{-# LANGUAGE TemplateHaskell, LambdaCase, CPP, ScopedTypeVariables,
TupleSections, DeriveDataTypeable, DeriveGeneric #-}
module Language.Haskell.TH.Desugar.Core where
import Prelude hiding (mapM, foldl, foldr, all, elem, exp, concatMap, and)
import Language.Haskell.TH hiding (match, clause, cxt)
import Language.Haskell.TH.Syntax hiding (lift)
import Language.Haskell.TH.Datatype ( resolveTypeSynonyms )
#if __GLASGOW_HASKELL__ < 709
import Control.Applicative
#endif
import Control.Monad hiding (forM_, mapM)
import qualified Control.Monad.Fail as Fail
import Control.Monad.Zip
import Control.Monad.Writer hiding (forM_, mapM)
import Data.Data (Data, Typeable)
import Data.Either (lefts)
import Data.Foldable as F hiding (concat, notElem)
import qualified Data.Map as M
import Data.Map (Map)
import Data.Maybe (mapMaybe)
import qualified Data.Set as S
import Data.Set (Set)
import Data.Traversable
#if __GLASGOW_HASKELL__ > 710
import Data.Maybe (isJust)
#endif
#if __GLASGOW_HASKELL__ >= 800
import qualified Control.Monad.Fail as MonadFail
#endif
#if __GLASGOW_HASKELL__ >= 803
import GHC.OverloadedLabels ( fromLabel )
#endif
#if __GLASGOW_HASKELL__ >= 807
import GHC.Classes (IP(..))
#endif
import GHC.Exts
import GHC.Generics (Generic)
import Language.Haskell.TH.Desugar.AST
import Language.Haskell.TH.Desugar.FV
import qualified Language.Haskell.TH.Desugar.OSet as OS
import Language.Haskell.TH.Desugar.OSet (OSet)
import Language.Haskell.TH.Desugar.Util
import Language.Haskell.TH.Desugar.Reify
dsExp :: DsMonad q => Exp -> q DExp
dsExp (VarE n) = return $ DVarE n
dsExp (ConE n) = return $ DConE n
dsExp (LitE lit) = return $ DLitE lit
dsExp (AppE e1 e2) = DAppE <$> dsExp e1 <*> dsExp e2
dsExp (InfixE Nothing op Nothing) = dsExp op
dsExp (InfixE (Just lhs) op Nothing) = DAppE <$> (dsExp op) <*> (dsExp lhs)
dsExp (InfixE Nothing op (Just rhs)) = do
lhsName <- newUniqueName "lhs"
op' <- dsExp op
rhs' <- dsExp rhs
return $ DLamE [lhsName] (foldl DAppE op' [DVarE lhsName, rhs'])
dsExp (InfixE (Just lhs) op (Just rhs)) =
DAppE <$> (DAppE <$> dsExp op <*> dsExp lhs) <*> dsExp rhs
dsExp (UInfixE _ _ _) =
fail "Cannot desugar unresolved infix operators."
dsExp (ParensE exp) = dsExp exp
dsExp (LamE pats exp) = dsLam pats =<< dsExp exp
dsExp (LamCaseE matches) = do
x <- newUniqueName "x"
matches' <- dsMatches x matches
return $ DLamE [x] (DCaseE (DVarE x) matches')
dsExp (TupE exps) = dsTup tupleDataName exps
dsExp (UnboxedTupE exps) = dsTup unboxedTupleDataName exps
dsExp (CondE e1 e2 e3) =
dsExp (CaseE e1 [ Match (ConP 'True []) (NormalB e2) []
, Match (ConP 'False []) (NormalB e3) [] ])
dsExp (MultiIfE guarded_exps) =
let failure = DAppE (DVarE 'error) (DLitE (StringL "Non-exhaustive guards in multi-way if")) in
dsGuards guarded_exps failure
dsExp (LetE decs exp) = do
(decs', ip_binder) <- dsLetDecs decs
exp' <- dsExp exp
return $ DLetE decs' $ ip_binder exp'
dsExp (CaseE (VarE scrutinee) matches) = do
matches' <- dsMatches scrutinee matches
return $ DCaseE (DVarE scrutinee) matches'
dsExp (CaseE exp matches) = do
scrutinee <- newUniqueName "scrutinee"
exp' <- dsExp exp
matches' <- dsMatches scrutinee matches
return $ DLetE [DValD (DVarP scrutinee) exp'] $
DCaseE (DVarE scrutinee) matches'
dsExp (DoE stmts) = dsDoStmts stmts
dsExp (CompE stmts) = dsComp stmts
dsExp (ArithSeqE (FromR exp)) = DAppE (DVarE 'enumFrom) <$> dsExp exp
dsExp (ArithSeqE (FromThenR exp1 exp2)) =
DAppE <$> (DAppE (DVarE 'enumFromThen) <$> dsExp exp1) <*> dsExp exp2
dsExp (ArithSeqE (FromToR exp1 exp2)) =
DAppE <$> (DAppE (DVarE 'enumFromTo) <$> dsExp exp1) <*> dsExp exp2
dsExp (ArithSeqE (FromThenToR e1 e2 e3)) =
DAppE <$> (DAppE <$> (DAppE (DVarE 'enumFromThenTo) <$> dsExp e1) <*>
dsExp e2) <*>
dsExp e3
dsExp (ListE exps) = go exps
where go [] = return $ DConE '[]
go (h : t) = DAppE <$> (DAppE (DConE '(:)) <$> dsExp h) <*> go t
dsExp (SigE exp ty) = DSigE <$> dsExp exp <*> dsType ty
dsExp (RecConE con_name field_exps) = do
con <- dataConNameToCon con_name
reordered <- reorder con
return $ foldl DAppE (DConE con_name) reordered
where
reorder con = case con of
NormalC _name fields -> non_record fields
InfixC field1 _name field2 -> non_record [field1, field2]
RecC _name fields -> reorder_fields fields
ForallC _ _ c -> reorder c
#if __GLASGOW_HASKELL__ >= 800
GadtC _names fields _ret_ty -> non_record fields
RecGadtC _names fields _ret_ty -> reorder_fields fields
#endif
reorder_fields fields = reorderFields con_name fields field_exps
(repeat $ DVarE 'undefined)
non_record fields | null field_exps
= return $ replicate (length fields) $ DVarE 'undefined
| otherwise =
impossible $ "Record syntax used with non-record constructor "
++ (show con_name) ++ "."
dsExp (RecUpdE exp field_exps) = do
first_name <- case field_exps of
((name, _) : _) -> return name
_ -> impossible "Record update with no fields listed."
info <- reifyWithLocals first_name
applied_type <- case info of
#if __GLASGOW_HASKELL__ > 710
VarI _name ty _m_dec -> extract_first_arg ty
#else
VarI _name ty _m_dec _fixity -> extract_first_arg ty
#endif
_ -> impossible "Record update with an invalid field name."
type_name <- extract_type_name applied_type
(_, cons) <- getDataD "This seems to be an error in GHC." type_name
let filtered_cons = filter_cons_with_names cons (map fst field_exps)
exp' <- dsExp exp
matches <- mapM con_to_dmatch filtered_cons
let all_matches
| length filtered_cons == length cons = matches
| otherwise = matches ++ [error_match]
return $ DCaseE exp' all_matches
where
extract_first_arg :: DsMonad q => Type -> q Type
extract_first_arg (AppT (AppT ArrowT arg) _) = return arg
extract_first_arg (ForallT _ _ t) = extract_first_arg t
extract_first_arg (SigT t _) = extract_first_arg t
extract_first_arg _ = impossible "Record selector not a function."
extract_type_name :: DsMonad q => Type -> q Name
extract_type_name (AppT t1 _) = extract_type_name t1
extract_type_name (SigT t _) = extract_type_name t
extract_type_name (ConT n) = return n
extract_type_name _ = impossible "Record selector domain not a datatype."
filter_cons_with_names cons field_names =
filter has_names cons
where
args_contain_names args =
let con_field_names = map fst_of_3 args in
all (`elem` con_field_names) field_names
has_names (RecC _con_name args) =
args_contain_names args
#if __GLASGOW_HASKELL__ >= 800
has_names (RecGadtC _con_name args _ret_ty) =
args_contain_names args
#endif
has_names (ForallC _ _ c) = has_names c
has_names _ = False
rec_con_to_dmatch con_name args = do
let con_field_names = map fst_of_3 args
field_var_names <- mapM (newUniqueName . nameBase) con_field_names
DMatch (DConP con_name (map DVarP field_var_names)) <$>
(foldl DAppE (DConE con_name) <$>
(reorderFields con_name args field_exps (map DVarE field_var_names)))
con_to_dmatch :: DsMonad q => Con -> q DMatch
con_to_dmatch (RecC con_name args) = rec_con_to_dmatch con_name args
#if __GLASGOW_HASKELL__ >= 800
con_to_dmatch (RecGadtC [con_name] args _ret_ty) = rec_con_to_dmatch con_name args
#endif
con_to_dmatch (ForallC _ _ c) = con_to_dmatch c
con_to_dmatch _ = impossible "Internal error within th-desugar."
error_match = DMatch DWildP (DAppE (DVarE 'error)
(DLitE (StringL "Non-exhaustive patterns in record update")))
fst_of_3 (x, _, _) = x
#if __GLASGOW_HASKELL__ >= 709
dsExp (StaticE exp) = DStaticE <$> dsExp exp
#endif
#if __GLASGOW_HASKELL__ > 710
dsExp (UnboundVarE n) = return (DVarE n)
#endif
#if __GLASGOW_HASKELL__ >= 801
dsExp (AppTypeE exp ty) = DAppTypeE <$> dsExp exp <*> dsType ty
dsExp (UnboxedSumE exp alt arity) =
DAppE (DConE $ unboxedSumDataName alt arity) <$> dsExp exp
#endif
#if __GLASGOW_HASKELL__ >= 803
dsExp (LabelE str) = return $ DVarE 'fromLabel `DAppTypeE` DLitT (StrTyLit str)
#endif
#if __GLASGOW_HASKELL__ >= 807
dsExp (ImplicitParamVarE n) = return $ DVarE 'ip `DAppTypeE` DLitT (StrTyLit n)
dsExp (MDoE {}) = fail "th-desugar currently does not support RecursiveDo"
#endif
#if __GLASGOW_HASKELL__ >= 809
dsTup :: DsMonad q => (Int -> Name) -> [Maybe Exp] -> q DExp
dsTup = ds_tup
#else
dsTup :: DsMonad q => (Int -> Name) -> [Exp] -> q DExp
dsTup tuple_data_name = ds_tup tuple_data_name . map Just
#endif
ds_tup :: forall q. DsMonad q
=> (Int -> Name)
-> [Maybe Exp]
-> q DExp
ds_tup tuple_data_name mb_exps = do
section_exps <- mapM ds_section_exp mb_exps
let section_vars = lefts section_exps
tup_body = mk_tup_body section_exps
if null section_vars
then return tup_body
else dsLam (map VarP section_vars) tup_body
where
ds_section_exp :: Maybe Exp -> q (Either Name DExp)
ds_section_exp = maybe (Left <$> qNewName "ts") (fmap Right . dsExp)
mk_tup_body :: [Either Name DExp] -> DExp
mk_tup_body section_exps =
foldl' apply_tup_body (DConE $ tuple_data_name (length section_exps))
section_exps
apply_tup_body :: DExp -> Either Name DExp -> DExp
apply_tup_body f (Left n) = f `DAppE` DVarE n
apply_tup_body f (Right e) = f `DAppE` e
dsLam :: DsMonad q => [Pat] -> DExp -> q DExp
dsLam = mkLam stripVarP_maybe dsPatsOverExp
mkDLamEFromDPats :: DsMonad q => [DPat] -> DExp -> q DExp
mkDLamEFromDPats = mkLam stripDVarP_maybe (\pats exp -> return (pats, exp))
where
stripDVarP_maybe :: DPat -> Maybe Name
stripDVarP_maybe (DVarP n) = Just n
stripDVarP_maybe _ = Nothing
mkLam :: DsMonad q
=> (pat -> Maybe Name)
-> ([pat] -> DExp -> q ([DPat], DExp))
-> [pat] -> DExp -> q DExp
mkLam mb_strip_var_pat process_pats_over_exp pats exp
| Just names <- mapM mb_strip_var_pat pats
= return $ DLamE names exp
| otherwise
= do arg_names <- replicateM (length pats) (newUniqueName "arg")
let scrutinee = mkTupleDExp (map DVarE arg_names)
(pats', exp') <- process_pats_over_exp pats exp
let match = DMatch (mkTupleDPat pats') exp'
return $ DLamE arg_names (DCaseE scrutinee [match])
dsMatches :: DsMonad q
=> Name
-> [Match]
-> q [DMatch]
dsMatches scr = go
where
go :: DsMonad q => [Match] -> q [DMatch]
go [] = return []
go (Match pat body where_decs : rest) = do
rest' <- go rest
let failure = DCaseE (DVarE scr) rest'
exp' <- dsBody body where_decs failure
(pat', exp'') <- dsPatOverExp pat exp'
uni_pattern <- isUniversalPattern pat'
if uni_pattern
then return [DMatch pat' exp'']
else return (DMatch pat' exp'' : rest')
dsBody :: DsMonad q
=> Body
-> [Dec]
-> DExp
-> q DExp
dsBody (NormalB exp) decs _ = do
(decs', ip_binder) <- dsLetDecs decs
exp' <- dsExp exp
return $ maybeDLetE decs' $ ip_binder exp'
dsBody (GuardedB guarded_exps) decs failure = do
(decs', ip_binder) <- dsLetDecs decs
guarded_exp' <- dsGuards guarded_exps failure
return $ maybeDLetE decs' $ ip_binder guarded_exp'
maybeDLetE :: [DLetDec] -> DExp -> DExp
maybeDLetE [] exp = exp
maybeDLetE decs exp = DLetE decs exp
maybeDCaseE :: String -> DExp -> [DMatch] -> DExp
maybeDCaseE err _ [] = DAppE (DVarE 'error) (DLitE (StringL err))
maybeDCaseE _ scrut matches = DCaseE scrut matches
dsGuards :: DsMonad q
=> [(Guard, Exp)]
-> DExp
-> q DExp
dsGuards [] thing_inside = return thing_inside
dsGuards ((NormalG gd, exp) : rest) thing_inside =
dsGuards ((PatG [NoBindS gd], exp) : rest) thing_inside
dsGuards ((PatG stmts, exp) : rest) thing_inside = do
success <- dsExp exp
failure <- dsGuards rest thing_inside
dsGuardStmts stmts success failure
dsGuardStmts :: DsMonad q
=> [Stmt]
-> DExp
-> DExp
-> q DExp
dsGuardStmts [] success _failure = return success
dsGuardStmts (BindS pat exp : rest) success failure = do
success' <- dsGuardStmts rest success failure
(pat', success'') <- dsPatOverExp pat success'
exp' <- dsExp exp
return $ DCaseE exp' [DMatch pat' success'', DMatch DWildP failure]
dsGuardStmts (LetS decs : rest) success failure = do
(decs', ip_binder) <- dsLetDecs decs
success' <- dsGuardStmts rest success failure
return $ DLetE decs' $ ip_binder success'
dsGuardStmts [NoBindS exp] success _failure
| VarE name <- exp
, name == 'otherwise
= return success
| ConE name <- exp
, name == 'True
= return success
dsGuardStmts (NoBindS exp : rest) success failure = do
exp' <- dsExp exp
success' <- dsGuardStmts rest success failure
return $ DCaseE exp' [ DMatch (DConP 'True []) success'
, DMatch (DConP 'False []) failure ]
dsGuardStmts (ParS _ : _) _ _ = impossible "Parallel comprehension in a pattern guard."
#if __GLASGOW_HASKELL__ >= 807
dsGuardStmts (RecS {} : _) _ _ = fail "th-desugar currently does not support RecursiveDo"
#endif
dsDoStmts :: DsMonad q => [Stmt] -> q DExp
dsDoStmts [] = impossible "do-expression ended with something other than bare statement."
dsDoStmts [NoBindS exp] = dsExp exp
dsDoStmts (BindS pat exp : rest) = do
rest' <- dsDoStmts rest
dsBindS exp pat rest' "do expression"
dsDoStmts (LetS decs : rest) = do
(decs', ip_binder) <- dsLetDecs decs
rest' <- dsDoStmts rest
return $ DLetE decs' $ ip_binder rest'
dsDoStmts (NoBindS exp : rest) = do
exp' <- dsExp exp
rest' <- dsDoStmts rest
return $ DAppE (DAppE (DVarE '(>>)) exp') rest'
dsDoStmts (ParS _ : _) = impossible "Parallel comprehension in a do-statement."
#if __GLASGOW_HASKELL__ >= 807
dsDoStmts (RecS {} : _) = fail "th-desugar currently does not support RecursiveDo"
#endif
dsComp :: DsMonad q => [Stmt] -> q DExp
dsComp [] = impossible "List/monad comprehension ended with something other than a bare statement."
dsComp [NoBindS exp] = DAppE (DVarE 'return) <$> dsExp exp
dsComp (BindS pat exp : rest) = do
rest' <- dsComp rest
dsBindS exp pat rest' "monad comprehension"
dsComp (LetS decs : rest) = do
(decs', ip_binder) <- dsLetDecs decs
rest' <- dsComp rest
return $ DLetE decs' $ ip_binder rest'
dsComp (NoBindS exp : rest) = do
exp' <- dsExp exp
rest' <- dsComp rest
return $ DAppE (DAppE (DVarE '(>>)) (DAppE (DVarE 'guard) exp')) rest'
dsComp (ParS stmtss : rest) = do
(pat, exp) <- dsParComp stmtss
rest' <- dsComp rest
DAppE (DAppE (DVarE '(>>=)) exp) <$> dsLam [pat] rest'
#if __GLASGOW_HASKELL__ >= 807
dsComp (RecS {} : _) = fail "th-desugar currently does not support RecursiveDo"
#endif
dsBindS :: forall q. DsMonad q => Exp -> Pat -> DExp -> String -> q DExp
dsBindS bind_arg_exp success_pat success_exp ctxt = do
bind_arg_exp' <- dsExp bind_arg_exp
(success_pat', success_exp') <- dsPatOverExp success_pat success_exp
is_univ_pat <- isUniversalPattern success_pat'
let bind_into = DAppE (DAppE (DVarE '(>>=)) bind_arg_exp')
if is_univ_pat
then bind_into <$> mkDLamEFromDPats [success_pat'] success_exp'
else do arg_name <- newUniqueName "arg"
fail_name <- mk_fail_name
return $ bind_into $ DLamE [arg_name] $ DCaseE (DVarE arg_name)
[ DMatch success_pat' success_exp'
, DMatch DWildP $
DVarE fail_name `DAppE`
DLitE (StringL $ "Pattern match failure in " ++ ctxt)
]
where
mk_fail_name :: q Name
#if __GLASGOW_HASKELL__ >= 807
mk_fail_name = return 'MonadFail.fail
#elif __GLASGOW_HASKELL__ >= 800
mk_fail_name = do
mfd <- qIsExtEnabled MonadFailDesugaring
return $ if mfd then 'MonadFail.fail else 'Prelude.fail
#else
mk_fail_name = return 'Prelude.fail
#endif
dsParComp :: DsMonad q => [[Stmt]] -> q (Pat, DExp)
dsParComp [] = impossible "Empty list of parallel comprehension statements."
dsParComp [r] = do
let rv = foldMap extractBoundNamesStmt r
dsR <- dsComp (r ++ [mk_tuple_stmt rv])
return (mk_tuple_pat rv, dsR)
dsParComp (q : rest) = do
let qv = foldMap extractBoundNamesStmt q
(rest_pat, rest_exp) <- dsParComp rest
dsQ <- dsComp (q ++ [mk_tuple_stmt qv])
let zipped = DAppE (DAppE (DVarE 'mzip) dsQ) rest_exp
return (ConP (tupleDataName 2) [mk_tuple_pat qv, rest_pat], zipped)
mk_tuple_stmt :: OSet Name -> Stmt
mk_tuple_stmt name_set =
NoBindS (mkTupleExp (F.foldr ((:) . VarE) [] name_set))
mk_tuple_pat :: OSet Name -> Pat
mk_tuple_pat name_set =
mkTuplePat (F.foldr ((:) . VarP) [] name_set)
dsPatOverExp :: DsMonad q => Pat -> DExp -> q (DPat, DExp)
dsPatOverExp pat exp = do
(pat', vars) <- runWriterT $ dsPat pat
let name_decs = uncurry (zipWith (DValD . DVarP)) $ unzip vars
return (pat', maybeDLetE name_decs exp)
dsPatsOverExp :: DsMonad q => [Pat] -> DExp -> q ([DPat], DExp)
dsPatsOverExp pats exp = do
(pats', vars) <- runWriterT $ mapM dsPat pats
let name_decs = uncurry (zipWith (DValD . DVarP)) $ unzip vars
return (pats', maybeDLetE name_decs exp)
dsPatX :: DsMonad q => Pat -> q (DPat, [(Name, DExp)])
dsPatX = runWriterT . dsPat
type PatM q = WriterT [(Name, DExp)] q
dsPat :: DsMonad q => Pat -> PatM q DPat
dsPat (LitP lit) = return $ DLitP lit
dsPat (VarP n) = return $ DVarP n
dsPat (TupP pats) = DConP (tupleDataName (length pats)) <$> mapM dsPat pats
dsPat (UnboxedTupP pats) = DConP (unboxedTupleDataName (length pats)) <$>
mapM dsPat pats
dsPat (ConP name pats) = DConP name <$> mapM dsPat pats
dsPat (InfixP p1 name p2) = DConP name <$> mapM dsPat [p1, p2]
dsPat (UInfixP _ _ _) =
fail "Cannot desugar unresolved infix operators."
dsPat (ParensP pat) = dsPat pat
dsPat (TildeP pat) = DTildeP <$> dsPat pat
dsPat (BangP pat) = DBangP <$> dsPat pat
dsPat (AsP name pat) = do
pat' <- dsPat pat
pat'' <- lift $ removeWilds pat'
tell [(name, dPatToDExp pat'')]
return pat''
dsPat WildP = return DWildP
dsPat (RecP con_name field_pats) = do
con <- lift $ dataConNameToCon con_name
reordered <- reorder con
return $ DConP con_name reordered
where
reorder con = case con of
NormalC _name fields -> non_record fields
InfixC field1 _name field2 -> non_record [field1, field2]
RecC _name fields -> reorder_fields_pat fields
ForallC _ _ c -> reorder c
#if __GLASGOW_HASKELL__ >= 800
GadtC _names fields _ret_ty -> non_record fields
RecGadtC _names fields _ret_ty -> reorder_fields_pat fields
#endif
reorder_fields_pat fields = reorderFieldsPat con_name fields field_pats
non_record fields | null field_pats
= return $ replicate (length fields) DWildP
| otherwise = lift $ impossible
$ "Record syntax used with non-record constructor "
++ (show con_name) ++ "."
dsPat (ListP pats) = go pats
where go [] = return $ DConP '[] []
go (h : t) = do
h' <- dsPat h
t' <- go t
return $ DConP '(:) [h', t']
dsPat (SigP pat ty) = DSigP <$> dsPat pat <*> dsType ty
#if __GLASGOW_HASKELL__ >= 801
dsPat (UnboxedSumP pat alt arity) =
DConP (unboxedSumDataName alt arity) <$> ((:[]) <$> dsPat pat)
#endif
dsPat (ViewP _ _) =
fail "View patterns are not supported in th-desugar. Use pattern guards instead."
dPatToDExp :: DPat -> DExp
dPatToDExp (DLitP lit) = DLitE lit
dPatToDExp (DVarP name) = DVarE name
dPatToDExp (DConP name pats) = foldl DAppE (DConE name) (map dPatToDExp pats)
dPatToDExp (DTildeP pat) = dPatToDExp pat
dPatToDExp (DBangP pat) = dPatToDExp pat
dPatToDExp (DSigP pat ty) = DSigE (dPatToDExp pat) ty
dPatToDExp DWildP = error "Internal error in th-desugar: wildcard in rhs of as-pattern"
removeWilds :: DsMonad q => DPat -> q DPat
removeWilds p@(DLitP _) = return p
removeWilds p@(DVarP _) = return p
removeWilds (DConP con_name pats) = DConP con_name <$> mapM removeWilds pats
removeWilds (DTildeP pat) = DTildeP <$> removeWilds pat
removeWilds (DBangP pat) = DBangP <$> removeWilds pat
removeWilds (DSigP pat ty) = DSigP <$> removeWilds pat <*> pure ty
removeWilds DWildP = DVarP <$> newUniqueName "wild"
dsInfo :: DsMonad q => Info -> q DInfo
dsInfo (ClassI dec instances) = do
[ddec] <- dsDec dec
dinstances <- dsDecs instances
return $ DTyConI ddec (Just dinstances)
#if __GLASGOW_HASKELL__ > 710
dsInfo (ClassOpI name ty parent) =
#else
dsInfo (ClassOpI name ty parent _fixity) =
#endif
DVarI name <$> dsType ty <*> pure (Just parent)
dsInfo (TyConI dec) = do
[ddec] <- dsDec dec
return $ DTyConI ddec Nothing
dsInfo (FamilyI dec instances) = do
[ddec] <- dsDec dec
dinstances <- dsDecs instances
return $ DTyConI ddec (Just dinstances)
dsInfo (PrimTyConI name arity unlifted) =
return $ DPrimTyConI name arity unlifted
#if __GLASGOW_HASKELL__ > 710
dsInfo (DataConI name ty parent) =
DVarI name <$> dsType ty <*> pure (Just parent)
dsInfo (VarI name ty Nothing) =
DVarI name <$> dsType ty <*> pure Nothing
dsInfo (VarI name _ (Just _)) =
impossible $ "Declaration supplied with variable: " ++ show name
#else
dsInfo (DataConI name ty parent _fixity) =
DVarI name <$> dsType ty <*> pure (Just parent)
dsInfo (VarI name ty Nothing _fixity) =
DVarI name <$> dsType ty <*> pure Nothing
dsInfo (VarI name _ (Just _) _) =
impossible $ "Declaration supplied with variable: " ++ show name
#endif
dsInfo (TyVarI name ty) = DTyVarI name <$> dsType ty
#if __GLASGOW_HASKELL__ >= 801
dsInfo (PatSynI name ty) = DPatSynI name <$> dsType ty
#endif
dsDecs :: DsMonad q => [Dec] -> q [DDec]
dsDecs = concatMapM dsDec
dsDec :: DsMonad q => Dec -> q [DDec]
dsDec d@(FunD {}) = dsTopLevelLetDec d
dsDec d@(ValD {}) = dsTopLevelLetDec d
#if __GLASGOW_HASKELL__ > 710
dsDec (DataD cxt n tvbs mk cons derivings) =
dsDataDec Data cxt n tvbs mk cons derivings
dsDec (NewtypeD cxt n tvbs mk con derivings) =
dsDataDec Newtype cxt n tvbs mk [con] derivings
#else
dsDec (DataD cxt n tvbs cons derivings) =
dsDataDec Data cxt n tvbs Nothing cons derivings
dsDec (NewtypeD cxt n tvbs con derivings) =
dsDataDec Newtype cxt n tvbs Nothing [con] derivings
#endif
dsDec (TySynD n tvbs ty) =
(:[]) <$> (DTySynD n <$> mapM dsTvb tvbs <*> dsType ty)
dsDec (ClassD cxt n tvbs fds decs) =
(:[]) <$> (DClassD <$> dsCxt cxt <*> pure n <*> mapM dsTvb tvbs
<*> pure fds <*> dsDecs decs)
#if __GLASGOW_HASKELL__ >= 711
dsDec (InstanceD over cxt ty decs) =
(:[]) <$> (DInstanceD over Nothing <$> dsCxt cxt <*> dsType ty <*> dsDecs decs)
#else
dsDec (InstanceD cxt ty decs) =
(:[]) <$> (DInstanceD Nothing Nothing <$> dsCxt cxt <*> dsType ty <*> dsDecs decs)
#endif
dsDec d@(SigD {}) = dsTopLevelLetDec d
dsDec (ForeignD f) = (:[]) <$> (DForeignD <$> dsForeign f)
dsDec d@(InfixD {}) = dsTopLevelLetDec d
dsDec d@(PragmaD {}) = dsTopLevelLetDec d
#if __GLASGOW_HASKELL__ > 710
dsDec (OpenTypeFamilyD tfHead) =
(:[]) <$> (DOpenTypeFamilyD <$> dsTypeFamilyHead tfHead)
dsDec (DataFamilyD n tvbs m_k) =
(:[]) <$> (DDataFamilyD n <$> mapM dsTvb tvbs <*> mapM dsType m_k)
#else
dsDec (FamilyD TypeFam n tvbs m_k) = do
(:[]) <$> (DOpenTypeFamilyD <$> dsTypeFamilyHead n tvbs m_k)
dsDec (FamilyD DataFam n tvbs m_k) =
(:[]) <$> (DDataFamilyD n <$> mapM dsTvb tvbs <*> mapM dsType m_k)
#endif
#if __GLASGOW_HASKELL__ >= 807
dsDec (DataInstD cxt mtvbs lhs mk cons derivings) =
case unfoldType lhs of
(ConT n, tys) -> dsDataInstDec Data cxt n mtvbs tys mk cons derivings
(_, _) -> fail $ "Unexpected data instance LHS: " ++ pprint lhs
dsDec (NewtypeInstD cxt mtvbs lhs mk con derivings) =
case unfoldType lhs of
(ConT n, tys) -> dsDataInstDec Newtype cxt n mtvbs tys mk [con] derivings
(_, _) -> fail $ "Unexpected newtype instance LHS: " ++ pprint lhs
#elif __GLASGOW_HASKELL__ > 710
dsDec (DataInstD cxt n tys mk cons derivings) =
dsDataInstDec Data cxt n Nothing (map TANormal tys) mk cons derivings
dsDec (NewtypeInstD cxt n tys mk con derivings) =
dsDataInstDec Newtype cxt n Nothing (map TANormal tys) mk [con] derivings
#else
dsDec (DataInstD cxt n tys cons derivings) =
dsDataInstDec Data cxt n Nothing (map TANormal tys) Nothing cons derivings
dsDec (NewtypeInstD cxt n tys con derivings) =
dsDataInstDec Newtype cxt n Nothing (map TANormal tys) Nothing [con] derivings
#endif
#if __GLASGOW_HASKELL__ >= 807
dsDec (TySynInstD eqn) = (:[]) <$> (DTySynInstD <$> dsTySynEqn unusedArgument eqn)
#else
dsDec (TySynInstD n eqn) = (:[]) <$> (DTySynInstD <$> dsTySynEqn n eqn)
#endif
#if __GLASGOW_HASKELL__ > 710
dsDec (ClosedTypeFamilyD tfHead eqns) =
(:[]) <$> (DClosedTypeFamilyD <$> dsTypeFamilyHead tfHead
<*> mapM (dsTySynEqn (typeFamilyHeadName tfHead)) eqns)
#else
dsDec (ClosedTypeFamilyD n tvbs m_k eqns) = do
(:[]) <$> (DClosedTypeFamilyD <$> dsTypeFamilyHead n tvbs m_k
<*> mapM (dsTySynEqn n) eqns)
#endif
dsDec (RoleAnnotD n roles) = return [DRoleAnnotD n roles]
#if __GLASGOW_HASKELL__ >= 709
#if __GLASGOW_HASKELL__ >= 801
dsDec (PatSynD n args dir pat) = do
dir' <- dsPatSynDir n dir
(pat', vars) <- dsPatX pat
unless (null vars) $
fail $ "Pattern synonym definition cannot contain as-patterns (@)."
return [DPatSynD n args dir' pat']
dsDec (PatSynSigD n ty) = (:[]) <$> (DPatSynSigD n <$> dsType ty)
dsDec (StandaloneDerivD mds cxt ty) =
(:[]) <$> (DStandaloneDerivD <$> mapM dsDerivStrategy mds
<*> pure Nothing <*> dsCxt cxt <*> dsType ty)
#else
dsDec (StandaloneDerivD cxt ty) =
(:[]) <$> (DStandaloneDerivD Nothing Nothing <$> dsCxt cxt <*> dsType ty)
#endif
dsDec (DefaultSigD n ty) = (:[]) <$> (DDefaultSigD n <$> dsType ty)
#endif
#if __GLASGOW_HASKELL__ >= 807
dsDec (ImplicitParamBindD {}) = impossible "Non-`let`-bound implicit param binding"
#endif
dsDataDec :: DsMonad q
=> NewOrData -> Cxt -> Name -> [TyVarBndr]
-> Maybe Kind -> [Con] -> [DerivingClause] -> q [DDec]
dsDataDec nd cxt n tvbs mk cons derivings = do
tvbs' <- mapM dsTvb tvbs
let h98_tvbs = case mk of
Just {} -> unusedArgument
Nothing -> tvbs'
h98_return_type = nonFamilyDataReturnType n tvbs'
(:[]) <$> (DDataD nd <$> dsCxt cxt <*> pure n
<*> pure tvbs' <*> mapM dsType mk
<*> concatMapM (dsCon h98_tvbs h98_return_type) cons
<*> mapM dsDerivClause derivings)
dsDataInstDec :: DsMonad q
=> NewOrData -> Cxt -> Name -> Maybe [TyVarBndr] -> [TypeArg]
-> Maybe Kind -> [Con] -> [DerivingClause] -> q [DDec]
dsDataInstDec nd cxt n mtvbs tys mk cons derivings = do
mtvbs' <- mapM (mapM dsTvb) mtvbs
tys' <- mapM dsTypeArg tys
let lhs' = applyDType (DConT n) tys'
h98_tvbs =
case (mk, mtvbs') of
(Just {}, _) -> unusedArgument
(Nothing, Just tvbs') -> tvbs'
(Nothing, Nothing) -> dataFamInstTvbs tys'
h98_fam_inst_type = dataFamInstReturnType n tys'
(:[]) <$> (DDataInstD nd <$> dsCxt cxt <*> pure mtvbs'
<*> pure lhs' <*> mapM dsType mk
<*> concatMapM (dsCon h98_tvbs h98_fam_inst_type) cons
<*> mapM dsDerivClause derivings)
mkExtraKindBinders :: DsMonad q => Maybe Kind -> q [DTyVarBndr]
mkExtraKindBinders =
maybe (pure (DConT typeKindName)) (runQ . resolveTypeSynonyms >=> dsType)
>=> mkExtraDKindBinders'
mkExtraDKindBinders' :: Quasi q => DKind -> q [DTyVarBndr]
mkExtraDKindBinders' = mkExtraKindBindersGeneric unravel DKindedTV
#if __GLASGOW_HASKELL__ > 710
dsFamilyResultSig :: DsMonad q => FamilyResultSig -> q DFamilyResultSig
dsFamilyResultSig NoSig = return DNoSig
dsFamilyResultSig (KindSig k) = DKindSig <$> dsType k
dsFamilyResultSig (TyVarSig tvb) = DTyVarSig <$> dsTvb tvb
dsTypeFamilyHead :: DsMonad q => TypeFamilyHead -> q DTypeFamilyHead
dsTypeFamilyHead (TypeFamilyHead n tvbs result inj)
= DTypeFamilyHead n <$> mapM dsTvb tvbs
<*> dsFamilyResultSig result
<*> pure inj
typeFamilyHeadName :: TypeFamilyHead -> Name
typeFamilyHeadName (TypeFamilyHead n _ _ _) = n
#else
dsTypeFamilyHead :: DsMonad q
=> Name -> [TyVarBndr] -> Maybe Kind -> q DTypeFamilyHead
dsTypeFamilyHead n tvbs m_kind = do
result_sig <- case m_kind of
Nothing -> return DNoSig
Just k -> DKindSig <$> dsType k
DTypeFamilyHead n <$> mapM dsTvb tvbs
<*> pure result_sig
<*> pure Nothing
#endif
dsLetDecs :: DsMonad q => [Dec] -> q ([DLetDec], DExp -> DExp)
dsLetDecs decs = do
(let_decss, ip_binders) <- mapAndUnzipM dsLetDec decs
let let_decs :: [DLetDec]
let_decs = concat let_decss
ip_binder :: DExp -> DExp
ip_binder = foldr (.) id ip_binders
return (let_decs, ip_binder)
dsLetDec :: DsMonad q => Dec -> q ([DLetDec], DExp -> DExp)
dsLetDec (FunD name clauses) = do
clauses' <- dsClauses name clauses
return ([DFunD name clauses'], id)
dsLetDec (ValD pat body where_decs) = do
(pat', vars) <- dsPatX pat
body' <- dsBody body where_decs error_exp
let extras = uncurry (zipWith (DValD . DVarP)) $ unzip vars
return (DValD pat' body' : extras, id)
where
error_exp = DAppE (DVarE 'error) (DLitE
(StringL $ "Non-exhaustive patterns for " ++ pprint pat))
dsLetDec (SigD name ty) = do
ty' <- dsType ty
return ([DSigD name ty'], id)
dsLetDec (InfixD fixity name) = return ([DInfixD fixity name], id)
dsLetDec (PragmaD prag) = do
prag' <- dsPragma prag
return ([DPragmaD prag'], id)
#if __GLASGOW_HASKELL__ >= 807
dsLetDec (ImplicitParamBindD n e) = do
new_n_name <- qNewName $ "new_" ++ n ++ "_val"
e' <- dsExp e
let let_dec :: DLetDec
let_dec = DValD (DVarP new_n_name) e'
ip_binder :: DExp -> DExp
ip_binder = (DVarE 'bindIP `DAppTypeE`
DLitT (StrTyLit n) `DAppE`
DVarE new_n_name `DAppE`)
return ([let_dec], ip_binder)
#endif
dsLetDec _dec = impossible "Illegal declaration in let expression."
dsTopLevelLetDec :: DsMonad q => Dec -> q [DDec]
dsTopLevelLetDec = fmap (map DLetDec . fst) . dsLetDec
dsCon :: DsMonad q
=> [DTyVarBndr]
-> DType
-> Con -> q [DCon]
dsCon univ_dtvbs data_type con = do
dcons' <- dsCon' con
return $ flip map dcons' $ \(n, dtvbs, dcxt, fields, m_gadt_type) ->
case m_gadt_type of
Nothing ->
let ex_dtvbs = dtvbs
expl_dtvbs = univ_dtvbs ++ ex_dtvbs
impl_dtvbs = toposortTyVarsOf $ mapMaybe extractTvbKind expl_dtvbs in
DCon (impl_dtvbs ++ expl_dtvbs) dcxt n fields data_type
Just gadt_type ->
let univ_ex_dtvbs = dtvbs in
DCon univ_ex_dtvbs dcxt n fields gadt_type
dsCon' :: DsMonad q
=> Con -> q [(Name, [DTyVarBndr], DCxt, DConFields, Maybe DType)]
dsCon' (NormalC n stys) = do
dtys <- mapM dsBangType stys
return [(n, [], [], DNormalC False dtys, Nothing)]
dsCon' (RecC n vstys) = do
vdtys <- mapM dsVarBangType vstys
return [(n, [], [], DRecC vdtys, Nothing)]
dsCon' (InfixC sty1 n sty2) = do
dty1 <- dsBangType sty1
dty2 <- dsBangType sty2
return [(n, [], [], DNormalC True [dty1, dty2], Nothing)]
dsCon' (ForallC tvbs cxt con) = do
dtvbs <- mapM dsTvb tvbs
dcxt <- dsCxt cxt
dcons' <- dsCon' con
return $ flip map dcons' $ \(n, dtvbs', dcxt', fields, m_gadt_type) ->
(n, dtvbs ++ dtvbs', dcxt ++ dcxt', fields, m_gadt_type)
#if __GLASGOW_HASKELL__ > 710
dsCon' (GadtC nms btys rty) = do
dbtys <- mapM dsBangType btys
drty <- dsType rty
sequence $ flip map nms $ \nm -> do
mbFi <- reifyFixityWithLocals nm
let decInfix = isInfixDataCon (nameBase nm)
|| length dbtys == 2
|| isJust mbFi
return (nm, [], [], DNormalC decInfix dbtys, Just drty)
dsCon' (RecGadtC nms vbtys rty) = do
dvbtys <- mapM dsVarBangType vbtys
drty <- dsType rty
return $ flip map nms $ \nm ->
(nm, [], [], DRecC dvbtys, Just drty)
#endif
#if __GLASGOW_HASKELL__ > 710
dsBangType :: DsMonad q => BangType -> q DBangType
dsBangType (b, ty) = (b, ) <$> dsType ty
dsVarBangType :: DsMonad q => VarBangType -> q DVarBangType
dsVarBangType (n, b, ty) = (n, b, ) <$> dsType ty
#else
dsBangType :: DsMonad q => StrictType -> q DBangType
dsBangType (b, ty) = (strictToBang b, ) <$> dsType ty
dsVarBangType :: DsMonad q => VarStrictType -> q DVarBangType
dsVarBangType (n, b, ty) = (n, strictToBang b, ) <$> dsType ty
#endif
dsForeign :: DsMonad q => Foreign -> q DForeign
dsForeign (ImportF cc safety str n ty) = DImportF cc safety str n <$> dsType ty
dsForeign (ExportF cc str n ty) = DExportF cc str n <$> dsType ty
dsPragma :: DsMonad q => Pragma -> q DPragma
dsPragma (InlineP n inl rm phases) = return $ DInlineP n inl rm phases
dsPragma (SpecialiseP n ty m_inl phases) = DSpecialiseP n <$> dsType ty
<*> pure m_inl
<*> pure phases
dsPragma (SpecialiseInstP ty) = DSpecialiseInstP <$> dsType ty
#if __GLASGOW_HASKELL__ >= 807
dsPragma (RuleP str mtvbs rbs lhs rhs phases)
= DRuleP str <$> mapM (mapM dsTvb) mtvbs
<*> mapM dsRuleBndr rbs
<*> dsExp lhs
<*> dsExp rhs
<*> pure phases
#else
dsPragma (RuleP str rbs lhs rhs phases) = DRuleP str Nothing
<$> mapM dsRuleBndr rbs
<*> dsExp lhs
<*> dsExp rhs
<*> pure phases
#endif
dsPragma (AnnP target exp) = DAnnP target <$> dsExp exp
#if __GLASGOW_HASKELL__ >= 709
dsPragma (LineP n str) = return $ DLineP n str
#endif
#if __GLASGOW_HASKELL__ >= 801
dsPragma (CompleteP cls mty) = return $ DCompleteP cls mty
#endif
dsRuleBndr :: DsMonad q => RuleBndr -> q DRuleBndr
dsRuleBndr (RuleVar n) = return $ DRuleVar n
dsRuleBndr (TypedRuleVar n ty) = DTypedRuleVar n <$> dsType ty
#if __GLASGOW_HASKELL__ >= 807
dsTySynEqn :: DsMonad q => Name -> TySynEqn -> q DTySynEqn
dsTySynEqn _ (TySynEqn mtvbs lhs rhs) =
DTySynEqn <$> mapM (mapM dsTvb) mtvbs <*> dsType lhs <*> dsType rhs
#else
dsTySynEqn :: DsMonad q => Name -> TySynEqn -> q DTySynEqn
dsTySynEqn n (TySynEqn lhss rhs) = do
lhss' <- mapM dsType lhss
let lhs' = applyDType (DConT n) $ map DTANormal lhss'
DTySynEqn Nothing lhs' <$> dsType rhs
#endif
dsClauses :: DsMonad q
=> Name
-> [Clause]
-> q [DClause]
dsClauses _ [] = return []
dsClauses n (Clause pats (NormalB exp) where_decs : rest) = do
rest' <- dsClauses n rest
exp' <- dsExp exp
(where_decs', ip_binder) <- dsLetDecs where_decs
let exp_with_wheres = maybeDLetE where_decs' (ip_binder exp')
(pats', exp'') <- dsPatsOverExp pats exp_with_wheres
return $ DClause pats' exp'' : rest'
dsClauses n clauses@(Clause outer_pats _ _ : _) = do
arg_names <- replicateM (length outer_pats) (newUniqueName "arg")
let scrutinee = mkTupleDExp (map DVarE arg_names)
clause <- DClause (map DVarP arg_names) <$>
(DCaseE scrutinee <$> foldrM (clause_to_dmatch scrutinee) [] clauses)
return [clause]
where
clause_to_dmatch :: DsMonad q => DExp -> Clause -> [DMatch] -> q [DMatch]
clause_to_dmatch scrutinee (Clause pats body where_decs) failure_matches = do
let failure_exp = maybeDCaseE ("Non-exhaustive patterns in " ++ (show n))
scrutinee failure_matches
exp <- dsBody body where_decs failure_exp
(pats', exp') <- dsPatsOverExp pats exp
uni_pats <- fmap getAll $ concatMapM (fmap All . isUniversalPattern) pats'
let match = DMatch (mkTupleDPat pats') exp'
if uni_pats
then return [match]
else return (match : failure_matches)
dsType :: DsMonad q => Type -> q DType
dsType (ForallT tvbs preds ty) = DForallT <$> mapM dsTvb tvbs <*> dsCxt preds <*> dsType ty
dsType (AppT t1 t2) = DAppT <$> dsType t1 <*> dsType t2
dsType (SigT ty ki) = DSigT <$> dsType ty <*> dsType ki
dsType (VarT name) = return $ DVarT name
dsType (ConT name) = return $ DConT name
dsType (PromotedT name) = return $ DConT name
dsType (TupleT n) = return $ DConT (tupleTypeName n)
dsType (UnboxedTupleT n) = return $ DConT (unboxedTupleTypeName n)
dsType ArrowT = return DArrowT
dsType ListT = return $ DConT ''[]
dsType (PromotedTupleT n) = return $ DConT (tupleDataName n)
dsType PromotedNilT = return $ DConT '[]
dsType PromotedConsT = return $ DConT '(:)
dsType StarT = return $ DConT typeKindName
dsType ConstraintT = return $ DConT ''Constraint
dsType (LitT lit) = return $ DLitT lit
#if __GLASGOW_HASKELL__ >= 709
dsType EqualityT = return $ DConT ''(~)
#endif
#if __GLASGOW_HASKELL__ > 710
dsType (InfixT t1 n t2) = DAppT <$> (DAppT (DConT n) <$> dsType t1) <*> dsType t2
dsType (UInfixT _ _ _) = fail "Cannot desugar unresolved infix operators."
dsType (ParensT t) = dsType t
dsType WildCardT = return DWildCardT
#endif
#if __GLASGOW_HASKELL__ >= 801
dsType (UnboxedSumT arity) = return $ DConT (unboxedSumTypeName arity)
#endif
#if __GLASGOW_HASKELL__ >= 807
dsType (AppKindT t k) = DAppKindT <$> dsType t <*> dsType k
dsType (ImplicitParamT n t) = do
t' <- dsType t
return $ DConT ''IP `DAppT` DLitT (StrTyLit n) `DAppT` t'
#endif
dsTvb :: DsMonad q => TyVarBndr -> q DTyVarBndr
dsTvb (PlainTV n) = return $ DPlainTV n
dsTvb (KindedTV n k) = DKindedTV n <$> dsType k
dsCxt :: DsMonad q => Cxt -> q DCxt
dsCxt = concatMapM dsPred
#if __GLASGOW_HASKELL__ >= 801
type DerivingClause = DerivClause
dsDerivClause :: DsMonad q => DerivingClause -> q DDerivClause
dsDerivClause (DerivClause mds cxt) =
DDerivClause <$> mapM dsDerivStrategy mds <*> dsCxt cxt
#elif __GLASGOW_HASKELL__ >= 711
type DerivingClause = Pred
dsDerivClause :: DsMonad q => DerivingClause -> q DDerivClause
dsDerivClause p = DDerivClause Nothing <$> dsPred p
#else
type DerivingClause = Name
dsDerivClause :: DsMonad q => DerivingClause -> q DDerivClause
dsDerivClause n = pure $ DDerivClause Nothing [DConT n]
#endif
#if __GLASGOW_HASKELL__ >= 801
dsDerivStrategy :: DsMonad q => DerivStrategy -> q DDerivStrategy
dsDerivStrategy StockStrategy = pure DStockStrategy
dsDerivStrategy AnyclassStrategy = pure DAnyclassStrategy
dsDerivStrategy NewtypeStrategy = pure DNewtypeStrategy
#if __GLASGOW_HASKELL__ >= 805
dsDerivStrategy (ViaStrategy ty) = DViaStrategy <$> dsType ty
#endif
#endif
#if __GLASGOW_HASKELL__ >= 801
dsPatSynDir :: DsMonad q => Name -> PatSynDir -> q DPatSynDir
dsPatSynDir _ Unidir = pure DUnidir
dsPatSynDir _ ImplBidir = pure DImplBidir
dsPatSynDir n (ExplBidir clauses) = DExplBidir <$> dsClauses n clauses
#endif
dsPred :: DsMonad q => Pred -> q DCxt
#if __GLASGOW_HASKELL__ < 709
dsPred (ClassP n tys) = do
ts' <- mapM dsType tys
return [foldl DAppT (DConT n) ts']
dsPred (EqualP t1 t2) = do
ts' <- mapM dsType [t1, t2]
return [foldl DAppT (DConT ''(~)) ts']
#else
dsPred t
| Just ts <- splitTuple_maybe t
= concatMapM dsPred ts
dsPred (ForallT tvbs cxt p) = do
ps' <- dsPred p
case ps' of
[p'] -> (:[]) <$> (DForallT <$> mapM dsTvb tvbs <*> dsCxt cxt <*> pure p')
_ -> fail "Cannot desugar constraint tuples in the body of a quantified constraint"
dsPred (AppT t1 t2) = do
[p1] <- dsPred t1
(:[]) <$> DAppT p1 <$> dsType t2
dsPred (SigT ty ki) = do
preds <- dsPred ty
case preds of
[p] -> (:[]) <$> DSigT p <$> dsType ki
other -> return other
dsPred (VarT n) = return [DVarT n]
dsPred (ConT n) = return [DConT n]
dsPred t@(PromotedT _) =
impossible $ "Promoted type seen as head of constraint: " ++ show t
dsPred (TupleT 0) = return [DConT (tupleTypeName 0)]
dsPred (TupleT _) =
impossible "Internal error in th-desugar in detecting tuple constraints."
dsPred t@(UnboxedTupleT _) =
impossible $ "Unboxed tuple seen as head of constraint: " ++ show t
dsPred ArrowT = impossible "Arrow seen as head of constraint."
dsPred ListT = impossible "List seen as head of constraint."
dsPred (PromotedTupleT _) =
impossible "Promoted tuple seen as head of constraint."
dsPred PromotedNilT = impossible "Promoted nil seen as head of constraint."
dsPred PromotedConsT = impossible "Promoted cons seen as head of constraint."
dsPred StarT = impossible "* seen as head of constraint."
dsPred ConstraintT =
impossible "The kind `Constraint' seen as head of constraint."
dsPred t@(LitT _) =
impossible $ "Type literal seen as head of constraint: " ++ show t
dsPred EqualityT = return [DConT ''(~)]
#if __GLASGOW_HASKELL__ > 710
dsPred (InfixT t1 n t2) = (:[]) <$> (DAppT <$> (DAppT (DConT n) <$> dsType t1) <*> dsType t2)
dsPred (UInfixT _ _ _) = fail "Cannot desugar unresolved infix operators."
dsPred (ParensT t) = dsPred t
dsPred WildCardT = return [DWildCardT]
#endif
#if __GLASGOW_HASKELL__ >= 801
dsPred t@(UnboxedSumT {}) =
impossible $ "Unboxed sum seen as head of constraint: " ++ show t
#endif
#if __GLASGOW_HASKELL__ >= 807
dsPred (AppKindT t k) = do
[p] <- dsPred t
(:[]) <$> (DAppKindT p <$> dsType k)
dsPred (ImplicitParamT n t) = do
t' <- dsType t
return [DConT ''IP `DAppT` DLitT (StrTyLit n) `DAppT` t']
#endif
#endif
dsReify :: DsMonad q => Name -> q (Maybe DInfo)
dsReify = traverse dsInfo <=< reifyWithLocals_maybe
reorderFields :: DsMonad q => Name -> [VarStrictType] -> [FieldExp] -> [DExp] -> q [DExp]
reorderFields = reorderFields' dsExp
reorderFieldsPat :: DsMonad q => Name -> [VarStrictType] -> [FieldPat] -> PatM q [DPat]
reorderFieldsPat con_name field_decs field_pats =
reorderFields' dsPat con_name field_decs field_pats (repeat DWildP)
reorderFields' :: (Applicative m, Fail.MonadFail m)
=> (a -> m da)
-> Name
-> [VarStrictType] -> [(Name, a)]
-> [da] -> m [da]
reorderFields' ds_thing con_name field_names_types field_things deflts =
check_valid_fields >> reorder field_names deflts
where
field_names = map (\(a, _, _) -> a) field_names_types
check_valid_fields =
forM_ field_things $ \(thing_name, _) ->
unless (thing_name `elem` field_names) $
fail $ "Constructor ‘" ++ nameBase con_name ++ "‘ does not have field ‘"
++ nameBase thing_name ++ "‘"
reorder [] _ = return []
reorder (field_name : rest) (deflt : rest_deflt) = do
rest' <- reorder rest rest_deflt
case find (\(thing_name, _) -> thing_name == field_name) field_things of
Just (_, thing) -> (: rest') <$> ds_thing thing
Nothing -> return $ deflt : rest'
reorder (_ : _) [] = error "Internal error in th-desugar."
mkTupleDExp :: [DExp] -> DExp
mkTupleDExp [exp] = exp
mkTupleDExp exps = foldl DAppE (DConE $ tupleDataName (length exps)) exps
mkTupleExp :: [Exp] -> Exp
mkTupleExp [exp] = exp
mkTupleExp exps = foldl AppE (ConE $ tupleDataName (length exps)) exps
mkTupleDPat :: [DPat] -> DPat
mkTupleDPat [pat] = pat
mkTupleDPat pats = DConP (tupleDataName (length pats)) pats
mkTuplePat :: [Pat] -> Pat
mkTuplePat [pat] = pat
mkTuplePat pats = ConP (tupleDataName (length pats)) pats
isUniversalPattern :: DsMonad q => DPat -> q Bool
isUniversalPattern (DLitP {}) = return False
isUniversalPattern (DVarP {}) = return True
isUniversalPattern (DConP con_name pats) = do
data_name <- dataConNameToDataName con_name
(_tvbs, cons) <- getDataD "Internal error." data_name
if length cons == 1
then fmap and $ mapM isUniversalPattern pats
else return False
isUniversalPattern (DTildeP {}) = return True
isUniversalPattern (DBangP pat) = isUniversalPattern pat
isUniversalPattern (DSigP pat _) = isUniversalPattern pat
isUniversalPattern DWildP = return True
applyDExp :: DExp -> [DExp] -> DExp
applyDExp = foldl DAppE
applyDType :: DType -> [DTypeArg] -> DType
applyDType = foldl apply
where
apply :: DType -> DTypeArg -> DType
apply f (DTANormal x) = f `DAppT` x
apply f (DTyArg x) = f `DAppKindT` x
data DTypeArg
= DTANormal DType
| DTyArg DKind
deriving (Eq, Show, Typeable, Data, Generic)
dsTypeArg :: DsMonad q => TypeArg -> q DTypeArg
dsTypeArg (TANormal t) = DTANormal <$> dsType t
dsTypeArg (TyArg k) = DTyArg <$> dsType k
filterDTANormals :: [DTypeArg] -> [DType]
filterDTANormals = mapMaybe getDTANormal
where
getDTANormal :: DTypeArg -> Maybe DType
getDTANormal (DTANormal t) = Just t
getDTANormal (DTyArg {}) = Nothing
dTyVarBndrToDType :: DTyVarBndr -> DType
dTyVarBndrToDType (DPlainTV a) = DVarT a
dTyVarBndrToDType (DKindedTV a k) = DVarT a `DSigT` k
probablyWrongUnDTypeArg :: DTypeArg -> DType
probablyWrongUnDTypeArg (DTANormal t) = t
probablyWrongUnDTypeArg (DTyArg k) = k
#if __GLASGOW_HASKELL__ <= 710
strictToBang :: Strict -> Bang
strictToBang IsStrict = Bang NoSourceUnpackedness SourceStrict
strictToBang NotStrict = Bang NoSourceUnpackedness NoSourceStrictness
strictToBang Unpacked = Bang SourceUnpack SourceStrict
#else
strictToBang :: Bang -> Bang
strictToBang = id
#endif
nonFamilyDataReturnType :: Name -> [DTyVarBndr] -> DType
nonFamilyDataReturnType con_name =
applyDType (DConT con_name) . map (DTANormal . dTyVarBndrToDType)
dataFamInstReturnType :: Name -> [DTypeArg] -> DType
dataFamInstReturnType fam_name = applyDType (DConT fam_name)
dataFamInstTvbs :: [DTypeArg] -> [DTyVarBndr]
dataFamInstTvbs = toposortTyVarsOf . map probablyWrongUnDTypeArg
toposortTyVarsOf :: [DType] -> [DTyVarBndr]
toposortTyVarsOf tys =
let freeVars :: [Name]
freeVars = F.toList $ foldMap fvDType tys
varKindSigs :: Map Name DKind
varKindSigs = foldMap go_ty tys
where
go_ty :: DType -> Map Name DKind
go_ty (DForallT tvbs ctxt t) =
go_tvbs tvbs (foldMap go_ty ctxt `mappend` go_ty t)
go_ty (DAppT t1 t2) = go_ty t1 `mappend` go_ty t2
go_ty (DAppKindT t k) = go_ty t `mappend` go_ty k
go_ty (DSigT t k) =
let kSigs = go_ty k
in case t of
DVarT n -> M.insert n k kSigs
_ -> go_ty t `mappend` kSigs
go_ty (DVarT {}) = mempty
go_ty (DConT {}) = mempty
go_ty DArrowT = mempty
go_ty (DLitT {}) = mempty
go_ty DWildCardT = mempty
go_tvbs :: [DTyVarBndr] -> Map Name DKind -> Map Name DKind
go_tvbs tvbs m = foldr go_tvb m tvbs
go_tvb :: DTyVarBndr -> Map Name DKind -> Map Name DKind
go_tvb (DPlainTV n) m = M.delete n m
go_tvb (DKindedTV n k) m = M.delete n m `mappend` go_ty k
scopedSort :: [Name] -> [Name]
scopedSort = go [] []
go :: [Name]
-> [Set Name]
-> [Name]
-> [Name]
go acc _fv_list [] = reverse acc
go acc fv_list (tv:tvs)
= go acc' fv_list' tvs
where
(acc', fv_list') = insert tv acc fv_list
insert :: Name
-> [Name]
-> [Set Name]
-> ([Name], [Set Name])
insert tv [] [] = ([tv], [kindFVSet tv])
insert tv (a:as) (fvs:fvss)
| tv `S.member` fvs
, (as', fvss') <- insert tv as fvss
= (a:as', fvs `S.union` fv_tv : fvss')
| otherwise
= (tv:a:as, fvs `S.union` fv_tv : fvs : fvss)
where
fv_tv = kindFVSet tv
insert _ _ _ = error "scopedSort"
kindFVSet n =
maybe S.empty (OS.toSet . fvDType)
(M.lookup n varKindSigs)
ascribeWithKind n =
maybe (DPlainTV n) (DKindedTV n) (M.lookup n varKindSigs)
isKindBinderOnOldGHCs
#if __GLASGOW_HASKELL__ >= 800
= const False
#else
= (`elem` kindVars)
where
kindVars = foldMap fvDType $ M.elems varKindSigs
#endif
in map ascribeWithKind $
filter (not . isKindBinderOnOldGHCs) $
scopedSort freeVars
dtvbName :: DTyVarBndr -> Name
dtvbName (DPlainTV n) = n
dtvbName (DKindedTV n _) = n
unravel :: DType -> ([DTyVarBndr], [DPred], [DType], DType)
unravel (DForallT tvbs cxt ty) =
let (tvbs', cxt', tys, res) = unravel ty in
(tvbs ++ tvbs', cxt ++ cxt', tys, res)
unravel (DAppT (DAppT DArrowT t1) t2) =
let (tvbs, cxt, tys, res) = unravel t2 in
(tvbs, cxt, t1 : tys, res)
unravel t = ([], [], [], t)
unfoldDType :: DType -> (DType, [DTypeArg])
unfoldDType = go []
where
go :: [DTypeArg] -> DType -> (DType, [DTypeArg])
go acc (DForallT _ _ ty) = go acc ty
go acc (DAppT ty1 ty2) = go (DTANormal ty2:acc) ty1
go acc (DAppKindT ty ki) = go (DTyArg ki:acc) ty
go acc (DSigT ty _) = go acc ty
go acc ty = (ty, acc)
extractTvbKind :: DTyVarBndr -> Maybe DKind
extractTvbKind (DPlainTV _) = Nothing
extractTvbKind (DKindedTV _ k) = Just k
unusedArgument :: a
unusedArgument = error "Unused"