# How to construct BST given post-order traversal

I know there are ways to construct a tree from pre-order traversal (as an array). The more common question is to construct it, given the inorder and pre-order traversals. In this case, although the inorder traversal is redundant, it definitely makes things easier. Can anybody give me an idea how to do it for a post-order traversal? Both iterative and recursive solutions are required.

I tried to do it iteratively using stack, but couldn't at all get the logic right, so got a horrible messy tree. Same went for recursion.

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The inorder being given doesn't really make anything easier: just sort whatever traversal you're given and that's your inorder. –  IVlad Oct 31 '12 at 21:53
Yeah of course... –  Cupidvogel Nov 1 '12 at 5:27
possible duplicate of Construction of BST from given Postorder Traversal –  lucian Oct 31 '13 at 8:50

If you have an array from a post-order traversal of a BST, you know that the root is the last element of the array. The left child of the root takes up the first part of the array, and consists of entries smaller than the root. Then follows the right child, consisting of elements larger than the root. (Both children may be empty).

``````________________________________
|             |              |R|
--------------------------------
left child     right child   root
``````

So the main problem is to find the point where the left child ends and the right begins.

Both children are also obtained from their post-order traversal, so constructing them is done in the same way, recursively.

``````BST fromPostOrder(value[] nodes) {
// No nodes, no tree
if (nodes == null) return null;
return recursiveFromPostOrder(nodes, 0,  nodes.length - 1);
}

// Construct a BST from a segment of the nodes array
// That segment is assumed to be the post-order traversal of some subtree
private BST recursiveFromPostOrder(value[] nodes,
int leftIndex, int rightIndex) {
// Empty segment -> empty tree
if (rightIndex < leftIndex) return null;
// single node -> single element tree
if (rightIndex == leftIndex) return new BST(nodes[leftIndex]);

// It's a post-order traversal, so the root of the tree
// is in the last position
value rootval = nodes[rightIndex];

// Construct the root node, the left and right subtrees are then
// constructed in recursive calls, after finding their extent
BST root = new BST(rootval);

// It's supposed to be the post-order traversal of a BST, so
// * left child comes first
// * all values in the left child are smaller than the root value
// * all values in the right child are larger than the root value
// Hence we find the last index in the range [leftIndex .. rightIndex-1]
// that holds a value smaller than rootval
int leftLast = findLastSmaller(nodes, leftIndex, rightIndex-1, rootval);

// The left child occupies the segment [leftIndex .. leftLast]
// (may be empty) and that segment is the post-order traversal of it
root.left = recursiveFromPostOrder(nodes, leftIndex, leftLast);

// The right child occupies the segment [leftLast+1 .. rightIndex-1]
// (may be empty) and that segment is the post-order traversal of it
root.right = recursiveFromPostOrder(nodes, leftLast + 1, rightIndex-1);

// Both children constructed and linked to the root, done.
return root;
}

// find the last index of a value smaller than cut in a segment of the array
// using binary search
// supposes that the segment contains the concatenation of the post-order
// traversals of the left and right subtrees of a node with value cut,
// in particular, that the first (possibly empty) part of the segment contains
// only values < cut, and the second (possibly empty) part only values > cut
private int findLastSmaller(value[] nodes, int first, int last, value cut) {

// If the segment is empty, or the first value is larger than cut,
// by the assumptions, there is no value smaller than cut in the segment,
// return the position one before the start of the segment
if (last < first || nodes[first] > cut) return first - 1;

int low = first, high = last, mid;

// binary search for the last index of a value < cut
// invariants: nodes[low] < cut
//             (since cut is the root value and a BST has no dupes)
// and nodes[high] > cut, or (nodes[high] < cut < nodes[high+1]), or
// nodes[high] < cut and high == last, the latter two cases mean that
// high is the last index in the segment holding a value < cut
while (low < high && nodes[high] > cut) {

// check the middle of the segment
// In the case high == low+1 and nodes[low] < cut < nodes[high]
// we'd make no progress if we chose mid = (low+high)/2, since that
// would then be mid = low, so we round the index up instead of down
mid = low + (high-low+1)/2;

// The choice of mid guarantees low < mid <= high, so whichever
// case applies, we will either set low to a strictly greater index
// or high to a strictly smaller one, hence we won't become stuck.
if (nodes[mid] > cut) {
// The last index of a value < cut is in the first half
// of the range under consideration, so reduce the upper
// limit of that. Since we excluded mid as a possible
// last index, the upper limit becomes mid-1
high = mid-1;
} else {
// nodes[mid] < cut, so the last index with a value < cut is
// in the range [mid .. high]
low = mid;
}
}
// now either low == high or nodes[high] < cut and high is the result
// in either case by the loop invariants
return high;
}
``````
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Can you please explain you algorithm a bit more? Some inline comments would do fine... –  Cupidvogel Nov 3 '12 at 9:46
There you are, adding the comments even unearthed a superfluous `if`. –  Daniel Fischer Nov 3 '12 at 10:42
Won't the `findLastSmaller(nodes, 0, nodes.length - 2, rootval);` line be `findLastSmaller(nodes, leftindex, rightindex - 2, rootval);`? –  Cupidvogel Nov 3 '12 at 11:09
It's `rightIndex-1`, since the root value sat at `rightIndex`. But in principle, yeah. I moved that call from the public to the recursive when deciding I didn't need to handle the root specially and forgot to adjust parameters (:blush:). –  Daniel Fischer Nov 3 '12 at 11:26
@MohitJain `O(n*log n)`. For every node, we need a binary search with complexity `O(log n)` [a sharper bound is `O(log t)`, where `t` is the size of the subtree whose root is the node we're currently treating, that doesn't change the complexity, however, it only produces a constant factor]. –  Daniel Fischer Jan 18 '14 at 15:06

You don't really need the inorder traversal. There's a simple way to reconstruct the tree given only the post-order traversal:

1. Take the last element in the input array. This is the root.
2. Loop over the remaining input array looking for the point where the elements change from being smaller than the root to being bigger. Split the input array at that point. This can also be done with a binary search algorithm.
3. Recursively reconstruct the subtrees from those two sub-arrays.

This can easily be done either recursively or iteratively with a stack, and you can use two indices to indicate the start and end of the current sub-array rather than actually splitting the array.

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Postorder traversal goes like this:

``````visit left
visit right
print current.
``````

And inorder like this:

``````visit left
print current
visit right
``````

Let's take an example:

``````        7
/     \
3      10
/ \     / \
2   5   9   12
/
11
``````

Inorder is: `2 3 5 7 9 10 11 12`

Postorder is: `2 5 3 9 11 12 10 7`

Iterate the postorder array in reverse order and keep splitting the inorder array around where that value is. Do this recursively and that will be your tree. For example:

``````current = 7, split inorder at 7: 2 3 5 | 9 10 11 12
``````

Look familiar? What is on the left is the left subtree and what is on the right is the right subtree, in a pseudo-random order as far as the BST structure is concerned. However, you now know what your root is. Now do the same for the two halves. Find the first occurrence (from the end) of an element from the left half in the postorder traversal. That will be 3. Split around 3:

``````current = 3, split inorder at 3: 2 | 5 ...
``````

So you know your tree looks like this so far:

``````   7
/
3
``````

This is based on the facts that a value in the postorder traversal will always appear after its children have appeared and that a value in the inorder traversal will appear between its children values.

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