module VectUtils (
collectAnnTypeBinders, collectAnnTypeArgs, isAnnTypeArg,
collectAnnValBinders,
- mkDataConTag,
- splitClosureTy,
- mkPReprType, mkPReprAlts,
- mkPADictType, mkPArrayType,
- parrayReprTyCon, parrayReprDataCon, mkVScrut,
+ dataConTagZ, mkDataConTag, mkDataConTagLit,
+
+ newLocalVVar,
+
+ mkBuiltinCo, voidType, mkWrapType,
+ mkPADictType, mkPArrayType, mkPDataType, mkPReprType, mkPArray,
+
+ pdataReprTyCon, pdataReprDataCon, mkVScrut,
+ prDictOfType, prDFunOfTyCon,
paDictArgType, paDictOfType, paDFunType,
- paMethod, lengthPA, replicatePA, emptyPA, liftPA,
- polyAbstract, polyApply, polyVApply,
+ paMethod, wrapPR, replicatePD, emptyPD, packByTagPD,
+ combinePD,
+ liftPD,
+ zipScalars, scalarClosure,
+ polyAbstract, polyApply, polyVApply, polyArity,
+ Inline(..), addInlineArity, inlineMe,
hoistBinding, hoistExpr, hoistPolyVExpr, takeHoisted,
buildClosure, buildClosures,
mkClosureApp
) where
+import Vectorise.Monad
+import Vectorise.Env
+import Vectorise.Vect
+import Vectorise.Builtins
-#include "HsVersions.h"
-
-import VectCore
-import VectMonad
-
-import DsUtils
+import MkCore ( mkCoreTup, mkWildCase )
import CoreSyn
import CoreUtils
+import CoreUnfold ( mkInlineRule )
+import Coercion
import Type
import TypeRep
import TyCon
-import DataCon ( DataCon, dataConWrapId, dataConTag )
+import DataCon
import Var
-import Id ( mkWildId )
import MkId ( unwrapFamInstScrut )
-import Name ( Name )
-import PrelNames
+import Id ( setIdUnfolding )
import TysWiredIn
-import BasicTypes ( Boxity(..) )
+import BasicTypes ( Boxity(..), Arity )
+import Literal ( Literal, mkMachInt )
+
import Outputable
import FastString
-import Control.Monad ( liftM, zipWithM_ )
+import Control.Monad
collectAnnTypeArgs :: AnnExpr b ann -> (AnnExpr b ann, [Type])
collectAnnTypeArgs expr = go expr []
go bs e = (reverse bs, e)
isAnnTypeArg :: AnnExpr b ann -> Bool
-isAnnTypeArg (_, AnnType t) = True
+isAnnTypeArg (_, AnnType _) = True
isAnnTypeArg _ = False
-mkDataConTag :: DataCon -> CoreExpr
-mkDataConTag dc = mkConApp intDataCon [mkIntLitInt $ dataConTag dc]
-
-splitUnTy :: String -> Name -> Type -> Type
-splitUnTy s name ty
- | Just (tc, [ty']) <- splitTyConApp_maybe ty
- , tyConName tc == name
- = ty'
-
- | otherwise = pprPanic s (ppr ty)
-
-splitBinTy :: String -> Name -> Type -> (Type, Type)
-splitBinTy s name ty
- | Just (tc, [ty1, ty2]) <- splitTyConApp_maybe ty
- , tyConName tc == name
- = (ty1, ty2)
-
- | otherwise = pprPanic s (ppr ty)
+dataConTagZ :: DataCon -> Int
+dataConTagZ con = dataConTag con - fIRST_TAG
-splitCrossTy :: Type -> (Type, Type)
-splitCrossTy = splitBinTy "splitCrossTy" ndpCrossTyConName
+mkDataConTagLit :: DataCon -> Literal
+mkDataConTagLit = mkMachInt . toInteger . dataConTagZ
-splitPlusTy :: Type -> (Type, Type)
-splitPlusTy = splitBinTy "splitSumTy" ndpPlusTyConName
-
-splitEmbedTy :: Type -> Type
-splitEmbedTy = splitUnTy "splitEmbedTy" embedTyConName
+mkDataConTag :: DataCon -> CoreExpr
+mkDataConTag = mkIntLitInt . dataConTagZ
-splitClosureTy :: Type -> (Type, Type)
-splitClosureTy = splitBinTy "splitClosureTy" closureTyConName
+splitPrimTyCon :: Type -> Maybe TyCon
+splitPrimTyCon ty
+ | Just (tycon, []) <- splitTyConApp_maybe ty
+ , isPrimTyCon tycon
+ = Just tycon
-splitPArrayTy :: Type -> Type
-splitPArrayTy = splitUnTy "splitPArrayTy" parrayTyConName
+ | otherwise = Nothing
mkBuiltinTyConApp :: (Builtins -> TyCon) -> [Type] -> VM Type
mkBuiltinTyConApp get_tc tys
where
mk tc ty1 ty2 = mkTyConApp tc [ty1,ty2]
-mkBuiltinTyConApps1 :: (Builtins -> TyCon) -> Type -> [Type] -> VM Type
-mkBuiltinTyConApps1 get_tc dft [] = return dft
-mkBuiltinTyConApps1 get_tc dft tys
- = do
- tc <- builtin get_tc
- case tys of
- [] -> pprPanic "mkBuiltinTyConApps1" (ppr tc)
- _ -> return $ foldr1 (mk tc) tys
- where
- mk tc ty1 ty2 = mkTyConApp tc [ty1,ty2]
-
-mkPReprType :: [[Type]] -> VM Type
-mkPReprType [] = return unitTy
-mkPReprType tys
- = do
- embed <- builtin embedTyCon
- cross <- builtin crossTyCon
- plus <- builtin plusTyCon
-
- let mk_embed ty = mkTyConApp embed [ty]
- mk_cross ty1 ty2 = mkTyConApp cross [ty1, ty2]
- mk_plus ty1 ty2 = mkTyConApp plus [ty1, ty2]
-
- mk_tup [] = unitTy
- mk_tup tys = foldr1 mk_cross tys
-
- mk_sum [] = unitTy
- mk_sum tys = foldr1 mk_plus tys
+voidType :: VM Type
+voidType = mkBuiltinTyConApp voidTyCon []
- return . mk_sum
- . map (mk_tup . map mk_embed)
- $ tys
-
-mkPReprAlts :: [[CoreExpr]] -> VM ([CoreExpr], Type)
-mkPReprAlts ess
- = do
- embed_tc <- builtin embedTyCon
- embed_dc <- builtin embedDataCon
- cross_tc <- builtin crossTyCon
- cross_dc <- builtin crossDataCon
- plus_tc <- builtin plusTyCon
- left_dc <- builtin leftDataCon
- right_dc <- builtin rightDataCon
-
- let mk_embed (expr, ty, pa)
- = (mkConApp embed_dc [Type ty, pa, expr],
- mkTyConApp embed_tc [ty])
-
- mk_cross (expr1, ty1) (expr2, ty2)
- = (mkConApp cross_dc [Type ty1, Type ty2, expr1, expr2],
- mkTyConApp cross_tc [ty1, ty2])
-
- mk_tup [] = (Var unitDataConId, unitTy)
- mk_tup es = foldr1 mk_cross es
-
- mk_sum [] = ([Var unitDataConId], unitTy)
- mk_sum [(expr, ty)] = ([expr], ty)
- mk_sum ((expr, lty) : es)
- = let (alts, rty) = mk_sum es
- in
- (mkConApp left_dc [Type lty, Type rty, expr]
- : [mkConApp right_dc [Type lty, Type rty, alt] | alt <- alts],
- mkTyConApp plus_tc [lty, rty])
-
- liftM (mk_sum . map (mk_tup . map mk_embed))
- (mapM (mapM init) ess)
- where
- init expr = let ty = exprType expr
- in do
- pa <- paDictOfType ty
- return (expr, ty, pa)
-
-mkClosureType :: Type -> Type -> VM Type
-mkClosureType arg_ty res_ty = mkBuiltinTyConApp closureTyCon [arg_ty, res_ty]
+mkWrapType :: Type -> VM Type
+mkWrapType ty = mkBuiltinTyConApp wrapTyCon [ty]
mkClosureTypes :: [Type] -> Type -> VM Type
mkClosureTypes = mkBuiltinTyConApps closureTyCon
+mkPReprType :: Type -> VM Type
+mkPReprType ty = mkBuiltinTyConApp preprTyCon [ty]
+
mkPADictType :: Type -> VM Type
mkPADictType ty = mkBuiltinTyConApp paTyCon [ty]
mkPArrayType :: Type -> VM Type
+mkPArrayType ty
+ | Just tycon <- splitPrimTyCon ty
+ = do
+ r <- lookupPrimPArray tycon
+ case r of
+ Just arr -> return $ mkTyConApp arr []
+ Nothing -> cantVectorise "Primitive tycon not vectorised" (ppr tycon)
mkPArrayType ty = mkBuiltinTyConApp parrayTyCon [ty]
-parrayReprTyCon :: Type -> VM (TyCon, [Type])
-parrayReprTyCon ty = builtin parrayTyCon >>= (`lookupFamInst` [ty])
+mkPDataType :: Type -> VM Type
+mkPDataType ty = mkBuiltinTyConApp pdataTyCon [ty]
+
+mkPArray :: Type -> CoreExpr -> CoreExpr -> VM CoreExpr
+mkPArray ty len dat = do
+ tc <- builtin parrayTyCon
+ let [dc] = tyConDataCons tc
+ return $ mkConApp dc [Type ty, len, dat]
+
+mkBuiltinCo :: (Builtins -> TyCon) -> VM Coercion
+mkBuiltinCo get_tc
+ = do
+ tc <- builtin get_tc
+ return $ mkTyConApp tc []
+
+pdataReprTyCon :: Type -> VM (TyCon, [Type])
+pdataReprTyCon ty = builtin pdataTyCon >>= (`lookupFamInst` [ty])
-parrayReprDataCon :: Type -> VM (DataCon, [Type])
-parrayReprDataCon ty
+pdataReprDataCon :: Type -> VM (DataCon, [Type])
+pdataReprDataCon ty
= do
- (tc, arg_tys) <- parrayReprTyCon ty
+ (tc, arg_tys) <- pdataReprTyCon ty
let [dc] = tyConDataCons tc
return (dc, arg_tys)
-mkVScrut :: VExpr -> VM (VExpr, TyCon, [Type])
+mkVScrut :: VExpr -> VM (CoreExpr, CoreExpr, TyCon, [Type])
mkVScrut (ve, le)
= do
- (tc, arg_tys) <- parrayReprTyCon (exprType ve)
- return ((ve, unwrapFamInstScrut tc arg_tys le), tc, arg_tys)
+ (tc, arg_tys) <- pdataReprTyCon ty
+ return (ve, unwrapFamInstScrut tc arg_tys le, tc, arg_tys)
+ where
+ ty = exprType ve
+
+prDFunOfTyCon :: TyCon -> VM CoreExpr
+prDFunOfTyCon tycon
+ = liftM Var
+ . maybeCantVectoriseM "No PR dictionary for tycon" (ppr tycon)
+ $ lookupTyConPR tycon
+
paDictArgType :: TyVar -> VM (Maybe Type)
paDictArgType tv = go (TyVarTy tv) (tyVarKind tv)
go ty k | Just k' <- kindView k = go ty k'
go ty (FunTy k1 k2)
= do
- tv <- newTyVar FSLIT("a") k1
+ tv <- newTyVar (fsLit "a") k1
mty1 <- go (TyVarTy tv) k1
case mty1 of
Just ty1 -> do
| isLiftedTypeKind k
= liftM Just (mkPADictType ty)
- go ty k = return Nothing
+ go _ _ = return Nothing
+
-paDictOfType :: Type -> VM CoreExpr
-paDictOfType ty = paDictOfTyApp ty_fn ty_args
+-- | Get the PA dictionary for some type, or `Nothing` if there isn't one.
+paDictOfType :: Type -> VM (Maybe CoreExpr)
+paDictOfType ty
+ = paDictOfTyApp ty_fn ty_args
where
(ty_fn, ty_args) = splitAppTys ty
-paDictOfTyApp :: Type -> [Type] -> VM CoreExpr
-paDictOfTyApp ty_fn ty_args
- | Just ty_fn' <- coreView ty_fn = paDictOfTyApp ty_fn' ty_args
-paDictOfTyApp (TyVarTy tv) ty_args
- = do
- dfun <- maybeV (lookupTyVarPA tv)
- paDFunApply dfun ty_args
-paDictOfTyApp (TyConApp tc _) ty_args
- = do
- dfun <- traceMaybeV "paDictOfTyApp" (ppr tc) (lookupTyConPA tc)
- paDFunApply (Var dfun) ty_args
-paDictOfTyApp ty ty_args = pprPanic "paDictOfTyApp" (ppr ty)
+ paDictOfTyApp :: Type -> [Type] -> VM (Maybe CoreExpr)
+ paDictOfTyApp ty_fn ty_args
+ | Just ty_fn' <- coreView ty_fn
+ = paDictOfTyApp ty_fn' ty_args
+
+ paDictOfTyApp (TyVarTy tv) ty_args
+ = do dfun <- maybeV (lookupTyVarPA tv)
+ liftM Just $ paDFunApply dfun ty_args
+
+ paDictOfTyApp (TyConApp tc _) ty_args
+ = do mdfun <- lookupTyConPA tc
+ case mdfun of
+ Nothing
+ -> pprTrace "VectUtils.paDictOfType"
+ (vcat [ text "No PA dictionary"
+ , text "for tycon: " <> ppr tc
+ , text "in type: " <> ppr ty])
+ $ return Nothing
+
+ Just dfun -> liftM Just $ paDFunApply (Var dfun) ty_args
+
+ paDictOfTyApp ty _
+ = cantVectorise "Can't construct PA dictionary for type" (ppr ty)
+
+
paDFunType :: TyCon -> VM Type
paDFunType tc
paDFunApply :: CoreExpr -> [Type] -> VM CoreExpr
paDFunApply dfun tys
- = do
- dicts <- mapM paDictOfType tys
+ = do Just dicts <- liftM sequence $ mapM paDictOfType tys
return $ mkApps (mkTyApps dfun tys) dicts
-paMethod :: (Builtins -> Var) -> Type -> VM CoreExpr
-paMethod method ty
+
+paMethod :: (Builtins -> Var) -> String -> Type -> VM CoreExpr
+paMethod _ name ty
+ | Just tycon <- splitPrimTyCon ty
+ = liftM Var
+ . maybeCantVectoriseM "No PA method" (text name <+> text "for" <+> ppr tycon)
+ $ lookupPrimMethod tycon name
+
+paMethod method _ ty
= do
- fn <- builtin method
- dict <- paDictOfType ty
+ fn <- builtin method
+ Just dict <- paDictOfType ty
return $ mkApps (Var fn) [Type ty, dict]
-lengthPA :: CoreExpr -> VM CoreExpr
-lengthPA x = liftM (`App` x) (paMethod lengthPAVar ty)
+prDictOfType :: Type -> VM CoreExpr
+prDictOfType ty = prDictOfTyApp ty_fn ty_args
where
- ty = splitPArrayTy (exprType x)
+ (ty_fn, ty_args) = splitAppTys ty
-replicatePA :: CoreExpr -> CoreExpr -> VM CoreExpr
-replicatePA len x = liftM (`mkApps` [len,x])
- (paMethod replicatePAVar (exprType x))
+prDictOfTyApp :: Type -> [Type] -> VM CoreExpr
+prDictOfTyApp ty_fn ty_args
+ | Just ty_fn' <- coreView ty_fn = prDictOfTyApp ty_fn' ty_args
+prDictOfTyApp (TyConApp tc _) ty_args
+ = do
+ dfun <- liftM Var $ maybeV (lookupTyConPR tc)
+ prDFunApply dfun ty_args
+prDictOfTyApp _ _ = noV
-emptyPA :: Type -> VM CoreExpr
-emptyPA = paMethod emptyPAVar
+prDFunApply :: CoreExpr -> [Type] -> VM CoreExpr
+prDFunApply dfun tys
+ = do
+ dicts <- mapM prDictOfType tys
+ return $ mkApps (mkTyApps dfun tys) dicts
+
+wrapPR :: Type -> VM CoreExpr
+wrapPR ty
+ = do
+ Just pa_dict <- paDictOfType ty
+ pr_dfun <- prDFunOfTyCon =<< builtin wrapTyCon
+ return $ mkApps pr_dfun [Type ty, pa_dict]
+
+replicatePD :: CoreExpr -> CoreExpr -> VM CoreExpr
+replicatePD len x = liftM (`mkApps` [len,x])
+ (paMethod replicatePDVar "replicatePD" (exprType x))
+
+emptyPD :: Type -> VM CoreExpr
+emptyPD = paMethod emptyPDVar "emptyPD"
+
+packByTagPD :: Type -> CoreExpr -> CoreExpr -> CoreExpr -> CoreExpr
+ -> VM CoreExpr
+packByTagPD ty xs len tags t
+ = liftM (`mkApps` [xs, len, tags, t])
+ (paMethod packByTagPDVar "packByTagPD" ty)
+
+combinePD :: Type -> CoreExpr -> CoreExpr -> [CoreExpr]
+ -> VM CoreExpr
+combinePD ty len sel xs
+ = liftM (`mkApps` (len : sel : xs))
+ (paMethod (combinePDVar n) ("combine" ++ show n ++ "PD") ty)
+ where
+ n = length xs
-liftPA :: CoreExpr -> VM CoreExpr
-liftPA x
+-- | Like `replicatePD` but use the lifting context in the vectoriser state.
+liftPD :: CoreExpr -> VM CoreExpr
+liftPD x
= do
lc <- builtin liftingContext
- replicatePA (Var lc) x
+ replicatePD (Var lc) x
+
+zipScalars :: [Type] -> Type -> VM CoreExpr
+zipScalars arg_tys res_ty
+ = do
+ scalar <- builtin scalarClass
+ (dfuns, _) <- mapAndUnzipM (\ty -> lookupInst scalar [ty]) ty_args
+ zipf <- builtin (scalarZip $ length arg_tys)
+ return $ Var zipf `mkTyApps` ty_args `mkApps` map Var dfuns
+ where
+ ty_args = arg_tys ++ [res_ty]
+
+scalarClosure :: [Type] -> Type -> CoreExpr -> CoreExpr -> VM CoreExpr
+scalarClosure arg_tys res_ty scalar_fun array_fun
+ = do
+ ctr <- builtin (closureCtrFun $ length arg_tys)
+ Just pas <- liftM sequence $ mapM paDictOfType (init arg_tys)
+ return $ Var ctr `mkTyApps` (arg_tys ++ [res_ty])
+ `mkApps` (pas ++ [scalar_fun, array_fun])
newLocalVVar :: FastString -> Type -> VM VVar
newLocalVVar fs vty
= do
- lty <- mkPArrayType vty
+ lty <- mkPDataType vty
vv <- newLocalVar fs vty
lv <- newLocalVar fs lty
return (vv,lv)
-polyAbstract :: [TyVar] -> ((CoreExpr -> CoreExpr) -> VM a) -> VM a
+polyAbstract :: [TyVar] -> ([Var] -> VM a) -> VM a
polyAbstract tvs p
= localV
$ do
mdicts <- mapM mk_dict_var tvs
- zipWithM_ (\tv -> maybe (defLocalTyVar tv) (defLocalTyVarWithPA tv . Var)) tvs mdicts
- p (mk_lams mdicts)
+ zipWithM_ (\tv -> maybe (defLocalTyVar tv)
+ (defLocalTyVarWithPA tv . Var)) tvs mdicts
+ p (mk_args mdicts)
where
mk_dict_var tv = do
r <- paDictArgType tv
case r of
- Just ty -> liftM Just (newLocalVar FSLIT("dPA") ty)
+ Just ty -> liftM Just (newLocalVar (fsLit "dPA") ty)
Nothing -> return Nothing
- mk_lams mdicts = mkLams (tvs ++ [dict | Just dict <- mdicts])
+ mk_args mdicts = [dict | Just dict <- mdicts]
+
+polyArity :: [TyVar] -> VM Int
+polyArity tvs = do
+ tys <- mapM paDictArgType tvs
+ return $ length [() | Just _ <- tys]
polyApply :: CoreExpr -> [Type] -> VM CoreExpr
polyApply expr tys
- = do
- dicts <- mapM paDictOfType tys
+ = do Just dicts <- liftM sequence $ mapM paDictOfType tys
return $ expr `mkTyApps` tys `mkApps` dicts
polyVApply :: VExpr -> [Type] -> VM VExpr
polyVApply expr tys
- = do
- dicts <- mapM paDictOfType tys
- return $ mapVect (\e -> e `mkTyApps` tys `mkApps` dicts) expr
+ = do Just dicts <- liftM sequence $ mapM paDictOfType tys
+ return $ mapVect (\e -> e `mkTyApps` tys `mkApps` dicts) expr
+
+-- Inline ---------------------------------------------------------------------
+-- | Records whether we should inline a particular binding.
+data Inline
+ = Inline Arity
+ | DontInline
+
+-- | Add to the arity contained within an `Inline`, if any.
+addInlineArity :: Inline -> Int -> Inline
+addInlineArity (Inline m) n = Inline (m+n)
+addInlineArity DontInline _ = DontInline
+
+-- | Says to always inline a binding.
+inlineMe :: Inline
+inlineMe = Inline 0
+
+-- Hoising --------------------------------------------------------------------
hoistBinding :: Var -> CoreExpr -> VM ()
hoistBinding v e = updGEnv $ \env ->
env { global_bindings = (v,e) : global_bindings env }
-hoistExpr :: FastString -> CoreExpr -> VM Var
-hoistExpr fs expr
+hoistExpr :: FastString -> CoreExpr -> Inline -> VM Var
+hoistExpr fs expr inl
= do
- var <- newLocalVar fs (exprType expr)
+ var <- mk_inline `liftM` newLocalVar fs (exprType expr)
hoistBinding var expr
return var
+ where
+ mk_inline var = case inl of
+ Inline arity -> var `setIdUnfolding`
+ mkInlineRule expr (Just arity)
+ DontInline -> var
-hoistVExpr :: VExpr -> VM VVar
-hoistVExpr (ve, le)
+hoistVExpr :: VExpr -> Inline -> VM VVar
+hoistVExpr (ve, le) inl
= do
fs <- getBindName
- vv <- hoistExpr ('v' `consFS` fs) ve
- lv <- hoistExpr ('l' `consFS` fs) le
+ vv <- hoistExpr ('v' `consFS` fs) ve inl
+ lv <- hoistExpr ('l' `consFS` fs) le (addInlineArity inl 1)
return (vv, lv)
-hoistPolyVExpr :: [TyVar] -> VM VExpr -> VM VExpr
-hoistPolyVExpr tvs p
+hoistPolyVExpr :: [TyVar] -> Inline -> VM VExpr -> VM VExpr
+hoistPolyVExpr tvs inline p
= do
- expr <- closedV . polyAbstract tvs $ \abstract ->
- liftM (mapVect abstract) p
- fn <- hoistVExpr expr
+ inline' <- liftM (addInlineArity inline) (polyArity tvs)
+ expr <- closedV . polyAbstract tvs $ \args ->
+ liftM (mapVect (mkLams $ tvs ++ args)) p
+ fn <- hoistVExpr expr inline'
polyVApply (vVar fn) (mkTyVarTys tvs)
takeHoisted :: VM [(Var, CoreExpr)]
setGEnv $ env { global_bindings = [] }
return $ global_bindings env
+{-
+boxExpr :: Type -> VExpr -> VM VExpr
+boxExpr ty (vexpr, lexpr)
+ | Just (tycon, []) <- splitTyConApp_maybe ty
+ , isUnLiftedTyCon tycon
+ = do
+ r <- lookupBoxedTyCon tycon
+ case r of
+ Just tycon' -> let [dc] = tyConDataCons tycon'
+ in
+ return (mkConApp dc [vexpr], lexpr)
+ Nothing -> return (vexpr, lexpr)
+-}
+
+-- Closures -------------------------------------------------------------------
mkClosure :: Type -> Type -> Type -> VExpr -> VExpr -> VM VExpr
mkClosure arg_ty res_ty env_ty (vfn,lfn) (venv,lenv)
- = do
- dict <- paDictOfType env_ty
- mkv <- builtin mkClosureVar
- mkl <- builtin mkClosurePVar
+ = do Just dict <- paDictOfType env_ty
+ mkv <- builtin closureVar
+ mkl <- builtin liftedClosureVar
return (Var mkv `mkTyApps` [arg_ty, res_ty, env_ty] `mkApps` [dict, vfn, lfn, venv],
Var mkl `mkTyApps` [arg_ty, res_ty, env_ty] `mkApps` [dict, vfn, lfn, lenv])
-mkClosureApp :: VExpr -> VExpr -> VM VExpr
-mkClosureApp (vclo, lclo) (varg, larg)
- = do
- vapply <- builtin applyClosureVar
- lapply <- builtin applyClosurePVar
+
+mkClosureApp :: Type -> Type -> VExpr -> VExpr -> VM VExpr
+mkClosureApp arg_ty res_ty (vclo, lclo) (varg, larg)
+ = do vapply <- builtin applyVar
+ lapply <- builtin liftedApplyVar
+ lc <- builtin liftingContext
return (Var vapply `mkTyApps` [arg_ty, res_ty] `mkApps` [vclo, varg],
- Var lapply `mkTyApps` [arg_ty, res_ty] `mkApps` [lclo, larg])
- where
- (arg_ty, res_ty) = splitClosureTy (exprType vclo)
+ Var lapply `mkTyApps` [arg_ty, res_ty] `mkApps` [Var lc, lclo, larg])
+
buildClosures :: [TyVar] -> [VVar] -> [Type] -> Type -> VM VExpr -> VM VExpr
-buildClosures tvs vars [] res_ty mk_body
+buildClosures _ _ [] _ mk_body
= mk_body
buildClosures tvs vars [arg_ty] res_ty mk_body
- = buildClosure tvs vars arg_ty res_ty mk_body
+ = -- liftM vInlineMe $
+ buildClosure tvs vars arg_ty res_ty mk_body
buildClosures tvs vars (arg_ty : arg_tys) res_ty mk_body
= do
res_ty' <- mkClosureTypes arg_tys res_ty
- arg <- newLocalVVar FSLIT("x") arg_ty
+ arg <- newLocalVVar (fsLit "x") arg_ty
+ -- liftM vInlineMe
buildClosure tvs vars arg_ty res_ty'
- . hoistPolyVExpr tvs
+ . hoistPolyVExpr tvs (Inline (length vars + 1))
$ do
lc <- builtin liftingContext
clo <- buildClosures tvs (vars ++ [arg]) arg_tys res_ty mk_body
buildClosure tvs vars arg_ty res_ty mk_body
= do
(env_ty, env, bind) <- buildEnv vars
- env_bndr <- newLocalVVar FSLIT("env") env_ty
- arg_bndr <- newLocalVVar FSLIT("arg") arg_ty
+ env_bndr <- newLocalVVar (fsLit "env") env_ty
+ arg_bndr <- newLocalVVar (fsLit "arg") arg_ty
- fn <- hoistPolyVExpr tvs
+ fn <- hoistPolyVExpr tvs (Inline 2)
$ do
lc <- builtin liftingContext
body <- mk_body
- body' <- bind (vVar env_bndr)
+ return -- . vInlineMe
+ . vLams lc [env_bndr, arg_bndr]
+ $ bind (vVar env_bndr)
(vVarApps lc body (vars ++ [arg_bndr]))
- return (vLamsWithoutLC [env_bndr, arg_bndr] body')
mkClosure arg_ty res_ty env_ty fn env
-buildEnv :: [VVar] -> VM (Type, VExpr, VExpr -> VExpr -> VM VExpr)
-buildEnv vvs
- = do
- lc <- builtin liftingContext
- let (ty, venv, vbind) = mkVectEnv tys vs
- (lenv, lbind) <- mkLiftEnv lc tys ls
- return (ty, (venv, lenv),
- \(venv,lenv) (vbody,lbody) ->
- do
- let vbody' = vbind venv vbody
- lbody' <- lbind lenv lbody
- return (vbody', lbody'))
- where
- (vs,ls) = unzip vvs
- tys = map idType vs
-
-mkVectEnv :: [Type] -> [Var] -> (Type, CoreExpr, CoreExpr -> CoreExpr -> CoreExpr)
-mkVectEnv [] [] = (unitTy, Var unitDataConId, \env body -> body)
-mkVectEnv [ty] [v] = (ty, Var v, \env body -> Let (NonRec v env) body)
-mkVectEnv tys vs = (ty, mkCoreTup (map Var vs),
- \env body -> Case env (mkWildId ty) (exprType body)
- [(DataAlt (tupleCon Boxed (length vs)), vs, body)])
- where
- ty = mkCoreTupTy tys
-
-mkLiftEnv :: Var -> [Type] -> [Var] -> VM (CoreExpr, CoreExpr -> CoreExpr -> VM CoreExpr)
-mkLiftEnv lc [ty] [v]
- = return (Var v, \env body ->
- do
- len <- lengthPA (Var v)
- return . Let (NonRec v env)
- $ Case len lc (exprType body) [(DEFAULT, [], body)])
-
--- NOTE: this transparently deals with empty environments
-mkLiftEnv lc tys vs
+
+-- Environments ---------------------------------------------------------------
+buildEnv :: [VVar] -> VM (Type, VExpr, VExpr -> VExpr -> VExpr)
+buildEnv [] = do
+ ty <- voidType
+ void <- builtin voidVar
+ pvoid <- builtin pvoidVar
+ return (ty, vVar (void, pvoid), \_ body -> body)
+
+buildEnv [v] = return (vVarType v, vVar v,
+ \env body -> vLet (vNonRec v env) body)
+
+buildEnv vs
= do
- (env_tc, env_tyargs) <- parrayReprTyCon vty
- let [env_con] = tyConDataCons env_tc
-
- env = Var (dataConWrapId env_con)
- `mkTyApps` env_tyargs
- `mkVarApps` (lc : vs)
-
- bind env body = let scrut = unwrapFamInstScrut env_tc env_tyargs env
- in
- return $ Case scrut (mkWildId (exprType scrut))
- (exprType body)
- [(DataAlt env_con, lc : bndrs, body)]
- return (env, bind)
- where
- vty = mkCoreTupTy tys
+
+ (lenv_tc, lenv_tyargs) <- pdataReprTyCon ty
+
+ let venv_con = tupleCon Boxed (length vs)
+ [lenv_con] = tyConDataCons lenv_tc
- bndrs | null vs = [mkWildId unitTy]
- | otherwise = vs
+ venv = mkCoreTup (map Var vvs)
+ lenv = Var (dataConWrapId lenv_con)
+ `mkTyApps` lenv_tyargs
+ `mkApps` map Var lvs
+
+ vbind env body = mkWildCase env ty (exprType body)
+ [(DataAlt venv_con, vvs, body)]
+
+ lbind env body =
+ let scrut = unwrapFamInstScrut lenv_tc lenv_tyargs env
+ in
+ mkWildCase scrut (exprType scrut) (exprType body)
+ [(DataAlt lenv_con, lvs, body)]
+
+ bind (venv, lenv) (vbody, lbody) = (vbind venv vbody,
+ lbind lenv lbody)
+
+ return (ty, (venv, lenv), bind)
+ where
+ (vvs, lvs) = unzip vs
+ tys = map vVarType vs
+ ty = mkBoxedTupleTy tys