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{-# OPTIONS --without-K --safe #-}
open import Level using (Level; suc; _⊔_)
open import Categories.Category using (Category)
module Category.Dagger.Semiadditive
{o ℓ e : Level}
(𝒞 : Category o ℓ e)
where
import Categories.Category.Monoidal.Reasoning as ⊗-Reasoning
import Categories.Morphism.Reasoning as ⇒-Reasoning
open import Categories.Category.BinaryProducts using (BinaryProducts)
open import Categories.Category.Cocartesian 𝒞 using (Cocartesian; module CocartesianMonoidal; module CocartesianSymmetricMonoidal)
open import Categories.Category.Dagger using (HasDagger)
open import Categories.Category.Monoidal using (Monoidal)
open import Categories.Category.Monoidal.Symmetric using (module Symmetric)
open import Categories.Category.Monoidal.Symmetric.Properties using () renaming (module Shorthands to σ-Shorthands)
open import Categories.Category.Monoidal.Utilities using (module Shorthands)
open import Categories.Object.Duality using (Coproduct⇒coProduct)
record DaggerCocartesianMonoidal : Set (suc (o ⊔ ℓ ⊔ e)) where
field
cocartesian : Cocartesian
dagger : HasDagger 𝒞
open Cocartesian cocartesian using (i₁; i₂)
open CocartesianMonoidal cocartesian using (+-monoidal; _⊗₀_; _⊗₁_)
open CocartesianSymmetricMonoidal cocartesian using (+-symmetric)
open HasDagger dagger using (_†; isUnitary; isSelfAdjoint)
open Shorthands +-monoidal using (λ⇒; λ⇐; ρ⇒; ρ⇐; α⇒; α⇐)
open σ-Shorthands +-symmetric using (σ⇒)
open Category 𝒞
-- dagger and cocartesian monoidal structure are compatible
field
λ≅† : {A : Obj} → λ⇒ {A} † ≈ λ⇐
ρ≅† : {A : Obj} → ρ⇒ {A} † ≈ ρ⇐
α≅† : {A B C : Obj} → α⇒ {A} {B} {C} † ≈ α⇐
σ≅† : {A B : Obj} → σ⇒ {A} {B} † ≈ σ⇒
†-resp-⊗ : {A B C D : Obj} {f : A ⇒ B} {g : C ⇒ D} → (f ⊗₁ g) † ≈ (f †) ⊗₁ (g †)
record SemiadditiveDagger : Set (suc (o ⊔ ℓ ⊔ e)) where
field
daggerCocartesianMonoidal : DaggerCocartesianMonoidal
open DaggerCocartesianMonoidal daggerCocartesianMonoidal public
open CocartesianMonoidal cocartesian using (+-monoidal) renaming (_⊗₀_ to _⊕₀_; _⊗₁_ to _⊕₁_; ⊗ to ⊕) public
open Cocartesian cocartesian using (⊥; i₁; i₂; [_,_]; ¡; ∘[]; []∘+₁; []-cong₂; coproduct; ¡-unique; inject₁; inject₂; +-unique; +-g-η)
open CocartesianSymmetricMonoidal cocartesian using (+-symmetric)
open HasDagger dagger using (_†; †-involutive; †-resp-≈; †-identity; †-homomorphism)
open Monoidal +-monoidal using (unitorˡ-commute-from; unitorʳ-commute-from; assoc-commute-from; module unitorˡ; module unitorʳ; module associator)
open σ-Shorthands +-symmetric using (σ⇒)
open Symmetric +-symmetric using (module braiding)
open Shorthands +-monoidal using (λ⇒; λ⇐; ρ⇒; ρ⇐; α⇒; α⇐)
open Category 𝒞
-- projection maps
p₁ : {A B : Obj} → A ⊕₀ B ⇒ A
p₁ = i₁ †
p₂ : {A B : Obj} → A ⊕₀ B ⇒ B
p₂ = i₂ †
-- codiagonal
▽ : {A : Obj} → A ⊕₀ A ⇒ A
▽ = [ id , id ]
-- diagonal
△ : {A : Obj} → A ⇒ A ⊕₀ A
△ = ▽ †
private
op-binaryProducts : BinaryProducts op
op-binaryProducts = record { product = Coproduct⇒coProduct 𝒞 coproduct }
open BinaryProducts op-binaryProducts using () renaming (assocʳ∘⟨⟩ to []-assoc; swap∘⟨⟩ to []∘swap)
open ⊗-Reasoning +-monoidal
open ⇒-Reasoning 𝒞
▽-assoc : {A : Obj} → ▽ {A} ∘ ▽ ⊕₁ id ≈ ▽ ∘ id ⊕₁ ▽ ∘ α⇒
▽-assoc = begin
[ id , id ] ∘ [ id , id ] ⊕₁ id ≈⟨ []∘+₁ ⟩
[ id ∘ [ id , id ] , id ∘ id ] ≈⟨ []-cong₂ identityˡ identityˡ ⟩
[ [ id , id ] , id ] ≈⟨ []-assoc ⟨
[ id , [ id , id ] ] ∘ α⇒ ≈⟨ []-cong₂ identityˡ identityˡ ⟩∘⟨refl ⟨
[ id ∘ id , id ∘ [ id , id ] ] ∘ α⇒ ≈⟨ pushˡ (Equiv.sym []∘+₁) ⟩
[ id , id ] ∘ id ⊕₁ [ id , id ] ∘ α⇒ ∎
△-assoc : {A : Obj} → id ⊕₁ △ ∘ △ {A} ≈ α⇒ ∘ △ ⊕₁ id ∘ △
△-assoc = begin
id ⊕₁ △ ∘ △ ≈⟨ †-involutive (id ⊕₁ △ ∘ △) ⟨
(id ⊕₁ △ ∘ △) † † ≈⟨ †-resp-≈ †-homomorphism ⟩
(△ † ∘ (id ⊕₁ △) †) † ≈⟨ †-resp-≈ (†-involutive ▽ ⟩∘⟨ †-resp-⊗) ⟩
(▽ ∘ (id †) ⊕₁ (△ †)) † ≈⟨ †-resp-≈ (refl⟩∘⟨ †-identity ⟩⊗⟨ †-involutive ▽)⟩
(▽ ∘ id ⊕₁ ▽) † ≈⟨ †-resp-≈ (refl⟩∘⟨ introʳ associator.isoʳ) ⟩
(▽ ∘ id ⊕₁ ▽ ∘ α⇒ ∘ α⇐) † ≈⟨ †-resp-≈ (refl⟩∘⟨ assoc ) ⟨
(▽ ∘ (id ⊕₁ ▽ ∘ α⇒) ∘ α⇐) † ≈⟨ †-resp-≈ (extendʳ ▽-assoc) ⟨
(▽ ∘ ▽ ⊕₁ id ∘ α⇐) † ≈⟨ †-homomorphism ⟩
(▽ ⊕₁ id ∘ α⇐) † ∘ ▽ † ≈⟨ pushˡ †-homomorphism ⟩
α⇐ † ∘ (▽ ⊕₁ id) † ∘ △ ≈⟨ †-resp-≈ α≅† ⟩∘⟨refl ⟨
α⇒ † † ∘ (▽ ⊕₁ id) † ∘ △ ≈⟨ †-involutive α⇒ ⟩∘⟨refl ⟩
α⇒ ∘ (▽ ⊕₁ id) † ∘ △ ≈⟨ refl⟩∘⟨ †-resp-⊗ ⟩∘⟨refl ⟩
α⇒ ∘ (▽ †) ⊕₁ (id †) ∘ △ ≈⟨ refl⟩∘⟨ refl⟩⊗⟨ †-identity ⟩∘⟨refl ⟩
α⇒ ∘ △ ⊕₁ id ∘ △ ∎
! : {A : Obj} → A ⇒ ⊥
! = ¡ †
▽-identityˡ : {A : Obj} → ▽ {A} ∘ ¡ ⊕₁ id ≈ λ⇒
▽-identityˡ = begin
[ id , id ] ∘ ¡ ⊕₁ id ≈⟨ []∘+₁ ⟩
[ id ∘ ¡ , id ∘ id ] ≈⟨ []-cong₂ identityˡ identity² ⟩
[ ¡ , id ] ∎
△-identityˡ : {A : Obj} → ! {A} ⊕₁ id ∘ △ ≈ λ⇐
△-identityˡ = begin
! ⊕₁ id ∘ △ ≈⟨ refl⟩⊗⟨ †-identity ⟩∘⟨refl ⟨
(¡ †) ⊕₁ (id †) ∘ ▽ † ≈⟨ †-resp-⊗ ⟩∘⟨refl ⟨
(¡ ⊕₁ id) † ∘ ▽ † ≈⟨ †-homomorphism ⟨
(▽ ∘ ¡ ⊕₁ id) † ≈⟨ †-resp-≈ ▽-identityˡ ⟩
λ⇒ † ≈⟨ λ≅† ⟩
λ⇐ ∎
▽-identityʳ : {A : Obj} → ▽ {A} ∘ id ⊕₁ ¡ ≈ ρ⇒
▽-identityʳ = begin
[ id , id ] ∘ id ⊕₁ ¡ ≈⟨ []∘+₁ ⟩
[ id ∘ id , id ∘ ¡ ] ≈⟨ []-cong₂ identity² identityˡ ⟩
[ id , ¡ ] ∎
△-identityʳ : {A : Obj} → id {A} ⊕₁ ! ∘ △ ≈ ρ⇐
△-identityʳ = begin
id ⊕₁ (¡ †) ∘ ▽ † ≈⟨ †-identity ⟩⊗⟨refl ⟩∘⟨refl ⟨
(id †) ⊕₁ (¡ †) ∘ ▽ † ≈⟨ †-resp-⊗ ⟩∘⟨refl ⟨
(id ⊕₁ ¡) † ∘ ▽ † ≈⟨ †-homomorphism ⟨
(▽ ∘ id ⊕₁ ¡) † ≈⟨ †-resp-≈ ▽-identityʳ ⟩
ρ⇒ † ≈⟨ ρ≅† ⟩
ρ⇐ ∎
▽-comm : {A : Obj} → ▽ {A} ∘ σ⇒ ≈ ▽
▽-comm = []∘swap
△-comm : {A : Obj} → σ⇒ ∘ △ {A} ≈ △
△-comm = begin
σ⇒ ∘ ▽ † ≈⟨ σ≅† ⟩∘⟨refl ⟨
σ⇒ † ∘ ▽ † ≈⟨ †-homomorphism ⟨
(▽ ∘ σ⇒) † ≈⟨ †-resp-≈ ▽-comm ⟩
▽ † ∎
⇒▽ : {A B : Obj} {f : A ⇒ B} → f ∘ ▽ ≈ ▽ ∘ f ⊕₁ f
⇒▽ {A} {B} {f} = begin
f ∘ [ id , id ] ≈⟨ ∘[] ⟩
[ f ∘ id , f ∘ id ] ≈⟨ []-cong₂ identityʳ identityʳ ⟩
[ f , f ] ≈⟨ []-cong₂ identityˡ identityˡ ⟨
[ id ∘ f , id ∘ f ] ≈⟨ []∘+₁ ⟨
[ id , id ] ∘ f ⊕₁ f ∎
⇒△ : {A B : Obj} {f : A ⇒ B} → △ ∘ f ≈ f ⊕₁ f ∘ △
⇒△ {A} {B} {f} = begin
▽ † ∘ f ≈⟨ refl⟩∘⟨ †-involutive f ⟨
▽ † ∘ f † † ≈⟨ †-homomorphism ⟨
(f † ∘ ▽) † ≈⟨ †-resp-≈ ⇒▽ ⟩
(▽ ∘ (f †) ⊕₁ (f †)) † ≈⟨ †-homomorphism ⟩
((f †) ⊕₁ (f †)) † ∘ ▽ † ≈⟨ †-resp-⊗ ⟩∘⟨refl ⟩
(f † †) ⊕₁ (f † †) ∘ ▽ † ≈⟨ †-involutive f ⟩⊗⟨ †-involutive f ⟩∘⟨refl ⟩
f ⊕₁ f ∘ ▽ † ∎
⇒¡ : {A B : Obj} {f : A ⇒ B} → f ∘ ¡ ≈ ¡
⇒¡ {A} {B} {f} = Equiv.sym (¡-unique (f ∘ ¡))
⇒! : {A B : Obj} {f : A ⇒ B} → ! ∘ f ≈ !
⇒! {A} {B} {f} = begin
¡ † ∘ f ≈⟨ refl⟩∘⟨ †-involutive f ⟨
¡ † ∘ f † † ≈⟨ †-homomorphism ⟨
(f † ∘ ¡) † ≈⟨ †-resp-≈ ⇒¡ ⟩
¡ † ∎
ρ⇐≈i₁ : {A : Obj} → ρ⇐ {A} ≈ i₁
ρ⇐≈i₁ = Equiv.refl
λ⇐≈i₂ : {A : Obj} → λ⇐ {A} ≈ i₂
λ⇐≈i₂ = Equiv.refl
λ⇒≈p₂ : {A : Obj} → λ⇒ {A} ≈ p₂
λ⇒≈p₂ = begin
λ⇒ ≈⟨ †-involutive λ⇒ ⟨
λ⇒ † † ≈⟨ †-resp-≈ λ≅† ⟩
λ⇐ † ≈⟨ †-resp-≈ λ⇐≈i₂ ⟩
i₂ † ∎
ρ⇒≈p₁ : {A : Obj} → ρ⇒ {A} ≈ p₁
ρ⇒≈p₁ = begin
ρ⇒ ≈⟨ †-involutive ρ⇒ ⟨
ρ⇒ † † ≈⟨ †-resp-≈ ρ≅† ⟩
ρ⇐ † ≈⟨ †-resp-≈ ρ⇐≈i₁ ⟩
i₁ † ∎
i₁-⊕ : {A B : Obj} → i₁ {A} {B} ≈ id ⊕₁ ¡ ∘ ρ⇐
i₁-⊕ = begin
i₁ ≈⟨ identityʳ ⟨
i₁ ∘ id ≈⟨ inject₁ ⟨
id ⊕₁ ¡ ∘ i₁ ≈⟨ refl⟩∘⟨ ρ⇐≈i₁ ⟨
id ⊕₁ ¡ ∘ ρ⇐ ∎
i₂-⊕ : {A B : Obj} → i₂ {A} {B} ≈ ¡ ⊕₁ id ∘ λ⇐
i₂-⊕ = begin
i₂ ≈⟨ identityʳ ⟨
i₂ ∘ id ≈⟨ inject₂ ⟨
¡ ⊕₁ id ∘ i₂ ≈⟨ refl⟩∘⟨ λ⇐≈i₂ ⟨
¡ ⊕₁ id ∘ λ⇐ ∎
p₁-⊕ : {A B : Obj} → p₁ {A} {B} ≈ ρ⇒ ∘ id ⊕₁ !
p₁-⊕ {A} {B} = begin
i₁ † ≈⟨ †-resp-≈ i₁-⊕ ⟩
(id ⊕₁ ¡ ∘ ρ⇐) † ≈⟨ †-homomorphism ⟩
ρ⇐ † ∘ (id ⊕₁ ¡) † ≈⟨ refl⟩∘⟨ †-resp-⊗ ⟩
ρ⇐ † ∘ (id †) ⊕₁ (¡ †) ≈⟨ †-resp-≈ ρ≅† ⟩∘⟨refl ⟨
ρ⇒ † † ∘ (id †) ⊕₁ (¡ †) ≈⟨ †-involutive ρ⇒ ⟩∘⟨ †-identity ⟩⊗⟨refl ⟩
ρ⇒ ∘ id ⊕₁ (¡ †) ∎
p₂-⊕ : {A B : Obj} → p₂ {A} {B} ≈ λ⇒ ∘ ! ⊕₁ id
p₂-⊕ {A} {B} = begin
i₂ † ≈⟨ †-resp-≈ i₂-⊕ ⟩
(¡ ⊕₁ id ∘ λ⇐) † ≈⟨ †-homomorphism ⟩
λ⇐ † ∘ (¡ ⊕₁ id) † ≈⟨ refl⟩∘⟨ †-resp-⊗ ⟩
λ⇐ † ∘ (¡ †) ⊕₁ (id †) ≈⟨ †-resp-≈ λ≅† ⟩∘⟨refl ⟨
λ⇒ † † ∘ (¡ †) ⊕₁ (id †) ≈⟨ †-involutive λ⇒ ⟩∘⟨ refl⟩⊗⟨ †-identity ⟩
λ⇒ ∘ (¡ †) ⊕₁ id ∎
-- zero arrows
z : {A B : Obj} → A ⇒ B
z = ¡ ∘ !
field
-- orthogonality conditions: pᵢiⱼ ≈ δᵢⱼ
p₁-i₁ : {A B : Obj} → p₁ {A} {B} ∘ i₁ ≈ id {A}
p₂-i₂ : {A B : Obj} → p₂ {A} {B} ∘ i₂ ≈ id {B}
p₂-i₁ : {A B : Obj} → p₂ {A} {B} ∘ i₁ ≈ z {A} {B}
p₁-i₂ : {A B : Obj} → p₁ {A} {B} ∘ i₂ ≈ z {B} {A}
-- commutative monoid structure on homs
module _ {A B : Obj} where
_+_ : A ⇒ B → A ⇒ B → A ⇒ B
_+_ f g = ▽ ∘ f ⊕₁ g ∘ △
+-associative : {f g h : A ⇒ B} → (f + g) + h ≈ f + (g + h)
+-associative {f} {g} {h} = begin
▽ ∘ (▽ ∘ f ⊕₁ g ∘ △) ⊕₁ h ∘ △ ≈⟨ refl⟩∘⟨ pushˡ split₁ˡ ⟩
▽ ∘ ▽ ⊕₁ id ∘ (f ⊕₁ g ∘ △) ⊕₁ h ∘ △ ≈⟨ refl⟩∘⟨ refl⟩∘⟨ pushˡ split₁ʳ ⟩
▽ ∘ ▽ ⊕₁ id ∘ (f ⊕₁ g) ⊕₁ h ∘ △ ⊕₁ id ∘ △ ≈⟨ extendʳ ▽-assoc ⟩
▽ ∘ (id ⊕₁ ▽ ∘ α⇒) ∘ (f ⊕₁ g) ⊕₁ h ∘ △ ⊕₁ id ∘ △ ≈⟨ refl⟩∘⟨ pullʳ (extendʳ assoc-commute-from) ⟩
▽ ∘ id ⊕₁ ▽ ∘ f ⊕₁ g ⊕₁ h ∘ α⇒ ∘ △ ⊕₁ id ∘ △ ≈⟨ refl⟩∘⟨ refl⟩∘⟨ refl⟩∘⟨ △-assoc ⟨
▽ ∘ id ⊕₁ ▽ ∘ f ⊕₁ g ⊕₁ h ∘ id ⊕₁ △ ∘ △ ≈⟨ refl⟩∘⟨ refl⟩∘⟨ pullˡ merge₂ʳ ⟩
▽ ∘ id ⊕₁ ▽ ∘ f ⊕₁ (g ⊕₁ h ∘ △) ∘ △ ≈⟨ refl⟩∘⟨ pullˡ merge₂ˡ ⟩
▽ ∘ f ⊕₁ (▽ ∘ g ⊕₁ h ∘ △) ∘ △ ∎
+-identityˡ : {f : A ⇒ B} → z + f ≈ f
+-identityˡ {f} = begin
▽ ∘ (¡ ∘ !) ⊕₁ f ∘ △ ≈⟨ refl⟩∘⟨ pushˡ split₁ˡ ⟩
▽ ∘ ¡ ⊕₁ id ∘ ! ⊕₁ f ∘ △ ≈⟨ pullˡ ▽-identityˡ ⟩
λ⇒ ∘ ! ⊕₁ f ∘ △ ≈⟨ refl⟩∘⟨ pushˡ serialize₂₁ ⟩
λ⇒ ∘ id ⊕₁ f ∘ ! ⊕₁ id ∘ △ ≈⟨ extendʳ unitorˡ-commute-from ⟩
f ∘ λ⇒ ∘ ! ⊕₁ id ∘ △ ≈⟨ refl⟩∘⟨ refl⟩∘⟨ △-identityˡ ⟩
f ∘ λ⇒ ∘ λ⇐ ≈⟨ elimʳ unitorˡ.isoʳ ⟩
f ∎
+-identityʳ : {f : A ⇒ B} → f + z ≈ f
+-identityʳ {f} = begin
▽ ∘ f ⊕₁ (¡ ∘ !) ∘ △ ≈⟨ refl⟩∘⟨ pushˡ split₂ˡ ⟩
▽ ∘ id ⊕₁ ¡ ∘ (f ⊕₁ !) ∘ △ ≈⟨ pullˡ ▽-identityʳ ⟩
ρ⇒ ∘ f ⊕₁ ! ∘ △ ≈⟨ refl⟩∘⟨ pushˡ serialize₁₂ ⟩
ρ⇒ ∘ f ⊕₁ id ∘ id ⊕₁ ! ∘ △ ≈⟨ extendʳ unitorʳ-commute-from ⟩
f ∘ ρ⇒ ∘ id ⊕₁ ! ∘ △ ≈⟨ refl⟩∘⟨ refl⟩∘⟨ △-identityʳ ⟩
f ∘ ρ⇒ ∘ ρ⇐ ≈⟨ elimʳ unitorʳ.isoʳ ⟩
f ∎
+-commutative : {f g : A ⇒ B} → f + g ≈ g + f
+-commutative {f} {g} = begin
▽ ∘ f ⊕₁ g ∘ △ ≈⟨ refl⟩∘⟨ refl⟩∘⟨ △-comm ⟨
▽ ∘ f ⊕₁ g ∘ σ⇒ ∘ △ ≈⟨ refl⟩∘⟨ extendʳ (braiding.⇒.sym-commute _) ⟩
▽ ∘ σ⇒ ∘ g ⊕₁ f ∘ △ ≈⟨ pullˡ ▽-comm ⟩
▽ ∘ g ⊕₁ f ∘ △ ∎
|
