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In the computational complexity theory, we say that an algorithm have complexity O(f(n)) if the number of computations that solve a problem with input size n is bounded by cf(n), for all integer n, where c is a positive constant non-depending on n, and f(n) is an increasing function that goes to infinity as n does.

The 3-SAT problem is stated as: given a CNF expression, whose clauses has exactly 3 literals, is there some assignment of TRUE and FALSE values to the variables that will make the entire expression true?

A CNF expression consists of, say, k clauses involving m variables x1, ..., xm.
In order to decide if 3-SAT has polynomial complexity P(n), or not, I need to understand something so simple as "what is n" in the problem.

My question is:

Which is considered, in this particular 3-SAT problem, the input size n?

Is it the number k of clauses? Or is it the number m of variables?
Or n is some function of k and m? ( n=f(k,m) ).

I am in trouble with this simple issue.

According to the answer of Timmie Smith, we can consider the estimate:

k <= constant * f(m)

where m is a polynomial function of m.
More precisely, the function P(m) it could be considered of exponent 3 (that is, cubic).

Thus, if we consider the complexity f(k) of 3-SAT, we would have:

f(k, m)=f(P(m),m), (with P(m) = m^3).

So, if the function f is polyonomial in k and m, then actually results polynomial in m. Thus, by considering m as the input size, it would be to estimate if a given algorithm is, or not, polynomial in m, in order to know if 3-SAT is in P or not.

If you agree, I can accept the answer of Timmie as the good one.


I did the same question here:

The accepted answer was helpful to me.

share|improve this question
Unless I'm misreading your description of the input, it's size is n = (k*m). – RBarryYoung Aug 25 '13 at 23:56
That seems right. However take in account what Timmie Smith says: it is possible to estimate the number k as a (polynomical) function of m. Perhaps I wasn't clear enough with my question. – pablo1977 Aug 26 '13 at 0:51
up vote 2 down vote accepted

The input is the number m of variables. This is because the number of possible clauses that can be formed given m variables is a polynomial function of the number of variables.

share|improve this answer
Thanks Timmie. However, are you saying that k <= constant * m? I can see the estimate k <= constant * m * (m - 1) * (m - 2), because the combinatory number mC3 (for 3-SAT). – pablo1977 Aug 25 '13 at 23:43
I think your estimate is a better one. I didn't consider the growth in the possible number of clauses as the number of variables grows. Still, the number of possible clauses is a function of the number of variables. – Timmie Smith Aug 25 '13 at 23:55
Ok, but what is important now, is that the "function of the number of variables" is polynomial in m, which doesn't change the status of 3-SAT as a P or an NP problem. – pablo1977 Aug 26 '13 at 0:18
Yes, you need the phrase "polynomial function", not "constant factor", to make this answer correct. – Nemo Aug 27 '13 at 14:56

I've seen in some papers of Carnegie Mellon University the following definition of "size of input" for this kind of problems:

number of bits it takes to write the input down

Considering that the input can be compressed, this definition makes sense to me, because it is a good measure of input entropy.

My 2 cents! Cheers!!

share|improve this answer
+1 since the encoding of the input is a part of the formulation of the problem. Could you elaborate on the encoding of the input for 3-SAT? – Dmitri Chubarov Aug 26 '13 at 0:39
Ok, but I need a more specific answer. How much it dependes n of k and m? Can we write n=P(m) for a polynomial P()? – pablo1977 Aug 26 '13 at 0:42
You could use n = (ceiling(log2(m)) + 1) * 3 * k where ceiling(log2(m)) is the number of bits necessary to represent a variable, plus 1 to represent its value, and all this multiplied by 3 literals and k clauses. – marcelrf Aug 27 '13 at 1:24

The input size is the number of variables m.

The reason for this is that the size of the search space that needs to be traversed for solving the problems is determined entirely by the number of variables: Each variable has two possible states (1 or 0), the search space consists of all possible assignments. A brute-force algorithm would just test all possible assignments (2^m) to traverse the search space. Although most 3-SAT algorithms will be impacted significantly by the number of clauses, that does not influence the underlying problem's complexity.

Therefore the input size is also the number of variables for plain-old SAT, where the search space looks the same, although resolving clauses in a non-brute-force way works quite differently.

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