The issue is quite simple in nature: the resulting type of `sToStat`

depends on the value of its first argument (`u : U`

in your code); when you later use `sToStat`

inside `check`

, you want the return type to depend on `someU`

- but `check`

promises that its return type depends on the implicit `u : U`

instead!

Now, let's imagine this does typecheck, I'll show you few issues that would arise.

What if `u1`

is `nothing`

? Well, in that case we would like to return `nothing`

as well. `nothing`

of what type? `Maybe (El u)`

you might say, but here's the thing - `u`

is marked as an implicit argument, which means the compiler will try to infer it for us from other context. But there's no other context that would pin down the value of `u`

!

Agda will most likely complain about unsolved metavariables whenever you try to use `check`

, which means you have to write the value of `u`

everywhere you use `check`

, thus defeating the point of marking `u`

implicit in the first place. In case you didn't know, Agda gives us a way to provide implicit arguments:

```
check {u = nat} {- ... -}
```

but I digress.

Another issue becomes apparent if you extend `U`

with more constructors:

```
data U : Set where
nat char : U
```

for example. We'll also have to account for this extra case in few other functions, but for the purpose of this example, let's just have:

```
El : U → Set
El nat = ℕ
El char = Char
```

Now, what is `check {u = char} (just nat)`

? `sToStat someU (nat 1)`

is `Maybe ℕ`

, but `El u`

is `Char`

!

And now for the possible solution. We need to make the result type of `check`

depend on `u1`

somehow. If we had some kind of `unJust`

function, we could write

```
check : (u1 : Maybe U) → Maybe (El (unJust u1))
```

You should see the problem with this code right away - nothing guarantees us that `u1`

is `just`

. Even though we are going to return `nothing`

, we must still provide a correct type!

First off, we need to pick some type for the `nothing`

case. Let's say I would like to extend `U`

later, so I need to pick something neutral. `Maybe ⊤`

sounds pretty reasonable (just a quick reminder, `⊤`

is what `()`

is in Haskell - the unit type).

How can we make `check`

return `Maybe ℕ`

in some cases and `Maybe ⊤`

in others? Ah, we could use a function!

```
Maybe-El : Maybe U → Set
Maybe-El nothing = Maybe ⊤
Maybe-El (just u) = Maybe (El u)
```

That's exactly what we needed! Now `check`

simply becomes:

```
check : (u : Maybe U) → Maybe-El u
check (just someU) = sToStat someU (nat 1)
check nothing = nothing
```

Also, this is the perfect opportunity to mention the *reduction behaviour* of these functions. `Maybe-El`

is very suboptimal in that regard, let's have a look at another implementation and do a bit of comparing.

```
Maybe-El₂ : Maybe U → Set
Maybe-El₂ = Maybe ∘ helper
where
helper : Maybe U → Set
helper nothing = ⊤
helper (just u) = El u
```

Or perhaps we could save us some typing and write:

```
Maybe-El₂ : Maybe U → Set
Maybe-El₂ = Maybe ∘ maybe El ⊤
```

Alright, the previous `Maybe-El`

and the new `Maybe-El₂`

are equivalent in the sense that they give same answers for same inputs. That is, `∀ x → Maybe-El x ≡ Maybe-El₂ x`

. But there's one huge difference. What can we tell about `Maybe-El x`

without looking at what `x`

is? That's right, we can't tell anything. Both function cases need to know something about `x`

before continuing.

But what about `Maybe-El₂`

? Let's try the same: we start with `Maybe-El₂ x`

, but this time, we can apply (the only) function case. Unrolling few definitions, we arrive at:

```
Maybe-El₂ x ⟶ (Maybe ∘ helper) x ⟶ Maybe (helper x)
```

And now we are stuck, because to reduce `helper x`

we need to know what `x`

is. But look, we got much, much farther than with `Maybe-El`

. Does it make a difference?

Consider this very silly function:

```
discard : {A : Set} → Maybe A → Maybe ⊤
discard _ = nothing
```

Naturally, we would expect the following function to typecheck.

```
discard₂ : Maybe U → Maybe ⊤
discard₂ = discard ∘ check
```

`check`

is producing `Maybe y`

for some `y`

, right? Ah, here comes the problem - we know that `check x : Maybe-El x`

, but we don't know anything about `x`

, so we can't assume `Maybe-El x`

reduces to `Maybe y`

either!

On the `Maybe-El₂`

side, the situation is completly different. We *know* that `Maybe-El₂ x`

reduces to `Maybe y`

, so the `discard₂`

now typechecks!