# Example problems not in P nor in NP-complete but in NP

I have a course called Algorithm Analysis at college, where we're currently studying the different complexity classes -- P, NP, NP-hard etc.

We've already discussed NP-complete problems as the intersection between NP and NP-hard, and P problems, contained in NP. We've also talked about some examples, mainly of NP-complete problems (k-coloring, k-clique, SAT).

Most of the time, we prove a problem is NP-complete by:

a. Finding a nondeterministic algorithm to solve it (that uses choice, success, fail);

b. Reducing a known NP-complete problem to it.

The thing is that these problems, when run on a deterministic machine (sequentially, instead of simultaneously branching when encountering a choice) have exponential-time solutions.

My question is this -- I've never encountered problems that were solvable neither in polynomial time neither in exponential time; polynomial time problems are in P and exponential-time problems are usually in NP-complete.

There's a helpful Venn diagram here: http://en.wikipedia.org/wiki/Np_complete

1. I'd like to know an example of a problem that is neither in P, neither in NP-complete, but in NP.

2. Also, are intrinsically exponential problems, like generating the power set of a set NP-complete? Or does that name only apply for problems for which an exponential time algorithm is used only because there's no other obvious method for solving it?

Ok, so I gave the answer to Rosh Oxymoron because he actually listed some examples of problems suspected to be between P and NPC. Thanks for your help guys, and I actually noticed that I put this question in the wrong place. There's also: https://cstheory.stackexchange.com/

where I found the following very useful answers to my question: https://cstheory.stackexchange.com/questions/79/problems-between-p-and-npc which is specifically about what I asked, and: https://cstheory.stackexchange.com/questions/52/hierarchies-in-np-under-the-assumption-that-p-np which is generally interesting, if not exactly related to the initial question.

Thanks a lot,

Dan

1. BQP problems such as integer factorization and discrete logarithm (cracking RSA and DSA) are thought to be outside of P and are also suspected to be in NP but not in NP-complete. Integer factorization is known to be in NP, and is supposed to be outside of P and NP-complete.

http://en.wikipedia.org/wiki/BQP

http://en.wikipedia.org/wiki/Integer_factorization

1. NP is a subset of EXPTIME, but it is expected that NP != EXPTIME (that is, EXPTIME-complete problems are not in NP). Like with P = NP, this is not yet proven (but it is known that P != EXPTIME). For example checking if an algorithm would half after k steps is EXPTIME-complete. Finding the power set is too (obviously).

http://en.wikipedia.org/wiki/EXPTIME

• It's important to stress that 1. is conjecture. If P=NP no such problems exist, but if P!=NP we know that NPI is not empty. – Raphael Jun 23 '16 at 9:29

I'd like to know an example of a problem that is neither in P, neither in NP-complete, but in NP.

Me too; if you find one go ahead and visit this web page to claim your \$1M prize: http://www.claymath.org/millennium/P_vs_NP/

• How about BQP above? – Rohit Banga Feb 24 '11 at 14:04
• @iamrohitbanga To use BQP as P≠NP proof all of these things must be proven: 1. BQP ⊆ NP 2. P ⊊ BQP 3. BQP ∩ NPC = ∅. All of those are currently not known. – dtech Apr 15 '12 at 12:59
1. There is no problem known to be in `NP \ NPC`.

2. A problem is in NP if and only if a non-deterministic turing machine can solve it in polynomial time (or, equivalently, a deterministic turing machine can decide it in polynomial time). This is not the case for your example.

Further it should be pointed out that we do not know whether `P = NP`, so it's perfectly possible (if highly unlikely) that all problems in `NP` can be solved in polynomial time. So if we know that a problem can not be solved in polynomial time, that problem is either not in NP or, if we can prove that it is indeed in NP, we just showed that `NP != P`.

• 1. I thought it was suspected that P≠NP actually? 2. Ah yes, I see your point, a non-deterministic machine would still not be able to find the answer to that problem. So, where is it really, in which class? – Dan Filimon Dec 13 '10 at 17:26
• @Dan: 1. Yes, it is believed that `P != NP`, which is why I said that `P = NP` is believed to be false. However since we don't know that it is false, we also don't know any problems in `NP \ NPC` (though we might suspect that they exist). 2. It's in `EXPTIME`. – sepp2k Dec 13 '10 at 17:36
• Oh, I misunderstood at first - I didn't pay attention to the whole sentence between the brackets. – Dan Filimon Dec 13 '10 at 17:39
• @sepp2k About 1: Usually even if P=NP not all NP problems are considered NP-Complete since you wouldn't really be reducing to them always. Take for example ∅ to which no language with yes-instances can be reduced, but it is in P (algorithm: "return FALSE"). – dtech Apr 15 '12 at 13:13
• @dtech Fair point. I've removed that part from the answer. – sepp2k Apr 15 '12 at 13:31