Given an array where elements are sorted in ascending order, convert it to a height balanced BST.

For this problem, a height-balanced binary tree is defined as a binary tree in which the depth of the two subtrees of every node never differ by more than 1.

Example:

Given the sorted array: [-10,-3,0,5,9],

One possible answer is: [0,-3,9,-10,null,5], which represents the following height balanced BST:

      0

     / \

   -3   9

   /   /

 -10  5 

给定一个升序排序的数组，把它转成一个高度平衡的二叉搜索树(两个子树的深度相差不大于1)。

二叉搜索树的特点：

1. 若任意节点的左子树不空，则左子树上所有节点的值均小于它的根节点的值；
2. 若任意节点的右子树不空，则右子树上所有节点的值均大于它的根节点的值；
3. 任意节点的左、右子树也分别为二叉查找树；
4. 没有键值相等的节点。

中序遍历二叉查找树可得到一个关键字的有序序列，一个无序序列可以通过构造一棵二叉查找树变成一个有序序列，构造树的过程即为对无序序列进行查找的过程。

public TreeNode sortedArrayToBST(int[] num) {

    if (num.length == 0) {

        return null;

    }

    TreeNode head = helper(num, 0, num.length - 1);

    return head;

}

public TreeNode helper(int[] num, int low, int high) {

    if (low > high) { // Done

        return null;

    }

    int mid = (low + high) / 2;

    TreeNode node = new TreeNode(num[mid]);

    node.left = helper(num, low, mid - 1);

    node.right = helper(num, mid + 1, high);

    return node;

}

public class Solution {

    public TreeNode sortedArrayToBST(int[] nums) {

        int len = nums.length;

        if ( len == 0 ) { return null; }

        // 0 as a placeholder

        TreeNode head = new TreeNode(0); 

        Deque<TreeNode> nodeStack       = new LinkedList<TreeNode>() {{ push(head);  }};

        Deque<Integer>  leftIndexStack  = new LinkedList<Integer>()  {{ push(0);     }};

        Deque<Integer>  rightIndexStack = new LinkedList<Integer>()  {{ push(len-1); }};

        while ( !nodeStack.isEmpty() ) {

            TreeNode currNode = nodeStack.pop();

            int left  = leftIndexStack.pop();

            int right = rightIndexStack.pop();

            int mid   = left + (right-left)/2; // avoid overflow

            currNode.val = nums[mid];

            if ( left <= mid-1 ) {

                currNode.left = new TreeNode(0);

                nodeStack.push(currNode.left);

                leftIndexStack.push(left);

                rightIndexStack.push(mid-1);

            }

            if ( mid+1 <= right ) {

                currNode.right = new TreeNode(0);

                nodeStack.push(currNode.right);

                leftIndexStack.push(mid+1);

                rightIndexStack.push(right);

            }

        }

        return head;

    }

}　　

class Solution(object):

    def sortedArrayToBST(self, nums):

        """

        :type nums: List[int]

        :rtype: TreeNode

        """

        return self.sortedArrayToBSTRecu(nums, 0, len(nums))

    def sortedArrayToBSTRecu(self, nums, start, end):

        if start == end:

            return None

        mid = start + self.perfect_tree_pivot(end - start)

        node = TreeNode(nums[mid])

        node.left = self.sortedArrayToBSTRecu(nums, start, mid)

        node.right = self.sortedArrayToBSTRecu(nums, mid + 1, end)

        return node

    def perfect_tree_pivot(self, n):

        """

        Find the point to partition n keys for a perfect binary search tree

        """

        x = 1

        # find a power of 2 <= n//2

        # while x <= n//2:  # this loop could probably be written more elegantly :)

        #     x *= 2

        x = 1 << (n.bit_length() - 1)  # use the left bit shift, same as multiplying x by 2**n-1

        if x // 2 - 1 <= (n - x):

            return x - 1  # case 1: the left subtree of the root is perfect and the right subtree has less nodes

        else:

            return n - x // 2  # case 2 == n - (x//2 - 1) - 1 : the left subtree of the root

                               # has more nodes and the right subtree is perfect.

class Solution {

public:

    TreeNode* sortedArrayToBST(vector<int>& nums) {

        return sortedArrayToBSTHelper(nums, 0, nums.size() - 1);

    }

private:

    TreeNode *sortedArrayToBSTHelper(vector<int> &nums, int start, int end) {

        if (start <= end) {

            TreeNode *node = new TreeNode(nums[start + (end - start) / 2]);

            node->left = sortedArrayToBSTHelper(nums, start, start + (end - start) / 2 - 1);

            node->right = sortedArrayToBSTHelper(nums, start + (end - start) / 2 + 1, end);

            return node;

        }

        return nullptr;

    }

};　　

/**

 * 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 *sortedArrayToBST(vector<int> &num) {

        return sortedArrayToBST(num, 0 , num.size() - 1);

    }

    TreeNode *sortedArrayToBST(vector<int> &num, int left, int right) {

        if (left > right) return NULL;

        int mid = (left + right) / 2;

        TreeNode *cur = new TreeNode(num[mid]);

        cur->left = sortedArrayToBST(num, left, mid - 1);

        cur->right = sortedArrayToBST(num, mid + 1, right);

        return cur;

    }

};