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I need to define a recursive function with no easily measurable argument. I keep a list of used arguments to ensure that each one is used at most once, and the input space is finite.

Using a measure (inpspacesize - (length l)) works mostly, but I get stuck in one case. It seems I'm missing the information that previous layers of l have been constructed correctly, i. e. there are no duplicates and all entries are really from the input space.

Now I'm searching for a list replacement that does what I need.

Edit I've reduced this to the following now:

I have nats smaller than a given max and need to ensure that the function is called at most once for every number. I've come up with the following:

(* the condition imposed *)
Inductive limited_unique_list (max : nat) : list nat -> Prop :=
  | LUNil  : limited_unique_list max nil
  | LUCons : forall x xs, limited_unique_list max xs
             -> x <= max
             -> ~ (In x xs)
             -> limited_unique_list max (x :: xs).

(* same as function *)
Fixpoint is_lulist (max : nat) (xs0 : list nat) : bool :=
  match xs0 with
  | nil     => true
  | (x::xs) => if (existsb (beq_nat x) xs) || negb (leb x max)
                 then false
                 else is_lulist max xs

(* really equivalent *)
Theorem is_lulist_iff_limited_unique_list : forall (max:nat) (xs0 : list nat),
    true = is_lulist max xs0 <-> limited_unique_list max xs0.
Proof. ... Qed.

(* used in the recursive function's step *)
Definition lucons {max : nat} (x : nat) (xs : list nat) : option (list nat) :=
  if is_lulist max (x::xs)
    then Some (x :: xs)
    else None.

(* equivalent to constructor *)
Theorem lucons_iff_LUCons : forall max x xs, limited_unique_list max xs ->
    (@lucons max x xs = Some (x :: xs) <-> limited_unique_list max (x::xs)).
Proof. ... Qed.

(* unfolding one step *)
Theorem lucons_step : forall max x xs v, @lucons max x xs = v ->
  (v = Some (x :: xs) /\ x <= max /\ ~ (In x xs)) \/ (v = None).
Proof. ... Qed.

(* upper limit *)
Theorem lucons_toobig : forall max x xs, max < x
    -> ~ limited_unique_list max (x::xs).
Proof. ... Qed.

(* for induction: increasing max is ok *)
Theorem limited_unique_list_increasemax : forall max xs,
  limited_unique_list max xs -> limited_unique_list (S max) xs.
Proof. ... Qed.

I keep getting stuck when trying to prove inductively that I cannot insert an element into the full list (either the IH comes out unusable or I can't find the information I need). As I think this non-insertability is crucial for showing termination, I've still not found a working solution.

Any suggestions on how to prove this differently, or on restructuring the above?

share|improve this question
Without specifics, in particular on the domain of your function, it's hard to help. Apparently, the domain can be enumerated in a finite list, but it has to verify a property - itself recursive, and contain no duplicate elements, is that it ? Would you mind giving us more indications on that, perhaps some of the code and definitions you have already ? Without them, it's hard to do more than recommend section 15 of the Coq'Art. – huitseeker Jul 5 '11 at 6:00

1 Answer 1

Hard to say much without more details (please elaborate!), but:

  • Are you using the Program command? It's certainly very helpful for defining functions with non-trivial measures.
  • For uniqueness wouldn't it work if you tried sets? I remember writing ones a function that sounds very much like what you are saying: I had a function for which an argument contained a set of items. This set of items was growing monotonously and was limited to a finite space of items, giving the termination argument.
share|improve this answer
Yes, I'm using Program Fixpoint. I did look at set and did not know how to use it, but I've simplified my problem to nats with an upper limit now, so maybe it'll work. I'll look at that again. – nobody Jul 5 '11 at 20:37
If you're still stucked try providing some more details here. – akoprowski Jul 5 '11 at 22:20

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