/** * Definition for a binary tree node. * struct TreeNode { * int val; * TreeNode *left; * TreeNode *right; * TreeNode(int x) : val(x), left(NULL), right(NULL) {} * }; */ class Solution { public: TreeNode* buildTree(vector<int>& preorder, vector<int>& inorder) { //要先明白,构造一颗二叉树,首先你得构造出根节点吧,然后你再去构造左右子节点 //根节点简单,就是前序遍历的第一个元素,很容易能够构造 //关键是你要构造左右子节点以及往下的,你得知道哪些元素是左子树哪些是右子树的,这就需要通过中序序列和已知的根节点的值来确定,这是中序的特性 return build(preorder, 0, preorder.size()-1, inorder, 0, inorder.size()-1); } TreeNode* build(vector<int> preorder, int prestart, int preend, vector<int> inorder, int instart, int inend) { if(prestart > preend) return nullptr; //先保存根节点的值,找到中序序列中根节点的位置 int rootval = preorder.at(prestart); int index = 0; for(int i=instart;i<=inend;i++) { if(inorder.at(i) == rootval) { index = i; break; } } //以上找到了中序序列中根节点的位置index int leftSize = index - instart;//得到左子树节点的个数,因为要分开前序遍历序列 //先构造根节点 TreeNode* root = new TreeNode(rootval); //递归构造 root->left = build(preorder, prestart+1, index+leftSize, inorder, instart, index-1); root->right = build(preorder, prestart+leftSize+1, preend, inorder, index+1, inend); return root; } };
/** * Definition for a binary tree node. * struct TreeNode { * int val; * TreeNode *left; * TreeNode *right; * TreeNode(int x) : val(x), left(NULL), right(NULL) {} * }; */ class Solution { public: TreeNode* buildTree(vector<int>& inorder, vector<int>& postorder) { //后序和中序跟前一个一样的道理,还是应该先构造头结点,然后递归构造左右子树 //需要新建一个函数进行数组起止位置控制,别的也没什么 //后序最后一个是根节点的值 return build(inorder, 0, inorder.size()-1, postorder, 0, postorder.size()-1); } TreeNode* build(vector<int>& inorder, int inStart, int inEnd, vector<int>& postorder, int postStart, int postEnd) { //base case if(inStart > inEnd) return nullptr; //先保存根节点的值 int rootVal = postorder.at(postEnd); int index = 0;//记录中序序列中根节点的位置 for(int i=inStart;i<=inEnd;i++) { if(inorder.at(i) == rootVal) { index = i; break; } } int leftSize = index - inStart; //构造根节点 TreeNode* root = new TreeNode(rootVal); //递归构造左右子树 root->left = build(inorder, inStart, index-1, postorder, postStart, postStart+leftSize-1); root->right = build(inorder, index+1, inEnd, postorder, postStart+leftSize, postEnd-1); return root; } };
/** * Definition for a binary tree node. * struct TreeNode { * int val; * TreeNode *left; * TreeNode *right; * TreeNode(int x) : val(x), left(NULL), right(NULL) {} * }; */ class Solution { public: TreeNode* constructMaximumBinaryTree(vector<int>& nums) { return build(nums, 0, nums.size()-1); } TreeNode* build(vector<int>& nums, int lo, int hi) { //终止条件 if(lo > hi) { return nullptr; } //找到数组中的最大值,和最大值的索引,注意下面循环的起止值是lo和hi,不是从0开始 int maxNum = INT_MIN; int index = -1; for(int i=lo; i<=hi; i++) { if(nums[i] > maxNum) { maxNum = nums[i]; index = i; } } //构造最大节点(根节点) TreeNode* head = new TreeNode(maxNum); //递归构造左右子节点 head->left = build(nums, lo, index-1); head->right = build(nums, index+1, hi); return head; } };