AVL树:平衡的二叉搜索树,其子树也是AVL树。
以下是我实现AVL树的源码(使用了泛型):
import java.util.Comparator; public class AVLTree<T extends Comparable<T>> { /* AVL树: 左右子树高度绝对值最多差1的二叉搜索树 子树也是AVL树 */ private Node<T> root; class Node<T extends Comparable<T>>{ T key; int height; Node<T> left; Node<T> right; public Node(T key, int height, Node<T> left, Node<T> right) { this.key = key; this.height = height; this.left = left; this.right = right; } public Node(T key){ this.key = key; this.height = 0; } } public int getHeight(Node<T> node){ return node == null ? 0 : node.height; } public Node<T> LL(Node<T> node){ //左子树插入节点在左导致不平衡,需要旋转,以下不再赘述 Node<T> leftNode = node.left; node.left = leftNode.right; leftNode.right = node; node.height = Math.max(node.left.height,node.right.height) + 1; leftNode.height = Math.max(leftNode.left.height, leftNode.right.height) + 1; return leftNode; } public Node<T> RR(Node<T> node) { Node<T> rightNode; rightNode = node.right; node.right = rightNode.left; rightNode.left = node; node.height = Math.max( node.left.height, node.right.height) + 1; rightNode.height = Math.max( rightNode.left.height, rightNode.right.height) + 1; return rightNode; } public Node<T> LR(Node<T> node){ //LR先对左子树RR再对本树LL node.left = RR(node.left); return LL(node); } public Node<T> RL(Node<T> node){ node.right = LL(node.right); return RR(node); } public Node<T> insert(Node<T> root,T key){ /* 插入:先判断插入点,再判断是否需要翻转 */ if(root == null){ return new Node<T>(key); } else{ if(key.compareTo(root.key)<0) //T是实现了comparable接口的,所以这里可以比较,但不能用大小于号 { root.left = insert(root.left,key); if(root.left.height - root.right.height == 2){ if (key.compareTo(root.left.key) < 0) root = LL(root); else root = LR(root); } }else if(key.compareTo(root.key)>0){ root.right = insert(root.right,key); if(root.left.height - root.right.height == -2){ if (key.compareTo(root.right.key) < 0) root = RL(root); else root = RR(root); } }else{ return root;//相同的节点不添加 } } return root; } public Node<T> delete(Node<T> root,T key){ /* 删除:找到删除点,判断是否需要翻转 */ if(root == null || key == null){ return root; } else{ if(key.compareTo(root.key)<0) //T是实现了comparable接口的,所以这里可以比较,但不能用大小于号 { root.left = delete(root.left,key); if(root.left.height - root.right.height == -2){ Node<T> rightNode = root.right; if (rightNode.right.height>root.left.height) root = RL(root); else root = RR(root); } }else if(key.compareTo(root.key)>0){ root.right = delete(root.right,key); if(root.left.height - root.right.height == 2){ Node<T> leftNode = root.left; if (leftNode.left.height>leftNode.right.height) root = LL(root); else root = LR(root); } }else { //找到了要删除的节点 if (root.left == null) root = root.right; else if (root.right == null) root = root.left; else { if (root.left.height < root.right.height) { Node<T> tempNode = root.right; while (tempNode.left != null) { tempNode = tempNode.left; }//为保证二叉树的平衡性、搜索性 //这里选择了高度较高的子树,选取中序遍历与root相邻的节点作为root,这样不会破坏搜索性 root.key = tempNode.key; delete(tempNode, key); } else { Node<T> tempNode = root.left; while (tempNode.right != null) { tempNode = tempNode.right; }//为保证二叉树的平衡性、搜索性 //这里选择了高度较高的子树,选取中序遍历与root相邻的节点作为root root.key = tempNode.key; delete(tempNode, key); } } } } return root; } }
内容来源于网络如有侵权请私信删除
- 还没有人评论,欢迎说说您的想法!
客服
