{-# OPTIONS --cubical-compatible --safe #-}
module Function.Properties.Bijection where
open import Function.Bundles
open import Level using (Level)
open import Relation.Binary.Bundles using (Setoid)
open import Relation.Binary.Structures using (IsEquivalence)
open import Relation.Binary.Definitions using (Reflexive; Trans)
open import Relation.Binary.PropositionalEquality as P using (setoid)
open import Data.Product.Base using (_,_; proj₁; proj₂)
open import Function.Base using (_∘_)
open import Function.Properties.Surjection using (injective⇒to⁻-cong)
open import Function.Properties.Inverse using (Inverse⇒Equivalence)
import Function.Construct.Identity as Identity
import Function.Construct.Symmetry as Symmetry
import Function.Construct.Composition as Composition
private
variable
a b c ℓ ℓ₁ ℓ₂ ℓ₃ : Level
A B : Set a
T S : Setoid a ℓ
refl : Reflexive (Bijection {a} {ℓ})
refl = Identity.bijection _
sym-≡ : Bijection S (P.setoid B) → Bijection (P.setoid B) S
sym-≡ = Symmetry.bijection-≡
trans : Trans (Bijection {a} {ℓ₁} {b} {ℓ₂}) (Bijection {b} {ℓ₂} {c} {ℓ₃}) Bijection
trans = Composition.bijection
⤖-isEquivalence : IsEquivalence {ℓ = ℓ} _⤖_
⤖-isEquivalence = record
{ refl = refl
; sym = sym-≡
; trans = trans
}
Bijection⇒Inverse : Bijection S T → Inverse S T
Bijection⇒Inverse bij = record
{ to = to
; from = to⁻
; to-cong = cong
; from-cong = injective⇒to⁻-cong surjection injective
; inverse = (λ y≈to⁻[x] → Eq₂.trans (cong y≈to⁻[x]) (to∘to⁻ _)) ,
(λ y≈to[x] → injective (Eq₂.trans (to∘to⁻ _) y≈to[x]))
}
where open Bijection bij; to∘to⁻ = proj₂ ∘ strictlySurjective
Bijection⇒Equivalence : Bijection T S → Equivalence T S
Bijection⇒Equivalence = Inverse⇒Equivalence ∘ Bijection⇒Inverse
⤖⇒↔ : A ⤖ B → A ↔ B
⤖⇒↔ = Bijection⇒Inverse
⤖⇒⇔ : A ⤖ B → A ⇔ B
⤖⇒⇔ = Bijection⇒Equivalence