module Relation.Binary.Product.Pointwise where
open import Data.Function
open import Data.Product
open import Data.Sum
open import Level
open import Relation.Nullary.Product
open import Relation.Binary
private
module Dummy {a₁ a₂ : Set} where
infixr 2 _×-Rel_
_×-Rel_ : Rel a₁ zero → Rel a₂ zero → Rel (a₁ × a₂) zero
∼₁ ×-Rel ∼₂ = (∼₁ on proj₁) -×- (∼₂ on proj₂)
_×-reflexive_ : ∀ {≈₁ ∼₁ ≈₂ ∼₂} →
≈₁ ⇒ ∼₁ → ≈₂ ⇒ ∼₂ → (≈₁ ×-Rel ≈₂) ⇒ (∼₁ ×-Rel ∼₂)
refl₁ ×-reflexive refl₂ = λ x≈y →
(refl₁ (proj₁ x≈y) , refl₂ (proj₂ x≈y))
_×-refl_ : ∀ {∼₁ ∼₂} →
Reflexive ∼₁ → Reflexive ∼₂ → Reflexive (∼₁ ×-Rel ∼₂)
refl₁ ×-refl refl₂ = (refl₁ , refl₂)
×-irreflexive₁ :
∀ {≈₁ <₁ ≈₂ <₂} →
Irreflexive ≈₁ <₁ → Irreflexive (≈₁ ×-Rel ≈₂) (<₁ ×-Rel <₂)
×-irreflexive₁ ir = λ x≈y x<y → ir (proj₁ x≈y) (proj₁ x<y)
×-irreflexive₂ :
∀ {≈₁ <₁ ≈₂ <₂} →
Irreflexive ≈₂ <₂ → Irreflexive (≈₁ ×-Rel ≈₂) (<₁ ×-Rel <₂)
×-irreflexive₂ ir = λ x≈y x<y → ir (proj₂ x≈y) (proj₂ x<y)
_×-symmetric_ : ∀ {∼₁ ∼₂} →
Symmetric ∼₁ → Symmetric ∼₂ → Symmetric (∼₁ ×-Rel ∼₂)
sym₁ ×-symmetric sym₂ = λ x∼y → sym₁ (proj₁ x∼y) , sym₂ (proj₂ x∼y)
_×-transitive_ : ∀ {∼₁ ∼₂} →
Transitive ∼₁ → Transitive ∼₂ →
Transitive (∼₁ ×-Rel ∼₂)
trans₁ ×-transitive trans₂ = λ x∼y y∼z →
trans₁ (proj₁ x∼y) (proj₁ y∼z) ,
trans₂ (proj₂ x∼y) (proj₂ y∼z)
_×-antisymmetric_ : ∀ {≈₁ ≤₁ ≈₂ ≤₂} →
Antisymmetric ≈₁ ≤₁ → Antisymmetric ≈₂ ≤₂ →
Antisymmetric (≈₁ ×-Rel ≈₂) (≤₁ ×-Rel ≤₂)
antisym₁ ×-antisymmetric antisym₂ = λ x≤y y≤x →
( antisym₁ (proj₁ x≤y) (proj₁ y≤x)
, antisym₂ (proj₂ x≤y) (proj₂ y≤x) )
×-asymmetric₁ : ∀ {<₁ ∼₂} → Asymmetric <₁ → Asymmetric (<₁ ×-Rel ∼₂)
×-asymmetric₁ asym₁ = λ x<y y<x → asym₁ (proj₁ x<y) (proj₁ y<x)
×-asymmetric₂ : ∀ {∼₁ <₂} → Asymmetric <₂ → Asymmetric (∼₁ ×-Rel <₂)
×-asymmetric₂ asym₂ = λ x<y y<x → asym₂ (proj₂ x<y) (proj₂ y<x)
_×-≈-respects₂_ : ∀ {≈₁ ∼₁ ≈₂ ∼₂} →
∼₁ Respects₂ ≈₁ → ∼₂ Respects₂ ≈₂ →
(∼₁ ×-Rel ∼₂) Respects₂ (≈₁ ×-Rel ≈₂)
_×-≈-respects₂_ {≈₁ = ≈₁} {∼₁ = ∼₁} {≈₂ = ≈₂} {∼₂ = ∼₂}
resp₁ resp₂ =
(λ {x y z} → resp¹ {x} {y} {z}) ,
(λ {x y z} → resp² {x} {y} {z})
where
∼ = ∼₁ ×-Rel ∼₂
resp¹ : ∀ {x} → (∼ x) Respects (≈₁ ×-Rel ≈₂)
resp¹ y≈y' x∼y = proj₁ resp₁ (proj₁ y≈y') (proj₁ x∼y) ,
proj₁ resp₂ (proj₂ y≈y') (proj₂ x∼y)
resp² : ∀ {y} → (flip ∼ y) Respects (≈₁ ×-Rel ≈₂)
resp² x≈x' x∼y = proj₂ resp₁ (proj₁ x≈x') (proj₁ x∼y) ,
proj₂ resp₂ (proj₂ x≈x') (proj₂ x∼y)
×-total : ∀ {∼₁ ∼₂} →
Symmetric ∼₁ → Total ∼₁ → Total ∼₂ → Total (∼₁ ×-Rel ∼₂)
×-total {∼₁ = ∼₁} {∼₂ = ∼₂} sym₁ total₁ total₂ = total
where
total : Total (∼₁ ×-Rel ∼₂)
total x y with total₁ (proj₁ x) (proj₁ y)
| total₂ (proj₂ x) (proj₂ y)
... | inj₁ x₁∼y₁ | inj₁ x₂∼y₂ = inj₁ ( x₁∼y₁ , x₂∼y₂)
... | inj₁ x₁∼y₁ | inj₂ y₂∼x₂ = inj₂ (sym₁ x₁∼y₁ , y₂∼x₂)
... | inj₂ y₁∼x₁ | inj₂ y₂∼x₂ = inj₂ ( y₁∼x₁ , y₂∼x₂)
... | inj₂ y₁∼x₁ | inj₁ x₂∼y₂ = inj₁ (sym₁ y₁∼x₁ , x₂∼y₂)
_×-decidable_ : ∀ {∼₁ ∼₂} →
Decidable ∼₁ → Decidable ∼₂ → Decidable (∼₁ ×-Rel ∼₂)
dec₁ ×-decidable dec₂ = λ x y →
dec₁ (proj₁ x) (proj₁ y)
×-dec
dec₂ (proj₂ x) (proj₂ y)
_×-isEquivalence_ : ∀ {≈₁ ≈₂} →
IsEquivalence ≈₁ → IsEquivalence ≈₂ →
IsEquivalence (≈₁ ×-Rel ≈₂)
_×-isEquivalence_ {≈₁ = ≈₁} {≈₂ = ≈₂} eq₁ eq₂ = record
{ refl = λ {x} →
_×-refl_ {∼₁ = ≈₁} {∼₂ = ≈₂}
(refl eq₁) (refl eq₂) {x}
; sym = λ {x y} →
_×-symmetric_ {∼₁ = ≈₁} {∼₂ = ≈₂}
(sym eq₁) (sym eq₂) {x} {y}
; trans = λ {x y z} →
_×-transitive_ {∼₁ = ≈₁} {∼₂ = ≈₂}
(trans eq₁) (trans eq₂) {x} {y} {z}
}
where open IsEquivalence
_×-isPreorder_ : ∀ {≈₁ ∼₁ ≈₂ ∼₂} →
IsPreorder ≈₁ ∼₁ → IsPreorder ≈₂ ∼₂ →
IsPreorder (≈₁ ×-Rel ≈₂) (∼₁ ×-Rel ∼₂)
_×-isPreorder_ {∼₁ = ∼₁} {∼₂ = ∼₂} pre₁ pre₂ = record
{ isEquivalence = isEquivalence pre₁ ×-isEquivalence
isEquivalence pre₂
; reflexive = λ {x y} →
_×-reflexive_ {∼₁ = ∼₁} {∼₂ = ∼₂}
(reflexive pre₁) (reflexive pre₂)
{x} {y}
; trans = λ {x y z} →
_×-transitive_ {∼₁ = ∼₁} {∼₂ = ∼₂}
(trans pre₁) (trans pre₂)
{x} {y} {z}
; ∼-resp-≈ = ∼-resp-≈ pre₁ ×-≈-respects₂ ∼-resp-≈ pre₂
}
where open IsPreorder
_×-isDecEquivalence_ : ∀ {≈₁ ≈₂} →
IsDecEquivalence ≈₁ → IsDecEquivalence ≈₂ →
IsDecEquivalence (≈₁ ×-Rel ≈₂)
eq₁ ×-isDecEquivalence eq₂ = record
{ isEquivalence = isEquivalence eq₁ ×-isEquivalence
isEquivalence eq₂
; _≟_ = _≟_ eq₁ ×-decidable _≟_ eq₂
}
where open IsDecEquivalence
_×-isPartialOrder_ : ∀ {≈₁ ≤₁ ≈₂ ≤₂} →
IsPartialOrder ≈₁ ≤₁ → IsPartialOrder ≈₂ ≤₂ →
IsPartialOrder (≈₁ ×-Rel ≈₂) (≤₁ ×-Rel ≤₂)
_×-isPartialOrder_ {≤₁ = ≤₁} {≤₂ = ≤₂} po₁ po₂ = record
{ isPreorder = isPreorder po₁ ×-isPreorder isPreorder po₂
; antisym = λ {x y} →
_×-antisymmetric_ {≤₁ = ≤₁} {≤₂ = ≤₂}
(antisym po₁) (antisym po₂)
{x} {y}
}
where open IsPartialOrder
_×-isStrictPartialOrder_ :
∀ {≈₁ <₁ ≈₂ <₂} →
IsStrictPartialOrder ≈₁ <₁ → IsStrictPartialOrder ≈₂ <₂ →
IsStrictPartialOrder (≈₁ ×-Rel ≈₂) (<₁ ×-Rel <₂)
_×-isStrictPartialOrder_ {<₁ = <₁} {≈₂ = ≈₂} {<₂ = <₂} spo₁ spo₂ =
record
{ isEquivalence = isEquivalence spo₁ ×-isEquivalence
isEquivalence spo₂
; irrefl = λ {x y} →
×-irreflexive₁ {<₁ = <₁} {≈₂ = ≈₂} {<₂ = <₂}
(irrefl spo₁) {x} {y}
; trans = λ {x y z} →
_×-transitive_ {∼₁ = <₁} {∼₂ = <₂}
(trans spo₁) (trans spo₂)
{x} {y} {z}
; <-resp-≈ = <-resp-≈ spo₁ ×-≈-respects₂ <-resp-≈ spo₂
}
where open IsStrictPartialOrder
open Dummy public
_×-preorder_ : Preorder _ _ _ → Preorder _ _ _ → Preorder _ _ _
p₁ ×-preorder p₂ = record
{ isPreorder = isPreorder p₁ ×-isPreorder isPreorder p₂
} where open Preorder
_×-setoid_ : Setoid _ _ → Setoid _ _ → Setoid _ _
s₁ ×-setoid s₂ = record
{ isEquivalence = isEquivalence s₁ ×-isEquivalence isEquivalence s₂
} where open Setoid
_×-decSetoid_ : DecSetoid _ _ → DecSetoid _ _ → DecSetoid _ _
s₁ ×-decSetoid s₂ = record
{ isDecEquivalence = isDecEquivalence s₁ ×-isDecEquivalence
isDecEquivalence s₂
} where open DecSetoid
_×-poset_ : Poset _ _ _ → Poset _ _ _ → Poset _ _ _
s₁ ×-poset s₂ = record
{ isPartialOrder = isPartialOrder s₁ ×-isPartialOrder
isPartialOrder s₂
} where open Poset
_×-strictPartialOrder_ :
StrictPartialOrder _ _ _ → StrictPartialOrder _ _ _ →
StrictPartialOrder _ _ _
s₁ ×-strictPartialOrder s₂ = record
{ isStrictPartialOrder = isStrictPartialOrder s₁
×-isStrictPartialOrder
isStrictPartialOrder s₂
} where open StrictPartialOrder