Any nonconstructive proof that P=NP really is not. It would imply that the following explicit 3-SAT algorithm runs in polynomial time:

Enumerate all programs. On round **i**, run all programs numbered
less than **i** for one step. If
a program terminates with a
*satisfying input to the formula*, return **true**. If a program
terminates with a *formal proof that
no such input exists*, return
**false**.

If P=NP, then there exists a program which runs in O(poly(N)) and outputs a satisfying input to the formula, if such a formula exists.

If P=coNP, there exists a program which runs in O(poly(N)) and outputs a formal proof that no formula exists, if no formula exists.

If P=NP, then since P is closed under complement NP=coNP. So, there exists a program which runs in O(poly(N)) and does both. That program is the **k**'th program in the enumeration. **k is O(1)**! Since it runs in O(poly(N)) our brute force simulation only requires

k*O(poly(N))+O(poly(N))^2

rounds once it reaches the program in question. As such, the brute force simulation runs in polynomial time!

(Note that k is exponential in the size of the program; this approach is not really feasible, but it suggests that it would be hard to do a nonconstructive proof that P=NP, even if it were the case.)

disproofof the theory, nowadays. – Noldorin May 22 '09 at 22:40