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{
Copyright (c) 2011 by Jonas Maebe
This unit provides helpers for creating new syms/defs based on string
representations.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
****************************************************************************
}
{$i fpcdefs.inc}
unit symcreat;
interface
uses
finput,tokens,scanner,globtype,
aasmdata,
symconst,symbase,symtype,symdef,symsym,
node;
type
tscannerstate = record
old_scanner: tscannerfile;
old_filepos: tfileposinfo;
old_token: ttoken;
old_c: char;
old_orgpattern: string;
old_modeswitches: tmodeswitches;
old_idtoken: ttoken;
valid: boolean;
end;
{ save/restore the scanner state before/after injecting }
procedure replace_scanner(const tempname: string; out sstate: tscannerstate);
procedure restore_scanner(const sstate: tscannerstate);
{ parses a (class or regular) method/constructor/destructor declaration from
str, as if it were declared in astruct's declaration body
WARNING: save the scanner state before calling this routine, and restore
when done. }
function str_parse_method_dec(str: ansistring; potype: tproctypeoption; is_classdef: boolean; astruct: tabstractrecorddef; out pd: tprocdef): boolean;
{ parses a (class or regular) method/constructor/destructor implementation
from str, as if it appeared in the current unit's implementation section
WARNINGS:
* save the scanner state before calling this routine, and restore when done.
* the code *must* be written in objfpc style
}
function str_parse_method_impl(const str: ansistring; usefwpd: tprocdef; is_classdef: boolean):boolean;
{ parses a typed constant assignment to ssym
WARNINGS:
* save the scanner state before calling this routine, and restore when done.
* the code *must* be written in objfpc style
}
procedure str_parse_typedconst(list: TAsmList; str: ansistring; ssym: tstaticvarsym);
{ in the JVM, constructors are not automatically inherited (so you can hide
them). To emulate the Pascal behaviour, we have to automatically add
all parent constructors to the current class as well. We also have to do
the same for the (emulated) virtual class methods }
procedure add_missing_parent_constructors_intf(obj: tobjectdef; addvirtclassmeth: boolean; forcevis: tvisibility);
{ goes through all defs in st to add implementations for synthetic methods
added earlier }
procedure add_synthetic_method_implementations(st: tsymtable);
{ create an alias for a procdef with Pascal name "newrealname",
mangledname "newmangledname", in symtable newparentst, part of the
record/class/.. "newstruct" (nil if none), and with synthetickind "sk" and
synthetic kind para "skpara" to create the implementation (tsk_none and nil
in case not necessary). Returns the new procdef; finish_copied_procdef() is
not required/must not be called for the result. }
function create_procdef_alias(pd: tprocdef; const newrealname: string; const newmangledname: TSymStr; newparentst: tsymtable; newstruct: tabstractrecorddef; sk: tsynthetickind; skpara: pointer): tprocdef;
{ finalize a procdef that has been copied with
tprocdef.getcopyas(procdef,pc_bareproc) }
procedure finish_copied_procdef(var pd: tprocdef; const realname: string; newparentst: tsymtable; newstruct: tabstractrecorddef);
{ checks whether sym (a local or para of pd) already has a counterpart in
pd's parentfpstruct, and if not adds a new field to the struct with type
"vardef" (can be different from sym's type in case it's a call-by-reference
parameter, which is indicated by addrparam). If it already has a field in
the parentfpstruct, this field is returned. }
function maybe_add_sym_to_parentfpstruct(pd: tprocdef; sym: tsym; vardef: tdef; addrparam: boolean): tsym;
{ given a localvarsym or paravarsym of pd, returns the field of the
parentfpstruct corresponding to this sym }
function find_sym_in_parentfpstruct(pd: tprocdef; sym: tsym): tsym;
{ replaces all local and paravarsyms that have been mirrored in the
parentfpstruct with aliasvarsyms that redirect to these fields (used to
make sure that references to these syms in the owning procdef itself also
use the ones in the parentfpstructs) }
procedure redirect_parentfpstruct_local_syms(pd: tprocdef);
{ finalises the parentfpstruct (alignment padding, ...) }
procedure finish_parentfpstruct(pd: tprocdef);
{ turns a fieldvarsym into a class/static field definition, and returns the
created staticvarsym that is responsible for allocating the global storage }
function make_field_static(recst: tsymtable; fieldvs: tfieldvarsym): tstaticvarsym;
{ create a new procdef with the signature of orgpd and (mangled) name
newname, and change the implementation of orgpd so that it calls through
to this new procedure }
procedure call_through_new_name(orgpd: tprocdef; const newname: TSymStr);
function generate_pkg_stub(pd:tprocdef):tnode;
implementation
uses
cutils,cclasses,globals,verbose,systems,comphook,fmodule,constexp,
symtable,defutil,symutil,
pbase,pdecobj,pdecsub,psub,ptconst,pparautl,
{$ifdef jvm}
pjvm,jvmdef,
{$endif jvm}
nbas,nld,nmem,ncon,
defcmp,
paramgr;
procedure replace_scanner(const tempname: string; out sstate: tscannerstate);
var
old_block_type: tblock_type;
begin
{ would require saving of cstringpattern, patternw }
if (token=_CSTRING) or
(token=_CWCHAR) or
(token=_CWSTRING) then
internalerror(2011032201);
sstate.old_scanner:=current_scanner;
sstate.old_filepos:=current_filepos;
sstate.old_token:=token;
sstate.old_c:=c;
sstate.old_orgpattern:=orgpattern;
sstate.old_modeswitches:=current_settings.modeswitches;
sstate.old_idtoken:=idtoken;
sstate.valid:=true;
{ creating a new scanner resets the block type, while we want to continue
in the current one }
old_block_type:=block_type;
current_scanner:=tscannerfile.Create('_Macro_.'+tempname,true);
block_type:=old_block_type;
{ required for e.g. FpcDeepCopy record method (uses "out" parameter; field
names are escaped via &, so should not cause conflicts }
current_settings.modeswitches:=objfpcmodeswitches;
end;
procedure restore_scanner(const sstate: tscannerstate);
begin
if sstate.valid then
begin
current_scanner.free;
current_scanner:=sstate.old_scanner;
current_filepos:=sstate.old_filepos;
token:=sstate.old_token;
current_settings.modeswitches:=sstate.old_modeswitches;
c:=sstate.old_c;
orgpattern:=sstate.old_orgpattern;
pattern:=upper(sstate.old_orgpattern);
idtoken:=sstate.old_idtoken;
end;
end;
function str_parse_method_dec(str: ansistring; potype: tproctypeoption; is_classdef: boolean; astruct: tabstractrecorddef; out pd: tprocdef): boolean;
var
oldparse_only: boolean;
begin
Message1(parser_d_internal_parser_string,str);
oldparse_only:=parse_only;
parse_only:=true;
result:=false;
{ in case multiple strings are injected, make sure to always close the
previous macro inputfile to prevent memory leaks }
if assigned(current_scanner.inputfile) and
not(current_scanner.inputfile.closed) then
current_scanner.closeinputfile;
{ inject the string in the scanner }
str:=str+'end;';
current_scanner.substitutemacro('meth_head_macro',@str[1],length(str),current_scanner.line_no,current_scanner.inputfile.ref_index);
current_scanner.readtoken(false);
{ and parse it... }
case potype of
potype_class_constructor:
pd:=class_constructor_head(astruct);
potype_class_destructor:
pd:=class_destructor_head(astruct);
potype_constructor:
pd:=constructor_head;
potype_destructor:
pd:=destructor_head;
else if assigned(astruct) and
(astruct.typ=recorddef) then
pd:=parse_record_method_dec(astruct,is_classdef,false)
else
pd:=method_dec(astruct,is_classdef,false);
end;
if assigned(pd) then
result:=true;
parse_only:=oldparse_only;
{ remove the temporary macro input file again }
current_scanner.closeinputfile;
current_scanner.nextfile;
current_scanner.tempopeninputfile;
end;
function str_parse_method_impl_with_fileinfo(str: ansistring; usefwpd: tprocdef; fileno, lineno: longint; is_classdef: boolean):boolean;
var
oldparse_only: boolean;
tmpstr: ansistring;
begin
if ((status.verbosity and v_debug)<>0) then
begin
if assigned(usefwpd) then
Message1(parser_d_internal_parser_string,usefwpd.customprocname([pno_proctypeoption,pno_paranames,pno_ownername,pno_noclassmarker,pno_noleadingdollar])+str)
else
begin
if is_classdef then
tmpstr:='class '
else
tmpstr:='';
Message1(parser_d_internal_parser_string,tmpstr+str);
end;
end;
oldparse_only:=parse_only;
parse_only:=false;
result:=false;
{ "const" starts a new kind of block and hence makes the scanner return }
str:=str+'const;';
{ inject the string in the scanner }
current_scanner.substitutemacro('meth_impl_macro',@str[1],length(str),lineno,fileno);
current_scanner.readtoken(false);
{ and parse it... }
read_proc(is_classdef,usefwpd,false);
parse_only:=oldparse_only;
{ remove the temporary macro input file again }
current_scanner.closeinputfile;
current_scanner.nextfile;
current_scanner.tempopeninputfile;
result:=true;
end;
function str_parse_method_impl(const str: ansistring; usefwpd: tprocdef; is_classdef: boolean):boolean;
begin
result:=str_parse_method_impl_with_fileinfo(str, usefwpd, current_scanner.inputfile.ref_index, current_scanner.line_no, is_classdef);
end;
procedure str_parse_typedconst(list: TAsmList; str: ansistring; ssym: tstaticvarsym);
var
old_block_type: tblock_type;
old_parse_only: boolean;
begin
Message1(parser_d_internal_parser_string,str);
{ a string that will be interpreted as the start of a new section ->
typed constant parsing will stop }
str:=str+'type ';
old_parse_only:=parse_only;
old_block_type:=block_type;
parse_only:=true;
block_type:=bt_const;
current_scanner.substitutemacro('typed_const_macro',@str[1],length(str),current_scanner.line_no,current_scanner.inputfile.ref_index);
current_scanner.readtoken(false);
read_typed_const(list,ssym,ssym.owner.symtabletype in [recordsymtable,objectsymtable]);
parse_only:=old_parse_only;
block_type:=old_block_type;
{ remove the temporary macro input file again }
current_scanner.closeinputfile;
current_scanner.nextfile;
current_scanner.tempopeninputfile;
end;
function def_unit_name_prefix_if_toplevel(def: tdef): TSymStr;
begin
result:='';
{ if the routine is a global routine in a unit, explicitly use this unit
name to avoid accidentally calling other same-named routines that may be
in scope }
if not assigned(def.owner.defowner) and
assigned(def.owner.realname) and
(def.owner.moduleid<>0) then
result:=def.owner.realname^+'.';
end;
procedure add_missing_parent_constructors_intf(obj: tobjectdef; addvirtclassmeth: boolean; forcevis: tvisibility);
var
parent: tobjectdef;
def: tdef;
parentpd,
childpd: tprocdef;
i: longint;
srsym: tsym;
srsymtable: tsymtable;
begin
if (oo_is_external in obj.objectoptions) or
not assigned(obj.childof) then
exit;
parent:=obj.childof;
{ find all constructor in the parent }
for i:=0 to tobjectsymtable(parent.symtable).deflist.count-1 do
begin
def:=tdef(tobjectsymtable(parent.symtable).deflist[i]);
if (def.typ<>procdef) or
((tprocdef(def).proctypeoption<>potype_constructor) and
(not addvirtclassmeth or
not([po_classmethod,po_virtualmethod]<=tprocdef(def).procoptions))) or
not is_visible_for_object(tprocdef(def),obj) then
continue;
parentpd:=tprocdef(def);
{ do we have this constructor too? (don't use
search_struct_member/searchsym_in_class, since those will
search parents too) }
if searchsym_in_record(obj,parentpd.procsym.name,srsym,srsymtable) then
begin
{ there's a symbol with the same name, is it a routine of the
same type with the same parameters? }
if srsym.typ=procsym then
begin
childpd:=tprocsym(srsym).find_procdef_bytype_and_para(
tprocdef(def).proctypeoption,parentpd.paras,nil,
[cpo_ignorehidden,cpo_ignoreuniv,cpo_openequalisexact]);
if assigned(childpd) then
continue;
end;
end;
{ if we get here, we did not find it in the current objectdef ->
add }
childpd:=tprocdef(parentpd.getcopy);
{ get rid of the import name for inherited virtual class methods,
it has to be regenerated rather than amended }
if [po_classmethod,po_virtualmethod]<=childpd.procoptions then
begin
stringdispose(childpd.import_name);
exclude(childpd.procoptions,po_has_importname);
end;
if forcevis<>vis_none then
childpd.visibility:=forcevis;
if po_virtualmethod in childpd.procoptions then
include(childpd.procoptions,po_overridingmethod);
{ ignore this artificially added procdef when looking for overloads }
include(childpd.procoptions,po_ignore_for_overload_resolution);
finish_copied_procdef(childpd,parentpd.procsym.realname,obj.symtable,obj);
exclude(childpd.procoptions,po_external);
childpd.synthetickind:=tsk_anon_inherited;
include(obj.objectoptions,oo_has_constructor);
end;
end;
procedure implement_anon_inherited(pd: tprocdef);
var
str: ansistring;
isclassmethod: boolean;
begin
isclassmethod:=
(po_classmethod in pd.procoptions) and
not(pd.proctypeoption in [potype_constructor,potype_destructor]);
str:='begin ';
if (pd.proctypeoption<>potype_constructor) and
not is_void(pd.returndef) then
str:=str+'result:=';
str:=str+'inherited end;';
str_parse_method_impl(str,pd,isclassmethod);
end;
procedure implement_jvm_clone(pd: tprocdef);
var
struct: tabstractrecorddef;
str: ansistring;
i: longint;
sym: tsym;
fsym: tfieldvarsym;
begin
if not(pd.struct.typ in [recorddef,objectdef]) then
internalerror(2011032802);
struct:=pd.struct;
{ anonymous record types must get an artificial name, so we can generate
a typecast at the scanner level }
if (struct.typ=recorddef) and
not assigned(struct.typesym) then
internalerror(2011032812);
{ We cannot easily use the inherited clone in case we have to create a
deep copy of certain fields. The reason is that e.g. sets are pointers
at the JVM level, but not in Pascal. So the JVM clone routine will copy
the pointer to the set from the old record (= class instance) to the new
one, but we have no way to change this pointer itself from inside Pascal
code.
We solve this by relying on the fact that the JVM is garbage collected:
we simply declare a temporary instance on the stack, which will be
allocated/initialized by the temp generator. We return its address as
the result of the clone routine, so it remains live. }
str:='var __fpc_newcopy:'+ struct.typesym.realname+'; begin clone:=JLObject(@__fpc_newcopy);';
{ copy all field contents }
for i:=0 to struct.symtable.symlist.count-1 do
begin
sym:=tsym(struct.symtable.symlist[i]);
if (sym.typ=fieldvarsym) then
begin
fsym:=tfieldvarsym(sym);
str:=str+'__fpc_newcopy.&'+fsym.realname+':=&'+fsym.realname+';';
end;
end;
str:=str+'end;';
str_parse_method_impl(str,pd,false);
end;
procedure implement_record_deepcopy(pd: tprocdef);
var
struct: tabstractrecorddef;
str: ansistring;
i: longint;
sym: tsym;
fsym: tfieldvarsym;
begin
if not(pd.struct.typ in [recorddef,objectdef]) then
internalerror(2011032810);
struct:=pd.struct;
{ anonymous record types must get an artificial name, so we can generate
a typecast at the scanner level }
if (struct.typ=recorddef) and
not assigned(struct.typesym) then
internalerror(2011032811);
{ copy all fields }
str:='type _fpc_ptrt = ^'+struct.typesym.realname+'; var res: _fpc_ptrt; begin res:=_fpc_ptrt(result);';
for i:=0 to struct.symtable.symlist.count-1 do
begin
sym:=tsym(struct.symtable.symlist[i]);
if (sym.typ=fieldvarsym) then
begin
fsym:=tfieldvarsym(sym);
str:=str+'res^.&'+fsym.realname+':=&'+fsym.realname+';';
end;
end;
str:=str+'end;';
str_parse_method_impl(str,pd,false);
end;
procedure implement_record_initialize(pd: tprocdef);
var
struct: tabstractrecorddef;
str: ansistring;
i: longint;
sym: tsym;
fsym: tfieldvarsym;
begin
if not(pd.struct.typ in [recorddef,objectdef]) then
internalerror(2011071710);
struct:=pd.struct;
{ anonymous record types must get an artificial name, so we can generate
a typecast at the scanner level }
if (struct.typ=recorddef) and
not assigned(struct.typesym) then
internalerror(2011032811);
{ walk over all fields that need initialization }
str:='begin ';
for i:=0 to struct.symtable.symlist.count-1 do
begin
sym:=tsym(struct.symtable.symlist[i]);
if (sym.typ=fieldvarsym) then
begin
fsym:=tfieldvarsym(sym);
if fsym.vardef.needs_inittable then
str:=str+'system.initialize(&'+fsym.realname+');';
end;
end;
str:=str+'end;';
str_parse_method_impl(str,pd,false);
end;
procedure implement_empty(pd: tprocdef);
var
str: ansistring;
isclassmethod: boolean;
begin
isclassmethod:=
(po_classmethod in pd.procoptions) and
not(pd.proctypeoption in [potype_constructor,potype_destructor]);
str:='begin end;';
str_parse_method_impl(str,pd,isclassmethod);
end;
procedure addvisibleparameters(var str: ansistring; pd: tprocdef);
var
currpara: tparavarsym;
i: longint;
firstpara: boolean;
begin
firstpara:=true;
for i:=0 to pd.paras.count-1 do
begin
currpara:=tparavarsym(pd.paras[i]);
if not(vo_is_hidden_para in currpara.varoptions) then
begin
if not firstpara then
str:=str+',';
firstpara:=false;
str:=str+'&'+currpara.realname;
end;
end;
end;
procedure implement_callthrough(pd: tprocdef);
var
str: ansistring;
callpd: tprocdef;
isclassmethod: boolean;
begin
isclassmethod:=
(po_classmethod in pd.procoptions) and
not(pd.proctypeoption in [potype_constructor,potype_destructor]);
callpd:=tprocdef(pd.skpara);
str:='begin ';
if pd.returndef<>voidtype then
str:=str+'result:=';
{ if the routine is a global routine in a unit/program, explicitly
mnetion this program/unit name to avoid accidentally calling other
same-named routines that may be in scope }
str:=str+def_unit_name_prefix_if_toplevel(callpd)+callpd.procsym.realname+'(';
addvisibleparameters(str,pd);
str:=str+') end;';
str_parse_method_impl(str,pd,isclassmethod);
end;
{$ifdef jvm}
procedure implement_jvm_enum_values(pd: tprocdef);
begin
str_parse_method_impl('begin result:=__fpc_FVALUES end;',pd,true);
end;
procedure implement_jvm_enum_valuof(pd: tprocdef);
begin
str_parse_method_impl('begin result:=__FPC_TEnumClassAlias(inherited valueOf(JLClass(__FPC_TEnumClassAlias),__fpc_str)) end;',pd,true);
end;
procedure implement_jvm_enum_jumps_constr(pd: tprocdef);
begin
str_parse_method_impl('begin inherited create(__fpc_name,__fpc_ord); __fpc_fenumval:=__fpc_initenumval end;',pd,false);
end;
procedure implement_jvm_enum_fpcordinal(pd: tprocdef);
var
enumclass: tobjectdef;
enumdef: tenumdef;
begin
enumclass:=tobjectdef(pd.owner.defowner);
enumdef:=tenumdef(ttypesym(search_struct_member(enumclass,'__FPC_TENUMALIAS')).typedef);
if not enumdef.has_jumps then
str_parse_method_impl('begin result:=ordinal end;',pd,false)
else
str_parse_method_impl('begin result:=__fpc_fenumval end;',pd,false);
end;
procedure implement_jvm_enum_fpcvalueof(pd: tprocdef);
var
enumclass: tobjectdef;
enumdef: tenumdef;
isclassmethod: boolean;
begin
isclassmethod:=
(po_classmethod in pd.procoptions) and
not(pd.proctypeoption in [potype_constructor,potype_destructor]);
enumclass:=tobjectdef(pd.owner.defowner);
enumdef:=tenumdef(ttypesym(search_struct_member(enumclass,'__FPC_TENUMALIAS')).typedef);
{ convert integer to corresponding enum instance: in case of no jumps
get it from the $VALUES array, otherwise from the __fpc_ord2enum
hashmap }
if not enumdef.has_jumps then
str_parse_method_impl('begin result:=__fpc_FVALUES[__fpc_int] end;',pd,isclassmethod)
else
str_parse_method_impl('begin result:=__FPC_TEnumClassAlias(__fpc_ord2enum.get(JLInteger.valueOf(__fpc_int))) end;',pd,isclassmethod);
end;
function CompareEnumSyms(Item1, Item2: Pointer): Integer;
var
I1 : tenumsym absolute Item1;
I2 : tenumsym absolute Item2;
begin
Result:=I1.value-I2.value;
end;
procedure implement_jvm_enum_classconstr(pd: tprocdef);
var
enumclass: tobjectdef;
enumdef: tenumdef;
enumname,
str: ansistring;
i: longint;
enumsym: tenumsym;
orderedenums: tfpobjectlist;
begin
enumclass:=tobjectdef(pd.owner.defowner);
enumdef:=tenumdef(ttypesym(search_struct_member(enumclass,'__FPC_TENUMALIAS')).typedef);
if not assigned(enumdef) then
internalerror(2011062305);
str:='begin ';
if enumdef.has_jumps then
{ init hashmap for ordinal -> enum instance mapping; don't let it grow,
and set the capacity to the next prime following the total number of
enum elements to minimise the number of collisions }
str:=str+'__fpc_ord2enum:=JUHashMap.Create('+tostr(next_prime(enumdef.symtable.symlist.count))+',1.0);';
{ iterate over all enum elements and initialise the class fields, and
store them in the values array. Since the java.lang.Enum doCompare
method is final and hardcoded to compare based on declaration order
(= java.lang.Enum.ordinal() value), we have to create them in order of
ascending FPC ordinal values (which may not be the same as the FPC
declaration order in case of jumps }
orderedenums:=tfpobjectlist.create(false);
for i:=0 to enumdef.symtable.symlist.count-1 do
orderedenums.add(enumdef.symtable.symlist[i]);
if enumdef.has_jumps then
orderedenums.sort(@CompareEnumSyms);
for i:=0 to orderedenums.count-1 do
begin
enumsym:=tenumsym(orderedenums[i]);
enumname:=enumsym.realname;
str:=str+enumsym.name+':=__FPC_TEnumClassAlias.Create('''+enumname+''','+tostr(i);
if enumdef.has_jumps then
str:=str+','+tostr(enumsym.value);
str:=str+');';
{ alias for $VALUES array used internally by the JDK, and also by FPC
in case of no jumps }
str:=str+'__fpc_FVALUES['+tostr(i)+']:='+enumname+';';
if enumdef.has_jumps then
str:=str+'__fpc_ord2enum.put(JLInteger.valueOf('+tostr(enumsym.value)+'),'+enumname+');';
end;
orderedenums.free;
str:=str+' end;';
str_parse_method_impl(str,pd,true);
end;
procedure implement_jvm_enum_long2set(pd: tprocdef);
begin
str_parse_method_impl(
'var '+
'i, setval: jint;'+
'begin '+
'result:=JUEnumSet.noneOf(JLClass(__FPC_TEnumClassAlias));'+
'if __val<>0 then '+
'begin '+
'__setsize:=__setsize*8;'+
'for i:=0 to __setsize-1 do '+
// setsize-i because JVM = big endian
'if (__val and (jlong(1) shl (__setsize-i)))<>0 then '+
'result.add(fpcValueOf(i+__setbase));'+
'end '+
'end;',
pd,true);
end;
procedure implement_jvm_enum_bitset2set(pd: tprocdef);
begin
str_parse_method_impl(
'var '+
'i, setval: jint;'+
'begin '+
'result:=JUEnumSet.noneOf(JLClass(__FPC_TEnumClassAlias));'+
'i:=__val.nextSetBit(0);'+
'while i>=0 do '+
'begin '+
'setval:=-__fromsetbase;'+
'result.add(fpcValueOf(setval+__tosetbase));'+
'i:=__val.nextSetBit(i+1);'+
'end '+
'end;',
pd,true);
end;
procedure implement_jvm_enum_set2set(pd: tprocdef);
begin
str_parse_method_impl(
'var '+
'it: JUIterator;'+
'ele: FpcEnumValueObtainable;'+
'i: longint;'+
'begin '+
'result:=JUEnumSet.noneOf(JLClass(__FPC_TEnumClassAlias));'+
'it:=__val.iterator;'+
'while it.hasNext do '+
'begin '+
'ele:=FpcEnumValueObtainable(it.next);'+
'i:=ele.fpcOrdinal-__fromsetbase;'+
'result.add(fpcValueOf(i+__tosetbase));'+
'end '+
'end;',
pd,true);
end;
procedure implement_jvm_procvar_invoke(pd: tprocdef);
var
pvclass: tobjectdef;
procvar: tprocvardef;
paraname,str,endstr: ansistring;
pvs: tparavarsym;
paradef,boxdef,boxargdef: tdef;
i: longint;
firstpara: boolean;
begin
pvclass:=tobjectdef(pd.owner.defowner);
procvar:=tprocvardef(ttypesym(search_struct_member(pvclass,'__FPC_PROCVARALIAS')).typedef);
{ the procvar wrapper class has a tmethod member called "method", whose
"code" field is a JLRMethod, and whose "data" field is the self pointer
if any (if none is required, it's ignored by the JVM, so there's no
problem with always passing it) }
{ force extended syntax to allow calling invokeObjectFunc() without using
its result }
str:='';
endstr:='';
{ create local pointer to result type for typecasting in case of an
implicit pointer type }
if jvmimplicitpointertype(procvar.returndef) then
str:=str+'type __FPC_returnptrtype = ^'+procvar.returndef.typename+';';
str:=str+'begin ';
{ result handling (skip for generic definitions, we'll generate a new
version for the specialized definition) ) }
if not is_void(procvar.returndef) and
(procvar.returndef.typ<>undefineddef) then
begin
str:=str+'invoke:=';
if procvar.returndef.typ in [orddef,floatdef] then
begin
{ primitivetype(boxtype(..).unboxmethod) }
jvmgetboxtype(procvar.returndef,boxdef,boxargdef,false);
str:=str+procvar.returndef.typename+'('+boxdef.typename+'(';
endstr:=').'+jvmgetunboxmethod(procvar.returndef)+')';
end
else if jvmimplicitpointertype(procvar.returndef) then
begin
str:=str+'__FPC_returnptrtype(';
{ dereference }
endstr:=')^';
end
else
begin
str:=str+procvar.returndef.typename+'(';
endstr:=')';
end;
end;
str:=str+'invokeObjectFunc([';
{ parameters are a constant array of jlobject }
firstpara:=true;
for i:=0 to procvar.paras.count-1 do
begin
{ skip self/vmt/parentfp, passed separately }
pvs:=tparavarsym(procvar.paras[i]);
if ([vo_is_self,vo_is_vmt,vo_is_parentfp]*pvs.varoptions)<>[] then
continue;
if not firstpara then
str:=str+',';
firstpara:=false;
paraname:=pvs.realname;
paradef:=pvs.vardef;
{ Pascalize hidden high parameter }
if vo_is_high_para in pvs.varoptions then
paraname:='high('+tparavarsym(procvar.paras[i-1]).realname+')'
else if vo_is_hidden_para in pvs.varoptions then
begin
if ([vo_is_range_check,vo_is_overflow_check]*pvs.varoptions)<>[] then
{ ok, simple boolean parameters }
else
internalerror(2011072403);
end;
{ var/out/constref parameters -> pass address through (same for
implicit pointer types) }
if paramanager.push_copyout_param(pvs.varspez,paradef,procvar.proccalloption) or
jvmimplicitpointertype(paradef) then
begin
paraname:='@'+paraname;
paradef:=java_jlobject;
end;
if paradef.typ in [orddef,floatdef] then
begin
{ box primitive types; use valueOf() rather than create because it
can give better performance }
jvmgetboxtype(paradef,boxdef,boxargdef,false);
str:=str+boxdef.typename+'.valueOf('+boxargdef.typename+'('+paraname+'))'
end
else
str:=str+'JLObject('+paraname+')';
end;
str:=str+'])'+endstr+' end;';
str_parse_method_impl(str,pd,false)
end;
procedure implement_jvm_procvar_intconstr(pd: tprocdef);
var
pvdef: tprocvardef;
begin
{ ideal, and most performant, would be to keep the interface instance
passed to the constructor around and always call its method directly
rather than working via reflection. Unfortunately, the procvar semantics
that allow directly modifying the procvar via typecasting it to a
tmethod make this very hard.
So for now we simply take the address of the interface instance's
method and assign it to the tmethod of this procvar }
pvdef:=tprocvardef(pd.skpara);
str_parse_method_impl('begin method:=System.TMethod(@__intf.'+pvdef.typesym.RealName+'Callback) end;',pd,false);
end;
procedure implement_jvm_virtual_clmethod(pd: tprocdef);
var
str: ansistring;
callpd: tprocdef;
begin
callpd:=tprocdef(pd.skpara);
str:='var pv: __fpc_virtualclassmethod_pv_t'+pd.unique_id_str+'; begin '
+ 'pv:=@'+callpd.procsym.RealName+';';
if (pd.proctypeoption<>potype_constructor) and
not is_void(pd.returndef) then
str:=str+'result:=';
str:=str+'pv(';
addvisibleparameters(str,pd);
str:=str+') end;';
str_parse_method_impl(str,pd,true)
end;
{$endif jvm}
procedure implement_field_getter(pd: tprocdef);
var
i: longint;
pvs: tparavarsym;
str: ansistring;
callthroughprop: tpropertysym;
propaccesslist: tpropaccesslist;
lastparanr: longint;
firstpara: boolean;
begin
callthroughprop:=tpropertysym(pd.skpara);
str:='begin result:='+callthroughprop.realname;
if ppo_hasparameters in callthroughprop.propoptions then
begin
if not callthroughprop.getpropaccesslist(palt_read,propaccesslist) then
internalerror(2012100701);
str:=str+'[';
firstpara:=true;
lastparanr:=tprocdef(propaccesslist.procdef).paras.count-1;
if ppo_indexed in callthroughprop.propoptions then
dec(lastparanr);
for i:=0 to lastparanr do
begin
{ skip self/vmt/parentfp, passed implicitly }
pvs:=tparavarsym(tprocdef(propaccesslist.procdef).paras[i]);
if ([vo_is_self,vo_is_vmt,vo_is_parentfp]*pvs.varoptions)<>[] then
continue;
if not firstpara then
str:=str+',';
firstpara:=false;
str:=str+pvs.realname;
end;
str:=str+']';
end;
str:=str+'; end;';
str_parse_method_impl(str,pd,po_classmethod in pd.procoptions)
end;
procedure implement_field_setter(pd: tprocdef);
var
i, lastparaindex: longint;
pvs: tparavarsym;
paraname, str: ansistring;
callthroughprop: tpropertysym;
propaccesslist: tpropaccesslist;
firstpara: boolean;
begin
callthroughprop:=tpropertysym(pd.skpara);
str:='begin '+callthroughprop.realname;
if not callthroughprop.getpropaccesslist(palt_write,propaccesslist) then
internalerror(2012100702);
if ppo_hasparameters in callthroughprop.propoptions then
begin
str:=str+'[';
firstpara:=true;
{ last parameter is the value to be set, skip (only add index
parameters here) }
lastparaindex:=tprocdef(propaccesslist.procdef).paras.count-2;
if ppo_indexed in callthroughprop.propoptions then
dec(lastparaindex);
for i:=0 to lastparaindex do
begin
{ skip self/vmt/parentfp/index, passed implicitly }
pvs:=tparavarsym(tprocdef(propaccesslist.procdef).paras[i]);
if ([vo_is_self,vo_is_vmt,vo_is_parentfp]*pvs.varoptions)<>[] then
continue;
if not firstpara then
str:=str+',';
firstpara:=false;
str:=str+pvs.realname;
end;
str:=str+']';
end;
{ the value-to-be-set }
if assigned(propaccesslist.procdef) then
begin
pvs:=tparavarsym(tprocdef(propaccesslist.procdef).paras[tprocdef(propaccesslist.procdef).paras.count-1]);
paraname:=pvs.realname;
end
else
paraname:='__fpc_newval__';
str:=str+':='+paraname+'; end;';
str_parse_method_impl(str,pd,po_classmethod in pd.procoptions)
end;
procedure implement_block_invoke_procvar(pd: tprocdef);
var
str: ansistring;
begin
str:='';
str:='begin ';
if pd.returndef<>voidtype then
str:=str+'result:=';
str:=str+'__FPC_BLOCK_INVOKE_PV_TYPE(PFPC_Block_literal_complex_procvar(FPC_Block_Self)^.pv)(';
addvisibleparameters(str,pd);
str:=str+') end;';
str_parse_method_impl(str,pd,false);
end;
procedure implement_interface_wrapper(pd: tprocdef);
var
wrapperinfo: pskpara_interface_wrapper;
callthroughpd: tprocdef;
str: ansistring;
fileinfo: tfileposinfo;
begin
wrapperinfo:=pskpara_interface_wrapper(pd.skpara);
if not assigned(wrapperinfo) then
internalerror(2015090801);
callthroughpd:=tprocdef(wrapperinfo^.pd);
str:='begin ';
{ self right now points to the VMT of interface inside the instance ->
adjust so it points to the start of the instance }
str:=str+'pointer(self):=pointer(self) - '+tostr(wrapperinfo^.offset)+';';
{ now call through to the actual method }
if pd.returndef<>voidtype then
str:=str+'result:=';
str:=str+'&'+callthroughpd.procsym.realname+'(';
addvisibleparameters(str,pd);
str:=str+') end;';
{ add dummy file info so we can step in/through it }
if pd.owner.iscurrentunit then
fileinfo:=pd.fileinfo
else
begin
fileinfo.moduleindex:=current_module.moduleid;
fileinfo.fileindex:=1;
fileinfo.line:=1;
fileinfo.column:=1;
end;
str_parse_method_impl_with_fileinfo(str,pd,fileinfo.fileindex,fileinfo.line,false);
dispose(wrapperinfo);
pd.skpara:=nil;
end;
procedure implement_call_no_parameters(pd: tprocdef);
var
callpd: tprocdef;
str: ansistring;
warningson,
isclassmethod: boolean;
begin
{ avoid warnings about unset function results in these abstract wrappers }
warningson:=(status.verbosity and V_Warning)<>0;
setverbosity('W-');
str:='begin ';
callpd:=tprocdef(pd.skpara);
str:=str+def_unit_name_prefix_if_toplevel(callpd)+callpd.procsym.realname+'; end;';
isclassmethod:=
(po_classmethod in pd.procoptions) and
not(pd.proctypeoption in [potype_constructor,potype_destructor]);
str_parse_method_impl(str,pd,isclassmethod);
if warningson then
setverbosity('W+');
end;
procedure add_synthetic_method_implementations_for_st(st: tsymtable);
var
i : longint;
def : tdef;
pd : tprocdef;
begin
for i:=0 to st.deflist.count-1 do
begin
def:=tdef(st.deflist[i]);
if (def.typ<>procdef) then
continue;
{ skip methods when processing unit symtable }
if def.owner<>st then
continue;
pd:=tprocdef(def);
case pd.synthetickind of
tsk_none:
;
tsk_anon_inherited:
implement_anon_inherited(pd);
tsk_jvm_clone:
implement_jvm_clone(pd);
tsk_record_deepcopy:
implement_record_deepcopy(pd);
tsk_record_initialize:
implement_record_initialize(pd);
tsk_empty,
{ special handling for this one is done in tnodeutils.wrap_proc_body }
tsk_tcinit:
implement_empty(pd);
tsk_callthrough:
implement_callthrough(pd);
tsk_callthrough_nonabstract:
begin
if (pd.owner.defowner.typ<>objectdef) or
(tobjectdef(pd.owner.defowner).abstractcnt=0) then
implement_callthrough(pd)
else
implement_empty(pd);
end;
{$ifdef jvm}
tsk_jvm_enum_values:
implement_jvm_enum_values(pd);
tsk_jvm_enum_valueof:
implement_jvm_enum_valuof(pd);
tsk_jvm_enum_classconstr:
implement_jvm_enum_classconstr(pd);
tsk_jvm_enum_jumps_constr:
implement_jvm_enum_jumps_constr(pd);
tsk_jvm_enum_fpcordinal:
implement_jvm_enum_fpcordinal(pd);
tsk_jvm_enum_fpcvalueof:
implement_jvm_enum_fpcvalueof(pd);
tsk_jvm_enum_long2set:
implement_jvm_enum_long2set(pd);
tsk_jvm_enum_bitset2set:
implement_jvm_enum_bitset2set(pd);
tsk_jvm_enum_set2set:
implement_jvm_enum_set2set(pd);
tsk_jvm_procvar_invoke:
implement_jvm_procvar_invoke(pd);
tsk_jvm_procvar_intconstr:
implement_jvm_procvar_intconstr(pd);
tsk_jvm_virtual_clmethod:
implement_jvm_virtual_clmethod(pd);
{$endif jvm}
tsk_field_getter:
implement_field_getter(pd);
tsk_field_setter:
implement_field_setter(pd);
tsk_block_invoke_procvar:
implement_block_invoke_procvar(pd);
tsk_interface_wrapper:
implement_interface_wrapper(pd);
tsk_call_no_parameters:
implement_call_no_parameters(pd);
else
internalerror(2011032801);
end;
end;
end;
procedure add_synthetic_method_implementations(st: tsymtable);
var
i: longint;
def: tdef;
sstate: tscannerstate;
begin
{ skip if any errors have occurred, since then this can only cause more
errors }
if ErrorCount<>0 then
exit;
replace_scanner('synthetic_impl',sstate);
add_synthetic_method_implementations_for_st(st);
for i:=0 to st.deflist.count-1 do
begin
def:=tdef(st.deflist[i]);
if (def.typ=procdef) and
assigned(tprocdef(def).localst) and
{ not true for the "main" procedure, whose localsymtable is the staticsymtable }
(tprocdef(def).localst.symtabletype=localsymtable) then
add_synthetic_method_implementations(tprocdef(def).localst)
else if ((def.typ=objectdef) and
not(oo_is_external in tobjectdef(def).objectoptions)) or
(def.typ=recorddef) then
begin
{ also complete nested types }
add_synthetic_method_implementations(tabstractrecorddef(def).symtable);
end;
end;
restore_scanner(sstate);
end;
function create_procdef_alias(pd: tprocdef; const newrealname: string; const newmangledname: TSymStr; newparentst: tsymtable; newstruct: tabstractrecorddef;
sk: tsynthetickind; skpara: pointer): tprocdef;
begin
{ bare copy so we don't copy the aliasnames (specify prefix for
parameter names so we don't get issues in the body in case
we e.g. reference system.initialize and one of the parameters
is called "system") }
result:=tprocdef(pd.getcopyas(procdef,pc_bareproc,'__FPCW_'));
{ set the mangled name to the wrapper name }
result.setmangledname(newmangledname);
{ finish creating the copy }
finish_copied_procdef(result,newrealname,newparentst,newstruct);
{ now insert self/vmt }
insert_self_and_vmt_para(result);
{ and the function result }
insert_funcret_para(result);
{ recalculate the parameters now that we've added the missing ones }
result.calcparas;
{ set the info required to generate the implementation }
result.synthetickind:=sk;
result.skpara:=skpara;
end;
procedure finish_copied_procdef(var pd: tprocdef; const realname: string; newparentst: tsymtable; newstruct: tabstractrecorddef);
var
sym: tsym;
parasym: tparavarsym;
ps: tprocsym;
stname: string;
i: longint;
begin
{ add generic flag if required }
if assigned(newstruct) and
(df_generic in newstruct.defoptions) then
include(pd.defoptions,df_generic);
{ associate the procdef with a procsym in the owner }
if not(pd.proctypeoption in [potype_class_constructor,potype_class_destructor]) then
stname:=upper(realname)
else
stname:=lower(realname);
sym:=tsym(newparentst.find(stname));
if assigned(sym) then
begin
if sym.typ<>procsym then
internalerror(2011040601);
ps:=tprocsym(sym);
end
else
begin
ps:=cprocsym.create(realname);
newparentst.insert(ps);
end;
pd.procsym:=ps;
pd.struct:=newstruct;
{ in case of methods, replace the special parameter types with new ones }
if assigned(newstruct) then
begin
symtablestack.push(pd.parast);
{ may not be assigned in case we converted a procvar into a procdef }
if assigned(pd.paras) then
begin
for i:=0 to pd.paras.count-1 do
begin
parasym:=tparavarsym(pd.paras[i]);
if vo_is_self in parasym.varoptions then
begin
if parasym.vardef.typ=classrefdef then
parasym.vardef:=cclassrefdef.create(newstruct)
else
parasym.vardef:=newstruct;
end
end;
end;
{ also fix returndef in case of a constructor }
if pd.proctypeoption=potype_constructor then
pd.returndef:=newstruct;
symtablestack.pop(pd.parast);
end;
pd.calcparas;
proc_add_definition(pd);
end;
function maybe_add_sym_to_parentfpstruct(pd: tprocdef; sym: tsym; vardef: tdef; addrparam: boolean): tsym;
var
fieldvardef,
nestedvarsdef: tdef;
nestedvarsst: tsymtable;
initcode: tnode;
old_filepos: tfileposinfo;
symname,
symrealname: TSymStr;
begin
nestedvarsdef:=tlocalvarsym(pd.parentfpstruct).vardef;
{ redirect all aliases for the function result also to the function
result }
if vo_is_funcret in tabstractvarsym(sym).varoptions then
begin
symname:='result';
symrealname:='$result'
end
else
begin
symname:=sym.name;
symrealname:=sym.realname;
end;
result:=search_struct_member(trecorddef(nestedvarsdef),symname);
if not assigned(result) then
begin
{ mark that this symbol is mirrored in the parentfpstruct }
tabstractnormalvarsym(sym).inparentfpstruct:=true;
{ add field to the struct holding all locals accessed
by nested routines }
nestedvarsst:=trecorddef(nestedvarsdef).symtable;
{ indicate whether or not this is a var/out/constref/... parameter }
if addrparam then
fieldvardef:=cpointerdef.getreusable(vardef)
else
fieldvardef:=vardef;
result:=cfieldvarsym.create(symrealname,vs_value,fieldvardef,[]);
if nestedvarsst.symlist.count=0 then
include(tfieldvarsym(result).varoptions,vo_is_first_field);
nestedvarsst.insert(result);
trecordsymtable(nestedvarsst).addfield(tfieldvarsym(result),vis_public);
{ add initialization with original value if it's a parameter }
if (sym.typ=paravarsym) then
begin
old_filepos:=current_filepos;
fillchar(current_filepos,sizeof(current_filepos),0);
initcode:=cloadnode.create(sym,sym.owner);
{ indicate that this load should not be transformed into a load
from the parentfpstruct, but instead should load the original
value }
include(initcode.flags,nf_internal);
{ in case it's a var/out/constref parameter, store the address of the
parameter in the struct }
if addrparam then
begin
initcode:=caddrnode.create_internal(initcode);
include(taddrnode(initcode).addrnodeflags,anf_typedaddr);
end;
initcode:=cassignmentnode.create(
csubscriptnode.create(result,cloadnode.create(pd.parentfpstruct,pd.parentfpstruct.owner)),
initcode);
tblocknode(pd.parentfpinitblock).left:=cstatementnode.create
(initcode,tblocknode(pd.parentfpinitblock).left);
current_filepos:=old_filepos;
end;
end;
end;
procedure redirect_parentfpstruct_local_syms(pd: tprocdef);
var
nestedvarsdef: trecorddef;
sl: tpropaccesslist;
fsym,
lsym,
aliassym: tsym;
i: longint;
begin
nestedvarsdef:=trecorddef(tlocalvarsym(pd.parentfpstruct).vardef);
for i:=0 to nestedvarsdef.symtable.symlist.count-1 do
begin
fsym:=tsym(nestedvarsdef.symtable.symlist[i]);
if fsym.typ<>fieldvarsym then
continue;
lsym:=tsym(pd.localst.find(fsym.name));
if not assigned(lsym) then
lsym:=tsym(pd.parast.find(fsym.name));
if not assigned(lsym) then
internalerror(2011060408);
{ add an absolute variable that redirects to the field }
sl:=tpropaccesslist.create;
sl.addsym(sl_load,pd.parentfpstruct);
sl.addsym(sl_subscript,tfieldvarsym(fsym));
aliassym:=cabsolutevarsym.create_ref(lsym.name,tfieldvarsym(fsym).vardef,sl);
{ hide the original variable (can't delete, because there
may be other loadnodes that reference it)
-- only for locals; hiding parameters changes the
function signature }
if lsym.typ<>paravarsym then
hidesym(lsym);
{ insert the absolute variable in the localst of the
routine; ignore duplicates, because this will also check the
parasymtable and we want to override parameters with our local
versions }
pd.localst.insert(aliassym,false);
end;
end;
function find_sym_in_parentfpstruct(pd: tprocdef; sym: tsym): tsym;
var
nestedvarsdef: tdef;
begin
nestedvarsdef:=tlocalvarsym(pd.parentfpstruct).vardef;
result:=search_struct_member(trecorddef(nestedvarsdef),sym.name);
end;
procedure finish_parentfpstruct(pd: tprocdef);
begin
trecordsymtable(trecorddef(tlocalvarsym(pd.parentfpstruct).vardef).symtable).addalignmentpadding;
end;
function make_field_static(recst: tsymtable; fieldvs: tfieldvarsym): tstaticvarsym;
var
static_name: string;
hstaticvs: tstaticvarsym;
tmp: tabsolutevarsym;
sl: tpropaccesslist;
begin
include(fieldvs.symoptions,sp_static);
{ generate the symbol which reserves the space }
static_name:=lower(generate_nested_name(recst,'_'))+'_'+fieldvs.name;
hstaticvs:=cstaticvarsym.create_from_fieldvar(static_name,fieldvs);
{$ifdef jvm}
{ for the JVM, static field accesses are name-based and
hence we have to keep the original name of the field.
Create a staticvarsym instead of a fieldvarsym so we can
nevertheless use a loadn instead of a subscriptn though,
since a subscriptn requires something to subscript and
there is nothing in this case (class+field name will be
encoded in the mangled symbol name) }
recst.insert(hstaticvs);
{ only set the staticvarsym's basename (= field name, without any
mangling), because generating the fully mangled name right now can
result in a wrong string in case the field's type is a forward
declared class whose external name will change when the actual
definition is parsed }
if (vo_has_mangledname in fieldvs.varoptions) then
hstaticvs.set_mangledbasename(fieldvs.externalname^)
else
hstaticvs.set_mangledbasename(fieldvs.realname);
{ for definition in class file }
hstaticvs.visibility:=fieldvs.visibility;
{$else jvm}
include(hstaticvs.symoptions,sp_internal);
tabstractrecordsymtable(recst).get_unit_symtable.insert(hstaticvs);
{$endif jvm}
{ generate the symbol for the access }
sl:=tpropaccesslist.create;
sl.addsym(sl_load,hstaticvs);
{ do *not* change the visibility of this absolutevarsym from vis_public
to anything else, because its visibility is used by visibility checks
after turning a class property referring to a class variable into a
load node (handle_staticfield_access -> searchsym_in_class ->
is_visible_for_object), which means that the load will fail if this
symbol is e.g. "strict private" while the property is public }
tmp:=cabsolutevarsym.create_ref('$'+static_name,fieldvs.vardef,sl);
recst.insert(tmp);
result:=hstaticvs;
end;
procedure call_through_new_name(orgpd: tprocdef; const newname: TSymStr);
var
newpd: tprocdef;
begin
{ we have a forward declaration like
procedure test; (in the unit interface or "forward")
and then an implementation like
procedure test; external name 'something';
To solve this, we create a new external procdef for the
implementation, and then generate a procedure body for the original
one that calls through to the external procdef. This is necessary
because there may already be references to the mangled name for the
non-external "test".
}
{ prefixing the parameters here is useless, because the new procdef will
just be an external declaration without a body }
newpd:=tprocdef(orgpd.getcopyas(procdef,pc_bareproc,''));
insert_funcret_para(newpd);
newpd.procoptions:=newpd.procoptions+orgpd.procoptions*[po_external,po_has_importname,po_has_importdll];
newpd.import_name:=orgpd.import_name;
orgpd.import_name:=nil;
newpd.import_dll:=orgpd.import_dll;
orgpd.import_dll:=nil;
newpd.import_nr:=orgpd.import_nr;
orgpd.import_nr:=0;
newpd.setmangledname(newname);
finish_copied_procdef(newpd,'__FPC_IMPL_EXTERNAL_REDIRECT_'+newname,current_module.localsymtable,nil);
newpd.forwarddef:=false;
{ ideally we would prefix the parameters of the original routine here, but since it
can be an interface definition, we cannot do that without risking to change the
interface crc }
orgpd.skpara:=newpd;
orgpd.synthetickind:=tsk_callthrough;
orgpd.procoptions:=orgpd.procoptions-[po_external,po_has_importname,po_has_importdll];
orgpd.forwarddef:=true;
end;
function generate_pkg_stub(pd:tprocdef):tnode;
begin
if target_info.system in systems_all_windows+systems_nativent then
begin
insert_funcret_local(pd);
result:=cassignmentnode.create(
cloadnode.create(pd.funcretsym,pd.localst),
cordconstnode.create(1,bool32type,false)
);
end
else
result:=cnothingnode.create;
end;
end.