# Proof on less than and less or equal on nat

Assuming the following definitions (the first two are taken from http://www.cis.upenn.edu/~bcpierce/sf/Basics.html):

``````Fixpoint beq_nat (n m : nat) : bool :=
match n with
| O => match m with
| O => true
| S m' => false
end
| S n' => match m with
| O => false
| S m' => beq_nat n' m'
end
end.

Fixpoint ble_nat (n m : nat) : bool :=
match n with
| O => true
| S n' =>
match m with
| O => false
| S m' => ble_nat n' m'
end
end.

Definition blt_nat (n m : nat) : bool :=
if andb (ble_nat n m) (negb (beq_nat n m)) then true else false.
``````

I would like to prove the following:

``````Lemma blt_nat_flip0 : forall (x y : nat),
blt_nat x y = false -> ble_nat y x = true.

Lemma blt_nat_flip : forall (x y : nat),
blt_nat x y = false -> beq_nat x y = false -> blt_nat y x = true.
``````

The furthest I was able to get to is to prove `blt_nat_flip` assuming `blt_nat_flip0`. I spent a lot of time and I am almost there but overall it seems more complex than it should be. Anybody has a better idea on how to prove the two lemmas?

Here is my attempt so far:

``````Lemma beq_nat_symmetric : forall (x y : nat),
beq_nat x y = beq_nat y x.
Proof.
intros x. induction x.
intros y. simpl. destruct y.
reflexivity. reflexivity.
intros y. simpl. destruct y.
reflexivity.
simpl. apply IHx.
Qed.

Lemma and_negb_false : forall (b1 b2 : bool),
b2 = false -> andb b1 (negb b2) = b1.
Proof.
intros. rewrite -> H. unfold negb. destruct b1.
simpl. reflexivity.
simpl. reflexivity.
Qed.

Lemma blt_nat_flip0 : forall (x y : nat),
blt_nat x y = false -> ble_nat y x = true.
Proof.
intros x.
induction x.
intros. destruct y.
simpl. reflexivity.
simpl. inversion H.
intros. destruct y. simpl. reflexivity.
simpl. rewrite -> IHx. reflexivity.
(* I am giving up for now at this point ... *)

Lemma blt_nat_flip : forall (x y : nat),
blt_nat x y = false -> beq_nat x y = false ->
blt_nat y x = true.
Proof.
intros.
unfold blt_nat.
rewrite -> beq_nat_symmetric. rewrite -> H0.
rewrite -> and_negb_false.
replace (ble_nat y x) with true.
reflexivity.
rewrite -> blt_nat_flip0. reflexivity. apply H. reflexivity.
Qed.
``````
-
coq seems to have trouble doing an `inversion` on `H` in the last case of your induction, but if you `unfold blt_nat` before, it seems to work as intended.