{ Copyright (c) 1998-2002 by Florian Klaempfl Routines for the code generation of RTTI data structures 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. **************************************************************************** } unit ncgrtti; {$i fpcdefs.inc} interface uses cclasses,constexp, aasmbase, symbase,symconst,symtype,symdef; type { TRTTIWriter } TRTTIWriter=class private procedure fields_write_rtti(st:tsymtable;rt:trttitype); procedure fields_write_rtti_data(def:tabstractrecorddef;rt:trttitype); procedure write_rtti_extrasyms(def:Tdef;rt:Trttitype;mainrtti:Tasmsymbol); procedure published_write_rtti(st:tsymtable;rt:trttitype); function published_properties_count(st:tsymtable):longint; procedure published_properties_write_rtti_data(propnamelist:TFPHashObjectList;st:tsymtable); procedure collect_propnamelist(propnamelist:TFPHashObjectList;objdef:tobjectdef); function ref_rtti(def:tdef;rt:trttitype):tasmsymbol; procedure write_rtti_name(def:tdef); procedure write_rtti_data(def:tdef;rt:trttitype); procedure write_child_rtti_data(def:tdef;rt:trttitype); procedure write_rtti_reference(def:tdef;rt:trttitype); procedure write_header(def: tdef; typekind: byte); procedure write_string(const s: string); procedure maybe_write_align; public procedure write_rtti(def:tdef;rt:trttitype); function get_rtti_label(def:tdef;rt:trttitype):tasmsymbol; function get_rtti_label_ord2str(def:tdef;rt:trttitype):tasmsymbol; function get_rtti_label_str2ord(def:tdef;rt:trttitype):tasmsymbol; end; var RTTIWriter : TRTTIWriter; implementation uses cutils, globals,globtype,verbose,systems, fmodule, procinfo, symsym, aasmtai,aasmdata, defutil, wpobase ; const rttidefstate : array[trttitype] of tdefstate = (ds_rtti_table_written,ds_init_table_written, { Objective-C related, does not pass here } symconst.ds_none,symconst.ds_none, symconst.ds_none,symconst.ds_none); type TPropNameListItem = class(TFPHashObject) propindex : longint; propowner : TSymtable; end; {*************************************************************************** TRTTIWriter ***************************************************************************} procedure TRTTIWriter.maybe_write_align; begin if (tf_requires_proper_alignment in target_info.flags) then current_asmdata.asmlists[al_rtti].concat(cai_align.Create(sizeof(TConstPtrUInt))); end; procedure TRTTIWriter.write_string(const s: string); begin current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(length(s))); current_asmdata.asmlists[al_rtti].concat(Tai_string.Create(s)); end; procedure TRTTIWriter.write_header(def: tdef; typekind: byte); begin if def.typ=arraydef then InternalError(201012211); current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(typekind)); if assigned(def.typesym) then write_string(ttypesym(def.typesym).realname) else current_asmdata.asmlists[al_rtti].concat(Tai_string.Create(#0)); end; procedure TRTTIWriter.write_rtti_name(def:tdef); var hs : string; begin if is_open_array(def) then { open arrays never have a typesym with a name, since you cannot define an "open array type". Kylix prints the type of the elements in the array in this case (so together with the pfArray flag, you can reconstruct the full typename, I assume (JM)) } def:=tarraydef(def).elementdef; { name } if assigned(def.typesym) then begin hs:=ttypesym(def.typesym).realname; current_asmdata.asmlists[al_rtti].concat(Tai_string.Create(chr(length(hs))+hs)); end else current_asmdata.asmlists[al_rtti].concat(Tai_string.Create(#0)); end; { writes a 32-bit count followed by array of field infos for given symtable } procedure TRTTIWriter.fields_write_rtti_data(def:tabstractrecorddef;rt:trttitype); var i : longint; sym : tsym; fieldcnt: longint; lastai: TLinkedListItem; st: tsymtable; begin fieldcnt:=0; { Count will be inserted at this location. It cannot be nil as we've just written header for this symtable owner. But stay safe. } lastai:=current_asmdata.asmlists[al_rtti].last; if lastai=nil then InternalError(201012212); { For objects, treat parent (if any) as a field with offset 0. This provides correct handling of entire instance with RTL rtti routines. } if (def.typ=objectdef) and (tobjectdef(def).objecttype=odt_object) and Assigned(tobjectdef(def).childof) and ((rt=fullrtti) or (tobjectdef(def).childof.needs_inittable)) then begin write_rtti_reference(tobjectdef(def).childof,rt); current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_pint(0)); inc(fieldcnt); end; st:=def.symtable; for i:=0 to st.SymList.Count-1 do begin sym:=tsym(st.SymList[i]); if (tsym(sym).typ=fieldvarsym) and not(sp_static in tsym(sym).symoptions) and ( (rt=fullrtti) or tfieldvarsym(sym).vardef.needs_inittable ) and not is_objc_class_or_protocol(tfieldvarsym(sym).vardef) then begin write_rtti_reference(tfieldvarsym(sym).vardef,rt); current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_pint(tfieldvarsym(sym).fieldoffset)); inc(fieldcnt); end; end; { insert field count before data } current_asmdata.asmlists[al_rtti].InsertAfter(Tai_const.Create_32bit(fieldcnt),lastai) end; procedure TRTTIWriter.fields_write_rtti(st:tsymtable;rt:trttitype); var i : longint; sym : tsym; begin for i:=0 to st.SymList.Count-1 do begin sym:=tsym(st.SymList[i]); if (tsym(sym).typ=fieldvarsym) and not(sp_static in tsym(sym).symoptions) and ( (rt=fullrtti) or tfieldvarsym(sym).vardef.needs_inittable ) then write_rtti(tfieldvarsym(sym).vardef,rt); end; end; procedure TRTTIWriter.published_write_rtti(st:tsymtable;rt:trttitype); var i : longint; sym : tsym; begin for i:=0 to st.SymList.Count-1 do begin sym:=tsym(st.SymList[i]); if (sym.visibility=vis_published) then begin case tsym(sym).typ of propertysym: write_rtti(tpropertysym(sym).propdef,rt); fieldvarsym: write_rtti(tfieldvarsym(sym).vardef,rt); end; end; end; end; function TRTTIWriter.published_properties_count(st:tsymtable):longint; var i : longint; sym : tsym; begin result:=0; for i:=0 to st.SymList.Count-1 do begin sym:=tsym(st.SymList[i]); if (tsym(sym).typ=propertysym) and (sym.visibility=vis_published) then inc(result); end; end; procedure TRTTIWriter.collect_propnamelist(propnamelist:TFPHashObjectList;objdef:tobjectdef); var i : longint; sym : tsym; pn : tpropnamelistitem; begin if assigned(objdef.childof) then collect_propnamelist(propnamelist,objdef.childof); for i:=0 to objdef.symtable.SymList.Count-1 do begin sym:=tsym(objdef.symtable.SymList[i]); if (tsym(sym).typ=propertysym) and (sym.visibility=vis_published) then begin pn:=TPropNameListItem(propnamelist.Find(tsym(sym).name)); if not assigned(pn) then begin pn:=tpropnamelistitem.create(propnamelist,tsym(sym).name); pn.propindex:=propnamelist.count-1; pn.propowner:=tsym(sym).owner; end; end; end; end; procedure TRTTIWriter.published_properties_write_rtti_data(propnamelist:TFPHashObjectList;st:tsymtable); var i : longint; sym : tsym; proctypesinfo : byte; propnameitem : tpropnamelistitem; procedure writeaccessproc(pap:tpropaccesslisttypes; shiftvalue : byte; unsetvalue: byte); var typvalue : byte; hp : ppropaccesslistitem; address,space : longint; def : tdef; hpropsym : tpropertysym; propaccesslist : tpropaccesslist; begin hpropsym:=tpropertysym(sym); repeat propaccesslist:=hpropsym.propaccesslist[pap]; if not propaccesslist.empty then break; hpropsym:=hpropsym.overriddenpropsym; until not assigned(hpropsym); if not(assigned(propaccesslist) and assigned(propaccesslist.firstsym)) then begin current_asmdata.asmlists[al_rtti].concat(Tai_const.create(aitconst_ptr,unsetvalue)); typvalue:=3; end else if propaccesslist.firstsym^.sym.typ=fieldvarsym then begin address:=0; hp:=propaccesslist.firstsym; def:=nil; while assigned(hp) do begin case hp^.sltype of sl_load : begin def:=tfieldvarsym(hp^.sym).vardef; inc(address,tfieldvarsym(hp^.sym).fieldoffset); end; sl_subscript : begin if not(assigned(def) and ((def.typ=recorddef) or is_object(def))) then internalerror(200402171); inc(address,tfieldvarsym(hp^.sym).fieldoffset); def:=tfieldvarsym(hp^.sym).vardef; end; sl_vec : begin if not(assigned(def) and (def.typ=arraydef)) then internalerror(200402172); def:=tarraydef(def).elementdef; {Hp.value is a Tconstexprint, which can be rather large, sanity check for longint overflow.} space:=(high(address)-address) div def.size; if int64(space)def.maxval then break; write_string(hp.realname); end; { write unit name } write_string(current_module.realmodulename^); { write zero which is required by RTL } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(0)); end; procedure orddef_rtti(def:torddef); procedure dointeger(typekind: byte); const trans : array[tordtype] of byte = (otUByte{otNone}, otUByte,otUWord,otULong,otUByte{otNone}, otSByte,otSWord,otSLong,otUByte{otNone}, otUByte,otUWord,otULong,otUByte, otSByte,otSWord,otSLong,otSByte, otUByte,otUWord,otUByte); begin write_header(def,typekind); maybe_write_align; current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(byte(trans[def.ordtype]))); maybe_write_align; {Convert to longint to smuggle values in high(longint)+1..high(cardinal) into asmlist.} current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(longint(def.low.svalue))); current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(longint(def.high.svalue))); end; begin case def.ordtype of s64bit : begin write_header(def,tkInt64); maybe_write_align; { low } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_64bit(def.low.svalue)); { high } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_64bit(def.high.svalue)); end; u64bit : begin write_header(def,tkQWord); maybe_write_align; {use svalue because Create_64bit accepts int64, prevents range checks} { low } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_64bit(def.low.svalue)); { high } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_64bit(def.high.svalue)); end; pasbool8: dointeger(tkBool); uchar: dointeger(tkChar); uwidechar: dointeger(tkWChar); scurrency: begin write_header(def,tkFloat); maybe_write_align; current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(ftCurr)); end; else dointeger(tkInteger); end; end; procedure floatdef_rtti(def:tfloatdef); const {tfloattype = (s32real,s64real,s80real,sc80real,s64bit,s128bit);} translate : array[tfloattype] of byte = (ftSingle,ftDouble,ftExtended,ftExtended,ftComp,ftCurr,ftFloat128); begin write_header(def,tkFloat); maybe_write_align; current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(translate[def.floattype])); end; procedure setdef_rtti(def:tsetdef); begin write_header(def,tkSet); maybe_write_align; case def.size of 1: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(otUByte)); 2: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(otUWord)); 4: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(otULong)); else current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(otUByte)); end; maybe_write_align; write_rtti_reference(def.elementdef,rt); end; procedure arraydef_rtti(def:tarraydef); var lastai: TLinkedListItem; dimcount: byte; totalcount: asizeuint; curdef:tarraydef; begin if ado_IsDynamicArray in def.arrayoptions then current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkdynarray)) else current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkarray)); write_rtti_name(def); maybe_write_align; if not(ado_IsDynamicArray in def.arrayoptions) then begin { remember tha last instruction. we will need to insert some calculated values after it } lastai:=current_asmdata.asmlists[al_rtti].last; curdef:=def; totalcount:=1; dimcount:=0; while assigned(curdef) do begin { Dims[i] PTypeInfo } write_rtti_reference(curdef.rangedef,rt); inc(dimcount); totalcount:=totalcount*curdef.elecount; { get the next static array } if assigned(curdef.elementdef) and (curdef.elementdef.typ=arraydef) and not(ado_IsDynamicArray in tarraydef(curdef.elementdef).arrayoptions) then curdef:=tarraydef(curdef.elementdef) else break; end; if (tf_requires_proper_alignment in target_info.flags) then current_asmdata.asmlists[al_rtti].InsertAfter(cai_align.Create(sizeof(TConstPtrUInt)),lastai); { dimension count } current_asmdata.asmlists[al_rtti].InsertAfter(Tai_const.Create_8bit(dimcount),lastai); { last dimension element type } current_asmdata.asmlists[al_rtti].InsertAfter(Tai_const.Create_sym(ref_rtti(curdef.elementdef,rt)),lastai); { total element count } current_asmdata.asmlists[al_rtti].InsertAfter(Tai_const.Create_pint(pint(totalcount)),lastai); { total size = elecount * elesize of the first arraydef } current_asmdata.asmlists[al_rtti].InsertAfter(Tai_const.Create_pint(def.elecount*def.elesize),lastai); end else { write a delphi almost compatible dyn. array entry: there are two types, eltype and eltype2, the latter is nil if the element type needs no finalization, the former is always valid, delphi has this swapped, but for compatibility with older fpc versions we do it different, to be delphi compatible, the names are swapped in typinfo.pp } begin { size of elements } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_pint(def.elesize)); { element type } write_rtti_reference(def.elementdef,rt); { variant type } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(tstoreddef(def.elementdef).getvardef)); { element type } if def.elementdef.needs_inittable then write_rtti_reference(def.elementdef,rt) else current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_pint(0)); { write unit name } write_string(current_module.realmodulename^); end; end; procedure classrefdef_rtti(def:tclassrefdef); begin write_header(def,tkClassRef); maybe_write_align; write_rtti_reference(def.pointeddef,rt); end; procedure pointerdef_rtti(def:tpointerdef); begin write_header(def,tkPointer); maybe_write_align; write_rtti_reference(def.pointeddef,rt); end; procedure recorddef_rtti(def:trecorddef); begin write_header(def,tkRecord); maybe_write_align; current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(def.size)); fields_write_rtti_data(def,rt); end; procedure procvardef_rtti(def:tprocvardef); const ProcCallOptionToCallConv: array[tproccalloption] of byte = ( { pocall_none } 0, { pocall_cdecl } 1, { pocall_cppdecl } 5, { pocall_far16 } 6, { pocall_oldfpccall } 7, { pocall_internproc } 8, { pocall_syscall } 9, { pocall_pascal } 2, { pocall_register } 0, { pocall_safecall } 4, { pocall_stdcall } 3, { pocall_softfloat } 10, { pocall_mwpascal } 11, { pocall_interrupt } 12 ); procedure write_param_flag(parasym:tparavarsym); var paraspec : byte; begin case parasym.varspez of vs_value : paraspec := 0; vs_const : paraspec := pfConst; vs_var : paraspec := pfVar; vs_out : paraspec := pfOut; vs_constref: paraspec := pfConstRef; end; { Kylix also seems to always add both pfArray and pfReference in this case } if is_open_array(parasym.vardef) then paraspec:=paraspec or pfArray or pfReference; { and these for classes and interfaces (maybe because they are themselves addresses?) } if is_class_or_interface(parasym.vardef) then paraspec:=paraspec or pfAddress; { set bits run from the highest to the lowest bit on big endian systems } if (target_info.endian = endian_big) then paraspec:=reverse_byte(paraspec); { write flags for current parameter } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(paraspec)); end; procedure write_para(parasym:tparavarsym); begin { only store user visible parameters } if not(vo_is_hidden_para in parasym.varoptions) then begin { write flags for current parameter } write_param_flag(parasym); { write name of current parameter } write_string(parasym.realname); { write name of type of current parameter } write_rtti_name(parasym.vardef); end; end; procedure write_procedure_param(parasym:tparavarsym); begin { only store user visible parameters } if not(vo_is_hidden_para in parasym.varoptions) then begin { write flags for current parameter } write_param_flag(parasym); maybe_write_align; { write param type } write_rtti_reference(parasym.vardef,fullrtti); { write name of current parameter } write_string(parasym.realname); end; end; var methodkind : byte; i : integer; begin if po_methodpointer in def.procoptions then begin { write method id and name } write_header(def,tkMethod); maybe_write_align; { write kind of method } case def.proctypeoption of potype_constructor: methodkind:=mkConstructor; potype_destructor: methodkind:=mkDestructor; potype_class_constructor: methodkind:=mkClassConstructor; potype_class_destructor: methodkind:=mkClassDestructor; potype_operator: methodkind:=mkOperatorOverload; potype_procedure: if po_classmethod in def.procoptions then methodkind:=mkClassProcedure else methodkind:=mkProcedure; potype_function: if po_classmethod in def.procoptions then methodkind:=mkClassFunction else methodkind:=mkFunction; else begin if def.returndef = voidtype then methodkind:=mkProcedure else methodkind:=mkFunction; end; end; current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(methodkind)); { write parameter info. The parameters must be written in reverse order if this method uses right to left parameter pushing! } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(def.maxparacount)); for i:=0 to def.paras.count-1 do write_para(tparavarsym(def.paras[i])); if (methodkind=mkFunction) or (methodkind=mkClassFunction) then begin { write name of result type } write_rtti_name(def.returndef); maybe_write_align; { write result typeinfo } write_rtti_reference(def.returndef,fullrtti); end; { write calling convention } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(ProcCallOptionToCallConv[def.proccalloption])); maybe_write_align; { write params typeinfo } for i:=0 to def.paras.count-1 do if not(vo_is_hidden_para in tparavarsym(def.paras[i]).varoptions) then write_rtti_reference(tparavarsym(def.paras[i]).vardef,fullrtti); end else begin write_header(def,tkProcvar); maybe_write_align; { flags } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(0)); //maybe_write_align; // aligning between bytes is not necessary { write calling convention } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(ProcCallOptionToCallConv[def.proccalloption])); maybe_write_align; { write result typeinfo } write_rtti_reference(def.returndef,fullrtti); { write parameter count } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(def.maxparacount)); for i:=0 to def.paras.count-1 do begin maybe_write_align; write_procedure_param(tparavarsym(def.paras[i])); end; end; end; procedure objectdef_rtti(def:tobjectdef); procedure objectdef_rtti_fields(def:tobjectdef); begin current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(def.size)); fields_write_rtti_data(def,rt); end; procedure objectdef_rtti_interface_init(def:tobjectdef); begin current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(def.size)); end; procedure objectdef_rtti_class_full(def:tobjectdef); var propnamelist : TFPHashObjectList; begin { Collect unique property names with nameindex } propnamelist:=TFPHashObjectList.Create; collect_propnamelist(propnamelist,def); if not is_objectpascal_helper(def) then if (oo_has_vmt in def.objectoptions) then current_asmdata.asmlists[al_rtti].concat(Tai_const.Createname(def.vmt_mangledname,0)) else current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_nil_dataptr); { write parent typeinfo } write_rtti_reference(def.childof,fullrtti); { write typeinfo of extended type } if is_objectpascal_helper(def) then if assigned(def.extendeddef) then write_rtti_reference(def.extendeddef,fullrtti) else InternalError(2011033001); { total number of unique properties } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_16bit(propnamelist.count)); { write unit name } write_string(current_module.realmodulename^); maybe_write_align; { write published properties for this object } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_16bit(published_properties_count(def.symtable))); maybe_write_align; published_properties_write_rtti_data(propnamelist,def.symtable); propnamelist.free; end; procedure objectdef_rtti_interface_full(def:tobjectdef); var i : longint; propnamelist : TFPHashObjectList; { if changed to a set, make sure it's still a byte large, and swap appropriately when cross-compiling } IntfFlags: byte; begin { Collect unique property names with nameindex } propnamelist:=TFPHashObjectList.Create; collect_propnamelist(propnamelist,def); { write parent typeinfo } write_rtti_reference(def.childof,fullrtti); { interface: write flags, iid and iidstr } IntfFlags:=0; if assigned(def.iidguid) then IntfFlags:=IntfFlags or (1 shl ord(ifHasGuid)); if assigned(def.iidstr) then IntfFlags:=IntfFlags or (1 shl ord(ifHasStrGUID)); if (def.objecttype=odt_dispinterface) then IntfFlags:=IntfFlags or (1 shl ord(ifDispInterface)); if (target_info.endian=endian_big) then IntfFlags:=reverse_byte(IntfFlags); { ifDispatch, } current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(IntfFlags)); maybe_write_align; current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_32bit(longint(def.iidguid^.D1))); current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_16bit(def.iidguid^.D2)); current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_16bit(def.iidguid^.D3)); for i:=Low(def.iidguid^.D4) to High(def.iidguid^.D4) do current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(def.iidguid^.D4[i])); { write unit name } write_string(current_module.realmodulename^); maybe_write_align; { write iidstr } if assigned(def.iidstr) then write_string(def.iidstr^) else current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(0)); maybe_write_align; { write published properties for this object } published_properties_write_rtti_data(propnamelist,def.symtable); propnamelist.free; end; begin case def.objecttype of odt_class: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkclass)); odt_object: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkobject)); odt_dispinterface, odt_interfacecom: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkinterface)); odt_interfacecorba: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkinterfaceCorba)); odt_helper: current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_8bit(tkhelper)); else internalerror(200611034); end; { generate the name } write_string(def.objrealname^); maybe_write_align; case rt of initrtti : begin if def.objecttype in [odt_class,odt_object,odt_helper] then objectdef_rtti_fields(def) else objectdef_rtti_interface_init(def); end; fullrtti : begin case def.objecttype of odt_helper, odt_class: objectdef_rtti_class_full(def); odt_object: objectdef_rtti_fields(def); else objectdef_rtti_interface_full(def); end; end; end; end; begin case def.typ of variantdef : variantdef_rtti(tvariantdef(def)); stringdef : stringdef_rtti(tstringdef(def)); enumdef : enumdef_rtti(tenumdef(def)); orddef : orddef_rtti(torddef(def)); floatdef : floatdef_rtti(tfloatdef(def)); setdef : setdef_rtti(tsetdef(def)); procvardef : procvardef_rtti(tprocvardef(def)); arraydef : begin if ado_IsBitPacked in tarraydef(def).arrayoptions then unknown_rtti(tstoreddef(def)) else arraydef_rtti(tarraydef(def)); end; recorddef : begin if trecorddef(def).is_packed then unknown_rtti(tstoreddef(def)) else recorddef_rtti(trecorddef(def)); end; objectdef : objectdef_rtti(tobjectdef(def)); classrefdef : classrefdef_rtti(tclassrefdef(def)); pointerdef : pointerdef_rtti(tpointerdef(def)); else unknown_rtti(tstoreddef(def)); end; end; procedure TRTTIWriter.write_rtti_extrasyms(def:Tdef;rt:Trttitype;mainrtti:Tasmsymbol); type Penumsym = ^Tenumsym; function enumdef_rtti_calcstringtablestart(const def : Tenumdef) : integer; begin { the alignment calls must correspond to the ones used during generating the actual data structure created elsewhere in this file } result:=1; if assigned(def.typesym) then inc(result,length(def.typesym.realname)+1) else inc(result); if (tf_requires_proper_alignment in target_info.flags) then result:=align(result,sizeof(Tconstptruint)); inc(result); if (tf_requires_proper_alignment in target_info.flags) then result:=align(result,sizeof(Tconstptruint)); inc(result, sizeof(longint) * 2); if (tf_requires_proper_alignment in target_info.flags) then result:=align(result,sizeof(Tconstptruint)); inc(result, sizeof(pint)); end; { Writes a helper table for accelerated conversion of ordinal enum values to strings. If you change something in this method, make sure to adapt the corresponding code in sstrings.inc. } procedure enumdef_rtti_ord2stringindex(const sym_count:longint; const offsets:plongint; const syms:Penumsym; const st:longint); var rttilab:Tasmsymbol; h,i,o,prev_value:longint; mode:(lookup,search); {Modify with care, ordinal value of enum is written.} r:single; {Must be real type because of integer overflow risk.} begin {Decide wether a lookup array is size efficient.} mode:=lookup; if sym_count>0 then begin i:=1; r:=0; h:=syms[0].value; {Next expected enum value is min.} { set prev_value for the first iteration to a value that is different from the first one without risking overflow (it's used to detect whether two enum values are the same) } if h=0 then prev_value:=1 else prev_value:=0; while isym_count then mode:=search; {Don't waste more than 50% space.} end; { write rtti data; make sure that the alignment matches the corresponding data structure in the code that uses it (if alignment is required). } with current_asmdata do begin rttilab:=defineasmsymbol(Tstoreddef(def).rtti_mangledname(rt)+'_o2s',AB_GLOBAL,AT_DATA); maybe_new_object_file(asmlists[al_rtti]); new_section(asmlists[al_rtti],sec_rodata,rttilab.name,const_align(sizeof(pint))); asmlists[al_rtti].concat(Tai_symbol.create_global(rttilab,0)); asmlists[al_rtti].concat(Tai_const.create_32bit(longint(mode))); if mode=lookup then begin maybe_write_align; o:=syms[0].value; {Start with min value.} for i:=0 to sym_count-1 do begin while odef.maxval then break; if sym_count>=sym_alloc then begin reallocmem(syms,2*sym_alloc*sizeof(Tenumsym)); reallocmem(offsets,2*sym_alloc*sizeof(longint)); sym_alloc:=sym_alloc*2; end; syms[sym_count]:=t; offsets[sym_count]:=st; inc(sym_count); st:=st+length(t.realname)+1; end; {Sort the syms by enum name} if sym_count>=2 then begin p:=1; while 2*p0 do begin for h:=p to sym_count-1 do begin i:=h; t:=syms[i]; o:=offsets[i]; repeat if syms[i-p].name<=t.name then break; syms[i]:=syms[i-p]; offsets[i]:=offsets[i-p]; dec(i,p); until i=2 then begin p:=1; while 2*p0 do begin for h:=p to sym_count-1 do begin i:=h; t:=syms[i]; o:=offsets[i]; repeat if syms[i-p].value<=t.value then break; syms[i]:=syms[i-p]; offsets[i]:=offsets[i-p]; dec(i,p); until iinitrtti) and is_objc_class_or_protocol(def)) then current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_nil_dataptr) else current_asmdata.asmlists[al_rtti].concat(Tai_const.Create_sym(ref_rtti(def,rt))); end; function TRTTIWriter.ref_rtti(def:tdef;rt:trttitype):tasmsymbol; begin result:=current_asmdata.RefAsmSymbol(def.rtti_mangledname(rt)); if (cs_create_pic in current_settings.moduleswitches) and assigned(current_procinfo) then include(current_procinfo.flags,pi_needs_got); end; procedure TRTTIWriter.write_rtti(def:tdef;rt:trttitype); var rttilab : tasmsymbol; begin { only write rtti of definitions from the current module } if not findunitsymtable(def.owner).iscurrentunit then exit; { check if separate initrtti is actually needed } if (rt=initrtti) and (not def.needs_separate_initrtti) then rt:=fullrtti; { prevent recursion } if rttidefstate[rt] in def.defstates then exit; include(def.defstates,rttidefstate[rt]); { write first all dependencies } write_child_rtti_data(def,rt); { write rtti data } rttilab:=current_asmdata.DefineAsmSymbol(tstoreddef(def).rtti_mangledname(rt),AB_GLOBAL,AT_DATA); maybe_new_object_file(current_asmdata.asmlists[al_rtti]); new_section(current_asmdata.asmlists[al_rtti],sec_rodata,rttilab.name,const_align(sizeof(pint))); current_asmdata.asmlists[al_rtti].concat(Tai_symbol.Create_global(rttilab,0)); write_rtti_data(def,rt); current_asmdata.asmlists[al_rtti].concat(Tai_symbol_end.Create(rttilab)); write_rtti_extrasyms(def,rt,rttilab); end; function TRTTIWriter.get_rtti_label(def:tdef;rt:trttitype):tasmsymbol; begin result:=current_asmdata.RefAsmSymbol(def.rtti_mangledname(rt)); if (cs_create_pic in current_settings.moduleswitches) and assigned(current_procinfo) then include(current_procinfo.flags,pi_needs_got); end; function TRTTIWriter.get_rtti_label_ord2str(def:tdef;rt:trttitype):tasmsymbol; begin result:=current_asmdata.RefAsmSymbol(def.rtti_mangledname(rt)+'_o2s'); if (cs_create_pic in current_settings.moduleswitches) and assigned(current_procinfo) then include(current_procinfo.flags,pi_needs_got); end; function TRTTIWriter.get_rtti_label_str2ord(def:tdef;rt:trttitype):tasmsymbol; begin result:=current_asmdata.RefAsmSymbol(def.rtti_mangledname(rt)+'_s2o'); if (cs_create_pic in current_settings.moduleswitches) and assigned(current_procinfo) then include(current_procinfo.flags,pi_needs_got); end; end.