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))).


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)

  unfold trident, denseover.
  rewrite triexpand.
  destruct H.
  destruct H0.
  destruct H.
  destruct H0.
  destruct H.
  destruct H0.

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:

  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:

  intros a b.
  unfold trident, denseover.
  now rewrite (or_comm a (a <-> b)).
  • 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
  • 1
    You hit an unprovable statement because you destructed too much. Not every tactic preserves provability, sometimes they loose information.
    – ana-borges
    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

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