442 lines
22 KiB
Agda
442 lines
22 KiB
Agda
module Lattice where
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open import Equivalence
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import Chain
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import Data.Nat.Properties as NatProps
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open import Relation.Binary.PropositionalEquality as Eq using (_≡_; sym; subst)
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open Eq.≡-Reasoning using (begin_; _≡⟨⟩_; step-≡; _∎)
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open import Relation.Binary.Definitions
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open import Relation.Binary.Core using (_Preserves_⟶_ )
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open import Relation.Nullary using (Dec; ¬_; yes; no)
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open import Data.Nat as Nat using (ℕ; _≤_; _+_; suc)
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open import Data.Product using (_×_; Σ; _,_; proj₁; proj₂)
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open import Data.Sum using (_⊎_; inj₁; inj₂)
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open import Agda.Primitive using (lsuc; Level) renaming (_⊔_ to _⊔ℓ_)
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open import Function.Definitions using (Injective)
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open import Data.Empty using (⊥)
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absurd : ∀ {a} {A : Set a} → ⊥ → A
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absurd ()
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IsDecidable : ∀ {a} {A : Set a} (R : A → A → Set a) → Set a
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IsDecidable {a} {A} R = ∀ (a₁ a₂ : A) → Dec (R a₁ a₂)
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record IsSemilattice {a} (A : Set a)
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(_≈_ : A → A → Set a)
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(_⊔_ : A → A → A) : Set a where
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_≼_ : A → A → Set a
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a ≼ b = Σ A (λ c → (a ⊔ c) ≈ b)
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_≺_ : A → A → Set a
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a ≺ b = (a ≼ b) × (¬ a ≈ b)
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field
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≈-equiv : IsEquivalence A _≈_
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≈-⊔-cong : ∀ {a₁ a₂ a₃ a₄} → a₁ ≈ a₂ → a₃ ≈ a₄ → (a₁ ⊔ a₃) ≈ (a₂ ⊔ a₄)
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⊔-assoc : (x y z : A) → ((x ⊔ y) ⊔ z) ≈ (x ⊔ (y ⊔ z))
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⊔-comm : (x y : A) → (x ⊔ y) ≈ (y ⊔ x)
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⊔-idemp : (x : A) → (x ⊔ x) ≈ x
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open IsEquivalence ≈-equiv public
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≼-refl : ∀ (a : A) → a ≼ a
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≼-refl a = (a , ⊔-idemp a)
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≼-cong : ∀ {a₁ a₂ a₃ a₄ : A} → a₁ ≈ a₂ → a₃ ≈ a₄ → a₁ ≼ a₃ → a₂ ≼ a₄
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≼-cong a₁≈a₂ a₃≈a₄ (c₁ , a₁⊔c₁≈a₃) = (c₁ , ≈-trans (≈-⊔-cong (≈-sym a₁≈a₂) ≈-refl) (≈-trans a₁⊔c₁≈a₃ a₃≈a₄))
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≺-cong : ∀ {a₁ a₂ a₃ a₄ : A} → a₁ ≈ a₂ → a₃ ≈ a₄ → a₁ ≺ a₃ → a₂ ≺ a₄
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≺-cong a₁≈a₂ a₃≈a₄ (a₁≼a₃ , a₁̷≈a₃) =
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( ≼-cong a₁≈a₂ a₃≈a₄ a₁≼a₃
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, λ a₂≈a₄ → a₁̷≈a₃ (≈-trans a₁≈a₂ (≈-trans a₂≈a₄ (≈-sym a₃≈a₄)))
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)
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record IsLattice {a} (A : Set a)
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(_≈_ : A → A → Set a)
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(_⊔_ : A → A → A)
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(_⊓_ : A → A → A) : Set a where
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field
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joinSemilattice : IsSemilattice A _≈_ _⊔_
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meetSemilattice : IsSemilattice A _≈_ _⊓_
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absorb-⊔-⊓ : (x y : A) → (x ⊔ (x ⊓ y)) ≈ x
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absorb-⊓-⊔ : (x y : A) → (x ⊓ (x ⊔ y)) ≈ x
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open IsSemilattice joinSemilattice public
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open IsSemilattice meetSemilattice public using () renaming
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( ⊔-assoc to ⊓-assoc
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; ⊔-comm to ⊓-comm
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; ⊔-idemp to ⊓-idemp
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; ≈-⊔-cong to ≈-⊓-cong
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; _≼_ to _≽_
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; _≺_ to _≻_
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; ≼-refl to ≽-refl
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)
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record IsFiniteHeightLattice {a} (A : Set a)
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(h : ℕ)
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(_≈_ : A → A → Set a)
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(_⊔_ : A → A → A)
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(_⊓_ : A → A → A) : Set (lsuc a) where
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field
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isLattice : IsLattice A _≈_ _⊔_ _⊓_
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fixedHeight : Chain.Height (_≈_) (IsLattice.≈-equiv isLattice) (IsLattice._≺_ isLattice) (IsLattice.≺-cong isLattice) h
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open IsLattice isLattice public
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module _ {a b} {A : Set a} {B : Set b}
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(_≼₁_ : A → A → Set a) (_≼₂_ : B → B → Set b) where
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Monotonic : (A → B) → Set (a ⊔ℓ b)
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Monotonic f = ∀ {a₁ a₂ : A} → a₁ ≼₁ a₂ → f a₁ ≼₂ f a₂
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module ChainMapping {a b} {A : Set a} {B : Set b}
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{_≈₁_ : A → A → Set a} {_≈₂_ : B → B → Set b}
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{_⊔₁_ : A → A → A} {_⊔₂_ : B → B → B}
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(slA : IsSemilattice A _≈₁_ _⊔₁_) (slB : IsSemilattice B _≈₂_ _⊔₂_) where
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open IsSemilattice slA renaming (_≼_ to _≼₁_; _≺_ to _≺₁_; ≈-equiv to ≈₁-equiv; ≺-cong to ≺₁-cong)
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open IsSemilattice slB renaming (_≼_ to _≼₂_; _≺_ to _≺₂_; ≈-equiv to ≈₂-equiv; ≺-cong to ≺₂-cong)
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open Chain _≈₁_ ≈₁-equiv _≺₁_ ≺₁-cong using () renaming (Chain to Chain₁; step to step₁; done to done₁)
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open Chain _≈₂_ ≈₂-equiv _≺₂_ ≺₂-cong using () renaming (Chain to Chain₂; step to step₂; done to done₂)
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Chain-map : ∀ (f : A → B) →
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Monotonic _≼₁_ _≼₂_ f →
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Injective _≈₁_ _≈₂_ f →
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f Preserves _≈₁_ ⟶ _≈₂_ →
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∀ {a₁ a₂ : A} {n : ℕ} → Chain₁ a₁ a₂ n → Chain₂ (f a₁) (f a₂) n
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Chain-map f Monotonicᶠ Injectiveᶠ Preservesᶠ (done₁ a₁≈a₂) =
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done₂ (Preservesᶠ a₁≈a₂)
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Chain-map f Monotonicᶠ Injectiveᶠ Preservesᶠ (step₁ (a₁≼₁a , a₁̷≈₁a) a≈₁a' a'a₂) =
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let fa₁≺₂fa = (Monotonicᶠ a₁≼₁a , λ fa₁≈₂fa → a₁̷≈₁a (Injectiveᶠ fa₁≈₂fa))
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fa≈fa' = Preservesᶠ a≈₁a'
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in step₂ fa₁≺₂fa fa≈fa' (Chain-map f Monotonicᶠ Injectiveᶠ Preservesᶠ a'a₂)
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record Semilattice {a} (A : Set a) : Set (lsuc a) where
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field
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_≈_ : A → A → Set a
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_⊔_ : A → A → A
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isSemilattice : IsSemilattice A _≈_ _⊔_
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open IsSemilattice isSemilattice public
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record Lattice {a} (A : Set a) : Set (lsuc a) where
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field
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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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isLattice : IsLattice A _≈_ _⊔_ _⊓_
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open IsLattice isLattice public
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module IsSemilatticeInstances where
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module ForNat where
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open Nat
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open NatProps
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open Eq
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private
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≡-⊔-cong : ∀ {a₁ a₂ a₃ a₄} → a₁ ≡ a₂ → a₃ ≡ a₄ → (a₁ ⊔ a₃) ≡ (a₂ ⊔ a₄)
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≡-⊔-cong a₁≡a₂ a₃≡a₄ rewrite a₁≡a₂ rewrite a₃≡a₄ = refl
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≡-⊓-cong : ∀ {a₁ a₂ a₃ a₄} → a₁ ≡ a₂ → a₃ ≡ a₄ → (a₁ ⊓ a₃) ≡ (a₂ ⊓ a₄)
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≡-⊓-cong a₁≡a₂ a₃≡a₄ rewrite a₁≡a₂ rewrite a₃≡a₄ = refl
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NatIsMaxSemilattice : IsSemilattice ℕ _≡_ _⊔_
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NatIsMaxSemilattice = record
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{ ≈-equiv = record
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{ ≈-refl = refl
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; ≈-sym = sym
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; ≈-trans = trans
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}
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; ≈-⊔-cong = ≡-⊔-cong
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; ⊔-assoc = ⊔-assoc
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; ⊔-comm = ⊔-comm
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; ⊔-idemp = ⊔-idem
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}
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NatIsMinSemilattice : IsSemilattice ℕ _≡_ _⊓_
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NatIsMinSemilattice = record
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{ ≈-equiv = record
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{ ≈-refl = refl
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; ≈-sym = sym
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; ≈-trans = trans
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}
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; ≈-⊔-cong = ≡-⊓-cong
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; ⊔-assoc = ⊓-assoc
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; ⊔-comm = ⊓-comm
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; ⊔-idemp = ⊓-idem
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}
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module ForProd {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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(sA : IsSemilattice A _≈₁_ _⊔₁_) (sB : IsSemilattice B _≈₂_ _⊔₂_) where
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open Eq
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open Data.Product
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module ProdEquiv = IsEquivalenceInstances.ForProd _≈₁_ _≈₂_ (IsSemilattice.≈-equiv sA) (IsSemilattice.≈-equiv sB)
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open ProdEquiv using (_≈_) public
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infixl 20 _⊔_
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_⊔_ : A × B → A × B → A × B
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(a₁ , b₁) ⊔ (a₂ , b₂) = (a₁ ⊔₁ a₂ , b₁ ⊔₂ b₂)
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ProdIsSemilattice : IsSemilattice (A × B) _≈_ _⊔_
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ProdIsSemilattice = record
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{ ≈-equiv = ProdEquiv.ProdEquivalence
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; ≈-⊔-cong = λ (a₁≈a₂ , b₁≈b₂) (a₃≈a₄ , b₃≈b₄) →
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( IsSemilattice.≈-⊔-cong sA a₁≈a₂ a₃≈a₄
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, IsSemilattice.≈-⊔-cong sB b₁≈b₂ b₃≈b₄
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)
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; ⊔-assoc = λ (a₁ , b₁) (a₂ , b₂) (a₃ , b₃) →
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( IsSemilattice.⊔-assoc sA a₁ a₂ a₃
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, IsSemilattice.⊔-assoc sB b₁ b₂ b₃
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)
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; ⊔-comm = λ (a₁ , b₁) (a₂ , b₂) →
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( IsSemilattice.⊔-comm sA a₁ a₂
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, IsSemilattice.⊔-comm sB b₁ b₂
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)
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; ⊔-idemp = λ (a , b) →
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( IsSemilattice.⊔-idemp sA a
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, IsSemilattice.⊔-idemp sB b
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)
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}
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module ForMap {a} {A B : Set a}
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(≡-dec-A : Decidable (_≡_ {a} {A}))
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(_≈₂_ : B → B → Set a)
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(_⊔₂_ : B → B → B)
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(sB : IsSemilattice B _≈₂_ _⊔₂_) where
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open import Map A B ≡-dec-A
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open IsSemilattice sB renaming
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( ≈-refl to ≈₂-refl; ≈-sym to ≈₂-sym; ≈-⊔-cong to ≈₂-⊔₂-cong
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; ⊔-assoc to ⊔₂-assoc; ⊔-comm to ⊔₂-comm; ⊔-idemp to ⊔₂-idemp
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)
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module MapEquiv = IsEquivalenceInstances.ForMap A B ≡-dec-A _≈₂_ (IsSemilattice.≈-equiv sB)
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open MapEquiv using (_≈_) public
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infixl 20 _⊔_
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infixl 20 _⊓_
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_⊔_ : Map → Map → Map
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m₁ ⊔ m₂ = union _⊔₂_ m₁ m₂
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_⊓_ : Map → Map → Map
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m₁ ⊓ m₂ = intersect _⊔₂_ m₁ m₂
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MapIsUnionSemilattice : IsSemilattice Map _≈_ _⊔_
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MapIsUnionSemilattice = record
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{ ≈-equiv = MapEquiv.LiftEquivalence
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; ≈-⊔-cong = λ {m₁} {m₂} {m₃} {m₄} → union-cong _≈₂_ _⊔₂_ ≈₂-⊔₂-cong {m₁} {m₂} {m₃} {m₄}
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; ⊔-assoc = union-assoc _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ ⊔₂-assoc
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; ⊔-comm = union-comm _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ ⊔₂-comm
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; ⊔-idemp = union-idemp _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ ⊔₂-idemp
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}
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MapIsIntersectSemilattice : IsSemilattice Map _≈_ _⊓_
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MapIsIntersectSemilattice = record
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{ ≈-equiv = MapEquiv.LiftEquivalence
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; ≈-⊔-cong = λ {m₁} {m₂} {m₃} {m₄} → intersect-cong _≈₂_ _⊔₂_ ≈₂-⊔₂-cong {m₁} {m₂} {m₃} {m₄}
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; ⊔-assoc = intersect-assoc _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ ⊔₂-assoc
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; ⊔-comm = intersect-comm _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ ⊔₂-comm
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; ⊔-idemp = intersect-idemp _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ ⊔₂-idemp
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}
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module IsLatticeInstances where
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module ForNat where
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open Nat
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open NatProps
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open Eq
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open IsSemilatticeInstances.ForNat
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open Data.Product
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private
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max-bound₁ : {x y z : ℕ} → x ⊔ y ≡ z → x ≤ z
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max-bound₁ {x} {y} {z} x⊔y≡z
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rewrite sym x⊔y≡z
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rewrite ⊔-comm x y = m≤n⇒m≤o⊔n y (≤-refl)
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min-bound₁ : {x y z : ℕ} → x ⊓ y ≡ z → z ≤ x
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min-bound₁ {x} {y} {z} x⊓y≡z
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rewrite sym x⊓y≡z = m≤n⇒m⊓o≤n y (≤-refl)
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minmax-absorb : {x y : ℕ} → x ⊓ (x ⊔ y) ≡ x
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minmax-absorb {x} {y} = ≤-antisym x⊓x⊔y≤x (helper x⊓x≤x⊓x⊔y (⊓-idem x))
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where
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x⊓x⊔y≤x = min-bound₁ {x} {x ⊔ y} {x ⊓ (x ⊔ y)} refl
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x⊓x≤x⊓x⊔y = ⊓-mono-≤ {x} {x} ≤-refl (max-bound₁ {x} {y} {x ⊔ y} refl)
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-- >:(
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helper : x ⊓ x ≤ x ⊓ (x ⊔ y) → x ⊓ x ≡ x → x ≤ x ⊓ (x ⊔ y)
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helper x⊓x≤x⊓x⊔y x⊓x≡x rewrite x⊓x≡x = x⊓x≤x⊓x⊔y
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maxmin-absorb : {x y : ℕ} → x ⊔ (x ⊓ y) ≡ x
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maxmin-absorb {x} {y} = ≤-antisym (helper x⊔x⊓y≤x⊔x (⊔-idem x)) x≤x⊔x⊓y
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where
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x≤x⊔x⊓y = max-bound₁ {x} {x ⊓ y} {x ⊔ (x ⊓ y)} refl
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x⊔x⊓y≤x⊔x = ⊔-mono-≤ {x} {x} ≤-refl (min-bound₁ {x} {y} {x ⊓ y} refl)
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-- >:(
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helper : x ⊔ (x ⊓ y) ≤ x ⊔ x → x ⊔ x ≡ x → x ⊔ (x ⊓ y) ≤ x
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helper x⊔x⊓y≤x⊔x x⊔x≡x rewrite x⊔x≡x = x⊔x⊓y≤x⊔x
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NatIsLattice : IsLattice ℕ _≡_ _⊔_ _⊓_
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NatIsLattice = record
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{ joinSemilattice = NatIsMaxSemilattice
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; meetSemilattice = NatIsMinSemilattice
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; absorb-⊔-⊓ = λ x y → maxmin-absorb {x} {y}
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; absorb-⊓-⊔ = λ x y → minmax-absorb {x} {y}
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}
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module ForProd {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) (_⊓₁_ : A → A → A)
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(_⊔₂_ : B → B → B) (_⊓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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module ProdJoin = IsSemilatticeInstances.ForProd _≈₁_ _≈₂_ _⊔₁_ _⊔₂_ (IsLattice.joinSemilattice lA) (IsLattice.joinSemilattice lB)
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open ProdJoin using (_⊔_; _≈_) public
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module ProdMeet = IsSemilatticeInstances.ForProd _≈₁_ _≈₂_ _⊓₁_ _⊓₂_ (IsLattice.meetSemilattice lA) (IsLattice.meetSemilattice lB)
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open ProdMeet using () renaming (_⊔_ to _⊓_) public
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ProdIsLattice : IsLattice (A × B) _≈_ _⊔_ _⊓_
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ProdIsLattice = record
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{ joinSemilattice = ProdJoin.ProdIsSemilattice
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; meetSemilattice = ProdMeet.ProdIsSemilattice
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; absorb-⊔-⊓ = λ (a₁ , b₁) (a₂ , b₂) →
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( IsLattice.absorb-⊔-⊓ lA a₁ a₂
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, IsLattice.absorb-⊔-⊓ lB b₁ b₂
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)
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; absorb-⊓-⊔ = λ (a₁ , b₁) (a₂ , b₂) →
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( IsLattice.absorb-⊓-⊔ lA a₁ a₂
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, IsLattice.absorb-⊓-⊔ lB b₁ b₂
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)
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}
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module ForMap {a} {A B : Set a}
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(≡-dec-A : Decidable (_≡_ {a} {A}))
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(_≈₂_ : B → B → Set a)
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(_⊔₂_ : B → B → B)
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(_⊓₂_ : B → B → B)
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(lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
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open import Map A B ≡-dec-A
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open IsLattice lB renaming
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( ≈-refl to ≈₂-refl; ≈-sym to ≈₂-sym
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; ⊔-idemp to ⊔₂-idemp; ⊓-idemp to ⊓₂-idemp
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; absorb-⊔-⊓ to absorb-⊔₂-⊓₂; absorb-⊓-⊔ to absorb-⊓₂-⊔₂
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)
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module MapJoin = IsSemilatticeInstances.ForMap ≡-dec-A _≈₂_ _⊔₂_ (IsLattice.joinSemilattice lB)
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open MapJoin using (_⊔_; _≈_) public
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module MapMeet = IsSemilatticeInstances.ForMap ≡-dec-A _≈₂_ _⊓₂_ (IsLattice.meetSemilattice lB)
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open MapMeet using (_⊓_) public
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MapIsLattice : IsLattice Map _≈_ _⊔_ _⊓_
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MapIsLattice = record
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{ joinSemilattice = MapJoin.MapIsUnionSemilattice
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; meetSemilattice = MapMeet.MapIsIntersectSemilattice
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; absorb-⊔-⊓ = union-intersect-absorb _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ _⊓₂_ ⊔₂-idemp ⊓₂-idemp absorb-⊔₂-⊓₂ absorb-⊓₂-⊔₂
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; absorb-⊓-⊔ = intersect-union-absorb _≈₂_ ≈₂-refl ≈₂-sym _⊔₂_ _⊓₂_ ⊔₂-idemp ⊓₂-idemp absorb-⊔₂-⊓₂ absorb-⊓₂-⊔₂
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}
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||
|
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module IsFiniteHeightLatticeInstances where
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module ForProd {a} {A B : Set a}
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(_≈₁_ : A → A → Set a) (_≈₂_ : B → B → Set a)
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||
(≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_)
|
||
(_⊔₁_ : A → A → A) (_⊓₁_ : A → A → A)
|
||
(_⊔₂_ : B → B → B) (_⊓₂_ : B → B → B)
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||
(h₁ h₂ : ℕ)
|
||
(lA : IsFiniteHeightLattice A h₁ _≈₁_ _⊔₁_ _⊓₁_) (lB : IsFiniteHeightLattice B h₂ _≈₂_ _⊔₂_ _⊓₂_) where
|
||
|
||
open NatProps
|
||
module ProdLattice = IsLatticeInstances.ForProd _≈₁_ _≈₂_ _⊔₁_ _⊓₁_ _⊔₂_ _⊓₂_ (IsFiniteHeightLattice.isLattice lA) (IsFiniteHeightLattice.isLattice lB)
|
||
open ProdLattice using (_⊔_; _⊓_; _≈_) public
|
||
open IsLattice ProdLattice.ProdIsLattice using (_≼_; _≺_; ≺-cong; ≈-equiv)
|
||
open IsFiniteHeightLattice lA using () renaming (⊔-idemp to ⊔₁-idemp; _≼_ to _≼₁_; ≈-equiv to ≈₁-equiv; ≈-refl to ≈₁-refl; ≈-trans to ≈₁-trans; ≈-sym to ≈₁-sym; _≺_ to _≺₁_; ≺-cong to ≺₁-cong)
|
||
open IsFiniteHeightLattice lB using () renaming (⊔-idemp to ⊔₂-idemp; _≼_ to _≼₂_; ≈-equiv to ≈₂-equiv; ≈-refl to ≈₂-refl; ≈-trans to ≈₂-trans; ≈-sym to ≈₂-sym; _≺_ to _≺₂_; ≺-cong to ≺₂-cong)
|
||
|
||
module ChainMapping₁ = ChainMapping (IsFiniteHeightLattice.joinSemilattice lA) (IsLattice.joinSemilattice ProdLattice.ProdIsLattice)
|
||
module ChainMapping₂ = ChainMapping (IsFiniteHeightLattice.joinSemilattice lB) (IsLattice.joinSemilattice ProdLattice.ProdIsLattice)
|
||
|
||
module ChainA = Chain _≈₁_ ≈₁-equiv _≺₁_ ≺₁-cong
|
||
module ChainB = Chain _≈₂_ ≈₂-equiv _≺₂_ ≺₂-cong
|
||
module ProdChain = Chain _≈_ ≈-equiv _≺_ ≺-cong
|
||
|
||
open ChainA using () renaming (Chain to Chain₁; done to done₁; step to step₁; Chain-≈-cong₁ to Chain₁-≈-cong₁)
|
||
open ChainB using () renaming (Chain to Chain₂; done to done₂; step to step₂; Chain-≈-cong₁ to Chain₂-≈-cong₁)
|
||
open ProdChain using (Chain; concat; done; step)
|
||
|
||
private
|
||
a,∙-Monotonic : ∀ (a : A) → Monotonic _≼₂_ _≼_ (λ b → (a , b))
|
||
a,∙-Monotonic a {b₁} {b₂} (b , b₁⊔b≈b₂) = ((a , b) , (⊔₁-idemp a , b₁⊔b≈b₂))
|
||
|
||
a,∙-Preserves-≈₂ : ∀ (a : A) → (λ b → (a , b)) Preserves _≈₂_ ⟶ _≈_
|
||
a,∙-Preserves-≈₂ a {b₁} {b₂} b₁≈b₂ = (≈₁-refl , b₁≈b₂)
|
||
|
||
∙,b-Monotonic : ∀ (b : B) → Monotonic _≼₁_ _≼_ (λ a → (a , b))
|
||
∙,b-Monotonic b {a₁} {a₂} (a , a₁⊔a≈a₂) = ((a , b) , (a₁⊔a≈a₂ , ⊔₂-idemp b))
|
||
|
||
∙,b-Preserves-≈₁ : ∀ (b : B) → (λ a → (a , b)) Preserves _≈₁_ ⟶ _≈_
|
||
∙,b-Preserves-≈₁ b {a₁} {a₂} a₁≈a₂ = (a₁≈a₂ , ≈₂-refl)
|
||
|
||
amin : A
|
||
amin = proj₁ (proj₁ (proj₁ (IsFiniteHeightLattice.fixedHeight lA)))
|
||
|
||
amax : A
|
||
amax = proj₂ (proj₁ (proj₁ (IsFiniteHeightLattice.fixedHeight lA)))
|
||
|
||
bmin : B
|
||
bmin = proj₁ (proj₁ (proj₁ (IsFiniteHeightLattice.fixedHeight lB)))
|
||
|
||
bmax : B
|
||
bmax = proj₂ (proj₁ (proj₁ (IsFiniteHeightLattice.fixedHeight lB)))
|
||
|
||
unzip : ∀ {a₁ a₂ : A} {b₁ b₂ : B} {n : ℕ} → Chain (a₁ , b₁) (a₂ , b₂) n → Σ (ℕ × ℕ) (λ (n₁ , n₂) → ((Chain₁ a₁ a₂ n₁ × Chain₂ b₁ b₂ n₂) × (n ≤ n₁ + n₂)))
|
||
unzip (done (a₁≈a₂ , b₁≈b₂)) = ((0 , 0) , ((done₁ a₁≈a₂ , done₂ b₁≈b₂) , ≤-refl))
|
||
unzip {a₁} {a₂} {b₁} {b₂} {n} (step {(a₁ , b₁)} {(a , b)} (((d₁ , d₂) , (a₁⊔d₁≈a , b₁⊔d₂≈b)) , a₁b₁̷≈ab) (a≈a' , b≈b') a'b'a₂b₂)
|
||
with ≈₁-dec a₁ a | ≈₂-dec b₁ b | unzip a'b'a₂b₂
|
||
... | yes a₁≈a | yes b₁≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) = absurd (a₁b₁̷≈ab (a₁≈a , b₁≈b))
|
||
... | no a₁̷≈a | yes b₁≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
|
||
((suc n₁ , n₂) , ((step₁ ((d₁ , a₁⊔d₁≈a) , a₁̷≈a) a≈a' c₁ , Chain₂-≈-cong₁ (≈₂-sym (≈₂-trans b₁≈b b≈b')) c₂), +-monoʳ-≤ 1 (n≤n₁+n₂)))
|
||
... | yes a₁≈a | no b₁̷≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
|
||
((n₁ , suc n₂) , ( (Chain₁-≈-cong₁ (≈₁-sym (≈₁-trans a₁≈a a≈a')) c₁ , step₂ ((d₂ , b₁⊔d₂≈b) , b₁̷≈b) b≈b' c₂)
|
||
, subst (n ≤_) (sym (+-suc n₁ n₂)) (+-monoʳ-≤ 1 n≤n₁+n₂)
|
||
))
|
||
... | no a₁̷≈a | no b₁̷≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
|
||
((suc n₁ , suc n₂) , ( (step₁ ((d₁ , a₁⊔d₁≈a) , a₁̷≈a) a≈a' c₁ , step₂ ((d₂ , b₁⊔d₂≈b) , b₁̷≈b) b≈b' c₂)
|
||
, ≤-stepsˡ 1 (subst (n ≤_) (sym (+-suc n₁ n₂)) (+-monoʳ-≤ 1 n≤n₁+n₂))
|
||
))
|
||
|
||
ProdIsFiniteHeightLattice : IsFiniteHeightLattice (A × B) (h₁ + h₂) _≈_ _⊔_ _⊓_
|
||
ProdIsFiniteHeightLattice = record
|
||
{ isLattice = ProdLattice.ProdIsLattice
|
||
; fixedHeight =
|
||
( ( ((amin , bmin) , (amax , bmax))
|
||
, concat
|
||
(ChainMapping₁.Chain-map (λ a → (a , bmin)) (∙,b-Monotonic _) proj₁ (∙,b-Preserves-≈₁ _) (proj₂ (proj₁ (IsFiniteHeightLattice.fixedHeight lA))))
|
||
(ChainMapping₂.Chain-map (λ b → (amax , b)) (a,∙-Monotonic _) proj₂ (a,∙-Preserves-≈₂ _) (proj₂ (proj₁ (IsFiniteHeightLattice.fixedHeight lB))))
|
||
)
|
||
, λ a₁b₁a₂b₂ → let ((n₁ , n₂) , ((a₁a₂ , b₁b₂) , n≤n₁+n₂)) = unzip a₁b₁a₂b₂
|
||
in ≤-trans n≤n₁+n₂ (+-mono-≤ (proj₂ (IsFiniteHeightLattice.fixedHeight lA) a₁a₂)
|
||
(proj₂ (IsFiniteHeightLattice.fixedHeight lB) b₁b₂))
|
||
)
|
||
}
|