sdk/lib/collection/linked_list.dart - sdk.git - Git at Google

 // Copyright (c) 2013, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 part of dart.collection;

 /// A specialized double-linked list of elements that extends [LinkedListEntry].
 ///
 /// This is not a generic data structure. It only accepts elements that *extend*
 /// the [LinkedListEntry] class. See the [Queue] implementations for generic
 /// collections that allow constant time adding and removing at the ends.
 ///
 /// This is not a [List] implementation. Despite its name, this class does not
 /// implement the [List] interface. It does not allow constant time lookup by
 /// index.
 ///
 /// Because the elements themselves contain the links of this linked list,
 /// each element can be in only one list at a time. To add an element to another
 /// list, it must first be removed from its current list (if any).
 /// For the same reason, the [remove] and [contains] methods
 /// are based on *identity*, even if the [LinkedListEntry] chooses
 /// to override [Object.==].
 ///
 /// In return, each element knows its own place in the linked list, as well as
 /// which list it is in. This allows constant time
 /// [LinkedListEntry.insertAfter], [LinkedListEntry.insertBefore] and
 /// [LinkedListEntry.unlink] operations when all you have is the element.
 ///
 /// A `LinkedList` also allows constant time adding and removing at either end,
 /// and a constant time length getter.
 ///
 /// Example:
 /// ```dart
 /// class EntryItem extends LinkedListEntry<EntryItem> {
 ///   final int id;
 ///   final String text;
 ///   EntryItem(this.id, this.text);
 ///
 ///   @override
 ///   String toString() {
 ///     return '$id : $text';
 ///   }
 /// }
 ///
 /// void main(){
 ///   final linkedList = LinkedList<EntryItem>();
 ///   linkedList.addAll(
 ///       [EntryItem(1, 'A'), EntryItem(2, 'B'), EntryItem(3, 'C')]);
 ///   print(linkedList.first); // 1 : A
 ///   print(linkedList.last); // 3 : C
 ///
 ///   // Add new item after first item.
 ///   linkedList.first.insertAfter(EntryItem(15, 'E'));
 ///   // Add new item before last item.
 ///   linkedList.last.insertBefore(EntryItem(10, 'D'));
 ///   // Iterate items.
 ///   for (var entry in linkedList) {
 ///     print(entry);
 ///     // 1 : A
 ///     // 15 : E
 ///     // 2 : B
 ///     // 10 : D
 ///     // 3 : C
 ///   }
 ///
 ///   // Remove item using index from list.
 ///   linkedList.elementAt(2).unlink();
 ///   print(linkedList); // (1 : A, 15 : E, 10 : D, 3 : C)
 ///   // Remove first item.
 ///   linkedList.first.unlink();
 ///   print(linkedList); // (15 : E, 10 : D, 3 : C)
 ///   // Remove last item from list.
 ///   linkedList.remove(linkedList.last);
 ///   print(linkedList); // (15 : E, 10 : D)
 ///   // Remove all items.
 ///   linkedList.clear();
 ///   print(linkedList.length); // 0
 ///   print(linkedList.isEmpty); // true
 /// }
 /// ```
 class LinkedList<E extends LinkedListEntry<E>> extends Iterable<E> {
   int _modificationCount = 0;
   int _length = 0;
   E? _first;

   /// Constructs a new empty linked list.
   LinkedList();

   /// Adds [entry] to the beginning of the linked list.
   void addFirst(E entry) {
     _insertBefore(_first, entry, updateFirst: true);
     _first = entry;
   }

   /// Adds [entry] to the end of the linked list.
   void add(E entry) {
     _insertBefore(_first, entry, updateFirst: false);
   }

   /// Adds [entries] to the end of the linked list.
   void addAll(Iterable<E> entries) {
     entries.forEach(add);
   }

   /// Removes [entry] from the linked list.
   ///
   /// Returns false and does nothing if [entry] is not in this linked list.
   ///
   /// This is equivalent to calling `entry.unlink()` if the entry is in this
   /// list.
   bool remove(E entry) {
     if (entry._list != this) return false;
     _unlink(entry); // Unlink will decrement length.
     return true;
   }

   /// Whether [entry] is a [LinkedListEntry] belonging to this list.
   ///
   /// The [entry] is considered as belonging to this list if
   /// its [LinkedListEntry.list] is this list.
   bool contains(Object? entry) =>
       entry is LinkedListEntry && identical(this, entry.list);

   Iterator<E> get iterator => _LinkedListIterator<E>(this);

   int get length => _length;

   /// Remove all elements from this linked list.
   void clear() {
     _modificationCount++;
     if (isEmpty) return;

     E next = _first!;
     do {
       E entry = next;
       next = entry._next!;
       entry._next = entry._previous = entry._list = null;
     } while (!identical(next, _first));

     _first = null;
     _length = 0;
   }

   E get first {
     if (isEmpty) {
       throw StateError('No such element');
     }
     return _first!;
   }

   E get last {
     if (isEmpty) {
       throw StateError('No such element');
     }
     return _first!._previous!;
   }

   E get single {
     if (isEmpty) {
       throw StateError('No such element');
     }
     if (_length > 1) {
       throw StateError('Too many elements');
     }
     return _first!;
   }

   /// Call [action] with each entry in this linked list.
   ///
   /// It's an error if [action] modifies the linked list.
   void forEach(void action(E entry)) {
     int modificationCount = _modificationCount;
     if (isEmpty) return;

     E current = _first!;
     do {
       action(current);
       if (modificationCount != _modificationCount) {
         throw ConcurrentModificationError(this);
       }
       current = current._next!;
     } while (!identical(current, _first));
   }

   bool get isEmpty => _length == 0;

   /// Inserts [newEntry] as last entry of the list.
   ///
   /// If [updateFirst] is true and [entry] is the first entry in the list,
   /// updates the [_first] field to point to the [newEntry] as first entry.
   void _insertBefore(E? entry, E newEntry, {required bool updateFirst}) {
     if (newEntry.list != null) {
       throw StateError('LinkedListEntry is already in a LinkedList');
     }
     _modificationCount++;

     newEntry._list = this;
     if (isEmpty) {
       assert(entry == null);
       newEntry._previous = newEntry._next = newEntry;
       _first = newEntry;
       _length++;
       return;
     }
     E predecessor = entry!._previous!;
     E successor = entry;
     newEntry._previous = predecessor;
     newEntry._next = successor;
     predecessor._next = newEntry;
     successor._previous = newEntry;
     if (updateFirst && identical(entry, _first)) {
       _first = newEntry;
     }
     _length++;
   }

   void _unlink(E entry) {
     _modificationCount++;
     entry._next!._previous = entry._previous;
     E? next = entry._previous!._next = entry._next;
     _length--;
     entry._list = entry._next = entry._previous = null;
     if (isEmpty) {
       _first = null;
     } else if (identical(entry, _first)) {
       _first = next;
     }
   }
 }

 class _LinkedListIterator<E extends LinkedListEntry<E>> implements Iterator<E> {
   final LinkedList<E> _list;
   final int _modificationCount;
   E? _current;
   E? _next;
   bool _visitedFirst;

   _LinkedListIterator(LinkedList<E> list)
       : _list = list,
         _modificationCount = list._modificationCount,
         _next = list._first,
         _visitedFirst = false;

   E get current => _current as E;

   bool moveNext() {
     if (_modificationCount != _list._modificationCount) {
       throw ConcurrentModificationError(this);
     }
     if (_list.isEmpty || (_visitedFirst && identical(_next, _list.first))) {
       _current = null;
       return false;
     }
     _visitedFirst = true;
     _current = _next;
     _next = _next!._next;
     return true;
   }
 }

 /// An object that can be an element in a [LinkedList].
 ///
 /// All elements of a `LinkedList` must extend this class.
 /// The class provides the internal links that link elements together
 /// in the `LinkedList`, and a reference to the linked list itself
 /// that an element is currently part of.
 ///
 /// An entry can be in at most one linked list at a time.
 /// While an entry is in a linked list, the [list] property points to that
 /// linked list, and otherwise the `list` property is `null`.
 ///
 /// When created, an entry is not in any linked list.
 abstract class LinkedListEntry<E extends LinkedListEntry<E>> {
   LinkedList<E>? _list;
   E? _next;
   E? _previous;

   /// The linked list containing this element.
   ///
   /// The value is `null` if this entry is not currently in any list.
   LinkedList<E>? get list => _list;

   /// Unlink the element from its linked list.
   ///
   /// The entry must currently be in a linked list when this method is called.
   void unlink() {
     _list!._unlink(this as E);
   }

   /// The successor of this element in its linked list.
   ///
   /// The value is `null` if there is no successor in the linked list,
   /// or if this entry is not currently in any list.
   E? get next {
     if (_list == null || identical(_list!.first, _next)) return null;
     return _next;
   }

   /// The predecessor of this element in its linked list.
   ///
   /// The value is `null` if there is no predecessor in the linked list,
   /// or if this entry is not currently in any list.
   E? get previous {
     if (_list == null || identical(this, _list!.first)) return null;
     return _previous;
   }

   /// Insert an element after this element in this element's linked list.
   ///
   /// This entry must be in a linked list when this method is called.
   /// The [entry] must not be in a linked list.
   void insertAfter(E entry) {
     _list!._insertBefore(_next, entry, updateFirst: false);
   }

   /// Insert an element before this element in this element's linked list.
   ///
   /// This entry must be in a linked list when this method is called.
   /// The [entry] must not be in a linked list.
   void insertBefore(E entry) {
     _list!._insertBefore(this as E, entry, updateFirst: true);
   }
 }
	// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	part of dart.collection;

	/// A specialized double-linked list of elements that extends [LinkedListEntry].
	///
	/// This is not a generic data structure. It only accepts elements that extend
	/// the [LinkedListEntry] class. See the [Queue] implementations for generic
	/// collections that allow constant time adding and removing at the ends.
	///
	/// This is not a [List] implementation. Despite its name, this class does not
	/// implement the [List] interface. It does not allow constant time lookup by
	/// index.
	///
	/// Because the elements themselves contain the links of this linked list,
	/// each element can be in only one list at a time. To add an element to another
	/// list, it must first be removed from its current list (if any).
	/// For the same reason, the [remove] and [contains] methods
	/// are based on identity, even if the [LinkedListEntry] chooses
	/// to override [Object.==].
	///
	/// In return, each element knows its own place in the linked list, as well as
	/// which list it is in. This allows constant time
	/// [LinkedListEntry.insertAfter], [LinkedListEntry.insertBefore] and
	/// [LinkedListEntry.unlink] operations when all you have is the element.
	///
	/// A `LinkedList` also allows constant time adding and removing at either end,
	/// and a constant time length getter.
	///
	/// Example:
	/// ```dart
	/// class EntryItem extends LinkedListEntry<EntryItem> {
	/// final int id;
	/// final String text;
	/// EntryItem(this.id, this.text);
	///
	/// @override
	/// String toString() {
	/// return '$id : $text';
	/// }
	/// }
	///
	/// void main(){
	/// final linkedList = LinkedList<EntryItem>();
	/// linkedList.addAll(
	/// [EntryItem(1, 'A'), EntryItem(2, 'B'), EntryItem(3, 'C')]);
	/// print(linkedList.first); // 1 : A
	/// print(linkedList.last); // 3 : C
	///
	/// // Add new item after first item.
	/// linkedList.first.insertAfter(EntryItem(15, 'E'));
	/// // Add new item before last item.
	/// linkedList.last.insertBefore(EntryItem(10, 'D'));
	/// // Iterate items.
	/// for (var entry in linkedList) {
	/// print(entry);
	/// // 1 : A
	/// // 15 : E
	/// // 2 : B
	/// // 10 : D
	/// // 3 : C
	/// }
	///
	/// // Remove item using index from list.
	/// linkedList.elementAt(2).unlink();
	/// print(linkedList); // (1 : A, 15 : E, 10 : D, 3 : C)
	/// // Remove first item.
	/// linkedList.first.unlink();
	/// print(linkedList); // (15 : E, 10 : D, 3 : C)
	/// // Remove last item from list.
	/// linkedList.remove(linkedList.last);
	/// print(linkedList); // (15 : E, 10 : D)
	/// // Remove all items.
	/// linkedList.clear();
	/// print(linkedList.length); // 0
	/// print(linkedList.isEmpty); // true
	/// }
	/// ```
	class LinkedList<E extends LinkedListEntry<E>> extends Iterable<E> {
	int _modificationCount = 0;
	int _length = 0;
	E? _first;

	/// Constructs a new empty linked list.
	LinkedList();

	/// Adds [entry] to the beginning of the linked list.
	void addFirst(E entry) {
	_insertBefore(_first, entry, updateFirst: true);
	_first = entry;
	}

	/// Adds [entry] to the end of the linked list.
	void add(E entry) {
	_insertBefore(_first, entry, updateFirst: false);
	}

	/// Adds [entries] to the end of the linked list.
	void addAll(Iterable<E> entries) {
	entries.forEach(add);
	}

	/// Removes [entry] from the linked list.
	///
	/// Returns false and does nothing if [entry] is not in this linked list.
	///
	/// This is equivalent to calling `entry.unlink()` if the entry is in this
	/// list.
	bool remove(E entry) {
	if (entry._list != this) return false;
	_unlink(entry); // Unlink will decrement length.
	return true;
	}

	/// Whether [entry] is a [LinkedListEntry] belonging to this list.
	///
	/// The [entry] is considered as belonging to this list if
	/// its [LinkedListEntry.list] is this list.
	bool contains(Object? entry) =>
	entry is LinkedListEntry && identical(this, entry.list);

	Iterator<E> get iterator => _LinkedListIterator<E>(this);

	int get length => _length;

	/// Remove all elements from this linked list.
	void clear() {
	_modificationCount++;
	if (isEmpty) return;

	E next = _first!;
	do {
	E entry = next;
	next = entry._next!;
	entry._next = entry._previous = entry._list = null;
	} while (!identical(next, _first));

	_first = null;
	_length = 0;
	}

	E get first {
	if (isEmpty) {
	throw StateError('No such element');
	}
	return _first!;
	}

	E get last {
	if (isEmpty) {
	throw StateError('No such element');
	}
	return _first!._previous!;
	}

	E get single {
	if (isEmpty) {
	throw StateError('No such element');
	}
	if (_length > 1) {
	throw StateError('Too many elements');
	}
	return _first!;
	}

	/// Call [action] with each entry in this linked list.
	///
	/// It's an error if [action] modifies the linked list.
	void forEach(void action(E entry)) {
	int modificationCount = _modificationCount;
	if (isEmpty) return;

	E current = _first!;
	do {
	action(current);
	if (modificationCount != _modificationCount) {
	throw ConcurrentModificationError(this);
	}
	current = current._next!;
	} while (!identical(current, _first));
	}

	bool get isEmpty => _length == 0;

	/// Inserts [newEntry] as last entry of the list.
	///
	/// If [updateFirst] is true and [entry] is the first entry in the list,
	/// updates the [_first] field to point to the [newEntry] as first entry.
	void _insertBefore(E? entry, E newEntry, {required bool updateFirst}) {
	if (newEntry.list != null) {
	throw StateError('LinkedListEntry is already in a LinkedList');
	}
	_modificationCount++;

	newEntry._list = this;
	if (isEmpty) {
	assert(entry == null);
	newEntry._previous = newEntry._next = newEntry;
	_first = newEntry;
	_length++;
	return;
	}
	E predecessor = entry!._previous!;
	E successor = entry;
	newEntry._previous = predecessor;
	newEntry._next = successor;
	predecessor._next = newEntry;
	successor._previous = newEntry;
	if (updateFirst && identical(entry, _first)) {
	_first = newEntry;
	}
	_length++;
	}

	void _unlink(E entry) {
	_modificationCount++;
	entry._next!._previous = entry._previous;
	E? next = entry._previous!._next = entry._next;
	_length--;
	entry._list = entry._next = entry._previous = null;
	if (isEmpty) {
	_first = null;
	} else if (identical(entry, _first)) {
	_first = next;
	}
	}
	}

	class _LinkedListIterator<E extends LinkedListEntry<E>> implements Iterator<E> {
	final LinkedList<E> _list;
	final int _modificationCount;
	E? _current;
	E? _next;
	bool _visitedFirst;

	_LinkedListIterator(LinkedList<E> list)
	: _list = list,
	_modificationCount = list._modificationCount,
	_next = list._first,
	_visitedFirst = false;

	E get current => _current as E;

	bool moveNext() {
	if (_modificationCount != _list._modificationCount) {
	throw ConcurrentModificationError(this);
	}
	if (_list.isEmpty \|\| (_visitedFirst && identical(_next, _list.first))) {
	_current = null;
	return false;
	}
	_visitedFirst = true;
	_current = _next;
	_next = _next!._next;
	return true;
	}
	}

	/// An object that can be an element in a [LinkedList].
	///
	/// All elements of a `LinkedList` must extend this class.
	/// The class provides the internal links that link elements together
	/// in the `LinkedList`, and a reference to the linked list itself
	/// that an element is currently part of.
	///
	/// An entry can be in at most one linked list at a time.
	/// While an entry is in a linked list, the [list] property points to that
	/// linked list, and otherwise the `list` property is `null`.
	///
	/// When created, an entry is not in any linked list.
	abstract class LinkedListEntry<E extends LinkedListEntry<E>> {
	LinkedList<E>? _list;
	E? _next;
	E? _previous;

	/// The linked list containing this element.
	///
	/// The value is `null` if this entry is not currently in any list.
	LinkedList<E>? get list => _list;

	/// Unlink the element from its linked list.
	///
	/// The entry must currently be in a linked list when this method is called.
	void unlink() {
	_list!._unlink(this as E);
	}

	/// The successor of this element in its linked list.
	///
	/// The value is `null` if there is no successor in the linked list,
	/// or if this entry is not currently in any list.
	E? get next {
	if (_list == null \|\| identical(_list!.first, _next)) return null;
	return _next;
	}

	/// The predecessor of this element in its linked list.
	///
	/// The value is `null` if there is no predecessor in the linked list,
	/// or if this entry is not currently in any list.
	E? get previous {
	if (_list == null \|\| identical(this, _list!.first)) return null;
	return _previous;
	}

	/// Insert an element after this element in this element's linked list.
	///
	/// This entry must be in a linked list when this method is called.
	/// The [entry] must not be in a linked list.
	void insertAfter(E entry) {
	_list!._insertBefore(_next, entry, updateFirst: false);
	}

	/// Insert an element before this element in this element's linked list.
	///
	/// This entry must be in a linked list when this method is called.
	/// The [entry] must not be in a linked list.
	void insertBefore(E entry) {
	_list!._insertBefore(this as E, entry, updateFirst: true);
	}
	}