Mercurial > hg > Members > kono > Proof > ZF-in-agda
view BAlgbra.agda @ 424:cc7909f86841
remvoe TransFinifte1
author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Sat, 01 Aug 2020 23:37:10 +0900 |
parents | 9984cdd88da3 |
children |
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open import Level open import Ordinals module BAlgbra {n : Level } (O : Ordinals {n}) where open import zf open import logic import OrdUtil import OD import ODUtil import ODC 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⊔_ ; _+_ to _n+_ ) open inOrdinal O open Ordinals.Ordinals O open Ordinals.IsOrdinals isOrdinal open Ordinals.IsNext isNext open OrdUtil O open ODUtil O open OD O open OD.OD open ODAxiom odAxiom open HOD open _∧_ open _∨_ open Bool --_∩_ : ( A B : HOD ) → HOD --A ∩ B = record { od = record { def = λ x → odef A x ∧ odef B x } ; -- odmax = omin (odmax A) (odmax B) ; <odmax = λ y → min1 (<odmax A (proj1 y)) (<odmax B (proj2 y)) } _∪_ : ( A B : HOD ) → HOD A ∪ B = record { od = record { def = λ x → odef A x ∨ odef B x } ; odmax = omax (odmax A) (odmax B) ; <odmax = lemma } where lemma : {y : Ordinal} → odef A y ∨ odef B y → y o< omax (odmax A) (odmax B) lemma {y} (case1 a) = ordtrans (<odmax A a) (omax-x _ _) lemma {y} (case2 b) = ordtrans (<odmax B b) (omax-y _ _) _\_ : ( A B : HOD ) → HOD A \ B = record { od = record { def = λ x → odef A x ∧ ( ¬ ( odef B x ) ) }; odmax = odmax A ; <odmax = λ y → <odmax A (proj1 y) } ∪-Union : { A B : HOD } → Union (A , B) ≡ ( A ∪ B ) ∪-Union {A} {B} = ==→o≡ ( record { eq→ = lemma1 ; eq← = lemma2 } ) where lemma1 : {x : Ordinal} → odef (Union (A , B)) x → odef (A ∪ B) x lemma1 {x} lt = lemma3 lt where lemma4 : {y : Ordinal} → odef (A , B) y ∧ odef (* y) x → ¬ (¬ ( odef A x ∨ odef B x) ) lemma4 {y} z with proj1 z lemma4 {y} z | case1 refl = double-neg (case1 ( subst (λ k → odef k x ) *iso (proj2 z)) ) lemma4 {y} z | case2 refl = double-neg (case2 ( subst (λ k → odef k x ) *iso (proj2 z)) ) lemma3 : (((u : Ordinal ) → ¬ odef (A , B) u ∧ odef (* u) x) → ⊥) → odef (A ∪ B) x lemma3 not = ODC.double-neg-eilm O (FExists _ lemma4 not) -- choice lemma2 : {x : Ordinal} → odef (A ∪ B) x → odef (Union (A , B)) x lemma2 {x} (case1 A∋x) = subst (λ k → odef (Union (A , B)) k) &iso ( IsZF.union→ isZF (A , B) (* x) A ⟪ case1 refl , d→∋ A A∋x ⟫ ) lemma2 {x} (case2 B∋x) = subst (λ k → odef (Union (A , B)) k) &iso ( IsZF.union→ isZF (A , B) (* x) B ⟪ case2 refl , d→∋ B B∋x ⟫ ) ∩-Select : { A B : HOD } → Select A ( λ x → ( A ∋ x ) ∧ ( B ∋ x ) ) ≡ ( A ∩ B ) ∩-Select {A} {B} = ==→o≡ ( record { eq→ = lemma1 ; eq← = lemma2 } ) where lemma1 : {x : Ordinal} → odef (Select A (λ x₁ → (A ∋ x₁) ∧ (B ∋ x₁))) x → odef (A ∩ B) x lemma1 {x} lt = ⟪ proj1 lt , subst (λ k → odef B k ) &iso (proj2 (proj2 lt)) ⟫ lemma2 : {x : Ordinal} → odef (A ∩ B) x → odef (Select A (λ x₁ → (A ∋ x₁) ∧ (B ∋ x₁))) x lemma2 {x} lt = ⟪ proj1 lt , ⟪ d→∋ A (proj1 lt) , d→∋ B (proj2 lt) ⟫ ⟫ dist-ord : {p q r : HOD } → p ∩ ( q ∪ r ) ≡ ( p ∩ q ) ∪ ( p ∩ r ) dist-ord {p} {q} {r} = ==→o≡ ( record { eq→ = lemma1 ; eq← = lemma2 } ) where lemma1 : {x : Ordinal} → odef (p ∩ (q ∪ r)) x → odef ((p ∩ q) ∪ (p ∩ r)) x lemma1 {x} lt with proj2 lt lemma1 {x} lt | case1 q∋x = case1 ⟪ proj1 lt , q∋x ⟫ lemma1 {x} lt | case2 r∋x = case2 ⟪ proj1 lt , r∋x ⟫ lemma2 : {x : Ordinal} → odef ((p ∩ q) ∪ (p ∩ r)) x → odef (p ∩ (q ∪ r)) x lemma2 {x} (case1 p∩q) = ⟪ proj1 p∩q , case1 (proj2 p∩q ) ⟫ lemma2 {x} (case2 p∩r) = ⟪ proj1 p∩r , case2 (proj2 p∩r ) ⟫ dist-ord2 : {p q r : HOD } → p ∪ ( q ∩ r ) ≡ ( p ∪ q ) ∩ ( p ∪ r ) dist-ord2 {p} {q} {r} = ==→o≡ ( record { eq→ = lemma1 ; eq← = lemma2 } ) where lemma1 : {x : Ordinal} → odef (p ∪ (q ∩ r)) x → odef ((p ∪ q) ∩ (p ∪ r)) x lemma1 {x} (case1 cp) = ⟪ case1 cp , case1 cp ⟫ lemma1 {x} (case2 cqr) = ⟪ case2 (proj1 cqr) , case2 (proj2 cqr) ⟫ lemma2 : {x : Ordinal} → odef ((p ∪ q) ∩ (p ∪ r)) x → odef (p ∪ (q ∩ r)) x lemma2 {x} lt with proj1 lt | proj2 lt lemma2 {x} lt | case1 cp | _ = case1 cp lemma2 {x} lt | _ | case1 cp = case1 cp lemma2 {x} lt | case2 cq | case2 cr = case2 ⟪ cq , cr ⟫ record IsBooleanAlgebra ( L : Set n) ( b1 : L ) ( b0 : L ) ( -_ : L → L ) ( _+_ : L → L → L ) ( _x_ : L → L → L ) : Set (suc n) where field +-assoc : {a b c : L } → a + ( b + c ) ≡ (a + b) + c x-assoc : {a b c : L } → a x ( b x c ) ≡ (a x b) x c +-sym : {a b : L } → a + b ≡ b + a -sym : {a b : L } → a x b ≡ b x a +-aab : {a b : L } → a + ( a x b ) ≡ a x-aab : {a b : L } → a x ( a + b ) ≡ a +-dist : {a b c : L } → a + ( b x c ) ≡ ( a x b ) + ( a x c ) x-dist : {a b c : L } → a x ( b + c ) ≡ ( a + b ) x ( a + c ) a+0 : {a : L } → a + b0 ≡ a ax1 : {a : L } → a x b1 ≡ a a+-a1 : {a : L } → a + ( - a ) ≡ b1 ax-a0 : {a : L } → a x ( - a ) ≡ b0 record BooleanAlgebra ( L : Set n) : Set (suc n) where field b1 : L b0 : L -_ : L → L _+_ : L → L → L _x_ : L → L → L isBooleanAlgebra : IsBooleanAlgebra L b1 b0 -_ _+_ _x_