{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998

\section[Name]{@Name@: to transmit name info from renamer to typechecker}
-}

{-# LANGUAGE RecordWildCards #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE PatternSynonyms #-}

-- |
-- #name_types#
-- GHC uses several kinds of name internally:
--
-- * 'GHC.Types.Name.Occurrence.OccName': see "GHC.Types.Name.Occurrence#name_types"
--
-- * 'GHC.Types.Name.Reader.RdrName': see "GHC.Types.Name.Reader#name_types"
--
-- * 'GHC.Types.Name.Name' is the type of names that have had their scoping and
--   binding resolved. They have an 'OccName' but also a 'GHC.Types.Unique.Unique'
--   that disambiguates Names that have the same 'OccName' and indeed is used for all
--   'Name' comparison. Names also contain information about where they originated
--   from, see "GHC.Types.Name#name_sorts"
--
-- * 'GHC.Types.Id.Id': see "GHC.Types.Id#name_types"
--
-- * 'GHC.Types.Var.Var': see "GHC.Types.Var#name_types"
--
-- #name_sorts#
-- Names are one of:
--
--  * External, if they name things declared in other modules. Some external
--    Names are wired in, i.e. they name primitives defined in the compiler itself
--
--  * Internal, if they name things in the module being compiled. Some internal
--    Names are system names, if they are names manufactured by the compiler

module GHC.Types.Name (
        -- * The main types
        Name,                                   -- Abstract
        BuiltInSyntax(..),

        -- ** Creating 'Name's
        mkSystemName, mkSystemNameAt,
        mkInternalName, mkClonedInternalName, mkDerivedInternalName,
        mkSystemVarName, mkSysTvName,
        mkFCallName,
        mkExternalName, mkWiredInName,

        -- ** Manipulating and deconstructing 'Name's
        nameUnique, setNameUnique,
        nameOccName, nameNameSpace, nameModule, nameModule_maybe,
        setNameLoc,
        tidyNameOcc,
        localiseName,

        nameSrcLoc, nameSrcSpan, pprNameDefnLoc, pprDefinedAt,

        -- ** Predicates on 'Name's
        isSystemName, isInternalName, isExternalName,
        isTyVarName, isTyConName, isDataConName,
        isValName, isVarName, isDynLinkName,
        isWiredInName, isWiredIn, isBuiltInSyntax,
        isHoleName,
        wiredInNameTyThing_maybe,
        nameIsLocalOrFrom, nameIsHomePackage,
        nameIsHomePackageImport, nameIsFromExternalPackage,
        stableNameCmp,

        -- * Class 'NamedThing' and overloaded friends
        NamedThing(..),
        getSrcLoc, getSrcSpan, getOccString, getOccFS,

        pprInfixName, pprPrefixName, pprModulePrefix, pprNameUnqualified,
        nameStableString,

        -- Re-export the OccName stuff
        module GHC.Types.Name.Occurrence
    ) where

import GHC.Prelude

import {-# SOURCE #-} GHC.Core.TyCo.Rep( TyThing )

import GHC.Platform
import GHC.Types.Name.Occurrence
import GHC.Unit.Module
import GHC.Types.SrcLoc
import GHC.Types.Unique
import GHC.Utils.Misc
import GHC.Data.Maybe
import GHC.Utils.Binary
import GHC.Data.FastString
import GHC.Utils.Outputable

import Control.DeepSeq
import Data.Data

{-
************************************************************************
*                                                                      *
\subsection[Name-datatype]{The @Name@ datatype, and name construction}
*                                                                      *
************************************************************************
-}

-- | A unique, unambiguous name for something, containing information about where
-- that thing originated.
data Name = Name {
                n_sort :: NameSort,     -- What sort of name it is
                n_occ  :: !OccName,     -- Its occurrence name
                n_uniq :: {-# UNPACK #-} !Unique,
                n_loc  :: !SrcSpan      -- Definition site
            }

-- NOTE: we make the n_loc field strict to eliminate some potential
-- (and real!) space leaks, due to the fact that we don't look at
-- the SrcLoc in a Name all that often.

-- See Note [About the NameSorts]
data NameSort
  = External Module

  | WiredIn Module TyThing BuiltInSyntax
        -- A variant of External, for wired-in things

  | Internal            -- A user-defined Id or TyVar
                        -- defined in the module being compiled

  | System              -- A system-defined Id or TyVar.  Typically the
                        -- OccName is very uninformative (like 's')

instance Outputable NameSort where
  ppr (External _)    = text "external"
  ppr (WiredIn _ _ _) = text "wired-in"
  ppr  Internal       = text "internal"
  ppr  System         = text "system"

instance NFData Name where
  rnf Name{..} = rnf n_sort

instance NFData NameSort where
  rnf (External m) = rnf m
  rnf (WiredIn m t b) = rnf m `seq` t `seq` b `seq` ()
    -- XXX this is a *lie*, we're not going to rnf the TyThing, but
    -- since the TyThings for WiredIn Names are all static they can't
    -- be hiding space leaks or errors.
  rnf Internal = ()
  rnf System = ()

-- | BuiltInSyntax is for things like @(:)@, @[]@ and tuples,
-- which have special syntactic forms.  They aren't in scope
-- as such.
data BuiltInSyntax = BuiltInSyntax | UserSyntax

{-
Note [About the NameSorts]

1.  Initially, top-level Ids (including locally-defined ones) get External names,
    and all other local Ids get Internal names

2.  In any invocation of GHC, an External Name for "M.x" has one and only one
    unique.  This unique association is ensured via the Name Cache;
    see Note [The Name Cache] in GHC.Iface.Env.

3.  Things with a External name are given C static labels, so they finally
    appear in the .o file's symbol table.  They appear in the symbol table
    in the form M.n.  If originally-local things have this property they
    must be made @External@ first.

4.  In the tidy-core phase, a External that is not visible to an importer
    is changed to Internal, and a Internal that is visible is changed to External

5.  A System Name differs in the following ways:
        a) has unique attached when printing dumps
        b) unifier eliminates sys tyvars in favour of user provs where possible

    Before anything gets printed in interface files or output code, it's
    fed through a 'tidy' processor, which zaps the OccNames to have
    unique names; and converts all sys-locals to user locals
    If any desugarer sys-locals have survived that far, they get changed to
    "ds1", "ds2", etc.

Built-in syntax => It's a syntactic form, not "in scope" (e.g. [])

Wired-in thing  => The thing (Id, TyCon) is fully known to the compiler,
                   not read from an interface file.
                   E.g. Bool, True, Int, Float, and many others

All built-in syntax is for wired-in things.
-}

instance HasOccName Name where
  occName = nameOccName

nameUnique              :: Name -> Unique
nameOccName             :: Name -> OccName
nameNameSpace           :: Name -> NameSpace
nameModule              :: HasDebugCallStack => Name -> Module
nameSrcLoc              :: Name -> SrcLoc
nameSrcSpan             :: Name -> SrcSpan

nameUnique    name = n_uniq name
nameOccName   name = n_occ  name
nameNameSpace name = occNameSpace (n_occ name)
nameSrcLoc    name = srcSpanStart (n_loc name)
nameSrcSpan   name = n_loc  name

{-
************************************************************************
*                                                                      *
\subsection{Predicates on names}
*                                                                      *
************************************************************************
-}

isInternalName    :: Name -> Bool
isExternalName    :: Name -> Bool
isSystemName      :: Name -> Bool
isWiredInName     :: Name -> Bool

isWiredInName (Name {n_sort = WiredIn _ _ _}) = True
isWiredInName _                               = False

isWiredIn :: NamedThing thing => thing -> Bool
isWiredIn = isWiredInName . getName

wiredInNameTyThing_maybe :: Name -> Maybe TyThing
wiredInNameTyThing_maybe (Name {n_sort = WiredIn _ thing _}) = Just thing
wiredInNameTyThing_maybe _                                   = Nothing

isBuiltInSyntax :: Name -> Bool
isBuiltInSyntax (Name {n_sort = WiredIn _ _ BuiltInSyntax}) = True
isBuiltInSyntax _                                           = False

isExternalName (Name {n_sort = External _})    = True
isExternalName (Name {n_sort = WiredIn _ _ _}) = True
isExternalName _                               = False

isInternalName name = not (isExternalName name)

isHoleName :: Name -> Bool
isHoleName = isHoleModule . nameModule

-- | Will the 'Name' come from a dynamically linked package?
isDynLinkName :: Platform -> Module -> Name -> Bool
isDynLinkName platform this_mod name
  | Just mod <- nameModule_maybe name
    -- Issue #8696 - when GHC is dynamically linked, it will attempt
    -- to load the dynamic dependencies of object files at compile
    -- time for things like QuasiQuotes or
    -- TemplateHaskell. Unfortunately, this interacts badly with
    -- intra-package linking, because we don't generate indirect
    -- (dynamic) symbols for intra-package calls. This means that if a
    -- module with an intra-package call is loaded without its
    -- dependencies, then GHC fails to link.
    --
    -- In the mean time, always force dynamic indirections to be
    -- generated: when the module name isn't the module being
    -- compiled, references are dynamic.
    = case platformOS platform of
        -- On Windows the hack for #8696 makes it unlinkable.
        -- As the entire setup of the code from Cmm down to the RTS expects
        -- the use of trampolines for the imported functions only when
        -- doing intra-package linking, e.g. referring to a symbol defined in the same
        -- package should not use a trampoline.
        -- I much rather have dynamic TH not supported than the entire Dynamic linking
        -- not due to a hack.
        -- Also not sure this would break on Windows anyway.
        OSMinGW32 -> moduleUnit mod /= moduleUnit this_mod

        -- For the other platforms, still perform the hack
        _         -> mod /= this_mod

  | otherwise = False  -- no, it is not even an external name


nameModule name =
  nameModule_maybe name `orElse`
  pprPanic "nameModule" (ppr (n_sort name) <+> ppr name)

nameModule_maybe :: Name -> Maybe Module
nameModule_maybe (Name { n_sort = External mod})    = Just mod
nameModule_maybe (Name { n_sort = WiredIn mod _ _}) = Just mod
nameModule_maybe _                                  = Nothing

nameIsLocalOrFrom :: Module -> Name -> Bool
-- ^ Returns True if the name is
--   (a) Internal
--   (b) External but from the specified module
--   (c) External but from the 'interactive' package
--
-- The key idea is that
--    False means: the entity is defined in some other module
--                 you can find the details (type, fixity, instances)
--                     in some interface file
--                 those details will be stored in the EPT or HPT
--
--    True means:  the entity is defined in this module or earlier in
--                     the GHCi session
--                 you can find details (type, fixity, instances) in the
--                     TcGblEnv or TcLclEnv
--
-- The isInteractiveModule part is because successive interactions of a GHCi session
-- each give rise to a fresh module (Ghci1, Ghci2, etc), but they all come
-- from the magic 'interactive' package; and all the details are kept in the
-- TcLclEnv, TcGblEnv, NOT in the HPT or EPT.
-- See Note [The interactive package] in "GHC.Driver.Types"

nameIsLocalOrFrom from name
  | Just mod <- nameModule_maybe name = from == mod || isInteractiveModule mod
  | otherwise                         = True

nameIsHomePackage :: Module -> Name -> Bool
-- True if the Name is defined in module of this package
nameIsHomePackage this_mod
  = \nm -> case n_sort nm of
              External nm_mod    -> moduleUnit nm_mod == this_pkg
              WiredIn nm_mod _ _ -> moduleUnit nm_mod == this_pkg
              Internal -> True
              System   -> False
  where
    this_pkg = moduleUnit this_mod

nameIsHomePackageImport :: Module -> Name -> Bool
-- True if the Name is defined in module of this package
-- /other than/ the this_mod
nameIsHomePackageImport this_mod
  = \nm -> case nameModule_maybe nm of
              Nothing -> False
              Just nm_mod -> nm_mod /= this_mod
                          && moduleUnit nm_mod == this_pkg
  where
    this_pkg = moduleUnit this_mod

-- | Returns True if the Name comes from some other package: neither this
-- package nor the interactive package.
nameIsFromExternalPackage :: Unit -> Name -> Bool
nameIsFromExternalPackage this_unit name
  | Just mod <- nameModule_maybe name
  , moduleUnit mod /= this_unit   -- Not the current unit
  , not (isInteractiveModule mod) -- Not the 'interactive' package
  = True
  | otherwise
  = False

isTyVarName :: Name -> Bool
isTyVarName name = isTvOcc (nameOccName name)

isTyConName :: Name -> Bool
isTyConName name = isTcOcc (nameOccName name)

isDataConName :: Name -> Bool
isDataConName name = isDataOcc (nameOccName name)

isValName :: Name -> Bool
isValName name = isValOcc (nameOccName name)

isVarName :: Name -> Bool
isVarName = isVarOcc . nameOccName

isSystemName (Name {n_sort = System}) = True
isSystemName _                        = False

{-
************************************************************************
*                                                                      *
\subsection{Making names}
*                                                                      *
************************************************************************
-}

-- | Create a name which is (for now at least) local to the current module and hence
-- does not need a 'Module' to disambiguate it from other 'Name's
mkInternalName :: Unique -> OccName -> SrcSpan -> Name
mkInternalName uniq occ loc = Name { n_uniq = uniq
                                   , n_sort = Internal
                                   , n_occ = occ
                                   , n_loc = loc }
        -- NB: You might worry that after lots of huffing and
        -- puffing we might end up with two local names with distinct
        -- uniques, but the same OccName.  Indeed we can, but that's ok
        --      * the insides of the compiler don't care: they use the Unique
        --      * when printing for -ddump-xxx you can switch on -dppr-debug to get the
        --        uniques if you get confused
        --      * for interface files we tidyCore first, which makes
        --        the OccNames distinct when they need to be

mkClonedInternalName :: Unique -> Name -> Name
mkClonedInternalName uniq (Name { n_occ = occ, n_loc = loc })
  = Name { n_uniq = uniq, n_sort = Internal
         , n_occ = occ, n_loc = loc }

mkDerivedInternalName :: (OccName -> OccName) -> Unique -> Name -> Name
mkDerivedInternalName derive_occ uniq (Name { n_occ = occ, n_loc = loc })
  = Name { n_uniq = uniq, n_sort = Internal
         , n_occ = derive_occ occ, n_loc = loc }

-- | Create a name which definitely originates in the given module
mkExternalName :: Unique -> Module -> OccName -> SrcSpan -> Name
-- WATCH OUT! External Names should be in the Name Cache
-- (see Note [The Name Cache] in GHC.Iface.Env), so don't just call mkExternalName
-- with some fresh unique without populating the Name Cache
mkExternalName uniq mod occ loc
  = Name { n_uniq = uniq, n_sort = External mod,
           n_occ = occ, n_loc = loc }

-- | Create a name which is actually defined by the compiler itself
mkWiredInName :: Module -> OccName -> Unique -> TyThing -> BuiltInSyntax -> Name
mkWiredInName mod occ uniq thing built_in
  = Name { n_uniq = uniq,
           n_sort = WiredIn mod thing built_in,
           n_occ = occ, n_loc = wiredInSrcSpan }

-- | Create a name brought into being by the compiler
mkSystemName :: Unique -> OccName -> Name
mkSystemName uniq occ = mkSystemNameAt uniq occ noSrcSpan

mkSystemNameAt :: Unique -> OccName -> SrcSpan -> Name
mkSystemNameAt uniq occ loc = Name { n_uniq = uniq, n_sort = System
                                   , n_occ = occ, n_loc = loc }

mkSystemVarName :: Unique -> FastString -> Name
mkSystemVarName uniq fs = mkSystemName uniq (mkVarOccFS fs)

mkSysTvName :: Unique -> FastString -> Name
mkSysTvName uniq fs = mkSystemName uniq (mkTyVarOccFS fs)

-- | Make a name for a foreign call
mkFCallName :: Unique -> String -> Name
mkFCallName uniq str = mkInternalName uniq (mkVarOcc str) noSrcSpan
   -- The encoded string completely describes the ccall

-- When we renumber/rename things, we need to be
-- able to change a Name's Unique to match the cached
-- one in the thing it's the name of.  If you know what I mean.
setNameUnique :: Name -> Unique -> Name
setNameUnique name uniq = name {n_uniq = uniq}

-- This is used for hsigs: we want to use the name of the originally exported
-- entity, but edit the location to refer to the reexport site
setNameLoc :: Name -> SrcSpan -> Name
setNameLoc name loc = name {n_loc = loc}

tidyNameOcc :: Name -> OccName -> Name
-- We set the OccName of a Name when tidying
-- In doing so, we change System --> Internal, so that when we print
-- it we don't get the unique by default.  It's tidy now!
tidyNameOcc name@(Name { n_sort = System }) occ = name { n_occ = occ, n_sort = Internal}
tidyNameOcc name                            occ = name { n_occ = occ }

-- | Make the 'Name' into an internal name, regardless of what it was to begin with
localiseName :: Name -> Name
localiseName n = n { n_sort = Internal }

{-
************************************************************************
*                                                                      *
\subsection{Hashing and comparison}
*                                                                      *
************************************************************************
-}

cmpName :: Name -> Name -> Ordering
cmpName n1 n2 = n_uniq n1 `nonDetCmpUnique` n_uniq n2

-- | Compare Names lexicographically
-- This only works for Names that originate in the source code or have been
-- tidied.
stableNameCmp :: Name -> Name -> Ordering
stableNameCmp (Name { n_sort = s1, n_occ = occ1 })
              (Name { n_sort = s2, n_occ = occ2 })
  = (s1 `sort_cmp` s2) `thenCmp` (occ1 `compare` occ2)
    -- The ordinary compare on OccNames is lexicographic
  where
    -- Later constructors are bigger
    sort_cmp (External m1) (External m2)       = m1 `stableModuleCmp` m2
    sort_cmp (External {}) _                   = LT
    sort_cmp (WiredIn {}) (External {})        = GT
    sort_cmp (WiredIn m1 _ _) (WiredIn m2 _ _) = m1 `stableModuleCmp` m2
    sort_cmp (WiredIn {})     _                = LT
    sort_cmp Internal         (External {})    = GT
    sort_cmp Internal         (WiredIn {})     = GT
    sort_cmp Internal         Internal         = EQ
    sort_cmp Internal         System           = LT
    sort_cmp System           System           = EQ
    sort_cmp System           _                = GT

{-
************************************************************************
*                                                                      *
\subsection[Name-instances]{Instance declarations}
*                                                                      *
************************************************************************
-}

-- | The same comments as for `Name`'s `Ord` instance apply.
instance Eq Name where
    a == b = case (a `compare` b) of { EQ -> True;  _ -> False }
    a /= b = case (a `compare` b) of { EQ -> False; _ -> True }

-- | __Caution__: This instance is implemented via `nonDetCmpUnique`, which
-- means that the ordering is not stable across deserialization or rebuilds.
--
-- See `nonDetCmpUnique` for further information, and trac #15240 for a bug
-- caused by improper use of this instance.

-- For a deterministic lexicographic ordering, use `stableNameCmp`.
instance Ord Name where
    a <= b = case (a `compare` b) of { LT -> True;  EQ -> True;  GT -> False }
    a <  b = case (a `compare` b) of { LT -> True;  EQ -> False; GT -> False }
    a >= b = case (a `compare` b) of { LT -> False; EQ -> True;  GT -> True  }
    a >  b = case (a `compare` b) of { LT -> False; EQ -> False; GT -> True  }
    compare a b = cmpName a b

instance Uniquable Name where
    getUnique = nameUnique

instance NamedThing Name where
    getName n = n

instance Data Name where
  -- don't traverse?
  toConstr _   = abstractConstr "Name"
  gunfold _ _  = error "gunfold"
  dataTypeOf _ = mkNoRepType "Name"

{-
************************************************************************
*                                                                      *
\subsection{Binary}
*                                                                      *
************************************************************************
-}

-- | Assumes that the 'Name' is a non-binding one. See
-- 'GHC.Iface.Syntax.putIfaceTopBndr' and 'GHC.Iface.Syntax.getIfaceTopBndr' for
-- serializing binding 'Name's. See 'UserData' for the rationale for this
-- distinction.
instance Binary Name where
   put_ bh name =
      case getUserData bh of
        UserData{ ud_put_nonbinding_name = put_name } -> put_name bh name

   get bh =
      case getUserData bh of
        UserData { ud_get_name = get_name } -> get_name bh

{-
************************************************************************
*                                                                      *
\subsection{Pretty printing}
*                                                                      *
************************************************************************
-}

instance Outputable Name where
    ppr name = pprName name

instance OutputableBndr Name where
    pprBndr _ name = pprName name
    pprInfixOcc  = pprInfixName
    pprPrefixOcc = pprPrefixName

pprName :: Name -> SDoc
pprName (Name {n_sort = sort, n_uniq = uniq, n_occ = occ})
  = getPprStyle $ \sty ->
    getPprDebug $ \debug ->
    case sort of
      WiredIn mod _ builtin   -> pprExternal debug sty uniq mod occ True  builtin
      External mod            -> pprExternal debug sty uniq mod occ False UserSyntax
      System                  -> pprSystem   debug sty uniq occ
      Internal                -> pprInternal debug sty uniq occ

-- | Print the string of Name unqualifiedly directly.
pprNameUnqualified :: Name -> SDoc
pprNameUnqualified Name { n_occ = occ } = ppr_occ_name occ

pprExternal :: Bool -> PprStyle -> Unique -> Module -> OccName -> Bool -> BuiltInSyntax -> SDoc
pprExternal debug sty uniq mod occ is_wired is_builtin
  | codeStyle sty = ppr mod <> char '_' <> ppr_z_occ_name occ
        -- In code style, always qualify
        -- ToDo: maybe we could print all wired-in things unqualified
        --       in code style, to reduce symbol table bloat?
  | debug         = pp_mod <> ppr_occ_name occ
                     <> braces (hsep [if is_wired then text "(w)" else empty,
                                      pprNameSpaceBrief (occNameSpace occ),
                                      pprUnique uniq])
  | BuiltInSyntax <- is_builtin = ppr_occ_name occ  -- Never qualify builtin syntax
  | otherwise                   =
        if isHoleModule mod
            then case qualName sty mod occ of
                    NameUnqual -> ppr_occ_name occ
                    _ -> braces (ppr (moduleName mod) <> dot <> ppr_occ_name occ)
            else pprModulePrefix sty mod occ <> ppr_occ_name occ
  where
    pp_mod = ppUnlessOption sdocSuppressModulePrefixes
               (ppr mod <> dot)

pprInternal :: Bool -> PprStyle -> Unique -> OccName -> SDoc
pprInternal debug sty uniq occ
  | codeStyle sty  = pprUniqueAlways uniq
  | debug          = ppr_occ_name occ <> braces (hsep [pprNameSpaceBrief (occNameSpace occ),
                                                       pprUnique uniq])
  | dumpStyle sty  = ppr_occ_name occ <> ppr_underscore_unique uniq
                        -- For debug dumps, we're not necessarily dumping
                        -- tidied code, so we need to print the uniques.
  | otherwise      = ppr_occ_name occ   -- User style

-- Like Internal, except that we only omit the unique in Iface style
pprSystem :: Bool -> PprStyle -> Unique -> OccName -> SDoc
pprSystem debug sty uniq occ
  | codeStyle sty  = pprUniqueAlways uniq
  | debug          = ppr_occ_name occ <> ppr_underscore_unique uniq
                     <> braces (pprNameSpaceBrief (occNameSpace occ))
  | otherwise      = ppr_occ_name occ <> ppr_underscore_unique uniq
                                -- If the tidy phase hasn't run, the OccName
                                -- is unlikely to be informative (like 's'),
                                -- so print the unique


pprModulePrefix :: PprStyle -> Module -> OccName -> SDoc
-- Print the "M." part of a name, based on whether it's in scope or not
-- See Note [Printing original names] in GHC.Driver.Types
pprModulePrefix sty mod occ = ppUnlessOption sdocSuppressModulePrefixes $
    case qualName sty mod occ of              -- See Outputable.QualifyName:
      NameQual modname -> ppr modname <> dot       -- Name is in scope
      NameNotInScope1  -> ppr mod <> dot           -- Not in scope
      NameNotInScope2  -> ppr (moduleUnit mod) <> colon     -- Module not in
                          <> ppr (moduleName mod) <> dot          -- scope either
      NameUnqual       -> empty                   -- In scope unqualified

pprUnique :: Unique -> SDoc
-- Print a unique unless we are suppressing them
pprUnique uniq
  = ppUnlessOption sdocSuppressUniques $
      pprUniqueAlways uniq

ppr_underscore_unique :: Unique -> SDoc
-- Print an underscore separating the name from its unique
-- But suppress it if we aren't printing the uniques anyway
ppr_underscore_unique uniq
  = ppUnlessOption sdocSuppressUniques $
      char '_' <> pprUniqueAlways uniq

ppr_occ_name :: OccName -> SDoc
ppr_occ_name occ = ftext (occNameFS occ)
        -- Don't use pprOccName; instead, just print the string of the OccName;
        -- we print the namespace in the debug stuff above

-- In code style, we Z-encode the strings.  The results of Z-encoding each FastString are
-- cached behind the scenes in the FastString implementation.
ppr_z_occ_name :: OccName -> SDoc
ppr_z_occ_name occ = ztext (zEncodeFS (occNameFS occ))

-- Prints (if mod information is available) "Defined at <loc>" or
--  "Defined in <mod>" information for a Name.
pprDefinedAt :: Name -> SDoc
pprDefinedAt name = text "Defined" <+> pprNameDefnLoc name

pprNameDefnLoc :: Name -> SDoc
-- Prints "at <loc>" or
--     or "in <mod>" depending on what info is available
pprNameDefnLoc name
  = case nameSrcLoc name of
         -- nameSrcLoc rather than nameSrcSpan
         -- It seems less cluttered to show a location
         -- rather than a span for the definition point
       RealSrcLoc s _ -> text "at" <+> ppr s
       UnhelpfulLoc s
         | isInternalName name || isSystemName name
         -> text "at" <+> ftext s
         | otherwise
         -> text "in" <+> quotes (ppr (nameModule name))


-- | Get a string representation of a 'Name' that's unique and stable
-- across recompilations. Used for deterministic generation of binds for
-- derived instances.
-- eg. "$aeson_70dylHtv1FFGeai1IoxcQr$Data.Aeson.Types.Internal$String"
nameStableString :: Name -> String
nameStableString Name{..} =
  nameSortStableString n_sort ++ "$" ++ occNameString n_occ

nameSortStableString :: NameSort -> String
nameSortStableString System = "$_sys"
nameSortStableString Internal = "$_in"
nameSortStableString (External mod) = moduleStableString mod
nameSortStableString (WiredIn mod _ _) = moduleStableString mod

{-
************************************************************************
*                                                                      *
\subsection{Overloaded functions related to Names}
*                                                                      *
************************************************************************
-}

-- | A class allowing convenient access to the 'Name' of various datatypes
class NamedThing a where
    getOccName :: a -> OccName
    getName    :: a -> Name

    getOccName n = nameOccName (getName n)      -- Default method

instance NamedThing e => NamedThing (Located e) where
    getName = getName . unLoc

getSrcLoc           :: NamedThing a => a -> SrcLoc
getSrcSpan          :: NamedThing a => a -> SrcSpan
getOccString        :: NamedThing a => a -> String
getOccFS            :: NamedThing a => a -> FastString

getSrcLoc           = nameSrcLoc           . getName
getSrcSpan          = nameSrcSpan          . getName
getOccString        = occNameString        . getOccName
getOccFS            = occNameFS            . getOccName

pprInfixName :: (Outputable a, NamedThing a) => a -> SDoc
-- See Outputable.pprPrefixVar, pprInfixVar;
-- add parens or back-quotes as appropriate
pprInfixName  n = pprInfixVar (isSymOcc (getOccName n)) (ppr n)

pprPrefixName :: NamedThing a => a -> SDoc
pprPrefixName thing = pprPrefixVar (isSymOcc (nameOccName name)) (ppr name)
 where
   name = getName thing