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.