// hash_map standard header
#ifndef _HASH_MAP_
#define _HASH_MAP_
#pragma option push -b -a8 -pc -Vx- -Ve- -w-inl -w-aus -w-sig
#include <xhash>
_STD_BEGIN

		// TEMPLATE CLASS _Hmap_traits
template<class _Kty,	// key type
	class _Ty,	// mapped type
	class _Tr,	// comparator predicate type
	class _Alloc,	// actual allocator type (should be value allocator)
	bool _Mfl>	// true if multiple equivalent keys are permitted
	class _Hmap_traits
		: public _Container_base
	{	// traits required to make _Hash behave like a map
public:
	typedef _Kty key_type;
	typedef pair<const _Kty, _Ty> value_type;
	typedef _Tr key_compare;
	typedef typename _Alloc::template rebind<value_type>::other
		allocator_type;

 #if _HAS_IMMUTABLE_SETS
	typedef _POINTER_X(value_type, allocator_type) _ITptr;
	typedef _REFERENCE_X(value_type, allocator_type) _IReft;
 #endif /* _HAS_IMMUTABLE_SETS */

	enum
		{	// make multi parameter visible as an enum constant
		_Multi = _Mfl};

	_Hmap_traits()
		: comp()
		{	// construct with default comparator
		}

	_Hmap_traits(const _Tr& _Traits)
		: comp(_Traits)
		{	// construct with specified comparator
		}

	class value_compare
		: public binary_function<value_type, value_type, bool>
		{	// functor for comparing two element values
		friend class _Hmap_traits<_Kty, _Ty, _Tr, _Alloc, _Mfl>;

	public:
		bool operator()(const value_type& _Left,
			const value_type& _Right) const
			{	// test if _Left precedes _Right by comparing just keys
			return (comp(_Left.first, _Right.first));
			}

		value_compare(const key_compare& _Traits)
			: comp(_Traits)
			{	// construct with specified predicate
			}

	protected:
		key_compare comp;	// the comparator predicate for keys
		};

	static const _Kty& _Kfn(const value_type& _Val)
		{	// extract key from element value
		return (_Val.first);
		}

	_Tr comp;	// the comparator predicate for keys
	};

		// TEMPLATE CLASS hash_map
template<class _Kty,
	class _Ty,
	class _Tr = hash_compare<_Kty, less<_Kty> >,
	class _Alloc = allocator<pair<const _Kty, _Ty> > >
	class hash_map
		: public _Hash<_Hmap_traits<_Kty, _Ty, _Tr, _Alloc, false> >
	{	// hash table of {key, mapped} values, unique keys
public:
	typedef hash_map<_Kty, _Ty, _Tr, _Alloc> _Myt;
	typedef _Hash<_Hmap_traits<_Kty, _Ty, _Tr, _Alloc, false> > _Mybase;
	typedef _Kty key_type;
	typedef _Ty mapped_type;
	typedef _Ty referent_type;
	typedef _Tr key_compare;
	typedef typename _Mybase::value_compare value_compare;
	typedef typename _Mybase::allocator_type allocator_type;
	typedef typename _Mybase::size_type size_type;
	typedef typename _Mybase::difference_type difference_type;
	typedef typename _Mybase::pointer pointer;
	typedef typename _Mybase::const_pointer const_pointer;
	typedef typename _Mybase::reference reference;
	typedef typename _Mybase::const_reference const_reference;
	typedef typename _Mybase::iterator iterator;
	typedef typename _Mybase::const_iterator const_iterator;
	typedef typename _Mybase::reverse_iterator reverse_iterator;
	typedef typename _Mybase::const_reverse_iterator
		const_reverse_iterator;
	typedef typename _Mybase::value_type value_type;

	hash_map()
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults
		}

	explicit hash_map(const key_compare& _Traits)
		: _Mybase(_Traits, allocator_type())
		{	// construct empty map from comparator
		}

	hash_map(const key_compare& _Traits, const allocator_type& _Al)
		: _Mybase(_Traits, _Al)
		{	// construct empty map from comparator and allocator
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last,
			const key_compare& _Traits)
		: _Mybase(_Traits, allocator_type())
		{	// construct map from sequence, comparator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last,
			const key_compare& _Traits,
			const allocator_type& _Al)
		: _Mybase(_Traits, _Al)
		{	// construct map from sequence, comparator, and allocator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	mapped_type& operator[](const key_type& _Keyval)
		{	// find element matching _Keyval or insert with default mapped
		iterator _Where = this->lower_bound(_Keyval);
		if (_Where == this->end())
			_Where = this->insert(value_type(_Keyval, mapped_type())).first;
		return ((*_Where).second);
		}
	};

template<class _Kty,
	class _Ty,
	class _Tr,
	class _Alloc> inline
	void swap(hash_map<_Kty, _Ty, _Tr, _Alloc>& _Left,
		hash_map<_Kty, _Ty, _Tr, _Alloc>& _Right)
	{	// swap _Left and _Right hash_maps
	_Left.swap(_Right);
	}

 #if _HAS_STLPORT_EMULATION
		// TEMPLATE CLASS hash_map, PARTIAL SPECIALIZATION (for STLport)
template<class _Kty,
	class _Ty,
	class _Keyeq>
	class hash_map<_Kty, _Ty, hash<_Kty>, _Keyeq>
		: public _Hash<_Hmap_traits<_Kty, _Ty,
			_Hash_compare<_Kty, hash<_Kty>, _Keyeq>, allocator<_Kty>, false> >
	{	// hash table of {key, mapped} values, unique keys
public:
	typedef hash_map<_Kty, _Ty, _Keyeq> _Myt;
	typedef _Hash_compare<_Kty, hash<_Kty>, _Keyeq> _Mytraits;
	typedef _Hash<_Hmap_traits<_Kty, _Ty,
		_Mytraits, allocator<_Kty>, false> > _Mybase;
	typedef hash<_Kty> hasher;
	typedef _Kty key_type;
	typedef _Ty mapped_type;
	typedef _Ty referent_type;
	typedef _Keyeq key_equal;
	typedef _Mytraits key_compare;

	typedef typename _Mybase::value_compare value_compare;
	typedef typename _Mybase::allocator_type allocator_type;
	typedef typename _Mybase::size_type size_type;
	typedef typename _Mybase::difference_type difference_type;
	typedef typename _Mybase::pointer pointer;
	typedef typename _Mybase::const_pointer const_pointer;
	typedef typename _Mybase::reference reference;
	typedef typename _Mybase::const_reference const_reference;
	typedef typename _Mybase::iterator iterator;
	typedef typename _Mybase::const_iterator const_iterator;
	typedef typename _Mybase::reverse_iterator reverse_iterator;
	typedef typename _Mybase::const_reverse_iterator
		const_reverse_iterator;
	typedef typename _Mybase::value_type value_type;

	hash_map()
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults
		}

	explicit hash_map(size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults, ignore initial size
		}

	hash_map(size_type, const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct empty map from hasher
		}

	hash_map(size_type, const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct empty map from hasher and equality comparator
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last,
			size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, ignore initial size
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last,
			size_type, const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct map from sequence, comparator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last,
			size_type, const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct map from sequence, comparator, and allocator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	hasher hash_funct() const
		{	// return hasher object
		return (this->comp._Hashobj);
		}

	key_equal key_eq() const
		{	// return equality comparator object
		return (this->comp._Keyeqobj);
		}

	void resize(size_type)
		{	// accept but ignore resize hint
		}

	mapped_type& operator[](const key_type& _Keyval)
		{	// find element matching _Keyval or insert with default mapped
		iterator _Where = this->lower_bound(_Keyval);
		if (_Where == this->end())
			_Where = this->insert(value_type(_Keyval, mapped_type())).first;
		return ((*_Where).second);
		}
	};
_STD_END

 #ifndef _NAMESPACE_STLPORT
  #define _NAMESPACE_STLPORT	stlport
 #endif /* _NAMESPACE_STLPORT */

namespace _NAMESPACE_STLPORT {

		// TEMPLATE CLASS hash_map, REPLACEMENT (for STLport)
template<class _Kty,
	class _Ty,
	class _Hasher = _STD hash<_Kty>,
	class _Keyeq = _STD equal_to<_Kty>,
	class _Alloc = _STD allocator<_STD pair<const _Kty, _Ty> > >
	class hash_map
		: public _STD _Hash<_STD _Hmap_traits<_Kty, _Ty,
			 _STD _Hash_compare<_Kty, _Hasher, _Keyeq>, _Alloc, false> >
	{	// hash table of {key, mapped} values, unique keys
public:
	typedef _STD _Hash_compare<_Kty, _Hasher, _Keyeq> _Mytraits;
	typedef _STD _Hash<_STD _Hmap_traits<_Kty, _Ty,
		_Mytraits, _Alloc, false> > _Mybase;
	typedef _Hasher hasher;
	typedef _Kty key_type;
	typedef _Ty mapped_type;
	typedef _Ty referent_type;
	typedef _Keyeq key_equal;
	typedef _Mytraits key_compare;

	typedef typename _Mybase::value_compare value_compare;
	typedef typename _Mybase::allocator_type allocator_type;
	typedef typename _Mybase::size_type size_type;
	typedef typename _Mybase::difference_type difference_type;
	typedef typename _Mybase::pointer pointer;
	typedef typename _Mybase::const_pointer const_pointer;
	typedef typename _Mybase::reference reference;
	typedef typename _Mybase::const_reference const_reference;
	typedef typename _Mybase::iterator iterator;
	typedef typename _Mybase::const_iterator const_iterator;
	typedef typename _Mybase::reverse_iterator reverse_iterator;
	typedef typename _Mybase::const_reverse_iterator
		const_reverse_iterator;
	typedef typename _Mybase::value_type value_type;

	hash_map()
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults
		}

	explicit hash_map(size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults, ignore initial size
		}

	hash_map(size_type, const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct empty map from hasher
		}

	hash_map(size_type, const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct empty map from hasher and equality comparator
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last, size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, ignore initial size
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last, size_type,
			const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct map from sequence, comparator
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_map(_Iter _First, _Iter _Last, size_type,
			const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct map from sequence, comparator, and allocator
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	hasher hash_funct() const
		{	// return hasher object
		return (this->comp._Hashobj);
		}

	key_equal key_eq() const
		{	// return equality comparator object
		return (this->comp._Keyeqobj);
		}

	void resize(size_type)
		{	// accept but ignore resize hint
		}

	mapped_type& operator[](const key_type& _Keyval)
		{	// find element matching _Keyval or insert with default mapped
		iterator _Where = this->lower_bound(_Keyval);
		if (_Where == this->end())
			_Where = this->insert(value_type(_Keyval, mapped_type())).first;
		return ((*_Where).second);
		}
	};
}	// namespace _NAMESPACE_STLPORT
_STD_BEGIN
 #endif /* _HAS_STLPORT_EMULATION */

		// TEMPLATE CLASS hash_multimap
template<class _Kty,
	class _Ty,
	class _Tr = hash_compare<_Kty, less<_Kty> >,
	class _Alloc = allocator<pair<const _Kty, _Ty> > >
	class hash_multimap
		: public _Hash<_Hmap_traits<_Kty, _Ty, _Tr, _Alloc, true> >
	{	// hash table of {key, mapped} values, non-unique keys
public:
	typedef hash_multimap<_Kty, _Ty, _Tr, _Alloc> _Myt;
	typedef _Hash<_Hmap_traits<_Kty, _Ty, _Tr, _Alloc, true> > _Mybase;
	typedef _Kty key_type;
	typedef _Ty mapped_type;
	typedef _Ty referent_type;	// old name, magically gone
	typedef _Tr key_compare;
	typedef typename _Mybase::value_compare value_compare;
	typedef typename _Mybase::allocator_type allocator_type;
	typedef typename _Mybase::size_type size_type;
	typedef typename _Mybase::difference_type difference_type;
	typedef typename _Mybase::pointer pointer;
	typedef typename _Mybase::const_pointer const_pointer;
	typedef typename _Mybase::reference reference;
	typedef typename _Mybase::const_reference const_reference;
	typedef typename _Mybase::iterator iterator;
	typedef typename _Mybase::const_iterator const_iterator;
	typedef typename _Mybase::reverse_iterator reverse_iterator;
	typedef typename _Mybase::const_reverse_iterator
		const_reverse_iterator;
	typedef typename _Mybase::value_type value_type;

	hash_multimap()
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults
		}

	explicit hash_multimap(const key_compare& _Traits)
		: _Mybase(_Traits, allocator_type())
		{	// construct empty map from comparator
		}

	hash_multimap(const key_compare& _Traits,
		const allocator_type& _Al)
		: _Mybase(_Traits, _Al)
		{	// construct empty map from comparator and allocator
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last,
			const key_compare& _Traits)
		: _Mybase(_Traits, allocator_type())
		{	// construct map from sequence, comparator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last,
			const key_compare& _Traits,
			const allocator_type& _Al)
		: _Mybase(_Traits, _Al)
		{	// construct map from sequence, comparator, and allocator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	iterator insert(const value_type& _Val)
		{	// insert a {key, mapped} value
		return (_Mybase::insert(_Val).first);
		}

	iterator insert(iterator _Where, const value_type& _Val)
		{	// insert a {key, mapped} value, with hint
		return (_Mybase::insert(_Where, _Val));
		}

	template<class _Iter>
		void insert(_Iter _First, _Iter _Last)
		{	// insert [_First, _Last), arbitrary iterators

 #if _HAS_ITERATOR_DEBUGGING
		_DEBUG_RANGE(_First, _Last);
		if (_Debug_get_cont(_First) == this)
			_DEBUG_ERROR("hash_multimap insertion overlaps range");
 #endif /* _HAS_ITERATOR_DEBUGGING */

		for (; _First != _Last; ++_First)
			insert(*_First);
		}
	};

template<class _Kty,
	class _Ty,
	class _Tr,
	class _Alloc> inline
	void swap(hash_multimap<_Kty, _Ty, _Tr, _Alloc>& _Left,
		hash_multimap<_Kty, _Ty, _Tr, _Alloc>& _Right)
	{	// swap _Left and _Right hash_multimaps
	_Left.swap(_Right);
	}

 #if _HAS_STLPORT_EMULATION
		// TEMPLATE CLASS hash_multimap, PARTIAL SPECIALIZATION (for STLport)
template<class _Kty,
	class _Ty,
	class _Keyeq>
	class hash_multimap<_Kty, _Ty, hash<_Kty>, _Keyeq>
		: public _Hash<_Hmap_traits<_Kty, _Ty,
			_Hash_compare<_Kty, hash<_Kty>, _Keyeq>, allocator<_Kty>, true> >
	{	// hash table of {key, mapped} values, non-unique keys
public:
	typedef hash_multimap<_Kty, _Ty, _Keyeq> _Myt;
	typedef _Hash_compare<_Kty, hash<_Kty>, _Keyeq> _Mytraits;
	typedef _Hash<_Hmap_traits<_Kty, _Ty,
		_Mytraits, allocator<_Kty>, true> > _Mybase;
	typedef hash<_Kty> hasher;
	typedef _Kty key_type;
	typedef _Ty mapped_type;
	typedef _Ty referent_type;	// old name, magically gone
	typedef _Keyeq key_equal;
	typedef _Mytraits key_compare;

	typedef typename _Mybase::value_compare value_compare;
	typedef typename _Mybase::allocator_type allocator_type;
	typedef typename _Mybase::size_type size_type;
	typedef typename _Mybase::difference_type difference_type;
	typedef typename _Mybase::pointer pointer;
	typedef typename _Mybase::const_pointer const_pointer;
	typedef typename _Mybase::reference reference;
	typedef typename _Mybase::const_reference const_reference;
	typedef typename _Mybase::iterator iterator;
	typedef typename _Mybase::const_iterator const_iterator;
	typedef typename _Mybase::reverse_iterator reverse_iterator;
	typedef typename _Mybase::const_reverse_iterator
		const_reverse_iterator;
	typedef typename _Mybase::value_type value_type;

	hash_multimap()
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults
		}

	explicit hash_multimap(size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults, ignore initial size
		}

	hash_multimap(size_type, const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct empty map from hasher
		}

	hash_multimap(size_type, const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct empty map from hasher and equality comparator
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last,
			size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults, ignore initial size
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last,
			size_type, const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct map from sequence, comparator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last,
			size_type, const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct map from sequence, comparator, and allocator
		_DEBUG_RANGE(_First, _Last);
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	hasher hash_funct() const
		{	// return hasher object
		return (this->comp._Hashobj);
		}

	key_equal key_eq() const
		{	// return equality comparator object
		return (this->comp._Keyeqobj);
		}

	void resize(size_type)
		{	// accept but ignore resize hint
		}

	iterator insert(const value_type& _Val)
		{	// insert a {key, mapped} value
		return (_Mybase::insert(_Val).first);
		}

	iterator insert(iterator _Where, const value_type& _Val)
		{	// insert a {key, mapped} value, with hint
		return (_Mybase::insert(_Where, _Val));
		}

	template<class _Iter>
		void insert(_Iter _First, _Iter _Last)
		{	// insert [_First, _Last), arbitrary iterators

 #if _HAS_ITERATOR_DEBUGGING
		_DEBUG_RANGE(_First, _Last);
		if (_Debug_get_cont(_First) == this)
			_DEBUG_ERROR("hash_multimap insertion overlaps range");
 #endif /* _HAS_ITERATOR_DEBUGGING */

		for (; _First != _Last; ++_First)
			insert(*_First);
		}
	};
_STD_END
namespace _NAMESPACE_STLPORT {

		// TEMPLATE CLASS hash_multimap, REPLACEMENT (for STLport)
template<class _Kty,
	class _Ty,
	class _Hasher = _STD hash<_Kty>,
	class _Keyeq = _STD equal_to<_Kty>,
	class _Alloc = _STD allocator<_STD pair<const _Kty, _Ty> > >
	class hash_multimap
		: public _STD _Hash<_STD _Hmap_traits<_Kty, _Ty,
			_STD _Hash_compare<_Kty, _Hasher, _Keyeq>, _Alloc, true> >
	{	// hash table of {key, mapped} values, non-unique keys
public:
	typedef _STD _Hash_compare<_Kty, _Hasher, _Keyeq> _Mytraits;
	typedef _STD _Hash<_STD _Hmap_traits<_Kty, _Ty,
		_Mytraits, _Alloc, true> > _Mybase;
	typedef _Hasher hasher;
	typedef _Kty key_type;
	typedef _Ty mapped_type;
	typedef _Ty referent_type;	// old name, magically gone
	typedef _Keyeq key_equal;
	typedef _Mytraits key_compare;

	typedef typename _Mybase::value_compare value_compare;
	typedef typename _Mybase::allocator_type allocator_type;
	typedef typename _Mybase::size_type size_type;
	typedef typename _Mybase::difference_type difference_type;
	typedef typename _Mybase::pointer pointer;
	typedef typename _Mybase::const_pointer const_pointer;
	typedef typename _Mybase::reference reference;
	typedef typename _Mybase::const_reference const_reference;
	typedef typename _Mybase::iterator iterator;
	typedef typename _Mybase::const_iterator const_iterator;
	typedef typename _Mybase::reverse_iterator reverse_iterator;
	typedef typename _Mybase::const_reverse_iterator
		const_reverse_iterator;
	typedef typename _Mybase::value_type value_type;

	hash_multimap()
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults
		}

	explicit hash_multimap(size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct empty map from defaults, ignore initial size
		}

	hash_multimap(size_type, const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct empty map from hasher
		}

	hash_multimap(size_type, const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct empty map from hasher and equality comparator
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last, size_type)
		: _Mybase(key_compare(), allocator_type())
		{	// construct map from sequence, defaults, ignore initial size
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last, size_type,
			const hasher& _Hasharg)
		: _Mybase(key_compare(_Hasharg), allocator_type())
		{	// construct map from sequence, comparator
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	template<class _Iter>
		hash_multimap(_Iter _First, _Iter _Last, size_type,
			const hasher& _Hasharg, const _Keyeq& _Keyeqarg)
		: _Mybase(key_compare(_Hasharg, _Keyeqarg), allocator_type())
		{	// construct map from sequence, comparator, and allocator
		for (; _First != _Last; ++_First)
			this->insert(*_First);
		}

	hasher hash_funct() const
		{	// return hasher object
		return (this->comp._Hashobj);
		}

	key_equal key_eq() const
		{	// return equality comparator object
		return (this->comp._Keyeqobj);
		}

	void resize(size_type)
		{	// accept but ignore resize hint
		}

	iterator insert(const value_type& _Val)
		{	// insert a {key, mapped} value
		return (_Mybase::insert(_Val).first);
		}

	iterator insert(iterator _Where, const value_type& _Val)
		{	// insert a {key, mapped} value, with hint
		return (_Mybase::insert(_Where, _Val));
		}

	template<class _Iter>
		void insert(_Iter _First, _Iter _Last)
		{	// insert [_First, _Last), arbitrary iterators
		for (; _First != _Last; ++_First)
			insert(*_First);
		}
	};
}	// namespace _NAMESPACE_STLPORT
_STD_BEGIN
 #endif /* _HAS_STLPORT_EMULATION */

_STD_END
#pragma option pop
#endif /* _HASH_MAP_ */

/*
 * Copyright (c) 1992-2003 by P.J. Plauger.  ALL RIGHTS RESERVED.
 * Consult your license regarding permissions and restrictions.
V4.02:1422 */
