{ Copyright (c) 2000-2002 by Florian Klaempfl Type checking and register allocation for memory related nodes 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 nmem; {$i fpcdefs.inc} interface uses node, symdef,symsym,symtable,symtype; type tloadvmtaddrnode = class(tunarynode) constructor create(l : tnode);virtual; function pass_1 : tnode;override; function pass_typecheck:tnode;override; end; tloadvmtaddrnodeclass = class of tloadvmtaddrnode; tloadparentfpnode = class(tunarynode) parentpd : tprocdef; parentpdderef : tderef; constructor create(pd:tprocdef);virtual; constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override; procedure ppuwrite(ppufile:tcompilerppufile);override; procedure buildderefimpl;override; procedure derefimpl;override; function pass_1 : tnode;override; function pass_typecheck:tnode;override; function docompare(p: tnode): boolean; override; function dogetcopy : tnode;override; end; tloadparentfpnodeclass = class of tloadparentfpnode; taddrnode = class(tunarynode) getprocvardef : tprocvardef; getprocvardefderef : tderef; constructor create(l : tnode);virtual; constructor create_internal(l : tnode); virtual; constructor create_internal_nomark(l : tnode); virtual; constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override; procedure ppuwrite(ppufile:tcompilerppufile);override; procedure mark_write;override; procedure buildderefimpl;override; procedure derefimpl;override; function docompare(p: tnode): boolean; override; function dogetcopy : tnode;override; function pass_1 : tnode;override; function pass_typecheck:tnode;override; private mark_read_written: boolean; end; taddrnodeclass = class of taddrnode; tderefnode = class(tunarynode) constructor create(l : tnode);virtual; function pass_1 : tnode;override; function pass_typecheck:tnode;override; procedure mark_write;override; end; tderefnodeclass = class of tderefnode; tsubscriptnode = class(tunarynode) vs : tfieldvarsym; vsderef : tderef; constructor create(varsym : tsym;l : tnode);virtual; constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override; procedure ppuwrite(ppufile:tcompilerppufile);override; procedure buildderefimpl;override; procedure derefimpl;override; function dogetcopy : tnode;override; function pass_1 : tnode;override; function docompare(p: tnode): boolean; override; function pass_typecheck:tnode;override; procedure mark_write;override; end; tsubscriptnodeclass = class of tsubscriptnode; tvecnode = class(tbinarynode) constructor create(l,r : tnode);virtual; function pass_1 : tnode;override; function pass_typecheck:tnode;override; procedure mark_write;override; end; tvecnodeclass = class of tvecnode; twithnode = class(tunarynode) constructor create(l:tnode); destructor destroy;override; constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override; procedure ppuwrite(ppufile:tcompilerppufile);override; function dogetcopy : tnode;override; function pass_1 : tnode;override; function docompare(p: tnode): boolean; override; function pass_typecheck:tnode;override; end; twithnodeclass = class of twithnode; var cloadvmtaddrnode : tloadvmtaddrnodeclass= tloadvmtaddrnode; caddrnode : taddrnodeclass= taddrnode; cderefnode : tderefnodeclass= tderefnode; csubscriptnode : tsubscriptnodeclass= tsubscriptnode; cvecnode : tvecnodeclass= tvecnode; cwithnode : twithnodeclass= twithnode; cloadparentfpnode : tloadparentfpnodeclass = tloadparentfpnode; function is_big_untyped_addrnode(p: tnode): boolean; implementation uses globtype,systems,constexp, cutils,verbose,globals, symconst,symbase,defutil,defcmp, nbas,nutils, wpobase, htypechk,pass_1,ncal,nld,ncon,ncnv,cgbase,procinfo ; {***************************************************************************** TLOADVMTADDRNODE *****************************************************************************} constructor tloadvmtaddrnode.create(l : tnode); begin inherited create(loadvmtaddrn,l); end; function tloadvmtaddrnode.pass_typecheck:tnode; var defaultresultdef : boolean; begin result:=nil; typecheckpass(left); if codegenerror then exit; case left.resultdef.typ of classrefdef : resultdef:=left.resultdef; objectdef, recorddef: { access to the classtype while specializing? } if (df_generic in left.resultdef.defoptions) then begin defaultresultdef:=true; if assigned(current_structdef) then begin if assigned(current_structdef.genericdef) then if current_structdef.genericdef=left.resultdef then begin resultdef:=tclassrefdef.create(current_structdef); defaultresultdef:=false; end else message(parser_e_cant_create_generics_of_this_type); end else message(parser_e_cant_create_generics_of_this_type); if defaultresultdef then resultdef:=tclassrefdef.create(left.resultdef); end else resultdef:=tclassrefdef.create(left.resultdef); else Message(parser_e_pointer_to_class_expected); end; end; function tloadvmtaddrnode.pass_1 : tnode; var vs: tsym; begin result:=nil; expectloc:=LOC_REGISTER; if left.nodetype<>typen then begin { make sure that the isa field is loaded correctly in case of the non-fragile ABI } if is_objcclass(left.resultdef) and (left.nodetype<>typen) then begin vs:=search_struct_member(tobjectdef(left.resultdef),'ISA'); if not assigned(vs) or (tsym(vs).typ<>fieldvarsym) then internalerror(2009092502); result:=csubscriptnode.create(tfieldvarsym(vs),left); inserttypeconv_internal(result,resultdef); { reused } left:=nil; end else firstpass(left) end else if not is_objcclass(left.resultdef) and not is_objcclassref(left.resultdef) then begin if not(nf_ignore_for_wpo in flags) and (not assigned(current_procinfo) or (po_inline in current_procinfo.procdef.procoptions) or wpoinfomanager.symbol_live(current_procinfo.procdef.mangledname)) then begin { keep track of which classes might be instantiated via a classrefdef } if (left.resultdef.typ=classrefdef) then tobjectdef(tclassrefdef(left.resultdef).pointeddef).register_maybe_created_object_type else if (left.resultdef.typ=objectdef) then tobjectdef(left.resultdef).register_maybe_created_object_type end end; end; {***************************************************************************** TLOADPARENTFPNODE *****************************************************************************} constructor tloadparentfpnode.create(pd:tprocdef); begin inherited create(loadparentfpn,nil); if not assigned(pd) then internalerror(200309288); if (pd.parast.symtablelevel>current_procinfo.procdef.parast.symtablelevel) then internalerror(200309284); parentpd:=pd; end; constructor tloadparentfpnode.ppuload(t:tnodetype;ppufile:tcompilerppufile); begin inherited ppuload(t,ppufile); ppufile.getderef(parentpdderef); end; procedure tloadparentfpnode.ppuwrite(ppufile:tcompilerppufile); begin inherited ppuwrite(ppufile); ppufile.putderef(parentpdderef); end; procedure tloadparentfpnode.buildderefimpl; begin inherited buildderefimpl; parentpdderef.build(parentpd); end; procedure tloadparentfpnode.derefimpl; begin inherited derefimpl; parentpd:=tprocdef(parentpdderef.resolve); end; function tloadparentfpnode.docompare(p: tnode): boolean; begin result:= inherited docompare(p) and (tloadparentfpnode(p).parentpd=parentpd); end; function tloadparentfpnode.dogetcopy : tnode; var p : tloadparentfpnode; begin p:=tloadparentfpnode(inherited dogetcopy); p.parentpd:=parentpd; dogetcopy:=p; end; function tloadparentfpnode.pass_typecheck:tnode; {$ifdef dummy} var currpi : tprocinfo; hsym : tparavarsym; {$endif dummy} begin result:=nil; resultdef:=voidpointertype; {$ifdef dummy} { currently parentfps are never loaded in registers (FK) } if (current_procinfo.procdef.parast.symtablelevel<>parentpd.parast.symtablelevel) then begin currpi:=current_procinfo; { walk parents } while (currpi.procdef.owner.symtablelevel>parentpd.parast.symtablelevel) do begin currpi:=currpi.parent; if not assigned(currpi) then internalerror(2005040602); hsym:=tparavarsym(currpi.procdef.parast.Find('parentfp')); if not assigned(hsym) then internalerror(2005040601); hsym.varregable:=vr_none; end; end; {$endif dummy} end; function tloadparentfpnode.pass_1 : tnode; begin result:=nil; expectloc:=LOC_REGISTER; end; {***************************************************************************** TADDRNODE *****************************************************************************} constructor taddrnode.create(l : tnode); begin inherited create(addrn,l); getprocvardef:=nil; mark_read_written := true; end; constructor taddrnode.create_internal(l : tnode); begin self.create(l); include(flags,nf_internal); end; constructor taddrnode.create_internal_nomark(l : tnode); begin self.create_internal(l); mark_read_written := false; end; constructor taddrnode.ppuload(t:tnodetype;ppufile:tcompilerppufile); begin inherited ppuload(t,ppufile); ppufile.getderef(getprocvardefderef); end; procedure taddrnode.ppuwrite(ppufile:tcompilerppufile); begin inherited ppuwrite(ppufile); ppufile.putderef(getprocvardefderef); end; procedure Taddrnode.mark_write; begin {@procvar:=nil is legal in Delphi mode.} left.mark_write; end; procedure taddrnode.buildderefimpl; begin inherited buildderefimpl; getprocvardefderef.build(getprocvardef); end; procedure taddrnode.derefimpl; begin inherited derefimpl; getprocvardef:=tprocvardef(getprocvardefderef.resolve); end; function taddrnode.docompare(p: tnode): boolean; begin result:= inherited docompare(p) and (taddrnode(p).getprocvardef=getprocvardef); end; function taddrnode.dogetcopy : tnode; var p : taddrnode; begin p:=taddrnode(inherited dogetcopy); p.getprocvardef:=getprocvardef; dogetcopy:=p; end; function taddrnode.pass_typecheck:tnode; var hp : tnode; hsym : tfieldvarsym; isprocvar : boolean; begin result:=nil; typecheckpass(left); if codegenerror then exit; make_not_regable(left,[ra_addr_regable,ra_addr_taken]); { don't allow constants, for internal use we also allow taking the address of strings } if is_constnode(left) and not( (nf_internal in flags) and (left.nodetype in [stringconstn]) ) then begin CGMessagePos(left.fileinfo,type_e_no_addr_of_constant); exit; end; { Handle @proc special, also @procvar in tp-mode needs special handling } if (left.resultdef.typ=procdef) or ( (left.resultdef.typ=procvardef) and ((m_tp_procvar in current_settings.modeswitches) or (m_mac_procvar in current_settings.modeswitches)) ) then begin isprocvar:=(left.resultdef.typ=procvardef); if not isprocvar then begin left:=ctypeconvnode.create_proc_to_procvar(left); left.fileinfo:=fileinfo; typecheckpass(left); end; { In tp procvar mode the result is always a voidpointer. Insert a typeconversion to voidpointer. For methodpointers we need to load the proc field } if (m_tp_procvar in current_settings.modeswitches) or (m_mac_procvar in current_settings.modeswitches) then begin if tabstractprocdef(left.resultdef).is_addressonly then begin result:=ctypeconvnode.create_internal(left,voidpointertype); include(result.flags,nf_load_procvar); left:=nil; end else begin { For procvars and for nested routines we need to return the proc field of the methodpointer } if isprocvar or is_nested_pd(tabstractprocdef(left.resultdef)) then begin { find proc field in methodpointer record } hsym:=tfieldvarsym(trecorddef(methodpointertype).symtable.Find('proc')); if not assigned(hsym) then internalerror(200412041); { Load tmehodpointer(left).proc } result:=csubscriptnode.create( hsym, ctypeconvnode.create_internal(left,methodpointertype)); left:=nil; end else CGMessage(type_e_variable_id_expected); end; end else begin { Return the typeconvn only } result:=left; left:=nil; end; end else begin { what are we getting the address from an absolute sym? } hp:=left; while assigned(hp) and (hp.nodetype in [typeconvn,vecn,derefn,subscriptn]) do hp:=tunarynode(hp).left; if not assigned(hp) then internalerror(200412042); {$ifdef i386} if (hp.nodetype=loadn) and ((tloadnode(hp).symtableentry.typ=absolutevarsym) and tabsolutevarsym(tloadnode(hp).symtableentry).absseg) then begin if not(nf_typedaddr in flags) then resultdef:=voidfarpointertype else resultdef:=tpointerdef.createfar(left.resultdef); end else {$endif i386} if (hp.nodetype=loadn) and (tloadnode(hp).symtableentry.typ=absolutevarsym) and {$ifdef i386} not(tabsolutevarsym(tloadnode(hp).symtableentry).absseg) and {$endif i386} (tabsolutevarsym(tloadnode(hp).symtableentry).abstyp=toaddr) then begin if nf_typedaddr in flags then result:=cpointerconstnode.create(tabsolutevarsym(tloadnode(hp).symtableentry).addroffset,tpointerdef.create(left.resultdef)) else result:=cpointerconstnode.create(tabsolutevarsym(tloadnode(hp).symtableentry).addroffset,voidpointertype); exit; end else if (nf_internal in flags) or valid_for_addr(left,true) then begin if not(nf_typedaddr in flags) then resultdef:=voidpointertype else resultdef:=tpointerdef.create(left.resultdef); end else CGMessage(type_e_variable_id_expected); end; if mark_read_written then begin { This is actually only "read", but treat it nevertheless as } { modified due to the possible use of pointers } { To avoid false positives regarding "uninitialised" } { warnings when using arrays, perform it in two steps } set_varstate(left,vs_written,[]); { vsf_must_be_valid so it doesn't get changed into } { vsf_referred_not_inited } set_varstate(left,vs_read,[vsf_must_be_valid]); end; end; function taddrnode.pass_1 : tnode; begin result:=nil; firstpass(left); if codegenerror then exit; { is this right for object of methods ?? } expectloc:=LOC_REGISTER; end; {***************************************************************************** TDEREFNODE *****************************************************************************} constructor tderefnode.create(l : tnode); begin inherited create(derefn,l); end; function tderefnode.pass_typecheck:tnode; begin result:=nil; typecheckpass(left); set_varstate(left,vs_read,[vsf_must_be_valid]); if codegenerror then exit; { tp procvar support } maybe_call_procvar(left,true); if left.resultdef.typ=pointerdef then resultdef:=tpointerdef(left.resultdef).pointeddef else CGMessage(parser_e_invalid_qualifier); end; procedure Tderefnode.mark_write; begin include(flags,nf_write); end; function tderefnode.pass_1 : tnode; begin result:=nil; firstpass(left); if codegenerror then exit; expectloc:=LOC_REFERENCE; end; {***************************************************************************** TSUBSCRIPTNODE *****************************************************************************} constructor tsubscriptnode.create(varsym : tsym;l : tnode); begin inherited create(subscriptn,l); { vs should be changed to tsym! } vs:=tfieldvarsym(varsym); end; constructor tsubscriptnode.ppuload(t:tnodetype;ppufile:tcompilerppufile); begin inherited ppuload(t,ppufile); ppufile.getderef(vsderef); end; procedure tsubscriptnode.ppuwrite(ppufile:tcompilerppufile); begin inherited ppuwrite(ppufile); ppufile.putderef(vsderef); end; procedure tsubscriptnode.buildderefimpl; begin inherited buildderefimpl; vsderef.build(vs); end; procedure tsubscriptnode.derefimpl; begin inherited derefimpl; vs:=tfieldvarsym(vsderef.resolve); end; function tsubscriptnode.dogetcopy : tnode; var p : tsubscriptnode; begin p:=tsubscriptnode(inherited dogetcopy); p.vs:=vs; dogetcopy:=p; end; function tsubscriptnode.pass_typecheck:tnode; begin result:=nil; typecheckpass(left); { tp procvar support } maybe_call_procvar(left,true); resultdef:=vs.vardef; // don't put records from which we load float fields // in integer registers if (left.resultdef.typ=recorddef) and (resultdef.typ=floatdef) then make_not_regable(left,[ra_addr_regable]); end; procedure Tsubscriptnode.mark_write; begin include(flags,nf_write); end; function tsubscriptnode.pass_1 : tnode; begin result:=nil; firstpass(left); if codegenerror then exit; { several object types must be dereferenced implicitly } if is_implicit_pointer_object_type(left.resultdef) then expectloc:=LOC_REFERENCE else begin case left.expectloc of LOC_REGISTER, LOC_SUBSETREG: // can happen for function results on win32 and darwin/x86 if (left.resultdef.size > sizeof(pint)) then expectloc:=LOC_REFERENCE else expectloc:=LOC_SUBSETREG; LOC_CREGISTER, LOC_CSUBSETREG: expectloc:=LOC_CSUBSETREG; LOC_REFERENCE, LOC_CREFERENCE: expectloc:=left.expectloc; else internalerror(20060521); end; end; end; function tsubscriptnode.docompare(p: tnode): boolean; begin docompare := inherited docompare(p) and (vs = tsubscriptnode(p).vs); end; {***************************************************************************** TVECNODE *****************************************************************************} constructor tvecnode.create(l,r : tnode); begin inherited create(vecn,l,r); end; function tvecnode.pass_typecheck:tnode; var hightree: tnode; htype,elementdef : tdef; valid : boolean; begin result:=nil; typecheckpass(left); typecheckpass(right); { implicitly convert stringconstant to stringdef, see tbs/tb0476.pp for a test } if (left.nodetype=stringconstn) and (tstringconstnode(left).cst_type=cst_conststring) then begin if tstringconstnode(left).len>255 then inserttypeconv(left,cansistringtype) else inserttypeconv(left,cshortstringtype); end; { In p[1] p is always valid, it is not possible to declared a shortstring or normal array that has undefined number of elements. Dynamic array and ansi/widestring needs to be valid } valid:=is_dynamic_array(left.resultdef) or is_ansistring(left.resultdef) or is_wide_or_unicode_string(left.resultdef) or { implicit pointer dereference -> pointer is read } (left.resultdef.typ = pointerdef); if valid then set_varstate(left,vs_read,[vsf_must_be_valid]); { A vecn is, just like a loadn, always part of an expression with its own read/write and must_be_valid semantics. Therefore we don't have to do anything else here, just like for loadn's } set_varstate(right,vs_read,[vsf_must_be_valid]); if codegenerror then exit; { maybe type conversion for the index value, but do not convert enums, char (why not? (JM)) and do not convert range nodes } if (right.nodetype<>rangen) and (is_integer(right.resultdef) or is_boolean(right.resultdef) or (left.resultdef.typ<>arraydef)) then case left.resultdef.typ of arraydef: if ado_isvariant in Tarraydef(left.resultdef).arrayoptions then {Variant arrays are a special array, can have negative indexes and would therefore need s32bit. However, they should not appear in a vecn, as they are handled in handle_variantarray in pexpr.pas. Therefore, encountering a variant array is an internal error... } internalerror(200707031) else if is_special_array(left.resultdef) then {Arrays without a high bound (dynamic arrays, open arrays) are zero based, convert indexes into these arrays to aword.} inserttypeconv(right,uinttype) { convert between pasbool and cbool if necessary } else if is_boolean(right.resultdef) then inserttypeconv(right,tarraydef(left.resultdef).rangedef) else {Convert array indexes to low_bound..high_bound.} inserttypeconv(right,Torddef.create(Torddef(sinttype).ordtype, int64(Tarraydef(left.resultdef).lowrange), int64(Tarraydef(left.resultdef).highrange) )); stringdef: if is_open_string(left.resultdef) then inserttypeconv(right,u8inttype) else if is_shortstring(left.resultdef) then {Convert shortstring indexes to 0..length.} inserttypeconv(right,Torddef.create(u8bit,0,int64(Tstringdef(left.resultdef).len))) else {Convert indexes into dynamically allocated strings to aword.} inserttypeconv(right,uinttype); else {Others, i.e. pointer indexes to aint.} inserttypeconv(right,sinttype); end; { although we never put regular arrays or shortstrings in registers, it's possible that another type was typecasted to a small record that has a field of one of these types -> in that case the record can't be a regvar either } if ((left.resultdef.typ=arraydef) and not is_special_array(left.resultdef)) or ((left.resultdef.typ=stringdef) and (tstringdef(left.resultdef).stringtype in [st_shortstring,st_longstring])) then make_not_regable(left,[ra_addr_regable]); case left.resultdef.typ of arraydef : begin { check type of the index value } if (compare_defs(right.resultdef,tarraydef(left.resultdef).rangedef,right.nodetype)=te_incompatible) then IncompatibleTypes(right.resultdef,tarraydef(left.resultdef).rangedef); if right.nodetype=rangen then resultdef:=left.resultdef else resultdef:=Tarraydef(left.resultdef).elementdef; { if we are range checking an open array or array of const, we } { need to load the high parameter. If the current procedure is } { nested inside the procedure to which the open array/of const } { was passed, then the high parameter must not be a regvar. } { So create a loadnode for the high parameter here and } { typecheck it, then the loadnode will make the high parameter } { not regable. Otherwise this would only happen inside pass_2, } { which is too late since by then the regvars are already } { assigned (pass_1 is also already too late, because then the } { regvars of the parent are also already assigned). } { webtbs/tw8975 } if (cs_check_range in current_settings.localswitches) and (is_open_array(left.resultdef) or is_array_of_const(left.resultdef)) and { cdecl functions don't have high() so we can not check the range } { (can't use current_procdef, since it may be a nested procedure) } not(tprocdef(tparasymtable(tparavarsym(tloadnode(left).symtableentry).owner).defowner).proccalloption in cdecl_pocalls) then begin { load_high_value_node already typechecks } hightree:=load_high_value_node(tparavarsym(tloadnode(left).symtableentry)); hightree.free; end; end; pointerdef : begin { are we accessing a pointer[], then convert the pointer to an array first, in FPC this is allowed for all pointers (except voidpointer) in delphi/tp7 it's only allowed for pchars. } if not is_voidpointer(left.resultdef) and ( (cs_pointermath in current_settings.localswitches) or tpointerdef(left.resultdef).has_pointer_math or is_pchar(left.resultdef) or is_pwidechar(left.resultdef) ) then begin { convert pointer to array } htype:=tarraydef.create_from_pointer(tpointerdef(left.resultdef).pointeddef); inserttypeconv(left,htype); if right.nodetype=rangen then resultdef:=htype else resultdef:=tarraydef(htype).elementdef; end else CGMessage(type_e_array_required); end; stringdef : begin case tstringdef(left.resultdef).stringtype of st_unicodestring, st_widestring : elementdef:=cwidechartype; st_ansistring : elementdef:=cchartype; st_longstring : elementdef:=cchartype; st_shortstring : elementdef:=cchartype; end; if right.nodetype=rangen then begin htype:=Tarraydef.create_from_pointer(elementdef); resultdef:=htype; end else begin { indexed access to 0 element is only allowed for shortstrings } if (right.nodetype=ordconstn) and (Tordconstnode(right).value.svalue=0) and not is_shortstring(left.resultdef) then CGMessage(cg_e_can_access_element_zero); resultdef:=elementdef; end; end; variantdef : resultdef:=cvarianttype; else CGMessage(type_e_array_required); end; end; procedure Tvecnode.mark_write; begin include(flags,nf_write); end; function tvecnode.pass_1 : tnode; begin result:=nil; firstpass(left); firstpass(right); if codegenerror then exit; if (nf_callunique in flags) and (is_ansistring(left.resultdef) or is_unicodestring(left.resultdef) or (is_widestring(left.resultdef) and not(tf_winlikewidestring in target_info.flags))) then begin left := ctypeconvnode.create_internal(ccallnode.createintern('fpc_'+tstringdef(left.resultdef).stringtypname+'_unique', ccallparanode.create( ctypeconvnode.create_internal(left,voidpointertype),nil)), left.resultdef); firstpass(left); { double resultdef passes somwhere else may cause this to be } { reset though :/ } exclude(flags,nf_callunique); end else if is_widestring(left.resultdef) and (tf_winlikewidestring in target_info.flags) then exclude(flags,nf_callunique); { a range node as array index can only appear in function calls, and those convert the range node into something else in tcallnode.gen_high_tree } if (right.nodetype=rangen) then CGMessagePos(right.fileinfo,parser_e_illegal_expression) else if (not is_packed_array(left.resultdef)) or ((tarraydef(left.resultdef).elepackedbitsize mod 8) = 0) then if left.expectloc=LOC_CREFERENCE then expectloc:=LOC_CREFERENCE else expectloc:=LOC_REFERENCE else if left.expectloc=LOC_CREFERENCE then expectloc:=LOC_CSUBSETREF else expectloc:=LOC_SUBSETREF; end; {***************************************************************************** TWITHNODE *****************************************************************************} constructor twithnode.create(l:tnode); begin inherited create(withn,l); fileinfo:=l.fileinfo; end; destructor twithnode.destroy; begin inherited destroy; end; constructor twithnode.ppuload(t:tnodetype;ppufile:tcompilerppufile); begin inherited ppuload(t,ppufile); end; procedure twithnode.ppuwrite(ppufile:tcompilerppufile); begin inherited ppuwrite(ppufile); end; function twithnode.dogetcopy : tnode; var p : twithnode; begin p:=twithnode(inherited dogetcopy); result:=p; end; function twithnode.pass_typecheck:tnode; begin result:=nil; resultdef:=voidtype; if assigned(left) then typecheckpass(left); end; function twithnode.pass_1 : tnode; begin result:=nil; expectloc:=LOC_VOID; end; function twithnode.docompare(p: tnode): boolean; begin docompare := inherited docompare(p); end; function is_big_untyped_addrnode(p: tnode): boolean; begin is_big_untyped_addrnode:=(p.nodetype=addrn) and not (nf_typedaddr in p.flags) and (taddrnode(p).left.resultdef.size > 1); end; end.