# Why does the formal procedure prove NP-Completeness? [closed]

I know how to show that a problem X is NP-Complete.

1. Show that X ∈ NP.
2. Show Y ≤p X: show a problem Y known to be NP-Complete can be reduced to X in polynomial time.

However, I'm stuck on why this procedure proves that X is NP-Complete. Could someone explain this in a relatively simple way?

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## closed as off-topic by Dukeling, hypercrypt, bmargulies, Alex Thornton, Christopher CreutzigApr 6 '14 at 19:30

• This question does not appear to be about programming within the scope defined in the help center.
If this question can be reworded to fit the rules in the help center, please edit the question.

Computer Science would be a better fit for this question. –  500 - Internal Server Error Apr 5 '14 at 19:47
You're probably right; sorry about that. Should I delete the question and re-ask there? –  CocoaDog Apr 5 '14 at 19:49
For a given NP-complete problem Y, we already know that any other problem in NP can be reduced to it in polynomial time. If you now who that Y <=p X (which is the direction you need), then you know by transitivity of polynomial reductions (polynomial times polynomial = polynomial) that any problem in NP can now be reduced to X. –  G. Bach Apr 5 '14 at 19:52
That's just 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
@G.Bach you're right. I updated the question accordingly. Thanks –  CocoaDog Apr 5 '14 at 21:17

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:

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

You can show (2) by 2 ways:

1. Prove directly that there is a reduction from every problem in NP to it (hard to do)
2. 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.

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2 is in the wrong direction. You want to reduce an NP-hard problem to your problem, not the other way around. Also, reductions are not transitive in general; polynomial reductions are, however. –  G. Bach Apr 5 '14 at 19:53
@G.Bach thanks, note that the explanation however follows the "correct" direction. –  amit Apr 5 '14 at 19:55
@amit Could you take a look at my question? stackoverflow.com/questions/29706726/reduction-to-clique-prob –  evinda Apr 18 at 16:53