# Using forall within recursive Function definition

I'm trying to use Function to define a recursive definition using a measure, and I'm getting the error:

``````Error: find_call_occs : Prod
``````

I'm posting the whole source code at the bottom, but my function is

``````Function kripke_sat (M : kripke) (s : U) (p : formula) {measure size p}: Prop :=
match p with
| Proposition p'  => L M (s)(p')
| Not p' => ~ kripke_sat M s p'
| And p' p''   => kripke_sat M s p' /\ kripke_sat M s p''
| Or p' p''  => kripke_sat M s p' \/ kripke_sat M s p''
| Implies p' p''  => ~kripke_sat M s p' \/  kripke_sat M s p''
| Knows a p' =>  forall t, ~(K M a) s t \/ kripke_sat M t p'
| EvKnows p' => forall i, kripke_sat M s (Knows i p' )
end.
``````

I know the problem is due to the foralls: if I replace them with True, it works. I also know I get the same error if my right-hand-side uses implications (->). Fixpoint works with foralls, but doesn't allow me to define a measure.

As promised, my complete code is:

``````Module Belief.

Require Import Arith.EqNat.
Require Import Arith.Gt.
Require Import Arith.Plus.
Require Import Arith.Le.
Require Import Arith.Lt.
Require Import Logic.
Require Import Logic.Classical_Prop.
Require Import Init.Datatypes.

Require Import funind.Recdef.

(* Formalization of a variant of a logic of knowledge, as given in Halpern 1995 *)

Section Kripke.

Variable n : nat.
(* Universe of "worlds" *)
Definition U := nat.
(* Universe of Principals *)
Definition P := nat.
(* Universe of Atomic propositions *)
Definition A := nat.

Inductive prop : Type :=
| Atomic : A -> prop.

Definition beq_prop (p1 p2 :prop) : bool :=
match (p1,p2) with
| (Atomic p1', Atomic p2') => beq_nat p1' p2'
end.

Inductive actor : Type :=
| Id : P -> actor.

Definition beq_actor (a1 a2: actor) : bool :=
match (a1,a2) with
| (Id a1', Id a2') => beq_nat a1' a2'
end.

Inductive formula : Type :=
| Proposition : prop -> formula
| Not : formula -> formula
| And :  formula  -> formula -> formula
| Or :  formula -> formula -> formula
| Implies :  formula -> formula ->formula
| Knows : actor -> formula -> formula
| EvKnows :  formula -> formula (*me*)
.

Inductive con : Type :=
| empty : con
| ext : con -> prop -> con.

Notation " C # P " := (ext C P) (at level 30).

Require Import Relations.

Record kripke : Type := mkKripke {
K : actor -> relation U;
K_equiv: forall y, equivalence _ (K y);
L : U -> (prop -> Prop)
}.

Fixpoint max (a b: nat) : nat :=
match a, b with
| 0, _ => a
| _, 0 => b
| S(a'), S(b') => 1 + max a' b'
end.

Fixpoint length (p: formula) : nat :=
match p with
| Proposition p' => 1
| Not p' => 1 + length(p')
| And p' p'' => 1 + max (length p') (length p'')
| Or p' p''  => 1 + max (length p') (length p'')
| Implies p' p'' => 1 + max  (length p') (length p'')
| Knows a p'  => 1 + length(p')
| EvKnows p' => 1 + length(p')
end.

Fixpoint numKnows (p: formula): nat :=
match p with
| Proposition p' => 0
| Not p' => 0 + numKnows(p')
| And p' p'' => 0 + max (numKnows p') (numKnows p'')
| Or p' p''  => 0 + max (numKnows p') (numKnows p'')
| Implies p' p'' => 0 + max  (numKnows p') (numKnows p'')
| Knows a p'  => 0 + numKnows(p')
| EvKnows p' => 1 + numKnows(p')
end.

Definition size (p: formula): nat :=
(numKnows p) + (length p).

Definition twice (n: nat) : nat :=
n + n.

Theorem duh: forall a: nat, 1 + a > a.
Proof.   induction a. apply gt_Sn_O.
apply gt_n_S in IHa. unfold plus in *. apply IHa. Qed.

Theorem eq_lt_lt: forall (a b c d: nat), a = b -> c<d -> a+ c< b+d.
Proof. intros. apply plus_le_lt_compat.
apply eq_nat_elim with (n:=a) (m := b). apply le_refl.
apply eq_nat_is_eq. apply H.  apply H0. Qed.

Function kripke_sat (M : kripke) (s : U) (p : formula) {measure size p}: Prop :=
match p with
| Proposition p'  => L M (s)(p')
| Not p' => ~ kripke_sat M s p'
| And p' p''   => kripke_sat M s p' /\ kripke_sat M s p''
| Or p' p''  => kripke_sat M s p' \/ kripke_sat M s p''
| Implies p' p''  => ~kripke_sat M s p' \/  kripke_sat M s p''
| Knows a p' =>   forall t, ~(K M a) s t \/ kripke_sat M t p'
| EvKnows p' =>  forall i, kripke_sat M s (Knows i p' )
end.
``````
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The "Function" plugin is still very experimental. In the documentation you can find

term0 must be build as a pure pattern-matching tree (match...with) with λ-abstractions and applications only at the end of each branch.

But I have to agree that this error message is far from being explicit (normally such error messages should either end with "Please report" or be more user friendly, I consider this as a bug). It means foralls are not allowed in the body of a Function (I don't know whether or not there are theoretical reasons for this behavior).

So you need to do your definition "by hand" without the help of Function. Here is a small example you can adapt for your development. Good luck !

``````
Inductive form : Set :=
| T : form
| K : nat -> form -> form
| eK : form -> form.

Fixpoint size (f : form) : nat := match f with
| T => 1
| K _ f => S (size f)
| eK f => S (S (size f))
end.

Require Import Wf.
Require Import Wf_nat.

Definition R x y := size x < size y.
Lemma R_wf : well_founded R.
apply well_founded_ltof.
Qed.

Lemma lem1 :
forall x n, R x (K n x).
unfold R; intuition.
Qed.

Lemma lem2 :
forall x n, R (K n x) (eK x).
unfold R; intuition.
Qed.

Definition interpret : form -> Prop.
(* we use the well_founded_induction instead of Function *)
refine (well_founded_induction_type R_wf (fun _ => Prop) (fun x f => _)).
destruct x.
exact True.                                     (* ⟦T⟧ ≡ True *)
exact (n = 2 /\ f x (lem1 x n)).                (* ⟦K n F⟧ ≡ (n = 2) ∧ ⟦F⟧ *)
exact (forall n:nat, f (K n x) (lem2 x n)).     (* ⟦eK F⟧ ≡ ∀n:nat,⟦K n F⟧ *)
Defined.
``````

PS: I am going to fill a bug report with the following simpler version of your code.

``````  Require Import Recdef.

Inductive I : Set :=
| C  : I.

Definition m (_ : I) := 0.

Function f (x : I)  {measure m x} : Type := match x with
| C => nat -> nat end.
``````
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The error message has changed in Coq 8.4 but the problem is still there. The new error message is: "Error: Found a product. Can not treat such a term"

This change in error message also lead to Marc's bug being closed: http://www.lix.polytechnique.fr/coq/bugs/show_bug.cgi?id=2457

-