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Error in defining Ackermann in Coq

I am trying to define the Ackermann-Peters function in Coq, and I'm getting an error message that I don't understand. As you can see, I'm packaging the arguments a, b of Ackermann in a pair ab; I provide an ordering defining an ordering function for the arguments. Then I use the Function form to define Ackermann itself, providing it with the ordering function for the ab argument.

Require Import Recdef.    
Definition ack_ordering (ab1 ab2 : nat * nat) :=
    match (ab1, ab2) with
    |((a1, b1), (a2, b2)) => 
       (a1 > a2) \/ ((a1 = a2) /\ (b1 > b2))   
    end.
Function ack (ab : nat * nat) {wf ack_ordering} : nat :=
match ab with
| (0, b) => b + 1
| (a, 0) => ack (a-1, 1)
| (a, b) => ack (a-1, ack (a, b-1))
end.

What I get is the following error message:

Error: No such section variable or assumption: ack.

I'm not sure what bothers Coq, but searching the internet, I found a suggestion there may be a problem with using a recursive function defined with an ordering or a measure, where the recursive call occurs within a match. However, using the projections fst and snd and an if-then-else generated a different error message. Can someone please suggest how to define Ackermann in Coq?

like image 614
Mayer Goldberg Avatar asked Apr 24 '12 05:04

Mayer Goldberg


3 Answers

It seems like Function can't solve this problem. However, its cousin Program Fixpoint can.

Let's define some lemmas treating well-foundedness first:

Require Import Coq.Program.Wf.
Require Import Coq.Arith.Arith.

Definition lexicographic_ordering (ab1 ab2 : nat * nat) : Prop :=
  match ab1, ab2 with
  | (a1, b1), (a2, b2) => 
      (a1 < a2) \/ ((a1 = a2) /\ (b1 < b2))
  end.

(* this is defined in stdlib, but unfortunately it is opaque *)
Lemma lt_wf_ind :
  forall n (P:nat -> Prop), (forall n, (forall m, m < n -> P m) -> P n) -> P n.
Proof. intro p; intros; elim (lt_wf p); auto with arith. Defined.

(* this is defined in stdlib, but unfortunately it is opaque too *)
Lemma lt_wf_double_ind :
  forall P:nat -> nat -> Prop,
    (forall n m,
      (forall p (q:nat), p < n -> P p q) ->
      (forall p, p < m -> P n p) -> P n m) -> forall n m, P n m.
Proof.
  intros P Hrec p. pattern p. apply lt_wf_ind.
  intros n H q. pattern q. apply lt_wf_ind. auto.
Defined.

Lemma lexicographic_ordering_wf : well_founded lexicographic_ordering.
Proof.
  intros (a, b); pattern a, b; apply lt_wf_double_ind.
  intros m n H1 H2.
  constructor; intros (m', n') [G | [-> G]].
  - now apply H1.
  - now apply H2.
Defined.

Now we can define the Ackermann-Péter function:

Program Fixpoint ack (ab : nat * nat) {wf lexicographic_ordering ab} : nat :=
  match ab with
  | (0, b) => b + 1
  | (S a, 0) => ack (a, 1)
  | (S a, S b) => ack (a, ack (S a, b))
  end.
Next Obligation.
  inversion Heq_ab; subst. left; auto. Defined.
Next Obligation.
  apply lexicographic_ordering_wf. Defined.

Some simple tests demonstrating that we can compute with ack:

Example test1 : ack (1, 2) = 4 := eq_refl.
Example test2 : ack (3, 4) = 125 := eq_refl.  (* this may take several seconds *)

Using the Equations plugin by M. Sozeau and C. Mangin it is possible to define the function this way:

From Equations Require Import Equations Subterm.

Equations ack (p : nat * nat) : nat :=
ack p by rec p (lexprod _ _ lt lt) :=
ack (pair 0 n) := n + 1;
ack (pair (S m) 0) := ack (m, 1);
ack (pair (S m) (S n)) := ack (m, ack (S m, n)).

Unfortunately, it's not possible to use the ( , ) notation for pairs due to issue #81. The code is taken from Equation's test suite: ack.v.

like image 196
Anton Trunov Avatar answered Oct 31 '22 23:10

Anton Trunov


You get this error because you are referencing the ack function while you are defining it. Self reference is only allowed in Fixpoints (ie. recursive functions) but the problem is, as you probably know, that the Ackermann function is not a primitive recursive function.

See Coq'Art section 4.3.2.2 for some more information on this.

So one alternative way to define it is by inlining a second recursive function that is structurally recursive for the second argument; so something like

Fixpoint ack (n m : nat) : nat :=
  match n with
  | O => S m
  | S p => let fix ackn (m : nat) :=
               match m with
               | O => ack p 1
               | S q => ack p (ackn q)
               end
           in ackn m
  end.
like image 3
wires Avatar answered Oct 31 '22 23:10

wires


I just tried your function with Coq 8.4, and the error is slightly different:

Error: Nested recursive function are not allowed with Function

I guess the inner call to ack is the problem, but I don't know why.

Hope this helps a bit, V.

PS: The usual way I define Ack is what wires wrote, with an inner fixpoint.

like image 1
Vinz Avatar answered Nov 01 '22 00:11

Vinz