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11
Lattice.agda
11
Lattice.agda
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@ -145,3 +145,14 @@ record Lattice {a} (A : Set a) : Set (lsuc a) where
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isLattice : IsLattice A _≈_ _⊔_ _⊓_
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open IsLattice isLattice public
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record FiniteHeightLattice {a} (A : Set a) : Set (lsuc a) where
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field
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height : ℕ
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_≈_ : A → A → Set a
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_⊔_ : A → A → A
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_⊓_ : A → A → A
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isFiniteHeightLattice : IsFiniteHeightLattice A height _≈_ _⊔_ _⊓_
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open IsFiniteHeightLattice isFiniteHeightLattice public
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78
Lattice/FiniteMap.agda
Normal file
78
Lattice/FiniteMap.agda
Normal file
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@ -0,0 +1,78 @@
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open import Lattice
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open import Relation.Binary.PropositionalEquality as Eq using (_≡_; refl; sym; trans; cong; subst)
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open import Relation.Binary.Definitions using (Decidable)
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open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔ℓ_)
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open import Data.List using (List)
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module Lattice.FiniteMap {a b : Level} (A : Set a) (B : Set b)
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(_≈₂_ : B → B → Set b)
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(_⊔₂_ : B → B → B) (_⊓₂_ : B → B → B)
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(≡-dec-A : Decidable (_≡_ {a} {A}))
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(lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
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open import Lattice.Map A B _≈₂_ _⊔₂_ _⊓₂_ ≡-dec-A lB as Map
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using (Map; ⊔-equal-keys; ⊓-equal-keys)
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renaming
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( _≈_ to _≈ᵐ_
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; _⊔_ to _⊔ᵐ_
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; _⊓_ to _⊓ᵐ_
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; ≈-equiv to ≈ᵐ-equiv
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; ≈-⊔-cong to ≈ᵐ-⊔ᵐ-cong
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; ⊔-assoc to ⊔ᵐ-assoc
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; ⊔-comm to ⊔ᵐ-comm
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; ⊔-idemp to ⊔ᵐ-idemp
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; ≈-⊓-cong to ≈ᵐ-⊓ᵐ-cong
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; ⊓-assoc to ⊓ᵐ-assoc
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; ⊓-comm to ⊓ᵐ-comm
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; ⊓-idemp to ⊓ᵐ-idemp
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; absorb-⊔-⊓ to absorb-⊔ᵐ-⊓ᵐ
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; absorb-⊓-⊔ to absorb-⊓ᵐ-⊔ᵐ
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)
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open import Data.Product using (_×_; _,_; Σ; proj₁ ; proj₂)
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open import Equivalence
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module _ (ks : List A) where
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FiniteMap : Set (a ⊔ℓ b)
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FiniteMap = Σ Map (λ m → Map.keys m ≡ ks)
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_≈_ : FiniteMap → FiniteMap → Set (a ⊔ℓ b)
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_≈_ (m₁ , _) (m₂ , _) = m₁ ≈ᵐ m₂
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_⊔_ : FiniteMap → FiniteMap → FiniteMap
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_⊔_ (m₁ , km₁≡ks) (m₂ , km₂≡ks) = (m₁ ⊔ᵐ m₂ , trans (sym (⊔-equal-keys {m₁} {m₂} (trans (km₁≡ks) (sym km₂≡ks)))) km₁≡ks)
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_⊓_ : FiniteMap → FiniteMap → FiniteMap
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_⊓_ (m₁ , km₁≡ks) (m₂ , km₂≡ks) = (m₁ ⊓ᵐ m₂ , trans (sym (⊓-equal-keys {m₁} {m₂} (trans (km₁≡ks) (sym km₂≡ks)))) km₁≡ks)
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≈-equiv : IsEquivalence FiniteMap _≈_
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≈-equiv = record
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{ ≈-refl = λ {(m , _)} → IsEquivalence.≈-refl ≈ᵐ-equiv {m}
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; ≈-sym = λ {(m₁ , _)} {(m₂ , _)} → IsEquivalence.≈-sym ≈ᵐ-equiv {m₁} {m₂}
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; ≈-trans = λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} → IsEquivalence.≈-trans ≈ᵐ-equiv {m₁} {m₂} {m₃}
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}
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isUnionSemilattice : IsSemilattice FiniteMap _≈_ _⊔_
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isUnionSemilattice = record
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{ ≈-equiv = ≈-equiv
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; ≈-⊔-cong = λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄ → ≈ᵐ-⊔ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
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; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) → ⊔ᵐ-assoc m₁ m₂ m₃
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; ⊔-comm = λ (m₁ , _) (m₂ , _) → ⊔ᵐ-comm m₁ m₂
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; ⊔-idemp = λ (m , _) → ⊔ᵐ-idemp m
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}
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isIntersectSemilattice : IsSemilattice FiniteMap _≈_ _⊓_
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isIntersectSemilattice = record
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{ ≈-equiv = ≈-equiv
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; ≈-⊔-cong = λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄ → ≈ᵐ-⊓ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
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; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) → ⊓ᵐ-assoc m₁ m₂ m₃
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; ⊔-comm = λ (m₁ , _) (m₂ , _) → ⊓ᵐ-comm m₁ m₂
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; ⊔-idemp = λ (m , _) → ⊓ᵐ-idemp m
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}
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isLattice : IsLattice FiniteMap _≈_ _⊔_ _⊓_
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isLattice = record
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{ joinSemilattice = isUnionSemilattice
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; meetSemilattice = isIntersectSemilattice
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; absorb-⊔-⊓ = λ (m₁ , _) (m₂ , _) → absorb-⊔ᵐ-⊓ᵐ m₁ m₂
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; absorb-⊓-⊔ = λ (m₁ , _) (m₂ , _) → absorb-⊓ᵐ-⊔ᵐ m₁ m₂
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}
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107
Lattice/IterProd.agda
Normal file
107
Lattice/IterProd.agda
Normal file
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@ -0,0 +1,107 @@
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open import Lattice
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module Lattice.IterProd {a} {A B : Set a}
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(_≈₁_ : A → A → Set a) (_≈₂_ : B → B → Set a)
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(_⊔₁_ : A → A → A) (_⊔₂_ : B → B → B)
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(_⊓₁_ : A → A → A) (_⊓₂_ : B → B → B)
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(lA : IsLattice A _≈₁_ _⊔₁_ _⊓₁_) (lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
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open import Agda.Primitive using (lsuc)
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open import Data.Nat using (ℕ; suc; _+_)
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open import Data.Product using (_×_)
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open import Utils using (iterate)
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open IsLattice lA renaming (FixedHeight to FixedHeight₁)
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open IsLattice lB renaming (FixedHeight to FixedHeight₂)
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IterProd : ℕ → Set a
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IterProd k = iterate k (λ t → A × t) B
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-- To make iteration more convenient, package the definitions in Lattice
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-- records, perform the recursion, and unpackage.
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private module _ where
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BLattice : Lattice B
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BLattice = record
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{ _≈_ = _≈₂_
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; _⊔_ = _⊔₂_
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; _⊓_ = _⊓₂_
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; isLattice = lB
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}
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IterProdLattice : ∀ {k : ℕ} → Lattice (IterProd k)
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IterProdLattice {0} = BLattice
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IterProdLattice {suc k'} = record
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{ _≈_ = _≈_
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; _⊔_ = _⊔_
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; _⊓_ = _⊓_
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; isLattice = isLattice
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}
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where
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Right : Lattice (IterProd k')
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Right = IterProdLattice {k'}
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open import Lattice.Prod
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_≈₁_ (Lattice._≈_ Right)
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_⊔₁_ (Lattice._⊔_ Right)
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_⊓₁_ (Lattice._⊓_ Right)
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lA (Lattice.isLattice Right)
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module _ (≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_)
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(h₁ h₂ : ℕ)
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(fhA : FixedHeight₁ h₁) (fhB : FixedHeight₂ h₂) where
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private module _ where
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record FiniteHeightAndDecEq (A : Set a) : Set (lsuc a) where
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field
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height : ℕ
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_≈_ : A → A → Set a
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_⊔_ : A → A → A
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_⊓_ : A → A → A
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isFiniteHeightLattice : IsFiniteHeightLattice A height _≈_ _⊔_ _⊓_
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≈-dec : IsDecidable _≈_
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open IsFiniteHeightLattice isFiniteHeightLattice public
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BFiniteHeightLattice : FiniteHeightAndDecEq B
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BFiniteHeightLattice = record
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{ height = h₂
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; _≈_ = _≈₂_
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; _⊔_ = _⊔₂_
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; _⊓_ = _⊓₂_
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; isFiniteHeightLattice = record
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{ isLattice = lB
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; fixedHeight = fhB
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}
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; ≈-dec = ≈₂-dec
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}
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IterProdFiniteHeightLattice : ∀ {k : ℕ} → FiniteHeightAndDecEq (IterProd k)
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IterProdFiniteHeightLattice {0} = BFiniteHeightLattice
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IterProdFiniteHeightLattice {suc k'} = record
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{ height = h₁ + FiniteHeightAndDecEq.height Right
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; _≈_ = _≈_
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; _⊔_ = _⊔_
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; _⊓_ = _⊓_
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; isFiniteHeightLattice = isFiniteHeightLattice
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≈₁-dec (FiniteHeightAndDecEq.≈-dec Right)
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h₁ (FiniteHeightAndDecEq.height Right)
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fhA (IsFiniteHeightLattice.fixedHeight (FiniteHeightAndDecEq.isFiniteHeightLattice Right))
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; ≈-dec = ≈-dec ≈₁-dec (FiniteHeightAndDecEq.≈-dec Right)
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}
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where
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Right = IterProdFiniteHeightLattice {k'}
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open import Lattice.Prod
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_≈₁_ (FiniteHeightAndDecEq._≈_ Right)
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_⊔₁_ (FiniteHeightAndDecEq._⊔_ Right)
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_⊓₁_ (FiniteHeightAndDecEq._⊓_ Right)
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lA (FiniteHeightAndDecEq.isLattice Right)
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module _ (k : ℕ) where
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open FiniteHeightAndDecEq (IterProdFiniteHeightLattice {k}) using (fixedHeight) public
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-- Expose the computed definition in public.
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module _ (k : ℕ) where
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open Lattice.Lattice (IterProdLattice {k}) public
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163
Lattice/Map.agda
163
Lattice/Map.agda
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@ -19,6 +19,7 @@ open import Data.List.Relation.Unary.Any using (Any; here; there) -- TODO: re-ex
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open import Data.Product using (_×_; _,_; Σ; proj₁ ; proj₂)
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open import Data.Empty using (⊥; ⊥-elim)
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open import Equivalence
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open import Utils using (Unique; push; empty; Unique-append; All¬-¬Any; All-x∈xs)
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open IsLattice lB using () renaming
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( ≈-refl to ≈₂-refl; ≈-sym to ≈₂-sym; ≈-trans to ≈₂-trans
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@ -28,35 +29,13 @@ open IsLattice lB using () renaming
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; absorb-⊔-⊓ to absorb-⊔₂-⊓₂; absorb-⊓-⊔ to absorb-⊓₂-⊔₂
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)
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keys : List (A × B) → List A
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keys = map proj₁
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data Unique {c} {C : Set c} : List C → Set c where
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empty : Unique []
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push : ∀ {x : C} {xs : List C}
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→ All (λ x' → ¬ x ≡ x') xs
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→ Unique xs
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→ Unique (x ∷ xs)
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Unique-append : ∀ {c} {C : Set c} {x : C} {xs : List C} →
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¬ MemProp._∈_ x xs → Unique xs → Unique (xs ++ (x ∷ []))
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Unique-append {c} {C} {x} {[]} _ _ = push [] empty
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Unique-append {c} {C} {x} {x' ∷ xs'} x∉xs (push x'≢ uxs') =
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push (help x'≢) (Unique-append (λ x∈xs' → x∉xs (there x∈xs')) uxs')
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where
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x'≢x : ¬ x' ≡ x
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x'≢x x'≡x = x∉xs (here (sym x'≡x))
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help : {l : List C} → All (λ x'' → ¬ x' ≡ x'') l → All (λ x'' → ¬ x' ≡ x'') (l ++ (x ∷ []))
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help {[]} _ = x'≢x ∷ []
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help {e ∷ es} (x'≢e ∷ x'≢es) = x'≢e ∷ help x'≢es
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All¬-¬Any : ∀ {p c} {C : Set c} {P : C → Set p} {l : List C} → All (λ x → ¬ P x) l → ¬ Any P l
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All¬-¬Any {l = x ∷ xs} (¬Px ∷ _) (here Px) = ¬Px Px
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All¬-¬Any {l = x ∷ xs} (_ ∷ ¬Pxs) (there Pxs) = All¬-¬Any ¬Pxs Pxs
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private module ImplKeys where
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keys : List (A × B) → List A
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keys = map proj₁
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private module _ where
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open MemProp using (_∈_)
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open ImplKeys
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unique-not-in : ∀ {k : A} {v : B} {l : List (A × B)} →
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¬ (All (λ k' → ¬ k ≡ k') (keys l) × (k , v) ∈ l)
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@ -108,6 +87,7 @@ private module ImplRelation where
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private module ImplInsert (f : B → B → B) where
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open import Data.List using (map)
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open MemProp using (_∈_)
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open ImplKeys
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private
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_∈k_ : A → List (A × B) → Set a
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@ -153,6 +133,20 @@ private module ImplInsert (f : B → B → B) where
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... | yes k∈kl rewrite insert-keys-∈ {v = v} k∈kl = u
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... | no k∉kl rewrite sym (insert-keys-∉ {v = v} k∉kl) = Unique-append k∉kl u
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union-subset-keys : ∀ {l₁ l₂ : List (A × B)} →
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All (λ k → k ∈k l₂) (keys l₁) →
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keys l₂ ≡ keys (union l₁ l₂)
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union-subset-keys {[]} _ = refl
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union-subset-keys {(k , v) ∷ l₁'} (k∈kl₂ ∷ kl₁'⊆kl₂)
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rewrite union-subset-keys kl₁'⊆kl₂ =
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insert-keys-∈ k∈kl₂
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union-equal-keys : ∀ {l₁ l₂ : List (A × B)} →
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keys l₁ ≡ keys l₂ → keys l₁ ≡ keys (union l₁ l₂)
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union-equal-keys {l₁} {l₂} kl₁≡kl₂
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with subst (λ l → All (λ k → k ∈ l) (keys l₁)) kl₁≡kl₂ (All-x∈xs (keys l₁))
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... | kl₁⊆kl₂ = trans kl₁≡kl₂ (union-subset-keys {l₁} {l₂} kl₁⊆kl₂)
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union-preserves-Unique : ∀ (l₁ l₂ : List (A × B)) →
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Unique (keys l₂) → Unique (keys (union l₁ l₂))
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union-preserves-Unique [] l₂ u₂ = u₂
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@ -366,6 +360,29 @@ private module ImplInsert (f : B → B → B) where
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let (k∈kl₁ , k∈kxs) = restrict-needs-both k∈l₁xs
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in (k∈kl₁ , there k∈kxs)
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restrict-subset-keys : ∀ {l₁ l₂ : List (A × B)} →
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All (λ k → k ∈k l₁) (keys l₂) →
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keys l₂ ≡ keys (restrict l₁ l₂)
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restrict-subset-keys {l₁} {[]} _ = refl
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restrict-subset-keys {l₁} {(k , v) ∷ l₂'} (k∈kl₁ ∷ kl₂'⊆kl₁)
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with ∈k-dec k l₁
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... | no k∉kl₁ = ⊥-elim (k∉kl₁ k∈kl₁)
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... | yes _ rewrite restrict-subset-keys {l₁} {l₂'} kl₂'⊆kl₁ = refl
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restrict-equal-keys : ∀ {l₁ l₂ : List (A × B)} →
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keys l₁ ≡ keys l₂ →
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keys l₁ ≡ keys (restrict l₁ l₂)
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restrict-equal-keys {l₁} {l₂} kl₁≡kl₂
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with subst (λ l → All (λ k → k ∈ l) (keys l₂)) (sym kl₁≡kl₂) (All-x∈xs (keys l₂))
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... | kl₂⊆kl₁ = trans kl₁≡kl₂ (restrict-subset-keys {l₁} {l₂} kl₂⊆kl₁)
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intersect-equal-keys : ∀ {l₁ l₂ : List (A × B)} →
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keys l₁ ≡ keys l₂ →
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keys l₁ ≡ keys (intersect l₁ l₂)
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intersect-equal-keys {l₁} {l₂} kl₁≡kl₂
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rewrite restrict-equal-keys (trans kl₁≡kl₂ (updates-keys {l₁} {l₂}))
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rewrite updates-keys {l₁} {l₂} = refl
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restrict-preserves-∉₁ : ∀ {k : A} {l₁ l₂ : List (A × B)} →
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¬ k ∈k l₁ → ¬ k ∈k restrict l₁ l₂
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restrict-preserves-∉₁ {k} {l₁} {l₂} k∉kl₁ k∈kl₁l₂ =
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@ -448,13 +465,16 @@ private module ImplInsert (f : B → B → B) where
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Map : Set (a ⊔ℓ b)
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Map = Σ (List (A × B)) (λ l → Unique (keys l))
|
||||
Map = Σ (List (A × B)) (λ l → Unique (ImplKeys.keys l))
|
||||
|
||||
keys : Map → List A
|
||||
keys (kvs , _) = ImplKeys.keys kvs
|
||||
|
||||
_∈_ : (A × B) → Map → Set (a ⊔ℓ b)
|
||||
_∈_ p (kvs , _) = MemProp._∈_ p kvs
|
||||
|
||||
_∈k_ : A → Map → Set a
|
||||
_∈k_ k (kvs , _) = MemProp._∈_ k (keys kvs)
|
||||
_∈k_ k m = MemProp._∈_ k (keys m)
|
||||
|
||||
Map-functional : ∀ {k : A} {v v' : B} {m : Map} → (k , v) ∈ m → (k , v') ∈ m → v ≡ v'
|
||||
Map-functional {m = (l , ul)} k,v∈m k,v'∈m = ListAB-functional ul k,v∈m k,v'∈m
|
||||
|
|
@ -492,8 +512,8 @@ data Expr : Set (a ⊔ℓ b) where
|
|||
_∪_ : Expr → Expr → Expr
|
||||
_∩_ : Expr → Expr → Expr
|
||||
|
||||
open ImplInsert _⊔₂_ using (union-preserves-Unique) renaming (insert to insert-impl; union to union-impl)
|
||||
open ImplInsert _⊓₂_ using (intersect-preserves-Unique) renaming (intersect to intersect-impl)
|
||||
open ImplInsert _⊔₂_ using (union-preserves-Unique; union-equal-keys) renaming (insert to insert-impl; union to union-impl)
|
||||
open ImplInsert _⊓₂_ using (intersect-preserves-Unique; intersect-equal-keys) renaming (intersect to intersect-impl)
|
||||
|
||||
_⊔_ : Map → Map → Map
|
||||
_⊔_ (kvs₁ , _) (kvs₂ , uks₂) = (union-impl kvs₁ kvs₂ , union-preserves-Unique kvs₁ kvs₂ uks₂)
|
||||
|
|
@ -553,45 +573,46 @@ Expr-Provenance k (e₁ ∩ e₂) k∈ke₁e₂
|
|||
... | no k∉ke₁ | yes k∈ke₂ = ⊥-elim (intersect-preserves-∉₁ {l₂ = proj₁ ⟦ e₂ ⟧} k∉ke₁ k∈ke₁e₂)
|
||||
... | no k∉ke₁ | no k∉ke₂ = ⊥-elim (intersect-preserves-∉₂ {l₁ = proj₁ ⟦ e₁ ⟧} k∉ke₂ k∈ke₁e₂)
|
||||
|
||||
data SubsetInfo (m₁ m₂ : Map) : Set (a ⊔ℓ b) where
|
||||
extra : (k : A) → k ∈k m₁ → ¬ k ∈k m₂ → SubsetInfo m₁ m₂
|
||||
mismatch : (k : A) (v₁ v₂ : B) → (k , v₁) ∈ m₁ → (k , v₂) ∈ m₂ → ¬ v₁ ≈₂ v₂ → SubsetInfo m₁ m₂
|
||||
fine : m₁ ⊆ m₂ → SubsetInfo m₁ m₂
|
||||
|
||||
SubsetInfo-to-dec : ∀ {m₁ m₂ : Map} → SubsetInfo m₁ m₂ → Dec (m₁ ⊆ m₂)
|
||||
SubsetInfo-to-dec (extra k k∈km₁ k∉km₂) =
|
||||
let (v , k,v∈m₁) = locate k∈km₁
|
||||
in no (λ m₁⊆m₂ →
|
||||
let (v' , (_ , k,v'∈m₂)) = m₁⊆m₂ k v k,v∈m₁
|
||||
in k∉km₂ (∈-cong proj₁ k,v'∈m₂))
|
||||
SubsetInfo-to-dec {m₁} {m₂} (mismatch k v₁ v₂ k,v₁∈m₁ k,v₂∈m₂ v₁̷≈v₂) =
|
||||
no (λ m₁⊆m₂ →
|
||||
let (v' , (v₁≈v' , k,v'∈m₂)) = m₁⊆m₂ k v₁ k,v₁∈m₁
|
||||
in v₁̷≈v₂ (subst (λ v'' → v₁ ≈₂ v'') (Map-functional {k} {v'} {v₂} {m₂} k,v'∈m₂ k,v₂∈m₂) v₁≈v')) -- for some reason, can't just use subst...
|
||||
SubsetInfo-to-dec (fine m₁⊆m₂) = yes m₁⊆m₂
|
||||
|
||||
module _ (≈₂-dec : ∀ (b₁ b₂ : B) → Dec (b₁ ≈₂ b₂)) where
|
||||
compute-SubsetInfo : ∀ m₁ m₂ → SubsetInfo m₁ m₂
|
||||
compute-SubsetInfo ([] , _) m₂ = fine (λ k v ())
|
||||
compute-SubsetInfo m₁@((k , v) ∷ xs₁ , push k≢xs₁ uxs₁) m₂@(l₂ , u₂)
|
||||
with compute-SubsetInfo (xs₁ , uxs₁) m₂
|
||||
... | extra k' k'∈kxs₁ k'∉km₂ = extra k' (there k'∈kxs₁) k'∉km₂
|
||||
... | mismatch k' v₁ v₂ k',v₁∈xs₁ k',v₂∈m₂ v₁̷≈v₂ =
|
||||
mismatch k' v₁ v₂ (there k',v₁∈xs₁) k',v₂∈m₂ v₁̷≈v₂
|
||||
... | fine xs₁⊆m₂ with ∈k-dec k l₂
|
||||
... | no k∉km₂ = extra k (here refl) k∉km₂
|
||||
... | yes k∈km₂ with locate k∈km₂
|
||||
... | (v' , k,v'∈m₂) with ≈₂-dec v v'
|
||||
... | no v̷≈v' = mismatch k v v' (here refl) (k,v'∈m₂) v̷≈v'
|
||||
... | yes v≈v' = fine m₁⊆m₂
|
||||
where
|
||||
m₁⊆m₂ : m₁ ⊆ m₂
|
||||
m₁⊆m₂ k' v'' (here k,v≡k',v'')
|
||||
rewrite cong proj₁ k,v≡k',v''
|
||||
rewrite cong proj₂ k,v≡k',v'' =
|
||||
(v' , (v≈v' , k,v'∈m₂))
|
||||
m₁⊆m₂ k' v'' (there k,v≡k',v'') =
|
||||
xs₁⊆m₂ k' v'' k,v≡k',v''
|
||||
private module _ where
|
||||
data SubsetInfo (m₁ m₂ : Map) : Set (a ⊔ℓ b) where
|
||||
extra : (k : A) → k ∈k m₁ → ¬ k ∈k m₂ → SubsetInfo m₁ m₂
|
||||
mismatch : (k : A) (v₁ v₂ : B) → (k , v₁) ∈ m₁ → (k , v₂) ∈ m₂ → ¬ v₁ ≈₂ v₂ → SubsetInfo m₁ m₂
|
||||
fine : m₁ ⊆ m₂ → SubsetInfo m₁ m₂
|
||||
|
||||
SubsetInfo-to-dec : ∀ {m₁ m₂ : Map} → SubsetInfo m₁ m₂ → Dec (m₁ ⊆ m₂)
|
||||
SubsetInfo-to-dec (extra k k∈km₁ k∉km₂) =
|
||||
let (v , k,v∈m₁) = locate k∈km₁
|
||||
in no (λ m₁⊆m₂ →
|
||||
let (v' , (_ , k,v'∈m₂)) = m₁⊆m₂ k v k,v∈m₁
|
||||
in k∉km₂ (∈-cong proj₁ k,v'∈m₂))
|
||||
SubsetInfo-to-dec {m₁} {m₂} (mismatch k v₁ v₂ k,v₁∈m₁ k,v₂∈m₂ v₁̷≈v₂) =
|
||||
no (λ m₁⊆m₂ →
|
||||
let (v' , (v₁≈v' , k,v'∈m₂)) = m₁⊆m₂ k v₁ k,v₁∈m₁
|
||||
in v₁̷≈v₂ (subst (λ v'' → v₁ ≈₂ v'') (Map-functional {k} {v'} {v₂} {m₂} k,v'∈m₂ k,v₂∈m₂) v₁≈v')) -- for some reason, can't just use subst...
|
||||
SubsetInfo-to-dec (fine m₁⊆m₂) = yes m₁⊆m₂
|
||||
|
||||
compute-SubsetInfo : ∀ m₁ m₂ → SubsetInfo m₁ m₂
|
||||
compute-SubsetInfo ([] , _) m₂ = fine (λ k v ())
|
||||
compute-SubsetInfo m₁@((k , v) ∷ xs₁ , push k≢xs₁ uxs₁) m₂@(l₂ , u₂)
|
||||
with compute-SubsetInfo (xs₁ , uxs₁) m₂
|
||||
... | extra k' k'∈kxs₁ k'∉km₂ = extra k' (there k'∈kxs₁) k'∉km₂
|
||||
... | mismatch k' v₁ v₂ k',v₁∈xs₁ k',v₂∈m₂ v₁̷≈v₂ =
|
||||
mismatch k' v₁ v₂ (there k',v₁∈xs₁) k',v₂∈m₂ v₁̷≈v₂
|
||||
... | fine xs₁⊆m₂ with ∈k-dec k l₂
|
||||
... | no k∉km₂ = extra k (here refl) k∉km₂
|
||||
... | yes k∈km₂ with locate k∈km₂
|
||||
... | (v' , k,v'∈m₂) with ≈₂-dec v v'
|
||||
... | no v̷≈v' = mismatch k v v' (here refl) (k,v'∈m₂) v̷≈v'
|
||||
... | yes v≈v' = fine m₁⊆m₂
|
||||
where
|
||||
m₁⊆m₂ : m₁ ⊆ m₂
|
||||
m₁⊆m₂ k' v'' (here k,v≡k',v'')
|
||||
rewrite cong proj₁ k,v≡k',v''
|
||||
rewrite cong proj₂ k,v≡k',v'' =
|
||||
(v' , (v≈v' , k,v'∈m₂))
|
||||
m₁⊆m₂ k' v'' (there k,v≡k',v'') =
|
||||
xs₁⊆m₂ k' v'' k,v≡k',v''
|
||||
|
||||
⊆-dec : ∀ m₁ m₂ → Dec (m₁ ⊆ m₂)
|
||||
⊆-dec m₁ m₂ = SubsetInfo-to-dec (compute-SubsetInfo m₁ m₂)
|
||||
|
|
@ -860,3 +881,9 @@ isLattice = record
|
|||
; absorb-⊔-⊓ = absorb-⊔-⊓
|
||||
; absorb-⊓-⊔ = absorb-⊓-⊔
|
||||
}
|
||||
|
||||
⊔-equal-keys : ∀ {m₁ m₂ : Map} → keys m₁ ≡ keys m₂ → keys m₁ ≡ keys (m₁ ⊔ m₂)
|
||||
⊔-equal-keys km₁≡km₂ = union-equal-keys km₁≡km₂
|
||||
|
||||
⊓-equal-keys : ∀ {m₁ m₂ : Map} → keys m₁ ≡ keys m₂ → keys m₁ ≡ keys (m₁ ⊓ m₂)
|
||||
⊓-equal-keys km₁≡km₂ = intersect-equal-keys km₁≡km₂
|
||||
|
|
|
|||
|
|
@ -94,6 +94,16 @@ isLattice = record
|
|||
)
|
||||
}
|
||||
|
||||
|
||||
module _ (≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_) where
|
||||
≈-dec : IsDecidable _≈_
|
||||
≈-dec (a₁ , b₁) (a₂ , b₂)
|
||||
with ≈₁-dec a₁ a₂ | ≈₂-dec b₁ b₂
|
||||
... | yes a₁≈a₂ | yes b₁≈b₂ = yes (a₁≈a₂ , b₁≈b₂)
|
||||
... | no a₁̷≈a₂ | _ = no (λ (a₁≈a₂ , _) → a₁̷≈a₂ a₁≈a₂)
|
||||
... | _ | no b₁̷≈b₂ = no (λ (_ , b₁≈b₂) → b₁̷≈b₂ b₁≈b₂)
|
||||
|
||||
|
||||
module _ (≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_)
|
||||
(h₁ h₂ : ℕ)
|
||||
(fhA : FixedHeight₁ h₁) (fhB : FixedHeight₂ h₂) where
|
||||
|
|
|
|||
41
Utils.agda
Normal file
41
Utils.agda
Normal file
|
|
@ -0,0 +1,41 @@
|
|||
module Utils where
|
||||
|
||||
open import Data.Nat using (ℕ; suc)
|
||||
open import Data.List using (List; []; _∷_; _++_)
|
||||
open import Data.List.Membership.Propositional using (_∈_)
|
||||
open import Data.List.Relation.Unary.All using (All; []; _∷_; map)
|
||||
open import Data.List.Relation.Unary.Any using (Any; here; there) -- TODO: re-export these with nicer names from map
|
||||
open import Relation.Binary.PropositionalEquality using (_≡_; sym; refl)
|
||||
open import Relation.Nullary using (¬_)
|
||||
|
||||
data Unique {c} {C : Set c} : List C → Set c where
|
||||
empty : Unique []
|
||||
push : ∀ {x : C} {xs : List C}
|
||||
→ All (λ x' → ¬ x ≡ x') xs
|
||||
→ Unique xs
|
||||
→ Unique (x ∷ xs)
|
||||
|
||||
Unique-append : ∀ {c} {C : Set c} {x : C} {xs : List C} →
|
||||
¬ x ∈ xs → Unique xs → Unique (xs ++ (x ∷ []))
|
||||
Unique-append {c} {C} {x} {[]} _ _ = push [] empty
|
||||
Unique-append {c} {C} {x} {x' ∷ xs'} x∉xs (push x'≢ uxs') =
|
||||
push (help x'≢) (Unique-append (λ x∈xs' → x∉xs (there x∈xs')) uxs')
|
||||
where
|
||||
x'≢x : ¬ x' ≡ x
|
||||
x'≢x x'≡x = x∉xs (here (sym x'≡x))
|
||||
|
||||
help : {l : List C} → All (λ x'' → ¬ x' ≡ x'') l → All (λ x'' → ¬ x' ≡ x'') (l ++ (x ∷ []))
|
||||
help {[]} _ = x'≢x ∷ []
|
||||
help {e ∷ es} (x'≢e ∷ x'≢es) = x'≢e ∷ help x'≢es
|
||||
|
||||
All¬-¬Any : ∀ {p c} {C : Set c} {P : C → Set p} {l : List C} → All (λ x → ¬ P x) l → ¬ Any P l
|
||||
All¬-¬Any {l = x ∷ xs} (¬Px ∷ _) (here Px) = ¬Px Px
|
||||
All¬-¬Any {l = x ∷ xs} (_ ∷ ¬Pxs) (there Pxs) = All¬-¬Any ¬Pxs Pxs
|
||||
|
||||
All-x∈xs : ∀ {a} {A : Set a} (xs : List A) → All (λ x → x ∈ xs) xs
|
||||
All-x∈xs [] = []
|
||||
All-x∈xs (x ∷ xs') = here refl ∷ map there (All-x∈xs xs')
|
||||
|
||||
iterate : ∀ {a} {A : Set a} (n : ℕ) → (f : A → A) → A → A
|
||||
iterate 0 _ a = a
|
||||
iterate (suc n) f a = f (iterate n f a)
|
||||
Loading…
Reference in New Issue
Block a user