-- There is no category of categories in our interpretation {-# OPTIONS --cubical --allow-unsolved-metas #-} module Cat.Categories.Cat where open import Cat.Prelude renaming (proj₁ to fst ; proj₂ to snd) open import Cat.Category open import Cat.Category.Functor open import Cat.Category.Product open import Cat.Category.Exponential hiding (_×_ ; product) import Cat.Category.NaturalTransformation open import Cat.Categories.Fun -- The category of categories module _ (ℓ ℓ' : Level) where RawCat : RawCategory (lsuc (ℓ ⊔ ℓ')) (ℓ ⊔ ℓ') RawCategory.Object RawCat = Category ℓ ℓ' RawCategory.Arrow RawCat = Functor RawCategory.𝟙 RawCat = Functors.identity RawCategory._∘_ RawCat = F[_∘_] -- NB! `ArrowsAreSets RawCat` is *not* provable. The type of functors, -- however, form a groupoid! Therefore there is no (1-)category of -- categories. There does, however, exist a 2-category of 1-categories. -- -- Because of this there is no category of categories. Cat : (unprovable : IsCategory RawCat) → Category (lsuc (ℓ ⊔ ℓ')) (ℓ ⊔ ℓ') Category.raw (Cat _) = RawCat Category.isCategory (Cat unprovable) = unprovable -- | In the following we will pretend there is a category of categories when -- e.g. talking about it being cartesian closed. It still makes sense to -- construct these things even though that category does not exist. -- -- If the notion of a category is later generalized to work on different -- homotopy levels, then the proof that the category of categories is cartesian -- closed will follow immediately from these constructions. -- | the category of categories have products. module CatProduct {ℓ ℓ' : Level} (ℂ 𝔻 : Category ℓ ℓ') where private module ℂ = Category ℂ module 𝔻 = Category 𝔻 module _ where private Obj = ℂ.Object × 𝔻.Object Arr : Obj → Obj → Set ℓ' Arr (c , d) (c' , d') = ℂ [ c , c' ] × 𝔻 [ d , d' ] 𝟙 : {o : Obj} → Arr o o 𝟙 = ℂ.𝟙 , 𝔻.𝟙 _∘_ : {a b c : Obj} → Arr b c → Arr a b → Arr a c _∘_ = λ { (bc∈C , bc∈D) (ab∈C , ab∈D) → ℂ [ bc∈C ∘ ab∈C ] , 𝔻 [ bc∈D ∘ ab∈D ]} rawProduct : RawCategory ℓ ℓ' RawCategory.Object rawProduct = Obj RawCategory.Arrow rawProduct = Arr RawCategory.𝟙 rawProduct = 𝟙 RawCategory._∘_ rawProduct = _∘_ open RawCategory rawProduct arrowsAreSets : ArrowsAreSets arrowsAreSets = setSig {sA = ℂ.arrowsAreSets} {sB = λ x → 𝔻.arrowsAreSets} isIdentity : IsIdentity 𝟙 isIdentity = Σ≡ (fst ℂ.isIdentity) (fst 𝔻.isIdentity) , Σ≡ (snd ℂ.isIdentity) (snd 𝔻.isIdentity) postulate univalent : Univalence.Univalent isIdentity instance isCategory : IsCategory rawProduct IsCategory.isAssociative isCategory = Σ≡ ℂ.isAssociative 𝔻.isAssociative IsCategory.isIdentity isCategory = isIdentity IsCategory.arrowsAreSets isCategory = arrowsAreSets IsCategory.univalent isCategory = univalent object : Category ℓ ℓ' Category.raw object = rawProduct proj₁ : Functor object ℂ proj₁ = record { raw = record { omap = fst ; fmap = fst } ; isFunctor = record { isIdentity = refl ; isDistributive = refl } } proj₂ : Functor object 𝔻 proj₂ = record { raw = record { omap = snd ; fmap = snd } ; isFunctor = record { isIdentity = refl ; isDistributive = refl } } module _ {X : Category ℓ ℓ'} (x₁ : Functor X ℂ) (x₂ : Functor X 𝔻) where private x : Functor X object x = record { raw = record { omap = λ x → x₁.omap x , x₂.omap x ; fmap = λ x → x₁.fmap x , x₂.fmap x } ; isFunctor = record { isIdentity = Σ≡ x₁.isIdentity x₂.isIdentity ; isDistributive = Σ≡ x₁.isDistributive x₂.isDistributive } } where open module x₁ = Functor x₁ open module x₂ = Functor x₂ isUniqL : F[ proj₁ ∘ x ] ≡ x₁ isUniqL = Functor≡ refl isUniqR : F[ proj₂ ∘ x ] ≡ x₂ isUniqR = Functor≡ refl isUniq : F[ proj₁ ∘ x ] ≡ x₁ × F[ proj₂ ∘ x ] ≡ x₂ isUniq = isUniqL , isUniqR isProduct : ∃![ x ] (F[ proj₁ ∘ x ] ≡ x₁ × F[ proj₂ ∘ x ] ≡ x₂) isProduct = x , isUniq , uq where module _ {y : Functor X object} (eq : F[ proj₁ ∘ y ] ≡ x₁ × F[ proj₂ ∘ y ] ≡ x₂) where omapEq : Functor.omap x ≡ Functor.omap y omapEq = {!!} -- fmapEq : (λ i → {!{A B : ?} → Arrow A B → 𝔻 [ ? A , ? B ]!}) [ Functor.fmap x ≡ Functor.fmap y ] -- fmapEq = {!!} rawEq : Functor.raw x ≡ Functor.raw y rawEq = {!!} uq : x ≡ y uq = Functor≡ rawEq module _ {ℓ ℓ' : Level} (unprovable : IsCategory (RawCat ℓ ℓ')) where private Catℓ = Cat ℓ ℓ' unprovable module _ (ℂ 𝔻 : Category ℓ ℓ') where private module P = CatProduct ℂ 𝔻 rawProduct : RawProduct Catℓ ℂ 𝔻 RawProduct.object rawProduct = P.object RawProduct.proj₁ rawProduct = P.proj₁ RawProduct.proj₂ rawProduct = P.proj₂ isProduct : IsProduct Catℓ _ _ rawProduct IsProduct.ump isProduct = P.isProduct product : Product Catℓ ℂ 𝔻 Product.raw product = rawProduct Product.isProduct product = isProduct instance hasProducts : HasProducts Catℓ hasProducts = record { product = product } -- | The category of categories have expoentntials - and because it has products -- it is therefory also cartesian closed. module CatExponential {ℓ : Level} (ℂ 𝔻 : Category ℓ ℓ) where open Cat.Category.NaturalTransformation ℂ 𝔻 renaming (identity to identityNT) using () private module ℂ = Category ℂ module 𝔻 = Category 𝔻 Categoryℓ = Category ℓ ℓ open Fun ℂ 𝔻 renaming (identity to idN) omap : Functor ℂ 𝔻 × ℂ.Object → 𝔻.Object omap (F , A) = Functor.omap F A -- The exponential object object : Categoryℓ object = Fun module _ {dom cod : Functor ℂ 𝔻 × ℂ.Object} where open Σ dom renaming (proj₁ to F ; proj₂ to A) open Σ cod renaming (proj₁ to G ; proj₂ to B) private module F = Functor F module G = Functor G fmap : (pobj : NaturalTransformation F G × ℂ [ A , B ]) → 𝔻 [ F.omap A , G.omap B ] fmap ((θ , θNat) , f) = 𝔻 [ θ B ∘ F.fmap f ] -- Alternatively: -- -- fmap ((θ , θNat) , f) = 𝔻 [ G.fmap f ∘ θ A ] -- -- Since they are equal by naturality of θ. open CatProduct renaming (object to _⊗_) using () module _ {c : Functor ℂ 𝔻 × ℂ.Object} where open Σ c renaming (proj₁ to F ; proj₂ to C) ident : fmap {c} {c} (identityNT F , ℂ.𝟙 {A = snd c}) ≡ 𝔻.𝟙 ident = begin fmap {c} {c} (Category.𝟙 (object ⊗ ℂ) {c}) ≡⟨⟩ fmap {c} {c} (idN F , ℂ.𝟙) ≡⟨⟩ 𝔻 [ identityTrans F C ∘ F.fmap ℂ.𝟙 ] ≡⟨⟩ 𝔻 [ 𝔻.𝟙 ∘ F.fmap ℂ.𝟙 ] ≡⟨ 𝔻.leftIdentity ⟩ F.fmap ℂ.𝟙 ≡⟨ F.isIdentity ⟩ 𝔻.𝟙 ∎ where module F = Functor F module _ {F×A G×B H×C : Functor ℂ 𝔻 × ℂ.Object} where open Σ F×A renaming (proj₁ to F ; proj₂ to A) open Σ G×B renaming (proj₁ to G ; proj₂ to B) open Σ H×C renaming (proj₁ to H ; proj₂ to C) private module F = Functor F module G = Functor G module H = Functor H module _ {θ×f : NaturalTransformation F G × ℂ [ A , B ]} {η×g : NaturalTransformation G H × ℂ [ B , C ]} where open Σ θ×f renaming (proj₁ to θNT ; proj₂ to f) open Σ θNT renaming (proj₁ to θ ; proj₂ to θNat) open Σ η×g renaming (proj₁ to ηNT ; proj₂ to g) open Σ ηNT renaming (proj₁ to η ; proj₂ to ηNat) private ηθNT : NaturalTransformation F H ηθNT = NT[_∘_] {F} {G} {H} ηNT θNT open Σ ηθNT renaming (proj₁ to ηθ ; proj₂ to ηθNat) isDistributive : 𝔻 [ 𝔻 [ η C ∘ θ C ] ∘ F.fmap ( ℂ [ g ∘ f ] ) ] ≡ 𝔻 [ 𝔻 [ η C ∘ G.fmap g ] ∘ 𝔻 [ θ B ∘ F.fmap f ] ] isDistributive = begin 𝔻 [ (ηθ C) ∘ F.fmap (ℂ [ g ∘ f ]) ] ≡⟨ ηθNat (ℂ [ g ∘ f ]) ⟩ 𝔻 [ H.fmap (ℂ [ g ∘ f ]) ∘ (ηθ A) ] ≡⟨ cong (λ φ → 𝔻 [ φ ∘ ηθ A ]) (H.isDistributive) ⟩ 𝔻 [ 𝔻 [ H.fmap g ∘ H.fmap f ] ∘ (ηθ A) ] ≡⟨ sym 𝔻.isAssociative ⟩ 𝔻 [ H.fmap g ∘ 𝔻 [ H.fmap f ∘ ηθ A ] ] ≡⟨ cong (λ φ → 𝔻 [ H.fmap g ∘ φ ]) 𝔻.isAssociative ⟩ 𝔻 [ H.fmap g ∘ 𝔻 [ 𝔻 [ H.fmap f ∘ η A ] ∘ θ A ] ] ≡⟨ cong (λ φ → 𝔻 [ H.fmap g ∘ φ ]) (cong (λ φ → 𝔻 [ φ ∘ θ A ]) (sym (ηNat f))) ⟩ 𝔻 [ H.fmap g ∘ 𝔻 [ 𝔻 [ η B ∘ G.fmap f ] ∘ θ A ] ] ≡⟨ cong (λ φ → 𝔻 [ H.fmap g ∘ φ ]) (sym 𝔻.isAssociative) ⟩ 𝔻 [ H.fmap g ∘ 𝔻 [ η B ∘ 𝔻 [ G.fmap f ∘ θ A ] ] ] ≡⟨ 𝔻.isAssociative ⟩ 𝔻 [ 𝔻 [ H.fmap g ∘ η B ] ∘ 𝔻 [ G.fmap f ∘ θ A ] ] ≡⟨ cong (λ φ → 𝔻 [ φ ∘ 𝔻 [ G.fmap f ∘ θ A ] ]) (sym (ηNat g)) ⟩ 𝔻 [ 𝔻 [ η C ∘ G.fmap g ] ∘ 𝔻 [ G.fmap f ∘ θ A ] ] ≡⟨ cong (λ φ → 𝔻 [ 𝔻 [ η C ∘ G.fmap g ] ∘ φ ]) (sym (θNat f)) ⟩ 𝔻 [ 𝔻 [ η C ∘ G.fmap g ] ∘ 𝔻 [ θ B ∘ F.fmap f ] ] ∎ eval : Functor (CatProduct.object object ℂ) 𝔻 eval = record { raw = record { omap = omap ; fmap = λ {dom} {cod} → fmap {dom} {cod} } ; isFunctor = record { isIdentity = λ {o} → ident {o} ; isDistributive = λ {f u n k y} → isDistributive {f} {u} {n} {k} {y} } } module _ (𝔸 : Category ℓ ℓ) (F : Functor (𝔸 ⊗ ℂ) 𝔻) where postulate parallelProduct : Functor 𝔸 object → Functor ℂ ℂ → Functor (𝔸 ⊗ ℂ) (object ⊗ ℂ) transpose : Functor 𝔸 object eq : F[ eval ∘ (parallelProduct transpose (Functors.identity {ℂ = ℂ})) ] ≡ F -- eq : F[ :eval: ∘ {!!} ] ≡ F -- eq : Catℓ [ :eval: ∘ (HasProducts._|×|_ hasProducts transpose (𝟙 Catℓ {o = ℂ})) ] ≡ F -- eq' : (Catℓ [ :eval: ∘ -- (record { product = product } HasProducts.|×| transpose) -- (𝟙 Catℓ) -- ]) -- ≡ F -- For some reason after `e8215b2c051062c6301abc9b3f6ec67106259758` -- `catTranspose` makes Agda hang. catTranspose : ∃![ F~ ] (Catℓ [ -- :eval: ∘ (parallelProduct F~ (𝟙 Catℓ {o = ℂ}))] ≡ F) catTranspose = -- transpose , eq -- We don't care about filling out the holes below since they are anyways hidden -- behind an unprovable statement. module _ (ℓ : Level) (unprovable : IsCategory (RawCat ℓ ℓ)) where private Catℓ : Category (lsuc (ℓ ⊔ ℓ)) (ℓ ⊔ ℓ) Catℓ = Cat ℓ ℓ unprovable module _ (ℂ 𝔻 : Category ℓ ℓ) where module CatExp = CatExponential ℂ 𝔻 _⊗_ = CatProduct.object -- Filling the hole causes Agda to loop indefinitely. eval : Functor (CatExp.object ⊗ ℂ) 𝔻 eval = {!CatExp.eval!} isExponential : IsExponential Catℓ ℂ 𝔻 CatExp.object eval isExponential = {!CatExp.isExponential!} exponent : Exponential Catℓ ℂ 𝔻 exponent = record { obj = CatExp.object ; eval = eval ; isExponential = isExponential } hasExponentials : HasExponentials Catℓ hasExponentials = record { exponent = exponent }