# Algorithm for finding an equidistributed solution to a linear congruence system

I face the following problem in a cryptographical application: I have given a set of linear congruences

``````a[1]*x[1]+a[2]*x[2]+a[3]*x[3] == d[1] (mod p)
b[1]*x[1]+b[2]*x[2]+b[3]*x[3] == d[2] (mod p)
c[1]*x[1]+c[2]*x[2]+c[3]*x[3] == d[3] (mod p)
``````

Here, x is unknown an a,b,c,d are given

The system is most likely underdetermined, so I have a large solution space. I need an algorithm that finds an equidistributed solution (that means equidistributed in the solution space) to that problem using a pseudo-random number generator (or fails).

Most standard algorithms for linear equation systems that I know from my linear algebra courses are not directly applicable to congruences as far as I can see...

My current, "safe" algorithm works as follows: Find all variable that appear in only one equation, and assign a random value. Now if in each row, only one variable is unassigned, assign the value according to the congruence. Otherwise fail.

Can anyone give me a clue how to solve this problem in general?

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You can use gaussian elimination and similar algorithms just like you learned in your linear algebra courses, but all arithmetic is performed mod p (p is a prime). The one important difference is in the definition of "division": to compute a / b you instead compute a * (1/b) (in words, "a times b inverse"). Consider the following changes to the math operations normally used

• addition: a+b becomes a+b mod p
• subtraction: a-b becomes a-b mod p
• multiplication: a*b becomes a*b mod p
• division: a/b becomes: if p divides b, then "error: divide by zero", else a * (1/b) mod p

To compute the inverse of b mod p you can use the extended euclidean algorithm or alternatively compute b**(p-2) mod p.

Rather than trying to roll this yourself, look for an existing library or package. I think maybe Sage can do this, and certainly Mathematica, and Maple, and similar commercial math tools can.

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Upvoted. But there are something I don't quite understand. Why should p be prime? What if those math operations are not performed mod p? Is there any tutorial on the web which can fill me in on this? –  Alcott Jun 5 '13 at 13:56
@Alcott: Can you be more specific? There are plenty of tutorials on gaussian elimination. The computing of inverses is needed to make the leading coefficient of each row 1. –  GregS Jun 6 '13 at 0:42
Here is the case, there is a system of linear congruences (mod p, and p might or might not be prime), I tried to solve it using ordinary Gaussian Elimination, during which I didn't make the leading coefficient of each row 1, does it matter? Here is the my post about this problem, math.stackexchange.com/q/411549/64610. –  Alcott Jun 6 '13 at 1:06
@Alcott: mathexchange is the right place to post the question. As far as I can tell, those guys know everything :) –  GregS Jun 8 '13 at 12:49
Yes, indeed, ;-) –  Alcott Jun 8 '13 at 13:50