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I have big numbers K, C[1], C[2], C[3] etc. and I have to calculate b:

b = C[1]*C[2]+C[3]*C[4]+... (mod K)

Now I calculate the full sum and then make something like

b = SUM % K.

But this is not work when SUM becomes bigger then unsigned long limit, so I have to use something like

b = (C[1]*C[2] %K + C[3]*C[4] %K ) %K

But this is time-consuming. I've tried to use unsigned long long except unsigned long and this is time-consuming too. Is there any better way?


  C = (unsigned long long int *) malloc(N*sizeof(unsigned long long int));
  unsigned long int i, j, l;
  C[0] = 1;
  for (i=1; i<=N; i++) {
    C[i] = 0;
    l = (unsigned long int) i/2;
    for (j=0; j<l; j++) {
      C[i] += C[j]*C[i-j-1];
      C[i] = C[i] % K;
    C[i] = C[i]*2;
    C[i] = C[i] % K;
    if (i - l*2 == 1) {
      C[i] += C[l]*C[l];
    C[i] = C[i] % K;
share|improve this question
How big is big? – ypercubeᵀᴹ May 15 '11 at 12:22
Big is about 2^100 – Ximik May 15 '11 at 14:07
So, if P is about 2^100, what datatype do you use for storing it? – ypercubeᵀᴹ May 15 '11 at 14:22
So, you mean that P is less than 2^16 ? Then you could use 32-bit integers for all your arithmetic functions. – ypercubeᵀᴹ May 15 '11 at 14:31
You have to do % P after each multiplication and after every addiition, correct. But I doubt this is slow. Please post the whole code you have by editing your question (add it in the end), so others can see and comment. Perhaps there are other issues that it is slow. – ypercubeᵀᴹ May 15 '11 at 14:35
up vote 1 down vote accepted

If you can factor K into pairwise relatively prime numbers K1,...,Kn then you can do the computation for each Ki and combine the results into a result for K by using the Chinese remainder theorem. This is usually much faster, especially if the Ki fit into a machine word.

share|improve this answer
I don't see how it solves the OP's problem. K doesn't exceed 2^16. What could we possibly gain by factoring K into K1,...,Kn? – ciamej Feb 18 '14 at 22:29
That's true, I probably missed the comment where he states that limit. For 2^100 it would be useful, but not for 2^16. – starblue Feb 22 '14 at 9:29

modulo m arithmetic is a ring homomorphism.

say f(x) = x%P then

f(a+b) = f(a)+f(b) and also

f(a*b) = f(a)*f(b).

this means you can do a mod P after every step.

share|improve this answer
No, i can't, because of limits in data types. – Ximik May 15 '11 at 13:48

To calculate

b = ( C[1]*C[2]+C[3]*C[4]+... ) % P 

you can do instead:

b = ( ( (C[1] % P) * (C[2] % P) % P )
    + ( (C[3] % P) * (C[4] % P) % P )
    + ...
    ) % P

Since all operations will not have results bigger than (P-1)^2, I expect this to be faster if you keep all intermediate results in variables with types as small as possible.

If the number P is some special form, like a power of 2, then there are faster methods.

In this SO question: big-numbers-in-c, you'll find a reference to GNU Multiple Precision Arithmetic Library. If you are not allowed to use such a library I guess that best choice then is to implement (a subset of) such a library of your own.

You could store integers (bigger than 2^64) in arrays and define addition, mupltiplication, division and modulo functions for such numbers.

share|improve this answer
Yes, there are a lot of examples with mod 2^N, but I can't found any for another P. This is the problem. – Ximik May 15 '11 at 14:09
Seems like this library can't help. Because it would be ever more slow then current solution. – Ximik May 15 '11 at 15:25

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