The transitive closure of a graph is defined e. g. here: http://mathworld.wolfram.com/TransitiveClosure.html
It is easily possible in O(n^3), where n is the number of vertices. I was wondering if it can be done in time O(n^2).
The transitive closure of a graph is defined e. g. here: http://mathworld.wolfram.com/TransitiveClosure.html It is easily possible in O(n^3), where n is the number of vertices. I was wondering if it can be done in time O(n^2). 


Nope. I don't think there is a O(n^{2}) algorithm for it. I would expect if such an algorithm existed, you could solve all pair shortest paths problem in O(n^{2}) too, which is not the case. The asymptotically fastest algorithm I can think of is an implementation of Dijkstra's shortest path algorithm with a Fibonacci heap (O(n^{2}log n) in not very dense graphs). 


Hmm. I found an algorithm that computes the transitive closure in O(n^2) EXPECTED run time. 


Given that this:
Is still considered an open question by people who think about these sorts of things more than we do, I'd say "I don't know". (But if you solve it and want a PhD, I know that algorithm.) 

