# Modular arithmetic

I'm new to cryptography and modular arithmetic. So, I'm sure it's a silly question, but I can't help it.

How do I calculate a from
pow(a,q) = 1 (mod p),
where p and q are known? I don't get the "1 (mod p)" part, it equals to 1, doesn't it? If so, than what is "mod p" about?
Is this the same as
pow(a,-q) (mod p) = 1?

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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.]

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Woah! I am glad that you are here to answer these sort of questions! – Tom Leys Nov 11 '08 at 3:09

Not silly at all, as this is the basis for public-key encryption. You can find an excellent discussion on this at http://home.scarlet.be/~ping1339/congr.htm#The-equation-a%3Csup%3Ex.

PKI works by choosing `p` and `q` that are large and relatively prime. One (say `p`) becomes your private key and the other (`q`) is your public key. The encryption is "broken" if an attacker guesses `p`, given `a``q` (the encrypted message) and `q` (your public key).

`a``q` = 1 mod `p`

This means `a``q` is a number that leaves a remainder of 1 when divided by `p`. We don't care about the integer portion of the quotient, so we can write:

`a``q` / `p` = `n` + 1/`p`

for any integer value of `n`. If we multiply both sides of the equation by `p`, we have:

`a``q` = `np` + 1

Solving for `a` we have:

`a` = (`np`+1)1/`q`

The final step is to find a value of `n` that generates the original value of `a`. I don't know of any way to do this other than trial and error -- which equates to a "brute force" attempt to break the encryption.

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