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0019.删除链表的倒数第N个节点.md

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参与本项目,贡献其他语言版本的代码,拥抱开源,让更多学习算法的小伙伴们收益!

19.删除链表的倒数第N个节点

力扣题目链接

给你一个链表,删除链表的倒数第 n 个结点,并且返回链表的头结点。

进阶:你能尝试使用一趟扫描实现吗?

示例 1:

19.删除链表的倒数第N个节点

输入:head = [1,2,3,4,5], n = 2 输出:[1,2,3,5] 示例 2:

输入:head = [1], n = 1 输出:[] 示例 3:

输入:head = [1,2], n = 1 输出:[1]

思路

《代码随想录》算法公开课:链表遍历学清楚! | LeetCode:19.删除链表倒数第N个节点,相信结合视频在看本篇题解,更有助于大家对链表的理解。

双指针的经典应用,如果要删除倒数第n个节点,让fast移动n步,然后让fast和slow同时移动,直到fast指向链表末尾。删掉slow所指向的节点就可以了。

思路是这样的,但要注意一些细节。

分为如下几步:

  • 首先这里我推荐大家使用虚拟头结点,这样方便处理删除实际头结点的逻辑,如果虚拟头结点不清楚,可以看这篇: 链表:听说用虚拟头节点会方便很多?

  • 定义fast指针和slow指针,初始值为虚拟头结点,如图:

  • fast首先走n + 1步 ,为什么是n+1呢,因为只有这样同时移动的时候slow才能指向删除节点的上一个节点(方便做删除操作),如图:

  • fast和slow同时移动,直到fast指向末尾,如题:

  • 删除slow指向的下一个节点,如图:

此时不难写出如下C++代码:

class Solution {
public:
    ListNode* removeNthFromEnd(ListNode* head, int n) {
        ListNode* dummyHead = new ListNode(0);
        dummyHead->next = head;
        ListNode* slow = dummyHead;
        ListNode* fast = dummyHead;
        while(n-- && fast != NULL) {
            fast = fast->next;
        }
        fast = fast->next; // fast再提前走一步,因为需要让slow指向删除节点的上一个节点
        while (fast != NULL) {
            fast = fast->next;
            slow = slow->next;
        }
        slow->next = slow->next->next; 
        
        // ListNode *tmp = slow->next;  C++释放内存的逻辑
        // slow->next = tmp->next;
        // delete nth;
        
        return dummyHead->next;
    }
};
  • 时间复杂度: O(n)
  • 空间复杂度: O(1)

其他语言版本

java:

public ListNode removeNthFromEnd(ListNode head, int n){
    ListNode dummyNode = new ListNode(0);
    dummyNode.next = head;

    ListNode fastIndex = dummyNode;
    ListNode slowIndex = dummyNode;

    //只要快慢指针相差 n 个结点即可
    for (int i = 0; i < n  ; i++){
        fastIndex = fastIndex.next;
    }

    while (fastIndex.next != null){
        fastIndex = fastIndex.next;
        slowIndex = slowIndex.next;
    }

    //此时 slowIndex 的位置就是待删除元素的前一个位置。
    //具体情况可自己画一个链表长度为 3 的图来模拟代码来理解
    slowIndex.next = slowIndex.next.next;
    return dummyNode.next;
}

Python:

# Definition for singly-linked list.
# class ListNode:
#     def __init__(self, val=0, next=None):
#         self.val = val
#         self.next = next

class Solution:
    def removeNthFromEnd(self, head: ListNode, n: int) -> ListNode:
        # 创建一个虚拟节点,并将其下一个指针设置为链表的头部
        dummy_head = ListNode(0, head)
        
        # 创建两个指针,慢指针和快指针,并将它们初始化为虚拟节点
        slow = fast = dummy_head
        
        # 快指针比慢指针快 n+1 步
        for i in range(n+1):
            fast = fast.next
        
        # 移动两个指针,直到快速指针到达链表的末尾
        while fast:
            slow = slow.next
            fast = fast.next
        
        # 通过更新第 (n-1) 个节点的 next 指针删除第 n 个节点
        slow.next = slow.next.next
        
        return dummy_head.next

Go:

/**
 * Definition for singly-linked list.
 * type ListNode struct {
 *     Val int
 *     Next *ListNode
 * }
 */
func removeNthFromEnd(head *ListNode, n int) *ListNode {
    dummyHead := &ListNode{}
    dummyHead.Next = head
    cur := head
    prev := dummyHead
    i := 1
    for cur != nil {
        cur = cur.Next
        if i > n {
            prev = prev.Next
        }
        i++
    }
    prev.Next = prev.Next.Next
    return dummyHead.Next
}

JavaScript:

/**
 * @param {ListNode} head
 * @param {number} n
 * @return {ListNode}
 */
var removeNthFromEnd = function(head, n) {
    let ret = new ListNode(0, head),
        slow = fast = ret;
    while(n--) fast = fast.next;
    while (fast.next !== null) {
        fast = fast.next; 
        slow = slow.next
    };
    slow.next = slow.next.next;
    return ret.next;
};

TypeScript:

版本一(快慢指针法):

function removeNthFromEnd(head: ListNode | null, n: number): ListNode | null {
    let newHead: ListNode | null = new ListNode(0, head);
    //根据leetcode题目的定义可推断这里快慢指针均不需要定义为ListNode | null。
    let slowNode: ListNode = newHead;
    let fastNode: ListNode = newHead;

    while(n--) {
        fastNode = fastNode.next!; //由虚拟头节点前进n个节点时,fastNode.next可推断不为null。
    }
    while(fastNode.next) {  //遍历直至fastNode.next = null, 即尾部节点。 此时slowNode指向倒数第n个节点。
        fastNode = fastNode.next;
        slowNode = slowNode.next!;
    }
    slowNode.next = slowNode.next!.next; //倒数第n个节点可推断其next节点不为空。 
    return newHead.next; 
}

版本二(计算节点总数法):

function removeNthFromEnd(head: ListNode | null, n: number): ListNode | null {
    let curNode: ListNode | null = head;
    let listSize: number = 0;
    while (curNode) {
        curNode = curNode.next;
        listSize++;
    }
    if (listSize === n) {
        head = head.next;
    } else {
        curNode = head;
        for (let i = 0; i < listSize - n - 1; i++) {
            curNode = curNode.next;
        }
        curNode.next = curNode.next.next;
    }
    return head;
};

版本三(递归倒退n法):

function removeNthFromEnd(head: ListNode | null, n: number): ListNode | null {
    let newHead: ListNode | null = new ListNode(0, head);
    let cnt = 0;
    function recur(node) {
        if (node === null) return;
        recur(node.next);
        cnt++;
        if (cnt === n + 1) {
            node.next = node.next.next;
        }
    }
    recur(newHead);
    return newHead.next;
};

Kotlin:

fun removeNthFromEnd(head: ListNode?, n: Int): ListNode? {
    val pre = ListNode(0).apply {
        this.next = head
    }
    var fastNode: ListNode? = pre
    var slowNode: ListNode? = pre
    for (i in 0..n) {
        fastNode = fastNode?.next
    }
    while (fastNode != null) {
        slowNode = slowNode?.next
        fastNode = fastNode.next
    }
    slowNode?.next = slowNode?.next?.next
    return pre.next
}

Swift:

func removeNthFromEnd(_ head: ListNode?, _ n: Int) -> ListNode? {
    if head == nil {
        return nil
    }
    if n == 0 {
        return head
    }
    let dummyHead = ListNode(-1, head)
    var fast: ListNode? = dummyHead
    var slow: ListNode? = dummyHead
    // fast 前移 n
    for _ in 0 ..< n {
        fast = fast?.next
    }
    while fast?.next != nil {
        fast = fast?.next
        slow = slow?.next
    }
    slow?.next = slow?.next?.next
    return dummyHead.next
}

PHP:

function removeNthFromEnd($head, $n) {
    // 设置虚拟头节点
    $dummyHead = new ListNode();
    $dummyHead->next = $head;

    $slow = $fast = $dummyHead;
    while($n-- && $fast != null){
        $fast = $fast->next;
    }
    // fast 再走一步,让 slow 指向删除节点的上一个节点
    $fast = $fast->next; 
    while ($fast != NULL) {
        $fast = $fast->next;
        $slow = $slow->next;
    }
    $slow->next = $slow->next->next;
    return $dummyHead->next;
    }

Scala:

object Solution {
  def removeNthFromEnd(head: ListNode, n: Int): ListNode = {
    val dummy = new ListNode(-1, head) // 定义虚拟头节点
    var fast = head // 快指针从头开始走
    var slow = dummy // 慢指针从虚拟头开始头
    // 因为参数 n 是不可变量,所以不能使用 while(n>0){n-=1}的方式
    for (i <- 0 until n) {
      fast = fast.next
    }
    // 快指针和满指针一起走,直到fast走到null
    while (fast != null) {
      slow = slow.next
      fast = fast.next
    }
    // 删除slow的下一个节点 
    slow.next = slow.next.next
    // 返回虚拟头节点的下一个
    dummy.next
  }
}

Rust:

impl Solution {
    pub fn remove_nth_from_end(head: Option<Box<ListNode>>, mut n: i32) -> Option<Box<ListNode>> {
        let mut dummy_head = Box::new(ListNode::new(0));
        dummy_head.next = head;
        let mut fast = &dummy_head.clone();
        let mut slow = &mut dummy_head;
        while n > 0 {
            fast = fast.next.as_ref().unwrap();
            n -= 1;
        }
        while fast.next.is_some() {
            fast = fast.next.as_ref().unwrap();
            slow = slow.next.as_mut().unwrap();
        }
        slow.next = slow.next.as_mut().unwrap().next.take();
        dummy_head.next
    }
}

C语言

/**c语言单链表的定义
 * Definition for singly-linked list.
 * struct ListNode {
 *     int val;
 *     struct ListNode *next;
 * };
 */
struct ListNode* removeNthFromEnd(struct ListNode* head, int n) {
    //定义虚拟头节点dummy 并初始化使其指向head
    struct ListNode* dummy = malloc(sizeof(struct ListNode));
    dummy->val = 0;
    dummy->next = head;
    //定义 fast slow 双指针
    struct ListNode* fast = head;
    struct ListNode* slow = dummy;

    for (int i = 0; i < n; ++i) {
        fast = fast->next;
    }
    while (fast) {
        fast = fast->next;
        slow = slow->next;
    }
    slow->next = slow->next->next;//删除倒数第n个节点
    head = dummy->next;
    free(dummy);//删除虚拟节点dummy
    return head;
}