What is NP?
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NP is the set of all decision problems (question with yes-or-no answer) for which the 'yes'-answers can be **verified** in polynomial time (O(n^k) where n is the problem size, and k is a constant) by a [deterministic Turing machine](http://en.wikipedia.org/wiki/Deterministic_Turing_machine). Polynomial time is sometimes used as the definition of *fast* or *quickly*. 

What is P?
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P is the set of all decision problems which can be **solved** in polynomial time by a deterministic Turing machine. Since it can solve in polynomial time, it can also be verified in polynomial time. Therefore P is a subset of NP.

What is NP-Complete?
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A problem x that is in NP is also in NP-Complete if and only if every other problem in NP can be quickly (ie. in polynomial time) transformed into x. In other words:

 1. x is in NP, and
 2. Every problem in NP is reducible to x

So what makes NP-Complete so interesting is that if any one of the NP-Complete problems was to be solved quickly then all NP problems can be solved quickly. Also see [What’s “P=NP?”, and why is it such a famous question?](http://stackoverflow.com/questions/111307/whats-pnp-and-why-is-it-such-a-famous-question)

What is NP-Hard?
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NP-Hard are problems that are at least as hard as the hardest problems in NP. Note that NP-Complete problems are also NP-hard. However not all NP-hard problems are NP (or even a decision problem), despite having 'NP' as a prefix. That is the NP in NP-hard does not mean non-polynomial. Yes this is confusing but its usage is entrenched and unlikely to change.