ghc-lib-parser-0.20200301: compiler/basicTypes/Id.hs
{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
\section[Id]{@Ids@: Value and constructor identifiers}
-}
{-# LANGUAGE CPP #-}
-- |
-- #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' represents names that not only have a 'Name.Name' but also a 'TyCoRep.Type' and some additional
-- details (a 'IdInfo.IdInfo' and one of 'Var.LocalIdDetails' or 'IdInfo.GlobalIdDetails') that
-- are added, modified and inspected by various compiler passes. These 'Var.Var' names may either
-- be global or local, see "Var#globalvslocal"
--
-- * 'Var.Var': see "Var#name_types"
module Id (
-- * The main types
Var, Id, isId,
-- * In and Out variants
InVar, InId,
OutVar, OutId,
-- ** Simple construction
mkGlobalId, mkVanillaGlobal, mkVanillaGlobalWithInfo,
mkLocalId, mkLocalCoVar, mkLocalIdOrCoVar,
mkLocalIdWithInfo, mkExportedLocalId, mkExportedVanillaId,
mkSysLocal, mkSysLocalM, mkSysLocalOrCoVar, mkSysLocalOrCoVarM,
mkUserLocal, mkUserLocalOrCoVar,
mkTemplateLocals, mkTemplateLocalsNum, mkTemplateLocal,
mkWorkerId,
-- ** Taking an Id apart
idName, idType, idUnique, idInfo, idDetails,
recordSelectorTyCon,
-- ** Modifying an Id
setIdName, setIdUnique, Id.setIdType,
setIdExported, setIdNotExported,
globaliseId, localiseId,
setIdInfo, lazySetIdInfo, modifyIdInfo, maybeModifyIdInfo,
zapLamIdInfo, zapIdDemandInfo, zapIdUsageInfo, zapIdUsageEnvInfo,
zapIdUsedOnceInfo, zapIdTailCallInfo,
zapFragileIdInfo, zapIdStrictness, zapStableUnfolding,
transferPolyIdInfo,
-- ** Predicates on Ids
isImplicitId, isDeadBinder,
isStrictId,
isExportedId, isLocalId, isGlobalId,
isRecordSelector, isNaughtyRecordSelector,
isPatSynRecordSelector,
isDataConRecordSelector,
isClassOpId_maybe, isDFunId,
isPrimOpId, isPrimOpId_maybe,
isFCallId, isFCallId_maybe,
isDataConWorkId, isDataConWorkId_maybe,
isDataConWrapId, isDataConWrapId_maybe,
isDataConId_maybe,
idDataCon,
isConLikeId, isBottomingId, idIsFrom,
hasNoBinding,
-- ** Join variables
JoinId, isJoinId, isJoinId_maybe, idJoinArity,
asJoinId, asJoinId_maybe, zapJoinId,
-- ** Inline pragma stuff
idInlinePragma, setInlinePragma, modifyInlinePragma,
idInlineActivation, setInlineActivation, idRuleMatchInfo,
-- ** One-shot lambdas
isOneShotBndr, isProbablyOneShotLambda,
setOneShotLambda, clearOneShotLambda,
updOneShotInfo, setIdOneShotInfo,
isStateHackType, stateHackOneShot, typeOneShot,
-- ** Reading 'IdInfo' fields
idArity,
idCallArity, idFunRepArity,
idUnfolding, realIdUnfolding,
idSpecialisation, idCoreRules, idHasRules,
idCafInfo,
idOneShotInfo, idStateHackOneShotInfo,
idOccInfo,
isNeverLevPolyId,
-- ** Writing 'IdInfo' fields
setIdUnfolding, setCaseBndrEvald,
setIdArity,
setIdCallArity,
setIdSpecialisation,
setIdCafInfo,
setIdOccInfo, zapIdOccInfo,
setIdDemandInfo,
setIdStrictness,
setIdCprInfo,
idDemandInfo,
idStrictness,
idCprInfo,
) where
#include "HsVersions.h"
import GhcPrelude
import GHC.Driver.Session
import GHC.Core ( CoreRule, isStableUnfolding, evaldUnfolding,
isCompulsoryUnfolding, Unfolding( NoUnfolding ) )
import IdInfo
import BasicTypes
-- Imported and re-exported
import Var( Id, CoVar, JoinId,
InId, InVar,
OutId, OutVar,
idInfo, idDetails, setIdDetails, globaliseId, varType,
isId, isLocalId, isGlobalId, isExportedId )
import qualified Var
import Type
import GHC.Types.RepType
import TysPrim
import DataCon
import Demand
import Cpr
import Name
import Module
import Class
import {-# SOURCE #-} PrimOp (PrimOp)
import ForeignCall
import Maybes
import SrcLoc
import Outputable
import Unique
import UniqSupply
import FastString
import Util
-- infixl so you can say (id `set` a `set` b)
infixl 1 `setIdUnfolding`,
`setIdArity`,
`setIdCallArity`,
`setIdOccInfo`,
`setIdOneShotInfo`,
`setIdSpecialisation`,
`setInlinePragma`,
`setInlineActivation`,
`idCafInfo`,
`setIdDemandInfo`,
`setIdStrictness`,
`setIdCprInfo`,
`asJoinId`,
`asJoinId_maybe`
{-
************************************************************************
* *
\subsection{Basic Id manipulation}
* *
************************************************************************
-}
idName :: Id -> Name
idName = Var.varName
idUnique :: Id -> Unique
idUnique = Var.varUnique
idType :: Id -> Kind
idType = Var.varType
setIdName :: Id -> Name -> Id
setIdName = Var.setVarName
setIdUnique :: Id -> Unique -> Id
setIdUnique = Var.setVarUnique
-- | Not only does this set the 'Id' 'Type', it also evaluates the type to try and
-- reduce space usage
setIdType :: Id -> Type -> Id
setIdType id ty = seqType ty `seq` Var.setVarType id ty
setIdExported :: Id -> Id
setIdExported = Var.setIdExported
setIdNotExported :: Id -> Id
setIdNotExported = Var.setIdNotExported
localiseId :: Id -> Id
-- Make an Id with the same unique and type as the
-- incoming Id, but with an *Internal* Name and *LocalId* flavour
localiseId id
| ASSERT( isId id ) isLocalId id && isInternalName name
= id
| otherwise
= Var.mkLocalVar (idDetails id) (localiseName name) (idType id) (idInfo id)
where
name = idName id
lazySetIdInfo :: Id -> IdInfo -> Id
lazySetIdInfo = Var.lazySetIdInfo
setIdInfo :: Id -> IdInfo -> Id
setIdInfo id info = info `seq` (lazySetIdInfo id info)
-- Try to avoid space leaks by seq'ing
modifyIdInfo :: HasDebugCallStack => (IdInfo -> IdInfo) -> Id -> Id
modifyIdInfo fn id = setIdInfo id (fn (idInfo id))
-- maybeModifyIdInfo tries to avoid unnecessary thrashing
maybeModifyIdInfo :: Maybe IdInfo -> Id -> Id
maybeModifyIdInfo (Just new_info) id = lazySetIdInfo id new_info
maybeModifyIdInfo Nothing id = id
{-
************************************************************************
* *
\subsection{Simple Id construction}
* *
************************************************************************
Absolutely all Ids are made by mkId. It is just like Var.mkId,
but in addition it pins free-tyvar-info onto the Id's type,
where it can easily be found.
Note [Free type variables]
~~~~~~~~~~~~~~~~~~~~~~~~~~
At one time we cached the free type variables of the type of an Id
at the root of the type in a TyNote. The idea was to avoid repeating
the free-type-variable calculation. But it turned out to slow down
the compiler overall. I don't quite know why; perhaps finding free
type variables of an Id isn't all that common whereas applying a
substitution (which changes the free type variables) is more common.
Anyway, we removed it in March 2008.
-}
-- | For an explanation of global vs. local 'Id's, see "Var#globalvslocal"
mkGlobalId :: IdDetails -> Name -> Type -> IdInfo -> Id
mkGlobalId = Var.mkGlobalVar
-- | Make a global 'Id' without any extra information at all
mkVanillaGlobal :: Name -> Type -> Id
mkVanillaGlobal name ty = mkVanillaGlobalWithInfo name ty vanillaIdInfo
-- | Make a global 'Id' with no global information but some generic 'IdInfo'
mkVanillaGlobalWithInfo :: Name -> Type -> IdInfo -> Id
mkVanillaGlobalWithInfo = mkGlobalId VanillaId
-- | For an explanation of global vs. local 'Id's, see "Var#globalvslocal"
mkLocalId :: HasDebugCallStack => Name -> Type -> Id
mkLocalId name ty = ASSERT( not (isCoVarType ty) )
mkLocalIdWithInfo name ty vanillaIdInfo
-- | Make a local CoVar
mkLocalCoVar :: Name -> Type -> CoVar
mkLocalCoVar name ty
= ASSERT( isCoVarType ty )
Var.mkLocalVar CoVarId name ty vanillaIdInfo
-- | Like 'mkLocalId', but checks the type to see if it should make a covar
mkLocalIdOrCoVar :: Name -> Type -> Id
mkLocalIdOrCoVar name ty
| isCoVarType ty = mkLocalCoVar name ty
| otherwise = mkLocalId name ty
-- proper ids only; no covars!
mkLocalIdWithInfo :: HasDebugCallStack => Name -> Type -> IdInfo -> Id
mkLocalIdWithInfo name ty info = ASSERT( not (isCoVarType ty) )
Var.mkLocalVar VanillaId name ty info
-- Note [Free type variables]
-- | Create a local 'Id' that is marked as exported.
-- This prevents things attached to it from being removed as dead code.
-- See Note [Exported LocalIds]
mkExportedLocalId :: IdDetails -> Name -> Type -> Id
mkExportedLocalId details name ty = Var.mkExportedLocalVar details name ty vanillaIdInfo
-- Note [Free type variables]
mkExportedVanillaId :: Name -> Type -> Id
mkExportedVanillaId name ty = Var.mkExportedLocalVar VanillaId name ty vanillaIdInfo
-- Note [Free type variables]
-- | Create a system local 'Id'. These are local 'Id's (see "Var#globalvslocal")
-- that are created by the compiler out of thin air
mkSysLocal :: FastString -> Unique -> Type -> Id
mkSysLocal fs uniq ty = ASSERT( not (isCoVarType ty) )
mkLocalId (mkSystemVarName uniq fs) ty
-- | Like 'mkSysLocal', but checks to see if we have a covar type
mkSysLocalOrCoVar :: FastString -> Unique -> Type -> Id
mkSysLocalOrCoVar fs uniq ty
= mkLocalIdOrCoVar (mkSystemVarName uniq fs) ty
mkSysLocalM :: MonadUnique m => FastString -> Type -> m Id
mkSysLocalM fs ty = getUniqueM >>= (\uniq -> return (mkSysLocal fs uniq ty))
mkSysLocalOrCoVarM :: MonadUnique m => FastString -> Type -> m Id
mkSysLocalOrCoVarM fs ty
= getUniqueM >>= (\uniq -> return (mkSysLocalOrCoVar fs uniq ty))
-- | Create a user local 'Id'. These are local 'Id's (see "Var#globalvslocal") with a name and location that the user might recognize
mkUserLocal :: OccName -> Unique -> Type -> SrcSpan -> Id
mkUserLocal occ uniq ty loc = ASSERT( not (isCoVarType ty) )
mkLocalId (mkInternalName uniq occ loc) ty
-- | Like 'mkUserLocal', but checks if we have a coercion type
mkUserLocalOrCoVar :: OccName -> Unique -> Type -> SrcSpan -> Id
mkUserLocalOrCoVar occ uniq ty loc
= mkLocalIdOrCoVar (mkInternalName uniq occ loc) ty
{-
Make some local @Ids@ for a template @CoreExpr@. These have bogus
@Uniques@, but that's OK because the templates are supposed to be
instantiated before use.
-}
-- | Workers get local names. "CoreTidy" will externalise these if necessary
mkWorkerId :: Unique -> Id -> Type -> Id
mkWorkerId uniq unwrkr ty
= mkLocalId (mkDerivedInternalName mkWorkerOcc uniq (getName unwrkr)) ty
-- | Create a /template local/: a family of system local 'Id's in bijection with @Int@s, typically used in unfoldings
mkTemplateLocal :: Int -> Type -> Id
mkTemplateLocal i ty = mkSysLocalOrCoVar (fsLit "v") (mkBuiltinUnique i) ty
-- "OrCoVar" since this is used in a superclass selector,
-- and "~" and "~~" have coercion "superclasses".
-- | Create a template local for a series of types
mkTemplateLocals :: [Type] -> [Id]
mkTemplateLocals = mkTemplateLocalsNum 1
-- | Create a template local for a series of type, but start from a specified template local
mkTemplateLocalsNum :: Int -> [Type] -> [Id]
mkTemplateLocalsNum n tys = zipWith mkTemplateLocal [n..] tys
{- Note [Exported LocalIds]
~~~~~~~~~~~~~~~~~~~~~~~~~~~
We use mkExportedLocalId for things like
- Dictionary functions (DFunId)
- Wrapper and matcher Ids for pattern synonyms
- Default methods for classes
- Pattern-synonym matcher and builder Ids
- etc
They marked as "exported" in the sense that they should be kept alive
even if apparently unused in other bindings, and not dropped as dead
code by the occurrence analyser. (But "exported" here does not mean
"brought into lexical scope by an import declaration". Indeed these
things are always internal Ids that the user never sees.)
It's very important that they are *LocalIds*, not GlobalIds, for lots
of reasons:
* We want to treat them as free variables for the purpose of
dependency analysis (e.g. GHC.Core.FVs.exprFreeVars).
* Look them up in the current substitution when we come across
occurrences of them (in Subst.lookupIdSubst). Lacking this we
can get an out-of-date unfolding, which can in turn make the
simplifier go into an infinite loop (#9857)
* Ensure that for dfuns that the specialiser does not float dict uses
above their defns, which would prevent good simplifications happening.
* The strictness analyser treats a occurrence of a GlobalId as
imported and assumes it contains strictness in its IdInfo, which
isn't true if the thing is bound in the same module as the
occurrence.
In CoreTidy we must make all these LocalIds into GlobalIds, so that in
importing modules (in --make mode) we treat them as properly global.
That is what is happening in, say tidy_insts in GHC.Iface.Tidy.
************************************************************************
* *
\subsection{Special Ids}
* *
************************************************************************
-}
-- | If the 'Id' is that for a record selector, extract the 'sel_tycon'. Panic otherwise.
recordSelectorTyCon :: Id -> RecSelParent
recordSelectorTyCon id
= case Var.idDetails id of
RecSelId { sel_tycon = parent } -> parent
_ -> panic "recordSelectorTyCon"
isRecordSelector :: Id -> Bool
isNaughtyRecordSelector :: Id -> Bool
isPatSynRecordSelector :: Id -> Bool
isDataConRecordSelector :: Id -> Bool
isPrimOpId :: Id -> Bool
isFCallId :: Id -> Bool
isDataConWorkId :: Id -> Bool
isDataConWrapId :: Id -> Bool
isDFunId :: Id -> Bool
isClassOpId_maybe :: Id -> Maybe Class
isPrimOpId_maybe :: Id -> Maybe PrimOp
isFCallId_maybe :: Id -> Maybe ForeignCall
isDataConWorkId_maybe :: Id -> Maybe DataCon
isDataConWrapId_maybe :: Id -> Maybe DataCon
isRecordSelector id = case Var.idDetails id of
RecSelId {} -> True
_ -> False
isDataConRecordSelector id = case Var.idDetails id of
RecSelId {sel_tycon = RecSelData _} -> True
_ -> False
isPatSynRecordSelector id = case Var.idDetails id of
RecSelId {sel_tycon = RecSelPatSyn _} -> True
_ -> False
isNaughtyRecordSelector id = case Var.idDetails id of
RecSelId { sel_naughty = n } -> n
_ -> False
isClassOpId_maybe id = case Var.idDetails id of
ClassOpId cls -> Just cls
_other -> Nothing
isPrimOpId id = case Var.idDetails id of
PrimOpId _ -> True
_ -> False
isDFunId id = case Var.idDetails id of
DFunId {} -> True
_ -> False
isPrimOpId_maybe id = case Var.idDetails id of
PrimOpId op -> Just op
_ -> Nothing
isFCallId id = case Var.idDetails id of
FCallId _ -> True
_ -> False
isFCallId_maybe id = case Var.idDetails id of
FCallId call -> Just call
_ -> Nothing
isDataConWorkId id = case Var.idDetails id of
DataConWorkId _ -> True
_ -> False
isDataConWorkId_maybe id = case Var.idDetails id of
DataConWorkId con -> Just con
_ -> Nothing
isDataConWrapId id = case Var.idDetails id of
DataConWrapId _ -> True
_ -> False
isDataConWrapId_maybe id = case Var.idDetails id of
DataConWrapId con -> Just con
_ -> Nothing
isDataConId_maybe :: Id -> Maybe DataCon
isDataConId_maybe id = case Var.idDetails id of
DataConWorkId con -> Just con
DataConWrapId con -> Just con
_ -> Nothing
isJoinId :: Var -> Bool
-- It is convenient in SetLevels.lvlMFE to apply isJoinId
-- to the free vars of an expression, so it's convenient
-- if it returns False for type variables
isJoinId id
| isId id = case Var.idDetails id of
JoinId {} -> True
_ -> False
| otherwise = False
isJoinId_maybe :: Var -> Maybe JoinArity
isJoinId_maybe id
| isId id = ASSERT2( isId id, ppr id )
case Var.idDetails id of
JoinId arity -> Just arity
_ -> Nothing
| otherwise = Nothing
idDataCon :: Id -> DataCon
-- ^ Get from either the worker or the wrapper 'Id' to the 'DataCon'. Currently used only in the desugarer.
--
-- INVARIANT: @idDataCon (dataConWrapId d) = d@: remember, 'dataConWrapId' can return either the wrapper or the worker
idDataCon id = isDataConId_maybe id `orElse` pprPanic "idDataCon" (ppr id)
hasNoBinding :: Id -> Bool
-- ^ Returns @True@ of an 'Id' which may not have a
-- binding, even though it is defined in this module.
-- Data constructor workers used to be things of this kind, but
-- they aren't any more. Instead, we inject a binding for
-- them at the CorePrep stage.
--
-- 'PrimOpId's also used to be of this kind. See Note [Primop wrappers] in PrimOp.hs.
-- for the history of this.
--
-- Note that CorePrep currently eta expands things no-binding things and this
-- can cause quite subtle bugs. See Note [Eta expansion of hasNoBinding things
-- in CorePrep] in CorePrep for details.
--
-- EXCEPT: unboxed tuples, which definitely have no binding
hasNoBinding id = case Var.idDetails id of
PrimOpId _ -> False -- See Note [Primop wrappers] in PrimOp.hs
FCallId _ -> True
DataConWorkId dc -> isUnboxedTupleCon dc || isUnboxedSumCon dc
_ -> isCompulsoryUnfolding (idUnfolding id)
-- See Note [Levity-polymorphic Ids]
isImplicitId :: Id -> Bool
-- ^ 'isImplicitId' tells whether an 'Id's info is implied by other
-- declarations, so we don't need to put its signature in an interface
-- file, even if it's mentioned in some other interface unfolding.
isImplicitId id
= case Var.idDetails id of
FCallId {} -> True
ClassOpId {} -> True
PrimOpId {} -> True
DataConWorkId {} -> True
DataConWrapId {} -> True
-- These are implied by their type or class decl;
-- remember that all type and class decls appear in the interface file.
-- The dfun id is not an implicit Id; it must *not* be omitted, because
-- it carries version info for the instance decl
_ -> False
idIsFrom :: Module -> Id -> Bool
idIsFrom mod id = nameIsLocalOrFrom mod (idName id)
{- Note [Levity-polymorphic Ids]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Some levity-polymorphic Ids must be applied and inlined, not left
un-saturated. Example:
unsafeCoerceId :: forall r1 r2 (a::TYPE r1) (b::TYPE r2). a -> b
This has a compulsory unfolding because we can't lambda-bind those
arguments. But the compulsory unfolding may leave levity-polymorphic
lambdas if it is not applied to enough arguments; e.g. (#14561)
bad :: forall (a :: TYPE r). a -> a
bad = unsafeCoerce#
The desugar has special magic to detect such cases: GHC.HsToCore.Expr.badUseOfLevPolyPrimop.
And we want that magic to apply to levity-polymorphic compulsory-inline things.
The easiest way to do this is for hasNoBinding to return True of all things
that have compulsory unfolding. Some Ids with a compulsory unfolding also
have a binding, but it does not harm to say they don't here, and its a very
simple way to fix #14561.
-}
isDeadBinder :: Id -> Bool
isDeadBinder bndr | isId bndr = isDeadOcc (idOccInfo bndr)
| otherwise = False -- TyVars count as not dead
{-
************************************************************************
* *
Join variables
* *
************************************************************************
-}
idJoinArity :: JoinId -> JoinArity
idJoinArity id = isJoinId_maybe id `orElse` pprPanic "idJoinArity" (ppr id)
asJoinId :: Id -> JoinArity -> JoinId
asJoinId id arity = WARN(not (isLocalId id),
text "global id being marked as join var:" <+> ppr id)
WARN(not (is_vanilla_or_join id),
ppr id <+> pprIdDetails (idDetails id))
id `setIdDetails` JoinId arity
where
is_vanilla_or_join id = case Var.idDetails id of
VanillaId -> True
JoinId {} -> True
_ -> False
zapJoinId :: Id -> Id
-- May be a regular id already
zapJoinId jid | isJoinId jid = zapIdTailCallInfo (jid `setIdDetails` VanillaId)
-- Core Lint may complain if still marked
-- as AlwaysTailCalled
| otherwise = jid
asJoinId_maybe :: Id -> Maybe JoinArity -> Id
asJoinId_maybe id (Just arity) = asJoinId id arity
asJoinId_maybe id Nothing = zapJoinId id
{-
************************************************************************
* *
\subsection{IdInfo stuff}
* *
************************************************************************
-}
---------------------------------
-- ARITY
idArity :: Id -> Arity
idArity id = arityInfo (idInfo id)
setIdArity :: Id -> Arity -> Id
setIdArity id arity = modifyIdInfo (`setArityInfo` arity) id
idCallArity :: Id -> Arity
idCallArity id = callArityInfo (idInfo id)
setIdCallArity :: Id -> Arity -> Id
setIdCallArity id arity = modifyIdInfo (`setCallArityInfo` arity) id
idFunRepArity :: Id -> RepArity
idFunRepArity x = countFunRepArgs (idArity x) (idType x)
-- | Returns true if an application to n args would diverge
isBottomingId :: Var -> Bool
isBottomingId v
| isId v = isBottomingSig (idStrictness v)
| otherwise = False
-- | Accesses the 'Id''s 'strictnessInfo'.
idStrictness :: Id -> StrictSig
idStrictness id = strictnessInfo (idInfo id)
setIdStrictness :: Id -> StrictSig -> Id
setIdStrictness id sig = modifyIdInfo (`setStrictnessInfo` sig) id
idCprInfo :: Id -> CprSig
idCprInfo id = cprInfo (idInfo id)
setIdCprInfo :: Id -> CprSig -> Id
setIdCprInfo id sig = modifyIdInfo (\info -> setCprInfo info sig) id
zapIdStrictness :: Id -> Id
zapIdStrictness id = modifyIdInfo (`setStrictnessInfo` nopSig) id
-- | This predicate says whether the 'Id' has a strict demand placed on it or
-- has a type such that it can always be evaluated strictly (i.e an
-- unlifted type, as of GHC 7.6). We need to
-- check separately whether the 'Id' has a so-called \"strict type\" because if
-- the demand for the given @id@ hasn't been computed yet but @id@ has a strict
-- type, we still want @isStrictId id@ to be @True@.
isStrictId :: Id -> Bool
isStrictId id
= ASSERT2( isId id, text "isStrictId: not an id: " <+> ppr id )
not (isJoinId id) && (
(isStrictType (idType id)) ||
-- Take the best of both strictnesses - old and new
(isStrictDmd (idDemandInfo id))
)
---------------------------------
-- UNFOLDING
idUnfolding :: Id -> Unfolding
-- Do not expose the unfolding of a loop breaker!
idUnfolding id
| isStrongLoopBreaker (occInfo info) = NoUnfolding
| otherwise = unfoldingInfo info
where
info = idInfo id
realIdUnfolding :: Id -> Unfolding
-- Expose the unfolding if there is one, including for loop breakers
realIdUnfolding id = unfoldingInfo (idInfo id)
setIdUnfolding :: Id -> Unfolding -> Id
setIdUnfolding id unfolding = modifyIdInfo (`setUnfoldingInfo` unfolding) id
idDemandInfo :: Id -> Demand
idDemandInfo id = demandInfo (idInfo id)
setIdDemandInfo :: Id -> Demand -> Id
setIdDemandInfo id dmd = modifyIdInfo (`setDemandInfo` dmd) id
setCaseBndrEvald :: StrictnessMark -> Id -> Id
-- Used for variables bound by a case expressions, both the case-binder
-- itself, and any pattern-bound variables that are argument of a
-- strict constructor. It just marks the variable as already-evaluated,
-- so that (for example) a subsequent 'seq' can be dropped
setCaseBndrEvald str id
| isMarkedStrict str = id `setIdUnfolding` evaldUnfolding
| otherwise = id
---------------------------------
-- SPECIALISATION
-- See Note [Specialisations and RULES in IdInfo] in IdInfo.hs
idSpecialisation :: Id -> RuleInfo
idSpecialisation id = ruleInfo (idInfo id)
idCoreRules :: Id -> [CoreRule]
idCoreRules id = ruleInfoRules (idSpecialisation id)
idHasRules :: Id -> Bool
idHasRules id = not (isEmptyRuleInfo (idSpecialisation id))
setIdSpecialisation :: Id -> RuleInfo -> Id
setIdSpecialisation id spec_info = modifyIdInfo (`setRuleInfo` spec_info) id
---------------------------------
-- CAF INFO
idCafInfo :: Id -> CafInfo
idCafInfo id = cafInfo (idInfo id)
setIdCafInfo :: Id -> CafInfo -> Id
setIdCafInfo id caf_info = modifyIdInfo (`setCafInfo` caf_info) id
---------------------------------
-- Occurrence INFO
idOccInfo :: Id -> OccInfo
idOccInfo id = occInfo (idInfo id)
setIdOccInfo :: Id -> OccInfo -> Id
setIdOccInfo id occ_info = modifyIdInfo (`setOccInfo` occ_info) id
zapIdOccInfo :: Id -> Id
zapIdOccInfo b = b `setIdOccInfo` noOccInfo
{-
---------------------------------
-- INLINING
The inline pragma tells us to be very keen to inline this Id, but it's still
OK not to if optimisation is switched off.
-}
idInlinePragma :: Id -> InlinePragma
idInlinePragma id = inlinePragInfo (idInfo id)
setInlinePragma :: Id -> InlinePragma -> Id
setInlinePragma id prag = modifyIdInfo (`setInlinePragInfo` prag) id
modifyInlinePragma :: Id -> (InlinePragma -> InlinePragma) -> Id
modifyInlinePragma id fn = modifyIdInfo (\info -> info `setInlinePragInfo` (fn (inlinePragInfo info))) id
idInlineActivation :: Id -> Activation
idInlineActivation id = inlinePragmaActivation (idInlinePragma id)
setInlineActivation :: Id -> Activation -> Id
setInlineActivation id act = modifyInlinePragma id (\prag -> setInlinePragmaActivation prag act)
idRuleMatchInfo :: Id -> RuleMatchInfo
idRuleMatchInfo id = inlinePragmaRuleMatchInfo (idInlinePragma id)
isConLikeId :: Id -> Bool
isConLikeId id = isDataConWorkId id || isConLike (idRuleMatchInfo id)
{-
---------------------------------
-- ONE-SHOT LAMBDAS
-}
idOneShotInfo :: Id -> OneShotInfo
idOneShotInfo id = oneShotInfo (idInfo id)
-- | Like 'idOneShotInfo', but taking the Horrible State Hack in to account
-- See Note [The state-transformer hack] in GHC.Core.Arity
idStateHackOneShotInfo :: Id -> OneShotInfo
idStateHackOneShotInfo id
| isStateHackType (idType id) = stateHackOneShot
| otherwise = idOneShotInfo id
-- | Returns whether the lambda associated with the 'Id' is certainly applied at most once
-- This one is the "business end", called externally.
-- It works on type variables as well as Ids, returning True
-- Its main purpose is to encapsulate the Horrible State Hack
-- See Note [The state-transformer hack] in GHC.Core.Arity
isOneShotBndr :: Var -> Bool
isOneShotBndr var
| isTyVar var = True
| OneShotLam <- idStateHackOneShotInfo var = True
| otherwise = False
-- | Should we apply the state hack to values of this 'Type'?
stateHackOneShot :: OneShotInfo
stateHackOneShot = OneShotLam
typeOneShot :: Type -> OneShotInfo
typeOneShot ty
| isStateHackType ty = stateHackOneShot
| otherwise = NoOneShotInfo
isStateHackType :: Type -> Bool
isStateHackType ty
| hasNoStateHack unsafeGlobalDynFlags
= False
| otherwise
= case tyConAppTyCon_maybe ty of
Just tycon -> tycon == statePrimTyCon
_ -> False
-- This is a gross hack. It claims that
-- every function over realWorldStatePrimTy is a one-shot
-- function. This is pretty true in practice, and makes a big
-- difference. For example, consider
-- a `thenST` \ r -> ...E...
-- The early full laziness pass, if it doesn't know that r is one-shot
-- will pull out E (let's say it doesn't mention r) to give
-- let lvl = E in a `thenST` \ r -> ...lvl...
-- When `thenST` gets inlined, we end up with
-- let lvl = E in \s -> case a s of (r, s') -> ...lvl...
-- and we don't re-inline E.
--
-- It would be better to spot that r was one-shot to start with, but
-- I don't want to rely on that.
--
-- Another good example is in fill_in in PrelPack.hs. We should be able to
-- spot that fill_in has arity 2 (and when Keith is done, we will) but we can't yet.
isProbablyOneShotLambda :: Id -> Bool
isProbablyOneShotLambda id = case idStateHackOneShotInfo id of
OneShotLam -> True
NoOneShotInfo -> False
setOneShotLambda :: Id -> Id
setOneShotLambda id = modifyIdInfo (`setOneShotInfo` OneShotLam) id
clearOneShotLambda :: Id -> Id
clearOneShotLambda id = modifyIdInfo (`setOneShotInfo` NoOneShotInfo) id
setIdOneShotInfo :: Id -> OneShotInfo -> Id
setIdOneShotInfo id one_shot = modifyIdInfo (`setOneShotInfo` one_shot) id
updOneShotInfo :: Id -> OneShotInfo -> Id
-- Combine the info in the Id with new info
updOneShotInfo id one_shot
| do_upd = setIdOneShotInfo id one_shot
| otherwise = id
where
do_upd = case (idOneShotInfo id, one_shot) of
(NoOneShotInfo, _) -> True
(OneShotLam, _) -> False
-- The OneShotLambda functions simply fiddle with the IdInfo flag
-- But watch out: this may change the type of something else
-- f = \x -> e
-- If we change the one-shot-ness of x, f's type changes
zapInfo :: (IdInfo -> Maybe IdInfo) -> Id -> Id
zapInfo zapper id = maybeModifyIdInfo (zapper (idInfo id)) id
zapLamIdInfo :: Id -> Id
zapLamIdInfo = zapInfo zapLamInfo
zapFragileIdInfo :: Id -> Id
zapFragileIdInfo = zapInfo zapFragileInfo
zapIdDemandInfo :: Id -> Id
zapIdDemandInfo = zapInfo zapDemandInfo
zapIdUsageInfo :: Id -> Id
zapIdUsageInfo = zapInfo zapUsageInfo
zapIdUsageEnvInfo :: Id -> Id
zapIdUsageEnvInfo = zapInfo zapUsageEnvInfo
zapIdUsedOnceInfo :: Id -> Id
zapIdUsedOnceInfo = zapInfo zapUsedOnceInfo
zapIdTailCallInfo :: Id -> Id
zapIdTailCallInfo = zapInfo zapTailCallInfo
zapStableUnfolding :: Id -> Id
zapStableUnfolding id
| isStableUnfolding (realIdUnfolding id) = setIdUnfolding id NoUnfolding
| otherwise = id
{-
Note [transferPolyIdInfo]
~~~~~~~~~~~~~~~~~~~~~~~~~
This transfer is used in three places:
FloatOut (long-distance let-floating)
SimplUtils.abstractFloats (short-distance let-floating)
StgLiftLams (selectively lambda-lift local functions to top-level)
Consider the short-distance let-floating:
f = /\a. let g = rhs in ...
Then if we float thus
g' = /\a. rhs
f = /\a. ...[g' a/g]....
we *do not* want to lose g's
* strictness information
* arity
* inline pragma (though that is bit more debatable)
* occurrence info
Mostly this is just an optimisation, but it's *vital* to
transfer the occurrence info. Consider
NonRec { f = /\a. let Rec { g* = ..g.. } in ... }
where the '*' means 'LoopBreaker'. Then if we float we must get
Rec { g'* = /\a. ...(g' a)... }
NonRec { f = /\a. ...[g' a/g]....}
where g' is also marked as LoopBreaker. If not, terrible things
can happen if we re-simplify the binding (and the Simplifier does
sometimes simplify a term twice); see #4345.
It's not so simple to retain
* worker info
* rules
so we simply discard those. Sooner or later this may bite us.
If we abstract wrt one or more *value* binders, we must modify the
arity and strictness info before transferring it. E.g.
f = \x. e
-->
g' = \y. \x. e
+ substitute (g' y) for g
Notice that g' has an arity one more than the original g
-}
transferPolyIdInfo :: Id -- Original Id
-> [Var] -- Abstract wrt these variables
-> Id -- New Id
-> Id
transferPolyIdInfo old_id abstract_wrt new_id
= modifyIdInfo transfer new_id
where
arity_increase = count isId abstract_wrt -- Arity increases by the
-- number of value binders
old_info = idInfo old_id
old_arity = arityInfo old_info
old_inline_prag = inlinePragInfo old_info
old_occ_info = occInfo old_info
new_arity = old_arity + arity_increase
new_occ_info = zapOccTailCallInfo old_occ_info
old_strictness = strictnessInfo old_info
new_strictness = increaseStrictSigArity arity_increase old_strictness
old_cpr = cprInfo old_info
transfer new_info = new_info `setArityInfo` new_arity
`setInlinePragInfo` old_inline_prag
`setOccInfo` new_occ_info
`setStrictnessInfo` new_strictness
`setCprInfo` old_cpr
isNeverLevPolyId :: Id -> Bool
isNeverLevPolyId = isNeverLevPolyIdInfo . idInfo