The arguments you provided aren't the ones `app_removelast_last`

expects. You can find this with `About`

:

```
About app_removelast_last.
(*
app_removelast_last :
forall [A : Type] [l : list A] (d : A),
l <> [] -> l = removelast l ++ [last l d]
app_removelast_last is not universe polymorphic
Arguments app_removelast_last [A]%type_scope [l]%list_scope d _
*)
```

Arguments that appear inside square brackets (or curly braces, although here there are none) are implicit. This means that Coq can infer them from the explicit arguments. So even though `app_removelast_last`

needs four arguments to reach the equality (namely, `A`

, `l`

, `d`

, and a proof of `l <> []`

), it only expects two of them (`d`

and a proof of `l <> []`

), because `A`

and `l`

can be inferred from those. Or in other words, once you provide `d`

and a proof of `l <> []`

, there is only one possible choice for `A`

and `l`

.

Note that `d`

is supposed to be a default value fed to `last`

in case the list is empty. Here we know that the list is non-empty, so it is completely irrelevant which default value we pick, but we still must pick one. When you write `app_removelast_last xp Hnilcons`

, you're saying that you want `xp`

to be the default value (remember, `l`

is implicit!). Then Coq infers that, since your default value has type `list nat`

, the relevant `l`

must have type `list (list nat)`

, which is why you get that error message in particular.

The solution is to rewrite with, for example, `app_removelast_last 0 Hnilcons`

, since `0`

is an adequate default value.

Edit: You may also avoid implicit arguments with `@`

as follows:

```
@app_removelast_last nat xp 0 Hnilcons
```

However, according to your comment you are not using the stdlib's version of this lemma, but `Constant AlphaCode1_forward_c.app_removelast_last`

, which apparently is specific to lists of natural numbers and has no implicit arguments, so this is probably not what's causing the issue.