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.

1 Answer 1


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.
  intros contra.
  specialize (contra True False). (* replace the hypothesis 
                                     by [True -> False] *)
  apply contra. (* At this point the goal becomes [True] *)
  • 1
    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
  • 2
    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.
    – larsr
    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

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