module Relation.Binary where
open import Data.Product
open import Data.Sum
open import Function
open import Level
import Relation.Binary.PropositionalEquality.Core as PropEq
open import Relation.Binary.Consequences as Consequences
open import Relation.Binary.Core as Core using (_≡_)
import Relation.Binary.Indexed.Core as I
open Core public hiding (_≡_; refl; _≢_)
open Consequences public using (Total)
record IsPreorder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁)
(_∼_ : Rel A ℓ₂)
: Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
field
isEquivalence : IsEquivalence _≈_
reflexive : _≈_ ⇒ _∼_
trans : Transitive _∼_
module Eq = IsEquivalence isEquivalence
refl : Reflexive _∼_
refl = reflexive Eq.refl
∼-resp-≈ : _∼_ Respects₂ _≈_
∼-resp-≈ = (λ x≈y z∼x → trans z∼x (reflexive x≈y))
, (λ x≈y x∼z → trans (reflexive $ Eq.sym x≈y) x∼z)
record Preorder c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _∼_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_∼_ : Rel Carrier ℓ₂
isPreorder : IsPreorder _≈_ _∼_
open IsPreorder isPreorder public
record Setoid c ℓ : Set (suc (c ⊔ ℓ)) where
infix 4 _≈_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ
isEquivalence : IsEquivalence _≈_
open IsEquivalence isEquivalence public
isPreorder : IsPreorder _≡_ _≈_
isPreorder = record
{ isEquivalence = PropEq.isEquivalence
; reflexive = reflexive
; trans = trans
}
preorder : Preorder c c ℓ
preorder = record { isPreorder = isPreorder }
indexedSetoid : ∀ {i} {I : Set i} → I.Setoid I c _
indexedSetoid = record
{ Carrier = λ _ → Carrier
; _≈_ = _≈_
; isEquivalence = record
{ refl = refl
; sym = sym
; trans = trans
}
}
record IsDecEquivalence {a ℓ} {A : Set a}
(_≈_ : Rel A ℓ) : Set (a ⊔ ℓ) where
infix 4 _≟_
field
isEquivalence : IsEquivalence _≈_
_≟_ : Decidable _≈_
open IsEquivalence isEquivalence public
record DecSetoid c ℓ : Set (suc (c ⊔ ℓ)) where
infix 4 _≈_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ
isDecEquivalence : IsDecEquivalence _≈_
open IsDecEquivalence isDecEquivalence public
setoid : Setoid c ℓ
setoid = record { isEquivalence = isEquivalence }
open Setoid setoid public using (preorder)
record IsPartialOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_≤_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
field
isPreorder : IsPreorder _≈_ _≤_
antisym : Antisymmetric _≈_ _≤_
open IsPreorder isPreorder public
renaming (∼-resp-≈ to ≤-resp-≈)
record Poset c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _≤_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_≤_ : Rel Carrier ℓ₂
isPartialOrder : IsPartialOrder _≈_ _≤_
open IsPartialOrder isPartialOrder public
preorder : Preorder c ℓ₁ ℓ₂
preorder = record { isPreorder = isPreorder }
record IsDecPartialOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_≤_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
infix 4 _≟_ _≤?_
field
isPartialOrder : IsPartialOrder _≈_ _≤_
_≟_ : Decidable _≈_
_≤?_ : Decidable _≤_
private
module PO = IsPartialOrder isPartialOrder
open PO public hiding (module Eq)
module Eq where
isDecEquivalence : IsDecEquivalence _≈_
isDecEquivalence = record
{ isEquivalence = PO.isEquivalence
; _≟_ = _≟_
}
open IsDecEquivalence isDecEquivalence public
record DecPoset c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _≤_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_≤_ : Rel Carrier ℓ₂
isDecPartialOrder : IsDecPartialOrder _≈_ _≤_
private
module DPO = IsDecPartialOrder isDecPartialOrder
open DPO public hiding (module Eq)
poset : Poset c ℓ₁ ℓ₂
poset = record { isPartialOrder = isPartialOrder }
open Poset poset public using (preorder)
module Eq where
decSetoid : DecSetoid c ℓ₁
decSetoid = record { isDecEquivalence = DPO.Eq.isDecEquivalence }
open DecSetoid decSetoid public
record IsStrictPartialOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_<_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
field
isEquivalence : IsEquivalence _≈_
irrefl : Irreflexive _≈_ _<_
trans : Transitive _<_
<-resp-≈ : _<_ Respects₂ _≈_
module Eq = IsEquivalence isEquivalence
record StrictPartialOrder c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _<_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_<_ : Rel Carrier ℓ₂
isStrictPartialOrder : IsStrictPartialOrder _≈_ _<_
open IsStrictPartialOrder isStrictPartialOrder public
asymmetric : Asymmetric _<_
asymmetric {x} {y} =
trans∧irr⟶asym Eq.refl trans irrefl {x = x} {y = y}
record IsDecStrictPartialOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_<_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
infix 4 _≟_ _<?_
field
isStrictPartialOrder : IsStrictPartialOrder _≈_ _<_
_≟_ : Decidable _≈_
_<?_ : Decidable _<_
private
module SPO = IsStrictPartialOrder isStrictPartialOrder
open SPO public hiding (module Eq)
module Eq where
isDecEquivalence : IsDecEquivalence _≈_
isDecEquivalence = record
{ isEquivalence = SPO.isEquivalence
; _≟_ = _≟_
}
open IsDecEquivalence isDecEquivalence public
record DecStrictPartialOrder c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _<_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_<_ : Rel Carrier ℓ₂
isDecStrictPartialOrder : IsDecStrictPartialOrder _≈_ _<_
private
module DSPO = IsDecStrictPartialOrder isDecStrictPartialOrder
open DSPO public hiding (module Eq)
strictPartialOrder : StrictPartialOrder c ℓ₁ ℓ₂
strictPartialOrder = record { isStrictPartialOrder = isStrictPartialOrder }
module Eq where
decSetoid : DecSetoid c ℓ₁
decSetoid = record { isDecEquivalence = DSPO.Eq.isDecEquivalence }
open DecSetoid decSetoid public
record IsTotalOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_≤_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
field
isPartialOrder : IsPartialOrder _≈_ _≤_
total : Total _≤_
open IsPartialOrder isPartialOrder public
record TotalOrder c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _≤_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_≤_ : Rel Carrier ℓ₂
isTotalOrder : IsTotalOrder _≈_ _≤_
open IsTotalOrder isTotalOrder public
poset : Poset c ℓ₁ ℓ₂
poset = record { isPartialOrder = isPartialOrder }
open Poset poset public using (preorder)
record IsDecTotalOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_≤_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
infix 4 _≟_ _≤?_
field
isTotalOrder : IsTotalOrder _≈_ _≤_
_≟_ : Decidable _≈_
_≤?_ : Decidable _≤_
private
module TO = IsTotalOrder isTotalOrder
open TO public hiding (module Eq)
module Eq where
isDecEquivalence : IsDecEquivalence _≈_
isDecEquivalence = record
{ isEquivalence = TO.isEquivalence
; _≟_ = _≟_
}
open IsDecEquivalence isDecEquivalence public
record DecTotalOrder c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _≤_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_≤_ : Rel Carrier ℓ₂
isDecTotalOrder : IsDecTotalOrder _≈_ _≤_
private
module DTO = IsDecTotalOrder isDecTotalOrder
open DTO public hiding (module Eq)
totalOrder : TotalOrder c ℓ₁ ℓ₂
totalOrder = record { isTotalOrder = isTotalOrder }
open TotalOrder totalOrder public using (poset; preorder)
module Eq where
decSetoid : DecSetoid c ℓ₁
decSetoid = record { isDecEquivalence = DTO.Eq.isDecEquivalence }
open DecSetoid decSetoid public
record IsStrictTotalOrder {a ℓ₁ ℓ₂} {A : Set a}
(_≈_ : Rel A ℓ₁) (_<_ : Rel A ℓ₂) :
Set (a ⊔ ℓ₁ ⊔ ℓ₂) where
field
isEquivalence : IsEquivalence _≈_
trans : Transitive _<_
compare : Trichotomous _≈_ _<_
<-resp-≈ : _<_ Respects₂ _≈_
infix 4 _≟_ _<?_
_≟_ : Decidable _≈_
_≟_ = tri⟶dec≈ compare
_<?_ : Decidable _<_
_<?_ = tri⟶dec< compare
isDecEquivalence : IsDecEquivalence _≈_
isDecEquivalence = record
{ isEquivalence = isEquivalence
; _≟_ = _≟_
}
module Eq = IsDecEquivalence isDecEquivalence
isStrictPartialOrder : IsStrictPartialOrder _≈_ _<_
isStrictPartialOrder = record
{ isEquivalence = isEquivalence
; irrefl = tri⟶irr <-resp-≈ Eq.sym compare
; trans = trans
; <-resp-≈ = <-resp-≈
}
open IsStrictPartialOrder isStrictPartialOrder public using (irrefl)
record StrictTotalOrder c ℓ₁ ℓ₂ : Set (suc (c ⊔ ℓ₁ ⊔ ℓ₂)) where
infix 4 _≈_ _<_
field
Carrier : Set c
_≈_ : Rel Carrier ℓ₁
_<_ : Rel Carrier ℓ₂
isStrictTotalOrder : IsStrictTotalOrder _≈_ _<_
open IsStrictTotalOrder isStrictTotalOrder public
hiding (module Eq)
strictPartialOrder : StrictPartialOrder c ℓ₁ ℓ₂
strictPartialOrder =
record { isStrictPartialOrder = isStrictPartialOrder }
decSetoid : DecSetoid c ℓ₁
decSetoid = record { isDecEquivalence = isDecEquivalence }
module Eq = DecSetoid decSetoid