{ $Id$ Copyright (c) 1998 by Florian Klaempfl Handles the parsing and loading of the modules (ppufiles) 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 pmodules; {define TEST_IMPL does not work well } interface uses files; procedure addlinkerfiles(hp:pmodule); procedure loadsystemunit; procedure proc_unit; procedure proc_program(islibrary : boolean); implementation uses cobjects,verbose,comphook,systems,globals, symtable,aasm,hcodegen, link,assemble,import {$ifndef OLDPPU} ,ppu {$endif OLDPPU} {$ifdef i386} ,i386 {$endif} {$ifdef m68k} ,m68k {$endif} ,scanner,pbase,psystem,pdecl,psub,parser; procedure addlinkerfiles(hp:pmodule); begin with hp^ do begin while not linkofiles.empty do Linker.AddObject(linkofiles.Get); while not linksharedlibs.empty do Linker.AddSharedLibrary(linksharedlibs.Get); while not linkstaticlibs.empty do Linker.AddStaticLibrary(linkstaticlibs.Get); end; end; procedure insertsegment; procedure fixseg(p:paasmoutput;sec:tsection); begin p^.insert(new(pai_section,init(sec))); if (cs_smartlink in aktmoduleswitches) then p^.insert(new(pai_cut,init)); p^.concat(new(pai_section,init(sec_none))); end; begin {Insert Ident of the compiler} if (not (cs_smartlink in aktmoduleswitches)) {$ifndef EXTDEBUG} and (not current_module^.is_unit) {$endif} then begin datasegment^.insert(new(pai_align,init(4))); datasegment^.insert(new(pai_string,init('FPC '+version_string+' for '+target_string+' - '+target_info.short_name))); end; { Insert start and end of sections } fixseg(codesegment,sec_code); fixseg(datasegment,sec_data); fixseg(bsssegment,sec_bss); fixseg(consts,sec_data); end; procedure insertheap; begin if (cs_smartlink in aktmoduleswitches) then begin bsssegment^.concat(new(pai_cut,init)); datasegment^.concat(new(pai_cut,init)); end; { On the Macintosh Classic M68k Architecture The Heap variable is simply a POINTER to the real HEAP. The HEAP must be set up by the RTL and must store the pointer in this value. On OS/2 the heap is also intialized by the RTL. We do not output a pointer } case target_info.target of {$ifdef i386} target_OS2 : ; {$endif i386} {$ifdef m68k} target_Mac68K : bsssegment^.concat(new(pai_datablock,init_global('HEAP',4))); {$endif m68k} else bsssegment^.concat(new(pai_datablock,init_global('HEAP',heapsize))); end; {$ifdef i386} datasegment^.concat(new(pai_symbol,init_global('HEAPSIZE'))); {$endif i386} {$ifdef m68k} datasegment^.concat(new(pai_symbol,init_global('HEAP_SIZE'))); {$endif m68k} datasegment^.concat(new(pai_const,init_32bit(heapsize))); end; procedure inserttargetspecific; begin {$ifdef i386} case target_info.target of target_GO32V2 : begin { stacksize can be specified } datasegment^.concat(new(pai_symbol,init_global('__stklen'))); datasegment^.concat(new(pai_const,init_32bit(stacksize))); end; target_WIN32 : begin { Generate an external entry to be sure that _mainCRTStarup will be linked, can't use concat_external because those aren't written for asw (PFV) } datasegment^.concat(new(pai_const,init_symbol('_mainCRTStartup'))); end; end; {$endif i386} end; {$ifndef OLDPPU} function loadunit(const s : string;compile_system:boolean) : pmodule;forward; procedure load_usedunits(compile_system:boolean); var pu : pused_unit; loaded_unit : pmodule; nextmapentry : longint; begin { init the map } new(current_module^.map); nextmapentry:=1; { load the used units from interface } pu:=pused_unit(current_module^.used_units.first); while assigned(pu) do begin if (not pu^.loaded) and (pu^.in_interface) then begin loaded_unit:=loadunit(pu^.name^,false); if current_module^.compiled then exit; { register unit in used units } pu^.u:=loaded_unit; pu^.loaded:=true; { need to recompile the current unit ? } if loaded_unit^.crc<>pu^.checksum then begin current_module^.do_compile:=true; exit; end; { setup the map entry for deref } current_module^.map^[nextmapentry]:=loaded_unit^.symtable; inc(nextmapentry); if nextmapentry>maxunits then Message(unit_f_too_much_units); end; pu:=pused_unit(pu^.next); end; { ok, now load the unit } current_module^.symtable:=new(punitsymtable,loadasunit); { if this is the system unit insert the intern symbols } if compile_system then begin make_ref:=false; insertinternsyms(psymtable(current_module^.symtable)); make_ref:=true; end; { now only read the implementation part } current_module^.in_implementation:=true; { load the used units from implementation } pu:=pused_unit(current_module^.used_units.first); while assigned(pu) do begin if (not pu^.loaded) and (not pu^.in_interface) then begin loaded_unit:=loadunit(pu^.name^,false); if current_module^.compiled then exit; { register unit in used units } pu^.u:=loaded_unit; pu^.loaded:=true; {$ifdef TEST_IMPL} { need to recompile the current unit ? } if loaded_unit^.crc<>pu^.checksum then begin current_module^.do_compile:=true; exit; end; { setup the map entry for deref } current_module^.map^[nextmapentry]:=loaded_unit^.symtable; inc(nextmapentry); if nextmapentry>maxunits then Message(unit_f_too_much_units); {$endif TEST_IMPL} end; pu:=pused_unit(pu^.next); end; { remove the map, it's not needed anymore } dispose(current_module^.map); current_module^.map:=nil; end; function loadunit(const s : string;compile_system:boolean) : pmodule; var st : punitsymtable; old_current_ppu : pppufile; old_current_module,hp : pmodule; procedure loadppufile; begin { load interface section } if not current_module^.do_compile then load_interface; { only load units when we don't recompile } if not current_module^.do_compile then load_usedunits(compile_system); { recompile if set } if current_module^.do_compile then begin { we needn't the ppufile } if assigned(current_module^.ppufile) then begin dispose(current_module^.ppufile,done); current_module^.ppufile:=nil; end; { recompile the unit or give a fatal error if sources not available } if not(current_module^.sources_avail) then Message1(unit_f_cant_compile_unit,current_module^.modulename^) else begin current_scanner^.close; compile(current_module^.mainsource^,compile_system); if (not old_current_module^.compiled) then current_scanner^.reopen; end; end else begin { only reassemble ? } if (current_module^.do_assemble) then OnlyAsm(current_module^.asmfilename^); { add the files for the linker } addlinkerfiles(current_module); end; if assigned(current_module^.ppufile) then begin dispose(current_module^.ppufile,done); current_module^.ppufile:=nil; end; end; begin old_current_module:=current_module; old_current_ppu:=current_ppu; { be sure not to mix lines from different files } { update_line; } { unit not found } st:=nil; { search all loaded units } hp:=pmodule(loaded_units.first); while assigned(hp) do begin if hp^.modulename^=s then begin { the unit is already registered } { and this means that the unit } { is already compiled } { else there is a cyclic unit use } if assigned(hp^.symtable) then st:=punitsymtable(hp^.symtable) else begin { recompile the unit ? } if (not current_module^.in_implementation) and (hp^.in_implementation) then Message(unit_f_circular_unit_reference); end; break; end; { the next unit } hp:=pmodule(hp^.next); end; { the unit is not in the symtable stack } if (not assigned(st)) then begin { if the unit is loaded remove it first } if assigned(hp) then begin { remove the old unit } loaded_units.remove(hp); dispose(hp,done); end; { generates a new unit info record } current_module:=new(pmodule,init(s,true)); current_ppu:=current_module^.ppufile; { now we can register the unit } loaded_units.insert(current_module); { now realy load the ppu } loadppufile; { set compiled flag } current_module^.compiled:=true; { register the unit _once_ } usedunits.concat(new(pused_unit,init(current_module,true))); { load return pointer } hp:=current_module; end; { set the old module } current_ppu:=old_current_ppu; current_module:=old_current_module; loadunit:=hp; end; {$else OLDPPU} {***************************************************************************** Old PPU *****************************************************************************} function loadunit(const s : string;compile_system, in_uses : boolean) : pmodule;forward; procedure load_ppu(oldhp,hp : pmodule;compile_system : boolean); var loaded_unit : pmodule; b : byte; checksum, count, nextmapentry : longint; hs : string; begin { init the map } new(hp^.map); nextmapentry:=1; { load the used units from interface } hp^.ppufile^.read_data(b,1,count); while (b=ibloadunit) do begin { read unit name } hp^.ppufile^.read_data(hs[0],1,count); hp^.ppufile^.read_data(hs[1],byte(hs[0]),count); hp^.ppufile^.read_data(checksum,4,count); loaded_unit:=loadunit(hs,false,false); if hp^.compiled then exit; { if the crc of a used unit is the same as } { written to the PPU file, we needn't to } { recompile the current unit } if (loaded_unit^.crc<>checksum) then begin { we have to compile the current unit } { remove stuff which isn't needed } { forget the map } dispose(hp^.map); hp^.map:=nil; hp^.ppufile^.close; dispose(hp^.ppufile,done); hp^.ppufile:=nil; if not(hp^.sources_avail) then Message1(unit_f_cant_compile_unit,hp^.modulename^) else begin if assigned(oldhp^.current_inputfile) then oldhp^.current_inputfile^.tempclose; compile(hp^.mainsource^,compile_system); if (not oldhp^.compiled) and assigned(oldhp^.current_inputfile) then oldhp^.current_inputfile^.tempreopen; end; exit; end; { setup the map entry for deref } hp^.map^[nextmapentry]:=loaded_unit^.symtable; inc(nextmapentry); if nextmapentry>maxunits then Message(unit_f_too_much_units); { read until ibend } hp^.ppufile^.read_data(b,1,count); end; { ok, now load the unit } hp^.symtable:=new(punitsymtable,load(hp^.modulename^)); { if this is the system unit insert the intern } { symbols } make_ref:=false; if compile_system then insertinternsyms(psymtable(hp^.symtable)); make_ref:=true; { now only read the implementation part } hp^.in_implementation:=true; { load the used units from implementation } hp^.ppufile^.read_data(b,1,count); while (b<>ibend) and (b=ibloadunit) do begin { read unit name } hp^.ppufile^.read_data(hs[0],1,count); hp^.ppufile^.read_data(hs[1],byte(hs[0]),count); hp^.ppufile^.read_data(checksum,4,count); loaded_unit:=loadunit(hs,false,false); if hp^.compiled then exit; { if the crc of a used unit is the same as } { written to the PPU file, we needn't to } { recompile the current unit } { but for the implementation part } { the written crc is false, because } { not defined when writing the ppufile !! } {$ifdef TEST_IMPL} if (checksum<>0) and (loaded_unit^.crc<>checksum) then begin { we have to compile the current unit } { remove stuff which isn't needed } { forget the map } dispose(hp^.map); hp^.map:=nil; hp^.ppufile^.close; dispose(hp^.ppufile,done); hp^.ppufile:=nil; if not(hp^.sources_avail) then Message1(unit_f_cant_compile_unit,hp^.modulename^) else begin oldhp^.current_inputfile^.tempclose; compile(hp^.mainsource^,compile_system); oldhp^.current_inputfile^.tempclose; end; exit; end; {$endif TEST_IMPL} { read until ibend } hp^.ppufile^.read_data(b,1,count); end; hp^.ppufile^.close; dispose(hp^.map); hp^.map:=nil; end; function loadunit(const s : string;compile_system, in_uses : boolean) : pmodule; var st : punitsymtable; old_current_module,hp,nextmodule : pmodule; pu : pused_unit; hs : pstring; begin old_current_module:=current_module; { be sure not to mix lines from different files } { update_line; } { unit not found } st:=nil; { search all loaded units } hp:=pmodule(loaded_units.first); while assigned(hp) do begin if hp^.modulename^=s then begin { the unit is already registered } { and this means that the unit } { is already compiled } { else there is a cyclic unit use } if assigned(hp^.symtable) then st:=punitsymtable(hp^.symtable) else begin { recompile the unit ? } if (not current_module^.in_implementation) and (hp^.in_implementation) then Message(unit_f_circular_unit_reference); end; break; end; { the next unit } hp:=pmodule(hp^.next); end; { no error and the unit isn't loaded } if not(assigned(hp)) and (st=nil) then begin { generates a new unit info record } hp:=new(pmodule,init(s,true)); { now we can register the unit } loaded_units.insert(hp); current_module:=hp; { force build ? } if (hp^.do_compile) or (hp^.sources_avail and do_build) then begin { we needn't the ppufile } if assigned(hp^.ppufile) then begin dispose(hp^.ppufile,done); hp^.ppufile:=nil; end; if not(hp^.sources_avail) then Message1(unit_f_cant_compile_unit,hp^.modulename^) else begin if assigned(old_current_module^.current_inputfile) then old_current_module^.current_inputfile^.tempclose; compile(hp^.mainsource^,compile_system); if (not old_current_module^.compiled) and assigned(old_current_module^.current_inputfile) then old_current_module^.current_inputfile^.tempreopen; end; end else begin { only reassemble ? } if (hp^.do_assemble) then OnlyAsm(hp^.asmfilename^); { we should know there the PPU file else it's an error and we can't load the unit } if hp^.ppufile^.name^<>'' then load_ppu(old_current_module,hp,compile_system); { add the files for the linker } addlinkerfiles(hp); end; { register the unit _once_ } usedunits.concat(new(pused_unit,init(hp,0))); { the unit is written, so we can set the symtable type } { to unitsymtable, else we get some dupid errors } { this is not the right place because of the } { ready label } { psymtable(hp^.symtable)^.symtabletype:=unitsymtable; } { placed at this end of proc_unit } psymtable(hp^.symtable)^.unitid:=0; { reset the unitnumbers for the other units } pu:=pused_unit(old_current_module^.used_units.first); while assigned(pu) do begin psymtable(pu^.u^.symtable)^.unitid:=pu^.unitid; pu:=pused_unit(pu^.next); end; end else if assigned(hp) and (st=nil) then begin { we have to compile the unit again, but it is already inserted !!} { we may have problem with the lost symtable !! } current_module:=hp; { we must preserve the unit chain } nextmodule:=pmodule(hp^.next); { we have to cleanup a little } hp^.special_done; new(hs); hs^:=hp^.mainsource^; hp^.init(hs^,true); dispose(hs); { we must preserve the unit chain } hp^.next:=nextmodule; if assigned(hp^.ppufile) then load_ppu(old_current_module,hp,compile_system) else begin {$ifdef UseBrowser} { here we need to remove the names ! } hp^.sourcefiles.done; hp^.sourcefiles.init; {$endif UseBrowser} if assigned(old_current_module^.current_inputfile) then old_current_module^.current_inputfile^.tempclose; Message1(parser_d_compiling_second_time,hp^.mainsource^); compile(hp^.mainsource^,compile_system); if (not old_current_module^.compiled) and assigned(old_current_module^.current_inputfile) then old_current_module^.current_inputfile^.tempreopen; end; current_module^.compiled:=true; end; { set the old module } current_module:=old_current_module; { the current module uses the unit hp } current_module^.used_units.concat(new(pused_unit,init(hp,0))); pused_unit(current_module^.used_units.last)^.in_uses:=in_uses; if in_uses and not current_module^.in_implementation then pused_unit(current_module^.used_units.last)^.in_interface:=true; loadunit:=hp; end; {$endif OLDPPU} procedure loadsystemunit; var hp : pmodule; begin { if the current file isn't a system unit the the system unit will be loaded } if not(cs_compilesystem in aktmoduleswitches) then begin {$ifndef OLDPPU} hp:=loadunit(upper(target_info.system_unit),true); systemunit:=hp^.symtable; { add to the used units } current_module^.used_units.concat(new(pused_unit,init(hp,true))); {$else OLDPPU} hp:=loadunit(upper(target_info.system_unit),true,true); systemunit:=hp^.symtable; { add to the used units } current_module^.used_units.concat(new(pused_unit,init(hp,0))); {$endif OLDPPU} { read default constant definitions } make_ref:=false; readconstdefs; { we could try to overload caret by default } symtablestack:=systemunit; { if POWER is defined in the RTL then use it for starstar overloading } getsym('POWER',false); if assigned(srsym) and (srsym^.typ=procsym) and (overloaded_operators[STARSTAR]=nil) then overloaded_operators[STARSTAR]:=pprocsym(srsym); make_ref:=true; end else begin createconstdefs; systemunit:=nil; end; end; procedure loadunits; var s : stringid; hp : pused_unit; hp2 : pmodule; hp3 : psymtable; oldprocsym:Pprocsym; begin oldprocsym:=aktprocsym; consume(_USES); {$ifdef DEBUG} test_symtablestack; {$endif DEBUG} repeat s:=pattern; consume(ID); {$ifndef OLDPPU} hp2:=loadunit(s,false); { the current module uses the unit hp2 } current_module^.used_units.concat(new(pused_unit,init(hp2,not current_module^.in_implementation))); pused_unit(current_module^.used_units.last)^.in_uses:=true; {$else OLDPPU} hp2:=loadunit(s,false,true); {$endif OLDPPU} if current_module^.compiled then exit; refsymtable^.insert(new(punitsym,init(s,hp2^.symtable))); if token=COMMA then begin pattern:=''; consume(COMMA); end else break; until false; consume(SEMICOLON); { set the symtable to systemunit so it gets reorderd correctly } symtablestack:=systemunit; { now insert the units in the symtablestack } hp:=pused_unit(current_module^.used_units.first); while assigned(hp) do begin {$IfDef GDB} if (cs_debuginfo in aktmoduleswitches) and not hp^.is_stab_written then begin punitsymtable(hp^.u^.symtable)^.concattypestabto(debuglist); hp^.is_stab_written:=true; hp^.unitid:=psymtable(hp^.u^.symtable)^.unitid; end; {$EndIf GDB} if hp^.in_uses then begin hp3:=symtablestack; while assigned(hp3) do begin { insert units only once ! } if hp^.u^.symtable=hp3 then break; hp3:=hp3^.next; { unit isn't inserted } if hp3=nil then begin psymtable(hp^.u^.symtable)^.next:=symtablestack; symtablestack:=psymtable(hp^.u^.symtable); {$ifdef CHAINPROCSYMS} symtablestack^.chainprocsyms; {$endif CHAINPROCSYMS} {$ifdef DEBUG} test_symtablestack; {$endif DEBUG} end; end; end; hp:=pused_unit(hp^.next); end; aktprocsym:=oldprocsym; end; procedure parse_implementation_uses(symt:Psymtable); var old_module_in_implementation : boolean; begin if token=_USES then begin old_module_in_implementation:=module_in_implementation; module_in_implementation:=true; current_module^.in_implementation:=true; symt^.symtabletype:=unitsymtable; loadunits; symt^.symtabletype:=globalsymtable; {$ifdef DEBUG} test_symtablestack; {$endif DEBUG} module_in_implementation:=old_module_in_implementation; end; end; procedure proc_unit; var { unitname : stringid; } names : Tstringcontainer; p : psymtable; unitst : punitsymtable; pu : pused_unit; i : longint; s1,s2 : ^string; {Saves stack space} begin consume(_UNIT); if token=ID then begin { create filenames and unit name } current_module^.SetFileName(current_scanner^.inputfile^.path^+current_scanner^.inputfile^.name^); stringdispose(current_module^.modulename); current_module^.modulename:=stringdup(upper(pattern)); { check for system unit } new(s1); new(s2); s1^:=upper(target_info.system_unit); s2^:=upper(current_scanner^.inputfile^.name^); { strip extension, there could only be one dot } i:=pos('.',s2^); if i>0 then s2^:=Copy(s2^,1,i-1); if (cs_compilesystem in aktmoduleswitches) then begin if (cs_check_unit_name in aktglobalswitches) and ((length(current_module^.modulename^)>8) or (current_module^.modulename^<>s1^) or (current_module^.modulename^<>s2^)) then Message1(unit_e_illegal_unit_name,s1^); end else if (current_module^.modulename^=s1^) then Message(unit_w_switch_us_missed); dispose(s2); dispose(s1); { Add Object File } if (cs_smartlink in aktmoduleswitches) then current_module^.linkstaticlibs.insert(current_module^.libfilename^) else current_module^.linkofiles.insert(current_module^.objfilename^); end; consume(ID); consume(SEMICOLON); consume(_INTERFACE); { update status } status.currentmodule:=current_module^.modulename^; { this should be placed after uses !!} {$ifndef UseNiceNames} procprefix:='_'+current_module^.modulename^+'$$'; {$else UseNiceNames} procprefix:='_'+tostr(length(current_module^.unitname^))+lowercase(current_module^.unitname^)+'_'; {$endif UseNiceNames} parse_only:=true; { generate now the global symboltable } p:=new(punitsymtable,init(globalsymtable,current_module^.modulename^)); refsymtable:=p; unitst:=punitsymtable(p); { the unit name must be usable as a unit specifier } { inside the unit itself (PM) } { this also forbids to have another symbol } { with the same name as the unit } refsymtable^.insert(new(punitsym,init(current_module^.modulename^,unitst))); { set the symbol table for the current unit } { this must be set later for interdependency } { current_module^.symtable:=psymtable(p); } { a unit compiled at command line must be inside the loaded_unit list } if (compile_level=1) then begin loaded_units.insert(current_module); if cs_createlib in initmoduleswitches then begin current_module^.flags:=current_module^.flags or uf_in_library; if cs_shared_lib in initmoduleswitches then current_module^.flags:=current_module^.flags or uf_shared_library; end; end; { insert qualifier for the system unit (allows system.writeln) } if not(cs_compilesystem in aktmoduleswitches) then begin { insert the system unit } { it is allways the first } systemunit^.next:=nil; symtablestack:=systemunit; refsymtable^.insert(new(punitsym,init('SYSTEM',systemunit))); if token=_USES then begin unitst^.symtabletype:=unitsymtable; loadunits; { has it been compiled at a higher level ?} if current_module^.compiled then exit; unitst^.symtabletype:=globalsymtable; end; { ... but insert the symbol table later } p^.next:=symtablestack; symtablestack:=p; end else { while compiling a system unit, some types are directly inserted } begin p^.next:=symtablestack; symtablestack:=p; insert_intern_types(p); end; { displaced for inter-dependency considerations } current_module^.symtable:=psymtable(p); constsymtable:=symtablestack; { ... parse the declarations } read_interface_declarations; consume(_IMPLEMENTATION); parse_only:=false; {$ifdef GDB} { add all used definitions even for implementation} if (cs_debuginfo in aktmoduleswitches) then begin { all types } punitsymtable(refsymtable)^.concattypestabto(debuglist); { and all local symbols} refsymtable^.concatstabto(debuglist); end; {$endif GDB} { generates static symbol table } p:=new(punitsymtable,init(staticsymtable,current_module^.modulename^)); {Generate a procsym.} make_ref:=false; aktprocsym:=new(Pprocsym,init(current_module^.modulename^+'_init')); aktprocsym^.definition:=new(Pprocdef,init); aktprocsym^.definition^.options:=aktprocsym^.definition^.options or pounitinit; aktprocsym^.definition^.setmangledname(current_module^.modulename^+'_init'); make_ref:=true; {The generated procsym has a local symtable. Discard it and turn it into the static one.} dispose(aktprocsym^.definition^.localst,done); aktprocsym^.definition^.localst:=p; { remove the globalsymtable from the symtable stack } { to reinsert it after loading the implementation units } symtablestack:=unitst^.next; { number the definitions, so a deref from other units works } refsymtable^.number_defs; { Read the implementation units } parse_implementation_uses(unitst); numberunits; { now we can change refsymtable } refsymtable:=p; { but reinsert the global symtable as lasts } unitst^.next:=symtablestack; symtablestack:=unitst; {$ifdef DEBUG} test_symtablestack; {$endif DEBUG} constsymtable:=symtablestack; {$ifdef Splitheap} if testsplit then begin Split_Heap; allow_special:=true; Switch_to_temp_heap; end; { it will report all crossings } allow_special:=false; {$endif Splitheap} { set some informations } procinfo.retdef:=voiddef; procinfo._class:=nil; procinfo.call_offset:=8; { for temporary values } procinfo.framepointer:=frame_pointer; { clear flags } procinfo.flags:=0; { Create a new procedure } codegen_newprocedure; { Compile the unit } names.init; names.insert(current_module^.modulename^+'_init'); names.insert('INIT$$'+current_module^.modulename^); compile_proc_body(names,true,false); names.done; { Shutdown the codegen for this procedure } codegen_doneprocedure; {$ifdef dummy} if token=_FINALIZATION then begin current_module^.flags:=current_module^.flags or uf_finalize; { clear flags } procinfo.flags:=0; {Reset the codegenerator.} codegen_newprocedure; names.init; names.insert(current_module^.modulename^+'_finalize'); names.insert('FINALIZE$$'+current_module^.modulename^); compile_proc_body(names,true,false); names.done; codegen_doneprocedure; end; {$endif dummy} consume(POINT); { size of the static data } datasize:=symtablestack^.datasize; { unsed static symbols ? } symtablestack^.allsymbolsused; {$ifdef GDB} { add all used definitions even for implementation} if (cs_debuginfo in aktmoduleswitches) then begin { all types } punitsymtable(symtablestack)^.concattypestabto(debuglist); { and all local symbols} symtablestack^.concatstabto(debuglist); end; {$endif GDB} current_module^.in_implementation:=false; { deletes all symtables generated in the implementation part } while symtablestack^.symtabletype<>globalsymtable do dellexlevel; { tests, if all forwards are resolved } symtablestack^.check_forwards; symtablestack^.symtabletype:=unitsymtable; punitsymtable(symtablestack)^.is_stab_written:=false; {Write out the unit if the compile was succesfull.} if status.errorcount=0 then writeunitas(current_module^.ppufilename^,punitsymtable(symtablestack)); pu:=pused_unit(usedunits.first); while assigned(pu) do begin punitsymtable(pu^.u^.symtable)^.is_stab_written:=false; pu:=pused_unit(pu^.next); end; inc(datasize,symtablestack^.datasize); { generate imports } if current_module^.uses_imports then importlib^.generatelib; { finish asmlist by adding segment starts } insertsegment; end; procedure proc_program(islibrary : boolean); var st : psymtable; names : Tstringcontainer; begin parse_only:=false; if islibrary then begin consume(_LIBRARY); stringdispose(current_module^.modulename); current_module^.modulename:=stringdup(pattern); consume(ID); consume(SEMICOLON); end else { is there an program head ? } if token=_PROGRAM then begin consume(_PROGRAM); stringdispose(current_module^.modulename); current_module^.modulename:=stringdup(pattern); consume(ID); if token=LKLAMMER then begin consume(LKLAMMER); idlist; consume(RKLAMMER); end; consume(SEMICOLON); end; { insert after the unit symbol tables the static symbol table } { of the program } st:=new(punitsymtable,init(staticsymtable,current_module^.modulename^)); {Generate a procsym.} make_ref:=false; aktprocsym:=new(Pprocsym,init('main')); aktprocsym^.definition:=new(Pprocdef,init); aktprocsym^.definition^.options:=aktprocsym^.definition^.options or poproginit; aktprocsym^.definition^.setmangledname(target_os.Cprefix+'main'); make_ref:=true; {The localst is a local symtable. Change it into the static symtable.} dispose(aktprocsym^.definition^.localst,done); aktprocsym^.definition^.localst:=st; refsymtable:=st; { necessary for browser } loaded_units.insert(current_module); {Insert the symbols of the system unit into the stack of symbol tables.} symtablestack:=systemunit; systemunit^.next:=nil; refsymtable^.insert(new(punitsym,init('SYSTEM',systemunit))); {Load the units used by the program we compile.} if token=_USES then loadunits; {Insert the name of the main program into the symbol table.} if current_module^.modulename^<>'' then st^.insert(new(pprogramsym,init(current_module^.modulename^))); { ...is also constsymtable, this is the symtable where } { the elements of enumeration types are inserted } constsymtable:=st; { set some informations about the main program } with procinfo do begin retdef:=voiddef; _class:=nil; call_offset:=8; framepointer:=frame_pointer; flags:=0; end; procprefix:=''; in_except_block:=false; codegen_newprocedure; {The program intialization needs an alias, so it can be called from the bootstrap code.} names.init; names.insert('program_init'); names.insert('PASCALMAIN'); names.insert(target_os.cprefix+'main'); compile_proc_body(names,true,false); names.done; codegen_doneprocedure; consume(POINT); if (cs_smartlink in aktmoduleswitches) then current_module^.linkstaticlibs.insert(current_module^.libfilename^) else current_module^.linkofiles.insert(current_module^.objfilename^); { insert heap } insertheap; { generate imports } if current_module^.uses_imports then importlib^.generatelib; inserttargetspecific; datasize:=symtablestack^.datasize; { finish asmlist by adding segment starts } insertsegment; end; end. { $Log$ Revision 1.38 1998-08-10 14:50:13 peter + localswitches, moduleswitches, globalswitches splitting Revision 1.37 1998/08/10 10:18:31 peter + Compiler,Comphook unit which are the new interface units to the compiler Revision 1.36 1998/07/14 14:46:54 peter * released NEWINPUT Revision 1.35 1998/07/08 12:39:38 peter * heap_size for m68k Revision 1.34 1998/07/07 11:20:03 peter + NEWINPUT for a better inputfile and scanner object Revision 1.33 1998/06/25 11:15:34 pierre * ppu files where not closed in newppu !! second compilation was impossible due to too many opened files (not visible in 'make cycle' as we remove all the ppu files) Revision 1.32 1998/06/25 08:48:16 florian * first version of rtti support Revision 1.31 1998/06/24 14:48:35 peter * ifdef newppu -> ifndef oldppu Revision 1.30 1998/06/17 14:10:16 peter * small os2 fixes * fixed interdependent units with newppu (remake3 under linux works now) Revision 1.29 1998/06/16 08:56:25 peter + targetcpu * cleaner pmodules for newppu Revision 1.28 1998/06/13 00:10:10 peter * working browser and newppu * some small fixes against crashes which occured in bp7 (but not in fpc?!) Revision 1.27 1998/06/11 13:58:08 peter * small fix to let newppu compile Revision 1.26 1998/06/09 16:01:47 pierre + added procedure directive parsing for procvars (accepted are popstack cdecl and pascal) + added C vars with the following syntax var C calias 'true_c_name';(can be followed by external) reason is that you must add the Cprefix which is target dependent Revision 1.25 1998/06/08 22:59:49 peter * smartlinking works for win32 * some defines to exclude some compiler parts Revision 1.24 1998/06/08 13:13:44 pierre + temporary variables now in temp_gen.pas unit because it is processor independent * mppc68k.bat modified to undefine i386 and support_mmx (which are defaults for i386) Revision 1.23 1998/06/05 17:47:29 peter * some better uses clauses Revision 1.22 1998/06/05 14:37:34 pierre * fixes for inline for operators * inline procedure more correctly restricted Revision 1.21 1998/06/04 23:51:53 peter * m68k compiles + .def file creation moved to gendef.pas so it could also be used for win32 Revision 1.20 1998/06/04 09:55:42 pierre * demangled name of procsym reworked to become independant of the mangling scheme Revision 1.19 1998/06/03 23:40:38 peter + unlimited file support, release tempclose Revision 1.18 1998/06/03 22:49:00 peter + wordbool,longbool * rename bis,von -> high,low * moved some systemunit loading/creating to psystem.pas Revision 1.17 1998/05/28 14:40:25 peter * fixes for newppu, remake3 works now with it Revision 1.16 1998/05/27 19:45:06 peter * symtable.pas splitted into includefiles * symtable adapted for $ifdef NEWPPU Revision 1.15 1998/05/23 01:21:22 peter + aktasmmode, aktoptprocessor, aktoutputformat + smartlink per module $SMARTLINK-/+ (like MMX) and moved to aktswitches + $LIBNAME to set the library name where the unit will be put in * splitted cgi386 a bit (codeseg to large for bp7) * nasm, tasm works again. nasm moved to ag386nsm.pas Revision 1.14 1998/05/20 09:42:35 pierre + UseTokenInfo now default * unit in interface uses and implementation uses gives error now * only one error for unknown symbol (uses lastsymknown boolean) the problem came from the label code ! + first inlined procedures and function work (warning there might be allowed cases were the result is still wrong !!) * UseBrower updated gives a global list of all position of all used symbols with switch -gb Revision 1.13 1998/05/12 10:47:00 peter * moved printstatus to verb_def + V_Normal which is between V_Error and V_Warning and doesn't have a prefix like error: warning: and is included in V_Default * fixed some messages * first time parameter scan is only for -v and -T - removed old style messages Revision 1.12 1998/05/11 13:07:56 peter + $ifdef NEWPPU for the new ppuformat + $define GDB not longer required * removed all warnings and stripped some log comments * no findfirst/findnext anymore to remove smartlink *.o files Revision 1.11 1998/05/06 18:36:53 peter * tai_section extended with code,data,bss sections and enumerated type * ident 'compiled by FPC' moved to pmodules * small fix for smartlink Revision 1.10 1998/05/04 17:54:28 peter + smartlinking works (only case jumptable left todo) * redesign of systems.pas to support assemblers and linkers + Unitname is now also in the PPU-file, increased version to 14 Revision 1.9 1998/05/01 16:38:45 florian * handling of private and protected fixed + change_keywords_to_tp implemented to remove keywords which aren't supported by tp * break and continue are now symbols of the system unit + widestring, longstring and ansistring type released Revision 1.8 1998/04/30 15:59:41 pierre * GDB works again better : correct type info in one pass + UseTokenInfo for better source position * fixed one remaining bug in scanner for line counts * several little fixes Revision 1.7 1998/04/29 10:33:59 pierre + added some code for ansistring (not complete nor working yet) * corrected operator overloading * corrected nasm output + started inline procedures + added starstarn : use ** for exponentiation (^ gave problems) + started UseTokenInfo cond to get accurate positions Revision 1.6 1998/04/27 23:10:28 peter + new scanner * $makelib -> if smartlink * small filename fixes pmodule.setfilename * moved import from files.pas -> import.pas Revision 1.5 1998/04/14 23:27:03 florian + exclude/include with constant second parameter added Revision 1.4 1998/04/10 14:41:43 peter * removed some Hints * small speed optimization for AsmLn Revision 1.3 1998/04/03 09:51:00 daniel * Fixed heap allocation for OS/2. }