Define a "canonical" form for your indices such as this:

- [h] is largest magnitude index,with sign +1;
- [k] is second largest magnitude index;
- [l] is remaining index
- all common factors have been factored out

Now convert all your indices to their canonical form, and eliminate them if they are a duplicate of one already found.

This form also allows for sorting of your Miller indices, speeding up searchng, etc.

I have a physics degree; I knew Miller indices couldn't get too large. ;-)

Here is a "Canonization" procedure. It uses brute force for the factorization, but I believe that is sufficient for the problem domain; if performance is an issue that can be addressed later.

**2013-03-09: Updated to use pre-computed table of primes <= 31**

```
public struct MillerIndex {
public int H { get; private set; }
public int K { get; private set; }
public int L { get; private set; }
public MillerIndex( int h, int k, int l) : this() {
H = h; K = k; L = l;
}
}
public static class MillereHandler {
static IList<int> Primes = new List<int> {2,3,5,7,11,13,17,19,23,29,31};
public static MillerIndex GetCanonical(MillerIndex mi) {
int h, k, l, sign;
if (Math.Abs(mi.H) > Math.Abs(mi.K) && Math.Abs(mi.H) > Math.Abs(mi.L) ) {
sign = Math.Sign(mi.H);
h = mi.H;
k = Math.Abs(mi.K) > Math.Abs(mi.L) ? mi.K : mi.L;
l = Math.Abs(mi.K) > Math.Abs(mi.L) ? mi.L : mi.K;
} else if (Math.Abs(mi.K) > Math.Abs(mi.H) && Math.Abs(mi.K) > Math.Abs(mi.L) ) {
sign = Math.Sign(mi.K);
h = mi.K;
k = Math.Abs(mi.H) > Math.Abs(mi.L) ? mi.H : mi.L;
l = Math.Abs(mi.H) > Math.Abs(mi.L) ? mi.L : mi.H;
} else {
sign = Math.Sign(mi.L);
h = mi.L;
k = Math.Abs(mi.H) > Math.Abs(mi.K) ? mi.H : mi.K;
l = Math.Abs(mi.H) > Math.Abs(mi.K) ? mi.K : mi.H;
}
h *= sign; k *= sign; l *= sign;
foreach (var i in Primes.Where(i=> (i^2) < l) ) {
while ( (h/i)*i == h && (k/i)*i == k && (l/i)*i == l ) {
h /= h/i; k /= k/i; l /= l/i;
}
}
return new MillerIndex(h, k, l);
}
}
```