笔试和面试题答案
1.Oracle分页查询 sql
2.二叉树的遍历
二叉树的遍历有三种形式:
先序遍历 中序遍历和后序遍历
先序遍历:1)确定结点 2) 先遍历左子树 3)再遍历右子树
中序遍历:1)先遍历左子树 2)选择结点 3)再遍历右子树
后序遍历:1)先遍历左子树 2)遍历右子树 3)选择结点
其实就是递归。 不停的递归,直到二叉树的所有结点都访问完一次。 参考代码如下:
3.多线程的状态;1)初始化: new Thread的时候
2)就绪:会调用Runnable的run方法
3)阻塞:会因为挂起或者是等待请求而产生
4)停止: 执行完run()方法或者是 调用stop()方法
select *from (select A.* ,rownum rn from ( select * from employees) A where rownum <=10) where rn>0;
2.二叉树的遍历
二叉树的遍历有三种形式:
先序遍历 中序遍历和后序遍历
先序遍历:1)确定结点 2) 先遍历左子树 3)再遍历右子树
中序遍历:1)先遍历左子树 2)选择结点 3)再遍历右子树
后序遍历:1)先遍历左子树 2)遍历右子树 3)选择结点
其实就是递归。 不停的递归,直到二叉树的所有结点都访问完一次。 参考代码如下:
package com.text;
import java.util.Stack;
public class BinaryTree {
protected Node root;
public BinaryTree(Node root) {
this.root = root;
}
public Node getRoot() {
return root;
}
/** 构造树 */
public static Node init() {
Node a = new Node('A');
Node b = new Node('B', null, a);
Node c = new Node('C');
Node d = new Node('D', b, c);
Node e = new Node('E');
Node f = new Node('F', e, null);
Node g = new Node('G', null, f);
Node h = new Node('H', d, g);
return h;// root
}
/** 访问节点 */
public static void visit(Node p) {
System.out.print(p.getKey() + " ");
}
/** 递归实现前序遍历 */
protected static void preorder(Node p) {
if (p != null) {
visit(p);
preorder(p.getLeft());
preorder(p.getRight());
}
}
/** 递归实现中序遍历 */
protected static void inorder(Node p) {
if (p != null) {
inorder(p.getLeft());
visit(p);
inorder(p.getRight());
}
}
/** 递归实现后序遍历 */
protected static void postorder(Node p) {
if (p != null) {
postorder(p.getLeft());
postorder(p.getRight());
visit(p);
}
}
/** 非递归实现前序遍历 */
protected static void iterativePreorder(Node p) {
Stack<Node> stack = new Stack<Node>();
if (p != null) {
stack.push(p);
while (!stack.empty()) {
p = stack.pop();
visit(p);
if (p.getRight() != null)
stack.push(p.getRight());
if (p.getLeft() != null)
stack.push(p.getLeft());
}
}
}
/** 非递归实现前序遍历2 */
protected static void iterativePreorder2(Node p) {
Stack<Node> stack = new Stack<Node>();
Node node = p;
while (node != null || stack.size() > 0) {
while (node != null) {//压入所有的左节点,压入前访问它
visit(node);
stack.push(node);
node = node.getLeft();
}
if (stack.size() > 0) {//
node = stack.pop();
node = node.getRight();
}
}
}
/** 非递归实现后序遍历 */
protected static void iterativePostorder(Node p) {
Node q = p;
Stack<Node> stack = new Stack<Node>();
while (p != null) {
// 左子树入栈
for (; p.getLeft() != null; p = p.getLeft())
stack.push(p);
// 当前节点无右子或右子已经输出
while (p != null && (p.getRight() == null || p.getRight() == q)) {
visit(p);
q = p;// 记录上一个已输出节点
if (stack.empty())
return;
p = stack.pop();
}
// 处理右子
stack.push(p);
p = p.getRight();
}
}
/** 非递归实现后序遍历 双栈法 */
protected static void iterativePostorder2(Node p) {
Stack<Node> lstack = new Stack<Node>();
Stack<Node> rstack = new Stack<Node>();
Node node = p, right;
do {
while (node != null) {
right = node.getRight();
lstack.push(node);
rstack.push(right);
node = node.getLeft();
}
node = lstack.pop();
right = rstack.pop();
if (right == null) {
visit(node);
} else {
lstack.push(node);
rstack.push(null);
}
node = right;
} while (lstack.size() > 0 || rstack.size() > 0);
}
/** 非递归实现后序遍历 单栈法*/
protected static void iterativePostorder3(Node p) {
Stack<Node> stack = new Stack<Node>();
Node node = p, prev = p;
while (node != null || stack.size() > 0) {
while (node != null) {
stack.push(node);
node = node.getLeft();
}
if (stack.size() > 0) {
Node temp = stack.peek().getRight();
if (temp == null || temp == prev) {
node = stack.pop();
visit(node);
prev = node;
node = null;
} else {
node = temp;
}
}
}
}
/** 非递归实现后序遍历4 双栈法*/
protected static void iterativePostorder4(Node p) {
Stack<Node> stack = new Stack<Node>();
Stack<Node> temp = new Stack<Node>();
Node node = p;
while (node != null || stack.size() > 0) {
while (node != null) {
temp.push(node);
stack.push(node);
node = node.getRight();
}
if (stack.size() > 0) {
node = stack.pop();
node = node.getLeft();
}
}
while (temp.size() > 0) {
node = temp.pop();
visit(node);
}
}
/** 非递归实现中序遍历 */
protected static void iterativeInorder(Node p) {
Stack<Node> stack = new Stack<Node>();
while (p != null) {
while (p != null) {
if (p.getRight() != null)
stack.push(p.getRight());// 当前节点右子入栈
stack.push(p);// 当前节点入栈
p = p.getLeft();
}
p = stack.pop();
while (!stack.empty() && p.getRight() == null) {
visit(p);
p = stack.pop();
}
visit(p);
if (!stack.empty())
p = stack.pop();
else
p = null;
}
}
/** 非递归实现中序遍历2 */
protected static void iterativeInorder2(Node p) {
Stack<Node> stack = new Stack<Node>();
Node node = p;
while (node != null || stack.size() > 0) {
while (node != null) {
stack.push(node);
node = node.getLeft();
}
if (stack.size() > 0) {
node = stack.pop();
visit(node);
node = node.getRight();
}
}
}
/**
* @param args
*/
public static void main(String[] args) {
BinaryTree tree = new BinaryTree(init());
System.out.print(" Pre-Order:");
preorder(tree.getRoot());
System.out.println();
System.out.print(" In-Order:");
inorder(tree.getRoot());
System.out.println();
System.out.print("Post-Order:");
postorder(tree.getRoot());
System.out.println();
System.out.print(" Pre-Order:");
iterativePreorder(tree.getRoot());
System.out.println();
System.out.print("Pre-Order2:");
iterativePreorder2(tree.getRoot());
System.out.println();
System.out.print(" In-Order:");
iterativeInorder(tree.getRoot());
System.out.println();
System.out.print(" In-Order2:");
iterativeInorder2(tree.getRoot());
System.out.println();
System.out.print(" Post-Order:");
iterativePostorder(tree.getRoot());
System.out.println();
System.out.print("Post-Order2:");
iterativePostorder2(tree.getRoot());
System.out.println();
System.out.print("Post-Order3:");
iterativePostorder3(tree.getRoot());
System.out.println();
System.out.print("Post-Order4:");
iterativePostorder4(tree.getRoot());
System.out.println();
}
}
package com.text;
public class Node {
private char key;
private Node left, right;
public Node(char key) {
this(key, null, null);
}
public Node(char key, Node left, Node right) {
this.key = key;
this.left = left;
this.right = right;
}
public char getKey() {
return key;
}
public void setKey(char key) {
this.key = key;
}
public Node getLeft() {
return left;
}
public void setLeft(Node left) {
this.left = left;
}
public Node getRight() {
return right;
}
public void setRight(Node right) {
this.right = right;
}
}
3.多线程的状态;1)初始化: new Thread的时候
2)就绪:会调用Runnable的run方法
3)阻塞:会因为挂起或者是等待请求而产生
4)停止: 执行完run()方法或者是 调用stop()方法