Mercurial > hg > Members > kono > Proof > category
annotate freyd.agda @ 460:961c236807f1
limit-to done
discrete done
author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Fri, 03 Mar 2017 12:12:06 +0900 |
parents | 9d24fb809746 |
children | 65e6906782bb |
rev | line source |
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304
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Freyd Adjoint Functor Theorem
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1 open import Category -- https://github.com/konn/category-agda |
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2 open import Level |
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3 |
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4 module freyd {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) |
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5 where |
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6 |
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7 open import cat-utility |
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8 open import HomReasoning |
304
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9 open import Relation.Binary.Core |
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10 open Functor |
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11 |
311 | 12 -- C is small full subcategory of A ( C is image of F ) |
304
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13 |
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14 record SmallFullSubcategory {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) |
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15 : Set (suc ℓ ⊔ (suc c₁ ⊔ suc c₂)) where |
306
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Small Full Subcategory (underconstruction)
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16 field |
442 | 17 SFSF : Functor A A |
18 SFSFMap← : { a b : Obj A } → Hom A (FObj SFSF a) (FObj SFSF b ) → Hom A a b | |
19 full→ : { a b : Obj A } { x : Hom A (FObj SFSF a) (FObj SFSF b) } → A [ FMap SFSF ( SFSFMap← x ) ≈ x ] | |
20 | |
21 -- ≈→≡ : {a b : Obj A } → { x y : Hom A (FObj SFSF a) (FObj SFSF b) } → | |
22 -- (x≈y : A [ FMap SFSF x ≈ FMap SFSF y ]) → FMap SFSF x ≡ FMap SFSF y -- codomain of FMap is local small | |
305 | 23 |
309
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24 -- pre-initial |
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25 |
311 | 26 record PreInitial {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) |
27 (F : Functor A A ) : Set (suc ℓ ⊔ (suc c₁ ⊔ suc c₂)) where | |
308 | 28 field |
314 | 29 preinitialObj : ∀{ a : Obj A } → Obj A |
30 preinitialArrow : ∀{ a : Obj A } → Hom A ( FObj F (preinitialObj {a} )) a | |
309
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31 |
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32 -- initial object |
308 | 33 |
309
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34 record HasInitialObject {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) (i : Obj A) : Set (suc ℓ ⊔ (suc c₁ ⊔ suc c₂)) where |
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35 field |
314 | 36 initial : ∀( a : Obj A ) → Hom A i a |
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37 uniqueness : ( a : Obj A ) → ( f : Hom A i a ) → A [ f ≈ initial a ] |
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38 |
315 | 39 -- A complete catagory has initial object if it has PreInitial-SmallFullSubcategory |
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40 |
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41 open NTrans |
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42 open Limit |
313 | 43 open SmallFullSubcategory |
44 open PreInitial | |
440 | 45 open Complete |
46 open Equalizer | |
443 | 47 open IsEqualizer |
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48 |
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49 initialFromPreInitialFullSubcategory : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) |
440 | 50 (comp : Complete A A) |
442 | 51 (SFS : SmallFullSubcategory A ) → |
52 (PI : PreInitial A (SFSF SFS )) → { a0 : Obj A } → HasInitialObject A (limit-c comp (SFSF SFS)) | |
53 initialFromPreInitialFullSubcategory A comp SFS PI = record { | |
314 | 54 initial = initialArrow ; |
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55 uniqueness = λ a f → lemma1 a f |
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56 } where |
442 | 57 F : Functor A A |
58 F = SFSF SFS | |
59 FMap← : { a b : Obj A } → Hom A (FObj F a) (FObj F b ) → Hom A a b | |
60 FMap← = SFSFMap← SFS | |
459 | 61 a0 : Obj A |
62 a0 = limit-c comp F | |
460 | 63 lim : ( Γ : Functor A A ) → Limit A A Γ (limit-c comp Γ) (limit-u comp Γ) |
64 lim Γ = isLimit comp Γ | |
459 | 65 u : NTrans A A (K A A a0) F |
66 u = T0 ( lim F ) | |
443 | 67 equ : {a b : Obj A} → (f g : Hom A a b) → IsEqualizer A (equalizer-e comp f g ) f g |
68 equ f g = Complete.isEqualizer comp f g | |
442 | 69 ep : {a b : Obj A} → {f g : Hom A a b} → Obj A |
70 ep {a} {b} {f} {g} = equalizer-p comp f g | |
71 ee : {a b : Obj A} → {f g : Hom A a b} → Hom A (ep {a} {b} {f} {g} ) a | |
72 ee {a} {b} {f} {g} = equalizer-e comp f g | |
73 f : {a : Obj A} → Hom A a0 (FObj F (preinitialObj PI {a} ) ) | |
440 | 74 f {a} = TMap u (preinitialObj PI {a} ) |
314 | 75 initialArrow : ∀( a : Obj A ) → Hom A a0 a |
437 | 76 initialArrow a = A [ preinitialArrow PI {a} o f ] |
442 | 77 equ-fi : { a : Obj A} → {f' : Hom A a0 a} → |
443 | 78 IsEqualizer A ee ( A [ preinitialArrow PI {a} o f ] ) f' |
440 | 79 equ-fi {a} {f'} = equ ( A [ preinitialArrow PI {a} o f ] ) f' |
442 | 80 e=id : {e : Hom A a0 a0} → ( {c : Obj A} → A [ A [ TMap u c o e ] ≈ TMap u c ] ) → A [ e ≈ id1 A a0 ] |
438 | 81 e=id {e} uce=uc = let open ≈-Reasoning (A) in |
437 | 82 begin |
83 e | |
442 | 84 ≈↑⟨ limit-uniqueness (lim F) e ( λ {i} → uce=uc ) ⟩ |
440 | 85 limit (lim F) a0 u |
442 | 86 ≈⟨ limit-uniqueness (lim F) (id1 A a0) ( λ {i} → idR ) ⟩ |
437 | 87 id1 A a0 |
88 ∎ | |
442 | 89 kfuc=uc : {c k1 : Obj A} → {p : Hom A k1 a0} → A [ A [ TMap u c o |
440 | 90 A [ p o A [ preinitialArrow PI {k1} o TMap u (preinitialObj PI) ] ] ] |
91 ≈ TMap u c ] | |
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92 kfuc=uc {c} {k1} {p} = let open ≈-Reasoning (A) in |
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93 begin |
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94 TMap u c o ( p o ( preinitialArrow PI {k1} o TMap u (preinitialObj PI) )) |
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95 ≈⟨ cdr assoc ⟩ |
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96 TMap u c o ((p o preinitialArrow PI) o TMap u (preinitialObj PI)) |
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97 ≈⟨ assoc ⟩ |
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98 (TMap u c o ( p o ( preinitialArrow PI {k1} ))) o TMap u (preinitialObj PI) |
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99 ≈↑⟨ car ( full→ SFS ) ⟩ |
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100 FMap F (FMap← (TMap u c o p o preinitialArrow PI)) o TMap u (preinitialObj PI) |
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101 ≈⟨ nat u ⟩ |
442 | 102 TMap u c o FMap (K A A a0) (FMap← (TMap u c o p o preinitialArrow PI)) |
441
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103 ≈⟨⟩ |
442 | 104 TMap u c o id1 A a0 |
441
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105 ≈⟨ idR ⟩ |
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106 TMap u c |
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107 ∎ |
442 | 108 kfuc=1 : {k1 : Obj A} → {p : Hom A k1 a0} → A [ A [ p o A [ preinitialArrow PI {k1} o TMap u (preinitialObj PI) ] ] ≈ id1 A a0 ] |
439 | 109 kfuc=1 {k1} {p} = e=id ( kfuc=uc ) |
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110 -- if equalizer has right inverse, f = g |
438 | 111 lemma2 : (a b : Obj A) {c : Obj A} ( f g : Hom A a b ) |
443 | 112 {e : Hom A c a } {e' : Hom A a c } ( equ : IsEqualizer A e f g ) (inv-e : A [ A [ e o e' ] ≈ id1 A a ] ) |
442 | 113 → A [ f ≈ g ] |
438 | 114 lemma2 a b {c} f g {e} {e'} equ inv-e = let open ≈-Reasoning (A) in |
435
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115 let open Equalizer in |
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116 begin |
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117 f |
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118 ≈↑⟨ idR ⟩ |
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119 f o id1 A a |
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120 ≈↑⟨ cdr inv-e ⟩ |
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121 f o ( e o e' ) |
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122 ≈⟨ assoc ⟩ |
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123 ( f o e ) o e' |
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124 ≈⟨ car ( fe=ge equ ) ⟩ ( g o e ) o e' |
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125 ≈↑⟨ assoc ⟩ |
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126 g o ( e o e' ) |
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127 ≈⟨ cdr inv-e ⟩ |
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128 g o id1 A a |
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129 ≈⟨ idR ⟩ |
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130 g |
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131 ∎ |
439 | 132 lemma1 : (a : Obj A) (f' : Hom A a0 a) → A [ f' ≈ initialArrow a ] |
438 | 133 lemma1 a f' = let open ≈-Reasoning (A) in |
436
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134 sym ( |
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135 begin |
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136 initialArrow a |
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137 ≈⟨⟩ |
440 | 138 preinitialArrow PI {a} o f |
442 | 139 ≈⟨ lemma2 a0 a (A [ preinitialArrow PI {a} o f ]) f' {ee {a0} {a} {A [ preinitialArrow PI {a} o f ]} {f'} } (equ-fi ) |
140 (kfuc=1 {ep} {ee} ) ⟩ | |
438 | 141 f' |
436
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142 ∎ ) |
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143 |