{-# OPTIONS --without-K --safe #-}
module Data.List.Relation.Binary.Pointwise where
open import Function.Base
open import Function.Inverse using (Inverse)
open import Data.Product hiding (map)
open import Data.List.Base as List hiding (map; head; tail; uncons)
open import Data.List.Properties using (≡-dec; length-++)
open import Data.Fin using (Fin) renaming (zero to fzero; suc to fsuc)
open import Data.Nat using (ℕ; zero; suc)
open import Data.Nat.Properties
open import Level
open import Relation.Nullary hiding (Irrelevant)
open import Relation.Nullary.Negation using (contradiction)
import Relation.Nullary.Decidable as Dec using (map′)
open import Relation.Nullary.Product using (_×-dec_)
open import Relation.Unary as U using (Pred)
open import Relation.Binary renaming (Rel to Rel₂)
open import Relation.Binary.PropositionalEquality as P using (_≡_)
private
variable
a b c d p q ℓ ℓ₁ ℓ₂ ℓ₃ : Level
A : Set a
B : Set b
C : Set c
D : Set d
infixr 5 _∷_
data Pointwise {A : Set a} {B : Set b} (_∼_ : REL A B ℓ)
: List A → List B → Set (a ⊔ b ⊔ ℓ) where
[] : Pointwise _∼_ [] []
_∷_ : ∀ {x xs y ys} (x∼y : x ∼ y) (xs∼ys : Pointwise _∼_ xs ys) →
Pointwise _∼_ (x ∷ xs) (y ∷ ys)
module _ {_∼_ : REL A B ℓ} where
head : ∀ {x y xs ys} → Pointwise _∼_ (x ∷ xs) (y ∷ ys) → x ∼ y
head (x∼y ∷ xs∼ys) = x∼y
tail : ∀ {x y xs ys} → Pointwise _∼_ (x ∷ xs) (y ∷ ys) →
Pointwise _∼_ xs ys
tail (x∼y ∷ xs∼ys) = xs∼ys
uncons : ∀ {x y xs ys} → Pointwise _∼_ (x ∷ xs) (y ∷ ys) →
x ∼ y × Pointwise _∼_ xs ys
uncons = < head , tail >
rec : ∀ (P : ∀ {xs ys} → Pointwise _∼_ xs ys → Set c) →
(∀ {x y xs ys} {xs∼ys : Pointwise _∼_ xs ys} →
(x∼y : x ∼ y) → P xs∼ys → P (x∼y ∷ xs∼ys)) →
P [] →
∀ {xs ys} (xs∼ys : Pointwise _∼_ xs ys) → P xs∼ys
rec P c n [] = n
rec P c n (x∼y ∷ xs∼ys) = c x∼y (rec P c n xs∼ys)
map : ∀ {_≈_ : REL A B ℓ₂} → _≈_ ⇒ _∼_ → Pointwise _≈_ ⇒ Pointwise _∼_
map ≈⇒∼ [] = []
map ≈⇒∼ (x≈y ∷ xs≈ys) = ≈⇒∼ x≈y ∷ map ≈⇒∼ xs≈ys
reflexive : ∀ {_≈_ : REL A B ℓ₁} {_∼_ : REL A B ℓ₂} →
_≈_ ⇒ _∼_ → Pointwise _≈_ ⇒ Pointwise _∼_
reflexive ≈⇒∼ [] = []
reflexive ≈⇒∼ (x≈y ∷ xs≈ys) = ≈⇒∼ x≈y ∷ reflexive ≈⇒∼ xs≈ys
refl : ∀ {_∼_ : Rel₂ A ℓ} → Reflexive _∼_ → Reflexive (Pointwise _∼_)
refl rfl {[]} = []
refl rfl {x ∷ xs} = rfl ∷ refl rfl
symmetric : ∀ {_≈_ : REL A B ℓ₁} {_∼_ : REL B A ℓ₂} →
Sym _≈_ _∼_ → Sym (Pointwise _≈_) (Pointwise _∼_)
symmetric sym [] = []
symmetric sym (x∼y ∷ xs∼ys) = sym x∼y ∷ symmetric sym xs∼ys
transitive : ∀ {_≋_ : REL A B ℓ₁} {_≈_ : REL B C ℓ₂} {_∼_ : REL A C ℓ₃} →
Trans _≋_ _≈_ _∼_ →
Trans (Pointwise _≋_) (Pointwise _≈_) (Pointwise _∼_)
transitive trans [] [] = []
transitive trans (x∼y ∷ xs∼ys) (y∼z ∷ ys∼zs) =
trans x∼y y∼z ∷ transitive trans xs∼ys ys∼zs
antisymmetric : ∀ {_≤_ : REL A B ℓ₁} {_≤′_ : REL B A ℓ₂} {_≈_ : REL A B ℓ₃} →
Antisym _≤_ _≤′_ _≈_ →
Antisym (Pointwise _≤_) (Pointwise _≤′_) (Pointwise _≈_)
antisymmetric antisym [] [] = []
antisymmetric antisym (x∼y ∷ xs∼ys) (y∼x ∷ ys∼xs) =
antisym x∼y y∼x ∷ antisymmetric antisym xs∼ys ys∼xs
respects₂ : ∀ {_≈_ : Rel₂ A ℓ₁} {_∼_ : Rel₂ A ℓ₂} →
_∼_ Respects₂ _≈_ → (Pointwise _∼_) Respects₂ (Pointwise _≈_)
respects₂ {_≈_ = _≈_} {_∼_} resp = respʳ , respˡ
where
respʳ : (Pointwise _∼_) Respectsʳ (Pointwise _≈_)
respʳ [] [] = []
respʳ (x≈y ∷ xs≈ys) (z∼x ∷ zs∼xs) =
proj₁ resp x≈y z∼x ∷ respʳ xs≈ys zs∼xs
respˡ : (Pointwise _∼_) Respectsˡ (Pointwise _≈_)
respˡ [] [] = []
respˡ (x≈y ∷ xs≈ys) (x∼z ∷ xs∼zs) =
proj₂ resp x≈y x∼z ∷ respˡ xs≈ys xs∼zs
module _ {_∼_ : REL A B ℓ} (dec : Decidable _∼_) where
decidable : Decidable (Pointwise _∼_)
decidable [] [] = yes []
decidable [] (y ∷ ys) = no (λ ())
decidable (x ∷ xs) [] = no (λ ())
decidable (x ∷ xs) (y ∷ ys) =
Dec.map′ (uncurry _∷_) uncons (dec x y ×-dec decidable xs ys)
module _ {_≈_ : Rel₂ A ℓ} where
isEquivalence : IsEquivalence _≈_ → IsEquivalence (Pointwise _≈_)
isEquivalence eq = record
{ refl = refl Eq.refl
; sym = symmetric Eq.sym
; trans = transitive Eq.trans
} where module Eq = IsEquivalence eq
isDecEquivalence : IsDecEquivalence _≈_ → IsDecEquivalence (Pointwise _≈_)
isDecEquivalence eq = record
{ isEquivalence = isEquivalence DE.isEquivalence
; _≟_ = decidable DE._≟_
} where module DE = IsDecEquivalence eq
module _ {_≈_ : Rel₂ A ℓ₁} {_∼_ : Rel₂ A ℓ₂} where
isPreorder : IsPreorder _≈_ _∼_ → IsPreorder (Pointwise _≈_) (Pointwise _∼_)
isPreorder pre = record
{ isEquivalence = isEquivalence Pre.isEquivalence
; reflexive = reflexive Pre.reflexive
; trans = transitive Pre.trans
} where module Pre = IsPreorder pre
isPartialOrder : IsPartialOrder _≈_ _∼_ →
IsPartialOrder (Pointwise _≈_) (Pointwise _∼_)
isPartialOrder po = record
{ isPreorder = isPreorder PO.isPreorder
; antisym = antisymmetric PO.antisym
} where module PO = IsPartialOrder po
setoid : Setoid a ℓ → Setoid a (a ⊔ ℓ)
setoid s = record
{ isEquivalence = isEquivalence (Setoid.isEquivalence s)
}
decSetoid : DecSetoid a ℓ → DecSetoid a (a ⊔ ℓ)
decSetoid d = record
{ isDecEquivalence = isDecEquivalence (DecSetoid.isDecEquivalence d)
}
preorder : Preorder a ℓ₁ ℓ₂ → Preorder _ _ _
preorder p = record
{ isPreorder = isPreorder (Preorder.isPreorder p)
}
poset : Poset a ℓ₁ ℓ₂ → Poset _ _ _
poset p = record
{ isPartialOrder = isPartialOrder (Poset.isPartialOrder p)
}
module _ {_∼_ : REL A B ℓ} where
Pointwise-length : ∀ {xs ys} → Pointwise _∼_ xs ys →
length xs ≡ length ys
Pointwise-length [] = P.refl
Pointwise-length (x∼y ∷ xs∼ys) = P.cong ℕ.suc (Pointwise-length xs∼ys)
module _ {_∼_ : REL A B ℓ} where
tabulate⁺ : ∀ {n} {f : Fin n → A} {g : Fin n → B} →
(∀ i → f i ∼ g i) → Pointwise _∼_ (tabulate f) (tabulate g)
tabulate⁺ {zero} f∼g = []
tabulate⁺ {suc n} f∼g = f∼g fzero ∷ tabulate⁺ (f∼g ∘ fsuc)
tabulate⁻ : ∀ {n} {f : Fin n → A} {g : Fin n → B} →
Pointwise _∼_ (tabulate f) (tabulate g) → (∀ i → f i ∼ g i)
tabulate⁻ {suc n} (x∼y ∷ xs∼ys) fzero = x∼y
tabulate⁻ {suc n} (x∼y ∷ xs∼ys) (fsuc i) = tabulate⁻ xs∼ys i
module _ {_∼_ : REL A B ℓ} where
++⁺ : ∀ {ws xs ys zs} → Pointwise _∼_ ws xs → Pointwise _∼_ ys zs →
Pointwise _∼_ (ws ++ ys) (xs ++ zs)
++⁺ [] ys∼zs = ys∼zs
++⁺ (w∼x ∷ ws∼xs) ys∼zs = w∼x ∷ ++⁺ ws∼xs ys∼zs
module _ {_∼_ : Rel₂ A ℓ} where
++-cancelˡ : ∀ xs {ys zs : List A} → Pointwise _∼_ (xs ++ ys) (xs ++ zs) → Pointwise _∼_ ys zs
++-cancelˡ [] ys∼zs = ys∼zs
++-cancelˡ (x ∷ xs) (_ ∷ xs++ys∼xs++zs) = ++-cancelˡ xs xs++ys∼xs++zs
++-cancelʳ : ∀ {xs : List A} ys zs → Pointwise _∼_ (ys ++ xs) (zs ++ xs) → Pointwise _∼_ ys zs
++-cancelʳ [] [] _ = []
++-cancelʳ (y ∷ ys) (z ∷ zs) (y∼z ∷ ys∼zs) = y∼z ∷ (++-cancelʳ ys zs ys∼zs)
++-cancelʳ {xs} [] (z ∷ zs) eq =
contradiction (P.trans (Pointwise-length eq) (length-++ (z ∷ zs))) (m≢1+n+m (length xs))
++-cancelʳ {xs} (y ∷ ys) [] eq =
contradiction (P.trans (P.sym (length-++ (y ∷ ys))) (Pointwise-length eq)) (m≢1+n+m (length xs) ∘ P.sym)
module _ {_∼_ : REL A B ℓ} where
concat⁺ : ∀ {xss yss} → Pointwise (Pointwise _∼_) xss yss →
Pointwise _∼_ (concat xss) (concat yss)
concat⁺ [] = []
concat⁺ (xs∼ys ∷ xss∼yss) = ++⁺ xs∼ys (concat⁺ xss∼yss)
module _ {R : REL A B ℓ} where
reverseAcc⁺ : ∀ {as bs as′ bs′} → Pointwise R as′ bs′ → Pointwise R as bs →
Pointwise R (reverseAcc as′ as) (reverseAcc bs′ bs)
reverseAcc⁺ rs′ [] = rs′
reverseAcc⁺ rs′ (r ∷ rs) = reverseAcc⁺ (r ∷ rs′) rs
ʳ++⁺ : ∀ {as bs as′ bs′} →
Pointwise R as bs →
Pointwise R as′ bs′ →
Pointwise R (as ʳ++ as′) (bs ʳ++ bs′)
ʳ++⁺ rs rs′ = reverseAcc⁺ rs′ rs
reverse⁺ : ∀ {as bs} → Pointwise R as bs → Pointwise R (reverse as) (reverse bs)
reverse⁺ = reverseAcc⁺ []
module _ {R : REL C D ℓ} where
map⁺ : ∀ {as bs} (f : A → C) (g : B → D) →
Pointwise (λ a b → R (f a) (g b)) as bs →
Pointwise R (List.map f as) (List.map g bs)
map⁺ f g [] = []
map⁺ f g (r ∷ rs) = r ∷ map⁺ f g rs
map⁻ : ∀ {as bs} (f : A → C) (g : B → D) →
Pointwise R (List.map f as) (List.map g bs) →
Pointwise (λ a b → R (f a) (g b)) as bs
map⁻ {as = []} {[]} f g [] = []
map⁻ {as = []} {b ∷ bs} f g rs = contradiction (Pointwise-length rs) λ()
map⁻ {as = a ∷ as} {[]} f g rs = contradiction (Pointwise-length rs) λ()
map⁻ {as = a ∷ as} {b ∷ bs} f g (r ∷ rs) = r ∷ map⁻ f g rs
module _ {R : REL A B ℓ} {P : Pred A p} {Q : Pred B q}
(P? : U.Decidable P) (Q? : U.Decidable Q)
(P⇒Q : ∀ {a b} → R a b → P a → Q b)
(Q⇒P : ∀ {a b} → R a b → Q b → P a)
where
filter⁺ : ∀ {as bs} → Pointwise R as bs → Pointwise R (filter P? as) (filter Q? bs)
filter⁺ [] = []
filter⁺ {a ∷ _} {b ∷ _} (r ∷ rs) with P? a | Q? b
... | yes p | yes q = r ∷ filter⁺ rs
... | yes p | no ¬q = contradiction (P⇒Q r p) ¬q
... | no ¬p | yes q = contradiction (Q⇒P r q) ¬p
... | no ¬p | no ¬q = filter⁺ rs
module _ {R : REL A B ℓ} where
replicate⁺ : ∀ {a b} → R a b → ∀ n → Pointwise R (replicate n a) (replicate n b)
replicate⁺ r 0 = []
replicate⁺ r (suc n) = r ∷ replicate⁺ r n
module _ {R : REL A B ℓ} where
irrelevant : Irrelevant R → Irrelevant (Pointwise R)
irrelevant R-irr [] [] = P.refl
irrelevant R-irr (r ∷ rs) (r₁ ∷ rs₁) =
P.cong₂ _∷_ (R-irr r r₁) (irrelevant R-irr rs rs₁)
Pointwise-≡⇒≡ : Pointwise {A = A} _≡_ ⇒ _≡_
Pointwise-≡⇒≡ [] = P.refl
Pointwise-≡⇒≡ (P.refl ∷ xs∼ys) with Pointwise-≡⇒≡ xs∼ys
... | P.refl = P.refl
≡⇒Pointwise-≡ : _≡_ ⇒ Pointwise {A = A} _≡_
≡⇒Pointwise-≡ P.refl = refl P.refl
Pointwise-≡↔≡ : Inverse (setoid (P.setoid A)) (P.setoid (List A))
Pointwise-≡↔≡ = record
{ to = record { _⟨$⟩_ = id; cong = Pointwise-≡⇒≡ }
; from = record { _⟨$⟩_ = id; cong = ≡⇒Pointwise-≡ }
; inverse-of = record
{ left-inverse-of = λ _ → refl P.refl
; right-inverse-of = λ _ → P.refl
}
}
Rel = Pointwise
{-# WARNING_ON_USAGE Rel
"Warning: Rel was deprecated in v0.15.
Please use Pointwise instead."
#-}
Rel≡⇒≡ = Pointwise-≡⇒≡
{-# WARNING_ON_USAGE Rel≡⇒≡
"Warning: Rel≡⇒≡ was deprecated in v0.15.
Please use Pointwise-≡⇒≡ instead."
#-}
≡⇒Rel≡ = ≡⇒Pointwise-≡
{-# WARNING_ON_USAGE ≡⇒Rel≡
"Warning: ≡⇒Rel≡ was deprecated in v0.15.
Please use ≡⇒Pointwise-≡ instead."
#-}
Rel↔≡ = Pointwise-≡↔≡
{-# WARNING_ON_USAGE Rel↔≡
"Warning: Rel↔≡ was deprecated in v0.15.
Please use Pointwise-≡↔≡ instead."
#-}
decidable-≡ = ≡-dec
{-# WARNING_ON_USAGE decidable-≡
"Warning: decidable-≡ was deprecated in v1.0.
Please use ≡-dec from `Data.List.Properties` instead."
#-}