module Data.Plus where
open import Function
open import Function.Equivalence as Equiv using (_⇔_)
open import Level
open import Relation.Binary
infix 4 Plus
syntax Plus R x y = x [ R ]⁺ y
data Plus {a ℓ} {A : Set a} (_∼_ : Rel A ℓ) : Rel A (a ⊔ ℓ) where
[_] : ∀ {x y} (x∼y : x ∼ y) → x [ _∼_ ]⁺ y
_∼⁺⟨_⟩_ : ∀ x {y z} (x∼⁺y : x [ _∼_ ]⁺ y) (y∼⁺z : y [ _∼_ ]⁺ z) →
x [ _∼_ ]⁺ z
finally : ∀ {a ℓ} {A : Set a} {_∼_ : Rel A ℓ} x y →
x [ _∼_ ]⁺ y → x [ _∼_ ]⁺ y
finally _ _ = id
syntax finally x y x∼⁺y = x ∼⁺⟨ x∼⁺y ⟩∎ y ∎
infixr 2 _∼⁺⟨_⟩_
infix 3 finally
map : ∀ {a a′ ℓ ℓ′} {A : Set a} {A′ : Set a′}
{_R_ : Rel A ℓ} {_R′_ : Rel A′ ℓ′} {f : A → A′} →
_R_ =[ f ]⇒ _R′_ → Plus _R_ =[ f ]⇒ Plus _R′_
map R⇒R′ [ xRy ] = [ R⇒R′ xRy ]
map R⇒R′ (x ∼⁺⟨ xR⁺z ⟩ zR⁺y) =
_ ∼⁺⟨ map R⇒R′ xR⁺z ⟩ map R⇒R′ zR⁺y
infixr 5 _∷_ _++_
infix 4 Plus′
syntax Plus′ R x y = x ⟨ R ⟩⁺ y
data Plus′ {a ℓ} {A : Set a} (_∼_ : Rel A ℓ) : Rel A (a ⊔ ℓ) where
[_] : ∀ {x y} (x∼y : x ∼ y) → x ⟨ _∼_ ⟩⁺ y
_∷_ : ∀ {x y z} (x∼y : x ∼ y) (y∼⁺z : y ⟨ _∼_ ⟩⁺ z) → x ⟨ _∼_ ⟩⁺ z
_++_ : ∀ {a ℓ} {A : Set a} {_∼_ : Rel A ℓ} {x y z} →
x ⟨ _∼_ ⟩⁺ y → y ⟨ _∼_ ⟩⁺ z → x ⟨ _∼_ ⟩⁺ z
[ x∼y ] ++ y∼⁺z = x∼y ∷ y∼⁺z
(x∼y ∷ y∼⁺z) ++ z∼⁺u = x∼y ∷ (y∼⁺z ++ z∼⁺u)
equivalent : ∀ {a ℓ} {A : Set a} {_∼_ : Rel A ℓ} {x y} →
Plus _∼_ x y ⇔ Plus′ _∼_ x y
equivalent {_∼_ = _∼_} = Equiv.equivalence complete sound
where
complete : Plus _∼_ ⇒ Plus′ _∼_
complete [ x∼y ] = [ x∼y ]
complete (x ∼⁺⟨ x∼⁺y ⟩ y∼⁺z) = complete x∼⁺y ++ complete y∼⁺z
sound : Plus′ _∼_ ⇒ Plus _∼_
sound [ x∼y ] = [ x∼y ]
sound (x∼y ∷ y∼⁺z) = _ ∼⁺⟨ [ x∼y ] ⟩ sound y∼⁺z