java 单链表反转

时间:2023-03-09 10:02:56
java 单链表反转

最近与人瞎聊,聊到各大厂的面试题,其中有一个就是用java实现单链表反转。闲来无事,决定就这个问题进行一番尝试。

1.准备链表

准备一个由DataNode组成的单向链表,DataNode如下:

public class DataNode {

    private int data;

    private DataNode next;

    public int getData() {

        return data;

    }

    public void setData(int data) {

        this.data = data;

    }

    public DataNode getNext() {

        return next;

    }

    public void setNext(DataNode next) {

        this.next = next;

    }

    public DataNode(int data) {

        this.data = data;

    }

}

构造链表

public class DataChain {

    private  DataNode head;

    public DataChain(int size) {

        DataNode head = new DataNode(0);

        DataNode cur = head;

        for (int i = 1; i < size; i++) {

            DataNode tmp = new DataNode(i);

            cur.setNext(tmp);

            cur = tmp;

        }

        this.head = head;

    }

    public DataNode getHead() {

        return head;

    }

    public void setHead(DataNode head) {

        this.head = head;

    }

    public static void printChain(DataNode head) {

        StringBuilder sb = new StringBuilder();

        DataNode cur = head;

        sb.append(cur.getData());

        while (null != cur.getNext()) {

            sb.append(" -> ");

            sb.append(cur.getNext().getData());

            cur = cur.getNext();

        }

        System.out.println(sb.toString());

    }

    public static void main(String... strings) {

        DataChain chain = new DataChain(10);

        printChain(chain.getHead());

    }

}

运行main方法,即构造了一个包含10个node节点的单链表。

#运行结果

0 -> 1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8 -> 9

2.通过递归实现单链表反转

考虑到代码的简洁性,首先考虑的是通过递归实现。

 /**

     * 递归实现 当栈深度大于12000 则会出现StakOverflowError

     *

     * @param head

     * @return

     */

    public static DataNode reverse1(DataNode head) {

        if (null == head || null == head.getNext())

            return head;

        DataNode revHead = reverse1(head.getNext());

        head.getNext().setNext(head);

        head.setNext(null);

        return revHead;

    }

以上即是递归实现的源码,但是需要考虑的问题是递归都在java栈中进行,需要考虑jdk支持的栈的深度。在jdk1.8.0_91版本中,当上述链表长度大于12000则会出现*Error错误。说明对于该版本jdk栈的深度不能大于12000。

3.通过遍历实现

最通用的实现方式就是遍历。

/**

     * 遍历实现 通用实现方法

     *

     * @param head

     * @return

     */

    public static DataNode reverse2(DataNode head) {

        if (null == head || null == head.getNext())

            return head;

        DataNode pre = head;

        DataNode cur = head.getNext();

        while (null != cur.getNext()) {

            DataNode tmp = cur.getNext();

            cur.setNext(pre);

            pre = cur;

            cur = tmp;

        }

        cur.setNext(pre);

        head.setNext(null);

        return cur;

    }

4.借助stack实现

考虑到stack具有先进后出这一特性,因此可以借助于stack数据结构来实现单向链表的反转。

/**

     * 方法3 利用其他数据结构 stack

     * @param head

     * @return

     */

    public static DataNode reverse3(DataNode head) {

        Stack<DataNode> stack = new Stack<DataNode>();

        for (DataNode node = head; null != node; node = node.getNext()) {

            stack.add(node);

        }

        DataNode reHead = stack.pop();

        DataNode cur = reHead;

        while(!stack.isEmpty()){

            cur.setNext(stack.pop());

            cur = cur.getNext();

            cur.setNext(null);

        }

        return reHead;

    }

上述实现方法在于操作简单,对于算法并不精通的同学可以尝试。缺点在于需要通过其他数据结构实现,效率会降低,至于效率会降低到什么程度,后面举例说明。

5.三种实现方式效率分析

    public static void main(String... strings) {

        int size = 10;

        DataChain chain1 = new DataChain(size);

        printChain(chain1.getHead());

        long reverse1_start = System.currentTimeMillis();

        DataNode reNode1 = reverse1(chain1.getHead());

        long reverse1_cost = System.currentTimeMillis() - reverse1_start;

        printChain(reNode1);

        System.out.println("reverse1 cost time is ["+reverse1_cost+"]ms");

        DataChain chain2 = new DataChain(size);

        printChain(chain2.getHead());

        long reverse2_start = System.currentTimeMillis();

        DataNode reNode2 = reverse2(chain2.getHead());

        long reverse2_cost = System.currentTimeMillis() - reverse2_start;

        printChain(reNode2);

        System.out.println("reverse2 cost time is ["+reverse2_cost+"]ms");

        DataChain chain3 = new DataChain(size);

        printChain(chain3.getHead());

        long reverse3_start = System.currentTimeMillis();

        DataNode reNode3 = reverse3(chain3.getHead());

        long reverse3_cost = System.currentTimeMillis() - reverse3_start;

        printChain(reNode3);

        System.out.println("reverse3 cost time is ["+reverse3_cost+"]ms");

    }

执行结果:

0 -> 1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8 -> 9

9 -> 8 -> 7 -> 6 -> 5 -> 4 -> 3 -> 2 -> 1 -> 0

reverse1 cost time is [0]ms

0 -> 1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8 -> 9

9 -> 8 -> 7 -> 6 -> 5 -> 4 -> 3 -> 2 -> 1 -> 0

reverse2 cost time is [0]ms

0 -> 1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8 -> 9

9 -> 8 -> 7 -> 6 -> 5 -> 4 -> 3 -> 2 -> 1 -> 0

reverse3 cost time is [1]ms

在上述代码基础上,去掉打印输出,将size改为10000,结果如下:

reverse1 cost time is [1]ms

reverse2 cost time is [0]ms

reverse3 cost time is [6]ms

可以看出reverse2 明显优于其他两种实现方法。考虑到reverse1最多只支持12000,因此将size改为100000时,再观察reverse2和reverse3之间的执行结果:

reverse2 cost time is [6]ms

reverse3 cost time is [25]ms

因此可以看出,最好的方法是采用遍历的方式进行反转。

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