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][1] 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).

`b`

and then use`simpl`

and`reflexivity`

? like, hypothesize`b=true`

then prove it, then hypothesize`b=false`

and prove it.