mkDictFunId, mkDefaultMethodId,
mkDictSelId,
- mkDataConWorkId, mkDataConWrapId,
+ mkDataConIds,
mkRecordSelId,
mkPrimOpId, mkFCallId,
mkRuntimeErrorApp,
rEC_CON_ERROR_ID, iRREFUT_PAT_ERROR_ID, rUNTIME_ERROR_ID,
nON_EXHAUSTIVE_GUARDS_ERROR_ID, nO_METHOD_BINDING_ERROR_ID,
- pAT_ERROR_ID
+ pAT_ERROR_ID, eRROR_ID
) where
#include "HsVersions.h"
import TysWiredIn ( charTy, mkListTy )
import PrelRules ( primOpRules )
import Rules ( addRule )
+import Type ( TyThing(..) )
import TcType ( Type, ThetaType, mkDictTy, mkPredTys, mkTyConApp,
mkTyVarTys, mkClassPred, tcEqPred,
mkFunTys, mkFunTy, mkSigmaTy, tcSplitSigmaTy,
import Class ( Class, classTyCon, classTyVars, classSelIds )
import Var ( Id, TyVar, Var )
import VarSet ( isEmptyVarSet )
-import Name ( mkFCallName, Name )
-import PrimOp ( PrimOp, primOpSig, mkPrimOpIdName )
+import Name ( mkFCallName, mkWiredInName, Name )
+import OccName ( mkOccFS, varName )
+import PrimOp ( PrimOp, primOpSig, primOpOcc, primOpTag )
import ForeignCall ( ForeignCall )
-import DataCon ( DataCon,
- dataConFieldLabels, dataConRepArity, dataConTyCon,
+import DataCon ( DataCon, DataConIds(..),
+ dataConFieldLabels, dataConRepArity,
dataConArgTys, dataConRepType,
- dataConOrigArgTys,
- dataConTheta,
- dataConSig, dataConStrictMarks, dataConWorkId,
+ dataConOrigArgTys, dataConTheta,
+ dataConSig, dataConStrictMarks, dataConExStricts,
splitProductType
)
import Id ( idType, mkGlobalId, mkVanillaGlobal, mkSysLocal, mkLocalId,
mkTemplateLocals, mkTemplateLocalsNum, setIdLocalExported,
- mkTemplateLocal, idNewStrictness, idName
+ mkTemplateLocal, idName
)
import IdInfo ( IdInfo, noCafIdInfo, setUnfoldingInfo,
setArityInfo, setSpecInfo, setCafInfo,
setAllStrictnessInfo, vanillaIdInfo,
GlobalIdDetails(..), CafInfo(..)
)
-import NewDemand ( mkStrictSig, strictSigResInfo, DmdResult(..),
+import NewDemand ( mkStrictSig, DmdResult(..),
mkTopDmdType, topDmd, evalDmd, lazyDmd, retCPR,
Demand(..), Demands(..) )
-import FieldLabel ( mkFieldLabel, fieldLabelName,
- firstFieldLabelTag, allFieldLabelTags, fieldLabelType
+import FieldLabel ( fieldLabelName, firstFieldLabelTag,
+ allFieldLabelTags, fieldLabelType
)
import DmdAnal ( dmdAnalTopRhs )
import CoreSyn
-import Unique ( mkBuiltinUnique )
+import Unique ( mkBuiltinUnique, mkPrimOpIdUnique )
import Maybes
import PrelNames
import Maybe ( isJust )
%* *
%************************************************************************
-\begin{code}
-mkDataConWorkId :: Name -> DataCon -> Id
- -- Makes the *worker* for the data constructor; that is, the function
- -- that takes the reprsentation arguments and builds the constructor.
-mkDataConWorkId wkr_name data_con
- = mkGlobalId (DataConWorkId data_con) wkr_name
- (dataConRepType data_con) info
- where
- info = noCafIdInfo
- `setArityInfo` arity
- `setAllStrictnessInfo` Just strict_sig
-
- arity = dataConRepArity data_con
- strict_sig = mkStrictSig (mkTopDmdType (replicate arity topDmd) cpr_info)
- -- Notice that we do *not* say the worker is strict
- -- even if the data constructor is declared strict
- -- e.g. data T = MkT !(Int,Int)
- -- Why? Because the *wrapper* is strict (and its unfolding has case
- -- expresssions that do the evals) but the *worker* itself is not.
- -- If we pretend it is strict then when we see
- -- case x of y -> $wMkT y
- -- the simplifier thinks that y is "sure to be evaluated" (because
- -- $wMkT is strict) and drops the case. No, $wMkT is not strict.
- --
- -- When the simplifer sees a pattern
- -- case e of MkT x -> ...
- -- it uses the dataConRepStrictness of MkT to mark x as evaluated;
- -- but that's fine... dataConRepStrictness comes from the data con
- -- not from the worker Id.
-
- tycon = dataConTyCon data_con
- cpr_info | isProductTyCon tycon &&
- isDataTyCon tycon &&
- arity > 0 &&
- arity <= mAX_CPR_SIZE = retCPR
- | otherwise = TopRes
- -- RetCPR is only true for products that are real data types;
- -- that is, not unboxed tuples or [non-recursive] 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
any strict args, unboxes any args that are going to be flattened, and calls
the worker.
Making an explicit case expression allows the simplifier to eliminate
it in the (common) case where the constructor arg is already evaluated.
+
\begin{code}
-mkDataConWrapId :: Name -> DataCon -> Maybe Id
--- Only make a wrapper Id if necessary
+mkDataConIds :: Name -> Name -> DataCon -> DataConIds
+ -- Makes the *worker* for the data constructor; that is, the function
+ -- that takes the reprsentation arguments and builds the constructor.
+mkDataConIds wrap_name wkr_name data_con
+ | isNewTyCon tycon
+ = NewDC nt_wrap_id
-mkDataConWrapId wrap_name data_con
- | is_newtype || any isMarkedStrict strict_marks
- = -- We need a wrapper function
- Just (mkGlobalId (DataConWrapId data_con) wrap_name wrap_ty info)
+ | any isMarkedStrict all_strict_marks -- Algebraic, needs wrapper
+ = AlgDC (Just alg_wrap_id) wrk_id
- | otherwise
- = Nothing -- The common case, where there is no point in
- -- having a wrapper function. Not only is this efficient,
- -- but it also ensures that the wrapper is replaced
- -- by the worker (becuase it *is* the wroker)
- -- even when there are no args. E.g. in
- -- f (:) x
- -- the (:) *is* the worker.
- -- This is really important in rule matching,
- -- (We could match on the wrappers,
- -- but that makes it less likely that rules will match
- -- when we bring bits of unfoldings together.)
+ | otherwise -- Algebraic, no wrapper
+ = AlgDC Nothing wrk_id
where
(tyvars, _, ex_tyvars, ex_theta, orig_arg_tys, tycon) = dataConSig data_con
- is_newtype = isNewTyCon tycon
all_tyvars = tyvars ++ ex_tyvars
- work_id = dataConWorkId data_con
- common_info = noCafIdInfo -- The NoCaf-ness is set by noCafIdInfo
- `setArityInfo` arity
- -- It's important to specify the arity, so that partial
- -- applications are treated as values
+ ex_dict_tys = mkPredTys ex_theta
+ all_arg_tys = ex_dict_tys ++ orig_arg_tys
+ result_ty = mkTyConApp tycon (mkTyVarTys tyvars)
- info | is_newtype = common_info `setUnfoldingInfo` newtype_unf
- | otherwise = common_info `setUnfoldingInfo` data_unf
- `setAllStrictnessInfo` Just wrap_sig
+ wrap_ty = mkForAllTys all_tyvars (mkFunTys all_arg_tys result_ty)
+ -- We used to include the stupid theta in the wrapper's args
+ -- but now we don't. Instead the type checker just injects these
+ -- extra constraints where necessary.
- wrap_sig = mkStrictSig (mkTopDmdType arg_dmds res_info)
- res_info = strictSigResInfo (idNewStrictness work_id)
- arg_dmds = map mk_dmd strict_marks
+ ----------- Worker (algebraic data types only) --------------
+ wrk_id = mkGlobalId (DataConWorkId data_con) wkr_name
+ (dataConRepType data_con) wkr_info
+
+ wkr_arity = dataConRepArity data_con
+ wkr_info = noCafIdInfo
+ `setArityInfo` wkr_arity
+ `setAllStrictnessInfo` Just wkr_sig
+
+ wkr_sig = mkStrictSig (mkTopDmdType (replicate wkr_arity topDmd) cpr_info)
+ -- Notice that we do *not* say the worker is strict
+ -- even if the data constructor is declared strict
+ -- e.g. data T = MkT !(Int,Int)
+ -- Why? Because the *wrapper* is strict (and its unfolding has case
+ -- expresssions that do the evals) but the *worker* itself is not.
+ -- If we pretend it is strict then when we see
+ -- case x of y -> $wMkT y
+ -- the simplifier thinks that y is "sure to be evaluated" (because
+ -- $wMkT is strict) and drops the case. No, $wMkT is not strict.
+ --
+ -- When the simplifer sees a pattern
+ -- case e of MkT x -> ...
+ -- it uses the dataConRepStrictness of MkT to mark x as evaluated;
+ -- but that's fine... dataConRepStrictness comes from the data con
+ -- not from the worker Id.
+
+ cpr_info | isProductTyCon tycon &&
+ isDataTyCon tycon &&
+ wkr_arity > 0 &&
+ wkr_arity <= mAX_CPR_SIZE = retCPR
+ | otherwise = TopRes
+ -- RetCPR is only true for products that are real data types;
+ -- that is, not unboxed tuples or [non-recursive] newtypes
+
+ ----------- Wrappers for newtypes --------------
+ nt_wrap_id = mkGlobalId (DataConWrapId data_con) wrap_name wrap_ty nt_wrap_info
+ nt_wrap_info = noCafIdInfo -- The NoCaf-ness is set by noCafIdInfo
+ `setArityInfo` 1 -- Arity 1
+ `setUnfoldingInfo` newtype_unf
+ newtype_unf = ASSERT( null ex_tyvars && null ex_theta &&
+ isSingleton orig_arg_tys )
+ -- No existentials on a newtype, but it can have a context
+ -- e.g. newtype Eq a => T a = MkT (...)
+ mkTopUnfolding $ Note InlineMe $
+ mkLams tyvars $ Lam id_arg1 $
+ mkNewTypeBody tycon result_ty (Var id_arg1)
+
+ id_arg1 = mkTemplateLocal 1 (head orig_arg_tys)
+
+ ----------- Wrappers for algebraic data types --------------
+ alg_wrap_id = mkGlobalId (DataConWrapId data_con) wrap_name wrap_ty alg_wrap_info
+ alg_wrap_info = noCafIdInfo -- The NoCaf-ness is set by noCafIdInfo
+ `setArityInfo` alg_arity
+ -- It's important to specify the arity, so that partial
+ -- applications are treated as values
+ `setUnfoldingInfo` alg_unf
+ `setAllStrictnessInfo` Just wrap_sig
+
+ all_strict_marks = dataConExStricts data_con ++ dataConStrictMarks data_con
+ wrap_sig = mkStrictSig (mkTopDmdType arg_dmds cpr_info)
+ arg_dmds = map mk_dmd all_strict_marks
mk_dmd str | isMarkedStrict str = evalDmd
| otherwise = lazyDmd
-- The Cpr info can be important inside INLINE rhss, where the
-- ...(let w = C x in ...(w p q)...)...
-- we want to see that w is strict in its two arguments
- newtype_unf = ASSERT( null ex_tyvars && null ex_dict_args &&
- isSingleton orig_arg_tys )
- -- No existentials on a newtype, but it can have a context
- -- e.g. newtype Eq a => T a = MkT (...)
- mkTopUnfolding $ Note InlineMe $
- mkLams tyvars $ Lam id_arg1 $
- mkNewTypeBody tycon result_ty (Var id_arg1)
-
- data_unf = mkTopUnfolding $ Note InlineMe $
- mkLams all_tyvars $
- mkLams ex_dict_args $ mkLams id_args $
- foldr mk_case con_app
- (zip (ex_dict_args++id_args) strict_marks) i3 []
-
- con_app i rep_ids = mkApps (Var work_id)
- (map varToCoreExpr (all_tyvars ++ reverse rep_ids))
-
- ex_dict_tys = mkPredTys ex_theta
- all_arg_tys = ex_dict_tys ++ orig_arg_tys
- result_ty = mkTyConApp tycon (mkTyVarTys tyvars)
+ alg_unf = mkTopUnfolding $ Note InlineMe $
+ mkLams all_tyvars $
+ mkLams ex_dict_args $ mkLams id_args $
+ foldr mk_case con_app
+ (zip (ex_dict_args ++ id_args) all_strict_marks)
+ i3 []
- wrap_ty = mkForAllTys all_tyvars (mkFunTys all_arg_tys result_ty)
- -- We used to include the stupid theta in the wrapper's args
- -- but now we don't. Instead the type checker just injects these
- -- extra constraints where necessary.
-
- mkLocals i tys = (zipWith mkTemplateLocal [i..i+n-1] tys, i+n)
- where
- n = length tys
+ con_app i rep_ids = mkApps (Var wrk_id)
+ (map varToCoreExpr (all_tyvars ++ reverse rep_ids))
(ex_dict_args,i2) = mkLocals 1 ex_dict_tys
(id_args,i3) = mkLocals i2 orig_arg_tys
- arity = i3-1
- (id_arg1:_) = id_args -- Used for newtype only
-
- strict_marks = dataConStrictMarks data_con
+ alg_arity = i3-1
mk_case
:: (Id, StrictnessMark) -- Arg, strictness
body i' (reverse con_args ++ rep_args))]
where
(con_args, i') = mkLocals i tys
+
+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.
+
+mkLocals i tys = (zipWith mkTemplateLocal [i..i+n-1] tys, i+n)
+ where
+ n = length tys
\end{code}
\begin{code}
mkRecordSelId tycon field_label
-- 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 = mkGlobalId (RecordSelId field_label) (fieldLabelName field_label) selector_ty info
where
arg_ids = mkTemplateLocalsNum field_base (dataConOrigArgTys data_con)
-- No need to instantiate; same tyvars in datacon as tycon
+ -- Records can't be existential, so no existential tyvars or dicts
unpack_base = field_base + length arg_ids
uniqs = map mkBuiltinUnique [unpack_base..]
(DataAlt con, args', mkLets binds rhs)
where
- stricts = dataConStrictMarks con
+ stricts = dataConExStricts con ++ dataConStrictMarks con
go [] stricts us = ([], [])
-- But it's type must expose the representation of the dictionary
-- to gat (say) C a -> (a -> a)
- field_lbl = mkFieldLabel name tycon sel_ty tag
- tag = assoc "MkId.mkDictSelId" (map idName (classSelIds clas) `zip` allFieldLabelTags) name
+ tag = assoc "MkId.mkDictSelId" (map idName (classSelIds clas) `zip` allFieldLabelTags) name
- info = noCafIdInfo
+ info = noCafIdInfo
`setArityInfo` 1
`setUnfoldingInfo` mkTopUnfolding rhs
`setAllStrictnessInfo` Just strict_sig
where
(tyvars,arg_tys,res_ty, arity, strict_sig) = primOpSig prim_op
ty = mkForAllTys tyvars (mkFunTys arg_tys res_ty)
- name = mkPrimOpIdName prim_op
+ name = mkWiredInName gHC_PRIM (primOpOcc prim_op)
+ (mkPrimOpIdUnique (primOpTag prim_op))
+ Nothing (AnId id)
id = mkGlobalId (PrimOpId prim_op) name ty info
info = noCafIdInfo
another gun with which to shoot yourself in the foot.
\begin{code}
+mkWiredInIdName mod fs uniq id
+ = mkWiredInName mod (mkOccFS varName fs) uniq Nothing (AnId id)
+
+unsafeCoerceName = mkWiredInIdName gHC_PRIM FSLIT("unsafeCoerce#") unsafeCoerceIdKey unsafeCoerceId
+nullAddrName = mkWiredInIdName gHC_PRIM FSLIT("nullAddr#") nullAddrIdKey nullAddrId
+seqName = mkWiredInIdName gHC_PRIM FSLIT("seq") seqIdKey seqId
+realWorldName = mkWiredInIdName gHC_PRIM FSLIT("realWorld#") realWorldPrimIdKey realWorldPrimId
+lazyIdName = mkWiredInIdName pREL_BASE FSLIT("lazy") lazyIdKey lazyId
+
+errorName = mkWiredInIdName pREL_ERR FSLIT("error") errorIdKey eRROR_ID
+recSelErrorName = mkWiredInIdName pREL_ERR FSLIT("recSelError") recSelErrorIdKey rEC_SEL_ERROR_ID
+runtimeErrorName = mkWiredInIdName pREL_ERR FSLIT("runtimeError") runtimeErrorIdKey rUNTIME_ERROR_ID
+irrefutPatErrorName = mkWiredInIdName pREL_ERR FSLIT("irrefutPatError") irrefutPatErrorIdKey iRREFUT_PAT_ERROR_ID
+recConErrorName = mkWiredInIdName pREL_ERR FSLIT("recConError") recConErrorIdKey rEC_CON_ERROR_ID
+patErrorName = mkWiredInIdName pREL_ERR FSLIT("patError") patErrorIdKey pAT_ERROR_ID
+noMethodBindingErrorName = mkWiredInIdName pREL_ERR FSLIT("noMethodBindingError")
+ noMethodBindingErrorIdKey nO_METHOD_BINDING_ERROR_ID
+nonExhaustiveGuardsErrorName
+ = mkWiredInIdName pREL_ERR FSLIT("nonExhaustiveGuardsError")
+ nonExhaustiveGuardsErrorIdKey nON_EXHAUSTIVE_GUARDS_ERROR_ID
+\end{code}
+
+\begin{code}
-- unsafeCoerce# :: forall a b. a -> b
unsafeCoerceId
= pcMiscPrelId unsafeCoerceName ty info
rUNTIME_ERROR_ID = mkRuntimeErrorId runtimeErrorName
iRREFUT_PAT_ERROR_ID = mkRuntimeErrorId irrefutPatErrorName
rEC_CON_ERROR_ID = mkRuntimeErrorId recConErrorName
-nON_EXHAUSTIVE_GUARDS_ERROR_ID = mkRuntimeErrorId nonExhaustiveGuardsErrorName
pAT_ERROR_ID = mkRuntimeErrorId patErrorName
nO_METHOD_BINDING_ERROR_ID = mkRuntimeErrorId noMethodBindingErrorName
+nON_EXHAUSTIVE_GUARDS_ERROR_ID = mkRuntimeErrorId nonExhaustiveGuardsErrorName
-- The runtime error Ids take a UTF8-encoded string as argument
mkRuntimeErrorId name = pc_bottoming_Id name runtimeErrorTy