paweld/fpc
1
0
Fork 0
mirror of https://gitlab.com/freepascal.org/fpc/source.git synced 2025-10-22 11:46:58 +02:00
Code Issues Packages Projects Releases Wiki Activity
ed290df007
fpc/compiler/i386/n386cal.pas

1638 lines
71 KiB
ObjectPascal
Raw Blame History

{
$Id$
Copyright (c) 1998-2000 by Florian Klaempfl
Generate i386 assembler for in call nodes
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published bymethodpointer
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 n386cal;
{$i defines.inc}
interface
{ $define AnsiStrRef}
uses
symdef,node,ncal;
type
ti386callparanode = class(tcallparanode)
procedure secondcallparan(defcoll : TParaItem;
push_from_left_to_right,inlined,is_cdecl : boolean;
para_alignment,para_offset : longint);override;
end;
ti386callnode = class(tcallnode)
procedure pass_2;override;
end;
ti386procinlinenode = class(tprocinlinenode)
procedure pass_2;override;
end;
implementation
uses
{$ifdef delphi}
sysutils,
{$else}
strings,
{$endif}
globtype,systems,
cutils,verbose,globals,
symconst,symbase,symsym,symtable,aasm,types,
{$ifdef GDB}
gdb,
{$endif GDB}
hcodegen,temp_gen,pass_2,
cpubase,cpuasm,
nmem,nld,
cgai386,tgcpu,n386ld,n386util,regvars;
{*****************************************************************************
TI386CALLPARANODE
*****************************************************************************}
procedure ti386callparanode.secondcallparan(defcoll : TParaItem;
push_from_left_to_right,inlined,is_cdecl : boolean;para_alignment,para_offset : longint);
procedure maybe_push_high;
begin
{ open array ? }
{ defcoll.data can be nil for read/write }
if assigned(defcoll.paratype.def) and
assigned(hightree) then
begin
secondpass(hightree);
{ this is a longint anyway ! }
push_value_para(hightree,inlined,false,para_offset,4);
end;
end;
var
otlabel,oflabel : tasmlabel;
{ temporary variables: }
tempdeftype : tdeftype;
r : preference;
begin
{ set default para_alignment to target_info.stackalignment }
if para_alignment=0 then
para_alignment:=target_info.stackalignment;
{ push from left to right if specified }
if push_from_left_to_right and assigned(right) then
tcallparanode(right).secondcallparan(TParaItem(defcoll.next),push_from_left_to_right,
inlined,is_cdecl,para_alignment,para_offset);
otlabel:=truelabel;
oflabel:=falselabel;
getlabel(truelabel);
getlabel(falselabel);
secondpass(left);
{ filter array constructor with c styled args }
if is_array_constructor(left.resulttype.def) and (nf_cargs in left.flags) then
begin
{ nothing, everything is already pushed }
end
{ in codegen.handleread.. defcoll.data is set to nil }
else if assigned(defcoll.paratype.def) and
(defcoll.paratype.def.deftype=formaldef) then
begin
{ allow @var }
inc(pushedparasize,4);
if (left.nodetype=addrn) and
(not(nf_procvarload in left.flags)) then
begin
{ always a register }
if inlined then
begin
r:=new_reference(procinfo^.framepointer,para_offset-pushedparasize);
emit_reg_ref(A_MOV,S_L,
left.location.register,r);
end
else
emit_reg(A_PUSH,S_L,left.location.register);
ungetregister32(left.location.register);
end
else
begin
if not(left.location.loc in [LOC_MEM,LOC_REFERENCE]) then
CGMessage(type_e_mismatch)
else
begin
if inlined then
begin
getexplicitregister32(R_EDI);
emit_ref_reg(A_LEA,S_L,
newreference(left.location.reference),R_EDI);
r:=new_reference(procinfo^.framepointer,para_offset-pushedparasize);
emit_reg_ref(A_MOV,S_L,R_EDI,r);
ungetregister32(R_EDI);
end
else
emitpushreferenceaddr(left.location.reference);
del_reference(left.location.reference);
end;
end;
end
{ handle call by reference parameter }
else if (defcoll.paratyp in [vs_var,vs_out]) then
begin
if (left.location.loc<>LOC_REFERENCE) then
CGMessage(cg_e_var_must_be_reference);
maybe_push_high;
if (defcoll.paratyp=vs_out) and
assigned(defcoll.paratype.def) and
not is_class(defcoll.paratype.def) and
defcoll.paratype.def.needs_inittable then
finalize(defcoll.paratype.def,left.location.reference,false);
inc(pushedparasize,4);
if inlined then
begin
getexplicitregister32(R_EDI);
emit_ref_reg(A_LEA,S_L,
newreference(left.location.reference),R_EDI);
r:=new_reference(procinfo^.framepointer,para_offset-pushedparasize);
emit_reg_ref(A_MOV,S_L,R_EDI,r);
ungetregister32(R_EDI);
end
else
emitpushreferenceaddr(left.location.reference);
del_reference(left.location.reference);
end
else
begin
tempdeftype:=resulttype.def.deftype;
if tempdeftype=filedef then
CGMessage(cg_e_file_must_call_by_reference);
{ open array must always push the address, this is needed to
also push addr of small open arrays and with cdecl functions (PFV) }
if (
assigned(defcoll.paratype.def) and
(is_open_array(defcoll.paratype.def) or
is_array_of_const(defcoll.paratype.def))
) or
(
push_addr_param(resulttype.def) and
not is_cdecl
) then
begin
maybe_push_high;
inc(pushedparasize,4);
if inlined then
begin
getexplicitregister32(R_EDI);
emit_ref_reg(A_LEA,S_L,
newreference(left.location.reference),R_EDI);
r:=new_reference(procinfo^.framepointer,para_offset-pushedparasize);
emit_reg_ref(A_MOV,S_L,R_EDI,r);
ungetregister32(R_EDI);
end
else
emitpushreferenceaddr(left.location.reference);
del_reference(left.location.reference);
end
else
begin
push_value_para(left,inlined,is_cdecl,
para_offset,para_alignment);
end;
end;
truelabel:=otlabel;
falselabel:=oflabel;
{ push from right to left }
if not push_from_left_to_right and assigned(right) then
tcallparanode(right).secondcallparan(TParaItem(defcoll.next),push_from_left_to_right,
inlined,is_cdecl,para_alignment,para_offset);
end;
{*****************************************************************************
TI386CALLNODE
*****************************************************************************}
procedure ti386callnode.pass_2;
var
unusedregisters : tregisterset;
usablecount : byte;
pushed : tpushed;
hr,funcretref : treference;
hregister,hregister2 : tregister;
oldpushedparasize : longint;
{ true if ESI must be loaded again after the subroutine }
loadesi : boolean;
{ true if a virtual method must be called directly }
no_virtual_call : boolean;
{ true if we produce a con- or destrutor in a call }
is_con_or_destructor : boolean;
{ true if a constructor is called again }
extended_new : boolean;
{ adress returned from an I/O-error }
iolabel : tasmlabel;
{ lexlevel count }
i : longint;
{ help reference pointer }
r : preference;
hp : tnode;
pp : tbinarynode;
params : tnode;
inlined : boolean;
inlinecode : tprocinlinenode;
para_alignment,
para_offset : longint;
{ instruction for alignement correction }
{ corr : paicpu;}
{ we must pop this size also after !! }
{ must_pop : boolean; }
pop_size : longint;
{$ifdef dummy}
push_size : longint;
{$endif}
pop_esp : boolean;
pop_allowed : boolean;
regs_to_push : byte;
constructorfailed : tasmlabel;
label
dont_call;
begin
reset_reference(location.reference);
extended_new:=false;
iolabel:=nil;
inlinecode:=nil;
inlined:=false;
loadesi:=true;
no_virtual_call:=false;
unusedregisters:=unused;
usablecount:=usablereg32;
if ([pocall_cdecl,pocall_cppdecl,pocall_stdcall]*procdefinition.proccalloptions)<>[] then
para_alignment:=4
else
para_alignment:=target_info.stackalignment;
if not assigned(procdefinition) then
exit;
{ Deciding whether we may still need the parameters happens next (JM) }
if assigned(left) then
params:=left.getcopy
else params := nil;
if (pocall_inline in procdefinition.proccalloptions) then
begin
inlined:=true;
inlinecode:=tprocinlinenode(right);
{ set it to the same lexical level as the local symtable, becuase
the para's are stored there }
tprocdef(procdefinition).parast.symtablelevel:=aktprocsym.definition.localst.symtablelevel;
if assigned(params) then
inlinecode.para_offset:=gettempofsizepersistant(inlinecode.para_size);
tprocdef(procdefinition).parast.address_fixup:=inlinecode.para_offset;
{$ifdef extdebug}
Comment(V_debug,
'inlined parasymtable is at offset '
+tostr(tprocdef(procdefinition).parast.address_fixup));
exprasmList.concat(Tai_asm_comment.Create(
strpnew('inlined parasymtable is at offset '
+tostr(tprocdef(procdefinition).parast.address_fixup))));
{$endif extdebug}
{ disable further inlining of the same proc
in the args }
exclude(procdefinition.proccalloptions,pocall_inline);
end;
{ only if no proc var }
if inlined or
not(assigned(right)) then
is_con_or_destructor:=(procdefinition.proctypeoption in [potype_constructor,potype_destructor]);
{ proc variables destroy all registers }
if (inlined or
(right=nil)) and
{ virtual methods too }
not(po_virtualmethod in procdefinition.procoptions) then
begin
if (cs_check_io in aktlocalswitches) and
(po_iocheck in procdefinition.procoptions) and
not(po_iocheck in aktprocsym.definition.procoptions) then
begin
getaddrlabel(iolabel);
emitlab(iolabel);
end
else
iolabel:=nil;
{ save all used registers }
regs_to_push := tprocdef(procdefinition).usedregisters;
pushusedregisters(pushed,regs_to_push);
{ give used registers through }
usedinproc:=usedinproc or tprocdef(procdefinition).usedregisters;
end
else
begin
regs_to_push := $ff;
pushusedregisters(pushed,regs_to_push);
usedinproc:=$ff;
{ no IO check for methods and procedure variables }
iolabel:=nil;
end;
{ generate the code for the parameter and push them }
oldpushedparasize:=pushedparasize;
pushedparasize:=0;
pop_size:=0;
{ no inc esp for inlined procedure
and for objects constructors PM }
if (inlined or
(right=nil)) and
(procdefinition.proctypeoption=potype_constructor) and
{ quick'n'dirty check if it is a class or an object }
(resulttype.def.deftype=orddef) then
pop_allowed:=false
else
pop_allowed:=true;
if pop_allowed then
begin
{ Old pushedsize aligned on 4 ? }
i:=oldpushedparasize and 3;
if i>0 then
inc(pop_size,4-i);
{ This parasize aligned on 4 ? }
i:=procdefinition.para_size(para_alignment) and 3;
if i>0 then
inc(pop_size,4-i);
{ insert the opcode and update pushedparasize }
{ never push 4 or more !! }
pop_size:=pop_size mod 4;
if pop_size>0 then
begin
inc(pushedparasize,pop_size);
emit_const_reg(A_SUB,S_L,pop_size,R_ESP);
{$ifdef GDB}
if (cs_debuginfo in aktmoduleswitches) and
(exprasmList.first=exprasmList.last) then
exprasmList.concat(Tai_force_line.Create);
{$endif GDB}
end;
end;
{$ifdef dummy}
if pop_allowed and (cs_align in aktglobalswitches) then
begin
pop_esp:=true;
push_size:=procdefinition.para_size(para_alignment);
{ !!!! here we have to take care of return type, self
and nested procedures
}
inc(push_size,12);
emit_reg_reg(A_MOV,S_L,R_ESP,R_EDI);
if (push_size mod 8)=0 then
emit_const_reg(A_AND,S_L,longint($fffffff8),R_ESP)
else
begin
emit_const_reg(A_SUB,S_L,push_size,R_ESP);
emit_const_reg(A_AND,S_L,longint($fffffff8),R_ESP);
emit_const_reg(A_SUB,S_L,push_size,R_ESP);
end;
emit_reg(A_PUSH,S_L,R_EDI);
end
else
{$endif dummy}
pop_esp:=false;
if (not is_void(resulttype.def)) and
ret_in_param(resulttype.def) then
begin
funcretref.symbol:=nil;
{$ifdef test_dest_loc}
if dest_loc_known and (dest_loc_tree=p) and
(dest_loc.loc in [LOC_REFERENCE,LOC_MEM]) then
begin
funcretref:=dest_loc.reference;
if assigned(dest_loc.reference.symbol) then
funcretref.symbol:=stringdup(dest_loc.reference.symbol^);
in_dest_loc:=true;
end
else
{$endif test_dest_loc}
if inlined then
begin
reset_reference(funcretref);
funcretref.offset:=gettempofsizepersistant(procdefinition.rettype.def.size);
funcretref.base:=procinfo^.framepointer;
end
else
gettempofsizereference(procdefinition.rettype.def.size,funcretref);
end;
if assigned(params) then
begin
{ be found elsewhere }
if inlined then
para_offset:=tprocdef(procdefinition).parast.address_fixup+
tprocdef(procdefinition).parast.datasize
else
para_offset:=0;
if not(inlined) and
assigned(right) then
tcallparanode(params).secondcallparan(TParaItem(tabstractprocdef(right.resulttype.def).Para.first),
(pocall_leftright in procdefinition.proccalloptions),inlined,
(([pocall_cdecl,pocall_cppdecl]*procdefinition.proccalloptions)<>[]),
para_alignment,para_offset)
else
tcallparanode(params).secondcallparan(TParaItem(procdefinition.Para.first),
(pocall_leftright in procdefinition.proccalloptions),inlined,
(([pocall_cdecl,pocall_cppdecl]*procdefinition.proccalloptions)<>[]),
para_alignment,para_offset);
end;
if inlined then
inlinecode.retoffset:=gettempofsizepersistant(4);
if ret_in_param(resulttype.def) then
begin
{ This must not be counted for C code
complex return address is removed from stack
by function itself ! }
{$ifdef OLD_C_STACK}
inc(pushedparasize,4); { lets try without it PM }
{$endif not OLD_C_STACK}
if inlined then
begin
getexplicitregister32(R_EDI);
emit_ref_reg(A_LEA,S_L,
newreference(funcretref),R_EDI);
r:=new_reference(procinfo^.framepointer,inlinecode.retoffset);
emit_reg_ref(A_MOV,S_L,R_EDI,r);
ungetregister32(R_EDI);
end
else
emitpushreferenceaddr(funcretref);
end;
{ procedure variable ? }
if inlined or
(right=nil) then
begin
{ overloaded operator have no symtable }
{ push self }
if assigned(symtableproc) and
(symtableproc.symtabletype=withsymtable) then
begin
{ dirty trick to avoid the secondcall below }
methodpointer:=ccallparanode.create(nil,nil);
methodpointer.location.loc:=LOC_REGISTER;
getexplicitregister32(R_ESI);
methodpointer.location.register:=R_ESI;
{ ARGHHH this is wrong !!!
if we can init from base class for a child
class that the wrong VMT will be
transfered to constructor !! }
methodpointer.resulttype:=
twithnode(twithsymtable(symtableproc).withnode).left.resulttype;
{ make a reference }
new(r);
reset_reference(r^);
{ if assigned(ptree(twithsymtable(symtable).withnode)^.pref) then
begin
r^:=ptree(twithsymtable(symtable).withnode)^.pref^;
end
else
begin
r^.offset:=symtable.datasize;
r^.base:=procinfo^.framepointer;
end; }
r^:=twithnode(twithsymtable(symtableproc).withnode).withreference^;
if ((not(nf_islocal in twithnode(twithsymtable(symtableproc).withnode).flags)) and
(not twithsymtable(symtableproc).direct_with)) or
is_class_or_interface(methodpointer.resulttype.def) then
emit_ref_reg(A_MOV,S_L,r,R_ESI)
else
emit_ref_reg(A_LEA,S_L,r,R_ESI);
end;
{ push self }
if assigned(symtableproc) and
((symtableproc.symtabletype=objectsymtable) or
(symtableproc.symtabletype=withsymtable)) then
begin
if assigned(methodpointer) then
begin
{
if methodpointer^.resulttype.def=classrefdef then
begin
two possibilities:
1. constructor
2. class method
end
else }
begin
case methodpointer.nodetype of
typen:
begin
{ direct call to inherited method }
if (po_abstractmethod in procdefinition.procoptions) then
begin
CGMessage(cg_e_cant_call_abstract_method);
goto dont_call;
end;
{ generate no virtual call }
no_virtual_call:=true;
if (sp_static in symtableprocentry.symoptions) then
begin
{ well lets put the VMT address directly into ESI }
{ it is kind of dirty but that is the simplest }
{ way to accept virtual static functions (PM) }
loadesi:=true;
{ if no VMT just use $0 bug0214 PM }
getexplicitregister32(R_ESI);
if not(oo_has_vmt in tobjectdef(methodpointer.resulttype.def).objectoptions) then
emit_const_reg(A_MOV,S_L,0,R_ESI)
else
begin
emit_sym_ofs_reg(A_MOV,S_L,
newasmsymbol(tobjectdef(methodpointer.resulttype.def).vmt_mangledname),
0,R_ESI);
end;
{ emit_reg(A_PUSH,S_L,R_ESI);
this is done below !! }
end
else
{ this is a member call, so ESI isn't modfied }
loadesi:=false;
{ a class destructor needs a flag }
if is_class(tobjectdef(methodpointer.resulttype.def)) and
{assigned(aktprocsym) and
(aktprocsym.definition.proctypeoption=potype_destructor)}
(procdefinition.proctypeoption=potype_destructor) then
begin
push_int(0);
emit_reg(A_PUSH,S_L,R_ESI);
end;
if not(is_con_or_destructor and
is_class(methodpointer.resulttype.def) and
{assigned(aktprocsym) and
(aktprocsym.definition.proctypeoption in [potype_constructor,potype_destructor])}
(procdefinition.proctypeoption in [potype_constructor,potype_destructor])
) then
emit_reg(A_PUSH,S_L,R_ESI);
{ if an inherited con- or destructor should be }
{ called in a con- or destructor then a warning }
{ will be made }
{ con- and destructors need a pointer to the vmt }
if is_con_or_destructor and
is_object(methodpointer.resulttype.def) and
assigned(aktprocsym) then
begin
if not(aktprocsym.definition.proctypeoption in
[potype_constructor,potype_destructor]) then
CGMessage(cg_w_member_cd_call_from_method);
end;
{ class destructors get there flag above }
{ constructor flags ? }
if is_con_or_destructor and
not(
is_class(methodpointer.resulttype.def) and
assigned(aktprocsym) and
(aktprocsym.definition.proctypeoption=potype_destructor)) then
begin
{ a constructor needs also a flag }
if is_class(methodpointer.resulttype.def) then
push_int(0);
push_int(0);
end;
end;
hnewn:
begin
{ extended syntax of new }
{ ESI must be zero }
getexplicitregister32(R_ESI);
emit_reg_reg(A_XOR,S_L,R_ESI,R_ESI);
emit_reg(A_PUSH,S_L,R_ESI);
{ insert the vmt }
emit_sym(A_PUSH,S_L,
newasmsymbol(tobjectdef(methodpointer.resulttype.def).vmt_mangledname));
extended_new:=true;
end;
hdisposen:
begin
secondpass(methodpointer);
{ destructor with extended syntax called from dispose }
{ hdisposen always deliver LOC_REFERENCE }
getexplicitregister32(R_ESI);
emit_ref_reg(A_LEA,S_L,
newreference(methodpointer.location.reference),R_ESI);
del_reference(methodpointer.location.reference);
emit_reg(A_PUSH,S_L,R_ESI);
emit_sym(A_PUSH,S_L,
newasmsymbol(tobjectdef(methodpointer.resulttype.def).vmt_mangledname));
end;
else
begin
{ call to an instance member }
if (symtableproc.symtabletype<>withsymtable) then
begin
secondpass(methodpointer);
getexplicitregister32(R_ESI);
case methodpointer.location.loc of
LOC_CREGISTER,
LOC_REGISTER:
begin
emit_reg_reg(A_MOV,S_L,methodpointer.location.register,R_ESI);
ungetregister32(methodpointer.location.register);
end;
else
begin
if (methodpointer.resulttype.def.deftype=classrefdef) or
is_class_or_interface(methodpointer.resulttype.def) then
emit_ref_reg(A_MOV,S_L,
newreference(methodpointer.location.reference),R_ESI)
else
emit_ref_reg(A_LEA,S_L,
newreference(methodpointer.location.reference),R_ESI);
del_reference(methodpointer.location.reference);
end;
end;
end;
{ when calling a class method, we have to load ESI with the VMT !
But, not for a class method via self }
if not(po_containsself in procdefinition.procoptions) then
begin
if (po_classmethod in procdefinition.procoptions) and
not(methodpointer.resulttype.def.deftype=classrefdef) then
begin
{ class method needs current VMT }
getexplicitregister32(R_ESI);
new(r);
reset_reference(r^);
r^.base:=R_ESI;
r^.offset:= tprocdef(procdefinition)._class.vmt_offset;
emit_ref_reg(A_MOV,S_L,r,R_ESI);
end;
{ direct call to destructor: remove data }
if (procdefinition.proctypeoption=potype_destructor) and
is_class(methodpointer.resulttype.def) then
emit_const(A_PUSH,S_L,1);
{ direct call to class constructor, don't allocate memory }
if (procdefinition.proctypeoption=potype_constructor) and
is_class(methodpointer.resulttype.def) then
begin
emit_const(A_PUSH,S_L,0);
emit_const(A_PUSH,S_L,0);
end
else
begin
{ constructor call via classreference => allocate memory }
if (procdefinition.proctypeoption=potype_constructor) and
(methodpointer.resulttype.def.deftype=classrefdef) and
is_class(tclassrefdef(methodpointer.resulttype.def).pointertype.def) then
emit_const(A_PUSH,S_L,1);
emit_reg(A_PUSH,S_L,R_ESI);
end;
end;
if is_con_or_destructor then
begin
{ classes don't get a VMT pointer pushed }
if is_object(methodpointer.resulttype.def) then
begin
if (procdefinition.proctypeoption=potype_constructor) then
begin
{ it's no bad idea, to insert the VMT }
emit_sym(A_PUSH,S_L,newasmsymbol(
tobjectdef(methodpointer.resulttype.def).vmt_mangledname));
end
{ destructors haven't to dispose the instance, if this is }
{ a direct call }
else
push_int(0);
end;
end;
end;
end;
end;
end
else
begin
if (po_classmethod in procdefinition.procoptions) and
not(
assigned(aktprocsym) and
(po_classmethod in aktprocsym.definition.procoptions)
) then
begin
{ class method needs current VMT }
getexplicitregister32(R_ESI);
new(r);
reset_reference(r^);
r^.base:=R_ESI;
r^.offset:= tprocdef(procdefinition)._class.vmt_offset;
emit_ref_reg(A_MOV,S_L,r,R_ESI);
end
else
begin
{ member call, ESI isn't modified }
loadesi:=false;
end;
{ direct call to destructor: don't remove data! }
if is_class(procinfo^._class) then
begin
if (procdefinition.proctypeoption=potype_destructor) then
begin
emit_const(A_PUSH,S_L,0);
emit_reg(A_PUSH,S_L,R_ESI);
end
else if (procdefinition.proctypeoption=potype_constructor) then
begin
emit_const(A_PUSH,S_L,0);
emit_const(A_PUSH,S_L,0);
end
else
emit_reg(A_PUSH,S_L,R_ESI);
end
else if is_object(procinfo^._class) then
begin
emit_reg(A_PUSH,S_L,R_ESI);
if is_con_or_destructor then
begin
if (procdefinition.proctypeoption=potype_constructor) then
begin
{ it's no bad idea, to insert the VMT }
emit_sym(A_PUSH,S_L,newasmsymbol(
procinfo^._class.vmt_mangledname));
end
{ destructors haven't to dispose the instance, if this is }
{ a direct call }
else
push_int(0);
end;
end
else
Internalerror(200006165);
end;
end;
{ call to BeforeDestruction? }
if (procdefinition.proctypeoption=potype_destructor) and
assigned(methodpointer) and
(methodpointer.nodetype<>typen) and
is_class(tobjectdef(methodpointer.resulttype.def)) and
(inlined or
(right=nil)) then
begin
emit_reg(A_PUSH,S_L,R_ESI);
new(r);
reset_reference(r^);
r^.base:=R_ESI;
getexplicitregister32(R_EDI);
emit_ref_reg(A_MOV,S_L,r,R_EDI);
new(r);
reset_reference(r^);
r^.offset:=72;
r^.base:=R_EDI;
emit_ref(A_CALL,S_NO,r);
ungetregister32(R_EDI);
end;
{ push base pointer ?}
if (lexlevel>=normal_function_level) and assigned(tprocdef(procdefinition).parast) and
((tprocdef(procdefinition).parast.symtablelevel)>normal_function_level) then
begin
{ if we call a nested function in a method, we must }
{ push also SELF! }
{ THAT'S NOT TRUE, we have to load ESI via frame pointer }
{ access }
{
begin
loadesi:=false;
emit_reg(A_PUSH,S_L,R_ESI);
end;
}
if lexlevel=(tprocdef(procdefinition).parast.symtablelevel) then
begin
new(r);
reset_reference(r^);
r^.offset:=procinfo^.framepointer_offset;
r^.base:=procinfo^.framepointer;
emit_ref(A_PUSH,S_L,r)
end
{ this is only true if the difference is one !!
but it cannot be more !! }
else if (lexlevel=tprocdef(procdefinition).parast.symtablelevel-1) then
begin
emit_reg(A_PUSH,S_L,procinfo^.framepointer)
end
else if (lexlevel>tprocdef(procdefinition).parast.symtablelevel) then
begin
hregister:=getregister32;
new(r);
reset_reference(r^);
r^.offset:=procinfo^.framepointer_offset;
r^.base:=procinfo^.framepointer;
emit_ref_reg(A_MOV,S_L,r,hregister);
for i:=(tprocdef(procdefinition).parast.symtablelevel) to lexlevel-1 do
begin
new(r);
reset_reference(r^);
{we should get the correct frame_pointer_offset at each level
how can we do this !!! }
r^.offset:=procinfo^.framepointer_offset;
r^.base:=hregister;
emit_ref_reg(A_MOV,S_L,r,hregister);
end;
emit_reg(A_PUSH,S_L,hregister);
ungetregister32(hregister);
end
else
internalerror(25000);
end;
saveregvars(regs_to_push);
if (po_virtualmethod in procdefinition.procoptions) and
not(no_virtual_call) then
begin
{ static functions contain the vmt_address in ESI }
{ also class methods }
{ Here it is quite tricky because it also depends }
{ on the methodpointer PM }
getexplicitregister32(R_ESI);
if assigned(aktprocsym) then
begin
if (((sp_static in aktprocsym.symoptions) or
(po_classmethod in aktprocsym.definition.procoptions)) and
((methodpointer=nil) or (methodpointer.nodetype=typen)))
or
(po_staticmethod in procdefinition.procoptions) or
((procdefinition.proctypeoption=potype_constructor) and
{ esi contains the vmt if we call a constructor via a class ref }
assigned(methodpointer) and
(methodpointer.resulttype.def.deftype=classrefdef)
) or
{ is_interface(tprocdef(procdefinition)._class) or }
{ ESI is loaded earlier }
(po_classmethod in procdefinition.procoptions) then
begin
new(r);
reset_reference(r^);
r^.base:=R_ESI;
end
else
begin
new(r);
reset_reference(r^);
r^.base:=R_ESI;
{ this is one point where we need vmt_offset (PM) }
r^.offset:= tprocdef(procdefinition)._class.vmt_offset;
getexplicitregister32(R_EDI);
emit_ref_reg(A_MOV,S_L,r,R_EDI);
new(r);
reset_reference(r^);
r^.base:=R_EDI;
end;
end
else
{ aktprocsym should be assigned, also in main program }
internalerror(12345);
{
begin
new(r);
reset_reference(r^);
r^.base:=R_ESI;
emit_ref_reg(A_MOV,S_L,r,R_EDI);
new(r);
reset_reference(r^);
r^.base:=R_EDI;
end;
}
if tprocdef(procdefinition).extnumber=-1 then
internalerror(44584);
r^.offset:=tprocdef(procdefinition)._class.vmtmethodoffset(tprocdef(procdefinition).extnumber);
if not(is_interface(tprocdef(procdefinition)._class)) and
not(is_cppclass(tprocdef(procdefinition)._class)) then
begin
if (cs_check_object_ext in aktlocalswitches) then
begin
emit_sym(A_PUSH,S_L,
newasmsymbol(tprocdef(procdefinition)._class.vmt_mangledname));
emit_reg(A_PUSH,S_L,r^.base);
emitcall('FPC_CHECK_OBJECT_EXT');
end
else if (cs_check_range in aktlocalswitches) then
begin
emit_reg(A_PUSH,S_L,r^.base);
emitcall('FPC_CHECK_OBJECT');
end;
end;
emit_ref(A_CALL,S_NO,r);
ungetregister32(R_EDI);
end
else if not inlined then
begin
{ We can call interrupts from within the smae code
by just pushing the flags and CS PM }
if (po_interrupt in procdefinition.procoptions) then
begin
emit_none(A_PUSHF,S_L);
emit_reg(A_PUSH,S_L,R_CS);
end;
emitcall(tprocdef(procdefinition).mangledname);
end
else { inlined proc }
{ inlined code is in inlinecode }
begin
{ set poinline again }
include(procdefinition.proccalloptions,pocall_inline);
{ process the inlinecode }
secondpass(inlinecode);
{ free the args }
if tprocdef(procdefinition).parast.datasize>0 then
ungetpersistanttemp(tprocdef(procdefinition).parast.address_fixup);
end;
end
else
{ now procedure variable case }
begin
secondpass(right);
if (po_interrupt in procdefinition.procoptions) then
begin
emit_none(A_PUSHF,S_L);
emit_reg(A_PUSH,S_L,R_CS);
end;
{ procedure of object? }
if (po_methodpointer in procdefinition.procoptions) then
begin
{ method pointer can't be in a register }
hregister:=R_NO;
{ do some hacking if we call a method pointer }
{ which is a class member }
{ else ESI is overwritten ! }
if (right.location.reference.base=R_ESI) or
(right.location.reference.index=R_ESI) then
begin
del_reference(right.location.reference);
getexplicitregister32(R_EDI);
emit_ref_reg(A_MOV,S_L,
newreference(right.location.reference),R_EDI);
hregister:=R_EDI;
end;
{ load self, but not if it's already explicitly pushed }
if not(po_containsself in procdefinition.procoptions) then
begin
{ load ESI }
inc(right.location.reference.offset,4);
getexplicitregister32(R_ESI);
emit_ref_reg(A_MOV,S_L,
newreference(right.location.reference),R_ESI);
dec(right.location.reference.offset,4);
{ push self pointer }
emit_reg(A_PUSH,S_L,R_ESI);
end;
saveregvars($ff);
if hregister=R_NO then
emit_ref(A_CALL,S_NO,newreference(right.location.reference))
else
begin
ungetregister32(hregister);
emit_reg(A_CALL,S_NO,hregister);
end;
del_reference(right.location.reference);
end
else
begin
saveregvars($ff);
case right.location.loc of
LOC_REGISTER,LOC_CREGISTER:
begin
emit_reg(A_CALL,S_NO,right.location.register);
ungetregister32(right.location.register);
end
else
emit_ref(A_CALL,S_NO,newreference(right.location.reference));
del_reference(right.location.reference);
end;
end;
end;
{ this was only for normal functions
displaced here so we also get
it to work for procvars PM }
if (not inlined) and (pocall_clearstack in procdefinition.proccalloptions) then
begin
{ we also add the pop_size which is included in pushedparasize }
pop_size:=0;
{ better than an add on all processors }
if pushedparasize=4 then
begin
getexplicitregister32(R_EDI);
emit_reg(A_POP,S_L,R_EDI);
ungetregister32(R_EDI);
end
{ the pentium has two pipes and pop reg is pairable }
{ but the registers must be different! }
else if (pushedparasize=8) and
not(cs_littlesize in aktglobalswitches) and
(aktoptprocessor=ClassP5) and
(procinfo^._class=nil) then
begin
getexplicitregister32(R_EDI);
emit_reg(A_POP,S_L,R_EDI);
ungetregister32(R_EDI);
exprasmList.concat(Tairegalloc.Alloc(R_ESI));
emit_reg(A_POP,S_L,R_ESI);
exprasmList.concat(Tairegalloc.Alloc(R_ESI));
end
else if pushedparasize<>0 then
emit_const_reg(A_ADD,S_L,pushedparasize,R_ESP);
end;
if pop_esp then
emit_reg(A_POP,S_L,R_ESP);
dont_call:
pushedparasize:=oldpushedparasize;
unused:=unusedregisters;
usablereg32:=usablecount;
{$ifdef TEMPREGDEBUG}
testregisters32;
{$endif TEMPREGDEBUG}
{ a constructor could be a function with boolean result }
{ if calling constructor called fail we
must jump directly to quickexitlabel PM
but only if it is a call of an inherited constructor }
if (inlined or
(right=nil)) and
(procdefinition.proctypeoption=potype_constructor) and
assigned(methodpointer) and
(methodpointer.nodetype=typen) and
(aktprocsym.definition.proctypeoption=potype_constructor) then
begin
emitjmp(C_Z,faillabel);
end;
{ call to AfterConstruction? }
if is_class(resulttype.def) and
(inlined or
(right=nil)) and
(procdefinition.proctypeoption=potype_constructor) and
assigned(methodpointer) and
(methodpointer.nodetype<>typen) then
begin
getlabel(constructorfailed);
emitjmp(C_Z,constructorfailed);
emit_reg(A_PUSH,S_L,R_ESI);
new(r);
reset_reference(r^);
r^.base:=R_ESI;
getexplicitregister32(R_EDI);
emit_ref_reg(A_MOV,S_L,r,R_EDI);
new(r);
reset_reference(r^);
r^.offset:=68;
r^.base:=R_EDI;
emit_ref(A_CALL,S_NO,r);
ungetregister32(R_EDI);
exprasmList.concat(Tairegalloc.Alloc(R_EAX));
emitlab(constructorfailed);
emit_reg_reg(A_MOV,S_L,R_ESI,R_EAX);
end;
{ handle function results }
{ structured results are easy to handle.... }
{ needed also when result_no_used !! }
if (not is_void(resulttype.def)) and ret_in_param(resulttype.def) then
begin
location.loc:=LOC_MEM;
location.reference.symbol:=nil;
location.reference:=funcretref;
end;
{ we have only to handle the result if it is used, but }
{ ansi/widestrings must be registered, so we can dispose them }
if (not is_void(resulttype.def)) and ((nf_return_value_used in flags) or
is_ansistring(resulttype.def) or is_widestring(resulttype.def)) then
begin
{ a contructor could be a function with boolean result }
if (inlined or
(right=nil)) and
(procdefinition.proctypeoption=potype_constructor) and
{ quick'n'dirty check if it is a class or an object }
(resulttype.def.deftype=orddef) then
begin
{ this fails if popsize > 0 PM }
location.loc:=LOC_FLAGS;
location.resflags:=F_NE;
if extended_new then
begin
{$ifdef test_dest_loc}
if dest_loc_known and (dest_loc_tree=p) then
mov_reg_to_dest(p,S_L,R_EAX)
else
{$endif test_dest_loc}
begin
hregister:=getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_L,R_EAX,hregister);
location.register:=hregister;
end;
end;
end
{ structed results are easy to handle.... }
else if ret_in_param(resulttype.def) then
begin
{location.loc:=LOC_MEM;
stringdispose(location.reference.symbol);
location.reference:=funcretref;
already done above (PM) }
end
else
begin
if (resulttype.def.deftype in [orddef,enumdef]) then
begin
location.loc:=LOC_REGISTER;
case resulttype.def.size of
4 :
begin
{$ifdef test_dest_loc}
if dest_loc_known and (dest_loc_tree=p) then
mov_reg_to_dest(p,S_L,R_EAX)
else
{$endif test_dest_loc}
begin
hregister:=getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_L,R_EAX,hregister);
location.register:=hregister;
end;
end;
1 :
begin
{$ifdef test_dest_loc}
if dest_loc_known and (dest_loc_tree=p) then
mov_reg_to_dest(p,S_B,R_AL)
else
{$endif test_dest_loc}
begin
hregister:=getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_B,R_AL,reg32toreg8(hregister));
location.register:=reg32toreg8(hregister);
end;
end;
2 :
begin
{$ifdef test_dest_loc}
if dest_loc_known and (dest_loc_tree=p) then
mov_reg_to_dest(p,S_W,R_AX)
else
{$endif test_dest_loc}
begin
hregister:=getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_W,R_AX,reg32toreg16(hregister));
location.register:=reg32toreg16(hregister);
end;
end;
8 :
begin
{$ifdef test_dest_loc}
{$error Don't know what to do here}
{$endif test_dest_loc}
if R_EDX in unused then
begin
hregister2:=getexplicitregister32(R_EDX);
hregister:=getexplicitregister32(R_EAX);
end
else
begin
hregister:=getexplicitregister32(R_EAX);
hregister2:=getexplicitregister32(R_EDX);
end;
emit_reg_reg(A_MOV,S_L,R_EAX,hregister);
emit_reg_reg(A_MOV,S_L,R_EDX,hregister2);
location.registerlow:=hregister;
location.registerhigh:=hregister2;
end;
else internalerror(7);
end
end
else if (resulttype.def.deftype=floatdef) then
begin
location.loc:=LOC_FPU;
inc(fpuvaroffset);
end
else if is_ansistring(resulttype.def) or
is_widestring(resulttype.def) then
begin
hregister:=getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_L,R_EAX,hregister);
gettempansistringreference(hr);
decrstringref(resulttype.def,hr);
emit_reg_ref(A_MOV,S_L,hregister,
newreference(hr));
ungetregister32(hregister);
location.loc:=LOC_MEM;
location.reference:=hr;
end
else
begin
location.loc:=LOC_REGISTER;
{$ifdef test_dest_loc}
if dest_loc_known and (dest_loc_tree=p) then
mov_reg_to_dest(p,S_L,R_EAX)
else
{$endif test_dest_loc}
begin
hregister:=getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_L,R_EAX,hregister);
location.register:=hregister;
end;
end;
end;
end;
{ perhaps i/o check ? }
if iolabel<>nil then
begin
emit_sym(A_PUSH,S_L,iolabel);
emitcall('FPC_IOCHECK');
end;
if pop_size>0 then
emit_const_reg(A_ADD,S_L,pop_size,R_ESP);
{ restore registers }
popusedregisters(pushed);
{ at last, restore instance pointer (SELF) }
if loadesi then
maybe_loadself;
pp:=tbinarynode(params);
while assigned(pp) do
begin
if assigned(pp.left) then
begin
if (pp.left.location.loc in [LOC_REFERENCE,LOC_MEM]) then
ungetiftemp(pp.left.location.reference);
{ process also all nodes of an array of const }
if pp.left.nodetype=arrayconstructorn then
begin
if assigned(tarrayconstructornode(pp.left).left) then
begin
hp:=pp.left;
while assigned(hp) do
begin
if (tarrayconstructornode(tunarynode(hp).left).location.loc in [LOC_REFERENCE,LOC_MEM]) then
ungetiftemp(tarrayconstructornode(hp).left.location.reference);
hp:=tbinarynode(hp).right;
end;
end;
end;
end;
pp:=tbinarynode(pp.right);
end;
if inlined then
ungetpersistanttemp(inlinecode.retoffset);
if assigned(params) then
params.free;
{ from now on the result can be freed normally }
if inlined and ret_in_param(resulttype.def) then
persistanttemptonormal(funcretref.offset);
{ if return value is not used }
if (not(nf_return_value_used in flags)) and (not is_void(resulttype.def)) then
begin
if location.loc in [LOC_MEM,LOC_REFERENCE] then
begin
{ data which must be finalized ? }
if (resulttype.def.needs_inittable) then
finalize(resulttype.def,location.reference,false);
{ release unused temp }
ungetiftemp(location.reference)
end
else if location.loc=LOC_FPU then
begin
{ release FPU stack }
emit_reg(A_FSTP,S_NO,R_ST0);
{
dec(fpuvaroffset);
do NOT decrement as the increment before
is not called for unused results PM }
end;
end;
end;
{*****************************************************************************
TI386PROCINLINENODE
*****************************************************************************}
procedure ti386procinlinenode.pass_2;
var st : tsymtable;
oldprocsym : tprocsym;
ps, i : longint;
tmpreg: tregister;
oldprocinfo : pprocinfo;
oldinlining_procedure,
nostackframe,make_global : boolean;
inlineentrycode,inlineexitcode : TAAsmoutput;
oldexitlabel,oldexit2label,oldquickexitlabel:tasmlabel;
oldunused,oldusableregs : tregisterset;
oldc_usableregs : longint;
oldreg_pushes : regvar_longintarray;
oldregvar_loaded,
oldis_reg_var : regvar_booleanarray;
{$ifdef TEMPREGDEBUG}
oldreg_user : regvar_ptreearray;
oldreg_releaser : regvar_ptreearray;
{$endif TEMPREGDEBUG}
{$ifdef GDB}
startlabel,endlabel : tasmlabel;
pp : pchar;
mangled_length : longint;
{$endif GDB}
begin
{ deallocate the registers used for the current procedure's regvars }
if assigned(aktprocsym.definition.regvarinfo) then
begin
with pregvarinfo(aktprocsym.definition.regvarinfo)^ do
for i := 1 to maxvarregs do
if assigned(regvars[i]) then
store_regvar(exprasmlist,regvars[i].reg);
oldunused := unused;
oldusableregs := usableregs;
oldc_usableregs := c_usableregs;
oldreg_pushes := reg_pushes;
oldis_reg_var := is_reg_var;
oldregvar_loaded := regvar_loaded;
{$ifdef TEMPREGDEBUG}
oldreg_user := reg_user;
oldreg_releaser := reg_releaser;
{$endif TEMPREGDEBUG}
{ make sure the register allocator knows what the regvars in the }
{ inlined code block are (JM) }
resetusableregisters;
clearregistercount;
cleartempgen;
if assigned(inlineprocsym.definition.regvarinfo) then
with pregvarinfo(inlineprocsym.definition.regvarinfo)^ do
for i := 1 to maxvarregs do
if assigned(regvars[i]) then
begin
case regsize(regvars[i].reg) of
S_B: tmpreg := reg8toreg32(regvars[i].reg);
S_W: tmpreg := reg16toreg32(regvars[i].reg);
S_L: tmpreg := regvars[i].reg;
end;
usableregs:=usableregs-[tmpreg];
is_reg_var[tmpreg]:=true;
dec(c_usableregs);
end;
end;
oldinlining_procedure:=inlining_procedure;
oldexitlabel:=aktexitlabel;
oldexit2label:=aktexit2label;
oldquickexitlabel:=quickexitlabel;
getlabel(aktexitlabel);
getlabel(aktexit2label);
oldprocsym:=aktprocsym;
{ we're inlining a procedure }
inlining_procedure:=true;
{ save old procinfo }
getmem(oldprocinfo,sizeof(tprocinfo));
move(procinfo^,oldprocinfo^,sizeof(tprocinfo));
{ set the return value }
aktprocsym:=inlineprocsym;
procinfo^.returntype:=aktprocsym.definition.rettype;
procinfo^.return_offset:=retoffset;
procinfo^.para_offset:=para_offset;
{ arg space has been filled by the parent secondcall }
st:=aktprocsym.definition.localst;
{ set it to the same lexical level }
st.symtablelevel:=oldprocsym.definition.localst.symtablelevel;
if st.datasize>0 then
begin
st.address_fixup:=gettempofsizepersistant(st.datasize)+st.datasize;
{$ifdef extdebug}
Comment(V_debug,'local symtable is at offset '+tostr(st.address_fixup));
exprasmList.concat(Tai_asm_comment.Create(strpnew(
'local symtable is at offset '+tostr(st.address_fixup))));
{$endif extdebug}
end;
exprasmList.concat(Tai_Marker.Create(InlineStart));
{$ifdef extdebug}
exprasmList.concat(Tai_asm_comment.Create(strpnew('Start of inlined proc')));
{$endif extdebug}
{$ifdef GDB}
if (cs_debuginfo in aktmoduleswitches) then
begin
getaddrlabel(startlabel);
getaddrlabel(endlabel);
emitlab(startlabel);
inlineprocsym.definition.localst.symtabletype:=inlinelocalsymtable;
inlineprocsym.definition.parast.symtabletype:=inlineparasymtable;
{ Here we must include the para and local symtable info }
inlineprocsym.concatstabto(withdebuglist);
{ set it back for safety }
inlineprocsym.definition.localst.symtabletype:=localsymtable;
inlineprocsym.definition.parast.symtabletype:=parasymtable;
mangled_length:=length(oldprocsym.definition.mangledname);
getmem(pp,mangled_length+50);
strpcopy(pp,'192,0,0,'+startlabel.name);
if (target_info.use_function_relative_addresses) then
begin
strpcopy(strend(pp),'-');
strpcopy(strend(pp),oldprocsym.definition.mangledname);
end;
withdebugList.concat(Tai_stabn.Create(strnew(pp)));
end;
{$endif GDB}
{ takes care of local data initialization }
inlineentrycode:=TAAsmoutput.Create;
inlineexitcode:=TAAsmoutput.Create;
ps:=para_size;
make_global:=false; { to avoid warning }
genentrycode(inlineentrycode,make_global,0,ps,nostackframe,true);
if po_assembler in aktprocsym.definition.procoptions then
inlineentrycode.insert(Tai_marker.Create(asmblockstart));
exprasmList.concatlist(inlineentrycode);
secondpass(inlinetree);
genexitcode(inlineexitcode,0,false,true);
if po_assembler in aktprocsym.definition.procoptions then
inlineexitcode.concat(Tai_marker.Create(asmblockend));
exprasmList.concatlist(inlineexitcode);
inlineentrycode.free;
inlineexitcode.free;
{$ifdef extdebug}
exprasmList.concat(Tai_asm_comment.Create(strpnew('End of inlined proc')));
{$endif extdebug}
exprasmList.concat(Tai_Marker.Create(InlineEnd));
{we can free the local data now, reset also the fixup address }
if st.datasize>0 then
begin
ungetpersistanttemp(st.address_fixup-st.datasize);
st.address_fixup:=0;
end;
{ restore procinfo }
move(oldprocinfo^,procinfo^,sizeof(tprocinfo));
freemem(oldprocinfo,sizeof(tprocinfo));
{$ifdef GDB}
if (cs_debuginfo in aktmoduleswitches) then
begin
emitlab(endlabel);
strpcopy(pp,'224,0,0,'+endlabel.name);
if (target_info.use_function_relative_addresses) then
begin
strpcopy(strend(pp),'-');
strpcopy(strend(pp),oldprocsym.definition.mangledname);
end;
withdebugList.concat(Tai_stabn.Create(strnew(pp)));
freemem(pp,mangled_length+50);
end;
{$endif GDB}
{ restore }
aktprocsym:=oldprocsym;
aktexitlabel:=oldexitlabel;
aktexit2label:=oldexit2label;
quickexitlabel:=oldquickexitlabel;
inlining_procedure:=oldinlining_procedure;
{ reallocate the registers used for the current procedure's regvars, }
{ since they may have been used and then deallocated in the inlined }
{ procedure (JM) }
if assigned(aktprocsym.definition.regvarinfo) then
begin
unused := oldunused;
usableregs := oldusableregs;
c_usableregs := oldc_usableregs;
reg_pushes := oldreg_pushes;
is_reg_var := oldis_reg_var;
regvar_loaded := oldregvar_loaded;
{$ifdef TEMPREGDEBUG}
reg_user := oldreg_user;
reg_releaser := oldreg_releaser;
{$endif TEMPREGDEBUG}
end;
end;
begin
ccallparanode:=ti386callparanode;
ccallnode:=ti386callnode;
cprocinlinenode:=ti386procinlinenode;
end.
{
$Log$
Revision 1.22 2001-04-18 22:02:01 peter
* registration of targets and assemblers
Revision 1.21 2001/04/13 01:22:18 peter
* symtable change to classes
* range check generation and errors fixed, make cycle DEBUG=1 works
* memory leaks fixed
Revision 1.20 2001/04/02 21:20:36 peter
* resulttype rewrite
Revision 1.19 2001/03/11 22:58:51 peter
* getsym redesign, removed the globals srsym,srsymtable
Revision 1.18 2001/01/27 21:29:35 florian
* behavior -Oa optimized
Revision 1.17 2001/01/08 21:46:46 peter
* don't push high value for open array with cdecl;external;
Revision 1.16 2000/12/25 00:07:32 peter
+ new tlinkedlist class (merge of old tstringqueue,tcontainer and
tlinkedlist objects)
Revision 1.15 2000/12/09 10:45:40 florian
* AfterConstructor isn't called anymore when a constructor failed
Revision 1.14 2000/12/07 17:19:46 jonas
* new constant handling: from now on, hex constants >$7fffffff are
parsed as unsigned constants (otherwise, $80000000 got sign extended
and became $ffffffff80000000), all constants in the longint range
become longints, all constants >$7fffffff and <=cardinal($ffffffff)
are cardinals and the rest are int64's.
* added lots of longint typecast to prevent range check errors in the
compiler and rtl
* type casts of symbolic ordinal constants are now preserved
* fixed bug where the original resulttype.def wasn't restored correctly
after doing a 64bit rangecheck
Revision 1.13 2000/12/05 11:44:33 jonas
+ new integer regvar handling, should be much more efficient
Revision 1.12 2000/12/03 22:26:54 florian
* fixed web buzg 1275: problem with int64 functions results
Revision 1.11 2000/11/29 00:30:46 florian
* unused units removed from uses clause
* some changes for widestrings
Revision 1.10 2000/11/23 13:26:34 jonas
* fix for webbug 1066/1126
Revision 1.9 2000/11/22 15:12:06 jonas
* fixed inline-related problems (partially "merges")
Revision 1.8 2000/11/17 09:54:58 florian
* INT_CHECK_OBJECT_* isn't applied to interfaces anymore
Revision 1.7 2000/11/12 23:24:14 florian
* interfaces are basically running
Revision 1.6 2000/11/07 23:40:49 florian
+ AfterConstruction and BeforeDestruction impemented
Revision 1.5 2000/11/06 23:15:01 peter
* added copyvaluepara call again
Revision 1.4 2000/11/04 14:25:23 florian
+ merged Attila's changes for interfaces, not tested yet
Revision 1.3 2000/11/04 13:12:14 jonas
* check for nil pointers before calling getcopy
Revision 1.2 2000/10/31 22:02:56 peter
* symtable splitted, no real code changes
Revision 1.1 2000/10/15 09:33:31 peter
* moved n386*.pas to i386/ cpu_target dir
Revision 1.2 2000/10/14 10:14:48 peter
* moehrendorf oct 2000 rewrite
Revision 1.1 2000/10/10 17:31:56 florian
* initial revision
}
Reference in New Issue View Git Blame Copy Permalink