X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=ghc%2Fcompiler%2FdeSugar%2FDsListComp.lhs;h=6bb41a92e4b54bcd7cfcdbd3c2babd43ca1a2885;hb=28a464a75e14cece5db40f2765a29348273ff2d2;hp=99b8980f26aa8a3047c4ec6a31b99eb88b0e7bf1;hpb=10fcd78ccde892feccda3f5eacd221c1de75feea;p=ghc-hetmet.git diff --git a/ghc/compiler/deSugar/DsListComp.lhs b/ghc/compiler/deSugar/DsListComp.lhs index 99b8980..6bb41a9 100644 --- a/ghc/compiler/deSugar/DsListComp.lhs +++ b/ghc/compiler/deSugar/DsListComp.lhs @@ -8,36 +8,31 @@ module DsListComp ( dsListComp, dsPArrComp ) where #include "HsVersions.h" -import {-# SOURCE #-} DsExpr ( dsExpr, dsLet ) +import {-# SOURCE #-} DsExpr ( dsLExpr, dsLocalBinds ) import BasicTypes ( Boxity(..) ) -import DataCon ( dataConId ) -import TyCon ( tyConName ) -import HsSyn ( OutPat(..), HsExpr(..), Stmt(..), - HsMatchContext(..), HsDoContext(..), - collectHsOutBinders ) -import TcHsSyn ( TypecheckedStmt, TypecheckedPat, TypecheckedHsExpr, - outPatType ) +import HsSyn +import TcHsSyn ( hsPatType, mkVanillaTuplePat ) import CoreSyn import DsMonad -- the monadery used in the desugarer import DsUtils -import CmdLineOpts ( opt_FoldrBuildOn ) +import DynFlags ( DynFlag(..), dopt ) +import StaticFlags ( opt_RulesOff ) import CoreUtils ( exprType, mkIfThenElse ) import Id ( idType ) import Var ( Id ) import Type ( mkTyVarTy, mkFunTys, mkFunTy, Type, splitTyConApp_maybe ) import TysPrim ( alphaTyVar ) -import TysWiredIn ( nilDataCon, consDataCon, unitDataConId, unitTy, - mkListTy, mkTupleTy, intDataCon ) +import TysWiredIn ( nilDataCon, consDataCon, trueDataConId, falseDataConId, + unitDataConId, unitTy, mkListTy, parrTyCon ) import Match ( matchSimply ) -import PrelNames ( trueDataConName, falseDataConName, foldrName, - buildName, replicatePName, mapPName, filterPName, - zipPName, crossPName, parrTyConName ) +import PrelNames ( foldrName, buildName, replicatePName, mapPName, + filterPName, zipPName, crossPName ) import PrelInfo ( pAT_ERROR_ID ) -import SrcLoc ( noSrcLoc ) +import SrcLoc ( noLoc, unLoc ) import Panic ( panic ) \end{code} @@ -48,29 +43,39 @@ turned on'' (if you read Gill {\em et al.}'s paper on the subject). There will be at least one ``qualifier'' in the input. \begin{code} -dsListComp :: [TypecheckedStmt] +dsListComp :: [LStmt Id] + -> LHsExpr Id -> Type -- Type of list elements -> DsM CoreExpr - -dsListComp quals elt_ty - | not opt_FoldrBuildOn -- Be boring - || isParallelComp quals - = deListComp quals (mkNilExpr elt_ty) - - | otherwise -- foldr/build lives! - = newTyVarsDs [alphaTyVar] `thenDs` \ [n_tyvar] -> +dsListComp lquals body elt_ty + = getDOptsDs `thenDs` \dflags -> + let + quals = map unLoc lquals + in + if opt_RulesOff || dopt Opt_IgnoreInterfacePragmas dflags + -- Either rules are switched off, or we are ignoring what there are; + -- Either way foldr/build won't happen, so use the more efficient + -- Wadler-style desugaring + || isParallelComp quals + -- Foldr-style desugaring can't handle + -- parallel list comprehensions + then deListComp quals body (mkNilExpr elt_ty) + + else -- Foldr/build should be enabled, so desugar + -- into foldrs and builds + newTyVarsDs [alphaTyVar] `thenDs` \ [n_tyvar] -> let n_ty = mkTyVarTy n_tyvar c_ty = mkFunTys [elt_ty, n_ty] n_ty in newSysLocalsDs [c_ty,n_ty] `thenDs` \ [c, n] -> - dfListComp c n quals `thenDs` \ result -> - dsLookupGlobalValue buildName `thenDs` \ build_id -> + dfListComp c n quals body `thenDs` \ result -> + dsLookupGlobalId buildName `thenDs` \ build_id -> returnDs (Var build_id `App` Type elt_ty `App` mkLams [n_tyvar, c, n] result) - where isParallelComp (ParStmtOut bndrstmtss : _) = True - isParallelComp _ = False + where isParallelComp (ParStmt bndrstmtss : _) = True + isParallelComp _ = False \end{code} %************************************************************************ @@ -127,7 +132,7 @@ comprehensions. The translation goes roughly as follows: where (x1, .., xn) are the variables bound in p1, v1, p2 (y1, .., ym) are the variables bound in q1, v2, q2 -In the translation below, the ParStmtOut branch translates each parallel branch +In the translation below, the ParStmt branch translates each parallel branch into a sub-comprehension, and desugars each independently. The resulting lists are fed to a zip function, we create a binding for all the variables bound in all the comprehensions, and then we hand things off the the desugarer for bindings. @@ -138,59 +143,61 @@ The introduced tuples are Boxed, but only because I couldn't get it to work with the Unboxed variety. \begin{code} +deListComp :: [Stmt Id] -> LHsExpr Id -> CoreExpr -> DsM CoreExpr -deListComp :: [TypecheckedStmt] -> CoreExpr -> DsM CoreExpr - -deListComp (ParStmtOut bndrstmtss : quals) list - = mapDs do_list_comp bndrstmtss `thenDs` \ exps -> +deListComp (ParStmt stmtss_w_bndrs : quals) body list + = mappM do_list_comp stmtss_w_bndrs `thenDs` \ exps -> mkZipBind qual_tys `thenDs` \ (zip_fn, zip_rhs) -> -- Deal with [e | pat <- zip l1 .. ln] in example above deBindComp pat (Let (Rec [(zip_fn, zip_rhs)]) (mkApps (Var zip_fn) exps)) - quals list + quals body list + + where + bndrs_s = map snd stmtss_w_bndrs - where -- pat is the pattern ((x1,..,xn), (y1,..,ym)) in the example above - pat = TuplePat pats Boxed - pats = map (\(bs,_) -> mk_hs_tuple_pat bs) bndrstmtss + -- pat is the pattern ((x1,..,xn), (y1,..,ym)) in the example above + pat = mkTuplePat pats + pats = map mk_hs_tuple_pat bndrs_s -- Types of (x1,..,xn), (y1,..,yn) etc - qual_tys = [ mk_bndrs_tys bndrs | (bndrs,_) <- bndrstmtss ] + qual_tys = map mk_bndrs_tys bndrs_s - do_list_comp (bndrs, stmts) - = dsListComp (stmts ++ [ResultStmt (mk_hs_tuple_expr bndrs) noSrcLoc]) + do_list_comp (stmts, bndrs) + = dsListComp stmts (mk_hs_tuple_expr bndrs) (mk_bndrs_tys bndrs) - mk_bndrs_tys bndrs = mk_tuple_ty (map idType bndrs) + mk_bndrs_tys bndrs = mkCoreTupTy (map idType bndrs) -- Last: the one to return -deListComp [ResultStmt expr locn] list -- Figure 7.4, SLPJ, p 135, rule C above - = dsExpr expr `thenDs` \ core_expr -> - returnDs (mkConsExpr (exprType core_expr) core_expr list) +deListComp [] body list -- Figure 7.4, SLPJ, p 135, rule C above + = dsLExpr body `thenDs` \ core_body -> + returnDs (mkConsExpr (exprType core_body) core_body list) -- Non-last: must be a guard -deListComp (ExprStmt guard ty locn : quals) list -- rule B above - = dsExpr guard `thenDs` \ core_guard -> - deListComp quals list `thenDs` \ core_rest -> +deListComp (ExprStmt guard _ _ : quals) body list -- rule B above + = dsLExpr guard `thenDs` \ core_guard -> + deListComp quals body list `thenDs` \ core_rest -> returnDs (mkIfThenElse core_guard core_rest list) -- [e | let B, qs] = let B in [e | qs] -deListComp (LetStmt binds : quals) list - = deListComp quals list `thenDs` \ core_rest -> - dsLet binds core_rest +deListComp (LetStmt binds : quals) body list + = deListComp quals body list `thenDs` \ core_rest -> + dsLocalBinds binds core_rest -deListComp (BindStmt pat list1 locn : quals) core_list2 -- rule A' above - = dsExpr list1 `thenDs` \ core_list1 -> - deBindComp pat core_list1 quals core_list2 +deListComp (BindStmt pat list1 _ _ : quals) body core_list2 -- rule A' above + = dsLExpr list1 `thenDs` \ core_list1 -> + deBindComp pat core_list1 quals body core_list2 \end{code} \begin{code} -deBindComp pat core_list1 quals core_list2 +deBindComp pat core_list1 quals body core_list2 = let u3_ty@u1_ty = exprType core_list1 -- two names, same thing -- u1_ty is a [alpha] type, and u2_ty = alpha - u2_ty = outPatType pat + u2_ty = hsPatType pat res_ty = exprType core_list2 h_ty = u1_ty `mkFunTy` res_ty @@ -202,13 +209,15 @@ deBindComp pat core_list1 quals core_list2 core_fail = App (Var h) (Var u3) letrec_body = App (Var h) core_list1 in - deListComp quals core_fail `thenDs` \ rest_expr -> - matchSimply (Var u2) (DoCtxt ListComp) pat + deListComp quals body core_fail `thenDs` \ rest_expr -> + matchSimply (Var u2) (StmtCtxt ListComp) pat rest_expr core_fail `thenDs` \ core_match -> let rhs = Lam u1 $ - Case (Var u1) u1 [(DataAlt nilDataCon, [], core_list2), - (DataAlt consDataCon, [u2, u3], core_match)] + Case (Var u1) u1 res_ty + [(DataAlt nilDataCon, [], core_list2), + (DataAlt consDataCon, [u2, u3], core_match)] + -- Increasing order of tag in returnDs (Let (Rec [(h, rhs)]) letrec_body) \end{code} @@ -225,38 +234,36 @@ mkZipBind :: [Type] -> DsM (Id, CoreExpr) -- (a2:as'2) -> (a2,a2) : zip as'1 as'2)] mkZipBind elt_tys - = mapDs newSysLocalDs list_tys `thenDs` \ ass -> - mapDs newSysLocalDs elt_tys `thenDs` \ as' -> - mapDs newSysLocalDs list_tys `thenDs` \ as's -> + = mappM newSysLocalDs list_tys `thenDs` \ ass -> + mappM newSysLocalDs elt_tys `thenDs` \ as' -> + mappM newSysLocalDs list_tys `thenDs` \ as's -> newSysLocalDs zip_fn_ty `thenDs` \ zip_fn -> let - inner_rhs = mkConsExpr ret_elt_ty (mkTupleExpr as') (mkVarApps (Var zip_fn) as's) + inner_rhs = mkConsExpr ret_elt_ty + (mkCoreTup (map Var as')) + (mkVarApps (Var zip_fn) as's) zip_body = foldr mk_case inner_rhs (zip3 ass as' as's) in returnDs (zip_fn, mkLams ass zip_body) where - list_tys = map mkListTy elt_tys - ret_elt_ty = mk_tuple_ty elt_tys - zip_fn_ty = mkFunTys list_tys (mkListTy ret_elt_ty) + list_tys = map mkListTy elt_tys + ret_elt_ty = mkCoreTupTy elt_tys + list_ret_ty = mkListTy ret_elt_ty + zip_fn_ty = mkFunTys list_tys list_ret_ty mk_case (as, a', as') rest - = Case (Var as) as [(DataAlt nilDataCon, [], mkNilExpr ret_elt_ty), - (DataAlt consDataCon, [a', as'], rest)] - --- Helper function -mk_tuple_ty :: [Type] -> Type -mk_tuple_ty [ty] = ty -mk_tuple_ty tys = mkTupleTy Boxed (length tys) tys - + = Case (Var as) as list_ret_ty + [(DataAlt nilDataCon, [], mkNilExpr ret_elt_ty), + (DataAlt consDataCon, [a', as'], rest)] + -- Increasing order of tag -- Helper functions that makes an HsTuple only for non-1-sized tuples -mk_hs_tuple_expr :: [Id] -> TypecheckedHsExpr -mk_hs_tuple_expr [] = HsVar unitDataConId -mk_hs_tuple_expr [id] = HsVar id -mk_hs_tuple_expr ids = ExplicitTuple [ HsVar i | i <- ids ] Boxed - -mk_hs_tuple_pat :: [Id] -> TypecheckedPat -mk_hs_tuple_pat [b] = VarPat b -mk_hs_tuple_pat bs = TuplePat (map VarPat bs) Boxed +mk_hs_tuple_expr :: [Id] -> LHsExpr Id +mk_hs_tuple_expr [] = nlHsVar unitDataConId +mk_hs_tuple_expr [id] = nlHsVar id +mk_hs_tuple_expr ids = noLoc $ ExplicitTuple [ nlHsVar i | i <- ids ] Boxed + +mk_hs_tuple_pat :: [Id] -> LPat Id +mk_hs_tuple_pat bs = mkTuplePat (map nlVarPat bs) \end{code} @@ -281,31 +288,32 @@ TE[ e | p <- l , q ] c n = let \begin{code} dfListComp :: Id -> Id -- 'c' and 'n' - -> [TypecheckedStmt] -- the rest of the qual's + -> [Stmt Id] -- the rest of the qual's + -> LHsExpr Id -> DsM CoreExpr -- Last: the one to return -dfListComp c_id n_id [ResultStmt expr locn] - = dsExpr expr `thenDs` \ core_expr -> - returnDs (mkApps (Var c_id) [core_expr, Var n_id]) +dfListComp c_id n_id [] body + = dsLExpr body `thenDs` \ core_body -> + returnDs (mkApps (Var c_id) [core_body, Var n_id]) -- Non-last: must be a guard -dfListComp c_id n_id (ExprStmt guard ty locn : quals) - = dsExpr guard `thenDs` \ core_guard -> - dfListComp c_id n_id quals `thenDs` \ core_rest -> +dfListComp c_id n_id (ExprStmt guard _ _ : quals) body + = dsLExpr guard `thenDs` \ core_guard -> + dfListComp c_id n_id quals body `thenDs` \ core_rest -> returnDs (mkIfThenElse core_guard core_rest (Var n_id)) -dfListComp c_id n_id (LetStmt binds : quals) +dfListComp c_id n_id (LetStmt binds : quals) body -- new in 1.3, local bindings - = dfListComp c_id n_id quals `thenDs` \ core_rest -> - dsLet binds core_rest + = dfListComp c_id n_id quals body `thenDs` \ core_rest -> + dsLocalBinds binds core_rest -dfListComp c_id n_id (BindStmt pat list1 locn : quals) +dfListComp c_id n_id (BindStmt pat list1 _ _ : quals) body -- evaluate the two lists - = dsExpr list1 `thenDs` \ core_list1 -> + = dsLExpr list1 `thenDs` \ core_list1 -> -- find the required type - let x_ty = outPatType pat + let x_ty = hsPatType pat b_ty = idType n_id in @@ -313,14 +321,14 @@ dfListComp c_id n_id (BindStmt pat list1 locn : quals) newSysLocalsDs [b_ty,x_ty] `thenDs` \ [b,x] -> -- build rest of the comprehesion - dfListComp c_id b quals `thenDs` \ core_rest -> + dfListComp c_id b quals body `thenDs` \ core_rest -> -- build the pattern match - matchSimply (Var x) (DoCtxt ListComp) + matchSimply (Var x) (StmtCtxt ListComp) pat core_rest (Var b) `thenDs` \ core_expr -> -- now build the outermost foldr, and return - dsLookupGlobalValue foldrName `thenDs` \ foldr_id -> + dsLookupGlobalId foldrName `thenDs` \ foldr_id -> returnDs ( Var foldr_id `App` Type x_ty `App` Type b_ty @@ -342,28 +350,30 @@ dfListComp c_id n_id (BindStmt pat list1 locn : quals) -- -- [:e | qss:] = <<[:e | qss:]>> () [:():] -- -dsPArrComp :: [TypecheckedStmt] +dsPArrComp :: [Stmt Id] + -> LHsExpr Id -> Type -- Don't use; called with `undefined' below -> DsM CoreExpr -dsPArrComp qs _ = - dsLookupGlobalValue replicatePName `thenDs` \repP -> +dsPArrComp qs body _ = + dsLookupGlobalId replicatePName `thenDs` \repP -> let unitArray = mkApps (Var repP) [Type unitTy, - mkConApp intDataCon [mkIntLit 1], - mkTupleExpr []] + mkIntExpr 1, + mkCoreTup []] in - dePArrComp qs (TuplePat [] Boxed) unitArray + dePArrComp qs body (mkTuplePat []) unitArray -- the work horse -- -dePArrComp :: [TypecheckedStmt] - -> TypecheckedPat -- the current generator pattern - -> CoreExpr -- the current generator expression +dePArrComp :: [Stmt Id] + -> LHsExpr Id + -> LPat Id -- the current generator pattern + -> CoreExpr -- the current generator expression -> DsM CoreExpr -- -- <<[:e' | :]>> pa ea = mapP (\pa -> e') ea -- -dePArrComp [ResultStmt e' _] pa cea = - dsLookupGlobalValue mapPName `thenDs` \mapP -> +dePArrComp [] e' pa cea = + dsLookupGlobalId mapPName `thenDs` \mapP -> let ty = parrElemType cea in deLambda ty pa e' `thenDs` \(clam, @@ -372,36 +382,34 @@ dePArrComp [ResultStmt e' _] pa cea = -- -- <<[:e' | b, qs:]>> pa ea = <<[:e' | qs:]>> pa (filterP (\pa -> b) ea) -- -dePArrComp (ExprStmt b _ _ : qs) pa cea = - dsLookupGlobalValue filterPName `thenDs` \filterP -> +dePArrComp (ExprStmt b _ _ : qs) body pa cea = + dsLookupGlobalId filterPName `thenDs` \filterP -> let ty = parrElemType cea in - deLambda ty pa b `thenDs` \(clam,_) -> - dePArrComp qs pa (mkApps (Var filterP) [Type ty, clam, cea]) + deLambda ty pa b `thenDs` \(clam,_) -> + dePArrComp qs body pa (mkApps (Var filterP) [Type ty, clam, cea]) -- -- <<[:e' | p <- e, qs:]>> pa ea = -- let ef = filterP (\x -> case x of {p -> True; _ -> False}) e -- in -- <<[:e' | qs:]>> (pa, p) (crossP ea ef) -- -dePArrComp (BindStmt p e _ : qs) pa cea = - dsLookupGlobalValue falseDataConName `thenDs` \falseId -> - dsLookupGlobalValue trueDataConName `thenDs` \trueId -> - dsLookupGlobalValue filterPName `thenDs` \filterP -> - dsLookupGlobalValue crossPName `thenDs` \crossP -> - dsExpr e `thenDs` \ce -> +dePArrComp (BindStmt p e _ _ : qs) body pa cea = + dsLookupGlobalId filterPName `thenDs` \filterP -> + dsLookupGlobalId crossPName `thenDs` \crossP -> + dsLExpr e `thenDs` \ce -> let ty'cea = parrElemType cea ty'ce = parrElemType ce - false = Var falseId - true = Var trueId + false = Var falseDataConId + true = Var trueDataConId in newSysLocalDs ty'ce `thenDs` \v -> - matchSimply (Var v) (DoCtxt PArrComp) p true false `thenDs` \pred -> + matchSimply (Var v) (StmtCtxt PArrComp) p true false `thenDs` \pred -> let cef = mkApps (Var filterP) [Type ty'ce, mkLams [v] pred, ce] ty'cef = ty'ce -- filterP preserves the type - pa' = TuplePat [pa, p] Boxed + pa' = mkTuplePat [pa, p] in - dePArrComp qs pa' (mkApps (Var crossP) [Type ty'cea, Type ty'cef, cea, cef]) + dePArrComp qs body pa' (mkApps (Var crossP) [Type ty'cea, Type ty'cef, cea, cef]) -- -- <<[:e' | let ds, qs:]>> pa ea = -- <<[:e' | qs:]>> (pa, (x_1, ..., x_n)) @@ -409,24 +417,25 @@ dePArrComp (BindStmt p e _ : qs) pa cea = -- where -- {x_1, ..., x_n} = DV (ds) -- Defined Variables -- -dePArrComp (LetStmt ds : qs) pa cea = - dsLookupGlobalValue mapPName `thenDs` \mapP -> - let xs = collectHsOutBinders ds +dePArrComp (LetStmt ds : qs) body pa cea = + dsLookupGlobalId mapPName `thenDs` \mapP -> + let xs = map unLoc (collectLocalBinders ds) ty'cea = parrElemType cea in newSysLocalDs ty'cea `thenDs` \v -> - dsLet ds (mkTupleExpr xs) `thenDs` \clet -> + dsLocalBinds ds (mkCoreTup (map Var xs)) `thenDs` \clet -> newSysLocalDs (exprType clet) `thenDs` \let'v -> - let projBody = mkDsLet (NonRec let'v clet) $ mkTupleExpr [v, let'v] + let projBody = mkDsLet (NonRec let'v clet) $ + mkCoreTup [Var v, Var let'v] errTy = exprType projBody errMsg = "DsListComp.dePArrComp: internal error!" in mkErrorAppDs pAT_ERROR_ID errTy errMsg `thenDs` \cerr -> - matchSimply (Var v) (DoCtxt PArrComp) pa projBody cerr `thenDs` \ccase -> - let pa' = TuplePat [pa, TuplePat (map VarPat xs) Boxed] Boxed + matchSimply (Var v) (StmtCtxt PArrComp) pa projBody cerr`thenDs` \ccase -> + let pa' = mkTuplePat [pa, mkTuplePat (map nlVarPat xs)] proj = mkLams [v] ccase in - dePArrComp qs pa' (mkApps (Var mapP) [Type ty'cea, proj, cea]) + dePArrComp qs body pa' (mkApps (Var mapP) [Type ty'cea, proj, cea]) -- -- <<[:e' | qs | qss:]>> pa ea = -- <<[:e' | qss:]>> (pa, (x_1, ..., x_n)) @@ -434,33 +443,53 @@ dePArrComp (LetStmt ds : qs) pa cea = -- where -- {x_1, ..., x_n} = DV (qs) -- -dePArrComp (ParStmtOut [] : qss2) pa cea = dePArrComp qss2 pa cea -dePArrComp (ParStmtOut ((xs, qs):qss) : qss2) pa cea = - dsLookupGlobalValue zipPName `thenDs` \zipP -> - let pa' = TuplePat [pa, TuplePat (map VarPat xs) Boxed] Boxed - ty'cea = parrElemType cea - resStmt = ResultStmt (ExplicitTuple (map HsVar xs) Boxed) noSrcLoc - in - dsPArrComp (qs ++ [resStmt]) undefined `thenDs` \cqs -> - let ty'cqs = parrElemType cqs - cea' = mkApps (Var zipP) [Type ty'cea, Type ty'cqs, cea, cqs] +dePArrComp (ParStmt qss : qs) body pa cea = + dsLookupGlobalId crossPName `thenDs` \crossP -> + deParStmt qss `thenDs` \(pQss, + ceQss) -> + let ty'cea = parrElemType cea + ty'ceQss = parrElemType ceQss + pa' = mkTuplePat [pa, pQss] in - dePArrComp (ParStmtOut qss : qss2) pa' cea' + dePArrComp qs body pa' (mkApps (Var crossP) [Type ty'cea, Type ty'ceQss, + cea, ceQss]) + where + deParStmt [] = + -- empty parallel statement lists have not source representation + panic "DsListComp.dePArrComp: Empty parallel list comprehension" + deParStmt ((qs, xs):qss) = -- first statement + let res_expr = mkExplicitTuple (map nlHsVar xs) + in + dsPArrComp (map unLoc qs) res_expr undefined `thenDs` \cqs -> + parStmts qss (mkTuplePat (map nlVarPat xs)) cqs + --- + parStmts [] pa cea = return (pa, cea) + parStmts ((qs, xs):qss) pa cea = -- subsequent statements (zip'ed) + dsLookupGlobalId zipPName `thenDs` \zipP -> + let pa' = mkTuplePat [pa, mkTuplePat (map nlVarPat xs)] + ty'cea = parrElemType cea + res_expr = mkExplicitTuple (map nlHsVar xs) + in + dsPArrComp (map unLoc qs) res_expr undefined `thenDs` \cqs -> + let ty'cqs = parrElemType cqs + cea' = mkApps (Var zipP) [Type ty'cea, Type ty'cqs, cea, cqs] + in + parStmts qss pa' cea' -- generate Core corresponding to `\p -> e' -- deLambda :: Type -- type of the argument - -> TypecheckedPat -- argument pattern - -> TypecheckedHsExpr -- body + -> LPat Id -- argument pattern + -> LHsExpr Id -- body -> DsM (CoreExpr, Type) deLambda ty p e = newSysLocalDs ty `thenDs` \v -> - dsExpr e `thenDs` \ce -> + dsLExpr e `thenDs` \ce -> let errTy = exprType ce errMsg = "DsListComp.deLambda: internal error!" in - mkErrorAppDs pAT_ERROR_ID errTy errMsg `thenDs` \cerr -> - matchSimply (Var v) (DoCtxt PArrComp) p ce cerr `thenDs` \res -> + mkErrorAppDs pAT_ERROR_ID errTy errMsg `thenDs` \cerr -> + matchSimply (Var v) (StmtCtxt PArrComp) p ce cerr `thenDs` \res -> returnDs (mkLams [v] res, errTy) -- obtain the element type of the parallel array produced by the given Core @@ -469,7 +498,19 @@ deLambda ty p e = parrElemType :: CoreExpr -> Type parrElemType e = case splitTyConApp_maybe (exprType e) of - Just (tycon, [ty]) | tyConName tycon == parrTyConName -> ty + Just (tycon, [ty]) | tycon == parrTyCon -> ty _ -> panic "DsListComp.parrElemType: not a parallel array type" + +-- Smart constructor for source tuple patterns +-- +mkTuplePat :: [LPat Id] -> LPat Id +mkTuplePat [lpat] = lpat +mkTuplePat lpats = noLoc $ mkVanillaTuplePat lpats Boxed + +-- Smart constructor for source tuple expressions +-- +mkExplicitTuple :: [LHsExpr id] -> LHsExpr id +mkExplicitTuple [lexp] = lexp +mkExplicitTuple lexps = noLoc $ ExplicitTuple lexps Boxed \end{code}