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d2e1952377
fpc/compiler/ncnv.pas
peter d2e1952377 * procsym definition rewrite
2001-11-02 22:58:00 +00:00

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{
$Id$
Copyright (c) 2000 by Florian Klaempfl
Type checking and register allocation for type converting 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 ncnv;
{$i defines.inc}
interface
uses
node,
symtype,types,
nld;
type
ttypeconvnode = class(tunarynode)
totype : ttype;
convtype : tconverttype;
constructor create(node : tnode;const t : ttype);virtual;
function getcopy : tnode;override;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
function docompare(p: tnode) : boolean; override;
private
function resulttype_cord_to_pointer : tnode;
function resulttype_chararray_to_string : tnode;
function resulttype_string_to_chararray : tnode;
function resulttype_string_to_string : tnode;
function resulttype_char_to_string : tnode;
function resulttype_int_to_real : tnode;
function resulttype_real_to_real : tnode;
function resulttype_cchar_to_pchar : tnode;
function resulttype_cstring_to_pchar : tnode;
function resulttype_char_to_char : tnode;
function resulttype_arrayconstructor_to_set : tnode;
function resulttype_pchar_to_string : tnode;
function resulttype_interface_to_guid : tnode;
function resulttype_call_helper(c : tconverttype) : tnode;
protected
function first_int_to_int : tnode;virtual;
function first_cstring_to_pchar : tnode;virtual;
function first_string_to_chararray : tnode;virtual;
function first_char_to_string : tnode;virtual;
function first_nothing : tnode;virtual;
function first_array_to_pointer : tnode;virtual;
function first_int_to_real : tnode;virtual;
function first_real_to_real : tnode;virtual;
function first_pointer_to_array : tnode;virtual;
function first_cchar_to_pchar : tnode;virtual;
function first_bool_to_int : tnode;virtual;
function first_int_to_bool : tnode;virtual;
function first_bool_to_bool : tnode;virtual;
function first_proc_to_procvar : tnode;virtual;
function first_load_smallset : tnode;virtual;
function first_cord_to_pointer : tnode;virtual;
function first_ansistring_to_pchar : tnode;virtual;
function first_arrayconstructor_to_set : tnode;virtual;
function first_class_to_intf : tnode;virtual;
function first_char_to_char : tnode;virtual;
function first_call_helper(c : tconverttype) : tnode;
procedure second_int_to_int;virtual;abstract;
procedure second_string_to_string;virtual;abstract;
procedure second_cstring_to_pchar;virtual;abstract;
procedure second_string_to_chararray;virtual;abstract;
procedure second_array_to_pointer;virtual;abstract;
procedure second_pointer_to_array;virtual;abstract;
procedure second_chararray_to_string;virtual;abstract;
procedure second_char_to_string;virtual;abstract;
procedure second_int_to_real;virtual;abstract;
procedure second_real_to_real;virtual;abstract;
procedure second_cord_to_pointer;virtual;abstract;
procedure second_proc_to_procvar;virtual;abstract;
procedure second_bool_to_int;virtual;abstract;
procedure second_int_to_bool;virtual;abstract;
procedure second_load_smallset;virtual;abstract;
procedure second_ansistring_to_pchar;virtual;abstract;
procedure second_pchar_to_string;virtual;abstract;
procedure second_class_to_intf;virtual;abstract;
procedure second_char_to_char;virtual;abstract;
procedure second_nothing; virtual;
end;
ttypeconvnodeclass = class of ttypeconvnode;
tasnode = class(tbinarynode)
constructor create(l,r : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
procedure pass_2;override;
end;
tasnodeclass = class of tasnode;
tisnode = class(tbinarynode)
constructor create(l,r : tnode);virtual;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
procedure pass_2;override;
end;
tisnodeclass = class of tisnode;
var
ctypeconvnode : ttypeconvnodeclass;
casnode : tasnodeclass;
cisnode : tisnodeclass;
procedure inserttypeconv(var p:tnode;const t:ttype);
procedure arrayconstructor_to_set(var p : tarrayconstructornode);
implementation
uses
globtype,systems,tokens,
cutils,verbose,globals,widestr,
symconst,symdef,symsym,symtable,
ncon,ncal,nset,nadd,ninl,
cgbase,
htypechk,pass_1,cpubase,cpuinfo;
{*****************************************************************************
Helpers
*****************************************************************************}
procedure inserttypeconv(var p:tnode;const t:ttype);
begin
if not assigned(p.resulttype.def) then
begin
resulttypepass(p);
if codegenerror then
exit;
end;
{ don't insert obsolete type conversions }
if is_equal(p.resulttype.def,t.def) and
not ((p.resulttype.def.deftype=setdef) and
(tsetdef(p.resulttype.def).settype <>
tsetdef(t.def).settype)) then
begin
p.resulttype:=t;
end
else
begin
p:=ctypeconvnode.create(p,t);
resulttypepass(p);
end;
end;
{*****************************************************************************
Array constructor to Set Conversion
*****************************************************************************}
procedure arrayconstructor_to_set(var p : tarrayconstructornode);
var
constp : tsetconstnode;
buildp,
p2,p3,p4 : tnode;
htype : ttype;
constset : pconstset;
constsetlo,
constsethi : longint;
procedure update_constsethi(t:ttype);
begin
if ((t.def.deftype=orddef) and
(torddef(t.def).high>=constsethi)) then
begin
constsethi:=torddef(t.def).high;
if htype.def=nil then
begin
if (constsethi>255) or
(torddef(t.def).low<0) then
htype:=u8bittype
else
htype:=t;
end;
if constsethi>255 then
constsethi:=255;
end
else if ((t.def.deftype=enumdef) and
(tenumdef(t.def).max>=constsethi)) then
begin
if htype.def=nil then
htype:=t;
constsethi:=tenumdef(t.def).max;
end;
end;
procedure do_set(pos : longint);
var
mask,l : longint;
begin
if (pos>255) or (pos<0) then
Message(parser_e_illegal_set_expr);
if pos>constsethi then
constsethi:=pos;
if pos<constsetlo then
constsetlo:=pos;
{ to do this correctly we use the 32bit array }
l:=pos shr 5;
mask:=1 shl (pos mod 32);
{ do we allow the same twice }
if (pconst32bitset(constset)^[l] and mask)<>0 then
Message(parser_e_illegal_set_expr);
pconst32bitset(constset)^[l]:=pconst32bitset(constset)^[l] or mask;
end;
var
l : longint;
lr,hr : longint;
begin
new(constset);
FillChar(constset^,sizeof(constset^),0);
htype.reset;
constsetlo:=0;
constsethi:=0;
constp:=csetconstnode.create(nil,htype);
constp.value_set:=constset;
buildp:=constp;
if assigned(p.left) then
begin
while assigned(p) do
begin
p4:=nil; { will contain the tree to create the set }
{split a range into p2 and p3 }
if p.left.nodetype=arrayconstructorrangen then
begin
p2:=tarrayconstructorrangenode(p.left).left;
p3:=tarrayconstructorrangenode(p.left).right;
tarrayconstructorrangenode(p.left).left:=nil;
tarrayconstructorrangenode(p.left).right:=nil;
end
else
begin
p2:=p.left;
p.left:=nil;
p3:=nil;
end;
resulttypepass(p2);
if assigned(p3) then
resulttypepass(p3);
if codegenerror then
break;
case p2.resulttype.def.deftype of
enumdef,
orddef:
begin
getrange(p2.resulttype.def,lr,hr);
if assigned(p3) then
begin
{ this isn't good, you'll get problems with
type t010 = 0..10;
ts = set of t010;
var s : ts;b : t010
begin s:=[1,2,b]; end.
if is_integer(p3^.resulttype.def) then
begin
inserttypeconv(p3,u8bitdef);
end;
}
if assigned(htype.def) and not(is_equal(htype.def,p3.resulttype.def)) then
begin
aktfilepos:=p3.fileinfo;
CGMessage(type_e_typeconflict_in_set);
end
else
begin
if (p2.nodetype=ordconstn) and (p3.nodetype=ordconstn) then
begin
if not(is_integer(p3.resulttype.def)) then
htype:=p3.resulttype
else
begin
inserttypeconv(p3,u8bittype);
inserttypeconv(p2,u8bittype);
end;
for l:=tordconstnode(p2).value to tordconstnode(p3).value do
do_set(l);
p2.free;
p3.free;
end
else
begin
update_constsethi(p2.resulttype);
inserttypeconv(p2,htype);
update_constsethi(p3.resulttype);
inserttypeconv(p3,htype);
if assigned(htype.def) then
inserttypeconv(p3,htype)
else
inserttypeconv(p3,u8bittype);
p4:=csetelementnode.create(p2,p3);
end;
end;
end
else
begin
{ Single value }
if p2.nodetype=ordconstn then
begin
if not(is_integer(p2.resulttype.def)) then
update_constsethi(p2.resulttype)
else
inserttypeconv(p2,u8bittype);
do_set(tordconstnode(p2).value);
p2.free;
end
else
begin
update_constsethi(p2.resulttype);
if assigned(htype.def) then
inserttypeconv(p2,htype)
else
inserttypeconv(p2,u8bittype);
p4:=csetelementnode.create(p2,nil);
end;
end;
end;
stringdef :
begin
{ if we've already set elements which are constants }
{ throw an error }
if ((htype.def=nil) and assigned(buildp)) or
not(is_char(htype.def)) then
CGMessage(type_e_typeconflict_in_set)
else
for l:=1 to length(pstring(tstringconstnode(p2).value_str)^) do
do_set(ord(pstring(tstringconstnode(p2).value_str)^[l]));
if htype.def=nil then
htype:=cchartype;
p2.free;
end;
else
CGMessage(type_e_ordinal_expr_expected);
end;
{ insert the set creation tree }
if assigned(p4) then
buildp:=caddnode.create(addn,buildp,p4);
{ load next and dispose current node }
p2:=p;
p:=tarrayconstructornode(tarrayconstructornode(p2).right);
tarrayconstructornode(p2).right:=nil;
p2.free;
end;
if (htype.def=nil) then
htype:=u8bittype;
end
else
begin
{ empty set [], only remove node }
p.free;
end;
{ set the initial set type }
constp.resulttype.setdef(tsetdef.create(htype,constsethi));
{ determine the resulttype for the tree }
resulttypepass(buildp);
{ set the new tree }
p:=tarrayconstructornode(buildp);
end;
{*****************************************************************************
TTYPECONVNODE
*****************************************************************************}
constructor ttypeconvnode.create(node : tnode;const t:ttype);
begin
inherited create(typeconvn,node);
convtype:=tc_not_possible;
totype:=t;
if t.def=nil then
internalerror(200103281);
set_file_line(node);
end;
function ttypeconvnode.getcopy : tnode;
var
n : ttypeconvnode;
begin
n:=ttypeconvnode(inherited getcopy);
n.convtype:=convtype;
getcopy:=n;
end;
function ttypeconvnode.resulttype_cord_to_pointer : tnode;
var
t : tnode;
begin
result:=nil;
if left.nodetype=ordconstn then
begin
{ check if we have a valid pointer constant (JM) }
if (sizeof(pointer) > sizeof(TConstPtrUInt)) then
if (sizeof(TConstPtrUInt) = 4) then
begin
if (tordconstnode(left).value < low(longint)) or
(tordconstnode(left).value > high(cardinal)) then
CGMessage(parser_e_range_check_error);
end
else if (sizeof(TConstPtrUInt) = 8) then
begin
if (tordconstnode(left).value < low(int64)) or
(tordconstnode(left).value > high(qword)) then
CGMessage(parser_e_range_check_error);
end
else
internalerror(2001020801);
t:=cpointerconstnode.create(TConstPtrUInt(tordconstnode(left).value),resulttype);
result:=t;
end
else
internalerror(200104023);
end;
function ttypeconvnode.resulttype_chararray_to_string : tnode;
begin
result := ccallnode.createinternres(
'fpc_chararray_to_'+lower(tstringdef(resulttype.def).stringtypname),
ccallparanode.create(left,nil),resulttype);
left := nil;
end;
function ttypeconvnode.resulttype_string_to_chararray : tnode;
var
arrsize: longint;
begin
with tarraydef(resulttype.def) do
begin
if highrange<lowrange then
internalerror(75432653);
arrsize := highrange-lowrange+1;
end;
if (left.nodetype = stringconstn) and
{ left.length+1 since there's always a terminating #0 character (JM) }
(tstringconstnode(left).len+1 >= arrsize) and
(tstringdef(left.resulttype.def).string_typ=st_shortstring) then
begin
{ handled separately }
result := nil;
exit;
end;
result := ccallnode.createinternres(
'fpc_'+lower(tstringdef(left.resulttype.def).stringtypname)+
'_to_chararray',ccallparanode.create(left,ccallparanode.create(
cordconstnode.create(arrsize,s32bittype),nil)),resulttype);
left := nil;
end;
function ttypeconvnode.resulttype_string_to_string : tnode;
var
procname: string[31];
stringpara : tcallparanode;
pw : pcompilerwidestring;
pc : pchar;
begin
result:=nil;
if left.nodetype=stringconstn then
begin
{ convert ascii 2 unicode }
if (tstringdef(resulttype.def).string_typ=st_widestring) and
(tstringconstnode(left).st_type in [st_ansistring,st_shortstring,st_longstring]) then
begin
initwidestring(pw);
ascii2unicode(tstringconstnode(left).value_str,tstringconstnode(left).len,pw);
ansistringdispose(tstringconstnode(left).value_str,tstringconstnode(left).len);
pcompilerwidestring(tstringconstnode(left).value_str):=pw;
end
else
{ convert unicode 2 ascii }
if (tstringconstnode(left).st_type=st_widestring) and
(tstringdef(resulttype.def).string_typ in [st_ansistring,st_shortstring,st_longstring]) then
begin
pw:=pcompilerwidestring(tstringconstnode(left).value_str);
getmem(pc,getlengthwidestring(pw)+1);
unicode2ascii(pw,pc);
donewidestring(pw);
tstringconstnode(left).value_str:=pc;
end;
tstringconstnode(left).st_type:=tstringdef(resulttype.def).string_typ;
tstringconstnode(left).resulttype:=resulttype;
result:=left;
left:=nil;
end
else
begin
{ get the correct procedure name }
procname := 'fpc_'+
lower(tstringdef(left.resulttype.def).stringtypname+
'_to_'+tstringdef(resulttype.def).stringtypname);
{ create parameter (and remove left node from typeconvnode }
{ since it's reused as parameter) }
stringpara := ccallparanode.create(left,nil);
left := nil;
{ hen converting to shortstrings, we have to pass high(destination) too }
if (tstringdef(resulttype.def).string_typ =
st_shortstring) then
stringpara.right := ccallparanode.create(cinlinenode.create(
in_high_x,false,self.getcopy),nil);
{ and create the callnode }
result := ccallnode.createinternres(procname,stringpara,resulttype);
end;
end;
function ttypeconvnode.resulttype_char_to_string : tnode;
var
procname: string[31];
para : tcallparanode;
hp : tstringconstnode;
ws : pcompilerwidestring;
begin
result:=nil;
if left.nodetype=ordconstn then
begin
if tstringdef(resulttype.def).string_typ=st_widestring then
begin
initwidestring(ws);
concatwidestringchar(ws,tcompilerwidechar(chr(tordconstnode(left).value)));
hp:=cstringconstnode.createwstr(ws);
donewidestring(ws);
end
else
hp:=cstringconstnode.createstr(chr(tordconstnode(left).value),tstringdef(resulttype.def).string_typ);
result:=hp;
end
else
{ shortstrings are handled 'inline' }
if tstringdef(resulttype.def).string_typ <> st_shortstring then
begin
{ create the parameter }
para := ccallparanode.create(left,nil);
left := nil;
{ and the procname }
procname := 'fpc_char_to_' +
lower(tstringdef(resulttype.def).stringtypname);
{ and finally the call }
result := ccallnode.createinternres(procname,para,resulttype);
end;
end;
function ttypeconvnode.resulttype_char_to_char : tnode;
var
hp : tordconstnode;
begin
result:=nil;
if left.nodetype=ordconstn then
begin
if (torddef(resulttype.def).typ=uchar) and
(torddef(left.resulttype.def).typ=uwidechar) then
begin
hp:=cordconstnode.create(
ord(unicode2asciichar(tcompilerwidechar(tordconstnode(left).value))),cchartype);
result:=hp;
end
else if (torddef(resulttype.def).typ=uwidechar) and
(torddef(left.resulttype.def).typ=uchar) then
begin
hp:=cordconstnode.create(
asciichar2unicode(chr(tordconstnode(left).value)),cwidechartype);
result:=hp;
end
else
internalerror(200105131);
exit;
end;
end;
function ttypeconvnode.resulttype_int_to_real : tnode;
var
t : trealconstnode;
begin
result:=nil;
if left.nodetype=ordconstn then
begin
t:=crealconstnode.create(tordconstnode(left).value,resulttype);
result:=t;
exit;
end;
end;
function ttypeconvnode.resulttype_real_to_real : tnode;
var
t : tnode;
begin
result:=nil;
if left.nodetype=realconstn then
begin
t:=crealconstnode.create(trealconstnode(left).value_real,resulttype);
result:=t;
end;
end;
function ttypeconvnode.resulttype_cchar_to_pchar : tnode;
begin
result:=nil;
if is_pwidechar(resulttype.def) then
inserttypeconv(left,cwidestringtype)
else
inserttypeconv(left,cshortstringtype);
{ evaluate again, reset resulttype so the convert_typ
will be calculated again and cstring_to_pchar will
be used for futher conversion }
result:=det_resulttype;
end;
function ttypeconvnode.resulttype_cstring_to_pchar : tnode;
begin
result:=nil;
if is_pwidechar(resulttype.def) then
inserttypeconv(left,cwidestringtype);
end;
function ttypeconvnode.resulttype_arrayconstructor_to_set : tnode;
var
hp : tnode;
begin
result:=nil;
if left.nodetype<>arrayconstructorn then
internalerror(5546);
{ remove typeconv node }
hp:=left;
left:=nil;
{ create a set constructor tree }
arrayconstructor_to_set(tarrayconstructornode(hp));
result:=hp;
end;
function ttypeconvnode.resulttype_pchar_to_string : tnode;
begin
result := ccallnode.createinternres(
'fpc_pchar_to_'+lower(tstringdef(resulttype.def).stringtypname),
ccallparanode.create(left,nil),resulttype);
left := nil;
end;
function ttypeconvnode.resulttype_interface_to_guid : tnode;
begin
if tobjectdef(left.resulttype.def).isiidguidvalid then
result:=cguidconstnode.create(tobjectdef(left.resulttype.def).iidguid);
end;
function ttypeconvnode.resulttype_call_helper(c : tconverttype) : tnode;
const
resulttypeconvert : array[tconverttype] of pointer = (
{equal} nil,
{not_possible} nil,
{ string_2_string } @ttypeconvnode.resulttype_string_to_string,
{ char_2_string } @ttypeconvnode.resulttype_char_to_string,
{ pchar_2_string } @ttypeconvnode.resulttype_pchar_to_string,
{ cchar_2_pchar } @ttypeconvnode.resulttype_cchar_to_pchar,
{ cstring_2_pchar } @ttypeconvnode.resulttype_cstring_to_pchar,
{ ansistring_2_pchar } nil,
{ string_2_chararray } @ttypeconvnode.resulttype_string_to_chararray,
{ chararray_2_string } @ttypeconvnode.resulttype_chararray_to_string,
{ array_2_pointer } nil,
{ pointer_2_array } nil,
{ int_2_int } nil,
{ int_2_bool } nil,
{ bool_2_bool } nil,
{ bool_2_int } nil,
{ real_2_real } @ttypeconvnode.resulttype_real_to_real,
{ int_2_real } @ttypeconvnode.resulttype_int_to_real,
{ proc_2_procvar } nil,
{ arrayconstructor_2_set } @ttypeconvnode.resulttype_arrayconstructor_to_set,
{ load_smallset } nil,
{ cord_2_pointer } @ttypeconvnode.resulttype_cord_to_pointer,
{ intf_2_string } nil,
{ intf_2_guid } @ttypeconvnode.resulttype_interface_to_guid,
{ class_2_intf } nil,
{ char_2_char } @ttypeconvnode.resulttype_char_to_char,
{ nomal_2_smallset} nil
);
type
tprocedureofobject = function : tnode of object;
var
r : packed record
proc : pointer;
obj : pointer;
end;
begin
result:=nil;
{ this is a little bit dirty but it works }
{ and should be quite portable too }
r.proc:=resulttypeconvert[c];
r.obj:=self;
if assigned(r.proc) then
result:=tprocedureofobject(r){$ifdef FPC}();{$endif FPC}
end;
function ttypeconvnode.det_resulttype:tnode;
var
hp : tnode;
currprocdef,
aprocdef : tprocdef;
begin
result:=nil;
resulttype:=totype;
resulttypepass(left);
if codegenerror then
exit;
{ remove obsolete type conversions }
if is_equal(left.resulttype.def,resulttype.def) then
begin
{ becuase is_equal only checks the basetype for sets we need to
check here if we are loading a smallset into a normalset }
if (resulttype.def.deftype=setdef) and
(left.resulttype.def.deftype=setdef) and
((tsetdef(resulttype.def).settype = smallset) xor
(tsetdef(left.resulttype.def).settype = smallset)) then
begin
{ try to define the set as a normalset if it's a constant set }
if (tsetdef(resulttype.def).settype <> smallset) then
begin
if (left.nodetype=setconstn) then
begin
tsetdef(left.resulttype.def).changesettype(normset);
result:=left;
left:=nil;
exit;
end
else
convtype:=tc_load_smallset;
end
else
convtype := tc_normal_2_smallset;
exit;
end
else
begin
left.resulttype:=resulttype;
result:=left;
left:=nil;
exit;
end;
end;
aprocdef:=assignment_overloaded(left.resulttype.def,resulttype.def);
if assigned(aprocdef) then
begin
procinfo^.flags:=procinfo^.flags or pi_do_call;
hp:=ccallnode.create(ccallparanode.create(left,nil),
overloaded_operators[_assignment],nil,nil);
{ tell explicitly which def we must use !! (PM) }
tcallnode(hp).procdefinition:=aprocdef;
left:=nil;
result:=hp;
exit;
end;
if isconvertable(left.resulttype.def,resulttype.def,convtype,left.nodetype,nf_explizit in flags)=0 then
begin
{Procedures have a resulttype.def of voiddef and functions of their
own resulttype.def. They will therefore always be incompatible with
a procvar. Because isconvertable cannot check for procedures we
use an extra check for them.}
if (m_tp_procvar in aktmodeswitches) then
begin
if (resulttype.def.deftype=procvardef) and
(is_procsym_load(left) or is_procsym_call(left)) then
begin
if is_procsym_call(left) then
begin
currprocdef:=get_proc_2_procvar_def(tprocsym(tcallnode(left).symtableprocentry),tprocvardef(resulttype.def));
hp:=cloadnode.create_procvar(tprocsym(tcallnode(left).symtableprocentry),
currprocdef,tcallnode(left).symtableproc);
if (tcallnode(left).symtableprocentry.owner.symtabletype=objectsymtable) and
assigned(tcallnode(left).methodpointer) then
tloadnode(hp).set_mp(tcallnode(left).methodpointer.getcopy);
resulttypepass(hp);
left.free;
left:=hp;
aprocdef:=tprocdef(left.resulttype.def);
end
else
begin
if (left.nodetype<>addrn) then
aprocdef:=tprocsym(tloadnode(left).symtableentry).defs^.def;
end;
convtype:=tc_proc_2_procvar;
{ Now check if the procedure we are going to assign to
the procvar, is compatible with the procvar's type }
if assigned(aprocdef) then
begin
if not proc_to_procvar_equal(aprocdef,tprocvardef(resulttype.def),false) then
CGMessage2(type_e_incompatible_types,aprocdef.typename,resulttype.def.typename);
end
else
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
exit;
end;
end;
if nf_explizit in flags then
begin
{ check if the result could be in a register }
if not(tstoreddef(resulttype.def).is_intregable) and
not(tstoreddef(resulttype.def).is_fpuregable) then
make_not_regable(left);
{ boolean to byte are special because the
location can be different }
if is_integer(resulttype.def) and
is_boolean(left.resulttype.def) then
begin
convtype:=tc_bool_2_int;
exit;
end;
{ ansistring to pchar }
if is_pchar(resulttype.def) and
is_ansistring(left.resulttype.def) then
begin
convtype:=tc_ansistring_2_pchar;
exit;
end;
{ do common tc_equal cast }
convtype:=tc_equal;
{ enum to ordinal will always be s32bit }
if (left.resulttype.def.deftype=enumdef) and
is_ordinal(resulttype.def) then
begin
if left.nodetype=ordconstn then
begin
hp:=cordconstnode.create(tordconstnode(left).value,resulttype);
result:=hp;
exit;
end
else
begin
if isconvertable(s32bittype.def,resulttype.def,convtype,ordconstn,false)=0 then
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
end
{ ordinal to enumeration }
else
if (resulttype.def.deftype=enumdef) and
is_ordinal(left.resulttype.def) then
begin
if left.nodetype=ordconstn then
begin
hp:=cordconstnode.create(tordconstnode(left).value,resulttype);
result:=hp;
exit;
end
else
begin
if IsConvertable(left.resulttype.def,s32bittype.def,convtype,ordconstn,false)=0 then
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
end
{ nil to ordinal node }
else if (left.nodetype=niln) and is_ordinal(resulttype.def) then
begin
hp:=cordconstnode.create(0,resulttype);
result:=hp;
exit;
end
{ constant pointer to ordinal }
else if is_ordinal(resulttype.def) and
(left.nodetype=pointerconstn) then
begin
hp:=cordconstnode.create(tpointerconstnode(left).value,resulttype);
result:=hp;
exit;
end
{Are we typecasting an ordconst to a char?}
else
if is_char(resulttype.def) and
is_ordinal(left.resulttype.def) then
begin
if left.nodetype=ordconstn then
begin
hp:=cordconstnode.create(tordconstnode(left).value,resulttype);
result:=hp;
exit;
end
else
begin
if IsConvertable(left.resulttype.def,u8bittype.def,convtype,ordconstn,false)=0 then
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
end
{Are we typecasting an ordconst to a wchar?}
else
if is_widechar(resulttype.def) and
is_ordinal(left.resulttype.def) then
begin
if left.nodetype=ordconstn then
begin
hp:=cordconstnode.create(tordconstnode(left).value,resulttype);
result:=hp;
exit;
end
else
begin
if IsConvertable(left.resulttype.def,u16bittype.def,convtype,ordconstn,false)=0 then
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
end
{ char to ordinal }
else
if is_char(left.resulttype.def) and
is_ordinal(resulttype.def) then
begin
if left.nodetype=ordconstn then
begin
hp:=cordconstnode.create(tordconstnode(left).value,resulttype);
result:=hp;
exit;
end
else
begin
if IsConvertable(u8bittype.def,resulttype.def,convtype,ordconstn,false)=0 then
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
end
{ widechar to ordinal }
else
if is_widechar(left.resulttype.def) and
is_ordinal(resulttype.def) then
begin
if left.nodetype=ordconstn then
begin
hp:=cordconstnode.create(tordconstnode(left).value,resulttype);
result:=hp;
exit;
end
else
begin
if IsConvertable(u16bittype.def,resulttype.def,convtype,ordconstn,false)=0 then
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
end
{ only if the same size or formal def }
{ why do we allow typecasting of voiddef ?? (PM) }
else
begin
if not(
(left.resulttype.def.deftype=formaldef) or
(left.resulttype.def.size=resulttype.def.size) or
(is_void(left.resulttype.def) and
(left.nodetype=derefn))
) then
CGMessage(cg_e_illegal_type_conversion);
if ((left.resulttype.def.deftype=orddef) and
(resulttype.def.deftype=pointerdef)) or
((resulttype.def.deftype=orddef) and
(left.resulttype.def.deftype=pointerdef)) then
CGMessage(cg_d_pointer_to_longint_conv_not_portable);
end;
{ the conversion into a strutured type is only }
{ possible, if the source is not a register }
if ((resulttype.def.deftype in [recorddef,stringdef,arraydef]) or
((resulttype.def.deftype=objectdef) and not(is_class(resulttype.def)))
) and (left.location.loc in [LOC_REGISTER,LOC_CREGISTER]) { and
it also works if the assignment is overloaded
YES but this code is not executed if assignment is overloaded (PM)
not assigned(assignment_overloaded(left.resulttype.def,resulttype.def))} then
CGMessage(cg_e_illegal_type_conversion);
end
else
CGMessage2(type_e_incompatible_types,left.resulttype.def.typename,resulttype.def.typename);
end;
{ tp7 procvar support, when right is not a procvardef and we got a
loadn of a procvar then convert to a calln, the check for the
result is already done in is_convertible, also no conflict with
@procvar is here because that has an extra addrn }
if (m_tp_procvar in aktmodeswitches) and
(resulttype.def.deftype<>procvardef) and
(left.resulttype.def.deftype=procvardef) and
(left.nodetype=loadn) then
begin
hp:=ccallnode.create(nil,nil,nil,nil);
tcallnode(hp).set_procvar(left);
resulttypepass(hp);
left:=hp;
end;
{ remove typeconv after niln }
if (left.nodetype=niln) then
begin
left.resulttype:=resulttype;
result:=left;
left:=nil;
exit;
end;
{ ordinal contants can be directly converted }
if (left.nodetype=ordconstn) and is_ordinal(resulttype.def) then
begin
{ replace the resulttype and recheck the range }
left.resulttype:=resulttype;
testrange(left.resulttype.def,tordconstnode(left).value,(nf_explizit in flags));
result:=left;
left:=nil;
exit;
end;
{ fold nil to any pointer type }
if (left.nodetype=niln) and (resulttype.def.deftype=pointerdef) then
begin
hp:=cnilnode.create;
hp.resulttype:=resulttype;
result:=hp;
exit;
end;
{ further, pointerconstn to any pointer is folded too }
if (left.nodetype=pointerconstn) and (resulttype.def.deftype=pointerdef) then
begin
left.resulttype:=resulttype;
result:=left;
left:=nil;
exit;
end;
{ now call the resulttype helper to do constant folding }
result:=resulttype_call_helper(convtype);
end;
function ttypeconvnode.first_cord_to_pointer : tnode;
begin
result:=nil;
internalerror(200104043);
end;
function ttypeconvnode.first_int_to_int : tnode;
begin
first_int_to_int:=nil;
if (left.location.loc<>LOC_REGISTER) and
(resulttype.def.size>left.resulttype.def.size) then
location.loc:=LOC_REGISTER;
if is_64bitint(resulttype.def) then
registers32:=max(registers32,2)
else
registers32:=max(registers32,1);
end;
function ttypeconvnode.first_cstring_to_pchar : tnode;
begin
first_cstring_to_pchar:=nil;
registers32:=1;
location.loc:=LOC_REGISTER;
end;
function ttypeconvnode.first_string_to_chararray : tnode;
begin
first_string_to_chararray:=nil;
registers32:=1;
location.loc:=LOC_REGISTER;
end;
function ttypeconvnode.first_char_to_string : tnode;
begin
first_char_to_string:=nil;
location.loc:=LOC_MEM;
end;
function ttypeconvnode.first_nothing : tnode;
begin
first_nothing:=nil;
location.loc:=LOC_MEM;
end;
function ttypeconvnode.first_array_to_pointer : tnode;
begin
first_array_to_pointer:=nil;
if registers32<1 then
registers32:=1;
location.loc:=LOC_REGISTER;
end;
function ttypeconvnode.first_int_to_real : tnode;
begin
first_int_to_real:=nil;
{$ifdef m68k}
if (cs_fp_emulation in aktmoduleswitches) or
(tfloatdef(resulttype.def).typ=s32real) then
begin
if registers32<1 then
registers32:=1;
end
else
if registersfpu<1 then
registersfpu:=1;
{$else not m68k}
if registersfpu<1 then
registersfpu:=1;
{$endif not m68k}
location.loc:=LOC_FPU;
end;
function ttypeconvnode.first_real_to_real : tnode;
begin
first_real_to_real:=nil;
{ comp isn't a floating type }
{$ifdef i386}
if (tfloatdef(resulttype.def).typ=s64comp) and
(tfloatdef(left.resulttype.def).typ<>s64comp) and
not (nf_explizit in flags) then
CGMessage(type_w_convert_real_2_comp);
{$endif}
if registersfpu<1 then
registersfpu:=1;
location.loc:=LOC_FPU;
end;
function ttypeconvnode.first_pointer_to_array : tnode;
begin
first_pointer_to_array:=nil;
if registers32<1 then
registers32:=1;
location.loc:=LOC_REFERENCE;
end;
function ttypeconvnode.first_cchar_to_pchar : tnode;
begin
first_cchar_to_pchar:=nil;
internalerror(200104021);
end;
function ttypeconvnode.first_bool_to_int : tnode;
begin
first_bool_to_int:=nil;
{ byte(boolean) or word(wordbool) or longint(longbool) must
be accepted for var parameters }
if (nf_explizit in flags) and
(left.resulttype.def.size=resulttype.def.size) and
(left.location.loc in [LOC_REFERENCE,LOC_MEM,LOC_CREGISTER]) then
exit;
{ when converting to 64bit, first convert to a 32bit int and then }
{ convert to a 64bit int (only necessary for 32bit processors) (JM) }
if resulttype.def.size > sizeof(aword) then
begin
result := ctypeconvnode.create(left,u32bittype);
result.toggleflag(nf_explizit);
result := ctypeconvnode.create(result,resulttype);
left := nil;
firstpass(result);
exit;
end;
location.loc:=LOC_REGISTER;
if registers32<1 then
registers32:=1;
end;
function ttypeconvnode.first_int_to_bool : tnode;
begin
first_int_to_bool:=nil;
{ byte(boolean) or word(wordbool) or longint(longbool) must
be accepted for var parameters }
if (nf_explizit in flags) and
(left.resulttype.def.size=resulttype.def.size) and
(left.location.loc in [LOC_REFERENCE,LOC_MEM,LOC_CREGISTER]) then
exit;
location.loc:=LOC_REGISTER;
{ need if bool to bool !!
not very nice !!
insertypeconv(left,s32bittype);
left.explizit:=true;
firstpass(left); }
if registers32<1 then
registers32:=1;
end;
function ttypeconvnode.first_bool_to_bool : tnode;
begin
first_bool_to_bool:=nil;
location.loc:=LOC_REGISTER;
if registers32<1 then
registers32:=1;
end;
function ttypeconvnode.first_char_to_char : tnode;
begin
first_char_to_char:=nil;
location.loc:=LOC_REGISTER;
if registers32<1 then
registers32:=1;
end;
function ttypeconvnode.first_proc_to_procvar : tnode;
begin
first_proc_to_procvar:=nil;
if (left.location.loc<>LOC_REFERENCE) then
CGMessage(cg_e_illegal_expression);
registers32:=left.registers32;
if registers32<1 then
registers32:=1;
location.loc:=LOC_REGISTER;
end;
function ttypeconvnode.first_load_smallset : tnode;
var
srsym: ttypesym;
p: tcallparanode;
begin
if not searchsystype('FPC_SMALL_SET',srsym) then
internalerror(200108313);
p := ccallparanode.create(left,nil);
{ reused }
left := nil;
{ convert parameter explicitely to fpc_small_set }
p.left := ctypeconvnode.create(p.left,srsym.restype);
p.left.toggleflag(nf_explizit);
{ create call, adjust resulttype }
result :=
ccallnode.createinternres('fpc_set_load_small',p,resulttype);
firstpass(result);
end;
function ttypeconvnode.first_ansistring_to_pchar : tnode;
begin
first_ansistring_to_pchar:=nil;
location.loc:=LOC_REGISTER;
if registers32<1 then
registers32:=1;
end;
function ttypeconvnode.first_arrayconstructor_to_set : tnode;
begin
first_arrayconstructor_to_set:=nil;
internalerror(200104022);
end;
function ttypeconvnode.first_class_to_intf : tnode;
begin
first_class_to_intf:=nil;
location.loc:=LOC_REFERENCE;
if registers32<1 then
registers32:=1;
end;
function ttypeconvnode.first_call_helper(c : tconverttype) : tnode;
const
firstconvert : array[tconverttype] of pointer = (
@ttypeconvnode.first_nothing, {equal}
@ttypeconvnode.first_nothing, {not_possible}
nil, { removed in resulttype_string_to_string }
@ttypeconvnode.first_char_to_string,
nil, { removed in resulttype_chararray_to_string }
@ttypeconvnode.first_cchar_to_pchar,
@ttypeconvnode.first_cstring_to_pchar,
@ttypeconvnode.first_ansistring_to_pchar,
@ttypeconvnode.first_string_to_chararray,
nil, { removed in resulttype_chararray_to_string }
@ttypeconvnode.first_array_to_pointer,
@ttypeconvnode.first_pointer_to_array,
@ttypeconvnode.first_int_to_int,
@ttypeconvnode.first_int_to_bool,
@ttypeconvnode.first_bool_to_bool,
@ttypeconvnode.first_bool_to_int,
@ttypeconvnode.first_real_to_real,
@ttypeconvnode.first_int_to_real,
@ttypeconvnode.first_proc_to_procvar,
@ttypeconvnode.first_arrayconstructor_to_set,
@ttypeconvnode.first_load_smallset,
@ttypeconvnode.first_cord_to_pointer,
@ttypeconvnode.first_nothing,
@ttypeconvnode.first_nothing,
@ttypeconvnode.first_class_to_intf,
@ttypeconvnode.first_char_to_char,
@ttypeconvnode.first_nothing
);
type
tprocedureofobject = function : tnode of object;
var
r : packed record
proc : pointer;
obj : pointer;
end;
begin
{ this is a little bit dirty but it works }
{ and should be quite portable too }
r.proc:=firstconvert[c];
r.obj:=self;
first_call_helper:=tprocedureofobject(r){$ifdef FPC}();{$endif FPC}
end;
function ttypeconvnode.pass_1 : tnode;
begin
result:=nil;
firstpass(left);
if codegenerror then
exit;
{ load the value_str from the left part }
registers32:=left.registers32;
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=left.registersmmx;
{$endif}
set_location(location,left.location);
if nf_explizit in flags then
begin
{ check if the result could be in a register }
if not(tstoreddef(resulttype.def).is_intregable) and
not(tstoreddef(resulttype.def).is_fpuregable) then
make_not_regable(left);
end;
if convtype=tc_equal then
begin
{ remove typeconv node if left is a const. For other nodes we can't
remove it because the secondpass can still depend on the old type (PFV) }
if is_constnode(left) then
begin
left.resulttype:=resulttype;
result:=left;
left:=nil;
end;
end
else
begin
result:=first_call_helper(convtype);
end;
end;
function ttypeconvnode.docompare(p: tnode) : boolean;
begin
docompare :=
inherited docompare(p) and
(convtype = ttypeconvnode(p).convtype);
end;
procedure ttypeconvnode.second_nothing;
begin
end;
{*****************************************************************************
TISNODE
*****************************************************************************}
constructor tisnode.create(l,r : tnode);
begin
inherited create(isn,l,r);
end;
function tisnode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(left);
resulttypepass(right);
set_varstate(left,true);
set_varstate(right,true);
if codegenerror then
exit;
if (right.resulttype.def.deftype=classrefdef) then
begin
{ left must be a class }
if is_class(left.resulttype.def) then
begin
{ the operands must be related }
if (not(tobjectdef(left.resulttype.def).is_related(
tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def)))) and
(not(tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def).is_related(
tobjectdef(left.resulttype.def)))) then
CGMessage(type_e_mismatch);
end
else
CGMessage(type_e_mismatch);
end
else
CGMessage(type_e_mismatch);
resulttype:=booltype;
end;
function tisnode.pass_1 : tnode;
var
paras: tcallparanode;
begin
paras := ccallparanode.create(left,ccallparanode.create(right,nil));
left := nil;
right := nil;
result := ccallnode.createintern('fpc_do_is',paras);
firstpass(result);
end;
{ dummy pass_2, it will never be called, but we need one since }
{ you can't instantiate an abstract class }
procedure tisnode.pass_2;
begin
end;
{*****************************************************************************
TASNODE
*****************************************************************************}
constructor tasnode.create(l,r : tnode);
begin
inherited create(asn,l,r);
end;
function tasnode.det_resulttype:tnode;
begin
result:=nil;
resulttypepass(right);
resulttypepass(left);
set_varstate(right,true);
set_varstate(left,true);
if codegenerror then
exit;
if (right.resulttype.def.deftype=classrefdef) then
begin
{ left must be a class }
if is_class(left.resulttype.def) then
begin
{ the operands must be related }
if (not(tobjectdef(left.resulttype.def).is_related(
tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def)))) and
(not(tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def).is_related(
tobjectdef(left.resulttype.def)))) then
CGMessage(type_e_mismatch);
end
else
CGMessage(type_e_mismatch);
resulttype:=tclassrefdef(right.resulttype.def).pointertype;
end
else
CGMessage(type_e_mismatch);
end;
function tasnode.pass_1 : tnode;
var
paras: tcallparanode;
begin
paras := ccallparanode.create(left,ccallparanode.create(right,nil));
left := nil;
right := nil;
result := ccallnode.createinternres('fpc_do_as',paras,
resulttype);
firstpass(result);
end;
{ dummy pass_2, it will never be called, but we need one since }
{ you can't instantiate an abstract class }
procedure tasnode.pass_2;
begin
end;
begin
ctypeconvnode:=ttypeconvnode;
casnode:=tasnode;
cisnode:=tisnode;
end.
{
$Log$
Revision 1.43 2001-11-02 22:58:02 peter
* procsym definition rewrite
Revision 1.42 2001/10/28 17:22:25 peter
* allow assignment of overloaded procedures to procvars when we know
which procedure to take
Revision 1.41 2001/10/20 19:28:37 peter
* interface 2 guid support
* guid constants support
Revision 1.40 2001/10/20 17:21:54 peter
* fixed size of constset when change from small to normalset
Revision 1.39 2001/09/30 16:12:46 jonas
- removed unnecessary i386 pass_2 of as- and isnode and added dummy generic ones
Revision 1.38 2001/09/29 21:32:46 jonas
* almost all second pass typeconvnode helpers are now processor independent
* fixed converting boolean to int64/qword
* fixed register allocation bugs which could cause internalerror 10
* isnode and asnode are completely processor indepent now as well
* fpc_do_as now returns its class argument (necessary to be able to use it
properly with compilerproc)
Revision 1.37 2001/09/03 13:27:42 jonas
* compilerproc implementation of set addition/substraction/...
* changed the declaration of some set helpers somewhat to accomodate the
above change
* i386 still uses the old code for comparisons of sets, because its
helpers return the results in the flags
* dummy tc_normal_2_small_set type conversion because I need the original
resulttype of the set add nodes
NOTE: you have to start a cycle with 1.0.5!
Revision 1.36 2001/09/02 21:12:06 peter
* move class of definitions into type section for delphi
Revision 1.35 2001/08/29 19:49:03 jonas
* some fixes in compilerprocs for chararray to string conversions
* conversion from string to chararray is now also done via compilerprocs
Revision 1.34 2001/08/29 12:18:07 jonas
+ new createinternres() constructor for tcallnode to support setting a
custom resulttype
* compilerproc typeconversions now set the resulttype from the type
conversion for the generated call node, because the resulttype of
of the compilerproc helper isn't always exact (e.g. the ones that
return shortstrings, actually return a shortstring[x], where x is
specified by the typeconversion node)
* ti386callnode.pass_2 now always uses resulttype instead of
procsym.definition.rettype (so the custom resulttype, if any, is
always used). Note that this "rettype" stuff is only for use with
compilerprocs.
Revision 1.33 2001/08/28 13:24:46 jonas
+ compilerproc implementation of most string-related type conversions
- removed all code from the compiler which has been replaced by
compilerproc implementations (using (ifdef hascompilerproc) is not
necessary in the compiler)
Revision 1.32 2001/08/26 13:36:40 florian
* some cg reorganisation
* some PPC updates
Revision 1.31 2001/08/05 13:19:51 peter
* partly fix for proc of obj=nil
Revision 1.30 2001/07/30 20:59:27 peter
* m68k updates from v10 merged
Revision 1.29 2001/07/08 21:00:15 peter
* various widestring updates, it works now mostly without charset
mapping supported
Revision 1.28 2001/05/13 15:43:46 florian
* made resultype_char_to_char a little bit robuster
Revision 1.27 2001/05/08 21:06:30 florian
* some more support for widechars commited especially
regarding type casting and constants
Revision 1.26 2001/05/04 15:52:03 florian
* some Delphi incompatibilities fixed:
- out, dispose and new can be used as idenfiers now
- const p = apointerype(nil); is supported now
+ support for const p = apointertype(pointer(1234)); added
Revision 1.25 2001/04/13 22:20:58 peter
* remove wrongly placed first_call_helper
Revision 1.24 2001/04/13 01:22:08 peter
* symtable change to classes
* range check generation and errors fixed, make cycle DEBUG=1 works
* memory leaks fixed
Revision 1.23 2001/04/04 22:42:39 peter
* move constant folding into det_resulttype
Revision 1.22 2001/04/02 21:20:30 peter
* resulttype rewrite
Revision 1.21 2001/03/08 17:44:47 jonas
* fixed web bug 1430
Revision 1.20 2001/02/21 11:49:50 jonas
* evaluate typecasts of const pointers to ordinals inline ('merged')
Revision 1.19 2001/02/20 18:37:10 peter
* removed unused code
Revision 1.18 2001/02/20 13:14:18 marco
* Fix from Peter for passing a procedure of method to a other method in a method
Revision 1.17 2001/02/08 13:09:03 jonas
* fixed web bug 1396: tpointerord is now a cardinal instead of a longint,
but added a hack in ncnv so that pointer(-1) still works
Revision 1.16 2000/12/31 11:14:10 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 1.15 2000/12/08 12:41:01 jonas
* fixed bug in sign extension patch
Revision 1.14 2000/12/07 17:19:42 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 2000/11/29 00:30:32 florian
* unused units removed from uses clause
* some changes for widestrings
Revision 1.12 2000/11/20 16:06:04 jonas
+ allow evaluation of 64bit constant expressions at compile time
* disable range checking for explicit typecasts of constant expressions
Revision 1.11 2000/11/12 23:24:11 florian
* interfaces are basically running
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 22:02:48 peter
* symtable splitted, no real code changes
Revision 1.8 2000/10/14 21:52:55 peter
* fixed memory leaks
Revision 1.7 2000/10/14 10:14:50 peter
* moehrendorf oct 2000 rewrite
Revision 1.6 2000/10/01 19:48:24 peter
* lot of compile updates for cg11
Revision 1.5 2000/09/28 19:49:52 florian
*** empty log message ***
Revision 1.4 2000/09/27 18:14:31 florian
* fixed a lot of syntax errors in the n*.pas stuff
Revision 1.3 2000/09/26 20:06:13 florian
* hmm, still a lot of work to get things compilable
Revision 1.2 2000/09/26 14:59:34 florian
* more conversion work done
Revision 1.1 2000/09/25 15:37:14 florian
* more fixes
}
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