I'm trying to define a function on a weakly-specified type in Coq. Specifically, I have a type that is defined inductively by a set of recursive constructors, and I want to define a function that is only defined when the argument has been constructed using a subset of these.

To be more concrete, I have the following type definition:

```
Inductive Example : Set :=
| Example_cons0 : nat -> Example
| Example_cons1 : Example -> Example
.
```

Now, I have a function that only applies to the ground case. (The following definition will not work obviously, but is meant to suggest my intent.)

```
Definition example (x:Example) : nat :=
match x with
| Example_cons0 n => n
end.
```

Ideally, I'd like to communicate that my argument, x, has been constructed using a subset of the general type constructors, in this case, Example_cons0. I thought that I could do this by defining a predicate that states this fact and passing a proof of the predicate as an argument. For example:

```
Definition example_pred (x:Example) : Prop :=
match x with
| Example_cons0 _ => True
| _ => False
end.
```

And then (following the recommendation given by Robin Green) something like,

```
Definition example2 (x:Example) : example_pred x -> nat :=
(use proof to define example2?)
```

Unfortunately, I'm not sure how I would go about doing any of this. I'm not even sure that this is the correct way to define restricted functions on weakly-specified types.

Any guidance, hints, or suggestions would be strongly appreciated! - Lee

Update:

Following recommendations by jozefg, the example function can be defined as:

```
Definition example (x:Example) : example_pred x -> nat :=
match x with
| Example_cons0 n => fun _ => n
| _ => fun proof => match proof with end
end.
```

See his comments for details. This function can be evaluated using the following syntax, which also demonstrates how proof terms are represented in Coq:

```
Coq < Eval compute in Example.example (Example.Example_cons0 0) (I : Example.example_pred (Example.Example_cons0 0)).
= 0
: nat
```