# How to proof by natural number case analysis in Coq?

I am stucked by a proof using coq. I have the following definitions:

``````Require Import List.
Require Import Nat.

Fixpoint Inb(x: nat) (A: list nat) :=
match A with
| nil => false
| h :: t => if h =? x then true else (Inb x t)
end.

Definition In (x: nat) (A: list nat) :=
Inb x A = true.
``````

Then I want to proof the theorem:

``````Theorem inside_thm: forall x, In x (3::4::nil) -> x = 3 \/ x = 4.
``````

However, I got stucked and no idea of how can I proof it.

Could you please give me a guide and write an example to solve it?

For instance, you may start with a few helpful lemmas about `In`.

``````Lemma In1 x y l : In x (y::l) <-> y = x \/ In x l.
Proof.
unfold In;  simpl; rewrite <- PeanoNat.Nat.eqb_eq.
case (y =? x).
- split;  auto.
- split.
+ auto.
+ destruct 1; [discriminate | auto].
Qed.

Lemma In2 x : ~ In x nil.
Proof.
discriminate.
Qed.
``````

Then your lemma can be easily proved.

``````Theorem inside_thm: forall x, In x (3::4::nil) -> x = 3 \/ x = 4.
Proof.
intros x H; rewrite In1 in H.
(* ... *)
``````

Another, very specific, approach to proving this particular theorem could be to:

1. first, assume that `x = 3` and then show, in that case, that the statement is trivially true, after rewriting everywhere `x` by 3;
2. now, under the hypothesis that `x` is not equalt to 3, do the same, assuming now that `x = 4`;
3. finally, show that, if `x` is neither 3 nor 4, the statement remains valid, since, by expanding the definitions of `In` and `Inb`, you can show that all the tests in the Coq-generated `if` statement are false (Coq is able to unroll all the calls to `Inb`, since the list argument is a constant in your case), yielding `false = true` as an hypothesis in the goal, which makes it trivially true.

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.
``````