= dsFExport mod_name id (idType id)
ext_nm cconv False `thenDs` \(feb, b, h, c) ->
warnDepr depr loc `thenDs` \_ ->
- returnDs (feb:acc_feb, b : acc_f, h $$ acc_h, c $$ acc_c, acc_header)
+ returnDs (feb:acc_feb, b:acc_f, h $$ acc_h, c $$ acc_c, acc_header)
warnDepr False _ = returnDs ()
warnDepr True loc = dsWarn (addShortWarnLocLine loc msg)
the_body = mkLams (tvs ++ wrapper_args) the_app
(h_stub, c_stub) = fexportEntry (moduleUserString mod)
- ext_name f_helper_glob
- wrapper_arg_tys res_ty cconv isDyn
+ ext_name
+ (if isDyn then Nothing else Just f_helper_glob)
+ fe_arg_tys res_ty cconv
in
returnDs (f_helper_glob, (f_helper_glob, the_body), h_stub, c_stub)
-- hack: need to get at the name of the C stub we're about to generate.
fe_nm = _PK_ (moduleUserString mod_name ++ "_" ++ toCName fe_id)
in
- dsFExport mod_name id export_ty fe_nm cconv True `thenDs` \ (feb, fe, h_code, c_code) ->
+ dsFExport mod_name id export_ty fe_nm cconv True `thenDs` \ ({-feb-}_, {-fe-}_, h_code, c_code) ->
newSysLocalDs arg_ty `thenDs` \ cback ->
dsLookupGlobalValue newStablePtrName `thenDs` \ newStablePtrId ->
let
-- Never inline the f.e.d. function, because the litlit
-- might not be in scope in other modules.
in
- returnDs ([fed, fe], h_code, c_code)
+ returnDs ([fed] {-[fed, fe]-}, h_code, c_code)
where
ty = idType id
\begin{code}
fexportEntry :: String
-> FAST_STRING
- -> Id
+ -> Maybe Id -- Just==static, Nothing==dynamic
-> [Type]
-> Type
-> CCallConv
- -> Bool
-> (SDoc, SDoc)
-fexportEntry mod_nm c_nm helper args res_ty cc isDyn = (header_bits, c_bits)
+fexportEntry mod_nm c_nm maybe_target arg_htys res_hty cc = (header_bits, c_bits)
where
- -- name of the (Haskell) helper function generated by the desugarer.
- h_nm = ppr helper <> text "_closure"
- -- prototype for the exported function.
+ -- Create up types and names for the real args
+ arg_cnames, arg_ctys :: [SDoc]
+ arg_cnames = mkCArgNames 1 arg_htys
+ arg_ctys = map showStgType arg_htys
+
+ -- and also for auxiliary ones; the stable ptr in the dynamic case, and
+ -- a slot for the dummy return address in the dynamic + ccall case
+ extra_cnames_and_ctys
+ = case maybe_target of
+ Nothing -> [(text "the_stableptr", text "StgStablePtr")]
+ other -> []
+ ++
+ case (maybe_target, cc) of
+ (Nothing, CCallConv) -> [(text "original_return_addr", text "void*")]
+ other -> []
+
+ all_cnames_and_ctys :: [(SDoc, SDoc)]
+ all_cnames_and_ctys
+ = extra_cnames_and_ctys ++ zip arg_cnames arg_ctys
+
+ -- stuff to do with the return type of the C function
+ res_hty_is_unit = res_hty `eqType` unitTy -- Look through any newtypes
+
+ cResType | res_hty_is_unit = text "void"
+ | otherwise = showStgType res_hty
+
+ -- Now we can cook up the prototype for the exported function.
+ pprCconv = case cc of
+ CCallConv -> empty
+ StdCallConv -> text (ccallConvAttribute cc)
+
header_bits = ptext SLIT("extern") <+> fun_proto <> semi
fun_proto = cResType <+> pprCconv <+> ptext c_nm <>
- parens (hsep (punctuate comma (zipWith (<+>) cParamTypes proto_args)))
-
+ parens (hsep (punctuate comma (map (\(nm,ty) -> ty <+> nm)
+ all_cnames_and_ctys)))
+
+ -- the target which will form the root of what we ask rts_evalIO to run
+ the_cfun
+ = case maybe_target of
+ Nothing -> text "(StgClosure*)deRefStablePtr(the_stableptr)"
+ Just hs_fn -> ppr hs_fn <> text "_closure"
+
+ -- the expression we give to rts_evalIO
+ expr_to_run
+ = foldl appArg the_cfun (zip arg_cnames arg_htys)
+ where
+ appArg acc (arg_cname, arg_hty)
+ = text "rts_apply"
+ <> parens (acc <> comma <> mkHObj arg_hty <> parens arg_cname)
+
+ -- various other bits for inside the fn
+ declareResult = text "HaskellObj ret;"
+
+ return_what | res_hty_is_unit = empty
+ | otherwise = parens (unpackHObj res_hty <> parens (text "ret"))
+
+ -- an extern decl for the fn being called
+ extern_decl
+ = case maybe_target of
+ Nothing -> empty
+ Just hs_fn -> text "extern StgClosure* " <> ppr hs_fn <> text "_closure" <> semi
+
+ -- finally, the whole darn thing
c_bits =
+ extern_decl $$
fun_proto $$
vcat
[ lbrace
, declareResult
-- create the application + perform it.
, text "rc=rts_evalIO"
- <> parens (foldl appArg (text "(StgClosure*)deRefStablePtr(a0)")
- (tail (zip args c_args))
- <> comma
- <> text "&ret"
- )
+ <> parens (expr_to_run <+> comma <> text "&ret")
<> semi
, text "rts_checkSchedStatus" <> parens (doubleQuotes (ptext c_nm)
<> comma <> text "rc") <> semi
, rbrace
]
- appArg acc (a,c_a) =
- text "rts_apply" <> parens (acc <> comma <> mkHObj a <> parens c_a)
-
- cParamTypes = map showStgType real_args
-
- res_ty_is_unit = res_ty `eqType` unitTy -- Look through any newtypes
-
- cResType | res_ty_is_unit = text "void"
- | otherwise = showStgType res_ty
-
- pprCconv = case cc of
- CCallConv -> empty
- StdCallConv -> text (ccallConvAttribute cc)
-
- declareResult = text "HaskellObj ret;"
-
- mkExtern ty nm = text "extern" <+> ty <+> nm <> semi
-
- return_what | res_ty_is_unit = empty
- | otherwise = parens (unpackHObj res_ty <> parens (text "ret"))
-
- c_args = mkCArgNames 0 args
-
- {-
- If we're generating an entry point for a 'foreign export ccall dynamic',
- then we receive the return address of the C function that wants to
- invoke a Haskell function as any other C function, as second arg.
- This arg is unused within the body of the generated C stub, but
- needed by the Adjustor.c code to get the stack cleanup right.
- -}
- (proto_args, real_args)
- = case cc of
- CCallConv | isDyn -> ( text "a0" : text "original_return_addr"
- : mkCArgNames 1 (tail args)
- , head args : addrTy : tail args)
- other -> (mkCArgNames 0 args, args)
mkCArgNames :: Int -> [a] -> [SDoc]
mkCArgNames n as = zipWith (\ _ n -> text ('a':show n)) as [n..]