module Language.Graphs where open import Language.Base using (Expr; Stmt; BasicStmt; ⟨_⟩; _then_; if_then_else_; while_repeat_) open import Data.Fin as Fin using (Fin; suc; zero) open import Data.Fin.Properties as FinProp using (suc-injective) open import Data.List as List using (List; []; _∷_) open import Data.List.Membership.Propositional as ListMem using () open import Data.List.Membership.Propositional.Properties as ListMemProp using () open import Data.Nat as Nat using (ℕ; suc) open import Data.Nat.Properties using (+-assoc; +-comm) open import Data.Product using (_×_; Σ; _,_) open import Data.Vec using (Vec; []; _∷_; lookup; cast; _++_) open import Data.Vec.Properties using (cast-is-id; ++-assoc; lookup-++ˡ; cast-sym; ++-identityʳ; lookup-++ʳ) open import Relation.Binary.PropositionalEquality as Eq using (_≡_; sym; refl; subst; trans) open import Lattice open import Utils using (x∈xs⇒fx∈fxs; _⊗_; _,_; ∈-cartesianProduct) record Graph : Set where constructor MkGraph field size : ℕ Index : Set Index = Fin size Edge : Set Edge = Index × Index field nodes : Vec (List BasicStmt) size edges : List Edge inputs : List Index outputs : List Index _↑ˡ_ : ∀ {n} → (Fin n × Fin n) → ∀ m → (Fin (n Nat.+ m) × Fin (n Nat.+ m)) _↑ˡ_ (idx₁ , idx₂) m = (idx₁ Fin.↑ˡ m , idx₂ Fin.↑ˡ m) _↑ʳ_ : ∀ {m} n → (Fin m × Fin m) → Fin (n Nat.+ m) × Fin (n Nat.+ m) _↑ʳ_ n (idx₁ , idx₂) = (n Fin.↑ʳ idx₁ , n Fin.↑ʳ idx₂) _↑ˡⁱ_ : ∀ {n} → List (Fin n) → ∀ m → List (Fin (n Nat.+ m)) _↑ˡⁱ_ l m = List.map (Fin._↑ˡ m) l _↑ʳⁱ_ : ∀ {m} n → List (Fin m) → List (Fin (n Nat.+ m)) _↑ʳⁱ_ n l = List.map (n Fin.↑ʳ_) l _↑ˡᵉ_ : ∀ {n} → List (Fin n × Fin n) → ∀ m → List (Fin (n Nat.+ m) × Fin (n Nat.+ m)) _↑ˡᵉ_ l m = List.map (_↑ˡ m) l _↑ʳᵉ_ : ∀ {m} n → List (Fin m × Fin m) → List (Fin (n Nat.+ m) × Fin (n Nat.+ m)) _↑ʳᵉ_ n l = List.map (n ↑ʳ_) l infixl 5 _∙_ _∙_ : Graph → Graph → Graph _∙_ g₁ g₂ = record { size = Graph.size g₁ Nat.+ Graph.size g₂ ; nodes = Graph.nodes g₁ ++ Graph.nodes g₂ ; edges = (Graph.edges g₁ ↑ˡᵉ Graph.size g₂) List.++ (Graph.size g₁ ↑ʳᵉ Graph.edges g₂) ; inputs = (Graph.inputs g₁ ↑ˡⁱ Graph.size g₂) List.++ (Graph.size g₁ ↑ʳⁱ Graph.inputs g₂) ; outputs = (Graph.outputs g₁ ↑ˡⁱ Graph.size g₂) List.++ (Graph.size g₁ ↑ʳⁱ Graph.outputs g₂) } infixl 5 _↦_ _↦_ : Graph → Graph → Graph _↦_ g₁ g₂ = record { size = Graph.size g₁ Nat.+ Graph.size g₂ ; nodes = Graph.nodes g₁ ++ Graph.nodes g₂ ; edges = (Graph.edges g₁ ↑ˡᵉ Graph.size g₂) List.++ (Graph.size g₁ ↑ʳᵉ Graph.edges g₂) List.++ (List.cartesianProduct (Graph.outputs g₁ ↑ˡⁱ Graph.size g₂) (Graph.size g₁ ↑ʳⁱ Graph.inputs g₂)) ; inputs = Graph.inputs g₁ ↑ˡⁱ Graph.size g₂ ; outputs = Graph.size g₁ ↑ʳⁱ Graph.outputs g₂ } loop : Graph → Graph loop g = record { size = Graph.size g ; nodes = Graph.nodes g ; edges = Graph.edges g List.++ List.cartesianProduct (Graph.outputs g) (Graph.inputs g) ; inputs = Graph.inputs g ; outputs = Graph.outputs g } _[_] : ∀ (g : Graph) → Graph.Index g → List BasicStmt _[_] g idx = lookup (Graph.nodes g) idx singleton : List BasicStmt → Graph singleton bss = record { size = 1 ; nodes = bss ∷ [] ; edges = [] ; inputs = zero ∷ [] ; outputs = zero ∷ [] } buildCfg : Stmt → Graph buildCfg ⟨ bs₁ ⟩ = singleton (bs₁ ∷ []) buildCfg (s₁ then s₂) = buildCfg s₁ ↦ buildCfg s₂ buildCfg (if _ then s₁ else s₂) = singleton [] ↦ (buildCfg s₁ ∙ buildCfg s₂) ↦ singleton [] buildCfg (while _ repeat s) = loop (buildCfg s ↦ singleton [])