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ghcide/src-ghc88/Development/IDE/GHC/HieAst.hs
Dmitrii Kovanikov 07cf929ac6
[#518] Build ghcide with GHC 8.10.1 (#519) 
* [#518] Build ghcide with GHC 8.10.1

Resolves #518

* Move CPP logic to the Compat module

* Revert changes to mkHieFile

* Add local fork of HieAst for 8.10.1

The fix for mkHieFile didn't make it into 8.10.1, so the override is still needed

* Ignore hlint in src-ghc810/HieAst.hs

* Whitelist CPP for Development.IDE.GHC.Orphans

* [#518] Build ghcide with GHC 8.10.1

Resolves #518

* Move CPP logic to the Compat module

* Revert changes to mkHieFile

* Add local fork of HieAst for 8.10.1

The fix for mkHieFile didn't make it into 8.10.1, so the override is still needed

* Ignore hlint in src-ghc810/HieAst.hs

* Whitelist CPP for Development.IDE.GHC.Orphans

* Plugin tests known broken in 8.10.1 (#556)

* Bump up ghc-check version

Co-authored-by: Pepe Iborra <pepeiborra@gmail.com>

Co-authored-by: pepe iborra <pepeiborra@gmail.com>
2020-05-11 16:55:54 +02:00

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{-
Forked from GHC v8.8.1 to work around the readFile side effect in mkHiefile
Main functions for .hie file generation
-}
{- HLINT ignore -}
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE UndecidableInstances #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE TypeSynonymInstances #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE TypeApplications #-}
{-# LANGUAGE AllowAmbiguousTypes #-}
{-# LANGUAGE ViewPatterns #-}
{-# LANGUAGE DeriveDataTypeable #-}
module Development.IDE.GHC.HieAst ( mkHieFile ) where
import Avail ( Avails )
import Bag ( Bag, bagToList )
import BasicTypes
import BooleanFormula
import Class ( FunDep )
import CoreUtils ( exprType )
import ConLike ( conLikeName )
import Desugar ( deSugarExpr )
import FieldLabel
import HsSyn
import HscTypes
import Module ( ModuleName, ml_hs_file )
import MonadUtils ( concatMapM, liftIO )
import Name ( Name, nameSrcSpan, setNameLoc )
import SrcLoc
import TcHsSyn ( hsLitType, hsPatType )
import Type ( mkFunTys, Type )
import TysWiredIn ( mkListTy, mkSumTy )
import Var ( Id, Var, setVarName, varName, varType )
import TcRnTypes
import MkIface ( mkIfaceExports )
import HieTypes
import HieUtils
import qualified Data.Array as A
import qualified Data.ByteString as BS
import qualified Data.Map as M
import qualified Data.Set as S
import Data.Data ( Data, Typeable )
import Data.List (foldl', foldl1' )
import Data.Maybe ( listToMaybe )
import Control.Monad.Trans.Reader
import Control.Monad.Trans.Class ( lift )
-- These synonyms match those defined in main/GHC.hs
type RenamedSource = ( HsGroup GhcRn, [LImportDecl GhcRn]
, Maybe [(LIE GhcRn, Avails)]
, Maybe LHsDocString )
type TypecheckedSource = LHsBinds GhcTc
{- Note [Name Remapping]
The Typechecker introduces new names for mono names in AbsBinds.
We don't care about the distinction between mono and poly bindings,
so we replace all occurrences of the mono name with the poly name.
-}
newtype HieState = HieState
{ name_remapping :: M.Map Name Id
}
initState :: HieState
initState = HieState M.empty
class ModifyState a where -- See Note [Name Remapping]
addSubstitution :: a -> a -> HieState -> HieState
instance ModifyState Name where
addSubstitution _ _ hs = hs
instance ModifyState Id where
addSubstitution mono poly hs =
hs{name_remapping = M.insert (varName mono) poly (name_remapping hs)}
modifyState :: ModifyState (IdP p) => [ABExport p] -> HieState -> HieState
modifyState = foldr go id
where
go ABE{abe_poly=poly,abe_mono=mono} f = addSubstitution mono poly . f
go _ f = f
type HieM = ReaderT HieState Hsc
-- | Construct an 'HieFile' from the outputs of the typechecker.
mkHieFile :: ModSummary
-> TcGblEnv
-> RenamedSource
-> BS.ByteString
-> Hsc HieFile
mkHieFile ms ts rs src = do
let tc_binds = tcg_binds ts
(asts', arr) <- getCompressedAsts tc_binds rs
let Just src_file = ml_hs_file $ ms_location ms
return $ HieFile
{ hie_hs_file = src_file
, hie_module = ms_mod ms
, hie_types = arr
, hie_asts = asts'
-- mkIfaceExports sorts the AvailInfos for stability
, hie_exports = mkIfaceExports (tcg_exports ts)
, hie_hs_src = src
}
getCompressedAsts :: TypecheckedSource -> RenamedSource
-> Hsc (HieASTs TypeIndex, A.Array TypeIndex HieTypeFlat)
getCompressedAsts ts rs = do
asts <- enrichHie ts rs
return $ compressTypes asts
enrichHie :: TypecheckedSource -> RenamedSource -> Hsc (HieASTs Type)
enrichHie ts (hsGrp, imports, exports, _) = flip runReaderT initState $ do
tasts <- toHie $ fmap (BC RegularBind ModuleScope) ts
rasts <- processGrp hsGrp
imps <- toHie $ filter (not . ideclImplicit . unLoc) imports
exps <- toHie $ fmap (map $ IEC Export . fst) exports
let spanFile children = case children of
[] -> mkRealSrcSpan (mkRealSrcLoc "" 1 1) (mkRealSrcLoc "" 1 1)
_ -> mkRealSrcSpan (realSrcSpanStart $ nodeSpan $ head children)
(realSrcSpanEnd $ nodeSpan $ last children)
modulify xs =
Node (simpleNodeInfo "Module" "Module") (spanFile xs) xs
asts = HieASTs
$ resolveTyVarScopes
$ M.map (modulify . mergeSortAsts)
$ M.fromListWith (++)
$ map (\x -> (srcSpanFile (nodeSpan x),[x])) flat_asts
flat_asts = concat
[ tasts
, rasts
, imps
, exps
]
return asts
where
processGrp grp = concatM
[ toHie $ fmap (RS ModuleScope ) hs_valds grp
, toHie $ hs_splcds grp
, toHie $ hs_tyclds grp
, toHie $ hs_derivds grp
, toHie $ hs_fixds grp
, toHie $ hs_defds grp
, toHie $ hs_fords grp
, toHie $ hs_warnds grp
, toHie $ hs_annds grp
, toHie $ hs_ruleds grp
]
getRealSpan :: SrcSpan -> Maybe Span
getRealSpan (RealSrcSpan sp) = Just sp
getRealSpan _ = Nothing
grhss_span :: GRHSs p body -> SrcSpan
grhss_span (GRHSs _ xs bs) = foldl' combineSrcSpans (getLoc bs) (map getLoc xs)
grhss_span (XGRHSs _) = error "XGRHS has no span"
bindingsOnly :: [Context Name] -> [HieAST a]
bindingsOnly [] = []
bindingsOnly (C c n : xs) = case nameSrcSpan n of
RealSrcSpan span -> Node nodeinfo span [] : bindingsOnly xs
where nodeinfo = NodeInfo S.empty [] (M.singleton (Right n) info)
info = mempty{identInfo = S.singleton c}
_ -> bindingsOnly xs
concatM :: Monad m => [m [a]] -> m [a]
concatM xs = concat <$> sequence xs
{- Note [Capturing Scopes and other non local information]
toHie is a local tranformation, but scopes of bindings cannot be known locally,
hence we have to push the relevant info down into the binding nodes.
We use the following types (*Context and *Scoped) to wrap things and
carry the required info
(Maybe Span) always carries the span of the entire binding, including rhs
-}
data Context a = C ContextInfo a -- Used for names and bindings
data RContext a = RC RecFieldContext a
data RFContext a = RFC RecFieldContext (Maybe Span) a
-- ^ context for record fields
data IEContext a = IEC IEType a
-- ^ context for imports/exports
data BindContext a = BC BindType Scope a
-- ^ context for imports/exports
data PatSynFieldContext a = PSC (Maybe Span) a
-- ^ context for pattern synonym fields.
data SigContext a = SC SigInfo a
-- ^ context for type signatures
data SigInfo = SI SigType (Maybe Span)
data SigType = BindSig | ClassSig | InstSig
data RScoped a = RS Scope a
-- ^ Scope spans over everything to the right of a, (mostly) not
-- including a itself
-- (Includes a in a few special cases like recursive do bindings) or
-- let/where bindings
-- | Pattern scope
data PScoped a = PS (Maybe Span)
Scope -- ^ use site of the pattern
Scope -- ^ pattern to the right of a, not including a
a
deriving (Typeable, Data) -- Pattern Scope
{- Note [TyVar Scopes]
Due to -XScopedTypeVariables, type variables can be in scope quite far from
their original binding. We resolve the scope of these type variables
in a separate pass
-}
data TScoped a = TS TyVarScope a -- TyVarScope
data TVScoped a = TVS TyVarScope Scope a -- TyVarScope
-- ^ First scope remains constant
-- Second scope is used to build up the scope of a tyvar over
-- things to its right, ala RScoped
-- | Each element scopes over the elements to the right
listScopes :: Scope -> [Located a] -> [RScoped (Located a)]
listScopes _ [] = []
listScopes rhsScope [pat] = [RS rhsScope pat]
listScopes rhsScope (pat : pats) = RS sc pat : pats'
where
pats'@((RS scope p):_) = listScopes rhsScope pats
sc = combineScopes scope $ mkScope $ getLoc p
-- | 'listScopes' specialised to 'PScoped' things
patScopes
:: Maybe Span
-> Scope
-> Scope
-> [LPat (GhcPass p)]
-> [PScoped (LPat (GhcPass p))]
patScopes rsp useScope patScope xs =
map (\(RS sc a) -> PS rsp useScope sc (unLoc a)) $
listScopes patScope (map dL xs)
-- | 'listScopes' specialised to 'TVScoped' things
tvScopes
:: TyVarScope
-> Scope
-> [LHsTyVarBndr a]
-> [TVScoped (LHsTyVarBndr a)]
tvScopes tvScope rhsScope xs =
map (\(RS sc a)-> TVS tvScope sc a) $ listScopes rhsScope xs
{- Note [Scoping Rules for SigPat]
Explicitly quantified variables in pattern type signatures are not
brought into scope in the rhs, but implicitly quantified variables
are (HsWC and HsIB).
This is unlike other signatures, where explicitly quantified variables
are brought into the RHS Scope
For example
foo :: forall a. ...;
foo = ... -- a is in scope here
bar (x :: forall a. a -> a) = ... -- a is not in scope here
-- ^ a is in scope here (pattern body)
bax (x :: a) = ... -- a is in scope here
Because of HsWC and HsIB pass on their scope to their children
we must wrap the LHsType in pattern signatures in a
Shielded explictly, so that the HsWC/HsIB scope is not passed
on the the LHsType
-}
data Shielded a = SH Scope a -- Ignores its TScope, uses its own scope instead
type family ProtectedSig a where
ProtectedSig GhcRn = HsWildCardBndrs GhcRn (HsImplicitBndrs
GhcRn
(Shielded (LHsType GhcRn)))
ProtectedSig GhcTc = NoExt
class ProtectSig a where
protectSig :: Scope -> LHsSigWcType (NoGhcTc a) -> ProtectedSig a
instance (HasLoc a) => HasLoc (Shielded a) where
loc (SH _ a) = loc a
instance (ToHie (TScoped a)) => ToHie (TScoped (Shielded a)) where
toHie (TS _ (SH sc a)) = toHie (TS (ResolvedScopes [sc]) a)
instance ProtectSig GhcTc where
protectSig _ _ = NoExt
instance ProtectSig GhcRn where
protectSig sc (HsWC a (HsIB b sig)) =
HsWC a (HsIB b (SH sc sig))
protectSig _ _ = error "protectSig not given HsWC (HsIB)"
class HasLoc a where
-- ^ defined so that HsImplicitBndrs and HsWildCardBndrs can
-- know what their implicit bindings are scoping over
loc :: a -> SrcSpan
instance HasLoc thing => HasLoc (TScoped thing) where
loc (TS _ a) = loc a
instance HasLoc thing => HasLoc (PScoped thing) where
loc (PS _ _ _ a) = loc a
instance HasLoc (LHsQTyVars GhcRn) where
loc (HsQTvs _ vs) = loc vs
loc _ = noSrcSpan
instance HasLoc thing => HasLoc (HsImplicitBndrs a thing) where
loc (HsIB _ a) = loc a
loc _ = noSrcSpan
instance HasLoc thing => HasLoc (HsWildCardBndrs a thing) where
loc (HsWC _ a) = loc a
loc _ = noSrcSpan
instance HasLoc (Located a) where
loc (L l _) = l
instance HasLoc a => HasLoc [a] where
loc [] = noSrcSpan
loc xs = foldl1' combineSrcSpans $ map loc xs
instance (HasLoc a, HasLoc b) => HasLoc (FamEqn s a b) where
loc (FamEqn _ a Nothing b _ c) = foldl1' combineSrcSpans [loc a, loc b, loc c]
loc (FamEqn _ a (Just tvs) b _ c) = foldl1' combineSrcSpans
[loc a, loc tvs, loc b, loc c]
loc _ = noSrcSpan
instance (HasLoc tm, HasLoc ty) => HasLoc (HsArg tm ty) where
loc (HsValArg tm) = loc tm
loc (HsTypeArg _ ty) = loc ty
loc (HsArgPar sp) = sp
instance HasLoc (HsDataDefn GhcRn) where
loc def@(HsDataDefn{}) = loc $ dd_cons def
-- Only used for data family instances, so we only need rhs
-- Most probably the rest will be unhelpful anyway
loc _ = noSrcSpan
instance HasLoc (Pat (GhcPass a)) where
loc (dL -> L l _) = l
-- | The main worker class
class ToHie a where
toHie :: a -> HieM [HieAST Type]
-- | Used to collect type info
class Data a => HasType a where
getTypeNode :: a -> HieM [HieAST Type]
instance (ToHie a) => ToHie [a] where
toHie = concatMapM toHie
instance (ToHie a) => ToHie (Bag a) where
toHie = toHie . bagToList
instance (ToHie a) => ToHie (Maybe a) where
toHie = maybe (pure []) toHie
instance ToHie (Context (Located NoExt)) where
toHie _ = pure []
instance ToHie (TScoped NoExt) where
toHie _ = pure []
instance ToHie (IEContext (Located ModuleName)) where
toHie (IEC c (L (RealSrcSpan span) mname)) =
pure $ [Node (NodeInfo S.empty [] idents) span []]
where details = mempty{identInfo = S.singleton (IEThing c)}
idents = M.singleton (Left mname) details
toHie _ = pure []
instance ToHie (Context (Located Var)) where
toHie c = case c of
C context (L (RealSrcSpan span) name')
-> do
m <- asks name_remapping
let name = M.findWithDefault name' (varName name') m
pure
[Node
(NodeInfo S.empty [] $
M.singleton (Right $ varName name)
(IdentifierDetails (Just $ varType name')
(S.singleton context)))
span
[]]
_ -> pure []
instance ToHie (Context (Located Name)) where
toHie c = case c of
C context (L (RealSrcSpan span) name') -> do
m <- asks name_remapping
let name = case M.lookup name' m of
Just var -> varName var
Nothing -> name'
pure
[Node
(NodeInfo S.empty [] $
M.singleton (Right name)
(IdentifierDetails Nothing
(S.singleton context)))
span
[]]
_ -> pure []
-- | Dummy instances - never called
instance ToHie (TScoped (LHsSigWcType GhcTc)) where
toHie _ = pure []
instance ToHie (TScoped (LHsWcType GhcTc)) where
toHie _ = pure []
instance ToHie (SigContext (LSig GhcTc)) where
toHie _ = pure []
instance ToHie (TScoped Type) where
toHie _ = pure []
instance HasType (LHsBind GhcRn) where
getTypeNode (L spn bind) = makeNode bind spn
instance HasType (LHsBind GhcTc) where
getTypeNode (L spn bind) = case bind of
FunBind{fun_id = name} -> makeTypeNode bind spn (varType $ unLoc name)
_ -> makeNode bind spn
instance HasType (LPat GhcRn) where
getTypeNode (dL -> L spn pat) = makeNode pat spn
instance HasType (LPat GhcTc) where
getTypeNode (dL -> L spn opat) = makeTypeNode opat spn (hsPatType opat)
instance HasType (LHsExpr GhcRn) where
getTypeNode (L spn e) = makeNode e spn
-- | This instance tries to construct 'HieAST' nodes which include the type of
-- the expression. It is not yet possible to do this efficiently for all
-- expression forms, so we skip filling in the type for those inputs.
--
-- 'HsApp', for example, doesn't have any type information available directly on
-- the node. Our next recourse would be to desugar it into a 'CoreExpr' then
-- query the type of that. Yet both the desugaring call and the type query both
-- involve recursive calls to the function and argument! This is particularly
-- problematic when you realize that the HIE traversal will eventually visit
-- those nodes too and ask for their types again.
--
-- Since the above is quite costly, we just skip cases where computing the
-- expression's type is going to be expensive.
--
-- See #16233
instance HasType (LHsExpr GhcTc) where
getTypeNode e@(L spn e') = lift $
-- Some expression forms have their type immediately available
let tyOpt = case e' of
HsLit _ l -> Just (hsLitType l)
HsOverLit _ o -> Just (overLitType o)
HsLam _ (MG { mg_ext = groupTy }) -> Just (matchGroupType groupTy)
HsLamCase _ (MG { mg_ext = groupTy }) -> Just (matchGroupType groupTy)
HsCase _ _ (MG { mg_ext = groupTy }) -> Just (mg_res_ty groupTy)
ExplicitList ty _ _ -> Just (mkListTy ty)
ExplicitSum ty _ _ _ -> Just (mkSumTy ty)
HsDo ty _ _ -> Just ty
HsMultiIf ty _ -> Just ty
_ -> Nothing
in
case tyOpt of
_ | skipDesugaring e' -> fallback
| otherwise -> do
hs_env <- Hsc $ \e w -> return (e,w)
(_,mbe) <- liftIO $ deSugarExpr hs_env e
maybe fallback (makeTypeNode e' spn . exprType) mbe
where
fallback = makeNode e' spn
matchGroupType :: MatchGroupTc -> Type
matchGroupType (MatchGroupTc args res) = mkFunTys args res
-- | Skip desugaring of these expressions for performance reasons.
--
-- See impact on Haddock output (esp. missing type annotations or links)
-- before marking more things here as 'False'. See impact on Haddock
-- performance before marking more things as 'True'.
skipDesugaring :: HsExpr a -> Bool
skipDesugaring e = case e of
HsVar{} -> False
HsUnboundVar{} -> False
HsConLikeOut{} -> False
HsRecFld{} -> False
HsOverLabel{} -> False
HsIPVar{} -> False
HsWrap{} -> False
_ -> True
instance ( ToHie (Context (Located (IdP a)))
, ToHie (MatchGroup a (LHsExpr a))
, ToHie (PScoped (LPat a))
, ToHie (GRHSs a (LHsExpr a))
, ToHie (LHsExpr a)
, ToHie (Located (PatSynBind a a))
, HasType (LHsBind a)
, ModifyState (IdP a)
, Data (HsBind a)
) => ToHie (BindContext (LHsBind a)) where
toHie (BC context scope b@(L span bind)) =
concatM $ getTypeNode b : case bind of
FunBind{fun_id = name, fun_matches = matches} ->
[ toHie $ C (ValBind context scope $ getRealSpan span) name
, toHie matches
]
PatBind{pat_lhs = lhs, pat_rhs = rhs} ->
[ toHie $ PS (getRealSpan span) scope NoScope lhs
, toHie rhs
]
VarBind{var_rhs = expr} ->
[ toHie expr
]
AbsBinds{abs_exports = xs, abs_binds = binds} ->
[ local (modifyState xs) $ -- Note [Name Remapping]
toHie $ fmap (BC context scope) binds
]
PatSynBind _ psb ->
[ toHie $ L span psb -- PatSynBinds only occur at the top level
]
XHsBindsLR _ -> []
instance ( ToHie (LMatch a body)
) => ToHie (MatchGroup a body) where
toHie mg = concatM $ case mg of
MG{ mg_alts = (L span alts) , mg_origin = FromSource } ->
[ pure $ locOnly span
, toHie alts
]
MG{} -> []
XMatchGroup _ -> []
instance ( ToHie (Context (Located (IdP a)))
, ToHie (PScoped (LPat a))
, ToHie (HsPatSynDir a)
) => ToHie (Located (PatSynBind a a)) where
toHie (L sp psb) = concatM $ case psb of
PSB{psb_id=var, psb_args=dets, psb_def=pat, psb_dir=dir} ->
[ toHie $ C (Decl PatSynDec $ getRealSpan sp) var
, toHie $ toBind dets
, toHie $ PS Nothing lhsScope NoScope pat
, toHie dir
]
where
lhsScope = combineScopes varScope detScope
varScope = mkLScope var
detScope = case dets of
(PrefixCon args) -> foldr combineScopes NoScope $ map mkLScope args
(InfixCon a b) -> combineScopes (mkLScope a) (mkLScope b)
(RecCon r) -> foldr go NoScope r
go (RecordPatSynField a b) c = combineScopes c
$ combineScopes (mkLScope a) (mkLScope b)
detSpan = case detScope of
LocalScope a -> Just a
_ -> Nothing
toBind (PrefixCon args) = PrefixCon $ map (C Use) args
toBind (InfixCon a b) = InfixCon (C Use a) (C Use b)
toBind (RecCon r) = RecCon $ map (PSC detSpan) r
XPatSynBind _ -> []
instance ( ToHie (MatchGroup a (LHsExpr a))
) => ToHie (HsPatSynDir a) where
toHie dir = case dir of
ExplicitBidirectional mg -> toHie mg
_ -> pure []
instance ( a ~ GhcPass p
, ToHie body
, ToHie (HsMatchContext (NameOrRdrName (IdP a)))
, ToHie (PScoped (LPat a))
, ToHie (GRHSs a body)
, Data (Match a body)
) => ToHie (LMatch (GhcPass p) body) where
toHie (L span m ) = concatM $ makeNode m span : case m of
Match{m_ctxt=mctx, m_pats = pats, m_grhss = grhss } ->
[ toHie mctx
, let rhsScope = mkScope $ grhss_span grhss
in toHie $ patScopes Nothing rhsScope NoScope pats
, toHie grhss
]
XMatch _ -> []
instance ( ToHie (Context (Located a))
) => ToHie (HsMatchContext a) where
toHie (FunRhs{mc_fun=name}) = toHie $ C MatchBind name
toHie (StmtCtxt a) = toHie a
toHie _ = pure []
instance ( ToHie (HsMatchContext a)
) => ToHie (HsStmtContext a) where
toHie (PatGuard a) = toHie a
toHie (ParStmtCtxt a) = toHie a
toHie (TransStmtCtxt a) = toHie a
toHie _ = pure []
instance ( a ~ GhcPass p
, ToHie (Context (Located (IdP a)))
, ToHie (RContext (HsRecFields a (PScoped (LPat a))))
, ToHie (LHsExpr a)
, ToHie (TScoped (LHsSigWcType a))
, ProtectSig a
, ToHie (TScoped (ProtectedSig a))
, HasType (LPat a)
, Data (HsSplice a)
) => ToHie (PScoped (LPat (GhcPass p))) where
toHie (PS rsp scope pscope lpat@(dL -> L ospan opat)) =
concatM $ getTypeNode lpat : case opat of
WildPat _ ->
[]
VarPat _ lname ->
[ toHie $ C (PatternBind scope pscope rsp) lname
]
LazyPat _ p ->
[ toHie $ PS rsp scope pscope p
]
AsPat _ lname pat ->
[ toHie $ C (PatternBind scope
(combineScopes (mkLScope (dL pat)) pscope)
rsp)
lname
, toHie $ PS rsp scope pscope pat
]
ParPat _ pat ->
[ toHie $ PS rsp scope pscope pat
]
BangPat _ pat ->
[ toHie $ PS rsp scope pscope pat
]
ListPat _ pats ->
[ toHie $ patScopes rsp scope pscope pats
]
TuplePat _ pats _ ->
[ toHie $ patScopes rsp scope pscope pats
]
SumPat _ pat _ _ ->
[ toHie $ PS rsp scope pscope pat
]
ConPatIn c dets ->
[ toHie $ C Use c
, toHie $ contextify dets
]
ConPatOut {pat_con = con, pat_args = dets}->
[ toHie $ C Use $ fmap conLikeName con
, toHie $ contextify dets
]
ViewPat _ expr pat ->
[ toHie expr
, toHie $ PS rsp scope pscope pat
]
SplicePat _ sp ->
[ toHie $ L ospan sp
]
LitPat _ _ ->
[]
NPat _ _ _ _ ->
[]
NPlusKPat _ n _ _ _ _ ->
[ toHie $ C (PatternBind scope pscope rsp) n
]
SigPat _ pat sig ->
[ toHie $ PS rsp scope pscope pat
, let cscope = mkLScope (dL pat) in
toHie $ TS (ResolvedScopes [cscope, scope, pscope])
(protectSig @a cscope sig)
-- See Note [Scoping Rules for SigPat]
]
CoPat _ _ _ _ ->
[]
XPat _ -> []
where
contextify (PrefixCon args) = PrefixCon $ patScopes rsp scope pscope args
contextify (InfixCon a b) = InfixCon a' b'
where [a', b'] = patScopes rsp scope pscope [a,b]
contextify (RecCon r) = RecCon $ RC RecFieldMatch $ contextify_rec r
contextify_rec (HsRecFields fds a) = HsRecFields (map go scoped_fds) a
where
go (RS fscope (L spn (HsRecField lbl pat pun))) =
L spn $ HsRecField lbl (PS rsp scope fscope pat) pun
scoped_fds = listScopes pscope fds
instance ( ToHie body
, ToHie (LGRHS a body)
, ToHie (RScoped (LHsLocalBinds a))
) => ToHie (GRHSs a body) where
toHie grhs = concatM $ case grhs of
GRHSs _ grhss binds ->
[ toHie grhss
, toHie $ RS (mkScope $ grhss_span grhs) binds
]
XGRHSs _ -> []
instance ( ToHie (Located body)
, ToHie (RScoped (GuardLStmt a))
, Data (GRHS a (Located body))
) => ToHie (LGRHS a (Located body)) where
toHie (L span g) = concatM $ makeNode g span : case g of
GRHS _ guards body ->
[ toHie $ listScopes (mkLScope body) guards
, toHie body
]
XGRHS _ -> []
instance ( a ~ GhcPass p
, ToHie (Context (Located (IdP a)))
, HasType (LHsExpr a)
, ToHie (PScoped (LPat a))
, ToHie (MatchGroup a (LHsExpr a))
, ToHie (LGRHS a (LHsExpr a))
, ToHie (RContext (HsRecordBinds a))
, ToHie (RFContext (Located (AmbiguousFieldOcc a)))
, ToHie (ArithSeqInfo a)
, ToHie (LHsCmdTop a)
, ToHie (RScoped (GuardLStmt a))
, ToHie (RScoped (LHsLocalBinds a))
, ToHie (TScoped (LHsWcType (NoGhcTc a)))
, ToHie (TScoped (LHsSigWcType (NoGhcTc a)))
, Data (HsExpr a)
, Data (HsSplice a)
, Data (HsTupArg a)
, Data (AmbiguousFieldOcc a)
) => ToHie (LHsExpr (GhcPass p)) where
toHie e@(L mspan oexpr) = concatM $ getTypeNode e : case oexpr of
HsVar _ (L _ var) ->
[ toHie $ C Use (L mspan var)
-- Patch up var location since typechecker removes it
]
HsUnboundVar _ _ ->
[]
HsConLikeOut _ con ->
[ toHie $ C Use $ L mspan $ conLikeName con
]
HsRecFld _ fld ->
[ toHie $ RFC RecFieldOcc Nothing (L mspan fld)
]
HsOverLabel _ _ _ -> []
HsIPVar _ _ -> []
HsOverLit _ _ -> []
HsLit _ _ -> []
HsLam _ mg ->
[ toHie mg
]
HsLamCase _ mg ->
[ toHie mg
]
HsApp _ a b ->
[ toHie a
, toHie b
]
HsAppType _ expr sig ->
[ toHie expr
, toHie $ TS (ResolvedScopes []) sig
]
OpApp _ a b c ->
[ toHie a
, toHie b
, toHie c
]
NegApp _ a _ ->
[ toHie a
]
HsPar _ a ->
[ toHie a
]
SectionL _ a b ->
[ toHie a
, toHie b
]
SectionR _ a b ->
[ toHie a
, toHie b
]
ExplicitTuple _ args _ ->
[ toHie args
]
ExplicitSum _ _ _ expr ->
[ toHie expr
]
HsCase _ expr matches ->
[ toHie expr
, toHie matches
]
HsIf _ _ a b c ->
[ toHie a
, toHie b
, toHie c
]
HsMultiIf _ grhss ->
[ toHie grhss
]
HsLet _ binds expr ->
[ toHie $ RS (mkLScope expr) binds
, toHie expr
]
HsDo _ _ (L ispan stmts) ->
[ pure $ locOnly ispan
, toHie $ listScopes NoScope stmts
]
ExplicitList _ _ exprs ->
[ toHie exprs
]
RecordCon {rcon_con_name = name, rcon_flds = binds}->
[ toHie $ C Use name
, toHie $ RC RecFieldAssign $ binds
]
RecordUpd {rupd_expr = expr, rupd_flds = upds}->
[ toHie expr
, toHie $ map (RC RecFieldAssign) upds
]
ExprWithTySig _ expr sig ->
[ toHie expr
, toHie $ TS (ResolvedScopes [mkLScope expr]) sig
]
ArithSeq _ _ info ->
[ toHie info
]
HsSCC _ _ _ expr ->
[ toHie expr
]
HsCoreAnn _ _ _ expr ->
[ toHie expr
]
HsProc _ pat cmdtop ->
[ toHie $ PS Nothing (mkLScope cmdtop) NoScope pat
, toHie cmdtop
]
HsStatic _ expr ->
[ toHie expr
]
HsArrApp _ a b _ _ ->
[ toHie a
, toHie b
]
HsArrForm _ expr _ cmds ->
[ toHie expr
, toHie cmds
]
HsTick _ _ expr ->
[ toHie expr
]
HsBinTick _ _ _ expr ->
[ toHie expr
]
HsTickPragma _ _ _ _ expr ->
[ toHie expr
]
HsWrap _ _ a ->
[ toHie $ L mspan a
]
HsBracket _ b ->
[ toHie b
]
HsRnBracketOut _ b p ->
[ toHie b
, toHie p
]
HsTcBracketOut _ b p ->
[ toHie b
, toHie p
]
HsSpliceE _ x ->
[ toHie $ L mspan x
]
EWildPat _ -> []
EAsPat _ a b ->
[ toHie $ C Use a
, toHie b
]
EViewPat _ a b ->
[ toHie a
, toHie b
]
ELazyPat _ a ->
[ toHie a
]
XExpr _ -> []
instance ( a ~ GhcPass p
, ToHie (LHsExpr a)
, Data (HsTupArg a)
) => ToHie (LHsTupArg (GhcPass p)) where
toHie (L span arg) = concatM $ makeNode arg span : case arg of
Present _ expr ->
[ toHie expr
]
Missing _ -> []
XTupArg _ -> []
instance ( a ~ GhcPass p
, ToHie (PScoped (LPat a))
, ToHie (LHsExpr a)
, ToHie (SigContext (LSig a))
, ToHie (RScoped (LHsLocalBinds a))
, ToHie (RScoped (ApplicativeArg a))
, ToHie (Located body)
, Data (StmtLR a a (Located body))
, Data (StmtLR a a (Located (HsExpr a)))
) => ToHie (RScoped (LStmt (GhcPass p) (Located body))) where
toHie (RS scope (L span stmt)) = concatM $ makeNode stmt span : case stmt of
LastStmt _ body _ _ ->
[ toHie body
]
BindStmt _ pat body _ _ ->
[ toHie $ PS (getRealSpan $ getLoc body) scope NoScope pat
, toHie body
]
ApplicativeStmt _ stmts _ ->
[ concatMapM (toHie . RS scope . snd) stmts
]
BodyStmt _ body _ _ ->
[ toHie body
]
LetStmt _ binds ->
[ toHie $ RS scope binds
]
ParStmt _ parstmts _ _ ->
[ concatMapM (\(ParStmtBlock _ stmts _ _) ->
toHie $ listScopes NoScope stmts)
parstmts
]
TransStmt {trS_stmts = stmts, trS_using = using, trS_by = by} ->
[ toHie $ listScopes scope stmts
, toHie using
, toHie by
]
RecStmt {recS_stmts = stmts} ->
[ toHie $ map (RS $ combineScopes scope (mkScope span)) stmts
]
XStmtLR _ -> []
instance ( ToHie (LHsExpr a)
, ToHie (PScoped (LPat a))
, ToHie (BindContext (LHsBind a))
, ToHie (SigContext (LSig a))
, ToHie (RScoped (HsValBindsLR a a))
, Data (HsLocalBinds a)
) => ToHie (RScoped (LHsLocalBinds a)) where
toHie (RS scope (L sp binds)) = concatM $ makeNode binds sp : case binds of
EmptyLocalBinds _ -> []
HsIPBinds _ _ -> []
HsValBinds _ valBinds ->
[ toHie $ RS (combineScopes scope $ mkScope sp)
valBinds
]
XHsLocalBindsLR _ -> []
instance ( ToHie (BindContext (LHsBind a))
, ToHie (SigContext (LSig a))
, ToHie (RScoped (XXValBindsLR a a))
) => ToHie (RScoped (HsValBindsLR a a)) where
toHie (RS sc v) = concatM $ case v of
ValBinds _ binds sigs ->
[ toHie $ fmap (BC RegularBind sc) binds
, toHie $ fmap (SC (SI BindSig Nothing)) sigs
]
XValBindsLR x -> [ toHie $ RS sc x ]
instance ToHie (RScoped (NHsValBindsLR GhcTc)) where
toHie (RS sc (NValBinds binds sigs)) = concatM $
[ toHie (concatMap (map (BC RegularBind sc) . bagToList . snd) binds)
, toHie $ fmap (SC (SI BindSig Nothing)) sigs
]
instance ToHie (RScoped (NHsValBindsLR GhcRn)) where
toHie (RS sc (NValBinds binds sigs)) = concatM $
[ toHie (concatMap (map (BC RegularBind sc) . bagToList . snd) binds)
, toHie $ fmap (SC (SI BindSig Nothing)) sigs
]
instance ( ToHie (RContext (LHsRecField a arg))
) => ToHie (RContext (HsRecFields a arg)) where
toHie (RC c (HsRecFields fields _)) = toHie $ map (RC c) fields
instance ( ToHie (RFContext (Located label))
, ToHie arg
, HasLoc arg
, Data label
, Data arg
) => ToHie (RContext (LHsRecField' label arg)) where
toHie (RC c (L span recfld)) = concatM $ makeNode recfld span : case recfld of
HsRecField label expr _ ->
[ toHie $ RFC c (getRealSpan $ loc expr) label
, toHie expr
]
removeDefSrcSpan :: Name -> Name
removeDefSrcSpan n = setNameLoc n noSrcSpan
instance ToHie (RFContext (LFieldOcc GhcRn)) where
toHie (RFC c rhs (L nspan f)) = concatM $ case f of
FieldOcc name _ ->
[ toHie $ C (RecField c rhs) (L nspan $ removeDefSrcSpan name)
]
XFieldOcc _ -> []
instance ToHie (RFContext (LFieldOcc GhcTc)) where
toHie (RFC c rhs (L nspan f)) = concatM $ case f of
FieldOcc var _ ->
let var' = setVarName var (removeDefSrcSpan $ varName var)
in [ toHie $ C (RecField c rhs) (L nspan var')
]
XFieldOcc _ -> []
instance ToHie (RFContext (Located (AmbiguousFieldOcc GhcRn))) where
toHie (RFC c rhs (L nspan afo)) = concatM $ case afo of
Unambiguous name _ ->
[ toHie $ C (RecField c rhs) $ L nspan $ removeDefSrcSpan name
]
Ambiguous _name _ ->
[ ]
XAmbiguousFieldOcc _ -> []
instance ToHie (RFContext (Located (AmbiguousFieldOcc GhcTc))) where
toHie (RFC c rhs (L nspan afo)) = concatM $ case afo of
Unambiguous var _ ->
let var' = setVarName var (removeDefSrcSpan $ varName var)
in [ toHie $ C (RecField c rhs) (L nspan var')
]
Ambiguous var _ ->
let var' = setVarName var (removeDefSrcSpan $ varName var)
in [ toHie $ C (RecField c rhs) (L nspan var')
]
XAmbiguousFieldOcc _ -> []
instance ( a ~ GhcPass p
, ToHie (PScoped (LPat a))
, ToHie (BindContext (LHsBind a))
, ToHie (LHsExpr a)
, ToHie (SigContext (LSig a))
, ToHie (RScoped (HsValBindsLR a a))
, Data (StmtLR a a (Located (HsExpr a)))
, Data (HsLocalBinds a)
) => ToHie (RScoped (ApplicativeArg (GhcPass p))) where
toHie (RS sc (ApplicativeArgOne _ pat expr _)) = concatM
[ toHie $ PS Nothing sc NoScope pat
, toHie expr
]
toHie (RS sc (ApplicativeArgMany _ stmts _ pat)) = concatM
[ toHie $ listScopes NoScope stmts
, toHie $ PS Nothing sc NoScope pat
]
toHie (RS _ (XApplicativeArg _)) = pure []
instance (ToHie arg, ToHie rec) => ToHie (HsConDetails arg rec) where
toHie (PrefixCon args) = toHie args
toHie (RecCon rec) = toHie rec
toHie (InfixCon a b) = concatM [ toHie a, toHie b]
instance ( ToHie (LHsCmd a)
, Data (HsCmdTop a)
) => ToHie (LHsCmdTop a) where
toHie (L span top) = concatM $ makeNode top span : case top of
HsCmdTop _ cmd ->
[ toHie cmd
]
XCmdTop _ -> []
instance ( a ~ GhcPass p
, ToHie (PScoped (LPat a))
, ToHie (BindContext (LHsBind a))
, ToHie (LHsExpr a)
, ToHie (MatchGroup a (LHsCmd a))
, ToHie (SigContext (LSig a))
, ToHie (RScoped (HsValBindsLR a a))
, Data (HsCmd a)
, Data (HsCmdTop a)
, Data (StmtLR a a (Located (HsCmd a)))
, Data (HsLocalBinds a)
, Data (StmtLR a a (Located (HsExpr a)))
) => ToHie (LHsCmd (GhcPass p)) where
toHie (L span cmd) = concatM $ makeNode cmd span : case cmd of
HsCmdArrApp _ a b _ _ ->
[ toHie a
, toHie b
]
HsCmdArrForm _ a _ _ cmdtops ->
[ toHie a
, toHie cmdtops
]
HsCmdApp _ a b ->
[ toHie a
, toHie b
]
HsCmdLam _ mg ->
[ toHie mg
]
HsCmdPar _ a ->
[ toHie a
]
HsCmdCase _ expr alts ->
[ toHie expr
, toHie alts
]
HsCmdIf _ _ a b c ->
[ toHie a
, toHie b
, toHie c
]
HsCmdLet _ binds cmd' ->
[ toHie $ RS (mkLScope cmd') binds
, toHie cmd'
]
HsCmdDo _ (L ispan stmts) ->
[ pure $ locOnly ispan
, toHie $ listScopes NoScope stmts
]
HsCmdWrap _ _ _ -> []
XCmd _ -> []
instance ToHie (TyClGroup GhcRn) where
toHie (TyClGroup _ classes roles instances) = concatM
[ toHie classes
, toHie roles
, toHie instances
]
toHie (XTyClGroup _) = pure []
instance ToHie (LTyClDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
FamDecl {tcdFam = fdecl} ->
[ toHie (L span fdecl)
]
SynDecl {tcdLName = name, tcdTyVars = vars, tcdRhs = typ} ->
[ toHie $ C (Decl SynDec $ getRealSpan span) name
, toHie $ TS (ResolvedScopes [mkScope $ getLoc typ]) vars
, toHie typ
]
DataDecl {tcdLName = name, tcdTyVars = vars, tcdDataDefn = defn} ->
[ toHie $ C (Decl DataDec $ getRealSpan span) name
, toHie $ TS (ResolvedScopes [quant_scope, rhs_scope]) vars
, toHie defn
]
where
quant_scope = mkLScope $ dd_ctxt defn
rhs_scope = sig_sc `combineScopes` con_sc `combineScopes` deriv_sc
sig_sc = maybe NoScope mkLScope $ dd_kindSig defn
con_sc = foldr combineScopes NoScope $ map mkLScope $ dd_cons defn
deriv_sc = mkLScope $ dd_derivs defn
ClassDecl { tcdCtxt = context
, tcdLName = name
, tcdTyVars = vars
, tcdFDs = deps
, tcdSigs = sigs
, tcdMeths = meths
, tcdATs = typs
, tcdATDefs = deftyps
} ->
[ toHie $ C (Decl ClassDec $ getRealSpan span) name
, toHie context
, toHie $ TS (ResolvedScopes [context_scope, rhs_scope]) vars
, toHie deps
, toHie $ map (SC $ SI ClassSig $ getRealSpan span) sigs
, toHie $ fmap (BC InstanceBind ModuleScope) meths
, toHie typs
, concatMapM (pure . locOnly . getLoc) deftyps
, toHie $ map (go . unLoc) deftyps
]
where
context_scope = mkLScope context
rhs_scope = foldl1' combineScopes $ map mkScope
[ loc deps, loc sigs, loc (bagToList meths), loc typs, loc deftyps]
go :: TyFamDefltEqn GhcRn
-> FamEqn GhcRn (TScoped (LHsQTyVars GhcRn)) (LHsType GhcRn)
go (FamEqn a var bndrs pat b rhs) =
FamEqn a var bndrs (TS (ResolvedScopes [mkLScope rhs]) pat) b rhs
go (XFamEqn NoExt) = XFamEqn NoExt
XTyClDecl _ -> []
instance ToHie (LFamilyDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
FamilyDecl _ info name vars _ sig inj ->
[ toHie $ C (Decl FamDec $ getRealSpan span) name
, toHie $ TS (ResolvedScopes [rhsSpan]) vars
, toHie info
, toHie $ RS injSpan sig
, toHie inj
]
where
rhsSpan = sigSpan `combineScopes` injSpan
sigSpan = mkScope $ getLoc sig
injSpan = maybe NoScope (mkScope . getLoc) inj
XFamilyDecl _ -> []
instance ToHie (FamilyInfo GhcRn) where
toHie (ClosedTypeFamily (Just eqns)) = concatM $
[ concatMapM (pure . locOnly . getLoc) eqns
, toHie $ map go eqns
]
where
go (L l ib) = TS (ResolvedScopes [mkScope l]) ib
toHie _ = pure []
instance ToHie (RScoped (LFamilyResultSig GhcRn)) where
toHie (RS sc (L span sig)) = concatM $ makeNode sig span : case sig of
NoSig _ ->
[]
KindSig _ k ->
[ toHie k
]
TyVarSig _ bndr ->
[ toHie $ TVS (ResolvedScopes [sc]) NoScope bndr
]
XFamilyResultSig _ -> []
instance ToHie (Located (FunDep (Located Name))) where
toHie (L span fd@(lhs, rhs)) = concatM $
[ makeNode fd span
, toHie $ map (C Use) lhs
, toHie $ map (C Use) rhs
]
instance (ToHie pats, ToHie rhs, HasLoc pats, HasLoc rhs)
=> ToHie (TScoped (FamEqn GhcRn pats rhs)) where
toHie (TS _ f) = toHie f
instance ( ToHie pats
, ToHie rhs
, HasLoc pats
, HasLoc rhs
) => ToHie (FamEqn GhcRn pats rhs) where
toHie fe@(FamEqn _ var tybndrs pats _ rhs) = concatM $
[ toHie $ C (Decl InstDec $ getRealSpan $ loc fe) var
, toHie $ fmap (tvScopes (ResolvedScopes []) scope) tybndrs
, toHie pats
, toHie rhs
]
where scope = combineScopes patsScope rhsScope
patsScope = mkScope (loc pats)
rhsScope = mkScope (loc rhs)
toHie (XFamEqn _) = pure []
instance ToHie (LInjectivityAnn GhcRn) where
toHie (L span ann) = concatM $ makeNode ann span : case ann of
InjectivityAnn lhs rhs ->
[ toHie $ C Use lhs
, toHie $ map (C Use) rhs
]
instance ToHie (HsDataDefn GhcRn) where
toHie (HsDataDefn _ _ ctx _ mkind cons derivs) = concatM
[ toHie ctx
, toHie mkind
, toHie cons
, toHie derivs
]
toHie (XHsDataDefn _) = pure []
instance ToHie (HsDeriving GhcRn) where
toHie (L span clauses) = concatM
[ pure $ locOnly span
, toHie clauses
]
instance ToHie (LHsDerivingClause GhcRn) where
toHie (L span cl) = concatM $ makeNode cl span : case cl of
HsDerivingClause _ strat (L ispan tys) ->
[ toHie strat
, pure $ locOnly ispan
, toHie $ map (TS (ResolvedScopes [])) tys
]
XHsDerivingClause _ -> []
instance ToHie (Located (DerivStrategy GhcRn)) where
toHie (L span strat) = concatM $ makeNode strat span : case strat of
StockStrategy -> []
AnyclassStrategy -> []
NewtypeStrategy -> []
ViaStrategy s -> [ toHie $ TS (ResolvedScopes []) s ]
instance ToHie (Located OverlapMode) where
toHie (L span _) = pure $ locOnly span
instance ToHie (LConDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
ConDeclGADT { con_names = names, con_qvars = qvars
, con_mb_cxt = ctx, con_args = args, con_res_ty = typ } ->
[ toHie $ map (C (Decl ConDec $ getRealSpan span)) names
, toHie $ TS (ResolvedScopes [ctxScope, rhsScope]) qvars
, toHie ctx
, toHie args
, toHie typ
]
where
rhsScope = combineScopes argsScope tyScope
ctxScope = maybe NoScope mkLScope ctx
argsScope = condecl_scope args
tyScope = mkLScope typ
ConDeclH98 { con_name = name, con_ex_tvs = qvars
, con_mb_cxt = ctx, con_args = dets } ->
[ toHie $ C (Decl ConDec $ getRealSpan span) name
, toHie $ tvScopes (ResolvedScopes []) rhsScope qvars
, toHie ctx
, toHie dets
]
where
rhsScope = combineScopes ctxScope argsScope
ctxScope = maybe NoScope mkLScope ctx
argsScope = condecl_scope dets
XConDecl _ -> []
where condecl_scope args = case args of
PrefixCon xs -> foldr combineScopes NoScope $ map mkLScope xs
InfixCon a b -> combineScopes (mkLScope a) (mkLScope b)
RecCon x -> mkLScope x
instance ToHie (Located [LConDeclField GhcRn]) where
toHie (L span decls) = concatM $
[ pure $ locOnly span
, toHie decls
]
instance ( HasLoc thing
, ToHie (TScoped thing)
) => ToHie (TScoped (HsImplicitBndrs GhcRn thing)) where
toHie (TS sc (HsIB ibrn a)) = concatM $
[ pure $ bindingsOnly $ map (C $ TyVarBind (mkScope span) sc) ibrn
, toHie $ TS sc a
]
where span = loc a
toHie (TS _ (XHsImplicitBndrs _)) = pure []
instance ( HasLoc thing
, ToHie (TScoped thing)
) => ToHie (TScoped (HsWildCardBndrs GhcRn thing)) where
toHie (TS sc (HsWC names a)) = concatM $
[ pure $ bindingsOnly $ map (C $ TyVarBind (mkScope span) sc) names
, toHie $ TS sc a
]
where span = loc a
toHie (TS _ (XHsWildCardBndrs _)) = pure []
instance ToHie (SigContext (LSig GhcRn)) where
toHie (SC (SI styp msp) (L sp sig)) = concatM $ makeNode sig sp : case sig of
TypeSig _ names typ ->
[ toHie $ map (C TyDecl) names
, toHie $ TS (UnresolvedScope (map unLoc names) Nothing) typ
]
PatSynSig _ names typ ->
[ toHie $ map (C TyDecl) names
, toHie $ TS (UnresolvedScope (map unLoc names) Nothing) typ
]
ClassOpSig _ _ names typ ->
[ case styp of
ClassSig -> toHie $ map (C $ ClassTyDecl $ getRealSpan sp) names
_ -> toHie $ map (C $ TyDecl) names
, toHie $ TS (UnresolvedScope (map unLoc names) msp) typ
]
IdSig _ _ -> []
FixSig _ fsig ->
[ toHie $ L sp fsig
]
InlineSig _ name _ ->
[ toHie $ (C Use) name
]
SpecSig _ name typs _ ->
[ toHie $ (C Use) name
, toHie $ map (TS (ResolvedScopes [])) typs
]
SpecInstSig _ _ typ ->
[ toHie $ TS (ResolvedScopes []) typ
]
MinimalSig _ _ form ->
[ toHie form
]
SCCFunSig _ _ name mtxt ->
[ toHie $ (C Use) name
, pure $ maybe [] (locOnly . getLoc) mtxt
]
CompleteMatchSig _ _ (L ispan names) typ ->
[ pure $ locOnly ispan
, toHie $ map (C Use) names
, toHie $ fmap (C Use) typ
]
XSig _ -> []
instance ToHie (LHsType GhcRn) where
toHie x = toHie $ TS (ResolvedScopes []) x
instance ToHie (TScoped (LHsType GhcRn)) where
toHie (TS tsc (L span t)) = concatM $ makeNode t span : case t of
HsForAllTy _ bndrs body ->
[ toHie $ tvScopes tsc (mkScope $ getLoc body) bndrs
, toHie body
]
HsQualTy _ ctx body ->
[ toHie ctx
, toHie body
]
HsTyVar _ _ var ->
[ toHie $ C Use var
]
HsAppTy _ a b ->
[ toHie a
, toHie b
]
HsAppKindTy _ ty ki ->
[ toHie ty
, toHie $ TS (ResolvedScopes []) ki
]
HsFunTy _ a b ->
[ toHie a
, toHie b
]
HsListTy _ a ->
[ toHie a
]
HsTupleTy _ _ tys ->
[ toHie tys
]
HsSumTy _ tys ->
[ toHie tys
]
HsOpTy _ a op b ->
[ toHie a
, toHie $ C Use op
, toHie b
]
HsParTy _ a ->
[ toHie a
]
HsIParamTy _ ip ty ->
[ toHie ip
, toHie ty
]
HsKindSig _ a b ->
[ toHie a
, toHie b
]
HsSpliceTy _ a ->
[ toHie $ L span a
]
HsDocTy _ a _ ->
[ toHie a
]
HsBangTy _ _ ty ->
[ toHie ty
]
HsRecTy _ fields ->
[ toHie fields
]
HsExplicitListTy _ _ tys ->
[ toHie tys
]
HsExplicitTupleTy _ tys ->
[ toHie tys
]
HsTyLit _ _ -> []
HsWildCardTy _ -> []
HsStarTy _ _ -> []
XHsType _ -> []
instance (ToHie tm, ToHie ty) => ToHie (HsArg tm ty) where
toHie (HsValArg tm) = toHie tm
toHie (HsTypeArg _ ty) = toHie ty
toHie (HsArgPar sp) = pure $ locOnly sp
instance ToHie (TVScoped (LHsTyVarBndr GhcRn)) where
toHie (TVS tsc sc (L span bndr)) = concatM $ makeNode bndr span : case bndr of
UserTyVar _ var ->
[ toHie $ C (TyVarBind sc tsc) var
]
KindedTyVar _ var kind ->
[ toHie $ C (TyVarBind sc tsc) var
, toHie kind
]
XTyVarBndr _ -> []
instance ToHie (TScoped (LHsQTyVars GhcRn)) where
toHie (TS sc (HsQTvs (HsQTvsRn implicits _) vars)) = concatM $
[ pure $ bindingsOnly bindings
, toHie $ tvScopes sc NoScope vars
]
where
varLoc = loc vars
bindings = map (C $ TyVarBind (mkScope varLoc) sc) implicits
toHie (TS _ (XLHsQTyVars _)) = pure []
instance ToHie (LHsContext GhcRn) where
toHie (L span tys) = concatM $
[ pure $ locOnly span
, toHie tys
]
instance ToHie (LConDeclField GhcRn) where
toHie (L span field) = concatM $ makeNode field span : case field of
ConDeclField _ fields typ _ ->
[ toHie $ map (RFC RecFieldDecl (getRealSpan $ loc typ)) fields
, toHie typ
]
XConDeclField _ -> []
instance ToHie (LHsExpr a) => ToHie (ArithSeqInfo a) where
toHie (From expr) = toHie expr
toHie (FromThen a b) = concatM $
[ toHie a
, toHie b
]
toHie (FromTo a b) = concatM $
[ toHie a
, toHie b
]
toHie (FromThenTo a b c) = concatM $
[ toHie a
, toHie b
, toHie c
]
instance ToHie (LSpliceDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
SpliceDecl _ splice _ ->
[ toHie splice
]
XSpliceDecl _ -> []
instance ToHie (HsBracket a) where
toHie _ = pure []
instance ToHie PendingRnSplice where
toHie _ = pure []
instance ToHie PendingTcSplice where
toHie _ = pure []
instance ToHie (LBooleanFormula (Located Name)) where
toHie (L span form) = concatM $ makeNode form span : case form of
Var a ->
[ toHie $ C Use a
]
And forms ->
[ toHie forms
]
Or forms ->
[ toHie forms
]
Parens f ->
[ toHie f
]
instance ToHie (Located HsIPName) where
toHie (L span e) = makeNode e span
instance ( ToHie (LHsExpr a)
, Data (HsSplice a)
) => ToHie (Located (HsSplice a)) where
toHie (L span sp) = concatM $ makeNode sp span : case sp of
HsTypedSplice _ _ _ expr ->
[ toHie expr
]
HsUntypedSplice _ _ _ expr ->
[ toHie expr
]
HsQuasiQuote _ _ _ ispan _ ->
[ pure $ locOnly ispan
]
HsSpliced _ _ _ ->
[]
HsSplicedT _ ->
[]
XSplice _ -> []
instance ToHie (LRoleAnnotDecl GhcRn) where
toHie (L span annot) = concatM $ makeNode annot span : case annot of
RoleAnnotDecl _ var roles ->
[ toHie $ C Use var
, concatMapM (pure . locOnly . getLoc) roles
]
XRoleAnnotDecl _ -> []
instance ToHie (LInstDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
ClsInstD _ d ->
[ toHie $ L span d
]
DataFamInstD _ d ->
[ toHie $ L span d
]
TyFamInstD _ d ->
[ toHie $ L span d
]
XInstDecl _ -> []
instance ToHie (LClsInstDecl GhcRn) where
toHie (L span decl) = concatM
[ toHie $ TS (ResolvedScopes [mkScope span]) $ cid_poly_ty decl
, toHie $ fmap (BC InstanceBind ModuleScope) $ cid_binds decl
, toHie $ map (SC $ SI InstSig $ getRealSpan span) $ cid_sigs decl
, pure $ concatMap (locOnly . getLoc) $ cid_tyfam_insts decl
, toHie $ cid_tyfam_insts decl
, pure $ concatMap (locOnly . getLoc) $ cid_datafam_insts decl
, toHie $ cid_datafam_insts decl
, toHie $ cid_overlap_mode decl
]
instance ToHie (LDataFamInstDecl GhcRn) where
toHie (L sp (DataFamInstDecl d)) = toHie $ TS (ResolvedScopes [mkScope sp]) d
instance ToHie (LTyFamInstDecl GhcRn) where
toHie (L sp (TyFamInstDecl d)) = toHie $ TS (ResolvedScopes [mkScope sp]) d
instance ToHie (Context a)
=> ToHie (PatSynFieldContext (RecordPatSynField a)) where
toHie (PSC sp (RecordPatSynField a b)) = concatM $
[ toHie $ C (RecField RecFieldDecl sp) a
, toHie $ C Use b
]
instance ToHie (LDerivDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
DerivDecl _ typ strat overlap ->
[ toHie $ TS (ResolvedScopes []) typ
, toHie strat
, toHie overlap
]
XDerivDecl _ -> []
instance ToHie (LFixitySig GhcRn) where
toHie (L span sig) = concatM $ makeNode sig span : case sig of
FixitySig _ vars _ ->
[ toHie $ map (C Use) vars
]
XFixitySig _ -> []
instance ToHie (LDefaultDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
DefaultDecl _ typs ->
[ toHie typs
]
XDefaultDecl _ -> []
instance ToHie (LForeignDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
ForeignImport {fd_name = name, fd_sig_ty = sig, fd_fi = fi} ->
[ toHie $ C (ValBind RegularBind ModuleScope $ getRealSpan span) name
, toHie $ TS (ResolvedScopes []) sig
, toHie fi
]
ForeignExport {fd_name = name, fd_sig_ty = sig, fd_fe = fe} ->
[ toHie $ C Use name
, toHie $ TS (ResolvedScopes []) sig
, toHie fe
]
XForeignDecl _ -> []
instance ToHie ForeignImport where
toHie (CImport (L a _) (L b _) _ _ (L c _)) = pure $ concat $
[ locOnly a
, locOnly b
, locOnly c
]
instance ToHie ForeignExport where
toHie (CExport (L a _) (L b _)) = pure $ concat $
[ locOnly a
, locOnly b
]
instance ToHie (LWarnDecls GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
Warnings _ _ warnings ->
[ toHie warnings
]
XWarnDecls _ -> []
instance ToHie (LWarnDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
Warning _ vars _ ->
[ toHie $ map (C Use) vars
]
XWarnDecl _ -> []
instance ToHie (LAnnDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
HsAnnotation _ _ prov expr ->
[ toHie prov
, toHie expr
]
XAnnDecl _ -> []
instance ToHie (Context (Located a)) => ToHie (AnnProvenance a) where
toHie (ValueAnnProvenance a) = toHie $ C Use a
toHie (TypeAnnProvenance a) = toHie $ C Use a
toHie ModuleAnnProvenance = pure []
instance ToHie (LRuleDecls GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
HsRules _ _ rules ->
[ toHie rules
]
XRuleDecls _ -> []
instance ToHie (LRuleDecl GhcRn) where
toHie (L _ (XRuleDecl _)) = pure []
toHie (L span r@(HsRule _ rname _ tybndrs bndrs exprA exprB)) = concatM
[ makeNode r span
, pure $ locOnly $ getLoc rname
, toHie $ fmap (tvScopes (ResolvedScopes []) scope) tybndrs
, toHie $ map (RS $ mkScope span) bndrs
, toHie exprA
, toHie exprB
]
where scope = bndrs_sc `combineScopes` exprA_sc `combineScopes` exprB_sc
bndrs_sc = maybe NoScope mkLScope (listToMaybe bndrs)
exprA_sc = mkLScope exprA
exprB_sc = mkLScope exprB
instance ToHie (RScoped (LRuleBndr GhcRn)) where
toHie (RS sc (L span bndr)) = concatM $ makeNode bndr span : case bndr of
RuleBndr _ var ->
[ toHie $ C (ValBind RegularBind sc Nothing) var
]
RuleBndrSig _ var typ ->
[ toHie $ C (ValBind RegularBind sc Nothing) var
, toHie $ TS (ResolvedScopes [sc]) typ
]
XRuleBndr _ -> []
instance ToHie (LImportDecl GhcRn) where
toHie (L span decl) = concatM $ makeNode decl span : case decl of
ImportDecl { ideclName = name, ideclAs = as, ideclHiding = hidden } ->
[ toHie $ IEC Import name
, toHie $ fmap (IEC ImportAs) as
, maybe (pure []) goIE hidden
]
XImportDecl _ -> []
where
goIE (hiding, (L sp liens)) = concatM $
[ pure $ locOnly sp
, toHie $ map (IEC c) liens
]
where
c = if hiding then ImportHiding else Import
instance ToHie (IEContext (LIE GhcRn)) where
toHie (IEC c (L span ie)) = concatM $ makeNode ie span : case ie of
IEVar _ n ->
[ toHie $ IEC c n
]
IEThingAbs _ n ->
[ toHie $ IEC c n
]
IEThingAll _ n ->
[ toHie $ IEC c n
]
IEThingWith _ n _ ns flds ->
[ toHie $ IEC c n
, toHie $ map (IEC c) ns
, toHie $ map (IEC c) flds
]
IEModuleContents _ n ->
[ toHie $ IEC c n
]
IEGroup _ _ _ -> []
IEDoc _ _ -> []
IEDocNamed _ _ -> []
XIE _ -> []
instance ToHie (IEContext (LIEWrappedName Name)) where
toHie (IEC c (L span iewn)) = concatM $ makeNode iewn span : case iewn of
IEName n ->
[ toHie $ C (IEThing c) n
]
IEPattern p ->
[ toHie $ C (IEThing c) p
]
IEType n ->
[ toHie $ C (IEThing c) n
]
instance ToHie (IEContext (Located (FieldLbl Name))) where
toHie (IEC c (L span lbl)) = concatM $ makeNode lbl span : case lbl of
FieldLabel _ _ n ->
[ toHie $ C (IEThing c) $ L span n
]
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