One way to do it that is simpler than your try is:

```
Definition get_first (l : list nat) (good : Good l) : nat :=
match good with
| GoodNonEmpty h _ => h
end.
```

Here is a way to do it in the way you wanted to do it. You'll notice it is very verbose to prove that "Good nil" does not exist, inlined.

```
Definition get_first (l : list nat) (good : Good l) : nat :=
(
match l as l' return (Good l' -> nat) with
| nil =>
fun (goodnil : Good nil) =>
(
match goodnil in (Good l'') return (nil = l'' -> nat) with
| GoodNonEmpty h t =>
fun H => False_rect _ (nil_cons H)
end
)
(@eq_refl _ nil)
| h :: _ => fun _ => h
end
) good.
```

You can surely define some of that outside and reuse it. I am not aware of the best practices though. Maybe someone can come with a shorter way to do the same thing.

EDIT:

By the way, you can get to pretty much the same result, in a much easier way, in proof mode:

```
Definition get_first' (l : list nat) (good : Good l) : nat.
Proof.
destruct l. inversion good. exact n.
Defined.
```

You can then:

```
Print get_first'.
```

To see how Coq defines it. However, for more involved things, you might be better off following what gdsfhl from the #coq IRC channel proposed as a solution:

http://paste.in.ua/4782/

You can see that he uses the `refine`

tactic to provide part of the skeleton of the term to write, and defer the missing proofs.