# What would be the time complexity of counting the number of all structurally different binary trees?

Using the method presented here: http://cslibrary.stanford.edu/110/BinaryTrees.html#java

```12. countTrees() Solution (Java)
/**
For the key values 1...numKeys, how many structurally unique
binary search trees are possible that store those keys?

Strategy: consider that each value could be the root.
Recursively find the size of the left and right subtrees.
*/
public static int countTrees(int numKeys) {
if (numKeys <=1) {
return(1);
}
else {
// there will be one value at the root, with whatever remains
// on the left and right each forming their own subtrees.
// Iterate through all the values that could be the root...
int sum = 0;
int left, right, root;

for (root=1; root<=numKeys; root++) {
left = countTrees(root-1);
right = countTrees(numKeys - root);

// number of possible trees with this root == left*right
sum += left*right;
}

return(sum);
}
}
```

I have a sense that it might be n(n-1)(n-2)...1, i.e. n!

If using a memoizer, is the complexity O(n)?

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The number of full binary trees with number of nodes n is the nth Catalan number. Catalan Numbers are calculated as

which is complexity O(n).

http://mathworld.wolfram.com/BinaryTree.html

http://en.wikipedia.org/wiki/Catalan_number#Applications_in_combinatorics

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It's easy enough to count the number of calls to `countTrees` this algorithm uses for a given node count. After a few trial runs, it looks to me like it requires 5*3^(n-2) calls for n >= 2, which grows much more slowly than n!. The proof of this assertion is left as an exercise for the reader. :-)
Incidentally, the number of binary trees with n nodes equals the n-th Catalan number. The obvious approaches to calculating Cn all seem to be linear in n, so a memoized implementation of `countTrees` is probably the best one can do.