ladybird/AK/SinglyLinkedList.h
Lenny Maiorani e0ab7763da AK: Combine SinglyLinkedList and SinglyLinkedListWithCount
Using policy based design `SinglyLinkedList` and
`SinglyLinkedListWithCount` can be combined into one class which takes
a policy to determine how to keep track of the size of the list. The
default policy is to use list iteration to count the items in the list
each time. The `WithCount` form is a different policy which tracks the
size, but comes with the overhead of storing the count and
incrementing/decrementing on each modification.

This model is extensible to have other forms of counting by
implementing only a new policy instead of implementing a totally new
type.
2023-01-02 20:13:24 +00:00

311 lines
7.6 KiB
C++

/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <AK/Assertions.h>
#include <AK/Error.h>
#include <AK/Find.h>
#include <AK/StdLibExtras.h>
#include <AK/Traits.h>
#include <AK/Types.h>
namespace AK {
template<typename ListType, typename ElementType>
class SinglyLinkedListIterator {
public:
SinglyLinkedListIterator() = default;
bool operator!=(SinglyLinkedListIterator const& other) const { return m_node != other.m_node; }
SinglyLinkedListIterator& operator++()
{
if (m_removed)
m_removed = false;
else
m_prev = m_node;
m_node = m_next;
if (m_next)
m_next = m_next->next;
return *this;
}
ElementType& operator*()
{
VERIFY(!m_removed);
return m_node->value;
}
ElementType* operator->()
{
VERIFY(!m_removed);
return &m_node->value;
}
bool is_end() const { return !m_node; }
bool is_begin() const { return !m_prev; }
void remove(ListType& list)
{
m_removed = true;
list.remove(*this);
};
private:
friend ListType;
explicit SinglyLinkedListIterator(typename ListType::Node* node, typename ListType::Node* prev = nullptr)
: m_node(node)
, m_prev(prev)
, m_next(node ? node->next : nullptr)
{
}
typename ListType::Node* m_node { nullptr };
typename ListType::Node* m_prev { nullptr };
typename ListType::Node* m_next { nullptr };
bool m_removed { false };
};
template<typename T, typename TSizeCalculationPolicy>
class SinglyLinkedList {
private:
struct Node {
explicit Node(T&& v)
: value(move(v))
{
}
explicit Node(T const& v)
: value(v)
{
}
T value;
Node* next { nullptr };
};
public:
SinglyLinkedList() = default;
SinglyLinkedList(SinglyLinkedList const& other) = delete;
SinglyLinkedList(SinglyLinkedList&& other)
: m_head(other.m_head)
, m_tail(other.m_tail)
{
other.m_head = nullptr;
other.m_tail = nullptr;
}
SinglyLinkedList& operator=(SinglyLinkedList const& other) = delete;
SinglyLinkedList& operator=(SinglyLinkedList&&) = delete;
~SinglyLinkedList() { clear(); }
bool is_empty() const { return !head(); }
inline size_t size() const
{
return m_size_policy.size(m_head);
}
void clear()
{
for (auto* node = m_head; node;) {
auto* next = node->next;
delete node;
node = next;
}
m_head = nullptr;
m_tail = nullptr;
m_size_policy.reset();
}
T& first()
{
VERIFY(head());
return head()->value;
}
T const& first() const
{
VERIFY(head());
return head()->value;
}
T& last()
{
VERIFY(head());
return tail()->value;
}
T const& last() const
{
VERIFY(head());
return tail()->value;
}
T take_first()
{
VERIFY(m_head);
auto* prev_head = m_head;
T value = move(first());
if (m_tail == m_head)
m_tail = nullptr;
m_head = m_head->next;
m_size_policy.decrease_size(value);
delete prev_head;
return value;
}
template<typename U = T>
ErrorOr<void> try_append(U&& value)
{
auto* node = new (nothrow) Node(forward<U>(value));
if (!node)
return Error::from_errno(ENOMEM);
m_size_policy.increase_size(value);
if (!m_head) {
m_head = node;
m_tail = node;
return {};
}
m_tail->next = node;
m_tail = node;
return {};
}
template<typename U = T>
ErrorOr<void> try_prepend(U&& value)
{
auto* node = new (nothrow) Node(forward<U>(value));
if (!node)
return Error::from_errno(ENOMEM);
m_size_policy.increase_size(value);
if (!m_head) {
m_head = node;
m_tail = node;
return {};
}
node->next = m_head;
m_head = node;
return {};
}
#ifndef KERNEL
template<typename U = T>
void append(U&& value)
{
MUST(try_append(forward<U>(value)));
}
template<typename U = T>
void prepend(U&& value)
{
MUST(try_prepend(forward<U>(value)));
}
#endif
bool contains_slow(T const& value) const
{
return find(value) != end();
}
using Iterator = SinglyLinkedListIterator<SinglyLinkedList, T>;
friend Iterator;
Iterator begin() { return Iterator(m_head); }
Iterator end() { return {}; }
using ConstIterator = SinglyLinkedListIterator<const SinglyLinkedList, T const>;
friend ConstIterator;
ConstIterator begin() const { return ConstIterator(m_head); }
ConstIterator end() const { return {}; }
template<typename TUnaryPredicate>
ConstIterator find_if(TUnaryPredicate&& pred) const
{
return AK::find_if(begin(), end(), forward<TUnaryPredicate>(pred));
}
template<typename TUnaryPredicate>
Iterator find_if(TUnaryPredicate&& pred)
{
return AK::find_if(begin(), end(), forward<TUnaryPredicate>(pred));
}
ConstIterator find(T const& value) const
{
return find_if([&](auto& other) { return Traits<T>::equals(value, other); });
}
Iterator find(T const& value)
{
return find_if([&](auto& other) { return Traits<T>::equals(value, other); });
}
template<typename U = T>
ErrorOr<void> try_insert_before(Iterator iterator, U&& value)
{
auto* node = new (nothrow) Node(forward<U>(value));
if (!node)
return Error::from_errno(ENOMEM);
m_size_policy.increase_size(value);
node->next = iterator.m_node;
if (m_head == iterator.m_node)
m_head = node;
if (iterator.m_prev)
iterator.m_prev->next = node;
return {};
}
template<typename U = T>
ErrorOr<void> try_insert_after(Iterator iterator, U&& value)
{
if (iterator.is_end())
return try_append(value);
auto* node = new (nothrow) Node(forward<U>(value));
if (!node)
return Error::from_errno(ENOMEM);
m_size_policy.increase_size(value);
node->next = iterator.m_node->next;
iterator.m_node->next = node;
if (m_tail == iterator.m_node)
m_tail = node;
return {};
}
#ifndef KERNEL
template<typename U = T>
void insert_before(Iterator iterator, U&& value)
{
MUST(try_insert_before(iterator, forward<U>(value)));
}
template<typename U = T>
void insert_after(Iterator iterator, U&& value)
{
MUST(try_insert_after(iterator, forward<U>(value)));
}
#endif
void remove(Iterator& iterator)
{
VERIFY(!iterator.is_end());
if (m_head == iterator.m_node)
m_head = iterator.m_node->next;
if (m_tail == iterator.m_node)
m_tail = iterator.m_prev;
if (iterator.m_prev)
iterator.m_prev->next = iterator.m_node->next;
m_size_policy.decrease_size(iterator.m_node->value);
delete iterator.m_node;
}
private:
Node* head() { return m_head; }
Node const* head() const { return m_head; }
Node* tail() { return m_tail; }
Node const* tail() const { return m_tail; }
Node* m_head { nullptr };
Node* m_tail { nullptr };
TSizeCalculationPolicy m_size_policy {};
};
}
#if USING_AK_GLOBALLY
using AK::SinglyLinkedList;
#endif