# Parametrized Inductive Types in Agda

I'm just reading Dependent Types at Work. In the introduction to parametrised types, the author mentions that in this declaration

``````data List (A : Set) : Set where
[]   : List A
_::_ : A → List A → List A
``````

the type of `List` is `Set → Set` and that `A` becomes implicit argument to both constructors, ie.

``````[]   : {A : Set} → List A
_::_ : {A : Set} → A → List A → List A
``````

Well, I tried to rewrite it a bit differently

``````data List : Set → Set where
[]   : {A : Set} → List A
_::_ : {A : Set} → A → List A → List A
``````

which sadly doesn't work (I'm trying to learn Agda for two days or so, but from what I gathered it's because the constructors are parametrised over `Set₀` and so `List A` must be in `Set₁`).

Indeed, the following is accepted

``````data List : Set₀ → Set₁ where
[]   : {A : Set₀} → List A
_::_ : {A : Set₀} → A → List A → List A
``````

however, I'm no longer able to use `{A : Set} → ... → List (List A)` (which is perfectly understandable).

So my question: What is the actual difference between `List (A : Set) : Set` and `List : Set → Set`?

-

I take the liberty to rename the data types. The first, which is indexed on `Set` will be called `ListI`, and the second `ListP`, has `Set` as a parameter:

``````data ListI : Set → Set₁ where
[]  : {A : Set} → ListI A
_∷_ : {A : Set} → A → ListI A → ListI A

data ListP (A : Set) : Set where
[]  : ListP A
_∷_ : A → ListP A → ListP A
``````

In data types parameters go before the colon, and arguments after the colon are called indicies. The constructors can be used in the same way, you can apply the implicit set:

``````nilI : {A : Set} → ListI A
nilI {A} = [] {A}

nilP : {A : Set} → ListP A
nilP {A} = [] {A}
``````

There difference comes when pattern matching. For the indexed version we have:

``````null : {A : Set} → ListI A → Bool
null ([]  {A})     = true
null (_∷_ {A} _ _) = false
``````

This cannot be done for `ListP`:

``````-- does not work
null′ : {A : Set} → ListP A → Bool
null′ ([]  {A})     = true
null′ (_∷_ {A} _ _) = false
``````

The error message is

``````The constructor [] expects 0 arguments, but has been given 1
when checking that the pattern [] {A} has type ListP A
``````

`ListP` can also be defined with a dummy module, as `ListD`:

``````module Dummy (A : Set) where
data ListD : Set where
[]  : ListD
_∷_ : A → ListD → ListD

open Dummy public
``````

Perhaps a bit surprising, `ListD` is equal to `ListP`. We cannot pattern match on the argument to `Dummy`:

``````-- does not work
null″ : {A : Set} → ListD A → Bool
null″ ([]  {A})     = true
null″ (_∷_ {A} _ _) = false
``````

This gives the same error message as for `ListP`.

`ListP` is an example of a parameterised data type, which is simpler than `ListI`, which is an inductive family: it "depends" on the indicies, although in this example in a trivial way.

Parameterised data types are defined on the wiki, and here is a small introduction.

Inductive families are not really defined, but elaborated on in the wiki with the canonical example of something that seems to need inductive families:

``````data Term (Γ : Ctx) : Type → Set where
var : Var Γ τ → Term Γ τ
app : Term Γ (σ → τ) → Term Γ σ → Term Γ τ
lam : Term (Γ , σ) τ → Term Γ (σ → τ)
``````

Disregarding the Type index, a simplified version of this could not be written with in the `Dummy`-module way because of `lam` constructor.

Another good reference is Inductive Families by Peter Dybjer from 1997.

Happy Agda coding!

-
Thanks for your answer! There's still one thing I'd like to know (my question might have been a bit ambiguous, I'm afraid): I cannot define `List` as `Set → Set` to prevent inconsistency in the type system, what is the actual mechanism that makes `List (A : Set) : Set` "work"? Because to me (coming from Haskell background), they both seem to be `data List :: * -> * where (...)`, but one works and the other doesn't. Thanks! –  Vitus Jan 27 '12 at 16:46
I think you have already stated the reason; to avoid inconsistencies constructors with Set as an argument must necessary belong in Set₁. The parametric data types allows us to write datatypes that with indicies would have to end up one level "higher", and it "works" just because of the well-behaved conditions of parametric datatypes. On the other hand, there is some controversy how "safe" the inductive families are, as the page to the wiki illustrates, and I think the current consensus is to have some small and trusted Agda code that fancy data types can be translated to. –  danr Jan 28 '12 at 1:54
That clears it up for me, thanks. Here's your well-deserved bounty. –  Vitus Jan 28 '12 at 11:06
I am a bit tempted to rewrite some of this answer... Would that be ok with you Vitus? A rewrite to the better, I might add. –  danr Apr 25 '12 at 20:16
Sure! Go ahead. –  Vitus Apr 25 '12 at 21:36