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[I am not sure this is appropriate for stack overflow, but there are many other Coq questions here so perhaps someone can help.]

I am working through the following from http://www.cis.upenn.edu/~bcpierce/sf/Basics.html#lab28 (just below where Case is introduced). Note that I am a complete beginner at this, and am working at home - I am not a student.

Theorem andb_true_elim1 : forall b c : bool,
  andb b c = true -> b = true.
  intros b c H.
  destruct b.
  Case "b = true".
  Case "b = false".
    rewrite <- H. reflexivity.

and I am looking at what the rewrite does:

  Case := "b = false" : String.string
  c : bool
  H : andb false c = true
   false = true

then rewrite <- H. is applied:

  Case := "b = false" : String.string
  c : bool
  H : andb false c = true
   false = andb false c

and it's clear how the proof will succeed.

I can see how in terms of manipulating symbols in a mechanical way I am arriving at a proof. That's fine. But I am disturbed by the "meaning". In particular, how can I have false = true in the middle of a proof?

It seems like I am making some kind of argument with contradictions, but I am not sure what. I feel like I have been blindly following rules and have somehow arrived at a point where I am typing nonsense.

What am I doing above?

I hope the question is clear.

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You could try using: discriminate. (I see it's an old post) –  guest Sep 28 '13 at 18:07
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2 Answers

up vote 12 down vote accepted

Generally, when you do a case analysis in a theorem prover, a lot of the cases boil down to "cannot happen". For example, if you are proving some fact about the integers, you may need to do a case analysis of whether the integer i is positive, zero, or negative. But there may be other hypotheses lying around in your context, or perhaps some part of your goal, that is contradictory with one of the cases. You may know from a previous assertion, for example, that i can never be negative.

However Coq is not that smart. So you still have to go through the mechanics of actually showing that the two contradictory hypotheses can be glued together into a proof of absurdity and hence a proof of your theorem.

Think about it like in a computer program:

switch (k) {
  case X:
    /* do stuff */
  case Y:
    /* do other stuff */
    assert(false, "can't ever happen");

The false = true goal is the "can't ever happen". But you can't just assert your way out in Coq. You actually have to put down a proof term.

So above, you have to prove the absurd goal false = true. And the only thing you have to work with is the hyothesis H: andb false c = true. A moment's thought will show you that actually this is an absurd hypothesis (because andb false y reduces to false for any y and hence cannot possibly be true). So you bang on the goal with the only thing at your disposal (namely H) and your new goal is false = andb false c.

So you apply an absurd hypothesis trying to achive an absurd goal. And lo and behold you end up with something you can actually show by reflexivity. Qed.

UPDATE Formally, here's what's going on.

Recall that every inductive definition in Coq comes with an induction principle. Here are the types of the induction principles for equality and the False proposition (as opposed to the term false of type bool):

Check eq_ind.
  : forall (A : Type) (x : A) (P : A -> Prop),
    P x -> forall y : A, x = y -> P y
Check False_ind.
 : forall P : Prop, False -> P

That induction principle for False says that if you give me a proof of False, I can give you a proof of any proposition P.

The induction principle for eq is more complicated. Let's consider it confined to bool. And specifically to false. It says:

Check eq_ind false.
eq_ind false
 : forall P : bool -> Prop, P false -> forall y : bool, false = y -> P y

So if you start with some proposition P(b) that depends on a boolean b, and you have a proof of P(false), then for any other boolean y that is equal to false, you have a proof of P(y).

This doesn't sound terribly exiciting, but we can apply it to any proposition P that we want. And we want a particularly nasty one.

Check eq_ind false (fun b : bool => if b then False else True).
eq_ind false (fun b : bool => if b then False else True)
 : (fun b : bool => if b then False else True) false ->
   forall y : bool,
   false = y -> (fun b : bool => if b then False else True) y

Simplifying a bit, what this says is True -> forall y : bool, false = y -> (if y then False else True).

So this wants a proof of True and then some boolean y that we get to pick. So let's do that.

Check eq_ind false (fun b : bool => if b then False else True) I true.
eq_ind false (fun b : bool => if b then False else True) I true
 : false = true -> (fun b : bool => if b then False else True) true

And here we are: false = true -> False.

Combining with what we know about the induction principle for False, we have: if you give me a proof of false = true, I can prove any proposition.

So back to andb_true_elim1. We have a hypothesis H that is false = true. And we want to prove some kind of goal. As I've shown above, there exists a proof term that turns proofs of false = true into proofs of anything you want. So in particular H is a proof of false = true, so you can now prove any goal you want.

The tactics are basically machinery that builds the proof term.

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thanks, that makes a lot of sense, but what i still don't understand is how combining two things that are both "wrong" or "absurd" somehow makes things "right". i can see that it works - the proof comes out - but why should it work? why is it that one absurd thing somehow cancels another absurd thing, and will it always work that way? it seems like there is something "deeper" that i am still missing? is it that i am assuming something contradictory and then showing that it is indeed contradictory? –  andrew cooke Nov 1 '11 at 17:35
@andrewcooke What you have here is not two wrong things, but two contradictory things. Your hypotheses taken as a whole are self-contradictory. more precisely, your hypotheses as a whole imply a false statement, and therefore you can prove anything (including your goal) from these hypotheses. The only way way hypotheses can imply a false statement is if there is no way for the hypotheses to be true. –  Gilles Nov 1 '11 at 19:05
so i could just as well type "Admit." instead of the rewrite and the proof would be equally as good? –  andrew cooke Nov 1 '11 at 19:16
@andrew cooke: "admit" is not a "real" proof. All it does is introduce an axiom that is precisely the thing you are trying to prove. It's a way to leave holes to be proved later. You can however complete the branch via exact H –  Lambdageek Nov 1 '11 at 19:40
if i cannot use Admit then i am doing something with the rewrite. yet when i say that i am cancelling contradictions @Giles corrects me (i think). either the rewrite is doing something useful, and in some way i don't understand "two wrongs are making a right" or i am simply forcing Coq to stop complaining, in which case Admit should be acceptable. obviously i am wrong here, but perhaps the above shows my confusion? –  andrew cooke Nov 1 '11 at 20:31
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true = false is a statement equating two different boolean values. Since those values are different this statement is clearly not provable (in the empty context).

Considering your proof: you arrive at the stage where the goal is false = true, so clearly you won't be able to prove it... but the thing is that your context (assumptions) are also contradictory. This often happens for instance when you do case-analysis and one of the cases is contradictory with your other assumptions.

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thanks. as with the other reply, this makes sense, but i still don't grasp why two contradictory things somehow "cancel each other out". i can see that it happens, but it feels like there must be some underlying reason "why"...? do contradictions always appear in pairs? if so, what is the principle that makes this so? –  andrew cooke Nov 1 '11 at 17:36
Correction: It's clearly not provable in the empty context. –  Robin Green Nov 2 '11 at 21:12
@RobinGreen: indeed, that's what I had in mind. Clarified the answered; thanks. –  akoprowski Nov 3 '11 at 9:49
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