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|
{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
This module converts Template Haskell syntax into HsSyn
-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE ScopedTypeVariables #-}
module Convert( convertToHsExpr, convertToPat, convertToHsDecls,
convertToHsType,
thRdrNameGuesses ) where
import GhcPrelude
import HsSyn as Hs
import qualified Class
import RdrName
import qualified Name
import Module
import RdrHsSyn
import qualified OccName
import OccName
import SrcLoc
import Type
import qualified Coercion ( Role(..) )
import TysWiredIn
import TysPrim (eqPrimTyCon)
import BasicTypes as Hs
import ForeignCall
import Unique
import ErrUtils
import Bag
import Lexeme
import Util
import FastString
import Outputable
import MonadUtils ( foldrM )
import qualified Data.ByteString as BS
import Control.Monad( unless, liftM, ap, (<=<) )
import Data.Maybe( catMaybes, isNothing )
import Language.Haskell.TH as TH hiding (sigP)
import Language.Haskell.TH.Syntax as TH
-------------------------------------------------------------------
-- The external interface
convertToHsDecls :: SrcSpan -> [TH.Dec] -> Either MsgDoc [LHsDecl GhcPs]
convertToHsDecls loc ds = initCvt loc (fmap catMaybes (mapM cvt_dec ds))
where
cvt_dec d = wrapMsg "declaration" d (cvtDec d)
convertToHsExpr :: SrcSpan -> TH.Exp -> Either MsgDoc (LHsExpr GhcPs)
convertToHsExpr loc e
= initCvt loc $ wrapMsg "expression" e $ cvtl e
convertToPat :: SrcSpan -> TH.Pat -> Either MsgDoc (LPat GhcPs)
convertToPat loc p
= initCvt loc $ wrapMsg "pattern" p $ cvtPat p
convertToHsType :: SrcSpan -> TH.Type -> Either MsgDoc (LHsType GhcPs)
convertToHsType loc t
= initCvt loc $ wrapMsg "type" t $ cvtType t
-------------------------------------------------------------------
newtype CvtM a = CvtM { unCvtM :: SrcSpan -> Either MsgDoc (SrcSpan, a) }
-- Push down the source location;
-- Can fail, with a single error message
-- NB: If the conversion succeeds with (Right x), there should
-- be no exception values hiding in x
-- Reason: so a (head []) in TH code doesn't subsequently
-- make GHC crash when it tries to walk the generated tree
-- Use the loc everywhere, for lack of anything better
-- In particular, we want it on binding locations, so that variables bound in
-- the spliced-in declarations get a location that at least relates to the splice point
instance Functor CvtM where
fmap = liftM
instance Applicative CvtM where
pure x = CvtM $ \loc -> Right (loc,x)
(<*>) = ap
instance Monad CvtM where
(CvtM m) >>= k = CvtM $ \loc -> case m loc of
Left err -> Left err
Right (loc',v) -> unCvtM (k v) loc'
initCvt :: SrcSpan -> CvtM a -> Either MsgDoc a
initCvt loc (CvtM m) = fmap snd (m loc)
force :: a -> CvtM ()
force a = a `seq` return ()
failWith :: MsgDoc -> CvtM a
failWith m = CvtM (\_ -> Left m)
getL :: CvtM SrcSpan
getL = CvtM (\loc -> Right (loc,loc))
setL :: SrcSpan -> CvtM ()
setL loc = CvtM (\_ -> Right (loc, ()))
returnL :: a -> CvtM (Located a)
returnL x = CvtM (\loc -> Right (loc, L loc x))
returnJustL :: a -> CvtM (Maybe (Located a))
returnJustL = fmap Just . returnL
wrapParL :: (Located a -> a) -> a -> CvtM a
wrapParL add_par x = CvtM (\loc -> Right (loc, add_par (L loc x)))
wrapMsg :: (Show a, TH.Ppr a) => String -> a -> CvtM b -> CvtM b
-- E.g wrapMsg "declaration" dec thing
wrapMsg what item (CvtM m)
= CvtM (\loc -> case m loc of
Left err -> Left (err $$ getPprStyle msg)
Right v -> Right v)
where
-- Show the item in pretty syntax normally,
-- but with all its constructors if you say -dppr-debug
msg sty = hang (text "When splicing a TH" <+> text what <> colon)
2 (if debugStyle sty
then text (show item)
else text (pprint item))
wrapL :: CvtM a -> CvtM (Located a)
wrapL (CvtM m) = CvtM (\loc -> case m loc of
Left err -> Left err
Right (loc',v) -> Right (loc',L loc v))
-------------------------------------------------------------------
cvtDecs :: [TH.Dec] -> CvtM [LHsDecl GhcPs]
cvtDecs = fmap catMaybes . mapM cvtDec
cvtDec :: TH.Dec -> CvtM (Maybe (LHsDecl GhcPs))
cvtDec (TH.ValD pat body ds)
| TH.VarP s <- pat
= do { s' <- vNameL s
; cl' <- cvtClause (mkPrefixFunRhs s') (Clause [] body ds)
; returnJustL $ Hs.ValD $ mkFunBind s' [cl'] }
| otherwise
= do { pat' <- cvtPat pat
; body' <- cvtGuard body
; ds' <- cvtLocalDecs (text "a where clause") ds
; returnJustL $ Hs.ValD $
PatBind { pat_lhs = pat', pat_rhs = GRHSs body' (noLoc ds')
, pat_rhs_ty = placeHolderType, bind_fvs = placeHolderNames
, pat_ticks = ([],[]) } }
cvtDec (TH.FunD nm cls)
| null cls
= failWith (text "Function binding for"
<+> quotes (text (TH.pprint nm))
<+> text "has no equations")
| otherwise
= do { nm' <- vNameL nm
; cls' <- mapM (cvtClause (mkPrefixFunRhs nm')) cls
; returnJustL $ Hs.ValD $ mkFunBind nm' cls' }
cvtDec (TH.SigD nm typ)
= do { nm' <- vNameL nm
; ty' <- cvtType typ
; returnJustL $ Hs.SigD (TypeSig [nm'] (mkLHsSigWcType ty')) }
cvtDec (TH.InfixD fx nm)
-- Fixity signatures are allowed for variables, constructors, and types
-- the renamer automatically looks for types during renaming, even when
-- the RdrName says it's a variable or a constructor. So, just assume
-- it's a variable or constructor and proceed.
= do { nm' <- vcNameL nm
; returnJustL (Hs.SigD (FixSig (FixitySig [nm'] (cvtFixity fx)))) }
cvtDec (PragmaD prag)
= cvtPragmaD prag
cvtDec (TySynD tc tvs rhs)
= do { (_, tc', tvs') <- cvt_tycl_hdr [] tc tvs
; rhs' <- cvtType rhs
; returnJustL $ TyClD $
SynDecl { tcdLName = tc', tcdTyVars = tvs'
, tcdFixity = Prefix
, tcdFVs = placeHolderNames
, tcdRhs = rhs' } }
cvtDec (DataD ctxt tc tvs ksig constrs derivs)
= do { let isGadtCon (GadtC _ _ _) = True
isGadtCon (RecGadtC _ _ _) = True
isGadtCon (ForallC _ _ c) = isGadtCon c
isGadtCon _ = False
isGadtDecl = all isGadtCon constrs
isH98Decl = all (not . isGadtCon) constrs
; unless (isGadtDecl || isH98Decl)
(failWith (text "Cannot mix GADT constructors with Haskell 98"
<+> text "constructors"))
; unless (isNothing ksig || isGadtDecl)
(failWith (text "Kind signatures are only allowed on GADTs"))
; (ctxt', tc', tvs') <- cvt_tycl_hdr ctxt tc tvs
; ksig' <- cvtKind `traverse` ksig
; cons' <- mapM cvtConstr constrs
; derivs' <- cvtDerivs derivs
; let defn = HsDataDefn { dd_ND = DataType, dd_cType = Nothing
, dd_ctxt = ctxt'
, dd_kindSig = ksig'
, dd_cons = cons', dd_derivs = derivs' }
; returnJustL $ TyClD (DataDecl { tcdLName = tc', tcdTyVars = tvs'
, tcdFixity = Prefix
, tcdDataDefn = defn
, tcdDataCusk = PlaceHolder
, tcdFVs = placeHolderNames }) }
cvtDec (NewtypeD ctxt tc tvs ksig constr derivs)
= do { (ctxt', tc', tvs') <- cvt_tycl_hdr ctxt tc tvs
; ksig' <- cvtKind `traverse` ksig
; con' <- cvtConstr constr
; derivs' <- cvtDerivs derivs
; let defn = HsDataDefn { dd_ND = NewType, dd_cType = Nothing
, dd_ctxt = ctxt'
, dd_kindSig = ksig'
, dd_cons = [con']
, dd_derivs = derivs' }
; returnJustL $ TyClD (DataDecl { tcdLName = tc', tcdTyVars = tvs'
, tcdFixity = Prefix
, tcdDataDefn = defn
, tcdDataCusk = PlaceHolder
, tcdFVs = placeHolderNames }) }
cvtDec (ClassD ctxt cl tvs fds decs)
= do { (cxt', tc', tvs') <- cvt_tycl_hdr ctxt cl tvs
; fds' <- mapM cvt_fundep fds
; (binds', sigs', fams', ats', adts') <- cvt_ci_decs (text "a class declaration") decs
; unless (null adts')
(failWith $ (text "Default data instance declarations"
<+> text "are not allowed:")
$$ (Outputable.ppr adts'))
; at_defs <- mapM cvt_at_def ats'
; returnJustL $ TyClD $
ClassDecl { tcdCtxt = cxt', tcdLName = tc', tcdTyVars = tvs'
, tcdFixity = Prefix
, tcdFDs = fds', tcdSigs = Hs.mkClassOpSigs sigs'
, tcdMeths = binds'
, tcdATs = fams', tcdATDefs = at_defs, tcdDocs = []
, tcdFVs = placeHolderNames }
-- no docs in TH ^^
}
where
cvt_at_def :: LTyFamInstDecl GhcPs -> CvtM (LTyFamDefltEqn GhcPs)
-- Very similar to what happens in RdrHsSyn.mkClassDecl
cvt_at_def decl = case RdrHsSyn.mkATDefault decl of
Right def -> return def
Left (_, msg) -> failWith msg
cvtDec (InstanceD o ctxt ty decs)
= do { let doc = text "an instance declaration"
; (binds', sigs', fams', ats', adts') <- cvt_ci_decs doc decs
; unless (null fams') (failWith (mkBadDecMsg doc fams'))
; ctxt' <- cvtContext ctxt
; L loc ty' <- cvtType ty
; let inst_ty' = mkHsQualTy ctxt loc ctxt' $ L loc ty'
; returnJustL $ InstD $ ClsInstD $
ClsInstDecl { cid_poly_ty = mkLHsSigType inst_ty'
, cid_binds = binds'
, cid_sigs = Hs.mkClassOpSigs sigs'
, cid_tyfam_insts = ats', cid_datafam_insts = adts'
, cid_overlap_mode = fmap (L loc . overlap) o } }
where
overlap pragma =
case pragma of
TH.Overlaps -> Hs.Overlaps (SourceText "OVERLAPS")
TH.Overlappable -> Hs.Overlappable (SourceText "OVERLAPPABLE")
TH.Overlapping -> Hs.Overlapping (SourceText "OVERLAPPING")
TH.Incoherent -> Hs.Incoherent (SourceText "INCOHERENT")
cvtDec (ForeignD ford)
= do { ford' <- cvtForD ford
; returnJustL $ ForD ford' }
cvtDec (DataFamilyD tc tvs kind)
= do { (_, tc', tvs') <- cvt_tycl_hdr [] tc tvs
; result <- cvtMaybeKindToFamilyResultSig kind
; returnJustL $ TyClD $ FamDecl $
FamilyDecl DataFamily tc' tvs' Prefix result Nothing }
cvtDec (DataInstD ctxt tc tys ksig constrs derivs)
= do { (ctxt', tc', typats') <- cvt_tyinst_hdr ctxt tc tys
; ksig' <- cvtKind `traverse` ksig
; cons' <- mapM cvtConstr constrs
; derivs' <- cvtDerivs derivs
; let defn = HsDataDefn { dd_ND = DataType, dd_cType = Nothing
, dd_ctxt = ctxt'
, dd_kindSig = ksig'
, dd_cons = cons', dd_derivs = derivs' }
; returnJustL $ InstD $ DataFamInstD
{ dfid_inst = DataFamInstDecl { dfid_eqn = mkHsImplicitBndrs $
FamEqn { feqn_tycon = tc', feqn_pats = typats'
, feqn_rhs = defn
, feqn_fixity = Prefix } }}}
cvtDec (NewtypeInstD ctxt tc tys ksig constr derivs)
= do { (ctxt', tc', typats') <- cvt_tyinst_hdr ctxt tc tys
; ksig' <- cvtKind `traverse` ksig
; con' <- cvtConstr constr
; derivs' <- cvtDerivs derivs
; let defn = HsDataDefn { dd_ND = NewType, dd_cType = Nothing
, dd_ctxt = ctxt'
, dd_kindSig = ksig'
, dd_cons = [con'], dd_derivs = derivs' }
; returnJustL $ InstD $ DataFamInstD
{ dfid_inst = DataFamInstDecl { dfid_eqn = mkHsImplicitBndrs $
FamEqn { feqn_tycon = tc', feqn_pats = typats'
, feqn_rhs = defn
, feqn_fixity = Prefix } }}}
cvtDec (TySynInstD tc eqn)
= do { tc' <- tconNameL tc
; L _ eqn' <- cvtTySynEqn tc' eqn
; returnJustL $ InstD $ TyFamInstD
{ tfid_inst = TyFamInstDecl { tfid_eqn = eqn' } } }
cvtDec (OpenTypeFamilyD head)
= do { (tc', tyvars', result', injectivity') <- cvt_tyfam_head head
; returnJustL $ TyClD $ FamDecl $
FamilyDecl OpenTypeFamily tc' tyvars' Prefix result' injectivity' }
cvtDec (ClosedTypeFamilyD head eqns)
= do { (tc', tyvars', result', injectivity') <- cvt_tyfam_head head
; eqns' <- mapM (cvtTySynEqn tc') eqns
; returnJustL $ TyClD $ FamDecl $
FamilyDecl (ClosedTypeFamily (Just eqns')) tc' tyvars' Prefix result'
injectivity' }
cvtDec (TH.RoleAnnotD tc roles)
= do { tc' <- tconNameL tc
; let roles' = map (noLoc . cvtRole) roles
; returnJustL $ Hs.RoleAnnotD (RoleAnnotDecl tc' roles') }
cvtDec (TH.StandaloneDerivD ds cxt ty)
= do { cxt' <- cvtContext cxt
; L loc ty' <- cvtType ty
; let inst_ty' = mkHsQualTy cxt loc cxt' $ L loc ty'
; returnJustL $ DerivD $
DerivDecl { deriv_strategy = fmap (L loc . cvtDerivStrategy) ds
, deriv_type = mkLHsSigType inst_ty'
, deriv_overlap_mode = Nothing } }
cvtDec (TH.DefaultSigD nm typ)
= do { nm' <- vNameL nm
; ty' <- cvtType typ
; returnJustL $ Hs.SigD $ ClassOpSig True [nm'] (mkLHsSigType ty') }
cvtDec (TH.PatSynD nm args dir pat)
= do { nm' <- cNameL nm
; args' <- cvtArgs args
; dir' <- cvtDir nm' dir
; pat' <- cvtPat pat
; returnJustL $ Hs.ValD $ PatSynBind $
PSB nm' placeHolderType args' pat' dir' }
where
cvtArgs (TH.PrefixPatSyn args) = Hs.PrefixPatSyn <$> mapM vNameL args
cvtArgs (TH.InfixPatSyn a1 a2) = Hs.InfixPatSyn <$> vNameL a1 <*> vNameL a2
cvtArgs (TH.RecordPatSyn sels)
= do { sels' <- mapM vNameL sels
; vars' <- mapM (vNameL . mkNameS . nameBase) sels
; return $ Hs.RecordPatSyn $ zipWith RecordPatSynField sels' vars' }
cvtDir _ Unidir = return Unidirectional
cvtDir _ ImplBidir = return ImplicitBidirectional
cvtDir n (ExplBidir cls) =
do { ms <- mapM (cvtClause (mkPrefixFunRhs n)) cls
; return $ ExplicitBidirectional $ mkMatchGroup FromSource ms }
cvtDec (TH.PatSynSigD nm ty)
= do { nm' <- cNameL nm
; ty' <- cvtPatSynSigTy ty
; returnJustL $ Hs.SigD $ PatSynSig [nm'] (mkLHsSigType ty') }
----------------
cvtTySynEqn :: Located RdrName -> TySynEqn -> CvtM (LTyFamInstEqn GhcPs)
cvtTySynEqn tc (TySynEqn lhs rhs)
= do { lhs' <- mapM (wrap_apps <=< cvtType) lhs
; rhs' <- cvtType rhs
; returnL $ mkHsImplicitBndrs
$ FamEqn { feqn_tycon = tc
, feqn_pats = lhs'
, feqn_fixity = Prefix
, feqn_rhs = rhs' } }
----------------
cvt_ci_decs :: MsgDoc -> [TH.Dec]
-> CvtM (LHsBinds GhcPs,
[LSig GhcPs],
[LFamilyDecl GhcPs],
[LTyFamInstDecl GhcPs],
[LDataFamInstDecl GhcPs])
-- Convert the declarations inside a class or instance decl
-- ie signatures, bindings, and associated types
cvt_ci_decs doc decs
= do { decs' <- cvtDecs decs
; let (ats', bind_sig_decs') = partitionWith is_tyfam_inst decs'
; let (adts', no_ats') = partitionWith is_datafam_inst bind_sig_decs'
; let (sigs', prob_binds') = partitionWith is_sig no_ats'
; let (binds', prob_fams') = partitionWith is_bind prob_binds'
; let (fams', bads) = partitionWith is_fam_decl prob_fams'
; unless (null bads) (failWith (mkBadDecMsg doc bads))
--We use FromSource as the origin of the bind
-- because the TH declaration is user-written
; return (listToBag binds', sigs', fams', ats', adts') }
----------------
cvt_tycl_hdr :: TH.Cxt -> TH.Name -> [TH.TyVarBndr]
-> CvtM ( LHsContext GhcPs
, Located RdrName
, LHsQTyVars GhcPs)
cvt_tycl_hdr cxt tc tvs
= do { cxt' <- cvtContext cxt
; tc' <- tconNameL tc
; tvs' <- cvtTvs tvs
; return (cxt', tc', tvs')
}
cvt_tyinst_hdr :: TH.Cxt -> TH.Name -> [TH.Type]
-> CvtM ( LHsContext GhcPs
, Located RdrName
, HsTyPats GhcPs)
cvt_tyinst_hdr cxt tc tys
= do { cxt' <- cvtContext cxt
; tc' <- tconNameL tc
; tys' <- mapM (wrap_apps <=< cvtType) tys
; return (cxt', tc', tys') }
----------------
cvt_tyfam_head :: TypeFamilyHead
-> CvtM ( Located RdrName
, LHsQTyVars GhcPs
, Hs.LFamilyResultSig GhcPs
, Maybe (Hs.LInjectivityAnn GhcPs))
cvt_tyfam_head (TypeFamilyHead tc tyvars result injectivity)
= do {(_, tc', tyvars') <- cvt_tycl_hdr [] tc tyvars
; result' <- cvtFamilyResultSig result
; injectivity' <- traverse cvtInjectivityAnnotation injectivity
; return (tc', tyvars', result', injectivity') }
-------------------------------------------------------------------
-- Partitioning declarations
-------------------------------------------------------------------
is_fam_decl :: LHsDecl GhcPs -> Either (LFamilyDecl GhcPs) (LHsDecl GhcPs)
is_fam_decl (L loc (TyClD (FamDecl { tcdFam = d }))) = Left (L loc d)
is_fam_decl decl = Right decl
is_tyfam_inst :: LHsDecl GhcPs -> Either (LTyFamInstDecl GhcPs) (LHsDecl GhcPs)
is_tyfam_inst (L loc (Hs.InstD (TyFamInstD { tfid_inst = d }))) = Left (L loc d)
is_tyfam_inst decl = Right decl
is_datafam_inst :: LHsDecl GhcPs
-> Either (LDataFamInstDecl GhcPs) (LHsDecl GhcPs)
is_datafam_inst (L loc (Hs.InstD (DataFamInstD { dfid_inst = d }))) = Left (L loc d)
is_datafam_inst decl = Right decl
is_sig :: LHsDecl GhcPs -> Either (LSig GhcPs) (LHsDecl GhcPs)
is_sig (L loc (Hs.SigD sig)) = Left (L loc sig)
is_sig decl = Right decl
is_bind :: LHsDecl GhcPs -> Either (LHsBind GhcPs) (LHsDecl GhcPs)
is_bind (L loc (Hs.ValD bind)) = Left (L loc bind)
is_bind decl = Right decl
mkBadDecMsg :: Outputable a => MsgDoc -> [a] -> MsgDoc
mkBadDecMsg doc bads
= sep [ text "Illegal declaration(s) in" <+> doc <> colon
, nest 2 (vcat (map Outputable.ppr bads)) ]
---------------------------------------------------
-- Data types
---------------------------------------------------
cvtConstr :: TH.Con -> CvtM (LConDecl GhcPs)
cvtConstr (NormalC c strtys)
= do { c' <- cNameL c
; cxt' <- returnL []
; tys' <- mapM cvt_arg strtys
; returnL $ mkConDeclH98 c' Nothing cxt' (PrefixCon tys') }
cvtConstr (RecC c varstrtys)
= do { c' <- cNameL c
; cxt' <- returnL []
; args' <- mapM cvt_id_arg varstrtys
; returnL $ mkConDeclH98 c' Nothing cxt'
(RecCon (noLoc args')) }
cvtConstr (InfixC st1 c st2)
= do { c' <- cNameL c
; cxt' <- returnL []
; st1' <- cvt_arg st1
; st2' <- cvt_arg st2
; returnL $ mkConDeclH98 c' Nothing cxt' (InfixCon st1' st2') }
cvtConstr (ForallC tvs ctxt con)
= do { tvs' <- cvtTvs tvs
; ctxt' <- cvtContext ctxt
; L _ con' <- cvtConstr con
; let all_tvs = hsQTvExplicit tvs' ++ hsQTvExplicit (con_qvars con')
all_cxt = add_cxt ctxt' (con_mb_cxt con')
; returnL $ con' { con_forall = not (null all_tvs)
, con_qvars = mkHsQTvs all_tvs
, con_mb_cxt = all_cxt } }
where
add_cxt lcxt Nothing = Just lcxt
add_cxt (L loc cxt1) (Just (L _ cxt2)) = Just (L loc (cxt1 ++ cxt2))
cvtConstr (GadtC c strtys ty)
= do { c' <- mapM cNameL c
; args <- mapM cvt_arg strtys
; L _ ty' <- cvtType ty
; c_ty <- mk_arr_apps args ty'
; returnL $ mkGadtDecl c' c_ty}
cvtConstr (RecGadtC c varstrtys ty)
= do { c' <- mapM cNameL c
; ty' <- cvtType ty
; rec_flds <- mapM cvt_id_arg varstrtys
; let rec_ty = noLoc (HsFunTy (noLoc $ HsRecTy rec_flds) ty')
; returnL $ mkGadtDecl c' rec_ty }
cvtSrcUnpackedness :: TH.SourceUnpackedness -> SrcUnpackedness
cvtSrcUnpackedness NoSourceUnpackedness = NoSrcUnpack
cvtSrcUnpackedness SourceNoUnpack = SrcNoUnpack
cvtSrcUnpackedness SourceUnpack = SrcUnpack
cvtSrcStrictness :: TH.SourceStrictness -> SrcStrictness
cvtSrcStrictness NoSourceStrictness = NoSrcStrict
cvtSrcStrictness SourceLazy = SrcLazy
cvtSrcStrictness SourceStrict = SrcStrict
cvt_arg :: (TH.Bang, TH.Type) -> CvtM (LHsType GhcPs)
cvt_arg (Bang su ss, ty)
= do { ty'' <- cvtType ty
; ty' <- wrap_apps ty''
; let su' = cvtSrcUnpackedness su
; let ss' = cvtSrcStrictness ss
; returnL $ HsBangTy (HsSrcBang NoSourceText su' ss') ty' }
cvt_id_arg :: (TH.Name, TH.Bang, TH.Type) -> CvtM (LConDeclField GhcPs)
cvt_id_arg (i, str, ty)
= do { L li i' <- vNameL i
; ty' <- cvt_arg (str,ty)
; return $ noLoc (ConDeclField
{ cd_fld_names
= [L li $ FieldOcc (L li i') PlaceHolder]
, cd_fld_type = ty'
, cd_fld_doc = Nothing}) }
cvtDerivs :: [TH.DerivClause] -> CvtM (HsDeriving GhcPs)
cvtDerivs cs = do { cs' <- mapM cvtDerivClause cs
; returnL cs' }
cvt_fundep :: FunDep -> CvtM (Located (Class.FunDep (Located RdrName)))
cvt_fundep (FunDep xs ys) = do { xs' <- mapM tNameL xs
; ys' <- mapM tNameL ys
; returnL (xs', ys') }
------------------------------------------
-- Foreign declarations
------------------------------------------
cvtForD :: Foreign -> CvtM (ForeignDecl GhcPs)
cvtForD (ImportF callconv safety from nm ty)
-- the prim and javascript calling conventions do not support headers
-- and are inserted verbatim, analogous to mkImport in RdrHsSyn
| callconv == TH.Prim || callconv == TH.JavaScript
= mk_imp (CImport (noLoc (cvt_conv callconv)) (noLoc safety') Nothing
(CFunction (StaticTarget (SourceText from)
(mkFastString from) Nothing
True))
(noLoc $ quotedSourceText from))
| Just impspec <- parseCImport (noLoc (cvt_conv callconv)) (noLoc safety')
(mkFastString (TH.nameBase nm))
from (noLoc $ quotedSourceText from)
= mk_imp impspec
| otherwise
= failWith $ text (show from) <+> text "is not a valid ccall impent"
where
mk_imp impspec
= do { nm' <- vNameL nm
; ty' <- cvtType ty
; return (ForeignImport { fd_name = nm'
, fd_sig_ty = mkLHsSigType ty'
, fd_co = noForeignImportCoercionYet
, fd_fi = impspec })
}
safety' = case safety of
Unsafe -> PlayRisky
Safe -> PlaySafe
Interruptible -> PlayInterruptible
cvtForD (ExportF callconv as nm ty)
= do { nm' <- vNameL nm
; ty' <- cvtType ty
; let e = CExport (noLoc (CExportStatic (SourceText as)
(mkFastString as)
(cvt_conv callconv)))
(noLoc (SourceText as))
; return $ ForeignExport { fd_name = nm'
, fd_sig_ty = mkLHsSigType ty'
, fd_co = noForeignExportCoercionYet
, fd_fe = e } }
cvt_conv :: TH.Callconv -> CCallConv
cvt_conv TH.CCall = CCallConv
cvt_conv TH.StdCall = StdCallConv
cvt_conv TH.CApi = CApiConv
cvt_conv TH.Prim = PrimCallConv
cvt_conv TH.JavaScript = JavaScriptCallConv
------------------------------------------
-- Pragmas
------------------------------------------
cvtPragmaD :: Pragma -> CvtM (Maybe (LHsDecl GhcPs))
cvtPragmaD (InlineP nm inline rm phases)
= do { nm' <- vNameL nm
; let dflt = dfltActivation inline
; let src TH.NoInline = "{-# NOINLINE"
src TH.Inline = "{-# INLINE"
src TH.Inlinable = "{-# INLINABLE"
; let ip = InlinePragma { inl_src = SourceText $ src inline
, inl_inline = cvtInline inline
, inl_rule = cvtRuleMatch rm
, inl_act = cvtPhases phases dflt
, inl_sat = Nothing }
; returnJustL $ Hs.SigD $ InlineSig nm' ip }
cvtPragmaD (SpecialiseP nm ty inline phases)
= do { nm' <- vNameL nm
; ty' <- cvtType ty
; let src TH.NoInline = "{-# SPECIALISE NOINLINE"
src TH.Inline = "{-# SPECIALISE INLINE"
src TH.Inlinable = "{-# SPECIALISE INLINE"
; let (inline', dflt,srcText) = case inline of
Just inline1 -> (cvtInline inline1, dfltActivation inline1,
src inline1)
Nothing -> (NoUserInline, AlwaysActive,
"{-# SPECIALISE")
; let ip = InlinePragma { inl_src = SourceText srcText
, inl_inline = inline'
, inl_rule = Hs.FunLike
, inl_act = cvtPhases phases dflt
, inl_sat = Nothing }
; returnJustL $ Hs.SigD $ SpecSig nm' [mkLHsSigType ty'] ip }
cvtPragmaD (SpecialiseInstP ty)
= do { ty' <- cvtType ty
; returnJustL $ Hs.SigD $
SpecInstSig (SourceText "{-# SPECIALISE") (mkLHsSigType ty') }
cvtPragmaD (RuleP nm bndrs lhs rhs phases)
= do { let nm' = mkFastString nm
; let act = cvtPhases phases AlwaysActive
; bndrs' <- mapM cvtRuleBndr bndrs
; lhs' <- cvtl lhs
; rhs' <- cvtl rhs
; returnJustL $ Hs.RuleD
$ HsRules (SourceText "{-# RULES")
[noLoc $ HsRule (noLoc (SourceText nm,nm')) act bndrs'
lhs' placeHolderNames
rhs' placeHolderNames]
}
cvtPragmaD (AnnP target exp)
= do { exp' <- cvtl exp
; target' <- case target of
ModuleAnnotation -> return ModuleAnnProvenance
TypeAnnotation n -> do
n' <- tconName n
return (TypeAnnProvenance (noLoc n'))
ValueAnnotation n -> do
n' <- vcName n
return (ValueAnnProvenance (noLoc n'))
; returnJustL $ Hs.AnnD $ HsAnnotation (SourceText "{-# ANN") target'
exp'
}
cvtPragmaD (LineP line file)
= do { setL (srcLocSpan (mkSrcLoc (fsLit file) line 1))
; return Nothing
}
cvtPragmaD (CompleteP cls mty)
= do { cls' <- noLoc <$> mapM cNameL cls
; mty' <- traverse tconNameL mty
; returnJustL $ Hs.SigD
$ CompleteMatchSig NoSourceText cls' mty' }
dfltActivation :: TH.Inline -> Activation
dfltActivation TH.NoInline = NeverActive
dfltActivation _ = AlwaysActive
cvtInline :: TH.Inline -> Hs.InlineSpec
cvtInline TH.NoInline = Hs.NoInline
cvtInline TH.Inline = Hs.Inline
cvtInline TH.Inlinable = Hs.Inlinable
cvtRuleMatch :: TH.RuleMatch -> RuleMatchInfo
cvtRuleMatch TH.ConLike = Hs.ConLike
cvtRuleMatch TH.FunLike = Hs.FunLike
cvtPhases :: TH.Phases -> Activation -> Activation
cvtPhases AllPhases dflt = dflt
cvtPhases (FromPhase i) _ = ActiveAfter NoSourceText i
cvtPhases (BeforePhase i) _ = ActiveBefore NoSourceText i
cvtRuleBndr :: TH.RuleBndr -> CvtM (Hs.LRuleBndr GhcPs)
cvtRuleBndr (RuleVar n)
= do { n' <- vNameL n
; return $ noLoc $ Hs.RuleBndr n' }
cvtRuleBndr (TypedRuleVar n ty)
= do { n' <- vNameL n
; ty' <- cvtType ty
; return $ noLoc $ Hs.RuleBndrSig n' $ mkLHsSigWcType ty' }
---------------------------------------------------
-- Declarations
---------------------------------------------------
cvtLocalDecs :: MsgDoc -> [TH.Dec] -> CvtM (HsLocalBinds GhcPs)
cvtLocalDecs doc ds
| null ds
= return EmptyLocalBinds
| otherwise
= do { ds' <- cvtDecs ds
; let (binds, prob_sigs) = partitionWith is_bind ds'
; let (sigs, bads) = partitionWith is_sig prob_sigs
; unless (null bads) (failWith (mkBadDecMsg doc bads))
; return (HsValBinds (ValBindsIn (listToBag binds) sigs)) }
cvtClause :: HsMatchContext RdrName
-> TH.Clause -> CvtM (Hs.LMatch GhcPs (LHsExpr GhcPs))
cvtClause ctxt (Clause ps body wheres)
= do { ps' <- cvtPats ps
; pps <- mapM wrap_conpat ps'
; g' <- cvtGuard body
; ds' <- cvtLocalDecs (text "a where clause") wheres
; returnL $ Hs.Match ctxt pps (GRHSs g' (noLoc ds')) }
-------------------------------------------------------------------
-- Expressions
-------------------------------------------------------------------
cvtl :: TH.Exp -> CvtM (LHsExpr GhcPs)
cvtl e = wrapL (cvt e)
where
cvt (VarE s) = do { s' <- vName s; return $ HsVar (noLoc s') }
cvt (ConE s) = do { s' <- cName s; return $ HsVar (noLoc s') }
cvt (LitE l)
| overloadedLit l = do { l' <- cvtOverLit l; return $ HsOverLit l' }
| otherwise = do { l' <- cvtLit l; return $ HsLit l' }
cvt (AppE x@(LamE _ _) y) = do { x' <- cvtl x; y' <- cvtl y
; return $ HsApp (mkLHsPar x') (mkLHsPar y')}
cvt (AppE x y) = do { x' <- cvtl x; y' <- cvtl y
; return $ HsApp (mkLHsPar x') (mkLHsPar y')}
cvt (AppTypeE e t) = do { e' <- cvtl e
; t' <- cvtType t
; tp <- wrap_apps t'
; return $ HsAppType e' $ mkHsWildCardBndrs tp }
cvt (LamE [] e) = cvt e -- Degenerate case. We convert the body as its
-- own expression to avoid pretty-printing
-- oddities that can result from zero-argument
-- lambda expressions. See #13856.
cvt (LamE ps e) = do { ps' <- cvtPats ps; e' <- cvtl e
; return $ HsLam (mkMatchGroup FromSource
[mkSimpleMatch LambdaExpr ps' e'])}
cvt (LamCaseE ms) = do { ms' <- mapM (cvtMatch LambdaExpr) ms
; return $ HsLamCase (mkMatchGroup FromSource ms')
}
cvt (TupE [e]) = do { e' <- cvtl e; return $ HsPar e' }
-- Note [Dropping constructors]
-- Singleton tuples treated like nothing (just parens)
cvt (TupE es) = do { es' <- mapM cvtl es
; return $ ExplicitTuple (map (noLoc . Present) es')
Boxed }
cvt (UnboxedTupE es) = do { es' <- mapM cvtl es
; return $ ExplicitTuple
(map (noLoc . Present) es') Unboxed }
cvt (UnboxedSumE e alt arity) = do { e' <- cvtl e
; unboxedSumChecks alt arity
; return $ ExplicitSum
alt arity e' placeHolderType }
cvt (CondE x y z) = do { x' <- cvtl x; y' <- cvtl y; z' <- cvtl z;
; return $ HsIf (Just noSyntaxExpr) x' y' z' }
cvt (MultiIfE alts)
| null alts = failWith (text "Multi-way if-expression with no alternatives")
| otherwise = do { alts' <- mapM cvtpair alts
; return $ HsMultiIf placeHolderType alts' }
cvt (LetE ds e) = do { ds' <- cvtLocalDecs (text "a let expression") ds
; e' <- cvtl e; return $ HsLet (noLoc ds') e' }
cvt (CaseE e ms) = do { e' <- cvtl e; ms' <- mapM (cvtMatch CaseAlt) ms
; return $ HsCase e' (mkMatchGroup FromSource ms') }
cvt (DoE ss) = cvtHsDo DoExpr ss
cvt (CompE ss) = cvtHsDo ListComp ss
cvt (ArithSeqE dd) = do { dd' <- cvtDD dd; return $ ArithSeq noPostTcExpr Nothing dd' }
cvt (ListE xs)
| Just s <- allCharLs xs = do { l' <- cvtLit (StringL s); return (HsLit l') }
-- Note [Converting strings]
| otherwise = do { xs' <- mapM cvtl xs
; return $ ExplicitList placeHolderType Nothing xs'
}
-- Infix expressions
cvt (InfixE (Just x) s (Just y)) = do { x' <- cvtl x; s' <- cvtl s; y' <- cvtl y
; wrapParL HsPar $
OpApp (mkLHsPar x') s' undefined (mkLHsPar y') }
-- Parenthesise both arguments and result,
-- to ensure this operator application does
-- does not get re-associated
-- See Note [Operator association]
cvt (InfixE Nothing s (Just y)) = do { s' <- cvtl s; y' <- cvtl y
; wrapParL HsPar $ SectionR s' y' }
-- See Note [Sections in HsSyn] in HsExpr
cvt (InfixE (Just x) s Nothing ) = do { x' <- cvtl x; s' <- cvtl s
; wrapParL HsPar $ SectionL x' s' }
cvt (InfixE Nothing s Nothing ) = do { s' <- cvtl s; return $ HsPar s' }
-- Can I indicate this is an infix thing?
-- Note [Dropping constructors]
cvt (UInfixE x s y) = do { x' <- cvtl x
; let x'' = case x' of
L _ (OpApp {}) -> x'
_ -> mkLHsPar x'
; cvtOpApp x'' s y } -- Note [Converting UInfix]
cvt (ParensE e) = do { e' <- cvtl e; return $ HsPar e' }
cvt (SigE e t) = do { e' <- cvtl e; t' <- cvtType t
; return $ ExprWithTySig e' (mkLHsSigWcType t') }
cvt (RecConE c flds) = do { c' <- cNameL c
; flds' <- mapM (cvtFld (mkFieldOcc . noLoc)) flds
; return $ mkRdrRecordCon c' (HsRecFields flds' Nothing) }
cvt (RecUpdE e flds) = do { e' <- cvtl e
; flds'
<- mapM (cvtFld (mkAmbiguousFieldOcc . noLoc))
flds
; return $ mkRdrRecordUpd e' flds' }
cvt (StaticE e) = fmap (HsStatic placeHolderNames) $ cvtl e
cvt (UnboundVarE s) = do { s' <- vName s; return $ HsVar (noLoc s') }
cvt (LabelE s) = do { return $ HsOverLabel Nothing (fsLit s) }
{- Note [Dropping constructors]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When we drop constructors from the input (for instance, when we encounter @TupE [e]@)
we must insert parentheses around the argument. Otherwise, @UInfix@ constructors in @e@
could meet @UInfix@ constructors containing the @TupE [e]@. For example:
UInfixE x * (TupE [UInfixE y + z])
If we drop the singleton tuple but don't insert parentheses, the @UInfixE@s would meet
and the above expression would be reassociated to
OpApp (OpApp x * y) + z
which we don't want.
-}
cvtFld :: (RdrName -> t) -> (TH.Name, TH.Exp)
-> CvtM (LHsRecField' t (LHsExpr GhcPs))
cvtFld f (v,e)
= do { v' <- vNameL v; e' <- cvtl e
; return (noLoc $ HsRecField { hsRecFieldLbl = fmap f v'
, hsRecFieldArg = e'
, hsRecPun = False}) }
cvtDD :: Range -> CvtM (ArithSeqInfo GhcPs)
cvtDD (FromR x) = do { x' <- cvtl x; return $ From x' }
cvtDD (FromThenR x y) = do { x' <- cvtl x; y' <- cvtl y; return $ FromThen x' y' }
cvtDD (FromToR x y) = do { x' <- cvtl x; y' <- cvtl y; return $ FromTo x' y' }
cvtDD (FromThenToR x y z) = do { x' <- cvtl x; y' <- cvtl y; z' <- cvtl z; return $ FromThenTo x' y' z' }
{- Note [Operator assocation]
We must be quite careful about adding parens:
* Infix (UInfix ...) op arg Needs parens round the first arg
* Infix (Infix ...) op arg Needs parens round the first arg
* UInfix (UInfix ...) op arg No parens for first arg
* UInfix (Infix ...) op arg Needs parens round first arg
Note [Converting UInfix]
~~~~~~~~~~~~~~~~~~~~~~~~
When converting @UInfixE@, @UInfixP@, and @UInfixT@ values, we want to readjust
the trees to reflect the fixities of the underlying operators:
UInfixE x * (UInfixE y + z) ---> (x * y) + z
This is done by the renamer (see @mkOppAppRn@, @mkConOppPatRn@, and
@mkHsOpTyRn@ in RnTypes), which expects that the input will be completely
right-biased for types and left-biased for everything else. So we left-bias the
trees of @UInfixP@ and @UInfixE@ and use HsAppsTy for UInfixT.
Sample input:
UInfixE
(UInfixE x op1 y)
op2
(UInfixE z op3 w)
Sample output:
OpApp
(OpApp
(OpApp x op1 y)
op2
z)
op3
w
The functions @cvtOpApp@, @cvtOpAppP@, and @cvtOpAppT@ are responsible for this
biasing.
-}
{- | @cvtOpApp x op y@ converts @op@ and @y@ and produces the operator application @x `op` y@.
The produced tree of infix expressions will be left-biased, provided @x@ is.
We can see that @cvtOpApp@ is correct as follows. The inductive hypothesis
is that @cvtOpApp x op y@ is left-biased, provided @x@ is. It is clear that
this holds for both branches (of @cvtOpApp@), provided we assume it holds for
the recursive calls to @cvtOpApp@.
When we call @cvtOpApp@ from @cvtl@, the first argument will always be left-biased
since we have already run @cvtl@ on it.
-}
cvtOpApp :: LHsExpr GhcPs -> TH.Exp -> TH.Exp -> CvtM (HsExpr GhcPs)
cvtOpApp x op1 (UInfixE y op2 z)
= do { l <- wrapL $ cvtOpApp x op1 y
; cvtOpApp l op2 z }
cvtOpApp x op y
= do { op' <- cvtl op
; y' <- cvtl y
; return (OpApp x op' undefined y') }
-------------------------------------
-- Do notation and statements
-------------------------------------
cvtHsDo :: HsStmtContext Name.Name -> [TH.Stmt] -> CvtM (HsExpr GhcPs)
cvtHsDo do_or_lc stmts
| null stmts = failWith (text "Empty stmt list in do-block")
| otherwise
= do { stmts' <- cvtStmts stmts
; let Just (stmts'', last') = snocView stmts'
; last'' <- case last' of
L loc (BodyStmt body _ _ _) -> return (L loc (mkLastStmt body))
_ -> failWith (bad_last last')
; return $ HsDo do_or_lc (noLoc (stmts'' ++ [last''])) placeHolderType }
where
bad_last stmt = vcat [ text "Illegal last statement of" <+> pprAStmtContext do_or_lc <> colon
, nest 2 $ Outputable.ppr stmt
, text "(It should be an expression.)" ]
cvtStmts :: [TH.Stmt] -> CvtM [Hs.LStmt GhcPs (LHsExpr GhcPs)]
cvtStmts = mapM cvtStmt
cvtStmt :: TH.Stmt -> CvtM (Hs.LStmt GhcPs (LHsExpr GhcPs))
cvtStmt (NoBindS e) = do { e' <- cvtl e; returnL $ mkBodyStmt e' }
cvtStmt (TH.BindS p e) = do { p' <- cvtPat p; e' <- cvtl e; returnL $ mkBindStmt p' e' }
cvtStmt (TH.LetS ds) = do { ds' <- cvtLocalDecs (text "a let binding") ds
; returnL $ LetStmt (noLoc ds') }
cvtStmt (TH.ParS dss) = do { dss' <- mapM cvt_one dss; returnL $ ParStmt dss' noExpr noSyntaxExpr placeHolderType }
where
cvt_one ds = do { ds' <- cvtStmts ds; return (ParStmtBlock ds' undefined noSyntaxExpr) }
cvtMatch :: HsMatchContext RdrName
-> TH.Match -> CvtM (Hs.LMatch GhcPs (LHsExpr GhcPs))
cvtMatch ctxt (TH.Match p body decs)
= do { p' <- cvtPat p
; lp <- case ctxt of
CaseAlt -> return p'
_ -> wrap_conpat p'
; g' <- cvtGuard body
; decs' <- cvtLocalDecs (text "a where clause") decs
; returnL $ Hs.Match ctxt [lp] (GRHSs g' (noLoc decs')) }
cvtGuard :: TH.Body -> CvtM [LGRHS GhcPs (LHsExpr GhcPs)]
cvtGuard (GuardedB pairs) = mapM cvtpair pairs
cvtGuard (NormalB e) = do { e' <- cvtl e; g' <- returnL $ GRHS [] e'; return [g'] }
cvtpair :: (TH.Guard, TH.Exp) -> CvtM (LGRHS GhcPs (LHsExpr GhcPs))
cvtpair (NormalG ge,rhs) = do { ge' <- cvtl ge; rhs' <- cvtl rhs
; g' <- returnL $ mkBodyStmt ge'
; returnL $ GRHS [g'] rhs' }
cvtpair (PatG gs,rhs) = do { gs' <- cvtStmts gs; rhs' <- cvtl rhs
; returnL $ GRHS gs' rhs' }
cvtOverLit :: Lit -> CvtM (HsOverLit GhcPs)
cvtOverLit (IntegerL i)
= do { force i; return $ mkHsIntegral (mkIntegralLit i) placeHolderType}
cvtOverLit (RationalL r)
= do { force r; return $ mkHsFractional (mkFractionalLit r) placeHolderType}
cvtOverLit (StringL s)
= do { let { s' = mkFastString s }
; force s'
; return $ mkHsIsString (quotedSourceText s) s' placeHolderType
}
cvtOverLit _ = panic "Convert.cvtOverLit: Unexpected overloaded literal"
-- An Integer is like an (overloaded) '3' in a Haskell source program
-- Similarly 3.5 for fractionals
{- Note [Converting strings]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If we get (ListE [CharL 'x', CharL 'y']) we'd like to convert to
a string literal for "xy". Of course, we might hope to get
(LitE (StringL "xy")), but not always, and allCharLs fails quickly
if it isn't a literal string
-}
allCharLs :: [TH.Exp] -> Maybe String
-- Note [Converting strings]
-- NB: only fire up this setup for a non-empty list, else
-- there's a danger of returning "" for [] :: [Int]!
allCharLs xs
= case xs of
LitE (CharL c) : ys -> go [c] ys
_ -> Nothing
where
go cs [] = Just (reverse cs)
go cs (LitE (CharL c) : ys) = go (c:cs) ys
go _ _ = Nothing
cvtLit :: Lit -> CvtM (HsLit GhcPs)
cvtLit (IntPrimL i) = do { force i; return $ HsIntPrim NoSourceText i }
cvtLit (WordPrimL w) = do { force w; return $ HsWordPrim NoSourceText w }
cvtLit (FloatPrimL f)
= do { force f; return $ HsFloatPrim def (mkFractionalLit f) }
cvtLit (DoublePrimL f)
= do { force f; return $ HsDoublePrim def (mkFractionalLit f) }
cvtLit (CharL c) = do { force c; return $ HsChar NoSourceText c }
cvtLit (CharPrimL c) = do { force c; return $ HsCharPrim NoSourceText c }
cvtLit (StringL s) = do { let { s' = mkFastString s }
; force s'
; return $ HsString (quotedSourceText s) s' }
cvtLit (StringPrimL s) = do { let { s' = BS.pack s }
; force s'
; return $ HsStringPrim NoSourceText s' }
cvtLit _ = panic "Convert.cvtLit: Unexpected literal"
-- cvtLit should not be called on IntegerL, RationalL
-- That precondition is established right here in
-- Convert.hs, hence panic
quotedSourceText :: String -> SourceText
quotedSourceText s = SourceText $ "\"" ++ s ++ "\""
cvtPats :: [TH.Pat] -> CvtM [Hs.LPat GhcPs]
cvtPats pats = mapM cvtPat pats
cvtPat :: TH.Pat -> CvtM (Hs.LPat GhcPs)
cvtPat pat = wrapL (cvtp pat)
cvtp :: TH.Pat -> CvtM (Hs.Pat GhcPs)
cvtp (TH.LitP l)
| overloadedLit l = do { l' <- cvtOverLit l
; return (mkNPat (noLoc l') Nothing) }
-- Not right for negative patterns;
-- need to think about that!
| otherwise = do { l' <- cvtLit l; return $ Hs.LitPat l' }
cvtp (TH.VarP s) = do { s' <- vName s; return $ Hs.VarPat (noLoc s') }
cvtp (TupP [p]) = do { p' <- cvtPat p; return $ ParPat p' } -- Note [Dropping constructors]
cvtp (TupP ps) = do { ps' <- cvtPats ps; return $ TuplePat ps' Boxed [] }
cvtp (UnboxedTupP ps) = do { ps' <- cvtPats ps; return $ TuplePat ps' Unboxed [] }
cvtp (UnboxedSumP p alt arity)
= do { p' <- cvtPat p
; unboxedSumChecks alt arity
; return $ SumPat p' alt arity placeHolderType }
cvtp (ConP s ps) = do { s' <- cNameL s; ps' <- cvtPats ps
; pps <- mapM wrap_conpat ps'
; return $ ConPatIn s' (PrefixCon pps) }
cvtp (InfixP p1 s p2) = do { s' <- cNameL s; p1' <- cvtPat p1; p2' <- cvtPat p2
; wrapParL ParPat $
ConPatIn s' (InfixCon (mkParPat p1') (mkParPat p2')) }
-- See Note [Operator association]
cvtp (UInfixP p1 s p2) = do { p1' <- cvtPat p1; cvtOpAppP p1' s p2 } -- Note [Converting UInfix]
cvtp (ParensP p) = do { p' <- cvtPat p;
; case p' of -- may be wrapped ConPatIn
(L _ (ParPat {})) -> return $ unLoc p'
_ -> return $ ParPat p' }
cvtp (TildeP p) = do { p' <- cvtPat p; return $ LazyPat p' }
cvtp (BangP p) = do { p' <- cvtPat p; return $ BangPat p' }
cvtp (TH.AsP s p) = do { s' <- vNameL s; p' <- cvtPat p; return $ AsPat s' p' }
cvtp TH.WildP = return $ WildPat placeHolderType
cvtp (RecP c fs) = do { c' <- cNameL c; fs' <- mapM cvtPatFld fs
; return $ ConPatIn c'
$ Hs.RecCon (HsRecFields fs' Nothing) }
cvtp (ListP ps) = do { ps' <- cvtPats ps
; return $ ListPat ps' placeHolderType Nothing }
cvtp (SigP p t) = do { p' <- cvtPat p; t' <- cvtType t
; return $ SigPatIn p' (mkLHsSigWcType t') }
cvtp (ViewP e p) = do { e' <- cvtl e; p' <- cvtPat p
; return $ ViewPat e' p' placeHolderType }
cvtPatFld :: (TH.Name, TH.Pat) -> CvtM (LHsRecField GhcPs (LPat GhcPs))
cvtPatFld (s,p)
= do { L ls s' <- vNameL s; p' <- cvtPat p
; return (noLoc $ HsRecField { hsRecFieldLbl
= L ls $ mkFieldOcc (L ls s')
, hsRecFieldArg = p'
, hsRecPun = False}) }
wrap_conpat :: Hs.LPat GhcPs -> CvtM (Hs.LPat GhcPs)
wrap_conpat p@(L _ (ConPatIn _ (InfixCon{}))) = returnL $ ParPat p
wrap_conpat p@(L _ (ConPatIn _ (PrefixCon []))) = return p
wrap_conpat p@(L _ (ConPatIn _ (PrefixCon _))) = returnL $ ParPat p
wrap_conpat p = return p
{- | @cvtOpAppP x op y@ converts @op@ and @y@ and produces the operator application @x `op` y@.
The produced tree of infix patterns will be left-biased, provided @x@ is.
See the @cvtOpApp@ documentation for how this function works.
-}
cvtOpAppP :: Hs.LPat GhcPs -> TH.Name -> TH.Pat -> CvtM (Hs.Pat GhcPs)
cvtOpAppP x op1 (UInfixP y op2 z)
= do { l <- wrapL $ cvtOpAppP x op1 y
; cvtOpAppP l op2 z }
cvtOpAppP x op y
= do { op' <- cNameL op
; y' <- cvtPat y
; return (ConPatIn op' (InfixCon x y')) }
-----------------------------------------------------------
-- Types and type variables
cvtTvs :: [TH.TyVarBndr] -> CvtM (LHsQTyVars GhcPs)
cvtTvs tvs = do { tvs' <- mapM cvt_tv tvs; return (mkHsQTvs tvs') }
cvt_tv :: TH.TyVarBndr -> CvtM (LHsTyVarBndr GhcPs)
cvt_tv (TH.PlainTV nm)
= do { nm' <- tNameL nm
; returnL $ UserTyVar nm' }
cvt_tv (TH.KindedTV nm ki)
= do { nm' <- tNameL nm
; ki' <- cvtKind ki
; returnL $ KindedTyVar nm' ki' }
cvtRole :: TH.Role -> Maybe Coercion.Role
cvtRole TH.NominalR = Just Coercion.Nominal
cvtRole TH.RepresentationalR = Just Coercion.Representational
cvtRole TH.PhantomR = Just Coercion.Phantom
cvtRole TH.InferR = Nothing
cvtContext :: TH.Cxt -> CvtM (LHsContext GhcPs)
cvtContext tys = do { preds' <- mapM cvtPred tys; returnL preds' }
cvtPred :: TH.Pred -> CvtM (LHsType GhcPs)
cvtPred = cvtType
cvtDerivClause :: TH.DerivClause
-> CvtM (LHsDerivingClause GhcPs)
cvtDerivClause (TH.DerivClause ds ctxt)
= do { ctxt'@(L loc _) <- fmap (map mkLHsSigType) <$> cvtContext ctxt
; let ds' = fmap (L loc . cvtDerivStrategy) ds
; returnL $ HsDerivingClause ds' ctxt' }
cvtDerivStrategy :: TH.DerivStrategy -> Hs.DerivStrategy
cvtDerivStrategy TH.StockStrategy = Hs.StockStrategy
cvtDerivStrategy TH.AnyclassStrategy = Hs.AnyclassStrategy
cvtDerivStrategy TH.NewtypeStrategy = Hs.NewtypeStrategy
cvtType :: TH.Type -> CvtM (LHsType GhcPs)
cvtType = cvtTypeKind "type"
cvtTypeKind :: String -> TH.Type -> CvtM (LHsType GhcPs)
cvtTypeKind ty_str ty
= do { (head_ty, tys') <- split_ty_app ty
; case head_ty of
TupleT n
| tys' `lengthIs` n -- Saturated
-> if n==1 then return (head tys') -- Singleton tuples treated
-- like nothing (ie just parens)
else returnL (HsTupleTy HsBoxedOrConstraintTuple tys')
| n == 1
-> failWith (ptext (sLit ("Illegal 1-tuple " ++ ty_str ++ " constructor")))
| otherwise
-> mk_apps (HsTyVar NotPromoted
(noLoc (getRdrName (tupleTyCon Boxed n)))) tys'
UnboxedTupleT n
| tys' `lengthIs` n -- Saturated
-> returnL (HsTupleTy HsUnboxedTuple tys')
| otherwise
-> mk_apps (HsTyVar NotPromoted
(noLoc (getRdrName (tupleTyCon Unboxed n)))) tys'
UnboxedSumT n
| n < 2
-> failWith $
vcat [ text "Illegal sum arity:" <+> text (show n)
, nest 2 $
text "Sums must have an arity of at least 2" ]
| tys' `lengthIs` n -- Saturated
-> returnL (HsSumTy tys')
| otherwise
-> mk_apps (HsTyVar NotPromoted (noLoc (getRdrName (sumTyCon n))))
tys'
ArrowT
| [x',y'] <- tys' -> do
case x' of
(L _ HsFunTy{}) -> do { x'' <- returnL (HsParTy x')
; returnL (HsFunTy x'' y') }
_ -> returnL (HsFunTy x' y')
| otherwise ->
mk_apps (HsTyVar NotPromoted (noLoc (getRdrName funTyCon)))
tys'
ListT
| [x'] <- tys' -> returnL (HsListTy x')
| otherwise ->
mk_apps (HsTyVar NotPromoted (noLoc (getRdrName listTyCon)))
tys'
VarT nm -> do { nm' <- tNameL nm
; mk_apps (HsTyVar NotPromoted nm') tys' }
ConT nm -> do { nm' <- tconName nm
; mk_apps (HsTyVar NotPromoted (noLoc nm')) tys' }
ForallT tvs cxt ty
| null tys'
-> do { tvs' <- cvtTvs tvs
; cxt' <- cvtContext cxt
; ty' <- cvtType ty
; loc <- getL
; let hs_ty = mkHsForAllTy tvs loc tvs' rho_ty
rho_ty = mkHsQualTy cxt loc cxt' ty'
; return hs_ty }
SigT ty ki
-> do { ty' <- cvtType ty
; ki' <- cvtKind ki
; mk_apps (HsKindSig ty' ki') tys'
}
LitT lit
-> returnL (HsTyLit (cvtTyLit lit))
WildCardT
-> mk_apps mkAnonWildCardTy tys'
InfixT t1 s t2
-> do { s' <- tconName s
; t1' <- cvtType t1
; t2' <- cvtType t2
; mk_apps (HsTyVar NotPromoted (noLoc s')) [t1', t2']
}
UInfixT t1 s t2
-> do { t1' <- cvtType t1
; t2' <- cvtType t2
; s' <- tconName s
; return $ cvtOpAppT t1' s' t2'
} -- Note [Converting UInfix]
ParensT t
-> do { t' <- cvtType t
; returnL $ HsParTy t'
}
PromotedT nm -> do { nm' <- cName nm
; mk_apps (HsTyVar NotPromoted (noLoc nm')) tys' }
-- Promoted data constructor; hence cName
PromotedTupleT n
| n == 1
-> failWith (ptext (sLit ("Illegal promoted 1-tuple " ++ ty_str)))
| m == n -- Saturated
-> do { let kis = replicate m placeHolderKind
; returnL (HsExplicitTupleTy kis tys')
}
where
m = length tys'
PromotedNilT
-> returnL (HsExplicitListTy Promoted placeHolderKind [])
PromotedConsT -- See Note [Representing concrete syntax in types]
-- in Language.Haskell.TH.Syntax
| [ty1, L _ (HsExplicitListTy ip _ tys2)] <- tys'
-> returnL (HsExplicitListTy ip placeHolderKind (ty1:tys2))
| otherwise
-> mk_apps (HsTyVar NotPromoted (noLoc (getRdrName consDataCon)))
tys'
StarT
-> returnL (HsTyVar NotPromoted (noLoc
(getRdrName liftedTypeKindTyCon)))
ConstraintT
-> returnL (HsTyVar NotPromoted
(noLoc (getRdrName constraintKindTyCon)))
EqualityT
| [x',y'] <- tys' -> returnL (HsEqTy x' y')
| otherwise ->
mk_apps (HsTyVar NotPromoted
(noLoc (getRdrName eqPrimTyCon))) tys'
_ -> failWith (ptext (sLit ("Malformed " ++ ty_str)) <+> text (show ty))
}
-- | Constructs an application of a type to arguments passed in a list.
mk_apps :: HsType GhcPs -> [LHsType GhcPs] -> CvtM (LHsType GhcPs)
mk_apps head_ty [] = returnL head_ty
mk_apps head_ty (ty:tys) =
do { head_ty' <- returnL head_ty
; p_ty <- add_parens ty
; mk_apps (HsAppTy head_ty' p_ty) tys }
where
-- See Note [Adding parens for splices]
add_parens t
| isCompoundHsType t = returnL (HsParTy t)
| otherwise = return t
wrap_apps :: LHsType GhcPs -> CvtM (LHsType GhcPs)
wrap_apps t@(L _ HsAppTy {}) = returnL (HsParTy t)
wrap_apps t = return t
-- ---------------------------------------------------------------------
-- Note [Adding parens for splices]
{-
The hsSyn representation of parsed source explicitly contains all the original
parens, as written in the source.
When a Template Haskell (TH) splice is evaluated, the original splice is first
renamed and type checked and then finally converted to core in DsMeta. This core
is then run in the TH engine, and the result comes back as a TH AST.
In the process, all parens are stripped out, as they are not needed.
This Convert module then converts the TH AST back to hsSyn AST.
In order to pretty-print this hsSyn AST, parens need to be adde back at certain
points so that the code is readable with its original meaning.
So scattered through Convert.hs are various points where parens are added.
See (among other closed issued) https://ghc.haskell.org/trac/ghc/ticket/14289
-}
-- ---------------------------------------------------------------------
-- | Constructs an arrow type with a specified return type
mk_arr_apps :: [LHsType GhcPs] -> HsType GhcPs -> CvtM (LHsType GhcPs)
mk_arr_apps tys return_ty = foldrM go return_ty tys >>= returnL
where go :: LHsType GhcPs -> HsType GhcPs -> CvtM (HsType GhcPs)
go arg ret_ty = do { ret_ty_l <- returnL ret_ty
; return (HsFunTy arg ret_ty_l) }
split_ty_app :: TH.Type -> CvtM (TH.Type, [LHsType GhcPs])
split_ty_app ty = go ty []
where
go (AppT f a) as' = do { a' <- cvtType a; go f (a':as') }
go f as = return (f,as)
cvtTyLit :: TH.TyLit -> HsTyLit
cvtTyLit (TH.NumTyLit i) = HsNumTy NoSourceText i
cvtTyLit (TH.StrTyLit s) = HsStrTy NoSourceText (fsLit s)
{- | @cvtOpAppT x op y@ takes converted arguments and flattens any HsAppsTy
structure in them.
-}
cvtOpAppT :: LHsType GhcPs -> RdrName -> LHsType GhcPs -> LHsType GhcPs
cvtOpAppT t1@(L loc1 _) op t2@(L loc2 _)
= L (combineSrcSpans loc1 loc2) $
HsAppsTy (t1' ++ [noLoc $ HsAppInfix (noLoc op)] ++ t2')
where
t1' | L _ (HsAppsTy t1s) <- t1
= t1s
| otherwise
= [noLoc $ HsAppPrefix t1]
t2' | L _ (HsAppsTy t2s) <- t2
= t2s
| otherwise
= [noLoc $ HsAppPrefix t2]
cvtKind :: TH.Kind -> CvtM (LHsKind GhcPs)
cvtKind = cvtTypeKind "kind"
-- | Convert Maybe Kind to a type family result signature. Used with data
-- families where naming of the result is not possible (thus only kind or no
-- signature is possible).
cvtMaybeKindToFamilyResultSig :: Maybe TH.Kind
-> CvtM (LFamilyResultSig GhcPs)
cvtMaybeKindToFamilyResultSig Nothing = returnL Hs.NoSig
cvtMaybeKindToFamilyResultSig (Just ki) = do { ki' <- cvtKind ki
; returnL (Hs.KindSig ki') }
-- | Convert type family result signature. Used with both open and closed type
-- families.
cvtFamilyResultSig :: TH.FamilyResultSig -> CvtM (Hs.LFamilyResultSig GhcPs)
cvtFamilyResultSig TH.NoSig = returnL Hs.NoSig
cvtFamilyResultSig (TH.KindSig ki) = do { ki' <- cvtKind ki
; returnL (Hs.KindSig ki') }
cvtFamilyResultSig (TH.TyVarSig bndr) = do { tv <- cvt_tv bndr
; returnL (Hs.TyVarSig tv) }
-- | Convert injectivity annotation of a type family.
cvtInjectivityAnnotation :: TH.InjectivityAnn
-> CvtM (Hs.LInjectivityAnn GhcPs)
cvtInjectivityAnnotation (TH.InjectivityAnn annLHS annRHS)
= do { annLHS' <- tNameL annLHS
; annRHS' <- mapM tNameL annRHS
; returnL (Hs.InjectivityAnn annLHS' annRHS') }
cvtPatSynSigTy :: TH.Type -> CvtM (LHsType GhcPs)
-- pattern synonym types are of peculiar shapes, which is why we treat
-- them separately from regular types;
-- see Note [Pattern synonym type signatures and Template Haskell]
cvtPatSynSigTy (ForallT univs reqs (ForallT exis provs ty))
| null exis, null provs = cvtType (ForallT univs reqs ty)
| null univs, null reqs = do { l <- getL
; ty' <- cvtType (ForallT exis provs ty)
; return $ L l (HsQualTy { hst_ctxt = L l []
, hst_body = ty' }) }
| null reqs = do { l <- getL
; univs' <- hsQTvExplicit <$> cvtTvs univs
; ty' <- cvtType (ForallT exis provs ty)
; let forTy = HsForAllTy { hst_bndrs = univs'
, hst_body = L l cxtTy }
cxtTy = HsQualTy { hst_ctxt = L l []
, hst_body = ty' }
; return $ L l forTy }
| otherwise = cvtType (ForallT univs reqs (ForallT exis provs ty))
cvtPatSynSigTy ty = cvtType ty
-----------------------------------------------------------
cvtFixity :: TH.Fixity -> Hs.Fixity
cvtFixity (TH.Fixity prec dir) = Hs.Fixity NoSourceText prec (cvt_dir dir)
where
cvt_dir TH.InfixL = Hs.InfixL
cvt_dir TH.InfixR = Hs.InfixR
cvt_dir TH.InfixN = Hs.InfixN
-----------------------------------------------------------
-----------------------------------------------------------
-- some useful things
overloadedLit :: Lit -> Bool
-- True for literals that Haskell treats as overloaded
overloadedLit (IntegerL _) = True
overloadedLit (RationalL _) = True
overloadedLit _ = False
-- Checks that are performed when converting unboxed sum expressions and
-- patterns alike.
unboxedSumChecks :: TH.SumAlt -> TH.SumArity -> CvtM ()
unboxedSumChecks alt arity
| alt > arity
= failWith $ text "Sum alternative" <+> text (show alt)
<+> text "exceeds its arity," <+> text (show arity)
| alt <= 0
= failWith $ vcat [ text "Illegal sum alternative:" <+> text (show alt)
, nest 2 $ text "Sum alternatives must start from 1" ]
| arity < 2
= failWith $ vcat [ text "Illegal sum arity:" <+> text (show arity)
, nest 2 $ text "Sums must have an arity of at least 2" ]
| otherwise
= return ()
-- | If passed an empty list of 'TH.TyVarBndr's, this simply returns the
-- third argument (an 'LHsType'). Otherwise, return an 'HsForAllTy'
-- using the provided 'LHsQTyVars' and 'LHsType'.
mkHsForAllTy :: [TH.TyVarBndr]
-- ^ The original Template Haskell type variable binders
-> SrcSpan
-- ^ The location of the returned 'LHsType' if it needs an
-- explicit forall
-> LHsQTyVars name
-- ^ The converted type variable binders
-> LHsType name
-- ^ The converted rho type
-> LHsType name
-- ^ The complete type, quantified with a forall if necessary
mkHsForAllTy tvs loc tvs' rho_ty
| null tvs = rho_ty
| otherwise = L loc $ HsForAllTy { hst_bndrs = hsQTvExplicit tvs'
, hst_body = rho_ty }
-- | If passed an empty 'TH.Cxt', this simply returns the third argument
-- (an 'LHsType'). Otherwise, return an 'HsQualTy' using the provided
-- 'LHsContext' and 'LHsType'.
-- It's important that we don't build an HsQualTy if the context is empty,
-- as the pretty-printer for HsType _always_ prints contexts, even if
-- they're empty. See Trac #13183.
mkHsQualTy :: TH.Cxt
-- ^ The original Template Haskell context
-> SrcSpan
-- ^ The location of the returned 'LHsType' if it needs an
-- explicit context
-> LHsContext name
-- ^ The converted context
-> LHsType name
-- ^ The converted tau type
-> LHsType name
-- ^ The complete type, qualified with a context if necessary
mkHsQualTy ctxt loc ctxt' ty
| null ctxt = ty
| otherwise = L loc $ HsQualTy { hst_ctxt = ctxt', hst_body = ty }
--------------------------------------------------------------------
-- Turning Name back into RdrName
--------------------------------------------------------------------
-- variable names
vNameL, cNameL, vcNameL, tNameL, tconNameL :: TH.Name -> CvtM (Located RdrName)
vName, cName, vcName, tName, tconName :: TH.Name -> CvtM RdrName
-- Variable names
vNameL n = wrapL (vName n)
vName n = cvtName OccName.varName n
-- Constructor function names; this is Haskell source, hence srcDataName
cNameL n = wrapL (cName n)
cName n = cvtName OccName.dataName n
-- Variable *or* constructor names; check by looking at the first char
vcNameL n = wrapL (vcName n)
vcName n = if isVarName n then vName n else cName n
-- Type variable names
tNameL n = wrapL (tName n)
tName n = cvtName OccName.tvName n
-- Type Constructor names
tconNameL n = wrapL (tconName n)
tconName n = cvtName OccName.tcClsName n
cvtName :: OccName.NameSpace -> TH.Name -> CvtM RdrName
cvtName ctxt_ns (TH.Name occ flavour)
| not (okOcc ctxt_ns occ_str) = failWith (badOcc ctxt_ns occ_str)
| otherwise
= do { loc <- getL
; let rdr_name = thRdrName loc ctxt_ns occ_str flavour
; force rdr_name
; return rdr_name }
where
occ_str = TH.occString occ
okOcc :: OccName.NameSpace -> String -> Bool
okOcc ns str
| OccName.isVarNameSpace ns = okVarOcc str
| OccName.isDataConNameSpace ns = okConOcc str
| otherwise = okTcOcc str
-- Determine the name space of a name in a type
--
isVarName :: TH.Name -> Bool
isVarName (TH.Name occ _)
= case TH.occString occ of
"" -> False
(c:_) -> startsVarId c || startsVarSym c
badOcc :: OccName.NameSpace -> String -> SDoc
badOcc ctxt_ns occ
= text "Illegal" <+> pprNameSpace ctxt_ns
<+> text "name:" <+> quotes (text occ)
thRdrName :: SrcSpan -> OccName.NameSpace -> String -> TH.NameFlavour -> RdrName
-- This turns a TH Name into a RdrName; used for both binders and occurrences
-- See Note [Binders in Template Haskell]
-- The passed-in name space tells what the context is expecting;
-- use it unless the TH name knows what name-space it comes
-- from, in which case use the latter
--
-- We pass in a SrcSpan (gotten from the monad) because this function
-- is used for *binders* and if we make an Exact Name we want it
-- to have a binding site inside it. (cf Trac #5434)
--
-- ToDo: we may generate silly RdrNames, by passing a name space
-- that doesn't match the string, like VarName ":+",
-- which will give confusing error messages later
--
-- The strict applications ensure that any buried exceptions get forced
thRdrName loc ctxt_ns th_occ th_name
= case th_name of
TH.NameG th_ns pkg mod -> thOrigRdrName th_occ th_ns pkg mod
TH.NameQ mod -> (mkRdrQual $! mk_mod mod) $! occ
TH.NameL uniq -> nameRdrName $! (((Name.mkInternalName $! mk_uniq uniq) $! occ) loc)
TH.NameU uniq -> nameRdrName $! (((Name.mkSystemNameAt $! mk_uniq uniq) $! occ) loc)
TH.NameS | Just name <- isBuiltInOcc_maybe occ -> nameRdrName $! name
| otherwise -> mkRdrUnqual $! occ
-- We check for built-in syntax here, because the TH
-- user might have written a (NameS "(,,)"), for example
where
occ :: OccName.OccName
occ = mk_occ ctxt_ns th_occ
thOrigRdrName :: String -> TH.NameSpace -> PkgName -> ModName -> RdrName
thOrigRdrName occ th_ns pkg mod = (mkOrig $! (mkModule (mk_pkg pkg) (mk_mod mod))) $! (mk_occ (mk_ghc_ns th_ns) occ)
thRdrNameGuesses :: TH.Name -> [RdrName]
thRdrNameGuesses (TH.Name occ flavour)
-- This special case for NameG ensures that we don't generate duplicates in the output list
| TH.NameG th_ns pkg mod <- flavour = [ thOrigRdrName occ_str th_ns pkg mod]
| otherwise = [ thRdrName noSrcSpan gns occ_str flavour
| gns <- guessed_nss]
where
-- guessed_ns are the name spaces guessed from looking at the TH name
guessed_nss | isLexCon (mkFastString occ_str) = [OccName.tcName, OccName.dataName]
| otherwise = [OccName.varName, OccName.tvName]
occ_str = TH.occString occ
-- The packing and unpacking is rather turgid :-(
mk_occ :: OccName.NameSpace -> String -> OccName.OccName
mk_occ ns occ = OccName.mkOccName ns occ
mk_ghc_ns :: TH.NameSpace -> OccName.NameSpace
mk_ghc_ns TH.DataName = OccName.dataName
mk_ghc_ns TH.TcClsName = OccName.tcClsName
mk_ghc_ns TH.VarName = OccName.varName
mk_mod :: TH.ModName -> ModuleName
mk_mod mod = mkModuleName (TH.modString mod)
mk_pkg :: TH.PkgName -> UnitId
mk_pkg pkg = stringToUnitId (TH.pkgString pkg)
mk_uniq :: Int -> Unique
mk_uniq u = mkUniqueGrimily u
{-
Note [Binders in Template Haskell]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider this TH term construction:
do { x1 <- TH.newName "x" -- newName :: String -> Q TH.Name
; x2 <- TH.newName "x" -- Builds a NameU
; x3 <- TH.newName "x"
; let x = mkName "x" -- mkName :: String -> TH.Name
-- Builds a NameS
; return (LamE (..pattern [x1,x2]..) $
LamE (VarPat x3) $
..tuple (x1,x2,x3,x)) }
It represents the term \[x1,x2]. \x3. (x1,x2,x3,x)
a) We don't want to complain about "x" being bound twice in
the pattern [x1,x2]
b) We don't want x3 to shadow the x1,x2
c) We *do* want 'x' (dynamically bound with mkName) to bind
to the innermost binding of "x", namely x3.
d) When pretty printing, we want to print a unique with x1,x2
etc, else they'll all print as "x" which isn't very helpful
When we convert all this to HsSyn, the TH.Names are converted with
thRdrName. To achieve (b) we want the binders to be Exact RdrNames.
Achieving (a) is a bit awkward, because
- We must check for duplicate and shadowed names on Names,
not RdrNames, *after* renaming.
See Note [Collect binders only after renaming] in HsUtils
- But to achieve (a) we must distinguish between the Exact
RdrNames arising from TH and the Unqual RdrNames that would
come from a user writing \[x,x] -> blah
So in Convert.thRdrName we translate
TH Name RdrName
--------------------------------------------------------
NameU (arising from newName) --> Exact (Name{ System })
NameS (arising from mkName) --> Unqual
Notice that the NameUs generate *System* Names. Then, when
figuring out shadowing and duplicates, we can filter out
System Names.
This use of System Names fits with other uses of System Names, eg for
temporary variables "a". Since there are lots of things called "a" we
usually want to print the name with the unique, and that is indeed
the way System Names are printed.
There's a small complication of course; see Note [Looking up Exact
RdrNames] in RnEnv.
-}
{-
Note [Pattern synonym type signatures and Template Haskell]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
In general, the type signature of a pattern synonym
pattern P x1 x2 .. xn = <some-pattern>
is of the form
forall univs. reqs => forall exis. provs => t1 -> t2 -> ... -> tn -> t
with the following parts:
1) the (possibly empty lists of) universally quantified type
variables `univs` and required constraints `reqs` on them.
2) the (possibly empty lists of) existentially quantified type
variables `exis` and the provided constraints `provs` on them.
3) the types `t1`, `t2`, .., `tn` of the pattern synonym's arguments x1,
x2, .., xn, respectively
4) the type `t` of <some-pattern>, mentioning only universals from `univs`.
Due to the two forall quantifiers and constraint contexts (either of
which might be empty), pattern synonym type signatures are treated
specially in `deSugar/DsMeta.hs`, `hsSyn/Convert.hs`, and
`typecheck/TcSplice.hs`:
(a) When desugaring a pattern synonym from HsSyn to TH.Dec in
`deSugar/DsMeta.hs`, we represent its *full* type signature in TH, i.e.:
ForallT univs reqs (ForallT exis provs ty)
(where ty is the AST representation of t1 -> t2 -> ... -> tn -> t)
(b) When converting pattern synonyms from TH.Dec to HsSyn in
`hsSyn/Convert.hs`, we convert their TH type signatures back to an
appropriate Haskell pattern synonym type of the form
forall univs. reqs => forall exis. provs => t1 -> t2 -> ... -> tn -> t
where initial empty `univs` type variables or an empty `reqs`
constraint context are represented *explicitly* as `() =>`.
(c) When reifying a pattern synonym in `typecheck/TcSplice.hs`, we always
return its *full* type, i.e.:
ForallT univs reqs (ForallT exis provs ty)
(where ty is the AST representation of t1 -> t2 -> ... -> tn -> t)
The key point is to always represent a pattern synonym's *full* type
in cases (a) and (c) to make it clear which of the two forall
quantifiers and/or constraint contexts are specified, and which are
not. See GHC's user's guide on pattern synonyms for more information
about pattern synonym type signatures.
-}
|