You have to think about how natural numbers and booleans work in Coq. The whole difficulty with boolean conditionals is that you have to establish **constructively** whether or not the conditional holds in order to determine the value of the expression. Likewise, a hallmark of the inductive **construction** of natural numbers is that you can determine (constructively) whether or not a natural number is 0, whether it is 1, whether it is 2, whether it is 3, etc., and you have to use such a chain of reasoning in order to unwind the boolean expression `In x (3::4::nil)`

into an outcome like `x = 3 ∨ x = 4`

.

With all that said, your proof can be done very simply by repeatedly testing whether `x`

is 0, 1, 2, 3, ... until the proof finishes. One convenient idiom for doing so is

```
Theorem inside_thm: forall x, In x (3::4::nil) -> x = 3 \/ x = 4.
Proof. intros; repeat (destruct x; try intuition discriminate). Qed.
```

By contrast, if you're using the built-in `List.In`

which is defined with propositional expressions, then the corresponding theorem is trivial enough for Coq to figure out by itself:

```
Theorem inside_thm2 : forall x, List.In x (3::4::nil) -> x = 3 \/ x = 4.
Proof. firstorder. Qed.
```