Worked on commutativity

2024-05-31 07:28:34 +02:00 · 2023-10-29 10:54:09 +01:00 · 2023-10-29 10:54:09 +01:00 · e8d8377c79
commit e8d8377c79
parent f92fbc76ed
1 changed files with 62 additions and 13 deletions
--- a/src/Monad/Instance/K/Commutative.lagda.md
+++ b/src/Monad/Instance/K/Commutative.lagda.md
@ -29,15 +29,15 @@ module Monad.Instance.K.Commutative {o ℓ e} (ambient : Ambient o ℓ e) (MK :
 # K is a commutative monad
 The proof is analogous to the ones for strength, this is the relevant diagram is:
-<!-- https://q.uiver.app/#q=WzAsNyxbMCwxLCJLWCBcXHRpbWVzIEtZIl0sWzEsMCwiSyhLWCBcXHRpbWVzIFkpIl0sWzIsMCwiSyhLKFggXFx0aW1lcyBZKSkiXSxbMywxLCJLKFggXFx0aW1lcyBZKSJdLFsxLDIsIksoWCBcXHRpbWVzIEtZKSJdLFsyLDIsIksoSyhYIFxcdGltZXMgWSkpIl0sWzAsNCwiS1ggXFx0aW1lcyBZIl0sWzAsMSwiXFx0YXUiXSxbMSwyLCJcXGhhdHtcXHRhdX1eKiJdLFsyLDMsIlxcbXUiXSxbMCw0LCJcXGhhdHtcXHRhdX0iLDJdLFs0LDUsIlxcdGF1XioiLDJdLFs1LDMsIlxcbXUiLDJdLFs2LDAsImlkIFxcdGltZXMgXFxldGEiXSxbNiwzLCJcXGhhdHtcXHRhdX0iLDAseyJjdXJ2ZSI6NX1dLFswLDMsIlxcaGF0e1xcdGF1fV5cXCMiXV0= -->
+<!-- https://q.uiver.app/#q=WzAsNyxbMCwxLCJLWCBcXHRpbWVzIEtZIl0sWzEsMCwiSyhLWCBcXHRpbWVzIFkpIl0sWzIsMCwiSyhLKFggXFx0aW1lcyBZKSkiXSxbMywxLCJLKFggXFx0aW1lcyBZKSJdLFsxLDIsIksoWCBcXHRpbWVzIEtZKSJdLFsyLDIsIksoSyhYIFxcdGltZXMgWSkpIl0sWzAsNCwiS1ggXFx0aW1lcyBZIl0sWzAsMSwiXFx0YXUiXSxbMSwyLCJLXFxoYXR7XFx0YXV9Il0sWzIsMywiXFxtdSJdLFswLDQsIlxcaGF0e1xcdGF1fSIsMl0sWzQsNSwiS1xcdGF1IiwyXSxbNSwzLCJcXG11IiwyXSxbNiwwLCJpZCBcXHRpbWVzIFxcZXRhIl0sWzYsMywiXFxoYXR7XFx0YXV9IiwwLHsiY3VydmUiOjV9XSxbMCwzLCJcXGhhdHtcXHRhdX1eXFwjIl1d -->
-<iframe class="quiver-embed" src="https://q.uiver.app/#q=WzAsNyxbMCwxLCJLWCBcXHRpbWVzIEtZIl0sWzEsMCwiSyhLWCBcXHRpbWVzIFkpIl0sWzIsMCwiSyhLKFggXFx0aW1lcyBZKSkiXSxbMywxLCJLKFggXFx0aW1lcyBZKSJdLFsxLDIsIksoWCBcXHRpbWVzIEtZKSJdLFsyLDIsIksoSyhYIFxcdGltZXMgWSkpIl0sWzAsNCwiS1ggXFx0aW1lcyBZIl0sWzAsMSwiXFx0YXUiXSxbMSwyLCJcXGhhdHtcXHRhdX1eKiJdLFsyLDMsIlxcbXUiXSxbMCw0LCJcXGhhdHtcXHRhdX0iLDJdLFs0LDUsIlxcdGF1XioiLDJdLFs1LDMsIlxcbXUiLDJdLFs2LDAsImlkIFxcdGltZXMgXFxldGEiXSxbNiwzLCJcXGhhdHtcXHRhdX0iLDAseyJjdXJ2ZSI6NX1dLFswLDMsIlxcaGF0e1xcdGF1fV5cXCMiXV0=&embed" width="974" height="688" style="border-radius: 8px; border: none;"></iframe>
+<iframe class="quiver-embed" src="https://q.uiver.app/#q=WzAsNyxbMCwxLCJLWCBcXHRpbWVzIEtZIl0sWzEsMCwiSyhLWCBcXHRpbWVzIFkpIl0sWzIsMCwiSyhLKFggXFx0aW1lcyBZKSkiXSxbMywxLCJLKFggXFx0aW1lcyBZKSJdLFsxLDIsIksoWCBcXHRpbWVzIEtZKSJdLFsyLDIsIksoSyhYIFxcdGltZXMgWSkpIl0sWzAsNCwiS1ggXFx0aW1lcyBZIl0sWzAsMSwiXFx0YXUiXSxbMSwyLCJLXFxoYXR7XFx0YXV9Il0sWzIsMywiXFxtdSJdLFswLDQsIlxcaGF0e1xcdGF1fSIsMl0sWzQsNSwiS1xcdGF1IiwyXSxbNSwzLCJcXG11IiwyXSxbNiwwLCJpZCBcXHRpbWVzIFxcZXRhIl0sWzYsMywiXFxoYXR7XFx0YXV9IiwwLHsiY3VydmUiOjV9XSxbMCwzLCJcXGhhdHtcXHRhdX1eXFwjIl1d&embed" width="974" height="688" style="border-radius: 8px; border: none;"></iframe>
 ```agda
  KCommutative : CommutativeMonad {C = C} {V = monoidal} symmetric KStrong
  KCommutative = record { commutes = commutes' }
    where
      open monadK using (μ)
-      open StrongMonad KStrong
+      open StrongMonad KStrong using (strengthen)
      open IsStableFreeUniformIterationAlgebra using (♯-law; ♯-preserving; ♯-unique)
      open Uniform-Iteration-Algebra using (#-Uniformity; #-Fixpoint; #-resp-≈)
@ -48,10 +48,19 @@ The proof is analogous to the ones for strength, this is the relevant diagram is
      σ : ∀ ((X , Y) : Obj ×f Obj) → K.₀ X × Y ⇒ K.₀ (X × Y)
      σ _ = K.₁ swap ∘ (τ _) ∘ swap
      σ-preserve : ∀ {X Y Z : Obj} (h : Z ⇒ K.₀ Y + Z) → σ (Y , X) ∘ (h # ⁂ idC) ≈ ((σ _ +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC))#
      {-
      K.₁ swap ∘ τ ∘ swap ∘ (h # ⁂ idC)
      ≈ K.₁ swap ∘ τ ∘ (idC ⁂ h #) ∘ swap
      ≈ K.₁ swap ∘ ()# ∘ swap
      ≈ ((K.₁ swap +₁ τ) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ∘ swap
      -}
      σ-preserve {Z} h = {!   !}
      commutes' : ∀ {X Y : Obj} → μ.η _ ∘ K.₁ (σ _) ∘ τ (K.₀ X , Y) ≈ μ.η _ ∘ K.₁ (τ _) ∘ σ _
      commutes' {X} {Y} = begin 
        μ.η _ ∘ K.₁ (σ _) ∘ τ _ ≈⟨ ♯-unique (stable _) (σ _) (μ.η (X × Y) ∘ K.₁ (σ _) ∘ τ _) comm₁ comm₂ ⟩ 
-        (σ _) ♯ ≈⟨ sym (♯-unique (stable _) (σ _) (μ.η _ ∘ K.₁ (τ _) ∘ σ _) comm₃ {!   !}) ⟩ 
+        (σ _) ♯ ≈⟨ sym (♯-unique (stable _) (σ _) (μ.η _ ∘ K.₁ (τ _) ∘ σ _) comm₃ comm₄) ⟩ 
        μ.η _ ∘ K.₁ (τ _) ∘ σ _ ∎
        where
          comm₁ : σ _ ≈ (μ.η _ ∘ K.₁ (σ _) ∘ τ _) ∘ (idC ⁂ η _)
@ -71,14 +80,54 @@ The proof is analogous to the ones for strength, this is the relevant diagram is
            ((μ.η _ ∘ K.₁ (σ _) ∘ τ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ∎
          comm₃ : σ _ ≈ (μ.η _ ∘ K.₁ (τ _) ∘ σ _) ∘ (idC ⁂ η _)
          comm₃ = sym (begin 
-            -- idea use swap epi and K.₁ swap mono:
+            (μ.η _ ∘ K.₁ (τ _) ∘ σ _) ∘ (idC ⁂ η _) ≈⟨ pullʳ (pullʳ (pullʳ (pullʳ swap∘⁂))) ⟩ 
-            {-
+            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ swap ∘ τ _ ∘ (η _ ⁂ idC) ∘ swap ≈⟨ refl⟩∘⟨ refl⟩∘⟨ refl⟩∘⟨ refl⟩∘⟨ ⁂-cong₂ refl (sym K.identity) ⟩∘⟨refl ⟩ 
-            K.₁ swap ∘ (μ.η _ ∘ K.₁ (K.₁ swap ∘ τ _) ∘ σ _) ∘ (idC ⁂ η _) ∘ swap
+            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ swap ∘ τ _ ∘ (η _ ⁂ K.₁ idC) ∘ swap ≈⟨ refl⟩∘⟨ refl⟩∘⟨ refl⟩∘⟨ pullˡ (strengthen.commute (η _ , idC)) ⟩ 
-            ≈ (μ.η _ ∘ K.₁ (σ _) ∘ (τ _)) ∘ (η _ ⁂ idC)
+            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ swap ∘ (K.₁ (η _ ⁂ idC) ∘ τ _) ∘ swap ≈⟨ refl⟩∘⟨ refl⟩∘⟨ pullˡ (pullˡ (sym K.homomorphism)) ⟩ 
-            -}
+            μ.η _ ∘ K.₁ (τ _) ∘ (K.₁ (swap ∘ (η _ ⁂ idC)) ∘ τ _) ∘ swap ≈⟨ refl⟩∘⟨ (pullˡ (pullˡ (sym K.homomorphism))) ⟩ 
-            (μ.η _ ∘ K.₁ (τ _) ∘ σ _) ∘ (idC ⁂ η _) ≈⟨ {!   !} ⟩ 
+            μ.η _ ∘ (K.₁ (τ _ ∘ swap ∘ (η _ ⁂ idC)) ∘ τ _) ∘ swap ≈⟨ refl⟩∘⟨ (((K.F-resp-≈ (refl⟩∘⟨ swap∘⁂)) ⟩∘⟨refl) ⟩∘⟨refl) ⟩ 
-            {!   !} ≈⟨ {!   !} ⟩ 
+            μ.η _ ∘ (K.₁ (τ _ ∘ (idC ⁂ η _) ∘ swap) ∘ τ _) ∘ swap ≈⟨ refl⟩∘⟨ (K.F-resp-≈ (pullˡ (τ-η _))) ⟩∘⟨refl ⟩∘⟨refl ⟩ 
-            {!   !} ≈⟨ {!   !} ⟩ 
+            μ.η _ ∘ (K.₁ (η _ ∘ swap) ∘ τ _) ∘ swap ≈⟨ refl⟩∘⟨ ((K.homomorphism ⟩∘⟨refl) ⟩∘⟨refl) ⟩ 
-            {!   !} ≈⟨ {!   !} ⟩ 
+            μ.η _ ∘ ((K.₁ (η _) ∘ K.₁ swap) ∘ τ _) ∘ swap ≈⟨ pullˡ (pullˡ (cancelˡ monadK.identityˡ)) ⟩ 
            (K.₁ swap ∘ τ _) ∘ swap ≈⟨ assoc ⟩ 
            σ _ ∎)
          comm₄ : ∀ {Z : Obj} (h : Z ⇒ K.₀ Y + Z) → (μ.η _ ∘ K.₁ (τ _) ∘ σ _) ∘ (idC ⁂ h #) ≈ ((μ.η _ ∘ K.₁ (τ _) ∘ σ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))#
          comm₄ {Z} h = begin 
            (μ.η _ ∘ K.₁ (τ _) ∘ σ _) ∘ (idC ⁂ h #) ≈⟨ {!   !} ⟩ 
            μ.η (X × Y) ∘ K.₁ (τ _) ∘ K.₁ swap ∘ τ _ ∘ (h # ⁂ idC) ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ swap ∘ τ _ ∘ (h # ⁂ K.₁ idC) ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ swap ∘ K.₁ (h # ⁂ idC) ∘ τ _ ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ (swap ∘ (h # ⁂ idC)) ∘ τ _ ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ ((idC ⁂ h #) ∘ swap) ∘ τ _ ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ (K.₁ (idC ⁂ h #) ∘ K.₁ swap) ∘ τ _ ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ (K.₁ (τ _ ∘ (idC ⁂ h #)) ∘ K.₁ swap) ∘ τ _ ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ (K.₁ (((τ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h)) #) ∘ K.₁ swap) ∘ τ _ ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (((τ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h)) #) ∘ σ _ ≈⟨ {!   !} ⟩ 
            {!   !} ≈⟨ {!   !} ⟩
            {!   !} ≈⟨ {!   !} ⟩
            {!   !} ≈⟨ {!   !} ⟩
            {!   !} ≈⟨ {!   !} ⟩
            μ.η (X × Y) ∘ K.₁ (τ _) ∘ K.₁ swap ∘ ((τ _ +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC)) # ∘ swap ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ K.₁ swap ∘ ((τ _ ∘ swap +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ K.₁ (τ _) ∘ ((σ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ≈⟨ {!   !} ⟩ 
            μ.η _ ∘ ((K.₁ (τ _) ∘ σ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ≈⟨ {!   !} ⟩ 
            ((μ.η _ ∘ K.₁ (τ _) ∘ σ _ +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ∎
            where
              test : ((τ (X , Y) +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h))# ∘ swap ≈ ((τ (X , Y) ∘ swap +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC)) #
              test = sym (#-Uniformity (algebras _) (sym (begin 
                ((τ (X , Y) +₁ idC) ∘ distributeˡ⁻¹ ∘ (idC ⁂ h)) ∘ swap ≈⟨ pullʳ (pullʳ (sym swap∘⁂)) ⟩ 
                (τ (X , Y) +₁ idC) ∘ distributeˡ⁻¹ ∘ swap ∘ (h ⁂ idC) ≈⟨ refl⟩∘⟨ (pullˡ distributeˡ⁻¹∘swap) ⟩
                (τ (X , Y) +₁ idC) ∘ ((swap +₁ swap) ∘ distributeʳ⁻¹) ∘ (h ⁂ idC) ≈⟨ pullˡ (pullˡ (+₁∘+₁ ○ +₁-cong₂ (sym identityˡ) id-comm-sym)) ⟩
                ((idC ∘ τ (X , Y) ∘ swap +₁ swap ∘ idC) ∘ distributeʳ⁻¹) ∘ (h ⁂ idC) ≈⟨ assoc ○ (sym +₁∘+₁) ⟩∘⟨refl ⟩
                ((idC +₁ swap) ∘ (τ (X , Y) ∘ swap +₁ idC)) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC) ≈⟨ assoc ⟩
                (idC +₁ swap) ∘ (τ (X , Y) ∘ swap +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC) ∎)))
              helper : τ _ ∘ (h # ⁂ idC) ∘ swap ≈ ((τ _ +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC)) # ∘ swap
              helper = {!   !}
              τ∘swap-preserving : τ (K.₀ Y , X) ∘ (h # ⁂ idC) ≈ ((τ _ +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC)) #
              τ∘swap-preserving = begin 
                τ (K.₀ Y , X) ∘ (h # ⁂ idC) ≈⟨ {!   !} ⟩ 
                τ (K.₀ Y , X) ∘ (h # ⁂ K.₁ idC) ≈⟨ {!   !} ⟩ 
                K.₁ (h # ⁂ idC) ∘ τ _ ≈⟨ {!   !} ⟩ 
                {!   !} ≈⟨ {!   !} ⟩ 
                ((τ _ +₁ idC) ∘ distributeʳ⁻¹ ∘ (h ⁂ idC)) # ∎
 ```