Consider I have an array
[3,18,15,25,26], how many possible binary search trees can be formed from it?
After looking at the question linked by MicSim, I still wasn't satisfied with that, so I began looking at it myself. Here's what I came up with...
Each tree can be thought of as two trees with a parent root node. If you know the number of possible combinations of the two children branches separately, the total combinations having that root node is the product of the children combinations.
We can begin building up a higher count solution by solving the lower count instances first.
I will use
Hopefully these two are obvious:
C(2) is also fairly obvious, but it can be built, so let's do that. There are two ways to choose the root node. One leaves a child count (left:right) of
Nothing too exciting yet. Now let's do 3 nodes. There are 3 ways to choose the root node and, hence, 3 child groupings. Your possible groups are
Based on our prior defintions,
4 nodes has child groupings of
Hopefully, two things are beginning to become apparent. First, this will start becoming cumbersome fairly soon. Second, that what I have described, in a fairly long-winded fashion, is the recurrence relation representation on the wiki page.
I don't know if this helps, but it helped me to go through the exercise, so I thought I'd share. I wasn't trying to recreate the recurrence relation when I started, so it was good that my results matched one of the existing methods.
The possible number of binary search trees that can be created with N keys is given by the Nth catalan number.
Any of the nodes of the array can be the root of a BST, and for each root, the number of distinct search trees is the combination (product) of the left and the right subarray. So,
You can evaluate this function for the first few n and then look up the sequence in the On-Line Encyclopedia of Integer Sequences™ (OEIS) to find a closed form.