# Coq seemingly refuses to recognize a simple substitution of a propositional formula for a propositional variable?

After many failures I discovered a strange thing Coq does that I don't understand. Sorry for involved code, I was not able to isolate a simpler example. I have a formula I call `trident` in three variables `p`, `q`, `r`. I then simply write out an instance of this formula with `a <-> b` in place of `p`, `a` in place of `q` and `b` in place of `r`, and just try to prove a lemma stating that the result is equivalent to the substitution into `trident` as above. When trying to prove I am stuck with the first subgoal which reads

`````` a, b : Prop
H : b
============================
a \/ (a <-> b)
``````

and this is obviously unprovable: if `b` is assumed to be true, then `a \/ (a <-> b)` becomes just `a`, and there is no reason for it to be true.

Here is the whole code:

``````From Coq Require Import Setoid.

Definition denseover (p q : Prop) := (p -> q) -> q.

Definition trident (p q r : Prop) :=
(
(denseover p (q \/ r))
/\ (denseover q (r \/ p))
/\ (denseover r (p \/ q))
) -> (p \/ q \/ r).

Lemma triexpand : forall a b : Prop,
((a <-> b) \/ a \/ b)
<-> ((a \/ (a -> b)) /\ (b \/ (b -> a))).

Proof.
tauto.
Qed.

Lemma substritwo : forall a b : Prop,
(trident (a <-> b) a b)
<->
(
(
(denseover (a <-> b) (a \/ b))
/\ (denseover a (b \/ (a <-> b)))
/\ (denseover b (a \/ (a <-> b)))
) -> ((a <-> b) \/ a \/ b)
).

Proof.
unfold trident, denseover.
split.
rewrite triexpand.
split.
destruct H.
destruct H0.
destruct H.
destruct H0.
destruct H.
destruct H0.
intuition.
``````

## 1 Answer

a lemma stating that the result is equivalent to the substitution into trident as above

This should be trivial for Coq with a tactic such as `easy`. The fact that it doesn't work led me to discover that your lemma switched the order of a disjunction: the third statement with `denseover` is

``````denseover r (p \/ q)
``````

in the definition of `trident` and

``````denseover b (a \/ (a <-> b))
``````

in the lemma, instead of `denseover b ((a <-> b) \/ a)`.

If you change this, `easy` works.

But suppose you want to prove the lemma as stated. Then the argument is that `\/` is commutative, and you shouldn't be breaking down the statement, you should just rewrite with the commutativity lemma, which is called `or_comm`. Interestingly, the following doesn't work:

``````Proof.
intros a b.
rewrite (or_comm a (a <-> b)).
``````

and it gives a scary-looking error. Here's why it shouldn't work: as of the current goal, `denseover` could be anything, and we don't know a priori that replacing arguments of `denseover` by equivalent (but not equal!) arguments will give the same result. As far as Coq knows without inspecting the definition of `denseover`, it could match on disjunctions and behave differently in the left and right branches.

In this case the problem is solved by simply unfolding `denseover`. Since this is a simple chain of implications, Coq knows that rewriting with equivalent statements is fine:

``````Proof.
intros a b.
unfold trident, denseover.
now rewrite (or_comm a (a <-> b)).
Qed.
``````
• Fantastic, thanks! I already accepted it but still, may I ask - how did I manage to hit an unprovable statement? Can one say that "if disjunction would be noncommutative" this would imply it? Nov 13 '21 at 22:02
• You hit an unprovable statement because you destructed too much. Not every tactic preserves provability, sometimes they loose information. Nov 13 '21 at 22:12
• Yes, thanks! Actually right now I was studying a reply at coq discourse with this kind of explanation. I certainly had no idea about what am I doing when doing `destruct`... Nov 13 '21 at 22:22