------------------------------------------------------------------------ -- The Agda standard library -- -- Inverses ------------------------------------------------------------------------ {-# OPTIONS --without-K --safe #-} -- Note: use of the standard function hierarchy is encouraged. The -- module `Function` re-exports `Inverseᵇ`, `IsInverse` and -- `Inverse`. The alternative definitions found in this file will -- eventually be deprecated. module Function.Inverse where open import Level open import Function.Base using (flip) open import Function.Bijection hiding (id; _∘_; bijection) open import Function.Equality as F using (_⟶_) renaming (_∘_ to _⟪∘⟫_) open import Function.LeftInverse as Left hiding (id; _∘_) open import Relation.Binary open import Relation.Binary.PropositionalEquality as P using (_≗_; _≡_) open import Relation.Unary using (Pred) ------------------------------------------------------------------------ -- Inverses record _InverseOf_ {f₁ f₂ t₁ t₂} {From : Setoid f₁ f₂} {To : Setoid t₁ t₂} (from : To ⟶ From) (to : From ⟶ To) : Set (f₁ ⊔ f₂ ⊔ t₁ ⊔ t₂) where field left-inverse-of : from LeftInverseOf to right-inverse-of : from RightInverseOf to ------------------------------------------------------------------------ -- The set of all inverses between two setoids record Inverse {f₁ f₂ t₁ t₂} (From : Setoid f₁ f₂) (To : Setoid t₁ t₂) : Set (f₁ ⊔ f₂ ⊔ t₁ ⊔ t₂) where field to : From ⟶ To from : To ⟶ From inverse-of : from InverseOf to open _InverseOf_ inverse-of public left-inverse : LeftInverse From To left-inverse = record { to = to ; from = from ; left-inverse-of = left-inverse-of } open LeftInverse left-inverse public using (injective; injection) bijection : Bijection From To bijection = record { to = to ; bijective = record { injective = injective ; surjective = record { from = from ; right-inverse-of = right-inverse-of } } } open Bijection bijection public using (equivalence; surjective; surjection; right-inverse; to-from; from-to) ------------------------------------------------------------------------ -- The set of all inverses between two sets (i.e. inverses with -- propositional equality) infix 3 _↔_ _↔̇_ _↔_ : ∀ {f t} → Set f → Set t → Set _ From ↔ To = Inverse (P.setoid From) (P.setoid To) _↔̇_ : ∀ {i f t} {I : Set i} → Pred I f → Pred I t → Set _ From ↔̇ To = ∀ {i} → From i ↔ To i inverse : ∀ {f t} {From : Set f} {To : Set t} → (to : From → To) (from : To → From) → (∀ x → from (to x) ≡ x) → (∀ x → to (from x) ≡ x) → From ↔ To inverse to from from∘to to∘from = record { to = P.→-to-⟶ to ; from = P.→-to-⟶ from ; inverse-of = record { left-inverse-of = from∘to ; right-inverse-of = to∘from } } ------------------------------------------------------------------------ -- If two setoids are in bijective correspondence, then there is an -- inverse between them fromBijection : ∀ {f₁ f₂ t₁ t₂} {From : Setoid f₁ f₂} {To : Setoid t₁ t₂} → Bijection From To → Inverse From To fromBijection b = record { to = Bijection.to b ; from = Bijection.from b ; inverse-of = record { left-inverse-of = Bijection.left-inverse-of b ; right-inverse-of = Bijection.right-inverse-of b } } ------------------------------------------------------------------------ -- Inverse is an equivalence relation -- Reflexivity id : ∀ {s₁ s₂} → Reflexive (Inverse {s₁} {s₂}) id {x = S} = record { to = F.id ; from = F.id ; inverse-of = record { left-inverse-of = LeftInverse.left-inverse-of id′ ; right-inverse-of = LeftInverse.left-inverse-of id′ } } where id′ = Left.id {S = S} -- Transitivity infixr 9 _∘_ _∘_ : ∀ {f₁ f₂ m₁ m₂ t₁ t₂} → TransFlip (Inverse {f₁} {f₂} {m₁} {m₂}) (Inverse {m₁} {m₂} {t₁} {t₂}) (Inverse {f₁} {f₂} {t₁} {t₂}) f ∘ g = record { to = to f ⟪∘⟫ to g ; from = from g ⟪∘⟫ from f ; inverse-of = record { left-inverse-of = LeftInverse.left-inverse-of (Left._∘_ (left-inverse f) (left-inverse g)) ; right-inverse-of = LeftInverse.left-inverse-of (Left._∘_ (right-inverse g) (right-inverse f)) } } where open Inverse -- Symmetry. sym : ∀ {f₁ f₂ t₁ t₂} → Sym (Inverse {f₁} {f₂} {t₁} {t₂}) (Inverse {t₁} {t₂} {f₁} {f₂}) sym inv = record { from = to ; to = from ; inverse-of = record { left-inverse-of = right-inverse-of ; right-inverse-of = left-inverse-of } } where open Inverse inv ------------------------------------------------------------------------ -- Transformations map : ∀ {f₁ f₂ t₁ t₂} {From : Setoid f₁ f₂} {To : Setoid t₁ t₂} {f₁′ f₂′ t₁′ t₂′} {From′ : Setoid f₁′ f₂′} {To′ : Setoid t₁′ t₂′} → (t : (From ⟶ To) → (From′ ⟶ To′)) → (f : (To ⟶ From) → (To′ ⟶ From′)) → (∀ {to from} → from InverseOf to → f from InverseOf t to) → Inverse From To → Inverse From′ To′ map t f pres eq = record { to = t to ; from = f from ; inverse-of = pres inverse-of } where open Inverse eq zip : ∀ {f₁₁ f₂₁ t₁₁ t₂₁} {From₁ : Setoid f₁₁ f₂₁} {To₁ : Setoid t₁₁ t₂₁} {f₁₂ f₂₂ t₁₂ t₂₂} {From₂ : Setoid f₁₂ f₂₂} {To₂ : Setoid t₁₂ t₂₂} {f₁ f₂ t₁ t₂} {From : Setoid f₁ f₂} {To : Setoid t₁ t₂} → (t : (From₁ ⟶ To₁) → (From₂ ⟶ To₂) → (From ⟶ To)) → (f : (To₁ ⟶ From₁) → (To₂ ⟶ From₂) → (To ⟶ From)) → (∀ {to₁ from₁ to₂ from₂} → from₁ InverseOf to₁ → from₂ InverseOf to₂ → f from₁ from₂ InverseOf t to₁ to₂) → Inverse From₁ To₁ → Inverse From₂ To₂ → Inverse From To zip t f pres eq₁ eq₂ = record { to = t (to eq₁) (to eq₂) ; from = f (from eq₁) (from eq₂) ; inverse-of = pres (inverse-of eq₁) (inverse-of eq₂) } where open Inverse