# finding a/b mod c

I know this may seem like a math question but i just saw this in a contest and I really want to know how to solve it.

We have

a (mod c)

and

b (mod c)

and we're looking for the value of the quotient

(a/b) (mod c)

Any ideas?

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This question might be a better fit for math.stackexchange.com. –  Greg Hewgill Aug 20 '10 at 12:04
And as a hint, `a/b` is the same as `a * (1/b)` where `(1/b)` is the multiplicative inverse of `b` in the group Z (mod c). –  Greg Hewgill Aug 20 '10 at 12:07
This is on-topic, the solution is an algorithm to compute 1/b. –  starblue Aug 20 '10 at 12:21
By the way, in Java, there's `BigInteger.modInverse`. You can also implement extended Euclidian algorithm yourself for instructional purposes. –  polygenelubricants Aug 20 '10 at 12:40

In the ring of integers modulo `C`, these equations are equivalent:

`A / B (mod C)`
`A * (1/B) (mod C)`
`A * B`-1`(mod C)`.

Thus you need to find `B`-1, the multiplicative inverse of `B` modulo `C`. You can find it using e.g. extended Euclidian algorithm.

Note that not every number has a multiplicative inverse for the given modulus.

Specifically, `B`-1 exists if and only if `gcd(B, C) = 1` (i.e. `B` and `C` are coprime).

### Modular multiplicative inverse: Example

Suppose we want to find the multiplicative inverse of 3 modulo 11.

That is, we want to find

`x = 3`-1`(mod 11)`
`x = 1/3 (mod 11)`
`3x = 1 (mod 11)`

Using extended Euclidian algorithm, you will find that:

`x = 4 (mod 11)`

Thus, the modular multiplicative inverse of 3 modulo 11 is 4. In other words:

`A / 3 == A * 4 (mod 11)`

### Naive algorithm: brute force search

One way to solve this:

`3x = 1 (mod 11)`

Is to simply try `x` for all values `0..11`, and see if the equation holds true. For small modulus, this algorithm may be acceptable, but extended Euclidian algorithm is much better asymptotically.

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That's like me saying A-B is A+(-B)...true, but not productive. –  rownage Aug 20 '10 at 12:09
Sorry but i just didn't understand that. can you please explain more? –  AKGMA Aug 20 '10 at 12:10
@rownage It IS productive, because division is not simple in modular arithmetic. The only way to actually perform division is to find the multiplicative inverse. A google search for modular division wouldn't be nearly as helpful as a google search for multiplicative inverse. Just because a property is simple for normal mathematics doesn't mean the property is even true in more elaborate situations such as this. –  Dave McClelland Aug 20 '10 at 12:14
so it isn't (ab^-1)(mod c), but rather ab^-1(mod c)? –  rownage Aug 20 '10 at 12:21
@rownage: `a * b^-1 (mod c)` is mathematical notation. Using C-notation, that would be equivalent to `(a * inverseOfB) % c` –  BlueRaja - Danny Pflughoeft Aug 20 '10 at 15:27

There are potentially many answers. When all you have is k = B mod C, then B could be any k+CN for all integer N.

This means B could potentially be very large. So large, in fact, to make A/B into zero.

However, that's just one way to respond.

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No, B could never be large enough to make A/B into zero. It could be very large and A/B would be extremely small but it would never actually be zero. You can say it tends to zero as B tends to infinity though so your general idea was right. I'm just a mathematician so like to be precise. :) But that observation of taking a fixed A and varying B does admirably demonstrate the fact there are multiple valid answers. Its interesting to wonder if the correct answer is meant to be a function of m,n or if it just a badly specified question... +1 overall anyway. ;-) –  Chris Aug 20 '10 at 12:17
Eh? are you two using real numbers in an equation that specified "mod C"? In princple of course it's possible to specify a number system that works that way, but the normal convention is that you're working with integers modulo some integer, so no matter how large B is, it is also some value 0 <= n < C (the numbers represent infinite sets of integers), and while A/B will always have an integer result. Division is always defined as the inverse of multiplication, so where multiplication behaves differently (e.g. by giving a modulo C result), division behaves differently to match. –  Steve314 Aug 20 '10 at 12:28
Specific example: Mod-6 arithmetic. 3/2 is undefined. Why? Nothing you can multiply by two will yield an odd number, given the even modulus. Is that what you mean? Us computer guys are used to dealing with mod-2^32 arithmetic, except that division is defined as an approximation so that |b*(a/b)| <= |a|. Oh, and one other thing: He didn't say he was working in modular arithmetic; he said he had some numbers modulo another number. This is maybe splitting hairs, but should the presence of a modulus operation be enough to conclude that the entire problem is about modular arithmetic? –  Ian Aug 20 '10 at 14:01

I think it can be written as(But not sure)

(a/b)%c= ----------->((a)%(b*c))/b

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I don't think that's correct. Regardless, `/` changes its definition when `mod` is involved. –  Teepeemm Oct 1 '14 at 19:04