The fact that you are using `int`

numbers from CompCert makes everything more complicated, because there is too little arithmetic available for this datatype.

If you were using just plain integers of type `Z`

, you would be able to perform the proof you require by using `well_founded_induction`

and `Zwf.Zwf_well_founded`

. Here is an example.

```
Theorem foo:
forall i: Z, (0 <= i)%Z -> P i.
intros i.
induction i using
(well_founded_ind (Zwf.Zwf_well_founded 0)).
Print Zwf.
intros ige0.
assert (cases : (i = 0 \/ 0 < i)%Z) by lia.
destruct cases as [case0 | casegt0].
rewrite case0.
now apply base_case.
assert (dec : i = ((i - 1) + 1)%Z) by lia.
rewrite dec.
apply rec_case.
apply H.
unfold Zwf.
lia.
lia.
Qed.
```

Now, if we want to make a similar proof using numbers of type `int`

, life is more complicated because these numbers are in a record, and this record contains a field that is a proof. Usually, the value of the proof is irrelevant, only its existence matters, in in this case we would rather have the `intval`

projection be injective. To make it short, I simply place myself in a theoretical setting where this is granted, this well known and acceptable in most use cases. Here is the full example:

```
Require Import ZArith Zwf.
Require Import Wellfounded.
Require Import Lia.
Require Import ProofIrrelevance.
Open Scope Z_scope.
Parameter modulus : Z.
Hypothesis modulus_gt_0 : 0 < modulus.
Record int : Type := mkint {intval : Z; intrange: -1 < intval < modulus}.
Lemma intval_inj : forall x y : int, intval x = intval y -> x = y.
Proof.
intros [x xp] [y yp]; simpl.
intros xy; revert xp; rewrite xy; intros xp.
now rewrite (proof_irrelevance _ xp yp).
Qed.
Definition int0 := mkint 0 (conj eq_refl modulus_gt_0).
Parameter P : int -> Prop.
Axiom base_case : P int0.
Lemma modulo_Z_bound (z : Z) : -1 < z mod modulus < modulus.
Proof.
assert (tmp := Z.mod_pos_bound z modulus modulus_gt_0).
lia.
Qed.
Axiom rec_case : forall x, P x -> P (mkint _ (modulo_Z_bound (intval x + 1))).
Theorem foo: forall i, P i.
intros i; destruct i as [z zbounds].
revert zbounds.
induction z as [z Ih] using (well_founded_ind (Zwf_well_founded 0)).
intros zbounds.
assert (cases : z = 0 \/ 0 < z) by lia.
destruct cases as [case0 | casegt0].
revert zbounds; rewrite case0.
intros zbounds; assert (isint0 : {|intval := 0; intrange := zbounds|} = int0).
now apply intval_inj; simpl.
now rewrite isint0; apply base_case.
assert (zm1_bounds : -1 < z - 1 < modulus) by lia.
assert (dec : {| intval := z; intrange := zbounds|} =
mkint _ (modulo_Z_bound (intval (mkint _ zm1_bounds) + 1))).
apply intval_inj; simpl.
replace (z - 1 + 1) with z by ring.
symmetry; apply Z.mod_small; lia.
rewrite dec.
apply rec_case.
apply Ih.
unfold Zwf.
lia.
Qed.
```

Note that `mkint _ (modulo_Z_bound (intval x + 1))`

is just a way to write `x + 1`

when `x`

has type `int`

(with the convention that
the successor of the largest number is 0).

There is a way to avoid using the `proof_irrelevance`

axiom, but this would make this answer even longer.