# Coq: Prove Inductive relation (vs Fixpoint)

Is it possible to "convert" a `Fixpoint` definition for the `count` function:

``````Fixpoint count (z: Z) (l: list Z) {struct l} : nat :=
match l with
| nil => 0%nat
| (z' :: l') => if (Z.eq_dec z z')
then S (count z l')
else count z l'
end.
``````

To an `Inductive` predicate (I have my first attempt bellow, but I'm not sure if it is correct)? (This predicate is supposed to describe the relation between the function's input and output)

``````Inductive Count : nat -> list Z -> Z -> Prop :=
| CountNil : forall (z: Z), Count 0 nil z
| CountCons: forall (n: nat) (l0: list Z) (z: Z), Count n l0 z -> Count (S n) (cons z l0) z.
``````

To find out if it's correct, I defined this Theorem (weak specification):

``````Theorem count_correct : forall (n: nat) (z: Z) (l: list Z), Count (count z l) l z.
Proof.
intros.
destruct l.
- constructor.
- ...
``````

But I don't know how to complete it... Anyone can help?

## 1 Answer

Your relation is incorrect because it is missing the case for when the head of your list is not the `Z` you're looking for. E.g. there is no term of type `Count 0  1` even though `count 1  = 0`. Add that, and while you're at it make the type more natural (order the arguments in the same way and also make `z` a parameter).

``````Inductive Count (z : Z) : list Z -> nat -> Prop :=
| CountNil : Count z nil 0
| CountYes : forall l n, Count z l n -> Count z (z :: l) (S n)
| CountNo  : forall z' l n, z <> z' -> Count z l n -> Count z (z' :: l) n.
``````

As for the correctness theorem, well, `count` is inductive on `l`, so probably so should be any theorem about it.

``````Theorem count_correct (z : Z) (n : N) (l : list Z) : Count z l (count z l).
Proof.
intros.
induction l as [ | z' l rec].
- constructor.
- cbn [count].
destruct (Z.eq_dec z z') as [<- | no]; constructor; assumption.
Qed.
``````

Do note that there's an automated mechanism to define `Count` and `count_correct` from `count`:

``````Require Import FunInd.

Function count (z : Z) (l : list Z) {struct l} : nat :=
match l with
| nil => 0
| z' :: l =>
if Z.eq_dec z z'
then S (count z l)
else count z l
end.

Print R_count. (* Like Count *)
(* Inductive R_count (z : Z) : list Z -> nat -> Set :=
R_count_0 : forall l : list Z, l = nil -> R_count z nil 0
| R_count_1 : forall (l : list Z) (z' : Z) (l' : list Z),
l = z' :: l' ->
forall _x : z = z',
Z.eq_dec z z' = left _x ->
forall _res : nat,
R_count z l' _res -> R_count z (z' :: l') (S _res)
| R_count_2 : forall (l : list Z) (z' : Z) (l' : list Z),
l = z' :: l' ->
forall _x : z <> z',
Z.eq_dec z z' = right _x ->
forall _res : nat,
R_count z l' _res -> R_count z (z' :: l') _res. *)
Check R_count_correct. (* : forall z l _res, _res = count z l -> R_count z l _res *)
Check R_count_complete. (* : forall z l _res, R_count z l _res -> _res = count z l *)
``````
• Thank you so much for your explanation! But, since I'm kinda new to Coq, there something I don't understand - I know the syntax, but in `destruct (Z.eq_dec z z') as [<- | no]` that does `[<- | no]`mean? Is there any other way to write that? – Cris Teller May 24 at 16:22
• `destruct (Z.eq_dec z z') as [<- | no]; constructor; assumption.` = `destruct (Z.eq_dec z z') as [yes | no]. + rewrite <- yes. constructor. assumption. + constructor. * assumption. * assumption.` Putting `<-` or `->` instead of a variable name in an `intro`-pattern rewrites according to that variable in that direction and then deletes the variable all at once. Please see the manual. – HTNW May 24 at 17:27
• Thank you! I know what rewrite is but I haven't found anything on `yes` and `no`. Do they mean `yes` if `z==z'` and `no` otherwise? – Cris Teller May 24 at 17:35
• They are just variable names. I named them `yes` and `no` because they are the possible results of `dec`iding `eq`uality. You could rewrite `destruct (Z.eq_dec z z') as [yes | no].` as `refine (match Z.eq_dec z z' with left yes => _ | right no => _ end).` – HTNW May 24 at 18:07
• Yes, it's always better to name the variables, thank you for your explanation! – Cris Teller May 24 at 19:39