The (mod p) part refers not to the right hand side, but to the equality sign: it says that *modulo p, pow(a,q) and 1 are equal*. For instance, "modulo 10, 246126 and 7868726 are equal" (and they are also both equal to 6 modulo 10): **two numbers x and y are equal modulo p if they have the same remainder on dividing by p, or equivalently, if p divides x-y.**

Since you seem to be coming from a programming perspective, another way of saying it is that pow(a,q)%p=1, where "%" is the "remainder" operator as implemented in several languages (assuming that p>1).

You should read the Wikipedia article on Modular arithmetic, or any elementary number theory book (or even a cryptography book, since it is likely to introduce modular arithmetic).

To answer your other question: there is no general formula for finding such an *a* (to the best of my knowledge) in general. Assuming that p is prime, and using Fermat's little theorem to reduce q modulo p-1, and assuming that q divides p-1 (or else no such *a* exists), you can produce such an *a* by taking a primitive root of p and raising it to the power (p-1)/q. [And more generally, when p is not prime, you can reduce q modulo φ(p), then assuming it divides φ(p) and you know a primitive root (say r) mod p, you can take r to the power of φ(p)/q, where φ is the totient function -- this comes from Euler's theorem.]