# Proving f (f bool) = bool

How can I in coq, prove that a function `f` that accepts a bool `true|false` and returns a bool `true|false` (shown below), when applied twice to a single bool `true|false` would always return that same value `true|false`:

``````(f:bool -> bool)
``````

For example the function `f` can only do 4 things, lets call the input of the function `b`:

• Always return `true`
• Always return `false`
• Return `b` (i.e. returns true if b is true vice versa)
• Return `not b` (i.e. returns false if b is true and vice vera)

So if the function always returns true:

``````f (f bool) = f true = true
``````

and if the function always return false we would get:

``````f (f bool) = f false = false
``````

For the other cases lets assum the function returns `not b`

``````f (f true) = f false = true
f (f false) = f true = false
``````

In both possible input cases, we we always end up with with the original input. The same holds if we assume the function returns `b`.

So how would you prove this in coq?

``````Goal forall (f:bool -> bool) (b:bool), f (f b) = f b.
``````
-
I have realised that f (f b:bool) = b cannot be proved, as if f always returned true f (f false) == f true == true != false. – Marcus Whybrow Nov 4 '09 at 15:20
However, f (f (f b)) = f (b). Perhaps this is closer to your desired question? I don't know how to prove this in Coq though! – Rob Golding Nov 4 '09 at 15:21

``````Goal forall (f:bool -> bool) (b:bool), f (f (f b)) = f b.
Proof.
intros.
remember (f true) as ft.
remember (f false) as ff.
destruct ff ; destruct ft ; destruct b ;
try rewrite <- Heqft ; try rewrite <- Heqff ;
try rewrite <- Heqft ; try rewrite <- Heqff ; auto.
Qed.
``````
-
What language is that written in? Maths? – Ethan Heilman Jan 5 '10 at 23:05
It's Coq. It's not too readable, I guess. – mattiast Jan 7 '10 at 20:54

``````Require Import Sumbool.

Goal forall (f : bool -> bool) (b:bool), f (f (f b)) = f b.
Proof.
destruct b;                             (* case analysis on [b] *)
destruct (sumbool_of_bool (f true));  (* case analysis on [f true] *)
destruct (sumbool_of_bool (f false)); (* case analysis on [f false] *)
congruence.                           (* equational reasoning *)
Qed.
``````
-

In SSReflect:

``````Require Import ssreflect.

Goal forall (f:bool -> bool) (b:bool), f (f (f b)) = f b.
Proof.
move=> f.
by case et:(f true); case ef:(f false); case; rewrite ?et ?ef // !et ?ef.
Qed.
``````
-

Thanks for wonderful assignment! Such a lovely theorem!

This is the proof using C-zar declarative proof style for Coq. It is a much longer than imperative ones (altrough it might be such because of my too low skill).

```Theorem bool_cases : forall a, a = true \/ a = false.
proof.
let a:bool.
per cases on a.
suppose it is false.
thus thesis.
suppose it is true.
thus thesis.
end cases.
end proof. Qed.

Goal forall (b:bool), f (f (f b)) = f b.
proof.
let b:bool.
per cases on b.

suppose it is false.
per cases of (f false = false \/ f false = true) by bool_cases.
suppose (f false = false).
hence (f (f (f false)) = f false).
suppose H:(f false = true).
per cases of (f true = false \/ f true = true) by bool_cases.
suppose (f true = false).
hence (f (f (f false)) = f false) by H.
suppose (f true = true).
hence (f (f (f false)) = f false) by H.
end cases.
end cases.

suppose it is true.
per cases of (f true = false \/ f true = true) by bool_cases.
suppose H:(f true = false).
per cases of (f false = false \/ f false = true) by bool_cases.
suppose (f false = false).
hence (f (f (f true)) = f true) by H.
suppose (f false = true).
hence (f (f (f true)) = f true) by H.
end cases.
suppose (f true = true).
hence (f (f (f true)) = f true).
end cases.

end cases.
end proof. Qed.
```
-