Mercurial > hg > Members > kono > Proof > ZF-in-agda

--- a/generic-filter.agda	Wed Jul 29 21:51:00 2020 +0900
+++ b/generic-filter.agda	Thu Jul 30 00:29:50 2020 +0900
@@ -143,32 +143,10 @@

 open _⊆_

-ω→2f-iso : (X : HOD) → ( lt : ω→2 ∋ X ) → fω→2 ( ω→2f X lt )  =h= X
-ω→2f-iso X lt = record {
-     eq→ = eq1
-   ; eq← = eq2
-  } where
-     X⊆ω : {x : HOD } → X ∋ x → infinite ∋ x
-     X⊆ω {x} x<X = incl (ODC.power→⊆ O infinite X lt ) x<X
-     eq1 : {x : Ordinal} → odef (fω→2 (ω→2f X lt)) x → odef X x
-     eq1 {x} fx = {!!} where
-         x-nat : odef infinite x
-         x-nat =  subst (λ k → odef infinite k) diso ( ODC.double-neg-eilm O
-             (power→ infinite _ (ω2∋f (ω→2f X lt)) (d→∋ (fω→2 (ω→2f X lt)) fx )))
-         i : Nat
-         i = ω→nat (ord→od x) (d→∋ infinite x-nat)
-         is-i1 : ω→2f X lt i ≡ i1
-         is-i1 = {!!}
-     eq2 : {x : Ordinal} → odef X x → odef (fω→2 (ω→2f X lt)) x
-     eq2 {x} Xx = {!!} where
-         x-nat : odef infinite x
-         x-nat = subst ( λ k → odef infinite k ) diso ( X⊆ω (subst(λ k → odef X  k ) (sym diso ) Xx) )
-
-fω→2-iso : (f : Nat → Two) → ω→2f ( fω→2 f ) (ω2∋f f) ≡ f
-fω→2-iso f = f-extensionality (λ x → eq1 x ) where
-     eq1 : (x : Nat) → ω→2f (fω→2 f) (ω2∋f f) x ≡ f x
-     eq1 x = {!!}
-
+-- someday ...
+postulate
+   ω→2f-iso : (X : HOD) → ( lt : ω→2 ∋ X ) → fω→2 ( ω→2f X lt )  =h= X
+   fω→2-iso : (f : Nat → Two) → ω→2f ( fω→2 f ) (ω2∋f f) ≡ f

 ↑n : (f n : HOD) → ((ω→2 ∋ f ) ∧ (infinite ∋ n)) → HOD
 ↑n f n lt = 3→Hω2 ( ω→2f f (proj1 lt) 3↑ (ω→nat n (proj2 lt) ))
@@ -193,41 +171,70 @@
 open CountableOrdinal
 open CountableHOD

+----
+--   a(n) ∈ M
+--   ∃ q ∈ Power P → q ∈ a(n) ∧ p(n) ⊆ q
+--
 PGHOD :  (i : Nat) → (C : CountableOrdinal) → (P : HOD) → (p : Ordinal) → HOD
-PGHOD i C P p = record { od = record { def = λ x  → odef P x ∧ odef (ord→od (ctl→ C i)) x  ∧  ( (y : Ordinal ) → odef (ord→od p) y →  odef (ord→od x) y ) }
+PGHOD i C P p = record { od = record { def = λ x  →
+       odef P x ∧ odef (ord→od (ctl→ C i)) x  ∧  ( (y : Ordinal ) → odef (ord→od p) y →  odef (ord→od x) y ) }
    ; odmax = odmax P  ; <odmax = λ {y} lt → <odmax P (proj1 lt) }

+---
+--   p(n+1) = if PGHOD n qn otherwise p(n)
+--
 next-p :  (C : CountableOrdinal) (P : HOD ) (i : Nat) → (p : Ordinal) → Ordinal
 next-p C P i p with ODC.decp O ( PGHOD i C P p =h= od∅ )
 next-p C P i p | yes y = p
 next-p C P i p | no not = od→ord (ODC.minimal O (PGHOD i C P p ) not)

+---
+--  ascendant search on p(n)
+--
 find-p :  (C : CountableOrdinal) (P : HOD ) (i : Nat) → (x : Ordinal) → Ordinal
 find-p C P Zero x = x
 find-p C P (Suc i) x = find-p C P i ( next-p C P i x )

+---
+-- G = { r ∈ Power P | ∃ n → r ⊆ p(n) }
+--
 record PDN  (C : CountableOrdinal) (P : HOD ) (x : Ordinal) : Set n where
    field
        gr : Nat
        pn<gr : (y : Ordinal) → odef (ord→od x) y → odef (ord→od (find-p C P gr o∅)) y
-       px∈ω  : odef P x
+       px∈ω  : odef (Power P) x

 open PDN

+---
+-- G as an HOD
+--
 PDHOD :  (C : CountableOrdinal) → (P : HOD ) → HOD
 PDHOD C P = record { od = record { def = λ x →  PDN C P x }
-    ; odmax = odmax (Power P) ; <odmax = {!!}  } where
+    ; odmax = odmax (Power P) ; <odmax = λ {y} lt → <odmax (Power P) {y} (PDN.px∈ω lt)  } where

 --
 --  p 0 ≡ ∅
 --  p (suc n) = if ∃ q ∈ ord→od ( ctl→ n ) ∧ p n ⊆ q → q
 ---             else p n

+open PDN
+
+----
+--  Generic Filter on Power P for HOD's Ordinal
+--
 P-GenericFilter : (C : CountableOrdinal) → (P : HOD ) → GenericFilter P
 P-GenericFilter C P = record {
-      genf = record { filter = PDHOD C P ; f⊆PL = {!!} ; filter1 = {!!} ; filter2 = {!!} }
+      genf = record { filter = PDHOD C P ; f⊆PL =  f⊆PL ; filter1 = {!!} ; filter2 = {!!} }
     ; generic = λ D → {!!}
-   }
+   } where
+        find-p-⊆P : (C : CountableOrdinal) (P : HOD ) (i : Nat) → (x y : Ordinal)  → odef (ord→od (find-p C P i x)) y → odef P y
+        find-p-⊆P C P Zero x y Py = {!!}
+        find-p-⊆P C P (Suc i) x y Py = {!!} -- find-p-⊆P C P i x {!!}
+        f⊆PL :  PDHOD C P ⊆ Power P
+        f⊆PL = record { incl = λ {x} lt → power← P x (λ {y} y<x →
+             find-p-⊆P C P (gr lt) o∅ (od→ord y) (pn<gr lt (od→ord y) (subst (λ k → odef k (od→ord y)) (sym oiso) y<x))) }
+

 open GenericFilter
 open Filter
@@ -235,11 +242,11 @@
 record Incompatible  (P : HOD ) : Set (suc (suc n)) where
    field
       except : HOD → ( HOD ∧ HOD )
-      incompatible : { p : HOD } →  P ∋ p  →  P ∋ proj1 (except p )  →  P ∋ proj2 (except p )
+      incompatible : { p : HOD } →  Power P ∋ p  →  Power P ∋ proj1 (except p )  →  Power P ∋ proj2 (except p )
           → ( p ⊆ proj1 (except p)  ) ∧ ( p ⊆ proj2 (except p)  )
-          → ∀ ( r : HOD ) →  P ∋ r → ¬ (( proj1 (except p)  ⊆ r ) ∧ ( proj2 (except p)  ⊆ r ))
+          → ∀ ( r : HOD ) →  Power P ∋ r → ¬ (( proj1 (except p)  ⊆ r ) ∧ ( proj2 (except p)  ⊆ r ))

-lemma725 : (M : CountableHOD ) (C : CountableOrdinal) (P : HOD ) →  mhod M ∋ P
+lemma725 : (M : CountableHOD ) (C : CountableOrdinal) (P : HOD ) →  mhod M ∋ Power P
     →  Incompatible P → ¬ ( mhod M ∋ filter ( genf ( P-GenericFilter C P )))
 lemma725 = {!!}