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binaryTreeLevelOrderTraversal.II.cpp
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binaryTreeLevelOrderTraversal.II.cpp
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// Source : https://oj.leetcode.com/problems/binary-tree-level-order-traversal-ii/
// Author : Hao Chen
// Date : 2014-06-27
/**********************************************************************************
*
* Given a binary tree, return the bottom-up level order traversal of its nodes' values.
* (ie, from left to right, level by level from leaf to root).
*
* For example:
* Given binary tree {3,9,20,#,#,15,7},
*
* 3
* / \
* 9 20
* / \
* 15 7
*
* return its bottom-up level order traversal as:
*
* [
* [15,7],
* [9,20],
* [3]
* ]
*
* 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}".
*
*
**********************************************************************************/
/**
* 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) {
queue<TreeNode*> q;
vector< vector<int> > vv;
vector<int> v;
if (root){
v.push_back(root->val);
vv.push_back(v);
}
q.push(root);
int i=0;
vector<TreeNode*> vt;
while(q.size()>0){
TreeNode *p = q.front();
q.pop();
vt.push_back(p);
if ( p==NULL ) {
continue;
}
q.push(p->left);
q.push(p->right);
}
int step = 2;
int j;
for (int i=1; i<vt.size(); i=j ){
v.clear();
int cnt=0;
for (j=i; j<i+step && j<vt.size(); j++){
if (vt[j]) {
v.push_back(vt[j]->val);
cnt += 2;
}
}
step = cnt;
if (v.size()>0) {
vv.push_back(v);
}
}
//reverse the order
reverse(vv.begin(), vv.end());
return vv;
}
};