Mercurial > hg > Members > kono > Proof > ZF-in-agda
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author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Sat, 21 Jan 2023 09:02:52 +0900 |
parents | 0a6040d914f8 |
children | 5e065f0a7ba2 |
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open import Level open import Ordinals module Topology {n : Level } (O : Ordinals {n}) where open import zf open import logic open _∧_ open _∨_ open Bool import OD open import Relation.Nullary open import Data.Empty open import Relation.Binary.Core open import Relation.Binary.Definitions open import Relation.Binary.PropositionalEquality import BAlgebra open BAlgebra 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 ODC O open import filter O open import OPair O record Topology ( L : HOD ) : Set (suc n) where field OS : HOD OS⊆PL : OS ⊆ Power L o∩ : { p q : HOD } → OS ∋ p → OS ∋ q → OS ∋ (p ∩ q) o∪ : { P : HOD } → P ⊆ OS → OS ∋ Union P OS∋od∅ : OS ∋ od∅ --- we may add -- OS∋L : OS ∋ L -- closed Set CS : HOD CS = record { od = record { def = λ x → (* x ⊆ L) ∧ odef OS (& ( L \ (* x ))) } ; odmax = osuc (& L) ; <odmax = tp02 } where tp02 : {y : Ordinal } → (* y ⊆ L) ∧ odef OS (& (L \ * y)) → y o< osuc (& L) tp02 {y} nop = subst (λ k → k o≤ & L ) &iso ( ⊆→o≤ (λ {x} yx → proj1 nop yx )) os⊆L : {x : HOD} → OS ∋ x → x ⊆ L os⊆L {x} Ox {y} xy = ( OS⊆PL Ox ) _ (subst (λ k → odef k y) (sym *iso) xy ) cs⊆L : {x : HOD} → CS ∋ x → x ⊆ L cs⊆L {x} Cx {y} xy = proj1 Cx (subst (λ k → odef k y ) (sym *iso) xy ) CS∋L : CS ∋ L CS∋L = ⟪ subst (λ k → k ⊆ L) (sym *iso) (λ x → x) , subst (λ k → odef OS (& k)) (sym lem0) OS∋od∅ ⟫ where lem0 : L \ * (& L) ≡ od∅ lem0 = subst (λ k → L \ k ≡ od∅) (sym *iso) L\L=0 CS⊆PL : CS ⊆ Power L CS⊆PL {x} Cx y xy = proj1 Cx xy P\CS=OS : {cs : HOD} → CS ∋ cs → OS ∋ ( L \ cs ) P\CS=OS {cs} ⟪ cs⊆L , olcs ⟫ = subst (λ k → odef OS k) (cong (λ k → & ( L \ k)) *iso) olcs P\OS=CS : {cs : HOD} → OS ∋ cs → CS ∋ ( L \ cs ) P\OS=CS {os} oos = ⟪ subst (λ k → k ⊆ L) (sym *iso) proj1 , subst (λ k → odef OS k) (cong (&) (trans (sym (L\Lx=x (os⊆L oos))) (cong (λ k → L \ k) (sym *iso)) )) oos ⟫ open Topology -- Closure ( Intersection of Closed Set which include A ) Cl : {L : HOD} → (top : Topology L) → (A : HOD) → HOD Cl {L} top A = record { od = record { def = λ x → odef L x ∧ ( (c : Ordinal) → odef (CS top) c → A ⊆ * c → odef (* c) x ) } ; odmax = & L ; <odmax = odef∧< } ClL : {L : HOD} → (top : Topology L) → Cl top L ≡ L ClL {L} top = ==→o≡ ( record { eq→ = λ {x} ic → subst (λ k → odef k x) *iso ((proj2 ic) (& L) (CS∋L top) (subst (λ k → L ⊆ k) (sym *iso) ( λ x → x))) ; eq← = λ {x} lx → ⟪ lx , ( λ c cs l⊆c → l⊆c lx) ⟫ } ) -- Closure is Closed Set CS∋Cl : {L : HOD} → (top : Topology L) → (A : HOD) → CS top ∋ Cl top A CS∋Cl {L} top A = subst (λ k → CS top ∋ k) (==→o≡ cc00) (P\OS=CS top UOCl-is-OS) where OCl : HOD -- set of open set which it not contains A OCl = record { od = record { def = λ o → odef (OS top) o ∧ ( A ⊆ (L \ * o) ) } ; odmax = & (OS top) ; <odmax = odef∧< } OCl⊆OS : OCl ⊆ OS top OCl⊆OS ox = proj1 ox UOCl-is-OS : OS top ∋ Union OCl UOCl-is-OS = o∪ top OCl⊆OS cc00 : (L \ Union OCl) =h= Cl top A cc00 = record { eq→ = cc01 ; eq← = cc03 } where cc01 : {x : Ordinal} → odef (L \ Union OCl) x → odef L x ∧ ((c : Ordinal) → odef (CS top) c → A ⊆ * c → odef (* c) x) cc01 {x} ⟪ Lx , nul ⟫ = ⟪ Lx , ( λ c cc ac → cc02 c cc ac nul ) ⟫ where cc02 : (c : Ordinal) → odef (CS top) c → A ⊆ * c → ¬ odef (Union OCl) x → odef (* c) x cc02 c cc ac nox with ODC.∋-p O (* c) (* x) ... | yes y = subst (λ k → odef (* c) k) &iso y ... | no ncx = ⊥-elim ( nox record { owner = & ( L \ * c) ; ao = ⟪ proj2 cc , cc07 ⟫ ; ox = subst (λ k → odef k x) (sym *iso) cc06 } ) where cc06 : odef (L \ * c) x cc06 = ⟪ Lx , subst (λ k → ¬ odef (* c) k) &iso ncx ⟫ cc08 : * c ⊆ L cc08 = cs⊆L top (subst (λ k → odef (CS top) k ) (sym &iso) cc ) cc07 : A ⊆ (L \ * (& (L \ * c))) cc07 {z} az = subst (λ k → odef k z ) ( begin * c ≡⟨ sym ( L\Lx=x cc08 ) ⟩ L \ (L \ * c) ≡⟨ cong (λ k → L \ k ) (sym *iso) ⟩ L \ * (& (L \ * c)) ∎ ) ( ac az ) where open ≡-Reasoning cc03 : {x : Ordinal} → odef L x ∧ ((c : Ordinal) → odef (CS top) c → A ⊆ * c → odef (* c) x) → odef (L \ Union OCl) x cc03 {x} ⟪ Lx , ccx ⟫ = ⟪ Lx , cc04 ⟫ where -- if x is in Cl A, it is in some c : CS, OCl says it is not , i.e. L \ o ∋ x, so it is in (L \ Union OCl) x cc04 : ¬ odef (Union OCl) x cc04 record { owner = o ; ao = ⟪ oo , A⊆L-o ⟫ ; ox = ox } = proj2 ( subst (λ k → odef k x) *iso cc05) ox where cc05 : odef (* (& (L \ * o))) x cc05 = ccx (& (L \ * o)) (P\OS=CS top (subst (λ k → odef (OS top) k) (sym &iso) oo)) (subst (λ k → A ⊆ k) (sym *iso) A⊆L-o) -- Subbase P -- A set of countable intersection of P will be a base (x ix an element of the base) data Subbase (P : HOD) : Ordinal → Set n where gi : {x : Ordinal } → odef P x → Subbase P x g∩ : {x y : Ordinal } → Subbase P x → Subbase P y → Subbase P (& (* x ∩ * y)) -- -- if y is in a Subbase, some element of P contains it sbp : (P : HOD) {x : Ordinal } → Subbase P x → Ordinal sbp P {x} (gi {y} px) = x sbp P {.(& (* _ ∩ * _))} (g∩ sb sb₁) = sbp P sb is-sbp : (P : HOD) {x y : Ordinal } → (px : Subbase P x) → odef (* x) y → odef P (sbp P px ) ∧ odef (* (sbp P px)) y is-sbp P {x} (gi px) xy = ⟪ px , xy ⟫ is-sbp P {.(& (* _ ∩ * _))} (g∩ {x} {y} px px₁) xy = is-sbp P px (proj1 (subst (λ k → odef k _ ) *iso xy)) sb⊆ : {P Q : HOD} {x : Ordinal } → P ⊆ Q → Subbase P x → Subbase Q x sb⊆ {P} {Q} P⊆Q (gi px) = gi (P⊆Q px) sb⊆ {P} {Q} P⊆Q (g∩ px qx) = g∩ (sb⊆ P⊆Q px) (sb⊆ P⊆Q qx) -- An open set generate from a base -- -- OS = { U ⊆ L | ∀ x ∈ U → ∃ b ∈ P → x ∈ b ⊆ U } record Base (L P : HOD) (u x : Ordinal) : Set n where field b : Ordinal u⊆L : * u ⊆ L sb : Subbase P b b⊆u : * b ⊆ * u bx : odef (* b) x x⊆L : odef L x x⊆L = u⊆L (b⊆u bx) SO : (L P : HOD) → HOD SO L P = record { od = record { def = λ u → {x : Ordinal } → odef (* u) x → Base L P u x } ; odmax = osuc (& L) ; <odmax = tp00 } where tp00 : {y : Ordinal} → ({x : Ordinal} → odef (* y) x → Base L P y x) → y o< osuc (& L) tp00 {y} op = subst (λ k → k o≤ & L ) &iso ( ⊆→o≤ (λ {x} yx → Base.x⊆L (op yx) )) record IsSubBase (L P : HOD) : Set (suc n) where field P⊆PL : P ⊆ Power L -- we may need these if OS ∋ L is necessary -- p : {x : HOD} → L ∋ x → HOD -- Pp : {x : HOD} → {lx : L ∋ x } → P ∋ p lx -- px : {x : HOD} → {lx : L ∋ x } → p lx ∋ x InducedTopology : (L P : HOD) → IsSubBase L P → Topology L InducedTopology L P isb = record { OS = SO L P ; OS⊆PL = tp00 ; o∪ = tp02 ; o∩ = tp01 ; OS∋od∅ = tp03 } where tp03 : {x : Ordinal } → odef (* (& od∅)) x → Base L P (& od∅) x tp03 {x} 0x = ⊥-elim ( empty (* x) ( subst₂ (λ j k → odef j k ) *iso (sym &iso) 0x )) tp00 : SO L P ⊆ Power L tp00 {u} ou x ux with ou ux ... | record { b = b ; u⊆L = u⊆L ; sb = sb ; b⊆u = b⊆u ; bx = bx } = u⊆L (b⊆u bx) tp01 : {p q : HOD} → SO L P ∋ p → SO L P ∋ q → SO L P ∋ (p ∩ q) tp01 {p} {q} op oq {x} ux = record { b = b ; u⊆L = subst (λ k → k ⊆ L) (sym *iso) ul ; sb = g∩ (Base.sb (op px)) (Base.sb (oq qx)) ; b⊆u = tp08 ; bx = tp14 } where px : odef (* (& p)) x px = subst (λ k → odef k x ) (sym *iso) ( proj1 (subst (λ k → odef k _ ) *iso ux ) ) qx : odef (* (& q)) x qx = subst (λ k → odef k x ) (sym *iso) ( proj2 (subst (λ k → odef k _ ) *iso ux ) ) b : Ordinal b = & (* (Base.b (op px)) ∩ * (Base.b (oq qx))) tp08 : * b ⊆ * (& (p ∩ q) ) tp08 = subst₂ (λ j k → j ⊆ k ) (sym *iso) (sym *iso) (⊆∩-dist {(* (Base.b (op px)) ∩ * (Base.b (oq qx)))} {p} {q} tp09 tp10 ) where tp11 : * (Base.b (op px)) ⊆ * (& p ) tp11 = Base.b⊆u (op px) tp12 : * (Base.b (oq qx)) ⊆ * (& q ) tp12 = Base.b⊆u (oq qx) tp09 : (* (Base.b (op px)) ∩ * (Base.b (oq qx))) ⊆ p tp09 = ⊆∩-incl-1 {* (Base.b (op px))} {* (Base.b (oq qx))} {p} (subst (λ k → (* (Base.b (op px))) ⊆ k ) *iso tp11) tp10 : (* (Base.b (op px)) ∩ * (Base.b (oq qx))) ⊆ q tp10 = ⊆∩-incl-2 {* (Base.b (oq qx))} {* (Base.b (op px))} {q} (subst (λ k → (* (Base.b (oq qx))) ⊆ k ) *iso tp12) tp14 : odef (* (& (* (Base.b (op px)) ∩ * (Base.b (oq qx))))) x tp14 = subst (λ k → odef k x ) (sym *iso) ⟪ Base.bx (op px) , Base.bx (oq qx) ⟫ ul : (p ∩ q) ⊆ L ul = subst (λ k → k ⊆ L ) *iso (λ {z} pq → (Base.u⊆L (op px)) (pz pq) ) where pz : {z : Ordinal } → odef (* (& (p ∩ q))) z → odef (* (& p)) z pz {z} pq = subst (λ k → odef k z ) (sym *iso) ( proj1 (subst (λ k → odef k _ ) *iso pq ) ) tp02 : { q : HOD} → q ⊆ SO L P → SO L P ∋ Union q tp02 {q} q⊆O {x} ux with subst (λ k → odef k x) *iso ux ... | record { owner = y ; ao = qy ; ox = yx } with q⊆O qy yx ... | record { b = b ; u⊆L = u⊆L ; sb = sb ; b⊆u = b⊆u ; bx = bx } = record { b = b ; u⊆L = subst (λ k → k ⊆ L) (sym *iso) tp04 ; sb = sb ; b⊆u = subst ( λ k → * b ⊆ k ) (sym *iso) tp06 ; bx = bx } where tp05 : Union q ⊆ L tp05 {z} record { owner = y ; ao = qy ; ox = yx } with q⊆O qy yx ... | record { b = b ; u⊆L = u⊆L ; sb = sb ; b⊆u = b⊆u ; bx = bx } = IsSubBase.P⊆PL isb (proj1 (is-sbp P sb bx )) _ (proj2 (is-sbp P sb bx )) tp04 : Union q ⊆ L tp04 = tp05 tp06 : * b ⊆ Union q tp06 {z} bz = record { owner = y ; ao = qy ; ox = b⊆u bz } -- Product Topology open ZFProduct -- Product Topology is not -- ZFP (OS TP) (OS TQ) (box) record BaseP {P : HOD} (TP : Topology P ) (Q : HOD) (x : Ordinal) : Set n where field p q : Ordinal op : odef (OS TP) p prod : x ≡ & (ZFP (* p) Q ) record BaseQ (P : HOD) {Q : HOD} (TQ : Topology Q ) (x : Ordinal) : Set n where field p q : Ordinal oq : odef (OS TQ) q prod : x ≡ & (ZFP P (* q )) pbase⊆PL : {P Q : HOD} → (TP : Topology P) → (TQ : Topology Q) → {x : Ordinal } → BaseP TP Q x ∨ BaseQ P TQ x → odef (Power (ZFP P Q)) x pbase⊆PL {P} {Q} TP TQ {z} (case1 record { p = p ; q = q ; op = op ; prod = prod }) = subst (λ k → odef (Power (ZFP P Q)) k ) (sym prod) tp01 where tp01 : odef (Power (ZFP P Q)) (& (ZFP (* p) Q)) tp01 w wz with subst (λ k → odef k w ) *iso wz ... | ab-pair {a} {b} pa qb = ZFP→ (subst (λ k → odef P k ) (sym &iso) tp03 ) (subst (λ k → odef Q k ) (sym &iso) qb ) where tp03 : odef P a tp03 = os⊆L TP (subst (λ k → odef (OS TP) k) (sym &iso) op) pa pbase⊆PL {P} {Q} TP TQ {z} (case2 record { p = p ; q = q ; oq = oq ; prod = prod }) = subst (λ k → odef (Power (ZFP P Q)) k ) (sym prod) tp01 where tp01 : odef (Power (ZFP P Q)) (& (ZFP P (* q) )) tp01 w wz with subst (λ k → odef k w ) *iso wz ... | ab-pair {a} {b} pa qb = ZFP→ (subst (λ k → odef P k ) (sym &iso) pa ) (subst (λ k → odef Q k ) (sym &iso) tp03 ) where tp03 : odef Q b tp03 = os⊆L TQ (subst (λ k → odef (OS TQ) k) (sym &iso) oq) qb pbase : {P Q : HOD} → Topology P → Topology Q → HOD pbase {P} {Q} TP TQ = record { od = record { def = λ x → BaseP TP Q x ∨ BaseQ P TQ x } ; odmax = & (Power (ZFP P Q)) ; <odmax = tp00 } where tp00 : {y : Ordinal} → BaseP TP Q y ∨ BaseQ P TQ y → y o< & (Power (ZFP P Q)) tp00 {y} bpq = odef< ( pbase⊆PL TP TQ bpq ) ProductTopology : {P Q : HOD} → Topology P → Topology Q → Topology (ZFP P Q) ProductTopology {P} {Q} TP TQ = InducedTopology (ZFP P Q) (pbase TP TQ) record { P⊆PL = pbase⊆PL TP TQ } -- covers ( q ⊆ Union P ) record _covers_ ( P q : HOD ) : Set n where field cover : {x : Ordinal } → odef q x → Ordinal P∋cover : {x : Ordinal } → (lt : odef q x) → odef P (cover lt) isCover : {x : Ordinal } → (lt : odef q x) → odef (* (cover lt)) x open _covers_ -- Finite Intersection Property record FIP {L : HOD} (top : Topology L) : Set n where field limit : {X : Ordinal } → * X ⊆ CS top → ( { C : Ordinal } { x : Ordinal } → * C ⊆ * X → Subbase (* C) x → o∅ o< x ) → Ordinal is-limit : {X : Ordinal } → (CX : * X ⊆ CS top ) → ( fip : { C : Ordinal } { x : Ordinal } → * C ⊆ * X → Subbase (* C) x → o∅ o< x ) → {x : Ordinal } → odef (* X) x → odef (* x) (limit CX fip) L∋limit : {X : Ordinal } → (CX : * X ⊆ CS top ) → ( fip : { C : Ordinal } { x : Ordinal } → * C ⊆ * X → Subbase (* C) x → o∅ o< x ) → {x : Ordinal } → odef (* X) x → odef L (limit CX fip) L∋limit {X} CX fip {x} xx = cs⊆L top (subst (λ k → odef (CS top) k) (sym &iso) (CX xx)) (is-limit CX fip xx) -- Compact data Finite-∪ (S : HOD) : Ordinal → Set n where fin-e : {x : Ordinal } → * x ⊆ S → Finite-∪ S x fin-∪ : {x y : Ordinal } → Finite-∪ S x → Finite-∪ S y → Finite-∪ S (& (* x ∪ * y)) record Compact {L : HOD} (top : Topology L) : Set n where field finCover : {X : Ordinal } → (* X) ⊆ OS top → (* X) covers L → Ordinal isCover : {X : Ordinal } → (xo : (* X) ⊆ OS top) → (xcp : (* X) covers L ) → (* (finCover xo xcp )) covers L isFinite : {X : Ordinal } → (xo : (* X) ⊆ OS top) → (xcp : (* X) covers L ) → Finite-∪ (* X) (finCover xo xcp ) -- FIP is Compact FIP→Compact : {L : HOD} → (top : Topology L ) → FIP top → Compact top FIP→Compact {L} top fip with trio< (& L) o∅ ... | tri< a ¬b ¬c = ⊥-elim ( ¬x<0 a ) ... | tri≈ ¬a b ¬c = record { finCover = λ _ _ → o∅ ; isCover = λ {X} _ xcp → fip01 xcp ; isFinite = fip00 } where -- L is empty fip02 : {x : Ordinal } → ¬ odef L x fip02 {x} Lx = ⊥-elim ( o<¬≡ (sym b) (∈∅< Lx) ) fip01 : {X : Ordinal } → (xcp : * X covers L) → (* o∅) covers L fip01 xcp = record { cover = λ Lx → ⊥-elim (fip02 Lx) ; P∋cover = λ Lx → ⊥-elim (fip02 Lx) ; isCover = λ Lx → ⊥-elim (fip02 Lx) } fip00 : {X : Ordinal} (xo : * X ⊆ OS top) (xcp : * X covers L) → Finite-∪ (* X) o∅ fip00 {X} xo xcp = fin-e ( λ {x} 0x → ⊥-elim (¬x<0 (subst (λ k → odef k x) o∅≡od∅ 0x) ) ) ... | tri> ¬a ¬b 0<L = record { finCover = finCover ; isCover = isCover1 ; isFinite = isFinite } where -- set of coset of X CX : {X : Ordinal} → * X ⊆ OS top → Ordinal CX {X} ox = & ( Replace' (* X) (λ z xz → L \ z )) CCX : {X : Ordinal} → (os : * X ⊆ OS top) → * (CX os) ⊆ CS top CCX {X} os {x} ox with subst (λ k → odef k x) *iso ox ... | record { z = z ; az = az ; x=ψz = x=ψz } = ⟪ fip05 , fip06 ⟫ where -- x ≡ & (L \ * z) fip07 : z ≡ & (L \ * x) fip07 = subst₂ (λ j k → j ≡ k) &iso (cong (λ k → & ( L \ k )) (cong (*) (sym x=ψz))) ( cong (&) ( ==→o≡ record { eq→ = fip09 ; eq← = fip08 } )) where fip08 : {x : Ordinal} → odef L x ∧ (¬ odef (* (& (L \ * z))) x) → odef (* z) x fip08 {x} ⟪ Lx , not ⟫ with subst (λ k → (¬ odef k x)) *iso not -- ( odef L x ∧ odef (* z) x → ⊥) → ⊥ ... | Lx∧¬zx = ODC.double-neg-elim O ( λ nz → Lx∧¬zx ⟪ Lx , nz ⟫ ) fip09 : {x : Ordinal} → odef (* z) x → odef L x ∧ (¬ odef (* (& (L \ * z))) x) fip09 {w} zw = ⟪ os⊆L top (os (subst (λ k → odef (* X) k) (sym &iso) az)) zw , subst (λ k → ¬ odef k w) (sym *iso) fip10 ⟫ where fip10 : ¬ (odef (L \ * z) w) fip10 ⟪ Lw , nzw ⟫ = nzw zw fip06 : odef (OS top) (& (L \ * x)) fip06 = os ( subst (λ k → odef (* X) k ) fip07 az ) fip05 : * x ⊆ L fip05 {w} xw = proj1 ( subst (λ k → odef k w) (trans (cong (*) x=ψz) *iso ) xw ) -- -- X covres L means Intersection of (CX X) contains nothing -- then some finite Intersection of (CX X) contains nothing ( contraposition of FIP .i.e. CFIP) -- it means there is a finite cover -- record CFIP (X x : Ordinal) : Set n where field is-CS : * x ⊆ Replace' (* X) (λ z xz → L \ z) sx : Subbase (* x) o∅ Cex : (X : Ordinal ) → HOD Cex X = record { od = record { def = λ x → CFIP X x } ; odmax = osuc (& (Replace' (* X) (λ z xz → L \ z))) ; <odmax = fip05 } where fip05 : {y : Ordinal} → CFIP X y → y o< osuc (& (Replace' (* X) (λ z xz → L \ z))) fip05 {y} cf = subst₂ (λ j k → j o< osuc k ) &iso refl ( ⊆→o≤ ( CFIP.is-CS cf ) ) fip00 : {X : Ordinal } → * X ⊆ OS top → * X covers L → ¬ ( Cex X =h= od∅ ) fip00 {X} ox oc cex=0 = ⊥-elim (fip09 fip25 fip20) where -- CX is finite intersection fip02 : {C x : Ordinal} → * C ⊆ * (CX ox) → Subbase (* C) x → o∅ o< x fip02 {C} {x} C<CX sc with trio< x o∅ ... | tri< a ¬b ¬c = ⊥-elim ( ¬x<0 a ) ... | tri> ¬a ¬b c = c ... | tri≈ ¬a b ¬c = ⊥-elim (¬x<0 ( _==_.eq→ cex=0 record { is-CS = fip10 ; sx = subst (λ k → Subbase (* C) k) b sc } )) where fip10 : * C ⊆ Replace' (* X) (λ z xz → L \ z) fip10 {w} cw = subst (λ k → odef k w) *iso ( C<CX cw ) -- we have some intersection because L is not empty (if we have an element of L, we don't need choice) fip26 : odef (* (CX ox)) (& (L \ * ( cover oc ( ODC.x∋minimal O L (0<P→ne 0<L) ) ))) fip26 = subst (λ k → odef k (& (L \ * ( cover oc ( ODC.x∋minimal O L (0<P→ne 0<L) ) )) )) (sym *iso) record { z = cover oc (x∋minimal L (0<P→ne 0<L)) ; az = P∋cover oc (x∋minimal L (0<P→ne 0<L)) ; x=ψz = refl } fip25 : odef L( FIP.limit fip (CCX ox) fip02 ) fip25 = FIP.L∋limit fip (CCX ox) fip02 fip26 fip20 : {y : Ordinal } → (Xy : odef (* X) y) → ¬ ( odef (* y) ( FIP.limit fip (CCX ox) fip02 )) fip20 {y} Xy yl = proj2 fip21 yl where fip22 : odef (* (CX ox)) (& ( L \ * y )) fip22 = subst (λ k → odef k (& ( L \ * y ))) (sym *iso) record { z = y ; az = Xy ; x=ψz = refl } fip21 : odef (L \ * y) ( FIP.limit fip (CCX ox) fip02 ) fip21 = subst (λ k → odef k ( FIP.limit fip (CCX ox) fip02 ) ) *iso ( FIP.is-limit fip (CCX ox) fip02 fip22 ) fip09 : {z : Ordinal } → odef L z → ¬ ( {y : Ordinal } → (Xy : odef (* X) y) → ¬ ( odef (* y) z )) fip09 {z} Lz nc = nc ( P∋cover oc Lz ) (subst (λ k → odef (* (cover oc Lz)) k) refl (isCover oc _ )) cex : {X : Ordinal } → * X ⊆ OS top → * X covers L → Ordinal cex {X} ox oc = & ( ODC.minimal O (Cex X) (fip00 ox oc)) -- this will be the finite cover CXfip : {X : Ordinal } → (ox : * X ⊆ OS top) → (oc : * X covers L) → CFIP X (cex ox oc) CXfip {X} ox oc = ODC.x∋minimal O (Cex X) (fip00 ox oc) -- -- this defines finite cover finCover : {X : Ordinal} → * X ⊆ OS top → * X covers L → Ordinal finCover {X} ox oc = & ( Replace' (* (cex ox oc)) (λ z xz → L \ z )) -- create Finite-∪ from cex isFinite : {X : Ordinal} (xo : * X ⊆ OS top) (xcp : * X covers L) → Finite-∪ (* X) (finCover xo xcp) isFinite {X} xo xcp = fip30 (cex xo xcp) o∅ (CFIP.is-CS (CXfip xo xcp)) (CFIP.sx (CXfip xo xcp)) where fip30 : ( x y : Ordinal ) → * x ⊆ Replace' (* X) (λ z xz → L \ z) → Subbase (* x) y → Finite-∪ (* X) (& (Replace' (* x) (λ z xz → L \ z ))) fip30 x y x⊆cs (gi sb) = fip31 where fip32 : Replace' (* x) (λ z xz → L \ z) ⊆ * X -- x⊆cs :* x ⊆ Replace' (* X) (λ z₁ xz → L \ z₁) , x=ψz : w ≡ & (L \ * z) , odef (* x) z fip32 {w} record { z = z ; az = xz ; x=ψz = x=ψz } with x⊆cs xz ... | record { z = z1 ; az = az1 ; x=ψz = x=ψz1 } = subst (λ k → odef (* X) k) fip33 az1 where fip34 : * z1 ⊆ L fip34 {w} wz1 = os⊆L top (subst (λ k → odef (OS top) k) (sym &iso) (xo az1)) wz1 fip33 : z1 ≡ w fip33 = begin z1 ≡⟨ sym &iso ⟩ & (* z1) ≡⟨ cong (&) (sym (L\Lx=x fip34 )) ⟩ & (L \ ( L \ * z1)) ≡⟨ cong (λ k → & ( L \ k )) (sym *iso) ⟩ & (L \ * (& ( L \ * z1))) ≡⟨ cong (λ k → & ( L \ * k )) (sym x=ψz1) ⟩ & (L \ * z) ≡⟨ sym x=ψz ⟩ w ∎ where open ≡-Reasoning fip31 : Finite-∪ (* X) (& (Replace' (* x) (λ z xz → L \ z))) fip31 = fin-e (subst (λ k → k ⊆ * X ) (sym *iso) fip32 ) fip30 x yz x⊆cs (g∩ {y} {z} sy sz) = fip35 where fip35 : Finite-∪ (* X) (& (Replace' (* x) (λ z₁ xz → L \ z₁))) fip35 = subst (λ k → Finite-∪ (* X) k) (cong (&) (subst (λ k → (k ∪ k ) ≡ (Replace' (* x) (λ z₁ xz → L \ z₁)) ) (sym *iso) x∪x≡x )) ( fin-∪ (fip30 _ _ x⊆cs sy) (fip30 _ _ x⊆cs sz) ) -- is also a cover isCover1 : {X : Ordinal} (xo : * X ⊆ OS top) (xcp : * X covers L) → * (finCover xo xcp) covers L isCover1 {X} xo xcp = subst₂ (λ j k → j covers k ) (sym *iso) (subst (λ k → L \ k ≡ L) (sym o∅≡od∅) L\0=L) ( fip40 (cex xo xcp) o∅ (CFIP.is-CS (CXfip xo xcp)) (CFIP.sx (CXfip xo xcp))) where fip45 : {L a b : HOD} → (L \ (a ∩ b)) ⊆ ( (L \ a) ∪ (L \ b)) fip45 {L} {a} {b} {x} Lab with ODC.∋-p O b (* x) ... | yes bx = case1 ⟪ proj1 Lab , (λ ax → proj2 Lab ⟪ ax , subst (λ k → odef b k) &iso bx ⟫ ) ⟫ ... | no ¬bx = case2 ⟪ proj1 Lab , subst (λ k → ¬ ( odef b k)) &iso ¬bx ⟫ fip43 : {A L a b : HOD } → A covers (L \ a) → A covers (L \ b ) → A covers ( L \ ( a ∩ b ) ) fip43 {A} {L} {a} {b} ca cb = record { cover = fip44 ; P∋cover = fip46 ; isCover = fip47 } where fip44 : {x : Ordinal} → odef (L \ (a ∩ b)) x → Ordinal fip44 {x} Lab with fip45 {L} {a} {b} Lab ... | case1 La = cover ca La ... | case2 Lb = cover cb Lb fip46 : {x : Ordinal} (lt : odef (L \ (a ∩ b)) x) → odef A (fip44 lt) fip46 {x} Lab with fip45 {L} {a} {b} Lab ... | case1 La = P∋cover ca La ... | case2 Lb = P∋cover cb Lb fip47 : {x : Ordinal} (lt : odef (L \ (a ∩ b)) x) → odef (* (fip44 lt)) x fip47 {x} Lab with fip45 {L} {a} {b} Lab ... | case1 La = isCover ca La ... | case2 Lb = isCover cb Lb fip40 : ( x y : Ordinal ) → * x ⊆ Replace' (* X) (λ z xz → L \ z) → Subbase (* x) y → (Replace' (* x) (λ z xz → L \ z )) covers (L \ * y ) fip40 x .(& (* _ ∩ * _)) x⊆r (g∩ {a} {b} sa sb) = subst (λ k → (Replace' (* x) (λ z xz → L \ z)) covers ( L \ k ) ) (sym *iso) ( fip43 {_} {L} {* a} {* b} fip41 fip42 ) where fip41 : Replace' (* x) (λ z xz → L \ z) covers (L \ * a) fip41 = fip40 x a x⊆r sa fip42 : Replace' (* x) (λ z xz → L \ z) covers (L \ * b) fip42 = fip40 x b x⊆r sb fip40 x y x⊆r (gi sb) with x⊆r sb ... | record { z = z ; az = az ; x=ψz = x=ψz } = record { cover = fip51 ; P∋cover = fip53 ; isCover = fip50 }where fip51 : {w : Ordinal} (Lyw : odef (L \ * y) w) → Ordinal fip51 {w} Lyw = z fip52 : {w : Ordinal} (Lyw : odef (L \ * y) w) → odef (* X) z fip52 {w} Lyw = az fip55 : * z ⊆ L fip55 {w} wz1 = os⊆L top (subst (λ k → odef (OS top) k) (sym &iso) (xo az)) wz1 fip56 : * z ≡ L \ * y fip56 = begin * z ≡⟨ sym (L\Lx=x fip55 ) ⟩ L \ ( L \ * z ) ≡⟨ cong (λ k → L \ k) (sym *iso) ⟩ L \ * ( & ( L \ * z )) ≡⟨ cong (λ k → L \ * k) (sym x=ψz) ⟩ L \ * y ∎ where open ≡-Reasoning fip53 : {w : Ordinal} (Lyw : odef (L \ * y) w) → odef (Replace' (* x) (λ z₁ xz → L \ z₁)) z fip53 {w} Lyw = record { z = _ ; az = sb ; x=ψz = fip54 } where fip54 : z ≡ & ( L \ * y ) fip54 = begin z ≡⟨ sym &iso ⟩ & (* z) ≡⟨ cong (&) fip56 ⟩ & (L \ * y ) ∎ where open ≡-Reasoning fip50 : {w : Ordinal} (Lyw : odef (L \ * y) w) → odef (* z) w fip50 {w} Lyw = subst (λ k → odef k w ) (sym fip56) Lyw Compact→FIP : {L : HOD} → (top : Topology L ) → Compact top → FIP top Compact→FIP = ? -- existence of Ultra Filter open Filter -- Ultra Filter has limit point record Neighbor {P : HOD} (TP : Topology P) (x v : Ordinal) : Set n where field u : Ordinal ou : odef (OS TP) u ux : odef (* u) x v⊆P : * v ⊆ P o⊆u : * u ⊆ * v record UFLP {P : HOD} (TP : Topology P) {L : HOD} (LP : L ⊆ Power P ) (F : Filter {L} {P} LP ) (ultra : ultra-filter F ) : Set (suc (suc n)) where field limit : Ordinal P∋limit : odef P limit is-limit : {v : Ordinal} → Neighbor TP limit v → filter F ⊆ (* v) -- FIP is UFL -- filter Base record FBase (P : HOD )(X : Ordinal ) (u : Ordinal) : Set n where field b x : Ordinal b⊆X : * b ⊆ * X sb : Subbase (* b) x u⊆P : * u ⊆ P x⊆u : * x ⊆ * u open import maximum-filter O UFLP→FIP : {P : HOD} (TP : Topology P) → ( {L : HOD} (LP : L ⊆ Power P ) → (F : Filter {L} {P} LP ) (UF : ultra-filter F ) → UFLP TP LP F UF ) → FIP TP UFLP→FIP {P} TP uflp with trio< (& P) o∅ ... | tri< a ¬b ¬c = ⊥-elim ( ¬x<0 a ) ... | tri≈ ¬a b ¬c = record { limit = ? ; is-limit = {!!} } where -- P is empty fip02 : {x : Ordinal } → ¬ odef P x fip02 {x} Px = ⊥-elim ( o<¬≡ (sym b) (∈∅< Px) ) ... | tri> ¬a ¬b 0<P = record { limit = uf00 ; is-limit = {!!} } where fip : {X : Ordinal} → * X ⊆ CS TP → Set n fip {X} CSX = {u x : Ordinal} → * u ⊆ * X → Subbase (* u) x → o∅ o< x N : {X : Ordinal} → (CSX : * X ⊆ CS TP) → fip CSX → HOD N {X} CSX fp = record { od = record { def = λ u → FBase P X u } ; odmax = osuc (& P) ; <odmax = λ {x} lt → subst₂ (λ j k → j o< osuc k) &iso refl (⊆→o≤ (FBase.u⊆P lt)) } N⊆PP : {X : Ordinal } → (CSX : * X ⊆ CS TP) → (fp : fip CSX) → N CSX fp ⊆ Power P N⊆PP CSX fp nx b xb = FBase.u⊆P nx xb F : {X : Ordinal} → (CSX : * X ⊆ CS TP) → (fp : fip CSX) → Filter {Power P} {P} (λ x → x) F {X} CSX fp = record { filter = N CSX fp ; f⊆L = N⊆PP CSX fp ; filter1 = f1 ; filter2 = f2 } where f1 : {p q : HOD} → Power P ∋ q → N CSX fp ∋ p → p ⊆ q → N CSX fp ∋ q f1 {p} {q} Xq record { b = b ; x = x ; b⊆X = b⊆X ; sb = sb ; u⊆P = Xp ; x⊆u = x⊆p } p⊆q = record { b = b ; x = x ; b⊆X = b⊆X ; sb = sb ; u⊆P = subst (λ k → k ⊆ P) (sym *iso) f10 ; x⊆u = λ {z} xp → subst (λ k → odef k z) (sym *iso) (p⊆q (subst (λ k → odef k z) *iso (x⊆p xp))) } where f10 : q ⊆ P f10 {x} qx = subst (λ k → odef P k) &iso (power→ P _ Xq (subst (λ k → odef q k) (sym &iso) qx )) f2 : {p q : HOD} → N CSX fp ∋ p → N CSX fp ∋ q → Power P ∋ (p ∩ q) → N CSX fp ∋ (p ∩ q) f2 {p} {q} Np Nq Xpq = record { b = & Np+Nq ; x = & xp∧xq ; b⊆X = f20 ; sb = sbpq ; u⊆P = p∩q⊆p ; x⊆u = f22 } where p∩q⊆p : * (& (p ∩ q)) ⊆ P p∩q⊆p {x} pqx = subst (λ k → odef P k) &iso (power→ P _ Xpq (subst₂ (λ j k → odef j k ) *iso (sym &iso) pqx )) Np+Nq = * (FBase.b Np) ∪ * (FBase.b Nq) xp∧xq = * (FBase.x Np) ∩ * (FBase.x Nq) sbpq : Subbase (* (& Np+Nq)) (& xp∧xq) sbpq = subst₂ (λ j k → Subbase j k ) (sym *iso) refl ( g∩ (sb⊆ case1 (FBase.sb Np)) (sb⊆ case2 (FBase.sb Nq))) f20 : * (& Np+Nq) ⊆ * X f20 {x} npq with subst (λ k → odef k x) *iso npq ... | case1 np = FBase.b⊆X Np np ... | case2 nq = FBase.b⊆X Nq nq f22 : * (& xp∧xq) ⊆ * (& (p ∩ q)) f22 = subst₂ ( λ j k → j ⊆ k ) (sym *iso) (sym *iso) (λ {w} xpq → ⟪ subst (λ k → odef k w) *iso ( FBase.x⊆u Np (proj1 xpq)) , subst (λ k → odef k w) *iso ( FBase.x⊆u Nq (proj2 xpq)) ⟫ ) proper : {X : Ordinal} → (CSX : * X ⊆ CS TP) → (fp : fip {X} CSX) → ¬ (N CSX fp ∋ od∅) proper = ? CAP : {X : Ordinal} → (CSX : * X ⊆ CS TP) → (fp : fip {X} CSX) → {p q : HOD } → Power P ∋ p → Power P ∋ q → Power P ∋ (p ∩ q) CAP {X} CSX fp {p} {q} Pp Pq x pqx with subst (λ k → odef k x ) *iso pqx ... | ⟪ px , qx ⟫ = Pp _ (subst (λ k → odef k x) (sym *iso) px ) maxf : {X : Ordinal} → (CSX : * X ⊆ CS TP) → (fp : fip {X} CSX) → MaximumFilter (λ x → x) (F CSX fp) maxf {X} CSX fp = F→Maximum {Power P} {P} (λ x → x) (CAP CSX fp) (F CSX fp) ? ? (proper CSX fp) uf00 : {X : Ordinal} → (CSX : * X ⊆ CS TP) → fip {X} CSX → Ordinal uf00 {X} CSX fp = UFLP.limit ( uflp (λ x → x) ( MaximumFilter.mf (maxf CSX fp) ) (F→ultra {Power P} {P} (λ x → x) (CAP CSX fp) (F CSX fp) ? ? (proper CSX fp))) FIP→UFLP : {P : HOD} (TP : Topology P) → FIP TP → {L : HOD} (LP : L ⊆ Power P ) (F : Filter LP ) (UF : ultra-filter F ) → UFLP {P} TP {L} LP F UF FIP→UFLP {P} TP fip {L} LP F UF = record { limit = FIP.limit fip (subst (λ k → k ⊆ CS TP) (sym *iso) CF⊆CS) ufl01 ; P∋limit = ? ; is-limit = ufl00 } where CF : HOD CF = Replace' (filter F) (λ x fx → Cl TP x ) CF⊆CS : CF ⊆ CS TP CF⊆CS {x} record { z = z ; az = az ; x=ψz = x=ψz } = subst (λ k → odef (CS TP) k) (sym x=ψz) (CS∋Cl TP (* z)) ufl01 : {C x : Ordinal} → * C ⊆ * (& CF) → Subbase (* C) x → o∅ o< x ufl01 = ? ufl00 : {v : Ordinal} → Neighbor TP (FIP.limit fip ? ?) v → filter F ⊆ * v ufl00 {v} record { u = u ; ou = ou ; ux = ux ; v⊆P = v⊆P ; o⊆u = o⊆u } = ? FilterProduct : {P Q LP LQ : HOD } → (LPP : LP ⊆ Power P) (FP : Filter {LP} LPP) → (LPQ : LQ ⊆ Power Q) (FQ : Filter {LQ} LPQ) → Filter {ZFP LP LQ} ? FilterProduct = ? FilterProj : {P Q LPQ : HOD } → ( LPPQ : LPQ ⊆ Power (ZFP P Q)) → Filter {LPQ} LPPQ → (Filter {Proj1PP LPQ (Power P) (Power Q)} ?) ∧ (Filter {Proj2PP LPQ (Power P) (Power Q)} ?) FilterProj = ? ProuctLimit→ProjLimit : {P Q : HOD } → (TP : Topology P) → (TQ : Topology Q) → ( {L : HOD} → (LPQ : L ⊆ Power (ZFP P Q )) (F : Filter {L} LPQ) (UF : ultra-filter F) → UFLP (ProductTopology TP TQ) LPQ F UF ) → ( {L : HOD} → (LP : L ⊆ Power P) (F : Filter {L} LP) (UF : ultra-filter F) → UFLP TP LP F UF) ∧ ( {L : HOD} → (LP : L ⊆ Power Q) (F : Filter {L} LP) (UF : ultra-filter F) → UFLP TQ LP F UF) ProuctLimit→ProjLimit = ? ProjLimit→ProductLimit : {P Q : HOD } → (TP : Topology P) → (TQ : Topology Q) → ( {L : HOD} → (LP : L ⊆ Power P) (F : Filter {L} LP) (UF : ultra-filter F) → UFLP TP LP F UF) ∧ ( {L : HOD} → (LP : L ⊆ Power Q) (F : Filter {L} LP) (UF : ultra-filter F) → UFLP TQ LP F UF) → {L : HOD} → (LPQ : L ⊆ Power (ZFP P Q )) (F : Filter {L} LPQ) (UF : ultra-filter F) → UFLP (ProductTopology TP TQ) LPQ F UF ProjLimit→ProductLimit = ? -- product topology of compact topology is compact Tychonoff : {P Q : HOD } → (TP : Topology P) → (TQ : Topology Q) → Compact TP → Compact TQ → Compact (ProductTopology TP TQ) Tychonoff {P} {Q} TP TQ CP CQ = FIP→Compact (ProductTopology TP TQ) (UFLP→FIP (ProductTopology TP TQ) uflPQ ) where uflP : {L : HOD} → (LP : L ⊆ Power P) (F : Filter {L} LP) (UF : ultra-filter F) → UFLP TP LP F UF uflP {L} LP F UF = FIP→UFLP TP (Compact→FIP TP CP) LP F UF uflQ : {L : HOD} → (LP : L ⊆ Power Q) (F : Filter {L} LP) (UF : ultra-filter F) → UFLP TQ LP F UF uflQ {L} LP F UF = FIP→UFLP TQ (Compact→FIP TQ CQ) LP F UF -- Product of UFL has limit point uflPQ : {L : HOD} → (LPQ : L ⊆ Power (ZFP P Q )) (F : Filter {L} LPQ) (UF : ultra-filter F) → UFLP (ProductTopology TP TQ) LPQ F UF uflPQ {L} LPQ F UF = record { limit = & < * ( UFLP.limit uflp ) , {!!} > ; P∋limit = {!!} ; is-limit = {!!} } where LP : HOD -- proj1 of LPQ LP = Proj1PP L (Power P) (Power Q) LPP : LP ⊆ Power P LPP {x} ⟪ Px , p1 ⟫ = Px FP : Filter {LP} {P} LPP FP = record { filter = Proj1PP (filter F) (Power P) (Power Q) ; f⊆L = ty00 ; filter1 = ? ; filter2 = ? } where ty00 : Proj1PP (filter F) (Power P) (Power Q) ⊆ LP ty00 {x} ⟪ PPx , ppf ⟫ = ⟪ PPx , ( λ y → record { pq = PProj1.pq (ppf y) ; opq = PProj1.opq (ppf y) ; Lpq = f⊆L F (PProj1.Lpq (ppf y)) ; x=pi1 = PProj1.x=pi1 (ppf y) } ) ⟫ UFP : ultra-filter FP UFP = record { proper = ? ; ultra = ? } uflp : UFLP TP LPP FP UFP uflp = FIP→UFLP TP (Compact→FIP TP CP) LPP FP UFP