Prime finite field (Z/pZ) in Haskell with Operator Overloading [duplicate]

Question

I have some code right now that creates a prime field of order n, with all the necessary functions to compute addition, multiplication, and their inverses. It works fine, but I really want to be able to overload the Integral and Num infix functions of +, -, *, /, and ^, but I don't know how to do this. Here's my current code:

import Data.Maybe

data FiniteField = FiniteField {add::(FieldElement -> FieldElement -> FieldElement),
              addinv::(FieldElement -> FieldElement),
              mul::(FieldElement -> FieldElement -> FieldElement),
              mulinv::(FieldElement -> FieldElement),
              new::(Integer -> FieldElement)
              }

newtype FieldElement = FieldElement Integer deriving (Eq, Show, Read)

toInt :: FieldElement -> Integer
toInt (FieldElement x) = x

gcdExt :: Integer -> Integer -> (Integer, Integer, Integer)
gcdExt a 0 = (1, 0, a)
gcdExt a b = (t, s - q * t, g)
    where (q, r) = quotRem a b
          (s, t, g) = gcdExt b r

modMulInv :: Integer -> Integer -> Integer
modMulInv a n = i
    where (i, _, _) = gcdExt a n

isPrimeLoop :: Integer -> Integer -> Bool
isPrimeLoop n i
    | i == n = True
    | i == 2 = (mod n i /= 0) && isPrimeLoop n (i+1)
    | otherwise = (mod n i /= 0) && isPrimeLoop n (i+2)

isPrime :: Integer -> Bool
isPrime n = isPrimeLoop n 2

newFiniteField :: Integer -> Maybe FiniteField
newFiniteField n
    | not (isPrime n) = Nothing
    | otherwise = Just (FiniteField add addinv mul mulinv new)
    where
        add = (\x y -> FieldElement (mod (toInt x + toInt y) n) )
        addinv = (\x -> FieldElement (mod (n - toInt x) n) )
        mul = (\x y -> FieldElement (mod (toInt x * toInt y) n) )
        mulinv = (\x -> FieldElement (mod (modMulInv (toInt x) n) n) )
        new = (\x -> FieldElement x)

Answer 1

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 Integers 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

Answer 2

You can't productively use Num with this design. The important thing about type classes is that dispatch is done by type, not value. An instance of Num for FieldElement wouldn't have any way of knowing what FiniteField it belongs to, so its operations can't depend on what field you're operating in.

There are a couple directions you could take this that would work with Num.

The first is making FieldElement an expression type that builds up expression trees with its Num instance, then can be evaluated within a particular FiniteField. This has the advantage of using very simple techniques. It has the disadvantage of being really bad for memory and performance when the computations get complex.

The second is to follow a pattern like Data.Fixed. You would change FiniteField to a class and implement it on some empty types representing various specific fields, with names like F17, for instance. Then you parameterize FieldElement with a type argument that's used to mark which FiniteField they belong to. Finally, the instance of Num for FiniteElement requires that its argument have a FiniteField instance, which is used in its implementation. This approach has the advantage of being really nice to work with. The disadvantage is requiring a boilerplate FiniteField instance for each field you want to work in.

A third option is very similar to the above, but replacing the custom F17 like data types with some sort of type-level natural. (Either manual, or from -XDataKinds). Then you can implement the Num instance in terms of the type-level natural. The advantage here is that you get rid of all the boilerplate instances from the previous approach. The disadvantage is that it doesn't require that the type-level argument is a prime number, and several calculations are wrong if it isn't prime.