Mercurial > hg > Members > kono > Proof > category
view limit-to.agda @ 465:d3cd28a71b3f
clean up
author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Sat, 04 Mar 2017 16:26:57 +0900 |
parents | e618db534987 |
children | 44bd77c80555 |
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open import Category -- https://github.com/konn/category-agda open import Level module limit-to where open import cat-utility open import HomReasoning open import Relation.Binary.Core open import discrete --- Equalizer from Limit ( 2->A functor Γ and Nat : K -> Γ) --- --- --- f --- e -----→ --- c -----→ a b A --- ^ / -----→ --- |k h g --- | / --- | / ^ --- | / | --- |/ | Γ --- d _ | --- |\ | --- \ K af --- \ -----→ --- \ t0 t1 I --- -----→ --- ag --- --- open Complete open Limit open NTrans -- Functor Γ : TwoCat -> A IndexFunctor : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) ( a b : Obj A) ( f g : Hom A a b ) → Functor (TwoCat {c₁} {c₂}) A IndexFunctor {c₁} {c₂} {ℓ} A a b f g = record { FObj = λ a → fobj a ; FMap = λ {a} {b} f → fmap {a} {b} f ; isFunctor = record { identity = λ{x} → identity x ; distr = λ {a} {b} {c} {f} {g} → distr1 {a} {b} {c} {f} {g} ; ≈-cong = λ {a} {b} {c} {f} → ≈-cong {a} {b} {c} {f} } } where T = TwoCat {c₁} {c₂} fobj : Obj T → Obj A fobj t0 = a fobj t1 = b fmap : {x y : Obj T } → (Hom T x y ) → Hom A (fobj x) (fobj y) fmap {t0} {t0} id-t0 = id1 A a fmap {t1} {t1} id-t1 = id1 A b fmap {t0} {t1} arrow-f = f fmap {t0} {t1} arrow-g = g ≈-cong : {a : Obj T} {b : Obj T} {f g : Hom T a b} → T [ f ≈ g ] → A [ fmap f ≈ fmap g ] ≈-cong {a} {b} {f} {.f} refl = let open ≈-Reasoning A in refl-hom identity : (x : Obj T ) -> A [ fmap (id1 T x) ≈ id1 A (fobj x) ] identity t0 = let open ≈-Reasoning A in refl-hom identity t1 = let open ≈-Reasoning A in refl-hom distr1 : {a : Obj T} {b : Obj T} {c : Obj T} {f : Hom T a b} {g : Hom T b c} → A [ fmap (T [ g o f ]) ≈ A [ fmap g o fmap f ] ] distr1 {t0} {t0} {t0} {id-t0 } { id-t0 } = let open ≈-Reasoning A in sym-hom idL distr1 {t1} {t1} {t1} { id-t1 } { id-t1 } = let open ≈-Reasoning A in begin id1 A b ≈↑⟨ idL ⟩ id1 A b o id1 A b ∎ distr1 {t0} {t0} {t1} { id-t0 } { arrow-f } = let open ≈-Reasoning A in begin fmap (T [ arrow-f o id-t0 ] ) ≈⟨⟩ fmap arrow-f ≈↑⟨ idR ⟩ fmap arrow-f o id1 A a ∎ distr1 {t0} {t0} {t1} { id-t0 } { arrow-g } = let open ≈-Reasoning A in begin fmap (T [ arrow-g o id-t0 ] ) ≈⟨⟩ fmap arrow-g ≈↑⟨ idR ⟩ fmap arrow-g o id1 A a ∎ distr1 {t0} {t1} {t1} { arrow-f } { id-t1 } = let open ≈-Reasoning A in begin fmap (T [ id-t1 o arrow-f ] ) ≈⟨⟩ fmap arrow-f ≈↑⟨ idL ⟩ id1 A b o fmap arrow-f ∎ distr1 {t0} {t1} {t1} { arrow-g } { id-t1 } = let open ≈-Reasoning A in begin fmap (T [ id-t1 o arrow-g ] ) ≈⟨⟩ fmap arrow-g ≈↑⟨ idL ⟩ id1 A b o fmap arrow-g ∎ --- Nat for Limit -- -- Nat : K -> IndexFunctor -- open Functor IndexNat : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) → {a b : Obj A} (f g : Hom A a b ) (d : Obj A) → (h : Hom A d a ) → A [ A [ f o h ] ≈ A [ g o h ] ] → NTrans TwoCat A (K A TwoCat d) (IndexFunctor {c₁} {c₂} {ℓ} A a b f g) IndexNat {c₁} {c₂} {ℓ} A {a} {b} f g d h fh=gh = record { TMap = λ x → nmap x d h ; isNTrans = record { commute = λ {x} {y} {f'} → commute1 {x} {y} {f'} d h fh=gh } } where I = TwoCat {c₁} {c₂} Γ : Functor I A Γ = IndexFunctor {c₁} {c₂} {ℓ} A a b f g nmap : (x : Obj I ) ( d : Obj (A) ) (h : Hom A d a ) → Hom A (FObj (K A I d) x) (FObj Γ x) nmap t0 d h = h nmap t1 d h = A [ f o h ] commute1 : {x y : Obj I} {f' : Hom I x y} (d : Obj A) (h : Hom A d a ) → A [ A [ f o h ] ≈ A [ g o h ] ] → A [ A [ FMap Γ f' o nmap x d h ] ≈ A [ nmap y d h o FMap (K A I d) f' ] ] commute1 {t0} {t1} {arrow-f} d h fh=gh = let open ≈-Reasoning A in begin f o h ≈↑⟨ idR ⟩ (f o h ) o id1 A d ∎ commute1 {t0} {t1} {arrow-g} d h fh=gh = let open ≈-Reasoning A in begin g o h ≈↑⟨ fh=gh ⟩ f o h ≈↑⟨ idR ⟩ (f o h ) o id1 A d ∎ commute1 {t0} {t0} {id-t0} d h fh=gh = let open ≈-Reasoning A in begin id1 A a o h ≈⟨ idL ⟩ h ≈↑⟨ idR ⟩ h o id1 A d ∎ commute1 {t1} {t1} {id-t1} d h fh=gh = let open ≈-Reasoning A in begin id1 A b o ( f o h ) ≈⟨ idL ⟩ f o h ≈↑⟨ idR ⟩ ( f o h ) o id1 A d ∎ equlimit : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) {a b : Obj A} -> (f g : Hom A a b) (comp : Complete A TwoCat ) -> Hom A ( limit-c comp (IndexFunctor A a b f g)) a equlimit A {a} {b} f g comp = TMap (limit-u comp (IndexFunctor A a b f g)) t0 lim-to-equ : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) (comp : Complete A TwoCat ) → {a b : Obj A} (f g : Hom A a b ) → (fe=ge : A [ A [ f o (equlimit A f g comp) ] ≈ A [ g o (equlimit A f g comp) ] ] ) → IsEqualizer A (equlimit A f g comp) f g lim-to-equ {c₁} {c₂} {ℓ} A comp {a} {b} f g fe=ge = record { fe=ge = fe=ge ; k = λ {d} h fh=gh → k {d} h fh=gh ; ek=h = λ {d} {h} {fh=gh} → ek=h d h fh=gh ; uniqueness = λ {d} {h} {fh=gh} {k'} → uniquness d h fh=gh k' } where I : Category c₁ c₂ c₂ I = TwoCat Γ : Functor I A Γ = IndexFunctor A a b f g e : Hom A (limit-c comp (IndexFunctor A a b f g)) a e = equlimit A f g comp c : Obj A c = limit-c comp Γ natL : NTrans I A (K A I c) Γ natL = limit-u comp Γ lim : Limit A I Γ c natL lim = isLimit comp Γ nat0 : (d : Obj A) (h : Hom A d a) → A [ A [ f o h ] ≈ A [ g o h ] ] → NTrans I A (K A I d) Γ nat0 = IndexNat A f g k : {d : Obj A} (h : Hom A d a) → A [ A [ f o h ] ≈ A [ g o h ] ] → Hom A d c k {d} h fh=gh = limit lim d (nat0 d h fh=gh ) ek=h : (d : Obj A ) (h : Hom A d a ) → ( fh=gh : A [ A [ f o h ] ≈ A [ g o h ] ] ) → A [ A [ e o k h fh=gh ] ≈ h ] ek=h d h fh=gh = let open ≈-Reasoning A in begin e o k h fh=gh ≈⟨⟩ TMap (limit-u comp Γ) t0 o k h fh=gh ≈⟨ t0f=t lim {d} {nat0 d h fh=gh } {t0} ⟩ TMap (nat0 d h fh=gh) t0 ≈⟨⟩ h ∎ uniq-nat : {i : Obj I} → (d : Obj A ) (h : Hom A d a ) ( k' : Hom A d c ) ( fh=gh : A [ A [ f o h ] ≈ A [ g o h ] ]) → A [ A [ e o k' ] ≈ h ] → A [ A [ TMap (limit-u comp Γ) i o k' ] ≈ TMap (nat0 d h fh=gh) i ] uniq-nat {t0} d h k' fh=gh ek'=h = let open ≈-Reasoning A in begin TMap (limit-u comp Γ) t0 o k' ≈⟨⟩ e o k' ≈⟨ ek'=h ⟩ h ≈⟨⟩ TMap (nat0 d h fh=gh) t0 ∎ uniq-nat {t1} d h k' fh=gh ek'=h = let open ≈-Reasoning A in begin TMap (limit-u comp Γ) t1 o k' ≈↑⟨ car (idR) ⟩ ( TMap (limit-u comp Γ) t1 o id1 A c ) o k' ≈⟨⟩ ( TMap (limit-u comp Γ) t1 o FMap (K A I c) arrow-f ) o k' ≈↑⟨ car ( nat1 (limit-u comp Γ) arrow-f ) ⟩ ( FMap Γ arrow-f o TMap (limit-u comp Γ) t0 ) o k' ≈⟨⟩ (f o e ) o k' ≈↑⟨ assoc ⟩ f o ( e o k' ) ≈⟨ cdr ek'=h ⟩ f o h ≈⟨⟩ TMap (nat0 d h fh=gh) t1 ∎ uniquness : (d : Obj A ) (h : Hom A d a ) → ( fh=gh : A [ A [ f o h ] ≈ A [ g o h ] ] ) → ( k' : Hom A d c ) → A [ A [ e o k' ] ≈ h ] → A [ k h fh=gh ≈ k' ] uniquness d h fh=gh k' ek'=h = let open ≈-Reasoning A in begin k h fh=gh ≈⟨ limit-uniqueness lim k' ( λ{i} → uniq-nat {i} d h k' fh=gh ek'=h ) ⟩ k' ∎