media/libdrm/mobile2/src/util/ustl-1.0/umultimap.h - platform/frameworks/base - Git at Google

 // This file is part of the ustl library, an STL implementation.
 //
 // Copyright (C) 2005 by Mike Sharov <msharov@users.sourceforge.net>
 // This file is free software, distributed under the MIT License.
 //
 // umultimap.h
 //

 #ifndef UMULTIMAP_H_45743F516E02A87A3FCEA5024052A6F5
 #define UMULTIMAP_H_45743F516E02A87A3FCEA5024052A6F5

 #include "uassert.h"
 #include "ufunction.h"
 #include "uvector.h"

 namespace ustl {

 /// \class multimap umultimap.h ustl.h
 /// \ingroup AssociativeContainers
 ///
 /// \brief A sorted associative container that may container multiple entries for each key.
 ///
 template <typename K, typename V>
 class multimap : public vector<pair<K,V> > {
 public:
     typedef K						key_type;
     typedef V						data_type;
     typedef const K&					const_key_ref;
     typedef const V&					const_data_ref;
     typedef const multimap<K,V>&			rcself_t;
     typedef vector<pair<K,V> >				base_class;
     typedef typename base_class::value_type	value_type;
     typedef typename base_class::size_type	size_type;
     typedef typename base_class::pointer	pointer;
     typedef typename base_class::const_pointer	const_pointer;
     typedef typename base_class::reference	reference;
     typedef typename base_class::const_reference	const_reference;
     typedef typename base_class::const_iterator		const_iterator;
     typedef typename base_class::iterator		iterator;
     typedef typename base_class::reverse_iterator	reverse_iterator;
     typedef typename base_class::const_reverse_iterator	const_reverse_iterator;
     typedef pair<const_iterator,const_iterator>		const_range_t;
     typedef pair<iterator,iterator>			range_t;
 public:
     inline			multimap (void)		: vector<pair<K,V> > () {}
     explicit inline		multimap (size_type n)	: vector<pair<K,V> > (n) {}
     inline			multimap (rcself_t v)	: vector<pair<K,V> > (v) {}
     inline			multimap (const_iterator i1, const_iterator i2)	: vector<pair<K,V> > () { insert (i1, i2); }
     inline rcself_t		operator= (rcself_t v)	{ base_class::operator= (v); return (*this); }
     inline size_type		size (void) const	{ return (base_class::size()); }
     inline iterator		begin (void)		{ return (base_class::begin()); }
     inline const_iterator	begin (void) const	{ return (base_class::begin()); }
     inline iterator		end (void)		{ return (base_class::end()); }
     inline const_iterator	end (void) const	{ return (base_class::end()); }
     inline void			assign (const_iterator i1, const_iterator i2) { clear(); insert (i1, i2); }
     inline size_type		count (const_key_ref k) const		{ return (upper_bound(k) - lower_bound(k)); }
     inline void			push_back (const_reference v)		{ insert (v); }
     inline const_range_t	equal_range (const_key_ref k) const	{ return (make_pair (lower_bound(k), upper_bound(k))); }
     inline range_t		equal_range (const_key_ref k)		{ return (make_pair (const_cast<iterator>(lower_bound(k)), const_cast<iterator>(upper_bound(k)))); }
     const_iterator		lower_bound (const_key_ref k) const;
     const_iterator		upper_bound (const_key_ref k) const;
     inline iterator		insert (const_reference v);
     void			insert (const_iterator i1, const_iterator i2);
     inline void			erase (const_key_ref k)			{ erase (const_cast<iterator>(lower_bound(k)), const_cast<iterator>(upper_bound(k))); }
     inline iterator		erase (iterator ep)			{ return (base_class::erase (ep)); }
     inline iterator		erase (iterator ep1, iterator ep2)	{ return (base_class::erase (ep1, ep2)); }
     inline void			clear (void)				{ base_class::clear(); }
 };

 /// Returns an iterator to the first element with key value \p k.
 template <typename K, typename V>
 typename multimap<K,V>::const_iterator multimap<K,V>::lower_bound (const_key_ref k) const
 {
     const_iterator first (begin()), last (end());
     while (first != last) {
 	const_iterator mid = advance (first, distance (first,last) / 2);
 	if (mid->first < k)
 	    first = advance (mid, 1);
 	else
 	    last = mid;
     }
     return (first);
 }

 /// Returns an iterator to the first element with key value \p k.
 template <typename K, typename V>
 typename multimap<K,V>::const_iterator multimap<K,V>::upper_bound (const_key_ref k) const
 {
     const_iterator first (begin()), last (end());
     while (first != last) {
 	const_iterator mid = advance (first, distance (first,last) / 2);
 	if (k < mid->first)
 	    last = mid;
 	else
 	    first = advance (mid, 1);
     }
     return (last);
 }

 /// Inserts the pair into the container.
 template <typename K, typename V>
 inline typename multimap<K,V>::iterator multimap<K,V>::insert (const_reference v)
 {
     iterator ip = const_cast<iterator> (upper_bound (v.first));
     return (base_class::insert (ip, v));
 }

 /// Inserts elements from range [i1,i2) into the container.
 template <typename K, typename V>
 void multimap<K,V>::insert (const_iterator i1, const_iterator i2)
 {
     assert (i1 <= i2);
     reserve (size() + distance (i1, i2));
     for (; i1 != i2; ++i1)
 	insert (*i1);
 }

 } // namespace ustl

 #endif
	// This file is part of the ustl library, an STL implementation.
	//
	// Copyright (C) 2005 by Mike Sharov <msharov@users.sourceforge.net>
	// This file is free software, distributed under the MIT License.
	//
	// umultimap.h
	//

	#ifndef UMULTIMAP_H_45743F516E02A87A3FCEA5024052A6F5
	#define UMULTIMAP_H_45743F516E02A87A3FCEA5024052A6F5

	#include "uassert.h"
	#include "ufunction.h"
	#include "uvector.h"

	namespace ustl {

	/// \class multimap umultimap.h ustl.h
	/// \ingroup AssociativeContainers
	///
	/// \brief A sorted associative container that may container multiple entries for each key.
	///
	template <typename K, typename V>
	class multimap : public vector<pair<K,V> > {
	public:
	typedef K key_type;
	typedef V data_type;
	typedef const K& const_key_ref;
	typedef const V& const_data_ref;
	typedef const multimap<K,V>& rcself_t;
	typedef vector<pair<K,V> > base_class;
	typedef typename base_class::value_type value_type;
	typedef typename base_class::size_type size_type;
	typedef typename base_class::pointer pointer;
	typedef typename base_class::const_pointer const_pointer;
	typedef typename base_class::reference reference;
	typedef typename base_class::const_reference const_reference;
	typedef typename base_class::const_iterator const_iterator;
	typedef typename base_class::iterator iterator;
	typedef typename base_class::reverse_iterator reverse_iterator;
	typedef typename base_class::const_reverse_iterator const_reverse_iterator;
	typedef pair<const_iterator,const_iterator> const_range_t;
	typedef pair<iterator,iterator> range_t;
	public:
	inline multimap (void) : vector<pair<K,V> > () {}
	explicit inline multimap (size_type n) : vector<pair<K,V> > (n) {}
	inline multimap (rcself_t v) : vector<pair<K,V> > (v) {}
	inline multimap (const_iterator i1, const_iterator i2) : vector<pair<K,V> > () { insert (i1, i2); }
	inline rcself_t operator= (rcself_t v) { base_class::operator= (v); return (*this); }
	inline size_type size (void) const { return (base_class::size()); }
	inline iterator begin (void) { return (base_class::begin()); }
	inline const_iterator begin (void) const { return (base_class::begin()); }
	inline iterator end (void) { return (base_class::end()); }
	inline const_iterator end (void) const { return (base_class::end()); }
	inline void assign (const_iterator i1, const_iterator i2) { clear(); insert (i1, i2); }
	inline size_type count (const_key_ref k) const { return (upper_bound(k) - lower_bound(k)); }
	inline void push_back (const_reference v) { insert (v); }
	inline const_range_t equal_range (const_key_ref k) const { return (make_pair (lower_bound(k), upper_bound(k))); }
	inline range_t equal_range (const_key_ref k) { return (make_pair (const_cast<iterator>(lower_bound(k)), const_cast<iterator>(upper_bound(k)))); }
	const_iterator lower_bound (const_key_ref k) const;
	const_iterator upper_bound (const_key_ref k) const;
	inline iterator insert (const_reference v);
	void insert (const_iterator i1, const_iterator i2);
	inline void erase (const_key_ref k) { erase (const_cast<iterator>(lower_bound(k)), const_cast<iterator>(upper_bound(k))); }
	inline iterator erase (iterator ep) { return (base_class::erase (ep)); }
	inline iterator erase (iterator ep1, iterator ep2) { return (base_class::erase (ep1, ep2)); }
	inline void clear (void) { base_class::clear(); }
	};

	/// Returns an iterator to the first element with key value \p k.
	template <typename K, typename V>
	typename multimap<K,V>::const_iterator multimap<K,V>::lower_bound (const_key_ref k) const
	{
	const_iterator first (begin()), last (end());
	while (first != last) {
	const_iterator mid = advance (first, distance (first,last) / 2);
	if (mid->first < k)
	first = advance (mid, 1);
	else
	last = mid;
	}
	return (first);
	}

	/// Returns an iterator to the first element with key value \p k.
	template <typename K, typename V>
	typename multimap<K,V>::const_iterator multimap<K,V>::upper_bound (const_key_ref k) const
	{
	const_iterator first (begin()), last (end());
	while (first != last) {
	const_iterator mid = advance (first, distance (first,last) / 2);
	if (k < mid->first)
	last = mid;
	else
	first = advance (mid, 1);
	}
	return (last);
	}

	/// Inserts the pair into the container.
	template <typename K, typename V>
	inline typename multimap<K,V>::iterator multimap<K,V>::insert (const_reference v)
	{
	iterator ip = const_cast<iterator> (upper_bound (v.first));
	return (base_class::insert (ip, v));
	}

	/// Inserts elements from range [i1,i2) into the container.
	template <typename K, typename V>
	void multimap<K,V>::insert (const_iterator i1, const_iterator i2)
	{
	assert (i1 <= i2);
	reserve (size() + distance (i1, i2));
	for (; i1 != i2; ++i1)
	insert (*i1);
	}

	} // namespace ustl

	#endif