{-# OPTIONS --safe #-} module Cubical.Induction.WellFounded where open import Cubical.Foundations.Prelude Rel : ∀{ℓ} → Type ℓ → ∀ ℓ' → Type _ Rel A ℓ = A → A → Type ℓ module _ {ℓ ℓ'} {A : Type ℓ} (_<_ : A → A → Type ℓ') where WFRec : ∀{ℓ''} → (A → Type ℓ'') → A → Type _ WFRec P x = ∀ y → y < x → P y data Acc (x : A) : Type (ℓ-max ℓ ℓ') where acc : WFRec Acc x → Acc x WellFounded : Type _ WellFounded = ∀ x → Acc x module _ {ℓ ℓ'} {A : Type ℓ} {_<_ : A → A → Type ℓ'} where isPropAcc : ∀ x → isProp (Acc _<_ x) isPropAcc x (acc p) (acc q) = λ i → acc (λ y y<x → isPropAcc y (p y y<x) (q y y<x) i) access : ∀{x} → Acc _<_ x → WFRec _<_ (Acc _<_) x access (acc r) = r private wfi : ∀{ℓ''} {P : A → Type ℓ''} → ∀ x → (wf : Acc _<_ x) → (∀ x → (∀ y → y < x → P y) → P x) → P x wfi x (acc p) e = e x λ y y<x → wfi y (p y y<x) e module WFI (wf : WellFounded _<_) where module _ {ℓ''} {P : A → Type ℓ''} (e : ∀ x → (∀ y → y < x → P y) → P x) where private wfi-compute : ∀ x ax → wfi x ax e ≡ e x (λ y _ → wfi y (wf y) e) wfi-compute x (acc p) = λ i → e x (λ y y<x → wfi y (isPropAcc y (p y y<x) (wf y) i) e) induction : ∀ x → P x induction x = wfi x (wf x) e induction-compute : ∀ x → induction x ≡ (e x λ y _ → induction y) induction-compute x = wfi-compute x (wf x)