# Coq: Simpl in match pattern when having an inequality hypothesis

I have a definition involving match, similar like this:

``````Definition five (n: nat): bool :=
match n with
| 5 => true
| _ => false
end.
``````

I try to proof something similar like this:

``````Theorem fiveT: forall (n: nat),
n <> 5 -> five n = false.
Proof. intros. unfold five.
``````

But when I unfold the definition of `five`, I don't know how to tell coq that the first match case is irrelevant because of `H`. How can I proof this?

``````1 goal
n : nat
H : n <> 5
______________________________________(1/1)
match n with
| 5 => true
| _ => false
end = false
``````

Please note that my real problem is much bigger than this one but I wanted to give a small understandable example, so please don't tell me a complete different approach from mine, thank you :)

• You need to destruct [n] in order to simplify the pattern matching. You can do it with `repeat (destruct n; auto)` and then `destruct H; reflexivity` to exploit the assumption `5<>5`.
– pjm
Jul 29 at 9:09

You can use the contrapositive of your lemma, and then a (not elegant) case analysis to get rid of all the cases different from 5, for which evaluation works trivially (I'm using ssreflect here, but you should get the idea):

``````From mathcomp Require Import all_ssreflect.

Set Implicit Arguments.
Unset Strict Implicit.
Unset Printing Implicit Defensive.

Definition five (n: nat): bool :=
match n with
| 5 => true
| _ => false
end.

Theorem fiveT: forall (n: nat), n <> 5 -> five n = false.
Proof.
move=> n.
apply: contra_notF.
have [/eqP -> //|ne0] := boolP (n == 0).
have [/eqP -> //|ne1] := boolP (n == 1).
have [/eqP -> //|ne2] := boolP (n == 2).
have [/eqP -> //|ne3] := boolP (n == 3).
have [/eqP -> //|ne4] := boolP (n == 4).
have [/eqP -> //|ne5] := boolP (n == 5).
have [n' -> //=]: exists n', n = S (S (S (S (S (S n'))))).
exists (n - 6).
have lt0n: 0 < n by rewrite lt0n.
have lt1n: 1 < n by rewrite ltn_neqAle lt0n eq_sym ne1.
have lt2n: 2 < n by rewrite ltn_neqAle lt1n eq_sym ne2.
have lt3n: 3 < n by rewrite ltn_neqAle lt2n eq_sym ne3.
have lt4n: 4 < n by rewrite ltn_neqAle lt3n eq_sym ne4.
have lt5n: 5 < n by rewrite ltn_neqAle lt4n eq_sym ne5.
by rewrite !subnSK ?subn0.
Qed.
``````

There got to be a cleaner way to do this, though ;)