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module Analysis.Sign where
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open import Data.String using (String) renaming (_≟_ to _≟ˢ_)
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open import Data.Nat using (suc)
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open import Data.Product using (_×_; proj₁; _,_)
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open import Data.List using (List; _∷_; []; foldr; cartesianProduct; cartesianProductWith)
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open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
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open import Relation.Binary.PropositionalEquality using (_≡_; refl; sym; trans; subst)
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open import Relation.Nullary using (¬_; Dec; yes; no)
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open import Data.Unit using (⊤)
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open import Language
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open import Lattice
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open import Utils using (Pairwise)
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import Lattice.Bundles.FiniteValueMap
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private module FixedHeightFiniteMap = Lattice.Bundles.FiniteValueMap.FromFiniteHeightLattice
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data Sign : Set where
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+ : Sign
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- : Sign
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0ˢ : Sign
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-- g for siGn; s is used for strings and i is not very descriptive.
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_≟ᵍ_ : IsDecidable (_≡_ {_} {Sign})
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_≟ᵍ_ + + = yes refl
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_≟ᵍ_ + - = no (λ ())
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_≟ᵍ_ + 0ˢ = no (λ ())
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_≟ᵍ_ - + = no (λ ())
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_≟ᵍ_ - - = yes refl
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_≟ᵍ_ - 0ˢ = no (λ ())
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_≟ᵍ_ 0ˢ + = no (λ ())
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_≟ᵍ_ 0ˢ - = no (λ ())
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_≟ᵍ_ 0ˢ 0ˢ = yes refl
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2024-03-10 13:54:19 -07:00
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-- embelish 'sign' with a top and bottom element.
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open import Lattice.AboveBelow Sign _≡_ (record { ≈-refl = refl; ≈-sym = sym; ≈-trans = trans }) _≟ᵍ_ as AB
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using ()
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renaming
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( AboveBelow to SignLattice
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; ≈-dec to ≈ᵍ-dec
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; ⊥ to ⊥ᵍ
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; ⊤ to ⊤ᵍ
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; [_] to [_]ᵍ
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; _≈_ to _≈ᵍ_
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; ≈-⊥-⊥ to ≈ᵍ-⊥ᵍ-⊥ᵍ
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; ≈-⊤-⊤ to ≈ᵍ-⊤ᵍ-⊤ᵍ
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; ≈-lift to ≈ᵍ-lift
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; ≈-refl to ≈ᵍ-refl
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)
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-- 'sign' has no underlying lattice structure, so use the 'plain' above-below lattice.
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open AB.Plain 0ˢ using ()
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renaming
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( finiteHeightLattice to finiteHeightLatticeᵍ
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; _≼_ to _≼ᵍ_
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; _⊔_ to _⊔ᵍ_
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)
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plus : SignLattice → SignLattice → SignLattice
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plus ⊥ᵍ _ = ⊥ᵍ
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plus _ ⊥ᵍ = ⊥ᵍ
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plus ⊤ᵍ _ = ⊤ᵍ
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plus _ ⊤ᵍ = ⊤ᵍ
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plus [ + ]ᵍ [ + ]ᵍ = [ + ]ᵍ
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plus [ + ]ᵍ [ - ]ᵍ = ⊤ᵍ
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plus [ + ]ᵍ [ 0ˢ ]ᵍ = [ + ]ᵍ
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plus [ - ]ᵍ [ + ]ᵍ = ⊤ᵍ
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plus [ - ]ᵍ [ - ]ᵍ = [ - ]ᵍ
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plus [ - ]ᵍ [ 0ˢ ]ᵍ = [ - ]ᵍ
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plus [ 0ˢ ]ᵍ [ + ]ᵍ = [ + ]ᵍ
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plus [ 0ˢ ]ᵍ [ - ]ᵍ = [ - ]ᵍ
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plus [ 0ˢ ]ᵍ [ 0ˢ ]ᵍ = [ 0ˢ ]ᵍ
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-- this is incredibly tedious: 125 cases per monotonicity proof, and tactics
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-- are hard. postulate for now.
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postulate plus-Monoˡ : ∀ (s₂ : SignLattice) → Monotonic _≼ᵍ_ _≼ᵍ_ (λ s₁ → plus s₁ s₂)
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postulate plus-Monoʳ : ∀ (s₁ : SignLattice) → Monotonic _≼ᵍ_ _≼ᵍ_ (plus s₁)
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minus : SignLattice → SignLattice → SignLattice
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minus ⊥ᵍ _ = ⊥ᵍ
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minus _ ⊥ᵍ = ⊥ᵍ
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minus ⊤ᵍ _ = ⊤ᵍ
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minus _ ⊤ᵍ = ⊤ᵍ
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minus [ + ]ᵍ [ + ]ᵍ = ⊤ᵍ
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minus [ + ]ᵍ [ - ]ᵍ = [ + ]ᵍ
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minus [ + ]ᵍ [ 0ˢ ]ᵍ = [ + ]ᵍ
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minus [ - ]ᵍ [ + ]ᵍ = [ - ]ᵍ
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minus [ - ]ᵍ [ - ]ᵍ = ⊤ᵍ
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minus [ - ]ᵍ [ 0ˢ ]ᵍ = [ - ]ᵍ
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minus [ 0ˢ ]ᵍ [ + ]ᵍ = [ - ]ᵍ
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minus [ 0ˢ ]ᵍ [ - ]ᵍ = [ + ]ᵍ
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minus [ 0ˢ ]ᵍ [ 0ˢ ]ᵍ = [ 0ˢ ]ᵍ
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postulate minus-Monoˡ : ∀ (s₂ : SignLattice) → Monotonic _≼ᵍ_ _≼ᵍ_ (λ s₁ → minus s₁ s₂)
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postulate minus-Monoʳ : ∀ (s₁ : SignLattice) → Monotonic _≼ᵍ_ _≼ᵍ_ (minus s₁)
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module _ (prog : Program) where
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open Program prog
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-- The variable -> sign map is a finite value-map with keys strings. Use a bundle to avoid explicitly specifying operators.
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open FixedHeightFiniteMap String SignLattice _≟ˢ_ finiteHeightLatticeᵍ vars-Unique ≈ᵍ-dec
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using ()
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renaming
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( finiteHeightLattice to finiteHeightLatticeᵛ
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; FiniteMap to VariableSigns
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; _≈_ to _≈ᵛ_
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; _⊔_ to _⊔ᵛ_
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; ≈-dec to ≈ᵛ-dec
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; _∈_ to _∈ᵛ_
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; _∈k_ to _∈kᵛ_
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; _updating_via_ to _updatingᵛ_via_
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; locate to locateᵛ
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)
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open FiniteHeightLattice finiteHeightLatticeᵛ
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using ()
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renaming
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( ⊔-Monotonicˡ to ⊔ᵛ-Monotonicˡ
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; ⊔-Monotonicʳ to ⊔ᵛ-Monotonicʳ
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; _≼_ to _≼ᵛ_
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; joinSemilattice to joinSemilatticeᵛ
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; ⊔-idemp to ⊔ᵛ-idemp
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)
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⊥ᵛ = proj₁ (proj₁ (proj₁ (FiniteHeightLattice.fixedHeight finiteHeightLatticeᵛ)))
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-- Finally, the map we care about is (state -> (variables -> sign)). Bring that in.
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module StateVariablesFiniteMap = FixedHeightFiniteMap State VariableSigns _≟_ finiteHeightLatticeᵛ states-Unique ≈ᵛ-dec
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open StateVariablesFiniteMap
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using (_[_]; m₁≼m₂⇒m₁[ks]≼m₂[ks])
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renaming
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( finiteHeightLattice to finiteHeightLatticeᵐ
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; FiniteMap to StateVariables
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; isLattice to isLatticeᵐ
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; _∈k_ to _∈kᵐ_
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; locate to locateᵐ
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)
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open FiniteHeightLattice finiteHeightLatticeᵐ
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using ()
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renaming (_≼_ to _≼ᵐ_)
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-- build up the 'join' function, which follows from Exercise 4.26's
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--
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-- L₁ → (A → L₂)
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--
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-- Construction, with L₁ = (A → L₂), and f = id
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joinForKey : State → StateVariables → VariableSigns
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joinForKey k states = foldr _⊔ᵛ_ ⊥ᵛ (states [ incoming k ])
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-- The per-key join is made up of map key accesses (which are monotonic)
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-- and folds using the join operation (also monotonic)
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joinForKey-Mono : ∀ (k : State) → Monotonic _≼ᵐ_ _≼ᵛ_ (joinForKey k)
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joinForKey-Mono k {fm₁} {fm₂} fm₁≼fm₂ =
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foldr-Mono joinSemilatticeᵛ joinSemilatticeᵛ (fm₁ [ incoming k ]) (fm₂ [ incoming k ]) _⊔ᵛ_ ⊥ᵛ ⊥ᵛ
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(m₁≼m₂⇒m₁[ks]≼m₂[ks] fm₁ fm₂ (incoming k) fm₁≼fm₂)
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(⊔ᵛ-idemp ⊥ᵛ) ⊔ᵛ-Monotonicʳ ⊔ᵛ-Monotonicˡ
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-- The name f' comes from the formulation of Exercise 4.26.
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open StateVariablesFiniteMap.GeneralizedUpdate states isLatticeᵐ (λ x → x) (λ a₁≼a₂ → a₁≼a₂) joinForKey joinForKey-Mono states
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renaming
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( f' to joinAll
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; f'-Monotonic to joinAll-Mono
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)
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-- With 'join' in hand, we need to perform abstract evaluation.
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vars-in-Map : ∀ (k : String) (vs : VariableSigns) →
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k ∈ˡ vars → k ∈kᵛ vs
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vars-in-Map k vs@(m , kvs≡vars) k∈vars rewrite kvs≡vars = k∈vars
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states-in-Map : ∀ (s : State) (sv : StateVariables) → s ∈kᵐ sv
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states-in-Map s sv@(m , ksv≡states) rewrite ksv≡states = states-complete s
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eval : ∀ (e : Expr) → (∀ k → k ∈ᵉ e → k ∈ˡ vars) → VariableSigns → SignLattice
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eval (e₁ + e₂) k∈e⇒k∈vars vs =
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plus (eval e₁ (λ k k∈e₁ → k∈e⇒k∈vars k (in⁺₁ k∈e₁)) vs)
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(eval e₂ (λ k k∈e₂ → k∈e⇒k∈vars k (in⁺₂ k∈e₂)) vs)
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eval (e₁ - e₂) k∈e⇒k∈vars vs =
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minus (eval e₁ (λ k k∈e₁ → k∈e⇒k∈vars k (in⁻₁ k∈e₁)) vs)
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(eval e₂ (λ k k∈e₂ → k∈e⇒k∈vars k (in⁻₂ k∈e₂)) vs)
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eval (` k) k∈e⇒k∈vars vs = proj₁ (locateᵛ {k} {vs} (vars-in-Map k vs (k∈e⇒k∈vars k here)))
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eval (# 0) _ _ = [ 0ˢ ]ᵍ
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eval (# (suc n')) _ _ = [ + ]ᵍ
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updateForState : State → StateVariables → VariableSigns
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updateForState s sv
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with code s in p
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... | k ← e =
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let
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(vs , s,vs∈sv) = locateᵐ {s} {sv} (states-in-Map s sv)
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k∈e⇒k∈codes = λ k k∈e → subst (λ stmt → k ∈ᵗ stmt) (sym p) (in←₂ k∈e)
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k∈e⇒k∈vars = λ k k∈e → vars-complete s (k∈e⇒k∈codes k k∈e)
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in
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vs updatingᵛ (k ∷ []) via (λ _ → eval e k∈e⇒k∈vars vs)
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-- module Test = StateVariablesFiniteMap.GeneralizedUpdate states isLatticeᵐ joinAll joinAll-Mono
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