# Loop while proving a theorem

I am trying to prove the following theorem after formalizing lambda calculus with Debruijn indices and substitution in Coq.

``````Theorem atom_equality : forall e : expression , forall x : nat,
(beta_reduction (Var x) e) -> (e = Var x).
``````

and these are the definitions for expression and beta reduction

``````
Inductive expression : Type :=
| Var (n : nat)
| Abstraction (e : expression)
| Application (e1 : expression) (e2 : expression).
.
.

Inductive beta_reduction : expression -> expression -> Prop :=
| beta_1step (x y : expression) : beta_1reduction x y -> beta_reduction x y
| beta_reflexivity (x : expression) :  beta_reduction x x
| beta_transitivity (x y z : expression) : beta_reduction x y -> beta_reduction y z -> beta_reduction x z.

``````

I am stuck in a loop while trying to prove this theorem.

``````Proof.
intro e. induction e.
- intros. inversion H.
``````

After applying these steps, these are the hypothesis and subgoals I've to work with

``````3 subgoals
n, x : nat
H : beta_reduction (Var x) (Var n)
x0, y : expression
H0 : beta_1reduction (Var x) (Var n)
H1 : x0 = Var x
H2 : y = Var n
______________________________________(1/3)
Var n = Var x
______________________________________(2/3)
Var n = Var n
______________________________________(3/3)
Var n = Var x
``````

I can solve the first subgoal by "inversion H0" tactic and second subgoal by "reflexivity". However when I reach the third subgoal, this is what I am left with

``````1 subgoal
n, x : nat
H : beta_reduction (Var x) (Var n)
x0, y, z : expression
H0 : beta_reduction (Var x) y
H1 : beta_reduction y (Var n)
H2 : x0 = Var x
H3 : z = Var n
______________________________________(1/1)
Var n = Var x
``````

This is exactly what I started with. I will have to prove that y can only take the value of Var x for H0 to be provable.

(beta_1reduction is the one step beta reduction of lambda calculus, and beta_reduction is its reflexive, transitive closure)

You are stuck because inversion on `H` is not enough. Instead, you would need a kind of induction on `H` to provide you with the needed hypothesis in the transitive case, to allow you to conclude. However, since `H`'s type is an inductive predicate, induction on it is tricky. Indeed, if you use the usual `induction H.`, Coq will lose all informations about the indices in `H`'s type, and especially the `Var x` one. This will make your proof attempts fail.

Instead, what you can use is rely on the `dependent induction` tactic (you will need to `Require Import Program.Equality` to have access to this tactic). This tactic automatically handles the kind of induction on inductive predicates where the indices are not variables. Here you could start your proof with `intros e n H. dependent induction H.` and the rest should be easy.

In general, when you define inductive predicates (such as `beta_reduction`) over inductive datatypes (such as `expression`), and you want to use hypothesis using those inductive predicates (here `H`), doing induction directly on the predicate (using `dependent induction`) as we did here is very powerful. In particular, it specializes which constructors of your datatype can appear in the inductive hypothesis, thus in a way performs a kind of induction on the datatype at the same time.

@Meven's answer is a good explanation of what is wrong and gives a good solution. If you want to do it without the `dependent induction` tactic, you can `remember` the lost information yourself.

``````Proof.
(beta_reduction (Var x) e) -> (e = Var x).
intros e x H.
remember (Var x) as q eqn:Hq.
induction H; rewrite Hq in *.
- inversion H.
- reflexivity.
- rewrite IHbeta_reduction1 in IHbeta_reduction2.
apply IHbeta_reduction2.
reflexivity.
reflexivity.
Qed.
``````
• Indeed, and this is pretty much the magic that `dependent induction` automates behind the scene. – Meven Lennon-Bertrand Apr 2 at 16:59