The main issue you have to work around is the fact that you shouldn't be allowed to add/multiply/etc. values of `FiniteField`

under different orders. The solution is pretty straightforward from a type-system perspective: give values of different orders different types.

```
newtype FieldElem (n :: Nat) = FieldElem Integer
```

`Nat`

is a kind (from the GHC.TypeLits module) whose inhabitants are type-level numerical literals like `1`

, `2`

, `3`

, etc.

So now, you have different types:

```
FieldElem 7 -- the type of an element of a finite field of order 7
FieldElem 11 -- the type of an element of a finite field of order 11
```

So if you try to add two values of different types, you get a compile error.

```
> (x :: FieldElem 7) + (y :: FieldElem 11)
Error! You can only use + on two things of the same type!
> (x :: FieldElem 7) + (y :: FieldElem 7)
-- result: something of type FieldElem 7
```

Now you can implement the `Num`

instance:

```
instance Num (FieldElem n) where
(+) = ...
(*) = ...
```

One issue here is that `(+)`

needs to know what the order is, and the only information is in the type of `FieldElem`

. To go around this, we require `n`

to be an instance of the `KnownNat`

typeclass (also from GHC.TypeLits), which lets us get its integer value as a value at runtime:

```
natVal :: KnownNat n => Proxy n -> Integer
```

so,

```
> natVal (Proxy :: Proxy 10)
10
> natVal (Proxy :: Proxy 19)
19
```

And so our final design: (which requires `ScopedTypeVariables`

to let us use the `n`

type variable)

```
instance KnownNat n => Num (FieldElem n) where
FieldElem x + FieldElem y = FieldElem (mod (x + y) n)
where
n = natVal (Proxy :: Proxy n)
```

etc.!

You can bring in `Integer`

s into `FieldElem`

using a smart constructor:

```
mkFieldElem :: forall n. KnownNat n => Integer -> Maybe (FieldElem n)
mkFieldElem x | isPrime n = Just (FieldElem (mod x n))
| otherwise = Nothing
where
n = natVal (Proxy :: Proxy n)
```

The nice thing is that you get to use Haskell's type inference to specify the order you want:

```
> mkFieldElem 10 :: Maybe (FieldElem 23)
Just (FieldElem 10) -- :: Maybe (FieldElem 23)
```

Instead of manually passing it as a parameter! :)

By using smart constructors (and hiding the actual constructor) you can make sure that the user never has any values of type `FieldElem 8`

, for instance, so you don't have to worry about fields of bad orders being added together.

Note that, unfortunately, `fromInteger :: KnownNat n => Integer -> FieldElem n`

will necessarily be partial. It has to reject bad orders. But there are a large number of instances in *base* with partial implementations of `fromInteger`

anyway :| But, `fromInteger`

being in `Num`

is a bad idea anyways, and `Num`

is a bad typeclass, so it's `Num`

's fault :)

**EDIT** There's a potential way to make `fromInteger`

not partial/total: we could create a `Prime`

typeclass and have only instances where the `Nat`

parameter is prime:

```
class KnownNat n => Prime (n :: Nat)
```

Then you could make:

```
mkFieldElem :: Prime n => Integer -> FieldElem n
mkFieldElem x = FieldElem (mod x n)
where
n = natVal (Proxy :: Proxy n)
```

And now if you had:

```
instance Prime n => Num (FieldElem n) where
...
fromInteger = mkFieldElem
```

`fromInteger`

would be a total function, because the only instances would be for prime order fields!

However, in order for this to work, you need to get your instances of `Prime`

in a way that GHC can understand. In theory, this could be done using a GHC type checker extension --- you could write your own type checker extension so that `n`

is given a `Prime`

instance if it's prime at compile-time. However, this hasn't been done yet ... the next best thing you can do is offer run-time proofs of prime-ness:

```
witPrime :: forall n.KnownNat n => Proxy n -> Maybe (Dict (Prime n))
witPrime p | isPrime (natVal p) = Just (unsafeCoerce (Dict :: Dict (KnownNat n))
| otherwise = Nothing
```

This is using `Dict`

from the constraints library, which is one way of generating typeclass instances at runtime. If you ever pattern match on the `Dict`

constructor of a value of type `Dict c`

, the instance `c`

is "in scope" in that case statement.

In our case, then, we can do:

```
case witPrime (Proxy :: Proxy 11) of
Just Dict -> ... -- in this branch, `Prime 11` is an instance we can use
Nothing -> ... -- here, it isn't
```

Or we can run it in GHCi:

```
> let x = mkFieldElem 6 :: FieldElem 11
Error: No instance for (Prime 11)
> case witPrime (Proxy :: Proxy 11) of
Just Dict -> let x = mkFieldElem 6 :: FieldElem 11 -- okay, because of Dict constructor match
in print x
FieldElem 6 -- :: FieldElem 11
```