I am trying to prove the following lemma.

```
Inductive bool : Type :=
| true
| false.
Lemma andb_true_iff : forall b1 b2 : bool,
b1 && b2 = true <-> b1 = true /\ b2 = true.
Proof.
intros.
split.
- intros. split.
+ destruct b1.
* reflexivity.
* discriminate.
+ destruct b2.
* reflexivity.
* simpl.
```

And now I get

```
1 goal
b1 : bool
H : b1 && false = true
______________________________________(1/1)
false = true
```

This is very absurd, since `false = true`

is never True. However, I can't discriminate this goal.

OK, maybe we should prove `H`

to be False, which is exact `false = true`

. We can't reject to prove a goal which we believe to be False. However, why can't I even rewrite this goal to `False`

? Is it because we have not proved it yet? So I prove the following

```
Lemma false_true: (false = true) -> False.
Proof.
intros.
simpl in H.
discriminate H.
Qed.
```

And seems the `Lemma false_true`

can't be applied to this goal. Instead, I know I can write the following lemma to perform a rewrite

```
Lemma false_true2: (false = true) = False.
Proof. Admitted.
```

However, I think `false_true`

and `false_true2`

are somehow very similar. Is there any way that instead of rewrite by `false_true2`

, we can just apply `false_true`

?

Or must I write the following to apply?

```
Lemma false_true3: False -> (false = true).
Proof.
intros.
destruct H.
Qed.
```

== NOTE ==

I have solved this problem by destructing `b1`

either. However, I want to know is there any way to resolve `false = true`

, since it looks weird to me.

`bool`

instead of requires and imports, on the other hand you don't define`andb`

nor any notation, so I'd guess you do are using the Stdlib... Then the point is, with the Stdlib there are lemmas available that would make the proof of the theorem above quite shorter. Or, are you interested in proving it from "first principles"?