# How would I prove that b = c if (andb b c = orb b c) in coq?

I'm new to coq and I'm trying to prove this...

``````Theorem andb_eq_orb :
forall (b c : bool),
(andb b c = orb b c) -> (b = c).
``````

Here is my proof, but I get stuck when I get to the goal (false = true -> false = true).

``````Proof.
intros b c.
induction c.
destruct b.
reflexivity.
simpl.
reflexivity.
``````

I'm not sure how I would rewrite that expression so I can use reflexivity. But even if I do that, I'm not sure it will lead to the proof.

I was able to solve the prove if I started with the hypothesis b = c though. Namely...

``````Theorem andb_eq_orb_rev :
forall (b c : bool),
(b = c) -> (andb b c = orb b c).
Proof.
intros.
simpl.
rewrite H.
destruct c.
reflexivity.
reflexivity.
Qed.
``````

But I can't figure out how to solve if I start with the hypothesis that has boolean functions.

• man its been an extremely long period of time since i did this, but can't you just make it case out on `b` and then use `simpl` and `reflexivity` ? like, hypothesize `b=true` then prove it, then hypothesize `b=false` and prove it. Aug 30, 2015 at 0:44

You don't need induction, since `bool` is not a recursive data structure. Just go through the different cases for the values of `b` and `c`. Use `destruct` to do that. In two cases the hypothesis `H` will be of the type `true = false`, and you can finish the proof with `inversion H`. In the other two cases, the goal will be of the type `true = true` and it can be solved with `reflexivity`.

``````Theorem andb_eq_orb : forall b c, andb b c = orb b c -> b = c.
Proof. destruct b,c;  intro H; inversion H; reflexivity. Qed.
``````

You'll want to use the `intro` tactic. This will move `false = true` into your proof context as an assumption which you can then use to rewrite.

• Thank you, that helped. And from there I rewrote with the assumption. `rewrite H. reflexivity.` Aug 30, 2015 at 2:28

This might not be the most efficient way to do it.

At the step `induction c.` (where it's stuck):

``````______________________________________(1/2)
b && true = b || true -> b = true
______________________________________(2/2)
b && false = b || false -> b = false
``````

You can use `rewrite` and basic theorems in [bool] to simplify terms such as `b && true` to `b`, and `b || true` to `true`.

This can reduce it to two "trivial" sub goals:

``````b : bool
______________________________________(1/2)
b = true -> b = true
______________________________________(2/2)
false = b -> b = false
``````

This is almost trivial proof using `assumption`, except it is one `symmetry` away. You can `try` if `symmetry` will make them match using:

``````try (symmetry;assumption); try assumption.
``````

(Someone who really knows Coq may enlighten me how to `try` this more succinctly)

Putting it together:

``````Require Import Bool.
Theorem andb_eq_orb : forall b c, andb b c = orb b c -> b = c.
Proof.
destruct c;

try (rewrite andb_true_r);
try (rewrite orb_true_r);
try (rewrite andb_false_r);
try (rewrite orb_false_r);
intro H;
try (symmetry;assumption); try assumption.
Qed.
``````

A second approach is to brute-force it and using the "Truth table" method. This means you can break down all variables to their truth values, and simplify: `destruct b, c; simpl.`. This again gives four trivial implications, up to one `symmetry` to `try`:

``````4 subgoal
______________________________________(1/4)
true = true -> true = true
______________________________________(2/4)
false = true -> true = false
______________________________________(3/4)
false = true -> false = true
______________________________________(4/4)
false = false -> false = false
``````

Putting it together:

``````Theorem andb_eq_orb1 : forall b c, andb b c = orb b c -> b = c.
Proof.
destruct b, c; simpl; intro; try (symmetry;assumption); try assumption.
Qed.
``````

The first approach is more troublesome but it does not involve enumerating all truth table rows (I think).

• That's for the help I wasn't aware that I could import and use the theorems from the libraries. Aug 30, 2015 at 2:18
• One question though, if I wasn't to use auto after induction b, how would I resolve the false = true -> false = true? Since I'm a beginner I want to make sure I understand all the steps that auto is doing. Also `induction b. auto`. functions differently than `induction b; auto`. What does the semicolon do? Aug 30, 2015 at 2:21
• Oh, I think I got it. It was `intro. rewrite H. reflexivity.` Aug 30, 2015 at 2:25
• Just for the record, the bool type is not recursive (only 2 basic constructor, `true` and `false`), so you only need to `destruct b`, using `induction` won't give you more information.
– Vinz
Aug 31, 2015 at 7:14