• java顺序表和树的实现


    一、顺序表

    1.线性表

    //java顺序表的实现,如ArrayList就是用线性表实现的,优点是查找快,缺点是添加或删除要移动很多元素,速度慢
    public class SequenceList {
        private int MAXLENGTH;//顺序表大小
        private int count;//线性表存在数据个数
        private Data[] data;
        //数据储存
         private static class Data{
            String name;
            int stuNo;
            int scores;
        }
         public void init(int maxLength){
             this.MAXLENGTH=maxLength;
             data=new Data[MAXLENGTH];
         }
         //添加一条数据
         public void add(Data d){
             if(count==MAXLENGTH){
                 System.out.println("顺序表已满!不可添加");
             }
             else{
                 data[count]=d;
                 count++;
                 System.out.println("添加成功!");
             }
         }
         //插入任意一条数据
         public void insert(Data d,int position){
             if(count==MAXLENGTH||position>MAXLENGTH||position<0){
                 System.out.println("顺序表已满或者插入位置有问题!不可插入");
             }
             else{
                 for(int i=count;i>=position;i--){
                     data[i+1]=data[i];
                 }
                 data[position]=d;
                 count++;
                 System.out.println("插入成功!");
             }
         }
         //删除数据
         public void del(int position){
             if(position>count+1||position<0){
                 System.out.println("删除位置有误!");
             }
             else{
                 for(int i=position;i<count;i++){
                     data[i]=data[i+1];
                 }
                 count--;
                 System.out.println("删除成功!");
             }
         }
         //更新一个数据
         public void updata(Data d,int position){
             if(position>count+1||position<0){
                 System.out.println("更新位置有误!");
             }
             else{
                 data[position]=d;
                 System.out.println("更新成功!");
             }
         }
         //查询一个数据
         public Data sel(int position){
             if(position>count+1||position<0){
                 System.out.println("查询位置有误!");
                 return null;
             }
             else{
                 return data[position];
             }
         }
         public static void main(String[] args){
             SequenceList sl=new SequenceList();
             sl.init(10);
             Data d=new Data();
             sl.add(d);
             sl.insert(d, 0);
             sl.del(0);
         }
    }

    2.链式表

     public class SingleList {
        
        private Node_Single head = null;//头节点
        private Node_Single tail = null;//尾节点(空节点)相当于哨兵元素
     
        /**
         * 初始化一个链表(设置head )
         * @param key
         */
        public void initList(Node_Single node){
            head  = node;
            head.next = tail;
        }
         
        /**
         * 添加一个元素
         * @param node
         */
        public void addTolist(Node_Single node){
            if(head == null){
                initList(node);
            }else{
                Node_Single tmp = head;
                head = node;
                node.next = tmp;
            }
        }
         
        /**
         * 遍历链表,删除某一个节点
         * @param node
         * @param myList
         */
        public void deleteNode(Node_Single node,SingleList myList){
            if(myList == null){
                return ;
            }
            Node_Single tmp =null;
            for(tmp = myList.getHead();tmp!=null;tmp = tmp.next){
                if(tmp.next !=null && node.getKey().equals(tmp.next.getKey())){//该元素和后一个元素相同。指针指向下一元素的下一元素
                    if(tmp.next.next != null){
                        tmp.next = tmp.next.next;
                    }else{
                        tmp.next = null;
                    }
                }
            }
        }
         
        public void printList(SingleList myList){
            Node_Single tmp =null;
            for(tmp = myList.getHead();tmp!=null;tmp = tmp.next){
                System.out.println(tmp.getKey());
            }
        }
         
        public Node_Single getHead() {
            return head;
        }
        public void setHead(Node_Single head) {
            this.head = head;
        }
        public Node_Single getTail() {
            return tail;
        }
        public void setTail(Node_Single tail) {
            this.tail = tail;
        }
        public static void main(String[] args){
            SingleList myList = new SingleList();
            Node_Single node_1 = new Node_Single("1");
            Node_Single node_2 = new Node_Single("2");
            Node_Single node_3 = new Node_Single("3");
            Node_Single node_4 = new Node_Single("4");
            Node_Single node_5 = new Node_Single("5");
            Node_Single node_6 = new Node_Single("6");
            Node_Single node_7 = new Node_Single("7");
            myList.addTolist(node_1);
            myList.addTolist(node_2);
            myList.addTolist(node_3);
            myList.addTolist(node_4);
            myList.addTolist(node_5);
            myList.addTolist(node_6);
            myList.addTolist(node_7);
            myList.deleteNode(node_3, myList);
            myList.printList(myList);
        }
        public static class Node_Single {
            public String key;//节点的值
             
            public Node_Single next;//指向下一个的指针
         
            public Node_Single(String key){//初始化head
                this.key = key;
                this.next = null;
            }
            public Node_Single(String key,Node_Single next){
                this.key = key;
                this.next = next;
            }
            public String getKey() {
                return key;
            }
         
            public void setKey(String key) {
                this.key = key;
            }
         
            public Node_Single getNext() {
                return next;
            }
         
            public void setNext(Node_Single next) {
                this.next = next;
            }
            @Override
            public String toString() {
                return "Node_Single [key=" + key + ", next=" + next + "]";
            }
        }
    }

    三、二叉树

    import java.util.Stack;
    
    public class BinaryTree {  
      
          
        private TreeNode root=null;  
          
        public BinaryTree(){  
            root=new TreeNode(1,"rootNode(A)");  
        }  
          
        /** 
         * 创建一棵二叉树 
         * <pre> 
         *           A 
         *     B          C 
         *  D     E            F 
         *  </pre> 
         * @param root 
         * @author WWX 
         */  
        public void createBinTree(TreeNode root){  
            TreeNode newNodeB = new TreeNode(2,"B");  
            TreeNode newNodeC = new TreeNode(3,"C");  
            TreeNode newNodeD = new TreeNode(4,"D");  
            TreeNode newNodeE = new TreeNode(5,"E");  
            TreeNode newNodeF = new TreeNode(6,"F");  
            root.leftChild=newNodeB;  
            root.rightChild=newNodeC;  
            root.leftChild.leftChild=newNodeD;  
            root.leftChild.rightChild=newNodeE;  
            root.rightChild.rightChild=newNodeF;  
        }  
          
          
        public boolean isEmpty(){  
            return root==null;  
        }  
      
        //树的高度  
        public int height(){  
            return height(root);  
        }  
          
        //节点个数  
        public int size(){  
            return size(root);  
        }  
          
          
        private int height(TreeNode subTree){  
            if(subTree==null)  
                return 0;//递归结束:空树高度为0  
            else{  
                int i=height(subTree.leftChild);  
                int j=height(subTree.rightChild);  
                return (i<j)?(j+1):(i+1);  
            }  
        }  
          
        private int size(TreeNode subTree){  
            if(subTree==null){  
                return 0;  
            }else{  
                return 1+size(subTree.leftChild)  
                        +size(subTree.rightChild);  
            }  
        }  
          
        //返回双亲结点  
        public TreeNode parent(TreeNode element){  
            return (root==null|| root==element)?null:parent(root, element);  
        }  
          
        public TreeNode parent(TreeNode subTree,TreeNode element){  
            if(subTree==null)  
                return null;  
            if(subTree.leftChild==element||subTree.rightChild==element)  
                //返回父结点地址  
                return subTree;  
            TreeNode p;  
            //现在左子树中找,如果左子树中没有找到,才到右子树去找  
            if((p=parent(subTree.leftChild, element))!=null)  
                //递归在左子树中搜索  
                return p;  
            else  
                //递归在右子树中搜索  
                return parent(subTree.rightChild, element);  
        }  
          
        public TreeNode getLeftChildNode(TreeNode element){  
            return (element!=null)?element.leftChild:null;  
        }  
          
        public TreeNode getRightChildNode(TreeNode element){  
            return (element!=null)?element.rightChild:null;  
        }  
          
        public TreeNode getRoot(){  
            return root;  
        }  
          
        //在释放某个结点时,该结点的左右子树都已经释放,  
        //所以应该采用后续遍历,当访问某个结点时将该结点的存储空间释放  
        public void destroy(TreeNode subTree){  
            //删除根为subTree的子树  
            if(subTree!=null){  
                //删除左子树  
                destroy(subTree.leftChild);  
                //删除右子树  
                destroy(subTree.rightChild);  
                //删除根结点  
                subTree=null;  
            }  
        }  
          
        public void traverse(TreeNode subTree){  
            System.out.println("key:"+subTree.key+"--name:"+subTree.data);;  
            traverse(subTree.leftChild);  
            traverse(subTree.rightChild);  
        }  
          
        //前序遍历  
        public void preOrder(TreeNode subTree){  
            if(subTree!=null){  
                visted(subTree);  
                preOrder(subTree.leftChild);  
                preOrder(subTree.rightChild);  
            }  
        }  
          
        //中序遍历  
        public void inOrder(TreeNode subTree){  
            if(subTree!=null){  
                inOrder(subTree.leftChild);  
                visted(subTree);  
                inOrder(subTree.rightChild);  
            }  
        }  
          
        //后续遍历  
        public void postOrder(TreeNode subTree) {  
            if (subTree != null) {  
                postOrder(subTree.leftChild);  
                postOrder(subTree.rightChild);  
                visted(subTree);  
            }  
        }  
          
        //前序遍历的非递归实现  
        public void nonRecPreOrder(TreeNode p){  
            Stack<TreeNode> stack=new Stack<TreeNode>();  
            TreeNode node=p;  
            while(node!=null||stack.size()>0){  
                while(node!=null){  
                    visted(node);  
                    stack.push(node);  
                    node=node.leftChild;  
                }  
              while(stack.size()>0){  
                    node=stack.pop();  
                    node=node.rightChild;  
                }   
            }  
        }  
          
        //中序遍历的非递归实现  
        public void nonRecInOrder(TreeNode p){  
            Stack<TreeNode> stack =new Stack<BinaryTree.TreeNode>();  
            TreeNode node =p;  
            while(node!=null||stack.size()>0){  
                //存在左子树  
                while(node!=null){  
                    stack.push(node);  
                    node=node.leftChild;  
                }  
                //栈非空  
                if(stack.size()>0){  
                    node=stack.pop();  
                    visted(node);  
                    node=node.rightChild;  
                }  
            }  
        }  
          
        //后序遍历的非递归实现  
        public void noRecPostOrder(TreeNode p){  
            Stack<TreeNode> stack=new Stack<BinaryTree.TreeNode>();  
            TreeNode node =p;  
            while(p!=null){  
                //左子树入栈  
                for(;p.leftChild!=null;p=p.leftChild){  
                    stack.push(p);  
                }  
                //当前结点无右子树或右子树已经输出  
                while(p!=null&&(p.rightChild==null||p.rightChild==node)){  
                    visted(p);  
                    //纪录上一个已输出结点  
                    node =p;  
                    if(stack.empty())  
                        return;  
                    p=stack.pop();  
                }  
                //处理右子树  
                stack.push(p);  
                p=p.rightChild;  
            }  
        }  
        public void visted(TreeNode subTree){  
            subTree.isVisted=true;  
            System.out.println("key:"+subTree.key+"--name:"+subTree.data);;  
        }  
          
          
        /** 
         * 二叉树的节点数据结构 
         * @author WWX 
         */  
        private class  TreeNode{  
            private int key=0;  
            private String data=null;  
            private boolean isVisted=false;  
            private TreeNode leftChild=null;  
            private TreeNode rightChild=null;  
              
            public TreeNode(){}  
              
            /** 
             * @param key  层序编码 
             * @param data 数据域 
             */  
            public TreeNode(int key,String data){  
                this.key=key;  
                this.data=data;  
                this.leftChild=null;  
                this.rightChild=null;  
            }  
      
      
        }  
          
          
        //测试  
        public static void main(String[] args) {  
            BinaryTree bt = new BinaryTree();  
            bt.createBinTree(bt.root);  
            System.out.println("the size of the tree is " + bt.size());  
            System.out.println("the height of the tree is " + bt.height());  
              
            System.out.println("*******(前序遍历)[ABDECF]遍历*****************");  
            bt.preOrder(bt.root);  
              
            System.out.println("*******(中序遍历)[DBEACF]遍历*****************");  
            bt.inOrder(bt.root);  
             
            System.out.println("*******(后序遍历)[DEBFCA]遍历*****************");  
            bt.postOrder(bt.root);  
              
            System.out.println("***非递归实现****(前序遍历)[ABDECF]遍历*****************");  
            bt.nonRecPreOrder(bt.root);  
              
            System.out.println("***非递归实现****(中序遍历)[DBEACF]遍历*****************");  
            bt.nonRecInOrder(bt.root);  
              
            System.out.println("***非递归实现****(后序遍历)[DEBFCA]遍历*****************");  
            bt.noRecPostOrder(bt.root);  
        }  
    }  
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  • 原文地址:https://www.cnblogs.com/yzjT-mac/p/5872881.html
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