open import Level
open import Ordinals
module generic-filter {n : Level } (O : Ordinals {n})   where

import filter 
open import zf
open import logic
-- open import partfunc {n} O
import OD 

open import Relation.Nullary 
open import Relation.Binary 
open import Data.Empty 
open import Relation.Binary
open import Relation.Binary.Core
open import Relation.Binary.PropositionalEquality
open import Data.Nat renaming ( zero to Zero ; suc to Suc ;  ℕ to Nat ; _⊔_ to _n⊔_ ) 
import BAlgbra 

open BAlgbra O

open inOrdinal O
open OD O
open OD.OD
open ODAxiom odAxiom
import OrdUtil
import ODUtil
open Ordinals.Ordinals  O
open Ordinals.IsOrdinals isOrdinal
open Ordinals.IsNext isNext
open OrdUtil O
open ODUtil O


import ODC

open filter O

open _∧_
open _∨_
open Bool


open HOD

-------
--    the set of finite partial functions from ω to 2
--
--

open import Data.List hiding (filter)
open import Data.Maybe 

import OPair
open OPair O

record CountableModel : Set (suc (suc n)) where
   field
       ctl-M : Ordinal
       ctl→ : Nat → Ordinal
       ctl<M : (x : Nat) → odef (* ctl-M) (ctl→ x) 
       ctl← : (x : Ordinal )→  odef (* ctl-M ) x → Nat
       ctl-iso→ : { x : Ordinal } → (lt : odef (* ctl-M) x )  → ctl→ (ctl← x lt ) ≡ x 
       ctl-iso← : { x : Nat }  →  ctl← (ctl→ x ) (ctl<M x)  ≡ x
--
-- almmost universe
-- find-p contains ∃ x : Ordinal → x o< & M → ∀ r ∈ M → ∈ Ord x
-- 

-- we expect  P ∈ * ctl-M ∧ G  ⊆ L ⊆ Power P  , ¬ G ∈ * ctl-M, 

open CountableModel 

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

---
--   p(n+1) = if (f n) != ∅ then (f n) otherwise p(n)
--  
find-p :  (L : HOD ) (C : CountableModel )  (i : Nat) → (x : Ordinal) → Ordinal
find-p L C Zero x = x
find-p L C (Suc i) x with is-o∅ ( & ( PGHOD i L C (find-p L C i x)) )
... | yes y  = find-p L C i x
... | no not  = & (ODC.minimal O ( PGHOD i L C (find-p L C i x)) (λ eq → not (=od∅→≡o∅ eq)))  -- axiom of choice

---
-- G = { r ∈ L ⊆ Power P | ∃ n → p(n) ⊆ r }
--
record PDN  (L p : HOD ) (C : CountableModel )  (x : Ordinal) : Set n where
   field
       gr : Nat
       pn<gr : (y : Ordinal) → odef (* (find-p L C gr (& p))) y → odef (* x) y 
       x∈PP  : odef L x

open PDN

---
-- G as a HOD
--
PDHOD :  (L p : HOD ) (C : CountableModel  ) → HOD
PDHOD L p C  = record { od = record { def = λ x →  PDN L p C x }
    ; odmax = odmax L ; <odmax = λ {y} lt → <odmax L {y} (PDN.x∈PP lt)  } 

open PDN

----
--  Generic Filter on Power P for HOD's Countable Ordinal (G ⊆ Power P ≡ G i.e. Nat → P → Set )
--
--  p 0 ≡ ∅
--  p (suc n) = if ∃ q ∈ M ∧ p n ⊆ q → q  (by axiom of choice) ( q =  * ( ctl→ n ) )
---             else p n

P∅ : {P : HOD} → odef (Power P) o∅
P∅ {P} =  subst (λ k → odef (Power P) k ) ord-od∅ (lemma o∅  o∅≡od∅) where
    lemma : (x : Ordinal ) → * x ≡ od∅ → odef (Power P) (& od∅)
    lemma x eq = power← P od∅  (λ {x} lt → ⊥-elim (¬x<0 lt ))
x<y→∋ : {x y : Ordinal} → odef (* x) y → * x ∋ * y
x<y→∋ {x} {y} lt = subst (λ k → odef (* x) k ) (sym &iso) lt

open import Data.Nat.Properties
open import nat
open _⊆_

p-monotonic1 :  (L p : HOD ) (C : CountableModel  ) → {n : Nat} → (* (find-p L C (Suc n) (& p))) ⊆ (* (find-p L C n (& p)))
p-monotonic1 L p C {n} with is-o∅ (& (PGHOD n L C (find-p L C n (& p))))
... | yes y =   refl-⊆
... | no not = record { incl = λ {x} lt → proj2 (proj2 fmin∈PGHOD) (& x) lt  } where
    fmin : HOD
    fmin = ODC.minimal O (PGHOD n L C (find-p L C n (& p))) (λ eq → not (=od∅→≡o∅ eq))
    fmin∈PGHOD : PGHOD n L C (find-p L C n (& p)) ∋ fmin
    fmin∈PGHOD = ODC.x∋minimal O (PGHOD n L C (find-p L C n (& p))) (λ eq → not (=od∅→≡o∅ eq))

p-monotonic :  (L p : HOD ) (C : CountableModel  ) → {n m : Nat} → n ≤ m → (* (find-p L C m (& p))) ⊆ (* (find-p L C n (& p)))
p-monotonic L p C {Zero} {Zero} n≤m = refl-⊆
p-monotonic L p C {Zero} {Suc m} z≤n = trans-⊆ (p-monotonic1 L p C {m} )  (p-monotonic L p C {Zero} {m} z≤n ) 
p-monotonic L p C {Suc n} {Suc m} (s≤s n≤m) with <-cmp n m
... | tri< a ¬b ¬c = trans-⊆ (p-monotonic1 L p C {m}) (p-monotonic L p C {Suc n} {m} a)   
... | tri≈ ¬a refl ¬c = refl-⊆
... | tri> ¬a ¬b c = ⊥-elim ( nat-≤> n≤m c )

P-GenericFilter : (P L p0 : HOD ) → (LP : L ⊆ Power P) → L ∋ p0 → (C : CountableModel ) → GenericFilter LP
P-GenericFilter P L p0 L⊆PP Lp0 C = record {
      genf = record { filter = PDHOD L p0 C ; f⊆L =  f⊆PL ; filter1 = {!!} ; filter2 = {!!}  }
    ; generic = {!!}
   } where
        PGHOD∈PL :  (i : Nat) → (x : Ordinal) →  PGHOD i L C x ⊆ Power P
        PGHOD∈PL i x = record { incl = λ {x} p → {!!}  }
        Pp0 : p0 ∈ Power P
        Pp0 = {!!}
        f⊆PL :  PDHOD L p0 C ⊆ L -- Power P
        f⊆PL = record { incl = λ {x} lt →  {!!} } -- x∈PP lt  }
        f1 : {p q : HOD} → q ⊆ P → PDHOD P p0 C ∋ p → p ⊆ q → PDHOD P p0 C ∋ q
        f1 {p} {q}  q⊆P PD∋p p⊆q =  record { gr = gr PD∋p ;  pn<gr = f04 ; x∈PP = {!!} } where -- power←  _ _ (incl q⊆P) } where
           f04 : (y : Ordinal) → odef (* (find-p P C (gr PD∋p) (& p0))) y → odef (* (& q)) y
           f04 y lt1 = subst₂ (λ j k → odef j k ) (sym *iso) &iso (incl p⊆q (subst₂ (λ j k → odef k j ) (sym &iso) *iso ( pn<gr PD∋p y  lt1 )))
               -- odef (* (find-p P C (gr PD∋p) (& p0))) y → odef (* (& q)) y
        f2 : {p q : HOD} → PDHOD P p0 C ∋ p → PDHOD P p0 C ∋ q → PDHOD P p0 C ∋ (p ∩ q)
        f2 {p} {q} PD∋p PD∋q with <-cmp (gr PD∋q) (gr PD∋p)
        ... | tri< a ¬b ¬c = record { gr = gr PD∋p ;  pn<gr = λ y lt → subst (λ k → odef k y ) (sym *iso) (f3 y lt); x∈PP = {!!} } where
                -- ODC.power-∩ O (x∈PP PD∋p) (x∈PP PD∋q)   }  where
            f3 : (y : Ordinal) → odef (* (find-p P C (gr PD∋p) (& p0))) y → odef (p ∩ q) y
            f3 y lt = ⟪ subst (λ k → odef k y) *iso (pn<gr PD∋p y lt) , subst (λ k → odef k y) *iso (pn<gr PD∋q y (f5 lt)) ⟫ where
               f5 : odef (* (find-p P C (gr PD∋p) (& p0))) y → odef (* (find-p P C (gr PD∋q) (& p0))) y
               f5 lt = subst (λ k → odef (* (find-p P C (gr PD∋q) (& p0))) k ) &iso ( incl (p-monotonic P p0 C {gr PD∋q} {gr PD∋p} (<to≤ a))
                   (subst (λ k → odef (* (find-p P C (gr PD∋p) (& p0))) k ) (sym &iso) lt) )
        ... | tri≈ ¬a refl ¬c = record { gr = gr PD∋p ;  pn<gr =  λ y lt → subst (λ k → odef k y ) (sym *iso) (f4 y lt);  x∈PP = {!!} } where
               -- ODC.power-∩ O (x∈PP PD∋p) (x∈PP PD∋q)   }  where
            f4 : (y : Ordinal) → odef (* (find-p P C (gr PD∋p) (& p0))) y → odef (p ∩ q) y
            f4 y lt = ⟪ subst (λ k → odef k y) *iso (pn<gr PD∋p y lt) , subst (λ k → odef k y) *iso (pn<gr PD∋q y lt) ⟫ 
        ... | tri> ¬a ¬b c = record { gr = gr PD∋q ;  pn<gr =  λ y lt → subst (λ k → odef k y ) (sym *iso) (f3 y lt) ; x∈PP = {!!} } where --
           -- ODC.power-∩ O (x∈PP PD∋p) (x∈PP PD∋q)   } where
            f3 : (y : Ordinal) → odef (* (find-p P C (gr PD∋q) (& p0))) y → odef (p ∩ q) y
            f3 y lt = ⟪ subst (λ k → odef k y) *iso (pn<gr PD∋p y (f5 lt)) , subst (λ k → odef k y) *iso (pn<gr PD∋q y lt) ⟫ where
               f5 : odef (* (find-p P C (gr PD∋q) (& p0))) y → odef (* (find-p P C (gr PD∋p) (& p0))) y
               f5 lt = subst (λ k → odef (* (find-p P C (gr PD∋p) (& p0))) k ) &iso ( incl (p-monotonic P p0 C {gr PD∋p} {gr PD∋q} (<to≤ c))
                   (subst (λ k → odef (* (find-p P C (gr PD∋q) (& p0))) k ) (sym &iso) lt) )
        fdense : (D : Dense L⊆PP ) → ¬ (filter.Dense.dense D ∩ PDHOD P p0 C) ≡ od∅
        fdense D eq0  = ⊥-elim (  ∅< {Dense.dense D ∩ PDHOD P p0 C} fd01 (≡od∅→=od∅ eq0 )) where
           open Dense
           p0⊆P : L ∋ p0 
           p0⊆P = {!!}
           fd : HOD
           fd = dense-f D p0⊆P
           PP∋D : dense D ⊆ Power P
           PP∋D = {!!} 
           fd00 : PDHOD P p0 C ∋ p0
           fd00 = record { gr = 0 ; pn<gr = λ y lt → lt ; x∈PP = {!!}  }
           fd02 : dense D ∋ dense-f D {!!} -- p0⊆P
           fd02 = dense-d D {!!}
           fd04 : dense-f D p0⊆P ⊆ P
           fd04 = ODC.power→⊆ O _ _ ( incl PP∋D fd02 )
           fd03 : PDHOD P p0 C  ∋ dense-f D p0⊆P
           fd03 = {!!}
           -- f1 {p0} {dense-f D p0⊆P} fd04 fd00 ( dense-p D (ODC.power→⊆ O _ _ Pp0 ) )
           fd01 : (dense D ∩ PDHOD P p0 C) ∋ fd
           fd01 = ⟪ fd02 , fd03 ⟫ 

open GenericFilter
open Filter

record Incompatible  (P p : HOD ) (PP∋p : p  ⊆ P ) : Set (suc (suc n)) where
   field
      q r : HOD
      PP∋q : q ⊆ P 
      PP∋r : r ⊆ P 
      p⊆q :  p ⊆ q 
      p⊆r :  p ⊆ r 
      incompatible : ∀ ( s : HOD ) → s ⊆ P → (¬ ( q ⊆ s  )) ∨ (¬ ( r ⊆ s ))

lemma725 : (P p : HOD ) (C : CountableModel ) 
    →  (PP∋p : Power P ∋ p )
    →  * (ctl-M C) ∋ (Power P ∩  * (ctl-M C))                -- M is a Model of ZF
    →  * (ctl-M C) ∋ {!!} -- ( (Power P ∩  * (ctl-M C))  ＼ filter ( genf ( P-GenericFilter P ? p ?  C ? )) )      -- M ∋ G and M is a Model of ZF 
    →  ((p : HOD) → (PP∋p : p  ⊆ P ) → Incompatible P p PP∋p )
    → ¬ ( * (ctl-M C) ∋ filter {!!} ) -- ( genf ( P-GenericFilter P ? ? p PP∋p C )))
lemma725 P p C PP∋p M∋PM M∋D I M∋G = D∩G≠∅ D∩G=∅ where
    G = filter ( genf ( P-GenericFilter P {!!} p {!!} {!!} C ))
    M = * (ctl-M C)
    D : HOD
    D = Power P ＼ G
    p⊆P : p ⊆ P
    p⊆P =  ODC.power→⊆ O _ _ PP∋p
    df : {x : HOD} → x ⊆ P → HOD
    df {x} PP∋x with ODC.∋-p O G ( Incompatible.r (I x PP∋x) )
    ... | yes y = Incompatible.q (I x PP∋x) 
    ... | no n  = Incompatible.r (I x PP∋x) 
    df¬⊆P : {x : HOD} → (lt : x ⊆ P) → df lt  ⊆ P 
    df¬⊆P {x} PP∋x with ODC.∋-p O G ( Incompatible.r (I x PP∋x) )
    ... | yes _ = Incompatible.PP∋q (I x PP∋x)
    ... | no _  = Incompatible.PP∋r (I x PP∋x)
    ¬G∋df : {x : HOD} → (lt : x ⊆ P) → ¬ G ∋ (df lt ) 
    ¬G∋df {x} lt with ODC.∋-p O G ( Incompatible.r (I x lt ) )
    ... | no n = n
    ... | yes y with Incompatible.incompatible (I x lt ) (Incompatible.q (I x lt )) (Incompatible.PP∋q  (I x lt ))
    ... | case1 ¬q⊆pn = λ _ → ¬q⊆pn refl-⊆
    ... | case2 ¬r⊆pn = {!!}
    df-d : {x : HOD} → (lt : x ⊆ P) → D ∋ df lt
    df-d {x} lt = ⟪  power← P _ (incl (df¬⊆P lt)) , ¬G∋df lt ⟫
    df-p : {x : HOD} → (lt : x ⊆ P) → x ⊆ df lt
    df-p {x} lt with ODC.∋-p O G ( Incompatible.r (I x lt) )
    ... | yes _ = Incompatible.p⊆q (I x lt) 
    ... | no _ = Incompatible.p⊆r (I x lt) 
    D-Dense : Dense {!!}
    D-Dense = record {
           dense = D
       ;   d⊆P = record { incl = λ {x} lt → {!!} }
       ;   dense-f = {!!}
       ;   dense-d = {!!}
       ;   dense-p = {!!}
     }
    D∩G=∅ : ( D ∩ G ) =h= od∅ 
    D∩G=∅ = ≡od∅→=od∅ ([a-b]∩b=0 {Power P} {G})
    D∩G≠∅ : ¬ (( D ∩ G ) =h= od∅ )
    D∩G≠∅ eq = generic (P-GenericFilter P {!!} {!!} {!!} {!!} C) D-Dense ( ==→o≡ eq )

open import PFOD O

-- HODω2 : HOD
-- 
-- ω→2 : HOD
-- ω→2 = Power infinite

lemma725-1 :  (p : HOD) → (PP∋p : p  ⊆ HODω2 ) → Incompatible HODω2 p PP∋p
lemma725-1 = {!!}

lemma726 :  (C : CountableModel ) 
    →  Union ( Replace' (Power (ω→2 ＼ HODω2)) (λ p lt → filter ( genf ( P-GenericFilter {!!} (ω→2 ＼ HODω2) p {!!}  {!!} C )))) =h= ω→2 -- HODω2 ∋ p
lemma726 = {!!}

--
--   val x G = { val y G | ∃ p → G ∋ p → x ∋ < y , p > }
--

record valR (x : HOD) {P L : HOD} {LP : L ⊆ Power P} (G : GenericFilter LP) : Set (suc n) where
   field
     valx : HOD

record valS (ox oy oG : Ordinal) : Set n where
   field
     op : Ordinal
     p∈G : odef (* oG) op 
     is-val : odef (* ox) ( & < * oy , * op >  )

val : (x : HOD) {P L : HOD } {LP : L ⊆ Power P}
    →  (G : GenericFilter LP)
    →  HOD
val x G = TransFinite {λ x → HOD } ind (& x) where
  ind : (x : Ordinal) → ((y : Ordinal) → y o< x → HOD) → HOD
  ind x valy = record { od = record { def = λ y → valS x y (& (filter (genf G))) } ; odmax = {!!} ; <odmax = {!!} }


--
--   W (ω , H ( ω , 2 )) = { p ∈ ( Nat → H (ω , 2) ) |  { i ∈ Nat → p i ≠ i1 } is finite }
--