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.

`f`

which behaves on`[Bool]`

differently from on other list types`[a]`

can not exist (i.e. can not be written in Haskell) because ofparametricity. 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`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`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`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