------------------------------------------------------------------------ -- The Agda standard library -- -- Operations on and properties of decidable relations ------------------------------------------------------------------------ {-# OPTIONS --without-K --safe #-} module Relation.Nullary.Decidable where open import Level using (Level) open import Data.Bool.Base using (true; false) open import Data.Empty using (⊥-elim) open import Function.Base open import Function.Equality using (_⟨$⟩_; module Π) open import Function using (_↔_; mk↔′) open import Function.Equivalence using (_⇔_; equivalence; module Equivalence) open import Function.Injection using (Injection; module Injection) open import Relation.Binary using (Setoid; module Setoid; Decidable) open import Relation.Nullary open import Relation.Nullary.Reflects using (invert) open import Relation.Binary.PropositionalEquality using (cong′) private variable p q : Level P : Set p Q : Set q ------------------------------------------------------------------------ -- Re-exporting the core definitions open import Relation.Nullary.Decidable.Core public ------------------------------------------------------------------------ -- Maps map : P ⇔ Q → Dec P → Dec Q map P⇔Q = map′ (to ⟨$⟩_) (from ⟨$⟩_) where open Equivalence P⇔Q module _ {a₁ a₂ b₁ b₂} {A : Setoid a₁ a₂} {B : Setoid b₁ b₂} (inj : Injection A B) where open Injection inj open Setoid A using () renaming (_≈_ to _≈A_) open Setoid B using () renaming (_≈_ to _≈B_) -- If there is an injection from one setoid to another, and the -- latter's equivalence relation is decidable, then the former's -- equivalence relation is also decidable. via-injection : Decidable _≈B_ → Decidable _≈A_ via-injection dec x y = map′ injective (Π.cong to) (dec (to ⟨$⟩ x) (to ⟨$⟩ y)) ------------------------------------------------------------------------ -- A lemma relating True and Dec True-↔ : (dec : Dec P) → Irrelevant P → True dec ↔ P True-↔ (true because [p]) irr = mk↔′ (λ _ → invert [p]) _ (irr (invert [p])) cong′ True-↔ (false because ofⁿ ¬p) _ = mk↔′ (λ ()) (invert (ofⁿ ¬p)) (⊥-elim ∘ ¬p) λ ()
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