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fpc/compiler/nmem.pas
florian b60666ae1f + parasym to tparaitem added
2001-12-06 17:57:33 +00:00

1124 lines
34 KiB
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{
$Id$
Copyright (c) 2000 by Florian Klaempfl
Type checking and register allocation for memory related nodes
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
****************************************************************************
}
unit nmem;
{$i defines.inc}
interface
uses
node,
symtype,symdef,symsym,symtable,
cpubase;
type
tloadvmtnode = class(tunarynode)
constructor create(l : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tloadvmtnodeclass = class of tloadvmtnode;
thnewnode = class(tnode)
constructor create;virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
thnewnodeclass = class of thnewnode;
tnewnode = class(tunarynode)
constructor create(l : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tnewnodeclass = class of tnewnode;
thdisposenode = class(tunarynode)
constructor create(l : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
thdisposenodeclass = class of thdisposenode;
tsimplenewdisposenode = class(tunarynode)
constructor create(n : tnodetype;l : tnode);
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tsimplenewdisposenodeclass = class of tsimplenewdisposenode;
taddrnode = class(tunarynode)
getprocvardef : tprocvardef;
constructor create(l : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
taddrnodeclass = class of taddrnode;
tdoubleaddrnode = class(tunarynode)
constructor create(l : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tdoubleaddrnodeclass = class of tdoubleaddrnode;
tderefnode = class(tunarynode)
constructor create(l : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tderefnodeclass = class of tderefnode;
tsubscriptnode = class(tunarynode)
vs : tvarsym;
constructor create(varsym : tsym;l : tnode);virtual;
function getcopy : tnode;override;
function pass_1 : tnode;override;
function docompare(p: tnode): boolean; override;
function det_resulttype:tnode;override;
end;
tsubscriptnodeclass = class of tsubscriptnode;
tvecnode = class(tbinarynode)
constructor create(l,r : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tvecnodeclass = class of tvecnode;
tselfnode = class(tnode)
classdef : tobjectdef;
constructor create(_class : tobjectdef);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
end;
tselfnodeclass = class of tselfnode;
twithnode = class(tbinarynode)
withsymtable : twithsymtable;
tablecount : longint;
withreference : preference;
constructor create(symtable : twithsymtable;l,r : tnode;count : longint);virtual;
destructor destroy;override;
function getcopy : tnode;override;
function pass_1 : tnode;override;
function docompare(p: tnode): boolean; override;
function det_resulttype:tnode;override;
end;
twithnodeclass = class of twithnode;
var
cloadvmtnode : tloadvmtnodeclass;
chnewnode : thnewnodeclass;
cnewnode : tnewnodeclass;
chdisposenode : thdisposenodeclass;
csimplenewdisposenode : tsimplenewdisposenodeclass;
caddrnode : taddrnodeclass;
cdoubleaddrnode : tdoubleaddrnodeclass;
cderefnode : tderefnodeclass;
csubscriptnode : tsubscriptnodeclass;
cvecnode : tvecnodeclass;
cselfnode : tselfnodeclass;
cwithnode : twithnodeclass;
implementation
uses
globtype,systems,
cutils,verbose,globals,
symconst,symbase,types,
htypechk,pass_1,ncal,nld,ncon,ncnv,cgbase
;
{*****************************************************************************
TLOADVMTNODE
*****************************************************************************}
constructor tloadvmtnode.create(l : tnode);
begin
inherited create(loadvmtn,l);
end;
function tloadvmtnode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
if codegenerror then
exit;
resulttype.setdef(tclassrefdef.create(left.resulttype));
end;
function tloadvmtnode.pass_1 : tnode;
begin
result:=nil;
registers32:=1;
location.loc:=LOC_REGISTER;
end;
{*****************************************************************************
THNEWNODE
*****************************************************************************}
constructor thnewnode.create;
begin
inherited create(hnewn);
end;
function thnewnode.det_resulttype:tnode;
begin
result:=nil;
resulttype:=voidtype;
end;
function thnewnode.pass_1 : tnode;
begin
result:=nil;
end;
{*****************************************************************************
TNEWNODE
*****************************************************************************}
constructor tnewnode.create(l : tnode);
begin
inherited create(newn,l);
end;
function tnewnode.det_resulttype:tnode;
begin
result:=nil;
if assigned(left) then
resulttypepass(left);
resulttype:=voidtype;
end;
function tnewnode.pass_1 : tnode;
{$ifdef NEW_COMPILERPROC}
var
temp : ttempcreatenode;
newstatement : tstatementnode;
newblock : tblocknode;
{$endif NEW_COMPILERPROC}
begin
result:=nil;
{$ifdef NEW_COMPILERPROC}
{ create the blocknode which will hold the generated statements + }
{ an initial dummy statement }
newstatement := cstatementnode.create(nil,cnothingnode.create);
newblock := cblocknode.create(newstatement);
{ create temp for result }
temp := ctempcreatenode.create(resulttype,
resulttype.size,true);
newstatement.left := cstatementnode.create(nil,temp);
{ create parameter }
sizepara := ccallparanode.create(cordconstnode.create
(tpointerdef(resulttype.def).pointertype.def.size,s32bittype),nil);
{ create the call and assign the result to dest }
{ the assignment will take care of rangechecking }
newstatement.left := cstatementnode.create(nil,cassignmentnode.create(
ctemprefnode.create(tempcode),
ccallnode.createintern('fpc_getmem',sizepara)));
newstatement := tstatementnode(newstatement.left);
if tpointerdef(resulttype.def).pointertype.def.needs_inittable then
begin
para := ccallparanode.create(cloadnode.create
(tpointerdef(resulttype.def).pointertype.def.size,s32bittype),
ccallparanode.create(cordconstnode.create
(tpointerdef(resulttype.def).pointertype.def.size,s32bittype),nil));
newstatement.left := cstatementnode.create(nil,cassignmentnode.create(
ctemprefnode.create(tempcode),
ccallnode.createintern('fpc_initialize',sizepara)));
newstatement := tstatementnode(newstatement.left);
new(r);
reset_reference(r^);
r^.symbol:=tstoreddef(tpointerdef(resulttype.def).pointertype.def).get_rtti_label(initrtti);
emitpushreferenceaddr(r^);
dispose(r);
{ push pointer we just allocated, we need to initialize the
data located at that pointer not the pointer self (PFV) }
emit_push_loc(location);
emitcall('FPC_INITIALIZE');
end;
{ and return it }
result := newblock;
{$endif NEW_COMPILERPROC}
if assigned(left) then
begin
firstpass(left);
if codegenerror then
exit;
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
location.loc:=LOC_REGISTER
end
else
location.loc:=LOC_REFERENCE;
procinfo^.flags:=procinfo^.flags or pi_do_call;
end;
{*****************************************************************************
THDISPOSENODE
*****************************************************************************}
constructor thdisposenode.create(l : tnode);
begin
inherited create(hdisposen,l);
end;
function thdisposenode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
if codegenerror then
exit;
resulttype:=tpointerdef(left.resulttype.def).pointertype;
end;
function thdisposenode.pass_1 : tnode;
begin
result:=nil;
firstpass(left);
if codegenerror then
exit;
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
if registers32<1 then
registers32:=1;
{
if left.location.loc<>LOC_REFERENCE then
CGMessage(cg_e_illegal_expression);
}
if left.location.loc=LOC_CREGISTER then
inc(registers32);
location.loc:=LOC_REFERENCE;
end;
{*****************************************************************************
TSIMPLENEWDISPOSENODE
*****************************************************************************}
constructor tsimplenewdisposenode.create(n : tnodetype;l : tnode);
begin
inherited create(n,l);
end;
function tsimplenewdisposenode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
if codegenerror then
exit;
if (left.resulttype.def.deftype<>pointerdef) then
CGMessage1(type_e_pointer_type_expected,left.resulttype.def.typename);
resulttype:=voidtype;
end;
function tsimplenewdisposenode.pass_1 : tnode;
begin
result:=nil;
{ this cannot be in a register !! }
make_not_regable(left);
firstpass(left);
if codegenerror then
exit;
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
procinfo^.flags:=procinfo^.flags or pi_do_call;
end;
{*****************************************************************************
TADDRNODE
*****************************************************************************}
constructor taddrnode.create(l : tnode);
begin
inherited create(addrn,l);
end;
function taddrnode.det_resulttype:tnode;
var
hp : tnode;
hp2 : TParaItem;
hp3 : tabstractprocdef;
begin
result:=nil;
resulttypepass(left);
if codegenerror then
exit;
{ don't allow constants }
if is_constnode(left) then
begin
aktfilepos:=left.fileinfo;
CGMessage(type_e_no_addr_of_constant);
exit;
end;
{ tp @procvar support (type of @procvar is a void pointer)
Note: we need to leave the addrn in the tree,
else we can't see the difference between @procvar and procvar.
we set the procvarload flag so a secondpass does nothing for
this node (PFV) }
if (m_tp_procvar in aktmodeswitches) then
begin
case left.nodetype of
calln :
begin
{ is it a procvar? }
hp:=tcallnode(left).right;
if assigned(hp) then
begin
{ remove calln node }
tcallnode(left).right:=nil;
left.free;
left:=hp;
include(flags,nf_procvarload);
end;
end;
loadn,
subscriptn,
typeconvn,
vecn,
derefn :
begin
if left.resulttype.def.deftype=procvardef then
include(flags,nf_procvarload);
end;
end;
if nf_procvarload in flags then
begin
resulttype:=voidpointertype;
exit;
end;
end;
{ proc 2 procvar ? }
if left.nodetype=calln then
internalerror(200103253)
else
if (left.nodetype=loadn) and (tloadnode(left).symtableentry.typ=procsym) then
begin
{ the address is already available when loading a procedure of object }
if assigned(tloadnode(left).left) then
include(flags,nf_procvarload);
{ result is a procedure variable }
{ No, to be TP compatible, you must return a voidpointer to
the procedure that is stored in the procvar.}
if not(m_tp_procvar in aktmodeswitches) then
begin
if assigned(getprocvardef) then
hp3:=getprocvardef
else
hp3:=tabstractprocdef(tprocsym(tloadnode(left).symtableentry).defs^.def);
{ create procvardef }
resulttype.setdef(tprocvardef.create);
tprocvardef(resulttype.def).proctypeoption:=hp3.proctypeoption;
tprocvardef(resulttype.def).proccalloption:=hp3.proccalloption;
tprocvardef(resulttype.def).procoptions:=hp3.procoptions;
tprocvardef(resulttype.def).rettype:=hp3.rettype;
tprocvardef(resulttype.def).symtablelevel:=hp3.symtablelevel;
{ method ? then set the methodpointer flag }
if (hp3.owner.symtabletype=objectsymtable) then
include(tprocvardef(resulttype.def).procoptions,po_methodpointer);
{ we need to process the parameters reverse so they are inserted
in the correct right2left order (PFV) }
hp2:=TParaItem(hp3.Para.last);
while assigned(hp2) do
begin
tprocvardef(resulttype.def).concatpara(hp2.paratype,hp2.parasym,hp2.paratyp,hp2.defaultvalue);
hp2:=TParaItem(hp2.previous);
end;
end
else
resulttype:=voidpointertype;
end
else
begin
{ what are we getting the address from an absolute sym? }
hp:=left;
while assigned(hp) and (hp.nodetype in [vecn,derefn,subscriptn]) do
hp:=tunarynode(hp).left;
if assigned(hp) and (hp.nodetype=loadn) and
((tloadnode(hp).symtableentry.typ=absolutesym) and
tabsolutesym(tloadnode(hp).symtableentry).absseg) then
begin
if not(cs_typed_addresses in aktlocalswitches) then
resulttype:=voidfarpointertype
else
resulttype.setdef(tpointerdef.createfar(left.resulttype));
end
else
begin
if not(cs_typed_addresses in aktlocalswitches) then
resulttype:=voidpointertype
else
resulttype.setdef(tpointerdef.create(left.resulttype));
end;
end;
{ this is like the function addr }
inc(parsing_para_level);
set_varstate(left,false);
dec(parsing_para_level);
end;
function taddrnode.pass_1 : tnode;
begin
result:=nil;
firstpass(left);
if codegenerror then
exit;
make_not_regable(left);
if nf_procvarload in flags then
begin
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
if registers32<1 then
registers32:=1;
location.loc:=left.location.loc;
exit;
end;
{ we should allow loc_mem for @string }
if not(left.location.loc in [LOC_MEM,LOC_REFERENCE]) then
begin
aktfilepos:=left.fileinfo;
CGMessage(cg_e_illegal_expression);
end;
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
if registers32<1 then
registers32:=1;
{ is this right for object of methods ?? }
location.loc:=LOC_REGISTER;
end;
{*****************************************************************************
TDOUBLEADDRNODE
*****************************************************************************}
constructor tdoubleaddrnode.create(l : tnode);
begin
inherited create(doubleaddrn,l);
end;
function tdoubleaddrnode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
if codegenerror then
exit;
inc(parsing_para_level);
set_varstate(left,false);
dec(parsing_para_level);
if (left.resulttype.def.deftype)<>procvardef then
CGMessage(cg_e_illegal_expression);
resulttype:=voidpointertype;
end;
function tdoubleaddrnode.pass_1 : tnode;
begin
result:=nil;
make_not_regable(left);
firstpass(left);
if codegenerror then
exit;
if (left.location.loc<>LOC_REFERENCE) then
CGMessage(cg_e_illegal_expression);
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
if registers32<1 then
registers32:=1;
location.loc:=LOC_REGISTER;
end;
{*****************************************************************************
TDEREFNODE
*****************************************************************************}
constructor tderefnode.create(l : tnode);
begin
inherited create(derefn,l);
end;
function tderefnode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
set_varstate(left,true);
if codegenerror then
exit;
if left.resulttype.def.deftype=pointerdef then
resulttype:=tpointerdef(left.resulttype.def).pointertype
else
CGMessage(cg_e_invalid_qualifier);
end;
function tderefnode.pass_1 : tnode;
begin
result:=nil;
firstpass(left);
if codegenerror then
exit;
registers32:=max(left.registers32,1);
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
location.loc:=LOC_REFERENCE;
end;
{*****************************************************************************
TSUBSCRIPTNODE
*****************************************************************************}
constructor tsubscriptnode.create(varsym : tsym;l : tnode);
begin
inherited create(subscriptn,l);
{ vs should be changed to tsym! }
vs:=tvarsym(varsym);
end;
function tsubscriptnode.getcopy : tnode;
var
p : tsubscriptnode;
begin
p:=tsubscriptnode(inherited getcopy);
p.vs:=vs;
getcopy:=p;
end;
function tsubscriptnode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
resulttype:=vs.vartype;
end;
function tsubscriptnode.pass_1 : tnode;
begin
result:=nil;
firstpass(left);
if codegenerror then
exit;
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
{ classes must be dereferenced implicit }
if is_class_or_interface(left.resulttype.def) then
begin
if registers32=0 then
registers32:=1;
location.loc:=LOC_REFERENCE;
end
else
begin
if (left.location.loc<>LOC_MEM) and
(left.location.loc<>LOC_REFERENCE) then
CGMessage(cg_e_illegal_expression);
set_location(location,left.location);
end;
end;
function tsubscriptnode.docompare(p: tnode): boolean;
begin
docompare :=
inherited docompare(p) and
(vs = tsubscriptnode(p).vs);
end;
{*****************************************************************************
TVECNODE
*****************************************************************************}
constructor tvecnode.create(l,r : tnode);
begin
inherited create(vecn,l,r);
end;
function tvecnode.det_resulttype:tnode;
var
htype : ttype;
ct : tconverttype;
begin
result:=nil;
resulttypepass(left);
resulttypepass(right);
if codegenerror then
exit;
{ range check only for arrays }
if (left.resulttype.def.deftype=arraydef) then
begin
if (isconvertable(right.resulttype.def,tarraydef(left.resulttype.def).rangetype.def,
ct,ordconstn,false)=0) and
not(is_equal(right.resulttype.def,tarraydef(left.resulttype.def).rangetype.def)) then
CGMessage(type_e_mismatch);
end;
{ Never convert a boolean or a char !}
{ maybe type conversion }
if (right.resulttype.def.deftype<>enumdef) and
not(is_char(right.resulttype.def)) and
not(is_boolean(right.resulttype.def)) then
begin
inserttypeconv(right,s32bittype);
end;
{ are we accessing a pointer[], then convert the pointer to
an array first, in FPC this is allowed for all pointers in
delphi/tp7 it's only allowed for pchars }
if (left.resulttype.def.deftype=pointerdef) and
((m_fpc in aktmodeswitches) or
is_pchar(left.resulttype.def) or
is_pwidechar(left.resulttype.def)) then
begin
{ convert pointer to array }
htype.setdef(tarraydef.create(0,$7fffffff,s32bittype));
tarraydef(htype.def).elementtype:=tpointerdef(left.resulttype.def).pointertype;
inserttypeconv(left,htype);
resulttype:=tarraydef(htype.def).elementtype;
end;
{ determine return type }
if not assigned(resulttype.def) then
if left.resulttype.def.deftype=arraydef then
resulttype:=tarraydef(left.resulttype.def).elementtype
else if left.resulttype.def.deftype=stringdef then
begin
{ indexed access to strings }
case tstringdef(left.resulttype.def).string_typ of
st_widestring :
resulttype:=cwidechartype;
st_ansistring :
resulttype:=cchartype;
st_longstring :
resulttype:=cchartype;
st_shortstring :
resulttype:=cchartype;
end;
end
else
CGMessage(type_e_array_required);
end;
function tvecnode.pass_1 : tnode;
{$ifdef consteval}
var
tcsym : ttypedconstsym;
{$endif}
begin
result:=nil;
firstpass(left);
firstpass(right);
if codegenerror then
exit;
{ the register calculation is easy if a const index is used }
if right.nodetype=ordconstn then
begin
{$ifdef consteval}
{ constant evaluation }
if (left.nodetype=loadn) and
(left.symtableentry.typ=typedconstsym) then
begin
tcsym:=ttypedconstsym(left.symtableentry);
if tcsym.defintion^.typ=stringdef then
begin
end;
end;
{$endif}
registers32:=left.registers32;
{ for ansi/wide strings, we need at least one register }
if is_ansistring(left.resulttype.def) or
is_widestring(left.resulttype.def) or
{ ... as well as for dynamic arrays }
is_dynamic_array(left.resulttype.def) then
registers32:=max(registers32,1);
end
else
begin
{ this rules are suboptimal, but they should give }
{ good results }
registers32:=max(left.registers32,right.registers32);
{ for ansi/wide strings, we need at least one register }
if is_ansistring(left.resulttype.def) or
is_widestring(left.resulttype.def) or
{ ... as well as for dynamic arrays }
is_dynamic_array(left.resulttype.def) then
registers32:=max(registers32,1);
{ need we an extra register when doing the restore ? }
if (left.registers32<=right.registers32) and
{ only if the node needs less than 3 registers }
{ two for the right node and one for the }
{ left address }
(registers32<3) then
inc(registers32);
{ need we an extra register for the index ? }
if (right.location.loc<>LOC_REGISTER)
{ only if the right node doesn't need a register }
and (right.registers32<1) then
inc(registers32);
{ not correct, but what works better ?
if left.registers32>0 then
registers32:=max(registers32,2)
else
min. one register
registers32:=max(registers32,1);
}
end;
registersfpu:=max(left.registersfpu,right.registersfpu);
{$ifdef SUPPORT_MMX}
registersmmx:=max(left.registersmmx,right.registersmmx);
{$endif SUPPORT_MMX}
if left.location.loc in [LOC_CREGISTER,LOC_REFERENCE] then
location.loc:=LOC_REFERENCE
else
location.loc:=LOC_MEM;
end;
{*****************************************************************************
TSELFNODE
*****************************************************************************}
constructor tselfnode.create(_class : tobjectdef);
begin
inherited create(selfn);
classdef:=_class;
end;
function tselfnode.det_resulttype:tnode;
begin
result:=nil;
resulttype.setdef(classdef);
end;
function tselfnode.pass_1 : tnode;
begin
result:=nil;
if (resulttype.def.deftype=classrefdef) or
is_class(resulttype.def) then
location.loc:=LOC_CREGISTER
else
location.loc:=LOC_REFERENCE;
end;
{*****************************************************************************
TWITHNODE
*****************************************************************************}
constructor twithnode.create(symtable : twithsymtable;l,r : tnode;count : longint);
begin
inherited create(withn,l,r);
withsymtable:=symtable;
tablecount:=count;
withreference:=nil;
set_file_line(l);
end;
destructor twithnode.destroy;
var
symt : tsymtable;
i : longint;
begin
symt:=withsymtable;
for i:=1 to tablecount do
begin
if assigned(symt) then
begin
withsymtable:=twithsymtable(symt.next);
symt.free;
end;
symt:=withsymtable;
end;
inherited destroy;
end;
function twithnode.getcopy : tnode;
var
p : twithnode;
begin
p:=twithnode(inherited getcopy);
p.withsymtable:=withsymtable;
p.tablecount:=tablecount;
p.withreference:=withreference;
result:=p;
end;
function twithnode.det_resulttype:tnode;
var
symtable : twithsymtable;
i : longint;
begin
result:=nil;
resulttype:=voidtype;
if assigned(left) and assigned(right) then
begin
resulttypepass(left);
unset_varstate(left);
set_varstate(left,true);
if codegenerror then
exit;
symtable:=withsymtable;
for i:=1 to tablecount do
begin
if (left.nodetype=loadn) and
(tloadnode(left).symtable=aktprocdef.localst) then
symtable.direct_with:=true;
symtable.withnode:=self;
symtable:=twithsymtable(symtable.next);
end;
resulttypepass(right);
if codegenerror then
exit;
end;
resulttype:=voidtype;
end;
function twithnode.pass_1 : tnode;
begin
result:=nil;
if assigned(left) and assigned(right) then
begin
firstpass(left);
firstpass(right);
if codegenerror then
exit;
left_right_max;
end
else
begin
{ optimization }
result:=nil;
end;
end;
function twithnode.docompare(p: tnode): boolean;
begin
docompare :=
inherited docompare(p) and
(withsymtable = twithnode(p).withsymtable) and
(tablecount = twithnode(p).tablecount);
end;
begin
cloadvmtnode := tloadvmtnode;
chnewnode := thnewnode;
cnewnode := tnewnode;
chdisposenode := thdisposenode;
csimplenewdisposenode := tsimplenewdisposenode;
caddrnode := taddrnode;
cdoubleaddrnode := tdoubleaddrnode;
cderefnode := tderefnode;
csubscriptnode := tsubscriptnode;
cvecnode := tvecnode;
cselfnode := tselfnode;
cwithnode := twithnode;
end.
{
$Log$
Revision 1.25 2001-12-06 17:57:34 florian
+ parasym to tparaitem added
Revision 1.24 2001/12/03 21:48:42 peter
* freemem change to value parameter
* torddef low/high range changed to int64
Revision 1.23 2001/11/02 22:58:02 peter
* procsym definition rewrite
Revision 1.22 2001/10/28 17:22:25 peter
* allow assignment of overloaded procedures to procvars when we know
which procedure to take
Revision 1.20 2001/09/02 21:12:07 peter
* move class of definitions into type section for delphi
Revision 1.19 2001/08/26 13:36:42 florian
* some cg reorganisation
* some PPC updates
Revision 1.18 2001/04/13 22:15:21 peter
* removed wrongly placed set_varstate in subscriptnode
Revision 1.17 2001/04/13 01:22:10 peter
* symtable change to classes
* range check generation and errors fixed, make cycle DEBUG=1 works
* memory leaks fixed
Revision 1.16 2001/04/02 21:20:31 peter
* resulttype rewrite
Revision 1.15 2001/03/23 00:16:07 florian
+ some stuff to compile FreeCLX added
Revision 1.14 2000/12/31 11:14:11 jonas
+ implemented/fixed docompare() mathods for all nodes (not tested)
+ nopt.pas, nadd.pas, i386/n386opt.pas: optimized nodes for adding strings
and constant strings/chars together
* n386add.pas: don't copy temp strings (of size 256) to another temp string
when adding
Revision 1.13 2000/12/25 00:07:26 peter
+ new tlinkedlist class (merge of old tstringqueue,tcontainer and
tlinkedlist objects)
Revision 1.12 2000/12/05 15:19:50 jonas
* fixed webbug 1268 ("merged")
Revision 1.11 2000/11/29 00:30:34 florian
* unused units removed from uses clause
* some changes for widestrings
Revision 1.10 2000/11/04 14:25:20 florian
+ merged Attila's changes for interfaces, not tested yet
Revision 1.9 2000/10/31 22:02:49 peter
* symtable splitted, no real code changes
Revision 1.8 2000/10/21 18:16:11 florian
* a lot of changes:
- basic dyn. array support
- basic C++ support
- some work for interfaces done
....
Revision 1.7 2000/10/14 21:52:55 peter
* fixed memory leaks
Revision 1.6 2000/10/14 10:14:51 peter
* moehrendorf oct 2000 rewrite
Revision 1.5 2000/10/01 19:48:24 peter
* lot of compile updates for cg11
Revision 1.4 2000/09/28 19:49:52 florian
*** empty log message ***
Revision 1.3 2000/09/25 15:37:14 florian
* more fixes
Revision 1.2 2000/09/25 15:05:25 florian
* some updates
Revision 1.1 2000/09/25 09:58:22 florian
* first revision for testing purpose
}
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