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!