Mercurial > hg > Members > kono > Proof > ZF-in-agda
annotate ordinal.agda @ 33:2b853472cb24
fix
author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Tue, 21 May 2019 18:17:24 +0900 |
parents | 3b0fdb95618e |
children | c9ad0d97ce41 |
rev | line source |
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16 | 1 open import Level |
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posturate OD is isomorphic to Ordinal
Shinji KONO <kono@ie.u-ryukyu.ac.jp>
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2 module ordinal where |
3 | 3 |
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4 open import zf |
3 | 5 |
23 | 6 open import Data.Nat renaming ( zero to Zero ; suc to Suc ; ℕ to Nat ; _⊔_ to _n⊔_ ) |
3 | 7 |
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8 open import Relation.Binary.PropositionalEquality |
3 | 9 |
24 | 10 data OrdinalD {n : Level} : (lv : Nat) → Set n where |
11 Φ : (lv : Nat) → OrdinalD lv | |
12 OSuc : (lv : Nat) → OrdinalD {n} lv → OrdinalD lv | |
17 | 13 ℵ_ : (lv : Nat) → OrdinalD (Suc lv) |
3 | 14 |
24 | 15 record Ordinal {n : Level} : Set n where |
16 | 16 field |
17 lv : Nat | |
24 | 18 ord : OrdinalD {n} lv |
16 | 19 |
24 | 20 data _d<_ {n : Level} : {lx ly : Nat} → OrdinalD {n} lx → OrdinalD {n} ly → Set n where |
21 Φ< : {lx : Nat} → {x : OrdinalD {n} lx} → Φ lx d< OSuc lx x | |
22 s< : {lx : Nat} → {x y : OrdinalD {n} lx} → x d< y → OSuc lx x d< OSuc lx y | |
23 ℵΦ< : {lx : Nat} → {x : OrdinalD {n} (Suc lx) } → Φ (Suc lx) d< (ℵ lx) | |
24 ℵ< : {lx : Nat} → {x : OrdinalD {n} (Suc lx) } → OSuc (Suc lx) x d< (ℵ lx) | |
17 | 25 |
26 open Ordinal | |
27 | |
27 | 28 _o<_ : {n : Level} ( x y : Ordinal ) → Set n |
17 | 29 _o<_ x y = (lv x < lv y ) ∨ ( ord x d< ord y ) |
3 | 30 |
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31 open import Data.Nat.Properties |
6 | 32 open import Data.Empty |
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problem on Ordinal ( OSuc ℵ )
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33 open import Data.Unit using ( ⊤ ) |
6 | 34 open import Relation.Nullary |
35 | |
36 open import Relation.Binary | |
37 open import Relation.Binary.Core | |
38 | |
24 | 39 o∅ : {n : Level} → Ordinal {n} |
40 o∅ = record { lv = Zero ; ord = Φ Zero } | |
21 | 41 |
42 | |
24 | 43 ≡→¬d< : {n : Level} → {lv : Nat} → {x : OrdinalD {n} lv } → x d< x → ⊥ |
44 ≡→¬d< {n} {lx} {OSuc lx y} (s< t) = ≡→¬d< t | |
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45 |
24 | 46 trio<> : {n : Level} → {lx : Nat} {x : OrdinalD {n} lx } { y : OrdinalD lx } → y d< x → x d< y → ⊥ |
47 trio<> {n} {lx} {.(OSuc lx _)} {.(OSuc lx _)} (s< s) (s< t) = | |
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48 trio<> s t |
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49 |
24 | 50 trio<≡ : {n : Level} → {lx : Nat} {x : OrdinalD {n} lx } { y : OrdinalD lx } → x ≡ y → x d< y → ⊥ |
17 | 51 trio<≡ refl = ≡→¬d< |
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52 |
24 | 53 trio>≡ : {n : Level} → {lx : Nat} {x : OrdinalD {n} lx } { y : OrdinalD lx } → x ≡ y → y d< x → ⊥ |
17 | 54 trio>≡ refl = ≡→¬d< |
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try to fix axiom of replacement
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55 |
24 | 56 triO : {n : Level} → {lx ly : Nat} → OrdinalD {n} lx → OrdinalD {n} ly → Tri (lx < ly) ( lx ≡ ly ) ( lx > ly ) |
57 triO {n} {lx} {ly} x y = <-cmp lx ly | |
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58 |
24 | 59 triOrdd : {n : Level} → {lx : Nat} → Trichotomous _≡_ ( _d<_ {n} {lx} {lx} ) |
60 triOrdd {_} {lv} (Φ lv) (Φ lv) = tri≈ ≡→¬d< refl ≡→¬d< | |
61 triOrdd {_} {Suc lv} (ℵ lv) (ℵ lv) = tri≈ ≡→¬d< refl ≡→¬d< | |
62 triOrdd {_} {lv} (Φ lv) (OSuc lv y) = tri< Φ< (λ ()) ( λ lt → trio<> lt Φ< ) | |
63 triOrdd {_} {.(Suc lv)} (Φ (Suc lv)) (ℵ lv) = tri< (ℵΦ< {_} {lv} {Φ (Suc lv)} ) (λ ()) ( λ lt → trio<> lt ((ℵΦ< {_} {lv} {Φ (Suc lv)} )) ) | |
64 triOrdd {_} {Suc lv} (ℵ lv) (Φ (Suc lv)) = tri> ( λ lt → trio<> lt (ℵΦ< {_} {lv} {Φ (Suc lv)} ) ) (λ ()) (ℵΦ< {_} {lv} {Φ (Suc lv)} ) | |
65 triOrdd {_} {Suc lv} (ℵ lv) (OSuc (Suc lv) y) = tri> ( λ lt → trio<> lt (ℵ< {_} {lv} {y} ) ) (λ ()) (ℵ< {_} {lv} {y} ) | |
66 triOrdd {_} {lv} (OSuc lv x) (Φ lv) = tri> (λ lt → trio<> lt Φ<) (λ ()) Φ< | |
67 triOrdd {_} {.(Suc lv)} (OSuc (Suc lv) x) (ℵ lv) = tri< ℵ< (λ ()) (λ lt → trio<> lt ℵ< ) | |
68 triOrdd {_} {lv} (OSuc lv x) (OSuc lv y) with triOrdd x y | |
69 triOrdd {_} {lv} (OSuc lv x) (OSuc lv y) | tri< a ¬b ¬c = tri< (s< a) (λ tx=ty → trio<≡ tx=ty (s< a) ) ( λ lt → trio<> lt (s< a) ) | |
70 triOrdd {_} {lv} (OSuc lv x) (OSuc lv x) | tri≈ ¬a refl ¬c = tri≈ ≡→¬d< refl ≡→¬d< | |
71 triOrdd {_} {lv} (OSuc lv x) (OSuc lv y) | tri> ¬a ¬b c = tri> ( λ lt → trio<> lt (s< c) ) (λ tx=ty → trio>≡ tx=ty (s< c) ) (s< c) | |
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72 |
24 | 73 d<→lv : {n : Level} {x y : Ordinal {n}} → ord x d< ord y → lv x ≡ lv y |
17 | 74 d<→lv Φ< = refl |
75 d<→lv (s< lt) = refl | |
76 d<→lv ℵΦ< = refl | |
77 d<→lv ℵ< = refl | |
16 | 78 |
24 | 79 orddtrans : {n : Level} {lx : Nat} {x y z : OrdinalD {n} lx } → x d< y → y d< z → x d< z |
80 orddtrans {_} {lx} {.(Φ lx)} {.(OSuc lx _)} {.(OSuc lx _)} Φ< (s< y<z) = Φ< | |
81 orddtrans {_} {Suc lx} {Φ (Suc lx)} {OSuc (Suc lx) y} {ℵ lx} Φ< ℵ< = ℵΦ< {_} {lx} {y} | |
82 orddtrans {_} {lx} {.(OSuc lx _)} {.(OSuc lx _)} {.(OSuc lx _)} (s< x<y) (s< y<z) = s< ( orddtrans x<y y<z ) | |
83 orddtrans {_} {Suc lx} {.(OSuc (Suc lx) _)} {.(OSuc (Suc lx) _)} {.(ℵ _)} (s< x<y) ℵ< = ℵ< | |
84 orddtrans {_} {Suc lx} {Φ (Suc lx)} {.(ℵ _)} {z} ℵΦ< () | |
85 orddtrans {_} {Suc lx} {OSuc (Suc lx) _} {.(ℵ _)} {z} ℵ< () | |
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86 |
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87 max : (x y : Nat) → Nat |
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88 max Zero Zero = Zero |
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89 max Zero (Suc x) = (Suc x) |
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separete constructible set
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90 max (Suc x) Zero = (Suc x) |
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separete constructible set
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91 max (Suc x) (Suc y) = Suc ( max x y ) |
3 | 92 |
24 | 93 maxαd : {n : Level} → { lx : Nat } → OrdinalD {n} lx → OrdinalD lx → OrdinalD lx |
17 | 94 maxαd x y with triOrdd x y |
95 maxαd x y | tri< a ¬b ¬c = y | |
96 maxαd x y | tri≈ ¬a b ¬c = x | |
97 maxαd x y | tri> ¬a ¬b c = x | |
6 | 98 |
24 | 99 maxα : {n : Level} → Ordinal {n} → Ordinal → Ordinal |
17 | 100 maxα x y with <-cmp (lv x) (lv y) |
101 maxα x y | tri< a ¬b ¬c = x | |
102 maxα x y | tri> ¬a ¬b c = y | |
103 maxα x y | tri≈ ¬a refl ¬c = record { lv = lv x ; ord = maxαd (ord x) (ord y) } | |
7 | 104 |
24 | 105 _o≤_ : {n : Level} → Ordinal → Ordinal → Set (suc n) |
23 | 106 a o≤ b = (a ≡ b) ∨ ( a o< b ) |
107 | |
27 | 108 ordtrans : {n : Level} {x y z : Ordinal {n} } → x o< y → y o< z → x o< z |
109 ordtrans {n} {x} {y} {z} (case1 x₁) (case1 x₂) = case1 ( <-trans x₁ x₂ ) | |
110 ordtrans {n} {x} {y} {z} (case1 x₁) (case2 x₂) with d<→lv x₂ | |
111 ... | refl = case1 x₁ | |
112 ordtrans {n} {x} {y} {z} (case2 x₁) (case1 x₂) with d<→lv x₁ | |
113 ... | refl = case1 x₂ | |
114 ordtrans {n} {x} {y} {z} (case2 x₁) (case2 x₂) with d<→lv x₁ | d<→lv x₂ | |
115 ... | refl | refl = case2 ( orddtrans x₁ x₂ ) | |
116 | |
117 | |
24 | 118 trio< : {n : Level } → Trichotomous {suc n} _≡_ _o<_ |
23 | 119 trio< a b with <-cmp (lv a) (lv b) |
24 | 120 trio< a b | tri< a₁ ¬b ¬c = tri< (case1 a₁) (λ refl → ¬b (cong ( λ x → lv x ) refl ) ) lemma1 where |
121 lemma1 : ¬ (Suc (lv b) ≤ lv a) ∨ (ord b d< ord a) | |
122 lemma1 (case1 x) = ¬c x | |
123 lemma1 (case2 x) with d<→lv x | |
124 lemma1 (case2 x) | refl = ¬b refl | |
125 trio< a b | tri> ¬a ¬b c = tri> lemma1 (λ refl → ¬b (cong ( λ x → lv x ) refl ) ) (case1 c) where | |
126 lemma1 : ¬ (Suc (lv a) ≤ lv b) ∨ (ord a d< ord b) | |
127 lemma1 (case1 x) = ¬a x | |
128 lemma1 (case2 x) with d<→lv x | |
129 lemma1 (case2 x) | refl = ¬b refl | |
23 | 130 trio< a b | tri≈ ¬a refl ¬c with triOrdd ( ord a ) ( ord b ) |
24 | 131 trio< record { lv = .(lv b) ; ord = x } b | tri≈ ¬a refl ¬c | tri< a ¬b ¬c₁ = tri< (case2 a) (λ refl → ¬b (lemma1 refl )) lemma2 where |
132 lemma1 : (record { lv = _ ; ord = x }) ≡ b → x ≡ ord b | |
133 lemma1 refl = refl | |
134 lemma2 : ¬ (Suc (lv b) ≤ lv b) ∨ (ord b d< x) | |
135 lemma2 (case1 x) = ¬a x | |
136 lemma2 (case2 x) = trio<> x a | |
137 trio< record { lv = .(lv b) ; ord = x } b | tri≈ ¬a refl ¬c | tri> ¬a₁ ¬b c = tri> lemma2 (λ refl → ¬b (lemma1 refl )) (case2 c) where | |
138 lemma1 : (record { lv = _ ; ord = x }) ≡ b → x ≡ ord b | |
139 lemma1 refl = refl | |
140 lemma2 : ¬ (Suc (lv b) ≤ lv b) ∨ (x d< ord b) | |
141 lemma2 (case1 x) = ¬a x | |
142 lemma2 (case2 x) = trio<> x c | |
143 trio< record { lv = .(lv b) ; ord = x } b | tri≈ ¬a refl ¬c | tri≈ ¬a₁ refl ¬c₁ = tri≈ lemma1 refl lemma1 where | |
144 lemma1 : ¬ (Suc (lv b) ≤ lv b) ∨ (ord b d< ord b) | |
145 lemma1 (case1 x) = ¬a x | |
146 lemma1 (case2 x) = ≡→¬d< x | |
23 | 147 |
24 | 148 OrdTrans : {n : Level} → Transitive {suc n} _o≤_ |
16 | 149 OrdTrans (case1 refl) (case1 refl) = case1 refl |
150 OrdTrans (case1 refl) (case2 lt2) = case2 lt2 | |
151 OrdTrans (case2 lt1) (case1 refl) = case2 lt1 | |
17 | 152 OrdTrans (case2 (case1 x)) (case2 (case1 y)) = case2 (case1 ( <-trans x y ) ) |
153 OrdTrans (case2 (case1 x)) (case2 (case2 y)) with d<→lv y | |
154 OrdTrans (case2 (case1 x)) (case2 (case2 y)) | refl = case2 (case1 x ) | |
155 OrdTrans (case2 (case2 x)) (case2 (case1 y)) with d<→lv x | |
156 OrdTrans (case2 (case2 x)) (case2 (case1 y)) | refl = case2 (case1 y) | |
157 OrdTrans (case2 (case2 x)) (case2 (case2 y)) with d<→lv x | d<→lv y | |
158 OrdTrans (case2 (case2 x)) (case2 (case2 y)) | refl | refl = case2 (case2 (orddtrans x y )) | |
16 | 159 |
24 | 160 OrdPreorder : {n : Level} → Preorder (suc n) (suc n) (suc n) |
161 OrdPreorder {n} = record { Carrier = Ordinal | |
16 | 162 ; _≈_ = _≡_ |
23 | 163 ; _∼_ = _o≤_ |
16 | 164 ; isPreorder = record { |
165 isEquivalence = record { refl = refl ; sym = sym ; trans = trans } | |
166 ; reflexive = case1 | |
24 | 167 ; trans = OrdTrans |
16 | 168 } |
169 } | |
170 | |
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problem on Ordinal ( OSuc ℵ )
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171 TransFinite : {n : Level} → { ψ : Ordinal {n} → Set n } |
22 | 172 → ( ∀ (lx : Nat ) → ψ ( record { lv = Suc lx ; ord = ℵ lx } )) |
24 | 173 → ( ∀ (lx : Nat ) → ψ ( record { lv = lx ; ord = Φ lx } ) ) |
174 → ( ∀ (lx : Nat ) → (x : OrdinalD lx ) → ψ ( record { lv = lx ; ord = x } ) → ψ ( record { lv = lx ; ord = OSuc lx x } ) ) | |
22 | 175 → ∀ (x : Ordinal) → ψ x |
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problem on Ordinal ( OSuc ℵ )
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176 TransFinite caseℵ caseΦ caseOSuc record { lv = lv ; ord = Φ lv } = caseΦ lv |
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problem on Ordinal ( OSuc ℵ )
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177 TransFinite caseℵ caseΦ caseOSuc record { lv = lv ; ord = OSuc lv ord₁ } = caseOSuc lv ord₁ |
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problem on Ordinal ( OSuc ℵ )
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178 ( TransFinite caseℵ caseΦ caseOSuc (record { lv = lv ; ord = ord₁ } )) |
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problem on Ordinal ( OSuc ℵ )
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179 TransFinite caseℵ caseΦ caseOSuc record { lv = Suc lv₁ ; ord = ℵ lv₁ } = caseℵ lv₁ |
22 | 180 |