For Binary tree: There's no need to consider tree node values, I am interested about different tree topologies with 'N' nodes.
For Binary Search Tree: We obviously consider tree node values.
For Binary tree: There's no need to consider tree node values, I am interested about different tree topologies with 'N' nodes. For Binary Search Tree: We obviously consider tree node values. 


I recommend this article by my colleague Nick Parlante (from back when he was still at Stanford). The count of structurally different binary trees (problem 12) has a simple recursive solution (which in closed form ends up being the Catalan formula which @codeka's answer already mentioned). I'm not sure how the number of structurally different binary search trees (BSTs for short) would differ from that of "plain" binary trees  except that, if by "consider tree node values" you mean that each node may be e.g. any number compatible with the BST condition, then the number of different (but not all structurally different!) BSTs is infinite. I doubt you mean that, so, please clarify what you do mean with an example! 


The base case is t(0) = 1 and t(1) = 1, i.e. there is one empty BST and there is one BST with one node. So, In general you can compute total no of Binary Search Trees using above formula. I was asked a question in Google interview related on this formula. Question was how many total no of Binary Search Trees are possible with 6 vertices. So Answer is t(6) = 132 I think that I gave you some idea... 


Eric Lippert recently had a very indepth series of blog posts about this: "Every Binary Tree There Is" and "Every Tree There Is" (plus some more after that). In answer to your specific question, he says:



The number of binary trees can be calculated using the catalan number. The number of binary search trees can be seen as a recursive solution. i.e., Number of binary search trees = (Number of Left binary search subtrees) * (Number of Right binary search subtrees) * (Ways to choose the root) In a BST, only the relative ordering between the elements matter. So, without any loss on generality, we can assume the distinct elements in the tree are 1, 2, 3, 4, ...., n. Also, let the number of BST be represented by f(n) for n elements. Now we have the multiple cases for choosing the root.
...... Similarly, for ith element as the root, i1 elements can be on the left and ni on the right. These subtrees are itself BST, thus, we can summarize the formula as: f(n) = f(0)f(n1) + f(1)f(n2) + .......... + f(n1)f(0) Base cases, f(0) = 1, as there is exactly 1 way to make a BST with 0 nodes. f(1) = 1, as there is exactly 1 way to make a BST with 1 node. 





If given no. of Nodes are N Then. Different No. of BST=Catalan(N) Different No. of Binary Trees are=N!*Catalan(N) 


Different binary trees with n nodes:
where C=combination eg.






Just for reference : You could refer to problem 124 second edition from Cormen  Introduction to Algorithms. Solutions are pretty much available online. 


Answer for distinct binary trees is 2nCn/(n+1) (if nodes are unlabeled) Answer for distinct BST is also 2nCn/(n+1) (because here nodes must be labelled) The below link contains an intuitive explanation. http://gatecse.in/wiki/Number_of_Binary_trees_possible_with_n_nodes 


binary tree : No need to consider values, we need to look at the structrue. Given by (2 power n)  n Eg: for three nodes it is (2 power 3) 3 = 83 = 5 different structrues binary search tree: We need to consider even the node values. We call it as Catalan Number Given by 2n C n / n+1 


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