{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 \section{@Vars@: Variables} -} {-# LANGUAGE CPP, DeriveDataTypeable, MultiWayIf #-} -- | -- #name_types# -- GHC uses several kinds of name internally: -- -- * 'OccName.OccName': see "OccName#name_types" -- -- * 'RdrName.RdrName': see "RdrName#name_types" -- -- * 'Name.Name': see "Name#name_types" -- -- * 'Id.Id': see "Id#name_types" -- -- * 'Var.Var' is a synonym for the 'Id.Id' type but it may additionally -- potentially contain type variables, which have a 'TyCoRep.Kind' -- rather than a 'TyCoRep.Type' and only contain some extra -- details during typechecking. -- -- These 'Var.Var' names may either be global or local, see "Var#globalvslocal" -- -- #globalvslocal# -- Global 'Id's and 'Var's are those that are imported or correspond -- to a data constructor, primitive operation, or record selectors. -- Local 'Id's and 'Var's are those bound within an expression -- (e.g. by a lambda) or at the top level of the module being compiled. module Var ( -- * The main data type and synonyms Var, CoVar, Id, NcId, DictId, DFunId, EvVar, EqVar, EvId, IpId, TyVar, TypeVar, KindVar, TKVar, TyCoVar, -- ** Taking 'Var's apart varName, varUnique, varType, -- ** Modifying 'Var's setVarName, setVarUnique, setVarType, updateVarType, updateVarTypeM, -- ** Constructing, taking apart, modifying 'Id's mkGlobalVar, mkLocalVar, mkExportedLocalVar, mkCoVar, idInfo, idDetails, lazySetIdInfo, setIdDetails, globaliseId, setIdExported, setIdNotExported, -- ** Predicates isId, isTKVar, isTyVar, isTcTyVar, isLocalVar, isLocalId, isCoVar, isNonCoVarId, isTyCoVar, isGlobalId, isExportedId, mustHaveLocalBinding, -- ** Constructing 'TyVar's mkTyVar, mkTcTyVar, -- ** Taking 'TyVar's apart tyVarName, tyVarKind, tcTyVarDetails, setTcTyVarDetails, -- ** Modifying 'TyVar's setTyVarName, setTyVarUnique, setTyVarKind, updateTyVarKind, updateTyVarKindM ) where #include "HsVersions.h" import {-# SOURCE #-} TyCoRep( Type, Kind ) import {-# SOURCE #-} TcType( TcTyVarDetails, pprTcTyVarDetails, vanillaSkolemTv ) import {-# SOURCE #-} IdInfo( IdDetails, IdInfo, coVarDetails, isCoVarDetails, vanillaIdInfo, pprIdDetails ) import Name hiding (varName) import Unique import Util import DynFlags import Outputable import Data.Data {- ************************************************************************ * * Synonyms * * ************************************************************************ -- These synonyms are here and not in Id because otherwise we need a very -- large number of SOURCE imports of Id.hs :-( -} type Id = Var -- A term-level identifier -- predicate: isId type CoVar = Id -- See Note [Evidence: EvIds and CoVars] -- predicate: isCoVar type NcId = Id -- A term-level (value) variable that is -- /not/ an (unlifted) coercion -- predicate: isNonCoVarId type TyVar = Var -- Type *or* kind variable (historical) type TKVar = Var -- Type *or* kind variable (historical) type TypeVar = Var -- Definitely a type variable type KindVar = Var -- Definitely a kind variable -- See Note [Kind and type variables] -- See Note [Evidence: EvIds and CoVars] type EvId = Id -- Term-level evidence: DictId, IpId, or EqVar type EvVar = EvId -- ...historical name for EvId type DFunId = Id -- A dictionary function type DictId = EvId -- A dictionary variable type IpId = EvId -- A term-level implicit parameter type EqVar = EvId -- Boxed equality evidence type TyCoVar = Id -- Type, kind, *or* coercion variable -- predicate: isTyCoVar {- Note [Evidence: EvIds and CoVars] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * An EvId (evidence Id) is a term-level evidence variable (dictionary, implicit parameter, or equality). Could be boxed or unboxed. * DictId, IpId, and EqVar are synonyms when we know what kind of evidence we are talking about. For example, an EqVar has type (t1 ~ t2). * A CoVar is always an un-lifted coercion, of type (t1 ~# t2) or (t1 ~R# t2) Note [Kind and type variables] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Before kind polymorphism, TyVar were used to mean type variables. Now they are use to mean kind *or* type variables. KindVar is used when we know for sure that it is a kind variable. In future, we might want to go over the whole compiler code to use: - TKVar to mean kind or type variables - TypeVar to mean type variables only - KindVar to mean kind variables ************************************************************************ * * \subsection{The main data type declarations} * * ************************************************************************ Every @Var@ has a @Unique@, to uniquify it and for fast comparison, a @Type@, and an @IdInfo@ (non-essential info about it, e.g., strictness). The essential info about different kinds of @Vars@ is in its @VarDetails@. -} -- | Essentially a typed 'Name', that may also contain some additional information -- about the 'Var' and it's use sites. data Var = TyVar { -- Type and kind variables -- see Note [Kind and type variables] varName :: !Name, realUnique :: {-# UNPACK #-} !Int, -- ^ Key for fast comparison -- Identical to the Unique in the name, -- cached here for speed varType :: Kind -- ^ The type or kind of the 'Var' in question } | TcTyVar { -- Used only during type inference -- Used for kind variables during -- inference, as well varName :: !Name, realUnique :: {-# UNPACK #-} !Int, varType :: Kind, tc_tv_details :: TcTyVarDetails } | Id { varName :: !Name, realUnique :: {-# UNPACK #-} !Int, varType :: Type, idScope :: IdScope, id_details :: IdDetails, -- Stable, doesn't change id_info :: IdInfo } -- Unstable, updated by simplifier deriving Typeable data IdScope -- See Note [GlobalId/LocalId] = GlobalId | LocalId ExportFlag data ExportFlag -- See Note [ExportFlag on binders] = NotExported -- ^ Not exported: may be discarded as dead code. | Exported -- ^ Exported: kept alive {- Note [ExportFlag on binders] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ An ExportFlag of "Exported" on a top-level binder says "keep this binding alive; do not drop it as dead code". This transitively keeps alive all the other top-level bindings that this binding refers to. This property is persisted all the way down the pipeline, so that the binding will be compiled all the way to object code, and its symbols will appear in the linker symbol table. However, note that this use of "exported" is quite different to the export list on a Haskell module. Setting the ExportFlag on an Id does /not/ mean that if you import the module (in Haskell source code) you will see this Id. Of course, things that appear in the export list of the source Haskell module do indeed have their ExportFlag set. But many other things, such as dictionary functions, are kept alive by having their ExportFlag set, even though they are not exported in the source-code sense. We should probably use a different term for ExportFlag, like KeepAlive. Note [GlobalId/LocalId] ~~~~~~~~~~~~~~~~~~~~~~~ A GlobalId is * always a constant (top-level) * imported, or data constructor, or primop, or record selector * has a Unique that is globally unique across the whole GHC invocation (a single invocation may compile multiple modules) * never treated as a candidate by the free-variable finder; it's a constant! A LocalId is * bound within an expression (lambda, case, local let(rec)) * or defined at top level in the module being compiled * always treated as a candidate by the free-variable finder After CoreTidy, top-level LocalIds are turned into GlobalIds -} instance Outputable Var where ppr var = sdocWithDynFlags $ \dflags -> getPprStyle $ \ppr_style -> if | debugStyle ppr_style && (not (gopt Opt_SuppressVarKinds dflags)) -> parens (ppr (varName var) <+> ppr_debug var ppr_style <+> dcolon <+> ppr (tyVarKind var)) | otherwise -> ppr (varName var) <> ppr_debug var ppr_style ppr_debug :: Var -> PprStyle -> SDoc ppr_debug (TyVar {}) sty | debugStyle sty = brackets (text "tv") ppr_debug (TcTyVar {tc_tv_details = d}) sty | dumpStyle sty || debugStyle sty = brackets (pprTcTyVarDetails d) ppr_debug (Id { idScope = s, id_details = d }) sty | debugStyle sty = brackets (ppr_id_scope s <> pprIdDetails d) ppr_debug _ _ = empty ppr_id_scope :: IdScope -> SDoc ppr_id_scope GlobalId = text "gid" ppr_id_scope (LocalId Exported) = text "lidx" ppr_id_scope (LocalId NotExported) = text "lid" instance NamedThing Var where getName = varName instance Uniquable Var where getUnique = varUnique instance Eq Var where a == b = realUnique a == realUnique b instance Ord Var where a <= b = realUnique a <= realUnique b a < b = realUnique a < realUnique b a >= b = realUnique a >= realUnique b a > b = realUnique a > realUnique b a `compare` b = varUnique a `compare` varUnique b instance Data Var where -- don't traverse? toConstr _ = abstractConstr "Var" gunfold _ _ = error "gunfold" dataTypeOf _ = mkNoRepType "Var" varUnique :: Var -> Unique varUnique var = mkUniqueGrimily (realUnique var) setVarUnique :: Var -> Unique -> Var setVarUnique var uniq = var { realUnique = getKey uniq, varName = setNameUnique (varName var) uniq } setVarName :: Var -> Name -> Var setVarName var new_name = var { realUnique = getKey (getUnique new_name), varName = new_name } setVarType :: Id -> Type -> Id setVarType id ty = id { varType = ty } updateVarType :: (Type -> Type) -> Id -> Id updateVarType f id = id { varType = f (varType id) } updateVarTypeM :: Monad m => (Type -> m Type) -> Id -> m Id updateVarTypeM f id = do { ty' <- f (varType id) ; return (id { varType = ty' }) } {- ************************************************************************ * * \subsection{Type and kind variables} * * ************************************************************************ -} tyVarName :: TyVar -> Name tyVarName = varName tyVarKind :: TyVar -> Kind tyVarKind = varType setTyVarUnique :: TyVar -> Unique -> TyVar setTyVarUnique = setVarUnique setTyVarName :: TyVar -> Name -> TyVar setTyVarName = setVarName setTyVarKind :: TyVar -> Kind -> TyVar setTyVarKind tv k = tv {varType = k} updateTyVarKind :: (Kind -> Kind) -> TyVar -> TyVar updateTyVarKind update tv = tv {varType = update (tyVarKind tv)} updateTyVarKindM :: (Monad m) => (Kind -> m Kind) -> TyVar -> m TyVar updateTyVarKindM update tv = do { k' <- update (tyVarKind tv) ; return $ tv {varType = k'} } mkTyVar :: Name -> Kind -> TyVar mkTyVar name kind = TyVar { varName = name , realUnique = getKey (nameUnique name) , varType = kind } mkTcTyVar :: Name -> Kind -> TcTyVarDetails -> TyVar mkTcTyVar name kind details = -- NB: 'kind' may be a coercion kind; cf, 'TcMType.newMetaCoVar' TcTyVar { varName = name, realUnique = getKey (nameUnique name), varType = kind, tc_tv_details = details } tcTyVarDetails :: TyVar -> TcTyVarDetails tcTyVarDetails (TcTyVar { tc_tv_details = details }) = details tcTyVarDetails (TyVar {}) = vanillaSkolemTv tcTyVarDetails var = pprPanic "tcTyVarDetails" (ppr var <+> dcolon <+> ppr (tyVarKind var)) setTcTyVarDetails :: TyVar -> TcTyVarDetails -> TyVar setTcTyVarDetails tv details = tv { tc_tv_details = details } {- %************************************************************************ %* * \subsection{Ids} * * ************************************************************************ -} idInfo :: Id -> IdInfo idInfo (Id { id_info = info }) = info idInfo other = pprPanic "idInfo" (ppr other) idDetails :: Id -> IdDetails idDetails (Id { id_details = details }) = details idDetails other = pprPanic "idDetails" (ppr other) -- The next three have a 'Var' suffix even though they always build -- Ids, because Id.hs uses 'mkGlobalId' etc with different types mkGlobalVar :: IdDetails -> Name -> Type -> IdInfo -> Id mkGlobalVar details name ty info = mk_id name ty GlobalId details info mkLocalVar :: IdDetails -> Name -> Type -> IdInfo -> Id mkLocalVar details name ty info = mk_id name ty (LocalId NotExported) details info mkCoVar :: Name -> Type -> CoVar -- Coercion variables have no IdInfo mkCoVar name ty = mk_id name ty (LocalId NotExported) coVarDetails vanillaIdInfo -- | Exported 'Var's will not be removed as dead code mkExportedLocalVar :: IdDetails -> Name -> Type -> IdInfo -> Id mkExportedLocalVar details name ty info = mk_id name ty (LocalId Exported) details info mk_id :: Name -> Type -> IdScope -> IdDetails -> IdInfo -> Id mk_id name ty scope details info = Id { varName = name, realUnique = getKey (nameUnique name), varType = ty, idScope = scope, id_details = details, id_info = info } ------------------- lazySetIdInfo :: Id -> IdInfo -> Var lazySetIdInfo id info = id { id_info = info } setIdDetails :: Id -> IdDetails -> Id setIdDetails id details = id { id_details = details } globaliseId :: Id -> Id -- ^ If it's a local, make it global globaliseId id = id { idScope = GlobalId } setIdExported :: Id -> Id -- ^ Exports the given local 'Id'. Can also be called on global 'Id's, such as data constructors -- and class operations, which are born as global 'Id's and automatically exported setIdExported id@(Id { idScope = LocalId {} }) = id { idScope = LocalId Exported } setIdExported id@(Id { idScope = GlobalId }) = id setIdExported tv = pprPanic "setIdExported" (ppr tv) setIdNotExported :: Id -> Id -- ^ We can only do this to LocalIds setIdNotExported id = ASSERT( isLocalId id ) id { idScope = LocalId NotExported } {- ************************************************************************ * * \subsection{Predicates over variables} * * ************************************************************************ -} isTyVar :: Var -> Bool isTyVar = isTKVar -- Historical isTKVar :: Var -> Bool -- True of both type and kind variables isTKVar (TyVar {}) = True isTKVar (TcTyVar {}) = True isTKVar _ = False isTcTyVar :: Var -> Bool isTcTyVar (TcTyVar {}) = True isTcTyVar _ = False isTyCoVar :: Var -> Bool isTyCoVar v = isTyVar v || isCoVar v isId :: Var -> Bool isId (Id {}) = True isId _ = False isCoVar :: Var -> Bool -- A coercion variable isCoVar (Id { id_details = details }) = isCoVarDetails details isCoVar _ = False isNonCoVarId :: Var -> Bool -- A term variable (Id) that is /not/ a coercion variable isNonCoVarId (Id { id_details = details }) = not (isCoVarDetails details) isNonCoVarId _ = False isLocalId :: Var -> Bool isLocalId (Id { idScope = LocalId _ }) = True isLocalId _ = False -- | 'isLocalVar' returns @True@ for type variables as well as local 'Id's -- These are the variables that we need to pay attention to when finding free -- variables, or doing dependency analysis. isLocalVar :: Var -> Bool isLocalVar v = not (isGlobalId v) isGlobalId :: Var -> Bool isGlobalId (Id { idScope = GlobalId }) = True isGlobalId _ = False -- | 'mustHaveLocalBinding' returns @True@ of 'Id's and 'TyVar's -- that must have a binding in this module. The converse -- is not quite right: there are some global 'Id's that must have -- bindings, such as record selectors. But that doesn't matter, -- because it's only used for assertions mustHaveLocalBinding :: Var -> Bool mustHaveLocalBinding var = isLocalVar var -- | 'isExportedIdVar' means \"don't throw this away\" isExportedId :: Var -> Bool isExportedId (Id { idScope = GlobalId }) = True isExportedId (Id { idScope = LocalId Exported}) = True isExportedId _ = False