src/common/LinkedList.h - dawn - Git at Google

 // Copyright (c) 2009 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // This file is a copy of Chromium's /src/base/containers/linked_list.h with the following
 // modifications:
 //   - Added iterators for ranged based iterations
 //   - Added in list check before removing node to prevent segfault, now returns true iff removed
 //   - Added MoveInto functionality for moving list elements to another list

 #ifndef COMMON_LINKED_LIST_H
 #define COMMON_LINKED_LIST_H

 #include "common/Assert.h"

 // Simple LinkedList type. (See the Q&A section to understand how this
 // differs from std::list).
 //
 // To use, start by declaring the class which will be contained in the linked
 // list, as extending LinkNode (this gives it next/previous pointers).
 //
 //   class MyNodeType : public LinkNode<MyNodeType> {
 //     ...
 //   };
 //
 // Next, to keep track of the list's head/tail, use a LinkedList instance:
 //
 //   LinkedList<MyNodeType> list;
 //
 // To add elements to the list, use any of LinkedList::Append,
 // LinkNode::InsertBefore, or LinkNode::InsertAfter:
 //
 //   LinkNode<MyNodeType>* n1 = ...;
 //   LinkNode<MyNodeType>* n2 = ...;
 //   LinkNode<MyNodeType>* n3 = ...;
 //
 //   list.Append(n1);
 //   list.Append(n3);
 //   n3->InsertBefore(n3);
 //
 // Lastly, to iterate through the linked list forwards:
 //
 //   for (LinkNode<MyNodeType>* node = list.head();
 //        node != list.end();
 //        node = node->next()) {
 //     MyNodeType* value = node->value();
 //     ...
 //   }
 //
 //   for (LinkNode<MyNodeType*> node : list) {
 //     MyNodeType* value = node->value();
 //     ...
 //   }
 //
 // Or to iterate the linked list backwards:
 //
 //   for (LinkNode<MyNodeType>* node = list.tail();
 //        node != list.end();
 //        node = node->previous()) {
 //     MyNodeType* value = node->value();
 //     ...
 //   }
 //
 // Questions and Answers:
 //
 // Q. Should I use std::list or base::LinkedList?
 //
 // A. The main reason to use base::LinkedList over std::list is
 //    performance. If you don't care about the performance differences
 //    then use an STL container, as it makes for better code readability.
 //
 //    Comparing the performance of base::LinkedList<T> to std::list<T*>:
 //
 //    * Erasing an element of type T* from base::LinkedList<T> is
 //      an O(1) operation. Whereas for std::list<T*> it is O(n).
 //      That is because with std::list<T*> you must obtain an
 //      iterator to the T* element before you can call erase(iterator).
 //
 //    * Insertion operations with base::LinkedList<T> never require
 //      heap allocations.
 //
 // Q. How does base::LinkedList implementation differ from std::list?
 //
 // A. Doubly-linked lists are made up of nodes that contain "next" and
 //    "previous" pointers that reference other nodes in the list.
 //
 //    With base::LinkedList<T>, the type being inserted already reserves
 //    space for the "next" and "previous" pointers (base::LinkNode<T>*).
 //    Whereas with std::list<T> the type can be anything, so the implementation
 //    needs to glue on the "next" and "previous" pointers using
 //    some internal node type.

 // Forward declarations of the types in order for recursive referencing and friending.
 template <typename T>
 class LinkNode;
 template <typename T>
 class LinkedList;

 template <typename T>
 class LinkNode {
   public:
     LinkNode() : previous_(nullptr), next_(nullptr) {
     }
     LinkNode(LinkNode<T>* previous, LinkNode<T>* next) : previous_(previous), next_(next) {
     }

     LinkNode(LinkNode<T>&& rhs) {
         next_ = rhs.next_;
         rhs.next_ = nullptr;
         previous_ = rhs.previous_;
         rhs.previous_ = nullptr;

         // If the node belongs to a list, next_ and previous_ are both non-null.
         // Otherwise, they are both null.
         if (next_) {
             next_->previous_ = this;
             previous_->next_ = this;
         }
     }

     // Insert |this| into the linked list, before |e|.
     void InsertBefore(LinkNode<T>* e) {
         this->next_ = e;
         this->previous_ = e->previous_;
         e->previous_->next_ = this;
         e->previous_ = this;
     }

     // Insert |this| into the linked list, after |e|.
     void InsertAfter(LinkNode<T>* e) {
         this->next_ = e->next_;
         this->previous_ = e;
         e->next_->previous_ = this;
         e->next_ = this;
     }

     // Check if |this| is in a list.
     bool IsInList() const {
         ASSERT((this->previous_ == nullptr) == (this->next_ == nullptr));
         return this->next_ != nullptr;
     }

     // Remove |this| from the linked list. Returns true iff removed from a list.
     bool RemoveFromList() {
         if (!IsInList()) {
             return false;
         }

         this->previous_->next_ = this->next_;
         this->next_->previous_ = this->previous_;
         // next() and previous() return non-null if and only this node is not in any list.
         this->next_ = nullptr;
         this->previous_ = nullptr;
         return true;
     }

     LinkNode<T>* previous() const {
         return previous_;
     }

     LinkNode<T>* next() const {
         return next_;
     }

     // Cast from the node-type to the value type.
     const T* value() const {
         return static_cast<const T*>(this);
     }

     T* value() {
         return static_cast<T*>(this);
     }

   private:
     friend class LinkedList<T>;
     LinkNode<T>* previous_;
     LinkNode<T>* next_;
 };

 template <typename T>
 class LinkedList {
   public:
     // The "root" node is self-referential, and forms the basis of a circular
     // list (root_.next() will point back to the start of the list,
     // and root_->previous() wraps around to the end of the list).
     LinkedList() : root_(&root_, &root_) {
     }

     ~LinkedList() {
         // If any LinkNodes still exist in the LinkedList, there will be outstanding references to
         // root_ even after it has been freed. We should remove root_ from the list to prevent any
         // future access.
         root_.RemoveFromList();
     }

     // Appends |e| to the end of the linked list.
     void Append(LinkNode<T>* e) {
         e->InsertBefore(&root_);
     }

     // Moves all elements (in order) of the list and appends them into |l| leaving the list empty.
     void MoveInto(LinkedList<T>* l) {
         if (empty()) {
             return;
         }
         l->root_.previous_->next_ = root_.next_;
         root_.next_->previous_ = l->root_.previous_;
         l->root_.previous_ = root_.previous_;
         root_.previous_->next_ = &l->root_;

         root_.next_ = &root_;
         root_.previous_ = &root_;
     }

     LinkNode<T>* head() const {
         return root_.next();
     }

     LinkNode<T>* tail() const {
         return root_.previous();
     }

     const LinkNode<T>* end() const {
         return &root_;
     }

     bool empty() const {
         return head() == end();
     }

   private:
     LinkNode<T> root_;
 };

 template <typename T>
 class LinkedListIterator {
   public:
     LinkedListIterator(LinkNode<T>* node) : current_(node), next_(node->next()) {
     }

     // We keep an early reference to the next node in the list so that even if the current element
     // is modified or removed from the list, we have a valid next node.
     LinkedListIterator<T> const& operator++() {
         current_ = next_;
         next_ = current_->next();
         return *this;
     }

     bool operator!=(const LinkedListIterator<T>& other) const {
         return current_ != other.current_;
     }

     LinkNode<T>* operator*() const {
         return current_;
     }

   private:
     LinkNode<T>* current_;
     LinkNode<T>* next_;
 };

 template <typename T>
 LinkedListIterator<T> begin(LinkedList<T>& l) {
     return LinkedListIterator<T>(l.head());
 }

 // Free end function does't use LinkedList<T>::end because of it's const nature. Instead we wrap
 // around from tail.
 template <typename T>
 LinkedListIterator<T> end(LinkedList<T>& l) {
     return LinkedListIterator<T>(l.tail()->next());
 }

 #endif  // COMMON_LINKED_LIST_H
	// Copyright (c) 2009 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// This file is a copy of Chromium's /src/base/containers/linked_list.h with the following
	// modifications:
	// - Added iterators for ranged based iterations
	// - Added in list check before removing node to prevent segfault, now returns true iff removed
	// - Added MoveInto functionality for moving list elements to another list

	#ifndef COMMON_LINKED_LIST_H
	#define COMMON_LINKED_LIST_H

	#include "common/Assert.h"

	// Simple LinkedList type. (See the Q&A section to understand how this
	// differs from std::list).
	//
	// To use, start by declaring the class which will be contained in the linked
	// list, as extending LinkNode (this gives it next/previous pointers).
	//
	// class MyNodeType : public LinkNode<MyNodeType> {
	// ...
	// };
	//
	// Next, to keep track of the list's head/tail, use a LinkedList instance:
	//
	// LinkedList<MyNodeType> list;
	//
	// To add elements to the list, use any of LinkedList::Append,
	// LinkNode::InsertBefore, or LinkNode::InsertAfter:
	//
	// LinkNode<MyNodeType>* n1 = ...;
	// LinkNode<MyNodeType>* n2 = ...;
	// LinkNode<MyNodeType>* n3 = ...;
	//
	// list.Append(n1);
	// list.Append(n3);
	// n3->InsertBefore(n3);
	//
	// Lastly, to iterate through the linked list forwards:
	//
	// for (LinkNode<MyNodeType>* node = list.head();
	// node != list.end();
	// node = node->next()) {
	// MyNodeType* value = node->value();
	// ...
	// }
	//
	// for (LinkNode<MyNodeType*> node : list) {
	// MyNodeType* value = node->value();
	// ...
	// }
	//
	// Or to iterate the linked list backwards:
	//
	// for (LinkNode<MyNodeType>* node = list.tail();
	// node != list.end();
	// node = node->previous()) {
	// MyNodeType* value = node->value();
	// ...
	// }
	//
	// Questions and Answers:
	//
	// Q. Should I use std::list or base::LinkedList?
	//
	// A. The main reason to use base::LinkedList over std::list is
	// performance. If you don't care about the performance differences
	// then use an STL container, as it makes for better code readability.
	//
	// Comparing the performance of base::LinkedList<T> to std::list<T*>:
	//
	// * Erasing an element of type T* from base::LinkedList<T> is
	// an O(1) operation. Whereas for std::list<T*> it is O(n).
	// That is because with std::list<T*> you must obtain an
	// iterator to the T* element before you can call erase(iterator).
	//
	// * Insertion operations with base::LinkedList<T> never require
	// heap allocations.
	//
	// Q. How does base::LinkedList implementation differ from std::list?
	//
	// A. Doubly-linked lists are made up of nodes that contain "next" and
	// "previous" pointers that reference other nodes in the list.
	//
	// With base::LinkedList<T>, the type being inserted already reserves
	// space for the "next" and "previous" pointers (base::LinkNode<T>*).
	// Whereas with std::list<T> the type can be anything, so the implementation
	// needs to glue on the "next" and "previous" pointers using
	// some internal node type.

	// Forward declarations of the types in order for recursive referencing and friending.
	template <typename T>
	class LinkNode;
	template <typename T>
	class LinkedList;

	template <typename T>
	class LinkNode {
	public:
	LinkNode() : previous_(nullptr), next_(nullptr) {
	}
	LinkNode(LinkNode<T>* previous, LinkNode<T>* next) : previous_(previous), next_(next) {
	}

	LinkNode(LinkNode<T>&& rhs) {
	next_ = rhs.next_;
	rhs.next_ = nullptr;
	previous_ = rhs.previous_;
	rhs.previous_ = nullptr;

	// If the node belongs to a list, next_ and previous_ are both non-null.
	// Otherwise, they are both null.
	if (next_) {
	next_->previous_ = this;
	previous_->next_ = this;
	}
	}

	// Insert \|this\| into the linked list, before \|e\|.
	void InsertBefore(LinkNode<T>* e) {
	this->next_ = e;
	this->previous_ = e->previous_;
	e->previous_->next_ = this;
	e->previous_ = this;
	}

	// Insert \|this\| into the linked list, after \|e\|.
	void InsertAfter(LinkNode<T>* e) {
	this->next_ = e->next_;
	this->previous_ = e;
	e->next_->previous_ = this;
	e->next_ = this;
	}

	// Check if \|this\| is in a list.
	bool IsInList() const {
	ASSERT((this->previous_ == nullptr) == (this->next_ == nullptr));
	return this->next_ != nullptr;
	}

	// Remove \|this\| from the linked list. Returns true iff removed from a list.
	bool RemoveFromList() {
	if (!IsInList()) {
	return false;
	}

	this->previous_->next_ = this->next_;
	this->next_->previous_ = this->previous_;
	// next() and previous() return non-null if and only this node is not in any list.
	this->next_ = nullptr;
	this->previous_ = nullptr;
	return true;
	}

	LinkNode<T>* previous() const {
	return previous_;
	}

	LinkNode<T>* next() const {
	return next_;
	}

	// Cast from the node-type to the value type.
	const T* value() const {
	return static_cast<const T*>(this);
	}

	T* value() {
	return static_cast<T*>(this);
	}

	private:
	friend class LinkedList<T>;
	LinkNode<T>* previous_;
	LinkNode<T>* next_;
	};

	template <typename T>
	class LinkedList {
	public:
	// The "root" node is self-referential, and forms the basis of a circular
	// list (root_.next() will point back to the start of the list,
	// and root_->previous() wraps around to the end of the list).
	LinkedList() : root_(&root_, &root_) {
	}

	~LinkedList() {
	// If any LinkNodes still exist in the LinkedList, there will be outstanding references to
	// root_ even after it has been freed. We should remove root_ from the list to prevent any
	// future access.
	root_.RemoveFromList();
	}

	// Appends \|e\| to the end of the linked list.
	void Append(LinkNode<T>* e) {
	e->InsertBefore(&root_);
	}

	// Moves all elements (in order) of the list and appends them into \|l\| leaving the list empty.
	void MoveInto(LinkedList<T>* l) {
	if (empty()) {
	return;
	}
	l->root_.previous_->next_ = root_.next_;
	root_.next_->previous_ = l->root_.previous_;
	l->root_.previous_ = root_.previous_;
	root_.previous_->next_ = &l->root_;

	root_.next_ = &root_;
	root_.previous_ = &root_;
	}

	LinkNode<T>* head() const {
	return root_.next();
	}

	LinkNode<T>* tail() const {
	return root_.previous();
	}

	const LinkNode<T>* end() const {
	return &root_;
	}

	bool empty() const {
	return head() == end();
	}

	private:
	LinkNode<T> root_;
	};

	template <typename T>
	class LinkedListIterator {
	public:
	LinkedListIterator(LinkNode<T>* node) : current_(node), next_(node->next()) {
	}

	// We keep an early reference to the next node in the list so that even if the current element
	// is modified or removed from the list, we have a valid next node.
	LinkedListIterator<T> const& operator++() {
	current_ = next_;
	next_ = current_->next();
	return *this;
	}

	bool operator!=(const LinkedListIterator<T>& other) const {
	return current_ != other.current_;
	}

	LinkNode<T>* operator*() const {
	return current_;
	}

	private:
	LinkNode<T>* current_;
	LinkNode<T>* next_;
	};

	template <typename T>
	LinkedListIterator<T> begin(LinkedList<T>& l) {
	return LinkedListIterator<T>(l.head());
	}

	// Free end function does't use LinkedList<T>::end because of it's const nature. Instead we wrap
	// around from tail.
	template <typename T>
	LinkedListIterator<T> end(LinkedList<T>& l) {
	return LinkedListIterator<T>(l.tail()->next());
	}

	#endif // COMMON_LINKED_LIST_H