二叉树(二叉链表实现)JAVA代码

 
  1. publicclassTest{
  2.  
  3.     publicstaticvoid main(String[] args){
  4.  
  5.         char[] ch =newchar[]{'A','B','D','#','#','G','#','#','C','J','#','#','M','#','#'};
  6.         BinaryTree binaryTree =newBinaryTree(ch);
  7.  
  8.         binaryTree.preOrder();
  9.         System.out.println();
  10.  
  11.         binaryTree.inOrder();
  12.         System.out.println();
  13.  
  14.         binaryTree.postOrder();
  15.         System.out.println();
  16.  
  17.         binaryTree.levelOrder();
  18.         System.out.println();
  19.  
  20.     }
  21.  
  22. }
 
 
  1. publicclassBinaryTree{
  2.  
  3.     //二叉树结点
  4.     publicclassBiNode{
  5.         char data;
  6.         BiNode left;
  7.         BiNode right;
  8.  
  9.         BiNode(char data,BiNode left,BiNode right){
  10.             this.data = data;
  11.             this.left = left;
  12.             this.right = right;
  13.         }
  14.  
  15.         int flag =0;//供非递归后序遍历使用
  16.     }
  17.  
  18.     //根结点
  19.     publicBiNode root;
  20.  
  21.     privatestaticint i;
  22.     publicBinaryTree(char[] pre){
  23.         i =0;
  24.         root = create(pre);
  25.     }
  26.  
  27.     //初始化(先序遍历顺序存放数组、'#'表示null)
  28.     privateBiNode create(char[] pre)
  29.     {
  30.         if(i < pre.length)
  31.         {
  32.             if(pre[i]=='#')                             //结点为空
  33.             {
  34.                 i++;
  35.                 return null;
  36.             }
  37.  
  38.             BiNode p =newBiNode(pre[i], null, null);    //结点非空
  39.             i++;
  40.             p.left = create(pre);                         //递归建立左子树
  41.             p.right = create(pre);                       //递归建立右子树
  42.             return p;
  43.         }
  44.         return null;
  45.     }
  46.  
  47.     //先序遍历
  48.     publicvoid preOrder(){
  49.         System.out.print("preOrder traversal with recursion:");
  50.         preOrder(root);
  51.         System.out.println();
  52.  
  53.         System.out.print("preOrder traversal without recursion:");
  54.         preOrder2(root);
  55.         System.out.println();
  56.     }
  57.     //递归
  58.     privatevoid preOrder(BiNode root){
  59.         if(root == null)return;
  60.  
  61.         System.out.print(root.data);       //访问结点
  62.         preOrder(root.left);
  63.         preOrder(root.right);
  64.     }
  65.     //非递归
  66.     privatevoid preOrder2(BiNode head){
  67.         LinkedList<BiNode> s =newLinkedList<BiNode>();
  68.  
  69.         while(head != null ||!s.isEmpty())
  70.         {
  71.             while(head != null)                //访问左子树
  72.             {
  73.                 System.out.print(head.data);    //访问左子树
  74.                 s.push(head);                    //结点入栈(待后面找其右子树使用)= =(“递归”)
  75.                 head = head.left;
  76.             }
  77.  
  78.             if(!s.isEmpty())                   //转向右子树
  79.             {
  80.                 head = s.peek().right;     //转向右子树
  81.                 s.pop();                        //结点出栈(已经找到其右子树)= =(“递归结束”)
  82.             }
  83.         }
  84.     }
  85.  
  86.     //中序遍历
  87.     publicvoid inOrder(){
  88.         System.out.print("inOrder traversal with recursion:");
  89.         inOrder(root);
  90.         System.out.println();
  91.  
  92.         System.out.print("inOrder traversal without recursion:");
  93.         inOrder2(root);
  94.         System.out.println();
  95.     }
  96.     //递归
  97.     privatevoid inOrder(BiNode root){
  98.         if(root == null)return;
  99.  
  100.         inOrder(root.left);
  101.         System.out.print(root.data);      //访问结点
  102.         inOrder(root.right);
  103.     }
  104.     //非递归
  105.     privatevoid inOrder2(BiNode head){
  106.         LinkedList<BiNode> s =newLinkedList<BiNode>();
  107.  
  108.         while(head != null ||!s.isEmpty())
  109.         {
  110.             while(head != null)                //左子树入栈
  111.             {
  112.                 s.push(head);                    //结点入栈(待后面找其右子树使用)= =(“递归”)
  113.                 head = head.left;
  114.             }
  115.  
  116.             System.out.print(s.peek().data);    //访问左子树
  117.  
  118.             if(!s.isEmpty())                   //转向右子树
  119.             {
  120.                 head = s.peek().right;         //转向右子树
  121.                 s.pop();                        //结点出栈(已经找到其右子树)= =(“递归结束”)
  122.             }
  123.         }
  124.     }
  125.  
  126.     //后序遍历
  127.     publicvoid postOrder(){
  128.         System.out.print("postOrder traversal with recursion:");
  129.         postOrder(root);
  130.         System.out.println();
  131.  
  132.         System.out.print("postOrder traversal without recursion:");
  133.         postOrder2(root);
  134.         System.out.println();
  135.     }
  136.     //递归
  137.     privatevoid postOrder(BiNode root){
  138.         if(root == null)return;
  139.  
  140.         postOrder(root.left);
  141.         postOrder(root.right);
  142.         System.out.print(root.data);     //访问结点
  143.     }
  144.     //非递归
  145.     //后序遍历特点:递归左右子树后,还需访问结点:
  146.     //1、左子树入栈
  147.     //2、“两次出栈”(用flag标记模仿):第一次是为了找到左子树相应的右子树结点;第二次是为了访问结点
  148.     privatevoid postOrder2(BiNode head){
  149.         LinkedList<BiNode> s =newLinkedList<BiNode>();
  150.  
  151.         while(head != null ||!s.isEmpty())
  152.         {
  153.             while(head != null)                        //左子树入栈
  154.             {
  155.                 head.flag =1;
  156.                 s.push(head);                            //结点连同flag入栈(待后面找其右子树使用)= =(“递归”)
  157.                 head = head.left;
  158.             }
  159.  
  160.             while(!s.isEmpty()&& s.peek().flag ==2)  //若flag为2(已经找到其右子树出过一次栈),访问结点
  161.             {
  162.                 System.out.print(s.peek().data);       //访问结点元素
  163.                 s.pop();                                //(第二次“结点出栈”)实际结点出栈(已经访问结点元素)= =(“递归结束”)
  164.             }
  165.  
  166.             if(!s.isEmpty())                          //flag为1,转向右子树
  167.             {
  168.                 head = s.peek().right;                //转向右子树
  169.                 s.peek().flag =2;                    //(第一次“flag模拟出栈”)标记为2,但实际结点不出栈(已经找到其右子树)
  170.             }
  171.  
  172.  
  173.         }
  174.     }
  175.  
  176.     //层序遍历
  177.     publicvoid levelOrder(){
  178.         levelOrder(root);
  179.     }
  180.     privatevoid levelOrder(BiNode root){
  181.         LinkedList<BiNode>queue=newLinkedList<BiNode>();  //LinkedList实现了Queue接口
  182.  
  183.         BiNode p = root;
  184.         while(p != null){
  185.             System.out.print(p.data);    //访问结点
  186.  
  187.             if(p.left != null)
  188.                 queue.add(p.left);
  189.             if(p.right != null)
  190.                 queue.add(p.right);
  191.  
  192.             p =queue.poll();           //队头出队并返回为p
  193.         }
  194.     }
  195.  
  196.     //在p结点后插入data
  197.     publicvoid insert(BiNode p,char data, boolean left){
  198.         if(p != null){
  199.             if(left)                //插入位置为左孩子
  200.                 p.left =newBiNode(data,p.left,null);
  201.             else                   //插入位置为右孩子
  202.                 p.right =newBiNode(data,p.right,null);
  203.         }
  204.     }
  205.  
  206.     //删除p的一个子树
  207.     publicvoiddelete(BiNode p, boolean left){
  208.         if(p != null){
  209.             if(left)              //删除目标为左子树
  210.                 p.left = null;
  211.             else                  //删除目标为右子树
  212.                 p.right = null;
  213.         }
  214.     } 
  215.  
  216. }
 
 
 
 
 





posted @ 2016-05-27 16:17  _Doing  阅读(1078)  评论(0编辑  收藏  举报