# How to calculate “modular multiplicative inverse” when the denominator is not co-prime with m?

I need to calculate `(a/b) mod m` where `a` and `b` are very large numbers.

What I am trying to do is to calculate `(a mod m) * (x mod m)`, where `x` is the modular inverse of `b`.

I tried using Extended Euclidean algorithm, but what to do when b and m are not co-prime? It is specifically mentioned that b and m need to be co-prime.

I tried using the code here, and realized that for example: `3 * x mod 12` is not at all possible for any value of `x`, it does not exist!

What should I do? Can the algorithm be modified somehow?

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## 3 Answers

Yep, you are in trouble. x has no solution in `b*x = 1 mod m` if b and m have a common divisor. Similarly, in your original problem `a/b = y mod m`, you are looking for y such that `a=by mod m`. If a is divisible by `gcd(b,m)`, then you can divide out by that factor and solve for y. If not, then there is no y that can solve the equation (i.e. `a/b mod m` is not defined).

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@Keith Randall so, what can be done to solve this? – Lazer Oct 5 '09 at 20:26
I'm not sure what you mean. If a is divisible by gcd(b,m), then you can solve it. Otherwise, the divide operation isn't even defined. You'd need to figure out another way to achieve your ultimate objective without modular division. – Keith Randall Oct 5 '09 at 20:29
I mean, what can be the other ways to "achieve my ultimate objective without modular division"? – Lazer Oct 5 '09 at 22:53
Why are you doing modular division in the first place? I presume there is some task (a.k.a. ultimate objective) you're trying to perform using modular division as a subroutine. What is that task? Methinks that whatever it is, modular division probably isn't the answer. – Keith Randall Oct 6 '09 at 3:23
@Keith Randall yep, you are right. what I am trying to do is to caculate the mod of a series of the form 1+x+x^2+x^3+...+x^n % m. I mentioned a/b form because I tried to use the geometric sum formula. iterating the entire series id not an option as n is very very large (~10^17) – Lazer Oct 6 '09 at 11:07

The reason that b and m have to be coprime is because of the Chinese Remainder Theorem. Basically the problem:

`3 * x mod 12`

Can be thought of as a compound problem involving

`3*x mod 3` and `3*x mod 4 = 2^2`

Now if b is not coprime to 12, this is like trying to divide by zero. Thus the answer doesn't exist!

This is due to field theory in abstract algebra. A field is basically a set which has addition, subtraction, multiplication, and division well-defined. A finite field is always of the form GF(p^n), where p is prime and n is a positive integer, and the operations are addition and multiplication modulo p^n. Now, 12 is not a prime power, so your ring is not a field. Thus this problem can't be solved for any b which is not coprime to m.

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Check this: http://www.math.harvard.edu/~sarah/magic/topics/division It might help. It explains methods of modular division.

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@aakash I got it just now – avd Oct 5 '09 at 18:59