There is a very similar function in the `List`

theory in the standard library. That function takes a predicate as an argument, i.e. a function `f`

from the element type to `bool`

, and it returns `Some x`

if a matching element `x`

is found, or `None`

if none is found.

```
Variable A : Type.
Fixpoint find (f:A->bool) (l:list A) : option A :=
match l with
| nil => None
| x :: tl => if f x then Some x else find tl
end.
```

You're looking for an element that's equal to a particular object `a`

. That means your predicate is `eq_Interface a`

, where `eq_Interface`

is the equality you want over the `Interface`

.

It's up to you to define an equality function on your type, because there can be many definitions of equality. Coq defines `=`

, which is Leibniz equality: two values are equal iff there is no way to distinguish between them. `=`

is a proposition, not a boolean, because this property is not decidable in general. It's also not always the desirable equality on a type, sometimes you want a coarser equivalence relation, so that two objects can be considered equal if they were constructed in different ways but nonetheless have the same meaning.

If `Interface`

is a simple datatype — intuitively, a data structure with no embedded proposition — there's a built-in tactic to build a structural equality function from the type definition. Look up `decide equality`

in the reference manual.

```
Definition Interface_dec : forall x y : Interface, {x=y} + {x <> y}.
Proof. decide equality. Defined.
Definition Interface_eq x y := if Interface_dec x y then true else false.
```

`Interface_dec`

not only tells you whether its arguments are equal, but also comes with a proof that the arguments are equal or that they're different.

Once you have that equality function, you can define your `find`

function in terms of the standard library function:

```
Definition Interface_is_in x := if List.find (Interface_eq x) then true else false.
```