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  • [Leetcode] Binary tree Zigzag level order traversal二叉树Z形层次遍历

    Given a binary tree, return the zigzag level order traversal of its nodes' values. (ie, from left to right, then right to left for the next level and alternate between).

    For example:
    Given binary tree{3,9,20,#,#,15,7},

        3
       / 
      9  20
        /  
       15   7
    

    return its zigzag level order traversal as:

    [
      [3],
      [20,9],
      [15,7]
    ]
    

    confused what"{1,#,2,3}"means? > read more on how binary tree is serialized on OJ.


    OJ's Binary Tree Serialization:

    The serialization of a binary tree follows a level order traversal, where '#' signifies a path terminator where no node exists below.

    Here's an example:

       1
      / 
     2   3
        /
       4
        
         5
    
    The above binary tree is serialized as"{1,2,3,#,#,4,#,#,5}".
    题目要求按Z字形以此输出每层,主体还是层次遍历。
    思路一:只在Binary tree level order traversal的基础上增加对层数的奇偶的判断,然后依此来决定是否反转当前行即可;
    /**
     * Definition for binary tree
     * struct TreeNode {
     *     int val;
     *     TreeNode *left;
     *     TreeNode *right;
     *     TreeNode(int x) : val(x), left(NULL), right(NULL) {}
     * };
     */
    class Solution
    {
    public:
        vector<vector<int>> levelOrderBottom(TreeNode* root)
        {
            vector<vector<int>> res;
            queue<TreeNode *> Q;
            if(root)    Q.push(root);
            size_t level=1;     //第level层,初始为第一层
            while( !Q.empty())
            {
                int count=0;
                int levCount=Q.size();
                vector<int> levNode;
    
                while(count<levCount)
                {
                    TreeNode *curNode=Q.front();
                    Q.pop();
                    levNode.push_back(curNode->val);
                    if(curNode->left)
                        Q.push(curNode->left);
                    if(curNode->right)
                        Q.push(curNode->right);
                    count++;
                }
                if(level%2 ==0)     //偶数层,反转levNode再压入res
                    reverse(levNode.begin(),levNode.end());
                res.push_back(levNode);
                level++;
            }
            return res;
        }
    };

     思路二:

    利用队列,在每一层结束时向栈中压入NULL, 则遇到NULL就标志一层的结束,就可以存节点,分奇偶的选择性的反转当前层的节点。特别值得注意的是,循环到最后一行后,若是还压入NULL,会造成死循环,故在压人入NULL时要判断栈是否为空。这也是在

    层次遍历为主题的基础上增加层反转条件即可。

    /**
     * Definition for binary tree
     * struct TreeNode {
     *     int val;
     *     TreeNode *left;
     *     TreeNode *right;
     *     TreeNode(int x) : val(x), left(NULL), right(NULL) {}
     * };
     */
    class Solution {
    public:
        vector<vector<int> > zigzagLevelOrder(TreeNode *root) 
        {
            vector<vector<int>> res;
            queue<TreeNode *> Q;
            if(root==NULL)  return res;  
            Q.push(root);
            Q.push(NULL);              //第一层的结束
            vector<int> levNode;       //存放每层的节点
            size_t level=1;            //第level层,初始为第一层
            while( !Q.empty())
            {
                TreeNode *cur=Q.front();
                Q.pop();
                if(cur)
                {
                    levNode.push_back(cur->val);    //必须在if内,因栈顶节点可能为NULL
                    if(cur->left)   
                        Q.push(cur->left);
                    if(cur->right)
                        Q.push(cur->right);
                }
                else
                {
                    if(level%2 ==0)        //偶数层,反转levNode再压入res
                        reverse(levNode.begin(),levNode.end());
                    res.push_back(levNode);
                    level++;
    
                    levNode.clear();
                    if( !Q.empty())   //最后一行,不要压入
                        Q.push(NULL);
                }
            }
            return res;
        }
    };
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  • 原文地址:https://www.cnblogs.com/love-yh/p/6963057.html
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