6.链表相关面试题

简介: 6.链表相关面试题

         

链表问题
面试链表解题的方法论
  1. 对于笔试,不用太在乎空间复杂度,一切为了时间复杂度
  2. 对于面试,时间复杂度依然放在第一位,但是一定要找到空间最省的方法
链表面试题常用数据结构和技巧
  1. 使用容器(哈希表、数组等)
  2. 快慢指针
快慢指针
  1. 输入链表头节点,奇数长度返回中点,偶数长度返回上中点
  2. 输入链表头节点,奇数长度返回中点,偶数长度返回下中点
  3. 输入链表头节点,奇数长度返回中点前一个,偶数长度返回上中点前一个
  4. 输入链表头节点,奇数长度返回中点前一个,偶数长度返回下中点前一个
package com.harrison.six;
import java.util.ArrayList;
public class Code01_LinkedListMid {
  public static class Node {
    public int value;
    public Node next;
    public Node(int v) {
      value = v;
    }
  }
  // 奇数长度返回中点,偶数长度返回上中点
  public static Node midOrUpMidNode(Node head) {
    if (head == null || head.next == null || head.next.next == null) {
      return head;
    }
    // 代表链表有三个或三个以上节点
    Node slow = head.next;
    Node fast = head.next.next;
    while (fast.next != null && fast.next.next != null) {
      slow = slow.next;
      fast = fast.next.next;
    }
    return slow;
  }
  // 奇数长度返回中点,偶数长度返回下中点
  public static Node midOrDownMidNode(Node head) {
    if (head == null || head.next == null) {
      return head;
    }
    Node slow = head.next;
    Node fast = head.next;
    while (fast.next != null && fast.next.next != null) {
      slow = slow.next;
      fast = fast.next.next;
    }
    return slow;
  }
  // 奇数长度返回中点前一个,偶数长度返回上中点前一个
  public static Node midOrUpMidPreNode(Node head) {
    if (head == null || head.next == null || head.next.next == null) {
      return head;
    }
    // 代表链表有三个或三个以上节点
    Node slow = head;
    Node fast = head.next.next;
    while (fast.next != null && fast.next.next != null) {
      slow = slow.next;
      fast = fast.next.next;
    }
    return slow;
  }
  // 奇数长度返回中点前一个,偶数长度返回下中点前一个
  public static Node midOrDownMidPreNode(Node head) {
    if (head == null || head.next == null) {
      return null;
    }
    if (head.next.next == null) {
      return head;
    }
    Node slow = head;
    Node fast = head.next;
    while (fast.next != null && fast.next.next != null) {
      slow = slow.next;
      fast = fast.next.next;
    }
    return slow;
  }
  public static Node right1(Node head) {
    if (head == null) {
      return null;
    }
    Node cur = head;
    ArrayList<Node> arr = new ArrayList<>();
    while (cur != null) {
      arr.add(cur);
      cur = cur.next;
    }
    return arr.get((arr.size() - 1) / 2);
  }
  public static Node right2(Node head) {
    if (head == null) {
      return null;
    }
    Node cur = head;
    ArrayList<Node> arr = new ArrayList<>();
    while (cur != null) {
      arr.add(cur);
      cur = cur.next;
    }
    return arr.get(arr.size() / 2);
  }
  public static Node right3(Node head) {
    if (head == null || head.next == null || head.next.next == null) {
      return null;
    }
    Node cur = head;
    ArrayList<Node> arr = new ArrayList<>();
    while (cur != null) {
      arr.add(cur);
      cur = cur.next;
    }
    return arr.get((arr.size() - 3) / 2);
  }
  public static Node right4(Node head) {
    if (head == null || head.next == null) {
      return null;
    }
    Node cur = head;
    ArrayList<Node> arr = new ArrayList<>();
    while (cur != null) {
      arr.add(cur);
      cur = cur.next;
    }
    return arr.get((arr.size() - 2) / 2);
  }
  public static void main(String[] args) {
    Node test = null;
    test = new Node(0);
    test.next = new Node(1);
    test.next.next = new Node(2);
    test.next.next.next = new Node(3);
    test.next.next.next.next = new Node(4);
    test.next.next.next.next.next = new Node(5);
    test.next.next.next.next.next.next = new Node(6);
    test.next.next.next.next.next.next.next = new Node(7);
    test.next.next.next.next.next.next.next.next = new Node(8);
    Node ans1 = null;
    Node ans2 = null;
    ans1 = midOrUpMidNode(test);
    ans2 = right1(test);
    System.out.println(ans1 != null ? ans1.value : "无");
    System.out.println(ans2 != null ? ans2.value : "无");
    ans1 = midOrDownMidNode(test);
    ans2 = right2(test);
    System.out.println(ans1 != null ? ans1.value : "无");
    System.out.println(ans2 != null ? ans2.value : "无");
    ans1 = midOrUpMidPreNode(test);
    ans2 = right3(test);
    System.out.println(ans1 != null ? ans1.value : "无");
    System.out.println(ans2 != null ? ans2.value : "无");
    ans1 = midOrDownMidPreNode(test);
    ans2 = right4(test);
    System.out.println(ans1 != null ? ans1.value : "无");
    System.out.println(ans2 != null ? ans2.value : "无");
  }
}
常见面试题

给定一个单链表的头节点head,请判断该链表是否为回文结构。

  1. 栈方法特别简单(笔试用)
  2. 改原链表的方法就需要注意边界了(面试用)
package com.harrison.six;
import java.util.Stack;
public class Code02_PalindromeList {
  public static class Node {
    public int value;
    public Node next;
    public Node(int v) {
      value = v;
    }
  }
  // need n extra space
  public static boolean isPalindrome1(Node head) {
    Stack<Node> stack = new Stack<Node>();
    Node cur = head;
    while (cur != null) {
      stack.push(cur);
      cur = cur.next;
    }
    while (head != null) {
      if (head.value != stack.pop().value) {
        return false;
      }
      head = head.next;
    }
    return true;
  }
  // need n/2 extra space
  public static boolean isPalindrome2(Node head) {
    if (head == null || head.next == null) {
      return true;
    }
    Node right = head.next;
    Node cur = head;
    while (cur.next != null && cur.next.next != null) {
      right = right.next;
      cur = cur.next.next;
    }
    Stack<Node> stack = new Stack<Node>();
    while (right != null) {
      stack.push(right);
      right = right.next;
    }
    while (!stack.isEmpty()) {
      if (head.value != stack.pop().value) {
        return false;
      }
      head = head.next;
    }
    return true;
  }
  // need O(1) extra space
  public static boolean isPalindrome3(Node head) {
    if (head == null || head.next == null) {
      return true;
    }
    Node n1 = head;
    Node n2 = head;
    while (n2.next != null && n2.next.next != null) {// find mid node
      n1 = n1.next;// n1->mid
      n2 = n2.next.next;// n2-> end
    }
    // 奇数个n1来到中点,偶数个n1来到上中点
    n2 = n1.next;// n2 -> right part first node
    n1.next = null;// mid.next -> null
    Node n3 = null;
    while (n2 != null) {// right part convert
      n3 = n2.next;// n3-> save next node
      n2.next = n1;// next of right node convert
      n1 = n2;// n1 move
      n2 = n3;// n2 move
    }
    n3 = n1;// n3-> save last node
    n2 = head;// n2-> left first node
    boolean res = true;
    while (n1 != null && n2 != null) {// check palindrome
      if (n1.value != n2.value) {
        res = false;
        break;
      }
      n1 = n1.next;// left to mid
      n2 = n2.next;// right to mid
    }
    n1 = n3.next;
    n3.next = null;
    while (n1 != null) {// recover list
      n2 = n1.next;
      n1.next = n3;
      n3 = n1;
      n1 = n2;
    }
    return res;
  }
  public static void printLinkedList(Node node) {
    System.out.print("Linked List:");
    while (node != null) {
      System.out.print(node.value + " ");
      node = node.next;
    }
    System.out.println();
  }
  public static void main(String[] args) {
    Node head = null;
    printLinkedList(head);
    System.out.print(isPalindrome1(head)+ " | ");
    System.out.print(isPalindrome2(head)+ " | ");
    System.out.print(isPalindrome3(head)+ " | ");
    printLinkedList(head);
    System.out.println("=======================");
    head = new Node(1);
    printLinkedList(head);
    System.out.print(isPalindrome1(head)+ " | ");
    System.out.print(isPalindrome2(head)+ " | ");
    System.out.print(isPalindrome3(head)+ " | ");
    printLinkedList(head);
    System.out.println("=======================");
    head = new Node(1);
    head.next = new Node(2);
    printLinkedList(head);
    System.out.print(isPalindrome1(head)+ " | ");
    System.out.print(isPalindrome2(head)+ " | ");
    System.out.print(isPalindrome3(head)+ " | ");
    printLinkedList(head);
    System.out.println("=======================");
    head = new Node(1);
    head.next = new Node(1);
    printLinkedList(head);
    System.out.print(isPalindrome1(head) + " | ");
    System.out.print(isPalindrome2(head) + " | ");
    System.out.println(isPalindrome3(head) + " | ");
    printLinkedList(head);
    System.out.println("=========================");
    head = new Node(1);
    head.next = new Node(2);
    head.next.next = new Node(3);
    printLinkedList(head);
    System.out.print(isPalindrome1(head) + " | ");
    System.out.print(isPalindrome2(head) + " | ");
    System.out.println(isPalindrome3(head) + " | ");
    printLinkedList(head);
    System.out.println("=========================");
    head = new Node(1);
    head.next = new Node(2);
    head.next.next = new Node(1);
    printLinkedList(head);
    System.out.print(isPalindrome1(head) + " | ");
    System.out.print(isPalindrome2(head) + " | ");
    System.out.println(isPalindrome3(head) + " | ");
    printLinkedList(head);
    System.out.println("=========================");
    head = new Node(1);
    head.next = new Node(2);
    head.next.next = new Node(3);
    head.next.next.next = new Node(1);
    printLinkedList(head);
    System.out.print(isPalindrome1(head) + " | ");
    System.out.print(isPalindrome2(head) + " | ");
    System.out.println(isPalindrome3(head) + " | ");
    printLinkedList(head);
    System.out.println("=========================");
    head = new Node(1);
    head.next = new Node(2);
    head.next.next = new Node(2);
    head.next.next.next = new Node(1);
    printLinkedList(head);
    System.out.print(isPalindrome1(head) + " | ");
    System.out.print(isPalindrome2(head) + " | ");
    System.out.println(isPalindrome3(head) + " | ");
    printLinkedList(head);
    System.out.println("=========================");
    head = new Node(1);
    head.next = new Node(2);
    head.next.next = new Node(3);
    head.next.next.next = new Node(2);
    head.next.next.next.next = new Node(1);
    printLinkedList(head);
    System.out.print(isPalindrome1(head) + " | ");
    System.out.print(isPalindrome2(head) + " | ");
    System.out.println(isPalindrome3(head) + " | ");
    printLinkedList(head);
    System.out.println("=========================");
  }
}

将单向链表按某值划分成左边小、中间相等、右边大的形式

  1. 把链表放入数组里,在数组上做partition(笔试用)
  2. 分成小、中、大三部分,再把各个部分之间串起来(面试用)
package com.harrison.six;
public class Code03_SmallerEqualBigger {
  public static class Node{
    public int value;
    public Node next;
    public Node(int v) {
      value=v;
    }
  }
  public static void swap(Node [] nodeArr,int a,int b) {
    Node tmpNode=nodeArr[a];
    nodeArr[a]=nodeArr[b];
    nodeArr[b]=tmpNode;
  }
  public static void arrPartition(Node[] nodeArr,int pivot) {
    int small=-1;
    int big=nodeArr.length;
    int index=0;
    while(index!=big) {
      if(nodeArr[index].value<pivot) {
        swap(nodeArr, ++small, index++);
      }else if(nodeArr[index].value==pivot) {
        index++;
      }else {
        swap(nodeArr, --big, index);
      }
    }
  }
  public static Node listPartition1(Node head,int pivot) {
    if(head==null) {
      return head;
    }
    Node cur=head;
    int i=0;
    while(cur!=null) {
      i++;
      cur=cur.next;
    }
    Node[] nodeArr=new Node[i];
    i=0;
    cur=head;
    for(i=0; i!=nodeArr.length; i++) {
      nodeArr[i]=cur;
      cur=cur.next;
    }
    arrPartition(nodeArr, pivot);
    for(i=1; i!=nodeArr.length; i++) {
      nodeArr[i-1].next=nodeArr[i];
    }
    nodeArr[i-1]=null;
    return nodeArr[0];
  }
  public static Node listPartition2(Node head,int pivot) {
    Node sH=null;//小于区的头
    Node sT=null;//小于区的尾
    Node eH=null;//等于区的头
    Node eT=null;//等于区的尾
    Node bH=null;//大于区的头
    Node bT=null;//大于区的尾
    Node next=null;//save next node
    while(head!=null) {
      next=head.next;
      head.next=null;
      if(head.value<pivot) {
        if(sH==null) {
          sH=head;
          sT=head;
        }else {
          sT.next=head;
          sT=head;
        }
      }else if(head.value==pivot) {
        if(eH==null) {
          eH=head;
          eT=head;
        }else {
          eT.next=head;
          eT=head;
        }
      }else {
        if(bH==null) {
          bH=head;
          bT=head;
        }else {
          bT.next=head;
          bT=head;
        }
      }
      head=next;
    }
    // 小于区域的尾巴,连等于区域的头,等于区域的尾巴连大于区域的头
    if(sT!=null) {//如果有小于区域
      sT.next=eH;
      eT=eT==null?sT:eT;//谁去连大于区域的头,谁就变成等于区域的头eT
    }
    if(eT!=null) {
      eT.next=bH;
    }
    return sH!=null?sH:(eH!=null?eH:bH);
  }
  public static void printLinkedList(Node node) {
    System.out.print("Linked List:");
    while(node!=null) {
      System.out.print(node.value+" ");
      node=node.next;
    }
    System.out.println();
  }
  public static void main(String[] args) {
    Node head1=new Node(7);
    head1.next=new Node(9);
    head1.next.next=new Node(1);
    head1.next.next.next = new Node(8);
    head1.next.next.next.next = new Node(5);
    head1.next.next.next.next.next = new Node(2);
    head1.next.next.next.next.next.next = new Node(5);
    printLinkedList(head1);
    head1=listPartition2(head1, 5);
    printLinkedList(head1);
  }
}

一种特殊的单链表节点类型描述如下:

class Node{
  int value;
  Node next;
  Node rand;
  Node(int val){
    value=val;
  }
}

rand指针是单链表节点结构中新增的指针,rand可能指向链表中的任意一个节点,也可能指向null。给定一个由Node节点类型组成的无环单链表的头节点head,请实现一个函数完成这个链表的复制,并返回复制的新链表的头节点。要求:时间复杂度O(N),额外空间复杂度O(1)

package com.harrison.six;
import java.util.HashMap;
public class Code04_CopyListWithRandom {
  public static class Node {
    int value;
    Node next;
    Node rand;
    Node(int val) {
      value = val;
    }
  }
  public static Node copyRandomList1(Node head) {
    // key 老节点 value 新节点
    HashMap<Node, Node> map = new HashMap<Node, Node>();
    Node cur = head;
    while (cur != null) {
      map.put(cur, new Node(cur.value));
      cur = cur.next;
    }
    cur = head;
    while (cur != null) {
      // cur 老
      // map.get(cur) 新
      // 新.next -> cur.next克隆节点找到
      map.get(cur).next = map.get(cur.next);
      map.get(cur).rand = map.get(cur.rand);
      cur = cur.next;
    }
    return map.get(head);
  }
  public static Node copyRandomList2(Node head) {
    if (head == null) {
      return null;
    }
    Node cur = head;
    Node next = null;
    // copy node and link to every node
    // 1 -> 2 -> 3 -> null
    // 1 -> 1' -> 2 -> 2' -> 3 -> 3'
    while (cur != null) {
      // cur 老 next 老的下一个
      next = cur.next;
      cur.next = new Node(cur.value);
      cur.next.next = next;
      cur = next;
    }
    cur = head;
    Node curCopy = null;
    // set curCopy node rand
    while (cur != null) {
      next = cur.next.next;
      curCopy = cur.next;
      curCopy.rand = cur.rand != null ? cur.rand.next : null;
      cur = next;
    }
    Node res = head.next;
    cur = head;
    // split next方向上,把新老链表分离,不用动rand指针
    while (cur != null) {
      next = cur.next.next;
      curCopy = cur.next;
      cur.next = next;
      curCopy.next = next != null ? next.next : null;
      cur = next;
    }
    return res;
  }
  public static void printLinkedList(Node node) {
    System.out.print("Linked List:");
    while (node != null) {
      System.out.print(node.value + " ");
      node = node.next;
    }
    System.out.println();
  }
  public static void main(String[] args) {
    Node head1=new Node(7);
    head1.next=new Node(9);
    head1.next.next=new Node(1);
    head1.next.next.next = new Node(8);
    head1.next.next.next.next = new Node(5);
    head1.next.next.next.next.next = new Node(2);
    head1.next.next.next.next.next.next = new Node(5);
    printLinkedList(head1);
    //head1=copyRandomList1(head1);
    head1=copyRandomList2(head1);
    printLinkedList(head1);
  }
}

给定两个可能有环也可能无环的单链表,头节点head1和head2。请实现一个函数,如果两个链表相交,请返回相交的第一个节点。如果不相交,返回null。【要求】:如果两个链表长度之和为N,时间复杂度请达到O(N),额外空间复杂度请达到O(1)。

  1. 给你一个链表,返回第一个入环的节点
  2. 两个无环链表相交,返回第一个相交节点
  3. 两个有环链表相交,返回第一个相交节点
package com.harrison.six;
public class Code05_FindFirstIntesectNode {
  public static class Node {
    public int value;
    public Node next;
    public Node(int v) {
      value = v;
    }
  }
  // 找到链表第一个入环节点,如果无环,返回null
  public static Node getLoopNode(Node head) {
    if (head == null || head.next == null || head.next.next == null) {
      return null;
    }
    // n1 慢指针 n2 快指针
    Node n1 = head.next;
    Node n2 = head.next.next;
    while (n1 != n2) {
      if (n2.next == null || n2.next.next == null) {
        return null;
      }
      n2 = n2.next.next;
      n1 = n1.next;
    }
    n2 = head;// n2 -> walk again form head
    // n1位置不变
    while (n1 != n2) {
      n1 = n1.next;
      n2 = n2.next;
    }
    return n1;
  }
  // 如果两个链表都无环,返回第一个相交节点,如果不相交,返回null
  public static Node noLoop(Node head1, Node head2) {
    if (head1 == null || head2 == null) {
      return null;
    }
    Node cur1 = head1;
    Node cur2 = head2;
    int n = 0;
    // n>0 cur1长 n<0 cur2长 n==0 一样长
    while (cur1.next != null) {
      n++;
      cur1 = cur1.next;
    }
    while (cur2.next != null) {
      n--;
      cur2 = cur2.next;
    }
    // 结束两个while循环后,两个链表的当前节点分别来到了end1和end2
    // 如果end1!=end2,说明没有共用一块内存地址,两个链表必不相交
    if (cur1 != cur2) {
      return null;
    }
    // n 链表1减去链表2的长度
    cur1 = n > 0 ? head1 : head2;// 谁长,谁的头变成cur1
    cur2 = cur1 == head1 ? head2 : head1;// 谁短,谁的头变成cur2
    n = Math.abs(n);
    /**
     * 长的链表先把多的节点先走完,然后两条链表一起走 因为此时两条链表长度一样且公共部分也一样长 所以,必然会在第一个相交的节点处相遇
     */
    while (n != 0) {
      n--;
      cur1 = cur1.next;
    }
    while (cur1 != cur2) {
      cur1 = cur1.next;
      cur2 = cur2.next;
    }
    return cur1;
  }
  // 两个有环链表,返回第一个相交节点,如果不想相交返回null
  // 两个有环链表相交,则一定公用同一个环!!!
  public static Node bothLoop(Node head1, Node loop1, Node head2, Node loop2) {
    Node cur1 = null;
    Node cur2 = null;
    // 如果两个链表第一个相交节点相等,则不用考虑共同的环,且loop1和loop2成为end1和end2
    if (loop1 == loop2) {
      cur1 = head1;
      cur2 = head2;
      int n = 0;
      while (cur1 != loop1) {
        n++;
        cur1 = cur1.next;
      }
      while (cur2 != loop2) {
        n--;
        cur2 = cur2.next;
      }
      if (cur1 != cur2) {
        return null;
      }
      cur1 = n > 0 ? head1 : head2;
      cur2 = cur1 == head1 ? head2 : head1;
      n = Math.abs(n);
      while (n != 0) {
        n--;
        cur1 = cur1.next;
      }
      while (cur1 != cur2) {
        cur1 = cur1.next;
        cur2 = cur2.next;
      }
      return cur1;
    } else {
      cur1 = loop1.next;
      while (cur1 != loop1) {
        if (cur1 == loop2) {
          return loop1;
        }
        cur1 = cur1.next;
      }
      return null;
    }
  }
  public static Node getIntersectNode(Node head1, Node head2) {
    if (head1 == null || head2 == null) {
      return null;
    }
    Node loop1 = getLoopNode(head1);
    Node loop2 = getLoopNode(head2);
    if (loop1 == null && loop2 == null) {
      return noLoop(head1, head2);
    }
    if (loop1 != null && loop2 != null) {
      return bothLoop(head1, loop1, head2, loop2);
    }
    return null;
  }
  public static void main(String[] args) {
    // 1->2->3->4->5->6->7->null
    Node head1 = new Node(1);
    head1.next = new Node(2);
    head1.next.next = new Node(3);
    head1.next.next.next = new Node(4);
    head1.next.next.next.next = new Node(5);
    head1.next.next.next.next.next = new Node(6);
    head1.next.next.next.next.next.next = new Node(7);
    // 0->9->8->6->7->null
    Node head2 = new Node(0);
    head2.next = new Node(9);
    head2.next.next = new Node(8);
    head2.next.next.next = head1.next.next.next.next.next; // 8->6
    System.out.println(getIntersectNode(head1, head2).value);
    // 1->2->3->4->5->6->7->4...
    head1 = new Node(1);
    head1.next = new Node(2);
    head1.next.next = new Node(3);
    head1.next.next.next = new Node(4);
    head1.next.next.next.next = new Node(5);
    head1.next.next.next.next.next = new Node(6);
    head1.next.next.next.next.next.next = new Node(7);
    head1.next.next.next.next.next.next = head1.next.next.next; // 7->4
    // 0->9->8->2...
    head2 = new Node(0);
    head2.next = new Node(9);
    head2.next.next = new Node(8);
    head2.next.next.next = head1.next; // 8->2
    System.out.println(getIntersectNode(head1, head2).value);
    // 0->9->8->6->4->5->6..
    head2 = new Node(0);
    head2.next = new Node(9);
    head2.next.next = new Node(8);
    head2.next.next.next = head1.next.next.next.next.next; // 8->6
    System.out.println(getIntersectNode(head1, head2).value);
  }
}

能不能不给单链表的头节点,只给想要删除的节点,就能做到在链表上把这个点删掉?

可以,将要删除节点的下一个节点的值覆盖要删除节点的值,然后将要删除节点的next指针指向下下个节点。

缺点:事实上,没把想要删除的节点删掉,只是把下一个节点盖到了自己身上,删掉的其实是下一个节点。

  1. 节点是服务器
  2. 节点内容很复杂,连拷贝函数和构造函数都不能调用,那么无法完成值的覆盖
  3. 【最严重】无法删除链表最后一个节点


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