NP Complete problem is defined to be a problem that is both NP-Hard and in NP (definition), so you basically need to show 2 things:

- The problem is in NP (same as your 1)
- The problem is NP-Hard

You can show (2) by 2 ways:

- Prove directly that there is a reduction from every problem in NP to it (hard to do)
- Show a reduction from any known NP-Hard problem to your problem.

The thing is, reduction is transitive, so if you prove there is a reduction from some NP-Hard problem (let it be `L1`

) to your problem (Let it be `L2`

), you basically showed that there is a reduction from EVERY `L`

in NP to `L1`

(definition of NP-Hard), and from `L1`

to `L2`

(your reduction), thus the chain of these reductions (which is itself polynomial, neat things about polynoms), is a reduction by itself from every `L`

in NP to `L2`

(your problem).

In other words, since `L <=p L1 <=p L2`

for every `L`

, it follows that `L <=p L2`

for every `L`

as well, and this is the exact definition of NP-Hardness.

This way, you showed there is a reduction from every problem in NP to your problem, and this is the definition of NP-Hardness.

Since showing directly that there is a reduction from EVERY `L`

in NP to a language, it was done once on SAT (Cook-Levin theorem) [twice actually...], and now you can use reductions to increase the number of known NP-Hard Problems.

how it's defined. At the end of the day, it's just a man-made category. – j_random_hacker Apr 5 '14 at 20:05