Modulo algorithm with byte array and 8 bit integer: 8bit = bytes % 8bit

I need to create an algorithm implemented in C that do modulo arithmetic between an arbitrary number of bytes and one byte. See this:

``````typedef struct{
u_int8_t * data;
u_int16_t length;
}UBigInt;
u_int8_t UBigIntModuloWithUInt8(UBigInt a,u_int8_t b){

}
``````

For powers of two a & (b-1) can be used but what about non powers of two?

I realise one method is: a - b*(a/b)

That would require to use UBigIntDivisionWithUInt8 and UBigIntMultiplicationWithUInt8 and UBigIntSubtractionWithUBigInt. There might be a more efficient way to do this?

Thank you.

This is the implementation I now have:

``````u_int8_t UBigIntModuloWithUInt8(UBigInt a,u_int8_t b){
if (!(b & (b - 1)))
return a.data[a.length - 1] & b - 1; // For powers of two this can be done
// Wasn't a power of two.
u_int16_t result = 0; // Prevents overflow in calculations
for(int x = 0; x < a.length; x++) {
result *= (256 % b);
result %= b;
result += a.data[x] % b;
result %= b;
}
return result;
}
``````
-
you say `a` is an arbitrary # of bytes; what if anything can you say about b ? is it constant? if so what value? – violet313 May 3 '12 at 23:10
I think `b` is an arbitrary 8-bit (unsigned?) integer. – Adam Liss May 3 '12 at 23:27
b could be 1-255. I need to implement it for 58 but there might be more cases. If there is some specifically optimised solution for 58, then that would be good but I will likely need to implement it for any. – Matthew Mitchell May 3 '12 at 23:35
i imagine there's a reason why you cannot/do not want GMP ? ~which has many optimisations built in, even targetting specific processors, almost like the folk who wrote it live for this kind of thing ;) – violet313 May 3 '12 at 23:45
I looked into it and it gave me a headache. :-) If I could cannibalise just the parts I need, it would be good but I can't make my way around that library. Is there code in that library or another that I can take from? I found a library called BigDigits though it uses 32bit integers and not 8bit integers like I want. :-( – Matthew Mitchell May 3 '12 at 23:54

1 Answer

You can use a variation on Horner's method.
Process a byte by byte with this formula:
`a % b = ((a // 256) % b) * (256 % b) + (a % 256) % b`, where x // y is the rounding division (normal C integer division). The reason this will work is that congruence modulo b is an equivalence relation.
With this you have an `O(length)` algorithm, or `O(log(a))`.
Example snippet (untested, my C skills are rusty):

``````u_int16_t result = 0; // Just in case, to prevent overflow
for(i = 0, i<a.length; i++) {
result *= (256 % b);
result %= b;
result += (a[i] % b);
result %= b;
}
``````

Some justification: `a = (a // 256) * 256 + (a % 256)`, therefore `a % b = ((a // 256) * 256) % b + ((a % 256) % b)`. However `a % 256 = a[n-1]` and `a // 256 = a[0 .. n-2]`. Reversing the actions in a way similar to Horner's rule gives you the presented snippet.

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I have no idea how this works but from a single test it seems to. Will implement it and test and et back to you. Thanks. – Matthew Mitchell May 4 '12 at 1:04
Genius! It works. That's quite brilliant. :-) – Matthew Mitchell May 4 '12 at 1:13
Thanks, I tested it in Python (has native support for arbitrary-sized ints) with this code: codepad.org/Eo00RNEJ Didn't seem to give any errors after 2 minutes of cycling, so I guess it's ok ;) Note that I haven't covered division by zero. – K.Steff May 4 '12 at 1:20
I added a test for powers of two, fixed the for loop and put up the code I have. – Matthew Mitchell May 4 '12 at 1:26