Given a binary search tree (See Definition) and a node in it, find the in-order successor of that node in the BST.
If the given node has no in-order successor in the tree, return null.
It's guaranteed p is one node in the given tree. (You can directly compare the memory address to find p)
Given tree = [2,1] and node = 1:
2
/
1
return node 2.
Given tree = [2,1,3] and node = 2:
2
/
1 3
return node 3.
Challenge
O(h), where h is the height of the BST.
Solution 1. Recursive in-order traverse. O(n) runtime, O(h) space
1 public class Solution { 2 private boolean foundP = false; 3 private TreeNode successor = null; 4 public TreeNode inorderSuccessor(TreeNode root, TreeNode p) { 5 inOrderHelper(root, p); 6 return successor; 7 } 8 private void inOrderHelper(TreeNode node, TreeNode p) { 9 if(node == null) { 10 return; 11 } 12 inOrderHelper(node.left, p); 13 //already found p's successor 14 if(successor != null) { 15 return; 16 } 17 //just found p 18 else if(foundP) { 19 successor = node; 20 return; 21 } 22 if(node == p) { 23 foundP = true; 24 } 25 inOrderHelper(node.right, p); 26 } 27 }
Solution 2. Iterative in-order traverse. O(n) runtime, O(h) space
1 public class Solution { 2 public TreeNode inorderSuccessor(TreeNode root, TreeNode p) { 3 Stack<TreeNode> stack = new Stack<TreeNode>(); 4 TreeNode curr = root; 5 boolean findP = false; 6 while(curr != null || stack.isEmpty() == false) 7 { 8 while(curr != null) 9 { 10 stack.push(curr); 11 curr = curr.left; 12 } 13 curr = stack.pop(); 14 if(findP == true) 15 { 16 return curr; 17 } 18 if(curr == p) 19 { 20 findP = true; 21 } 22 curr = curr.right; 23 } 24 return null; 25 } 26 }
Solution 3. O(h) runtime
Since the given tree is a BST, we can use the relation between p.val and root.val to cut the current search range into half.
1. if root.val < p.val, then we need to look for p's successor in root's right subtree.
2. if root.val > p.val, then root may be p's successor, or it is in root's left subtree.
3. if root.val == p.val, if p has a right subtree, then p's successor is the smallest in p's right subtree.
Based on the above analysis, we can solve this problem in O(h) runtime either recursively or iteratively.
Iteration
Use binary search to find the node p. p is guranteed to be a node in the given tree.
1. If the current node curr's value is smaller than p's value, we know p's successor has to be on the curr's
right subtree and curr can not be p's successor. So curr should be simply eliminated from being a possible
candidate.
2. If the current node curr's value is bigger than p's value, then we must keep curr as a potential successor
candidate because curr's value is bigger than p's value.
3. After we've found p, we either check if p has a right subtree.
a.If it does, then find the smallest node out of its right subtree and that will be the correct successor.
b.If it does not have a right subtree, if successor is null, it means p is actually the last node, its successor
is nul; If successor is not null, since we only update successor when a node's value is bigger than p's value,
and no right subtree of p means its successor is the node that is stored in the variable successor.
So in both case a and b, nothing needs to be done, just return successor.
1 public TreeNode inorderSuccessor(TreeNode root, TreeNode p) { 2 if(root == null || p == null) { 3 return null; 4 } 5 TreeNode curr = root; 6 TreeNode successor = null; 7 while(curr != p) { 8 if(curr.val < p.val) { 9 curr = curr.right; 10 } 11 else { 12 successor = curr; 13 curr = curr.left; 14 } 15 } 16 if(curr.right != null) { 17 curr = curr.right; 18 while(curr != null) { 19 successor = curr; 20 curr = curr.left; 21 } 22 } 23 return successor; 24 }
Recursion
1. If current node curr's value is <= p.value, it means we need to look for p's successor in curr's right subtree.
2. If curr's value is > p.value, it means p's successor will either be curr or a node from curr's left subtree.
a. if no successor is found from curr's left subtree, then there is only one possibility: curr is p's successor;
b. if successor is found from curr's left subtree, then just return it.
1 public TreeNode inorderSuccessor(TreeNode root, TreeNode p) { 2 if(root == null) { 3 return null; 4 } 5 if(root.val <= p.val) { 6 return inorderSuccessor(root.right, p); 7 } 8 TreeNode left = inorderSuccessor(root.left, p); 9 return (left != null) ? left : root; 10 }
Related Problems
Validate Binary Search Tree
Binary Search Tree Iterator