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I work on mereology and I wanted to prove that a given theorem (Extensionality) follows from the four axioms I had.

This is my code:

Require Import Classical.
Parameter Entity: Set.
Parameter P : Entity -> Entity -> Prop.

Axiom P_refl : forall x, P x x.

Axiom P_trans : forall x y z,
  P x y -> P y z -> P x z.

Axiom P_antisym : forall x y,
  P x y -> P y x -> x = y.

Definition PP x y := P x y /\ x <> y.
Definition O x y := exists z, P z x /\ P z y.

Axiom strong_supp : forall x y,
  ~ P y x -> exists z, P z y /\ ~ O z x.

And this is my proof:

Theorem extension : forall x y,
  (exists z, PP z x) -> (forall z, PP z x <-> PP z y) -> x = y.
Proof.
  intros x y [w PPwx] H.
  apply Peirce.
  intros Hcontra.
  destruct (classic (P y x)) as [yesP|notP].
  - pose proof (H y) as [].
    destruct H0.
    split; auto.
    contradiction.
  - pose proof (strong_supp x y notP) as [z []].
    assert (y = z).
    apply Peirce.
    intros Hcontra'.
    pose proof (H z) as [].
    destruct H3.
    split; auto.
    destruct H1.
    exists z.
    split.
    apply P_refl.
    assumption.
    rewrite <- H2 in H1.
    pose proof (H w) as [].
    pose proof (H3 PPwx).
    destruct PPwx.
    destruct H5.
    destruct H1.
    exists w.
    split; assumption.
Qed.

I’m happy with the fact that I completed this proof. However, I find it quite messy. And I don’t know how to improve it. (The only thing I think of is to use patterns instead of destruct.) It is possible to improve this proof? If so, please do not use super complex tactics: I would like to understand the upgrades you will propose.

1 Answer 1

2

Here is a refactoring of your proof:

Require Import Classical.
Parameter Entity: Set.
Parameter P : Entity -> Entity -> Prop.

Axiom P_refl : forall x, P x x.

Axiom P_trans : forall x y z,
  P x y -> P y z -> P x z.

Axiom P_antisym : forall x y,
  P x y -> P y x -> x = y.

Definition PP x y := P x y /\ x <> y.
Definition O x y := exists z, P z x /\ P z y.

Axiom strong_supp : forall x y,
  ~ P y x -> exists z, P z y /\ ~ O z x.

Theorem extension : forall x y,
  (exists z, PP z x) -> (forall z, PP z x <-> PP z y) -> x = y.
Proof.
  intros x y [w PPwx] x_equiv_y.
  apply NNPP. intros x_ne_y.
  assert (~ P y x) as NPyx.
  { intros Pxy.
    enough (PP y y) as [_ y_ne_y] by congruence.
    rewrite <- x_equiv_y. split; congruence. }
  destruct (strong_supp x y NPyx) as (z & Pzy & NOzx).
  assert (y <> z) as y_ne_z.
  { intros <-. (* Substitute z right away. *)
    assert (PP w y) as [Pwy NEwy] by (rewrite <- x_equiv_y; trivial).
    destruct PPwx as [Pwx NEwx].
    apply NOzx.
    now exists w. }
  assert (PP z x) as [Pzx _].
  { rewrite x_equiv_y. split; congruence. }
  apply NOzx. exists z. split; trivial.
  apply P_refl.
Qed.

The main changes are:

  1. Give explicit and informative names to all the intermediate hypotheses (i.e., avoid doing destruct foo as [x []])

  2. Use curly braces to separate the proofs of the intermediate assertions from the main proof.

  3. Use the congruence tactic to automate some of the low-level equality reasoning. Roughly speaking, this tactic solves goals that can be established just by rewriting with equalities and pruning subgoals with contradictory statements like x <> x.

  4. Condense trivial proof steps using the assert ... by tactic, which does not generate new subgoals.

  5. Use the (a & b & c) destruct patterns rather than [a [b c]], which are harder to read.

  6. Rewrite with x_equiv_y to avoid doing sequences such as specialize... destruct... apply H0 in H1

  7. Avoid some unnecessary uses of classical reasoning.

3
  • Is destruct (strong_supp x y NPyx) as (z & Pzy & NOzx). equivalent to pose proof (strong_supp x y NPyx) as (z & Pzy & NOzx).? I tried and its the same result. Is there a difference?
    – Lepticed
    Jun 16 at 6:18
  • @Lepticed In this particular case, yes, they are equivalent. Jun 16 at 12:59
  • 1
    Classical reasoning can be replaced with an extra assumption that equality of Entity is decidable.
    – Li-yao Xia
    Jun 16 at 16:00

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