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@ -7,17 +7,19 @@ module Analysis.Forward
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(isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_)
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(isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_)
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(≈ˡ-dec : IsDecidable _≈ˡ_) where
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(≈ˡ-dec : IsDecidable _≈ˡ_) where
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open import Data.Empty using (⊥-elim)
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open import Data.String using (String) renaming (_≟_ to _≟ˢ_)
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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.Nat using (suc)
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open import Data.Product using (_×_; proj₁; _,_)
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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 using (List; _∷_; []; foldr; foldl; cartesianProduct; cartesianProductWith)
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open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
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open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
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open import Data.List.Relation.Unary.Any as Any using ()
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open import Relation.Binary.PropositionalEquality using (_≡_; refl; sym; trans; subst)
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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 Relation.Nullary using (¬_; Dec; yes; no)
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open import Data.Unit using (⊤)
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open import Data.Unit using (⊤)
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open import Function using (_∘_)
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open import Function using (_∘_; flip)
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open import Utils using (Pairwise)
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open import Utils using (Pairwise; _⇒_)
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import Lattice.FiniteValueMap
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import Lattice.FiniteValueMap
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open IsFiniteHeightLattice isFiniteHeightLatticeˡ
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open IsFiniteHeightLattice isFiniteHeightLatticeˡ
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@ -26,6 +28,7 @@ open IsFiniteHeightLattice isFiniteHeightLatticeˡ
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( isLattice to isLatticeˡ
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( isLattice to isLatticeˡ
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; fixedHeight to fixedHeightˡ
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; fixedHeight to fixedHeightˡ
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; _≼_ to _≼ˡ_
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; _≼_ to _≼ˡ_
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; ≈-sym to ≈ˡ-sym
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)
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)
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module WithProg (prog : Program) where
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module WithProg (prog : Program) where
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@ -93,6 +96,17 @@ module WithProg (prog : Program) where
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≈ᵐ-dec = ≈ᵛ-dec⇒≈ᵐ-dec ≈ᵛ-dec
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≈ᵐ-dec = ≈ᵛ-dec⇒≈ᵐ-dec ≈ᵛ-dec
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fixedHeightᵐ = IsFiniteHeightLattice.fixedHeight isFiniteHeightLatticeᵐ
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fixedHeightᵐ = IsFiniteHeightLattice.fixedHeight isFiniteHeightLatticeᵐ
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-- We now have our (state -> (variables -> value)) map.
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-- Define a couple of helpers to retrieve values from it. Specifically,
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-- since the State type is as specific as possible, it's always possible to
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-- retrieve the variable values at each state.
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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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variablesAt : State → StateVariables → VariableValues
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variablesAt s sv = proj₁ (locateᵐ {s} {sv} (states-in-Map s sv))
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-- build up the 'join' function, which follows from Exercise 4.26's
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-- build up the 'join' function, which follows from Exercise 4.26's
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--
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--
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-- L₁ → (A → L₂)
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-- L₁ → (A → L₂)
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@ -116,8 +130,15 @@ module WithProg (prog : Program) where
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renaming
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renaming
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( f' to joinAll
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( f' to joinAll
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; f'-Monotonic to joinAll-Mono
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; f'-Monotonic to joinAll-Mono
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; f'-k∈ks-≡ to joinAll-k∈ks-≡
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)
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)
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variablesAt-joinAll : ∀ (s : State) (sv : StateVariables) →
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variablesAt s (joinAll sv) ≡ joinForKey s sv
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variablesAt-joinAll s sv
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with (vs , s,vs∈usv) ← locateᵐ {s} {joinAll sv} (states-in-Map s (joinAll sv)) =
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joinAll-k∈ks-≡ {l = sv} (states-complete s) s,vs∈usv
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-- With 'join' in hand, we need to perform abstract evaluation.
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-- With 'join' in hand, we need to perform abstract evaluation.
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module WithEvaluator (eval : Expr → VariableValues → L)
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module WithEvaluator (eval : Expr → VariableValues → L)
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(eval-Mono : ∀ (e : Expr) → Monotonic _≼ᵛ_ _≼ˡ_ (eval e)) where
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(eval-Mono : ∀ (e : Expr) → Monotonic _≼ᵛ_ _≼ˡ_ (eval e)) where
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@ -131,12 +152,11 @@ module WithProg (prog : Program) where
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renaming
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renaming
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( f' to updateVariablesFromExpression
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( f' to updateVariablesFromExpression
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; f'-Monotonic to updateVariablesFromExpression-Mono
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; f'-Monotonic to updateVariablesFromExpression-Mono
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; f'-k∈ks-≡ to updateVariablesFromExpression-k∈ks-≡
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; f'-k∉ks-backward to updateVariablesFromExpression-k∉ks-backward
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)
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)
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public
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public
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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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-- The per-state update function makes use of the single-key setter,
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-- The per-state update function makes use of the single-key setter,
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-- updateVariablesFromExpression, for the case where the statement
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-- updateVariablesFromExpression, for the case where the statement
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-- is an assignment.
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-- is an assignment.
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@ -155,11 +175,7 @@ module WithProg (prog : Program) where
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updateVariablesForState : State → StateVariables → VariableValues
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updateVariablesForState : State → StateVariables → VariableValues
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updateVariablesForState s sv =
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updateVariablesForState s sv =
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let
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foldl (flip updateVariablesFromStmt) (variablesAt s sv) (code s)
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bss = code s
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(vs , s,vs∈sv) = locateᵐ {s} {sv} (states-in-Map s sv)
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in
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foldr updateVariablesFromStmt vs bss
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updateVariablesForState-Monoʳ : ∀ (s : State) → Monotonic _≼ᵐ_ _≼ᵛ_ (updateVariablesForState s)
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updateVariablesForState-Monoʳ : ∀ (s : State) → Monotonic _≼ᵐ_ _≼ᵛ_ (updateVariablesForState s)
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updateVariablesForState-Monoʳ s {sv₁} {sv₂} sv₁≼sv₂ =
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updateVariablesForState-Monoʳ s {sv₁} {sv₂} sv₁≼sv₂ =
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@ -169,14 +185,15 @@ module WithProg (prog : Program) where
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(vs₂ , s,vs₂∈sv₂) = locateᵐ {s} {sv₂} (states-in-Map s sv₂)
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(vs₂ , s,vs₂∈sv₂) = locateᵐ {s} {sv₂} (states-in-Map s sv₂)
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vs₁≼vs₂ = m₁≼m₂⇒m₁[k]ᵐ≼m₂[k]ᵐ sv₁ sv₂ sv₁≼sv₂ s,vs₁∈sv₁ s,vs₂∈sv₂
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vs₁≼vs₂ = m₁≼m₂⇒m₁[k]ᵐ≼m₂[k]ᵐ sv₁ sv₂ sv₁≼sv₂ s,vs₁∈sv₁ s,vs₂∈sv₂
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in
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in
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foldr-Mono' (IsLattice.joinSemilattice isLatticeᵛ) bss
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foldl-Mono' (IsLattice.joinSemilattice isLatticeᵛ) bss
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updateVariablesFromStmt updateVariablesFromStmt-Monoʳ
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(flip updateVariablesFromStmt) updateVariablesFromStmt-Monoʳ
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vs₁≼vs₂
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vs₁≼vs₂
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open StateVariablesFiniteMap.GeneralizedUpdate states isLatticeᵐ (λ x → x) (λ a₁≼a₂ → a₁≼a₂) updateVariablesForState updateVariablesForState-Monoʳ states
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open StateVariablesFiniteMap.GeneralizedUpdate states isLatticeᵐ (λ x → x) (λ a₁≼a₂ → a₁≼a₂) updateVariablesForState updateVariablesForState-Monoʳ states
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renaming
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renaming
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( f' to updateAll
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( f' to updateAll
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; f'-Monotonic to updateAll-Mono
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; f'-Monotonic to updateAll-Mono
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; f'-k∈ks-≡ to updateAll-k∈ks-≡
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)
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)
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-- Finally, the whole analysis consists of getting the 'join'
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-- Finally, the whole analysis consists of getting the 'join'
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@ -194,5 +211,62 @@ module WithProg (prog : Program) where
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-- The fixed point of the 'analyze' function is our final goal.
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-- The fixed point of the 'analyze' function is our final goal.
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open import Fixedpoint ≈ᵐ-dec isFiniteHeightLatticeᵐ analyze (λ {m₁} {m₂} m₁≼m₂ → analyze-Mono {m₁} {m₂} m₁≼m₂)
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open import Fixedpoint ≈ᵐ-dec isFiniteHeightLatticeᵐ analyze (λ {m₁} {m₂} m₁≼m₂ → analyze-Mono {m₁} {m₂} m₁≼m₂)
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using ()
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using ()
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renaming (aᶠ to result)
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renaming (aᶠ to result; aᶠ≈faᶠ to result≈analyze-result)
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public
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public
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variablesAt-updateAll : ∀ (s : State) (sv : StateVariables) →
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variablesAt s (updateAll sv) ≡ updateVariablesForState s sv
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variablesAt-updateAll s sv
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with (vs , s,vs∈usv) ← locateᵐ {s} {updateAll sv} (states-in-Map s (updateAll sv)) =
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updateAll-k∈ks-≡ {l = sv} (states-complete s) s,vs∈usv
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module WithInterpretation (latticeInterpretationˡ : LatticeInterpretation isLatticeˡ) where
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open LatticeInterpretation latticeInterpretationˡ
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using ()
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renaming (⟦_⟧ to ⟦_⟧ˡ; ⟦⟧-respects-≈ to ⟦⟧ˡ-respects-≈ˡ)
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⟦_⟧ᵛ : VariableValues → Env → Set
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⟦_⟧ᵛ vs ρ = ∀ {k l} → (k , l) ∈ᵛ vs → ∀ {v} → (k , v) Language.∈ ρ → ⟦ l ⟧ˡ v
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⟦⟧ᵛ-respects-≈ᵛ : ∀ {vs₁ vs₂ : VariableValues} → vs₁ ≈ᵛ vs₂ → ⟦ vs₁ ⟧ᵛ ⇒ ⟦ vs₂ ⟧ᵛ
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⟦⟧ᵛ-respects-≈ᵛ {m₁ , _} {m₂ , _}
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(m₁⊆m₂ , m₂⊆m₁) ρ ⟦vs₁⟧ρ {k} {l} k,l∈m₂ {v} k,v∈ρ =
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let
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(l' , (l≈l' , k,l'∈m₁)) = m₂⊆m₁ _ _ k,l∈m₂
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⟦l'⟧v = ⟦vs₁⟧ρ k,l'∈m₁ k,v∈ρ
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in
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⟦⟧ˡ-respects-≈ˡ (≈ˡ-sym l≈l') v ⟦l'⟧v
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InterpretationValid : Set
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InterpretationValid = ∀ {vs ρ e v} → ρ , e ⇒ᵉ v → ⟦ vs ⟧ᵛ ρ → ⟦ eval e vs ⟧ˡ v
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module WithValidity (interpretationValidˡ : InterpretationValid) where
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updateVariablesFromStmt-matches : ∀ {bs vs ρ₁ ρ₂} → ρ₁ , bs ⇒ᵇ ρ₂ → ⟦ vs ⟧ᵛ ρ₁ → ⟦ updateVariablesFromStmt bs vs ⟧ᵛ ρ₂
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updateVariablesFromStmt-matches {_} {vs} {ρ₁} {ρ₁} (⇒ᵇ-noop ρ₁) ⟦vs⟧ρ₁ = ⟦vs⟧ρ₁
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updateVariablesFromStmt-matches {_} {vs} {ρ₁} {_} (⇒ᵇ-← ρ₁ k e v ρ,e⇒v) ⟦vs⟧ρ₁ {k'} {l} k',l∈vs' {v'} k',v'∈ρ₂
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with k ≟ˢ k' | k',v'∈ρ₂
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... | yes refl | here _ v _
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rewrite updateVariablesFromExpression-k∈ks-≡ k e {l = vs} (Any.here refl) k',l∈vs' =
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interpretationValidˡ ρ,e⇒v ⟦vs⟧ρ₁
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... | yes k≡k' | there _ _ _ _ _ k'≢k _ = ⊥-elim (k'≢k (sym k≡k'))
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... | no k≢k' | here _ _ _ = ⊥-elim (k≢k' refl)
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... | no k≢k' | there _ _ _ _ _ _ k',v'∈ρ₁ =
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let
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k'∉[k] = (λ { (Any.here refl) → k≢k' refl })
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k',l∈vs = updateVariablesFromExpression-k∉ks-backward k e {l = vs} k'∉[k] k',l∈vs'
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in
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⟦vs⟧ρ₁ k',l∈vs k',v'∈ρ₁
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updateVariablesFromStmt-fold-matches : ∀ {bss vs ρ₁ ρ₂} → ρ₁ , bss ⇒ᵇˢ ρ₂ → ⟦ vs ⟧ᵛ ρ₁ → ⟦ foldl (flip updateVariablesFromStmt) vs bss ⟧ᵛ ρ₂
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updateVariablesFromStmt-fold-matches [] ⟦vs⟧ρ = ⟦vs⟧ρ
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updateVariablesFromStmt-fold-matches {bs ∷ bss'} {vs} {ρ₁} {ρ₂} (ρ₁,bs⇒ρ ∷ ρ,bss'⇒ρ₂) ⟦vs⟧ρ₁ =
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updateVariablesFromStmt-fold-matches {bss'} {updateVariablesFromStmt bs vs} ρ,bss'⇒ρ₂ (updateVariablesFromStmt-matches ρ₁,bs⇒ρ ⟦vs⟧ρ₁)
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updateVariablesForState-matches : ∀ {s sv ρ₁ ρ₂} → ρ₁ , (code s) ⇒ᵇˢ ρ₂ → ⟦ variablesAt s sv ⟧ᵛ ρ₁ → ⟦ updateVariablesForState s sv ⟧ᵛ ρ₂
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updateVariablesForState-matches = updateVariablesFromStmt-fold-matches
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updateAll-matches : ∀ {s sv ρ₁ ρ₂} → ρ₁ , (code s) ⇒ᵇˢ ρ₂ → ⟦ variablesAt s sv ⟧ᵛ ρ₁ → ⟦ variablesAt s (updateAll sv) ⟧ᵛ ρ₂
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updateAll-matches {s} {sv} ρ₁,bss⇒ρ₂ ⟦vs⟧ρ₁ rewrite variablesAt-updateAll s sv =
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updateVariablesForState-matches {s} {sv} ρ₁,bss⇒ρ₂ ⟦vs⟧ρ₁
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19
Lattice.agda
19
Lattice.agda
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@ -137,7 +137,7 @@ module _ {a b} {A : Set a} {B : Set b}
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const-Mono : ∀ (x : B) → Monotonic _≼₁_ _≼₂_ (λ _ → x)
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const-Mono : ∀ (x : B) → Monotonic _≼₁_ _≼₂_ (λ _ → x)
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const-Mono x _ = ⊔₂-idemp x
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const-Mono x _ = ⊔₂-idemp x
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open import Data.List as List using (List; foldr; _∷_)
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open import Data.List as List using (List; foldr; foldl; _∷_)
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open import Utils using (Pairwise; _∷_)
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open import Utils using (Pairwise; _∷_)
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foldr-Mono : ∀ (l₁ l₂ : List A) (f : A → B → B) (b₁ b₂ : B) →
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foldr-Mono : ∀ (l₁ l₂ : List A) (f : A → B → B) (b₁ b₂ : B) →
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@ -150,13 +150,22 @@ module _ {a b} {A : Set a} {B : Set b}
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≼₂-trans (f-Mono₁ (foldr f b₁ xs) x≼y)
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≼₂-trans (f-Mono₁ (foldr f b₁ xs) x≼y)
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(f-Mono₂ y (foldr-Mono xs ys f b₁ b₂ xs≼ys b₁≼b₂ f-Mono₁ f-Mono₂))
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(f-Mono₂ y (foldr-Mono xs ys f b₁ b₂ xs≼ys b₁≼b₂ f-Mono₁ f-Mono₂))
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foldl-Mono : ∀ (l₁ l₂ : List A) (f : B → A → B) (b₁ b₂ : B) →
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Pairwise _≼₁_ l₁ l₂ → b₁ ≼₂ b₂ →
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(∀ a → Monotonic _≼₂_ _≼₂_ (λ b → f b a)) →
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(∀ b → Monotonic _≼₁_ _≼₂_ (f b)) →
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foldl f b₁ l₁ ≼₂ foldl f b₂ l₂
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foldl-Mono List.[] List.[] f b₁ b₂ _ b₁≼b₂ _ _ = b₁≼b₂
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foldl-Mono (x ∷ xs) (y ∷ ys) f b₁ b₂ (x≼y ∷ xs≼ys) b₁≼b₂ f-Mono₁ f-Mono₂ =
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foldl-Mono xs ys f (f b₁ x) (f b₂ y) xs≼ys (≼₂-trans (f-Mono₁ x b₁≼b₂) (f-Mono₂ b₂ x≼y)) f-Mono₁ f-Mono₂
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module _ {a b} {A : Set a} {B : Set b}
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module _ {a b} {A : Set a} {B : Set b}
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{_≈₂_ : B → B → Set b} {_⊔₂_ : B → B → B}
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{_≈₂_ : B → B → Set b} {_⊔₂_ : B → B → B}
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(lB : IsSemilattice B _≈₂_ _⊔₂_) where
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(lB : IsSemilattice B _≈₂_ _⊔₂_) where
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open IsSemilattice lB using () renaming (_≼_ to _≼₂_; ⊔-idemp to ⊔₂-idemp; ≼-trans to ≼₂-trans)
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open IsSemilattice lB using () renaming (_≼_ to _≼₂_; ⊔-idemp to ⊔₂-idemp; ≼-trans to ≼₂-trans)
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open import Data.List as List using (List; foldr; _∷_)
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open import Data.List as List using (List; foldr; foldl; _∷_)
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open import Utils using (Pairwise; _∷_)
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open import Utils using (Pairwise; _∷_)
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foldr-Mono' : ∀ (l : List A) (f : A → B → B) →
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foldr-Mono' : ∀ (l : List A) (f : A → B → B) →
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@ -165,6 +174,12 @@ module _ {a b} {A : Set a} {B : Set b}
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foldr-Mono' List.[] f _ b₁≼b₂ = b₁≼b₂
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foldr-Mono' List.[] f _ b₁≼b₂ = b₁≼b₂
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foldr-Mono' (x ∷ xs) f f-Mono₂ b₁≼b₂ = f-Mono₂ x (foldr-Mono' xs f f-Mono₂ b₁≼b₂)
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foldr-Mono' (x ∷ xs) f f-Mono₂ b₁≼b₂ = f-Mono₂ x (foldr-Mono' xs f f-Mono₂ b₁≼b₂)
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foldl-Mono' : ∀ (l : List A) (f : B → A → B) →
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(∀ b → Monotonic _≼₂_ _≼₂_ (λ a → f a b)) →
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Monotonic _≼₂_ _≼₂_ (λ b → foldl f b l)
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foldl-Mono' List.[] f _ b₁≼b₂ = b₁≼b₂
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foldl-Mono' (x ∷ xs) f f-Mono₁ b₁≼b₂ = foldl-Mono' xs f f-Mono₁ (f-Mono₁ x b₁≼b₂)
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|
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record IsLattice {a} (A : Set a)
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record IsLattice {a} (A : Set a)
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(_≈_ : 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)
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|
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@ -35,6 +35,11 @@ open import Lattice.Map ≡-dec-A lB as Map
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; keys to keysᵐ
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; keys to keysᵐ
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; _updating_via_ to _updatingᵐ_via_
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; _updating_via_ to _updatingᵐ_via_
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; updating-via-keys-≡ to updatingᵐ-via-keys-≡
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; updating-via-keys-≡ to updatingᵐ-via-keys-≡
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||||||
|
; updating-via-k∈ks to updatingᵐ-via-k∈ks
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||||||
|
; updating-via-k∈ks-≡ to updatingᵐ-via-k∈ks-≡
|
||||||
|
; updating-via-∈k-forward to updatingᵐ-via-∈k-forward
|
||||||
|
; updating-via-k∉ks-forward to updatingᵐ-via-k∉ks-forward
|
||||||
|
; updating-via-k∉ks-backward to updatingᵐ-via-k∉ks-backward
|
||||||
; f'-Monotonic to f'-Monotonicᵐ
|
; f'-Monotonic to f'-Monotonicᵐ
|
||||||
; _≼_ to _≼ᵐ_
|
; _≼_ to _≼ᵐ_
|
||||||
; ∈k-dec to ∈k-decᵐ
|
; ∈k-dec to ∈k-decᵐ
|
||||||
|
@ -83,6 +88,8 @@ module WithKeys (ks : List A) where
|
||||||
_∈k_ : A → FiniteMap → Set a
|
_∈k_ : A → FiniteMap → Set a
|
||||||
_∈k_ k (m₁ , _) = k ∈ˡ (keysᵐ m₁)
|
_∈k_ k (m₁ , _) = k ∈ˡ (keysᵐ m₁)
|
||||||
|
|
||||||
|
open Map using (forget) public
|
||||||
|
|
||||||
∈k-dec = ∈k-decᵐ
|
∈k-dec = ∈k-decᵐ
|
||||||
|
|
||||||
locate : ∀ {k : A} {fm : FiniteMap} → k ∈k fm → Σ B (λ v → (k , v) ∈ fm)
|
locate : ∀ {k : A} {fm : FiniteMap} → k ∈k fm → Σ B (λ v → (k , v) ∈ fm)
|
||||||
|
@ -171,6 +178,21 @@ module WithKeys (ks : List A) where
|
||||||
f'-Monotonic : Monotonic _≼ˡ_ _≼_ f'
|
f'-Monotonic : Monotonic _≼ˡ_ _≼_ f'
|
||||||
f'-Monotonic {l₁} {l₂} l₁≼l₂ = f'-Monotonicᵐ lL (proj₁ ∘ f) f-Monotonic g g-Monotonicʳ ks l₁≼l₂
|
f'-Monotonic {l₁} {l₂} l₁≼l₂ = f'-Monotonicᵐ lL (proj₁ ∘ f) f-Monotonic g g-Monotonicʳ ks l₁≼l₂
|
||||||
|
|
||||||
|
f'-∈k-forward : ∀ {k l} → k ∈k (f l) → k ∈k (f' l)
|
||||||
|
f'-∈k-forward {k} {l} = updatingᵐ-via-∈k-forward (proj₁ (f l)) ks (updater l)
|
||||||
|
|
||||||
|
f'-k∈ks : ∀ {k l} → k ∈ˡ ks → k ∈k (f' l) → (k , updater l k) ∈ (f' l)
|
||||||
|
f'-k∈ks {k} {l} = updatingᵐ-via-k∈ks (proj₁ (f l)) (updater l)
|
||||||
|
|
||||||
|
f'-k∈ks-≡ : ∀ {k v l} → k ∈ˡ ks → (k , v) ∈ (f' l) → v ≡ updater l k
|
||||||
|
f'-k∈ks-≡ {k} {v} {l} = updatingᵐ-via-k∈ks-≡ (proj₁ (f l)) (updater l)
|
||||||
|
|
||||||
|
f'-k∉ks-forward : ∀ {k v l} → ¬ k ∈ˡ ks → (k , v) ∈ (f l) → (k , v) ∈ (f' l)
|
||||||
|
f'-k∉ks-forward {k} {v} {l} = updatingᵐ-via-k∉ks-forward (proj₁ (f l)) (updater l)
|
||||||
|
|
||||||
|
f'-k∉ks-backward : ∀ {k v l} → ¬ k ∈ˡ ks → (k , v) ∈ (f' l) → (k , v) ∈ (f l)
|
||||||
|
f'-k∉ks-backward {k} {v} {l} = updatingᵐ-via-k∉ks-backward (proj₁ (f l)) (updater l)
|
||||||
|
|
||||||
all-equal-keys : ∀ (fm₁ fm₂ : FiniteMap) → (Map.keys (proj₁ fm₁) ≡ Map.keys (proj₁ fm₂))
|
all-equal-keys : ∀ (fm₁ fm₂ : FiniteMap) → (Map.keys (proj₁ fm₁) ≡ Map.keys (proj₁ fm₂))
|
||||||
all-equal-keys (fm₁ , km₁≡ks) (fm₂ , km₂≡ks) = trans km₁≡ks (sym km₂≡ks)
|
all-equal-keys (fm₁ , km₁≡ks) (fm₂ , km₂≡ks) = trans km₁≡ks (sym km₂≡ks)
|
||||||
|
|
||||||
|
|
|
@ -32,7 +32,7 @@ open import Isomorphism using (IsInverseˡ; IsInverseʳ)
|
||||||
open import Lattice.Map ≡-dec-A lB
|
open import Lattice.Map ≡-dec-A lB
|
||||||
using
|
using
|
||||||
( subset-impl
|
( subset-impl
|
||||||
; locate; forget
|
; locate
|
||||||
; Map-functional
|
; Map-functional
|
||||||
; Expr-Provenance
|
; Expr-Provenance
|
||||||
; Expr-Provenance-≡
|
; Expr-Provenance-≡
|
||||||
|
|
Loading…
Reference in New Issue
Block a user