module CgCon (
cgTopRhsCon, buildDynCon,
bindConArgs, bindUnboxedTupleComponents,
- cgReturnDataCon
+ cgReturnDataCon,
+ cgTyCon
) where
#include "HsVersions.h"
import CgMonad
-import AbsCSyn
import StgSyn
-import AbsCUtils ( getAmodeRep )
import CgBindery ( getArgAmodes, bindNewToNode,
- bindArgsToRegs, newTempAmodeAndIdInfo,
- idInfoToAmode, stableAmodeIdInfo,
- heapIdInfo, CgIdInfo, bindNewToStack
- )
-import CgStackery ( mkTaggedVirtStkOffsets, freeStackSlots )
-import CgUsages ( getRealSp, getVirtSp, setRealAndVirtualSp )
-import CgClosure ( cgTopRhsClosure )
-import CgRetConv ( assignRegs )
-import Constants ( mAX_INTLIKE, mIN_INTLIKE )
-import CgHeapery ( allocDynClosure )
-import CgTailCall ( performReturn, mkStaticAlgReturnCode, doTailCall,
- mkUnboxedTupleReturnCode )
-import CLabel ( mkClosureLabel, mkStaticClosureLabel )
-import ClosureInfo ( mkClosureLFInfo, mkConLFInfo, mkLFArgument,
- layOutDynCon, layOutDynClosure,
- layOutStaticClosure
+ bindArgsToRegs, idInfoToAmode, stableIdInfo,
+ heapIdInfo, CgIdInfo, bindArgsToStack
)
+import CgStackery ( mkVirtStkOffsets, freeStackSlots,
+ getRealSp, getVirtSp, setRealAndVirtualSp )
+import CgUtils ( addIdReps, cmmLabelOffW, emitRODataLits, emitDataLits )
+import CgCallConv ( assignReturnRegs )
+import Constants ( mAX_INTLIKE, mIN_INTLIKE, mAX_CHARLIKE, mIN_CHARLIKE )
+import CgHeapery ( allocDynClosure, layOutDynConstr,
+ layOutStaticConstr, mkStaticClosureFields )
+import CgTailCall ( performReturn, emitKnownConReturnCode, returnUnboxedTuple )
+import CgProf ( mkCCostCentreStack, ldvEnter, curCCS )
+import CgTicky
+import CgInfoTbls ( emitClosureCodeAndInfoTable, dataConTagZ )
+import CLabel
+import ClosureInfo ( mkConLFInfo, mkLFArgument )
+import CmmUtils ( mkLblExpr )
+import Cmm
+import SMRep ( WordOff, CgRep, separateByPtrFollowness,
+ fixedHdrSize, typeCgRep )
import CostCentre ( currentOrSubsumedCCS, dontCareCCS, CostCentreStack,
currentCCS )
-import DataCon ( DataCon, dataConName, dataConTag, dataConTyCon,
- isUnboxedTupleCon )
-import MkId ( mkDataConId )
-import Id ( Id, idName, idType, idPrimRep )
-import Name ( nameModule, isLocallyDefinedName )
-import Module ( isDynamicModule )
-import Const ( Con(..), Literal(..), isLitLitLit )
+import Constants ( mIN_INTLIKE, mAX_INTLIKE, mIN_CHARLIKE, mAX_CHARLIKE )
+import TyCon ( TyCon, tyConDataCons, isEnumerationTyCon, tyConName )
+import DataCon ( DataCon, dataConRepArgTys, isNullaryRepDataCon,
+ isUnboxedTupleCon, dataConWorkId,
+ dataConName, dataConRepArity
+ )
+import Id ( Id, idName, isDeadBinder )
+import Type ( Type )
import PrelInfo ( maybeCharLikeCon, maybeIntLikeCon )
-import PrimRep ( PrimRep(..) )
-import Util
-import Panic ( assertPanic, trace )
+import Outputable
+import Util ( lengthIs )
+import ListSetOps ( assocMaybe )
\end{code}
+
%************************************************************************
%* *
\subsection[toplevel-constructors]{Top-level constructors}
cgTopRhsCon :: Id -- Name of thing bound to this RHS
-> DataCon -- Id
-> [StgArg] -- Args
- -> Bool -- All zero-size args (see buildDynCon)
-> FCode (Id, CgIdInfo)
-cgTopRhsCon id con args all_zero_size_args
- = ASSERT(not (any_litlit_args || dynamic_con_or_args))
- (
- -- LAY IT OUT
- getArgAmodes args `thenFC` \ amodes ->
-
- let
- (closure_info, amodes_w_offsets)
- = layOutStaticClosure name getAmodeRep amodes lf_info
- in
-
- -- BUILD THE OBJECT
- absC (CStaticClosure
- closure_label -- Labelled with the name on lhs of defn
- closure_info -- Closure is static
- top_ccc
- (map fst amodes_w_offsets)) -- Sorted into ptrs first, then nonptrs
-
- ) `thenC`
-
- -- RETURN
- returnFC (id, stableAmodeIdInfo id (CLbl closure_label PtrRep) lf_info)
- where
- con_tycon = dataConTyCon con
- lf_info = mkConLFInfo con
- closure_label = mkClosureLabel name
- name = idName id
-
- top_ccc = mkCCostCentreStack dontCareCCS -- because it's static data
-
- -- stuff needed by the assert pred only.
- any_litlit_args = any isLitLitArg args
- dynamic_con_or_args = dynamic_con || any (isDynamic) args
-
- dynamic_con = isDynName (dataConName con)
-
- isDynName nm =
- not (isLocallyDefinedName nm) &&
- isDynamicModule (nameModule nm)
-
- {-
- Do any of the arguments refer to something in a DLL?
- -}
- isDynamic (StgVarArg v) = isDynName (idName v)
- isDynamic (StgConArg c) =
- case c of
- DataCon dc -> isDynName (dataConName dc)
- Literal l -> isLitLitLit l -- all bets are off if it is.
- _ -> False
-
+cgTopRhsCon id con args
+ = do {
+ ; hmods <- getHomeModules
+#if mingw32_TARGET_OS
+ -- Windows DLLs have a problem with static cross-DLL refs.
+ ; ASSERT( not (isDllConApp hmods con args) ) return ()
+#endif
+ ; ASSERT( args `lengthIs` dataConRepArity con ) return ()
+ -- LAY IT OUT
+ ; amodes <- getArgAmodes args
+
+ ; let
+ name = idName id
+ lf_info = mkConLFInfo con
+ closure_label = mkClosureLabel hmods name
+ caffy = any stgArgHasCafRefs args
+ (closure_info, amodes_w_offsets) = layOutStaticConstr hmods con amodes
+ closure_rep = mkStaticClosureFields
+ closure_info
+ dontCareCCS -- Because it's static data
+ caffy -- Has CAF refs
+ payload
+
+ payload = map get_lit amodes_w_offsets
+ get_lit (CmmLit lit, _offset) = lit
+ get_lit other = pprPanic "CgCon.get_lit" (ppr other)
+ -- NB1: amodes_w_offsets is sorted into ptrs first, then non-ptrs
+ -- NB2: all the amodes should be Lits!
+
+ -- BUILD THE OBJECT
+ ; emitDataLits closure_label closure_rep
+
+ -- RETURN
+ ; returnFC (id, stableIdInfo id (mkLblExpr closure_label) lf_info) }
\end{code}
%************************************************************************
\subsection[code-for-constructors]{The code for constructors}
\begin{code}
-buildDynCon :: Id -- Name of the thing to which this constr will
- -- be bound
- -> CostCentreStack -- Where to grab cost centre from;
- -- current CCS if currentOrSubsumedCCS
- -> DataCon -- The data constructor
- -> [CAddrMode] -- Its args
- -> Bool -- True <=> all args (if any) are
- -- of "zero size" (i.e., VoidRep);
- -- The reason we don't just look at the
- -- args is that we may be in a "knot", and
- -- premature looking at the args will cause
- -- the compiler to black-hole!
- -> FCode CgIdInfo -- Return details about how to find it
+buildDynCon :: Id -- Name of the thing to which this constr will
+ -- be bound
+ -> CostCentreStack -- Where to grab cost centre from;
+ -- current CCS if currentOrSubsumedCCS
+ -> DataCon -- The data constructor
+ -> [(CgRep,CmmExpr)] -- Its args
+ -> FCode CgIdInfo -- Return details about how to find it
+
+-- We used to pass a boolean indicating whether all the
+-- args were of size zero, so we could use a static
+-- construtor; but I concluded that it just isn't worth it.
+-- Now I/O uses unboxed tuples there just aren't any constructors
+-- with all size-zero args.
+--
+-- The reason for having a separate argument, rather than looking at
+-- the addr modes of the args is that we may be in a "knot", and
+-- premature looking at the args will cause the compiler to black-hole!
\end{code}
First we deal with the case of zero-arity constructors. Now, they
at all.
\begin{code}
-buildDynCon binder cc con args all_zero_size_args@True
- = returnFC (stableAmodeIdInfo binder
- (CLbl (mkStaticClosureLabel (dataConName con)) PtrRep)
- (mkConLFInfo con))
+buildDynCon binder cc con []
+ = do hmods <- getHomeModules
+ returnFC (stableIdInfo binder
+ (mkLblExpr (mkClosureLabel hmods (dataConName con)))
+ (mkConLFInfo con))
\end{code}
+The following three paragraphs about @Char@-like and @Int@-like
+closures are obsolete, but I don't understand the details well enough
+to properly word them, sorry. I've changed the treatment of @Char@s to
+be analogous to @Int@s: only a subset is preallocated, because @Char@
+has now 31 bits. Only literals are handled here. -- Qrczak
+
Now for @Char@-like closures. We generate an assignment of the
address of the closure to a temporary. It would be possible simply to
generate no code, and record the addressing mode in the environment,
Because of this, we use can safely return an addressing mode.
\begin{code}
-buildDynCon binder cc con [arg_amode] all_zero_size_args@False
-
- | maybeCharLikeCon con
- = absC (CAssign temp_amode (CCharLike arg_amode)) `thenC`
- returnFC temp_id_info
-
- | maybeIntLikeCon con && in_range_int_lit arg_amode
- = returnFC (stableAmodeIdInfo binder (CIntLike arg_amode) (mkConLFInfo con))
- where
- (temp_amode, temp_id_info) = newTempAmodeAndIdInfo binder (mkConLFInfo con)
-
- in_range_int_lit (CLit (MachInt val _)) = val <= mAX_INTLIKE && val >= mIN_INTLIKE
- in_range_int_lit other_amode = False
-
- tycon = dataConTyCon con
+buildDynCon binder cc con [arg_amode]
+ | maybeIntLikeCon con
+ , (_, CmmLit (CmmInt val _)) <- arg_amode
+ , let val_int = (fromIntegral val) :: Int
+ , val_int <= mAX_INTLIKE && val_int >= mIN_INTLIKE
+ = do { let intlike_lbl = mkRtsDataLabel SLIT("stg_INTLIKE_closure")
+ offsetW = (val_int - mIN_INTLIKE) * (fixedHdrSize + 1)
+ -- INTLIKE closures consist of a header and one word payload
+ intlike_amode = CmmLit (cmmLabelOffW intlike_lbl offsetW)
+ ; returnFC (stableIdInfo binder intlike_amode (mkConLFInfo con)) }
+
+buildDynCon binder cc con [arg_amode]
+ | maybeCharLikeCon con
+ , (_, CmmLit (CmmInt val _)) <- arg_amode
+ , let val_int = (fromIntegral val) :: Int
+ , val_int <= mAX_CHARLIKE && val_int >= mIN_CHARLIKE
+ = do { let charlike_lbl = mkRtsDataLabel SLIT("stg_CHARLIKE_closure")
+ offsetW = (val_int - mIN_CHARLIKE) * (fixedHdrSize + 1)
+ -- CHARLIKE closures consist of a header and one word payload
+ charlike_amode = CmmLit (cmmLabelOffW charlike_lbl offsetW)
+ ; returnFC (stableIdInfo binder charlike_amode (mkConLFInfo con)) }
\end{code}
Now the general case.
\begin{code}
-buildDynCon binder ccs con args all_zero_size_args@False
- = allocDynClosure closure_info use_cc blame_cc amodes_w_offsets `thenFC` \ hp_off ->
- returnFC (heapIdInfo binder hp_off lf_info)
+buildDynCon binder ccs con args
+ = do {
+ ; hmods <- getHomeModules
+ ; let
+ (closure_info, amodes_w_offsets) = layOutDynConstr hmods con args
+
+ ; hp_off <- allocDynClosure closure_info use_cc blame_cc amodes_w_offsets
+ ; returnFC (heapIdInfo binder hp_off lf_info) }
where
- (closure_info, amodes_w_offsets)
- = layOutDynClosure (idName binder) getAmodeRep args lf_info
lf_info = mkConLFInfo con
use_cc -- cost-centre to stick in the object
- = if currentOrSubsumedCCS ccs
- then CReg CurCostCentre
- else mkCCostCentreStack ccs
+ | currentOrSubsumedCCS ccs = curCCS
+ | otherwise = CmmLit (mkCCostCentreStack ccs)
blame_cc = use_cc -- cost-centre on which to blame the alloc (same)
\end{code}
found a $con$.
\begin{code}
-bindConArgs
- :: DataCon -> [Id] -- Constructor and args
- -> Code
-
+bindConArgs :: DataCon -> [Id] -> Code
bindConArgs con args
- = ASSERT(not (isUnboxedTupleCon con))
- mapCs bind_arg args_w_offsets
- where
- bind_arg (arg, offset) = bindNewToNode arg offset mkLFArgument
- (_, args_w_offsets) = layOutDynCon con idPrimRep args
+ = do hmods <- getHomeModules
+ let
+ bind_arg (arg, offset) = bindNewToNode arg offset (mkLFArgument arg)
+ (_, args_w_offsets) = layOutDynConstr hmods con (addIdReps args)
+ --
+ ASSERT(not (isUnboxedTupleCon con)) return ()
+ mapCs bind_arg args_w_offsets
\end{code}
Unboxed tuples are handled slightly differently - the object is
\begin{code}
bindUnboxedTupleComponents
- :: [Id] -- args
- -> FCode ([MagicId], -- regs assigned
- [(VirtualSpOffset,Int)], -- tag slots
- Bool) -- any components on stack?
+ :: [Id] -- Args
+ -> FCode ([(Id,GlobalReg)], -- Regs assigned
+ WordOff, -- Number of pointer stack slots
+ WordOff, -- Number of non-pointer stack slots
+ VirtualSpOffset) -- Offset of return address slot
+ -- (= realSP on entry)
bindUnboxedTupleComponents args
- = -- Assign as many components as possible to registers
- let (arg_regs, leftovers) = assignRegs [] (map idPrimRep args)
- (reg_args, stk_args) = splitAt (length arg_regs) args
- in
-
- -- Allocate the rest on the stack (ToDo: separate out pointers)
- getVirtSp `thenFC` \ vsp ->
- getRealSp `thenFC` \ rsp ->
- let (top_sp, stk_offsets, tags) =
- mkTaggedVirtStkOffsets rsp idPrimRep stk_args
- in
-
- -- The stack pointer points to the last stack-allocated component
- setRealAndVirtualSp top_sp `thenC`
-
- -- need to explicitly free any empty slots we just jumped over
- (if vsp < rsp then freeStackSlots [vsp+1 .. rsp] else nopC) `thenC`
-
- bindArgsToRegs reg_args arg_regs `thenC`
- mapCs bindNewToStack stk_offsets `thenC`
- returnFC (arg_regs,tags, not (null stk_offsets))
+ = do {
+ vsp <- getVirtSp
+ ; rsp <- getRealSp
+
+ -- Assign as many components as possible to registers
+ ; let (reg_args, stk_args) = assignReturnRegs (addIdReps args)
+
+ -- Separate the rest of the args into pointers and non-pointers
+ (ptr_args, nptr_args) = separateByPtrFollowness stk_args
+
+ -- Allocate the rest on the stack
+ -- The real SP points to the return address, above which any
+ -- leftover unboxed-tuple components will be allocated
+ (ptr_sp, ptr_offsets) = mkVirtStkOffsets rsp ptr_args
+ (nptr_sp, nptr_offsets) = mkVirtStkOffsets ptr_sp nptr_args
+ ptrs = ptr_sp - rsp
+ nptrs = nptr_sp - ptr_sp
+
+ -- The stack pointer points to the last stack-allocated component
+ ; setRealAndVirtualSp nptr_sp
+
+ -- We have just allocated slots starting at real SP + 1, and set the new
+ -- virtual SP to the topmost allocated slot.
+ -- If the virtual SP started *below* the real SP, we've just jumped over
+ -- some slots that won't be in the free-list, so put them there
+ -- This commonly happens because we've freed the return-address slot
+ -- (trimming back the virtual SP), but the real SP still points to that slot
+ ; freeStackSlots [vsp+1,vsp+2 .. rsp]
+
+ ; bindArgsToRegs reg_args
+ ; bindArgsToStack ptr_offsets
+ ; bindArgsToStack nptr_offsets
+
+ ; returnFC (reg_args, ptrs, nptrs, rsp) }
\end{code}
%************************************************************************
%* *
-\subsubsection[CgRetConv-cgReturnDataCon]{Actually generate code for a constructor return}
+ Actually generate code for a constructor return
%* *
%************************************************************************
Note: it's the responsibility of the @cgReturnDataCon@ caller to be
sure the @amodes@ passed don't conflict with each other.
\begin{code}
-cgReturnDataCon :: DataCon -> [CAddrMode] -> Bool -> Code
-
-cgReturnDataCon con amodes all_zero_size_args
- = getEndOfBlockInfo `thenFC` \ (EndOfBlockInfo args_sp sequel) ->
-
- case sequel of
-
- CaseAlts _ (Just (alts, Just (maybe_deflt_binder, (_,deflt_lbl))))
- | not (dataConTag con `is_elem` map fst alts)
- ->
- -- Special case! We're returning a constructor to the default case
- -- of an enclosing case. For example:
- --
- -- case (case e of (a,b) -> C a b) of
- -- D x -> ...
- -- y -> ...<returning here!>...
- --
- -- In this case,
- -- if the default is a non-bind-default (ie does not use y),
- -- then we should simply jump to the default join point;
- --
- -- if the default is a bind-default (ie does use y), we
- -- should return the constructor in the heap,
- -- pointed to by Node.
-
- case maybe_deflt_binder of
- Just binder ->
- ASSERT(not (isUnboxedTupleCon con))
- buildDynCon binder currentCCS con amodes all_zero_size_args
- `thenFC` \ idinfo ->
- profCtrC SLIT("TICK_RET_NEW") [mkIntCLit (length amodes)] `thenC`
- idInfoToAmode PtrRep idinfo `thenFC` \ amode ->
- performReturn (move_to_reg amode node) jump_to_join_point
-
- Nothing ->
- performReturn AbsCNop {- No reg assts -} jump_to_join_point
- where
- is_elem = isIn "cgReturnDataCon"
- jump_to_join_point sequel = absC (CJump (CLbl deflt_lbl CodePtrRep))
- -- Ignore the sequel: we've already looked at it above
-
- other_sequel -- The usual case
-
- | isUnboxedTupleCon con ->
- -- Return unboxed tuple in registers
- let (ret_regs, leftovers) =
- assignRegs [] (map getAmodeRep amodes)
- in
- profCtrC SLIT("TICK_RET_UNBOXED_TUP")
- [mkIntCLit (length amodes)] `thenC`
-
- doTailCall amodes ret_regs
- mkUnboxedTupleReturnCode
- (length leftovers) {- fast args arity -}
- AbsCNop {-no pending assigments-}
- Nothing {-not a let-no-escape-}
- False {-node doesn't point-}
-
- | otherwise ->
- -- BUILD THE OBJECT IN THE HEAP
- -- The first "con" says that the name bound to this
- -- closure is "con", which is a bit of a fudge, but it only
- -- affects profiling
-
- -- This Id is also used to get a unique for a
- -- temporary variable, if the closure is a CHARLIKE.
- -- funilly enough, this makes the unique always come
- -- out as '54' :-)
- buildDynCon (mkDataConId con) currentCCS
- con amodes all_zero_size_args
- `thenFC` \ idinfo ->
- idInfoToAmode PtrRep idinfo `thenFC` \ amode ->
-
-
- -- RETURN
- profCtrC SLIT("TICK_RET_NEW") [mkIntCLit (length amodes)] `thenC`
- -- could use doTailCall here.
- performReturn (move_to_reg amode node)
- (mkStaticAlgReturnCode con)
-
+cgReturnDataCon :: DataCon -> [(CgRep, CmmExpr)] -> Code
+
+cgReturnDataCon con amodes
+ = ASSERT( amodes `lengthIs` dataConRepArity con )
+ do { EndOfBlockInfo _ sequel <- getEndOfBlockInfo
+ ; case sequel of
+ CaseAlts _ (Just (alts, deflt_lbl)) bndr _
+ -> -- Ho! We know the constructor so we can
+ -- go straight to the right alternative
+ case assocMaybe alts (dataConTagZ con) of {
+ Just join_lbl -> build_it_then (jump_to join_lbl);
+ Nothing
+ -- Special case! We're returning a constructor to the default case
+ -- of an enclosing case. For example:
+ --
+ -- case (case e of (a,b) -> C a b) of
+ -- D x -> ...
+ -- y -> ...<returning here!>...
+ --
+ -- In this case,
+ -- if the default is a non-bind-default (ie does not use y),
+ -- then we should simply jump to the default join point;
+
+ | isDeadBinder bndr -> performReturn (jump_to deflt_lbl)
+ | otherwise -> build_it_then (jump_to deflt_lbl) }
+
+ other_sequel -- The usual case
+ | isUnboxedTupleCon con -> returnUnboxedTuple amodes
+ | otherwise -> build_it_then (emitKnownConReturnCode con)
+ }
where
- con_name = dataConName con
+ jump_to lbl = stmtC (CmmJump (CmmLit lbl) [])
+ build_it_then return_code
+ = do { -- BUILD THE OBJECT IN THE HEAP
+ -- The first "con" says that the name bound to this
+ -- closure is "con", which is a bit of a fudge, but it only
+ -- affects profiling
+
+ -- This Id is also used to get a unique for a
+ -- temporary variable, if the closure is a CHARLIKE.
+ -- funnily enough, this makes the unique always come
+ -- out as '54' :-)
+ tickyReturnNewCon (length amodes)
+ ; idinfo <- buildDynCon (dataConWorkId con) currentCCS con amodes
+ ; amode <- idInfoToAmode idinfo
+ ; checkedAbsC (CmmAssign nodeReg amode)
+ ; performReturn return_code }
+\end{code}
+
+
+%************************************************************************
+%* *
+ Generating static stuff for algebraic data types
+%* *
+%************************************************************************
+
+ [These comments are rather out of date]
+
+\begin{tabular}{lll}
+Info tbls & Macro & Kind of constructor \\
+\hline
+info & @CONST_INFO_TABLE@& Zero arity (no info -- compiler uses static closure)\\
+info & @CHARLIKE_INFO_TABLE@& Charlike (no info -- compiler indexes fixed array)\\
+info & @INTLIKE_INFO_TABLE@& Intlike; the one macro generates both info tbls\\
+info & @SPEC_INFO_TABLE@& SPECish, and bigger than or equal to @MIN_UPD_SIZE@\\
+info & @GEN_INFO_TABLE@& GENish (hence bigger than or equal to @MIN_UPD_SIZE@)\\
+\end{tabular}
+
+Possible info tables for constructor con:
- move_to_reg :: CAddrMode -> MagicId -> AbstractC
- move_to_reg src_amode dest_reg = CAssign (CReg dest_reg) src_amode
+\begin{description}
+\item[@_con_info@:]
+Used for dynamically let(rec)-bound occurrences of
+the constructor, and for updates. For constructors
+which are int-like, char-like or nullary, when GC occurs,
+the closure tries to get rid of itself.
+
+\item[@_static_info@:]
+Static occurrences of the constructor
+macro: @STATIC_INFO_TABLE@.
+\end{description}
+
+For zero-arity constructors, \tr{con}, we NO LONGER generate a static closure;
+it's place is taken by the top level defn of the constructor.
+
+For charlike and intlike closures there is a fixed array of static
+closures predeclared.
+
+\begin{code}
+cgTyCon :: TyCon -> FCode [Cmm] -- each constructor gets a separate Cmm
+cgTyCon tycon
+ = do { constrs <- mapM (getCmm . cgDataCon) (tyConDataCons tycon)
+
+ -- Generate a table of static closures for an enumeration type
+ -- Put the table after the data constructor decls, because the
+ -- datatype closure table (for enumeration types)
+ -- to (say) PrelBase_$wTrue_closure, which is defined in code_stuff
+ ; extra <-
+ if isEnumerationTyCon tycon then do
+ tbl <- getCmm (emitRODataLits (mkLocalClosureTableLabel
+ (tyConName tycon))
+ [ CmmLabel (mkLocalClosureLabel (dataConName con))
+ | con <- tyConDataCons tycon])
+ return [tbl]
+ else
+ return []
+
+ ; return (extra ++ constrs)
+ }
+\end{code}
+
+Generate the entry code, info tables, and (for niladic constructor) the
+static closure, for a constructor.
+
+\begin{code}
+cgDataCon :: DataCon -> Code
+cgDataCon data_con
+ = do { -- Don't need any dynamic closure code for zero-arity constructors
+ hmods <- getHomeModules
+
+ ; let
+ -- To allow the debuggers, interpreters, etc to cope with
+ -- static data structures (ie those built at compile
+ -- time), we take care that info-table contains the
+ -- information we need.
+ (static_cl_info, _) =
+ layOutStaticConstr hmods data_con arg_reps
+
+ (dyn_cl_info, arg_things) =
+ layOutDynConstr hmods data_con arg_reps
+
+ emit_info cl_info ticky_code
+ = do { code_blks <- getCgStmts the_code
+ ; emitClosureCodeAndInfoTable cl_info [] code_blks }
+ where
+ the_code = do { ticky_code
+ ; ldvEnter (CmmReg nodeReg)
+ ; body_code }
+
+ arg_reps :: [(CgRep, Type)]
+ arg_reps = [(typeCgRep ty, ty) | ty <- dataConRepArgTys data_con]
+
+ body_code = do {
+ -- NB: We don't set CC when entering data (WDP 94/06)
+ tickyReturnOldCon (length arg_things)
+ ; performReturn (emitKnownConReturnCode data_con) }
+ -- noStmts: Ptr to thing already in Node
+
+ ; whenC (not (isNullaryRepDataCon data_con))
+ (emit_info dyn_cl_info tickyEnterDynCon)
+
+ -- Dynamic-Closure first, to reduce forward references
+ ; emit_info static_cl_info tickyEnterStaticCon }
+
+ where
\end{code}