First off, let me argue about style. You could have written your function CompStrings as this:

```
Fixpoint CompStrings' (sa : string) (sb : string) {struct sb}: bool :=
match sa, sb with
| EmptyString, EmptyString => true
| EmptyString, _
| _, EmptyString => false
| String a sa', String b sb'=> CompStrings sa' sb'
end.
```

I find it easier to read. Here is a proof it's the same as yours, in case you're suspicious:

```
Theorem CompStrings'ok: forall sa sb, CompStrings sa sb = CompStrings' sa sb.
Proof.
intros. destruct sa, sb; simpl; reflexivity.
Qed.
```

Now, this will be a two-fold answer. First I'm just going to hint you at the direction for the proof. Then, I'll give you a full proof that I encourage you not to read before you've tried it yourself.

First off, I assumed this definition of `length`

since you did not provide it:

```
Fixpoint length (s: string): nat :=
match s with
| EmptyString => O
| String _ rest => S (length rest)
end.
```

And since I did not have Eq_nat either, I proceeded to prove that the lengths are propositionally equal. It should be fairly trivial to adapt to Eq_nat.

```
Lemma Eq_length' : forall (s1 s2 : string),
CompStrings s1 s2 = true ->
length s1 = length s2.
Proof.
induction s1.
(* TODO *)
Admitted.
```

So here is the start! You want to prove a property about the inductive data type string. The thing is, you will want to proceed by case analysis, but if you just do it with `destruct`

s, it'll never end. This is why we proceed by `induction`

. That is, you will need to prove that `if s1 is the EmptyString, then the property holds`

, and that `if the property holds for a substring, then it holds for the string with one character added`

. The two cases are fairly simple, in each case you can proceed by case analysis on s2 (that is, using `destruct`

).

Note that I did not do `intros s1 s2 C.`

before doing `induction s1.`

. This is fairly important for one reason: if you do it (try!), your induction hypothesis will be too constrained as it will talk about one particular `s2`

, rather than being quantified by it. This can be tricky when you start doing proofs by induction. So, be sure to try to continue this proof:

```
Lemma Eq_length'_will_fail : forall (s1 s2 : string),
CompStrings s1 s2 = true ->
length s1 = length s2.
Proof.
intros s1 s2 C. induction s1.
(* TODO *)
Admitted.
```

eventually, you'll find that your induction hypothesis can't be applied to your goal, because it's speaking about a particular `s2`

.

I hope you've tried these two exercises.

Now if you're stuck, here is one way to prove the first goal.

Don't cheat! :)

```
Lemma Eq_length' : forall (s1 s2 : string),
CompStrings s1 s2 = true ->
length s1 = length s2.
Proof.
induction s1.
intros s2 C. destruct s2. reflexivity. inversion C.
intros s2 C. destruct s2. inversion C. simpl in *. f_equal.
exact (IHs1 _ C).
Qed.
```

To put that in intelligible terms:

Note that for that last step, there are many ways to proceed to prove `S (length rest1) = S (length rest2)`

. One of which is using `f_equal.`

which asks you to prove a pairwise equality between the parameters of the constructor. You could also use a `rewrite (IHs1 _ C).`

then use reflexivity on that goal.

Hopefully this will help you not only solve this particular goal, but get a first understanding at proofs by induction!

To close on this, here are two interesting links.

This presents the basics of induction (see paragraph "Induction on lists").

This explains, better than me, why and how to generalize your induction hypotheses. You'll learn how to solve the goal where I did `intros s1 s2 C.`

by putting back the `s2`

in the goal before starting the induction, using the tactic `generalize (dependent)`

.

In general, I'd recommend reading the whole book. It's slow-paced and very didactic.