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5a2ccfff52
fpc/compiler/symtable.pas
Jonas Maebe 5a2ccfff52 --WARNING: start build process with FPC 2.2.4; won't work when 
starting with a previous 2.3.1 or compiler built from the objc branch
  + added basic objcprotocol support (only for external protocols
    currently)
     o use in type declaration: "type xp = objcprotocol ... end;"
     o when defining a root class that implements it:
       "type yc = objcclass(xp) ... end" (note: no support yet
       for something like "objcclass(id,xp)" or so)
     o when defining a non-root class that implements a protocol:
       "type zc = objcclass(nsobject,xp) ... end"
     o includes support for "required" and "optional" sections
     o no support yet for the objcprotocol(<protocol>) expression
       that enables getting a class instance representing the
       protocol (e.g., for use with "conformsToProtocol:")
     o message names have to specified in protocol declarations,
       but if an objcclass implements a protocol, the message names do
       not have to be repeated (but if they are, they have to match;
       the same goes when overriding inherited methods)
  + allow specifying the external name of Objective-C classes and
    protocols, since classes and protocols can have the same name
    (and you cannot use the same Pascal identifier in such caseq)
  + added NSObject protocol, and make the NSObject class use it
  + added missing NSObject class methods that have the same name
    as instance methods (added "class" name prefix to avoid clashes)
  * fixed several cases where the compiler did not treat Objective-C
    classes/protocols the same as Object Pascal classes/interfaces
    (a.o., forward declarations, alignment, regvars, several type
     conversions, ...)
  * allow "override" directive in objcclass declarations, and print
    a hint if it's forgotten in an external declaration (because it
    doesn't really matter there, and may make automated header
    conversion harder than necessary) and an error if will be used in
    a non-external declaration (because it is not possible to start
    a new vmt entry-tree in Objective-C, you can only override parent
    methods)
  * reject objcclasses/protocols as parameters to typeof()
  * don't try to test VMT validity of objcclasses/protocols

git-svn-id: branches/objc@13375 -
2009-07-09 20:48:28 +00:00

2264 lines
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{
Copyright (c) 1998-2002 by Florian Klaempfl, Pierre Muller
This unit handles the symbol tables
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 symtable;
{$i fpcdefs.inc}
interface
uses
{ common }
cutils,cclasses,
{ global }
cpuinfo,globtype,tokens,
{ symtable }
symconst,symbase,symtype,symdef,symsym,
{ ppu }
ppu,
{ assembler }
aasmtai,aasmdata
;
{****************************************************************************
Symtable types
****************************************************************************}
type
tstoredsymtable = class(TSymtable)
private
b_needs_init_final : boolean;
procedure _needs_init_final(sym:TObject;arg:pointer);
procedure check_forward(sym:TObject;arg:pointer);
procedure labeldefined(sym:TObject;arg:pointer);
procedure varsymbolused(sym:TObject;arg:pointer);
procedure TestPrivate(sym:TObject;arg:pointer);
procedure objectprivatesymbolused(sym:TObject;arg:pointer);
procedure loaddefs(ppufile:tcompilerppufile);
procedure loadsyms(ppufile:tcompilerppufile);
procedure writedefs(ppufile:tcompilerppufile);
procedure writesyms(ppufile:tcompilerppufile);
public
procedure insert(sym:TSymEntry;checkdup:boolean=true);override;
procedure delete(sym:TSymEntry);override;
{ load/write }
procedure ppuload(ppufile:tcompilerppufile);virtual;
procedure ppuwrite(ppufile:tcompilerppufile);virtual;
procedure buildderef;virtual;
procedure buildderefimpl;virtual;
procedure deref;virtual;
procedure derefimpl;virtual;
function checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;override;
procedure reset_all_defs;virtual;
procedure allsymbolsused;
procedure allprivatesused;
procedure check_forwards;
procedure checklabels;
function needs_init_final : boolean;
procedure testfordefaultproperty(sym:TObject;arg:pointer);
end;
tabstractrecordsymtable = class(tstoredsymtable)
public
usefieldalignment, { alignment to use for fields (PACKRECORDS value), C_alignment is C style }
recordalignment, { alignment desired when inserting this record }
fieldalignment, { alignment current alignment used when fields are inserted }
padalignment : shortint; { size to a multiple of which the symtable has to be rounded up }
constructor create(const n:string;usealign:shortint);
procedure ppuload(ppufile:tcompilerppufile);override;
procedure ppuwrite(ppufile:tcompilerppufile);override;
procedure alignrecord(fieldoffset:aint;varalign:shortint);
procedure addfield(sym:tfieldvarsym;vis:tvisibility);
procedure addalignmentpadding;
procedure insertdef(def:TDefEntry);override;
function is_packed: boolean;
protected
_datasize : aint;
{ size in bits of the data in case of bitpacked record. Only important during construction, }
{ no need to save in/restore from ppu file. datasize is always (databitsize+7) div 8. }
databitsize : aint;
procedure setdatasize(val: aint);
public
property datasize : aint read _datasize write setdatasize;
end;
trecordsymtable = class(tabstractrecordsymtable)
public
constructor create(usealign:shortint);
procedure insertunionst(unionst : trecordsymtable;offset : longint);
end;
tObjectSymtable = class(tabstractrecordsymtable)
public
constructor create(adefowner:tdef;const n:string;usealign:shortint);
function checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;override;
end;
{ tabstractlocalsymtable }
tabstractlocalsymtable = class(tstoredsymtable)
public
procedure ppuwrite(ppufile:tcompilerppufile);override;
function count_locals:longint;
end;
tlocalsymtable = class(tabstractlocalsymtable)
public
constructor create(adefowner:tdef;level:byte);
function checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;override;
end;
tparasymtable = class(tabstractlocalsymtable)
public
constructor create(adefowner:tdef;level:byte);
function checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;override;
end;
tabstractuniTSymtable = class(tstoredsymtable)
public
constructor create(const n : string;id:word);
function iscurrentunit:boolean;override;
end;
tglobalsymtable = class(tabstractuniTSymtable)
public
unittypecount : word;
constructor create(const n : string;id:word);
procedure ppuload(ppufile:tcompilerppufile);override;
procedure ppuwrite(ppufile:tcompilerppufile);override;
function checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;override;
end;
tstaticsymtable = class(tabstractuniTSymtable)
public
constructor create(const n : string;id:word);
procedure ppuload(ppufile:tcompilerppufile);override;
procedure ppuwrite(ppufile:tcompilerppufile);override;
function checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;override;
end;
twithsymtable = class(TSymtable)
withrefnode : tobject; { tnode }
constructor create(aowner:tdef;ASymList:TFPHashObjectList;refnode:tobject{tnode});
destructor destroy;override;
procedure clear;override;
procedure insertdef(def:TDefEntry);override;
end;
tstt_excepTSymtable = class(TSymtable)
public
constructor create;
end;
tmacrosymtable = class(tstoredsymtable)
public
constructor create(exported: boolean);
end;
var
systemunit : tglobalsymtable; { pointer to the system unit }
{****************************************************************************
Functions
****************************************************************************}
{*** Misc ***}
function FullTypeName(def,otherdef:tdef):string;
procedure incompatibletypes(def1,def2:tdef);
procedure hidesym(sym:TSymEntry);
procedure duplicatesym(var hashedid:THashedIDString;dupsym,origsym:TSymEntry);
{*** Search ***}
procedure addsymref(sym:tsym);
function is_visible_for_object(symst:tsymtable;symvisibility:tvisibility;contextobjdef:tobjectdef):boolean;
function is_visible_for_object(pd:tprocdef;contextobjdef:tobjectdef):boolean;
function is_visible_for_object(sym:tsym;contextobjdef:tobjectdef):boolean;
function searchsym(const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
function searchsym_type(const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
function searchsym_in_module(pm:pointer;const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
function searchsym_in_named_module(const unitname, symname: TIDString; out srsym: tsym; out srsymtable: tsymtable): boolean;
function searchsym_in_class(classh,contextclassh:tobjectdef;const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
function searchsym_in_class_by_msgint(classh:tobjectdef;msgid:longint;out srdef : tdef;out srsym:tsym;out srsymtable:TSymtable):boolean;
function searchsym_in_class_by_msgstr(classh:tobjectdef;const s:string;out srsym:tsym;out srsymtable:TSymtable):boolean;
function search_system_type(const s: TIDString): ttypesym;
function search_named_unit_globaltype(const unitname, typename: TIDString): ttypesym;
function search_class_member(pd : tobjectdef;const s : string):tsym;
function search_assignment_operator(from_def,to_def:Tdef):Tprocdef;
{Looks for macro s (must be given in upper case) in the macrosymbolstack, }
{and returns it if found. Returns nil otherwise.}
function search_macro(const s : string):tsym;
{ Additionally to searching for a macro, also checks whether it's still }
{ actually defined (could be disable using "undef") }
function defined_macro(const s : string):boolean;
{*** Object Helpers ***}
function search_default_property(pd : tobjectdef) : tpropertysym;
{*** Macro Helpers ***}
{If called initially, the following procedures manipulate macros in }
{initialmacrotable, otherwise they manipulate system macros local to a module.}
{Name can be given in any case (it will be converted to upper case).}
procedure def_system_macro(const name : string);
procedure set_system_macro(const name, value : string);
procedure set_system_compvar(const name, value : string);
procedure undef_system_macro(const name : string);
{*** symtable stack ***}
{ $ifdef DEBUG
procedure test_symtablestack;
procedure list_symtablestack;
$endif DEBUG}
{$ifdef UNITALIASES}
type
punit_alias = ^tunit_alias;
tunit_alias = object(TNamedIndexItem)
newname : pshortstring;
constructor init(const n:string);
destructor done;virtual;
end;
var
unitaliases : pdictionary;
procedure addunitalias(const n:string);
function getunitalias(const n:string):string;
{$endif UNITALIASES}
{*** Init / Done ***}
procedure IniTSymtable;
procedure DoneSymtable;
const
overloaded_names : array [NOTOKEN..last_overloaded] of string[16] =
('error',
'plus','minus','star','slash','equal',
'greater','lower','greater_or_equal',
'lower_or_equal',
'sym_diff','starstar',
'as','is','in','or',
'and','div','mod','not','shl','shr','xor',
'assign');
implementation
uses
{ global }
verbose,globals,
{ target }
systems,
{ symtable }
symutil,defcmp,defutil,
{ module }
fmodule,
{ codegen }
procinfo
;
var
dupnr : longint; { unique number for duplicate symbols }
{*****************************************************************************
TStoredSymtable
*****************************************************************************}
procedure tstoredsymtable.insert(sym:TSymEntry;checkdup:boolean=true);
begin
inherited insert(sym,checkdup);
end;
procedure tstoredsymtable.delete(sym:TSymEntry);
begin
inherited delete(sym);
end;
procedure tstoredsymtable.ppuload(ppufile:tcompilerppufile);
begin
{ load definitions }
loaddefs(ppufile);
{ load symbols }
loadsyms(ppufile);
end;
procedure tstoredsymtable.ppuwrite(ppufile:tcompilerppufile);
begin
{ write definitions }
writedefs(ppufile);
{ write symbols }
writesyms(ppufile);
end;
procedure tstoredsymtable.loaddefs(ppufile:tcompilerppufile);
var
def : tdef;
b : byte;
begin
{ load start of definition section, which holds the amount of defs }
if ppufile.readentry<>ibstartdefs then
Message(unit_f_ppu_read_error);
{ read definitions }
repeat
b:=ppufile.readentry;
case b of
ibpointerdef : def:=tpointerdef.ppuload(ppufile);
ibarraydef : def:=tarraydef.ppuload(ppufile);
iborddef : def:=torddef.ppuload(ppufile);
ibfloatdef : def:=tfloatdef.ppuload(ppufile);
ibprocdef : def:=tprocdef.ppuload(ppufile);
ibshortstringdef : def:=tstringdef.loadshort(ppufile);
iblongstringdef : def:=tstringdef.loadlong(ppufile);
ibansistringdef : def:=tstringdef.loadansi(ppufile);
ibwidestringdef : def:=tstringdef.loadwide(ppufile);
ibunicodestringdef : def:=tstringdef.loadunicode(ppufile);
ibrecorddef : def:=trecorddef.ppuload(ppufile);
ibobjectdef : def:=tobjectdef.ppuload(ppufile);
ibenumdef : def:=tenumdef.ppuload(ppufile);
ibsetdef : def:=tsetdef.ppuload(ppufile);
ibprocvardef : def:=tprocvardef.ppuload(ppufile);
ibfiledef : def:=tfiledef.ppuload(ppufile);
ibclassrefdef : def:=tclassrefdef.ppuload(ppufile);
ibformaldef : def:=tformaldef.ppuload(ppufile);
ibvariantdef : def:=tvariantdef.ppuload(ppufile);
ibundefineddef : def:=tundefineddef.ppuload(ppufile);
ibenddefs : break;
ibend : Message(unit_f_ppu_read_error);
else
Message1(unit_f_ppu_invalid_entry,tostr(b));
end;
InsertDef(def);
until false;
end;
procedure tstoredsymtable.loadsyms(ppufile:tcompilerppufile);
var
b : byte;
sym : tsym;
begin
{ load start of definition section, which holds the amount of defs }
if ppufile.readentry<>ibstartsyms then
Message(unit_f_ppu_read_error);
{ now read the symbols }
repeat
b:=ppufile.readentry;
case b of
ibtypesym : sym:=ttypesym.ppuload(ppufile);
ibprocsym : sym:=tprocsym.ppuload(ppufile);
ibconstsym : sym:=tconstsym.ppuload(ppufile);
ibstaticvarsym : sym:=tstaticvarsym.ppuload(ppufile);
iblocalvarsym : sym:=tlocalvarsym.ppuload(ppufile);
ibparavarsym : sym:=tparavarsym.ppuload(ppufile);
ibfieldvarsym : sym:=tfieldvarsym.ppuload(ppufile);
ibabsolutevarsym : sym:=tabsolutevarsym.ppuload(ppufile);
ibenumsym : sym:=tenumsym.ppuload(ppufile);
ibpropertysym : sym:=tpropertysym.ppuload(ppufile);
ibunitsym : sym:=tunitsym.ppuload(ppufile);
iblabelsym : sym:=tlabelsym.ppuload(ppufile);
ibsyssym : sym:=tsyssym.ppuload(ppufile);
ibmacrosym : sym:=tmacro.ppuload(ppufile);
ibendsyms : break;
ibend : Message(unit_f_ppu_read_error);
else
Message1(unit_f_ppu_invalid_entry,tostr(b));
end;
Insert(sym,false);
until false;
end;
procedure tstoredsymtable.writedefs(ppufile:tcompilerppufile);
var
i : longint;
def : tstoreddef;
begin
{ each definition get a number, write then the amount of defs to the
ibstartdef entry }
ppufile.putlongint(DefList.count);
ppufile.writeentry(ibstartdefs);
{ now write the definition }
for i:=0 to DefList.Count-1 do
begin
def:=tstoreddef(DefList[i]);
def.ppuwrite(ppufile);
end;
{ write end of definitions }
ppufile.writeentry(ibenddefs);
end;
procedure tstoredsymtable.writesyms(ppufile:tcompilerppufile);
var
i : longint;
sym : Tstoredsym;
begin
{ each definition get a number, write then the amount of syms and the
datasize to the ibsymdef entry }
ppufile.putlongint(SymList.count);
ppufile.writeentry(ibstartsyms);
{ foreach is used to write all symbols }
for i:=0 to SymList.Count-1 do
begin
sym:=tstoredsym(SymList[i]);
sym.ppuwrite(ppufile);
end;
{ end of symbols }
ppufile.writeentry(ibendsyms);
end;
procedure tstoredsymtable.buildderef;
var
i : longint;
def : tstoreddef;
sym : tstoredsym;
begin
{ interface definitions }
for i:=0 to DefList.Count-1 do
begin
def:=tstoreddef(DefList[i]);
def.buildderef;
end;
{ interface symbols }
for i:=0 to SymList.Count-1 do
begin
sym:=tstoredsym(SymList[i]);
sym.buildderef;
end;
end;
procedure tstoredsymtable.buildderefimpl;
var
i : longint;
def : tstoreddef;
begin
{ implementation definitions }
for i:=0 to DefList.Count-1 do
begin
def:=tstoreddef(DefList[i]);
def.buildderefimpl;
end;
end;
procedure tstoredsymtable.deref;
var
i : longint;
def : tstoreddef;
sym : tstoredsym;
begin
{ first deref the interface ttype symbols. This is needs
to be done before the interface defs are derefed, because
the interface defs can contain references to the type symbols
which then already need to contain a resolved typedef field (PFV) }
for i:=0 to SymList.Count-1 do
begin
sym:=tstoredsym(SymList[i]);
if sym.typ=typesym then
sym.deref;
end;
{ interface definitions }
for i:=0 to DefList.Count-1 do
begin
def:=tstoreddef(DefList[i]);
def.deref;
end;
{ interface symbols }
for i:=0 to SymList.Count-1 do
begin
sym:=tstoredsym(SymList[i]);
if sym.typ<>typesym then
sym.deref;
end;
end;
procedure tstoredsymtable.derefimpl;
var
i : longint;
def : tstoreddef;
begin
{ implementation definitions }
for i:=0 to DefList.Count-1 do
begin
def:=tstoreddef(DefList[i]);
def.derefimpl;
end;
end;
function tstoredsymtable.checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;
var
hsym : tsym;
begin
hsym:=tsym(FindWithHash(hashedid));
if assigned(hsym) then
DuplicateSym(hashedid,sym,hsym);
result:=assigned(hsym);
end;
{**************************************
Callbacks
**************************************}
procedure TStoredSymtable.check_forward(sym:TObject;arg:pointer);
begin
if tsym(sym).typ=procsym then
tprocsym(sym).check_forward
{ check also object method table }
{ we needn't to test the def list }
{ because each object has to have a type sym,
only test objects declarations, not type renamings }
else
if (tsym(sym).typ=typesym) and
assigned(ttypesym(sym).typedef) and
(ttypesym(sym).typedef.typesym=ttypesym(sym)) and
(ttypesym(sym).typedef.typ=objectdef) then
tobjectdef(ttypesym(sym).typedef).check_forwards;
end;
procedure TStoredSymtable.labeldefined(sym:TObject;arg:pointer);
begin
if (tsym(sym).typ=labelsym) and
not(tlabelsym(sym).defined) then
begin
if tlabelsym(sym).used then
Message1(sym_e_label_used_and_not_defined,tlabelsym(sym).realname)
else
Message1(sym_w_label_not_defined,tlabelsym(sym).realname);
end;
end;
procedure TStoredSymtable.varsymbolused(sym:TObject;arg:pointer);
begin
if (tsym(sym).typ in [staticvarsym,localvarsym,paravarsym,fieldvarsym]) and
((tsym(sym).owner.symtabletype in
[parasymtable,localsymtable,ObjectSymtable,staticsymtable])) then
begin
{ unused symbol should be reported only if no }
{ error is reported }
{ if the symbol is in a register it is used }
{ also don't count the value parameters which have local copies }
{ also don't claim for high param of open parameters (PM) }
if (Errorcount<>0) or
([vo_is_hidden_para,vo_is_funcret] * tabstractvarsym(sym).varoptions = [vo_is_hidden_para]) then
exit;
if (tstoredsym(sym).refs=0) then
begin
if (vo_is_funcret in tabstractvarsym(sym).varoptions) then
begin
{ don't warn about the result of constructors }
if ((tsym(sym).owner.symtabletype<>localsymtable) or
(tprocdef(tsym(sym).owner.defowner).proctypeoption<>potype_constructor)) and
not(cs_opt_nodedfa in current_settings.optimizerswitches) then
MessagePos(tsym(sym).fileinfo,sym_w_function_result_not_set)
end
else if (tsym(sym).owner.symtabletype=parasymtable) then
MessagePos1(tsym(sym).fileinfo,sym_h_para_identifier_not_used,tsym(sym).realname)
else if (tsym(sym).owner.symtabletype=ObjectSymtable) then
MessagePos2(tsym(sym).fileinfo,sym_n_private_identifier_not_used,tsym(sym).owner.realname^,tsym(sym).realname)
else
MessagePos1(tsym(sym).fileinfo,sym_n_local_identifier_not_used,tsym(sym).realname);
end
else if tabstractvarsym(sym).varstate in [vs_written,vs_initialised] then
begin
if (tsym(sym).owner.symtabletype=parasymtable) then
begin
if not(tabstractvarsym(sym).varspez in [vs_var,vs_out]) and
not(vo_is_funcret in tabstractvarsym(sym).varoptions) then
MessagePos1(tsym(sym).fileinfo,sym_h_para_identifier_only_set,tsym(sym).realname)
end
else if (tsym(sym).owner.symtabletype=ObjectSymtable) then
MessagePos2(tsym(sym).fileinfo,sym_n_private_identifier_only_set,tsym(sym).owner.realname^,tsym(sym).realname)
else if tabstractvarsym(sym).varoptions*[vo_is_funcret,vo_is_public,vo_is_external]=[] then
MessagePos1(tsym(sym).fileinfo,sym_n_local_identifier_only_set,tsym(sym).realname);
end
else if (tabstractvarsym(sym).varstate = vs_read_not_warned) and
([vo_is_public,vo_is_external] * tabstractvarsym(sym).varoptions = []) then
MessagePos1(tsym(sym).fileinfo,sym_w_identifier_only_read,tsym(sym).realname)
end
else if ((tsym(sym).owner.symtabletype in
[ObjectSymtable,parasymtable,localsymtable,staticsymtable])) then
begin
if (Errorcount<>0) or
(sp_internal in tsym(sym).symoptions) then
exit;
{ do not claim for inherited private fields !! }
if (Tsym(sym).refs=0) and (tsym(sym).owner.symtabletype=ObjectSymtable) then
MessagePos2(tsym(sym).fileinfo,sym_n_private_method_not_used,tsym(sym).owner.realname^,tsym(sym).realname)
{ units references are problematic }
else
begin
if (Tsym(sym).refs=0) and
not(tsym(sym).typ in [enumsym,unitsym]) and
not(is_funcret_sym(tsym(sym))) and
(
(tsym(sym).typ<>procsym) or
((tsym(sym).owner.symtabletype=staticsymtable) and
not current_module.is_unit)
) then
MessagePos2(tsym(sym).fileinfo,sym_h_local_symbol_not_used,SymTypeName[tsym(sym).typ],tsym(sym).realname);
end;
end;
end;
procedure TStoredSymtable.TestPrivate(sym:TObject;arg:pointer);
begin
if tsym(sym).visibility=vis_private then
varsymbolused(sym,arg);
end;
procedure TStoredSymtable.objectprivatesymbolused(sym:TObject;arg:pointer);
begin
{
Don't test simple object aliases PM
}
if (tsym(sym).typ=typesym) and
(ttypesym(sym).typedef.typ=objectdef) and
(ttypesym(sym).typedef.typesym=tsym(sym)) then
tobjectdef(ttypesym(sym).typedef).symtable.SymList.ForEachCall(@TestPrivate,nil);
end;
procedure tstoredsymtable.testfordefaultproperty(sym:TObject;arg:pointer);
begin
if (tsym(sym).typ=propertysym) and
(ppo_defaultproperty in tpropertysym(sym).propoptions) then
ppointer(arg)^:=sym;
end;
{***********************************************
Process all entries
***********************************************}
procedure Tstoredsymtable.reset_all_defs;
var
i : longint;
def : tstoreddef;
begin
for i:=0 to DefList.Count-1 do
begin
def:=tstoreddef(DefList[i]);
def.reset;
end;
end;
{ checks, if all procsyms and methods are defined }
procedure tstoredsymtable.check_forwards;
begin
SymList.ForEachCall(@check_forward,nil);
end;
procedure tstoredsymtable.checklabels;
begin
SymList.ForEachCall(@labeldefined,nil);
end;
procedure tstoredsymtable.allsymbolsused;
begin
SymList.ForEachCall(@varsymbolused,nil);
end;
procedure tstoredsymtable.allprivatesused;
begin
SymList.ForEachCall(@objectprivatesymbolused,nil);
end;
procedure TStoredSymtable._needs_init_final(sym:TObject;arg:pointer);
begin
if b_needs_init_final then
exit;
case tsym(sym).typ of
fieldvarsym,
staticvarsym,
localvarsym,
paravarsym :
begin
if not(is_class(tabstractvarsym(sym).vardef)) and
tstoreddef(tabstractvarsym(sym).vardef).needs_inittable then
b_needs_init_final:=true;
end;
end;
end;
{ returns true, if p contains data which needs init/final code }
function tstoredsymtable.needs_init_final : boolean;
begin
b_needs_init_final:=false;
SymList.ForEachCall(@_needs_init_final,nil);
needs_init_final:=b_needs_init_final;
end;
{****************************************************************************
TAbstractRecordSymtable
****************************************************************************}
constructor tabstractrecordsymtable.create(const n:string;usealign:shortint);
begin
inherited create(n);
_datasize:=0;
databitsize:=0;
recordalignment:=1;
usefieldalignment:=usealign;
padalignment:=1;
{ recordalign C_alignment means C record packing, that starts
with an alignment of 1 }
case usealign of
C_alignment,
bit_alignment:
fieldalignment:=1
else
fieldalignment:=usealign;
end;
end;
procedure tabstractrecordsymtable.ppuload(ppufile:tcompilerppufile);
begin
inherited ppuload(ppufile);
end;
procedure tabstractrecordsymtable.ppuwrite(ppufile:tcompilerppufile);
var
oldtyp : byte;
begin
oldtyp:=ppufile.entrytyp;
ppufile.entrytyp:=subentryid;
inherited ppuwrite(ppufile);
ppufile.entrytyp:=oldtyp;
end;
function field2recordalignment(fieldoffs, fieldalign: aint): aint;
begin
{ optimal alignment of the record when declaring a variable of this }
{ type is independent of the packrecords setting }
if (fieldoffs mod fieldalign) = 0 then
result:=fieldalign
else if (fieldalign >= 16) and
((fieldoffs mod 16) = 0) and
((fieldalign mod 16) = 0) then
result:=16
else if (fieldalign >= 8) and
((fieldoffs mod 8) = 0) and
((fieldalign mod 8) = 0) then
result:=8
else if (fieldalign >= 4) and
((fieldoffs mod 4) = 0) and
((fieldalign mod 4) = 0) then
result:=4
else if (fieldalign >= 2) and
((fieldoffs mod 2) = 0) and
((fieldalign mod 2) = 0) then
result:=2
else
result:=1;
end;
procedure tabstractrecordsymtable.alignrecord(fieldoffset:aint;varalign:shortint);
var
varalignrecord: shortint;
begin
if (usefieldalignment=C_alignment) then
varalignrecord:=used_align(varalign,current_settings.alignment.recordalignmin,current_settings.alignment.maxCrecordalign)
else
varalignrecord:=field2recordalignment(fieldoffset,varalign);
recordalignment:=max(recordalignment,varalignrecord);
end;
procedure tabstractrecordsymtable.addfield(sym:tfieldvarsym;vis:tvisibility);
var
l : aint;
varalignfield,
varalign : shortint;
vardef : tdef;
begin
if (sym.owner<>self) then
internalerror(200602031);
if sym.fieldoffset<>-1 then
internalerror(200602032);
{ set visibility for the symbol }
sym.visibility:=vis;
{ this symbol can't be loaded to a register }
sym.varregable:=vr_none;
{ Calculate field offset }
l:=sym.getsize;
vardef:=sym.vardef;
varalign:=vardef.alignment;
if (usefieldalignment=bit_alignment) then
begin
{ bitpacking only happens for ordinals, the rest is aligned at }
{ 1 byte (compatible with GPC/GCC) }
if is_ordinal(vardef) then
begin
sym.fieldoffset:=databitsize;
l:=sym.getpackedbitsize;
end
else
begin
databitsize:=_datasize*8;
sym.fieldoffset:=databitsize;
if (l>high(aint) div 8) then
Message(sym_e_segment_too_large);
l:=l*8;
end;
if varalign=0 then
varalign:=size_2_align(l);
recordalignment:=max(recordalignment,field2recordalignment(databitsize mod 8,varalign));
{ bit packed records are limited to high(aint) bits }
{ instead of bytes to avoid double precision }
{ arithmetic in offset calculations }
if int64(l)>high(aint)-sym.fieldoffset then
begin
Message(sym_e_segment_too_large);
_datasize:=high(aint);
databitsize:=high(aint);
end
else
begin
databitsize:=sym.fieldoffset+l;
_datasize:=(databitsize+7) div 8;
end;
{ rest is not applicable }
exit;
end;
{ Calc the alignment size for C style records }
if (usefieldalignment=C_alignment) then
begin
if (varalign>4) and
((varalign mod 4)<>0) and
(vardef.typ=arraydef) then
Message1(sym_w_wrong_C_pack,vardef.typename);
if varalign=0 then
varalign:=l;
if (fieldalignment<current_settings.alignment.maxCrecordalign) then
begin
if (varalign>16) and (fieldalignment<32) then
fieldalignment:=32
else if (varalign>12) and (fieldalignment<16) then
fieldalignment:=16
{ 12 is needed for long double }
else if (varalign>8) and (fieldalignment<12) then
fieldalignment:=12
else if (varalign>4) and (fieldalignment<8) then
fieldalignment:=8
else if (varalign>2) and (fieldalignment<4) then
fieldalignment:=4
else if (varalign>1) and (fieldalignment<2) then
fieldalignment:=2;
end;
fieldalignment:=min(fieldalignment,current_settings.alignment.maxCrecordalign);
end;
if varalign=0 then
varalign:=size_2_align(l);
varalignfield:=used_align(varalign,current_settings.alignment.recordalignmin,fieldalignment);
sym.fieldoffset:=align(_datasize,varalignfield);
if l>high(aint)-sym.fieldoffset then
begin
Message(sym_e_segment_too_large);
_datasize:=high(aint);
end
else
_datasize:=sym.fieldoffset+l;
{ Calc alignment needed for this record }
alignrecord(sym.fieldoffset,varalign);
end;
procedure tabstractrecordsymtable.addalignmentpadding;
begin
{ make the record size aligned correctly so it can be
used as elements in an array. For C records we
use the fieldalignment, because that is updated with the
used alignment. }
if (padalignment = 1) then
case usefieldalignment of
C_alignment:
padalignment:=fieldalignment;
{ bitpacked }
bit_alignment:
padalignment:=1;
{ default/no packrecords specified }
0:
padalignment:=recordalignment
{ specific packrecords setting -> use as upper limit }
else
padalignment:=min(recordalignment,usefieldalignment);
end;
_datasize:=align(_datasize,padalignment);
end;
procedure tabstractrecordsymtable.insertdef(def:TDefEntry);
begin
{ Enums must also be available outside the record scope,
insert in the owner of this symtable }
if def.typ=enumdef then
defowner.owner.insertdef(def)
else
inherited insertdef(def);
end;
function tabstractrecordsymtable.is_packed: boolean;
begin
result:=usefieldalignment=bit_alignment;
end;
procedure tabstractrecordsymtable.setdatasize(val: aint);
begin
_datasize:=val;
if (usefieldalignment=bit_alignment) then
{ can overflow in non bitpacked records }
databitsize:=val*8;
end;
{****************************************************************************
TRecordSymtable
****************************************************************************}
constructor trecordsymtable.create(usealign:shortint);
begin
inherited create('',usealign);
symtabletype:=recordsymtable;
end;
{ this procedure is reserved for inserting case variant into
a record symtable }
{ the offset is the location of the start of the variant
and datasize and dataalignment corresponds to
the complete size (see code in pdecl unit) PM }
procedure trecordsymtable.insertunionst(unionst : trecordsymtable;offset : longint);
var
sym : tsym;
def : tdef;
i : integer;
varalignrecord,varalign,
storesize,storealign : aint;
bitsize: aint;
begin
storesize:=_datasize;
storealign:=fieldalignment;
_datasize:=offset;
if (usefieldalignment=bit_alignment) then
databitsize:=offset*8;
{ We move the ownership of the defs and symbols to the new recordsymtable.
The old unionsymtable keeps the references, but doesn't own the
objects anymore }
unionst.DefList.OwnsObjects:=false;
unionst.SymList.OwnsObjects:=false;
{ copy symbols }
for i:=0 to unionst.SymList.Count-1 do
begin
sym:=TSym(unionst.SymList[i]);
if sym.typ<>fieldvarsym then
internalerror(200601272);
{ add to this record symtable }
// unionst.SymList.List.List^[i].Data:=nil;
sym.ChangeOwner(self);
varalign:=tfieldvarsym(sym).vardef.alignment;
if varalign=0 then
varalign:=size_2_align(tfieldvarsym(sym).getsize);
{ retrieve size }
if (usefieldalignment=bit_alignment) then
begin
{ bit packed records are limited to high(aint) bits }
{ instead of bytes to avoid double precision }
{ arithmetic in offset calculations }
if is_ordinal(tfieldvarsym(sym).vardef) then
bitsize:=tfieldvarsym(sym).getpackedbitsize
else
begin
bitsize:=tfieldvarsym(sym).getsize;
if (bitsize>high(aint) div 8) then
Message(sym_e_segment_too_large);
bitsize:=bitsize*8;
end;
if bitsize>high(aint)-databitsize then
begin
Message(sym_e_segment_too_large);
_datasize:=high(aint);
databitsize:=high(aint);
end
else
begin
databitsize:=tfieldvarsym(sym).fieldoffset+offset*8;
_datasize:=(databitsize+7) div 8;
end;
tfieldvarsym(sym).fieldoffset:=databitsize;
varalignrecord:=field2recordalignment(tfieldvarsym(sym).fieldoffset div 8,varalign);
end
else
begin
if tfieldvarsym(sym).getsize>high(aint)-_datasize then
begin
Message(sym_e_segment_too_large);
_datasize:=high(aint);
end
else
_datasize:=tfieldvarsym(sym).fieldoffset+offset;
{ update address }
tfieldvarsym(sym).fieldoffset:=_datasize;
varalignrecord:=field2recordalignment(tfieldvarsym(sym).fieldoffset,varalign);
end;
{ update alignment of this record }
if (usefieldalignment<>C_alignment) then
recordalignment:=max(recordalignment,varalignrecord);
end;
{ update alignment for C records }
if (usefieldalignment=C_alignment) then
recordalignment:=max(recordalignment,unionst.recordalignment);
{ Register defs in the new record symtable }
for i:=0 to unionst.DefList.Count-1 do
begin
def:=TDef(unionst.DefList[i]);
def.ChangeOwner(self);
end;
_datasize:=storesize;
fieldalignment:=storealign;
end;
{****************************************************************************
TObjectSymtable
****************************************************************************}
constructor tObjectSymtable.create(adefowner:tdef;const n:string;usealign:shortint);
begin
inherited create(n,usealign);
symtabletype:=ObjectSymtable;
defowner:=adefowner;
end;
function tObjectSymtable.checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;
var
hsym : tsym;
begin
result:=false;
if not assigned(defowner) then
internalerror(200602061);
{ procsym and propertysym have special code
to override values in inherited classes. For other
symbols check for duplicates }
if not(sym.typ in [procsym,propertysym]) then
begin
{ but private ids can be reused }
hsym:=search_class_member(tobjectdef(defowner),hashedid.id);
if assigned(hsym) and
(
(
not(m_delphi in current_settings.modeswitches) and
is_visible_for_object(hsym,tobjectdef(defowner))
) or
(
{ In Delphi, you can repeat members of a parent class. You can't }
{ do this for objects however, and you (obviouly) can't }
{ declare two fields with the same name in a single class }
(m_delphi in current_settings.modeswitches) and
(
is_object(tdef(defowner)) or
(hsym.owner = self)
)
)
) then
begin
DuplicateSym(hashedid,sym,hsym);
result:=true;
end;
end
else
begin
if not(m_duplicate_names in current_settings.modeswitches) then
result:=inherited checkduplicate(hashedid,sym);
end;
end;
{****************************************************************************
TAbstractLocalSymtable
****************************************************************************}
procedure tabstractlocalsymtable.ppuwrite(ppufile:tcompilerppufile);
var
oldtyp : byte;
begin
oldtyp:=ppufile.entrytyp;
ppufile.entrytyp:=subentryid;
{ write definitions }
writedefs(ppufile);
{ write symbols }
writesyms(ppufile);
ppufile.entrytyp:=oldtyp;
end;
function tabstractlocalsymtable.count_locals:longint;
var
i : longint;
sym : tsym;
begin
result:=0;
for i:=0 to SymList.Count-1 do
begin
sym:=tsym(SymList[i]);
{ Count only varsyms, but ignore the funcretsym }
if (tsym(sym).typ in [localvarsym,paravarsym]) and
(tsym(sym)<>current_procinfo.procdef.funcretsym) and
(not(vo_is_parentfp in tabstractvarsym(sym).varoptions) or
(tstoredsym(sym).refs>0)) then
inc(result);
end;
end;
{****************************************************************************
TLocalSymtable
****************************************************************************}
constructor tlocalsymtable.create(adefowner:tdef;level:byte);
begin
inherited create('');
defowner:=adefowner;
symtabletype:=localsymtable;
symtablelevel:=level;
end;
function tlocalsymtable.checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;
var
hsym : tsym;
begin
if not assigned(defowner) or
(defowner.typ<>procdef) then
internalerror(200602042);
result:=false;
hsym:=tsym(FindWithHash(hashedid));
if assigned(hsym) then
begin
{ a local and the function can have the same
name in TP and Delphi, but RESULT not }
if (m_duplicate_names in current_settings.modeswitches) and
(hsym.typ in [absolutevarsym,localvarsym]) and
(vo_is_funcret in tabstractvarsym(hsym).varoptions) and
not((m_result in current_settings.modeswitches) and
(vo_is_result in tabstractvarsym(hsym).varoptions)) then
HideSym(hsym)
else
DuplicateSym(hashedid,sym,hsym);
result:=true;
exit;
end;
{ check also parasymtable, this needs to be done here becuase
of the special situation with the funcret sym that needs to be
hidden for tp and delphi modes }
hsym:=tsym(tabstractprocdef(defowner).parast.FindWithHash(hashedid));
if assigned(hsym) then
begin
{ a local and the function can have the same
name in TP and Delphi, but RESULT not }
if (m_duplicate_names in current_settings.modeswitches) and
(sym.typ in [absolutevarsym,localvarsym]) and
(vo_is_funcret in tabstractvarsym(sym).varoptions) and
not((m_result in current_settings.modeswitches) and
(vo_is_result in tabstractvarsym(sym).varoptions)) then
Hidesym(sym)
else
DuplicateSym(hashedid,sym,hsym);
result:=true;
exit;
end;
{ check ObjectSymtable, skip this for funcret sym because
that will always be positive because it has the same name
as the procsym }
if not is_funcret_sym(sym) and
(defowner.typ=procdef) and
assigned(tprocdef(defowner)._class) and
(tprocdef(defowner).owner.defowner=tprocdef(defowner)._class) and
(
not(m_delphi in current_settings.modeswitches) or
is_object(tprocdef(defowner)._class)
) then
result:=tprocdef(defowner)._class.symtable.checkduplicate(hashedid,sym);
end;
{****************************************************************************
TParaSymtable
****************************************************************************}
constructor tparasymtable.create(adefowner:tdef;level:byte);
begin
inherited create('');
defowner:=adefowner;
symtabletype:=parasymtable;
symtablelevel:=level;
end;
function tparasymtable.checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;
begin
result:=inherited checkduplicate(hashedid,sym);
if result then
exit;
if not(m_duplicate_names in current_settings.modeswitches) and
(defowner.typ=procdef) and
assigned(tprocdef(defowner)._class) and
(tprocdef(defowner).owner.defowner=tprocdef(defowner)._class) and
(
not(m_delphi in current_settings.modeswitches) or
is_object(tprocdef(defowner)._class)
) then
result:=tprocdef(defowner)._class.symtable.checkduplicate(hashedid,sym);
end;
{****************************************************************************
TAbstractUniTSymtable
****************************************************************************}
constructor tabstractuniTSymtable.create(const n : string;id:word);
begin
inherited create(n);
moduleid:=id;
end;
function tabstractuniTSymtable.iscurrentunit:boolean;
begin
result:=assigned(current_module) and
(
(current_module.globalsymtable=self) or
(current_module.localsymtable=self)
);
end;
{****************************************************************************
TStaticSymtable
****************************************************************************}
constructor tstaticsymtable.create(const n : string;id:word);
begin
inherited create(n,id);
symtabletype:=staticsymtable;
symtablelevel:=main_program_level;
end;
procedure tstaticsymtable.ppuload(ppufile:tcompilerppufile);
begin
inherited ppuload(ppufile);
{ now we can deref the syms and defs }
deref;
end;
procedure tstaticsymtable.ppuwrite(ppufile:tcompilerppufile);
begin
inherited ppuwrite(ppufile);
end;
function tstaticsymtable.checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;
var
hsym : tsym;
begin
result:=false;
hsym:=tsym(FindWithHash(hashedid));
if assigned(hsym) then
begin
{ Delphi (contrary to TP) you can have a symbol with the same name as the
unit, the unit can then not be accessed anymore using
<unit>.<id>, so we can hide the symbol }
if (m_delphi in current_settings.modeswitches) and
(hsym.typ=symconst.unitsym) then
HideSym(hsym)
else
DuplicateSym(hashedid,sym,hsym);
result:=true;
exit;
end;
if (current_module.localsymtable=self) and
assigned(current_module.globalsymtable) then
result:=tglobalsymtable(current_module.globalsymtable).checkduplicate(hashedid,sym);
end;
{****************************************************************************
TGlobalSymtable
****************************************************************************}
constructor tglobalsymtable.create(const n : string;id:word);
begin
inherited create(n,id);
symtabletype:=globalsymtable;
symtablelevel:=main_program_level;
end;
procedure tglobalsymtable.ppuload(ppufile:tcompilerppufile);
begin
inherited ppuload(ppufile);
{ now we can deref the syms and defs }
deref;
end;
procedure tglobalsymtable.ppuwrite(ppufile:tcompilerppufile);
begin
{ write the symtable entries }
inherited ppuwrite(ppufile);
end;
function tglobalsymtable.checkduplicate(var hashedid:THashedIDString;sym:TSymEntry):boolean;
var
hsym : tsym;
begin
result:=false;
hsym:=tsym(FindWithHash(hashedid));
if assigned(hsym) then
begin
{ Delphi (contrary to TP) you can have a symbol with the same name as the
unit, the unit can then not be accessed anymore using
<unit>.<id>, so we can hide the symbol }
if (m_delphi in current_settings.modeswitches) and
(hsym.typ=symconst.unitsym) then
HideSym(hsym)
else
DuplicateSym(hashedid,sym,hsym);
result:=true;
exit;
end;
end;
{****************************************************************************
TWITHSYMTABLE
****************************************************************************}
constructor twithsymtable.create(aowner:tdef;ASymList:TFPHashObjectList;refnode:tobject{tnode});
begin
inherited create('');
symtabletype:=withsymtable;
withrefnode:=refnode;
{ Replace SymList with the passed symlist }
SymList.free;
SymList:=ASymList;
defowner:=aowner;
end;
destructor twithsymtable.destroy;
begin
withrefnode.free;
{ Disable SymList because we don't Own it }
SymList:=nil;
inherited destroy;
end;
procedure twithsymtable.clear;
begin
{ remove no entry from a withsymtable as it is only a pointer to the
recorddef or objectdef symtable }
end;
procedure twithsymtable.insertdef(def:TDefEntry);
begin
{ Definitions can't be registered in the withsymtable
because the withsymtable is removed after the with block.
We can't easily solve it here because the next symtable in the
stack is not known. }
internalerror(200602046);
end;
{****************************************************************************
TSTT_ExceptionSymtable
****************************************************************************}
constructor tstt_excepTSymtable.create;
begin
inherited create('');
symtabletype:=stt_excepTSymtable;
end;
{****************************************************************************
TMacroSymtable
****************************************************************************}
constructor tmacrosymtable.create(exported: boolean);
begin
inherited create('');
if exported then
symtabletype:=exportedmacrosymtable
else
symtabletype:=localmacrosymtable;
symtablelevel:=main_program_level;
end;
{*****************************************************************************
Helper Routines
*****************************************************************************}
function FullTypeName(def,otherdef:tdef):string;
var
s1,s2 : string;
begin
s1:=def.typename;
{ When the names are the same try to include the unit name }
if assigned(otherdef) and
(def.owner.symtabletype in [globalsymtable,staticsymtable]) then
begin
s2:=otherdef.typename;
if upper(s1)=upper(s2) then
s1:=def.owner.realname^+'.'+s1;
end;
FullTypeName:=s1;
end;
procedure incompatibletypes(def1,def2:tdef);
begin
{ When there is an errordef there is already an error message show }
if (def2.typ=errordef) or
(def1.typ=errordef) then
exit;
CGMessage2(type_e_incompatible_types,FullTypeName(def1,def2),FullTypeName(def2,def1));
end;
procedure hidesym(sym:TSymEntry);
begin
sym.realname:='$hidden'+sym.realname;
tsym(sym).visibility:=vis_hidden;
end;
procedure duplicatesym(var hashedid:THashedIDString;dupsym,origsym:TSymEntry);
var
st : TSymtable;
begin
Message1(sym_e_duplicate_id,tsym(origsym).realname);
{ Write hint where the original symbol was found }
st:=finduniTSymtable(origsym.owner);
with tsym(origsym).fileinfo do
begin
if assigned(st) and
(st.symtabletype=globalsymtable) and
st.iscurrentunit then
Message2(sym_h_duplicate_id_where,current_module.sourcefiles.get_file_name(fileindex),tostr(line))
else if assigned(st.name) then
Message2(sym_h_duplicate_id_where,'unit '+st.name^,tostr(line));
end;
{ Rename duplicate sym to an unreachable name, but it can be
inserted in the symtable without errors }
inc(dupnr);
hashedid.id:='dup'+tostr(dupnr)+hashedid.id;
if assigned(dupsym) then
include(tsym(dupsym).symoptions,sp_implicitrename);
end;
{*****************************************************************************
Search
*****************************************************************************}
procedure addsymref(sym:tsym);
begin
{ symbol uses count }
sym.IncRefCount;
{ unit uses count }
if assigned(current_module) and
(sym.owner.symtabletype=globalsymtable) then
begin
if tglobalsymtable(sym.owner).moduleid>=current_module.unitmapsize then
internalerror(200501152);
inc(current_module.unitmap[tglobalsymtable(sym.owner).moduleid].refs);
end;
end;
function is_visible_for_object(symst:tsymtable;symvisibility:tvisibility;contextobjdef:tobjectdef):boolean;
var
symownerdef : tobjectdef;
begin
result:=false;
{ Get objdectdef owner of the symtable for the is_related checks }
if not assigned(symst) or
(symst.symtabletype<>objectsymtable) then
internalerror(200810285);
symownerdef:=tobjectdef(symst.defowner);
case symvisibility of
vis_private :
begin
{ private symbols are allowed when we are in the same
module as they are defined }
result:=(symownerdef.owner.symtabletype in [globalsymtable,staticsymtable]) and
(symownerdef.owner.iscurrentunit);
end;
vis_strictprivate :
begin
result:=assigned(current_objectdef) and
(current_objectdef=symownerdef);
end;
vis_strictprotected :
begin
result:=assigned(current_objectdef) and
current_objectdef.is_related(symownerdef);
end;
vis_protected :
begin
{ protected symbols are visible in the module that defines them and
also visible to related objects. The related object must be defined
in the current module }
result:=(
(
(symownerdef.owner.symtabletype in [globalsymtable,staticsymtable]) and
(symownerdef.owner.iscurrentunit)
) or
(
assigned(contextobjdef) and
(contextobjdef.owner.symtabletype in [globalsymtable,staticsymtable]) and
(contextobjdef.owner.iscurrentunit) and
contextobjdef.is_related(symownerdef)
)
);
end;
vis_public,
vis_published :
result:=true;
end;
end;
function is_visible_for_object(pd:tprocdef;contextobjdef:tobjectdef):boolean;
begin
result:=is_visible_for_object(pd.owner,pd.visibility,contextobjdef);
end;
function is_visible_for_object(sym:tsym;contextobjdef:tobjectdef):boolean;
var
i : longint;
pd : tprocdef;
begin
if sym.typ=procsym then
begin
{ A procsym is visible, when there is at least one of the procdefs visible }
result:=false;
for i:=0 to tprocsym(sym).ProcdefList.Count-1 do
begin
pd:=tprocdef(tprocsym(sym).ProcdefList[i]);
if (pd.owner=sym.owner) and
is_visible_for_object(pd,contextobjdef) then
begin
result:=true;
exit;
end;
end;
end
else
result:=is_visible_for_object(sym.owner,sym.visibility,contextobjdef);
end;
function searchsym(const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
var
hashedid : THashedIDString;
contextobjdef : tobjectdef;
stackitem : psymtablestackitem;
begin
result:=false;
hashedid.id:=s;
stackitem:=symtablestack.stack;
while assigned(stackitem) do
begin
srsymtable:=stackitem^.symtable;
srsym:=tsym(srsymtable.FindWithHash(hashedid));
if assigned(srsym) then
begin
{ use the class from withsymtable only when it is
defined in this unit }
if (srsymtable.symtabletype=withsymtable) and
assigned(srsymtable.defowner) and
(srsymtable.defowner.typ=objectdef) and
(srsymtable.defowner.owner.symtabletype in [globalsymtable,staticsymtable]) and
(srsymtable.defowner.owner.iscurrentunit) then
contextobjdef:=tobjectdef(srsymtable.defowner)
else
contextobjdef:=current_objectdef;
if (srsym.owner.symtabletype<>objectsymtable) or
is_visible_for_object(srsym,contextobjdef) then
begin
{ we need to know if a procedure references symbols
in the static symtable, because then it can't be
inlined from outside this unit }
if assigned(current_procinfo) and
(srsym.owner.symtabletype=staticsymtable) then
include(current_procinfo.flags,pi_uses_static_symtable);
addsymref(srsym);
result:=true;
exit;
end;
end;
stackitem:=stackitem^.next;
end;
srsym:=nil;
srsymtable:=nil;
end;
function searchsym_type(const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
var
hashedid : THashedIDString;
stackitem : psymtablestackitem;
begin
result:=false;
hashedid.id:=s;
stackitem:=symtablestack.stack;
while assigned(stackitem) do
begin
{
It is not possible to have type symbols in:
records
objects
parameters
Exception are generic definitions and specializations
that have the parameterized types inserted in the symtable.
}
srsymtable:=stackitem^.symtable;
if not(srsymtable.symtabletype in [recordsymtable,ObjectSymtable,parasymtable]) or
(assigned(srsymtable.defowner) and
(
(df_generic in tdef(srsymtable.defowner).defoptions) or
(df_specialization in tdef(srsymtable.defowner).defoptions))
) then
begin
srsym:=tsym(srsymtable.FindWithHash(hashedid));
if assigned(srsym) and
not(srsym.typ in [fieldvarsym,paravarsym]) and
(
(srsym.owner.symtabletype<>objectsymtable) or
is_visible_for_object(srsym,current_objectdef)
) then
begin
{ we need to know if a procedure references symbols
in the static symtable, because then it can't be
inlined from outside this unit }
if assigned(current_procinfo) and
(srsym.owner.symtabletype=staticsymtable) then
include(current_procinfo.flags,pi_uses_static_symtable);
addsymref(srsym);
result:=true;
exit;
end;
end;
stackitem:=stackitem^.next;
end;
result:=false;
srsym:=nil;
srsymtable:=nil;
end;
function searchsym_in_module(pm:pointer;const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
var
pmod : tmodule;
begin
pmod:=tmodule(pm);
result:=false;
if assigned(pmod.globalsymtable) then
begin
srsym:=tsym(pmod.globalsymtable.Find(s));
if assigned(srsym) then
begin
srsymtable:=pmod.globalsymtable;
addsymref(srsym);
result:=true;
exit;
end;
end;
{ If the module is the current unit we also need
to search the local symtable }
if (pmod=current_module) and
assigned(pmod.localsymtable) then
begin
srsym:=tsym(pmod.localsymtable.Find(s));
if assigned(srsym) then
begin
srsymtable:=pmod.localsymtable;
addsymref(srsym);
result:=true;
exit;
end;
end;
srsym:=nil;
srsymtable:=nil;
end;
function searchsym_in_named_module(const unitname, symname: TIDString; out srsym: tsym; out srsymtable: tsymtable): boolean;
var
stackitem : psymtablestackitem;
begin
result:=false;
stackitem:=symtablestack.stack;
while assigned(stackitem) do
begin
srsymtable:=stackitem^.symtable;
if (srsymtable.symtabletype=globalsymtable) and
(srsymtable.name^=unitname) then
begin
srsym:=tsym(srsymtable.find(symname));
if not assigned(srsym) then
break;
result:=true;
exit;
end;
stackitem:=stackitem^.next;
end;
{ If the module is the current unit we also need
to search the local symtable }
if (current_module.globalsymtable=srsymtable) and
assigned(current_module.localsymtable) then
begin
srsymtable:=current_module.localsymtable;
srsym:=tsym(srsymtable.find(symname));
if assigned(srsym) then
begin
result:=true;
exit;
end;
end;
end;
function searchsym_in_class(classh,contextclassh:tobjectdef;const s : TIDString;out srsym:tsym;out srsymtable:TSymtable):boolean;
var
hashedid : THashedIDString;
begin
{ The contextclassh is used for visibility. The classh must be equal to
or be a parent of contextclassh. E.g. for inherited searches the classh is the
parent. }
if assigned(classh) and
not contextclassh.is_related(classh) then
internalerror(200811161);
result:=false;
hashedid.id:=s;
while assigned(classh) do
begin
srsymtable:=classh.symtable;
srsym:=tsym(srsymtable.FindWithHash(hashedid));
if assigned(srsym) and
is_visible_for_object(srsym,contextclassh) then
begin
addsymref(srsym);
result:=true;
exit;
end;
classh:=classh.childof;
end;
srsym:=nil;
srsymtable:=nil;
end;
function searchsym_in_class_by_msgint(classh:tobjectdef;msgid:longint;out srdef : tdef;out srsym:tsym;out srsymtable:TSymtable):boolean;
var
def : tdef;
i : longint;
begin
result:=false;
def:=nil;
while assigned(classh) do
begin
for i:=0 to classh.symtable.DefList.Count-1 do
begin
def:=tstoreddef(classh.symtable.DefList[i]);
{ Find also all hidden private methods to
be compatible with delphi, see tw6203 (PFV) }
if (def.typ=procdef) and
(po_msgint in tprocdef(def).procoptions) and
(tprocdef(def).messageinf.i=msgid) then
begin
srdef:=def;
srsym:=tprocdef(def).procsym;
srsymtable:=classh.symtable;
addsymref(srsym);
result:=true;
exit;
end;
end;
classh:=classh.childof;
end;
srdef:=nil;
srsym:=nil;
srsymtable:=nil;
end;
function searchsym_in_class_by_msgstr(classh:tobjectdef;const s:string;out srsym:tsym;out srsymtable:TSymtable):boolean;
var
def : tdef;
i : longint;
begin
result:=false;
def:=nil;
while assigned(classh) do
begin
for i:=0 to classh.symtable.DefList.Count-1 do
begin
def:=tstoreddef(classh.symtable.DefList[i]);
{ Find also all hidden private methods to
be compatible with delphi, see tw6203 (PFV) }
if (def.typ=procdef) and
(po_msgstr in tprocdef(def).procoptions) and
(tprocdef(def).messageinf.str^=s) then
begin
srsym:=tprocdef(def).procsym;
srsymtable:=classh.symtable;
addsymref(srsym);
result:=true;
exit;
end;
end;
classh:=classh.childof;
end;
srsym:=nil;
srsymtable:=nil;
end;
function search_assignment_operator(from_def,to_def:Tdef):Tprocdef;
var
sym : Tprocsym;
hashedid : THashedIDString;
curreq,
besteq : tequaltype;
currpd,
bestpd : tprocdef;
stackitem : psymtablestackitem;
begin
hashedid.id:='assign';
besteq:=te_incompatible;
bestpd:=nil;
stackitem:=symtablestack.stack;
while assigned(stackitem) do
begin
sym:=Tprocsym(stackitem^.symtable.FindWithHash(hashedid));
if sym<>nil then
begin
if sym.typ<>procsym then
internalerror(200402031);
{ if the source type is an alias then this is only the second choice,
if you mess with this code, check tw4093 }
currpd:=sym.find_procdef_assignment_operator(from_def,to_def,curreq);
if curreq>besteq then
begin
besteq:=curreq;
bestpd:=currpd;
if (besteq=te_exact) then
break;
end;
end;
stackitem:=stackitem^.next;
end;
result:=bestpd;
end;
function search_system_type(const s: TIDString): ttypesym;
var
sym : tsym;
begin
sym:=tsym(systemunit.Find(s));
if not assigned(sym) or
(sym.typ<>typesym) then
cgmessage1(cg_f_unknown_system_type,s);
result:=ttypesym(sym);
end;
function search_named_unit_globaltype(const unitname, typename: TIDString): ttypesym;
var
contextobjdef : tobjectdef;
stackitem : psymtablestackitem;
srsymtable: tsymtable;
sym: tsym;
begin
if searchsym_in_named_module(unitname,typename,sym,srsymtable) and
(sym.typ=typesym) then
begin
result:=ttypesym(sym);
exit;
end
else
begin
cgmessage2(cg_f_unknown_type_in_unit,typename,unitname);
result:=nil;
end;
end;
function search_class_member(pd : tobjectdef;const s : string):tsym;
{ searches n in symtable of pd and all anchestors }
var
hashedid : THashedIDString;
srsym : tsym;
begin
hashedid.id:=s;
while assigned(pd) do
begin
srsym:=tsym(pd.symtable.FindWithHash(hashedid));
if assigned(srsym) then
begin
search_class_member:=srsym;
exit;
end;
pd:=pd.childof;
end;
search_class_member:=nil;
end;
function search_macro(const s : string):tsym;
var
stackitem : psymtablestackitem;
hashedid : THashedIDString;
srsym : tsym;
begin
hashedid.id:=s;
{ First search the localmacrosymtable before searching the
global macrosymtables from the units }
if assigned(current_module) then
begin
srsym:=tsym(current_module.localmacrosymtable.FindWithHash(hashedid));
if assigned(srsym) then
begin
result:= srsym;
exit;
end;
end;
stackitem:=macrosymtablestack.stack;
while assigned(stackitem) do
begin
srsym:=tsym(stackitem^.symtable.FindWithHash(hashedid));
if assigned(srsym) then
begin
result:= srsym;
exit;
end;
stackitem:=stackitem^.next;
end;
result:= nil;
end;
function defined_macro(const s : string):boolean;
var
mac: tmacro;
begin
mac:=tmacro(search_macro(s));
if assigned(mac) then
begin
mac.is_used:=true;
defined_macro:=mac.defined;
end
else
defined_macro:=false;
end;
{****************************************************************************
Object Helpers
****************************************************************************}
function search_default_property(pd : tobjectdef) : tpropertysym;
{ returns the default property of a class, searches also anchestors }
var
_defaultprop : tpropertysym;
begin
_defaultprop:=nil;
while assigned(pd) do
begin
pd.symtable.SymList.ForEachCall(@tstoredsymtable(pd.symtable).testfordefaultproperty,@_defaultprop);
if assigned(_defaultprop) then
break;
pd:=pd.childof;
end;
search_default_property:=_defaultprop;
end;
{****************************************************************************
Macro Helpers
****************************************************************************}
procedure def_system_macro(const name : string);
var
mac : tmacro;
s: string;
begin
if name = '' then
internalerror(2004121202);
s:= upper(name);
mac:=tmacro(search_macro(s));
if not assigned(mac) then
begin
mac:=tmacro.create(s);
if assigned(current_module) then
current_module.localmacrosymtable.insert(mac)
else
initialmacrosymtable.insert(mac);
end;
if not mac.defined then
Message1(parser_c_macro_defined,mac.name);
mac.defined:=true;
end;
procedure set_system_macro(const name, value : string);
var
mac : tmacro;
s: string;
begin
if name = '' then
internalerror(2004121203);
s:= upper(name);
mac:=tmacro(search_macro(s));
if not assigned(mac) then
begin
mac:=tmacro.create(s);
if assigned(current_module) then
current_module.localmacrosymtable.insert(mac)
else
initialmacrosymtable.insert(mac);
end
else
begin
mac.is_compiler_var:=false;
if assigned(mac.buftext) then
freemem(mac.buftext,mac.buflen);
end;
Message2(parser_c_macro_set_to,mac.name,value);
mac.buflen:=length(value);
getmem(mac.buftext,mac.buflen);
move(value[1],mac.buftext^,mac.buflen);
mac.defined:=true;
end;
procedure set_system_compvar(const name, value : string);
var
mac : tmacro;
s: string;
begin
if name = '' then
internalerror(2004121204);
s:= upper(name);
mac:=tmacro(search_macro(s));
if not assigned(mac) then
begin
mac:=tmacro.create(s);
mac.is_compiler_var:=true;
if assigned(current_module) then
current_module.localmacrosymtable.insert(mac)
else
initialmacrosymtable.insert(mac);
end
else
begin
mac.is_compiler_var:=true;
if assigned(mac.buftext) then
freemem(mac.buftext,mac.buflen);
end;
Message2(parser_c_macro_set_to,mac.name,value);
mac.buflen:=length(value);
getmem(mac.buftext,mac.buflen);
move(value[1],mac.buftext^,mac.buflen);
mac.defined:=true;
end;
procedure undef_system_macro(const name : string);
var
mac : tmacro;
s: string;
begin
if name = '' then
internalerror(2004121205);
s:= upper(name);
mac:=tmacro(search_macro(s));
if not assigned(mac) then
{If not found, then it's already undefined.}
else
begin
if mac.defined then
Message1(parser_c_macro_undefined,mac.name);
mac.defined:=false;
mac.is_compiler_var:=false;
{ delete old definition }
if assigned(mac.buftext) then
begin
freemem(mac.buftext,mac.buflen);
mac.buftext:=nil;
end;
end;
end;
{$ifdef UNITALIASES}
{****************************************************************************
TUNIT_ALIAS
****************************************************************************}
constructor tunit_alias.create(const n:string);
var
i : longint;
begin
i:=pos('=',n);
if i=0 then
fail;
inherited createname(Copy(n,1,i-1));
newname:=stringdup(Copy(n,i+1,255));
end;
destructor tunit_alias.destroy;
begin
stringdispose(newname);
inherited destroy;
end;
procedure addunitalias(const n:string);
begin
unitaliases^.insert(tunit_alias,init(Upper(n))));
end;
function getunitalias(const n:string):string;
var
p : punit_alias;
begin
p:=punit_alias(unitaliases^.Find(Upper(n)));
if assigned(p) then
getunitalias:=punit_alias(p).newname^
else
getunitalias:=n;
end;
{$endif UNITALIASES}
{****************************************************************************
Init/Done Symtable
****************************************************************************}
procedure InitSymtable;
begin
{ Reset symbolstack }
symtablestack:=nil;
systemunit:=nil;
{ create error syms and def }
generrorsym:=terrorsym.create;
generrordef:=terrordef.create;
{ macros }
initialmacrosymtable:=tmacrosymtable.create(false);
macrosymtablestack:=TSymtablestack.create;
macrosymtablestack.push(initialmacrosymtable);
{$ifdef UNITALIASES}
{ unit aliases }
unitaliases:=TFPHashObjectList.create;
{$endif}
{ set some global vars to nil, might be important for the ide }
class_tobject:=nil;
interface_iunknown:=nil;
rec_tguid:=nil;
dupnr:=0;
end;
procedure DoneSymtable;
begin
generrorsym.owner:=nil;
generrorsym.free;
generrordef.owner:=nil;
generrordef.free;
initialmacrosymtable.free;
macrosymtablestack.free;
{$ifdef UNITALIASES}
unitaliases.free;
{$endif}
end;
end.
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