标签:root size 节点 构建 turn 中序遍历 ini amp 左右子树
class Solution { public: TreeNode *buildTree(vector<int> &inorder, vector<int> &postorder) { vector<int>::size_type lenIn = inorder.size(); vector<int>::size_type lenPost = postorder.size(); return buildTree_Aux(inorder,0,lenIn-1,postorder,0,lenPost-1); } TreeNode *buildTree_Aux(vector<int> &inorder,int inB,int inE, vector<int> &postorder,int poB,int poE) { if(inB > inE || poB > poE) return NULL; //在后序遍历中确定根节点 TreeNode* root = new TreeNode(postorder[poE]); //在中序遍历中确定左右子树 vector<int>::iterator iter = find(inorder.begin()+inB,inorder.begin()+inE,postorder[poE]); int index = iter - inorder.begin();//根节点的位置
root->left = buildTree_Aux(inorder,inB,index-1,postorder,poB,poB+index-1-inB);
//这里postorder,poB,poB+index-1-inB这部分表示后序的左子树。pob是开始位置,index-1-inB是后序左子树的节点数的个数。poB+index-1-inB是后序的左子树的尾部 root->right = buildTree_Aux(inorder,index+1,inE,postorder,poB+index-inB,poE-1);
//这里postorder,poB+index-inB,poE-1这部分表示后序的右子树。poB+index-inB右子树开始位置,poE-1右子树结束位置,去掉了根节点的值(最尾部) return root; } };
/** * Definition for binary tree * 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) { vector<int>::size_type lenIn = inorder.size(); vector<int>::size_type lenPre = preorder.size(); return buildTree_Aux(preorder, 0, lenPre-1, inorder, 0, lenIn-1); } TreeNode *buildTree_Aux(vector<int> &preorder,int prb,int pre, vector<int> &inorder,int inb,int ine) { if (prb > pre || inb > ine) return NULL; TreeNode *root = new TreeNode(preorder[prb]); vector<int>::iterator iter = find(inorder.begin()+inb,inorder.begin()+ine,preorder[pre]); int mid = iter - inorder.begin(); root->left = buildTree_Aux(preorder, prb+1, prb+mid-inb, inorder, inb, mid-1); root->right = buildTree_Aux(preorder, prb+1+mid-inb, pre, inorder, mid+1, ine); return root; } };
标签:root size 节点 构建 turn 中序遍历 ini amp 左右子树
原文地址:http://www.cnblogs.com/Kobe10/p/6363455.html
