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I assume, that it is not possible to just add two type level natural numbers in haskell. Is this true?

Suppose the natural numbers are defined like so:

class HNat a

data HZero
instance HNat HZero

data HSucc n
instance (HNat n) => HNat (HSucc n)

Is it pssible to define HAdd in a way similar to:

class (HNat n1, HNat n2, HNat ne) => HAdd n1 n2 ne | n1 n2 -> ne
instance             HAdd HZero HZero HZero
instance (HNat x) => HAdd HZero x     x
instance (HNat n1 
         ,HNat x) => HAdd (HSucc n1)  x (HAdd n1 (HSucc x) (???))
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2 Answers 2

up vote 18 down vote accepted

You don't need the case for adding HZero and HZero. This is already covered by the second case. Think how you'd add Peano naturals on the term level, by induction on the first argument:

 data Nat = Zero | Succ Nat

 add :: Nat -> Nat -> Nat
 add Zero     y = y
 add (Succ x) y = Succ (add x y)

Now if you're using functional dependencies, you're writing a logic program. So instead of making a recursive call on the right hand side, you add a constraint for the result of the recursive call on the left:

 class (HNat x, HNat y, HNat r) => HAdd x y r | x y -> r
 instance (HNat y)     => HAdd HZero     y y
 instance (HAdd x y r) => HAdd (HSucc x) y (HSucc r)

You don't need the HNat constraints in the second instance. They're implied by the superclass constraints on the class.

These days, I think the nicest way of doing this sort of type-level programming is to use DataKinds and TypeFamilies. You define just as on the term level:

 data Nat = Zero | Succ Nat

You can then use Nat not only as a type, but also as a kind. You can then define a type family for addition on two natural numbers as follows:

 type family Add (x :: Nat) (y :: Nat) :: Nat
 type instance Add Zero     y = y
 type instance Add (Succ x) y = Succ (Add x y)

This is much closer to the term-level definition of addition. Also, using the "promoted" kind Nat saves you from having to define a class such as HNat.

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+1 for DataKinds, they're great –  luqui Jan 28 '13 at 15:33
    
Note that a type family suffices for type-level addition alone, but in order to do term-level calculations that require type-level addition (concatenating fixed-length sequences, for example) you'll generally need a type class as well. –  C. A. McCann Jan 28 '13 at 20:33
    
@C.A.McCann The need for type classes to implement additional functions is independent of the approach taken to implement type-level addition. (I.e., if you use a class to implement additional functionality, then you'd need it when using the HAdd-based implementation, too.) Also, I'm not entirely sure why you're saying you need a class in order to implement concatenation fixed-length sequences. When using GADTs, this can easily be done without a class. –  kosmikus Jan 28 '13 at 21:38
    
Yeah, that was probably a bad example since the GADT approach is very simple in that case. :] I just wanted to mention that type-level computation alone (by whatever means) doesn't generally let you do term-level computation based on those types without something explicitly connecting the two levels. I've seen people stumble at first because they expect GHC to figure things out for them. –  C. A. McCann Jan 28 '13 at 21:51
    
Ok, I agree then :) –  kosmikus Jan 28 '13 at 22:47

It is possible. Take a look at the packages type-level-natural-number and `type-level-natural-number-operations. Both are a bit old, but easy to use and the latter defines a Plus type family.

Anyway, I would change your last line to something like this (I didn't test if this compiles).

instance (HNat n1, HNat x, HAdd n1 x y) => HAdd (HSucc n1) x (HAdd n1 x (HSucc y))

Basically, what you do is to define addition inductively and the additional constraint HAdd n1 x y adds the necessary inductive case.

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