1、单向链表
实现思路:创建Node类,包括自己的数据和指向下一个;创建Node类,包括头尾节点,实现添加、删除、输出等功能。
tips:n = n.next不破坏链表结果,而n.next = n.next.next就等于是n节点的next属性变成了再下一个,即指向n+1个节点的指针丢失,但实际上n+1节点仍在,只不过从链表中去除。
具体代码:
public class NodeList<Integer> { class Node<Integer> { Node<Integer> next = null; //指向下一节点 Integer data; //节点所存数据 //Node类构造方法 public Node(Integer d) { this.data = d; } } Node<Integer> head; //链表的头节点 Node<Integer> last; //链表的尾节点 int length; //链表长度 //链表的无参构造方法 public NodeList() { this.head = new Node<Integer>(null); //头节点为空 } //创建链表的同时添加第一个数据 public NodeList(Integer d) { this.head = new Node<Integer>(d); this.last = head; //此时头尾节点一样 length++; } //尾部添加节点 public void add(Integer d) { if (head == null) { head = new Node<Integer>(d); last = head; length++; } else { Node<Integer> newNode = new Node<Integer>(d); last.next = newNode; //令之前的尾节点指向新节点 last = newNode; //新节点成为尾节点 length++; } } //删除指定数据 public boolean del(Integer d) { if (head == null) { return false; } Node<Integer> n = head; //从头开始判断 if (n.data == d) { head = head.next; length--; return true; } while (n.next != null) { if (n.next.data == d) { n.next = n.next.next; //n节点指向了n+2节点 length--; return true; } n = n.next; //正常移动不破坏链表 } return false; } public void print() { if (head == null) { System.out.println("此链表为空!"); } Node<Integer> n = head; while (n != null) { System.out.println(n.data+","); n = n.next; } } }
2016-12-13 16:22:13
2、栈(链式结构)
实现思路:仍然使用节点,最重要的是栈顶节点top,利用其完成压、弹栈操作。
tips:出栈就是改栈顶为下一个,压栈就是新栈顶与原栈顶建立链接。
具体代码:
public class Stack { class Node { Object data; Node next = null; public Node(Object d) { this.data = d; } } Node top; //创建栈顶节点 //出栈 public Object pop() { if (top != null) { Object d = top.data; top = top.next; //栈顶改为下一个 return d; } return null; } //压栈 public void push(Object d) { Node n = new Node(d); n.next = top; //与原栈进行连接 top = n; } //输出栈顶的元素 public Object peek() { return top.data; } }
2016-12-14 14:14:12
3、队列(链式结构)
实现思路:创建首尾节点first、last,实现入队出队操作。
tips:记得判断是否为空。
具体代码:
public class Queue { class Node { Object data; Node next; public Node(Object d) { this.data = d; } } //创建队首队尾指针 Node first; Node last; //入队 public void enQueue(Object d) { if (first == null) { first = new Node(d); last = first; } else { last.next = new Node(d); //原队尾指向新节点 last = last.next; //更改队尾 } } //出队 public Object deQueue() { if (first != null) { Object item = first.data; //保存原队首数据 first = first.next; //更改队首 return item; } return null; } }
2016-12-14 14:27:16
4、树的遍历
4.1、前序preorder
顺序:根左右
非递归:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Preorder in ArrayList which contains node values. */ public List<Integer> preorderTraversal(TreeNode root) { Stack<TreeNode> stack = new Stack<TreeNode>(); List<Integer> preorder = new ArrayList<Integer>(); if (root == null) { return preorder; } stack.push(root); while (!stack.empty()) { TreeNode node = stack.pop(); preorder.add(node.val); if (node.right != null) { stack.push(node.right); } if (node.left != null) { stack.push(node.left); } } return preorder; } }
Traverse:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Preorder in ArrayList which contains node values. */ public ArrayList<Integer> preorderTraversal(TreeNode root) { ArrayList<Integer> preorder = new ArrayList<Integer>(); helper(root, preorder); return preorder; } private void helper(TreeNode root, ArrayList<Integer> preorder) { if (root == null) { return; } preorder.add(root.val); helper(root.left, preorder); helper(root.right, preorder); }
Divide & Conquer:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Preorder in ArrayList which contains node values. */ public ArrayList<Integer> preorderTraversal(TreeNode root) { ArrayList<Integer> preorder = new ArrayList<Integer>(); if (root == null) { return preorder; } //Divide ArrayList<Integer> left = preorderTraversal(root.left); ArrayList<Integer> right = preorderTraversal(root.right); //Conquer preorder.add(root.val); preorder.addAll(left); preorder.addAll(right); return preorder; } }
4.2、中序inorder
顺序:左根右
非递归:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Inorder in ArrayList which contains node values. */ public ArrayList<Integer> inorderTraversal(TreeNode root) { Stack<TreeNode> stack = new Stack<TreeNode>(); ArrayList<Integer> inorder = new ArrayList<Integer>(); TreeNode curt = root; while (curt != null || !stack.empty()) { while (curt != null) { stack.add(curt); curt = curt.left; } curt = stack.peek(); stack.pop(); inorder.add(curt.val); curt = curt.right; } return inorder; } }
Traverse:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Inorder in ArrayList which contains node values. */ public ArrayList<Integer> inorderTraversal(TreeNode root) { ArrayList<Integer> inorder = new ArrayList<Integer>(); helper(root, inorder); return inorder; } private void helper(TreeNode root, ArrayList<Integer> inorder) { if (root == null) { return; } helper(root.left, inorder); inorder.add(root.val); helper(root.right, inorder); } }
Divide & Conquer:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Inorder in ArrayList which contains node values. */ public ArrayList<Integer> inorderTraversal(TreeNode root) { ArrayList<Integer> inorder = new ArrayList<Integer>(); if (root == null) { return inorder; } ArrayList<Integer> left = inorderTraversal(root.left); ArrayList<Integer> right = inorderTraversal(root.right); inorder.addAll(left); inorder.add(root.val); inorder.addAll(right); return inorder; } }
4.3、后序postorder
顺序:左右根
非递归:
/** * Definition of TreeNode: * public class TreeNode { * public int val; * public TreeNode left, right; * public TreeNode(int val) { * this.val = val; * this.left = this.right = null; * } * } */ public class Solution { /** * @param root: The root of binary tree. * @return: Postorder in ArrayList which contains node values. */ public ArrayList<Integer> postorderTraversal(TreeNode root) { ArrayList<Integer> postorder = new ArrayList<Integer>(); Stack<TreeNode> stack = new Stack<TreeNode>(); TreeNode prev = null; //前一个遍历节点 TreeNode curr = root; if (root == null) { return postorder; } stack.push(root); while (!stack.empty()) { curr = stack.peek(); if (prev == null || prev.left == curr || prev.right == curr) { //往下遍历 if (curr.left != null) { stack.push(curr.left); } else if (curr.right != null) { stack.push(curr.right); } } else if (curr.left == prev) { //从左往上遍历 if (curr.right != null) { stack.push(curr.right); } } else { //从右往上遍历 postorder.add(curr.val); stack.pop(); } prev = curr; } return postorder; } }
递归与上面一样
2017-01-27