# How to get an induction principle for nested fix

I am working with a function that searches through a range of values.

``````Require Import List.

(* Implementation of ListTest omitted. *)
Definition ListTest (l : list nat) := false.

Definition SearchCountList n :=
(fix f i l := match i with
| 0 => ListTest (rev l)
| S i1 =>
(fix g j l1 := match j with
| 0 => false
| S j1 =>
if f i1 (j :: l1)
then true
else g j1 l1
end) (n + n) (i :: l)
end) n nil
.
``````

However, I can't seem to get coq's built-in induction principle facilities to work.

``````Functional Scheme SearchCountList := Induction for SearchCountList Sort Prop.

Error: GRec not handled
``````

It looks like coq is set up for handling mutual recursion, not nested recursion. In this case, I have essentially 2 nested for loops.

However, translating to mutual recursion isn't so easy either:

``````Definition SearchCountList_Loop :=
fix outer n i l {struct i} :=
match i with
| 0 => ListTest (rev l)
| S i1 => inner n i1 (n + n) (i :: l)
end
with inner n i j l {struct j} :=
match j with
| 0 => false
| S j1 =>
if outer n i (j :: l)
then true
else inner n i j1 l
end
for outer
.
``````

but that yields the error

``````Recursive call to inner has principal argument equal to
"n + n" instead of "i1".
``````

So, it looks like I would need to use measure to get it to accept the definition directly. It is confused that I reset j sometimes. But, in a nested set up, that makes sense, since i has decreased, and i is the outer loop.

So, is there a standard way of handling nested recursion, as opposed to mutual recursion? Are there easier ways to reason about the cases, not involving making separate induction theorems? Since I haven't found a way to generate it automatically, I guess I'm stuck with writing the induction principle directly.

-

There's a trick for avoiding mutual recursion in this case: you can compute `f i1` inside `f` and pass the result to `g`.

``````Fixpoint g (f_n_i1 : list nat -> bool) (j : nat) (l1 : list nat) : bool :=
match j with
| 0 => false
| S j1 => if f_n_i1 (j :: l1) then true else g f_n_i1 j1 l1
end.

Fixpoint f (n i : nat) (l : list nat) : bool :=
match i with
| 0 => ListTest (rev l)
| S i1 => g (f n i1) (n + n) (i :: l)
end.

Definition SearchCountList (n : nat) : bool := f n n nil.
``````

Are you sure simple induction wouldn't have been enough in the original code? What about well founded induction?

-
Thanks. This construction should work. Flipping it around by turning the captured variables into curried arguments is a good idea. Now, I have separate functions, and probably can just use plain induction without extra fuss. Ideally I'd want to be able to say something like: induction n, (SearchCountList n) and have all of the extra premises and loop invariant, etc. But, with this hint, I should be able to get there more easily and directly. –  scubed Oct 6 '13 at 19:56