Linux ip-172-26-2-223 5.4.0-1018-aws #18-Ubuntu SMP Wed Jun 24 01:15:00 UTC 2020 x86_64
Apache
: 172.26.2.223 | : 3.135.201.190
Cant Read [ /etc/named.conf ]
8.1.13
www
www.github.com/MadExploits
Terminal
AUTO ROOT
Adminer
Backdoor Destroyer
Linux Exploit
Lock Shell
Lock File
Create User
CREATE RDP
PHP Mailer
BACKCONNECT
UNLOCK SHELL
HASH IDENTIFIER
CPANEL RESET
CREATE WP USER
BLACK DEFEND!
README
+ Create Folder
+ Create File
/
usr /
include /
c++ /
9 /
backward /
[ HOME SHELL ]
Name
Size
Permission
Action
auto_ptr.h
10.55
KB
-rw-r--r--
backward_warning.h
2.43
KB
-rw-r--r--
binders.h
7
KB
-rw-r--r--
hash_fun.h
4.15
KB
-rw-r--r--
hash_map
17.4
KB
-rw-r--r--
hash_set
16.84
KB
-rw-r--r--
hashtable.h
32.95
KB
-rw-r--r--
strstream
7.28
KB
-rw-r--r--
Delete
Unzip
Zip
${this.title}
Close
Code Editor : hashtable.h
// Hashtable implementation used by containers -*- C++ -*- // Copyright (C) 2001-2019 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License and // a copy of the GCC Runtime Library Exception along with this program; // see the files COPYING3 and COPYING.RUNTIME respectively. If not, see // <http://www.gnu.org/licenses/>. /* * Copyright (c) 1996,1997 * Silicon Graphics Computer Systems, Inc. * * Permission to use, copy, modify, distribute and sell this software * and its documentation for any purpose is hereby granted without fee, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. Silicon Graphics makes no * representations about the suitability of this software for any * purpose. It is provided "as is" without express or implied warranty. * * * Copyright (c) 1994 * Hewlett-Packard Company * * Permission to use, copy, modify, distribute and sell this software * and its documentation for any purpose is hereby granted without fee, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. Hewlett-Packard Company makes no * representations about the suitability of this software for any * purpose. It is provided "as is" without express or implied warranty. * */ /** @file backward/hashtable.h * This file is a GNU extension to the Standard C++ Library (possibly * containing extensions from the HP/SGI STL subset). */ #ifndef _BACKWARD_HASHTABLE_H #define _BACKWARD_HASHTABLE_H 1 // Hashtable class, used to implement the hashed associative containers // hash_set, hash_map, hash_multiset, and hash_multimap. #include <vector> #include <iterator> #include <algorithm> #include <bits/stl_function.h> #include <backward/hash_fun.h> namespace __gnu_cxx _GLIBCXX_VISIBILITY(default) { _GLIBCXX_BEGIN_NAMESPACE_VERSION using std::size_t; using std::ptrdiff_t; using std::forward_iterator_tag; using std::input_iterator_tag; using std::_Construct; using std::_Destroy; using std::distance; using std::vector; using std::pair; using std::__iterator_category; template<class _Val> struct _Hashtable_node { _Hashtable_node* _M_next; _Val _M_val; }; template<class _Val, class _Key, class _HashFcn, class _ExtractKey, class _EqualKey, class _Alloc = std::allocator<_Val> > class hashtable; template<class _Val, class _Key, class _HashFcn, class _ExtractKey, class _EqualKey, class _Alloc> struct _Hashtable_iterator; template<class _Val, class _Key, class _HashFcn, class _ExtractKey, class _EqualKey, class _Alloc> struct _Hashtable_const_iterator; template<class _Val, class _Key, class _HashFcn, class _ExtractKey, class _EqualKey, class _Alloc> struct _Hashtable_iterator { typedef hashtable<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> _Hashtable; typedef _Hashtable_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> iterator; typedef _Hashtable_const_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> const_iterator; typedef _Hashtable_node<_Val> _Node; typedef forward_iterator_tag iterator_category; typedef _Val value_type; typedef ptrdiff_t difference_type; typedef size_t size_type; typedef _Val& reference; typedef _Val* pointer; _Node* _M_cur; _Hashtable* _M_ht; _Hashtable_iterator(_Node* __n, _Hashtable* __tab) : _M_cur(__n), _M_ht(__tab) { } _Hashtable_iterator() { } reference operator*() const { return _M_cur->_M_val; } pointer operator->() const { return &(operator*()); } iterator& operator++(); iterator operator++(int); bool operator==(const iterator& __it) const { return _M_cur == __it._M_cur; } bool operator!=(const iterator& __it) const { return _M_cur != __it._M_cur; } }; template<class _Val, class _Key, class _HashFcn, class _ExtractKey, class _EqualKey, class _Alloc> struct _Hashtable_const_iterator { typedef hashtable<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> _Hashtable; typedef _Hashtable_iterator<_Val,_Key,_HashFcn, _ExtractKey,_EqualKey,_Alloc> iterator; typedef _Hashtable_const_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> const_iterator; typedef _Hashtable_node<_Val> _Node; typedef forward_iterator_tag iterator_category; typedef _Val value_type; typedef ptrdiff_t difference_type; typedef size_t size_type; typedef const _Val& reference; typedef const _Val* pointer; const _Node* _M_cur; const _Hashtable* _M_ht; _Hashtable_const_iterator(const _Node* __n, const _Hashtable* __tab) : _M_cur(__n), _M_ht(__tab) { } _Hashtable_const_iterator() { } _Hashtable_const_iterator(const iterator& __it) : _M_cur(__it._M_cur), _M_ht(__it._M_ht) { } reference operator*() const { return _M_cur->_M_val; } pointer operator->() const { return &(operator*()); } const_iterator& operator++(); const_iterator operator++(int); bool operator==(const const_iterator& __it) const { return _M_cur == __it._M_cur; } bool operator!=(const const_iterator& __it) const { return _M_cur != __it._M_cur; } }; // Note: assumes long is at least 32 bits. enum { _S_num_primes = 29 }; template<typename _PrimeType> struct _Hashtable_prime_list { static const _PrimeType __stl_prime_list[_S_num_primes]; static const _PrimeType* _S_get_prime_list(); }; template<typename _PrimeType> const _PrimeType _Hashtable_prime_list<_PrimeType>::__stl_prime_list[_S_num_primes] = { 5ul, 53ul, 97ul, 193ul, 389ul, 769ul, 1543ul, 3079ul, 6151ul, 12289ul, 24593ul, 49157ul, 98317ul, 196613ul, 393241ul, 786433ul, 1572869ul, 3145739ul, 6291469ul, 12582917ul, 25165843ul, 50331653ul, 100663319ul, 201326611ul, 402653189ul, 805306457ul, 1610612741ul, 3221225473ul, 4294967291ul }; template<class _PrimeType> inline const _PrimeType* _Hashtable_prime_list<_PrimeType>::_S_get_prime_list() { return __stl_prime_list; } inline unsigned long __stl_next_prime(unsigned long __n) { const unsigned long* __first = _Hashtable_prime_list<unsigned long>::_S_get_prime_list(); const unsigned long* __last = __first + (int)_S_num_primes; const unsigned long* pos = std::lower_bound(__first, __last, __n); return pos == __last ? *(__last - 1) : *pos; } // Forward declaration of operator==. template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> class hashtable; template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> bool operator==(const hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>& __ht1, const hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>& __ht2); // Hashtables handle allocators a bit differently than other // containers do. If we're using standard-conforming allocators, then // a hashtable unconditionally has a member variable to hold its // allocator, even if it so happens that all instances of the // allocator type are identical. This is because, for hashtables, // this extra storage is negligible. Additionally, a base class // wouldn't serve any other purposes; it wouldn't, for example, // simplify the exception-handling code. template<class _Val, class _Key, class _HashFcn, class _ExtractKey, class _EqualKey, class _Alloc> class hashtable { public: typedef _Key key_type; typedef _Val value_type; typedef _HashFcn hasher; typedef _EqualKey key_equal; typedef size_t size_type; typedef ptrdiff_t difference_type; typedef value_type* pointer; typedef const value_type* const_pointer; typedef value_type& reference; typedef const value_type& const_reference; hasher hash_funct() const { return _M_hash; } key_equal key_eq() const { return _M_equals; } private: typedef _Hashtable_node<_Val> _Node; public: typedef typename _Alloc::template rebind<value_type>::other allocator_type; allocator_type get_allocator() const { return _M_node_allocator; } private: typedef typename _Alloc::template rebind<_Node>::other _Node_Alloc; typedef typename _Alloc::template rebind<_Node*>::other _Nodeptr_Alloc; typedef vector<_Node*, _Nodeptr_Alloc> _Vector_type; _Node_Alloc _M_node_allocator; _Node* _M_get_node() { return _M_node_allocator.allocate(1); } void _M_put_node(_Node* __p) { _M_node_allocator.deallocate(__p, 1); } private: hasher _M_hash; key_equal _M_equals; _ExtractKey _M_get_key; _Vector_type _M_buckets; size_type _M_num_elements; public: typedef _Hashtable_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> iterator; typedef _Hashtable_const_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc> const_iterator; friend struct _Hashtable_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc>; friend struct _Hashtable_const_iterator<_Val, _Key, _HashFcn, _ExtractKey, _EqualKey, _Alloc>; public: hashtable(size_type __n, const _HashFcn& __hf, const _EqualKey& __eql, const _ExtractKey& __ext, const allocator_type& __a = allocator_type()) : _M_node_allocator(__a), _M_hash(__hf), _M_equals(__eql), _M_get_key(__ext), _M_buckets(__a), _M_num_elements(0) { _M_initialize_buckets(__n); } hashtable(size_type __n, const _HashFcn& __hf, const _EqualKey& __eql, const allocator_type& __a = allocator_type()) : _M_node_allocator(__a), _M_hash(__hf), _M_equals(__eql), _M_get_key(_ExtractKey()), _M_buckets(__a), _M_num_elements(0) { _M_initialize_buckets(__n); } hashtable(const hashtable& __ht) : _M_node_allocator(__ht.get_allocator()), _M_hash(__ht._M_hash), _M_equals(__ht._M_equals), _M_get_key(__ht._M_get_key), _M_buckets(__ht.get_allocator()), _M_num_elements(0) { _M_copy_from(__ht); } hashtable& operator= (const hashtable& __ht) { if (&__ht != this) { clear(); _M_hash = __ht._M_hash; _M_equals = __ht._M_equals; _M_get_key = __ht._M_get_key; _M_copy_from(__ht); } return *this; } ~hashtable() { clear(); } size_type size() const { return _M_num_elements; } size_type max_size() const { return size_type(-1); } _GLIBCXX_NODISCARD bool empty() const { return size() == 0; } void swap(hashtable& __ht) { std::swap(_M_hash, __ht._M_hash); std::swap(_M_equals, __ht._M_equals); std::swap(_M_get_key, __ht._M_get_key); _M_buckets.swap(__ht._M_buckets); std::swap(_M_num_elements, __ht._M_num_elements); } iterator begin() { for (size_type __n = 0; __n < _M_buckets.size(); ++__n) if (_M_buckets[__n]) return iterator(_M_buckets[__n], this); return end(); } iterator end() { return iterator(0, this); } const_iterator begin() const { for (size_type __n = 0; __n < _M_buckets.size(); ++__n) if (_M_buckets[__n]) return const_iterator(_M_buckets[__n], this); return end(); } const_iterator end() const { return const_iterator(0, this); } template<class _Vl, class _Ky, class _HF, class _Ex, class _Eq, class _Al> friend bool operator==(const hashtable<_Vl, _Ky, _HF, _Ex, _Eq, _Al>&, const hashtable<_Vl, _Ky, _HF, _Ex, _Eq, _Al>&); public: size_type bucket_count() const { return _M_buckets.size(); } size_type max_bucket_count() const { return _Hashtable_prime_list<unsigned long>:: _S_get_prime_list()[(int)_S_num_primes - 1]; } size_type elems_in_bucket(size_type __bucket) const { size_type __result = 0; for (_Node* __n = _M_buckets[__bucket]; __n; __n = __n->_M_next) __result += 1; return __result; } pair<iterator, bool> insert_unique(const value_type& __obj) { resize(_M_num_elements + 1); return insert_unique_noresize(__obj); } iterator insert_equal(const value_type& __obj) { resize(_M_num_elements + 1); return insert_equal_noresize(__obj); } pair<iterator, bool> insert_unique_noresize(const value_type& __obj); iterator insert_equal_noresize(const value_type& __obj); template<class _InputIterator> void insert_unique(_InputIterator __f, _InputIterator __l) { insert_unique(__f, __l, __iterator_category(__f)); } template<class _InputIterator> void insert_equal(_InputIterator __f, _InputIterator __l) { insert_equal(__f, __l, __iterator_category(__f)); } template<class _InputIterator> void insert_unique(_InputIterator __f, _InputIterator __l, input_iterator_tag) { for ( ; __f != __l; ++__f) insert_unique(*__f); } template<class _InputIterator> void insert_equal(_InputIterator __f, _InputIterator __l, input_iterator_tag) { for ( ; __f != __l; ++__f) insert_equal(*__f); } template<class _ForwardIterator> void insert_unique(_ForwardIterator __f, _ForwardIterator __l, forward_iterator_tag) { size_type __n = distance(__f, __l); resize(_M_num_elements + __n); for ( ; __n > 0; --__n, ++__f) insert_unique_noresize(*__f); } template<class _ForwardIterator> void insert_equal(_ForwardIterator __f, _ForwardIterator __l, forward_iterator_tag) { size_type __n = distance(__f, __l); resize(_M_num_elements + __n); for ( ; __n > 0; --__n, ++__f) insert_equal_noresize(*__f); } reference find_or_insert(const value_type& __obj); iterator find(const key_type& __key) { size_type __n = _M_bkt_num_key(__key); _Node* __first; for (__first = _M_buckets[__n]; __first && !_M_equals(_M_get_key(__first->_M_val), __key); __first = __first->_M_next) { } return iterator(__first, this); } const_iterator find(const key_type& __key) const { size_type __n = _M_bkt_num_key(__key); const _Node* __first; for (__first = _M_buckets[__n]; __first && !_M_equals(_M_get_key(__first->_M_val), __key); __first = __first->_M_next) { } return const_iterator(__first, this); } size_type count(const key_type& __key) const { const size_type __n = _M_bkt_num_key(__key); size_type __result = 0; for (const _Node* __cur = _M_buckets[__n]; __cur; __cur = __cur->_M_next) if (_M_equals(_M_get_key(__cur->_M_val), __key)) ++__result; return __result; } pair<iterator, iterator> equal_range(const key_type& __key); pair<const_iterator, const_iterator> equal_range(const key_type& __key) const; size_type erase(const key_type& __key); void erase(const iterator& __it); void erase(iterator __first, iterator __last); void erase(const const_iterator& __it); void erase(const_iterator __first, const_iterator __last); void resize(size_type __num_elements_hint); void clear(); private: size_type _M_next_size(size_type __n) const { return __stl_next_prime(__n); } void _M_initialize_buckets(size_type __n) { const size_type __n_buckets = _M_next_size(__n); _M_buckets.reserve(__n_buckets); _M_buckets.insert(_M_buckets.end(), __n_buckets, (_Node*) 0); _M_num_elements = 0; } size_type _M_bkt_num_key(const key_type& __key) const { return _M_bkt_num_key(__key, _M_buckets.size()); } size_type _M_bkt_num(const value_type& __obj) const { return _M_bkt_num_key(_M_get_key(__obj)); } size_type _M_bkt_num_key(const key_type& __key, size_t __n) const { return _M_hash(__key) % __n; } size_type _M_bkt_num(const value_type& __obj, size_t __n) const { return _M_bkt_num_key(_M_get_key(__obj), __n); } _Node* _M_new_node(const value_type& __obj) { _Node* __n = _M_get_node(); __n->_M_next = 0; __try { this->get_allocator().construct(&__n->_M_val, __obj); return __n; } __catch(...) { _M_put_node(__n); __throw_exception_again; } } void _M_delete_node(_Node* __n) { this->get_allocator().destroy(&__n->_M_val); _M_put_node(__n); } void _M_erase_bucket(const size_type __n, _Node* __first, _Node* __last); void _M_erase_bucket(const size_type __n, _Node* __last); void _M_copy_from(const hashtable& __ht); }; template<class _Val, class _Key, class _HF, class _ExK, class _EqK, class _All> _Hashtable_iterator<_Val, _Key, _HF, _ExK, _EqK, _All>& _Hashtable_iterator<_Val, _Key, _HF, _ExK, _EqK, _All>:: operator++() { const _Node* __old = _M_cur; _M_cur = _M_cur->_M_next; if (!_M_cur) { size_type __bucket = _M_ht->_M_bkt_num(__old->_M_val); while (!_M_cur && ++__bucket < _M_ht->_M_buckets.size()) _M_cur = _M_ht->_M_buckets[__bucket]; } return *this; } template<class _Val, class _Key, class _HF, class _ExK, class _EqK, class _All> inline _Hashtable_iterator<_Val, _Key, _HF, _ExK, _EqK, _All> _Hashtable_iterator<_Val, _Key, _HF, _ExK, _EqK, _All>:: operator++(int) { iterator __tmp = *this; ++*this; return __tmp; } template<class _Val, class _Key, class _HF, class _ExK, class _EqK, class _All> _Hashtable_const_iterator<_Val, _Key, _HF, _ExK, _EqK, _All>& _Hashtable_const_iterator<_Val, _Key, _HF, _ExK, _EqK, _All>:: operator++() { const _Node* __old = _M_cur; _M_cur = _M_cur->_M_next; if (!_M_cur) { size_type __bucket = _M_ht->_M_bkt_num(__old->_M_val); while (!_M_cur && ++__bucket < _M_ht->_M_buckets.size()) _M_cur = _M_ht->_M_buckets[__bucket]; } return *this; } template<class _Val, class _Key, class _HF, class _ExK, class _EqK, class _All> inline _Hashtable_const_iterator<_Val, _Key, _HF, _ExK, _EqK, _All> _Hashtable_const_iterator<_Val, _Key, _HF, _ExK, _EqK, _All>:: operator++(int) { const_iterator __tmp = *this; ++*this; return __tmp; } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> bool operator==(const hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>& __ht1, const hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>& __ht2) { typedef typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::_Node _Node; if (__ht1._M_buckets.size() != __ht2._M_buckets.size()) return false; for (size_t __n = 0; __n < __ht1._M_buckets.size(); ++__n) { _Node* __cur1 = __ht1._M_buckets[__n]; _Node* __cur2 = __ht2._M_buckets[__n]; // Check same length of lists for (; __cur1 && __cur2; __cur1 = __cur1->_M_next, __cur2 = __cur2->_M_next) { } if (__cur1 || __cur2) return false; // Now check one's elements are in the other for (__cur1 = __ht1._M_buckets[__n] ; __cur1; __cur1 = __cur1->_M_next) { bool _found__cur1 = false; for (__cur2 = __ht2._M_buckets[__n]; __cur2; __cur2 = __cur2->_M_next) { if (__cur1->_M_val == __cur2->_M_val) { _found__cur1 = true; break; } } if (!_found__cur1) return false; } } return true; } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> inline bool operator!=(const hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>& __ht1, const hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>& __ht2) { return !(__ht1 == __ht2); } template<class _Val, class _Key, class _HF, class _Extract, class _EqKey, class _All> inline void swap(hashtable<_Val, _Key, _HF, _Extract, _EqKey, _All>& __ht1, hashtable<_Val, _Key, _HF, _Extract, _EqKey, _All>& __ht2) { __ht1.swap(__ht2); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> pair<typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::iterator, bool> hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: insert_unique_noresize(const value_type& __obj) { const size_type __n = _M_bkt_num(__obj); _Node* __first = _M_buckets[__n]; for (_Node* __cur = __first; __cur; __cur = __cur->_M_next) if (_M_equals(_M_get_key(__cur->_M_val), _M_get_key(__obj))) return pair<iterator, bool>(iterator(__cur, this), false); _Node* __tmp = _M_new_node(__obj); __tmp->_M_next = __first; _M_buckets[__n] = __tmp; ++_M_num_elements; return pair<iterator, bool>(iterator(__tmp, this), true); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::iterator hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: insert_equal_noresize(const value_type& __obj) { const size_type __n = _M_bkt_num(__obj); _Node* __first = _M_buckets[__n]; for (_Node* __cur = __first; __cur; __cur = __cur->_M_next) if (_M_equals(_M_get_key(__cur->_M_val), _M_get_key(__obj))) { _Node* __tmp = _M_new_node(__obj); __tmp->_M_next = __cur->_M_next; __cur->_M_next = __tmp; ++_M_num_elements; return iterator(__tmp, this); } _Node* __tmp = _M_new_node(__obj); __tmp->_M_next = __first; _M_buckets[__n] = __tmp; ++_M_num_elements; return iterator(__tmp, this); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::reference hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: find_or_insert(const value_type& __obj) { resize(_M_num_elements + 1); size_type __n = _M_bkt_num(__obj); _Node* __first = _M_buckets[__n]; for (_Node* __cur = __first; __cur; __cur = __cur->_M_next) if (_M_equals(_M_get_key(__cur->_M_val), _M_get_key(__obj))) return __cur->_M_val; _Node* __tmp = _M_new_node(__obj); __tmp->_M_next = __first; _M_buckets[__n] = __tmp; ++_M_num_elements; return __tmp->_M_val; } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> pair<typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::iterator, typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::iterator> hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: equal_range(const key_type& __key) { typedef pair<iterator, iterator> _Pii; const size_type __n = _M_bkt_num_key(__key); for (_Node* __first = _M_buckets[__n]; __first; __first = __first->_M_next) if (_M_equals(_M_get_key(__first->_M_val), __key)) { for (_Node* __cur = __first->_M_next; __cur; __cur = __cur->_M_next) if (!_M_equals(_M_get_key(__cur->_M_val), __key)) return _Pii(iterator(__first, this), iterator(__cur, this)); for (size_type __m = __n + 1; __m < _M_buckets.size(); ++__m) if (_M_buckets[__m]) return _Pii(iterator(__first, this), iterator(_M_buckets[__m], this)); return _Pii(iterator(__first, this), end()); } return _Pii(end(), end()); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> pair<typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::const_iterator, typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::const_iterator> hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: equal_range(const key_type& __key) const { typedef pair<const_iterator, const_iterator> _Pii; const size_type __n = _M_bkt_num_key(__key); for (const _Node* __first = _M_buckets[__n]; __first; __first = __first->_M_next) { if (_M_equals(_M_get_key(__first->_M_val), __key)) { for (const _Node* __cur = __first->_M_next; __cur; __cur = __cur->_M_next) if (!_M_equals(_M_get_key(__cur->_M_val), __key)) return _Pii(const_iterator(__first, this), const_iterator(__cur, this)); for (size_type __m = __n + 1; __m < _M_buckets.size(); ++__m) if (_M_buckets[__m]) return _Pii(const_iterator(__first, this), const_iterator(_M_buckets[__m], this)); return _Pii(const_iterator(__first, this), end()); } } return _Pii(end(), end()); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> typename hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>::size_type hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: erase(const key_type& __key) { const size_type __n = _M_bkt_num_key(__key); _Node* __first = _M_buckets[__n]; _Node* __saved_slot = 0; size_type __erased = 0; if (__first) { _Node* __cur = __first; _Node* __next = __cur->_M_next; while (__next) { if (_M_equals(_M_get_key(__next->_M_val), __key)) { if (&_M_get_key(__next->_M_val) != &__key) { __cur->_M_next = __next->_M_next; _M_delete_node(__next); __next = __cur->_M_next; ++__erased; --_M_num_elements; } else { __saved_slot = __cur; __cur = __next; __next = __cur->_M_next; } } else { __cur = __next; __next = __cur->_M_next; } } bool __delete_first = _M_equals(_M_get_key(__first->_M_val), __key); if (__saved_slot) { __next = __saved_slot->_M_next; __saved_slot->_M_next = __next->_M_next; _M_delete_node(__next); ++__erased; --_M_num_elements; } if (__delete_first) { _M_buckets[__n] = __first->_M_next; _M_delete_node(__first); ++__erased; --_M_num_elements; } } return __erased; } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: erase(const iterator& __it) { _Node* __p = __it._M_cur; if (__p) { const size_type __n = _M_bkt_num(__p->_M_val); _Node* __cur = _M_buckets[__n]; if (__cur == __p) { _M_buckets[__n] = __cur->_M_next; _M_delete_node(__cur); --_M_num_elements; } else { _Node* __next = __cur->_M_next; while (__next) { if (__next == __p) { __cur->_M_next = __next->_M_next; _M_delete_node(__next); --_M_num_elements; break; } else { __cur = __next; __next = __cur->_M_next; } } } } } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: erase(iterator __first, iterator __last) { size_type __f_bucket = __first._M_cur ? _M_bkt_num(__first._M_cur->_M_val) : _M_buckets.size(); size_type __l_bucket = __last._M_cur ? _M_bkt_num(__last._M_cur->_M_val) : _M_buckets.size(); if (__first._M_cur == __last._M_cur) return; else if (__f_bucket == __l_bucket) _M_erase_bucket(__f_bucket, __first._M_cur, __last._M_cur); else { _M_erase_bucket(__f_bucket, __first._M_cur, 0); for (size_type __n = __f_bucket + 1; __n < __l_bucket; ++__n) _M_erase_bucket(__n, 0); if (__l_bucket != _M_buckets.size()) _M_erase_bucket(__l_bucket, __last._M_cur); } } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> inline void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: erase(const_iterator __first, const_iterator __last) { erase(iterator(const_cast<_Node*>(__first._M_cur), const_cast<hashtable*>(__first._M_ht)), iterator(const_cast<_Node*>(__last._M_cur), const_cast<hashtable*>(__last._M_ht))); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> inline void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: erase(const const_iterator& __it) { erase(iterator(const_cast<_Node*>(__it._M_cur), const_cast<hashtable*>(__it._M_ht))); } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: resize(size_type __num_elements_hint) { const size_type __old_n = _M_buckets.size(); if (__num_elements_hint > __old_n) { const size_type __n = _M_next_size(__num_elements_hint); if (__n > __old_n) { _Vector_type __tmp(__n, (_Node*)(0), _M_buckets.get_allocator()); __try { for (size_type __bucket = 0; __bucket < __old_n; ++__bucket) { _Node* __first = _M_buckets[__bucket]; while (__first) { size_type __new_bucket = _M_bkt_num(__first->_M_val, __n); _M_buckets[__bucket] = __first->_M_next; __first->_M_next = __tmp[__new_bucket]; __tmp[__new_bucket] = __first; __first = _M_buckets[__bucket]; } } _M_buckets.swap(__tmp); } __catch(...) { for (size_type __bucket = 0; __bucket < __tmp.size(); ++__bucket) { while (__tmp[__bucket]) { _Node* __next = __tmp[__bucket]->_M_next; _M_delete_node(__tmp[__bucket]); __tmp[__bucket] = __next; } } __throw_exception_again; } } } } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: _M_erase_bucket(const size_type __n, _Node* __first, _Node* __last) { _Node* __cur = _M_buckets[__n]; if (__cur == __first) _M_erase_bucket(__n, __last); else { _Node* __next; for (__next = __cur->_M_next; __next != __first; __cur = __next, __next = __cur->_M_next) ; while (__next != __last) { __cur->_M_next = __next->_M_next; _M_delete_node(__next); __next = __cur->_M_next; --_M_num_elements; } } } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: _M_erase_bucket(const size_type __n, _Node* __last) { _Node* __cur = _M_buckets[__n]; while (__cur != __last) { _Node* __next = __cur->_M_next; _M_delete_node(__cur); __cur = __next; _M_buckets[__n] = __cur; --_M_num_elements; } } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: clear() { if (_M_num_elements == 0) return; for (size_type __i = 0; __i < _M_buckets.size(); ++__i) { _Node* __cur = _M_buckets[__i]; while (__cur != 0) { _Node* __next = __cur->_M_next; _M_delete_node(__cur); __cur = __next; } _M_buckets[__i] = 0; } _M_num_elements = 0; } template<class _Val, class _Key, class _HF, class _Ex, class _Eq, class _All> void hashtable<_Val, _Key, _HF, _Ex, _Eq, _All>:: _M_copy_from(const hashtable& __ht) { _M_buckets.clear(); _M_buckets.reserve(__ht._M_buckets.size()); _M_buckets.insert(_M_buckets.end(), __ht._M_buckets.size(), (_Node*) 0); __try { for (size_type __i = 0; __i < __ht._M_buckets.size(); ++__i) { const _Node* __cur = __ht._M_buckets[__i]; if (__cur) { _Node* __local_copy = _M_new_node(__cur->_M_val); _M_buckets[__i] = __local_copy; for (_Node* __next = __cur->_M_next; __next; __cur = __next, __next = __cur->_M_next) { __local_copy->_M_next = _M_new_node(__next->_M_val); __local_copy = __local_copy->_M_next; } } } _M_num_elements = __ht._M_num_elements; } __catch(...) { clear(); __throw_exception_again; } } _GLIBCXX_END_NAMESPACE_VERSION } // namespace #endif
Close
