You've gotten confused by the (confusing) fact that `[]`

means two different things in different contexts in Haskell, which has made it hard for you to interpret the rest of your experiments.

At the value level `[]`

indeed is the empty constructor for lists. But when you asked for the type of `Property "Colors" [1,2,3,4]`

and saw `Property [] a`

you're looking at a **type** expression, not a value expression. There is no empty list at the type level.^{1} Instead `[]`

is the *type constructor* for the list type. You can have `[Int]`

(the type of lists of ints), `[Bool]`

(the type of lists of bools), or `[a]`

(the polymorphic type of lists of `a`

); `[]`

is the thing that's being applied to `Int`

, `Bool`

, and `a`

in those examples.

You can actually write `[Int]`

as `[] Int`

if you want, though it looks weird, so you usually only see `[]`

at the type level when you want to use it unapplied.

Lets take a look at your data declaration again:

```
data Property f a = Property String (f a) | Zilch
```

On the left-hand side you've declared the shape of the **type** `Property`

; `Property f a`

forms a type. On the right hand side you declare the shape of the **values** that go in that type, by listing the possible value constructors (`Property`

and `Zilch`

) and the types of the "slots" in those constructors (none for `Zilch`

; one slot of type `String`

and another one of type `f a`

, for `Property`

).

So from that we can tell that whatever `f`

and `a`

are, the type expression `f a`

(`f`

applied to `a`

) must form a type that has values. But `f`

doesn't have to be (in fact it can't be) a normal type of values on its own! There is no slot of type `f`

in the `Property`

value constructor.

A much clearer example to use would have been this:

```
*Main> var = Property "Stuff" (Just True)
*Main> :t var
var :: Property Maybe Bool
```

If you don't know it, `Maybe`

is a built in type whose declaration looks like this:

```
data Maybe a = Just a | Nothing
```

It's good for this example because we're not using the same name at the type level and the value level, which avoids confusion when you're trying to learn how things work.

`Just True`

is a value of type `Maybe Bool`

. At the value level we have the `Just`

data constructor applied to the value `True`

. At the type level we have the `Maybe`

*type constructor* applied to the type `Bool`

. `Maybe Bool`

values go in the `f a`

slot of the `Property`

value constructor, which fits straightforwardly: `f`

is `Maybe`

and `a`

is `Bool`

.

So going back to your original example:

```
*Main> var = Property "Colors" [1,2,3,4]
*Main> :t var
var :: Num a => Property [] a
```

You're filling the `f a`

slot with `[1, 2, 3, 4]`

. That's a list of some kind of number, so it'll be `Num t => [t]`

. So the `a`

in `f a`

is the `t`

(with a `Num`

constraint that needs to come along), and the `f`

is the **list type constructor** `[]`

. This `[]`

is like `Maybe`

, not like `Nothing`

.

```
*Main> var = Property "Colors" (1,"Red")
*Main> :t var
var :: Num t => Property ((,) t) [Char]
```

Here the `f a`

slot is being filled with `(1, "Red")`

, which is of type `Num t => (t, [Char])`

(remembering that `String`

is just another way of writing `[Char]`

). Now to understand this we have to get a little finicky. Forget the constraint for now, and just focus on `(t, [Char])`

. Somehow we need to interpret that as something applied to something else, so we can match it to `f a`

. Well it turns out that although we have special *syntax* for tuple types (like `(a, b)`

), they're really just like ordinary ADTs you could declare without the special syntax. A 2-tuple type is a type constructor that we can write `(,)`

applied to two other types, in this case `t`

and `[Char]`

. And we can use partially applied type constructors, so we can think of `(,)`

applied to `t`

as one unit, and that unit applied to `[Char]`

. We can write that interpretation as a Haskell type expression `((,) t) [Char]`

, but I'm not sure if that's clearer. But what it comes down to is that we can match this to `f a`

by taking the first "unit" `(,) t`

as `f`

and `[Char]`

as `a`

. Which then gives us `Property ((,) t) [Char]`

(only we have to also put back the `Num t`

constraint we forgot about earlier).

And finally this one:

```
*Main> var = Property "Colors" 20
*Main> :t var
var :: Num (f a) => Property f a
```

Here we're filling the `f a`

slot with `20`

, some sort of number. We haven't specified exactly what type the number is, so Haskell is willing to believe it could be any type in the `Num`

class. But we still need the type to have a "shape" we can match with `f a`

: some type constructor applied to some other type. And it's the whole type expression `f a`

that needs to match the type of `20`

, so *that's* what has a `Num`

constraint. But we haven't said anything else about what `f`

or `a`

might be, and `20`

can by *any* type that meets a `Num`

constraint, so it can be any `Num (f a) => f a`

we want for it, hence why the type of your `var`

is still polymorphic in `f`

and `a`

(just with the added constraint).

You might have only seen numeric types like `Integer`

, `Int`

, `Double`

, etc, and so be wondering how there could possibly be an `f a`

that's a number; all of those examples are just single basic types, not something applied to something. But you can write your own `Num`

instances, so Haskell never assumes a given type (or shape of type) *couldn't* be a number, it'll just complain if you actually attempt to use it and it can't find a `Num`

instance. So sometimes you get things like this that are *probably* errors, but Haskell accepts (for now) with a `Num`

type on an odd thing that you weren't expecting.

And in fact there *are* already types in the built-in libraries that do have compound type-level structore and have a `Num`

instance. One example is the `Ratio`

type for representing fractional numbers as ratios of two integers. You can have a `Ratio Int`

or a `Ratio Integer`

, for example:

```
Main*> 4 :: Ratio Int
4 % 1
```

So you could say:

```
*Main> var = Property "Colors" (20 :: Ratio Integer)
*Main> :t var
var :: Property Ratio Integer
```

^{1} Actually there can be, with the `DataKinds`

extension enabled to allow types that mirror the structure of almost any value, so you can have type-level lists. But that's not what's going on here and it's not really a feature you can use until you've got a good handle on the way types and values work in vanilla Haskell, so I recommend you ignore this footnote and pretend it doesn't exist yet.

notTuring complete. There are extensions in GHC to make it Turing complete. – Willem Van Onsem Jul 19 '17 at 23:53`Property "Colors" (1,"Red")`

, try`:t (1,3) :: ((,) Int) Integer`

at GHCi prompt. – Will Ness Nov 2 '17 at 11:24