What is validating a binary search tree?

I read on here of an exercise in interviews known as validating a binary search tree.

How exactly does this work? What would one be looking for in validating a binary search tree? I have written a basic search tree, but never heard of this concept.

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Use inorder traversal, and check if each element is greater than the previous element. –  dalle Mar 30 '10 at 8:16
Please unaccept the current accepted answer, which is blatantly wrong. –  Aryabhatta Apr 29 '11 at 22:50

Actually that is the mistake everybody does in an interview.

Leftchild must be checked against (minLimitof node,node.value)

Rightchild must be checked against (node.value,MaxLimit of node)

``````IsValidBST(root,-infinity,infinity);

bool IsValidBST(BinaryNode node, int MIN, int MAX)
{
if(node == null)
return true;
if(node.element > MIN
&& node.element < MAX
&& IsValidBST(node.left,MIN,node.element)
&& IsValidBST(node.right,node.element,MAX))
return true;
else
return false;
}
``````

Another solution (if space is not a constraint): Do an inorder traversal of the tree and store the node values in an array. If the array is in sorted order, its a valid BST otherwise not.

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"Another solution(if space is not a constraint) Do an inorder traversal of the tree and store the node values in an array. If the array is in sorted order, its a valid BST otherwise not."... Well you don't need space or an array to do that. If you can do the traversal in the first place, and the array that you would create should be sorted, then each element that you visit during the traversal must be greater (or, in the limit case, equal) to the previous one, right? –  Daniel Daranas Apr 17 '09 at 10:33
Yes. I agree with that. but still we need one global variable to assign and access the previous value in the recursive calls. and its better than my previous example passing (MIN,MAX) on each call and eat up space on stack. Thanks –  g0na Apr 17 '09 at 10:50
Your algorithm is wrong... as if you have a tree with one root of value: 2 and one right child with value: 2, you will say it isn't a BST, when in fact it is. –  Yarneo Sep 20 '12 at 14:55
@Yarneo A valid BST contains no duplicate nodes so I believe this algorithm is correct: en.wikipedia.org/wiki/Binary_search_tree –  user784637 Jan 20 at 23:35

"Validating" a binary search tree means that you check that it does indeed have all smaller items on the left and large items on the right. Essentially, it's a check to see if a binary tree is a binary search tree.

This page allows you to draw a binary tree and validate it to see if it's a binary search tree.

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@j32: The page you linked to doesn't 'do' anything. It's just doco... –  Mitch Wheat Feb 1 '09 at 1:56
It has a Java applet that allows you draw a binary tree... Anyway, that was just an example usage of the term. –  wj32 Feb 1 '09 at 2:00
broken page, fyi –  dotcomXY Nov 8 at 20:16

Iterative solution using inorder traversal.

``````bool is_bst(Node *root) {
if (!root)
return true;

std::stack<Node*> stack;
bool started = false;
Node *node = root;
int prev_val;

while(true) {
if (node) {
stack.push(node);
node = node->left();
continue;
}
if (stack.empty())
break;
node = stack.top();
stack.pop();

/* beginning of bst check */
if(!started) {
prev_val = node->val();
started = true;
} else {
if (prev_val > node->val())
return false;
prev_val = node->val();
}
/* end of bst check */

node = node->right();
}
return true;
}
``````
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Good note to point out from your solution is that recursive solutions can sometimes be bad news on a production instance if you smash the stack –  TheCapn Jul 19 '12 at 13:58

Here is my solution in Clojure:

``````(defstruct BST :val :left :right)

(defn in-order [bst]
(when-let [{:keys [val, left, right]} bst]
(lazy-seq
(concat (in-order left) (list val) (in-order right)))))

(defn is-strictly-sorted? [col]
(every?
(fn [[a b]] (< a  b))
(partition 2 1 col)))

(defn is-valid-BST [bst]
(is-strictly-sorted? (in-order bst)))
``````
-

The best solution I found is O(n) and it uses no extra space. It is similar to inorder traversal but instead of storing it to array and then checking whether it is sorted we can take a static variable and check while inorder traversing whether array is sorted.

``````static struct node *prev = NULL;

bool isBST(struct node* root)
{
// traverse the tree in inorder fashion and keep track of prev node
if (root)
{
if (!isBST(root->left))
return false;

// Allows only distinct valued nodes
if (prev != NULL && root->data <= prev->data)
return false;

prev = root;

return isBST(root->right);
}

return true;
}
``````
-

Recursive solution:

isBinary(root)

``````{
if root == null
return true
else if( root.left == NULL and root.right == NULL)
return true
else if(root.left == NULL)
if(root.right.element > root.element)
rerturn isBInary(root.right)
else if (root.left.element < root.element)
return isBinary(root.left)
else
return isBInary(root.left) and isBinary(root.right)

}
``````
-
``````bool BinarySearchTree::validate() {
int minVal = -1;
int maxVal = -1;
return ValidateImpl(root, minVal, maxVal);
}

bool BinarySearchTree::ValidateImpl(Node *currRoot, int &minVal, int &maxVal)
{
int leftMin = -1;
int leftMax = -1;
int rightMin = -1;
int rightMax = -1;

if (currRoot == NULL) return true;

if (currRoot->left) {
if (currRoot->left->value < currRoot->value) {
if (!ValidateImpl(currRoot->left, leftMin, leftMax)) return false;
if (leftMax != currRoot->left->value && currRoot->value < leftMax)  return false;
}
else
return false;
} else {
leftMin = leftMax = currRoot->value;
}

if (currRoot->right) {
if (currRoot->right->value > currRoot->value) {
if(!ValidateImpl(currRoot->right, rightMin, rightMax)) return false;
if (rightMin != currRoot->right->value && currRoot->value > rightMin)  return false;
}
else return false;
} else {
rightMin = rightMax = currRoot->value;
}

minVal = leftMin < rightMin ? leftMin : rightMin;
maxVal = leftMax > rightMax ? leftMax : rightMax;

return true;
}
``````
-
``````bool ValidateBST(Node *pCurrentNode, int nMin = INT_MIN, int nMax = INT_MAX)
{
return
(
pCurrentNode == NULL
)
||
(
(
!pCurrentNode->pLeftNode ||
(
pCurrentNode->pLeftNode->value < pCurrentNode->value &&
pCurrentNode->pLeftNode->value < nMax &&
ValidateBST(pCurrentNode->pLeftNode, nMin, pCurrentNode->value)
)
)
&&
(
!pCurrentNode->pRightNode ||
(
pCurrentNode->pRightNode->value > pCurrentNode->value &&
pCurrentNode->pRightNode->value > nMin &&
ValidateBST(pCurrentNode->pRightNode, pCurrentNode->value, nMax)
)
)
);
}
``````
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My intention is to show another solution where the recursion doesn't go into a branch unless it's valid. The current top answer must go into a branch to check it's validity... –  Mike X May 20 '12 at 4:22

I used the code from g0na in an interview last week. I had gotten this exact question in a previous interview and looked up the the answer. The code is exactly what an interviewer is looking for: a simple, tight solution to a problem you'll likely never see in the real world. I still waiting for "how to tell if 2 rectangles overlap."

-

Here is my Java solution of determining whether a tree is a valid BST or not:

http://exceptional-code.blogspot.com/2011/08/binary-search-trees-primer.html

It also contains other familiar operations that can be done on a BST like finding the successor or a predecessor of a node. Hope you find this useful too.

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``````// using inorder traverse based Impl
bool BinarySearchTree::validate() {
int val = -1;
return ValidateImpl(root, val);
}

// inorder traverse based Impl
bool BinarySearchTree::ValidateImpl(Node *currRoot, int &val) {
if (currRoot == NULL) return true;

if (currRoot->left) {
if (currRoot->left->value > currRoot->value) return false;
if(!ValidateImpl(currRoot->left, val)) return false;
}

if (val > currRoot->value) return false;
val = currRoot->value;

if (currRoot->right) {
if (currRoot->right->value < currRoot->value) return false;
if(!ValidateImpl(currRoot->right, val)) return false;
}
return true;
}
``````
-

"It's better to define an invariant first. Here the invariant is -- any two sequential elements of the BST in the in-order traversal must be in strictly increasing order of their appearance (can't be equal, always increasing in in-order traversal). So solution can be just a simple in-order traversal with remembering the last visited node and comparison the current node against the last visited one to '<' (or '>')."

-

To find out whether given BT is BST for any datatype, you need go with below approach. 1. call recursive function till the end of leaf node using inorder traversal 2. Build your min and max values yourself.

Tree element must have less than / greater than operator defined.

``````#define MIN (FirstVal, SecondVal) ((FirstVal) < (SecondVal)) ? (FirstVal):(SecondVal)
#define MAX (FirstVal, SecondVal) ((FirstVal) > (SecondVal)) ? (FirstVal):(SecondVal)

template <class T>
bool IsValidBST (treeNode &root)
{

T min,  max;
return IsValidBST (root, &min, &max);
}

template <class T>
bool IsValidBST (treeNode *root, T *MIN , T *MAX)
{
T leftMin, leftMax, rightMin, rightMax;
bool isValidBST;

if (root->leftNode == NULL && root->rightNode == NULL)
{
*MIN = root->element;
*MAX = root->element;
return true;
}

isValidBST = IsValidBST (root->leftNode, &leftMin, &leftMax);

if (isValidBST)
isValidBST = IsValidBST (root->rightNode, &rightMin, &rightMax);

if (isValidBST)
{
*MIN = MIN (leftMIN, rightMIN);
*Max = MAX (rightMax, leftMax);
}

return isValidBST;
}
``````
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Probably should fix up your code -- you've made pre-processor macros of MIN and MAX, but then try to use MIN and MAX as variable (parameter) names. –  MikeB Jan 31 at 18:18
``````bool isBST(struct node* root)
{
static struct node *prev = NULL;
// traverse the tree in inorder fashion and keep track of prev node
if (root)
{
if (!isBST(root->left))
return false;
// Allows only distinct valued nodes
if (prev != NULL && root->data <= prev->data)
return false;
prev = root;
return isBST(root->right);
}
return true;
}
``````

Works Fine :)

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This doesn't work if you call it more than once, and it's also not thread safe. –  Andrey Feb 12 at 15:46

My dear friends all answers are great but be prepared to answer the following potential follow up questions:

1. what if you have not number but something different with natural ordering to compare each other. Answer can be for java language to implement compareTo method.

2. what if you have not number but something different without natural ordering to compare each other. Answer can be for java language to implement comparator .

3. what kind of design patters will you use in above cases. Answer can be tamplate method(or ill formed of it)

I have personally used to have such follow up questions in my interview with one well known company for the same question.

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In a job interview the most correct answer depends on what person who is conducting interview wants. You should anticipate or listen to what interviewer wants. And be always prepared for follow up questions. Be prepared to defend correctly you answer. So here copy and paste method does not work. –  Khurshed Salimov Dec 12 '12 at 15:50
Think of real software development project's development environment. You have always a context to apply your solution in, right? So job interviewer simulates that environment for you. –  Khurshed Salimov Dec 12 '12 at 16:03

Recursion is easy but iterative approach is better, there is one iterative version above but it's way too complex than necessary. Here is the best solution in `c++` you'll ever find anywhere:

This algorithm runs in `O(N)` time and needs `O(lgN)` space.

``````struct TreeNode
{
int value;
TreeNode* left;
TreeNode* right;
};

bool isBST(TreeNode* root) {
vector<TreeNode*> stack;
TreeNode* prev = nullptr;
while (root || stack.size()) {
if (root) {
stack.push_back(root);
root = root->left;
} else {
if (prev && stack.back()->value <= prev->value)
return false;
prev = stack.back();
root = prev->right;
stack.pop_back();
}
}
return true;
}
``````
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This code doesn't seem to detect duplicate values. –  MikeB Jan 31 at 19:10
I think it does, can you construct a counter example? –  shuais Feb 8 at 10:06
Trivially: a two node tree that has the same integer in "value" of both nodes will still have your isBST() function returning "true". Since you're only returning false when value < value, you'll never detect it. Why do you think that test works to find duplicates? –  MikeB Feb 10 at 16:01
I thought duplicates are allowed in BST, but wikipedia seems to be against it. Then you're right, the < should be <=. –  shuais Feb 11 at 5:22
Using <= means that no node can have INT_MIN as its value. –  MikeB Feb 11 at 16:15

I wrote a solution to use inorder Traversal BST and check whether the nodes is increasing order for space `O(1)` AND time `O(n)`. `TreeNode predecessor` is prev node. I am not sure the solution is right or not. Because the inorder Traversal can not define a whole tree.

``````public boolean isValidBST(TreeNode root, TreeNode predecessor) {
boolean left = true, right = true;
if (root.left != null) {
left = isValidBST(root.left, predecessor);
}
if (!left)
return false;

if (predecessor.val > root.val)
return false;

predecessor.val = root.val;
if (root.right != null) {
right = isValidBST(root.right, predecessor);
}

if (!right)
return false;

return true;

}
``````
-
``````boolean isBST(Node root) {
if (root == null) { return true; }
return (isBST(root.left) && (isBST(root.right) && (root.left == null || root.left.data <= root.data) && (root.right == null || root.right.data > root.data));
}
``````
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This is wrong. See Scott's Answer. –  st0le May 8 '12 at 4:27

Here is the iterative solution without using extra space.

``````Node{
int value;
Node right, left
}

public boolean ValidateBST(Node root){
Node currNode = root;
Node prevNode = null;
Stack<Node> stack = new Stack<Node>();
while(true){
if(currNode != null){
stack.push(currNode);
currNode = currNode.left;
continue;
}
if(stack.empty()){
return;
}
currNode = stack.pop();
if(prevNode != null){
if(currNode.value < prevNode.value){
return false;
}
}
prevNode = currNode;
currNode = currNode.right;
}
}
``````
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Iterative solution without using extra space? But you're using a stack here and do `stack.push()`! –  Alexey Frunze May 20 '12 at 4:53