If you see an impossible goal, there are two possibilities: either you made a mistake in your proof strategy (perhaps your lemma is wrong), or the hypotheses are contradictory.
If you think the hypotheses are contradictory, you can set the goal to
False, to get a little complexity out of the way.
elimtype False achieves this. Often, you prove
False by proving a proposition
P and its negation
~P; the tactic
absurd P deduces any goal from
~P. If there's a particular hypothesis which is contradictory,
contradict H will set the goal to
~H, or if the hypothesis is a negation
~A then the goal will be
A (stronger than
~ ~A but usually more convenient). If one particular hypothesis is obviously contradictory,
contradition H or just
contradiction will prove any goal.
There are many tactics involving hypotheses of inductive types. Figuring out which one to use is mostly a matter of experience. Here are the main ones (but you will run into cases not covered here soon):
destruct simply breaks down the hypothesis into several parts. It loses information about dependencies and recursion. A typical example is
destruct H where
H is a conjunction
H : A /\ B, which splits
H into two independent hypotheses of types
B; or dually
destruct H where
H is a disjunction
H : A \/ B, which splits the proof into two different subproofs, one with the hypothesis
A and one with the hypothesis
case_eq is similar to
destruct, but retains the connections that the hypothesis has with other hypotheses. For example,
destruct n where
n : nat breaks the proof into two subproofs, one for
n = 0 and one for
n = S m. If
n is used in other hypotheses (i.e. you have a
H : P n), you may need to remember that the
n you've destructed is the same
n used in these hypotheses:
case_eq n does this.
inversion performs a case analysis on the type of a hypothesis. It is particularly useful when there are dependencies in the type of the hypothesis that
destruct would forget. You would typically use
case_eq on hypotheses in
Set (where equality is relevant) and
inversion on hypotheses in
Prop (which have very dependent types). The
inversion tactic leaves a lot of equalities behind, and it's often followed by
subst to simplify the hypotheses. The
inversion_clear tactic is a simple alternative to
inversion; subst but loses a little information.
induction means that you are going to prove the goal by induction (= recursion) on the given hypothesis. For example,
induction n where
n : nat means that you'll perform integer induction and prove the base case (
n replaced by
0) and the inductive case (
n replaced by
Your example is simple enough that you can prove it as “obvious by case analysis on
Lemma has2b2: forall a:three, a<>zero/\a<>one ->a=two.
Proof. destruct a; tauto. Qed.
But let's look at the cases generated by the
destruct tactic, i.e. after just
intros; destruct a.. (The case where
one is symmetric; the last case, where
two, is obvious by reflexivity.)
H : zero <> zero /\ zero <> one
zero = two
The goal looks impossible. We can tell this to Coq, and here it can spot the contradiction automatically (
zero=zero is obvious, and the rest is a first-order tautology handled by the
elimtype False. tauto.
tauto works even if you don't start by telling Coq not to worry about the goal and wrote
tauto without the
elimtype False first (IIRC it didn't in older versions of Coq). You can see what Coq is doing with the
tauto tactic by writing
info tauto. Coq will tell you what proof script the
tauto tactic generated. It's not very easy to follow, so let's look at a manual proof of this case. First, let's split the hypothesis (which is a conjunction) into two.
destruct H as [H0 H1].
We now have two hypotheses, one of which is
zero <> zero. This is clearly false, because it's the negation of
zero = zero which is clearly true.
contradiction H0. reflexivity.
We can look in even more detail at what the
contradiction tactic does. (
info contradiction would reveal what happens under the scene, but again it's not novice-friendly). We claim that the goal is true because the hypotheses are contradictory so we can prove anything. So let's set the intermediate goal to
assert (F : False).
red in H0. to see that
zero <> zero is really notation for
~(zero=zero) which in turn is defined as meaning
zero=zero -> False. So
False is the conclusion of
And now we need to prove that
zero=zero, which is
Now we've proved our assertion of
False. What remains is to prove that
False implies our goal. Well,
False implies any goal, that's its definition (
False is defined as an inductive type with 0 case).