0
// Make the dispatch fail if c is not an Associative Container (and thus
// doesn't have equal_range unless it is sorted, which we cannot check
// statically and is not typically true for BGL's uses of this function).
template <class Container,
class LessThanComparable>
std::pair<typename Container::iterator, typename Container::iterator>
equal_range_dispatch(Container& c,
const LessThanComparable& value,
container_tag)
{
// c must be sorted for std::equal_range to behave properly.
return std::equal_range(c.begin(), c.end(), value);
}
#endif
template <class AssociativeContainer, class Value>
std::pair<typename AssociativeContainer::iterator,
typename AssociativeContainer::iterator>
equal_range_dispatch(AssociativeContainer& c,
const Value& value,
associative_container_tag)
{
return c.equal_range(value);
}
template <class Container, class Value>
std::pair<typename Container::iterator, typename Container::iterator>
equal_range(Container& c,
const Value& value)
{
return equal_range_dispatch(c, value,
graph_detail::container_category(c));
}
}} // namespace boost::graph_detail
#undef BOOST_PENDING_FWD_TYPE
#undef BOOST_PENDING_FWD_VALUE
#endif // BOOST_GRAPH_DETAIL_CONTAINER_TRAITS_H