Proof by counterexample in Coq

After proving tens of lemmas in propositional and predicate calculus (some more challenging than others but generally still provable on an `intro-apply-destruct` autopilot) I hit one starting w/ `~forall` and was immediately snagged. Clearly, my understanding and knowledge of Coq was lacking. So, I'm asking for a low-level Coq technique for proving statements of the general form

``````~forall A [B].., C -> D.
exists A [B].., ~(C -> D).
``````

In words, I'm hoping for a general Coq recipy for setting up and firing counterexamples. (The main reason for quantifying over functions above is that it's a (or the) primitive connective in Coq.) If you want examples, I suggest e.g.

``````~forall P Q: Prop, P -> Q.
~forall P: Prop, P -> ~P.
``````

There is a related question which neither posed nor answered mine, so I suppose it's not a duplicate.

Recall that `~ P` is defined as `P -> False`. In other words, to show such a statement, it suffices to assume `P` and derive a contradiction. The crucial point is that you are allowed to use `P` as a hypothesis in any way you like. In the particular case of universally quantified statements, the `specialize` tactic might come in handy. This tactic allows us to instantiate a universally quantified variable with a particular value. For instance,

``````Goal ~ forall P Q, P -> Q.
Proof.
intros contra.
specialize (contra True False). (* replace the hypothesis
by [True -> False] *)
apply contra. (* At this point the goal becomes [True] *)
trivial.
Qed.
``````
• Thanks, `specialize` it was (solved my original problem as well). Are there any other less common (than `intro`, `apply`, `destruct`..) tactics frequently useful in proofs by counterexample?
– jaam
Commented Mar 1, 2016 at 19:11
• You don't "need" `specialize`, in the sense that it does something special that you couldn't do already. In the solution above `contra` is a function of three arguments of type `forall P Q, P->Q`. You can just use it to construct a value that you can apply. So in this case you can solve it all with `intro C; apply (C True False I).` or even (using Coq's type inference) `intro C; apply (C _ _ I).` where `I` is the constructor for `True`. Commented Mar 2, 2016 at 9:19
• @jaam the basic set of tactics that is shipped with Coq is not very orthogonal, and there are many tactics that could be useful in proofs by counterexample, such as `contradiction`, `discriminate`... But note that you can in principle solve all of those by using very few tactics. As larsr pointed out, for example, you could just have used `apply`. You could also use `assert` to build intermediate results with proof scripts, without building a proof object by hand. Commented Mar 2, 2016 at 13:07
• Thanks. So, referring @larsr above, with the goal `C : forall P Q : Prop, P -> Q ├ False`, the 1st `_` is inferred from `I` and the second from conclusion `False`?
– jaam
Commented Mar 3, 2016 at 8:31
• @jaam When I started using Coq, I often used `exfalso` to "force" the current goal to `False`, then `apply H`, where `H` is the hypothesis of the form `~ P`, that is, `P -> False`. It suits a linear, traditional backward-proof style. It's not necessary but it can be easier to follow.
– anol
Commented Mar 7, 2016 at 13:50