\begin{code}
module MkId (
- mkSpecPragmaId, mkWorkerId,
-
mkDictFunId, mkDefaultMethodId,
mkDictSelId,
#include "HsVersions.h"
+import BasicTypes ( Arity )
import TysPrim ( openAlphaTyVars, alphaTyVar, alphaTy,
intPrimTy, realWorldStatePrimTy
)
-import TysWiredIn ( boolTy, charTy, mkListTy )
-import PrelMods ( pREL_ERR, pREL_GHC )
+import TysWiredIn ( charTy, mkListTy )
+import PrelNames ( pREL_ERR, pREL_GHC )
import PrelRules ( primOpRule )
import Rules ( addRule )
-import Type ( Type, ClassContext, mkDictTy, mkTyConApp, mkTyVarTys,
- mkFunTys, mkFunTy, mkSigmaTy, classesToPreds,
- isUnLiftedType, mkForAllTys, mkTyVarTy, tyVarsOfType, tyVarsOfTypes,
- splitSigmaTy, splitFunTy_maybe, splitAlgTyConApp,
- splitFunTys, splitForAllTys, unUsgTy,
- mkUsgTy, UsageAnn(..)
+import Type ( Type, ThetaType, mkDictTy, mkPredTys, mkTyConApp, mkTyVarTys,
+ mkFunTys, mkFunTy, mkSigmaTy, splitSigmaTy,
+ isUnLiftedType, mkForAllTys, mkTyVarTy, tyVarsOfType,
+ splitFunTys, splitForAllTys, mkPredTy
)
-import PprType ( pprParendType )
import Module ( Module )
-import CoreUtils ( mkInlineMe )
+import CoreUtils ( exprType, mkInlineMe )
import CoreUnfold ( mkTopUnfolding, mkCompulsoryUnfolding, mkOtherCon )
-import Subst ( mkTopTyVarSubst, substClasses )
-import TyCon ( TyCon, isNewTyCon, tyConTyVars, tyConDataCons, isDataTyCon, isProductTyCon, isUnboxedTupleTyCon )
-import Class ( Class, classBigSig, classTyCon, classTyVars, classSelIds )
+import Literal ( Literal(..) )
+import TyCon ( TyCon, isNewTyCon, tyConTyVars, tyConDataCons,
+ tyConTheta, isProductTyCon, isDataTyCon )
+import Class ( Class, classTyCon, classTyVars, classSelIds )
import Var ( Id, TyVar )
import VarSet ( isEmptyVarSet )
-import Name ( mkDerivedName, mkWiredInIdName, mkLocalName,
- mkWorkerOcc, mkSuperDictSelOcc, mkCCallName,
- Name, NamedThing(..),
- )
-import OccName ( mkSrcVarOcc )
+import Name ( mkWiredInName, mkCCallName, Name )
+import OccName ( mkVarOcc )
import PrimOp ( PrimOp(DataToTagOp, CCallOp),
primOpSig, mkPrimOpIdName,
CCall, pprCCallOp
)
-import Demand ( wwStrict, wwPrim )
+import Demand ( wwStrict, wwPrim, mkStrictnessInfo )
import DataCon ( DataCon, StrictnessMark(..),
dataConFieldLabels, dataConRepArity, dataConTyCon,
- dataConArgTys, dataConRepType, dataConRepStrictness, dataConName,
- dataConSig, dataConStrictMarks, dataConId
+ dataConArgTys, dataConRepType, dataConRepStrictness,
+ dataConInstOrigArgTys,
+ dataConName, dataConTheta,
+ dataConSig, dataConStrictMarks, dataConId,
+ maybeMarkedUnboxed, splitProductType_maybe
)
-import Id ( idType, mkId,
- mkVanillaId, mkTemplateLocals,
- mkTemplateLocal, setInlinePragma, idCprInfo
+import Id ( idType, mkGlobalId, mkVanillaGlobal,
+ mkTemplateLocals, mkTemplateLocalsNum,
+ mkTemplateLocal, idCprInfo
)
-import IdInfo ( IdInfo, vanillaIdInfo, mkIdInfo,
- exactArity, setUnfoldingInfo, setCafInfo, setCprInfo,
- setArityInfo, setInlinePragInfo, setSpecInfo,
+import IdInfo ( IdInfo, noCafNoTyGenIdInfo,
+ exactArity, setUnfoldingInfo, setCprInfo,
+ setArityInfo, setSpecInfo, setCgInfo,
mkStrictnessInfo, setStrictnessInfo,
- IdFlavour(..), InlinePragInfo(..), CafInfo(..), StrictnessInfo(..), CprInfo(..)
+ GlobalIdDetails(..), CafInfo(..), CprInfo(..),
+ CgInfo(..), setCgArity
)
-import FieldLabel ( FieldLabel, FieldLabelTag, mkFieldLabel, fieldLabelName,
+import FieldLabel ( mkFieldLabel, fieldLabelName,
firstFieldLabelTag, allFieldLabelTags, fieldLabelType
)
import CoreSyn
import Maybes
-import BasicTypes ( Arity )
-import Unique
+import PrelNames
import Maybe ( isJust )
import Outputable
-import Util ( assoc )
-import List ( nub )
+import ListSetOps ( assoc, assocMaybe )
+import UnicodeUtil ( stringToUtf8 )
+import Char ( ord )
\end{code}
-
%************************************************************************
%* *
\subsection{Wired in Ids}
-- is 'open'; that is can be unified with an unboxed type
--
-- [The interface file format now carry such information, but there's
- -- no way yet of expressing at the definition site for these error-reporting
- -- functions that they have an 'open' result type. -- sof 1/99]
+ -- no way yet of expressing at the definition site for these
+ -- error-reporting
+ -- functions that they have an 'open' result type. -- sof 1/99]
aBSENT_ERROR_ID
, eRROR_ID
, rEC_CON_ERROR_ID
, rEC_UPD_ERROR_ID
- -- These two can't be defined in Haskell
+ -- These three can't be defined in Haskell
, realWorldPrimId
, unsafeCoerceId
, getTagId
%************************************************************************
%* *
-\subsection{Easy ones}
-%* *
-%************************************************************************
-
-\begin{code}
-mkSpecPragmaId occ uniq ty loc
- = mkId (mkLocalName uniq occ loc) ty (mkIdInfo SpecPragmaId)
- -- Maybe a SysLocal? But then we'd lose the location
-
-mkDefaultMethodId dm_name rec_c ty
- = mkVanillaId dm_name ty
-
-mkWorkerId uniq unwrkr ty
- = mkVanillaId (mkDerivedName mkWorkerOcc (getName unwrkr) uniq) ty
-\end{code}
-
-%************************************************************************
-%* *
\subsection{Data constructors}
%* *
%************************************************************************
-- Makes the *worker* for the data constructor; that is, the function
-- that takes the reprsentation arguments and builds the constructor.
mkDataConId work_name data_con
- = mkId work_name (dataConRepType data_con) info
+ = mkGlobalId (DataConId data_con) work_name (dataConRepType data_con) info
where
- info = mkIdInfo (DataConId data_con)
+ info = noCafNoTyGenIdInfo
+ `setCgArity` arity
`setArityInfo` exactArity arity
`setStrictnessInfo` strict_info
`setCprInfo` cpr_info
arity = dataConRepArity data_con
- strict_info = StrictnessInfo (dataConRepStrictness data_con) False
+ strict_info = mkStrictnessInfo (dataConRepStrictness data_con, False)
+ tycon = dataConTyCon data_con
cpr_info | isProductTyCon tycon &&
- not (isUnboxedTupleTyCon tycon) &&
- arity > 0 = ReturnsCPR
- | otherwise = NoCPRInfo
- where
- tycon = dataConTyCon data_con
- -- Newtypes don't have a worker at all
- --
- -- If we are a product with 0 args we must be void(like)
- -- We can't create an unboxed tuple with 0 args for this
- -- and since Void has only one, constant value it should
- -- just mean returning a pointer to a pre-existing cell.
- -- So we won't really gain from doing anything fancy
- -- and we treat this case as Top.
+ isDataTyCon tycon &&
+ arity > 0 &&
+ arity <= mAX_CPR_SIZE = ReturnsCPR
+ | otherwise = NoCPRInfo
+ -- ReturnsCPR is only true for products that are real data types;
+ -- that is, not unboxed tuples or newtypes
+
+mAX_CPR_SIZE :: Arity
+mAX_CPR_SIZE = 10
+-- We do not treat very big tuples as CPR-ish:
+-- a) for a start we get into trouble because there aren't
+-- "enough" unboxed tuple types (a tiresome restriction,
+-- but hard to fix),
+-- b) more importantly, big unboxed tuples get returned mainly
+-- on the stack, and are often then allocated in the heap
+-- by the caller. So doing CPR for them may in fact make
+-- things worse.
\end{code}
The wrapper for a constructor is an ordinary top-level binding that evaluates
mkDataConWrapId data_con
= wrap_id
where
- wrap_id = mkId (dataConName data_con) wrap_ty info
+ wrap_id = mkGlobalId (DataConWrapId data_con) (dataConName data_con) wrap_ty info
work_id = dataConId data_con
- info = mkIdInfo (DataConWrapId data_con)
- `setUnfoldingInfo` mkTopUnfolding cpr_info (mkInlineMe wrap_rhs)
+ info = noCafNoTyGenIdInfo
+ `setUnfoldingInfo` mkTopUnfolding (mkInlineMe wrap_rhs)
`setCprInfo` cpr_info
-- The Cpr info can be important inside INLINE rhss, where the
-- wrapper constructor isn't inlined
+ `setCgArity` arity
+ -- The NoCaf-ness is set by noCafNoTyGenIdInfo
`setArityInfo` exactArity arity
-- It's important to specify the arity, so that partial
-- applications are treated as values
- `setCafInfo` NoCafRefs
- -- The wrapper Id ends up in STG code as an argument,
- -- sometimes before its definition, so we want to
- -- signal that it has no CAFs
wrap_ty = mkForAllTys all_tyvars $
mkFunTys all_arg_tys
wrap_rhs | isNewTyCon tycon
= ASSERT( null ex_tyvars && null ex_dict_args && length orig_arg_tys == 1 )
- -- No existentials on a newtype, but it can have a contex
+ -- No existentials on a newtype, but it can have a context
-- e.g. newtype Eq a => T a = MkT (...)
mkLams tyvars $ mkLams dict_args $ Lam id_arg1 $
Note (Coerce result_ty (head orig_arg_tys)) (Var id_arg1)
-{- I nuked this because map (:) xs would create a
- new local lambda for the (:) in core-to-stg.
- There isn't a defn for the worker!
-
| null dict_args && all not_marked_strict strict_marks
= Var work_id -- The common case. Not only is this efficient,
-- but it also ensures that the wrapper is replaced
-- becomes
-- f $w: x
-- This is really important in rule matching,
- -- which is a bit sad. (We could match on the wrappers,
+ -- (We could match on the wrappers,
-- but that makes it less likely that rules will match
- -- when we bring bits of unfoldings together
--}
+ -- when we bring bits of unfoldings together.)
+ --
+ -- NB: because of this special case, (map (:) ys) turns into
+ -- (map $w: ys), and thence into (map (\x xs. $w: x xs) ys)
+ -- in core-to-stg. The top-level defn for (:) is never used.
+ -- This is somewhat of a bore, but I'm currently leaving it
+ -- as is, so that there still is a top level curried (:) for
+ -- the interpreter to call.
| otherwise
= mkLams all_tyvars $ mkLams dict_args $
(tyvars, theta, ex_tyvars, ex_theta, orig_arg_tys, tycon) = dataConSig data_con
all_tyvars = tyvars ++ ex_tyvars
- dict_tys = [mkDictTy clas tys | (clas,tys) <- theta]
- ex_dict_tys = [mkDictTy clas tys | (clas,tys) <- ex_theta]
+ dict_tys = mkPredTys theta
+ ex_dict_tys = mkPredTys ex_theta
all_arg_tys = dict_tys ++ ex_dict_tys ++ orig_arg_tys
result_ty = mkTyConApp tycon (mkTyVarTys tyvars)
MarkedUnboxed con tys ->
Case (Var arg) arg [(DataAlt con, con_args,
body i' (reverse con_args++rep_args))]
- where n_tys = length tys
- (con_args,i') = mkLocals i tys
+ where
+ (con_args,i') = mkLocals i tys
\end{code}
T2 ... x ... -> x
other -> error "..."
+Similarly for newtypes
+
+ newtype N a = MkN { unN :: a->a }
+
+ unN :: N a -> a -> a
+ unN n = coerce (a->a) n
+
+We need to take a little care if the field has a polymorphic type:
+
+ data R = R { f :: forall a. a->a }
+
+Then we want
+
+ f :: forall a. R -> a -> a
+ f = /\ a \ r = case r of
+ R f -> f a
+
+(not f :: R -> forall a. a->a, which gives the type inference mechanism
+problems at call sites)
+
+Similarly for newtypes
+
+ newtype N = MkN { unN :: forall a. a->a }
+
+ unN :: forall a. N -> a -> a
+ unN = /\a -> \n:N -> coerce (a->a) n
+
\begin{code}
-mkRecordSelId tycon field_label
- -- Assumes that all fields with the same field label
- -- have the same type
+mkRecordSelId tycon field_label unpack_id unpackUtf8_id
+ -- Assumes that all fields with the same field label have the same type
+ --
+ -- Annoyingly, we have to pass in the unpackCString# Id, because
+ -- we can't conjure it up out of thin air
= sel_id
where
- sel_id = mkId (fieldLabelName field_label) selector_ty info
-
+ sel_id = mkGlobalId (RecordSelId field_label) (fieldLabelName field_label) selector_ty info
field_ty = fieldLabelType field_label
- field_name = fieldLabelName field_label
data_cons = tyConDataCons tycon
tyvars = tyConTyVars tycon -- These scope over the types in
-- the FieldLabels of constructors of this type
-
- data_ty = mkTyConApp tycon (mkTyVarTys tyvars)
+ data_ty = mkTyConApp tycon tyvar_tys
tyvar_tys = mkTyVarTys tyvars
+ tycon_theta = tyConTheta tycon -- The context on the data decl
+ -- eg data (Eq a, Ord b) => T a b = ...
+ dict_tys = [mkPredTy pred | pred <- tycon_theta,
+ needed_dict pred]
+ needed_dict pred = or [ pred `elem` (dataConTheta dc)
+ | (DataAlt dc, _, _) <- the_alts]
+ n_dict_tys = length dict_tys
+
+ (field_tyvars,field_theta,field_tau) = splitSigmaTy field_ty
+ field_dict_tys = map mkPredTy field_theta
+ n_field_dict_tys = length field_dict_tys
+ -- If the field has a universally quantified type we have to
+ -- be a bit careful. Suppose we have
+ -- data R = R { op :: forall a. Foo a => a -> a }
+ -- Then we can't give op the type
+ -- op :: R -> forall a. Foo a => a -> a
+ -- because the typechecker doesn't understand foralls to the
+ -- right of an arrow. The "right" type to give it is
+ -- op :: forall a. Foo a => R -> a -> a
+ -- But then we must generate the right unfolding too:
+ -- op = /\a -> \dfoo -> \ r ->
+ -- case r of
+ -- R op -> op a dfoo
+ -- Note that this is exactly the type we'd infer from a user defn
+ -- op (R op) = op
+
+ -- Very tiresomely, the selectors are (unnecessarily!) overloaded over
+ -- just the dictionaries in the types of the constructors that contain
+ -- the relevant field. Urgh.
+ -- NB: this code relies on the fact that DataCons are quantified over
+ -- the identical type variables as their parent TyCon
+
selector_ty :: Type
- selector_ty = mkForAllTys tyvars (mkFunTy data_ty field_ty)
+ selector_ty = mkForAllTys tyvars $ mkForAllTys field_tyvars $
+ mkFunTys dict_tys $ mkFunTys field_dict_tys $
+ mkFunTy data_ty field_tau
- info = mkIdInfo (RecordSelId field_label)
- `setArityInfo` exactArity 1
+ arity = 1 + n_dict_tys + n_field_dict_tys
+ info = noCafNoTyGenIdInfo
+ `setCgInfo` (CgInfo arity caf_info)
+ `setArityInfo` exactArity arity
`setUnfoldingInfo` unfolding
- `setCafInfo` NoCafRefs
-- ToDo: consider adding further IdInfo
- unfolding = mkTopUnfolding NoCPRInfo sel_rhs
+ unfolding = mkTopUnfolding sel_rhs
+
+ -- Allocate Ids. We do it a funny way round because field_dict_tys is
+ -- almost always empty. Also note that we use length_tycon_theta
+ -- rather than n_dict_tys, because the latter gives an infinite loop:
+ -- n_dict tys depends on the_alts, which depens on arg_ids, which depends
+ -- on arity, which depends on n_dict tys. Sigh! Mega sigh!
+ field_dict_base = length tycon_theta + 1
+ dict_id_base = field_dict_base + n_field_dict_tys
+ field_base = dict_id_base + 1
+ dict_ids = mkTemplateLocalsNum 1 dict_tys
+ field_dict_ids = mkTemplateLocalsNum field_dict_base field_dict_tys
+ data_id = mkTemplateLocal dict_id_base data_ty
-
- [data_id] = mkTemplateLocals [data_ty]
alts = map mk_maybe_alt data_cons
the_alts = catMaybes alts
- default_alt | all isJust alts = [] -- No default needed
- | otherwise = [(DEFAULT, [], error_expr)]
- sel_rhs | isNewTyCon tycon = new_sel_rhs
- | otherwise = data_sel_rhs
+ no_default = all isJust alts -- No default needed
+ default_alt | no_default = []
+ | otherwise = [(DEFAULT, [], error_expr)]
- data_sel_rhs = mkLams tyvars $ Lam data_id $
- Case (Var data_id) data_id (the_alts ++ default_alt)
+ -- the default branch may have CAF refs, because it calls recSelError etc.
+ caf_info | no_default = NoCafRefs
+ | otherwise = MayHaveCafRefs
- new_sel_rhs = mkLams tyvars $ Lam data_id $
- Note (Coerce (unUsgTy field_ty) (unUsgTy data_ty)) (Var data_id)
+ sel_rhs = mkLams tyvars $ mkLams field_tyvars $
+ mkLams dict_ids $ mkLams field_dict_ids $
+ Lam data_id $ sel_body
+
+ sel_body | isNewTyCon tycon = Note (Coerce field_tau data_ty) (Var data_id)
+ | otherwise = Case (Var data_id) data_id (the_alts ++ default_alt)
mk_maybe_alt data_con
= case maybe_the_arg_id of
Nothing -> Nothing
- Just the_arg_id -> Just (DataAlt data_con, arg_ids, Var the_arg_id)
- where
- arg_ids = mkTemplateLocals (dataConArgTys data_con tyvar_tys)
- -- The first one will shadow data_id, but who cares
- field_lbls = dataConFieldLabels data_con
- maybe_the_arg_id = assocMaybe (field_lbls `zip` arg_ids) field_label
-
- error_expr = mkApps (Var rEC_SEL_ERROR_ID) [Type (unUsgTy field_ty), mkStringLit full_msg]
- -- preserves invariant that type args are *not* usage-annotated on top. KSW 1999-04.
+ Just the_arg_id -> Just (DataAlt data_con, real_args, expr)
+ where
+ body = mkVarApps (mkVarApps (Var the_arg_id) field_tyvars) field_dict_ids
+ strict_marks = dataConStrictMarks data_con
+ (expr, real_args) = rebuildConArgs data_con arg_ids strict_marks body
+ unpack_base
+ where
+ arg_ids = mkTemplateLocalsNum field_base (dataConInstOrigArgTys data_con tyvar_tys)
+
+ unpack_base = field_base + length arg_ids
+
+ -- arity+1 avoids all shadowing
+ maybe_the_arg_id = assocMaybe (field_lbls `zip` arg_ids) field_label
+ field_lbls = dataConFieldLabels data_con
+
+ error_expr = mkApps (Var rEC_SEL_ERROR_ID) [Type field_tau, err_string]
+ err_string
+ | all safeChar full_msg
+ = App (Var unpack_id) (Lit (MachStr (_PK_ full_msg)))
+ | otherwise
+ = App (Var unpackUtf8_id) (Lit (MachStr (_PK_ (stringToUtf8 (map ord full_msg)))))
+ where
+ safeChar c = c >= '\1' && c <= '\xFF'
+ -- TODO: Putting this Unicode stuff here is ugly. Find a better
+ -- generic place to make string literals. This logic is repeated
+ -- in DsUtils.
full_msg = showSDoc (sep [text "No match in record selector", ppr sel_id])
+
+
+-- this rather ugly function converts the unpacked data con arguments back into
+-- their packed form. It is almost the same as the version in DsUtils, except that
+-- we use template locals here rather than newDsId (ToDo: merge these).
+
+rebuildConArgs
+ :: DataCon -- the con we're matching on
+ -> [Id] -- the source-level args
+ -> [StrictnessMark] -- the strictness annotations (per-arg)
+ -> CoreExpr -- the body
+ -> Int -- template local
+ -> (CoreExpr, [Id])
+
+rebuildConArgs con [] stricts body i = (body, [])
+rebuildConArgs con (arg:args) stricts body i | isTyVar arg
+ = let (body', args') = rebuildConArgs con args stricts body i
+ in (body',arg:args')
+rebuildConArgs con (arg:args) (str:stricts) body i
+ = case maybeMarkedUnboxed str of
+ Just (pack_con1, _) ->
+ case splitProductType_maybe (idType arg) of
+ Just (_, tycon_args, pack_con, con_arg_tys) ->
+ ASSERT( pack_con == pack_con1 )
+ let unpacked_args = zipWith mkTemplateLocal [i..] con_arg_tys
+ (body', real_args) = rebuildConArgs con args stricts body
+ (i + length con_arg_tys)
+ in
+ (
+ Let (NonRec arg (mkConApp pack_con
+ (map Type tycon_args ++
+ map Var unpacked_args))) body',
+ unpacked_args ++ real_args
+ )
+
+ _ -> let (body', args') = rebuildConArgs con args stricts body i
+ in (body', arg:args')
\end{code}
ToDo: unify with mkRecordSelId.
\begin{code}
-mkDictSelId name clas ty
+mkDictSelId :: Name -> Class -> Id
+mkDictSelId name clas
= sel_id
where
- sel_id = mkId name ty info
- field_lbl = mkFieldLabel name ty tag
+ ty = exprType rhs
+ sel_id = mkGlobalId (RecordSelId field_lbl) name ty info
+ field_lbl = mkFieldLabel name tycon ty tag
tag = assoc "MkId.mkDictSelId" (classSelIds clas `zip` allFieldLabelTags) sel_id
- info = mkIdInfo (RecordSelId field_lbl)
+ info = noCafNoTyGenIdInfo
+ `setCgArity` 1
`setArityInfo` exactArity 1
`setUnfoldingInfo` unfolding
- `setCafInfo` NoCafRefs
-- We no longer use 'must-inline' on record selectors. They'll
-- inline like crazy if they scrutinise a constructor
- unfolding = mkTopUnfolding NoCPRInfo rhs
+ unfolding = mkTopUnfolding rhs
tyvars = classTyVars clas
where
(tyvars,arg_tys,res_ty, arity, strict_info) = primOpSig prim_op
ty = mkForAllTys tyvars (mkFunTys arg_tys res_ty)
- name = mkPrimOpIdName prim_op id
- id = mkId name ty info
+ name = mkPrimOpIdName prim_op
+ id = mkGlobalId (PrimOpId prim_op) name ty info
- info = mkIdInfo (PrimOpId prim_op)
+ info = noCafNoTyGenIdInfo
`setSpecInfo` rules
+ `setCgArity` arity
`setArityInfo` exactArity arity
`setStrictnessInfo` strict_info
- rules = addRule id emptyCoreRules (primOpRule prim_op)
+ rules = maybe emptyCoreRules (addRule emptyCoreRules id)
+ (primOpRule prim_op)
-- For each ccall we manufacture a separate CCallOpId, giving it
= ASSERT( isEmptyVarSet (tyVarsOfType ty) )
-- A CCallOpId should have no free type variables;
-- when doing substitutions won't substitute over it
- mkId name ty info
+ mkGlobalId (PrimOpId prim_op) name ty info
where
occ_str = showSDocIface (braces (pprCCallOp ccall <+> ppr ty))
-- The "occurrence name" of a ccall is the full info about the
name = mkCCallName uniq occ_str
prim_op = CCallOp ccall
- info = mkIdInfo (PrimOpId prim_op)
+ info = noCafNoTyGenIdInfo
+ `setCgArity` arity
`setArityInfo` exactArity arity
`setStrictnessInfo` strict_info
%************************************************************************
%* *
-\subsection{DictFuns}
+\subsection{DictFuns and default methods}
%* *
%************************************************************************
\begin{code}
+mkDefaultMethodId dm_name ty
+ = mkVanillaGlobal dm_name ty noCafNoTyGenIdInfo
+
mkDictFunId :: Name -- Name to use for the dict fun;
-> Class
-> [TyVar]
-> [Type]
- -> ClassContext
+ -> ThetaType
-> Id
-mkDictFunId dfun_name clas inst_tyvars inst_tys inst_decl_theta
- = mkVanillaId dfun_name dfun_ty
+mkDictFunId dfun_name clas inst_tyvars inst_tys dfun_theta
+ = mkVanillaGlobal dfun_name dfun_ty noCafNoTyGenIdInfo
where
- (class_tyvars, sc_theta, _, _) = classBigSig clas
- sc_theta' = substClasses (mkTopTyVarSubst class_tyvars inst_tys) sc_theta
-
- dfun_theta = classesToPreds inst_decl_theta
+ dfun_ty = mkSigmaTy inst_tyvars dfun_theta (mkDictTy clas inst_tys)
{- 1 dec 99: disable the Mark Jones optimisation for the sake
of compatibility with Hugs.
See `types/InstEnv' for a discussion related to this.
+ (class_tyvars, sc_theta, _, _) = classBigSig clas
+ not_const (clas, tys) = not (isEmptyVarSet (tyVarsOfTypes tys))
+ sc_theta' = substClasses (mkTopTyVarSubst class_tyvars inst_tys) sc_theta
dfun_theta = case inst_decl_theta of
[] -> [] -- If inst_decl_theta is empty, then we don't
-- want to have any dict arguments, so that we can
-- instance Wob b => Baz T b where..
-- Now sc_theta' has Foo T
-}
- dfun_ty = mkSigmaTy inst_tyvars dfun_theta (mkDictTy clas inst_tys)
-
- not_const (clas, tys) = not (isEmptyVarSet (tyVarsOfTypes tys))
\end{code}
unsafeCoerceId
= pcMiscPrelId unsafeCoerceIdKey pREL_GHC SLIT("unsafeCoerce#") ty info
where
- info = vanillaIdInfo
- `setUnfoldingInfo` mkCompulsoryUnfolding rhs
+ info = noCafNoTyGenIdInfo `setUnfoldingInfo` mkCompulsoryUnfolding rhs
ty = mkForAllTys [openAlphaTyVar,openBetaTyVar]
getTagId
= pcMiscPrelId getTagIdKey pREL_GHC SLIT("getTag#") ty info
where
- info = vanillaIdInfo
- `setUnfoldingInfo` mkCompulsoryUnfolding rhs
+ info = noCafNoTyGenIdInfo `setUnfoldingInfo` mkCompulsoryUnfolding rhs
-- We don't provide a defn for this; you must inline it
ty = mkForAllTys [alphaTyVar] (mkFunTy alphaTy intPrimTy)
realWorldPrimId -- :: State# RealWorld
= pcMiscPrelId realWorldPrimIdKey pREL_GHC SLIT("realWorld#")
realWorldStatePrimTy
- (noCafIdInfo `setUnfoldingInfo` mkOtherCon [])
+ (noCafNoTyGenIdInfo `setUnfoldingInfo` mkOtherCon [])
-- The mkOtherCon makes it look that realWorld# is evaluated
-- which in turn makes Simplify.interestingArg return True,
-- which in turn makes INLINE things applied to realWorld# likely
\begin{code}
eRROR_ID
= pc_bottoming_Id errorIdKey pREL_ERR SLIT("error") errorTy
-rEC_SEL_ERROR_ID
- = generic_ERROR_ID recSelErrIdKey SLIT("patError")
pAT_ERROR_ID
= generic_ERROR_ID patErrorIdKey SLIT("patError")
+rEC_SEL_ERROR_ID
+ = generic_ERROR_ID recSelErrIdKey SLIT("recSelError")
rEC_CON_ERROR_ID
= generic_ERROR_ID recConErrorIdKey SLIT("recConError")
rEC_UPD_ERROR_ID
pAR_ERROR_ID
= pcMiscPrelId parErrorIdKey pREL_ERR SLIT("parError")
- (mkSigmaTy [openAlphaTyVar] [] openAlphaTy) noCafIdInfo
-
+ (mkSigmaTy [openAlphaTyVar] [] openAlphaTy) noCafNoTyGenIdInfo
\end{code}
pcMiscPrelId :: Unique{-IdKey-} -> Module -> FAST_STRING -> Type -> IdInfo -> Id
pcMiscPrelId key mod str ty info
= let
- name = mkWiredInIdName key mod (mkSrcVarOcc str) imp
- imp = mkId name ty info -- the usual case...
+ name = mkWiredInName mod (mkVarOcc str) key
+ imp = mkVanillaGlobal name ty info -- the usual case...
in
imp
-- We lie and say the thing is imported; otherwise, we get into
pc_bottoming_Id key mod name ty
= pcMiscPrelId key mod name ty bottoming_info
where
- bottoming_info = noCafIdInfo
+ bottoming_info = noCafNoTyGenIdInfo
`setStrictnessInfo` mkStrictnessInfo ([wwStrict], True)
-
+
-- these "bottom" out, no matter what their arguments
generic_ERROR_ID u n = pc_bottoming_Id u pREL_ERR n errorTy
--- Very useful...
-noCafIdInfo = vanillaIdInfo `setCafInfo` NoCafRefs
-
(openAlphaTyVar:openBetaTyVar:_) = openAlphaTyVars
openAlphaTy = mkTyVarTy openAlphaTyVar
openBetaTy = mkTyVarTy openBetaTyVar
errorTy :: Type
-errorTy = mkUsgTy UsMany $
- mkSigmaTy [openAlphaTyVar] [] (mkFunTys [mkUsgTy UsOnce (mkListTy charTy)]
- (mkUsgTy UsMany openAlphaTy))
+errorTy = mkSigmaTy [openAlphaTyVar] [] (mkFunTys [mkListTy charTy]
+ openAlphaTy)
-- Notice the openAlphaTyVar. It says that "error" can be applied
-- to unboxed as well as boxed types. This is OK because it never
-- returns, so the return type is irrelevant.
projects / ghc-hetmet.git / blobdiff