# What is “n” in RankNTypes

I understand how `forall` enables us to write polymorphic function.

According to this chapter, the normal function which we generally write are Rank 1 types. And this function is of Rank 2 type:

``````foo :: (forall a. a -> a) -> (Char,Bool)
foo f = (f 'c', f True)
``````

It explains like this:

In general, a rank-n type is a function that has at least one rank-(n-1) argument but no arguments of even higher rank.

What does it actually mean by rank argument ?

Can somebody give an example of Rank 3 type which is similar to the above `foo` function.

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Rank is defined inductively on the structure of types:

``````rank (forall a. T) = max 1 (rank T)
rank (T -> U)      = max (if rank T = 0 then 0 else rank T + 1) (rank U)
rank (a)           = 0
``````

Note how it increases by one on the left-hand side of an arrow. So:

``````Rank 0: Int
Rank 1: forall a. a -> Int
Rank 2: (forall a. a -> Int) -> Int
Rank 3: ((forall a. a -> Int) -> Int) -> Int
``````

and so on.

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I don't think this is quite right: e.g. `fix :: (a -> a) -> a` sure is rank-1, not rank-2. –  leftaroundabout Mar 12 '14 at 20:00
Also why wouldn't a function that returns a polymorphic function be rank 2? That is why would the rank increase for a `forall` on the left side of the `->`, but not the right? Why wouldn't `Int -> (forall a. a -> a)` be a rank 2 type? –  sepp2k Mar 12 '14 at 20:02
@leftaroundabout, you are right, I fixed the definition. –  Andreas Rossberg Mar 12 '14 at 20:06
@sepp2k, that's how the definition goes. The deeper reason is that the left of an arrow has negative polarity, the right is positive. (It's similar to the definition of order.) –  Andreas Rossberg Mar 12 '14 at 20:06
@sepp2k: if you return a polymorphic function, it's the same as if your entire multi-argument function is (rank-1) polymorphic but the type variable just happens to turn not up in the first argument. –  leftaroundabout Mar 12 '14 at 20:08

`n` is the level at which the `forall`(s) is/are nested. So if you have `forall a. ((a -> a) -> Bla)` (which is simply a more verbose way of writing `(a -> a) -> Bla`), then the `forall` is on the outside and applies to the whole function, so it's rank 1. With `(forall a. a -> a) -> Bla` the `forall` only applies to the inner function (i.e. the one you take as an argument) and is thus rank 2.

If the function that you take as an argument would itself take another function as an argument and that function would have a `forall` in its type, then that would be rank 3. And so on.

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More precisely, `n` is the level at which the `forall`s are nested on the left of arrows (cf. the comments on Andreas Rossberg's answer). –  Antal Spector-Zabusky Mar 14 '14 at 7:16

`foo` has one argument that includes a universal quantor, that what kicks in the need for RankN. But this argument's type itself, `a -> a`, is rank-1, it's the only argument, so `foo` has rank n with n − 1 = 1, i.e. `foo` is rank-2.

Now consider

``````bar :: ((forall a. a -> a) -> (Char,Bool)) -> Int
``````

This has an argument of `foo`'s type, which as we said has Rank 2. So that's the highest rank in `bar`'s arguments; `bar` is thus a rank-3 function.

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