------------------------------------------------------------------------ -- The Agda standard library -- -- Code for converting Vec A n → B to and from n-ary functions ------------------------------------------------------------------------ {-# OPTIONS --cubical-compatible --safe #-} module Data.Vec.N-ary where open import Axiom.Extensionality.Propositional using (Extensionality) open import Function.Bundles using (_↔_; Inverse; mk↔′) open import Data.Nat.Base hiding (_⊔_) open import Data.Product as Prod open import Data.Vec.Base open import Function.Base open import Function.Bundles using (_⇔_; mk⇔) open import Level using (Level; _⊔_) open import Relation.Binary hiding (_⇔_) open import Relation.Binary.PropositionalEquality open import Relation.Nullary.Decidable private variable a b c ℓ ℓ₁ ℓ₂ : Level A : Set a B : Set b C : Set c ------------------------------------------------------------------------ -- N-ary functions N-ary-level : Level → Level → ℕ → Level N-ary-level ℓ₁ ℓ₂ zero = ℓ₂ N-ary-level ℓ₁ ℓ₂ (suc n) = ℓ₁ ⊔ N-ary-level ℓ₁ ℓ₂ n N-ary : ∀ (n : ℕ) → Set ℓ₁ → Set ℓ₂ → Set (N-ary-level ℓ₁ ℓ₂ n) N-ary zero A B = B N-ary (suc n) A B = A → N-ary n A B ------------------------------------------------------------------------ -- Conversion curryⁿ : ∀ {n} → (Vec A n → B) → N-ary n A B curryⁿ {n = zero} f = f [] curryⁿ {n = suc n} f = λ x → curryⁿ (f ∘ _∷_ x) _$ⁿ_ : ∀ {n} → N-ary n A B → (Vec A n → B) f $ⁿ [] = f f $ⁿ (x ∷ xs) = f x $ⁿ xs ------------------------------------------------------------------------ -- Quantifiers module _ {A : Set a} where -- Universal quantifier. ∀ⁿ : ∀ n → N-ary n A (Set ℓ) → Set (N-ary-level a ℓ n) ∀ⁿ zero P = P ∀ⁿ (suc n) P = ∀ x → ∀ⁿ n (P x) -- Universal quantifier with implicit (hidden) arguments. ∀ⁿʰ : ∀ n → N-ary n A (Set ℓ) → Set (N-ary-level a ℓ n) ∀ⁿʰ zero P = P ∀ⁿʰ (suc n) P = ∀ {x} → ∀ⁿʰ n (P x) -- Existential quantifier. ∃ⁿ : ∀ n → N-ary n A (Set ℓ) → Set (N-ary-level a ℓ n) ∃ⁿ zero P = P ∃ⁿ (suc n) P = ∃ λ x → ∃ⁿ n (P x) ------------------------------------------------------------------------ -- N-ary function equality Eq : ∀ {A : Set a} {B : Set b} {C : Set c} n → REL B C ℓ → REL (N-ary n A B) (N-ary n A C) (N-ary-level a ℓ n) Eq n _∼_ f g = ∀ⁿ n (curryⁿ {n = n} λ xs → (f $ⁿ xs) ∼ (g $ⁿ xs)) -- A variant where all the arguments are implicit (hidden). Eqʰ : ∀ {A : Set a} {B : Set b} {C : Set c} n → REL B C ℓ → REL (N-ary n A B) (N-ary n A C) (N-ary-level a ℓ n) Eqʰ n _∼_ f g = ∀ⁿʰ n (curryⁿ {n = n} λ xs → (f $ⁿ xs) ∼ (g $ⁿ xs)) ------------------------------------------------------------------------ -- Some lemmas -- The functions curryⁿ and _$ⁿ_ are inverses. left-inverse : ∀ {n} (f : Vec A n → B) → ∀ xs → (curryⁿ f $ⁿ xs) ≡ f xs left-inverse f [] = refl left-inverse f (x ∷ xs) = left-inverse (f ∘ _∷_ x) xs right-inverse : ∀ n (f : N-ary n A B) → Eq n _≡_ (curryⁿ (_$ⁿ_ {n = n} f)) f right-inverse zero f = refl right-inverse (suc n) f = λ x → right-inverse n (f x) -- ∀ⁿ can be expressed in an "uncurried" way. uncurry-∀ⁿ : ∀ n {P : N-ary n A (Set ℓ)} → ∀ⁿ n P ⇔ (∀ (xs : Vec A n) → P $ⁿ xs) uncurry-∀ⁿ {a} {A} {ℓ} n = mk⇔ (⇒ n) (⇐ n) where ⇒ : ∀ n {P : N-ary n A (Set ℓ)} → ∀ⁿ n P → (∀ (xs : Vec A n) → P $ⁿ xs) ⇒ zero p [] = p ⇒ (suc n) p (x ∷ xs) = ⇒ n (p x) xs ⇐ : ∀ n {P : N-ary n A (Set ℓ)} → (∀ (xs : Vec A n) → P $ⁿ xs) → ∀ⁿ n P ⇐ zero p = p [] ⇐ (suc n) p = λ x → ⇐ n (p ∘ _∷_ x) -- ∃ⁿ can be expressed in an "uncurried" way. uncurry-∃ⁿ : ∀ n {P : N-ary n A (Set ℓ)} → ∃ⁿ n P ⇔ (∃ λ (xs : Vec A n) → P $ⁿ xs) uncurry-∃ⁿ {a} {A} {ℓ} n = mk⇔ (⇒ n) (⇐ n) where ⇒ : ∀ n {P : N-ary n A (Set ℓ)} → ∃ⁿ n P → (∃ λ (xs : Vec A n) → P $ⁿ xs) ⇒ zero p = ([] , p) ⇒ (suc n) (x , p) = Prod.map (_∷_ x) id (⇒ n p) ⇐ : ∀ n {P : N-ary n A (Set ℓ)} → (∃ λ (xs : Vec A n) → P $ⁿ xs) → ∃ⁿ n P ⇐ zero ([] , p) = p ⇐ (suc n) (x ∷ xs , p) = (x , ⇐ n (xs , p)) -- Conversion preserves equality. module _ (_∼_ : REL B C ℓ) where curryⁿ-cong : ∀ {n} (f : Vec A n → B) (g : Vec A n → C) → (∀ xs → f xs ∼ g xs) → Eq n _∼_ (curryⁿ f) (curryⁿ g) curryⁿ-cong {n = zero} f g hyp = hyp [] curryⁿ-cong {n = suc n} f g hyp = λ x → curryⁿ-cong (f ∘ _∷_ x) (g ∘ _∷_ x) (λ xs → hyp (x ∷ xs)) curryⁿ-cong⁻¹ : ∀ {n} (f : Vec A n → B) (g : Vec A n → C) → Eq n _∼_ (curryⁿ f) (curryⁿ g) → ∀ xs → f xs ∼ g xs curryⁿ-cong⁻¹ f g hyp [] = hyp curryⁿ-cong⁻¹ f g hyp (x ∷ xs) = curryⁿ-cong⁻¹ (f ∘ _∷_ x) (g ∘ _∷_ x) (hyp x) xs appⁿ-cong : ∀ {n} (f : N-ary n A B) (g : N-ary n A C) → Eq n _∼_ f g → (xs : Vec A n) → (f $ⁿ xs) ∼ (g $ⁿ xs) appⁿ-cong f g hyp [] = hyp appⁿ-cong f g hyp (x ∷ xs) = appⁿ-cong (f x) (g x) (hyp x) xs appⁿ-cong⁻¹ : ∀ {n} (f : N-ary n A B) (g : N-ary n A C) → ((xs : Vec A n) → (f $ⁿ xs) ∼ (g $ⁿ xs)) → Eq n _∼_ f g appⁿ-cong⁻¹ {n = zero} f g hyp = hyp [] appⁿ-cong⁻¹ {n = suc n} f g hyp = λ x → appⁿ-cong⁻¹ (f x) (g x) (λ xs → hyp (x ∷ xs)) -- Eq and Eqʰ are equivalent. Eq-to-Eqʰ : ∀ n (_∼_ : REL B C ℓ) {f : N-ary n A B} {g : N-ary n A C} → Eq n _∼_ f g → Eqʰ n _∼_ f g Eq-to-Eqʰ zero _∼_ eq = eq Eq-to-Eqʰ (suc n) _∼_ eq = Eq-to-Eqʰ n _∼_ (eq _) Eqʰ-to-Eq : ∀ n (_∼_ : REL B C ℓ) {f : N-ary n A B} {g : N-ary n A C} → Eqʰ n _∼_ f g → Eq n _∼_ f g Eqʰ-to-Eq zero _∼_ eq = eq Eqʰ-to-Eq (suc n) _∼_ eq = λ _ → Eqʰ-to-Eq n _∼_ eq module _ (ext : ∀ {a b} → Extensionality a b) where Vec↔N-ary : ∀ n → (Vec A n → B) ↔ N-ary n A B Vec↔N-ary zero = mk↔′ (λ vxs → vxs []) (flip constᵣ) (λ _ → refl) (λ vxs → ext λ where [] → refl) Vec↔N-ary (suc n) = let open Inverse (Vec↔N-ary n) in mk↔′ (λ vxs x → to λ xs → vxs (x ∷ xs)) (λ any xs → from (any (head xs)) (tail xs)) (λ any → ext λ x → inverseˡ _) (λ vxs → ext λ where (x ∷ xs) → cong (λ f → f xs) (inverseʳ (λ ys → vxs (x ∷ ys))))