(* need this or the Haskell extraction fails *) Set Printing Width 1300000. Require Import Coq.Lists.List. Require Import Coq.Strings.Ascii. Require Import Coq.Strings.String. Require Import Preamble. Require Import General. Require Import NaturalDeduction. Require Import NaturalDeductionToLatex. Require Import HaskKinds. Require Import HaskLiteralsAndTyCons. Require Import HaskCoreVars. Require Import HaskCoreTypes. Require Import HaskCore. Require Import HaskWeakVars. Require Import HaskWeakTypes. Require Import HaskWeak. Require Import HaskStrongTypes. Require Import HaskStrong. Require Import HaskProof. Require Import HaskCoreToWeak. Require Import HaskWeakToStrong. Require Import HaskStrongToProof. (*Require Import HaskProofToStrong.*) Require Import HaskProofToLatex. Require Import HaskStrongToWeak. Require Import HaskWeakToCore. Open Scope string_scope. Extraction Language Haskell. (* I try to reuse Haskell types mostly to get the "deriving Show" aspect *) Extract Inductive option => "Prelude.Maybe" [ "Prelude.Just" "Prelude.Nothing" ]. Extract Inductive list => "([])" [ "([])" "(:)" ]. (*Extract Inductive vec => "([])" [ "([])" "(:)" ].*) (*Extract Inductive Tree => "([])" [ "([])" "(:)" ].*) Extract Inlined Constant map => "Prelude.map". Extract Inductive string => "Prelude.String" [ "([])" "(:)" ]. Extract Inductive prod => "(,)" [ "(,)" ]. Extract Inductive sum => "Prelude.Either" [ "Prelude.Left" "Prelude.Right" ]. Extract Inductive sumbool => "Prelude.Bool" [ "Prelude.True" "Prelude.False" ]. Extract Inductive bool => "Prelude.Bool" [ "Prelude.True" "Prelude.False" ]. Extract Inductive unit => "()" [ "()" ]. Extract Inlined Constant string_dec => "(==)". Extract Inlined Constant ascii_dec => "(==)". Extract Inductive string => "Prelude.String" [ "[]" "(:)" ]. (* adapted from ExtrOcamlString.v *) Extract Inductive ascii => "Prelude.Char" [ "bin2ascii" ] "bin2ascii'". Extract Constant zero => "'\000'". Extract Constant one => "'\001'". Extract Constant shift => "shiftAscii". Unset Extraction Optimize. Unset Extraction AutoInline. Variable Name : Type. Extract Inlined Constant Name => "Name.Name". Variable mkSystemName : Unique -> string -> nat -> Name. Extract Inlined Constant mkSystemName => "(\u s d -> Name.mkSystemName u (OccName.mkOccName (OccName.varNameDepth (nat2int d)) s))". Variable mkTyVar : Name -> Kind -> CoreVar. Extract Inlined Constant mkTyVar => "(\n k -> Var.mkTyVar n (kindToCoreKind k))". Variable mkCoVar : Name -> CoreType -> CoreType -> CoreVar. Extract Inlined Constant mkCoVar => "(\n t1 t2 -> Var.mkCoVar n (Coercion.mkCoKind t1 t2))". Variable mkExVar : Name -> CoreType -> CoreVar. Extract Inlined Constant mkExVar => "Id.mkLocalId". Section core2proof. Context (ce:@CoreExpr CoreVar). Definition Γ : TypeEnv := nil. Definition Δ : CoercionEnv Γ := nil. Definition φ : TyVarResolver Γ := fun cv => Error ("unbound tyvar: " +++ (cv:CoreVar)). (*fun tv => error ("tried to get the representative of an unbound tyvar:" +++ (getCoreVarOccString tv)).*) Definition ψ : CoVarResolver Γ Δ := fun cv => Error ("tried to get the representative of an unbound covar!" (*+++ (getTypeVarOccString cv)*)). (* We need to be able to resolve unbound exprvars, but we can be sure their types will have no * free tyvars in them *) Definition ξ (cv:CoreVar) : LeveledHaskType Γ ★ := match coreVarToWeakVar cv with | WExprVar wev => match weakTypeToTypeOfKind φ wev ★ with | Error s => Prelude_error ("Error in top-level xi: " +++ s) | OK t => t @@ nil end | WTypeVar _ => Prelude_error "top-level xi got a type variable" | WCoerVar _ => Prelude_error "top-level xi got a coercion variable" end. (* core-to-string (-dcoqpass) *) Definition header : string := "\documentclass[9pt]{article}"+++eol+++ "\usepackage{amsmath}"+++eol+++ "\usepackage{amssymb}"+++eol+++ "\usepackage{proof}"+++eol+++ "\usepackage{mathpartir} % http://cristal.inria.fr/~remy/latex/"+++eol+++ "\usepackage{trfrac} % http://www.utdallas.edu/~hamlen/trfrac.sty"+++eol+++ "\def\code#1#2{\Box_{#1} #2}"+++eol+++ "\usepackage[paperwidth=200in,centering]{geometry}"+++eol+++ "\usepackage[displaymath,tightpage,active]{preview}"+++eol+++ "\begin{document}"+++eol+++ "\begin{preview}"+++eol. Definition footer : string := eol+++"\end{preview}"+++ eol+++"\end{document}"+++ eol. Definition coreToStringExpr' (ce:@CoreExpr CoreVar) : ???string := addErrorMessage ("input CoreSyn: " +++ ce) (addErrorMessage ("input CoreType: " +++ coreTypeOfCoreExpr ce) ( coreExprToWeakExpr ce >>= fun we => addErrorMessage ("WeakExpr: " +++ we) ((addErrorMessage ("CoreType of WeakExpr: " +++ coreTypeOfCoreExpr (weakExprToCoreExpr we)) ((weakTypeOfWeakExpr we) >>= fun t => (addErrorMessage ("WeakType: " +++ t) ((weakTypeToTypeOfKind φ t ★) >>= fun τ => addErrorMessage ("HaskType: " +++ τ) ((weakExprToStrongExpr Γ Δ φ ψ ξ (fun _ => true) τ nil we) >>= fun e => OK (eol+++"$$"+++ nd_ml_toLatex (@expr2proof _ _ _ _ _ _ e)+++"$$"+++eol) )))))))). Definition coreToStringExpr (ce:@CoreExpr CoreVar) : string := match coreToStringExpr' ce with | OK x => x | Error s => Prelude_error s end. Definition coreToStringBind (binds:@CoreBind CoreVar) : string := match binds with | CoreNonRec _ e => coreToStringExpr e | CoreRec lbe => fold_left (fun x y => x+++eol+++eol+++y) (map (fun x => coreToStringExpr (snd x)) lbe) "" end. Definition coqPassCoreToString (lbinds:list (@CoreBind CoreVar)) : string := header +++ (fold_left (fun x y => x+++eol+++eol+++y) (map coreToStringBind lbinds) "") +++ footer. (* core-to-core (-fcoqpass) *) Section CoreToCore. Definition mkWeakTypeVar (u:Unique)(k:Kind) : WeakTypeVar := weakTypeVar (mkTyVar (mkSystemName u "tv" O) k) k. Definition mkWeakCoerVar (u:Unique)(k:Kind)(t1 t2:WeakType) : WeakCoerVar := weakCoerVar (mkCoVar (mkSystemName u "cv" O) (weakTypeToCoreType t1) (weakTypeToCoreType t2)) k t1 t2. Definition mkWeakExprVar (u:Unique)(t:WeakType) : WeakExprVar := weakExprVar (mkExVar (mkSystemName u "ev" O) (weakTypeToCoreType t)) t. Context (hetmet_brak : WeakExprVar). Context (hetmet_esc : WeakExprVar). Context (uniqueSupply : UniqSupply). Definition coreToCoreExpr' (ce:@CoreExpr CoreVar) : ???(@CoreExpr CoreVar) := addErrorMessage ("input CoreSyn: " +++ ce) (addErrorMessage ("input CoreType: " +++ coreTypeOfCoreExpr ce) ( coreExprToWeakExpr ce >>= fun we => addErrorMessage ("WeakExpr: " +++ we) ((addErrorMessage ("CoreType of WeakExpr: " +++ coreTypeOfCoreExpr (weakExprToCoreExpr we)) ((weakTypeOfWeakExpr we) >>= fun t => (addErrorMessage ("WeakType: " +++ t) ((weakTypeToTypeOfKind φ t ★) >>= fun τ => ((weakExprToStrongExpr Γ Δ φ ψ ξ (fun _ => true) τ nil we) >>= fun e => (* insert HaskStrong-to-HaskStrong manipulations here *) strongExprToWeakExpr hetmet_brak hetmet_esc mkWeakTypeVar mkWeakCoerVar mkWeakExprVar uniqueSupply e INil >>= fun q => OK (weakExprToCoreExpr q) (* OK (weakExprToCoreExpr we) *) )))))))). Definition coreToCoreExpr (ce:@CoreExpr CoreVar) : (@CoreExpr CoreVar) := match coreToCoreExpr' ce with | OK x => x | Error s => Prelude_error s end. Definition coreToCoreBind (binds:@CoreBind CoreVar) : @CoreBind CoreVar := match binds with | CoreNonRec v e => CoreNonRec v (coreToCoreExpr e) | CoreRec lbe => CoreRec (map (fun ve => match ve with (v,e) => (v,coreToCoreExpr e) end) lbe) end. Definition coqPassCoreToCore' (lbinds:list (@CoreBind CoreVar)) : list (@CoreBind CoreVar) := map coreToCoreBind lbinds. End CoreToCore. Definition coqPassCoreToCore (hetmet_brak : CoreVar) (hetmet_esc : CoreVar) (uniqueSupply : UniqSupply) (lbinds:list (@CoreBind CoreVar)) : list (@CoreBind CoreVar) := match coreVarToWeakVar hetmet_brak with | WExprVar hetmet_brak' => match coreVarToWeakVar hetmet_esc with | WExprVar hetmet_esc' => coqPassCoreToCore' hetmet_brak' hetmet_esc' uniqueSupply lbinds | _ => Prelude_error "IMPOSSIBLE" end | _ => Prelude_error "IMPOSSIBLE" end. End core2proof. Extraction "Extraction.hs" coqPassCoreToString coqPassCoreToCore.