188 lines
7.9 KiB
Agda
188 lines
7.9 KiB
Agda
module Language.Graphs where
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open import Language.Base
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open import Data.Fin as Fin using (Fin; suc; zero; _↑ˡ_; _↑ʳ_)
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open import Data.Fin.Properties as FinProp using (suc-injective)
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open import Data.List as List using (List; []; _∷_)
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open import Data.List.Membership.Propositional as ListMem using ()
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open import Data.List.Membership.Propositional.Properties as ListMemProp using ()
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open import Data.Nat as Nat using (ℕ; suc)
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open import Data.Nat.Properties using (+-assoc; +-comm)
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open import Data.Product using (_×_; Σ; _,_)
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open import Data.Vec using (Vec; []; _∷_; lookup; cast; _++_)
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open import Data.Vec.Properties using (cast-is-id; ++-assoc; lookup-++ˡ; cast-sym; ++-identityʳ; lookup-++ʳ)
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open import Relation.Binary.PropositionalEquality as Eq using (_≡_; sym; refl; subst; trans)
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open import Lattice
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open import Utils using (x∈xs⇒fx∈fxs; _⊗_; _,_)
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record Graph : Set where
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constructor MkGraph
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field
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size : ℕ
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Index : Set
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Index = Fin size
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Edge : Set
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Edge = Index × Index
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field
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nodes : Vec (List BasicStmt) size
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edges : List Edge
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empty : Graph
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empty = record
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{ size = 0
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; nodes = []
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; edges = []
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}
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↑ˡ-Edge : ∀ {n} → (Fin n × Fin n) → ∀ m → (Fin (n Nat.+ m) × Fin (n Nat.+ m))
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↑ˡ-Edge (idx₁ , idx₂) m = (idx₁ ↑ˡ m , idx₂ ↑ˡ m)
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_[_] : ∀ (g : Graph) → Graph.Index g → List BasicStmt
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_[_] g idx = lookup (Graph.nodes g) idx
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record _⊆_ (g₁ g₂ : Graph) : Set where
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constructor Mk-⊆
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field
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n : ℕ
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sg₂≡sg₁+n : Graph.size g₂ ≡ Graph.size g₁ Nat.+ n
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newNodes : Vec (List BasicStmt) n
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nsg₂≡nsg₁++newNodes : cast sg₂≡sg₁+n (Graph.nodes g₂) ≡ Graph.nodes g₁ ++ newNodes
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e∈g₁⇒e∈g₂ : ∀ {e : Graph.Edge g₁} →
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e ListMem.∈ (Graph.edges g₁) →
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(↑ˡ-Edge e n) ListMem.∈ (subst (λ m → List (Fin m × Fin m)) sg₂≡sg₁+n (Graph.edges g₂))
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private
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castᵉ : ∀ {n m : ℕ} .(p : n ≡ m) → (Fin n × Fin n) → (Fin m × Fin m)
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castᵉ p (idx₁ , idx₂) = (Fin.cast p idx₁ , Fin.cast p idx₂)
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↑ˡ-assoc : ∀ {s n₁ n₂} (f : Fin s) (p : s Nat.+ (n₁ Nat.+ n₂) ≡ s Nat.+ n₁ Nat.+ n₂) →
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f ↑ˡ n₁ ↑ˡ n₂ ≡ Fin.cast p (f ↑ˡ (n₁ Nat.+ n₂))
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↑ˡ-assoc zero p = refl
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↑ˡ-assoc {suc s'} {n₁} {n₂} (suc f') p rewrite ↑ˡ-assoc f' (sym (+-assoc s' n₁ n₂)) = refl
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↑ˡ-Edge-assoc : ∀ {s n₁ n₂} (e : Fin s × Fin s) (p : s Nat.+ (n₁ Nat.+ n₂) ≡ s Nat.+ n₁ Nat.+ n₂) →
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↑ˡ-Edge (↑ˡ-Edge e n₁) n₂ ≡ castᵉ p (↑ˡ-Edge e (n₁ Nat.+ n₂))
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↑ˡ-Edge-assoc (idx₁ , idx₂) p
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rewrite ↑ˡ-assoc idx₁ p
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rewrite ↑ˡ-assoc idx₂ p = refl
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↑ˡ-identityʳ : ∀ {s} (f : Fin s) (p : s Nat.+ 0 ≡ s) →
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f ≡ Fin.cast p (f ↑ˡ 0)
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↑ˡ-identityʳ zero p = refl
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↑ˡ-identityʳ {suc s'} (suc f') p rewrite sym (↑ˡ-identityʳ f' (+-comm s' 0)) = refl
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↑ˡ-Edge-identityʳ : ∀ {s} (e : Fin s × Fin s) (p : s Nat.+ 0 ≡ s) →
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e ≡ castᵉ p (↑ˡ-Edge e 0)
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↑ˡ-Edge-identityʳ (idx₁ , idx₂) p
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rewrite sym (↑ˡ-identityʳ idx₁ p)
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rewrite sym (↑ˡ-identityʳ idx₂ p) = refl
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cast∈⇒∈subst : ∀ {n m : ℕ} (p : n ≡ m) (q : m ≡ n)
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(e : Fin n × Fin n) (es : List (Fin m × Fin m)) →
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castᵉ p e ListMem.∈ es →
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e ListMem.∈ subst (λ m → List (Fin m × Fin m)) q es
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cast∈⇒∈subst refl refl (idx₁ , idx₂) es e∈es
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rewrite FinProp.cast-is-id refl idx₁
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rewrite FinProp.cast-is-id refl idx₂ = e∈es
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⊆-trans : ∀ {g₁ g₂ g₃ : Graph} → g₁ ⊆ g₂ → g₂ ⊆ g₃ → g₁ ⊆ g₃
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⊆-trans {MkGraph s₁ ns₁ es₁} {MkGraph s₂ ns₂ es₂} {MkGraph s₃ ns₃ es₃}
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(Mk-⊆ n₁ p₁@refl newNodes₁ nsg₂≡nsg₁++newNodes₁ e∈g₁⇒e∈g₂)
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(Mk-⊆ n₂ p₂@refl newNodes₂ nsg₃≡nsg₂++newNodes₂ e∈g₂⇒e∈g₃)
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rewrite cast-is-id refl ns₂
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rewrite cast-is-id refl ns₃
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with refl ← nsg₂≡nsg₁++newNodes₁
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with refl ← nsg₃≡nsg₂++newNodes₂ =
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record
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{ n = n₁ Nat.+ n₂
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; sg₂≡sg₁+n = +-assoc s₁ n₁ n₂
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; newNodes = newNodes₁ ++ newNodes₂
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; nsg₂≡nsg₁++newNodes = ++-assoc (+-assoc s₁ n₁ n₂) ns₁ newNodes₁ newNodes₂
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; e∈g₁⇒e∈g₂ = λ {e} e∈g₁ →
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cast∈⇒∈subst (sym (+-assoc s₁ n₁ n₂)) (+-assoc s₁ n₁ n₂) _ _
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(subst (λ e' → e' ListMem.∈ es₃)
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(↑ˡ-Edge-assoc e (sym (+-assoc s₁ n₁ n₂)))
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(e∈g₂⇒e∈g₃ (e∈g₁⇒e∈g₂ e∈g₁)))
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}
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open import MonotonicState _⊆_ ⊆-trans renaming (MonotonicState to MonotonicGraphFunction)
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instance
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IndexRelaxable : Relaxable Graph.Index
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IndexRelaxable = record
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{ relax = λ { (Mk-⊆ n refl _ _ _) idx → idx ↑ˡ n }
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}
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EdgeRelaxable : Relaxable Graph.Edge
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EdgeRelaxable = record
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{ relax = λ g₁⊆g₂ (idx₁ , idx₂) →
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( Relaxable.relax IndexRelaxable g₁⊆g₂ idx₁
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, Relaxable.relax IndexRelaxable g₁⊆g₂ idx₂
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)
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}
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open Relaxable {{...}}
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pushBasicBlock : List BasicStmt → MonotonicGraphFunction Graph.Index
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pushBasicBlock bss g =
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( record
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{ size = Graph.size g Nat.+ 1
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; nodes = Graph.nodes g ++ (bss ∷ [])
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; edges = List.map (λ e → ↑ˡ-Edge e 1) (Graph.edges g)
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}
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, ( Graph.size g ↑ʳ zero
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, record
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{ n = 1
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; sg₂≡sg₁+n = refl
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; newNodes = (bss ∷ [])
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; nsg₂≡nsg₁++newNodes = cast-is-id refl _
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; e∈g₁⇒e∈g₂ = λ e∈g₁ → x∈xs⇒fx∈fxs (λ e → ↑ˡ-Edge e 1) e∈g₁
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}
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)
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)
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pushEmptyBlock : MonotonicGraphFunction Graph.Index
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pushEmptyBlock = pushBasicBlock []
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addEdges : ∀ (g : Graph) → List (Graph.Edge g) → Σ Graph (λ g' → g ⊆ g')
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addEdges (MkGraph s ns es) es' =
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( record
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{ size = s
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; nodes = ns
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; edges = es' List.++ es
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}
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, record
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{ n = 0
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; sg₂≡sg₁+n = +-comm 0 s
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; newNodes = []
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; nsg₂≡nsg₁++newNodes = cast-sym _ (++-identityʳ (+-comm s 0) ns)
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; e∈g₁⇒e∈g₂ = λ {e} e∈es →
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cast∈⇒∈subst (+-comm s 0) (+-comm 0 s) _ _
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(subst (λ e' → e' ListMem.∈ _)
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(↑ˡ-Edge-identityʳ e (+-comm s 0))
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(ListMemProp.∈-++⁺ʳ es' e∈es))
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}
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)
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buildCfg : Stmt → MonotonicGraphFunction (Graph.Index ⊗ Graph.Index)
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buildCfg ⟨ bs₁ ⟩ = pushBasicBlock (bs₁ ∷ []) map (λ g idx → (idx , idx))
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buildCfg (s₁ then s₂) =
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(buildCfg s₁ ⟨⊗⟩ buildCfg s₂)
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update (λ { g ((idx₁ , idx₂) , (idx₃ , idx₄)) → addEdges g ((idx₂ , idx₃) ∷ []) })
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map (λ { g ((idx₁ , idx₂) , (idx₃ , idx₄)) → (idx₁ , idx₄) })
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buildCfg (if _ then s₁ else s₂) =
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(buildCfg s₁ ⟨⊗⟩ buildCfg s₂ ⟨⊗⟩ pushEmptyBlock ⟨⊗⟩ pushEmptyBlock)
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update (λ { g ((idx₁ , idx₂) , (idx₃ , idx₄) , idx , idx') →
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addEdges g ((idx , idx₁) ∷ (idx , idx₃) ∷ (idx₂ , idx') ∷ (idx₄ , idx') ∷ []) })
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map (λ { g ((idx₁ , idx₂) , (idx₃ , idx₄) , idx , idx') → (idx , idx') })
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buildCfg (while _ repeat s) =
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(buildCfg s ⟨⊗⟩ pushEmptyBlock ⟨⊗⟩ pushEmptyBlock)
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update (λ { g ((idx₁ , idx₂) , idx , idx') →
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addEdges g ((idx , idx') ∷ (idx , idx₁) ∷ (idx₂ , idx) ∷ []) })
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map (λ { g ((idx₁ , idx₂) , idx , idx') → (idx , idx') })
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