# Properties of the modulo operation

I have the compute the sum S = (a*x + b*y + c) % N. Yes it looks like a quadratic equation but it is not because the x and y have some properties and have to be calculated using some recurrence relations. Because the sum exceeds even the limits of unsigned long long I want to know how could I compute that sum using the properties of the modulo operation, properties that allow the writing of the sum something like that(I say something because I do not remember exactly how are those properties): (a*x)%N + (b*y)%N + c%N, thus avoiding exceeding the limits of unsigned long long.

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not completely off topic, since the problem is constrained by the word size limits of common languages –  Alnitak Apr 8 '11 at 13:15
Have you just tried breaking it up into that form with a test set of data to see if it even works (without delving into determining whether it can be done that way), sometimes the easiest thing is to just try it, you learn a lot that way –  onaclov2000 Apr 8 '11 at 13:16
Have you considered "S = (a*x % N) + (b*y % N) + (c % N)"? More specifically, are any of these negative? –  Brendan Apr 8 '11 at 13:16
@Alnitak: I agree. But sorry, can't cancel close vote... –  tibur Apr 8 '11 at 13:17
Hmm, if the sum would exceed the bounds it is very likely that just one term would exceed the bounds. The sum at most needs only 2 bits more space than each term. –  edA-qa mort-ora-y Apr 8 '11 at 13:23
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`a % N = x` means that for some integers `0 <= x < N` and `m`: `m * N + x = a`.

You can simply deduce then that if `a % N = x` and `b % N = y` then

``````(a + b) % N =
= (m * N + x + l * N + y) % N =
= ((m + l) * N + x + y) % N =
= (x + y) % N =
= (a % N + b % N) % N.
``````

We know that `0 < x + y < 2N`, that is why you need to keep remainder calculation. This shows that it is okay to split the summation and calculate the remainders separately and then add them, but don't forget to get the remainder for the sum.

For multiplication:

``````(a * b) % N =
= ((m * N + x) * (l * N + y)) % N =
= ((m * l + x * l + m * y) * N + x * y) % N =
= (x * y) % N =
= ((a % N) * (b % N)) % N.
``````

Thus you can also do the same with products.

These properties can be simply derived in a more general setting using some abstract algebra (the remainders form a factor ring `Z/nZ`).

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But you can even pull the modulo into the product. –  chuck Apr 8 '11 at 13:27
@chuck I showed this in the second paragraph. –  bandi Apr 8 '11 at 13:33
Excellent. I suspected but didn't remember off-hand that the modulo could be brought into the products as well. –  Dave Costa Apr 8 '11 at 17:16

You can take the idea even further, if needed:

``````S = ( (a%N)*(x%N)+(b%N)*(y%N)+c%N )%N
``````
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You can apply the modulus to each term of the sum as you've suggested; but even so after summing them you must apply the modulus again to get your final result.

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``````   int x = (7 + 7 + 7) % 10;

int y = (7 % 10 + 7 % 10 + 7 % 10) % 10;
``````
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You remember right. The equation you gave, where you %N every of the summands is correct. And that would be exactly what I use. You should also %N for every partial sum (and the total) again, as the addition results can be still greater than N. BUT be careful this works only if your size limit is at least twice as big as your N. If this is not the case, it can get really nasty.

Btw for the following %N operations of the partial sums, you dont have to perform a complete division, a check > N and if bigger just subtraction of N is enough.

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