diff --git a/CHANGELOG.md b/CHANGELOG.md index 2959d3d6ce..fe92365ef3 100644 --- a/CHANGELOG.md +++ b/CHANGELOG.md @@ -173,6 +173,29 @@ Additions to existing modules ∣ˡ-preorder : Preorder a ℓ _ ``` +* In `Algebra.Properties.Semigroup` adding consequences for associativity for semigroups + +``` + uv≈w⇒xu∙v≈xw : ∀ x → (x ∙ u) ∙ v ≈ x ∙ w + uv≈w⇒u∙vx≈wx : ∀ x → u ∙ (v ∙ x) ≈ w ∙ x + uv≈w⇒u[vx∙y]≈w∙xy : ∀ x y → u ∙ ((v ∙ x) ∙ y) ≈ w ∙ (x ∙ y) + uv≈w⇒x[uv∙y]≈x∙wy : ∀ x y → x ∙ (u ∙ (v ∙ y)) ≈ x ∙ (w ∙ y) + uv≈w⇒[x∙yu]v≈x∙yw : ∀ x y → (x ∙ (y ∙ u)) ∙ v ≈ x ∙ (y ∙ w) + uv≈w⇒[xu∙v]y≈x∙wy : ∀ x y → ((x ∙ u) ∙ v) ∙ y ≈ x ∙ (w ∙ y) + uv≈w⇒[xy∙u]v≈x∙yw : ∀ x y → ((x ∙ y) ∙ u) ∙ v ≈ x ∙ (y ∙ w) + uv≈w⇒xu∙vy≈x∙wy : ∀ x y → (x ∙ u) ∙ (v ∙ y) ≈ x ∙ (w ∙ y) + uv≈w⇒xy≈z⇒u[vx∙y]≈wz : ∀ z → x ∙ y ≈ z → u ∙ ((v ∙ x) ∙ y) ≈ w ∙ z + uv≈w⇒x∙wy≈x∙[u∙vy] : x ∙ (w ∙ y) ≈ x ∙ (u ∙ (v ∙ y)) + [uv∙w]x≈u[vw∙x] : ((u ∙ v) ∙ w) ∙ x ≈ u ∙ ((v ∙ w) ∙ x) + [uv∙w]x≈u[v∙wx] : ((u ∙ v) ∙ w) ∙ x ≈ u ∙ (v ∙ (w ∙ x)) + [u∙vw]x≈uv∙wx : (u ∙ (v ∙ w)) ∙ x ≈ (u ∙ v) ∙ (w ∙ x) + [u∙vw]x≈u[v∙wx] : (u ∙ (v ∙ w)) ∙ x ≈ u ∙ (v ∙ (w ∙ x)) + uv∙wx≈u[vw∙x] : (u ∙ v) ∙ (w ∙ x) ≈ u ∙ ((v ∙ w) ∙ x) + uv≈wx⇒yu∙v≈yw∙x : ∀ y → (y ∙ u) ∙ v ≈ (y ∙ w) ∙ x + uv≈wx⇒u∙vy≈w∙xy : ∀ y → u ∙ (v ∙ y) ≈ w ∙ (x ∙ y) + uv≈wx⇒yu∙vz≈yw∙xz : ∀ y z → (y ∙ u) ∙ (v ∙ z) ≈ (y ∙ w) ∙ (x ∙ z) +``` + * In `Algebra.Properties.Semigroup.Divisibility`: ```agda ∣ˡ-trans : Transitive _∣ˡ_ diff --git a/src/Algebra/Properties/Semigroup.agda b/src/Algebra/Properties/Semigroup.agda index 22aab4e66e..d81a56a539 100644 --- a/src/Algebra/Properties/Semigroup.agda +++ b/src/Algebra/Properties/Semigroup.agda @@ -10,9 +10,16 @@ open import Algebra using (Semigroup) module Algebra.Properties.Semigroup {a ℓ} (S : Semigroup a ℓ) where +open import Data.Product.Base using (_,_) + open Semigroup S + using (Carrier; _∙_; _≈_; setoid; trans ; refl; sym; assoc; ∙-cong; ∙-congˡ; ∙-congʳ) open import Algebra.Definitions _≈_ -open import Data.Product.Base using (_,_) + using (Alternative; LeftAlternative; RightAlternative; Flexible) + +private + variable + u v w x y z : Carrier x∙yz≈xy∙z : ∀ x y z → x ∙ (y ∙ z) ≈ (x ∙ y) ∙ z x∙yz≈xy∙z x y z = sym (assoc x y z) @@ -28,3 +35,62 @@ alternative = alternativeˡ , alternativeʳ flexible : Flexible _∙_ flexible x y = assoc x y x + +module _ (uv≈w : u ∙ v ≈ w) where + uv≈w⇒xu∙v≈xw : ∀ x → (x ∙ u) ∙ v ≈ x ∙ w + uv≈w⇒xu∙v≈xw x = trans (assoc x u v) (∙-congˡ uv≈w) + + uv≈w⇒u∙vx≈wx : ∀ x → u ∙ (v ∙ x) ≈ w ∙ x + uv≈w⇒u∙vx≈wx x = trans (sym (assoc u v x)) (∙-congʳ uv≈w) + + uv≈w⇒u[vx∙y]≈w∙xy : ∀ x y → u ∙ ((v ∙ x) ∙ y) ≈ w ∙ (x ∙ y) + uv≈w⇒u[vx∙y]≈w∙xy x y = trans (∙-congˡ (assoc v x y)) (uv≈w⇒u∙vx≈wx (x ∙ y)) + + uv≈w⇒x[uv∙y]≈x∙wy : ∀ x y → x ∙ (u ∙ (v ∙ y)) ≈ x ∙ (w ∙ y) + uv≈w⇒x[uv∙y]≈x∙wy x y = ∙-congˡ (uv≈w⇒u∙vx≈wx y) + + uv≈w⇒[x∙yu]v≈x∙yw : ∀ x y → (x ∙ (y ∙ u)) ∙ v ≈ x ∙ (y ∙ w) + uv≈w⇒[x∙yu]v≈x∙yw x y = trans (assoc x (y ∙ u) v) (∙-congˡ (uv≈w⇒xu∙v≈xw y)) + + uv≈w⇒[xu∙v]y≈x∙wy : ∀ x y → ((x ∙ u) ∙ v) ∙ y ≈ x ∙ (w ∙ y) + uv≈w⇒[xu∙v]y≈x∙wy x y = trans (∙-congʳ (uv≈w⇒xu∙v≈xw x)) (assoc x w y) + + uv≈w⇒[xy∙u]v≈x∙yw : ∀ x y → ((x ∙ y) ∙ u) ∙ v ≈ x ∙ (y ∙ w) + uv≈w⇒[xy∙u]v≈x∙yw x y = trans (∙-congʳ (assoc x y u)) (uv≈w⇒[x∙yu]v≈x∙yw x y ) + +module _ (uv≈w : u ∙ v ≈ w) where + + uv≈w⇒xu∙vy≈x∙wy : ∀ x y → (x ∙ u) ∙ (v ∙ y) ≈ x ∙ (w ∙ y) + uv≈w⇒xu∙vy≈x∙wy x y = uv≈w⇒xu∙v≈xw (uv≈w⇒u∙vx≈wx uv≈w y) x + + uv≈w⇒xy≈z⇒u[vx∙y]≈wz : ∀ x y → x ∙ y ≈ z → u ∙ ((v ∙ x) ∙ y) ≈ w ∙ z + uv≈w⇒xy≈z⇒u[vx∙y]≈wz x y xy≈z = trans (∙-congˡ (uv≈w⇒xu∙v≈xw xy≈z v)) (uv≈w⇒u∙vx≈wx uv≈w _) + + uv≈w⇒x∙wy≈x∙[u∙vy] : x ∙ (w ∙ y) ≈ x ∙ (u ∙ (v ∙ y)) + uv≈w⇒x∙wy≈x∙[u∙vy] = sym (uv≈w⇒x[uv∙y]≈x∙wy uv≈w _ _) + +module _ u v w x where + [uv∙w]x≈u[vw∙x] : ((u ∙ v) ∙ w) ∙ x ≈ u ∙ ((v ∙ w) ∙ x) + [uv∙w]x≈u[vw∙x] = uv≈w⇒[xu∙v]y≈x∙wy refl u x + + [uv∙w]x≈u[v∙wx] : ((u ∙ v) ∙ w) ∙ x ≈ u ∙ (v ∙ (w ∙ x)) + [uv∙w]x≈u[v∙wx] = uv≈w⇒[xy∙u]v≈x∙yw refl u v + + [u∙vw]x≈uv∙wx : (u ∙ (v ∙ w)) ∙ x ≈ (u ∙ v) ∙ (w ∙ x) + [u∙vw]x≈uv∙wx = trans (sym (∙-congʳ (assoc u v w))) (assoc (u ∙ v) w x) + + [u∙vw]x≈u[v∙wx] : (u ∙ (v ∙ w)) ∙ x ≈ u ∙ (v ∙ (w ∙ x)) + [u∙vw]x≈u[v∙wx] = uv≈w⇒[x∙yu]v≈x∙yw refl u v + + uv∙wx≈u[vw∙x] : (u ∙ v) ∙ (w ∙ x) ≈ u ∙ ((v ∙ w) ∙ x) + uv∙wx≈u[vw∙x] = uv≈w⇒xu∙vy≈x∙wy refl u x + +module _ (uv≈wx : u ∙ v ≈ w ∙ x) where + uv≈wx⇒yu∙v≈yw∙x : ∀ y → (y ∙ u) ∙ v ≈ (y ∙ w) ∙ x + uv≈wx⇒yu∙v≈yw∙x y = trans (uv≈w⇒xu∙v≈xw uv≈wx y) (sym (assoc y w x)) + + uv≈wx⇒u∙vy≈w∙xy : ∀ y → u ∙ (v ∙ y) ≈ w ∙ (x ∙ y) + uv≈wx⇒u∙vy≈w∙xy y = trans (uv≈w⇒u∙vx≈wx uv≈wx y) (assoc w x y) + + uv≈wx⇒yu∙vz≈yw∙xz : ∀ y z → (y ∙ u) ∙ (v ∙ z) ≈ (y ∙ w) ∙ (x ∙ z) + uv≈wx⇒yu∙vz≈yw∙xz y z = trans (uv≈w⇒xu∙v≈xw (uv≈wx⇒u∙vy≈w∙xy z) y) (sym (assoc y w (x ∙ z)))