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EDIT: Solved. I was unware that enabling a language extension in the source file did not enable the language extension in GHCi. The solution was to :set FlexibleContexts in GHCi.


I recently discovered that type declarations in classes and instances in Haskell are Horn clauses. So I encoded the arithmetic operations from The Art of Prolog, Chapter 3, into Haskell. For instance:

fac(0,s(0)).
fac(s(N),F) :- fac(N,X), mult(s(N),X,F).

class Fac x y | x -> y
instance Fac Z (S Z)
instance (Fac n x, Mult (S n) x f) => Fac (S n) f

pow(s(X),0,0) :- nat(X).
pow(0,s(X),s(0)) :- nat(X).
pow(s(N),X,Y) :- pow(N,X,Z), mult(Z,X,Y).

class Pow x y z | x y -> z
instance (N n) => Pow (S n) Z Z
instance (N n) => Pow Z (S n) (S Z)
instance (Pow n x z, Mult z x y) => Pow (S n) x y

In Prolog, values are instantiated for (logic) variable in a proof. However, I don't understand how to instantiate type variables in Haskell. That is, I don't understand what the Haskell equivalent of a Prolog query

?-f(X1,X2,...,Xn)

is. I assume that

:t undefined :: (f x1 x2 ... xn) => xi

would cause Haskell to instantiate xi, but this gives a Non type-variable argument in the constraint error, even with FlexibleContexts enabled.

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2  
Keep in mind that this does not embed prolog in haskell's type system. The typeclass solver does no backtracking. –  luqui Dec 21 '10 at 5:34
    
You're right; however, I wasn't under any impression that it did. An actual embedding would require much more work :). –  danportin Dec 21 '10 at 6:06

1 Answer 1

up vote 3 down vote accepted

No sure about Prolog samples, but I would define this in Haskell in the following way:

{-# LANGUAGE MultiParamTypeClasses, EmptyDataDecls, FlexibleInstances,
FlexibleContexts, UndecidableInstances, TypeFamilies, ScopedTypeVariables #-}

data Z
data S a
type One = S Z
type Two = S One
type Three = S Two
type Four = S Three 


class Plus x y r
instance (r ~ a) => Plus Z a r
instance (Plus a b p, r ~ S p) => Plus (S a) b r

p1 = undefined :: (Plus Two Three r) => r


class Mult x y r
instance (r ~ Z) => Mult Z a r
instance (Mult a b m, Plus m b r) => Mult (S a) b r

m1 = undefined :: (Mult Two Four r) => r


class Fac x r
instance (r ~ One) => Fac Z r
instance (Fac n r1, Mult (S n) r1 r) => Fac (S n) r

f1 = undefined :: (Fac Three r) => r


class Pow x y r
instance (r ~ One) => Pow x Z r
instance (r ~ Z) => Pow Z y r
instance (Pow x y z, Mult z x r) => Pow x (S y) r

pw1 = undefined :: (Pow Two Four r) => r

-- Handy output
class (Num n) => ToNum a n where
    toNum :: a -> n
instance (Num n) => ToNum Z n where
    toNum _ = 0
instance (ToNum a n) => ToNum (S a) n where
    toNum _ = 1 + toNum (undefined :: a) 

main = print $ (toNum p1, toNum m1, toNum f1, toNum pw1)

Update:

As danportin noted in his comment below TypeFamilies "Lazy pattern" (in instance context) is not needed here (his initial code is shorter and much cleaner).

One application of this pattern though, which I can think of in the context of this question is this: Say we want to add Boolean logic to our type-level arithmetic:

data HTrue
data HFalse

-- Will not compile
class And x y r | x y -> r
instance And HTrue HTrue HTrue
instance And a b HFalse -- we do not what to enumerate all the combination here - they all HFalse

But this will not compile due to "Functional dependencies conflict". And it looks to me that we still can express this overlapping case without fundeps:

class And x y r
instance (r ~ HTrue) => And HTrue HTrue r
instance (r ~ HFalse) => And a b r

b1 = undefined :: And HTrue HTrue r => r   -- HTrue
b2 = undefined :: And HTrue HFalse r => r  -- HFalse

It's definitely not a nicest way (it requires IncoherentInstances). So maybe somebody can suggest another, less 'traumatic' approach.

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1  
I'm not sure what the purpose of the lazy pattern match is. I'll have to do more reading. I was unaware that enabling language extensions in the source file did not enable those (the enabled) extensions in GHCi. So the solution was to :set FlexibleContexts in addition to interpreting with them. Thanks, however. –  danportin Dec 21 '10 at 6:01
2  
@danportin, yes, I agree - this "lazy pattern" wasn't needed here. I'll edit my post to reflect this. I think this patter will be useful when we face overlapping instances situation (otherwise we'll get Functional dependencies conflict). See my example of type-level And –  Ed'ka Dec 21 '10 at 7:50

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