From Undecidability.FOL Require Import Syntax.Facts Semantics.Tarski.FullFacts.
From Undecidability.FOL Require Import Sets.FST.
From Undecidability.FOL Require Import Undecidability.Reductions.PCPb_to_FST.
From Undecidability.TRAKHTENBROT Require Import hfs.
From Undecidability.Shared.Libs.DLW.Utils Require Import finite.
From Undecidability Require Import Shared.ListAutomation.
Import ListAutomationNotations.
#[local]
Instance hfs_interp :
interp hfs.
Proof.
split.
- intros [].
+ intros _. exact hfs_empty.
+ intros v. exact (hfs_cons (Vector.hd v) (Vector.hd (Vector.tl v))).
- intros [].
+ intros v. exact (hfs_mem (Vector.hd v) (Vector.hd (Vector.tl v))).
+ intros v. exact (Vector.hd v = Vector.hd (Vector.tl v)).
Defined.
Open Scope sem.
Lemma hfs_model :
forall rho, rho ⊫ FST.
Proof.
intros rho phi [<-|[<-|[<-|[]]]]; cbn.
- intros x y H1 H2. apply hfs_mem_ext. intuition.
- intros x. apply hfs_empty_spec.
- intros x y z. apply hfs_cons_spec.
Qed.
Lemma htrans_htrans {x y} :
htrans x -> y ∈ x -> htrans y.
Proof.
intros [H1 H2] H. split; try now apply H2.
intros z Hz. apply H2. now apply (H1 y).
Qed.
Definition max {X} (L : list X) :
forall (f : forall x, x el L -> nat), sig (fun n => forall x (H : x el L), f x H < n).
Proof.
intros f. induction L; cbn.
- exists 42. intros x [].
- unshelve edestruct IHL as [n Hn].
+ intros x Hx. apply (f x). now right.
+ pose (na := f a (or_introl eq_refl)). exists ((S na) + n). intros x [->|H].
* unfold na. apply NPeano.Nat.lt_lt_add_r. constructor.
* specialize (Hn x H). cbn in Hn. now apply NPeano.Nat.lt_lt_add_l.
Qed.
Lemma hfs_model_standard {x} :
htrans x -> sig (fun n => x = numeral n).
Proof.
induction x using hfs_rect.
intros Hx. destruct (hfs_mem_fin_t x) as [L HL].
unshelve edestruct (@max _ L) as [N HN].
- intros y Hy % HL. destruct (H y) as [n Hn]; auto. eapply htrans_htrans; eauto.
- apply numeral_trans_sub with N.
+ apply hfs_model.
+ reflexivity.
+ intros a b. destruct (hfs_mem_dec a b); auto.
+ intros y Hy. destruct (H y Hy (htrans_htrans Hx Hy)) as [n Hn].
rewrite Hn. apply numeral_lt; try apply hfs_model; try reflexivity.
assert (HLy : y el L) by now apply HL. specialize (HN y HLy).
cbn in HN. destruct H as [n' ->] in HN.
erewrite numeral_inj at 1; try apply HN; try apply hfs_model; try reflexivity.
now rewrite Hn.
+ apply (proj1 Hx).
Qed.
Lemma FST_model :
exists V (M : interp V), extensional M /\ standard M /\ forall rho, rho ⊫ FST.
Proof.
exists hfs, hfs_interp. split; try reflexivity.
split; try apply hfs_model.
intros x Hx. destruct (hfs_model_standard Hx) as [n Hn]. now exists n.
Qed.
Definition list2hfs L :=
fold_right hfs_cons hfs_empty L.
Lemma list2hfs_spec L x :
hfs_mem x (list2hfs L) <-> x el L.
Proof.
induction L; cbn.
- apply hfs_empty_spec.
- split.
+ intros [<-|H] % hfs_cons_spec; auto. right. now apply IHL.
+ intros [<-|H]; apply hfs_cons_spec; auto. right. now apply IHL.
Qed.
Lemma hfs_ind P :
P hfs_empty -> (forall x y, P x -> P y -> P (hfs_cons x y)) -> forall x, P x.
Proof.
intros H1 H2 x. induction (hfs_mem_wf x) as [x _ IH].
destruct (hfs_mem_fin_t x) as [L HL].
induction L in x, IH, HL |- *.
- assert (x = hfs_empty) as ->; try apply H1.
apply hfs_mem_ext. intros y. rewrite HL.
rewrite hfs_empty_spec. cbn. tauto.
- assert (x = hfs_cons a (list2hfs L)) as ->; try apply H2.
+ apply hfs_mem_ext. intros y.
change (hfs_cons a (list2hfs L)) with (list2hfs (a :: L)).
rewrite list2hfs_spec. apply HL.
+ apply IH. apply hfs_cons_spec. now left.
+ apply IHL.
* intros x Hx. apply IH. apply hfs_cons_spec. now right.
* apply list2hfs_spec.
Qed.
Lemma hfs_ax_ind phi rho :
rho ⊨ ax_ind phi.
Proof.
cbn. intros H1 H2. apply hfs_ind.
- apply sat_comp in H1. eapply sat_ext; try apply H1. now intros [].
- setoid_rewrite sat_comp in H2. intros x y Hx Hy. eapply sat_ext; try apply (H2 y x).
+ now intros [].
+ eapply sat_ext; try apply Hx. now intros [].
+ eapply sat_ext; try apply Hy. now intros [].
Qed.
Lemma FSTI_model :
exists V (M : interp V), extensional M /\ standard M /\ forall rho psi, FSTI psi -> rho ⊨ psi.
Proof.
exists hfs, hfs_interp. split; try reflexivity. split.
- intros x Hx. destruct (hfs_model_standard Hx) as [n Hn]. now exists n.
- intros rho psi []; try now apply hfs_model. apply hfs_ax_ind.
Qed.
From Undecidability.FOL Require Import Sets.FST.
From Undecidability.FOL Require Import Undecidability.Reductions.PCPb_to_FST.
From Undecidability.TRAKHTENBROT Require Import hfs.
From Undecidability.Shared.Libs.DLW.Utils Require Import finite.
From Undecidability Require Import Shared.ListAutomation.
Import ListAutomationNotations.
#[local]
Instance hfs_interp :
interp hfs.
Proof.
split.
- intros [].
+ intros _. exact hfs_empty.
+ intros v. exact (hfs_cons (Vector.hd v) (Vector.hd (Vector.tl v))).
- intros [].
+ intros v. exact (hfs_mem (Vector.hd v) (Vector.hd (Vector.tl v))).
+ intros v. exact (Vector.hd v = Vector.hd (Vector.tl v)).
Defined.
Open Scope sem.
Lemma hfs_model :
forall rho, rho ⊫ FST.
Proof.
intros rho phi [<-|[<-|[<-|[]]]]; cbn.
- intros x y H1 H2. apply hfs_mem_ext. intuition.
- intros x. apply hfs_empty_spec.
- intros x y z. apply hfs_cons_spec.
Qed.
Lemma htrans_htrans {x y} :
htrans x -> y ∈ x -> htrans y.
Proof.
intros [H1 H2] H. split; try now apply H2.
intros z Hz. apply H2. now apply (H1 y).
Qed.
Definition max {X} (L : list X) :
forall (f : forall x, x el L -> nat), sig (fun n => forall x (H : x el L), f x H < n).
Proof.
intros f. induction L; cbn.
- exists 42. intros x [].
- unshelve edestruct IHL as [n Hn].
+ intros x Hx. apply (f x). now right.
+ pose (na := f a (or_introl eq_refl)). exists ((S na) + n). intros x [->|H].
* unfold na. apply NPeano.Nat.lt_lt_add_r. constructor.
* specialize (Hn x H). cbn in Hn. now apply NPeano.Nat.lt_lt_add_l.
Qed.
Lemma hfs_model_standard {x} :
htrans x -> sig (fun n => x = numeral n).
Proof.
induction x using hfs_rect.
intros Hx. destruct (hfs_mem_fin_t x) as [L HL].
unshelve edestruct (@max _ L) as [N HN].
- intros y Hy % HL. destruct (H y) as [n Hn]; auto. eapply htrans_htrans; eauto.
- apply numeral_trans_sub with N.
+ apply hfs_model.
+ reflexivity.
+ intros a b. destruct (hfs_mem_dec a b); auto.
+ intros y Hy. destruct (H y Hy (htrans_htrans Hx Hy)) as [n Hn].
rewrite Hn. apply numeral_lt; try apply hfs_model; try reflexivity.
assert (HLy : y el L) by now apply HL. specialize (HN y HLy).
cbn in HN. destruct H as [n' ->] in HN.
erewrite numeral_inj at 1; try apply HN; try apply hfs_model; try reflexivity.
now rewrite Hn.
+ apply (proj1 Hx).
Qed.
Lemma FST_model :
exists V (M : interp V), extensional M /\ standard M /\ forall rho, rho ⊫ FST.
Proof.
exists hfs, hfs_interp. split; try reflexivity.
split; try apply hfs_model.
intros x Hx. destruct (hfs_model_standard Hx) as [n Hn]. now exists n.
Qed.
Definition list2hfs L :=
fold_right hfs_cons hfs_empty L.
Lemma list2hfs_spec L x :
hfs_mem x (list2hfs L) <-> x el L.
Proof.
induction L; cbn.
- apply hfs_empty_spec.
- split.
+ intros [<-|H] % hfs_cons_spec; auto. right. now apply IHL.
+ intros [<-|H]; apply hfs_cons_spec; auto. right. now apply IHL.
Qed.
Lemma hfs_ind P :
P hfs_empty -> (forall x y, P x -> P y -> P (hfs_cons x y)) -> forall x, P x.
Proof.
intros H1 H2 x. induction (hfs_mem_wf x) as [x _ IH].
destruct (hfs_mem_fin_t x) as [L HL].
induction L in x, IH, HL |- *.
- assert (x = hfs_empty) as ->; try apply H1.
apply hfs_mem_ext. intros y. rewrite HL.
rewrite hfs_empty_spec. cbn. tauto.
- assert (x = hfs_cons a (list2hfs L)) as ->; try apply H2.
+ apply hfs_mem_ext. intros y.
change (hfs_cons a (list2hfs L)) with (list2hfs (a :: L)).
rewrite list2hfs_spec. apply HL.
+ apply IH. apply hfs_cons_spec. now left.
+ apply IHL.
* intros x Hx. apply IH. apply hfs_cons_spec. now right.
* apply list2hfs_spec.
Qed.
Lemma hfs_ax_ind phi rho :
rho ⊨ ax_ind phi.
Proof.
cbn. intros H1 H2. apply hfs_ind.
- apply sat_comp in H1. eapply sat_ext; try apply H1. now intros [].
- setoid_rewrite sat_comp in H2. intros x y Hx Hy. eapply sat_ext; try apply (H2 y x).
+ now intros [].
+ eapply sat_ext; try apply Hx. now intros [].
+ eapply sat_ext; try apply Hy. now intros [].
Qed.
Lemma FSTI_model :
exists V (M : interp V), extensional M /\ standard M /\ forall rho psi, FSTI psi -> rho ⊨ psi.
Proof.
exists hfs, hfs_interp. split; try reflexivity. split.
- intros x Hx. destruct (hfs_model_standard Hx) as [n Hn]. now exists n.
- intros rho psi []; try now apply hfs_model. apply hfs_ax_ind.
Qed.