According to the Haskell 2010 language report, its type checker is based on Hindley-Milner. So consider a function f of this type,

f :: forall a. [a] -> Int

It could be the length function for instance. According to Hindley-Milner, f [] type checks to Int. We can prove this by instantiating the type of f to [Int] -> Int, and the type of [] to [Int], then conclude that the application ([Int] -> Int) [Int] is of type Int.

In this proof, I chose to instantiate types forall a. [a] -> Int and forall a. [a] by substituting Int to a. I can substitute Bool instead, the proof works too. Isn't it strange in Hindley-Milner that we can apply a polymorphic type to another, without specifying which instances we use ?

More specifically, what in Haskell prevents me from using the type a in the implementation of f ? I could imagine that f is a function that equals 18 on any [Bool], and equals the usual length function on all other types of lists. In this case, would f [] be 18 or 0 ? The Haskell report says "the kernel is not formally specified", so it's hard to tell.

  • 1
    That's a great question. Note that your function f which behaves on [Bool] differently from on other list types [a] can not exist (i.e. can not be written in Haskell) because of parametricity. In Haskell there is no way to write if a==Bool then ... and have an unaltered signature forall a. [a] -> Int. – chi Aug 10 at 12:07
  • See my answer below. Parametricity can be a bit overwhelming at first, but you can start from the classical "theorems for free" paper by Wadler, which shows nice examples. – chi Aug 10 at 12:22
  • I don't have a perfect reference. Parametricity is sometimes affected by bottoms (seq, infinite recursion) but I recall that assuming functions strict one can still have a weaker form of parametricity. (Again, I can't provide a reference). To completely "break" parametricity, one can use forall a. Typeable a => [a] -> Int which allows if a==Bool then ... -- but here the type changes, so it is not really broken: we have a type for parametric polymorphism and another one for ad-hoc (non-parametric) polymorphism. – chi Aug 10 at 21:26
  • No, the extra a argument is not needed at all in Haskell. And even in Coq, you can't eliminate (a : Type) so there is no "if". In Coq you would need some argument to eliminate such as forall (a : Type), typeable a -> list a -> int where typeable a is suitably defined, e.g. with an inductive definition. – chi Aug 11 at 8:41
  • @chi Without the extra a the best I found is f l = if typeOf l == typeOf ([True]) then 18 else length l. But then f [] crashes with a type error. Do you see an other way ? – V. Semeria Aug 11 at 8:49
up vote 3 down vote accepted

During type inference, such type variables can indeed instantiated to any type. This may be seen as a highly non deterministic step.

GHC, for what it is worth, uses the internal Any type in such cases. For instance, compiling

{-# NOINLINE myLength #-}
myLength :: [a] -> Int
myLength = length

test :: Int
test = myLength []

results in the following Core:

-- RHS size: {terms: 3, types: 4, coercions: 0}
myLength [InlPrag=NOINLINE] :: forall a_aw2. [a_aw2] -> Int
[GblId, Str=DmdType]
myLength =
  \ (@ a_aP5) -> length @ [] Data.Foldable.$fFoldable[] @ a_aP5

-- RHS size: {terms: 2, types: 6, coercions: 0}
test :: Int
[GblId, Str=DmdType]
test = myLength @ GHC.Prim.Any (GHC.Types.[] @ GHC.Prim.Any)

where GHC.Prim.Any occurs in the last line.

Now, is that really not deterministic? Well, it does involve a kind of non deterministic step "in the middle" of the algorithm, but the final resulting (most general) type is Int, and deterministically so. It does not matter what type we choose for a, we always get type Int at the end.

Of course, getting the same type is not enough: we also want to get the same Int value. I conjecture that it can be proven that, given

f :: forall a. T a
g :: forall a. T a -> U


g @ V (f @ V) :: U

is the same value whatever type V is. This should be a consequence of parametricity applied to those polymorphic types.

To follow-up on Chi's answer, here is the proof that f [] cannot depend on the type instances of f and []. According to Theorems for free (the last article here), for any types a,a' and any function g :: a -> a', then

f_a = f_a' . map g

where f_a is the instantiation of f on type a, for example in Haskell

f_Bool :: [Bool] -> Int
f_Bool = f

Then if you evaluate the previous equality on []_a, it yields f_a []_a = f_a' []_a'. In the case of the original question, f_Int []_Int = f_Bool []_Bool.

Some references for parametricity in Haskell would be useful too, because Haskell looks stronger than the polymorphic lambda calculus described in Walder's paper. In particular, this wiki page says parametricity can be broken in Haskell by using the seq function.

The wiki page also says that my type-depending function exists (in other languages than Haskell), it is called ad-hoc polymorphism.

  • You can do ad-hoc polymorphism (and therefore write your type-dependent function) in Haskell, using a typeclass. If you do this, the type checker will force you to explicitly specify which type you're using for a. – DarthFennec Aug 10 at 18:58
  • @DarthFennec hum... That seems to contradict the parametricity equation above. Or the type of the function is not forall a. [a] -> Int. Can you give the exact example you're thinking of? – V. Semeria Aug 10 at 19:31
  • You're correct, sorry I wasn't clear; if you use a typeclass (let's call it Foo) to make a type-dependent function, then the type of the function must be forall a. Foo a => [a] -> Int. If we don't add the class constraint to a, then yes, parametricity dictates the function cannot be type-dependent. – DarthFennec Aug 10 at 19:53

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