# How to express that one element of an inductive relation can't be derived from another in Coq?

This is slightly different from simple implication, as shown in this toy example.

Inductive R : nat -> nat -> Prop :=
| Base1: R 0 1
| Base2: R 0 2
| Ind: forall n m,
R n m -> R (n+1) (m+1).


Given this definition, we have three provable statements: R 2 3, R 3 5, and (R 2 3) -> (R 3 5). What I'm looking for is some way to formulate the following: "there does not exist a derivation path (i.e. a sequence of inductive constructor applications) that starts at R 2 3 and ends at R 3 5.

Is there a way to do this in Coq?

• If you happen to have R 3 5 as a hypothesis, you can "move back" in the implicit derivation path by using inversion, and observe that R 2 3 does not appear. But in order to actually state this result I think you would need to explicitly define the notion of derivation path. Oct 6 at 11:01
• Thanks, this makes sense. How could I go about defining a derivation path? I think this gets at the heart of the difficulty I'm having. Maybe another perspective on this question would be: "how do I express that one proposition requires use of another in its proof?" Oct 6 at 14:43
• “we have three provable statements: R 2 3, R 3 5, and (R 2 3) -> (R 3 5).” Should the last 5 be a 4? Oct 7 at 20:41
• The point is that there isn't a derivation path between R 2 3 and R 3 5, but the logical implication is still true. If you imagine proving this in Coq, this amounts to bringing R 2 3 into your context but never using it, and then just proving R 3 5 directly. Oct 11 at 12:33
• Ah I see now, apologies. Oct 13 at 18:37

Here is a suggestion for how you can define a derivation path. I don't know that this is the best way, but it's what I came up with.

Require Import List Lia.
Import ListNotations.

Inductive evidence :=
| B1 : evidence
| B2 : evidence
| Step : nat -> nat -> evidence.

Inductive R : nat -> nat -> list evidence -> Prop :=
| Base1 : R 0 1 [B1]
| Base2 : R 0 2 [B2]
| Ind : forall n m es, R n m es -> R (n+1) (m+1) (Step n m :: es).

Lemma R_B2 (n : nat) (es : list evidence) : R n (n + 2) es -> In B2 es.
Proof.
generalize dependent n.
induction es as [|e es' IHes'].
- now intros Rnn2nil; inversion Rnn2nil.
- intros n Rnn2.
case es' as [| e' es''].
+ inversion Rnn2.
* now left.
* now inversion H2.
+ inversion Rnn2.
right.
apply (IHes' n0).
now replace (n0 + 2) with m by lia.
Qed.


You can probably simplify this proof, and avoid lia if you want.

• Very interesting, thank you! I hadn't considered baking the derivation path into R itself. At the very least, I now know it's possible. Oct 6 at 23:12
• Yes, I played a bit with defining the derivation path outside of R, but since we want it to have the same inductive properties as R, my original definition ended up being a copy. If having a "simple" R is important, you can have both definitions and then prove R n m <-> exists es, R_ev n m es, but every time R is used instead of R_ev you won't have access to these kind of evidence properties. Oct 7 at 8:00