Mercurial > hg > Members > kono > Proof > category
changeset 72:cbc30519e961
stack overflow solved by moving implicit parameters to module parameters
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Fri, 26 Jul 2013 12:38:54 +0900 |
| parents | 709c1bde54dc |
| children | b75b5792bd81 |
| files | adj-monad.agda nat.agda |
| diffstat | 2 files changed, 147 insertions(+), 170 deletions(-) [+] |
line wrap: on
line diff
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/adj-monad.agda Fri Jul 26 12:38:54 2013 +0900 @@ -0,0 +1,95 @@ +-- Monad +-- Category A +-- A = Category +-- Functor T : A → A +--T(a) = t(a) +--T(f) = tf(f) + +open import Category -- https://github.com/konn/category-agda +open import Level +--open import Category.HomReasoning +open import HomReasoning +open import cat-utility +open import Category.Cat + +module adj-monad where + +---- +-- +-- Adjunction to Monad +-- +---- + +open Adjunction +open NTrans +open Functor + +UεF : {c₁ c₂ ℓ c₁' c₂' ℓ' : Level} (A : Category c₁ c₂ ℓ) (B : Category c₁' c₂' ℓ') + ( U : Functor B A ) + ( F : Functor A B ) + ( ε : NTrans B B ( F ○ U ) identityFunctor ) → NTrans A A (( U ○ F ) ○ ( U ○ F )) ( U ○ F ) +UεF A B U F ε = lemma11 ( + Functor*Nat A {B} A U {( F ○ U) ○ F} {identityFunctor ○ F} ( Nat*Functor A {B} B { F ○ U} {identityFunctor} ε F) ) where + lemma11 : NTrans A A ( U ○ ((F ○ U) ○ F )) ( U ○ (identityFunctor ○ F) ) + → NTrans A A (( U ○ F ) ○ ( U ○ F )) ( U ○ F ) + lemma11 n = record { TMap = \a → TMap n a; isNTrans = record { naturality = IsNTrans.naturality ( isNTrans n ) }} + +Adj2Monad : {c₁ c₂ ℓ c₁' c₂' ℓ' : Level} (A : Category c₁ c₂ ℓ) (B : Category c₁' c₂' ℓ') + { U : Functor B A } + { F : Functor A B } + { η : NTrans A A identityFunctor ( U ○ F ) } + { ε : NTrans B B ( F ○ U ) identityFunctor } → + Adjunction A B U F η ε → Monad A (U ○ F) η (UεF A B U F ε) +Adj2Monad A B {U} {F} {η} {ε} adj = record { + isMonad = record { + assoc = assoc1; + unity1 = unity1; + unity2 = unity2 + } + } where + T : Functor A A + T = U ○ F + μ : NTrans A A ( T ○ T ) T + μ = UεF A B U F ε + lemma-assoc1 : {a b : Obj B} → ( f : Hom B a b) → + B [ B [ f o TMap ε a ] ≈ B [ TMap ε b o FMap F (FMap U f ) ] ] + lemma-assoc1 f = IsNTrans.naturality ( isNTrans ε ) + assoc1 : {a : Obj A} → A [ A [ TMap μ a o TMap μ ( FObj T a ) ] ≈ A [ TMap μ a o FMap T (TMap μ a) ] ] + assoc1 {a} = let open ≈-Reasoning (A) in + begin + TMap μ a o TMap μ ( FObj T a ) + ≈⟨⟩ + (FMap U (TMap ε ( FObj F a ))) o (FMap U (TMap ε ( FObj F ( FObj U (FObj F a ))))) + ≈⟨ sym (distr U) ⟩ + FMap U (B [ TMap ε ( FObj F a ) o TMap ε ( FObj F ( FObj U (FObj F a ))) ] ) + ≈⟨ (IsFunctor.≈-cong (isFunctor U)) (lemma-assoc1 ( TMap ε (FObj F a ))) ⟩ + FMap U (B [ (TMap ε ( FObj F a )) o FMap F (FMap U (TMap ε ( FObj F a ))) ] ) + ≈⟨ distr U ⟩ + (FMap U (TMap ε ( FObj F a ))) o FMap U (FMap F (FMap U (TMap ε ( FObj F a )))) + ≈⟨⟩ + TMap μ a o FMap T (TMap μ a) + ∎ + unity1 : {a : Obj A} → A [ A [ TMap μ a o TMap η ( FObj T a ) ] ≈ Id {_} {_} {_} {A} (FObj T a) ] + unity1 {a} = let open ≈-Reasoning (A) in + begin + TMap μ a o TMap η ( FObj T a ) + ≈⟨⟩ + (FMap U (TMap ε ( FObj F a ))) o TMap η ( FObj U ( FObj F a )) + ≈⟨ IsAdjunction.adjoint1 ( isAdjunction adj ) ⟩ + id (FObj U ( FObj F a )) + ≈⟨⟩ + id (FObj T a) + ∎ + unity2 : {a : Obj A} → A [ A [ TMap μ a o (FMap T (TMap η a ))] ≈ Id {_} {_} {_} {A} (FObj T a) ] + unity2 {a} = let open ≈-Reasoning (A) in + begin + TMap μ a o (FMap T (TMap η a )) + ≈⟨⟩ + (FMap U (TMap ε ( FObj F a ))) o (FMap U ( FMap F (TMap η a ))) + ≈⟨ sym (distr U ) ⟩ + FMap U ( B [ (TMap ε ( FObj F a )) o ( FMap F (TMap η a )) ]) + ≈⟨ (IsFunctor.≈-cong (isFunctor U)) (IsAdjunction.adjoint2 ( isAdjunction adj )) ⟩ + FMap U ( id1 B (FObj F a) ) + ≈⟨ IsFunctor.identity ( isFunctor U ) ⟩ + id (FObj T a) + ∎
--- a/nat.agda Fri Jul 26 11:42:57 2013 +0900 +++ b/nat.agda Fri Jul 26 12:38:54 2013 +0900 @@ -1,4 +1,4 @@ -module nat where + -- Monad -- Category A @@ -12,6 +12,15 @@ --open import Category.HomReasoning open import HomReasoning open import cat-utility +open import Category.Cat + +module nat { c₁ c₂ ℓ : Level} { A : Category c₁ c₂ ℓ } + { T : Functor A A } + { η : NTrans A A identityFunctor T } + { μ : NTrans A A (T ○ T) T } + { M : Monad A T η μ } + { K : Kleisli A T η μ M } where + --T(g f) = T(g) T(f) @@ -27,8 +36,6 @@ → A [ A [ FMap G f o TMap μ a ] ≈ A [ TMap μ b o FMap F f ] ] Lemma2 = \n → IsNTrans.naturality ( isNTrans n ) -open import Category.Cat - -- η : 1_A → T -- μ : TT → T -- μ(a)η(T(a)) = a @@ -111,49 +118,36 @@ ∎ -- f ○ η(a) = f -Lemma8 : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) - ( T : Functor A A ) - ( η : NTrans A A identityFunctor T ) - { μ : NTrans A A (T ○ T) T } - ( a : Obj A ) ( b : Obj A ) +Lemma8 : ( a : Obj A ) ( b : Obj A ) ( f : Hom A a ( FObj T b) ) - ( m : Monad A T η μ ) - ( k : Kleisli A T η μ m) - → A [ join k f (TMap η a) ≈ f ] -Lemma8 c T η a b f m k = + → A [ join K f (TMap η a) ≈ f ] +Lemma8 a b f = begin - join k f (TMap η a) + join K f (TMap η a) ≈⟨ refl-hom ⟩ - c [ TMap μ b o c [ FMap T f o (TMap η a) ] ] + A [ TMap μ b o A [ FMap T f o (TMap η a) ] ] ≈⟨ cdr ( nat η ) ⟩ - c [ TMap μ b o c [ (TMap η ( FObj T b)) o f ] ] - ≈⟨ IsCategory.associative (Category.isCategory c) ⟩ - c [ c [ TMap μ b o (TMap η ( FObj T b)) ] o f ] - ≈⟨ car ( IsMonad.unity1 ( isMonad ( monad k )) ) ⟩ - c [ id (FObj T b) o f ] - ≈⟨ IsCategory.identityL (Category.isCategory c) ⟩ + A [ TMap μ b o A [ (TMap η ( FObj T b)) o f ] ] + ≈⟨ IsCategory.associative (Category.isCategory A) ⟩ + A [ A [ TMap μ b o (TMap η ( FObj T b)) ] o f ] + ≈⟨ car ( IsMonad.unity1 ( isMonad ( monad K )) ) ⟩ + A [ id (FObj T b) o f ] + ≈⟨ IsCategory.identityL (Category.isCategory A) ⟩ f ∎ where - open ≈-Reasoning (c) - μ = mu ( monad k ) + open ≈-Reasoning (A) -- h ○ (g ○ f) = (h ○ g) ○ f -Lemma9 : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) - { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } - { a b c d : Obj A } +Lemma9 : { a b c d : Obj A } ( f : Hom A a ( FObj T b) ) ( g : Hom A b ( FObj T c) ) ( h : Hom A c ( FObj T d) ) - ( m : Monad A T η μ ) - { k : Kleisli A T η μ m} - → A [ join k h (join k g f) ≈ join k ( join k h g) f ] -Lemma9 A {T} {η} {μ} {a} {b} {c} {d} f g h m {k} = + → A [ join K h (join K g f) ≈ join K ( join K h g) f ] +Lemma9 {a} {b} {c} {d} f g h = begin - join k h (join k g f) + join K h (join K g f) ≈⟨⟩ - join k h ( ( TMap μ c o ( FMap T g o f ) ) ) + join K h ( ( TMap μ c o ( FMap T g o f ) ) ) ≈⟨ refl-hom ⟩ ( TMap μ d o ( FMap T h o ( TMap μ c o ( FMap T g o f ) ) ) ) ≈⟨ cdr ( cdr ( assoc )) ⟩ @@ -186,7 +180,7 @@ ≈⟨ car ( car ( begin ( TMap μ d o TMap μ (FObj T d) ) - ≈⟨ IsMonad.assoc ( isMonad m) ⟩ + ≈⟨ IsMonad.assoc ( isMonad M) ⟩ ( TMap μ d o FMap T (TMap μ d) ) ∎ )) ⟩ @@ -198,176 +192,64 @@ ≈⟨ cdr ( car ( sym ( distr T ))) ⟩ ( TMap μ d o ( FMap T ( ( ( TMap μ d ) o ( FMap T h o g ) ) ) o f ) ) ≈⟨ refl-hom ⟩ - join k ( ( TMap μ d o ( FMap T h o g ) ) ) f + join K ( ( TMap μ d o ( FMap T h o g ) ) ) f ≈⟨ refl-hom ⟩ - join k ( join k h g) f + join K ( join K h g) f ∎ where open ≈-Reasoning (A) -KHom1 : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) → ( T : Functor A A ) (a : Obj A) → (b : Obj A) -> Set (c₂ ⊔ c₁) +KHom1 : (a : Obj A) → (b : Obj A) -> Set (c₂ ⊔ c₁) KHom1 = {!!} -record KHom {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) ( T : Functor A A ) (a : Obj A) (b : Obj A) +record KHom (a : Obj A) (b : Obj A) : Set (suc (c₂ ⊔ c₁)) where field KMap : Hom A a ( FObj T b ) -K-id : {c₁ c₂ ℓ : Level} {A : Category c₁ c₂ ℓ} { T : Functor A A } {η : NTrans A A identityFunctor T} {a : Obj A} → KHom A T a a -K-id {_} {_} {_} {A} {T} {η} {a = a} = record { KMap = TMap η a } +K-id : {a : Obj A} → KHom a a +K-id {a = a} = record { KMap = TMap η a } open import Relation.Binary.Core -_⋍_ : ∀{c₁ c₂ ℓ} {A : Category c₁ c₂ ℓ} { T : Functor A A } - { a : Obj A } { b : Obj A } (f g : KHom A T a b ) -> Set (suc ((c₂ ⊔ c₁) ⊔ ℓ)) +_⋍_ : + { a : Obj A } { b : Obj A } (f g : KHom a b ) -> Set (suc ((c₂ ⊔ c₁) ⊔ ℓ)) _⋍_ = {!!} +open KHom -_*_ : { c₁ c₂ ℓ : Level} { A : Category c₁ c₂ ℓ } - { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } - { M : Monad A T η μ } → - { K : Kleisli A T η μ M } → - { a b : Obj A } → { c : Obj A } → - ( Hom A b ( FObj T c )) → ( Hom A a ( FObj T b)) → Hom A a ( FObj T c ) -_*_ {_} {_} {_} {_} {_} {_} {_} {_} {K} {a} {b} {c} g f = join K {a} {b} {c} g f +_*_ : { a b : Obj A } → { c : Obj A } → + ( KHom b c) → ( KHom a b) → KHom a c +_*_ {a} {b} {c} g f = record { KMap = join K {a} {b} {c} (KMap g) (KMap f) } -isKleisliCategory : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) - { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } - ( m : Monad A T η μ ) - { k : Kleisli A T η μ m} → - IsCategory ( Obj A ) ( KHom A T ) _⋍_ _*_ K-id -isKleisliCategory A {T} {η} m = record { isEquivalence = isEquivalence A T +isKleisliCategory : IsCategory ( Obj A ) KHom _⋍_ _*_ K-id +isKleisliCategory = record { isEquivalence = isEquivalence ; identityL = KidL ; identityR = KidR ; o-resp-≈ = Ko-resp ; associative = Kassoc } where - isEquivalence : {c₁ c₂ ℓ : Level} (A : Category c₁ c₂ ℓ) → ( T : Functor A A ) -> { a b : Obj A } -> - IsEquivalence {_} {_} {KHom A T a b} _⋍_ - isEquivalence A T {C} {D} = + isEquivalence : { a b : Obj A } -> + IsEquivalence {_} {_} {KHom a b} _⋍_ + isEquivalence {C} {D} = record { refl = λ {F} → ⋍-refl {F} ; sym = λ {F} {G} → ⋍-sym {F} {G} ; trans = λ {F} {G} {H} → ⋍-trans {F} {G} {H} } where - ⋍-refl : {F : KHom A T C D} → F ⋍ F + ⋍-refl : {F : KHom C D} → F ⋍ F ⋍-refl = {!!} - ⋍-sym : {F G : KHom A T C D} → F ⋍ G → G ⋍ F + ⋍-sym : {F G : KHom C D} → F ⋍ G → G ⋍ F ⋍-sym = {!!} - ⋍-trans : {F G H : KHom A T C D} → F ⋍ G → G ⋍ H → F ⋍ H + ⋍-trans : {F G H : KHom C D} → F ⋍ G → G ⋍ H → F ⋍ H ⋍-trans = {!!} - KidL : {c₁ c₂ ℓ : Level} { A : Category c₁ c₂ ℓ} { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } { m : Monad A T η μ } → {C D : Obj A} -> {f : KHom A T C D} → (K-id * f) ⋍ f + KidL : {C D : Obj A} -> {f : KHom C D} → (K-id * f) ⋍ f KidL = {!!} - KidR : {c₁ c₂ ℓ : Level} { A : Category c₁ c₂ ℓ} { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } { m : Monad A T η μ } → {C D : Obj A} -> {f : KHom A T C D} → (f * K-id) ⋍ f + KidR : {C D : Obj A} -> {f : KHom C D} → (f * K-id) ⋍ f KidR = {!!} - Ko-resp : {c₁ c₂ ℓ : Level} { A : Category c₁ c₂ ℓ} { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } { m : Monad A T η μ } → {a b c : Obj A} -> {f g : KHom A T a b } → {h i : KHom A T b c } → + Ko-resp : {a b c : Obj A} -> {f g : KHom a b } → {h i : KHom b c } → f ⋍ g → h ⋍ i → (h * f) ⋍ (i * g) Ko-resp = {!!} - Kassoc : {c₁ c₂ ℓ : Level} { A : Category c₁ c₂ ℓ} { T : Functor A A } - { η : NTrans A A identityFunctor T } - { μ : NTrans A A (T ○ T) T } { m : Monad A T η μ } → {a b c : Obj A} -> {f g : KHom A T a b } → {h i : KHom A T b c } → + Kassoc : {a b c d : Obj A} -> {f : KHom c d } → {g : KHom b c } → {h : KHom a b } → (f * (g * h)) ⋍ ((f * g) * h) Kassoc = {!!} --- Kleisli : --- Kleisli = record { Hom = --- ; Hom = _⟶_ --- ; Id = IdProd --- ; _o_ = _∘_ --- ; _≈_ = _≈_ --- ; isCategory = record { isEquivalence = record { refl = λ {φ} → ≈-refl {φ = φ} --- ; sym = λ {φ ψ} → ≈-symm {φ = φ} {ψ} --- ; trans = λ {φ ψ σ} → ≈-trans {φ = φ} {ψ} {σ} --- } --- ; identityL = identityL --- ; identityR = identityR --- ; o-resp-≈ = o-resp-≈ --- ; associative = associative --- } --- } ----- --- --- Adjunction to Monad --- ----- - -open Adjunction - -UεF : {c₁ c₂ ℓ c₁' c₂' ℓ' : Level} (A : Category c₁ c₂ ℓ) (B : Category c₁' c₂' ℓ') - ( U : Functor B A ) - ( F : Functor A B ) - ( ε : NTrans B B ( F ○ U ) identityFunctor ) → NTrans A A (( U ○ F ) ○ ( U ○ F )) ( U ○ F ) -UεF A B U F ε = lemma11 ( - Functor*Nat A {B} A U {( F ○ U) ○ F} {identityFunctor ○ F} ( Nat*Functor A {B} B { F ○ U} {identityFunctor} ε F) ) where - lemma11 : NTrans A A ( U ○ ((F ○ U) ○ F )) ( U ○ (identityFunctor ○ F) ) - → NTrans A A (( U ○ F ) ○ ( U ○ F )) ( U ○ F ) - lemma11 n = record { TMap = \a → TMap n a; isNTrans = record { naturality = IsNTrans.naturality ( isNTrans n ) }} - -Adj2Monad : {c₁ c₂ ℓ c₁' c₂' ℓ' : Level} (A : Category c₁ c₂ ℓ) (B : Category c₁' c₂' ℓ') - { U : Functor B A } - { F : Functor A B } - { η : NTrans A A identityFunctor ( U ○ F ) } - { ε : NTrans B B ( F ○ U ) identityFunctor } → - Adjunction A B U F η ε → Monad A (U ○ F) η (UεF A B U F ε) -Adj2Monad A B {U} {F} {η} {ε} adj = record { - isMonad = record { - assoc = assoc1; - unity1 = unity1; - unity2 = unity2 - } - } where - T : Functor A A - T = U ○ F - μ : NTrans A A ( T ○ T ) T - μ = UεF A B U F ε - lemma-assoc1 : {a b : Obj B} → ( f : Hom B a b) → - B [ B [ f o TMap ε a ] ≈ B [ TMap ε b o FMap F (FMap U f ) ] ] - lemma-assoc1 f = IsNTrans.naturality ( isNTrans ε ) - assoc1 : {a : Obj A} → A [ A [ TMap μ a o TMap μ ( FObj T a ) ] ≈ A [ TMap μ a o FMap T (TMap μ a) ] ] - assoc1 {a} = let open ≈-Reasoning (A) in - begin - TMap μ a o TMap μ ( FObj T a ) - ≈⟨⟩ - (FMap U (TMap ε ( FObj F a ))) o (FMap U (TMap ε ( FObj F ( FObj U (FObj F a ))))) - ≈⟨ sym (distr U) ⟩ - FMap U (B [ TMap ε ( FObj F a ) o TMap ε ( FObj F ( FObj U (FObj F a ))) ] ) - ≈⟨ (IsFunctor.≈-cong (isFunctor U)) (lemma-assoc1 ( TMap ε (FObj F a ))) ⟩ - FMap U (B [ (TMap ε ( FObj F a )) o FMap F (FMap U (TMap ε ( FObj F a ))) ] ) - ≈⟨ distr U ⟩ - (FMap U (TMap ε ( FObj F a ))) o FMap U (FMap F (FMap U (TMap ε ( FObj F a )))) - ≈⟨⟩ - TMap μ a o FMap T (TMap μ a) - ∎ - unity1 : {a : Obj A} → A [ A [ TMap μ a o TMap η ( FObj T a ) ] ≈ Id {_} {_} {_} {A} (FObj T a) ] - unity1 {a} = let open ≈-Reasoning (A) in - begin - TMap μ a o TMap η ( FObj T a ) - ≈⟨⟩ - (FMap U (TMap ε ( FObj F a ))) o TMap η ( FObj U ( FObj F a )) - ≈⟨ IsAdjunction.adjoint1 ( isAdjunction adj ) ⟩ - id (FObj U ( FObj F a )) - ≈⟨⟩ - id (FObj T a) - ∎ - unity2 : {a : Obj A} → A [ A [ TMap μ a o (FMap T (TMap η a ))] ≈ Id {_} {_} {_} {A} (FObj T a) ] - unity2 {a} = let open ≈-Reasoning (A) in - begin - TMap μ a o (FMap T (TMap η a )) - ≈⟨⟩ - (FMap U (TMap ε ( FObj F a ))) o (FMap U ( FMap F (TMap η a ))) - ≈⟨ sym (distr U ) ⟩ - FMap U ( B [ (TMap ε ( FObj F a )) o ( FMap F (TMap η a )) ]) - ≈⟨ (IsFunctor.≈-cong (isFunctor U)) (IsAdjunction.adjoint2 ( isAdjunction adj )) ⟩ - FMap U ( id1 B (FObj F a) ) - ≈⟨ IsFunctor.identity ( isFunctor U ) ⟩ - id (FObj T a) - ∎