• Java集合基于JDK1.8的LinkedList源码分析


    上篇我们分析了ArrayList的底层实现,知道了ArrayList底层是基于数组实现的,因此具有查找修改快而插入删除慢的特点。本篇介绍的LinkedList是List接口的另一种实现,它的底层是基于双向链表实现的,因此它具有插入删除快而查找修改慢的特点,此外,通过对双向链表的操作还可以实现队列和栈的功能。LinkedList的底层结构如下图所示。

    F表示头结点引用,L表示尾结点引用,链表的每个结点都有三个元素,分别是前继结点引用(P),结点元素的值(E),后继结点的引用(N)。结点由内部类Node表示,我们看看它的内部结构。

    //结点内部类
    private static class Node<E> {
        E item;          //元素
        Node<E> next;    //下一个节点
        Node<E> prev;    //上一个节点
    
        Node(Node<E> prev, E element, Node<E> next) {
            this.item = element;
            this.next = next;
            this.prev = prev;
        }
    }
    

    Node这个内部类其实很简单,只有三个成员变量和一个构造器,item表示结点的值,next为下一个结点的引用,prev为上一个结点的引用,通过构造器传入这三个值。接下来再看看LinkedList的成员变量和构造器。

    //集合元素个数
    transient int size = 0;
    
    //头结点引用
    transient Node<E> first;
    
    //尾节点引用
    transient Node<E> last;
    
    //无参构造器
    public LinkedList() {}
    
    //传入外部集合的构造器
    public LinkedList(Collection<? extends E> c) {
        this();
        addAll(c);
    }
    

    LinkedList持有头结点的引用和尾结点的引用,它有两个构造器,一个是无参构造器,一个是传入外部集合的构造器。与ArrayList不同的是LinkedList没有指定初始大小的构造器。看看它的增删改查方法。

    //增(添加)
    public boolean add(E e) {
        //在链表尾部添加
        linkLast(e);
        return true;
    }
    
    //增(插入)
    public void add(int index, E element) {
    		//判定index位置的合法性,index >= 0 && index <= size才可以
        checkPositionIndex(index);
        //如果插入的index等于size,则表示index是最后一个
        if (index == size) {
            //在链表尾部添加
            linkLast(element);
        } else {
            //在链表中部插入
            //传入的参数为当前的值element和index处的节点node(index)
            linkBefore(element, node(index));
        }
    }
    
    //删(给定下标)
    public E remove(int index) {
        //检查下标是否合法,index >= 0 && index <= size才可以
        checkElementIndex(index);
        //unlink方法的参数是index处的节点
        return unlink(node(index));
    }
    
    //删(给定元素)
    public boolean remove(Object o) {
        if (o == null) {
        		//遍历整个链表删除
            for (Node<E> x = first; x != null; x = x.next) {
                if (x.item == null) {
                    unlink(x);
                    return true;
                }
            }
        } else {
            //遍历整个链表删除
            for (Node<E> x = first; x != null; x = x.next) {
                if (o.equals(x.item)) {
                    //找到了就删除
                    unlink(x);
                    return true;
                }
            }
        }
        return false;
    }
    
    //改
    public E set(int index, E element) {
        //检查下标是否合法
        checkElementIndex(index);
        //获取指定下标的结点引用
        Node<E> x = node(index);
        //获取指定下标结点的值
        E oldVal = x.item;
        //将结点元素设置为新的值
        x.item = element;
        //返回之前的值
        return oldVal;
    }
    
    //查
    public E get(int index) {
        //检查下标是否合法
        checkElementIndex(index);
        //返回指定下标的结点的值
        return node(index).item;
    }
    

    插入节点的具体方法

    //链接到指定结点之前
    void linkBefore(E e, Node<E> succ) {
        //获取给定结点的上一个结点引用
        final Node<E> pred = succ.prev;
        //创建新结点, 新结点的上一个结点引用指向给定结点的上一个结点
        //新结点的下一个结点的引用指向给定的结点
        final Node<E> newNode = new Node<>(pred, e, succ);
        //将给定结点的上一个结点引用指向新结点
        succ.prev = newNode;
        //如果给定结点的上一个结点为空, 表明给定结点为头结点
        if (pred == null) {
            //将头结点引用指向新结点
            first = newNode;
        } else {
            //否则, 将给定结点的上一个结点的下一个结点引用指向新结点
            pred.next = newNode;
        }
        //集合元素个数加一
        size++;
        //修改次数加一
        modCount++;
    }
    
    //卸载指定结点
    E unlink(Node<E> x) {
        //获取给定结点的元素
        final E element = x.item;
        //获取给定结点的下一个结点的引用
        final Node<E> next = x.next;
        //获取给定结点的上一个结点的引用
        final Node<E> prev = x.prev;
    
        //如果给定结点的上一个结点为空, 说明给定结点为头结点
        if (prev == null) {
            //将头结点引用指向给定结点的下一个结点
            first = next;
        } else {
            //将上一个结点的后继结点引用指向给定结点的后继结点
            prev.next = next;
            //将给定结点的上一个结点置空
            x.prev = null;
        }
    
        //如果给定结点的下一个结点为空, 说明给定结点为尾结点
        if (next == null) {
            //将尾结点引用指向给定结点的上一个结点
            last = prev;
        } else {
            //将下一个结点的前继结点引用指向给定结点的前继结点
            next.prev = prev;
            x.next = null;
        }
    
        //将给定结点的元素置空
        x.item = null;
        //集合元素个数减一
        size--;
        //修改次数加一
        modCount++;
        return element;
    }
    

    linkBefore和unlink是具有代表性的链接结点和卸载结点的操作,其他的链接和卸载两端结点的方法与此类似,所以我们重点介绍linkBefore和unlink方法。

    linkBefore方法的过程图:

    unlink方法的过程图:

    通过上面图示看到对链表的插入和删除操作的时间复杂度都是O(1),而对链表的查找和修改操作都需要遍历链表进行元素的定位,这两个操作都是调用的node(int index)方法定位元素,看看它是怎样通过下标来定位元素的。

    //根据指定位置获取结点
    Node<E> node(int index) {
        //如果下标在链表前半部分, 就从头开始查起.size >> 1值为size/2
        if (index < (size >> 1)) {
            Node<E> x = first;
            for (int i = 0; i < index; i++) {
                x = x.next;
            }
            return x;
        } else {
            //如果下标在链表后半部分, 就从尾开始查起
            Node<E> x = last;
            for (int i = size - 1; i > index; i--) {
                x = x.prev;
            }
            return x;
        }
    }
    

    通过下标定位时先判断是在链表的上半部分还是下半部分,如果是在上半部分就从头开始找起,如果是下半部分就从尾开始找起,因此通过下标的查找和修改操作的时间复杂度是O(n/2)。通过对双向链表的操作还可以实现单项队列,双向队列和栈的功能。

    单向队列操作:

    //获取头结点
    public E peek() {
        final Node<E> f = first;
        return (f == null) ? null : f.item;
    }
    
    //获取头结点
    public E element() {
        return getFirst();
    }
    
    //弹出头结点
    public E poll() {
        final Node<E> f = first;
        return (f == null) ? null : unlinkFirst(f);
    }
    
    //移除头结点
    public E remove() {
        return removeFirst();
    }
    
    //在队列尾部添加结点
    public boolean offer(E e) {
        return add(e);
    }
    

    双向队列操作:

    //在头部添加
    public boolean offerFirst(E e) {
        addFirst(e);
        return true;
    }
    
    //在尾部添加
    public boolean offerLast(E e) {
        addLast(e);
        return true;
    }
    
    //获取头结点
    public E peekFirst() {
        final Node<E> f = first;
        return (f == null) ? null : f.item;
     }
    
    //获取尾结点
    public E peekLast() {
        final Node<E> l = last;
        return (l == null) ? null : l.item;
    }
    

    栈操作:

    //入栈
    public void push(E e) {
        addFirst(e);
    }
    
    //出栈
    public E pop() {
        return removeFirst();
    }
    

    不管是单向队列还是双向队列还是栈,其实都是对链表的头结点和尾结点进行操作,它们的实现都是基于addFirst(),addLast(),removeFirst(),removeLast()这四个方法,它们的操作和linkBefore()和unlink()类似,只不过一个是对链表两端操作,一个是对链表中间操作。可以说这四个方法都是linkBefore()和unlink()方法的特殊情况,因此不难理解它们的内部实现,在此不多做介绍。

    到这里,我们对LinkedList的分析也即将结束,对全文中的重点做个总结:

    1. LinkedList是基于双向链表实现的,不论是增删改查方法还是队列和栈的实现,都可通过操作结点实现
    
    2. LinkedList无需提前指定容量,因为基于链表操作,集合的容量随着元素的加入自动增加
    
    3. LinkedList删除元素后集合占用的内存自动缩小,无需像ArrayList一样调用trimToSize()方法
    
    4. LinkedList的所有方法没有进行同步,因此它也不是线程安全的,应该避免在多线程环境下使用
    
    5. 以上分析基于JDK1.8,其他版本会有些出入,因此不能一概而论
    

    LinkedList源码JDK1.8

    /*
     * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
     * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
     *
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     *
     */
    
    package java.util;
    
    import java.util.function.Consumer;
    
    /**
     * Doubly-linked list implementation of the {@code List} and {@code Deque}
     * interfaces.  Implements all optional list operations, and permits all
     * elements (including {@code null}).
     *
     * <p>All of the operations perform as could be expected for a doubly-linked
     * list.  Operations that index into the list will traverse the list from
     * the beginning or the end, whichever is closer to the specified index.
     *
     * <p><strong>Note that this implementation is not synchronized.</strong>
     * If multiple threads access a linked list concurrently, and at least
     * one of the threads modifies the list structurally, it <i>must</i> be
     * synchronized externally.  (A structural modification is any operation
     * that adds or deletes one or more elements; merely setting the value of
     * an element is not a structural modification.)  This is typically
     * accomplished by synchronizing on some object that naturally
     * encapsulates the list.
     *
     * If no such object exists, the list should be "wrapped" using the
     * {@link Collections#synchronizedList Collections.synchronizedList}
     * method.  This is best done at creation time, to prevent accidental
     * unsynchronized access to the list:<pre>
     *   List list = Collections.synchronizedList(new LinkedList(...));</pre>
     *
     * <p>The iterators returned by this class's {@code iterator} and
     * {@code listIterator} methods are <i>fail-fast</i>: if the list is
     * structurally modified at any time after the iterator is created, in
     * any way except through the Iterator's own {@code remove} or
     * {@code add} methods, the iterator will throw a {@link
     * ConcurrentModificationException}.  Thus, in the face of concurrent
     * modification, the iterator fails quickly and cleanly, rather than
     * risking arbitrary, non-deterministic behavior at an undetermined
     * time in the future.
     *
     * <p>Note that the fail-fast behavior of an iterator cannot be guaranteed
     * as it is, generally speaking, impossible to make any hard guarantees in the
     * presence of unsynchronized concurrent modification.  Fail-fast iterators
     * throw {@code ConcurrentModificationException} on a best-effort basis.
     * Therefore, it would be wrong to write a program that depended on this
     * exception for its correctness:   <i>the fail-fast behavior of iterators
     * should be used only to detect bugs.</i>
     *
     * <p>This class is a member of the
     * <a href="{@docRoot}/../technotes/guides/collections/index.html">
     * Java Collections Framework</a>.
     *
     * @author  Josh Bloch
     * @see     List
     * @see     ArrayList
     * @since 1.2
     * @param <E> the type of elements held in this collection
     */
    
    public class LinkedList<E>
        extends AbstractSequentialList<E>
        implements List<E>, Deque<E>, Cloneable, java.io.Serializable
    {
        transient int size = 0;
    
        /**
         * Pointer to first node.
         * Invariant: (first == null && last == null) ||
         *            (first.prev == null && first.item != null)
         */
        transient Node<E> first;
    
        /**
         * Pointer to last node.
         * Invariant: (first == null && last == null) ||
         *            (last.next == null && last.item != null)
         */
        transient Node<E> last;
    
        /**
         * Constructs an empty list.
         */
        public LinkedList() {
        }
    
        /**
         * Constructs a list containing the elements of the specified
         * collection, in the order they are returned by the collection's
         * iterator.
         *
         * @param  c the collection whose elements are to be placed into this list
         * @throws NullPointerException if the specified collection is null
         */
        public LinkedList(Collection<? extends E> c) {
            this();
            addAll(c);
        }
    
        /**
         * Links e as first element.
         */
        private void linkFirst(E e) {
            final Node<E> f = first;
            final Node<E> newNode = new Node<>(null, e, f);
            first = newNode;
            if (f == null)
                last = newNode;
            else
                f.prev = newNode;
            size++;
            modCount++;
        }
    
        /**
         * Links e as last element.
         */
        void linkLast(E e) {
            final Node<E> l = last;
            final Node<E> newNode = new Node<>(l, e, null);
            last = newNode;
            if (l == null)
                first = newNode;
            else
                l.next = newNode;
            size++;
            modCount++;
        }
    
        /**
         * Inserts element e before non-null Node succ.
         */
        void linkBefore(E e, Node<E> succ) {
            // assert succ != null;
            final Node<E> pred = succ.prev;
            final Node<E> newNode = new Node<>(pred, e, succ);
            succ.prev = newNode;
            if (pred == null)
                first = newNode;
            else
                pred.next = newNode;
            size++;
            modCount++;
        }
    
        /**
         * Unlinks non-null first node f.
         */
        private E unlinkFirst(Node<E> f) {
            // assert f == first && f != null;
            final E element = f.item;
            final Node<E> next = f.next;
            f.item = null;
            f.next = null; // help GC
            first = next;
            if (next == null)
                last = null;
            else
                next.prev = null;
            size--;
            modCount++;
            return element;
        }
    
        /**
         * Unlinks non-null last node l.
         */
        private E unlinkLast(Node<E> l) {
            // assert l == last && l != null;
            final E element = l.item;
            final Node<E> prev = l.prev;
            l.item = null;
            l.prev = null; // help GC
            last = prev;
            if (prev == null)
                first = null;
            else
                prev.next = null;
            size--;
            modCount++;
            return element;
        }
    
        /**
         * Unlinks non-null node x.
         */
        E unlink(Node<E> x) {
            // assert x != null;
            final E element = x.item;
            final Node<E> next = x.next;
            final Node<E> prev = x.prev;
    
            if (prev == null) {
                first = next;
            } else {
                prev.next = next;
                x.prev = null;
            }
    
            if (next == null) {
                last = prev;
            } else {
                next.prev = prev;
                x.next = null;
            }
    
            x.item = null;
            size--;
            modCount++;
            return element;
        }
    
        /**
         * Returns the first element in this list.
         *
         * @return the first element in this list
         * @throws NoSuchElementException if this list is empty
         */
        public E getFirst() {
            final Node<E> f = first;
            if (f == null)
                throw new NoSuchElementException();
            return f.item;
        }
    
        /**
         * Returns the last element in this list.
         *
         * @return the last element in this list
         * @throws NoSuchElementException if this list is empty
         */
        public E getLast() {
            final Node<E> l = last;
            if (l == null)
                throw new NoSuchElementException();
            return l.item;
        }
    
        /**
         * Removes and returns the first element from this list.
         *
         * @return the first element from this list
         * @throws NoSuchElementException if this list is empty
         */
        public E removeFirst() {
            final Node<E> f = first;
            if (f == null)
                throw new NoSuchElementException();
            return unlinkFirst(f);
        }
    
        /**
         * Removes and returns the last element from this list.
         *
         * @return the last element from this list
         * @throws NoSuchElementException if this list is empty
         */
        public E removeLast() {
            final Node<E> l = last;
            if (l == null)
                throw new NoSuchElementException();
            return unlinkLast(l);
        }
    
        /**
         * Inserts the specified element at the beginning of this list.
         *
         * @param e the element to add
         */
        public void addFirst(E e) {
            linkFirst(e);
        }
    
        /**
         * Appends the specified element to the end of this list.
         *
         * <p>This method is equivalent to {@link #add}.
         *
         * @param e the element to add
         */
        public void addLast(E e) {
            linkLast(e);
        }
    
        /**
         * Returns {@code true} if this list contains the specified element.
         * More formally, returns {@code true} if and only if this list contains
         * at least one element {@code e} such that
         * <tt>(o==null&nbsp;?&nbsp;e==null&nbsp;:&nbsp;o.equals(e))</tt>.
         *
         * @param o element whose presence in this list is to be tested
         * @return {@code true} if this list contains the specified element
         */
        public boolean contains(Object o) {
            return indexOf(o) != -1;
        }
    
        /**
         * Returns the number of elements in this list.
         *
         * @return the number of elements in this list
         */
        public int size() {
            return size;
        }
    
        /**
         * Appends the specified element to the end of this list.
         *
         * <p>This method is equivalent to {@link #addLast}.
         *
         * @param e element to be appended to this list
         * @return {@code true} (as specified by {@link Collection#add})
         */
        public boolean add(E e) {
            linkLast(e);
            return true;
        }
    
        /**
         * Removes the first occurrence of the specified element from this list,
         * if it is present.  If this list does not contain the element, it is
         * unchanged.  More formally, removes the element with the lowest index
         * {@code i} such that
         * <tt>(o==null&nbsp;?&nbsp;get(i)==null&nbsp;:&nbsp;o.equals(get(i)))</tt>
         * (if such an element exists).  Returns {@code true} if this list
         * contained the specified element (or equivalently, if this list
         * changed as a result of the call).
         *
         * @param o element to be removed from this list, if present
         * @return {@code true} if this list contained the specified element
         */
        public boolean remove(Object o) {
            if (o == null) {
                for (Node<E> x = first; x != null; x = x.next) {
                    if (x.item == null) {
                        unlink(x);
                        return true;
                    }
                }
            } else {
                for (Node<E> x = first; x != null; x = x.next) {
                    if (o.equals(x.item)) {
                        unlink(x);
                        return true;
                    }
                }
            }
            return false;
        }
    
        /**
         * Appends all of the elements in the specified collection to the end of
         * this list, in the order that they are returned by the specified
         * collection's iterator.  The behavior of this operation is undefined if
         * the specified collection is modified while the operation is in
         * progress.  (Note that this will occur if the specified collection is
         * this list, and it's nonempty.)
         *
         * @param c collection containing elements to be added to this list
         * @return {@code true} if this list changed as a result of the call
         * @throws NullPointerException if the specified collection is null
         */
        public boolean addAll(Collection<? extends E> c) {
            return addAll(size, c);
        }
    
        /**
         * Inserts all of the elements in the specified collection into this
         * list, starting at the specified position.  Shifts the element
         * currently at that position (if any) and any subsequent elements to
         * the right (increases their indices).  The new elements will appear
         * in the list in the order that they are returned by the
         * specified collection's iterator.
         *
         * @param index index at which to insert the first element
         *              from the specified collection
         * @param c collection containing elements to be added to this list
         * @return {@code true} if this list changed as a result of the call
         * @throws IndexOutOfBoundsException {@inheritDoc}
         * @throws NullPointerException if the specified collection is null
         */
        public boolean addAll(int index, Collection<? extends E> c) {
            checkPositionIndex(index);
    
            Object[] a = c.toArray();
            int numNew = a.length;
            if (numNew == 0)
                return false;
    
            Node<E> pred, succ;
            if (index == size) {
                succ = null;
                pred = last;
            } else {
                succ = node(index);
                pred = succ.prev;
            }
    
            for (Object o : a) {
                @SuppressWarnings("unchecked") E e = (E) o;
                Node<E> newNode = new Node<>(pred, e, null);
                if (pred == null)
                    first = newNode;
                else
                    pred.next = newNode;
                pred = newNode;
            }
    
            if (succ == null) {
                last = pred;
            } else {
                pred.next = succ;
                succ.prev = pred;
            }
    
            size += numNew;
            modCount++;
            return true;
        }
    
        /**
         * Removes all of the elements from this list.
         * The list will be empty after this call returns.
         */
        public void clear() {
            // Clearing all of the links between nodes is "unnecessary", but:
            // - helps a generational GC if the discarded nodes inhabit
            //   more than one generation
            // - is sure to free memory even if there is a reachable Iterator
            for (Node<E> x = first; x != null; ) {
                Node<E> next = x.next;
                x.item = null;
                x.next = null;
                x.prev = null;
                x = next;
            }
            first = last = null;
            size = 0;
            modCount++;
        }
    
    
        // Positional Access Operations
    
        /**
         * Returns the element at the specified position in this list.
         *
         * @param index index of the element to return
         * @return the element at the specified position in this list
         * @throws IndexOutOfBoundsException {@inheritDoc}
         */
        public E get(int index) {
            checkElementIndex(index);
            return node(index).item;
        }
    
        /**
         * Replaces the element at the specified position in this list with the
         * specified element.
         *
         * @param index index of the element to replace
         * @param element element to be stored at the specified position
         * @return the element previously at the specified position
         * @throws IndexOutOfBoundsException {@inheritDoc}
         */
        public E set(int index, E element) {
            checkElementIndex(index);
            Node<E> x = node(index);
            E oldVal = x.item;
            x.item = element;
            return oldVal;
        }
    
        /**
         * Inserts the specified element at the specified position in this list.
         * Shifts the element currently at that position (if any) and any
         * subsequent elements to the right (adds one to their indices).
         *
         * @param index index at which the specified element is to be inserted
         * @param element element to be inserted
         * @throws IndexOutOfBoundsException {@inheritDoc}
         */
        public void add(int index, E element) {
            checkPositionIndex(index);
    
            if (index == size)
                linkLast(element);
            else
                linkBefore(element, node(index));
        }
    
        /**
         * Removes the element at the specified position in this list.  Shifts any
         * subsequent elements to the left (subtracts one from their indices).
         * Returns the element that was removed from the list.
         *
         * @param index the index of the element to be removed
         * @return the element previously at the specified position
         * @throws IndexOutOfBoundsException {@inheritDoc}
         */
        public E remove(int index) {
            checkElementIndex(index);
            return unlink(node(index));
        }
    
        /**
         * Tells if the argument is the index of an existing element.
         */
        private boolean isElementIndex(int index) {
            return index >= 0 && index < size;
        }
    
        /**
         * Tells if the argument is the index of a valid position for an
         * iterator or an add operation.
         */
        private boolean isPositionIndex(int index) {
            return index >= 0 && index <= size;
        }
    
        /**
         * Constructs an IndexOutOfBoundsException detail message.
         * Of the many possible refactorings of the error handling code,
         * this "outlining" performs best with both server and client VMs.
         */
        private String outOfBoundsMsg(int index) {
            return "Index: "+index+", Size: "+size;
        }
    
        private void checkElementIndex(int index) {
            if (!isElementIndex(index))
                throw new IndexOutOfBoundsException(outOfBoundsMsg(index));
        }
    
        private void checkPositionIndex(int index) {
            if (!isPositionIndex(index))
                throw new IndexOutOfBoundsException(outOfBoundsMsg(index));
        }
    
        /**
         * Returns the (non-null) Node at the specified element index.
         */
        Node<E> node(int index) {
            // assert isElementIndex(index);
    
            if (index < (size >> 1)) {
                Node<E> x = first;
                for (int i = 0; i < index; i++)
                    x = x.next;
                return x;
            } else {
                Node<E> x = last;
                for (int i = size - 1; i > index; i--)
                    x = x.prev;
                return x;
            }
        }
    
        // Search Operations
    
        /**
         * Returns the index of the first occurrence of the specified element
         * in this list, or -1 if this list does not contain the element.
         * More formally, returns the lowest index {@code i} such that
         * <tt>(o==null&nbsp;?&nbsp;get(i)==null&nbsp;:&nbsp;o.equals(get(i)))</tt>,
         * or -1 if there is no such index.
         *
         * @param o element to search for
         * @return the index of the first occurrence of the specified element in
         *         this list, or -1 if this list does not contain the element
         */
        public int indexOf(Object o) {
            int index = 0;
            if (o == null) {
                for (Node<E> x = first; x != null; x = x.next) {
                    if (x.item == null)
                        return index;
                    index++;
                }
            } else {
                for (Node<E> x = first; x != null; x = x.next) {
                    if (o.equals(x.item))
                        return index;
                    index++;
                }
            }
            return -1;
        }
    
        /**
         * Returns the index of the last occurrence of the specified element
         * in this list, or -1 if this list does not contain the element.
         * More formally, returns the highest index {@code i} such that
         * <tt>(o==null&nbsp;?&nbsp;get(i)==null&nbsp;:&nbsp;o.equals(get(i)))</tt>,
         * or -1 if there is no such index.
         *
         * @param o element to search for
         * @return the index of the last occurrence of the specified element in
         *         this list, or -1 if this list does not contain the element
         */
        public int lastIndexOf(Object o) {
            int index = size;
            if (o == null) {
                for (Node<E> x = last; x != null; x = x.prev) {
                    index--;
                    if (x.item == null)
                        return index;
                }
            } else {
                for (Node<E> x = last; x != null; x = x.prev) {
                    index--;
                    if (o.equals(x.item))
                        return index;
                }
            }
            return -1;
        }
    
        // Queue operations.
    
        /**
         * Retrieves, but does not remove, the head (first element) of this list.
         *
         * @return the head of this list, or {@code null} if this list is empty
         * @since 1.5
         */
        public E peek() {
            final Node<E> f = first;
            return (f == null) ? null : f.item;
        }
    
        /**
         * Retrieves, but does not remove, the head (first element) of this list.
         *
         * @return the head of this list
         * @throws NoSuchElementException if this list is empty
         * @since 1.5
         */
        public E element() {
            return getFirst();
        }
    
        /**
         * Retrieves and removes the head (first element) of this list.
         *
         * @return the head of this list, or {@code null} if this list is empty
         * @since 1.5
         */
        public E poll() {
            final Node<E> f = first;
            return (f == null) ? null : unlinkFirst(f);
        }
    
        /**
         * Retrieves and removes the head (first element) of this list.
         *
         * @return the head of this list
         * @throws NoSuchElementException if this list is empty
         * @since 1.5
         */
        public E remove() {
            return removeFirst();
        }
    
        /**
         * Adds the specified element as the tail (last element) of this list.
         *
         * @param e the element to add
         * @return {@code true} (as specified by {@link Queue#offer})
         * @since 1.5
         */
        public boolean offer(E e) {
            return add(e);
        }
    
        // Deque operations
        /**
         * Inserts the specified element at the front of this list.
         *
         * @param e the element to insert
         * @return {@code true} (as specified by {@link Deque#offerFirst})
         * @since 1.6
         */
        public boolean offerFirst(E e) {
            addFirst(e);
            return true;
        }
    
        /**
         * Inserts the specified element at the end of this list.
         *
         * @param e the element to insert
         * @return {@code true} (as specified by {@link Deque#offerLast})
         * @since 1.6
         */
        public boolean offerLast(E e) {
            addLast(e);
            return true;
        }
    
        /**
         * Retrieves, but does not remove, the first element of this list,
         * or returns {@code null} if this list is empty.
         *
         * @return the first element of this list, or {@code null}
         *         if this list is empty
         * @since 1.6
         */
        public E peekFirst() {
            final Node<E> f = first;
            return (f == null) ? null : f.item;
         }
    
        /**
         * Retrieves, but does not remove, the last element of this list,
         * or returns {@code null} if this list is empty.
         *
         * @return the last element of this list, or {@code null}
         *         if this list is empty
         * @since 1.6
         */
        public E peekLast() {
            final Node<E> l = last;
            return (l == null) ? null : l.item;
        }
    
        /**
         * Retrieves and removes the first element of this list,
         * or returns {@code null} if this list is empty.
         *
         * @return the first element of this list, or {@code null} if
         *     this list is empty
         * @since 1.6
         */
        public E pollFirst() {
            final Node<E> f = first;
            return (f == null) ? null : unlinkFirst(f);
        }
    
        /**
         * Retrieves and removes the last element of this list,
         * or returns {@code null} if this list is empty.
         *
         * @return the last element of this list, or {@code null} if
         *     this list is empty
         * @since 1.6
         */
        public E pollLast() {
            final Node<E> l = last;
            return (l == null) ? null : unlinkLast(l);
        }
    
        /**
         * Pushes an element onto the stack represented by this list.  In other
         * words, inserts the element at the front of this list.
         *
         * <p>This method is equivalent to {@link #addFirst}.
         *
         * @param e the element to push
         * @since 1.6
         */
        public void push(E e) {
            addFirst(e);
        }
    
        /**
         * Pops an element from the stack represented by this list.  In other
         * words, removes and returns the first element of this list.
         *
         * <p>This method is equivalent to {@link #removeFirst()}.
         *
         * @return the element at the front of this list (which is the top
         *         of the stack represented by this list)
         * @throws NoSuchElementException if this list is empty
         * @since 1.6
         */
        public E pop() {
            return removeFirst();
        }
    
        /**
         * Removes the first occurrence of the specified element in this
         * list (when traversing the list from head to tail).  If the list
         * does not contain the element, it is unchanged.
         *
         * @param o element to be removed from this list, if present
         * @return {@code true} if the list contained the specified element
         * @since 1.6
         */
        public boolean removeFirstOccurrence(Object o) {
            return remove(o);
        }
    
        /**
         * Removes the last occurrence of the specified element in this
         * list (when traversing the list from head to tail).  If the list
         * does not contain the element, it is unchanged.
         *
         * @param o element to be removed from this list, if present
         * @return {@code true} if the list contained the specified element
         * @since 1.6
         */
        public boolean removeLastOccurrence(Object o) {
            if (o == null) {
                for (Node<E> x = last; x != null; x = x.prev) {
                    if (x.item == null) {
                        unlink(x);
                        return true;
                    }
                }
            } else {
                for (Node<E> x = last; x != null; x = x.prev) {
                    if (o.equals(x.item)) {
                        unlink(x);
                        return true;
                    }
                }
            }
            return false;
        }
    
        /**
         * Returns a list-iterator of the elements in this list (in proper
         * sequence), starting at the specified position in the list.
         * Obeys the general contract of {@code List.listIterator(int)}.<p>
         *
         * The list-iterator is <i>fail-fast</i>: if the list is structurally
         * modified at any time after the Iterator is created, in any way except
         * through the list-iterator's own {@code remove} or {@code add}
         * methods, the list-iterator will throw a
         * {@code ConcurrentModificationException}.  Thus, in the face of
         * concurrent modification, the iterator fails quickly and cleanly, rather
         * than risking arbitrary, non-deterministic behavior at an undetermined
         * time in the future.
         *
         * @param index index of the first element to be returned from the
         *              list-iterator (by a call to {@code next})
         * @return a ListIterator of the elements in this list (in proper
         *         sequence), starting at the specified position in the list
         * @throws IndexOutOfBoundsException {@inheritDoc}
         * @see List#listIterator(int)
         */
        public ListIterator<E> listIterator(int index) {
            checkPositionIndex(index);
            return new ListItr(index);
        }
    
        private class ListItr implements ListIterator<E> {
            private Node<E> lastReturned;
            private Node<E> next;
            private int nextIndex;
            private int expectedModCount = modCount;
    
            ListItr(int index) {
                // assert isPositionIndex(index);
                next = (index == size) ? null : node(index);
                nextIndex = index;
            }
    
            public boolean hasNext() {
                return nextIndex < size;
            }
    
            public E next() {
                checkForComodification();
                if (!hasNext())
                    throw new NoSuchElementException();
    
                lastReturned = next;
                next = next.next;
                nextIndex++;
                return lastReturned.item;
            }
    
            public boolean hasPrevious() {
                return nextIndex > 0;
            }
    
            public E previous() {
                checkForComodification();
                if (!hasPrevious())
                    throw new NoSuchElementException();
    
                lastReturned = next = (next == null) ? last : next.prev;
                nextIndex--;
                return lastReturned.item;
            }
    
            public int nextIndex() {
                return nextIndex;
            }
    
            public int previousIndex() {
                return nextIndex - 1;
            }
    
            public void remove() {
                checkForComodification();
                if (lastReturned == null)
                    throw new IllegalStateException();
    
                Node<E> lastNext = lastReturned.next;
                unlink(lastReturned);
                if (next == lastReturned)
                    next = lastNext;
                else
                    nextIndex--;
                lastReturned = null;
                expectedModCount++;
            }
    
            public void set(E e) {
                if (lastReturned == null)
                    throw new IllegalStateException();
                checkForComodification();
                lastReturned.item = e;
            }
    
            public void add(E e) {
                checkForComodification();
                lastReturned = null;
                if (next == null)
                    linkLast(e);
                else
                    linkBefore(e, next);
                nextIndex++;
                expectedModCount++;
            }
    
            public void forEachRemaining(Consumer<? super E> action) {
                Objects.requireNonNull(action);
                while (modCount == expectedModCount && nextIndex < size) {
                    action.accept(next.item);
                    lastReturned = next;
                    next = next.next;
                    nextIndex++;
                }
                checkForComodification();
            }
    
            final void checkForComodification() {
                if (modCount != expectedModCount)
                    throw new ConcurrentModificationException();
            }
        }
    
        private static class Node<E> {
            E item;
            Node<E> next;
            Node<E> prev;
    
            Node(Node<E> prev, E element, Node<E> next) {
                this.item = element;
                this.next = next;
                this.prev = prev;
            }
        }
    
        /**
         * @since 1.6
         */
        public Iterator<E> descendingIterator() {
            return new DescendingIterator();
        }
    
        /**
         * Adapter to provide descending iterators via ListItr.previous
         */
        private class DescendingIterator implements Iterator<E> {
            private final ListItr itr = new ListItr(size());
            public boolean hasNext() {
                return itr.hasPrevious();
            }
            public E next() {
                return itr.previous();
            }
            public void remove() {
                itr.remove();
            }
        }
    
        @SuppressWarnings("unchecked")
        private LinkedList<E> superClone() {
            try {
                return (LinkedList<E>) super.clone();
            } catch (CloneNotSupportedException e) {
                throw new InternalError(e);
            }
        }
    
        /**
         * Returns a shallow copy of this {@code LinkedList}. (The elements
         * themselves are not cloned.)
         *
         * @return a shallow copy of this {@code LinkedList} instance
         */
        public Object clone() {
            LinkedList<E> clone = superClone();
    
            // Put clone into "virgin" state
            clone.first = clone.last = null;
            clone.size = 0;
            clone.modCount = 0;
    
            // Initialize clone with our elements
            for (Node<E> x = first; x != null; x = x.next)
                clone.add(x.item);
    
            return clone;
        }
    
        /**
         * Returns an array containing all of the elements in this list
         * in proper sequence (from first to last element).
         *
         * <p>The returned array will be "safe" in that no references to it are
         * maintained by this list.  (In other words, this method must allocate
         * a new array).  The caller is thus free to modify the returned array.
         *
         * <p>This method acts as bridge between array-based and collection-based
         * APIs.
         *
         * @return an array containing all of the elements in this list
         *         in proper sequence
         */
        public Object[] toArray() {
            Object[] result = new Object[size];
            int i = 0;
            for (Node<E> x = first; x != null; x = x.next)
                result[i++] = x.item;
            return result;
        }
    
        /**
         * Returns an array containing all of the elements in this list in
         * proper sequence (from first to last element); the runtime type of
         * the returned array is that of the specified array.  If the list fits
         * in the specified array, it is returned therein.  Otherwise, a new
         * array is allocated with the runtime type of the specified array and
         * the size of this list.
         *
         * <p>If the list fits in the specified array with room to spare (i.e.,
         * the array has more elements than the list), the element in the array
         * immediately following the end of the list is set to {@code null}.
         * (This is useful in determining the length of the list <i>only</i> if
         * the caller knows that the list does not contain any null elements.)
         *
         * <p>Like the {@link #toArray()} method, this method acts as bridge between
         * array-based and collection-based APIs.  Further, this method allows
         * precise control over the runtime type of the output array, and may,
         * under certain circumstances, be used to save allocation costs.
         *
         * <p>Suppose {@code x} is a list known to contain only strings.
         * The following code can be used to dump the list into a newly
         * allocated array of {@code String}:
         *
         * <pre>
         *     String[] y = x.toArray(new String[0]);</pre>
         *
         * Note that {@code toArray(new Object[0])} is identical in function to
         * {@code toArray()}.
         *
         * @param a the array into which the elements of the list are to
         *          be stored, if it is big enough; otherwise, a new array of the
         *          same runtime type is allocated for this purpose.
         * @return an array containing the elements of the list
         * @throws ArrayStoreException if the runtime type of the specified array
         *         is not a supertype of the runtime type of every element in
         *         this list
         * @throws NullPointerException if the specified array is null
         */
        @SuppressWarnings("unchecked")
        public <T> T[] toArray(T[] a) {
            if (a.length < size)
                a = (T[])java.lang.reflect.Array.newInstance(
                                    a.getClass().getComponentType(), size);
            int i = 0;
            Object[] result = a;
            for (Node<E> x = first; x != null; x = x.next)
                result[i++] = x.item;
    
            if (a.length > size)
                a[size] = null;
    
            return a;
        }
    
        private static final long serialVersionUID = 876323262645176354L;
    
        /**
         * Saves the state of this {@code LinkedList} instance to a stream
         * (that is, serializes it).
         *
         * @serialData The size of the list (the number of elements it
         *             contains) is emitted (int), followed by all of its
         *             elements (each an Object) in the proper order.
         */
        private void writeObject(java.io.ObjectOutputStream s)
            throws java.io.IOException {
            // Write out any hidden serialization magic
            s.defaultWriteObject();
    
            // Write out size
            s.writeInt(size);
    
            // Write out all elements in the proper order.
            for (Node<E> x = first; x != null; x = x.next)
                s.writeObject(x.item);
        }
    
        /**
         * Reconstitutes this {@code LinkedList} instance from a stream
         * (that is, deserializes it).
         */
        @SuppressWarnings("unchecked")
        private void readObject(java.io.ObjectInputStream s)
            throws java.io.IOException, ClassNotFoundException {
            // Read in any hidden serialization magic
            s.defaultReadObject();
    
            // Read in size
            int size = s.readInt();
    
            // Read in all elements in the proper order.
            for (int i = 0; i < size; i++)
                linkLast((E)s.readObject());
        }
    
        /**
         * Creates a <em><a href="Spliterator.html#binding">late-binding</a></em>
         * and <em>fail-fast</em> {@link Spliterator} over the elements in this
         * list.
         *
         * <p>The {@code Spliterator} reports {@link Spliterator#SIZED} and
         * {@link Spliterator#ORDERED}.  Overriding implementations should document
         * the reporting of additional characteristic values.
         *
         * @implNote
         * The {@code Spliterator} additionally reports {@link Spliterator#SUBSIZED}
         * and implements {@code trySplit} to permit limited parallelism..
         *
         * @return a {@code Spliterator} over the elements in this list
         * @since 1.8
         */
        @Override
        public Spliterator<E> spliterator() {
            return new LLSpliterator<E>(this, -1, 0);
        }
    
        /** A customized variant of Spliterators.IteratorSpliterator */
        static final class LLSpliterator<E> implements Spliterator<E> {
            static final int BATCH_UNIT = 1 << 10;  // batch array size increment
            static final int MAX_BATCH = 1 << 25;  // max batch array size;
            final LinkedList<E> list; // null OK unless traversed
            Node<E> current;      // current node; null until initialized
            int est;              // size estimate; -1 until first needed
            int expectedModCount; // initialized when est set
            int batch;            // batch size for splits
    
            LLSpliterator(LinkedList<E> list, int est, int expectedModCount) {
                this.list = list;
                this.est = est;
                this.expectedModCount = expectedModCount;
            }
    
            final int getEst() {
                int s; // force initialization
                final LinkedList<E> lst;
                if ((s = est) < 0) {
                    if ((lst = list) == null)
                        s = est = 0;
                    else {
                        expectedModCount = lst.modCount;
                        current = lst.first;
                        s = est = lst.size;
                    }
                }
                return s;
            }
    
            public long estimateSize() { return (long) getEst(); }
    
            public Spliterator<E> trySplit() {
                Node<E> p;
                int s = getEst();
                if (s > 1 && (p = current) != null) {
                    int n = batch + BATCH_UNIT;
                    if (n > s)
                        n = s;
                    if (n > MAX_BATCH)
                        n = MAX_BATCH;
                    Object[] a = new Object[n];
                    int j = 0;
                    do { a[j++] = p.item; } while ((p = p.next) != null && j < n);
                    current = p;
                    batch = j;
                    est = s - j;
                    return Spliterators.spliterator(a, 0, j, Spliterator.ORDERED);
                }
                return null;
            }
    
            public void forEachRemaining(Consumer<? super E> action) {
                Node<E> p; int n;
                if (action == null) throw new NullPointerException();
                if ((n = getEst()) > 0 && (p = current) != null) {
                    current = null;
                    est = 0;
                    do {
                        E e = p.item;
                        p = p.next;
                        action.accept(e);
                    } while (p != null && --n > 0);
                }
                if (list.modCount != expectedModCount)
                    throw new ConcurrentModificationException();
            }
    
            public boolean tryAdvance(Consumer<? super E> action) {
                Node<E> p;
                if (action == null) throw new NullPointerException();
                if (getEst() > 0 && (p = current) != null) {
                    --est;
                    E e = p.item;
                    current = p.next;
                    action.accept(e);
                    if (list.modCount != expectedModCount)
                        throw new ConcurrentModificationException();
                    return true;
                }
                return false;
            }
    
            public int characteristics() {
                return Spliterator.ORDERED | Spliterator.SIZED | Spliterator.SUBSIZED;
            }
        }
    
    }
    

    参考

    原文链接:https://www.cnblogs.com/liuyun1995/p/8287707.html

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  • 原文地址:https://www.cnblogs.com/eternityz/p/12253283.html
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