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cobalt / cobalt / e77c070364e97b7a7deea396227c08805cb9e66d / . / src / third_party / WebKit / Source / WTF / wtf / ListHashSet.h
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/*
* Copyright (C) 2005, 2006, 2007, 2008, 2011, 2012 Apple Inc. All rights reserved.
* Copyright (C) 2011, Benjamin Poulain <ikipou@gmail.com>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, 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
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public License
* along with this library; see the file COPYING.LIB. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
* Boston, MA 02110-1301, USA.
*
*/
#ifndef WTF_ListHashSet_h
#define WTF_ListHashSet_h
#include <wtf/HashSet.h>
#include <wtf/OwnPtr.h>
#include <wtf/PassOwnPtr.h>
namespace WTF {
// ListHashSet: Just like HashSet, this class provides a Set
// interface - a collection of unique objects with O(1) insertion,
// removal and test for containership. However, it also has an
// order - iterating it will always give back values in the order
// in which they are added.
// Unlike iteration of most WTF Hash data structures, iteration is
// guaranteed safe against mutation of the ListHashSet, except for
// removal of the item currently pointed to by a given iterator.
template<typename Value, size_t inlineCapacity, typename HashFunctions> class ListHashSet;
template<typename Value, size_t inlineCapacity, typename HashFunctions>
void deleteAllValues(const ListHashSet<Value, inlineCapacity, HashFunctions>&);
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetIterator;
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetConstIterator;
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetReverseIterator;
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetConstReverseIterator;
template<typename ValueArg, size_t inlineCapacity> struct ListHashSetNode;
template<typename ValueArg, size_t inlineCapacity> struct ListHashSetNodeAllocator;
template<typename HashArg> struct ListHashSetNodeHashFunctions;
template<typename HashArg> struct ListHashSetTranslator;
template<typename ValueArg, size_t inlineCapacity = 256, typename HashArg = typename DefaultHash<ValueArg>::Hash> class ListHashSet {
WTF_MAKE_FAST_ALLOCATED;
private:
typedef ListHashSetNode<ValueArg, inlineCapacity> Node;
typedef ListHashSetNodeAllocator<ValueArg, inlineCapacity> NodeAllocator;
typedef HashTraits<Node*> NodeTraits;
typedef ListHashSetNodeHashFunctions<HashArg> NodeHash;
typedef ListHashSetTranslator<HashArg> BaseTranslator;
typedef HashTable<Node*, Node*, IdentityExtractor, NodeHash, NodeTraits, NodeTraits> ImplType;
typedef HashTableIterator<Node*, Node*, IdentityExtractor, NodeHash, NodeTraits, NodeTraits> ImplTypeIterator;
typedef HashTableConstIterator<Node*, Node*, IdentityExtractor, NodeHash, NodeTraits, NodeTraits> ImplTypeConstIterator;
typedef HashArg HashFunctions;
public:
typedef ValueArg ValueType;
typedef ListHashSetIterator<ValueType, inlineCapacity, HashArg> iterator;
typedef ListHashSetConstIterator<ValueType, inlineCapacity, HashArg> const_iterator;
friend class ListHashSetConstIterator<ValueType, inlineCapacity, HashArg>;
typedef ListHashSetReverseIterator<ValueType, inlineCapacity, HashArg> reverse_iterator;
typedef ListHashSetConstReverseIterator<ValueType, inlineCapacity, HashArg> const_reverse_iterator;
friend class ListHashSetConstReverseIterator<ValueType, inlineCapacity, HashArg>;
typedef HashTableAddResult<iterator> AddResult;
ListHashSet();
ListHashSet(const ListHashSet&);
ListHashSet& operator=(const ListHashSet&);
~ListHashSet();
void swap(ListHashSet&);
int size() const;
int capacity() const;
bool isEmpty() const;
size_t sizeInBytes() const;
iterator begin();
iterator end();
const_iterator begin() const;
const_iterator end() const;
reverse_iterator rbegin();
reverse_iterator rend();
const_reverse_iterator rbegin() const;
const_reverse_iterator rend() const;
ValueType& first();
const ValueType& first() const;
void removeFirst();
ValueType& last();
const ValueType& last() const;
void removeLast();
iterator find(const ValueType&);
const_iterator find(const ValueType&) const;
bool contains(const ValueType&) const;
// An alternate version of find() that finds the object by hashing and comparing
// with some other type, to avoid the cost of type conversion.
// The HashTranslator interface is defined in HashSet.
// FIXME: We should reverse the order of the template arguments so that callers
// can just pass the translator let the compiler deduce T.
template<typename T, typename HashTranslator> iterator find(const T&);
template<typename T, typename HashTranslator> const_iterator find(const T&) const;
template<typename T, typename HashTranslator> bool contains(const T&) const;
// The return value of add is a pair of an iterator to the new value's location,
// and a bool that is true if an new entry was added.
AddResult add(const ValueType&);
// Add the value to the end of the collection. If the value was already in
// the list, it is moved to the end.
AddResult appendOrMoveToLast(const ValueType&);
// Add the value to the beginning of the collection. If the value was already in
// the list, it is moved to the beginning.
AddResult prependOrMoveToFirst(const ValueType&);
AddResult insertBefore(const ValueType& beforeValue, const ValueType& newValue);
AddResult insertBefore(iterator, const ValueType&);
void remove(const ValueType&);
void remove(iterator);
void clear();
private:
void unlink(Node*);
void unlinkAndDelete(Node*);
void appendNode(Node*);
void prependNode(Node*);
void insertNodeBefore(Node* beforeNode, Node* newNode);
void deleteAllNodes();
iterator makeIterator(Node*);
const_iterator makeConstIterator(Node*) const;
reverse_iterator makeReverseIterator(Node*);
const_reverse_iterator makeConstReverseIterator(Node*) const;
friend void deleteAllValues<>(const ListHashSet&);
ImplType m_impl;
Node* m_head;
Node* m_tail;
OwnPtr<NodeAllocator> m_allocator;
};
template<typename ValueArg, size_t inlineCapacity> struct ListHashSetNodeAllocator {
typedef ListHashSetNode<ValueArg, inlineCapacity> Node;
typedef ListHashSetNodeAllocator<ValueArg, inlineCapacity> NodeAllocator;
ListHashSetNodeAllocator()
: m_freeList(pool())
, m_isDoneWithInitialFreeList(false)
{
memset(m_pool.pool, 0, sizeof(m_pool.pool));
}
Node* allocate()
{
Node* result = m_freeList;
if (!result)
return static_cast<Node*>(fastMalloc(sizeof(Node)));
ASSERT(!result->m_isAllocated);
Node* next = result->m_next;
ASSERT(!next || !next->m_isAllocated);
if (!next && !m_isDoneWithInitialFreeList) {
next = result + 1;
if (next == pastPool()) {
m_isDoneWithInitialFreeList = true;
next = 0;
} else {
ASSERT(inPool(next));
ASSERT(!next->m_isAllocated);
}
}
m_freeList = next;
return result;
}
void deallocate(Node* node)
{
if (inPool(node)) {
#ifndef NDEBUG
node->m_isAllocated = false;
#endif
node->m_next = m_freeList;
m_freeList = node;
return;
}
fastFree(node);
}
bool inPool(Node* node)
{
return node >= pool() && node < pastPool();
}
private:
Node* pool() { return reinterpret_cast_ptr<Node*>(m_pool.pool); }
Node* pastPool() { return pool() + m_poolSize; }
Node* m_freeList;
bool m_isDoneWithInitialFreeList;
static const size_t m_poolSize = inlineCapacity;
union {
char pool[sizeof(Node) * m_poolSize];
double forAlignment;
} m_pool;
};
template<typename ValueArg, size_t inlineCapacity> struct ListHashSetNode {
typedef ListHashSetNodeAllocator<ValueArg, inlineCapacity> NodeAllocator;
ListHashSetNode(ValueArg value)
: m_value(value)
, m_prev(0)
, m_next(0)
#ifndef NDEBUG
, m_isAllocated(true)
#endif
{
}
void* operator new(size_t, NodeAllocator* allocator)
{
return allocator->allocate();
}
void destroy(NodeAllocator* allocator)
{
this->~ListHashSetNode();
allocator->deallocate(this);
}
ValueArg m_value;
ListHashSetNode* m_prev;
ListHashSetNode* m_next;
#ifndef NDEBUG
bool m_isAllocated;
#endif
};
template<typename HashArg> struct ListHashSetNodeHashFunctions {
template<typename T> static unsigned hash(const T& key) { return HashArg::hash(key->m_value); }
template<typename T> static bool equal(const T& a, const T& b) { return HashArg::equal(a->m_value, b->m_value); }
static const bool safeToCompareToEmptyOrDeleted = false;
};
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetIterator {
private:
typedef ListHashSet<ValueArg, inlineCapacity, HashArg> ListHashSetType;
typedef ListHashSetIterator<ValueArg, inlineCapacity, HashArg> iterator;
typedef ListHashSetConstIterator<ValueArg, inlineCapacity, HashArg> const_iterator;
typedef ListHashSetNode<ValueArg, inlineCapacity> Node;
typedef ValueArg ValueType;
typedef ValueType& ReferenceType;
typedef ValueType* PointerType;
friend class ListHashSet<ValueArg, inlineCapacity, HashArg>;
ListHashSetIterator(const ListHashSetType* set, Node* position) : m_iterator(set, position) { }
public:
ListHashSetIterator() { }
// default copy, assignment and destructor are OK
PointerType get() const { return const_cast<PointerType>(m_iterator.get()); }
ReferenceType operator*() const { return *get(); }
PointerType operator->() const { return get(); }
iterator& operator++() { ++m_iterator; return *this; }
// postfix ++ intentionally omitted
iterator& operator--() { --m_iterator; return *this; }
// postfix -- intentionally omitted
// Comparison.
bool operator==(const iterator& other) const { return m_iterator == other.m_iterator; }
bool operator!=(const iterator& other) const { return m_iterator != other.m_iterator; }
operator const_iterator() const { return m_iterator; }
private:
Node* node() { return m_iterator.node(); }
const_iterator m_iterator;
};
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetConstIterator {
private:
typedef ListHashSet<ValueArg, inlineCapacity, HashArg> ListHashSetType;
typedef ListHashSetIterator<ValueArg, inlineCapacity, HashArg> iterator;
typedef ListHashSetConstIterator<ValueArg, inlineCapacity, HashArg> const_iterator;
typedef ListHashSetNode<ValueArg, inlineCapacity> Node;
typedef ValueArg ValueType;
typedef const ValueType& ReferenceType;
typedef const ValueType* PointerType;
friend class ListHashSet<ValueArg, inlineCapacity, HashArg>;
friend class ListHashSetIterator<ValueArg, inlineCapacity, HashArg>;
ListHashSetConstIterator(const ListHashSetType* set, Node* position)
: m_set(set)
, m_position(position)
{
}
public:
ListHashSetConstIterator()
{
}
PointerType get() const
{
return &m_position->m_value;
}
ReferenceType operator*() const { return *get(); }
PointerType operator->() const { return get(); }
const_iterator& operator++()
{
ASSERT(m_position != 0);
m_position = m_position->m_next;
return *this;
}
// postfix ++ intentionally omitted
const_iterator& operator--()
{
ASSERT(m_position != m_set->m_head);
if (!m_position)
m_position = m_set->m_tail;
else
m_position = m_position->m_prev;
return *this;
}
// postfix -- intentionally omitted
// Comparison.
bool operator==(const const_iterator& other) const
{
return m_position == other.m_position;
}
bool operator!=(const const_iterator& other) const
{
return m_position != other.m_position;
}
private:
Node* node() { return m_position; }
const ListHashSetType* m_set;
Node* m_position;
};
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetReverseIterator {
private:
typedef ListHashSet<ValueArg, inlineCapacity, HashArg> ListHashSetType;
typedef ListHashSetReverseIterator<ValueArg, inlineCapacity, HashArg> reverse_iterator;
typedef ListHashSetConstReverseIterator<ValueArg, inlineCapacity, HashArg> const_reverse_iterator;
typedef ListHashSetNode<ValueArg, inlineCapacity> Node;
typedef ValueArg ValueType;
typedef ValueType& ReferenceType;
typedef ValueType* PointerType;
friend class ListHashSet<ValueArg, inlineCapacity, HashArg>;
ListHashSetReverseIterator(const ListHashSetType* set, Node* position) : m_iterator(set, position) { }
public:
ListHashSetReverseIterator() { }
// default copy, assignment and destructor are OK
PointerType get() const { return const_cast<PointerType>(m_iterator.get()); }
ReferenceType operator*() const { return *get(); }
PointerType operator->() const { return get(); }
reverse_iterator& operator++() { ++m_iterator; return *this; }
// postfix ++ intentionally omitted
reverse_iterator& operator--() { --m_iterator; return *this; }
// postfix -- intentionally omitted
// Comparison.
bool operator==(const reverse_iterator& other) const { return m_iterator == other.m_iterator; }
bool operator!=(const reverse_iterator& other) const { return m_iterator != other.m_iterator; }
operator const_reverse_iterator() const { return m_iterator; }
private:
Node* node() { return m_iterator.node(); }
const_reverse_iterator m_iterator;
};
template<typename ValueArg, size_t inlineCapacity, typename HashArg> class ListHashSetConstReverseIterator {
private:
typedef ListHashSet<ValueArg, inlineCapacity, HashArg> ListHashSetType;
typedef ListHashSetReverseIterator<ValueArg, inlineCapacity, HashArg> reverse_iterator;
typedef ListHashSetConstReverseIterator<ValueArg, inlineCapacity, HashArg> const_reverse_iterator;
typedef ListHashSetNode<ValueArg, inlineCapacity> Node;
typedef ValueArg ValueType;
typedef const ValueType& ReferenceType;
typedef const ValueType* PointerType;
friend class ListHashSet<ValueArg, inlineCapacity, HashArg>;
friend class ListHashSetReverseIterator<ValueArg, inlineCapacity, HashArg>;
ListHashSetConstReverseIterator(const ListHashSetType* set, Node* position)
: m_set(set)
, m_position(position)
{
}
public:
ListHashSetConstReverseIterator()
{
}
PointerType get() const
{
return &m_position->m_value;
}
ReferenceType operator*() const { return *get(); }
PointerType operator->() const { return get(); }
const_reverse_iterator& operator++()
{
ASSERT(m_position != 0);
m_position = m_position->m_prev;
return *this;
}
// postfix ++ intentionally omitted
const_reverse_iterator& operator--()
{
ASSERT(m_position != m_set->m_tail);
if (!m_position)
m_position = m_set->m_head;
else
m_position = m_position->m_next;
return *this;
}
// postfix -- intentionally omitted
// Comparison.
bool operator==(const const_reverse_iterator& other) const
{
return m_position == other.m_position;
}
bool operator!=(const const_reverse_iterator& other) const
{
return m_position != other.m_position;
}
private:
Node* node() { return m_position; }
const ListHashSetType* m_set;
Node* m_position;
};
template<typename HashFunctions>
struct ListHashSetTranslator {
template<typename T> static unsigned hash(const T& key) { return HashFunctions::hash(key); }
template<typename T, typename U> static bool equal(const T& a, const U& b) { return HashFunctions::equal(a->m_value, b); }
template<typename T, typename U, typename V> static void translate(T*& location, const U& key, const V& allocator)
{
location = new (allocator) T(key);
}
};
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSet<T, inlineCapacity, U>::ListHashSet()
: m_head(0)
, m_tail(0)
, m_allocator(adoptPtr(new NodeAllocator))
{
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSet<T, inlineCapacity, U>::ListHashSet(const ListHashSet& other)
: m_head(0)
, m_tail(0)
, m_allocator(adoptPtr(new NodeAllocator))
{
const_iterator end = other.end();
for (const_iterator it = other.begin(); it != end; ++it)
add(*it);
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSet<T, inlineCapacity, U>& ListHashSet<T, inlineCapacity, U>::operator=(const ListHashSet& other)
{
ListHashSet tmp(other);
swap(tmp);
return *this;
}
template<typename T, size_t inlineCapacity, typename U>
inline void ListHashSet<T, inlineCapacity, U>::swap(ListHashSet& other)
{
m_impl.swap(other.m_impl);
std::swap(m_head, other.m_head);
std::swap(m_tail, other.m_tail);
m_allocator.swap(other.m_allocator);
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSet<T, inlineCapacity, U>::~ListHashSet()
{
deleteAllNodes();
}
template<typename T, size_t inlineCapacity, typename U>
inline int ListHashSet<T, inlineCapacity, U>::size() const
{
return m_impl.size();
}
template<typename T, size_t inlineCapacity, typename U>
inline int ListHashSet<T, inlineCapacity, U>::capacity() const
{
return m_impl.capacity();
}
template<typename T, size_t inlineCapacity, typename U>
inline bool ListHashSet<T, inlineCapacity, U>::isEmpty() const
{
return m_impl.isEmpty();
}
template<typename T, size_t inlineCapacity, typename U>
size_t ListHashSet<T, inlineCapacity, U>::sizeInBytes() const
{
size_t result = sizeof(*this) + sizeof(*m_allocator);
result += sizeof(typename ImplType::ValueType) * m_impl.capacity();
for (Node* node = m_head; node; node = node->m_next) {
if (!m_allocator->inPool(node))
result += sizeof(Node);
}
return result;
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::iterator ListHashSet<T, inlineCapacity, U>::begin()
{
return makeIterator(m_head);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::iterator ListHashSet<T, inlineCapacity, U>::end()
{
return makeIterator(0);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::const_iterator ListHashSet<T, inlineCapacity, U>::begin() const
{
return makeConstIterator(m_head);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::const_iterator ListHashSet<T, inlineCapacity, U>::end() const
{
return makeConstIterator(0);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::reverse_iterator ListHashSet<T, inlineCapacity, U>::rbegin()
{
return makeReverseIterator(m_tail);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::reverse_iterator ListHashSet<T, inlineCapacity, U>::rend()
{
return makeReverseIterator(0);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::const_reverse_iterator ListHashSet<T, inlineCapacity, U>::rbegin() const
{
return makeConstReverseIterator(m_tail);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::const_reverse_iterator ListHashSet<T, inlineCapacity, U>::rend() const
{
return makeConstReverseIterator(0);
}
template<typename T, size_t inlineCapacity, typename U>
inline T& ListHashSet<T, inlineCapacity, U>::first()
{
ASSERT(!isEmpty());
return m_head->m_value;
}
template<typename T, size_t inlineCapacity, typename U>
inline void ListHashSet<T, inlineCapacity, U>::removeFirst()
{
ASSERT(!isEmpty());
m_impl.remove(m_head);
unlinkAndDelete(m_head);
}
template<typename T, size_t inlineCapacity, typename U>
inline const T& ListHashSet<T, inlineCapacity, U>::first() const
{
ASSERT(!isEmpty());
return m_head->m_value;
}
template<typename T, size_t inlineCapacity, typename U>
inline T& ListHashSet<T, inlineCapacity, U>::last()
{
ASSERT(!isEmpty());
return m_tail->m_value;
}
template<typename T, size_t inlineCapacity, typename U>
inline const T& ListHashSet<T, inlineCapacity, U>::last() const
{
ASSERT(!isEmpty());
return m_tail->m_value;
}
template<typename T, size_t inlineCapacity, typename U>
inline void ListHashSet<T, inlineCapacity, U>::removeLast()
{
ASSERT(!isEmpty());
m_impl.remove(m_tail);
unlinkAndDelete(m_tail);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::iterator ListHashSet<T, inlineCapacity, U>::find(const ValueType& value)
{
ImplTypeIterator it = m_impl.template find<BaseTranslator>(value);
if (it == m_impl.end())
return end();
return makeIterator(*it);
}
template<typename T, size_t inlineCapacity, typename U>
inline typename ListHashSet<T, inlineCapacity, U>::const_iterator ListHashSet<T, inlineCapacity, U>::find(const ValueType& value) const
{
ImplTypeConstIterator it = m_impl.template find<BaseTranslator>(value);
if (it == m_impl.end())
return end();
return makeConstIterator(*it);
}
template<typename Translator>
struct ListHashSetTranslatorAdapter {
template<typename T> static unsigned hash(const T& key) { return Translator::hash(key); }
template<typename T, typename U> static bool equal(const T& a, const U& b) { return Translator::equal(a->m_value, b); }
};
template<typename ValueType, size_t inlineCapacity, typename U>
template<typename T, typename HashTranslator>
inline typename ListHashSet<ValueType, inlineCapacity, U>::iterator ListHashSet<ValueType, inlineCapacity, U>::find(const T& value)
{
ImplTypeConstIterator it = m_impl.template find<ListHashSetTranslatorAdapter<HashTranslator> >(value);
if (it == m_impl.end())
return end();
return makeIterator(*it);
}
template<typename ValueType, size_t inlineCapacity, typename U>
template<typename T, typename HashTranslator>
inline typename ListHashSet<ValueType, inlineCapacity, U>::const_iterator ListHashSet<ValueType, inlineCapacity, U>::find(const T& value) const
{
ImplTypeConstIterator it = m_impl.template find<ListHashSetTranslatorAdapter<HashTranslator> >(value);
if (it == m_impl.end())
return end();
return makeConstIterator(*it);
}
template<typename ValueType, size_t inlineCapacity, typename U>
template<typename T, typename HashTranslator>
inline bool ListHashSet<ValueType, inlineCapacity, U>::contains(const T& value) const
{
return m_impl.template contains<ListHashSetTranslatorAdapter<HashTranslator> >(value);
}
template<typename T, size_t inlineCapacity, typename U>
inline bool ListHashSet<T, inlineCapacity, U>::contains(const ValueType& value) const
{
return m_impl.template contains<BaseTranslator>(value);
}
template<typename T, size_t inlineCapacity, typename U>
typename ListHashSet<T, inlineCapacity, U>::AddResult ListHashSet<T, inlineCapacity, U>::add(const ValueType &value)
{
typename ImplType::AddResult result = m_impl.template add<BaseTranslator>(value, m_allocator.get());
if (result.isNewEntry)
appendNode(*result.iterator);
return AddResult(makeIterator(*result.iterator), result.isNewEntry);
}
template<typename T, size_t inlineCapacity, typename U>
typename ListHashSet<T, inlineCapacity, U>::AddResult ListHashSet<T, inlineCapacity, U>::appendOrMoveToLast(const ValueType &value)
{
typename ImplType::AddResult result = m_impl.template add<BaseTranslator>(value, m_allocator.get());
Node* node = *result.iterator;
if (!result.isNewEntry)
unlink(node);
appendNode(node);
return AddResult(makeIterator(*result.iterator), result.isNewEntry);
}
template<typename T, size_t inlineCapacity, typename U>
typename ListHashSet<T, inlineCapacity, U>::AddResult ListHashSet<T, inlineCapacity, U>::prependOrMoveToFirst(const ValueType &value)
{
typename ImplType::AddResult result = m_impl.template add<BaseTranslator>(value, m_allocator.get());
Node* node = *result.iterator;
if (!result.isNewEntry)
unlink(node);
prependNode(node);
return AddResult(makeIterator(*result.iterator), result.isNewEntry);
}
template<typename T, size_t inlineCapacity, typename U>
typename ListHashSet<T, inlineCapacity, U>::AddResult ListHashSet<T, inlineCapacity, U>::insertBefore(iterator it, const ValueType& newValue)
{
typename ImplType::AddResult result = m_impl.template add<BaseTranslator>(newValue, m_allocator.get());
if (result.isNewEntry)
insertNodeBefore(it.node(), *result.iterator);
return AddResult(makeIterator(*result.iterator), result.isNewEntry);
}
template<typename T, size_t inlineCapacity, typename U>
typename ListHashSet<T, inlineCapacity, U>::AddResult ListHashSet<T, inlineCapacity, U>::insertBefore(const ValueType& beforeValue, const ValueType& newValue)
{
return insertBefore(find(beforeValue), newValue);
}
template<typename T, size_t inlineCapacity, typename U>
inline void ListHashSet<T, inlineCapacity, U>::remove(iterator it)
{
if (it == end())
return;
m_impl.remove(it.node());
unlinkAndDelete(it.node());
}
template<typename T, size_t inlineCapacity, typename U>
inline void ListHashSet<T, inlineCapacity, U>::remove(const ValueType& value)
{
remove(find(value));
}
template<typename T, size_t inlineCapacity, typename U>
inline void ListHashSet<T, inlineCapacity, U>::clear()
{
deleteAllNodes();
m_impl.clear();
m_head = 0;
m_tail = 0;
}
template<typename T, size_t inlineCapacity, typename U>
void ListHashSet<T, inlineCapacity, U>::unlink(Node* node)
{
if (!node->m_prev) {
ASSERT(node == m_head);
m_head = node->m_next;
} else {
ASSERT(node != m_head);
node->m_prev->m_next = node->m_next;
}
if (!node->m_next) {
ASSERT(node == m_tail);
m_tail = node->m_prev;
} else {
ASSERT(node != m_tail);
node->m_next->m_prev = node->m_prev;
}
}
template<typename T, size_t inlineCapacity, typename U>
void ListHashSet<T, inlineCapacity, U>::unlinkAndDelete(Node* node)
{
unlink(node);
node->destroy(m_allocator.get());
}
template<typename T, size_t inlineCapacity, typename U>
void ListHashSet<T, inlineCapacity, U>::appendNode(Node* node)
{
node->m_prev = m_tail;
node->m_next = 0;
if (m_tail) {
ASSERT(m_head);
m_tail->m_next = node;
} else {
ASSERT(!m_head);
m_head = node;
}
m_tail = node;
}
template<typename T, size_t inlineCapacity, typename U>
void ListHashSet<T, inlineCapacity, U>::prependNode(Node* node)
{
node->m_prev = 0;
node->m_next = m_head;
if (m_head)
m_head->m_prev = node;
else
m_tail = node;
m_head = node;
}
template<typename T, size_t inlineCapacity, typename U>
void ListHashSet<T, inlineCapacity, U>::insertNodeBefore(Node* beforeNode, Node* newNode)
{
if (!beforeNode)
return appendNode(newNode);
newNode->m_next = beforeNode;
newNode->m_prev = beforeNode->m_prev;
if (beforeNode->m_prev)
beforeNode->m_prev->m_next = newNode;
beforeNode->m_prev = newNode;
if (!newNode->m_prev)
m_head = newNode;
}
template<typename T, size_t inlineCapacity, typename U>
void ListHashSet<T, inlineCapacity, U>::deleteAllNodes()
{
if (!m_head)
return;
for (Node* node = m_head, *next = m_head->m_next; node; node = next, next = node ? node->m_next : 0)
node->destroy(m_allocator.get());
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSetReverseIterator<T, inlineCapacity, U> ListHashSet<T, inlineCapacity, U>::makeReverseIterator(Node* position)
{
return ListHashSetReverseIterator<T, inlineCapacity, U>(this, position);
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSetConstReverseIterator<T, inlineCapacity, U> ListHashSet<T, inlineCapacity, U>::makeConstReverseIterator(Node* position) const
{
return ListHashSetConstReverseIterator<T, inlineCapacity, U>(this, position);
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSetIterator<T, inlineCapacity, U> ListHashSet<T, inlineCapacity, U>::makeIterator(Node* position)
{
return ListHashSetIterator<T, inlineCapacity, U>(this, position);
}
template<typename T, size_t inlineCapacity, typename U>
inline ListHashSetConstIterator<T, inlineCapacity, U> ListHashSet<T, inlineCapacity, U>::makeConstIterator(Node* position) const
{
return ListHashSetConstIterator<T, inlineCapacity, U>(this, position);
}
template<bool, typename ValueType, typename HashTableType>
void deleteAllValues(HashTableType& collection)
{
typedef typename HashTableType::const_iterator iterator;
iterator end = collection.end();
for (iterator it = collection.begin(); it != end; ++it)
delete (*it)->m_value;
}
template<typename T, size_t inlineCapacity, typename U>
inline void deleteAllValues(const ListHashSet<T, inlineCapacity, U>& collection)
{
deleteAllValues<true, typename ListHashSet<T, inlineCapacity, U>::ValueType>(collection.m_impl);
}
} // namespace WTF
using WTF::ListHashSet;
#endif /* WTF_ListHashSet_h */