# Prove that all P problems except {} and {a,b}* are complete

It is easy to say that `{}` and `{a,b}*` are not P complete because other problems in P can't be reduced to these because `{}` can't accept anything and `{a,b}*` cannot reject anything. So, proper mapping can't be done with a reduction function. But I'm stuck with proving that every other problem in P is P-complete.

• Is there some context missing in the question? P is a class of decision problems, but `{}` and `{a, b}*` don't look like decision problems. (You may also find cs.stackexchange a better venue for this question as it doesn't seem to relate to programming). – Paul Hankin Jul 21 '16 at 3:37
• Just an advice: cs.stackexchange.com maybe more suitable for this question (thus easier to get an answer) – shole Jul 21 '16 at 7:39
• @PaulHankin `{}` and `{a,b}*` are acceptors for languages I believe. The first one rejects every input. The second one accepts every input assuming that the language is formed of symbol a and b only. – aste123 Jul 21 '16 at 17:03

You have to be careful when talking about P-completeness because this means different things to different people based on what type of reductions you're allowing. I'm going to assume that you're talking about using polynomial-time reductions. In that case, choose any language L ∈ P other than ∅ or `{a, b}*`. Now pick any language M in P that you like. Here's a silly reduction from M to L:
• Otherwise, w ∉ M, so output any string w ∉ L that you'd like (at least one exists, because L isn't `{a, b}*`.