# Can you prove Excluded Middle is wrong in Coq if I do not import classical logic

I know excluded middle is impossible in the logic of construction. However, I am stuck when I try to show it in Coq.

``````Theorem em: forall P : Prop, ~P \/ P -> False.
``````

My approach is:

``````intros P H.
unfold not in H.
intuition.
``````

The system says following:

``````2 subgoals
P : Prop
H0 : P -> False
______________________________________(1/2)
False
______________________________________(2/2)
False
``````

How should I proceed? Thanks

• This question is strongly related, but I think it's nevertheless different from the current one. Apr 28 '18 at 17:16
• If you had a metatheory, you could prove that no Coq program proves the law of the excluded middle. This would be closest to what you are trying to prove.
– Owen
Apr 30 '18 at 1:46

What you are trying to construct is not the negation of LEM, which would say "there exists some P such that EM doesn't hold", but the claim that says that no proposition is decidable, which of course leads to a trivial inconsistency:

``````Axiom not_lem : forall (P : Prop), ~ (P \/ ~ P).

Goal False.
now apply (not_lem True); left.
``````

No need to use the fancy double-negation lemma; as this is obviously inconsistent [imagine it would hold!]

The "classical" negation of LEM is indeed:

``````Axiom not_lem : exists (P : Prop), ~ (P \/ ~ P).
``````

and it is not provable [otherwise EM wouldn't be admissible], but you can assume it safely; however it won't be of much utility for you.

One cannot refute the law of excluded middle (LEM) in Coq. Let's suppose you proved your refutation of LEM. We model this kind of situation by postulating it as an axiom:

``````Axiom not_lem : forall (P : Prop), ~ (P \/ ~ P).
``````

But then we also have a weaker version (double-negated) of LEM:

``````Lemma not_not_lem (P : Prop) :
~ ~ (P \/ ~ P).
Proof.
intros nlem. apply nlem.
right. intros p. apply nlem.
left. exact p.
Qed.
``````

These two facts together would make Coq's logic inconsistent:

``````Lemma Coq_would_be_inconsistent :
False.
Proof.
apply (not_not_lem True).
apply not_lem.
Qed.
``````

I'm coming from mathoverflow, but I don't have permission to comment on @Anton Trunov's answer. I think his answer is unjust, or at least incomplete: he hides the following "folklore":

Coq + Impredicative Set + Weak Excluded-middle -> False

This folklore is a variation of the following facts:

proof irrelevance + large elimination -> false

And Coq + Impredicative Set is canonical, soundness, strong normalization, So it is consistent.

Coq + Impredicative Set is the old version of Coq. I think this at least shows that the defense of the LEM based on double negative translation is not that convincing.

If you want to get information about the solutions, you can get it from here https://github.com/FStarLang/FStar/issues/360

On the other hand, you may be interested in the story of how Coq-HoTT+UA went against LEM∞...

=====================================================

Ok, let's have some solutions.

1. use command-line flag `-impredicative-set`, or the install old version(<8.0) of coq.
2. excluded-middle -> proof-irrelevance
3. proof-irrelevance -> False

Or you can work with standard coq + coq-hott.

1. install coq-hott
2. Univalence + Global Excluded-middle (LEM∞) -> False

It is not recommended that you directly click on the code in question without grasping the specific concept.

I skipped a lot about meta-theoretic implementations, such as Univalence not being computable in Coq-HoTT but only in Agda-CuTT, such as the consistency proof for Coq+Impredicative Set/Coq-HoTT.

However, metatheoretical considerations are important. If we just want to get an Anti-LEM model and don't care about metatheory, then we can use "Boolean-valued forcing" in coq to wreak havoc on things that only LEM can introduce, such as Cauchy sequence real numbers, Dedekind infinite...