1.Given an array where elements are sorted in ascending order, convert it to a height balanced BST.
2.Given a singly linked list where elements are sorted in ascending order, convert it to a height balanced BST.
这里两道题目。是连在一起的两题。给你一个排好序(升序)的数组或者链表,将它们转为一棵平衡二叉树。如果不排好序的话。一组随机输入的数据,就必须採用RBT或者AVL树,这样操作会变得更复杂。涉及到旋转,可是这里排好序了。所以,仅仅要找到中位数。作为根,然后递归地依据中位数的左、右数列来构建左右子树;
两题的思路都是如上所述, 唯一的差别就是,链表寻找中位数会麻烦一些。须要引入fast、slow两个指针,来寻找中位数。代码例如以下:
2.link-list
2.Given a singly linked list where elements are sorted in ascending order, convert it to a height balanced BST.
这里两道题目。是连在一起的两题。给你一个排好序(升序)的数组或者链表,将它们转为一棵平衡二叉树。如果不排好序的话。一组随机输入的数据,就必须採用RBT或者AVL树,这样操作会变得更复杂。涉及到旋转,可是这里排好序了。所以,仅仅要找到中位数。作为根,然后递归地依据中位数的左、右数列来构建左右子树;
两题的思路都是如上所述, 唯一的差别就是,链表寻找中位数会麻烦一些。须要引入fast、slow两个指针,来寻找中位数。代码例如以下:
1.Array
class Solution {
public:
TreeNode *Tree(int left, int right, vector<int> &num){
TreeNode *root = NULL;
if (left <= right){
int cen = (left + right) / 2;
root = new TreeNode(num[cen]);
root->left = Tree(left, cen - 1, num);
root->right = Tree(cen + 1, right, num);
}
return root;
}
TreeNode *sortedArrayToBST(vector<int> &num) {
TreeNode *T = NULL;
int N = num.size();
T = Tree(0, N - 1, num);
return T;
}
};2.link-list
class Solution {
public:
ListNode *findMid(ListNode *head){ //这里假设链表中仅仅有两个数字。则mid返回的是head->next.
if (head == NULL || head -> next == NULL)
return head;
ListNode *fast, *slow, *pre;
fast = slow = head;
pre = NULL;
while (fast && fast->next){
pre = slow;
slow = slow->next;
fast = fast->next->next;
}
pre->next = NULL;
return slow;
}
TreeNode *buildTree(ListNode *head){
TreeNode *root = NULL;
ListNode *mid = NULL;
if (head){
mid = findMid(head);
root = new TreeNode(mid->val);
if (head != mid){
root->left = buildTree(head);
root->right = buildTree(mid->next);
}
}
return root;
}
TreeNode *sortedListToBST(ListNode *head) {
TreeNode *T;
T = buildTree(head);
return T;
}
};