I'm trying to calculate `a mod b`

in OpenCL, where `a`

is an array of `ulong`

elements, and is twice the length of `b`

.

```
__kernel void mod(__global ulong *a, __global ulong *b, __global ulong length) {
// length = len(a) = 2 * len(b)
...
}
```

What I want is something like `a %= b`

, but with arrays. The arrays represent numbers of course, with their last element representing the least significant bits.

Is it possible to do this in-place (i.e. without allocating extra memory)? What is a good algorithm for calculating the medulus for large numbers?

Note that neither of the two numbers can be easily represented in another way (e.g. using exponents). Most of the times they will be pseudoprimes. Also, having some concurrency would be nice.

Pointers to any useful material on this are welcome.

**EDIT:** if that helps, `length`

can be known at compile time.

**EDIT:** I'm sorry I wasn't clear here. I'm not working on an array of integers, I'm working on two big integers, for example `a`

is 8Mb (*a 67108864-bit number*) and

`b`

is 4Mb (*a*). I work them in base 2^64, hence the arrays of

**33554432-bit**number`ulong`

integers. Basically, those are just the digits of the number.
`b`

array should each be used twice? That is, if`a`

is [4,5,9,7] and`b`

is [2,3] do you expect that after this that`a`

should be [0,2,1,1] ? – Daniel Martin Jul 5 '11 at 15:18