二叉链表存储的思想是让每个节点都记住它的左、右两个子节点,为每个节点增加left、right两个指针,分别引用该节点的左、右两个子节点,如图所示:
其中,每个节点大致有如下定义:
class Node{ T data; Node left; Node right; }对于这种二叉链表存储的二叉树,如果程序需要,为指定节点添加子节点也非常容易,让父节点的left、right引用指向新节点即可。
Java实现代码:
package com.liuhao.DataStructures; public class TwoLinkBinTree<E> { public static class TreeNode{ Object data; TreeNode left; TreeNode right; public TreeNode(){} public TreeNode(Object data){ this.data = data; } public TreeNode(Object data, TreeNode left, TreeNode right) { this.data = data; this.left = left; this.right = right; } } private TreeNode root; //以默认的构造器创建 public TwoLinkBinTree(){ this.root = new TreeNode(); } //以指定根元素创建 public TwoLinkBinTree(E data){ this.root = new TreeNode(data); } /** * 为指定节点添加子节点 * @param parent 需要添加节点的父节点的索引 * @param data 新添加子节点的数据 * @param isLeft 是否是添加左子节点 * @return 新增的节点 */ public TreeNode addNode(TreeNode parent, E data, boolean isLeft){ if(parent == null){ throw new RuntimeException(parent + "节点为空,不能添加子节点!"); } if(isLeft && parent.left != null){ throw new RuntimeException(parent + "节点已有左子节点,不能添加左子节点!"); } if(!isLeft && parent.right != null){ throw new RuntimeException(parent + "节点已有右子节点,不能添加右子节点!"); } TreeNode newNode = new TreeNode(data); if(isLeft){ parent.left = newNode; }else{ parent.right = newNode; } return newNode; } //判断二叉树是否为空 public boolean isEmpty(){ return root.data == null; } //获取根节点 public TreeNode getRoot(){ if(isEmpty()){ throw new RuntimeException("树为空,无法获取根节点!"); } return root; } //获取指定节点的左子节点 public TreeNode getLeft(TreeNode parent){ if(parent == null){ throw new RuntimeException(parent + "节点为空,不能获取子节点!"); } return parent.left == null ? null : parent.left; } //获取指定节点的右子节点 public TreeNode getRight(TreeNode parent){ if(parent == null){ throw new RuntimeException(parent + "节点为空,不能获取子节点!"); } return parent.right == null ? null : parent.right; } //获取指定节点的深度 private int getDeep(TreeNode node){ if(node == null){ return 0; } if(node.left == null && node.right == null){ return 1; }else{ int leftDeep = getDeep(node.left); int rightDeep = getDeep(node.right); int max = leftDeep > rightDeep ? leftDeep : rightDeep; return max + 1; } } public int getTreeDeep(){ return this.getDeep(root); } }测试代码:
package com.liuhao.DataStructures; import org.junit.Test; public class TwoLinkBinTreeTest { @Test public void test() { TwoLinkBinTree<String> binTree = new TwoLinkBinTree<String>("根"); TwoLinkBinTree.TreeNode node1 = binTree.addNode(binTree.getRoot(), "根左", true); TwoLinkBinTree.TreeNode node2 = binTree.addNode(binTree.getRoot(), "根右", false); TwoLinkBinTree.TreeNode node3 = binTree.addNode(node2, "根右左", true); TwoLinkBinTree.TreeNode node4 = binTree.addNode(node2, "根右右", false); TwoLinkBinTree.TreeNode node5 = binTree.addNode(node4, "根右右左", true); TwoLinkBinTree.TreeNode node6 = binTree.addNode(node3, "根右左右", false); TwoLinkBinTree.TreeNode node7 = binTree.addNode(node6, "根右左右右", false); System.out.println("node2的左子节点:" + binTree.getLeft(node2).data); System.out.println("node2的右子节点:" + binTree.getRight(node2).data); System.out.println("树的深度:" + binTree.getTreeDeep()); } }对于这种二叉链表的二叉树,因为采用链表来记录树中所有节点,所以添加节点没有限制,而且不会希像顺序存储那样产生大量的空间浪费。当然,这种二叉链表的存储方式在遍历树节点时效率不高,指定节点访问其父节点时也是如此,程序必须采用遍历二叉树的方式来搜寻其父节点。
二叉树的二叉链表存储及其Java实现,布布扣,bubuko.com
原文地址:http://blog.csdn.net/bruce_6/article/details/38229639