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What are the differences between NP, NP-Complete and NP-Hard?

I am aware of many resources all over the web. I'd like to read your explanations, and the reason is they might be different then what's out there, or it's out there and I'm not aware.

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In your comments, you post that you have CLRS right in front of you. Either there is something you don't understand, or there isn't. If you would like further explanation on something, you need to ask specifically what that something is. You can't just walk on to SO and say: "talk about this proof for me." –  San Jacinto Dec 7 '09 at 1:38
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What s wrong with talking about a proof? May be there is a better approach to the proof. Example : video.google.com/videoplay?docid=-8534835263228710390# This guy in the this video explains better than Sipser in my opinion of course. so please dont judge me like that. –  DarthVader Dec 7 '09 at 1:42
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I dont understand all this reactions. If i cant ask such a question... One can google anything and will definetely find an answer, almost. Why do SO exist then, why do people asks questions here? –  DarthVader Dec 7 '09 at 1:44
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There's nothing wrong with talking about a proof. There's everything wrong with wanting people to read your mind. Ask a question about the proof, explain what you don't like about the proof you've seen, or why you don't like the approach that CLRS takes in talking about reducing problems to prove they are part of the class, or offer a new proof... otherwise, people just post WISHING what they type is what you want to see. I'm not sure how explaining your fault is "judging" you. –  San Jacinto Dec 7 '09 at 1:47
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I know an NP-Complete joke, but once you've heard one you've heard them all. –  jason Jul 10 '13 at 13:55

11 Answers 11

up vote 547 down vote accepted

I assume that you are looking for intuitive definitions, since the technical definitions require quite some time to understand. First of all, let's remember a preliminary needed concept to understand those definitions.

  • Decision problem: A problem with a yes or no answer.

Now, let us define those complexity classes.

P

P is a complexity class that represents the set of all decision problems that can be solved in polynomial time. That is, given an instance of the problem, the answer yes or no can be decided in polynomial time.

Example

Given a graph connected G, can its vertices be coloured using two colours so that no edge is monochromatic?

Algorithm: start with an arbitrary vertex, color it red and all of its neighbours blue and continue. Stop when you run out of vertices or you are forced to make an edge have both of its endpoints be the same color.


NP

NP is a complexity class that represents the set of all decision problems for which the answer is yes have proofs that can be verified in polynomial time.

This means that if someone gives us an instance of the problem and a certificate (sometimes called a witness) to the answer being yes, we can check that it is correct in polynomial time.

Example

Integer factorisation is in NP. This is the problem that given integers n and m, is there an integer f with 1 < f < m, such that f divides n (f is a small factor of n)?

This is a decision problem because the answers are yes or no. If someone hands us an instance of the problem (so they hand us integers n and m) and an integer f with 1 < f < m, and claim that f is a factor of n (the certificate), we can check the answer in polynomial time by performing the division n / f.


NP-Complete

NP is a complexity class which represents the set of all problems X for which it is possible to reduce any other NP problem Y to X in polynomial time.

Intuitively this means that we can solve Y quickly if we know how to solve X quickly. Precisely, Y is reducible to X, if there is a polynomial time algorithm f to transform instances y of Y to instances x = f(y) of X in polynomial time, with the property that the answer to y is yes, if and only if the answer to f(y) is yes.

Example

3-SAT. This is the problem wherein we are given a conjunction (ANDs) of 3-clause disjunctions (ORs), statements of the form

(x_v11 OR x_v21 OR x_v31) AND 
(x_v12 OR x_v22 OR x_v32) AND 
...                       AND 
(x_v1n OR x_v2n OR x_v3n)

where each x_vij is a boolean variable or the negation of a variable from a finite predefined list (x_1, x_2, ... x_n).

It can be shown that every NP problem can be reduced to 3-SAT. The proof of this is technical and requires use of the technical definition of NP (based on non-deterministic Turing machines). This is known as Cook's theorem.

What makes NP-complete problems important is that if a deterministic polynomial time algorithm can be found to solve one of them, every NP problem is solvable in polynomial time (one problem to rule them all).


NP-hard

Intuitively, these are the problems that are even harder than the NP-complete problems. Note that NP-hard problems do not have to be in NP, and they do not have to be decision problems.

The precise definition here is that a problem X is NP-hard, if there is an NP-complete problem Y, such that Y is reducible to X in polynomial time.

But since any NP-complete problem can be reduced to any other NP-complete problem in polynomial time, all NP-complete problems can be reduced to any NP-hard problem in polynomial time. Then, if there is a solution to one NP-hard problem in polynomial time, there is a solution to all NP problems in polynomial time.

Example

The halting problem is the classic NP-hard problem. This is the problem that given a program P and input I, will it halt? This is a decision problem but it is not in NP. It is clear that any NP-complete problem can be reduced to this one.

My favorite NP-complete problem is the Minesweeper problem.


P = NP

This one of most famous problem in computer science, and one of the most important outstanding questions in the mathematical sciences. In fact, the Clay Institute is offering one million dollars for a solution to the problem (Stephen Cook's writeup on the Clay website is quite good).

It's clear that P is a subset of NP. The open question is whether or not NP problems have deterministic polynomial time solutions. It is largely believed that they do not. Here is an outstanding recent article on the latest (and the importance) of the P = NP problem: The Status of the P versus NP problem.

The best book on the subject is Computers and Intractability by Garey and Johnson.

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@unknown (google): The explanations involving non-deterministic Turing machines are the technically correct explanations. Turing machines are how we formalize the notions of computers, algorithms, problems etc. –  jason Dec 7 '09 at 2:10
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@Paul Fisher: I'll show that SAT is reducible to the halting problem in polynomial time. Consider the following algorithm: given as input a proposition I over n variables, try all 2^n possible assignments to the variables and halt if one satisfies the proposition and otherwise enter an infinite loop. We see that this algorithm halts if and only if I is satisfiable. Thus, if we had a polynomial time algorithm for solving the halting problem then we could solve SAT in polynomial time. Therefore, the halting problem is NP-hard. –  jason Dec 7 '09 at 3:52
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@Jason - You can't reduce a decidable problem to an undecidable problem in that manner. Decidable problems have to result in a definitive yes or no answer in order to be considered to be decidable. The Halting Problem does not have a definitive yes or now answer since an arbitrary answer might throw any solution into a loop. –  rjzii Dec 13 '09 at 2:48
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@Rob: Yes, I can. The definition of reducible does not require that the problem being reduced to be solvable. This is true for either many-one reductions or Turing reductions. –  jason Dec 13 '09 at 13:12
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Using Halting problem as a "classic example" of NP-hard problem is incorrect. This is like saying: "Pacific Ocean is a classic example of a salt water aquarium." –  Michael Mar 11 '14 at 21:18

I've been looking around and seeing many long explanations. Here is a small chart that may be useful to summarise:

Notice how difficulty increases top to bottom: any NP can be reduced to NP-Complete, and any NP-Complete can be reduced to NP-Hard, all in P (polynomial) time.

If you can solve a more difficult class of problem in P time, that will mean you found how to solve all easier problems in P time (for example, proving P = NP, if you figure out how to solve any NP-Complete problem in P time).

____________________________________________________________
| Problem Type | Verifiable in P time | Solvable in P time | Increasing Difficulty
___________________________________________________________|           |
| P            |        Yes           |        Yes         |           |
| NP           |        Yes           |     Yes or No *    |           |
| NP-Complete  |        Yes           |      Unknown       |           |
| NP-Hard      |     Yes or No **     |      Unknown ***   |           |
____________________________________________________________           V

Notes on Yes or No entries:

  • * An NP problem that is also P is solvable in P time.
  • ** An NP-Hard problem that is also NP-Complete is verifiable in P time.
  • *** NP-Complete problems (all of which form a subset of NP-hard) might be. The rest of NP hard is not.

I also found this diagram quite useful in seeing how all these types correspond to each other (pay more attention to the left half of the diagram).

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I've a doubt related to your answer. I asked it in a separate question, but I was asked to post it here. Can you please help me here? stackoverflow.com/questions/21005651/… –  Srikanth Jan 8 '14 at 21:09
    
It is unknown whether NP-complete problems are solvable in polynomial time. Also, NP-complete problems are NP-hard, so some NP-hard problems are verifiable in polynomial time, and possible some also polynomial-time solvable. –  Falk Hüffner Jan 9 '14 at 16:50
    
This table is incorrect and self-contradictory. Even if you assume that NP!=P, which has not been proved yet, it would still be incorrect. For example, NP-Hard class includes NP-Complete problems; therefore your table claims that NP-Complete problems are simultaneously verifiable in polynomial time and not verifiable in polynomial time. –  Michael Feb 21 '14 at 18:11
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@FalkHüffner Thanks, table is updated (was an error in translating from the Venn diagram). –  Johnson Wong Feb 26 '14 at 7:16
    
I'm confused about your second comment. How can a problem be both NP-Hard as NP-Complete? Could you give me an example? –  Peter Raeves May 8 at 10:37

This is a very informal answer to the question asked.

Can 3233 be written as the product of two other numbers bigger than 1? Is there any way to walk a path around all of the Seven Bridges of Königsberg without taking any bridge twice? These are examples of questions that share a common trait. It may not be obvious how to efficiently determine the answer, but if the answer is 'yes', then there's a short and quick to check proof. In the first case a non-trivial factorization of 51; in the second, a route for walking the bridges (fitting the constraints).

A decision problem is a collection of questions with yes or no answers that vary only in one parameter. Say the problem COMPOSITE={"Is n composite": n is an integer} or EULERPATH={"Does the graph G have an Euler path?": G is a finite graph}.

Now, some decision problems lend themselves to efficient, if not obvious algorithms. Euler discovered an efficient algorithm for problems like the "Seven Bridges of Königsberg" over 250 years ago.

On the other hand, for many decision problems, it's not obvious how to get the answer -- but if you know some additional piece of information, it's obvious how to go about proving you've got the answer right. COMPOSITE is like this: Trial division is the obvious algorithm, and it's slow: to factor a 10 digit number, you have to try something like 100,000 possible divisors. But if, for example, somebody told you that 61 is a divisor of 3233, simple long division is a efficient way to see that they're correct.

The complexity class NP is the class of decision problems where the 'yes' answers have short to state, quick to check proofs. Like COMPOSITE. One important point is that this definition doesn't say anything about how hard the problem is. If you have a correct, efficient way to solve a decision problem, just writing down the steps in the solution is proof enough.

Algorithms research continues, and new clever algorithms are created all the time. A problem you might not know how to solve efficiently today may turn out to have an efficient (if not obvious) solution tomorrow. In fact, it took researchers until 2002 to find an efficient solution to COMPOSITE! With all these advances, one really has to wonder: Is this bit about having short proofs just an illusion? Maybe every decision problem that lends itself to efficient proofs has an efficient solution? Nobody knows.

Perhaps the biggest contribution to this field came with the discovery a peculiar class of NP problems. By playing around with circuit models for computation, Stephen Cook found a decision problem of the NP variety that was provably as hard or harder than every other NP problem. An efficient solution for the boolean satisfiability problem could be used to create an efficient solution to any other problem in NP. Soon after, Richard Karp showed that a number of other decision problems could serve the same purpose. These problems, in a sense the "hardest" problems in NP, became known as NP-complete problems.

Of course, NP is only a class of decision problems. Many problems aren't naturally stated in this manner: "find the factors of N", "find the shortest path in the graph G that visits every vertex", "give a set of variable assignments that makes the following boolean expression true". Though one may informally talk about some such problems being "in NP", technically that doesn't make much sense -- they're not decision problems. Some of these problems might even have the same sort of power as an NP-complete problem: an efficient solution to these (non-decision) problems would lead directly to an efficient solution to any NP problem. A problem like this is called NP-hard.

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Thank you. I've read about 10 explanations on this subject, watched 3 videos, and you're the only one who could resist the temptation to go into technical details. –  Adam Hughes Feb 4 at 7:43

The easiest way to explain P v. NP and such without getting into technicalities is to compare "word problems" with "multiple choice problems".

When you are trying to solve a "word problem" you have to find the solution from scratch. When you are trying to solve a "multiple choice problems" you have a choice: either solve it as you would a "word problem", or try to plug in each of the answers given to you, and pick the candidate answer that fits.

It often happens that a "multiple choice problem" is much easier than the corresponding "word problem": substituting the candidate answers and checking whether they fit may require significantly less effort than finding the right answer from scratch.

Now, if we would agree the effort that takes polynomial time "easy" then the class P would consist of "easy word problems", and the class NP would consist of "easy multiple choice problems".

The essence of P v. NP is the question: "Are there any easy multiple choice problems that are not easy as word problems"? That is, are there problems for which it's easy to verify the validity of a given answer but finding that answer from scratch is difficult?

Now that we understand intuitively what NP is, we have to challenge our intuition. It turns out that there are "multiple choice problems" that, in some sense, are hardest of them all: if one would find a solution to one of those "hardest of them all" problems one would be able to find a solution to ALL NP problems! When Cook discovered this 40 years ago it came as a complete surprise. These "hardest of them all" problems are known as NP-hard. If you find a "word problem solution" to one of them you would automatically find a "word problem solution" to each and every "easy multiple choice problem"!

Finally, NP-complete problems are those that are simultaneously NP and NP-hard. Following our analogy, they are simultaneously "easy as multiple choice problems" and "the hardest of them all as word problems".

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I think we can answer it much more succinctly. I answered a related question, and copying my answer from there

But first, an NP-hard problem is a problem for which we cannot prove that a polynomial time solution exists. NP-hardness of some "problem-P" is usually proven by converting an already proven NP-hard problem to the "problem-P" in polynomial time.

To answer the rest of question, you first need to understand which NP-hard problems are also NP-complete. If an NP-hard problem belongs to set NP, then it is NP-complete. To belong to set NP, a problem needs to be

(i) a decision problem,
(ii) the number of solutions to the problem should be finite and each solution should be of polynomial length, and
(iii) given a polynomial length solution, we should be able to say whether the answer to the problem is yes/no

Now, it is easy to see that there could be many NP-hard problems that do not belong to set NP and are harder to solve. As an intuitive example, the optimization-version of traveling salesman where we need to find an actual schedule is harder than the decision-version of traveling salesman where we just need to determine whether a schedule with length <= k exists or not.

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P (Polynomial Time) : As name itself suggests, these are the problems which can be solved in polynomial time.

NP (Non-deterministic-polynomial Time) : These are the decision problems which can be verified in polynomial time. That means, if I claim that there is a polynomial time solution for a particular problem, you ask me to prove it. Then, I will give you a proof which you can easily verify in polynomial time. These kind of problems are called NP problems. Note that, here we are not talking about whether there is a polynomial time solution for this problem or not. But we are talking about verifying the solution to a given problem in polynomial time.

NP-Hard : These are at least as hard as the hardest problems in NP. If we can solve these problems in polynomial time, we can solve any NP problem that can possibly exist. Note that these problems are not necessarily NP problems. That means, we may/may-not verify the solution to these problems in polynomial time.

NP-Complete : These are the problems which are both NP and NP-Hard. That means, if we can solve these problems, we can solve any other NP problem and the solutions to these problems can be verified in polynomial time.

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In addition to the other great answers, here is the typical schema people use to show the difference between NP, NP-Complete, and NP-Hard:

enter image description here

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Is it proven that there exist a problem in NP-Hard that is not in NP-Complete? Because this image suggests it. Thank you. –  Vitor Lima Dec 4 '14 at 21:23
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@VitorLima yes e.g. EXPSPACE-complete problems are NP-hard but proven not to be NP-complete. –  Franck Dernoncourt Dec 4 '14 at 21:43
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Ok, thank you. I found some references talking about it. For example, this one: princeton.edu/~achaney/tmve/wiki100k/docs/NP-hard.html –  Vitor Lima Dec 4 '14 at 23:28

NP-complete problems are those problems that are both NP-Hard and in the complexity class NP. Therefore, to show that any given problem is NP-complete, you need to show that the problem is both in NP and that it is NP-hard.

Problems that are in the NP complexity class can be solved non-deterministically in polynomial time and a possible solution (i.e., a certificate) for a problem in NP can be verified for correctness in polynomial time.

An example of a non-deterministic solution to the k-clique problem would be something like:

1) randomly select k nodes from a graph

2) verify that these k nodes form a clique.

The above strategy is polynomial in the size of the input graph and therefore the k-clique problem is in NP.

Note that all problems deterministically solvable in polynomial time are also in NP.

Showing that a problem is NP-hard typically involves a reduction from some other NP-hard problem to your problem using a polynomial time mapping: http://en.wikipedia.org/wiki/Reduction%5F%28complexity)

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Not that I see anything in this answer that is incorrect, but I don't know why it was accepted. It doesn't really offer much to what the OP was asking. It's not really even different than the standard explanations of these problems, and there aren't any clear explanations as to what makes these problems in these classes. Not worth a downvote, but certainly not worth answer acceptance. –  San Jacinto Dec 7 '09 at 1:50
    
@San, i asked the question. not you. you can ask it again on your own. I prefer this answer better than wiki links. –  DarthVader Dec 7 '09 at 1:52
    
@unknown okay, glad it helped you nonetheless :) –  San Jacinto Dec 7 '09 at 1:58

There are really nice answers for this particular question, so there is no point to write my own explanation. So I will try to contribute with an excellent resource about different classes of computational complexity.

For someone who thinks that computational complexity is only about P and NP, here is the most exhaustive resource about different computational complexity problems. Apart from problems asked by OP, it listed approximately 500 different classes of computational problems with nice descriptions and also the list of fundamental research papers which describe the class.

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As I understand it, an np-hard problem is not "harder" than an np-complete problem. In fact, by definition, every np-complete problem is:

  1. in NP
  2. np-hard

enter image description here

-- Intro. to Algorithms (3ed) by Cormen, Leiserson, Rivest, and Stein, pg 1069

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Your understanding is incorrect. Your definition of NP-complete is correct but has no bearing on your first statement. All problems in NP-hard are at least as hard as those in NP-complete; some (e.g. the Halting Problem, which is infinitely hard, and en.wikipedia.org/wiki/EXPSPACE) are provably harder. –  Jim Balter Jun 13 at 9:30

These refer to how long it takes a program to run. Problems in class P can be solved with algorithms that run in polynomial time.

Say you have an algorithm that finds the smallest integer in an array. One way to do this is by iterating over all the integers of the array and keeping track of the smallest number you've seen up to that point. Every time you look at an element, you compare it to the current minimum, and if it's smaller, you update the minimum.

How long does this take? Let's say there are n elements in the array. For every element the algorithm has to perform a constant number of operations. Therefore we can say that the algorithm runs in O(n) time, or that the runtime is a linear function of how many elements are in the array.* So this algorithm runs in linear time.

You can also have algorithms that run in quadratic time (O(n^2)), exponential time (O(2^n)), or even logarithmic time (O(log n)). Binary search (on a balanced tree) runs in logarithmic time because the height of the binary search tree is a logarithmic function of the number of elements in the tree.

If the running time is some polynomial function of the size of the input**, for instance if the algorithm runs in linear time or quadratic time or cubic time, then we say the algorithm runs in polynomial time and the problem it solves is in class P.

NP

Now there are a lot of programs that don't (necessarily) run in polynomial time on a regular computer, but do run in polynomial time on a nondeterministic Turing machine. These programs solve problems in NP, which stands for nondeterministic polynomial time. A nondeterministic Turing machine can do everything a regular computer can and more.*** This means all problems in P are also in NP.

An equivalent way to define NP is by pointing to the problems that can be verified in polynomial time. This means there is not necessarily a polynomial-time way to find a solution, but once you have a solution it only takes polynomial time to verify that it is correct.

Some people think P = NP, which means any problem that can be verified in polynomial time can also be solved in polynomial time and vice versa. If they could prove this, it would revolutionize computer science because people would be able to construct faster algorithms for a lot of important problems.

NP-hard

What does NP-hard mean? A lot of times you can solve a problem by reducing it to a different problem. I can reduce Problem B to Problem A if, given a solution to Problem A, I can easily construct a solution to Problem B. (In this case, "easily" means "in polynomial time.")

If a problem is NP-hard, this means I can reduce any problem in NP to that problem. This means if I can solve that problem, I can easily solve any problem in NP. If we could solve an NP-hard problem in polynomial time, this would prove P = NP.

NP-complete

A problem is NP-complete if the problem is both NP-hard, and in NP.

  • A technical point: O(n) actually means the algorithm runs in asymptotically linear time, which means the time complexity approaches a line as n gets very large. Also, O(n) is technically an upper bound, so if the algorithm ran in sublinear time you could still say it's O(n), even if that's not the best description of it.

** Note that if the input has many different parameters, like n and k, it might be polynomial in n and exponential in k

*** Per Xuan Luo's comment, deterministic and nondeterministic Turing machines can compute exactly the same things, since every nondeterministic Turing machine can be simulated by a deterministic Turing machine (a "regular computer"). However, they may compute things in different amounts of time.

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protected by Srikar Appal Feb 12 '14 at 4:06

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