agda-spa/Lattice/FiniteMap.agda

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open import Lattice
open import Relation.Binary.PropositionalEquality as Eq using (_≡_; refl; sym; trans; cong; subst)
open import Relation.Binary.Definitions using (Decidable)
open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔_)
open import Data.List using (List)
module Lattice.FiniteMap {a b : Level} (A : Set a) (B : Set b)
(_≈₂_ : B B Set b)
(_⊔₂_ : B B B) (_⊓₂_ : B B B)
(≡-dec-A : Decidable (_≡_ {a} {A}))
(lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
open import Lattice.Map A B _≈₂_ _⊔₂_ _⊓₂_ ≡-dec-A lB as Map
using (Map; ⊔-equal-keys; ⊓-equal-keys)
renaming
( _≈_ to _≈ᵐ_
; _⊔_ to _⊔ᵐ_
; _⊓_ to _⊓ᵐ_
; ≈-equiv to ≈ᵐ-equiv
; ≈-⊔-cong to ≈ᵐ-⊔ᵐ-cong
; ⊔-assoc to ⊔ᵐ-assoc
; ⊔-comm to ⊔ᵐ-comm
; ⊔-idemp to ⊔ᵐ-idemp
; ≈-⊓-cong to ≈ᵐ-⊓ᵐ-cong
; ⊓-assoc to ⊓ᵐ-assoc
; ⊓-comm to ⊓ᵐ-comm
; ⊓-idemp to ⊓ᵐ-idemp
; absorb-⊔-⊓ to absorb-⊔ᵐ-⊓ᵐ
; absorb-⊓-⊔ to absorb-⊓ᵐ-⊔ᵐ
)
open import Data.Product using (_×_; _,_; Σ; proj₁ ; proj₂)
open import Equivalence
module _ (ks : List A) where
FiniteMap : Set (a ⊔ℓ b)
FiniteMap = Σ Map (λ m Map.keys m ks)
_≈_ : FiniteMap FiniteMap Set (a ⊔ℓ b)
_≈_ (m₁ , _) (m₂ , _) = m₁ ≈ᵐ m₂
_⊔_ : FiniteMap FiniteMap FiniteMap
_⊔_ (m₁ , km₁≡ks) (m₂ , km₂≡ks) = (m₁ ⊔ᵐ m₂ , trans (sym (⊔-equal-keys {m₁} {m₂} (trans (km₁≡ks) (sym km₂≡ks)))) km₁≡ks)
_⊓_ : FiniteMap FiniteMap FiniteMap
_⊓_ (m₁ , km₁≡ks) (m₂ , km₂≡ks) = (m₁ ⊓ᵐ m₂ , trans (sym (⊓-equal-keys {m₁} {m₂} (trans (km₁≡ks) (sym km₂≡ks)))) km₁≡ks)
≈-equiv : IsEquivalence FiniteMap _≈_
≈-equiv = record
{ ≈-refl = λ {(m , _)} IsEquivalence.≈-refl ≈ᵐ-equiv {m}
; ≈-sym = λ {(m₁ , _)} {(m₂ , _)} IsEquivalence.≈-sym ≈ᵐ-equiv {m₁} {m₂}
; ≈-trans = λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} IsEquivalence.≈-trans ≈ᵐ-equiv {m₁} {m₂} {m₃}
}
isUnionSemilattice : IsSemilattice FiniteMap _≈_ _⊔_
isUnionSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄ ≈ᵐ-⊔ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) ⊔ᵐ-assoc m₁ m₂ m₃
; ⊔-comm = λ (m₁ , _) (m₂ , _) ⊔ᵐ-comm m₁ m₂
; ⊔-idemp = λ (m , _) ⊔ᵐ-idemp m
}
isIntersectSemilattice : IsSemilattice FiniteMap _≈_ _⊓_
isIntersectSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄ ≈ᵐ-⊓ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) ⊓ᵐ-assoc m₁ m₂ m₃
; ⊔-comm = λ (m₁ , _) (m₂ , _) ⊓ᵐ-comm m₁ m₂
; ⊔-idemp = λ (m , _) ⊓ᵐ-idemp m
}
isLattice : IsLattice FiniteMap _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isUnionSemilattice
; meetSemilattice = isIntersectSemilattice
; absorb-⊔-⊓ = λ (m₁ , _) (m₂ , _) absorb-⊔ᵐ-⊓ᵐ m₁ m₂
; absorb-⊓-⊔ = λ (m₁ , _) (m₂ , _) absorb-⊓ᵐ-⊔ᵐ m₁ m₂
}
lattice : Lattice FiniteMap
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}