Second max in BST

This is an interview question. Find the second max in BST.

The max element is the rightmost leaf in the BST. The second max is either its parent or its left child. So the solution is to traverse the BST to find the rightmost leaf and check its parent and left child.

Does it make sense?

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Recall that you can list the nodes of a BST in reverse order by doing a modofied inorder traversal where you explore the right subtree first. This leads to a simple algorithm:

``````if (root.right != null)
// The check above establishes that the rightmost node has a parent
return findRightmostNode(root.right).parent
else if (root.left != null)
// Root is the rightmost node; find the largest node among the remaining ones
return findRightmostNode(root.left)
else
// The tree has only a root and no other nodes
return null
``````
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No, that's wrong. Consider this BST:

``````        137
/
42
\
99
``````

Here, the second-to-max value is the rightmost child of the left child of the max value. Your algorithm will need to be updated so that you check the parent of the max value, or the rightmost subchild of the left child of the max.

Also, note that the max is not necessarily the rightmost leaf node, it's the node at the bottom of the right spine of the tree. Above, 137 is not a leaf.

Hope this helps!

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Thanks. I thought that BST is always balanced but it was not correct. –  Michael Jul 11 '12 at 13:35
@Michael -- You should change the correct answer for this one. –  Martin Oct 21 at 5:32

The algo can be as follows

``````1. find the largest number in the tree.

private static int findLargestValueInTree(Node root) {
while (root.right != null) {
root = root.right;
}
return root.data;
}

2. Find the largest number in the tree that is smaller than the number we found in step 1

public static int findSecondLargest(Node root, int largest, int current) {
while (root != null) {
if (root.data < largest) {
current = root.data;
root = root.right;
} else {
root = root.left;
}
}
return current;
}
``````

'current' keeps track of the current largest number which is smaller than the number found in step1

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One traversal variant:

``````   public Tree GetSecondMax(Tree root)
{
Tree parentOfMax = null;

var maxNode = GetMaxNode(root, ref parentOfMax);

if (maxNode == root || maxnode.left != null)
{
// if maximum node is root or have left subtree, then return maximum from left subtree
return GetMaxNode(maxnode.left, ref parentOfMax);
}

// if maximum node is not root, then return parent of maximum node
return parentOfMax;
}

private Tree GetMaxNode(Tree root, ref Tree previousNode)
{
if (root == null || root.right == null)
{
// The most right element have reached
return root;
}

// we was there
previousNode = root;

return GetMaxNode(root.right, ref previousNode);
}
``````
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``````public static int findSecondLargestValueInBST(Node root)
{
int secondMax;
Node pre = root;
Node cur = root;
while (cur.Right != null)
{
pre = cur;
cur = cur.Right;
}
if (cur.Left != null)
{
cur = cur.Left;
while (cur.Right != null)
cur = cur.Right;
secondMax = cur.Value;
}
else
{
if (cur == root && pre == root)
//Only one node in BST
secondMax = int.MinValue;
else
secondMax = pre.Value;
}
return secondMax;
}
``````
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``````int getmax(node *root)
{
if(root->right == NULL)
{
return root->d;
}
return getmax(root->right);
}

int secondmax(node *root)
{
if(root == NULL)
{
return -1;
}

if(root->right == NULL && root->left != NULL)
{
return getmax(root->left);
}

if(root->right != NULL)
{
if(root->right->right == NULL && root->right->left == NULL)
{
return root->d;
}
}

return secondmax(root->right);
}
``````
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