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|
{-# LANGUAGE BangPatterns, StandaloneDeriving, FlexibleInstances, ViewPatterns #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE TypeApplications #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE FlexibleContexts #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
{-# OPTIONS_GHC -Wno-incomplete-record-updates #-}
{-# OPTIONS_HADDOCK hide #-}
-----------------------------------------------------------------------------
-- |
-- Module : Haddock.GhcUtils
-- Copyright : (c) David Waern 2006-2009
-- License : BSD-like
--
-- Maintainer : haddock@projects.haskell.org
-- Stability : experimental
-- Portability : portable
--
-- Utils for dealing with types from the GHC API
-----------------------------------------------------------------------------
module Haddock.GhcUtils where
import Control.Arrow
import Data.Char ( isSpace )
import Data.Maybe ( mapMaybe )
import Haddock.Types( DocName, DocNameI )
import GHC.Utils.FV as FV
import GHC.Utils.Outputable ( Outputable )
import GHC.Utils.Panic ( panic )
import GHC.Driver.Ppr (showPpr )
import GHC.Types.Name
import GHC.Unit.Module
import GHC
import GHC.Core.Class
import GHC.Driver.Session
import GHC.Types.Basic
import GHC.Types.SrcLoc ( advanceSrcLoc )
import GHC.Types.Var ( Specificity, VarBndr(..), TyVarBinder
, tyVarKind, updateTyVarKind, isInvisibleArgFlag )
import GHC.Types.Var.Set ( VarSet, emptyVarSet )
import GHC.Types.Var.Env ( TyVarEnv, extendVarEnv, elemVarEnv, emptyVarEnv )
import GHC.Core.TyCo.Rep ( Type(..) )
import GHC.Core.Type ( isRuntimeRepVar )
import GHC.Builtin.Types( liftedRepDataConTyCon )
import GHC.Parser.Annotation (IsUnicodeSyntax(..))
import GHC.Data.StringBuffer ( StringBuffer )
import qualified GHC.Data.StringBuffer as S
import Data.ByteString ( ByteString )
import qualified Data.ByteString as BS
import qualified Data.ByteString.Internal as BS
import GHC.HsToCore.Docs
moduleString :: Module -> String
moduleString = moduleNameString . moduleName
isNameSym :: Name -> Bool
isNameSym = isSymOcc . nameOccName
-- Useful when there is a signature with multiple names, e.g.
-- foo, bar :: Types..
-- but only one of the names is exported and we have to change the
-- type signature to only include the exported names.
filterLSigNames :: (IdP (GhcPass p) -> Bool) -> LSig (GhcPass p) -> Maybe (LSig (GhcPass p))
filterLSigNames p (L loc sig) = L loc <$> (filterSigNames p sig)
filterSigNames :: (IdP (GhcPass p) -> Bool) -> Sig (GhcPass p) -> Maybe (Sig (GhcPass p))
filterSigNames p orig@(SpecSig _ n _ _) = ifTrueJust (p $ unLoc n) orig
filterSigNames p orig@(InlineSig _ n _) = ifTrueJust (p $ unLoc n) orig
filterSigNames p (FixSig _ (FixitySig _ ns ty)) =
case filter (p . unLoc) ns of
[] -> Nothing
filtered -> Just (FixSig noExtField (FixitySig noExtField filtered ty))
filterSigNames _ orig@(MinimalSig _ _ _) = Just orig
filterSigNames p (TypeSig _ ns ty) =
case filter (p . unLoc) ns of
[] -> Nothing
filtered -> Just (TypeSig noExtField filtered ty)
filterSigNames p (ClassOpSig _ is_default ns ty) =
case filter (p . unLoc) ns of
[] -> Nothing
filtered -> Just (ClassOpSig noExtField is_default filtered ty)
filterSigNames p (PatSynSig _ ns ty) =
case filter (p . unLoc) ns of
[] -> Nothing
filtered -> Just (PatSynSig noExtField filtered ty)
filterSigNames _ _ = Nothing
ifTrueJust :: Bool -> name -> Maybe name
ifTrueJust True = Just
ifTrueJust False = const Nothing
sigName :: LSig GhcRn -> [IdP GhcRn]
sigName (L _ sig) = sigNameNoLoc sig
-- | Was this signature given by the user?
isUserLSig :: forall p. UnXRec p => LSig p -> Bool
isUserLSig = isUserSig . unXRec @p
isClassD :: HsDecl a -> Bool
isClassD (TyClD _ d) = isClassDecl d
isClassD _ = False
pretty :: Outputable a => DynFlags -> a -> String
pretty = showPpr
-- ---------------------------------------------------------------------
-- These functions are duplicated from the GHC API, as they must be
-- instantiated at DocNameI instead of (GhcPass _).
-- | Like 'hsTyVarName' from GHC API, but not instantiated at (GhcPass _)
hsTyVarBndrName :: forall flag n. (XXTyVarBndr n ~ NoExtCon, UnXRec n)
=> HsTyVarBndr flag n -> IdP n
hsTyVarBndrName (UserTyVar _ _ name) = unXRec @n name
hsTyVarBndrName (KindedTyVar _ _ name _) = unXRec @n name
hsTyVarNameI :: HsTyVarBndr flag DocNameI -> DocName
hsTyVarNameI (UserTyVar _ _ (L _ n)) = n
hsTyVarNameI (KindedTyVar _ _ (L _ n) _) = n
hsLTyVarNameI :: LHsTyVarBndr flag DocNameI -> DocName
hsLTyVarNameI = hsTyVarNameI . unLoc
getConNamesI :: ConDecl DocNameI -> [Located DocName]
getConNamesI ConDeclH98 {con_name = name} = [name]
getConNamesI ConDeclGADT {con_names = names} = names
hsSigTypeI :: LHsSigType DocNameI -> LHsType DocNameI
hsSigTypeI = sig_body . unLoc
mkEmptySigType :: LHsType GhcRn -> LHsSigType GhcRn
-- Dubious, because the implicit binders are empty even
-- though the type might have free varaiables
mkEmptySigType lty@(L loc ty) = L loc $ case ty of
HsForAllTy { hst_tele = HsForAllInvis { hsf_invis_bndrs = bndrs }
, hst_body = body }
-> HsSig { sig_ext = noExtField
, sig_bndrs = HsOuterExplicit { hso_xexplicit = noExtField
, hso_bndrs = bndrs }
, sig_body = body }
_ -> HsSig { sig_ext = noExtField
, sig_bndrs = HsOuterImplicit{hso_ximplicit = []}
, sig_body = lty }
mkHsForAllInvisTeleI ::
[LHsTyVarBndr Specificity DocNameI] -> HsForAllTelescope DocNameI
mkHsForAllInvisTeleI invis_bndrs =
HsForAllInvis { hsf_xinvis = noExtField, hsf_invis_bndrs = invis_bndrs }
mkHsImplicitSigTypeI :: LHsType DocNameI -> HsSigType DocNameI
mkHsImplicitSigTypeI body =
HsSig { sig_ext = noExtField
, sig_bndrs = HsOuterImplicit{hso_ximplicit = noExtField}
, sig_body = body }
getGADTConType :: ConDecl DocNameI -> LHsSigType DocNameI
-- The full type of a GADT data constructor We really only get this in
-- order to pretty-print it, and currently only in Haddock's code. So
-- we are cavalier about locations and extensions, hence the
-- 'undefined's
getGADTConType (ConDeclGADT { con_bndrs = L _ outer_bndrs
, con_mb_cxt = mcxt, con_g_args = args
, con_res_ty = res_ty })
= noLoc (HsSig { sig_ext = noExtField
, sig_bndrs = outer_bndrs
, sig_body = theta_ty })
where
theta_ty | Just theta <- mcxt
= noLoc (HsQualTy { hst_xqual = noExtField, hst_ctxt = theta, hst_body = tau_ty })
| otherwise
= tau_ty
-- tau_ty :: LHsType DocNameI
tau_ty = case args of
RecConGADT flds -> mkFunTy (noLoc (HsRecTy noExtField (unLoc flds))) res_ty
PrefixConGADT pos_args -> foldr mkFunTy res_ty (map hsScaledThing pos_args)
mkFunTy a b = noLoc (HsFunTy noExtField (HsUnrestrictedArrow NormalSyntax) a b)
getGADTConType (ConDeclH98 {}) = panic "getGADTConType"
-- Should only be called on ConDeclGADT
getMainDeclBinderI :: HsDecl DocNameI -> [IdP DocNameI]
getMainDeclBinderI (TyClD _ d) = [tcdNameI d]
getMainDeclBinderI (ValD _ d) =
case collectHsBindBinders d of
[] -> []
(name:_) -> [name]
getMainDeclBinderI (SigD _ d) = sigNameNoLoc d
getMainDeclBinderI (ForD _ (ForeignImport _ name _ _)) = [unLoc name]
getMainDeclBinderI (ForD _ (ForeignExport _ _ _ _)) = []
getMainDeclBinderI _ = []
familyDeclLNameI :: FamilyDecl DocNameI -> Located DocName
familyDeclLNameI (FamilyDecl { fdLName = n }) = n
tyClDeclLNameI :: TyClDecl DocNameI -> Located DocName
tyClDeclLNameI (FamDecl { tcdFam = fd }) = familyDeclLNameI fd
tyClDeclLNameI (SynDecl { tcdLName = ln }) = ln
tyClDeclLNameI (DataDecl { tcdLName = ln }) = ln
tyClDeclLNameI (ClassDecl { tcdLName = ln }) = ln
tcdNameI :: TyClDecl DocNameI -> DocName
tcdNameI = unLoc . tyClDeclLNameI
addClassContext :: Name -> LHsQTyVars GhcRn -> LSig GhcRn -> LSig GhcRn
-- Add the class context to a class-op signature
addClassContext cls tvs0 (L pos (ClassOpSig _ _ lname ltype))
= L pos (TypeSig noExtField lname (mkEmptyWildCardBndrs (go_sig_ty ltype)))
where
go_sig_ty (L loc (HsSig { sig_bndrs = bndrs, sig_body = ty }))
= L loc (HsSig { sig_ext = noExtField
, sig_bndrs = bndrs, sig_body = go_ty ty })
go_ty (L loc (HsForAllTy { hst_tele = tele, hst_body = ty }))
= L loc (HsForAllTy { hst_xforall = noExtField
, hst_tele = tele, hst_body = go_ty ty })
go_ty (L loc (HsQualTy { hst_ctxt = ctxt, hst_body = ty }))
= L loc (HsQualTy { hst_xqual = noExtField
, hst_ctxt = add_ctxt ctxt, hst_body = ty })
go_ty (L loc ty)
= L loc (HsQualTy { hst_xqual = noExtField
, hst_ctxt = add_ctxt (L loc []), hst_body = L loc ty })
extra_pred = nlHsTyConApp Prefix cls (lHsQTyVarsToTypes tvs0)
add_ctxt (L loc preds) = L loc (extra_pred : preds)
addClassContext _ _ sig = sig -- E.g. a MinimalSig is fine
lHsQTyVarsToTypes :: LHsQTyVars GhcRn -> [LHsTypeArg GhcRn]
lHsQTyVarsToTypes tvs
= [ HsValArg $ noLoc (HsTyVar noExtField NotPromoted (noLoc (hsLTyVarName tv)))
| tv <- hsQTvExplicit tvs ]
--------------------------------------------------------------------------------
-- * Making abstract declarations
--------------------------------------------------------------------------------
restrictTo :: [Name] -> LHsDecl GhcRn -> LHsDecl GhcRn
restrictTo names (L loc decl) = L loc $ case decl of
TyClD x d | isDataDecl d ->
TyClD x (d { tcdDataDefn = restrictDataDefn names (tcdDataDefn d) })
TyClD x d | isClassDecl d ->
TyClD x (d { tcdSigs = restrictDecls names (tcdSigs d),
tcdATs = restrictATs names (tcdATs d) })
_ -> decl
restrictDataDefn :: [Name] -> HsDataDefn GhcRn -> HsDataDefn GhcRn
restrictDataDefn names defn@(HsDataDefn { dd_ND = new_or_data, dd_cons = cons })
| DataType <- new_or_data
= defn { dd_cons = restrictCons names cons }
| otherwise -- Newtype
= case restrictCons names cons of
[] -> defn { dd_ND = DataType, dd_cons = [] }
[con] -> defn { dd_cons = [con] }
_ -> error "Should not happen"
restrictCons :: [Name] -> [LConDecl GhcRn] -> [LConDecl GhcRn]
restrictCons names decls = [ L p d | L p (Just d) <- map (fmap keep) decls ]
where
keep :: ConDecl GhcRn -> Maybe (ConDecl GhcRn)
keep d
| any (\n -> n `elem` names) (map unLoc $ getConNames d) =
case d of
ConDeclH98 { con_args = con_args' } -> case con_args' of
PrefixCon {} -> Just d
RecCon fields
| all field_avail (unLoc fields) -> Just d
| otherwise -> Just (d { con_args = PrefixCon [] (field_types $ unLoc fields) })
-- if we have *all* the field names available, then
-- keep the record declaration. Otherwise degrade to
-- a constructor declaration. This isn't quite right, but
-- it's the best we can do.
InfixCon _ _ -> Just d
ConDeclGADT { con_g_args = con_args' } -> case con_args' of
PrefixConGADT {} -> Just d
RecConGADT fields
| all field_avail (unLoc fields) -> Just d
| otherwise -> Just (d { con_g_args = PrefixConGADT (field_types $ unLoc fields) })
-- see above
where
field_avail :: LConDeclField GhcRn -> Bool
field_avail (L _ (ConDeclField _ fs _ _))
= all (\f -> extFieldOcc (unLoc f) `elem` names) fs
field_types flds = [ hsUnrestricted t | L _ (ConDeclField _ _ t _) <- flds ]
keep _ = Nothing
restrictDecls :: [Name] -> [LSig GhcRn] -> [LSig GhcRn]
restrictDecls names = mapMaybe (filterLSigNames (`elem` names))
restrictATs :: [Name] -> [LFamilyDecl GhcRn] -> [LFamilyDecl GhcRn]
restrictATs names ats = [ at | at <- ats , unLoc (fdLName (unLoc at)) `elem` names ]
-------------------------------------------------------------------------------
-- * Parenthesization
-------------------------------------------------------------------------------
-- | Precedence level (inside the 'HsType' AST).
data Precedence
= PREC_TOP -- ^ precedence of 'type' production in GHC's parser
| PREC_SIG -- ^ explicit type signature
| PREC_CTX -- ^ Used for single contexts, eg. ctx => type
-- (as opposed to (ctx1, ctx2) => type)
| PREC_FUN -- ^ precedence of 'btype' production in GHC's parser
-- (used for LH arg of (->))
| PREC_OP -- ^ arg of any infix operator
-- (we don't keep have fixity info)
| PREC_CON -- ^ arg of type application: always parenthesize unless atomic
deriving (Eq, Ord)
-- | Add in extra 'HsParTy' where needed to ensure that what would be printed
-- out using 'ppr' has enough parentheses to be re-parsed properly.
--
-- We cannot add parens that may be required by fixities because we do not have
-- any fixity information to work with in the first place :(.
reparenTypePrec :: forall a. ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> Precedence -> HsType a -> HsType a
reparenTypePrec = go
where
-- Shorter name for 'reparenType'
go :: Precedence -> HsType a -> HsType a
go _ (HsBangTy x b ty) = HsBangTy x b (reparenLType ty)
go _ (HsTupleTy x con tys) = HsTupleTy x con (map reparenLType tys)
go _ (HsSumTy x tys) = HsSumTy x (map reparenLType tys)
go _ (HsListTy x ty) = HsListTy x (reparenLType ty)
go _ (HsRecTy x flds) = HsRecTy x (map (mapXRec @a reparenConDeclField) flds)
go p (HsDocTy x ty d) = HsDocTy x (goL p ty) d
go _ (HsExplicitListTy x p tys) = HsExplicitListTy x p (map reparenLType tys)
go _ (HsExplicitTupleTy x tys) = HsExplicitTupleTy x (map reparenLType tys)
go p (HsKindSig x ty kind)
= paren p PREC_SIG $ HsKindSig x (goL PREC_SIG ty) (goL PREC_SIG kind)
go p (HsIParamTy x n ty)
= paren p PREC_SIG $ HsIParamTy x n (reparenLType ty)
go p (HsForAllTy x tele ty)
= paren p PREC_CTX $ HsForAllTy x (reparenHsForAllTelescope tele) (reparenLType ty)
go p (HsQualTy x ctxt ty)
= let p' [_] = PREC_CTX
p' _ = PREC_TOP -- parens will get added anyways later...
ctxt' = mapXRec @a (\xs -> map (goL (p' xs)) xs) ctxt
in paren p PREC_CTX $ HsQualTy x ctxt' (goL PREC_TOP ty)
go p (HsFunTy x w ty1 ty2)
= paren p PREC_FUN $ HsFunTy x w (goL PREC_FUN ty1) (goL PREC_TOP ty2)
go p (HsAppTy x fun_ty arg_ty)
= paren p PREC_CON $ HsAppTy x (goL PREC_FUN fun_ty) (goL PREC_CON arg_ty)
go p (HsAppKindTy x fun_ty arg_ki)
= paren p PREC_CON $ HsAppKindTy x (goL PREC_FUN fun_ty) (goL PREC_CON arg_ki)
go p (HsOpTy x ty1 op ty2)
= paren p PREC_FUN $ HsOpTy x (goL PREC_OP ty1) op (goL PREC_OP ty2)
go p (HsParTy _ t) = unXRec @a $ goL p t -- pretend the paren doesn't exist - it will be added back if needed
go _ t@HsTyVar{} = t
go _ t@HsStarTy{} = t
go _ t@HsSpliceTy{} = t
go _ t@HsTyLit{} = t
go _ t@HsWildCardTy{} = t
go _ t@XHsType{} = t
-- Located variant of 'go'
goL :: Precedence -> LHsType a -> LHsType a
goL ctxt_prec = mapXRec @a (go ctxt_prec)
-- Optionally wrap a type in parens
paren :: Precedence -- Precedence of context
-> Precedence -- Precedence of top-level operator
-> HsType a -> HsType a -- Wrap in parens if (ctxt >= op)
paren ctxt_prec op_prec | ctxt_prec >= op_prec = HsParTy noExtField . wrapXRec @a
| otherwise = id
-- | Add parenthesis around the types in a 'HsType' (see 'reparenTypePrec')
reparenType :: ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> HsType a -> HsType a
reparenType = reparenTypePrec PREC_TOP
-- | Add parenthesis around the types in a 'LHsType' (see 'reparenTypePrec')
reparenLType :: forall a. ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> LHsType a -> LHsType a
reparenLType = mapXRec @a reparenType
-- | Add parentheses around the types in an 'HsSigType' (see 'reparenTypePrec')
reparenSigType :: forall a. ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> HsSigType a -> HsSigType a
reparenSigType (HsSig x bndrs body) =
HsSig x (reparenOuterTyVarBndrs bndrs) (reparenLType body)
reparenSigType v@XHsSigType{} = v
-- | Add parentheses around the types in an 'HsOuterTyVarBndrs' (see 'reparenTypePrec')
reparenOuterTyVarBndrs :: forall flag a. ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> HsOuterTyVarBndrs flag a -> HsOuterTyVarBndrs flag a
reparenOuterTyVarBndrs imp@HsOuterImplicit{} = imp
reparenOuterTyVarBndrs (HsOuterExplicit x exp_bndrs) =
HsOuterExplicit x (map (mapXRec @(NoGhcTc a) reparenTyVar) exp_bndrs)
reparenOuterTyVarBndrs v@XHsOuterTyVarBndrs{} = v
-- | Add parentheses around the types in an 'HsForAllTelescope' (see 'reparenTypePrec')
reparenHsForAllTelescope :: forall a. ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> HsForAllTelescope a -> HsForAllTelescope a
reparenHsForAllTelescope (HsForAllVis x bndrs) =
HsForAllVis x (map (mapXRec @a reparenTyVar) bndrs)
reparenHsForAllTelescope (HsForAllInvis x bndrs) =
HsForAllInvis x (map (mapXRec @a reparenTyVar) bndrs)
reparenHsForAllTelescope v@XHsForAllTelescope{} = v
-- | Add parenthesis around the types in a 'HsTyVarBndr' (see 'reparenTypePrec')
reparenTyVar :: ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> HsTyVarBndr flag a -> HsTyVarBndr flag a
reparenTyVar (UserTyVar x flag n) = UserTyVar x flag n
reparenTyVar (KindedTyVar x flag n kind) = KindedTyVar x flag n (reparenLType kind)
reparenTyVar v@XTyVarBndr{} = v
-- | Add parenthesis around the types in a 'ConDeclField' (see 'reparenTypePrec')
reparenConDeclField :: ( XParTy a ~ NoExtField, NoGhcTc a ~ a
, MapXRec a, UnXRec a, WrapXRec a )
=> ConDeclField a -> ConDeclField a
reparenConDeclField (ConDeclField x n t d) = ConDeclField x n (reparenLType t) d
reparenConDeclField c@XConDeclField{} = c
-------------------------------------------------------------------------------
-- * Located
-------------------------------------------------------------------------------
unL :: Located a -> a
unL (L _ x) = x
reL :: a -> Located a
reL = L undefined
-------------------------------------------------------------------------------
-- * NamedThing instances
-------------------------------------------------------------------------------
instance NamedThing (TyClDecl GhcRn) where
getName = tcdName
-------------------------------------------------------------------------------
-- * Subordinates
-------------------------------------------------------------------------------
class Parent a where
children :: a -> [Name]
instance Parent (ConDecl GhcRn) where
children con =
case getRecConArgs_maybe con of
Nothing -> []
Just flds -> map (extFieldOcc . unLoc) $ concatMap (cd_fld_names . unLoc) (unLoc flds)
instance Parent (TyClDecl GhcRn) where
children d
| isDataDecl d = map unLoc $ concatMap (getConNames . unLoc)
$ (dd_cons . tcdDataDefn) $ d
| isClassDecl d =
map (unLoc . fdLName . unLoc) (tcdATs d) ++
[ unLoc n | L _ (TypeSig _ ns _) <- tcdSigs d, n <- ns ]
| otherwise = []
-- | A parent and its children
family :: (NamedThing a, Parent a) => a -> (Name, [Name])
family = getName &&& children
familyConDecl :: ConDecl GHC.GhcRn -> [(Name, [Name])]
familyConDecl d = zip (map unLoc (getConNames d)) (repeat $ children d)
-- | A mapping from the parent (main-binder) to its children and from each
-- child to its grand-children, recursively.
families :: TyClDecl GhcRn -> [(Name, [Name])]
families d
| isDataDecl d = family d : concatMap (familyConDecl . unLoc) (dd_cons (tcdDataDefn d))
| isClassDecl d = [family d]
| otherwise = []
-- | A mapping from child to parent
parentMap :: TyClDecl GhcRn -> [(Name, Name)]
parentMap d = [ (c, p) | (p, cs) <- families d, c <- cs ]
-- | The parents of a subordinate in a declaration
parents :: Name -> HsDecl GhcRn -> [Name]
parents n (TyClD _ d) = [ p | (c, p) <- parentMap d, c == n ]
parents _ _ = []
-------------------------------------------------------------------------------
-- * Utils that work in monads defined by GHC
-------------------------------------------------------------------------------
modifySessionDynFlags :: (DynFlags -> DynFlags) -> Ghc ()
modifySessionDynFlags f = do
dflags <- getSessionDynFlags
_ <- setSessionDynFlags (f dflags)
return ()
-- Extract the minimal complete definition of a Name, if one exists
minimalDef :: GhcMonad m => Name -> m (Maybe ClassMinimalDef)
minimalDef n = do
mty <- lookupGlobalName n
case mty of
Just (ATyCon (tyConClass_maybe -> Just c)) -> return . Just $ classMinimalDef c
_ -> return Nothing
-------------------------------------------------------------------------------
-- * DynFlags
-------------------------------------------------------------------------------
-- TODO: use `setOutputDir` from GHC
setOutputDir :: FilePath -> DynFlags -> DynFlags
setOutputDir dir dynFlags =
dynFlags { objectDir = Just dir
, hiDir = Just dir
, hieDir = Just dir
, stubDir = Just dir
, includePaths = addGlobalInclude (includePaths dynFlags) [dir]
, dumpDir = Just dir
}
-------------------------------------------------------------------------------
-- * 'StringBuffer' and 'ByteString'
-------------------------------------------------------------------------------
-- We get away with a bunch of these functions because 'StringBuffer' and
-- 'ByteString' have almost exactly the same structure.
-- | Convert a UTF-8 encoded 'ByteString' into a 'StringBuffer. This really
-- relies on the internals of both 'ByteString' and 'StringBuffer'.
--
-- /O(n)/ (but optimized into a @memcpy@ by @bytestring@ under the hood)
stringBufferFromByteString :: ByteString -> StringBuffer
stringBufferFromByteString bs =
let BS.PS fp off len = bs <> BS.pack [0,0,0]
in S.StringBuffer { S.buf = fp, S.len = len - 3, S.cur = off }
-- | Take the first @n@ /bytes/ of the 'StringBuffer' and put them in a
-- 'ByteString'.
--
-- /O(1)/
takeStringBuffer :: Int -> StringBuffer -> ByteString
takeStringBuffer !n !(S.StringBuffer fp _ cur) = BS.PS fp cur n
-- | Return the prefix of the first 'StringBuffer' that /isn't/ in the second
-- 'StringBuffer'. **The behavior is undefined if the 'StringBuffers' use
-- separate buffers.**
--
-- /O(1)/
splitStringBuffer :: StringBuffer -> StringBuffer -> ByteString
splitStringBuffer buf1 buf2 = takeStringBuffer n buf1
where n = S.byteDiff buf1 buf2
-- | Split the 'StringBuffer' at the next newline (or the end of the buffer).
-- Also: initial position is passed in and the updated position is returned.
--
-- /O(n)/ (but /O(1)/ space)
spanLine :: RealSrcLoc -> StringBuffer -> (ByteString, RealSrcLoc, StringBuffer)
spanLine !loc !buf = go loc buf
where
go !l !b
| not (S.atEnd b)
= case S.nextChar b of
('\n', b') -> (splitStringBuffer buf b', advanceSrcLoc l '\n', b')
(c, b') -> go (advanceSrcLoc l c) b'
| otherwise
= (splitStringBuffer buf b, advanceSrcLoc l '\n', b)
-- | Given a start position and a buffer with that start position, split the
-- buffer at an end position.
--
-- /O(n)/ (but /O(1)/ space)
spanPosition :: RealSrcLoc -- ^ start of buffeer
-> RealSrcLoc -- ^ position until which to take
-> StringBuffer -- ^ buffer from which to take
-> (ByteString, StringBuffer)
spanPosition !start !end !buf = go start buf
where
go !l !b
| l < end
, not (S.atEnd b)
, (c, b') <- S.nextChar b
= go (advanceSrcLoc l c) b'
| otherwise
= (splitStringBuffer buf b, b)
-- | Try to parse a line of CPP from the from of the buffer. A \"line\" of CPP
-- consists of
--
-- * at most 10 whitespace characters, including at least one newline
-- * a @#@ character
-- * keep parsing lines until you find a line not ending in @\\@.
--
-- This is chock full of heuristics about what a line of CPP is.
--
-- /O(n)/ (but /O(1)/ space)
tryCppLine :: RealSrcLoc -> StringBuffer -> Maybe (ByteString, RealSrcLoc, StringBuffer)
tryCppLine !loc !buf = spanSpace (S.prevChar buf '\n' == '\n') loc buf
where
-- Keep consuming space characters until we hit either a @#@ or something
-- else. If we hit a @#@, start parsing CPP
spanSpace !seenNl !l !b
| S.atEnd b
= Nothing
| otherwise
= case S.nextChar b of
('#' , b') | not (S.atEnd b')
, ('-', b'') <- S.nextChar b'
, ('}', _) <- S.nextChar b''
-> Nothing -- Edge case exception for @#-}@
| seenNl
-> Just (spanCppLine (advanceSrcLoc l '#') b') -- parse CPP
| otherwise
-> Nothing -- We didn't see a newline, so this can't be CPP!
(c , b') | isSpace c -> spanSpace (seenNl || c == '\n')
(advanceSrcLoc l c) b'
| otherwise -> Nothing
-- Consume a CPP line to its "end" (basically the first line that ends not
-- with a @\@ character)
spanCppLine !l !b
| S.atEnd b
= (splitStringBuffer buf b, l, b)
| otherwise
= case S.nextChar b of
('\\', b') | not (S.atEnd b')
, ('\n', b'') <- S.nextChar b'
-> spanCppLine (advanceSrcLoc (advanceSrcLoc l '\\') '\n') b''
('\n', b') -> (splitStringBuffer buf b', advanceSrcLoc l '\n', b')
(c , b') -> spanCppLine (advanceSrcLoc l c) b'
-------------------------------------------------------------------------------
-- * Free variables of a 'Type'
-------------------------------------------------------------------------------
-- | Get free type variables in a 'Type' in their order of appearance.
-- See [Ordering of implicit variables].
orderedFVs
:: VarSet -- ^ free variables to ignore
-> [Type] -- ^ types to traverse (in order) looking for free variables
-> [TyVar] -- ^ free type variables, in the order they appear in
orderedFVs vs tys =
reverse . fst $ tyCoFVsOfTypes' tys (const True) vs ([], emptyVarSet)
-- See the "Free variables of types and coercions" section in 'TyCoRep', or
-- check out Note [Free variables of types]. The functions in this section
-- don't output type variables in the order they first appear in in the 'Type'.
--
-- For example, 'tyCoVarsOfTypeList' reports an incorrect order for the type
-- of 'const :: a -> b -> a':
--
-- >>> import GHC.Types.Name
-- >>> import TyCoRep
-- >>> import GHC.Builtin.Types.Prim
-- >>> import GHC.Types.Var
-- >>> a = TyVarTy alphaTyVar
-- >>> b = TyVarTy betaTyVar
-- >>> constTy = mkFunTys [a, b] a
-- >>> map (getOccString . tyVarName) (tyCoVarsOfTypeList constTy)
-- ["b","a"]
--
-- However, we want to reuse the very optimized traversal machinery there, so
-- so we make our own `tyCoFVsOfType'`, `tyCoFVsBndr'`, and `tyCoVarsOfTypes'`.
-- All these do differently is traverse in a different order and ignore
-- coercion variables.
-- | Just like 'tyCoFVsOfType', but traverses type variables in reverse order
-- of appearance.
tyCoFVsOfType' :: Type -> FV
tyCoFVsOfType' (TyVarTy v) a b c = (FV.unitFV v `unionFV` tyCoFVsOfType' (tyVarKind v)) a b c
tyCoFVsOfType' (TyConApp _ tys) a b c = tyCoFVsOfTypes' tys a b c
tyCoFVsOfType' (LitTy {}) a b c = emptyFV a b c
tyCoFVsOfType' (AppTy fun arg) a b c = (tyCoFVsOfType' arg `unionFV` tyCoFVsOfType' fun) a b c
tyCoFVsOfType' (FunTy _ w arg res) a b c = (tyCoFVsOfType' w `unionFV`
tyCoFVsOfType' res `unionFV`
tyCoFVsOfType' arg) a b c
tyCoFVsOfType' (ForAllTy bndr ty) a b c = tyCoFVsBndr' bndr (tyCoFVsOfType' ty) a b c
tyCoFVsOfType' (CastTy ty _) a b c = (tyCoFVsOfType' ty) a b c
tyCoFVsOfType' (CoercionTy _ ) a b c = emptyFV a b c
-- | Just like 'tyCoFVsOfTypes', but traverses type variables in reverse order
-- of appearance.
tyCoFVsOfTypes' :: [Type] -> FV
tyCoFVsOfTypes' (ty:tys) fv_cand in_scope acc = (tyCoFVsOfTypes' tys `unionFV` tyCoFVsOfType' ty) fv_cand in_scope acc
tyCoFVsOfTypes' [] fv_cand in_scope acc = emptyFV fv_cand in_scope acc
-- | Just like 'tyCoFVsBndr', but traverses type variables in reverse order of
-- appearance.
tyCoFVsBndr' :: TyVarBinder -> FV -> FV
tyCoFVsBndr' (Bndr tv _) fvs = FV.delFV tv fvs `unionFV` tyCoFVsOfType' (tyVarKind tv)
-------------------------------------------------------------------------------
-- * Defaulting RuntimeRep variables
-------------------------------------------------------------------------------
-- | Traverses the type, defaulting type variables of kind 'RuntimeRep' to
-- 'LiftedType'. See 'defaultRuntimeRepVars' in GHC.Iface.Type the original such
-- function working over `IfaceType`'s.
defaultRuntimeRepVars :: Type -> Type
defaultRuntimeRepVars = go emptyVarEnv
where
go :: TyVarEnv () -> Type -> Type
go subs (ForAllTy (Bndr var flg) ty)
| isRuntimeRepVar var
, isInvisibleArgFlag flg
= let subs' = extendVarEnv subs var ()
in go subs' ty
| otherwise
= ForAllTy (Bndr (updateTyVarKind (go subs) var) flg)
(go subs ty)
go subs (TyVarTy tv)
| tv `elemVarEnv` subs
= TyConApp liftedRepDataConTyCon []
| otherwise
= TyVarTy (updateTyVarKind (go subs) tv)
go subs (TyConApp tc tc_args)
= TyConApp tc (map (go subs) tc_args)
go subs (FunTy af w arg res)
= FunTy af (go subs w) (go subs arg) (go subs res)
go subs (AppTy t u)
= AppTy (go subs t) (go subs u)
go subs (CastTy x co)
= CastTy (go subs x) co
go _ ty@(LitTy {}) = ty
go _ ty@(CoercionTy {}) = ty
|