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 `nat`

s 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
end.
(* 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?