So I've been reading about coinduction a bit lately, and now I'm wondering: are Haskell lists inductive or coinductive? I've also heard that Haskell doesn't distinguish the two, but if so, how do they do so formally?

Lists are defined inductively, `data [a] = [] | a : [a]`

, yet can be used coinductively, `ones = a:ones`

. We can create infinite lists. Yet, we can create finite lists. So which are they?

Related is in Idris, where the type `List a`

is strictly an inductive type, and is thus only finite lists. It's defined akin to how it is in Haskell. However, `Stream a`

is a coinductive type, modeling an infinite list. It's defined as (or rather, the definition is equivalent to) `codata Stream a = a :: (Stream a)`

. It's impossible to create an infinite List or a finite Stream. However, when I write the definition

```
codata HList : Type -> Type where
Nil : HList a
Cons : a -> HList a -> HList a
```

I get the behavior that I expect from Haskell lists, namely that I can make both finite and infinite structures.

So let me boil them down to a few core questions:

Does Haskell not distinguish between inductive and coinductive types? If so, what's the formalization for that? If not, then which is [a]?

Is HList coinductive? If so, how can a coinductive type contain finite values?

What about if we defined

`data HList' a = L (List a) | R (Stream a)`

? What would that be considered and/or would it be useful over just`HList`

?

`HList`

type is usually called a co-list.