题解 | #输出二叉树的右视图#
输出二叉树的右视图
http://www.nowcoder.com/practice/c9480213597e45f4807880c763ddd5f0
思路
1)先通过前序遍历序列和中序遍历序列重建一棵二叉树(想知道如何具体实现的,可以看一看我这篇博客,里面有很详细的讲解,谢谢)
#重建二叉树(https://blog.nowcoder.net/n/897d1e8c90aa4bfbb8f6798359068ca5)
实现二叉树的重建代码如下
public TreeNode createTree (LinkedList<Integer> pre, ArrayList<Integer> vin, HashMap<Integer, Integer> nodeIndexs, int start, int end) {
if (start > end || pre.isEmpty()) {
return null;
}
if (start == end) {
return new TreeNode(pre.poll());
}
int val = pre.poll();
TreeNode root = new TreeNode(val);
int index = nodeIndexs.get(val);
TreeNode leftChild = createTree(pre, vin, nodeIndexs, start, index - 1);
TreeNode rightChild = createTree(pre, vin, nodeIndexs, index + 1, end);
root.left = leftChild;
root.right = rightChild;
return root;
}
2)然后,通过反向的广度优先遍历(即对于每一层来说,从右往左进行遍历),遍历中每一层的第一个节点就是全部加入到一个数组中,就是题目要求的右视图啦。
实现输出二叉树的右视图代码如下
public int[] rightView (TreeNode root) {
if (null == root) {
return new int[]{};
}
if (null == root.left && null == root.right) {
return new int[]{root.val};
}
LinkedList<TreeNode> queue = new LinkedList<>();
TreeNode tmpNode = root;
HashMap<TreeNode, Integer> nodeLevels = new HashMap<>();
int level = 1;
ArrayList<Integer> arrayList = new ArrayList<>();
queue.add(tmpNode);
nodeLevels.put(tmpNode, 1);
arrayList.add(tmpNode.val);
while (!queue.isEmpty()) {
tmpNode = queue.poll();
if (nodeLevels.get(tmpNode) > level) {
arrayList.add(tmpNode.val);
level = nodeLevels.get(tmpNode);
}
if (null != tmpNode.right) {
queue.add(tmpNode.right);
nodeLevels.put(tmpNode.right, nodeLevels.get(tmpNode) + 1);
}
if (null != tmpNode.left) {
queue.add(tmpNode.left);
nodeLevels.put(tmpNode.left, nodeLevels.get(tmpNode) + 1);
}
}
return arrayList.stream().mapToInt(Integer::intValue).toArray();
}
完整代码如下
public class Solution {
/**
* 代码中的类名、方法名、参数名已经指定,请勿修改,直接返回方法规定的值即可
* 求二叉树的右视图
* @param xianxu int整型一维数组 先序遍历
* @param zhongxu int整型一维数组 中序遍历
* @return int整型一维数组
*/
public int[] solve (int[] xianxu, int[] zhongxu) {
// write code here
if (0 == xianxu.length) {
return new int[]{};
}
if (1 == xianxu.length) {
return xianxu;
}
LinkedList<Integer> pre = new LinkedList<>();
ArrayList<Integer> vin = new ArrayList<>();
HashMap<Integer, Integer> nodeIndexs = new HashMap<>();
for (int val : xianxu) {
pre.add(val);
}
for (int i = 0; i < zhongxu.length; i++) {
vin.add(zhongxu[i]);
nodeIndexs.put(zhongxu[i], i);
}
TreeNode root = createTree(pre, vin, nodeIndexs, 0, vin.size() - 1);
return rightView(root);
}
public TreeNode createTree (LinkedList<Integer> pre, ArrayList<Integer> vin, HashMap<Integer, Integer> nodeIndexs, int start, int end) {
if (start > end || pre.isEmpty()) {
return null;
}
if (start == end) {
return new TreeNode(pre.poll());
}
int val = pre.poll();
TreeNode root = new TreeNode(val);
int index = nodeIndexs.get(val);
TreeNode leftChild = createTree(pre, vin, nodeIndexs, start, index - 1);
TreeNode rightChild = createTree(pre, vin, nodeIndexs, index + 1, end);
root.left = leftChild;
root.right = rightChild;
return root;
}
public int[] rightView (TreeNode root) {
if (null == root) {
return new int[]{};
}
if (null == root.left && null == root.right) {
return new int[]{root.val};
}
LinkedList<TreeNode> queue = new LinkedList<>();
TreeNode tmpNode = root;
HashMap<TreeNode, Integer> nodeLevels = new HashMap<>();
int level = 1;
ArrayList<Integer> arrayList = new ArrayList<>();
queue.add(tmpNode);
nodeLevels.put(tmpNode, 1);
arrayList.add(tmpNode.val);
while (!queue.isEmpty()) {
tmpNode = queue.poll();
if (nodeLevels.get(tmpNode) > level) {
arrayList.add(tmpNode.val);
level = nodeLevels.get(tmpNode);
}
if (null != tmpNode.right) {
queue.add(tmpNode.right);
nodeLevels.put(tmpNode.right, nodeLevels.get(tmpNode) + 1);
}
if (null != tmpNode.left) {
queue.add(tmpNode.left);
nodeLevels.put(tmpNode.left, nodeLevels.get(tmpNode) + 1);
}
}
return arrayList.stream().mapToInt(Integer::intValue).toArray();
}
}
