Category.Construction.ElgotAlgebras.Exponentials

module Category.Construction.ElgotAlgebras.Exponentials {o ℓ e} {C : Category o ℓ e} (distributive : Distributive C) (exp : ∀ {A B} → Exponential C A B) where
  open Category C
  open HomReasoning
  open M C
  open MR C
  open MP C
  open Equiv
  open Distributive distributive
  open import Categories.Category.Distributive.Properties distributive
  ccc : CartesianClosed C
  ccc = record { cartesian = cartesian ; exp = exp }
  open CartesianClosed ccc hiding (cartesian; exp)
  open Cocartesian cocartesian
  open Cartesian cartesian
  open BinaryProducts products renaming (unique to ⟨⟩-unique; unique′ to ⟨⟩-unique′)
  open import Algebra.Elgot cocartesian
  open import Category.Construction.ElgotAlgebras cocartesian
  open import Category.Construction.ElgotAlgebras.Products cocartesian cartesian
  
  Exponential-Elgot-Algebra : ∀ {EA : Elgot-Algebra} {X : Obj} → Elgot-Algebra
  Exponential-Elgot-Algebra {EA} {X} = record
    { A = A ^ X
    ; algebra = record
      { _# = λ {Z} f → λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)
      ; #-Fixpoint = λ {X} {f} → begin 
        λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ≈⟨ λ-cong #ᵃ-Fixpoint ⟩ 
        λg ([ id , ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ ] ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) ≈⟨ λ-cong ((pullˡ []∘+₁) ○ ([]-cong₂ identityˡ identityʳ) ⟩∘⟨refl) ⟩
        λg ([ eval′ , ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ ] ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) ≈˘⟨ λ-unique′ (begin 
          eval′ ∘ (([ id , λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ] ∘ f) ⁂ id) ≈˘⟨ refl⟩∘⟨ (⁂∘⁂ ○ ⁂-cong₂ refl identity²) ⟩ 
          eval′ ∘ ([ id , λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ] ⁂ id) ∘ (f ⁂ id) ≈⟨ refl⟩∘⟨ (⟨⟩-unique (begin 
            π₁ ∘ [ id , (λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) ⁂ id ] ∘ distributeʳ⁻¹ ≈⟨ pullˡ (∘[] ○ []-cong₂ id-comm π₁∘⁂) ⟩ 
            [ id ∘ π₁ , (λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) ∘ π₁ ] ∘ distributeʳ⁻¹ ≈˘⟨ pullˡ []∘+₁ ⟩ 
            [ id , (λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) ] ∘ (π₁ +₁ π₁) ∘ distributeʳ⁻¹ ≈⟨ refl⟩∘⟨ distributeʳ⁻¹-π₁ ⟩ 
            [ id , λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ] ∘ π₁ ∎) 
          (begin 
            π₂ ∘ [ id , (λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) ⁂ id ] ∘ distributeʳ⁻¹ ≈⟨ pullˡ (∘[] ○ []-cong₂ identityʳ (π₂∘⁂ ○ identityˡ)) ⟩ 
            [ π₂ , π₂ ] ∘ distributeʳ⁻¹ ≈⟨ distributeʳ⁻¹-π₂ ○ (sym identityˡ) ⟩ 
            id ∘ π₂ ∎) 
          ⟩∘⟨refl) ⟩ 
          eval′ ∘ ([ id , (λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) ⁂ id ] ∘ distributeʳ⁻¹) ∘ (f ⁂ id) ≈⟨ pullˡ (pullˡ ∘[]) ⟩ 
          ([ eval′ ∘ id , eval′ ∘ ((λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) ⁂ id) ] ∘ distributeʳ⁻¹) ∘ (f ⁂ id) ≈⟨ assoc ○ ([]-cong₂ identityʳ β′) ⟩∘⟨refl ⟩ 
          [ eval′ , ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ ] ∘ distributeʳ⁻¹ ∘ (f ⁂ id) ∎) ⟩
        [ id , λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ] ∘ f ∎
      ; #-Uniformity = #-Uniformity
      ; #-Folding = #-Folding
      ; #-resp-≈ = λ {Z} {f} {g} f≈g → λ-cong (#ᵃ-resp-≈ (refl⟩∘⟨ refl⟩∘⟨ ⁂-cong₂ f≈g refl))
      }
    }
    where
    open Elgot-Algebra EA using (A) renaming (_# to _#ᵃ; #-Fixpoint to #ᵃ-Fixpoint; #-Uniformity to #ᵃ-Uniformity; #-Folding to #ᵃ-Folding; #-resp-≈ to #ᵃ-resp-≈)
    #-Uniformity : ∀ {D E} {f : D ⇒ A ^ X + D} {g : E ⇒ A ^ X + E} {h : D ⇒ E} → (id +₁ h) ∘ f ≈ g ∘ h → λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ≈ λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ⁂ id)) #ᵃ) ∘ h
    #-Uniformity {D} {E} {f} {g} {h} eq = sym (λ-unique′ (begin 
      eval′ ∘ ((λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ⁂ id)) #ᵃ) ∘ h) ⁂ id) ≈˘⟨ refl⟩∘⟨ (⁂∘⁂ ○ ⁂-cong₂ refl identityˡ) ⟩ 
      eval′ ∘ ((λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ⁂ id)) #ᵃ)) ⁂ id) ∘ (h ⁂ id) ≈⟨ pullˡ β′ ⟩ 
      ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ⁂ id)) #ᵃ ∘ (h ⁂ id) ≈˘⟨ #ᵃ-Uniformity by-uni ⟩ 
      ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ ∎))
      where
      by-uni : (id +₁ (h ⁂ id)) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) ≈ ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ⁂ id)) ∘ (h ⁂ id)
      by-uni = begin 
        (id +₁ (h ⁂ id)) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) ≈⟨ pullˡ (+₁∘+₁ ○ +₁-cong₂ identityˡ identityʳ) ⟩ 
        (eval′ +₁ (h ⁂ id)) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) ≈˘⟨ pullˡ (+₁∘+₁ ○ +₁-cong₂ identityʳ identityˡ) ⟩ 
        (eval′ +₁ id) ∘ (id +₁ (h ⁂ id)) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) ≈⟨ refl⟩∘⟨ pullˡ ((+₁-cong₂ (sym (⟨⟩-unique id-comm id-comm)) refl) ⟩∘⟨refl ○ distributeʳ⁻¹-natural id id h) ⟩
        (eval′ +₁ id) ∘ (distributeʳ⁻¹ ∘ ((id +₁ h) ⁂ id)) ∘ (f ⁂ id) ≈⟨ refl⟩∘⟨ pullʳ (⁂∘⁂ ○ ⁂-cong₂ eq identity²) ⟩ 
        (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ∘ h ⁂ id) ≈˘⟨ pullʳ (pullʳ (⁂∘⁂ ○ ⁂-cong₂ refl identity²)) ⟩ 
        ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (g ⁂ id)) ∘ (h ⁂ id) ∎
    #-Folding : ∀ {D E} {f : D ⇒ A ^ X + D} {h : E ⇒ D + E} → λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ((λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) +₁ h) ⁂ id)) #ᵃ) ≈ λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id)) #ᵃ)
    #-Folding {D} {E} {f} {h} = λ-cong (begin 
      ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ((λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) +₁ h) ⁂ id)) #ᵃ ≈⟨ #ᵃ-resp-≈ (refl⟩∘⟨ sym (distributeʳ⁻¹-natural id (λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ)) h)) ⟩ 
      ((eval′ +₁ id) ∘ ((λg (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ) ⁂ id) +₁ (h ⁂ id)) ∘ distributeʳ⁻¹) #ᵃ ≈⟨ #ᵃ-resp-≈ (pullˡ (+₁∘+₁ ○ +₁-cong₂ β′ identityˡ)) ⟩ 
      ((((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ +₁ h ⁂ id) ∘ distributeʳ⁻¹) #ᵃ ≈⟨ #ᵃ-Uniformity by-uni₁ ⟩ 
      (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ +₁ distributeʳ⁻¹ ∘ (h ⁂ id)) #ᵃ ∘ distributeʳ⁻¹ ≈⟨ #ᵃ-Folding ⟩∘⟨refl ⟩ 
      [ ((id +₁ i₁) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) , (i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id)) ] #ᵃ ∘ distributeʳ⁻¹ ≈˘⟨ #ᵃ-Uniformity by-uni₂ ⟩ 
      ((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id)) #ᵃ ∎)
      where
      by-uni₁ : (id +₁ distributeʳ⁻¹) ∘ (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ +₁ h ⁂ id) ∘ distributeʳ⁻¹ ≈ ((((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ +₁ distributeʳ⁻¹ ∘ (h ⁂ id))) ∘ distributeʳ⁻¹
      by-uni₁ = begin 
        (id +₁ distributeʳ⁻¹) ∘ (((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ +₁ h ⁂ id) ∘ distributeʳ⁻¹ ≈⟨ pullˡ (+₁∘+₁ ○ +₁-cong₂ identityˡ refl) ⟩ 
        ((((eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id)) #ᵃ +₁ distributeʳ⁻¹ ∘ (h ⁂ id))) ∘ distributeʳ⁻¹ ∎
      by-uni₂ : (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id) ≈ [ (id +₁ i₁) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) , i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id) ] ∘ distributeʳ⁻¹
      by-uni₂ = Iso⇒Epi (IsIso.iso isIsoʳ) ((id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id)) ([ (id +₁ i₁) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) , i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id) ] ∘ distributeʳ⁻¹) (begin 
        ((id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id)) ∘ distributeʳ ≈⟨ ∘[] ⟩ 
        [ (((id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id)) ∘ (i₁ ⁂ id)) , (((id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ([ (id +₁ i₁) ∘ f , i₂ ∘ h ] ⁂ id)) ∘ (i₂ ⁂ id)) ] ≈⟨ []-cong₂ (pullʳ (pullʳ (pullʳ (⁂∘⁂ ○ ⁂-cong₂ inject₁ identity²)))) (pullʳ (pullʳ (pullʳ (⁂∘⁂ ○ ⁂-cong₂ inject₂ identity²)))) ⟩ 
        [ (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (((id +₁ i₁) ∘ f) ⁂ id) , (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ ((i₂ ∘ h) ⁂ id) ] ≈⟨ []-cong₂ (refl⟩∘⟨ refl⟩∘⟨ refl⟩∘⟨ sym (⁂∘⁂ ○ ⁂-cong₂ refl identity²)) (refl⟩∘⟨ refl⟩∘⟨ refl⟩∘⟨ sym (⁂∘⁂ ○ ⁂-cong₂ refl identity²)) ⟩ 
        [ (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (((id +₁ i₁)) ⁂ id) ∘ (f ⁂ id) , (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (i₂ ⁂ id) ∘ (h ⁂ id) ] ≈⟨ []-cong₂ (refl⟩∘⟨ refl⟩∘⟨ pullˡ (sym (distributeʳ⁻¹-natural id id i₁))) (refl⟩∘⟨ refl⟩∘⟨ pullˡ distributeʳ⁻¹-i₂) ⟩ 
        [ (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ ((id ⁂ id +₁ i₁ ⁂ id) ∘ distributeʳ⁻¹) ∘ (f ⁂ id) , (id +₁ distributeʳ⁻¹) ∘ (eval′ +₁ id) ∘ i₂ ∘ (h ⁂ id) ] ≈⟨ []-cong₂ (pullˡ +₁∘+₁) (pullˡ +₁∘+₁) ⟩ 
        [ (id ∘ eval′ +₁ distributeʳ⁻¹ ∘ id) ∘ ((id ⁂ id +₁ i₁ ⁂ id) ∘ distributeʳ⁻¹) ∘ (f ⁂ id) , (id ∘ eval′ +₁ distributeʳ⁻¹ ∘ id) ∘ i₂ ∘ (h ⁂ id) ] ≈⟨ []-cong₂ (pullˡ (pullˡ +₁∘+₁)) (pullˡ +₁∘i₂) ⟩ 
        [ ((((id ∘ eval′) ∘ (id ⁂ id)) +₁ ((distributeʳ⁻¹ ∘ id) ∘ (i₁ ⁂ id))) ∘ distributeʳ⁻¹) ∘ (f ⁂ id) , (i₂ ∘ (distributeʳ⁻¹ ∘ id)) ∘ (h ⁂ id) ] ≈⟨ []-cong₂ (((+₁-cong₂ (identityˡ ⟩∘⟨refl) (identityʳ ⟩∘⟨refl ○ distributeʳ⁻¹-i₁)) ⟩∘⟨refl) ⟩∘⟨refl) (pullʳ (pullʳ identityˡ)) ⟩ 
        [ (((eval′ ∘ (id ⁂ id)) +₁ i₁) ∘ distributeʳ⁻¹) ∘ (f ⁂ id) , i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id) ] ≈⟨ []-cong₂ (assoc ○ (+₁-cong₂ (elimʳ (⟨⟩-unique id-comm id-comm)) refl) ⟩∘⟨refl) refl ⟩ 
        [ (eval′ +₁ i₁) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) , i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id) ] ≈˘⟨ []-cong₂ (pullˡ (+₁∘+₁ ○ +₁-cong₂ identityˡ identityʳ)) refl ⟩ 
        [ (id +₁ i₁) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) , i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id) ] ≈˘⟨ cancelʳ (IsIso.isoˡ isIsoʳ) ⟩ 
        ([ (id +₁ i₁) ∘ (eval′ +₁ id) ∘ distributeʳ⁻¹ ∘ (f ⁂ id) , i₂ ∘ distributeʳ⁻¹ ∘ (h ⁂ id) ] ∘ distributeʳ⁻¹) ∘ distributeʳ ∎)