2 % (c) The GRASP/AQUA Project, Glasgow University, 1992-1998
4 %************************************************************************
6 \section[PprAbsC]{Pretty-printing Abstract~C}
8 %************************************************************************
18 #include "HsVersions.h"
25 import AbsCUtils ( getAmodeRep, nonemptyAbsC,
26 mixedPtrLocn, mixedTypeLocn
29 import ForeignCall ( CCallSpec(..), CCallTarget(..), playSafe, ccallConvAttribute )
30 import CLabel ( externallyVisibleCLabel,
31 needsCDecl, pprCLabel,
32 mkReturnInfoLabel, mkReturnPtLabel, mkClosureTblLabel,
33 mkClosureLabel, mkErrorStdEntryLabel,
34 CLabel, CLabelType(..), labelType, labelDynamic
37 import CmdLineOpts ( opt_SccProfilingOn, opt_GranMacros )
38 import CostCentre ( pprCostCentreDecl, pprCostCentreStackDecl )
40 import Costs ( costs, addrModeCosts, CostRes(..), Side(..) )
41 import CStrings ( pprStringInCStyle, pprCLabelString )
42 import FiniteMap ( addToFM, emptyFM, lookupFM, FiniteMap )
43 import Literal ( Literal(..) )
44 import TyCon ( tyConDataCons )
45 import Name ( NamedThing(..) )
46 import DataCon ( dataConWrapId )
47 import Maybes ( maybeToBool, catMaybes )
48 import PrimOp ( primOpNeedsWrapper )
49 import MachOp ( MachOp(..) )
50 import ForeignCall ( ForeignCall(..) )
51 import PrimRep ( isFloatingRep, PrimRep(..), getPrimRepSize, getPrimRepArrayElemSize )
52 import SMRep ( pprSMRep )
53 import Unique ( pprUnique, Unique{-instance NamedThing-} )
54 import UniqSet ( emptyUniqSet, elementOfUniqSet,
55 addOneToUniqSet, UniqSet
57 import StgSyn ( StgOp(..) )
58 import BitSet ( BitSet, intBS )
61 import Util ( lengthExceeds, listLengthCmp )
62 import Maybe ( isNothing, maybeToList )
69 For spitting out the costs of an abstract~C expression, @writeRealC@
70 now not only prints the C~code of the @absC@ arg but also adds a macro
71 call to a cost evaluation function @GRAN_EXEC@. For that,
72 @pprAbsC@ has a new ``costs'' argument. %% HWL
76 writeRealC :: Handle -> AbstractC -> IO ()
77 writeRealC handle absC
78 -- avoid holding on to the whole of absC in the !Gransim case.
80 then printForCFast fp (pprAbsC absC (costs absC))
81 else printForCFast fp (pprAbsC absC (panic "costs"))
82 --printForC handle (pprAbsC absC (panic "costs"))
83 dumpRealC :: AbstractC -> SDoc
84 dumpRealC absC = pprAbsC absC (costs absC)
87 writeRealC :: Handle -> AbstractC -> IO ()
88 --writeRealC handle absC =
90 -- printDoc LeftMode handle (pprAbsC absC (costs absC))
92 writeRealC handle absC
93 | opt_GranMacros = _scc_ "writeRealC" printForC handle $
94 pprCode CStyle (pprAbsC absC (costs absC))
95 | otherwise = _scc_ "writeRealC" printForC handle $
96 pprCode CStyle (pprAbsC absC (panic "costs"))
98 dumpRealC :: AbstractC -> SDoc
100 | opt_GranMacros = pprCode CStyle (pprAbsC absC (costs absC))
101 | otherwise = pprCode CStyle (pprAbsC absC (panic "costs"))
105 This emits the macro, which is used in GrAnSim to compute the total costs
106 from a cost 5 tuple. %% HWL
109 emitMacro :: CostRes -> SDoc
111 emitMacro _ | not opt_GranMacros = empty
113 emitMacro (Cost (i,b,l,s,f))
114 = hcat [ ptext SLIT("GRAN_EXEC"), char '(',
115 int i, comma, int b, comma, int l, comma,
116 int s, comma, int f, pp_paren_semi ]
118 pp_paren_semi = text ");"
121 New type: Now pprAbsC also takes the costs for evaluating the Abstract C
122 code as an argument (that's needed when spitting out the GRAN_EXEC macro
123 which must be done before the return i.e. inside absC code) HWL
126 pprAbsC :: AbstractC -> CostRes -> SDoc
127 pprAbsC AbsCNop _ = empty
128 pprAbsC (AbsCStmts s1 s2) c = ($$) (pprAbsC s1 c) (pprAbsC s2 c)
130 pprAbsC (CAssign dest src) _ = pprAssign (getAmodeRep dest) dest src
132 pprAbsC (CJump target) c
133 = ($$) (hcat [emitMacro c {-WDP:, text "/* <--++ CJump */"-} ])
134 (hcat [ text jmp_lit, pprAmode target, pp_paren_semi ])
136 pprAbsC (CFallThrough target) c
137 = ($$) (hcat [emitMacro c {-WDP:, text "/* <--++ CFallThrough */"-} ])
138 (hcat [ text jmp_lit, pprAmode target, pp_paren_semi ])
140 -- --------------------------------------------------------------------------
141 -- Spit out GRAN_EXEC macro immediately before the return HWL
143 pprAbsC (CReturn am return_info) c
144 = ($$) (hcat [emitMacro c {-WDP:, text "/* <---- CReturn */"-} ])
145 (hcat [text jmp_lit, target, pp_paren_semi ])
147 target = case return_info of
148 DirectReturn -> hcat [ptext SLIT("ENTRY_CODE"), lparen,
150 DynamicVectoredReturn am' -> mk_vector (pprAmode am')
151 StaticVectoredReturn n -> mk_vector (int n) -- Always positive
152 mk_vector x = hcat [ptext SLIT("RET_VEC"), char '(', pprAmode am, comma,
155 pprAbsC (CSplitMarker) _ = ptext SLIT("__STG_SPLIT_MARKER")
157 -- we optimise various degenerate cases of CSwitches.
159 -- --------------------------------------------------------------------------
160 -- Assume: CSwitch is also end of basic block
161 -- costs function yields nullCosts for whole switch
162 -- ==> inherited costs c are those of basic block up to switch
163 -- ==> inherit c + costs for the corresponding branch
165 -- --------------------------------------------------------------------------
167 pprAbsC (CSwitch discrim [] deflt) c
168 = pprAbsC deflt (c + costs deflt)
169 -- Empty alternative list => no costs for discrim as nothing cond. here HWL
171 pprAbsC (CSwitch discrim [(tag,alt_code)] deflt) c -- only one alt
172 = case (nonemptyAbsC deflt) of
173 Nothing -> -- one alt and no default
174 pprAbsC alt_code (c + costs alt_code)
175 -- Nothing conditional in here either HWL
177 Just dc -> -- make it an "if"
178 do_if_stmt discrim tag alt_code dc c
180 -- What problem is the re-ordering trying to solve ?
181 pprAbsC (CSwitch discrim [(tag1@(MachInt i1), alt_code1),
182 (tag2@(MachInt i2), alt_code2)] deflt) c
183 | empty_deflt && ((i1 == 0 && i2 == 1) || (i1 == 1 && i2 == 0))
185 do_if_stmt discrim tag1 alt_code1 alt_code2 c
187 do_if_stmt discrim tag2 alt_code2 alt_code1 c
189 empty_deflt = not (maybeToBool (nonemptyAbsC deflt))
191 pprAbsC (CSwitch discrim alts deflt) c -- general case
192 | isFloatingRep (getAmodeRep discrim)
193 = pprAbsC (foldr ( \ a -> CSwitch discrim [a]) deflt alts) c
196 hcat [text "switch (", pp_discrim, text ") {"],
197 nest 2 (vcat (map ppr_alt alts)),
198 (case (nonemptyAbsC deflt) of
201 nest 2 (vcat [ptext SLIT("default:"),
202 pprAbsC dc (c + switch_head_cost
204 ptext SLIT("break;")])),
211 = vcat [ hcat [ptext SLIT("case "), pprBasicLit lit, char ':'],
212 nest 2 (($$) (pprAbsC absC (c + switch_head_cost + costs absC))
213 (ptext SLIT("break;"))) ]
215 -- Costs for addressing header of switch and cond. branching -- HWL
216 switch_head_cost = addrModeCosts discrim Rhs + (Cost (0, 1, 0, 0, 0))
218 pprAbsC stmt@(COpStmt results (StgFCallOp fcall uniq) args vol_regs) _
219 = pprFCall fcall uniq args results vol_regs
221 pprAbsC stmt@(COpStmt results (StgPrimOp op) args vol_regs) _
223 non_void_args = grab_non_void_amodes args
224 non_void_results = grab_non_void_amodes results
225 -- if just one result, we print in the obvious "assignment" style;
226 -- if 0 or many results, we emit a macro call, w/ the results
227 -- followed by the arguments. The macro presumably knows which
230 the_op = ppr_op_call non_void_results non_void_args
231 -- liveness mask is *in* the non_void_args
233 if primOpNeedsWrapper op then
234 case (ppr_vol_regs vol_regs) of { (pp_saves, pp_restores) ->
243 ppr_op_call results args
244 = hcat [ ppr op, lparen,
245 hcat (punctuate comma (map ppr_op_result results)),
246 if null results || null args then empty else comma,
247 hcat (punctuate comma (map pprAmode args)),
250 ppr_op_result r = ppr_amode r
251 -- primop macros do their own casting of result;
252 -- hence we can toss the provided cast...
254 -- NEW CASES FOR EXPANDED PRIMOPS
256 pprAbsC stmt@(CMachOpStmt res mop [arg1,arg2] maybe_vols) _
257 = let prefix_fn = mop `elem` [MO_Dbl_Pwr, MO_Flt_Pwr, MO_NatS_MulMayOflo]
259 case ppr_maybe_vol_regs maybe_vols of {(saves,restores) ->
262 [ppr_amode res, equals]
264 then [pprMachOp_for_C mop, parens (pprAmode arg1 <> comma <> pprAmode arg2)]
265 else [pprAmode arg1, pprMachOp_for_C mop, pprAmode arg2])
271 pprAbsC stmt@(CMachOpStmt res mop [arg1] maybe_vols) _
272 = case ppr_maybe_vol_regs maybe_vols of {(saves,restores) ->
274 hcat [ppr_amode res, equals,
275 pprMachOp_for_C mop, parens (pprAmode arg1),
280 pprAbsC stmt@(CSequential stuff) c
281 = vcat (map (flip pprAbsC c) stuff)
283 -- end of NEW CASES FOR EXPANDED PRIMOPS
285 pprAbsC stmt@(CSRT lbl closures) c
286 = case (pprTempAndExternDecls stmt) of { (_, pp_exts) ->
288 $$ ptext SLIT("SRT") <> lparen <> pprCLabel lbl <> rparen
289 $$ nest 2 (hcat (punctuate comma (map pp_closure_lbl closures)))
293 pprAbsC stmt@(CBitmap lbl mask) c
294 = pp_bitmap_switch mask semi $
295 hcat [ ptext SLIT("BITMAP"), lparen,
296 pprCLabel lbl, comma,
297 int (length mask), comma,
298 pp_bitmap mask, rparen ]
300 pprAbsC (CSimultaneous abs_c) c
301 = hcat [ptext SLIT("{{"), pprAbsC abs_c c, ptext SLIT("}}")]
303 pprAbsC (CCheck macro as code) c
304 = hcat [ptext (cCheckMacroText macro), lparen,
305 hcat (punctuate comma (map ppr_amode as)), comma,
306 pprAbsC code c, pp_paren_semi
308 pprAbsC (CMacroStmt macro as) _
309 = hcat [ptext (cStmtMacroText macro), lparen,
310 hcat (punctuate comma (map ppr_amode as)),pp_paren_semi] -- no casting
311 pprAbsC (CCallProfCtrMacro op as) _
312 = hcat [ptext op, lparen,
313 hcat (punctuate comma (map ppr_amode as)),pp_paren_semi]
314 pprAbsC (CCallProfCCMacro op as) _
315 = hcat [ptext op, lparen,
316 hcat (punctuate comma (map ppr_amode as)),pp_paren_semi]
317 pprAbsC stmt@(CCallTypedef is_tdef (CCallSpec op_str cconv _) uniq results args) _
318 = hsep [ ptext (if is_tdef then SLIT("typedef") else SLIT("extern"))
321 , parens (hsep (punctuate comma ccall_decl_ty_args))
325 In the non-casm case, to ensure that we're entering the given external
326 entry point using the correct calling convention, we have to do the following:
328 - When entering via a function pointer (the `dynamic' case) using the specified
329 calling convention, we emit a typedefn declaration attributed with the
330 calling convention to use together with the result and parameter types we're
331 assuming. Coerce the function pointer to this type and go.
333 - to enter the function at a given code label, we emit an extern declaration
334 for the label here, stating the calling convention together with result and
335 argument types we're assuming.
337 The C compiler will hopefully use this extern declaration to good effect,
338 reporting any discrepancies between our extern decl and any other that
341 Re: calling convention, notice that gcc (2.8.1 and egcs-1.0.2) will for
342 the external function `foo' use the calling convention of the first `foo'
343 prototype it encounters (nor does it complain about conflicting attribute
344 declarations). The consequence of this is that you cannot override the
345 calling convention of `foo' using an extern declaration (you'd have to use
346 a typedef), but why you would want to do such a thing in the first place
347 is totally beyond me.
349 ToDo: petition the gcc folks to add code to warn about conflicting attribute
355 | is_tdef = parens (text (ccallConvAttribute cconv) <+> char '*' <> ccall_fun_ty)
356 | otherwise = text (ccallConvAttribute cconv) <+> ccall_fun_ty
360 DynamicTarget -> ptext SLIT("_ccall_fun_ty") <> ppr uniq
361 StaticTarget x -> pprCLabelString x
364 case non_void_results of
365 [] -> ptext SLIT("void")
366 [amode] -> ppr (getAmodeRep amode)
367 _ -> panic "pprAbsC{CCallTypedef}: ccall_res_ty"
370 | is_tdef = tail ccall_arg_tys
371 | otherwise = ccall_arg_tys
373 ccall_arg_tys = map (ppr . getAmodeRep) non_void_args
375 -- the first argument will be the "I/O world" token (a VoidRep)
376 -- all others should be non-void
379 in ASSERT (all non_void nvas) nvas
381 -- there will usually be two results: a (void) state which we
382 -- should ignore and a (possibly void) result.
384 let nvrs = grab_non_void_amodes results
385 in ASSERT (listLengthCmp nvrs 1 /= GT) nvrs
387 pprAbsC (CCodeBlock lbl abs_C) _
388 = if not (maybeToBool(nonemptyAbsC abs_C)) then
389 pprTrace "pprAbsC: curious empty code block for" (pprCLabel lbl) empty
391 case (pprTempAndExternDecls abs_C) of { (pp_temps, pp_exts) ->
395 hcat [text (if (externallyVisibleCLabel lbl)
396 then "FN_(" -- abbreviations to save on output
398 pprCLabel lbl, text ") {"],
402 nest 8 (ptext SLIT("FB_")),
403 nest 8 (pprAbsC abs_C (costs abs_C)),
404 nest 8 (ptext SLIT("FE_")),
410 pprAbsC (CInitHdr cl_info amode cost_centre size) _
411 = hcat [ ptext SLIT("SET_HDR_"), char '(',
412 ppr_amode amode, comma,
413 pprCLabelAddr info_lbl, comma,
414 if_profiling (pprAmode cost_centre), comma,
415 if_profiling (int size),
418 info_lbl = infoTableLabelFromCI cl_info
421 pprAbsC stmt@(CStaticClosure cl_info cost_centre amodes) _
422 = case (pprTempAndExternDecls stmt) of { (_, pp_exts) ->
426 ptext SLIT("SET_STATIC_HDR"), char '(',
427 pprCLabel closure_lbl, comma,
428 pprCLabel info_lbl, comma,
429 if_profiling (pprAmode cost_centre), comma,
430 ppLocalness closure_lbl, comma,
431 ppLocalnessMacro True{-include dyn-} info_lbl,
434 nest 2 (ppr_payload amodes),
438 closure_lbl = closureLabelFromCI cl_info
439 info_lbl = infoTableLabelFromCI cl_info
441 ppr_payload [] = empty
442 ppr_payload ls = comma <+>
443 braces (hsep (punctuate comma (map ((text "(L_)" <>).ppr_item) ls)))
446 | rep == VoidRep = text "0" -- might not even need this...
447 | rep == FloatRep = ppr_amode (floatToWord item)
448 | rep == DoubleRep = hcat (punctuate (text ", (L_)")
449 (map ppr_amode (doubleToWords item)))
450 | otherwise = ppr_amode item
452 rep = getAmodeRep item
455 pprAbsC stmt@(CClosureInfoAndCode cl_info slow maybe_fast cl_descr) _
458 ptext SLIT("INFO_TABLE"),
459 ( if is_selector then
460 ptext SLIT("_SELECTOR")
461 else if is_constr then
462 ptext SLIT("_CONSTR")
463 else if needs_srt then
465 else empty ), char '(',
467 pprCLabel info_lbl, comma,
468 pprCLabel slow_lbl, comma,
469 pp_rest, {- ptrs,nptrs,[srt,]type,-} comma,
471 ppLocalness info_lbl, comma,
472 ppLocalnessMacro True{-include dyn-} slow_lbl, comma,
474 if_profiling pp_descr, comma,
475 if_profiling pp_type,
481 Just fast -> let stuff = CCodeBlock fast_lbl fast in
482 pprAbsC stuff (costs stuff)
485 info_lbl = infoTableLabelFromCI cl_info
486 fast_lbl = fastLabelFromCI cl_info
489 = case (nonemptyAbsC slow) of
490 Nothing -> (mkErrorStdEntryLabel, empty)
491 Just xx -> (entryLabelFromCI cl_info,
492 let stuff = CCodeBlock slow_lbl xx in
493 pprAbsC stuff (costs stuff))
495 maybe_selector = maybeSelectorInfo cl_info
496 is_selector = maybeToBool maybe_selector
497 (Just select_word_i) = maybe_selector
499 maybe_tag = closureSemiTag cl_info
500 is_constr = maybeToBool maybe_tag
501 (Just tag) = maybe_tag
503 srt = closureSRT cl_info
504 needs_srt = case srt of
509 size = closureNonHdrSize cl_info
511 ptrs = closurePtrsSize cl_info
514 pp_rest | is_selector = int select_word_i
519 hcat [ int tag, comma ]
520 else if needs_srt then
525 type_str = pprSMRep (closureSMRep cl_info)
527 pp_descr = pprStringInCStyle cl_descr
528 pp_type = pprStringInCStyle (closureTypeDescr cl_info)
530 pprAbsC stmt@(CClosureTbl tycon) _
532 ptext SLIT("CLOSURE_TBL") <>
533 lparen <> pprCLabel (mkClosureTblLabel tycon) <> rparen :
535 map (pp_closure_lbl . mkClosureLabel . getName . dataConWrapId) (tyConDataCons tycon)
537 ) $$ ptext SLIT("};")
539 pprAbsC stmt@(CRetDirect uniq code srt liveness) _
542 ptext SLIT("INFO_TABLE_SRT_BITMAP"), lparen,
543 pprCLabel info_lbl, comma,
544 pprCLabel entry_lbl, comma,
545 pp_liveness liveness, comma, -- bitmap
546 pp_srt_info srt, -- SRT
547 closure_type, comma, -- closure type
548 ppLocalness info_lbl, comma, -- info table storage class
549 ppLocalnessMacro True{-include dyn-} entry_lbl, comma, -- entry pt storage class
556 info_lbl = mkReturnInfoLabel uniq
557 entry_lbl = mkReturnPtLabel uniq
559 pp_code = let stuff = CCodeBlock entry_lbl code in
560 pprAbsC stuff (costs stuff)
562 closure_type = pp_liveness_switch liveness
563 (ptext SLIT("RET_SMALL"))
564 (ptext SLIT("RET_BIG"))
566 pprAbsC stmt@(CRetVector lbl amodes srt liveness) _
567 = case (pprTempAndExternDecls stmt) of { (_, pp_exts) ->
571 ptext SLIT("VEC_INFO_") <> int size,
573 pprCLabel lbl, comma,
574 pp_liveness liveness, comma, -- bitmap liveness mask
575 pp_srt_info srt, -- SRT
577 ppLocalness lbl, comma
579 nest 2 (sep (punctuate comma (map ppr_item amodes))),
585 ppr_item item = (<>) (text "(F_) ") (ppr_amode item)
588 closure_type = pp_liveness_switch liveness
589 (ptext SLIT("RET_VEC_SMALL"))
590 (ptext SLIT("RET_VEC_BIG"))
593 pprAbsC stmt@(CModuleInitBlock lbl code) _
595 ptext SLIT("START_MOD_INIT") <> parens (pprCLabel lbl),
596 case (pprTempAndExternDecls stmt) of { (_, pp_exts) -> pp_exts },
597 pprAbsC code (costs code),
598 hcat [ptext SLIT("END_MOD_INIT"), lparen, rparen]
601 pprAbsC (CCostCentreDecl is_local cc) _ = pprCostCentreDecl is_local cc
602 pprAbsC (CCostCentreStackDecl ccs) _ = pprCostCentreStackDecl ccs
606 -- Print a CMachOp in a way suitable for emitting via C.
607 pprMachOp_for_C MO_Nat_Add = char '+'
608 pprMachOp_for_C MO_Nat_Sub = char '-'
609 pprMachOp_for_C MO_Nat_Eq = text "=="
610 pprMachOp_for_C MO_Nat_Ne = text "!="
612 pprMachOp_for_C MO_NatS_Ge = text ">="
613 pprMachOp_for_C MO_NatS_Le = text "<="
614 pprMachOp_for_C MO_NatS_Gt = text ">"
615 pprMachOp_for_C MO_NatS_Lt = text "<"
617 pprMachOp_for_C MO_NatU_Ge = text ">="
618 pprMachOp_for_C MO_NatU_Le = text "<="
619 pprMachOp_for_C MO_NatU_Gt = text ">"
620 pprMachOp_for_C MO_NatU_Lt = text "<"
622 pprMachOp_for_C MO_NatS_Mul = char '*'
623 pprMachOp_for_C MO_NatS_MulMayOflo = text "mulIntMayOflo"
624 pprMachOp_for_C MO_NatS_Quot = char '/'
625 pprMachOp_for_C MO_NatS_Rem = char '%'
626 pprMachOp_for_C MO_NatS_Neg = char '-'
628 pprMachOp_for_C MO_NatU_Mul = char '*'
629 pprMachOp_for_C MO_NatU_Quot = char '/'
630 pprMachOp_for_C MO_NatU_Rem = char '%'
632 pprMachOp_for_C MO_Nat_And = text "&"
633 pprMachOp_for_C MO_Nat_Or = text "|"
634 pprMachOp_for_C MO_Nat_Xor = text "^"
635 pprMachOp_for_C MO_Nat_Not = text "~"
636 pprMachOp_for_C MO_Nat_Shl = text "<<"
637 pprMachOp_for_C MO_Nat_Shr = text ">>"
638 pprMachOp_for_C MO_Nat_Sar = text ">>"
640 pprMachOp_for_C MO_32U_Eq = text "=="
641 pprMachOp_for_C MO_32U_Ne = text "!="
642 pprMachOp_for_C MO_32U_Ge = text ">="
643 pprMachOp_for_C MO_32U_Le = text "<="
644 pprMachOp_for_C MO_32U_Gt = text ">"
645 pprMachOp_for_C MO_32U_Lt = text "<"
647 pprMachOp_for_C MO_Dbl_Eq = text "=="
648 pprMachOp_for_C MO_Dbl_Ne = text "!="
649 pprMachOp_for_C MO_Dbl_Ge = text ">="
650 pprMachOp_for_C MO_Dbl_Le = text "<="
651 pprMachOp_for_C MO_Dbl_Gt = text ">"
652 pprMachOp_for_C MO_Dbl_Lt = text "<"
654 pprMachOp_for_C MO_Dbl_Add = text "+"
655 pprMachOp_for_C MO_Dbl_Sub = text "-"
656 pprMachOp_for_C MO_Dbl_Mul = text "*"
657 pprMachOp_for_C MO_Dbl_Div = text "/"
658 pprMachOp_for_C MO_Dbl_Pwr = text "pow"
660 pprMachOp_for_C MO_Dbl_Sin = text "sin"
661 pprMachOp_for_C MO_Dbl_Cos = text "cos"
662 pprMachOp_for_C MO_Dbl_Tan = text "tan"
663 pprMachOp_for_C MO_Dbl_Sinh = text "sinh"
664 pprMachOp_for_C MO_Dbl_Cosh = text "cosh"
665 pprMachOp_for_C MO_Dbl_Tanh = text "tanh"
666 pprMachOp_for_C MO_Dbl_Asin = text "asin"
667 pprMachOp_for_C MO_Dbl_Acos = text "acos"
668 pprMachOp_for_C MO_Dbl_Atan = text "atan"
669 pprMachOp_for_C MO_Dbl_Log = text "log"
670 pprMachOp_for_C MO_Dbl_Exp = text "exp"
671 pprMachOp_for_C MO_Dbl_Sqrt = text "sqrt"
672 pprMachOp_for_C MO_Dbl_Neg = text "-"
674 pprMachOp_for_C MO_Flt_Add = text "+"
675 pprMachOp_for_C MO_Flt_Sub = text "-"
676 pprMachOp_for_C MO_Flt_Mul = text "*"
677 pprMachOp_for_C MO_Flt_Div = text "/"
678 pprMachOp_for_C MO_Flt_Pwr = text "pow"
680 pprMachOp_for_C MO_Flt_Eq = text "=="
681 pprMachOp_for_C MO_Flt_Ne = text "!="
682 pprMachOp_for_C MO_Flt_Ge = text ">="
683 pprMachOp_for_C MO_Flt_Le = text "<="
684 pprMachOp_for_C MO_Flt_Gt = text ">"
685 pprMachOp_for_C MO_Flt_Lt = text "<"
687 pprMachOp_for_C MO_Flt_Sin = text "sin"
688 pprMachOp_for_C MO_Flt_Cos = text "cos"
689 pprMachOp_for_C MO_Flt_Tan = text "tan"
690 pprMachOp_for_C MO_Flt_Sinh = text "sinh"
691 pprMachOp_for_C MO_Flt_Cosh = text "cosh"
692 pprMachOp_for_C MO_Flt_Tanh = text "tanh"
693 pprMachOp_for_C MO_Flt_Asin = text "asin"
694 pprMachOp_for_C MO_Flt_Acos = text "acos"
695 pprMachOp_for_C MO_Flt_Atan = text "atan"
696 pprMachOp_for_C MO_Flt_Log = text "log"
697 pprMachOp_for_C MO_Flt_Exp = text "exp"
698 pprMachOp_for_C MO_Flt_Sqrt = text "sqrt"
699 pprMachOp_for_C MO_Flt_Neg = text "-"
701 pprMachOp_for_C MO_32U_to_NatS = text "(StgInt)"
702 pprMachOp_for_C MO_NatS_to_32U = text "(StgWord32)"
704 pprMachOp_for_C MO_NatS_to_Dbl = text "(StgDouble)"
705 pprMachOp_for_C MO_Dbl_to_NatS = text "(StgInt)"
707 pprMachOp_for_C MO_NatS_to_Flt = text "(StgFloat)"
708 pprMachOp_for_C MO_Flt_to_NatS = text "(StgInt)"
710 pprMachOp_for_C MO_NatS_to_NatU = text "(StgWord)"
711 pprMachOp_for_C MO_NatU_to_NatS = text "(StgInt)"
713 pprMachOp_for_C MO_NatS_to_NatP = text "(void*)"
714 pprMachOp_for_C MO_NatP_to_NatS = text "(StgInt)"
715 pprMachOp_for_C MO_NatU_to_NatP = text "(void*)"
716 pprMachOp_for_C MO_NatP_to_NatU = text "(StgWord)"
718 pprMachOp_for_C MO_Dbl_to_Flt = text "(StgFloat)"
719 pprMachOp_for_C MO_Flt_to_Dbl = text "(StgDouble)"
721 pprMachOp_for_C MO_8S_to_NatS = text "(StgInt8)(StgInt)"
722 pprMachOp_for_C MO_16S_to_NatS = text "(StgInt16)(StgInt)"
723 pprMachOp_for_C MO_32S_to_NatS = text "(StgInt32)(StgInt)"
725 pprMachOp_for_C MO_8U_to_NatU = text "(StgWord8)(StgWord)"
726 pprMachOp_for_C MO_16U_to_NatU = text "(StgWord16)(StgWord)"
727 pprMachOp_for_C MO_32U_to_NatU = text "(StgWord32)(StgWord)"
729 pprMachOp_for_C MO_8U_to_32U = text "(StgWord32)"
730 pprMachOp_for_C MO_32U_to_8U = text "(StgWord8)"
734 = if (externallyVisibleCLabel lbl)
736 else ptext SLIT("static ")
738 -- Horrible macros for declaring the types and locality of labels (see
741 ppLocalnessMacro include_dyn_prefix clabel =
746 ClosureType -> ptext SLIT("C_")
747 CodeType -> ptext SLIT("F_")
748 InfoTblType -> ptext SLIT("I_")
749 ClosureTblType -> ptext SLIT("CP_")
750 DataType -> ptext SLIT("D_")
753 is_visible = externallyVisibleCLabel clabel
754 label_type = labelType clabel
757 | is_visible = char 'E'
758 | otherwise = char 'I'
761 | include_dyn_prefix && labelDynamic clabel = char 'D'
769 grab_non_void_amodes amodes
770 = filter non_void amodes
773 = case (getAmodeRep amode) of
779 ppr_maybe_vol_regs :: Maybe [MagicId] -> (SDoc, SDoc)
780 ppr_maybe_vol_regs Nothing
782 ppr_maybe_vol_regs (Just vrs)
783 = case ppr_vol_regs vrs of
785 -> (pp_basic_saves $$ saves,
786 pp_basic_restores $$ restores)
788 ppr_vol_regs :: [MagicId] -> (SDoc, SDoc)
790 ppr_vol_regs [] = (empty, empty)
791 ppr_vol_regs (VoidReg:rs) = ppr_vol_regs rs
793 = let pp_reg = case r of
794 VanillaReg pk n -> pprVanillaReg n
796 (more_saves, more_restores) = ppr_vol_regs rs
798 (($$) ((<>) (ptext SLIT("CALLER_SAVE_")) pp_reg) more_saves,
799 ($$) ((<>) (ptext SLIT("CALLER_RESTORE_")) pp_reg) more_restores)
801 -- pp_basic_{saves,restores}: The BaseReg, Sp, Su, Hp and
802 -- HpLim (see StgRegs.lh) may need to be saved/restored around CCalls,
803 -- depending on the platform. (The "volatile regs" stuff handles all
804 -- other registers.) Just be *sure* BaseReg is OK before trying to do
805 -- anything else. The correct sequence of saves&restores are
806 -- encoded by the CALLER_*_SYSTEM macros.
807 pp_basic_saves = ptext SLIT("CALLER_SAVE_SYSTEM")
808 pp_basic_restores = ptext SLIT("CALLER_RESTORE_SYSTEM")
812 pp_srt_info NoC_SRT = hcat [ int 0, comma,
815 pp_srt_info (C_SRT lbl off len) = hcat [ pprCLabel lbl, comma,
822 | labelDynamic lbl = text "DLL_SRT_ENTRY" <> parens (pprCLabel lbl)
823 | otherwise = char '&' <> pprCLabel lbl
828 = if opt_SccProfilingOn
830 else char '0' -- leave it out!
831 -- ---------------------------------------------------------------------------
832 -- Changes for GrAnSim:
833 -- draw costs for computation in head of if into both branches;
834 -- as no abstractC data structure is given for the head, one is constructed
835 -- guessing unknown values and fed into the costs function
836 -- ---------------------------------------------------------------------------
838 do_if_stmt discrim tag alt_code deflt c
840 cond = hcat [ pprAmode discrim
843 , pprAmode (CLit tag)
845 -- to be absolutely sure that none of the
846 -- conversion rules hit, e.g.,
848 -- minInt is different to (int)minInt
850 -- in C (when minInt is a number not a constant
851 -- expression which evaluates to it.)
854 MachInt _ -> ptext SLIT("(I_)")
859 (addrModeCosts discrim Rhs) c
861 ppr_if_stmt pp_pred then_part else_part discrim_costs c
863 hcat [text "if (", pp_pred, text ") {"],
864 nest 8 (pprAbsC then_part (c + discrim_costs +
865 (Cost (0, 2, 0, 0, 0)) +
867 (case nonemptyAbsC else_part of Nothing -> empty; Just _ -> text "} else {"),
868 nest 8 (pprAbsC else_part (c + discrim_costs +
869 (Cost (0, 1, 0, 0, 0)) +
872 {- Total costs = inherited costs (before if) + costs for accessing discrim
873 + costs for cond branch ( = (0, 1, 0, 0, 0) )
874 + costs for that alternative
878 Historical note: this used to be two separate cases -- one for `ccall'
879 and one for `casm'. To get round a potential limitation to only 10
880 arguments, the numbering of arguments in @process_casm@ was beefed up a
883 Some rough notes on generating code for @CCallOp@:
885 1) Evaluate all arguments and stuff them into registers. (done elsewhere)
886 2) Save any essential registers (heap, stack, etc).
888 ToDo: If stable pointers are in use, these must be saved in a place
889 where the runtime system can get at them so that the Stg world can
890 be restarted during the call.
892 3) Save any temporary registers that are currently in use.
893 4) Do the call, putting result into a local variable
894 5) Restore essential registers
895 6) Restore temporaries
897 (This happens after restoration of essential registers because we
898 might need the @Base@ register to access all the others correctly.)
900 Otherwise, copy local variable into result register.
902 8) If ccall (not casm), declare the function being called as extern so
903 that C knows if it returns anything other than an int.
906 { ResultType _ccall_result;
909 _ccall_result = f( args );
913 return_reg = _ccall_result;
917 Amendment to the above: if we can GC, we have to:
919 * make sure we save all our registers away where the garbage collector
921 * be sure that there are no live registers or we're in trouble.
922 (This can cause problems if you try something foolish like passing
923 an array or a foreign obj to a _ccall_GC_ thing.)
924 * increment/decrement the @inCCallGC@ counter before/after the call so
925 that the runtime check that PerformGC is being used sensibly will work.
928 pprFCall call@(CCall (CCallSpec target cconv safety)) uniq args results vol_regs
931 declare_local_vars, -- local var for *result*
932 vcat local_arg_decls,
934 process_casm local_vars pp_non_void_args call_str,
940 (pp_saves, pp_restores) = ppr_vol_regs vol_regs
941 ppr_uniq_token = text "tok_" <> ppr uniq
942 (pp_save_context, pp_restore_context)
943 | playSafe safety = ( text "{ I_" <+> ppr_uniq_token <>
944 text "; SUSPEND_THREAD" <> parens ppr_uniq_token <> semi
945 , text "RESUME_THREAD" <> parens ppr_uniq_token <> text ";}"
947 | otherwise = ( pp_basic_saves $$ pp_saves,
948 pp_basic_restores $$ pp_restores)
952 in ASSERT2 ( all non_void nvas, ppr call <+> hsep (map pprAmode args) )
954 -- the last argument will be the "I/O world" token (a VoidRep)
955 -- all others should be non-void
958 let nvrs = grab_non_void_amodes results
959 in ASSERT (listLengthCmp nvrs 1 /= GT) nvrs
960 -- there will usually be two results: a (void) state which we
961 -- should ignore and a (possibly void) result.
963 (local_arg_decls, pp_non_void_args)
964 = unzip [ ppr_casm_arg a i | (a,i) <- non_void_args `zip` [1..] ]
966 (declare_local_vars, local_vars, assign_results)
967 = ppr_casm_results non_void_results
969 call_str = case target of
970 CasmTarget str -> _UNPK_ str
971 StaticTarget fn -> mk_ccall_str (pprCLabelString fn) ccall_args
972 DynamicTarget -> mk_ccall_str dyn_fun (tail ccall_args)
974 ccall_args = zipWith (\ _ i -> char '%' <> int i) non_void_args [0..]
975 dyn_fun = parens (parens (ptext SLIT("_ccall_fun_ty") <> ppr uniq) <> text "%0")
978 -- Remainder only used for ccall
979 mk_ccall_str fun_name ccall_fun_args = showSDoc
981 if null non_void_results
984 lparen, fun_name, lparen,
985 hcat (punctuate comma ccall_fun_args),
990 If the argument is a heap object, we need to reach inside and pull out
991 the bit the C world wants to see. The only heap objects which can be
992 passed are @Array@s and @ByteArray@s.
995 ppr_casm_arg :: CAddrMode -> Int -> (SDoc, SDoc)
996 -- (a) decl and assignment, (b) local var to be used later
998 ppr_casm_arg amode a_num
1000 a_kind = getAmodeRep amode
1001 pp_amode = pprAmode amode
1002 pp_kind = pprPrimKind a_kind
1004 local_var = (<>) (ptext SLIT("_ccall_arg")) (int a_num)
1006 (arg_type, pp_amode2)
1009 -- for array arguments, pass a pointer to the body of the array
1010 -- (PTRS_ARR_CTS skips over all the header nonsense)
1011 ArrayRep -> (pp_kind,
1012 hcat [ptext SLIT("PTRS_ARR_CTS"),char '(', pp_amode, rparen])
1013 ByteArrayRep -> (pp_kind,
1014 hcat [ptext SLIT("BYTE_ARR_CTS"),char '(', pp_amode, rparen])
1016 -- for ForeignObj, use FOREIGN_OBJ_DATA to fish out the contents.
1017 ForeignObjRep -> (pp_kind,
1018 hcat [ptext SLIT("ForeignObj_CLOSURE_DATA"),
1019 char '(', pp_amode, char ')'])
1021 other -> (pp_kind, pp_amode)
1024 = hcat [ arg_type, space, local_var, equals, pp_amode2, semi ]
1026 (declare_local_var, local_var)
1029 For l-values, the critical questions are:
1031 1) Are there any results at all?
1033 We only allow zero or one results.
1037 :: [CAddrMode] -- list of results (length <= 1)
1039 ( SDoc, -- declaration of any local vars
1040 [SDoc], -- list of result vars (same length as results)
1041 SDoc ) -- assignment (if any) of results in local var to registers
1044 = (empty, [], empty) -- no results
1046 ppr_casm_results [r]
1048 result_reg = ppr_amode r
1049 r_kind = getAmodeRep r
1051 local_var = ptext SLIT("_ccall_result")
1053 (result_type, assign_result)
1054 = (pprPrimKind r_kind,
1055 hcat [ result_reg, equals, local_var, semi ])
1057 declare_local_var = hcat [ result_type, space, local_var, semi ]
1059 (declare_local_var, [local_var], assign_result)
1062 = panic "ppr_casm_results: ccall/casm with many results"
1066 Note the sneaky way _the_ result is represented by a list so that we
1067 can complain if it's used twice.
1069 ToDo: Any chance of giving line numbers when process-casm fails?
1070 Or maybe we should do a check _much earlier_ in compiler. ADR
1073 process_casm :: [SDoc] -- results (length <= 1)
1074 -> [SDoc] -- arguments
1075 -> String -- format string (with embedded %'s)
1076 -> SDoc -- code being generated
1078 process_casm results args string = process results args string
1080 process [] _ "" = empty
1081 process (_:_) _ "" = error ("process_casm: non-void result not assigned while processing _casm_ \"" ++
1083 "\"\n(Try changing result type to IO ()\n")
1085 process ress args ('%':cs)
1088 error ("process_casm: lonely % while processing _casm_ \"" ++ string ++ "\".\n")
1091 char '%' <> process ress args css
1095 [] -> error ("process_casm: no result to match %r while processing _casm_ \"" ++ string ++ "\".\nTry deleting %r or changing result type from PrimIO ()\n")
1096 [r] -> r <> (process [] args css)
1097 _ -> panic ("process_casm: casm with many results while processing _casm_ \"" ++ string ++ "\".\n")
1101 read_int :: ReadS Int
1104 case (read_int other) of
1106 if num >= 0 && args `lengthExceeds` num
1107 then parens (args !! num) <> process ress args css
1108 else error ("process_casm: no such arg #:"++(show num)++" while processing \"" ++ string ++ "\".\n")
1109 _ -> error ("process_casm: not %<num> while processing _casm_ \"" ++ string ++ "\".\n")
1111 process ress args (other_c:cs)
1112 = char other_c <> process ress args cs
1115 %************************************************************************
1117 \subsection[a2r-assignments]{Assignments}
1119 %************************************************************************
1121 Printing assignments is a little tricky because of type coercion.
1123 First of all, the kind of the thing being assigned can be gotten from
1124 the destination addressing mode. (It should be the same as the kind
1125 of the source addressing mode.) If the kind of the assignment is of
1126 @VoidRep@, then don't generate any code at all.
1129 pprAssign :: PrimRep -> CAddrMode -> CAddrMode -> SDoc
1131 pprAssign VoidRep dest src = empty
1134 Special treatment for floats and doubles, to avoid unwanted conversions.
1137 pprAssign FloatRep dest@(CVal reg_rel _) src
1138 = hcat [ ptext SLIT("ASSIGN_FLT((W_*)"), parens (ppr_amode (CAddr reg_rel)), comma, pprAmode src, pp_paren_semi ]
1140 pprAssign DoubleRep dest@(CVal reg_rel _) src
1141 = hcat [ ptext SLIT("ASSIGN_DBL((W_*)"), parens (ppr_amode (CAddr reg_rel)), comma, pprAmode src, pp_paren_semi ]
1143 pprAssign Int64Rep dest@(CVal reg_rel _) src
1144 = hcat [ ptext SLIT("ASSIGN_Int64((W_*)"), parens (ppr_amode (CAddr reg_rel)), comma, pprAmode src, pp_paren_semi ]
1145 pprAssign Word64Rep dest@(CVal reg_rel _) src
1146 = hcat [ ptext SLIT("ASSIGN_Word64((W_*)"), parens (ppr_amode (CAddr reg_rel)), comma, pprAmode src, pp_paren_semi ]
1149 Lastly, the question is: will the C compiler think the types of the
1150 two sides of the assignment match?
1152 We assume that the types will match if neither side is a
1153 @CVal@ addressing mode for any register which can point into
1156 Why? Because the heap and stack are used to store miscellaneous
1157 things, whereas the temporaries, registers, etc., are only used for
1158 things of fixed type.
1161 pprAssign kind (CReg (VanillaReg _ dest)) (CReg (VanillaReg _ src))
1162 = hcat [ pprVanillaReg dest, equals,
1163 pprVanillaReg src, semi ]
1165 pprAssign kind dest src
1166 | mixedTypeLocn dest
1167 -- Add in a cast to StgWord (a.k.a. W_) iff the destination is mixed
1168 = hcat [ ppr_amode dest, equals,
1169 text "(W_)(", -- Here is the cast
1170 ppr_amode src, pp_paren_semi ]
1172 pprAssign kind dest src
1173 | mixedPtrLocn dest && getAmodeRep src /= PtrRep
1174 -- Add in a cast to StgPtr (a.k.a. P_) iff the destination is mixed
1175 = hcat [ ppr_amode dest, equals,
1176 text "(P_)(", -- Here is the cast
1177 ppr_amode src, pp_paren_semi ]
1179 pprAssign ByteArrayRep dest src
1181 -- Add in a cast iff the source is mixed
1182 = hcat [ ppr_amode dest, equals,
1183 text "(StgByteArray)(", -- Here is the cast
1184 ppr_amode src, pp_paren_semi ]
1186 pprAssign kind other_dest src
1187 = hcat [ ppr_amode other_dest, equals,
1188 pprAmode src, semi ]
1192 %************************************************************************
1194 \subsection[a2r-CAddrModes]{Addressing modes}
1196 %************************************************************************
1198 @pprAmode@ is used to print r-values (which may need casts), whereas
1199 @ppr_amode@ is used for l-values {\em and} as a help function for
1203 pprAmode, ppr_amode :: CAddrMode -> SDoc
1206 For reasons discussed above under assignments, @CVal@ modes need
1207 to be treated carefully. First come special cases for floats and doubles,
1208 similar to those in @pprAssign@:
1210 (NB: @PK_FLT@ and @PK_DBL@ require the {\em address} of the value in
1214 pprAmode (CVal reg_rel FloatRep)
1215 = hcat [ text "PK_FLT((W_*)", parens (ppr_amode (CAddr reg_rel)), rparen ]
1216 pprAmode (CVal reg_rel DoubleRep)
1217 = hcat [ text "PK_DBL((W_*)", parens (ppr_amode (CAddr reg_rel)), rparen ]
1218 pprAmode (CVal reg_rel Int64Rep)
1219 = hcat [ text "PK_Int64((W_*)", parens (ppr_amode (CAddr reg_rel)), rparen ]
1220 pprAmode (CVal reg_rel Word64Rep)
1221 = hcat [ text "PK_Word64((W_*)", parens (ppr_amode (CAddr reg_rel)), rparen ]
1224 Next comes the case where there is some other cast need, and the
1229 | mixedTypeLocn amode
1230 = parens (hcat [ pprPrimKind (getAmodeRep amode), ptext SLIT(")("),
1232 | otherwise -- No cast needed
1236 When we have an indirection through a CIndex, we have to be careful to
1237 get the type casts right.
1241 CVal (CIndex kind1 base offset) kind2
1245 *(kind2 *)((kind1 *)base + offset)
1247 That is, the indexing is done in units of kind1, but the resulting
1251 ppr_amode CBytesPerWord
1252 = text "(sizeof(void*))"
1254 ppr_amode (CVal reg_rel@(CIndex _ _ _) kind)
1255 = case (pprRegRelative False{-no sign wanted-} reg_rel) of
1256 (pp_reg, Nothing) -> panic "ppr_amode: CIndex"
1257 (pp_reg, Just offset) ->
1258 hcat [ char '*', parens (pprPrimKind kind <> char '*'),
1259 parens (pp_reg <> char '+' <> offset) ]
1262 Now the rest of the cases for ``workhorse'' @ppr_amode@:
1265 ppr_amode (CVal reg_rel _)
1266 = case (pprRegRelative False{-no sign wanted-} reg_rel) of
1267 (pp_reg, Nothing) -> (<>) (char '*') pp_reg
1268 (pp_reg, Just offset) -> hcat [ pp_reg, brackets offset ]
1270 ppr_amode (CAddr reg_rel)
1271 = case (pprRegRelative True{-sign wanted-} reg_rel) of
1272 (pp_reg, Nothing) -> pp_reg
1273 (pp_reg, Just offset) -> (<>) pp_reg offset
1275 ppr_amode (CReg magic_id) = pprMagicId magic_id
1277 ppr_amode (CTemp uniq kind) = char '_' <> pprUnique uniq <> char '_'
1279 ppr_amode (CLbl lbl kind) = pprCLabelAddr lbl
1281 ppr_amode (CCharLike ch)
1282 = hcat [ptext SLIT("CHARLIKE_CLOSURE"), char '(', pprAmode ch, rparen ]
1283 ppr_amode (CIntLike int)
1284 = hcat [ptext SLIT("INTLIKE_CLOSURE"), char '(', pprAmode int, rparen ]
1286 ppr_amode (CLit lit) = pprBasicLit lit
1288 ppr_amode (CJoinPoint _)
1289 = panic "ppr_amode: CJoinPoint"
1291 ppr_amode (CMacroExpr pk macro as)
1292 = parens (ptext (cExprMacroText macro) <>
1293 parens (hcat (punctuate comma (map pprAmode as))))
1297 cExprMacroText ENTRY_CODE = SLIT("ENTRY_CODE")
1298 cExprMacroText ARG_TAG = SLIT("ARG_TAG")
1299 cExprMacroText GET_TAG = SLIT("GET_TAG")
1300 cExprMacroText UPD_FRAME_UPDATEE = SLIT("UPD_FRAME_UPDATEE")
1301 cExprMacroText CCS_HDR = SLIT("CCS_HDR")
1303 cStmtMacroText ARGS_CHK = SLIT("ARGS_CHK")
1304 cStmtMacroText ARGS_CHK_LOAD_NODE = SLIT("ARGS_CHK_LOAD_NODE")
1305 cStmtMacroText UPD_CAF = SLIT("UPD_CAF")
1306 cStmtMacroText UPD_BH_UPDATABLE = SLIT("UPD_BH_UPDATABLE")
1307 cStmtMacroText UPD_BH_SINGLE_ENTRY = SLIT("UPD_BH_SINGLE_ENTRY")
1308 cStmtMacroText PUSH_UPD_FRAME = SLIT("PUSH_UPD_FRAME")
1309 cStmtMacroText PUSH_SEQ_FRAME = SLIT("PUSH_SEQ_FRAME")
1310 cStmtMacroText UPDATE_SU_FROM_UPD_FRAME = SLIT("UPDATE_SU_FROM_UPD_FRAME")
1311 cStmtMacroText SET_TAG = SLIT("SET_TAG")
1312 cStmtMacroText REGISTER_FOREIGN_EXPORT = SLIT("REGISTER_FOREIGN_EXPORT")
1313 cStmtMacroText REGISTER_IMPORT = SLIT("REGISTER_IMPORT")
1314 cStmtMacroText REGISTER_DIMPORT = SLIT("REGISTER_DIMPORT")
1315 cStmtMacroText GRAN_FETCH = SLIT("GRAN_FETCH")
1316 cStmtMacroText GRAN_RESCHEDULE = SLIT("GRAN_RESCHEDULE")
1317 cStmtMacroText GRAN_FETCH_AND_RESCHEDULE= SLIT("GRAN_FETCH_AND_RESCHEDULE")
1318 cStmtMacroText THREAD_CONTEXT_SWITCH = SLIT("THREAD_CONTEXT_SWITCH")
1319 cStmtMacroText GRAN_YIELD = SLIT("GRAN_YIELD")
1321 cCheckMacroText HP_CHK_NP = SLIT("HP_CHK_NP")
1322 cCheckMacroText STK_CHK_NP = SLIT("STK_CHK_NP")
1323 cCheckMacroText HP_STK_CHK_NP = SLIT("HP_STK_CHK_NP")
1324 cCheckMacroText HP_CHK_SEQ_NP = SLIT("HP_CHK_SEQ_NP")
1325 cCheckMacroText HP_CHK = SLIT("HP_CHK")
1326 cCheckMacroText STK_CHK = SLIT("STK_CHK")
1327 cCheckMacroText HP_STK_CHK = SLIT("HP_STK_CHK")
1328 cCheckMacroText HP_CHK_NOREGS = SLIT("HP_CHK_NOREGS")
1329 cCheckMacroText HP_CHK_UNPT_R1 = SLIT("HP_CHK_UNPT_R1")
1330 cCheckMacroText HP_CHK_UNBX_R1 = SLIT("HP_CHK_UNBX_R1")
1331 cCheckMacroText HP_CHK_F1 = SLIT("HP_CHK_F1")
1332 cCheckMacroText HP_CHK_D1 = SLIT("HP_CHK_D1")
1333 cCheckMacroText HP_CHK_L1 = SLIT("HP_CHK_L1")
1334 cCheckMacroText HP_CHK_UT_ALT = SLIT("HP_CHK_UT_ALT")
1335 cCheckMacroText HP_CHK_GEN = SLIT("HP_CHK_GEN")
1341 %************************************************************************
1343 \subsection[ppr-liveness-masks]{Liveness Masks}
1345 %************************************************************************
1348 pp_bitmap_switch :: [BitSet] -> SDoc -> SDoc -> SDoc
1349 pp_bitmap_switch ([ ]) small large = small
1350 pp_bitmap_switch ([_ ]) small large = small
1351 pp_bitmap_switch ([_,_]) small large = hcat
1352 [ptext SLIT("BITMAP_SWITCH64"), lparen, small, comma, large, rparen]
1353 pp_bitmap_switch (_ ) small large = large
1355 pp_liveness_switch :: Liveness -> SDoc -> SDoc -> SDoc
1356 pp_liveness_switch (Liveness lbl mask) = pp_bitmap_switch mask
1358 pp_bitset :: BitSet -> SDoc
1360 | i < -1 = int (i + 1) <> text "-1"
1364 pp_bitmap :: [BitSet] -> SDoc
1365 pp_bitmap [] = int 0
1366 pp_bitmap ss = hcat (punctuate delayed_comma (bundle ss)) where
1367 delayed_comma = hcat [space, ptext SLIT("COMMA"), space]
1369 bundle [s] = [hcat bitmap32]
1370 where bitmap32 = [ptext SLIT("BITMAP32"), lparen,
1371 pp_bitset s, rparen]
1372 bundle (s1:s2:ss) = hcat bitmap64 : bundle ss
1373 where bitmap64 = [ptext SLIT("BITMAP64"), lparen,
1374 pp_bitset s1, comma, pp_bitset s2, rparen]
1376 pp_liveness :: Liveness -> SDoc
1377 pp_liveness (Liveness lbl mask)
1378 = pp_bitmap_switch mask (pp_bitmap mask) (char '&' <> pprCLabel lbl)
1381 %************************************************************************
1383 \subsection[a2r-MagicIds]{Magic ids}
1385 %************************************************************************
1387 @pprRegRelative@ returns a pair of the @Doc@ for the register
1388 (some casting may be required), and a @Maybe Doc@ for the offset
1389 (zero offset gives a @Nothing@).
1392 addPlusSign :: Bool -> SDoc -> SDoc
1393 addPlusSign False p = p
1394 addPlusSign True p = (<>) (char '+') p
1396 pprSignedInt :: Bool -> Int -> Maybe SDoc -- Nothing => 0
1397 pprSignedInt sign_wanted n
1398 = if n == 0 then Nothing else
1399 if n > 0 then Just (addPlusSign sign_wanted (int n))
1402 pprRegRelative :: Bool -- True <=> Print leading plus sign (if +ve)
1404 -> (SDoc, Maybe SDoc)
1406 pprRegRelative sign_wanted (SpRel off)
1407 = (pprMagicId Sp, pprSignedInt sign_wanted (I# off))
1409 pprRegRelative sign_wanted r@(HpRel o)
1410 = let pp_Hp = pprMagicId Hp; off = I# o
1415 (pp_Hp, Just ((<>) (char '-') (int off)))
1417 pprRegRelative sign_wanted (NodeRel o)
1418 = let pp_Node = pprMagicId node; off = I# o
1423 (pp_Node, Just (addPlusSign sign_wanted (int off)))
1425 pprRegRelative sign_wanted (CIndex base offset kind)
1426 = ( hcat [text "((", pprPrimKind kind, text " *)(", ppr_amode base, text "))"]
1427 , Just (hcat [if sign_wanted then char '+' else empty,
1428 text "(I_)(", ppr_amode offset, ptext SLIT(")")])
1432 @pprMagicId@ just prints the register name. @VanillaReg@ registers are
1433 represented by a discriminated union (@StgUnion@), so we use the @PrimRep@
1434 to select the union tag.
1437 pprMagicId :: MagicId -> SDoc
1439 pprMagicId BaseReg = ptext SLIT("BaseReg")
1440 pprMagicId (VanillaReg pk n)
1441 = hcat [ pprVanillaReg n, char '.',
1443 pprMagicId (FloatReg n) = ptext SLIT("F") <> int (I# n)
1444 pprMagicId (DoubleReg n) = ptext SLIT("D") <> int (I# n)
1445 pprMagicId (LongReg _ n) = ptext SLIT("L") <> int (I# n)
1446 pprMagicId Sp = ptext SLIT("Sp")
1447 pprMagicId Su = ptext SLIT("Su")
1448 pprMagicId SpLim = ptext SLIT("SpLim")
1449 pprMagicId Hp = ptext SLIT("Hp")
1450 pprMagicId HpLim = ptext SLIT("HpLim")
1451 pprMagicId CurCostCentre = ptext SLIT("CCCS")
1452 pprMagicId VoidReg = panic "pprMagicId:VoidReg!"
1454 pprVanillaReg :: Int# -> SDoc
1455 pprVanillaReg n = char 'R' <> int (I# n)
1457 pprUnionTag :: PrimRep -> SDoc
1459 pprUnionTag PtrRep = char 'p'
1460 pprUnionTag CodePtrRep = ptext SLIT("fp")
1461 pprUnionTag DataPtrRep = char 'd'
1462 pprUnionTag RetRep = char 'p'
1463 pprUnionTag CostCentreRep = panic "pprUnionTag:CostCentre?"
1465 pprUnionTag CharRep = char 'c'
1466 pprUnionTag Int8Rep = ptext SLIT("i8")
1467 pprUnionTag IntRep = char 'i'
1468 pprUnionTag WordRep = char 'w'
1469 pprUnionTag Int32Rep = char 'i'
1470 pprUnionTag Word32Rep = char 'w'
1471 pprUnionTag AddrRep = char 'a'
1472 pprUnionTag FloatRep = char 'f'
1473 pprUnionTag DoubleRep = panic "pprUnionTag:Double?"
1475 pprUnionTag StablePtrRep = char 'p'
1476 pprUnionTag StableNameRep = char 'p'
1477 pprUnionTag WeakPtrRep = char 'p'
1478 pprUnionTag ForeignObjRep = char 'p'
1479 pprUnionTag PrimPtrRep = char 'p'
1481 pprUnionTag ThreadIdRep = char 't'
1483 pprUnionTag ArrayRep = char 'p'
1484 pprUnionTag ByteArrayRep = char 'b'
1485 pprUnionTag BCORep = char 'p'
1487 pprUnionTag _ = panic "pprUnionTag:Odd kind"
1491 Find and print local and external declarations for a list of
1492 Abstract~C statements.
1494 pprTempAndExternDecls :: AbstractC -> (SDoc{-temps-}, SDoc{-externs-})
1495 pprTempAndExternDecls AbsCNop = (empty, empty)
1497 pprTempAndExternDecls (AbsCStmts stmt1 stmt2)
1498 = initTE (ppr_decls_AbsC stmt1 `thenTE` \ (t_p1, e_p1) ->
1499 ppr_decls_AbsC stmt2 `thenTE` \ (t_p2, e_p2) ->
1500 case (catMaybes [t_p1, t_p2]) of { real_temps ->
1501 case (catMaybes [e_p1, e_p2]) of { real_exts ->
1502 returnTE (vcat real_temps, vcat real_exts) }}
1505 pprTempAndExternDecls other_stmt
1506 = initTE (ppr_decls_AbsC other_stmt `thenTE` \ (maybe_t, maybe_e) ->
1517 pprBasicLit :: Literal -> SDoc
1518 pprPrimKind :: PrimRep -> SDoc
1520 pprBasicLit lit = ppr lit
1521 pprPrimKind k = ppr k
1525 %************************************************************************
1527 \subsection[a2r-monad]{Monadery}
1529 %************************************************************************
1531 We need some monadery to keep track of temps and externs we have already
1532 printed. This info must be threaded right through the Abstract~C, so
1533 it's most convenient to hide it in this monad.
1535 WDP 95/02: Switched from \tr{([Unique], [CLabel])} to
1536 \tr{(UniqSet, CLabelSet)}. Allegedly for efficiency.
1539 type CLabelSet = FiniteMap CLabel (){-any type will do-}
1540 emptyCLabelSet = emptyFM
1541 x `elementOfCLabelSet` labs
1542 = case (lookupFM labs x) of { Just _ -> True; Nothing -> False }
1544 addToCLabelSet set x = addToFM set x ()
1546 type TEenv = (UniqSet Unique, CLabelSet)
1548 type TeM result = TEenv -> (TEenv, result)
1550 initTE :: TeM a -> a
1552 = case sa (emptyUniqSet, emptyCLabelSet) of { (_, result) ->
1555 {-# INLINE thenTE #-}
1556 {-# INLINE returnTE #-}
1558 thenTE :: TeM a -> (a -> TeM b) -> TeM b
1560 = case a u of { (u_1, result_of_a) ->
1563 mapTE :: (a -> TeM b) -> [a] -> TeM [b]
1564 mapTE f [] = returnTE []
1566 = f x `thenTE` \ r ->
1567 mapTE f xs `thenTE` \ rs ->
1570 returnTE :: a -> TeM a
1571 returnTE result env = (env, result)
1573 -- these next two check whether the thing is already
1574 -- recorded, and THEN THEY RECORD IT
1575 -- (subsequent calls will return False for the same uniq/label)
1577 tempSeenTE :: Unique -> TeM Bool
1578 tempSeenTE uniq env@(seen_uniqs, seen_labels)
1579 = if (uniq `elementOfUniqSet` seen_uniqs)
1581 else ((addOneToUniqSet seen_uniqs uniq,
1585 labelSeenTE :: CLabel -> TeM Bool
1586 labelSeenTE lbl env@(seen_uniqs, seen_labels)
1587 = if (lbl `elementOfCLabelSet` seen_labels)
1590 addToCLabelSet seen_labels lbl),
1595 pprTempDecl :: Unique -> PrimRep -> SDoc
1596 pprTempDecl uniq kind
1597 = hcat [ pprPrimKind kind, space, char '_', pprUnique uniq, ptext SLIT("_;") ]
1599 pprExternDecl :: Bool -> CLabel -> SDoc
1600 pprExternDecl in_srt clabel
1601 | not (needsCDecl clabel) = empty -- do not print anything for "known external" things
1603 hcat [ ppLocalnessMacro (not in_srt) clabel,
1604 lparen, dyn_wrapper (pprCLabel clabel), pp_paren_semi ]
1607 | in_srt && labelDynamic clabel = text "DLL_IMPORT_DATA_VAR" <> parens d
1613 ppr_decls_AbsC :: AbstractC -> TeM (Maybe SDoc{-temps-}, Maybe SDoc{-externs-})
1615 ppr_decls_AbsC AbsCNop = returnTE (Nothing, Nothing)
1617 ppr_decls_AbsC (AbsCStmts stmts_1 stmts_2)
1618 = ppr_decls_AbsC stmts_1 `thenTE` \ p1 ->
1619 ppr_decls_AbsC stmts_2 `thenTE` \ p2 ->
1620 returnTE (maybe_vcat [p1, p2])
1622 ppr_decls_AbsC (CSplitMarker) = returnTE (Nothing, Nothing)
1624 ppr_decls_AbsC (CAssign dest source)
1625 = ppr_decls_Amode dest `thenTE` \ p1 ->
1626 ppr_decls_Amode source `thenTE` \ p2 ->
1627 returnTE (maybe_vcat [p1, p2])
1629 ppr_decls_AbsC (CJump target) = ppr_decls_Amode target
1631 ppr_decls_AbsC (CFallThrough target) = ppr_decls_Amode target
1633 ppr_decls_AbsC (CReturn target _) = ppr_decls_Amode target
1635 ppr_decls_AbsC (CSwitch discrim alts deflt)
1636 = ppr_decls_Amode discrim `thenTE` \ pdisc ->
1637 mapTE ppr_alt_stuff alts `thenTE` \ palts ->
1638 ppr_decls_AbsC deflt `thenTE` \ pdeflt ->
1639 returnTE (maybe_vcat (pdisc:pdeflt:palts))
1641 ppr_alt_stuff (_, absC) = ppr_decls_AbsC absC
1643 ppr_decls_AbsC (CCodeBlock lbl absC)
1644 = ppr_decls_AbsC absC
1646 ppr_decls_AbsC (CInitHdr cl_info reg_rel cost_centre _)
1647 -- ToDo: strictly speaking, should chk "cost_centre" amode
1648 = labelSeenTE info_lbl `thenTE` \ label_seen ->
1653 Just (pprExternDecl False{-not in an SRT decl-} info_lbl))
1655 info_lbl = infoTableLabelFromCI cl_info
1657 ppr_decls_AbsC (CMachOpStmt res _ args _) = ppr_decls_Amodes (res : args)
1658 ppr_decls_AbsC (COpStmt results _ args _) = ppr_decls_Amodes (results ++ args)
1660 ppr_decls_AbsC (CSimultaneous abc) = ppr_decls_AbsC abc
1662 ppr_decls_AbsC (CSequential abcs)
1663 = mapTE ppr_decls_AbsC abcs `thenTE` \ t_and_e_s ->
1664 returnTE (maybe_vcat t_and_e_s)
1666 ppr_decls_AbsC (CCheck _ amodes code) =
1667 ppr_decls_Amodes amodes `thenTE` \p1 ->
1668 ppr_decls_AbsC code `thenTE` \p2 ->
1669 returnTE (maybe_vcat [p1,p2])
1671 ppr_decls_AbsC (CMacroStmt _ amodes) = ppr_decls_Amodes amodes
1673 ppr_decls_AbsC (CCallProfCtrMacro _ amodes) = ppr_decls_Amodes [] -- *****!!!
1674 -- you get some nasty re-decls of stdio.h if you compile
1675 -- the prelude while looking inside those amodes;
1676 -- no real reason to, anyway.
1677 ppr_decls_AbsC (CCallProfCCMacro _ amodes) = ppr_decls_Amodes amodes
1679 ppr_decls_AbsC (CStaticClosure closure_info cost_centre amodes)
1680 -- ToDo: strictly speaking, should chk "cost_centre" amode
1681 = ppr_decls_Amodes amodes
1683 ppr_decls_AbsC (CClosureInfoAndCode cl_info slow maybe_fast _)
1684 = ppr_decls_Amodes [entry_lbl] `thenTE` \ p1 ->
1685 ppr_decls_AbsC slow `thenTE` \ p2 ->
1687 Nothing -> returnTE (Nothing, Nothing)
1688 Just fast -> ppr_decls_AbsC fast) `thenTE` \ p3 ->
1689 returnTE (maybe_vcat [p1, p2, p3])
1691 entry_lbl = CLbl slow_lbl CodePtrRep
1692 slow_lbl = case (nonemptyAbsC slow) of
1693 Nothing -> mkErrorStdEntryLabel
1694 Just _ -> entryLabelFromCI cl_info
1696 ppr_decls_AbsC (CSRT _ closure_lbls)
1697 = mapTE labelSeenTE closure_lbls `thenTE` \ seen ->
1699 if and seen then Nothing
1700 else Just (vcat [ pprExternDecl True{-in SRT decl-} l
1701 | (l,False) <- zip closure_lbls seen ]))
1703 ppr_decls_AbsC (CRetDirect _ code _ _) = ppr_decls_AbsC code
1704 ppr_decls_AbsC (CRetVector _ amodes _ _) = ppr_decls_Amodes amodes
1705 ppr_decls_AbsC (CModuleInitBlock _ code) = ppr_decls_AbsC code
1707 ppr_decls_AbsC (_) = returnTE (Nothing, Nothing)
1711 ppr_decls_Amode :: CAddrMode -> TeM (Maybe SDoc, Maybe SDoc)
1712 ppr_decls_Amode (CVal (CIndex base offset _) _) = ppr_decls_Amodes [base,offset]
1713 ppr_decls_Amode (CAddr (CIndex base offset _)) = ppr_decls_Amodes [base,offset]
1714 ppr_decls_Amode (CVal _ _) = returnTE (Nothing, Nothing)
1715 ppr_decls_Amode (CAddr _) = returnTE (Nothing, Nothing)
1716 ppr_decls_Amode (CReg _) = returnTE (Nothing, Nothing)
1717 ppr_decls_Amode (CLit _) = returnTE (Nothing, Nothing)
1719 -- CIntLike must be a literal -- no decls
1720 ppr_decls_Amode (CIntLike int) = returnTE (Nothing, Nothing)
1723 ppr_decls_Amode (CCharLike char) = returnTE (Nothing, Nothing)
1725 -- now, the only place where we actually print temps/externs...
1726 ppr_decls_Amode (CTemp uniq kind)
1728 VoidRep -> returnTE (Nothing, Nothing)
1730 tempSeenTE uniq `thenTE` \ temp_seen ->
1732 (if temp_seen then Nothing else Just (pprTempDecl uniq kind), Nothing)
1734 ppr_decls_Amode (CLbl lbl VoidRep)
1735 = returnTE (Nothing, Nothing)
1737 ppr_decls_Amode (CLbl lbl kind)
1738 = labelSeenTE lbl `thenTE` \ label_seen ->
1740 if label_seen then Nothing else Just (pprExternDecl False{-not in an SRT decl-} lbl))
1742 ppr_decls_Amode (CMacroExpr _ _ amodes)
1743 = ppr_decls_Amodes amodes
1745 ppr_decls_Amode other = returnTE (Nothing, Nothing)
1748 maybe_vcat :: [(Maybe SDoc, Maybe SDoc)] -> (Maybe SDoc, Maybe SDoc)
1750 = case (unzip ps) of { (ts, es) ->
1751 case (catMaybes ts) of { real_ts ->
1752 case (catMaybes es) of { real_es ->
1753 (if (null real_ts) then Nothing else Just (vcat real_ts),
1754 if (null real_es) then Nothing else Just (vcat real_es))
1759 ppr_decls_Amodes :: [CAddrMode] -> TeM (Maybe SDoc, Maybe SDoc)
1760 ppr_decls_Amodes amodes
1761 = mapTE ppr_decls_Amode amodes `thenTE` \ ps ->
1762 returnTE ( maybe_vcat ps )
1765 Print out a C Label where you want the *address* of the label, not the
1766 object it refers to. The distinction is important when the label may
1767 refer to a C structure (info tables and closures, for instance).
1769 When just generating a declaration for the label, use pprCLabel.
1772 pprCLabelAddr :: CLabel -> SDoc
1773 pprCLabelAddr clabel =
1774 case labelType clabel of
1775 InfoTblType -> addr_of_label
1776 ClosureType -> addr_of_label
1777 VecTblType -> addr_of_label
1780 addr_of_label = ptext SLIT("(P_)&") <> pp_label
1781 pp_label = pprCLabel clabel
1785 -----------------------------------------------------------------------------
1786 Initialising static objects with floating-point numbers. We can't
1787 just emit the floating point number, because C will cast it to an int
1788 by rounding it. We want the actual bit-representation of the float.
1790 This is a hack to turn the floating point numbers into ints that we
1791 can safely initialise to static locations.
1794 big_doubles = (getPrimRepSize DoubleRep) /= 1
1796 -- floatss are always 1 word
1797 floatToWord :: CAddrMode -> CAddrMode
1798 floatToWord (CLit (MachFloat r))
1800 arr <- newFloatArray ((0::Int),0)
1801 writeFloatArray arr 0 (fromRational r)
1802 i <- readIntArray arr 0
1803 return (CLit (MachInt (toInteger i)))
1806 doubleToWords :: CAddrMode -> [CAddrMode]
1807 doubleToWords (CLit (MachDouble r))
1808 | big_doubles -- doubles are 2 words
1810 arr <- newDoubleArray ((0::Int),1)
1811 writeDoubleArray arr 0 (fromRational r)
1812 i1 <- readIntArray arr 0
1813 i2 <- readIntArray arr 1
1814 return [ CLit (MachInt (toInteger i1))
1815 , CLit (MachInt (toInteger i2))
1818 | otherwise -- doubles are 1 word
1820 arr <- newDoubleArray ((0::Int),0)
1821 writeDoubleArray arr 0 (fromRational r)
1822 i <- readIntArray arr 0
1823 return [ CLit (MachInt (toInteger i)) ]