Library ZFskol
Require Import basic.
Require Export ZFdef.
Module Skolem (Z : IZF_Ex_sig) <: IZF_sig.
Instance Zsetoid: Equivalence Z.eq_set.
Instance Zin_morph : Proper (Z.eq_set ==> Z.eq_set ==> iff) Z.in_set.
Definition set :=
{ f : Z.set -> Prop |
(exists u, f u) /\
(forall a a', f a -> f a' -> Z.eq_set a a') }.
Lemma set_intro : forall (f:Z.set->Prop) (P:set->Prop),
(exists u, f u) ->
(forall a a', f a -> f a' -> Z.eq_set a a') ->
(forall Hex Huniq, P (exist _ f (conj Hex Huniq))) ->
sig P.
Inductive in_set_ (x y:set) : Prop :=
InSet
(_:exists2 x', proj1_sig x x' &
exists2 y', proj1_sig y y' & Z.in_set x' y').
Definition in_set := in_set_.
Lemma in_set_elim : forall x y, in_set x y <->
exists2 x', proj1_sig x x' &
exists2 y', proj1_sig y y' & Z.in_set x' y'.
Notation "x \in y" := (in_set x y) (at level 60).
Definition eq_set a b := forall x, x \in a <-> x \in b.
Notation "x == y" := (eq_set x y) (at level 70).
Lemma eq_set_ax : forall a b, a == b <-> (forall x, x \in a <-> x \in b).
Instance eq_setoid: Equivalence eq_set.
Lemma In_intro: forall x y: set,
(forall x' y', proj1_sig x x' -> proj1_sig y y' -> Z.in_set x' y') ->
x \in y.
Definition Z2set (x:Z.set) : set.
Defined.
Lemma Z2set_surj : forall x, exists y, x == Z2set y.
Lemma Eq_proj : forall (x:set) x', proj1_sig x x' -> x == Z2set x'.
Lemma inZ_in : forall a b, Z.in_set a b -> Z2set a \in Z2set b.
Lemma in_inZ : forall a b, Z2set a \in Z2set b -> Z.in_set a b.
Lemma eq_Zeq : forall x y, Z2set x == Z2set y -> Z.eq_set x y.
Lemma Zeq_eq : forall x y, Z.eq_set x y -> Z2set x == Z2set y.
Instance Z2set_morph : Proper (Z.eq_set ==> eq_set) Z2set.
Qed.
Lemma in_reg : forall a a' b, a == a' -> a \in b -> a' \in b.
Instance in_morph : Proper (eq_set ==> eq_set ==> iff) in_set.
Lemma empty_sig : { empty | forall x, ~ x \in empty }.
Definition empty := proj1_sig empty_sig.
Lemma empty_ax: forall x, ~ x \in empty.
Lemma pair_sig : forall a b,
{ pair | forall x, x \in pair <-> (x == a \/ x == b) }.
Definition pair a b := proj1_sig (pair_sig a b).
Lemma pair_ax: forall a b x, x \in pair a b <-> (x == a \/ x == b).
Lemma union_sig: forall a,
{ union | forall x, x \in union <-> (exists2 y, x \in y & y \in a) }.
Definition union a := proj1_sig (union_sig a).
Lemma union_ax: forall a x,
x \in union a <-> (exists2 y, x \in y & y \in a).
Lemma power_sig: forall a,
{ power | forall x, x \in power <-> (forall y, y \in x -> y \in a) }.
Definition power a := proj1_sig (power_sig a).
Lemma power_ax:
forall a x, x \in power a <-> (forall y, y \in x -> y \in a).
Definition funDom (R:set -> set -> Prop) x :=
forall x' y y', R x y -> R x' y' -> x == x' -> y == y'.
Definition downR (R:set -> set -> Prop) x' y' :=
exists2 x, x == Z2set x' /\ funDom R x & exists2 y, y == Z2set y' & R x y.
Lemma downR_morph : Proper
((eq_set ==> eq_set ==> iff) ==> Z.eq_set ==> Z.eq_set ==> iff) downR.
Lemma downR_fun : forall R x x' y y',
downR R x y ->
downR R x' y' ->
Z.eq_set x x' ->
Z.eq_set y y'.
Lemma repl0 : forall (a:set) (R:set->set->Prop), set.
Definition incl_set x y := forall z, z \in x -> z \in y.
Lemma repl0_mono :
Proper (incl_set ==> (eq_set ==> eq_set ==> iff) ==> incl_set) repl0.
Lemma repl_sig :
{ repl |
Proper (incl_set ==> (eq_set ==> eq_set ==> iff) ==> incl_set) repl /\
forall a (R:set->set->Prop),
(forall x x' y y', x \in a -> R x y -> R x' y' -> x == x' -> y == y') ->
forall x, x \in repl a R <-> (exists2 y, y \in a & exists2 x', x == x' & R y x') }.
Definition repl := proj1_sig repl_sig.
Lemma repl_mono :
Proper (incl_set ==> (eq_set ==> eq_set ==> iff) ==> incl_set) repl.
Lemma repl_ax:
forall a (R:set->set->Prop),
(forall x x' y y', x \in a -> R x y -> R x' y' -> x == x' -> y == y') ->
forall x, x \in repl a R <-> (exists2 y, y \in a & exists2 x', x == x' & R y x').
Definition Nat x :=
forall (P:set),
empty \in P ->
(forall x, x \in P -> union (pair x (pair x x)) \in P) ->
x \in P.
Instance Nat_morph : Proper (eq_set ==> iff) Nat.
Qed.
Lemma Nat_S : forall x,
Nat x -> Nat (union (pair x (pair x x))).
Definition infinite_sig :
{ infty | empty \in infty /\
forall x, x \in infty -> union (pair x (pair x x)) \in infty }.
Qed.
Definition infinite := proj1_sig infinite_sig.
Lemma infinity_ax1: empty \in infinite.
Lemma infinity_ax2: forall x,
x \in infinite -> union (pair x (pair x x)) \in infinite.
Lemma regularity_ax: forall a a0, a0 \in a ->
exists2 b, b \in a & ~(exists2 c, c \in a & c \in b).
End Skolem.