)
import Constants ( mIN_UPD_SIZE )
-import CallConv ( CallConv, callConvAttribute, cCallConv )
-import CLabel ( externallyVisibleCLabel, mkErrorStdEntryLabel,
+import ForeignCall ( CCallSpec(..), CCallTarget(..), playSafe, ccallConvAttribute )
+import CLabel ( externallyVisibleCLabel,
needsCDecl, pprCLabel,
mkReturnInfoLabel, mkReturnPtLabel, mkClosureTblLabel,
- mkStaticClosureLabel,
+ mkClosureLabel, mkErrorStdEntryLabel,
CLabel, CLabelType(..), labelType, labelDynamic
)
-import CmdLineOpts ( opt_SccProfilingOn, opt_EmitCExternDecls, opt_GranMacros )
+import CmdLineOpts ( opt_SccProfilingOn, opt_GranMacros )
import CostCentre ( pprCostCentreDecl, pprCostCentreStackDecl )
import Costs ( costs, addrModeCosts, CostRes(..), Side(..) )
-import CStrings ( stringToC )
+import CStrings ( pprStringInCStyle, pprCLabelString )
import FiniteMap ( addToFM, emptyFM, lookupFM, FiniteMap )
-import Const ( Literal(..) )
+import Literal ( Literal(..) )
import TyCon ( tyConDataCons )
import Name ( NamedThing(..) )
-import DataCon ( DataCon{-instance NamedThing-} )
+import DataCon ( dataConWrapId )
import Maybes ( maybeToBool, catMaybes )
-import PrimOp ( primOpNeedsWrapper, pprPrimOp, PrimOp(..) )
-import PrimRep ( isFloatingRep, PrimRep(..), getPrimRepSize, showPrimRep )
+import PrimOp ( primOpNeedsWrapper )
+import ForeignCall ( ForeignCall(..) )
+import PrimRep ( isFloatingRep, PrimRep(..), getPrimRepSize )
import SMRep ( pprSMRep )
import Unique ( pprUnique, Unique{-instance NamedThing-} )
import UniqSet ( emptyUniqSet, elementOfUniqSet,
addOneToUniqSet, UniqSet
)
-import StgSyn ( SRT(..) )
-import BitSet ( intBS )
+import StgSyn ( StgOp(..) )
+import BitSet ( BitSet, intBS )
import Outputable
+import GlaExts
import Util ( nOfThem )
-import Addr ( Addr )
import ST
-import MutableArray
infixr 9 `thenTE`
\end{code}
mk_vector x = hcat [ptext SLIT("RET_VEC"), char '(', pprAmode am, comma,
x, rparen ]
-pprAbsC (CSplitMarker) _ = ptext SLIT("/* SPLIT */")
+pprAbsC (CSplitMarker) _ = ptext SLIT("__STG_SPLIT_MARKER")
-- we optimise various degenerate cases of CSwitches.
do_if_stmt discrim tag alt_code dc c
-- What problem is the re-ordering trying to solve ?
-pprAbsC (CSwitch discrim [(tag1@(MachInt i1 _), alt_code1),
- (tag2@(MachInt i2 _), alt_code2)] deflt) c
+pprAbsC (CSwitch discrim [(tag1@(MachInt i1), alt_code1),
+ (tag2@(MachInt i2), alt_code2)] deflt) c
| empty_deflt && ((i1 == 0 && i2 == 1) || (i1 == 1 && i2 == 0))
= if (i1 == 0) then
do_if_stmt discrim tag1 alt_code1 alt_code2 c
-- Costs for addressing header of switch and cond. branching -- HWL
switch_head_cost = addrModeCosts discrim Rhs + (Cost (0, 1, 0, 0, 0))
-pprAbsC stmt@(COpStmt results op@(CCallOp _ _ _ _) args vol_regs) _
- = pprCCall op args results vol_regs
+pprAbsC stmt@(COpStmt results (StgFCallOp fcall uniq) args vol_regs) _
+ = pprFCall fcall uniq args results vol_regs
-pprAbsC stmt@(COpStmt results op args vol_regs) _
+pprAbsC stmt@(COpStmt results (StgPrimOp op) args vol_regs) _
= let
non_void_args = grab_non_void_amodes args
non_void_results = grab_non_void_amodes results
the_op
where
ppr_op_call results args
- = hcat [ pprPrimOp op, lparen,
+ = hcat [ ppr op, lparen,
hcat (punctuate comma (map ppr_op_result results)),
if null results || null args then empty else comma,
hcat (punctuate comma (map pprAmode args)),
}
pprAbsC stmt@(CBitmap lbl mask) c
- = vcat [
- hcat [ ptext SLIT("BITMAP"), lparen,
- pprCLabel lbl, comma,
- int (length mask),
- rparen ],
- hcat (punctuate comma (map (int.intBS) mask)),
- ptext SLIT("}};")
- ]
+ = pp_bitmap_switch mask semi $
+ hcat [ ptext SLIT("BITMAP"), lparen,
+ pprCLabel lbl, comma,
+ int (length mask), comma,
+ pp_bitmap mask, rparen ]
pprAbsC (CSimultaneous abs_c) c
= hcat [ptext SLIT("{{"), pprAbsC abs_c c, ptext SLIT("}}")]
pprAbsC (CCallProfCCMacro op as) _
= hcat [ptext op, lparen,
hcat (punctuate comma (map ppr_amode as)),pp_paren_semi]
-pprAbsC stmt@(CCallTypedef op@(CCallOp op_str is_asm may_gc cconv) results args) _
- = hsep [ ptext SLIT("typedef")
+pprAbsC stmt@(CCallTypedef is_tdef (CCallSpec op_str cconv _) uniq results args) _
+ = hsep [ ptext (if is_tdef then SLIT("typedef") else SLIT("extern"))
, ccall_res_ty
, fun_nm
, parens (hsep (punctuate comma ccall_decl_ty_args))
] <> semi
where
- fun_nm = parens (text (callConvAttribute cconv) <+> char '*' <> ccall_fun_ty)
+ {-
+ In the non-casm case, to ensure that we're entering the given external
+ entry point using the correct calling convention, we have to do the following:
+
+ - When entering via a function pointer (the `dynamic' case) using the specified
+ calling convention, we emit a typedefn declaration attributed with the
+ calling convention to use together with the result and parameter types we're
+ assuming. Coerce the function pointer to this type and go.
+
+ - to enter the function at a given code label, we emit an extern declaration
+ for the label here, stating the calling convention together with result and
+ argument types we're assuming.
+
+ The C compiler will hopefully use this extern declaration to good effect,
+ reporting any discrepancies between our extern decl and any other that
+ may be in scope.
+
+ Re: calling convention, notice that gcc (2.8.1 and egcs-1.0.2) will for
+ the external function `foo' use the calling convention of the first `foo'
+ prototype it encounters (nor does it complain about conflicting attribute
+ declarations). The consequence of this is that you cannot override the
+ calling convention of `foo' using an extern declaration (you'd have to use
+ a typedef), but why you would want to do such a thing in the first place
+ is totally beyond me.
+
+ ToDo: petition the gcc folks to add code to warn about conflicting attribute
+ declarations.
+
+ -}
+
+ fun_nm
+ | is_tdef = parens (text (ccallConvAttribute cconv) <+> char '*' <> ccall_fun_ty)
+ | otherwise = text (ccallConvAttribute cconv) <+> ccall_fun_ty
ccall_fun_ty =
case op_str of
- Right u -> ptext SLIT("_ccall_fun_ty") <> ppr u
+ DynamicTarget -> ptext SLIT("_ccall_fun_ty") <> ppr uniq
+ StaticTarget x -> pprCLabelString x
ccall_res_ty =
case non_void_results of
[] -> ptext SLIT("void")
- [amode] -> text (showPrimRep (getAmodeRep amode))
+ [amode] -> ppr (getAmodeRep amode)
_ -> panic "pprAbsC{CCallTypedef}: ccall_res_ty"
- ccall_decl_ty_args = tail ccall_arg_tys
- ccall_arg_tys = map (text.showPrimRep.getAmodeRep) non_void_args
+ ccall_decl_ty_args
+ | is_tdef = tail ccall_arg_tys
+ | otherwise = ccall_arg_tys
+
+ ccall_arg_tys = map (ppr . getAmodeRep) non_void_args
-- the first argument will be the "I/O world" token (a VoidRep)
-- all others should be non-void
non_void_args =
- let nvas = tail args
+ let nvas = init args
in ASSERT (all non_void nvas) nvas
-- there will usually be two results: a (void) state which we
else
case (pprTempAndExternDecls abs_C) of { (pp_temps, pp_exts) ->
vcat [
+ empty,
+ pp_exts,
hcat [text (if (externallyVisibleCLabel lbl)
then "FN_(" -- abbreviations to save on output
else "IFN_("),
pprCLabel lbl, text ") {"],
- pp_exts, pp_temps,
+ pp_temps,
nest 8 (ptext SLIT("FB_")),
nest 8 (pprAbsC abs_C (costs abs_C)),
nest 8 (ptext SLIT("FE_")),
- char '}' ]
+ char '}',
+ char ' ' ]
}
where
rep = getAmodeRep item
- padding_wds =
- if not (closureUpdReqd cl_info) then
- []
- else
- case max 0 (mIN_UPD_SIZE - length amodes) of { still_needed ->
- nOfThem still_needed (mkIntCLit 0) } -- a bunch of 0s
+ upd_reqd = closureUpdReqd cl_info
+
+ padding_wds
+ | not upd_reqd = []
+ | otherwise = case max 0 (mIN_UPD_SIZE - length amodes) of { still_needed ->
+ nOfThem still_needed (mkIntCLit 0) } -- a bunch of 0s
+ -- always have a static link field, it's used to save the closure's
+ -- info pointer when we're reverting CAFs (see comment in Storage.c)
static_link_field
- | staticClosureNeedsLink cl_info = [mkIntCLit 0]
- | otherwise = []
+ | upd_reqd || staticClosureNeedsLink cl_info = [mkIntCLit 0]
+ | otherwise = []
pprAbsC stmt@(CClosureInfoAndCode cl_info slow maybe_fast cl_descr) _
= vcat [
is_constr = maybeToBool maybe_tag
(Just tag) = maybe_tag
- needs_srt = infoTblNeedsSRT cl_info
- srt = getSRTInfo cl_info
+ srt = closureSRT cl_info
+ needs_srt = case srt of
+ NoC_SRT -> False
+ other -> True
+
size = closureNonHdrSize cl_info
type_str = pprSMRep (closureSMRep cl_info)
- pp_descr = hcat [char '"', text (stringToC cl_descr), char '"']
- pp_type = hcat [char '"', text (stringToC (closureTypeDescr cl_info)), char '"']
+ pp_descr = pprStringInCStyle cl_descr
+ pp_type = pprStringInCStyle (closureTypeDescr cl_info)
pprAbsC stmt@(CClosureTbl tycon) _
= vcat (
ptext SLIT("CLOSURE_TBL") <>
lparen <> pprCLabel (mkClosureTblLabel tycon) <> rparen :
punctuate comma (
- map (pp_closure_lbl . mkStaticClosureLabel . getName) (tyConDataCons tycon)
+ map (pp_closure_lbl . mkClosureLabel . getName . dataConWrapId) (tyConDataCons tycon)
)
) $$ ptext SLIT("};")
pprCLabel entry_lbl, comma,
pp_liveness liveness, comma, -- bitmap
pp_srt_info srt, -- SRT
- ptext type_str, comma, -- closure type
+ closure_type, comma, -- closure type
ppLocalness info_lbl, comma, -- info table storage class
ppLocalnessMacro True{-include dyn-} entry_lbl, comma, -- entry pt storage class
int 0, comma,
pp_code
]
where
- info_lbl = mkReturnInfoLabel uniq
- entry_lbl = mkReturnPtLabel uniq
+ info_lbl = mkReturnInfoLabel uniq
+ entry_lbl = mkReturnPtLabel uniq
- pp_code = let stuff = CCodeBlock entry_lbl code in
- pprAbsC stuff (costs stuff)
+ pp_code = let stuff = CCodeBlock entry_lbl code in
+ pprAbsC stuff (costs stuff)
- type_str = case liveness of
- LvSmall _ -> SLIT("RET_SMALL")
- LvLarge _ -> SLIT("RET_BIG")
+ closure_type = pp_liveness_switch liveness
+ (ptext SLIT("RET_SMALL"))
+ (ptext SLIT("RET_BIG"))
pprAbsC stmt@(CRetVector lbl amodes srt liveness) _
= case (pprTempAndExternDecls stmt) of { (_, pp_exts) ->
pprCLabel lbl, comma,
pp_liveness liveness, comma, -- bitmap liveness mask
pp_srt_info srt, -- SRT
- ptext type_str, comma,
+ closure_type, comma,
ppLocalness lbl, comma
],
nest 2 (sep (punctuate comma (map ppr_item amodes))),
ppr_item item = (<>) (text "(F_) ") (ppr_amode item)
size = length amodes
- type_str = case liveness of
- LvSmall _ -> SLIT("RET_VEC_SMALL")
- LvLarge _ -> SLIT("RET_VEC_BIG")
+ closure_type = pp_liveness_switch liveness
+ (ptext SLIT("RET_VEC_SMALL"))
+ (ptext SLIT("RET_VEC_BIG"))
+
+pprAbsC stmt@(CModuleInitBlock lbl code) _
+ = vcat [
+ ptext SLIT("START_MOD_INIT") <> parens (pprCLabel lbl),
+ case (pprTempAndExternDecls stmt) of { (_, pp_exts) -> pp_exts },
+ pprAbsC code (costs code),
+ hcat [ptext SLIT("END_MOD_INIT"), lparen, rparen]
+ ]
pprAbsC (CCostCentreDecl is_local cc) _ = pprCostCentreDecl is_local cc
pprAbsC (CCostCentreStackDecl ccs) _ = pprCostCentreStackDecl ccs
where
is_visible = externallyVisibleCLabel clabel
label_type = labelType clabel
- is_dynamic = labelDynamic clabel
visiblity_prefix
| is_visible = char 'E'
| otherwise = char 'I'
dyn_prefix
- | not include_dyn_prefix = empty
- | is_dynamic = char 'D'
- | otherwise = empty
+ | include_dyn_prefix && labelDynamic clabel = char 'D'
+ | otherwise = empty
\end{code}
(($$) ((<>) (ptext SLIT("CALLER_SAVE_")) pp_reg) more_saves,
($$) ((<>) (ptext SLIT("CALLER_RESTORE_")) pp_reg) more_restores)
--- pp_basic_{saves,restores}: The BaseReg, SpA, SuA, SpB, SuB, Hp and
+-- pp_basic_{saves,restores}: The BaseReg, Sp, Su, Hp and
-- HpLim (see StgRegs.lh) may need to be saved/restored around CCalls,
-- depending on the platform. (The "volatile regs" stuff handles all
-- other registers.) Just be *sure* BaseReg is OK before trying to do
-- anything else. The correct sequence of saves&restores are
-- encoded by the CALLER_*_SYSTEM macros.
-pp_basic_saves
- = vcat
- [ ptext SLIT("CALLER_SAVE_Base")
- , ptext SLIT("CALLER_SAVE_SYSTEM")
- ]
-
+pp_basic_saves = ptext SLIT("CALLER_SAVE_SYSTEM")
pp_basic_restores = ptext SLIT("CALLER_RESTORE_SYSTEM")
\end{code}
\begin{code}
-has_srt (_, NoSRT) = False
-has_srt _ = True
-
-pp_srt_info srt =
- case srt of
- (lbl, NoSRT) ->
- hcat [ int 0, comma,
- int 0, comma,
- int 0, comma ]
- (lbl, SRT off len) ->
- hcat [ pprCLabel lbl, comma,
- int off, comma,
- int len, comma ]
+pp_srt_info NoC_SRT = hcat [ int 0, comma,
+ int 0, comma,
+ int 0, comma ]
+pp_srt_info (C_SRT lbl off len) = hcat [ pprCLabel lbl, comma,
+ int off, comma,
+ int len, comma ]
\end{code}
\begin{code}
= case tag of
-- This special case happens when testing the result of a comparison.
-- We can just avoid some redundant clutter in the output.
- MachInt n _ | n==0 -> ppr_if_stmt (pprAmode discrim)
+ MachInt n | n==0 -> ppr_if_stmt (pprAmode discrim)
deflt alt_code
(addrModeCosts discrim Rhs) c
- other -> let
+ other -> let
cond = hcat [ pprAmode discrim
, ptext SLIT(" == ")
, tcast
-- in C (when minInt is a number not a constant
-- expression which evaluates to it.)
--
- tcast =
- case other of
- MachInt _ signed | signed -> ptext SLIT("(I_)")
- _ -> empty
+ tcast = case other of
+ MachInt _ -> ptext SLIT("(I_)")
+ _ -> empty
in
ppr_if_stmt cond
alt_code deflt
that the runtime check that PerformGC is being used sensibly will work.
\begin{code}
-pprCCall op@(CCallOp op_str is_asm may_gc cconv) args results vol_regs
+pprFCall call@(CCall (CCallSpec target cconv safety)) uniq args results vol_regs
= vcat [
char '{',
declare_local_vars, -- local var for *result*
vcat local_arg_decls,
pp_save_context,
- declare_fun_extern, -- declare expected function type.
- process_casm local_vars pp_non_void_args casm_str,
+ process_casm local_vars pp_non_void_args call_str,
pp_restore_context,
assign_results,
char '}'
where
(pp_saves, pp_restores) = ppr_vol_regs vol_regs
(pp_save_context, pp_restore_context)
- | may_gc = ( text "do { SaveThreadState();"
- , text "LoadThreadState();} while(0);"
- )
+ | playSafe safety = ( text "{ I_ id; SUSPEND_THREAD(id);"
+ , text "RESUME_THREAD(id);}"
+ )
| otherwise = ( pp_basic_saves $$ pp_saves,
pp_basic_restores $$ pp_restores)
- non_void_args =
- let nvas = tail args
- in ASSERT (all non_void nvas) nvas
- -- the first argument will be the "I/O world" token (a VoidRep)
+ non_void_args =
+ let nvas = init args
+ in ASSERT2 ( all non_void nvas, ppr call <+> hsep (map pprAmode args) )
+ nvas
+ -- the last argument will be the "I/O world" token (a VoidRep)
-- all others should be non-void
non_void_results =
(local_arg_decls, pp_non_void_args)
= unzip [ ppr_casm_arg a i | (a,i) <- non_void_args `zip` [1..] ]
-
- {-
- In the non-casm case, to ensure that we're entering the given external
- entry point using the correct calling convention, we have to do the following:
-
- - When entering via a function pointer (the `dynamic' case) using the specified
- calling convention, we emit a typedefn declaration attributed with the
- calling convention to use together with the result and parameter types we're
- assuming. Coerce the function pointer to this type and go.
-
- - to enter the function at a given code label, we emit an extern declaration
- for the label here, stating the calling convention together with result and
- argument types we're assuming.
-
- The C compiler will hopefully use this extern declaration to good effect,
- reporting any discrepancies between our extern decl and any other that
- may be in scope.
-
- Re: calling convention, notice that gcc (2.8.1 and egcs-1.0.2) will for
- the external function `foo' use the calling convention of the first `foo'
- prototype it encounters (nor does it complain about conflicting attribute
- declarations). The consequence of this is that you cannot override the
- calling convention of `foo' using an extern declaration (you'd have to use
- a typedef), but why you would want to do such a thing in the first place
- is totally beyond me.
-
- ToDo: petition the gcc folks to add code to warn about conflicting attribute
- declarations.
-
- -}
- declare_fun_extern
- | is_dynamic || is_asm || not opt_EmitCExternDecls = empty
- | otherwise =
- hsep [ typedef_or_extern
- , ccall_res_ty
- , fun_nm
- , parens (hsep (punctuate comma ccall_decl_ty_args))
- ] <> semi
- where
- typedef_or_extern
- | is_dynamic = ptext SLIT("typedef")
- | otherwise = ptext SLIT("extern")
-
- fun_nm
- | is_dynamic = parens (text (callConvAttribute cconv) <+> char '*' <> ccall_fun_ty)
- | otherwise = text (callConvAttribute cconv) <+> ptext asm_str
-
- -- leave out function pointer
- ccall_decl_ty_args
- | is_dynamic = tail ccall_arg_tys
- | otherwise = ccall_arg_tys
-
- ccall_arg_tys = map (text.showPrimRep.getAmodeRep) non_void_args
-
- ccall_res_ty =
- case non_void_results of
- [] -> ptext SLIT("void")
- [amode] -> text (showPrimRep (getAmodeRep amode))
- _ -> panic "pprCCall: ccall_res_ty"
-
- ccall_fun_ty =
- ptext SLIT("_ccall_fun_ty") <>
- case op_str of
- Right u -> ppr u
- _ -> empty
-
(declare_local_vars, local_vars, assign_results)
= ppr_casm_results non_void_results
- (Left asm_str) = op_str
- is_dynamic =
- case op_str of
- Left _ -> False
- _ -> True
+ call_str = case target of
+ CasmTarget str -> _UNPK_ str
+ StaticTarget fn -> mk_ccall_str (pprCLabelString fn) ccall_args
+ DynamicTarget -> mk_ccall_str dyn_fun (tail ccall_args)
- casm_str = if is_asm then _UNPK_ asm_str else ccall_str
+ ccall_args = zipWith (\ _ i -> char '%' <> int i) non_void_args [0..]
+ dyn_fun = parens (parens (ptext SLIT("_ccall_fun_ty") <> ppr uniq) <> text "%0")
+
-- Remainder only used for ccall
-
- fun_name
- | is_dynamic = parens (parens (ccall_fun_ty) <> text "%0")
- | otherwise = ptext asm_str
-
- ccall_str = showSDoc
+ mk_ccall_str fun_name ccall_fun_args = showSDoc
(hcat [
if null non_void_results
then empty
hcat (punctuate comma ccall_fun_args),
text "));"
])
-
- ccall_fun_args
- | is_dynamic = tail ccall_args
- | otherwise = ccall_args
-
- ccall_args = zipWith (\ _ i -> char '%' <> int i) non_void_args [0..]
-
\end{code}
If the argument is a heap object, we need to reach inside and pull out
process [] _ "" = empty
process (_:_) _ "" = error ("process_casm: non-void result not assigned while processing _casm_ \"" ++
string ++
- "\"\n(Try changing result type to PrimIO ()\n")
+ "\"\n(Try changing result type to IO ()\n")
process ress args ('%':cs)
= case cs of
= ppr_amode amode
\end{code}
+When we have an indirection through a CIndex, we have to be careful to
+get the type casts right.
+
+this amode:
+
+ CVal (CIndex kind1 base offset) kind2
+
+means (in C speak):
+
+ *(kind2 *)((kind1 *)base + offset)
+
+That is, the indexing is done in units of kind1, but the resulting
+amode has kind2.
+
+\begin{code}
+ppr_amode (CVal reg_rel@(CIndex _ _ _) kind)
+ = case (pprRegRelative False{-no sign wanted-} reg_rel) of
+ (pp_reg, Nothing) -> panic "ppr_amode: CIndex"
+ (pp_reg, Just offset) ->
+ hcat [ char '*', parens (pprPrimKind kind <> char '*'),
+ parens (pp_reg <> char '+' <> offset) ]
+\end{code}
+
Now the rest of the cases for ``workhorse'' @ppr_amode@:
\begin{code}
ppr_amode (CLit lit) = pprBasicLit lit
-ppr_amode (CLitLit str _) = ptext str
-
ppr_amode (CJoinPoint _)
= panic "ppr_amode: CJoinPoint"
ppr_amode (CMacroExpr pk macro as)
- = parens (pprPrimKind pk) <>
- parens (ptext (cExprMacroText macro) <>
+ = parens (ptext (cExprMacroText macro) <>
parens (hcat (punctuate comma (map pprAmode as))))
\end{code}
cExprMacroText ARG_TAG = SLIT("ARG_TAG")
cExprMacroText GET_TAG = SLIT("GET_TAG")
cExprMacroText UPD_FRAME_UPDATEE = SLIT("UPD_FRAME_UPDATEE")
+cExprMacroText CCS_HDR = SLIT("CCS_HDR")
cStmtMacroText ARGS_CHK = SLIT("ARGS_CHK")
cStmtMacroText ARGS_CHK_LOAD_NODE = SLIT("ARGS_CHK_LOAD_NODE")
cStmtMacroText PUSH_SEQ_FRAME = SLIT("PUSH_SEQ_FRAME")
cStmtMacroText UPDATE_SU_FROM_UPD_FRAME = SLIT("UPDATE_SU_FROM_UPD_FRAME")
cStmtMacroText SET_TAG = SLIT("SET_TAG")
+cStmtMacroText REGISTER_FOREIGN_EXPORT = SLIT("REGISTER_FOREIGN_EXPORT")
+cStmtMacroText REGISTER_IMPORT = SLIT("REGISTER_IMPORT")
+cStmtMacroText REGISTER_DIMPORT = SLIT("REGISTER_DIMPORT")
cStmtMacroText GRAN_FETCH = SLIT("GRAN_FETCH")
cStmtMacroText GRAN_RESCHEDULE = SLIT("GRAN_RESCHEDULE")
cStmtMacroText GRAN_FETCH_AND_RESCHEDULE= SLIT("GRAN_FETCH_AND_RESCHEDULE")
%************************************************************************
\begin{code}
+pp_bitmap_switch :: [BitSet] -> SDoc -> SDoc -> SDoc
+pp_bitmap_switch ([ ]) small large = small
+pp_bitmap_switch ([_ ]) small large = small
+pp_bitmap_switch ([_,_]) small large = hcat
+ [ptext SLIT("BITMAP_SWITCH64"), lparen, small, comma, large, rparen]
+pp_bitmap_switch (_ ) small large = large
+
+pp_liveness_switch :: Liveness -> SDoc -> SDoc -> SDoc
+pp_liveness_switch (Liveness lbl mask) = pp_bitmap_switch mask
+
+pp_bitset :: BitSet -> SDoc
+pp_bitset s
+ | i < -1 = int (i + 1) <> text "-1"
+ | otherwise = int i
+ where i = intBS s
+
+pp_bitmap :: [BitSet] -> SDoc
+pp_bitmap [] = int 0
+pp_bitmap ss = hcat (punctuate delayed_comma (bundle ss)) where
+ delayed_comma = hcat [space, ptext SLIT("COMMA"), space]
+ bundle [] = []
+ bundle [s] = [hcat bitmap32]
+ where bitmap32 = [ptext SLIT("BITMAP32"), lparen,
+ pp_bitset s, rparen]
+ bundle (s1:s2:ss) = hcat bitmap64 : bundle ss
+ where bitmap64 = [ptext SLIT("BITMAP64"), lparen,
+ pp_bitset s1, comma, pp_bitset s2, rparen]
+
pp_liveness :: Liveness -> SDoc
-pp_liveness lv =
- case lv of
- LvSmall mask -> int (intBS mask)
- LvLarge lbl -> char '&' <> pprCLabel lbl
+pp_liveness (Liveness lbl mask)
+ = pp_bitmap_switch mask (pp_bitmap mask) (char '&' <> pprCLabel lbl)
\end{code}
%************************************************************************
pprMagicId (VanillaReg pk n)
= hcat [ pprVanillaReg n, char '.',
pprUnionTag pk ]
-pprMagicId (FloatReg n) = (<>) (ptext SLIT("F")) (int IBOX(n))
-pprMagicId (DoubleReg n) = (<>) (ptext SLIT("D")) (int IBOX(n))
-pprMagicId (LongReg _ n) = (<>) (ptext SLIT("L")) (int IBOX(n))
+pprMagicId (FloatReg n) = ptext SLIT("F") <> int (I# n)
+pprMagicId (DoubleReg n) = ptext SLIT("D") <> int (I# n)
+pprMagicId (LongReg _ n) = ptext SLIT("L") <> int (I# n)
pprMagicId Sp = ptext SLIT("Sp")
pprMagicId Su = ptext SLIT("Su")
pprMagicId SpLim = ptext SLIT("SpLim")
pprMagicId CurCostCentre = ptext SLIT("CCCS")
pprMagicId VoidReg = panic "pprMagicId:VoidReg!"
-pprVanillaReg :: FAST_INT -> SDoc
-pprVanillaReg n = (<>) (char 'R') (int IBOX(n))
+pprVanillaReg :: Int# -> SDoc
+pprVanillaReg n = char 'R' <> int (I# n)
pprUnionTag :: PrimRep -> SDoc
pprUnionTag CostCentreRep = panic "pprUnionTag:CostCentre?"
pprUnionTag CharRep = char 'c'
+pprUnionTag Int8Rep = ptext SLIT("i8")
pprUnionTag IntRep = char 'i'
pprUnionTag WordRep = char 'w'
+pprUnionTag Int32Rep = char 'i'
+pprUnionTag Word32Rep = char 'w'
pprUnionTag AddrRep = char 'a'
pprUnionTag FloatRep = char 'f'
pprUnionTag DoubleRep = panic "pprUnionTag:Double?"
-pprUnionTag StablePtrRep = char 'i'
+pprUnionTag StablePtrRep = char 'p'
pprUnionTag StableNameRep = char 'p'
pprUnionTag WeakPtrRep = char 'p'
pprUnionTag ForeignObjRep = char 'p'
+pprUnionTag PrimPtrRep = char 'p'
pprUnionTag ThreadIdRep = char 't'
pprUnionTag ArrayRep = char 'p'
pprUnionTag ByteArrayRep = char 'b'
+pprUnionTag BCORep = char 'p'
pprUnionTag _ = panic "pprUnionTag:Odd kind"
\end{code}
info_lbl = infoTableLabelFromCI cl_info
ppr_decls_AbsC (COpStmt results _ args _) = ppr_decls_Amodes (results ++ args)
-ppr_decls_AbsC (CSimultaneous abc) = ppr_decls_AbsC abc
+ppr_decls_AbsC (CSimultaneous abc) = ppr_decls_AbsC abc
ppr_decls_AbsC (CCheck _ amodes code) =
ppr_decls_Amodes amodes `thenTE` \p1 ->
Nothing -> mkErrorStdEntryLabel
Just _ -> entryLabelFromCI cl_info
-ppr_decls_AbsC (CSRT lbl closure_lbls)
+ppr_decls_AbsC (CSRT _ closure_lbls)
= mapTE labelSeenTE closure_lbls `thenTE` \ seen ->
returnTE (Nothing,
if and seen then Nothing
ppr_decls_AbsC (CRetDirect _ code _ _) = ppr_decls_AbsC code
ppr_decls_AbsC (CRetVector _ amodes _ _) = ppr_decls_Amodes amodes
+ppr_decls_AbsC (CModuleInitBlock _ code) = ppr_decls_AbsC code
+
+ppr_decls_AbsC (_) = returnTE (Nothing, Nothing)
\end{code}
\begin{code}
ppr_decls_Amode (CAddr _) = returnTE (Nothing, Nothing)
ppr_decls_Amode (CReg _) = returnTE (Nothing, Nothing)
ppr_decls_Amode (CLit _) = returnTE (Nothing, Nothing)
-ppr_decls_Amode (CLitLit _ _) = returnTE (Nothing, Nothing)
-- CIntLike must be a literal -- no decls
ppr_decls_Amode (CIntLike int) = returnTE (Nothing, Nothing)
--- CCharLike may have be arbitrary value -- may have decls
-ppr_decls_Amode (CCharLike char)
- = ppr_decls_Amode char
+-- CCharLike too
+ppr_decls_Amode (CCharLike char) = returnTE (Nothing, Nothing)
-- now, the only place where we actually print temps/externs...
ppr_decls_Amode (CTemp uniq kind)
arr <- newFloatArray ((0::Int),0)
writeFloatArray arr 0 (fromRational r)
i <- readIntArray arr 0
- return (CLit (MachInt (toInteger i) True))
+ return (CLit (MachInt (toInteger i)))
)
doubleToWords :: CAddrMode -> [CAddrMode]
writeDoubleArray arr 0 (fromRational r)
i1 <- readIntArray arr 0
i2 <- readIntArray arr 1
- return [ CLit (MachInt (toInteger i1) True)
- , CLit (MachInt (toInteger i2) True)
+ return [ CLit (MachInt (toInteger i1))
+ , CLit (MachInt (toInteger i2))
]
)
| otherwise -- doubles are 1 word
arr <- newDoubleArray ((0::Int),0)
writeDoubleArray arr 0 (fromRational r)
i <- readIntArray arr 0
- return [ CLit (MachInt (toInteger i) True) ]
+ return [ CLit (MachInt (toInteger i)) ]
)
\end{code}
projects / ghc-hetmet.git / blobdiff