From Undecidability.FOL Require Import Util.Aczel.
Local Set Implicit Arguments.
Local Unset Strict Implicit.
Definition CE :=
forall (P Q : Acz -> Prop), (forall s, P s <-> Q s) -> P = Q.
Section Model.
Definition eqclass P :=
exists s, P = Aeq s.
Hypothesis ce : CE.
Lemma PE (P P' : Prop) :
(P <-> P') -> P = P'.
Proof.
intros H.
change ((fun _ : Acz => P) AEmpty = P').
now rewrite (@ce (fun _ => P) (fun _ => P')).
Qed.
Lemma PI (P : Prop) (H H' : P) :
H = H'.
Proof.
assert (P = True) as ->. apply PE; tauto.
destruct H, H'. reflexivity.
Qed.
Definition SET' :=
{ P | eqclass P }.
Definition class (X : SET') : Acz -> Prop :=
proj1_sig X.
Definition ele X Y :=
forall s t, (class X) s -> (class Y) t -> Ain s t.
Definition sub X Y :=
forall Z, ele Z X -> ele Z Y.
Lemma Aeq_eqclass s :
eqclass (Aeq s).
Proof.
now exists s.
Qed.
Hint Resolve Aeq_eqclass : core.
Definition classof (s : Acz) : SET' :=
exist _ (Aeq s) (Aeq_eqclass s).
Lemma class_eq X X' s s' :
Aeq s s' -> class X s -> class X' s' -> X = X'.
Proof.
destruct X as [P HP], X' as [P' HP']; simpl.
intros H1 H2 XX. assert (H : P = P').
- destruct HP as [t ->], HP' as [t' ->].
apply ce. intros u. rewrite H2, H1, XX. tauto.
- subst P'. now rewrite (PI HP HP').
Qed.
Lemma classof_ex X :
exists s, X = classof s.
Proof.
destruct X as [P[s ->]]; simpl. exists s.
apply (@class_eq _ _ s s); simpl; auto.
Qed.
Lemma classof_class s :
class (classof s) s.
Proof.
simpl. reflexivity.
Qed.
Lemma classof_eq s t :
classof s = classof t <-> Aeq s t.
Proof.
split; intros H.
- specialize (classof_class s).
intros XX. rewrite H in XX. auto.
- apply (class_eq H); simpl; trivial.
Qed.
Lemma classof_ele s t :
ele (classof s) (classof t) <-> Ain s t.
Proof.
split; intros H.
- apply H; simpl; auto.
- intros s' t' H1 H2. now rewrite <- H1, <- H2.
Qed.
Lemma classof_sub s t :
sub (classof s) (classof t) <-> ASubq s t.
Proof.
split; intros H1.
- intros u H2. now apply classof_ele, H1, classof_ele.
- intros Z H2. destruct (classof_ex Z) as [u ->].
now apply classof_ele, H1, classof_ele.
Qed.
Hint Resolve classof_class classof_eq classof_ele classof_sub : core.
Definition empty :=
classof AEmpty.
Definition upair' X Y u :=
exists s t, (class X) s /\ (class Y) t /\ Aeq u (Aupair s t).
Lemma upair_eqclass X Y :
eqclass (upair' X Y).
Proof.
destruct (classof_ex X) as [s ->].
destruct (classof_ex Y) as [t ->].
exists (Aupair s t). apply ce. intros z. split; intros H.
- destruct H as [s'[t'[H1[H2 H3]]]]; simpl in H1, H2.
now rewrite H1, H2, H3.
- exists s, t. simpl. repeat split; auto.
Qed.
Definition upair X Y :=
exist _ (upair' X Y) (upair_eqclass X Y).
Definition union' X t :=
exists s, (class X) s /\ Aeq t (Aunion s).
Lemma union_eqclass X :
eqclass (union' X).
Proof.
destruct (classof_ex X) as [s ->].
exists (Aunion s). apply ce. intros z. split; intros H.
- destruct H as [s'[H1 H2]]; simpl in H1.
now rewrite H1, H2.
- exists s. auto.
Qed.
Definition union X :=
exist _ (union' X) (union_eqclass X).
Definition power' X t :=
exists s, (class X) s /\ Aeq t (Apower s).
Lemma power_eqclass X :
eqclass (power' X).
Proof.
destruct (classof_ex X) as [s ->].
exists (Apower s). apply ce. intros t. split; intros H.
- destruct H as [s'[H1 H2]]; simpl in H1.
now rewrite H1, H2.
- exists s. auto.
Qed.
Definition power X :=
exist _ (power' X) (power_eqclass X).
Definition empred (P : SET' -> Prop) :=
fun s => P (classof s).
Fact empred_Aeq P :
cres Aeq (empred P).
Proof.
intros s s' H % classof_eq. unfold empred. now rewrite H.
Qed.
Definition sep' P X t :=
exists s, (class X) s /\ Aeq t (Asep (empred P) s).
Lemma sep_eqclass P X :
eqclass (sep' P X).
Proof.
destruct (classof_ex X) as [s ->].
exists (Asep (empred P) s). apply ce. intros t. split; intros H.
- destruct H as [s'[H1 H2]]; simpl in H1.
now rewrite H2, (Asep_proper (@empred_Aeq P) H1).
- exists s. auto.
Qed.
Definition sep P X :=
exist _ (sep' P X) (sep_eqclass P X).
Lemma set_ext X Y :
sub X Y /\ sub Y X <-> X = Y.
Proof.
destruct (classof_ex X) as [s ->].
destruct (classof_ex Y) as [t ->].
repeat rewrite classof_sub. rewrite classof_eq.
split; intros H.
- now apply Aeq_ext.
- rewrite H. split; firstorder.
Qed.
Lemma emptyE X :
~ ele X empty.
Proof.
destruct (classof_ex X) as [s ->].
unfold empty. rewrite classof_ele.
apply AEmptyAx.
Qed.
Lemma upair_welldef s t :
upair (classof s) (classof t) = classof (Aupair s t).
Proof.
pose (u := Aupair s t).
apply (class_eq (s:=u) (s':=u)); trivial.
exists s, t. auto.
Qed.
Lemma upairAx X Y Z :
ele Z (upair X Y) <-> Z = X \/ Z = Y.
Proof.
destruct (classof_ex Z) as [u ->].
destruct (classof_ex X) as [s ->].
destruct (classof_ex Y) as [t ->].
repeat rewrite classof_eq.
rewrite upair_welldef, classof_ele.
apply AupairAx.
Qed.
Lemma union_welldef s :
union (classof s) = classof (Aunion s).
Proof.
pose (t := Aunion s).
apply (class_eq (s:=t) (s':=t)); trivial.
exists s. auto.
Qed.
Lemma unionAx X Z :
ele Z (union X) <-> exists Y, ele Y X /\ ele Z Y.
Proof.
destruct (classof_ex Z) as [u ->].
destruct (classof_ex X) as [s ->].
rewrite union_welldef, classof_ele, AunionAx.
split; intros [t H].
- exists (classof t). now repeat rewrite classof_ele.
- destruct (classof_ex t) as [t' ->].
exists t'. now repeat rewrite <- classof_ele.
Qed.
Lemma power_welldef s :
power (classof s) = classof (Apower s).
Proof.
pose (t := Apower s).
apply (class_eq (s:=t) (s':=t)); trivial.
exists s. auto.
Qed.
Lemma powerAx X Y :
ele Y (power X) <-> sub Y X.
Proof.
destruct (classof_ex Y) as [t ->].
destruct (classof_ex X) as [s ->].
rewrite power_welldef, classof_ele, classof_sub.
apply ApowerAx.
Qed.
Lemma sep_welldef P s :
sep P (classof s) = classof (Asep (empred P) s).
Proof.
pose (t := Asep (empred P) s).
apply (class_eq (s:=t) (s':=t)); trivial.
exists s. auto.
Qed.
Lemma sepAx P X Y :
ele Y (sep P X) <-> ele Y X /\ P Y.
Proof.
destruct (classof_ex Y) as [s ->].
destruct (classof_ex X) as [t ->].
rewrite sep_welldef. repeat rewrite classof_ele.
apply AsepAx, empred_Aeq.
Qed.
Definition succ X :=
union (upair X (upair X X)).
Definition inductive X :=
ele empty X /\ forall Y, ele Y X -> ele (succ Y) X.
Definition om :=
classof Aom.
Lemma succ_eq s :
succ (classof s) = classof (Asucc s).
Proof.
apply set_ext. split; intros X H.
- apply unionAx in H as [Y[H1 H2]].
destruct (classof_ex X) as [t ->].
apply classof_ele. apply AunionAx.
apply upairAx in H1 as [->| ->].
+ exists s. split; try now apply classof_ele.
apply AupairAx. now left.
+ exists (Aupair s s). rewrite AupairAx. split; auto.
apply upairAx in H2. rewrite !classof_eq in H2. now apply AupairAx.
- destruct (classof_ex X) as [t ->].
apply classof_ele in H.
apply AunionAx in H as [u[H1 H2]].
apply unionAx.
apply AupairAx in H1 as [H1| H1]; subst.
+ exists (classof u). split; try now apply classof_ele.
apply upairAx. left. now apply classof_eq.
+ exists (upair (classof s) (classof s)). rewrite upairAx. split; auto.
rewrite H1 in H2. apply AupairAx in H2. rewrite <- !classof_eq in H2. now apply upairAx.
Qed.
Lemma Ainductive_inductive s :
Ainductive s <-> inductive (classof s).
Proof.
split; intros H.
- split.
+ apply classof_ele. apply H.
+ intros X H'. destruct (classof_ex X) as [t ->].
rewrite succ_eq. apply classof_ele, H.
now apply classof_ele.
- split.
+ apply classof_ele. apply H.
+ intros t Ht. apply classof_ele.
rewrite <- succ_eq. apply H.
now apply classof_ele.
Qed.
Lemma om_Ax1 :
inductive om.
Proof.
split.
- apply classof_ele. apply AomAx1.
- intros X H. destruct (classof_ex X) as [s ->].
rewrite succ_eq. apply classof_ele, AomAx1.
now apply classof_ele.
Qed.
Lemma om_Ax2 :
forall X, inductive X -> sub om X.
Proof.
intros X H. destruct (classof_ex X) as [s ->].
apply classof_sub. now apply AomAx2, Ainductive_inductive.
Qed.
End Model.