As chi remarked: it's not quite accurate to say your type family is *empty*, rather it merely happens to not contain any yet-known instances.

But I think that's missing the point of the question, so let's discuss instead the type family

```
type family EmptyTypeFamily t where {}
```

This one really is empty: you *can't* write any instances for it.

Still, this causes exactly the same behaviour as you observed. Why?

Well, what GHC does with types during compilation is in some ways similar to how we're dealing with values in all Haskell programs: lazy evaluation and pattern matching. It's well known how the program

```
f :: Int -> Int
f _ = 624
main :: IO ()
main = print $ f undefined
```

runs without problems, even though it “evaluates” `undefined`

as the argument to `f`

. It's ok because `f`

doesn't actually need to know anything about its argument.

Similarly, if you write `return untypedValue`

, then the type checker doesn't need to know anything about `EmptyTypeFamily ()`

– it just treats it as an abstract entity. It can even unify different type variables to `EmptyTypeFamily ()`

. This only requires the assumption that, whatever `EmptyTypeFamily`

is under the hood, it must certainly be deterministic. That much is guaranteed, because the compiler *would* complain if you wrote two conflicting instances for it.

So, as long as you only use `untypedValue`

with unconstraint-polymorphic functions, it simply doesn't matter that its type doesn't actually exist, because it never needs to be evaluated any further.

In other words, `NotAType`

is purely *symbolic*. It's a bit like in maths, you can write a theorem starting with “let *S* be a set and *x* ∈ *S*, then *bla bla*” without actually pinning down what this set is or a value for *x*.

That changes only as you require additional constraints, like unifying it with a concrete type

```
f :: Int -> Int
f x = x + 1
main = print $ f untypedValue
```

• Couldn't match type ‘EmptyTypeFamily ()’ with ‘Int’
Expected type: Int
Actual type: NotAType
• In the first argument of ‘f’, namely ‘untypedValue’

...or, as you observed, use typeclass methods on it. In each case, the compiler has to start with performing an actual *pattern match* on the type-level value `EmptyTypeFamily ()`

. Well, in fact it's a more general process: what the compiler keeps track of are rather *propositions*. It has a database of knowledge that such and such types are equal, and such and such types match such and such class, and in this case GHC just determines that it doesn't have information which would allow deciding on any known `Show`

instance.

Note that it is actually possible to have a hypothetical context in which that information is available, however nonsensical that is:

```
{-# LANGUAGE RankNTypes, FlexibleContexts #-}
hypothetically :: (Show NotAType => r) -> ()
hypothetically _ = ()
main = return $ hypothetically (print untypedValue)
```

In this case, responsibility for proving `Show NotAType`

is deferred to the implementation of `hypothetically`

. As the compiler tackles `print untypedValue`

it just browses through the context and sees that `Show NotAType`

will be proved by whatever code eventually uses the argument to `hypothetically`

. ...Which of course never happens, but the compiler doesn't worry about that when typechecking `main`

.

This, in the maths analogy, is like writing a proof starting with “let *x* ∈ ℝ such that *x*^{2} = -1...” – this is perfectly valid and allows you to prove exciting things. Only, nobody will be able to *use* the theorem for computing something, because there exists no real number with the required property.

`NotAType`

has no values,`F NotAType`

might have values, especially if`F`

is a GADT. It does not seem that useful to use stuck families in that way, though.`NotAType`

as a valid type. The answers explain why, but I'm still finding the concept confusing.