Many times I've heard that if we can reduce problem A to problem B in polynomial time, then the problem B is at least as hard as problem A. How precise is this statement? I believe we should understand it in this way: if A can be poly-time reduced to B, then if there's a poly-time algorithm for B, then it must be there for A.

My point is that A can actually be harder than B (can have higher time complexity, for example O(n^100), compared to B - O(n^4), because the poly-time reduction itself can be time consuming. So the sum of O(n^4) and time needed for reduction could give an algorithm for A that will be O(n^100). So every time I read A is no harder than B in this context is that it's impossible for A to have no polynomial time algorithm while B has one. Is that correct?



In general, I would say that the term 'hard' in this statement corresponds to a complexity class, not to a degree of the polynomial. Or, rather, a 'hardness' of a problem is the minimal complexity class containing this problem.

That is, if A is at least as hard as B, then the minimal complexity class for B is superseded by the minimal complexity class of A.


As @Inspired points out , this statement is related to the complexity class rather than the actual time complexity of the two problems , this statement is generally used for NP complete problems .

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.