This lemma is in the standard library:

```
Require Import Arith.
Lemma not_lt_refl : forall n:nat, ~n<n.
Print Hint.
```

Amongst the results is `lt_irrefl`

. A more direct way of realizing that is

```
info auto with arith.
```

which proves the goal and shows how:

```
intro n; simple apply lt_irrefl.
```

Since you know where to find a proof, I'll just give a hint on how to do it from first principles (which I suppose is the point of your homework).

First, you need to prove a negation. This pretty much means you push `n<n`

as a hypothesis and prove that you can deduce a contradiction. Then, to reason on `n<n`

, expand it to its definition.

```
intros h H.
red in H. (* or `unfold lt in H` *)
```

Now you need to prove that `S n <= n`

cannot happen. To do this from first principles, you have two choices at that point: you can try to induct on `n`

, or you can try to induct on `<=`

. The `<=`

predicate is defined by induction, and often in these cases you need to induct on it — that is, to reason by induction on the proof of your hypothesis. Here, though, you'll ultimately need to reason on `n`

, to show that `n`

cannot be an m^{th} successor of `S n`

, and you can start inducting on `n`

straight away.

After `induction n`

, you need to prove the base case: you have the hypothesis `1 <= 0`

, and you need to prove that this is impossible (the goal is `False`

). Usually, to break down an inductive hypothesis into cases, you use the `induction`

tactic or one of its variants. This tactic constructs a fairly complex dependent case analysis on the hypothesis. One way to see what's going on is to call `simple inversion`

, which leaves you with two subgoals: either the proof of the hypothesis `1 <= 0`

uses the `le_n`

constructor, which requires that `1 = 0`

, or that proof uses the `le_S`

constructor, which requires that `S m = 0`

. In both cases, the requirement is clearly contradictory with the definition of `S`

, so the tactic `discriminate`

proves the subgoal. Instead of `simple inversion H`

, you can use `inversion H`

, which in this particular case directly proves the goal (the impossible hypothesis case is very common, and it's baked into the full-fledged `inversion`

tactic).

Now, we turn to the induction case, where we quickly come to the point where we would like to prove `S n <= n`

from `S (S n) <= S n`

. I recommend that you state this as a separate lemma (to be proved first), which can be generalized: `forall n m, S n <= S m -> n <= m`

.