Mercurial > hg > Members > kono > Proof > ZF-in-agda
annotate cardinal.agda @ 240:c76c812de395
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author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Wed, 21 Aug 2019 16:43:29 +0900 |
parents | b6d80eec5f9e |
children | ccc84f289c98 |
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16 | 1 open import Level |
224 | 2 open import Ordinals |
3 module cardinal {n : Level } (O : Ordinals {n}) where | |
3 | 4 |
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5 open import zf |
219 | 6 open import logic |
224 | 7 import OD |
23 | 8 open import Data.Nat renaming ( zero to Zero ; suc to Suc ; ℕ to Nat ; _⊔_ to _n⊔_ ) |
224 | 9 open import Relation.Binary.PropositionalEquality |
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10 open import Data.Nat.Properties |
6 | 11 open import Data.Empty |
12 open import Relation.Nullary | |
13 open import Relation.Binary | |
14 open import Relation.Binary.Core | |
15 | |
224 | 16 open inOrdinal O |
17 open OD O | |
219 | 18 open OD.OD |
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19 |
120 | 20 open _∧_ |
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21 open _∨_ |
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22 open Bool |
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od→lv : {n : Level} → OD {n} → Nat
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23 |
230 | 24 -- we have to work on Ordinal to keep OD Level n |
25 -- since we use p∨¬p which works only on Level n | |
225 | 26 |
233 | 27 <_,_> : (x y : OD) → OD |
28 < x , y > = (x , x ) , (x , y ) | |
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29 |
238 | 30 data ord-pair : (p : Ordinal) → Set n where |
31 pair : (x y : Ordinal ) → ord-pair ( od→ord ( < ord→od x , ord→od y > ) ) | |
32 | |
33 ZFProduct : OD | |
34 ZFProduct = record { def = λ x → ord-pair x } | |
35 | |
239 | 36 π1 : { p : OD } → ZFProduct ∋ p → Ordinal |
37 π1 lt = pi1 lt where | |
238 | 38 pi1 : { p : Ordinal } → ord-pair p → Ordinal |
39 pi1 ( pair x y ) = x | |
237 | 40 |
239 | 41 π2 : { p : OD } → ZFProduct ∋ p → Ordinal |
42 π2 lt = pi2 lt where | |
238 | 43 pi2 : { p : Ordinal } → ord-pair p → Ordinal |
44 pi2 ( pair x y ) = y | |
237 | 45 |
238 | 46 p-cons : { x y : OD } → ZFProduct ∋ < x , y > |
47 p-cons {x} {y} = def-subst {_} {_} {ZFProduct} {od→ord (< x , y >)} (pair (od→ord x) ( od→ord y )) refl ( | |
48 let open ≡-Reasoning in begin | |
49 od→ord < ord→od (od→ord x) , ord→od (od→ord y) > | |
50 ≡⟨ cong₂ (λ j k → od→ord < j , k >) oiso oiso ⟩ | |
51 od→ord < x , y > | |
52 ∎ ) | |
53 | |
54 | |
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55 ∋-p : (A x : OD ) → Dec ( A ∋ x ) |
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56 ∋-p A x with p∨¬p ( A ∋ x ) |
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57 ∋-p A x | case1 t = yes t |
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58 ∋-p A x | case2 t = no t |
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59 |
233 | 60 _⊗_ : (A B : OD) → OD |
239 | 61 A ⊗ B = record { def = λ x → def ZFProduct x ∧ ( { x : Ordinal } → (p : def ZFProduct x ) → checkAB p ) } where |
62 checkAB : { p : Ordinal } → def ZFProduct p → Set n | |
63 checkAB (pair x y) = def A x ∧ def B y | |
233 | 64 |
65 -- Power (Power ( A ∪ B )) ∋ ( A ⊗ B ) | |
225 | 66 |
233 | 67 Func : ( A B : OD ) → OD |
68 Func A B = record { def = λ x → def (Power (A ⊗ B)) x } | |
69 | |
70 -- power→ : ( A t : OD) → Power A ∋ t → {x : OD} → t ∋ x → ¬ ¬ (A ∋ x) | |
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71 |
236 | 72 |
233 | 73 func→od : (f : Ordinal → Ordinal ) → ( dom : OD ) → OD |
74 func→od f dom = Replace dom ( λ x → < x , ord→od (f (od→ord x)) > ) | |
75 | |
236 | 76 record Func←cd { dom cod : OD } {f : Ordinal } (f<F : def (Func dom cod ) f) : Set n where |
77 field | |
78 func-1 : Ordinal → Ordinal | |
79 func→od∈Func-1 : (Func dom (Ord (sup-o (λ x → func-1 x)) )) ∋ func→od func-1 dom | |
80 | |
240 | 81 od→func : { dom cod : OD } → {f : Ordinal } → (f<F : def (Func dom cod ) f ) → Func←cd {dom} {cod} {f} f<F |
82 od→func {dom} {cod} {f} lt = record { func-1 = λ x → sup-o ( λ y → lemma x y ) ; func→od∈Func-1 = record { proj1 = {!!} ; proj2 = {!!} } } where | |
236 | 83 lemma : Ordinal → Ordinal → Ordinal |
84 lemma x y with IsZF.power→ isZF (dom ⊗ cod) (ord→od f) (subst (λ k → def (Power (dom ⊗ cod)) k ) (sym diso) lt ) | ∋-p (ord→od f) (ord→od y) | |
85 lemma x y | p | no n = o∅ | |
240 | 86 lemma x y | p | yes f∋y = lemma2 (proj1 (double-neg-eilm ( p {ord→od y} f∋y ))) where -- p : {y : OD} → f ∋ y → ¬ ¬ (dom ⊗ cod ∋ y) |
87 lemma2 : {p : Ordinal} → ord-pair p → Ordinal | |
88 lemma2 (pair x1 y1) with decp ( x1 ≡ x) | |
89 lemma2 (pair x1 y1) | yes p = y1 | |
90 lemma2 (pair x1 y1) | no ¬p = o∅ | |
91 | |
92 | |
93 open Func←cd | |
236 | 94 |
95 func→od∈Func : (f : Ordinal → Ordinal ) ( dom : OD ) → (Func dom (Ord (sup-o (λ x → f x)) )) ∋ func→od f dom | |
240 | 96 func→od∈Func f dom = record { proj1 = {!!} ; proj2 = {!!} } where |
97 lemma : (Func dom (Ord (sup-o (λ x → f x)) )) ∋ func→od f dom | |
98 lemma = {!!} -- func→od∈Func-1 ( od→func {dom} {{!!}} {od→ord (func→od f {!!} )} {!!} ) | |
225 | 99 |
227 | 100 -- contra position of sup-o< |
101 -- | |
102 | |
235 | 103 -- postulate |
104 -- -- contra-position of mimimulity of supermum required in Cardinal | |
105 -- sup-x : ( Ordinal → Ordinal ) → Ordinal | |
106 -- sup-lb : { ψ : Ordinal → Ordinal } → {z : Ordinal } → z o< sup-o ψ → z o< osuc (ψ (sup-x ψ)) | |
227 | 107 |
219 | 108 ------------ |
109 -- | |
110 -- Onto map | |
111 -- def X x -> xmap | |
112 -- X ---------------------------> Y | |
113 -- ymap <- def Y y | |
114 -- | |
224 | 115 record Onto (X Y : OD ) : Set n where |
219 | 116 field |
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117 xmap : Ordinal |
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118 ymap : Ordinal |
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119 xfunc : def (Func X Y) xmap |
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120 yfunc : def (Func Y X) ymap |
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121 onto-iso : {y : Ordinal } → (lty : def Y y ) → |
240 | 122 func-1 ( od→func {X} {Y} {xmap} xfunc ) ( func-1 (od→func yfunc) y ) ≡ y |
230 | 123 |
124 open Onto | |
125 | |
126 onto-restrict : {X Y Z : OD} → Onto X Y → ({x : OD} → _⊆_ Z Y {x}) → Onto X Z | |
127 onto-restrict {X} {Y} {Z} onto Z⊆Y = record { | |
128 xmap = xmap1 | |
129 ; ymap = zmap | |
130 ; xfunc = xfunc1 | |
131 ; yfunc = zfunc | |
132 ; onto-iso = onto-iso1 | |
133 } where | |
134 xmap1 : Ordinal | |
135 xmap1 = od→ord (Select (ord→od (xmap onto)) {!!} ) | |
136 zmap : Ordinal | |
137 zmap = {!!} | |
138 xfunc1 : def (Func X Z) xmap1 | |
139 xfunc1 = {!!} | |
140 zfunc : def (Func Z X) zmap | |
141 zfunc = {!!} | |
240 | 142 onto-iso1 : {z : Ordinal } → (ltz : def Z z ) → func-1 (od→func xfunc1 ) (func-1 (od→func zfunc ) z ) ≡ z |
230 | 143 onto-iso1 = {!!} |
144 | |
51 | 145 |
224 | 146 record Cardinal (X : OD ) : Set n where |
219 | 147 field |
224 | 148 cardinal : Ordinal |
230 | 149 conto : Onto X (Ord cardinal) |
150 cmax : ( y : Ordinal ) → cardinal o< y → ¬ Onto X (Ord y) | |
151 | 151 |
224 | 152 cardinal : (X : OD ) → Cardinal X |
153 cardinal X = record { | |
219 | 154 cardinal = sup-o ( λ x → proj1 ( cardinal-p x) ) |
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155 ; conto = onto |
219 | 156 ; cmax = cmax |
157 } where | |
230 | 158 cardinal-p : (x : Ordinal ) → ( Ordinal ∧ Dec (Onto X (Ord x) ) ) |
159 cardinal-p x with p∨¬p ( Onto X (Ord x) ) | |
160 cardinal-p x | case1 True = record { proj1 = x ; proj2 = yes True } | |
219 | 161 cardinal-p x | case2 False = record { proj1 = o∅ ; proj2 = no False } |
229 | 162 S = sup-o (λ x → proj1 (cardinal-p x)) |
230 | 163 lemma1 : (x : Ordinal) → ((y : Ordinal) → y o< x → Lift (suc n) (y o< (osuc S) → Onto X (Ord y))) → |
164 Lift (suc n) (x o< (osuc S) → Onto X (Ord x) ) | |
229 | 165 lemma1 x prev with trio< x (osuc S) |
166 lemma1 x prev | tri< a ¬b ¬c with osuc-≡< a | |
230 | 167 lemma1 x prev | tri< a ¬b ¬c | case1 x=S = lift ( λ lt → {!!} ) |
168 lemma1 x prev | tri< a ¬b ¬c | case2 x<S = lift ( λ lt → lemma2 ) where | |
169 lemma2 : Onto X (Ord x) | |
170 lemma2 with prev {!!} {!!} | |
171 ... | lift t = t {!!} | |
229 | 172 lemma1 x prev | tri≈ ¬a b ¬c = lift ( λ lt → ⊥-elim ( o<¬≡ b lt )) |
173 lemma1 x prev | tri> ¬a ¬b c = lift ( λ lt → ⊥-elim ( o<> c lt )) | |
230 | 174 onto : Onto X (Ord S) |
175 onto with TransFinite {λ x → Lift (suc n) ( x o< osuc S → Onto X (Ord x) ) } lemma1 S | |
176 ... | lift t = t <-osuc | |
177 cmax : (y : Ordinal) → S o< y → ¬ Onto X (Ord y) | |
229 | 178 cmax y lt ontoy = o<> lt (o<-subst {_} {_} {y} {S} |
224 | 179 (sup-o< {λ x → proj1 ( cardinal-p x)}{y} ) lemma refl ) where |
219 | 180 lemma : proj1 (cardinal-p y) ≡ y |
230 | 181 lemma with p∨¬p ( Onto X (Ord y) ) |
219 | 182 lemma | case1 x = refl |
183 lemma | case2 not = ⊥-elim ( not ontoy ) | |
217 | 184 |
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186 ----- |
219 | 187 -- All cardinal is ℵ0, since we are working on Countable Ordinal, |
188 -- Power ω is larger than ℵ0, so it has no cardinal. | |
218 | 189 |
190 | |
191 |