# General recursion and induction in Coq

Let's suppose that I have

• type T
• wellfounded relation R: T->T->Prop
• function F1: T->T that makes argument "smaller"
• condition C: T->Prop that describes "start values" of R
• function F2: T->T that makes argument "bigger"

How can I make Fixpoint that looks similar to this:

``````Fixpoint Example (n:T):X :=
match {C n} + {~C n} with
left _ => ... |
right _ => Example (F1 n)
end.
``````

And how I can make possible the following usage of tactic 'induction' (or similar):

``````Theorem ...
Proof.
...
induction n F.
(* And now I have two goals:
the first with assumption C n and goal P n,
the second with assumption P n and goal P (F2 n) *)
...
Qed.
``````

I tried to do that with type nz: {n:nat | n<>O} (looking in the chapter 7.1 of Certiﬁed Programming with Dependent Types book) but got only this far:

``````Require Import Omega.

Definition nz: Set := {n:nat | n<>O}.
Theorem nz_t1 (n:nat): S n<>O. Proof. auto. Qed.

Definition nz_eq (n m:nz) := eq (projT1 n) (projT1 m).
Definition nz_one: nz := exist _ 1 (nz_t1 O).
Definition nz_lt (n m:nz) := lt (projT1 n) (projT1 m).

Definition nz_pred (n:nz): nz := exist _ (S (pred (pred (projT1 n)))) (nz_t1 _).

Theorem nz_Acc: forall (n:nz), Acc nz_lt n.
Proof.
intro. destruct n as [n pn], n as [|n]. omega.
induction n; split; intros; destruct y as [y py]; unfold nz_lt in *; simpl in *.
omega.
assert (y<S n\/y=S n). omega. destruct H0.
assert (S n<>O); auto.
assert (nz_lt (exist _ y py) (exist _ (S n) H1)). unfold nz_lt; simpl; assumption.
fold nz_lt in *. apply Acc_inv with (exist (fun n0:nat=>n0<>O) (S n) H1). apply IHn.
unfold nz_lt; simpl; assumption.
rewrite <- H0 in IHn. apply IHn.
Defined.

Theorem nz_lt_wf: well_founded nz_lt. Proof. exact nz_Acc. Qed.

Lemma pred_wf: forall (n m:nz), nz_lt nz_one n -> m = nz_pred n -> nz_lt m n.
Proof.
intros. unfold nz_lt, nz_pred in *. destruct n as [n pn], m as [m pm]. simpl in *.
destruct n, m; try omega. simpl in *. inversion H0. omega.
Defined.
``````

I couldn't understand what happens further because it was too complicated for me.

P.S. As I see it - there isn't any good enough tutorial about general recursion and induction in Coq for beginners. At least I could find. :(

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