paweld/fpc
1
0
Fork 0
mirror of https://gitlab.com/freepascal.org/fpc/source.git synced 2025-05-18 02:22:32 +02:00
Code Issues Packages Projects Releases Wiki Activity
2e3ba14936
fpc/compiler/i386/n386inl.pas
peter 32b9cdb7cf + new tlinkedlist class (merge of old tstringqueue,tcontainer and 
tlinkedlist objects)
2000-12-25 00:07:25 +00:00

1742 lines
71 KiB
ObjectPascal
Raw Blame History

{
$Id$
Copyright (c) 1998-2000 by Florian Klaempfl
Generate i386 inline 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 n386inl;
{$i defines.inc}
interface
uses
node,ninl;
type
ti386inlinenode = class(tinlinenode)
procedure pass_2;override;
end;
implementation
uses
globtype,systems,
cutils,verbose,globals,fmodule,
symconst,symbase,symtype,symdef,symsym,aasm,types,
hcodegen,temp_gen,pass_1,pass_2,
cpubase,
nbas,ncon,ncal,ncnv,nld,
cgai386,tgcpu,n386util;
{*****************************************************************************
Helpers
*****************************************************************************}
{ reverts the parameter list }
var nb_para : longint;
function reversparameter(p : tnode) : tnode;
var
hp1,hp2 : tnode;
begin
hp1:=nil;
nb_para := 0;
while assigned(p) do
begin
{ pull out }
hp2:=p;
p:=tbinarynode(p).right;
inc(nb_para);
{ pull in }
tbinarynode(hp2).right:=hp1;
hp1:=hp2;
end;
reversparameter:=hp1;
end;
{*****************************************************************************
TI386INLINENODE
*****************************************************************************}
procedure StoreDirectFuncResult(var dest:tnode);
var
hp : tnode;
hdef : porddef;
hreg : tregister;
hregister : tregister;
oldregisterdef : boolean;
op : tasmop;
opsize : topsize;
begin
{ Get the accumulator first so it can't be used in the dest }
if (dest.resulttype^.deftype=orddef) and
not(is_64bitint(dest.resulttype)) then
hregister:=getexplicitregister32(accumulator);
{ process dest }
SecondPass(dest);
if Codegenerror then
exit;
{ store the value }
Case dest.resulttype^.deftype of
floatdef:
if dest.location.loc=LOC_CFPUREGISTER then
begin
floatstoreops(pfloatdef(dest.resulttype)^.typ,op,opsize);
emit_reg(op,opsize,correct_fpuregister(dest.location.register,fpuvaroffset+1));
end
else
begin
inc(fpuvaroffset);
floatstore(PFloatDef(dest.resulttype)^.typ,dest.location.reference);
{ floatstore decrements the fpu var offset }
{ but in fact we didn't increment it }
end;
orddef:
begin
if is_64bitint(dest.resulttype) then
begin
emit_movq_reg_loc(R_EDX,R_EAX,dest.location);
end
else
begin
Case dest.resulttype^.size of
1 : hreg:=regtoreg8(hregister);
2 : hreg:=regtoreg16(hregister);
4 : hreg:=hregister;
End;
emit_mov_reg_loc(hreg,dest.location);
If (cs_check_range in aktlocalswitches) and
{no need to rangecheck longints or cardinals on 32bit processors}
not((porddef(dest.resulttype)^.typ = s32bit) and
(porddef(dest.resulttype)^.low = longint($80000000)) and
(porddef(dest.resulttype)^.high = $7fffffff)) and
not((porddef(dest.resulttype)^.typ = u32bit) and
(porddef(dest.resulttype)^.low = 0) and
(porddef(dest.resulttype)^.high = longint($ffffffff))) then
Begin
{do not register this temporary def}
OldRegisterDef := RegisterDef;
RegisterDef := False;
hdef:=nil;
Case PordDef(dest.resulttype)^.typ of
u8bit,u16bit,u32bit:
begin
new(hdef,init(u32bit,0,longint($ffffffff)));
hreg:=hregister;
end;
s8bit,s16bit,s32bit:
begin
new(hdef,init(s32bit,longint($80000000),$7fffffff));
hreg:=hregister;
end;
end;
{ create a fake node }
hp := cnothingnode.create;
hp.location.loc := LOC_REGISTER;
hp.location.register := hreg;
if assigned(hdef) then
hp.resulttype:=hdef
else
hp.resulttype:=dest.resulttype;
{ emit the range check }
emitrangecheck(hp,dest.resulttype);
if assigned(hdef) then
Dispose(hdef, Done);
RegisterDef := OldRegisterDef;
hp.free;
End;
ungetregister(hregister);
end;
End;
else
internalerror(66766766);
end;
{ free used registers }
del_locref(dest.location);
end;
procedure ti386inlinenode.pass_2;
const
{tfloattype = (s32real,s64real,s80real,s64bit,f16bit,f32bit);}
{ float_name: array[tfloattype] of string[8]=
('S32REAL','S64REAL','S80REAL','S64BIT','F16BIT','F32BIT'); }
incdecop:array[in_inc_x..in_dec_x] of tasmop=(A_INC,A_DEC);
addsubop:array[in_inc_x..in_dec_x] of tasmop=(A_ADD,A_SUB);
var
aktfile : treference;
ft : tfiletyp;
opsize : topsize;
op,
asmop : tasmop;
pushed : tpushed;
{inc/dec}
addconstant : boolean;
addvalue : longint;
hp : tnode;
procedure handlereadwrite(doread,doln : boolean);
{ produces code for READ(LN) and WRITE(LN) }
procedure loadstream;
const
io:array[boolean] of string[6]=('OUTPUT','INPUT');
var
r : preference;
begin
new(r);
reset_reference(r^);
r^.symbol:=newasmsymbol(
'U_SYSTEM_'+io[doread]);
getexplicitregister32(R_EDI);
emit_ref_reg(A_LEA,S_L,r,R_EDI)
end;
const
rdwrprefix:array[boolean] of string[15]=('FPC_WRITE_TEXT_','FPC_READ_TEXT_');
var
node : tcallparanode;
hp : tnode;
typedtyp,
pararesult : pdef;
orgfloattype : tfloattype;
dummycoll : tparaitem;
iolabel : pasmlabel;
npara : longint;
esireloaded : boolean;
begin
{ here we don't use register calling conventions }
dummycoll:=TParaItem.Create;
dummycoll.register:=R_NO;
{ I/O check }
if (cs_check_io in aktlocalswitches) and
not(po_iocheck in aktprocsym^.definition^.procoptions) then
begin
getaddrlabel(iolabel);
emitlab(iolabel);
end
else
iolabel:=nil;
{ for write of real with the length specified }
hp:=nil;
{ reserve temporary pointer to data variable }
aktfile.symbol:=nil;
gettempofsizereference(4,aktfile);
{ first state text data }
ft:=ft_text;
{ and state a parameter ? }
if left=nil then
begin
{ the following instructions are for "writeln;" }
loadstream;
{ save @aktfile in temporary variable }
emit_reg_ref(A_MOV,S_L,R_EDI,newreference(aktfile));
{$ifndef noAllocEdi}
ungetregister32(R_EDI);
{$endif noAllocEdi}
end
else
begin
{ revers paramters }
node:=tcallparanode(reversparameter(left));
left := node;
npara := nb_para;
{ calculate data variable }
{ is first parameter a file type ? }
if node.left.resulttype^.deftype=filedef then
begin
ft:=pfiledef(node.left.resulttype)^.filetyp;
if ft=ft_typed then
typedtyp:=pfiledef(node.left.resulttype)^.typedfiletype.def;
secondpass(node.left);
if codegenerror then
exit;
{ save reference in temporary variables }
if node.left.location.loc<>LOC_REFERENCE then
begin
CGMessage(cg_e_illegal_expression);
exit;
end;
{$ifndef noAllocEdi}
getexplicitregister32(R_EDI);
{$endif noAllocEdi}
emit_ref_reg(A_LEA,S_L,newreference(node.left.location.reference),R_EDI);
del_reference(node.left.location.reference);
{ skip to the next parameter }
node:=tcallparanode(node.right);
end
else
begin
{ load stdin/stdout stream }
loadstream;
end;
{ save @aktfile in temporary variable }
emit_reg_ref(A_MOV,S_L,R_EDI,newreference(aktfile));
{$ifndef noAllocEdi}
ungetregister32(R_EDI);
{$endif noAllocEdi}
if doread then
{ parameter by READ gives call by reference }
dummycoll.paratyp:=vs_var
{ an WRITE Call by "Const" }
else
dummycoll.paratyp:=vs_const;
{ because of secondcallparan, which otherwise attaches }
if ft=ft_typed then
{ this is to avoid copy of simple const parameters }
{dummycoll.data:=new(pformaldef,init)}
dummycoll.paratype.setdef(cformaldef)
else
{ I think, this isn't a good solution (FK) }
dummycoll.paratype.reset;
while assigned(node) do
begin
esireloaded:=false;
pushusedregisters(pushed,$ff);
hp:=node;
node:=tcallparanode(node.right);
tcallparanode(hp).right:=nil;
if cpf_is_colon_para in tcallparanode(hp).callparaflags then
CGMessage(parser_e_illegal_colon_qualifier);
{ when float is written then we need bestreal to be pushed
convert here else we loose the old float type }
if (not doread) and
(ft<>ft_typed) and
(tcallparanode(hp).left.resulttype^.deftype=floatdef) then
begin
orgfloattype:=pfloatdef(tcallparanode(hp).left.resulttype)^.typ;
tcallparanode(hp).left:=gentypeconvnode(tcallparanode(hp).left,bestrealdef^);
firstpass(tcallparanode(hp).left);
end;
{ when read ord,floats are functions, so they need this
parameter as their destination instead of being pushed }
if doread and
(ft<>ft_typed) and
(tcallparanode(hp).resulttype^.deftype in [orddef,floatdef]) then
begin
end
else
begin
if ft=ft_typed then
never_copy_const_param:=true;
{ reset data type }
dummycoll.paratype.reset;
{ create temporary defs for high tree generation }
if doread and (is_shortstring(tcallparanode(hp).resulttype)) then
dummycoll.paratype.setdef(openshortstringdef)
else
if (is_chararray(tcallparanode(hp).resulttype)) then
dummycoll.paratype.setdef(openchararraydef);
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
if ft=ft_typed then
never_copy_const_param:=false;
end;
tcallparanode(hp).right:=node;
if codegenerror then
exit;
emit_push_mem(aktfile);
if (ft=ft_typed) then
begin
{ OK let's try this }
{ first we must only allow the right type }
{ we have to call blockread or blockwrite }
{ but the real problem is that }
{ reset and rewrite should have set }
{ the type size }
{ as recordsize for that file !!!! }
{ how can we make that }
{ I think that is only possible by adding }
{ reset and rewrite to the inline list a call }
{ allways read only one record by element }
push_int(typedtyp^.size);
saveregvars($ff);
if doread then
emitcall('FPC_TYPED_READ')
else
emitcall('FPC_TYPED_WRITE');
end
else
begin
{ save current position }
pararesult:=tcallparanode(hp).left.resulttype;
{ handle possible field width }
{ of course only for write(ln) }
if not doread then
begin
{ handle total width parameter }
if assigned(node) and (cpf_is_colon_para in node.callparaflags) then
begin
hp:=node;
node:=tcallparanode(node.right);
tcallparanode(hp).right:=nil;
dummycoll.paratype.setdef(hp.resulttype);
dummycoll.paratyp:=vs_value;
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
tcallparanode(hp).right:=node;
if codegenerror then
exit;
end
else
if pararesult^.deftype<>floatdef then
push_int(0)
else
push_int(-32767);
{ a second colon para for a float ? }
if assigned(node) and (cpf_is_colon_para in node.callparaflags) then
begin
hp:=node;
node:=tcallparanode(node.right);
tcallparanode(hp).right:=nil;
dummycoll.paratype.setdef(hp.resulttype);
dummycoll.paratyp:=vs_value;
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
tcallparanode(hp).right:=node;
if pararesult^.deftype<>floatdef then
CGMessage(parser_e_illegal_colon_qualifier);
if codegenerror then
exit;
end
else
begin
if pararesult^.deftype=floatdef then
push_int(-1);
end;
{ push also the real type for floats }
if pararesult^.deftype=floatdef then
push_int(ord(orgfloattype));
end;
saveregvars($ff);
case pararesult^.deftype of
stringdef :
begin
emitcall(rdwrprefix[doread]+pstringdef(pararesult)^.stringtypname);
end;
pointerdef :
begin
if is_pchar(pararesult) then
emitcall(rdwrprefix[doread]+'PCHAR_AS_POINTER')
end;
arraydef :
begin
if is_chararray(pararesult) then
emitcall(rdwrprefix[doread]+'PCHAR_AS_ARRAY')
end;
floatdef :
begin
emitcall(rdwrprefix[doread]+'FLOAT');
{
if pfloatdef(resulttype)^.typ<>f32bit then
dec(fpuvaroffset);
}
if doread then
begin
maybe_loadesi;
esireloaded:=true;
StoreDirectFuncResult(tcallparanode(hp).left);
end;
end;
orddef :
begin
case porddef(pararesult)^.typ of
s8bit,s16bit,s32bit :
emitcall(rdwrprefix[doread]+'SINT');
u8bit,u16bit,u32bit :
emitcall(rdwrprefix[doread]+'UINT');
uchar :
emitcall(rdwrprefix[doread]+'CHAR');
s64bit :
emitcall(rdwrprefix[doread]+'INT64');
u64bit :
emitcall(rdwrprefix[doread]+'QWORD');
bool8bit,
bool16bit,
bool32bit :
emitcall(rdwrprefix[doread]+'BOOLEAN');
end;
if doread then
begin
maybe_loadesi;
esireloaded:=true;
StoreDirectFuncResult(tcallparanode(hp).left);
end;
end;
end;
end;
{ load ESI in methods again }
popusedregisters(pushed);
if not(esireloaded) then
maybe_loadesi;
end;
end;
{ Insert end of writing for textfiles }
if ft=ft_text then
begin
pushusedregisters(pushed,$ff);
emit_push_mem(aktfile);
saveregvars($ff);
if doread then
begin
if doln then
emitcall('FPC_READLN_END')
else
emitcall('FPC_READ_END');
end
else
begin
if doln then
emitcall('FPC_WRITELN_END')
else
emitcall('FPC_WRITE_END');
end;
popusedregisters(pushed);
maybe_loadesi;
end;
{ Insert IOCheck if set }
if assigned(iolabel) then
begin
{ registers are saved in the procedure }
emit_sym(A_PUSH,S_L,iolabel);
emitcall('FPC_IOCHECK');
end;
{ Freeup all used temps }
ungetiftemp(aktfile);
if assigned(left) then
begin
left:=reversparameter(left);
if npara<>nb_para then
CGMessage(cg_f_internal_error_in_secondinline);
hp:=left;
while assigned(hp) do
begin
if assigned(tcallparanode(hp).left) then
if (tcallparanode(hp).left.location.loc in [LOC_MEM,LOC_REFERENCE]) then
ungetiftemp(tcallparanode(hp).left.location.reference);
hp:=tcallparanode(hp).right;
end;
end;
end;
procedure handle_str;
var
hp,
node : tcallparanode;
dummycoll : tparaitem;
//hp2 : tstringconstnode;
is_real : boolean;
realtype : tfloattype;
procedureprefix : string;
begin
dummycoll:=TParaItem.Create;
dummycoll.register:=R_NO;
pushusedregisters(pushed,$ff);
node:=tcallparanode(left);
is_real:=false;
while assigned(node.right) do node:=tcallparanode(node.right);
{ if a real parameter somewhere then call REALSTR }
if (node.left.resulttype^.deftype=floatdef) then
begin
is_real:=true;
realtype:=pfloatdef(node.left.resulttype)^.typ;
end;
node:=tcallparanode(left);
{ we have at least two args }
{ with at max 2 colon_para in between }
{ string arg }
hp:=node;
node:=tcallparanode(node.right);
hp.right:=nil;
dummycoll.paratyp:=vs_var;
if is_shortstring(hp.resulttype) then
dummycoll.paratype.setdef(openshortstringdef)
else
dummycoll.paratype.setdef(hp.resulttype);
procedureprefix:='FPC_'+pstringdef(hp.resulttype)^.stringtypname+'_';
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
dummycoll.paratyp:=vs_const;
left.free;
left:=nil;
{ second arg }
hp:=node;
node:=tcallparanode(node.right);
hp.right:=nil;
{ if real push real type }
if is_real then
push_int(ord(realtype));
{ frac para }
if (cpf_is_colon_para in hp.callparaflags) and assigned(node) and
(cpf_is_colon_para in node.callparaflags) then
begin
dummycoll.paratype.setdef(hp.resulttype);
dummycoll.paratyp:=vs_value;
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
hp.free;
hp:=node;
node:=tcallparanode(node.right);
hp.right:=nil;
end
else
if is_real then
push_int(-1);
{ third arg, length only if is_real }
if (cpf_is_colon_para in hp.callparaflags) then
begin
dummycoll.paratype.setdef(hp.resulttype);
dummycoll.paratyp:=vs_value;
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
hp.free;
hp:=node;
node:=tcallparanode(node.right);
hp.right:=nil;
end
else
if is_real then
push_int(-32767)
else
push_int(-1);
{ Convert float to bestreal }
if is_real then
begin
hp.left:=gentypeconvnode(hp.left,bestrealdef^);
firstpass(hp.left);
end;
{ last arg longint or real }
dummycoll.paratype.setdef(hp.resulttype);
dummycoll.paratyp:=vs_value;
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
saveregvars($ff);
if is_real then
emitcall(procedureprefix+'FLOAT')
else
case porddef(hp.resulttype)^.typ of
u32bit:
emitcall(procedureprefix+'CARDINAL');
u64bit:
emitcall(procedureprefix+'QWORD');
s64bit:
emitcall(procedureprefix+'INT64');
else
emitcall(procedureprefix+'LONGINT');
end;
hp.free;
popusedregisters(pushed);
end;
Procedure Handle_Val;
var
hp,node,
code_para, dest_para : tcallparanode;
hreg,hreg2: TRegister;
hdef: POrdDef;
procedureprefix : string;
hr, hr2: TReference;
dummycoll : tparaitem;
has_code, has_32bit_code, oldregisterdef: boolean;
r : preference;
begin
dummycoll:=TParaItem.Create;
dummycoll.register:=R_NO;
node:=tcallparanode(left);
hp:=node;
node:=tcallparanode(node.right);
hp.right:=nil;
{if we have 3 parameters, we have a code parameter}
has_code := Assigned(node.right);
has_32bit_code := false;
reset_reference(hr);
hreg := R_NO;
If has_code then
Begin
{code is an orddef, that's checked in tcinl}
code_para := hp;
hp := node;
node := tcallparanode(node.right);
hp.right := nil;
has_32bit_code := (porddef(tcallparanode(code_para).left.resulttype)^.typ in [u32bit,s32bit]);
End;
{hp = destination now, save for later use}
dest_para := hp;
{if EAX is already in use, it's a register variable. Since we don't
need another register besides EAX, release the one we got}
If hreg <> R_EAX Then ungetregister32(hreg);
{load and push the address of the destination}
dummycoll.paratyp:=vs_var;
dummycoll.paratype.setdef(dest_para.resulttype);
dest_para.secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
{save the regvars}
pushusedregisters(pushed,$ff);
{now that we've already pushed the addres of dest_para.left on the
stack, we can put the real parameters on the stack}
If has_32bit_code Then
Begin
dummycoll.paratyp:=vs_var;
dummycoll.paratype.setdef(code_para.resulttype);
code_para.secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
code_para.free;
End
Else
Begin
{only 32bit code parameter is supported, so fake one}
GetTempOfSizeReference(4,hr);
emitpushreferenceaddr(hr);
End;
{node = first parameter = string}
dummycoll.paratyp:=vs_const;
dummycoll.paratype.setdef(node.resulttype);
node.secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
Case dest_para.resulttype^.deftype of
floatdef:
begin
procedureprefix := 'FPC_VAL_REAL_';
if pfloatdef(resulttype)^.typ<>f32bit then
inc(fpuvaroffset);
end;
orddef:
if is_64bitint(dest_para.resulttype) then
begin
if is_signed(dest_para.resulttype) then
procedureprefix := 'FPC_VAL_INT64_'
else
procedureprefix := 'FPC_VAL_QWORD_';
end
else
begin
if is_signed(dest_para.resulttype) then
begin
{if we are converting to a signed number, we have to include the
size of the destination, so the Val function can extend the sign
of the result to allow proper range checking}
emit_const(A_PUSH,S_L,dest_para.resulttype^.size);
procedureprefix := 'FPC_VAL_SINT_'
end
else
procedureprefix := 'FPC_VAL_UINT_';
end;
End;
saveregvars($ff);
emitcall(procedureprefix+pstringdef(node.resulttype)^.stringtypname);
{ before disposing node we need to ungettemp !! PM }
if node.left.location.loc in [LOC_REFERENCE,LOC_MEM] then
ungetiftemp(node.left.location.reference);
node.free;
left := nil;
{reload esi in case the dest_para/code_para is a class variable or so}
maybe_loadesi;
If (dest_para.resulttype^.deftype = orddef) Then
Begin
{store the result in a safe place, because EAX may be used by a
register variable}
hreg := getexplicitregister32(R_EAX);
emit_reg_reg(A_MOV,S_L,R_EAX,hreg);
if is_64bitint(dest_para.resulttype) then
begin
hreg2:=getexplicitregister32(R_EDX);
emit_reg_reg(A_MOV,S_L,R_EDX,hreg2);
end;
{as of now, hreg now holds the location of the result, if it was
integer}
End;
{ restore the register vars}
popusedregisters(pushed);
If has_code and Not(has_32bit_code) Then
{only 16bit code is possible}
Begin
{load the address of the code parameter}
secondpass(code_para.left);
{move the code to its destination}
{$ifndef noAllocEdi}
getexplicitregister32(R_EDI);
{$endif noAllocEdi}
emit_ref_reg(A_MOV,S_L,NewReference(hr),R_EDI);
emit_mov_reg_loc(R_DI,code_para.left.location);
{$ifndef noAllocEdi}
ungetregister32(R_EDI);
{$endif noAllocEdi}
code_para.free;
End;
{restore the address of the result}
{$ifndef noAllocEdi}
getexplicitregister32(R_EDI);
{$endif noAllocEdi}
emit_reg(A_POP,S_L,R_EDI);
{set up hr2 to a refernce with EDI as base register}
reset_reference(hr2);
hr2.base := R_EDI;
{save the function result in the destination variable}
Case dest_para.left.resulttype^.deftype of
floatdef:
floatstore(PFloatDef(dest_para.left.resulttype)^.typ, hr2);
orddef:
Case PordDef(dest_para.left.resulttype)^.typ of
u8bit,s8bit:
emit_reg_ref(A_MOV, S_B,
RegToReg8(hreg),newreference(hr2));
u16bit,s16bit:
emit_reg_ref(A_MOV, S_W,
RegToReg16(hreg),newreference(hr2));
u32bit,s32bit:
emit_reg_ref(A_MOV, S_L,
hreg,newreference(hr2));
u64bit,s64bit:
begin
emit_reg_ref(A_MOV, S_L,
hreg,newreference(hr2));
r:=newreference(hr2);
inc(r^.offset,4);
emit_reg_ref(A_MOV, S_L,
hreg2,r);
end;
End;
End;
{$ifndef noAllocEdi}
ungetregister32(R_EDI);
{$endif noAllocEdi}
If (cs_check_range in aktlocalswitches) and
(dest_para.left.resulttype^.deftype = orddef) and
(not(is_64bitint(dest_para.left.resulttype))) and
{the following has to be changed to 64bit checking, once Val
returns 64 bit values (unless a special Val function is created
for that)}
{no need to rangecheck longints or cardinals on 32bit processors}
not((porddef(dest_para.left.resulttype)^.typ = s32bit) and
(porddef(dest_para.left.resulttype)^.low = longint($80000000)) and
(porddef(dest_para.left.resulttype)^.high = $7fffffff)) and
not((porddef(dest_para.left.resulttype)^.typ = u32bit) and
(porddef(dest_para.left.resulttype)^.low = 0) and
(porddef(dest_para.left.resulttype)^.high = longint($ffffffff))) then
Begin
hp:=tcallparanode(dest_para.left.getcopy);
hp.location.loc := LOC_REGISTER;
hp.location.register := hreg;
{do not register this temporary def}
OldRegisterDef := RegisterDef;
RegisterDef := False;
Case PordDef(dest_para.left.resulttype)^.typ of
u8bit,u16bit,u32bit: new(hdef,init(u32bit,0,longint($ffffffff)));
s8bit,s16bit,s32bit: new(hdef,init(s32bit,longint($80000000),$7fffffff));
end;
hp.resulttype := hdef;
emitrangecheck(hp,dest_para.left.resulttype);
hp.right := nil;
Dispose(hp.resulttype, Done);
RegisterDef := OldRegisterDef;
hp.free;
End;
{dest_para.right is already nil}
dest_para.free;
UnGetIfTemp(hr);
end;
var
r : preference;
//hp : tcallparanode;
hp2 : tstringconstnode;
dummycoll : tparaitem;
l : longint;
ispushed : boolean;
hregister : tregister;
otlabel,oflabel{,l1} : pasmlabel;
oldpushedparasize : longint;
def : pdef;
hr,hr2 : treference;
begin
{ save & reset pushedparasize }
oldpushedparasize:=pushedparasize;
pushedparasize:=0;
case inlinenumber of
in_assert_x_y:
begin
{ the node should be removed in the firstpass }
if not (cs_do_assertion in aktlocalswitches) then
internalerror(7123458);
otlabel:=truelabel;
oflabel:=falselabel;
getlabel(truelabel);
getlabel(falselabel);
secondpass(tcallparanode(left).left);
maketojumpbool(tcallparanode(left).left);
emitlab(falselabel);
{ erroraddr }
emit_reg(A_PUSH,S_L,R_EBP);
{ lineno }
emit_const(A_PUSH,S_L,aktfilepos.line);
{ filename string }
hp2:=genstringconstnode(current_module.sourcefiles.get_file_name(aktfilepos.fileindex),st_shortstring);
secondpass(hp2);
if codegenerror then
exit;
emitpushreferenceaddr(hp2.location.reference);
hp2.free;
{ push msg }
secondpass(tcallparanode(tcallparanode(left).right).left);
emitpushreferenceaddr(tcallparanode(tcallparanode(left).right).left.location.reference);
{ call }
emitcall('FPC_ASSERT');
emitlab(truelabel);
truelabel:=otlabel;
falselabel:=oflabel;
end;
in_lo_word,
in_hi_word :
begin
secondpass(left);
location.loc:=LOC_REGISTER;
if left.location.loc<>LOC_REGISTER then
begin
if left.location.loc=LOC_CREGISTER then
begin
location.register:=reg32toreg16(getregister32);
emit_reg_reg(A_MOV,S_W,left.location.register,
location.register);
end
else
begin
del_reference(left.location.reference);
location.register:=reg32toreg16(getregister32);
emit_ref_reg(A_MOV,S_W,newreference(left.location.reference),
location.register);
end;
end
else location.register:=left.location.register;
if inlinenumber=in_hi_word then
emit_const_reg(A_SHR,S_W,8,location.register);
location.register:=reg16toreg8(location.register);
end;
in_sizeof_x,
in_typeof_x :
begin
{ for both cases load vmt }
if left.nodetype=typen then
begin
location.register:=getregister32;
emit_sym_ofs_reg(A_MOV,
S_L,newasmsymbol(pobjectdef(left.resulttype)^.vmt_mangledname),0,
location.register);
end
else
begin
secondpass(left);
del_reference(left.location.reference);
location.loc:=LOC_REGISTER;
location.register:=getregister32;
{ load VMT pointer }
inc(left.location.reference.offset,
pobjectdef(left.resulttype)^.vmt_offset);
emit_ref_reg(A_MOV,S_L,
newreference(left.location.reference),
location.register);
end;
{ in sizeof load size }
if inlinenumber=in_sizeof_x then
begin
new(r);
reset_reference(r^);
r^.base:=location.register;
emit_ref_reg(A_MOV,S_L,r,
location.register);
end;
end;
in_lo_long,
in_hi_long :
begin
secondpass(left);
location.loc:=LOC_REGISTER;
if left.location.loc<>LOC_REGISTER then
begin
if left.location.loc=LOC_CREGISTER then
begin
location.register:=getregister32;
emit_reg_reg(A_MOV,S_L,left.location.register,
location.register);
end
else
begin
del_reference(left.location.reference);
location.register:=getregister32;
emit_ref_reg(A_MOV,S_L,newreference(left.location.reference),
location.register);
end;
end
else location.register:=left.location.register;
if inlinenumber=in_hi_long then
emit_const_reg(A_SHR,S_L,16,location.register);
location.register:=reg32toreg16(location.register);
end;
in_lo_qword,
in_hi_qword:
begin
secondpass(left);
location.loc:=LOC_REGISTER;
case left.location.loc of
LOC_CREGISTER:
begin
location.register:=getregister32;
if inlinenumber=in_hi_qword then
emit_reg_reg(A_MOV,S_L,left.location.registerhigh,
location.register)
else
emit_reg_reg(A_MOV,S_L,left.location.registerlow,
location.register)
end;
LOC_MEM,LOC_REFERENCE:
begin
del_reference(left.location.reference);
location.register:=getregister32;
r:=newreference(left.location.reference);
if inlinenumber=in_hi_qword then
inc(r^.offset,4);
emit_ref_reg(A_MOV,S_L,
r,location.register);
end;
LOC_REGISTER:
begin
if inlinenumber=in_hi_qword then
begin
location.register:=left.location.registerhigh;
ungetregister32(left.location.registerlow);
end
else
begin
location.register:=left.location.registerlow;
ungetregister32(left.location.registerhigh);
end;
end;
end;
end;
in_length_string :
begin
secondpass(left);
set_location(location,left.location);
{ length in ansi strings is at offset -8 }
if is_ansistring(left.resulttype) then
dec(location.reference.offset,8)
{ char is always 1, so make it a constant value }
else if is_char(left.resulttype) then
begin
clear_location(location);
location.loc:=LOC_MEM;
location.reference.is_immediate:=true;
location.reference.offset:=1;
end;
end;
in_pred_x,
in_succ_x:
begin
secondpass(left);
if not (cs_check_overflow in aktlocalswitches) then
if inlinenumber=in_pred_x then
asmop:=A_DEC
else
asmop:=A_INC
else
if inlinenumber=in_pred_x then
asmop:=A_SUB
else
asmop:=A_ADD;
case resulttype^.size of
8 : opsize:=S_L;
4 : opsize:=S_L;
2 : opsize:=S_W;
1 : opsize:=S_B;
else
internalerror(10080);
end;
location.loc:=LOC_REGISTER;
if resulttype^.size=8 then
begin
if left.location.loc<>LOC_REGISTER then
begin
if left.location.loc=LOC_CREGISTER then
begin
location.registerlow:=getregister32;
location.registerhigh:=getregister32;
emit_reg_reg(A_MOV,opsize,left.location.registerlow,
location.registerlow);
emit_reg_reg(A_MOV,opsize,left.location.registerhigh,
location.registerhigh);
end
else
begin
del_reference(left.location.reference);
location.registerlow:=getregister32;
location.registerhigh:=getregister32;
emit_ref_reg(A_MOV,opsize,newreference(left.location.reference),
location.registerlow);
r:=newreference(left.location.reference);
inc(r^.offset,4);
emit_ref_reg(A_MOV,opsize,r,
location.registerhigh);
end;
end
else
begin
location.registerhigh:=left.location.registerhigh;
location.registerlow:=left.location.registerlow;
end;
if inlinenumber=in_succ_x then
begin
emit_const_reg(A_ADD,opsize,1,
location.registerlow);
emit_const_reg(A_ADC,opsize,0,
location.registerhigh);
end
else
begin
emit_const_reg(A_SUB,opsize,1,
location.registerlow);
emit_const_reg(A_SBB,opsize,0,
location.registerhigh);
end;
end
else
begin
if left.location.loc<>LOC_REGISTER then
begin
{ first, we've to release the source location ... }
if left.location.loc in [LOC_MEM,LOC_REFERENCE] then
del_reference(left.location.reference);
location.register:=getregister32;
if (resulttype^.size=2) then
location.register:=reg32toreg16(location.register);
if (resulttype^.size=1) then
location.register:=reg32toreg8(location.register);
if left.location.loc=LOC_CREGISTER then
emit_reg_reg(A_MOV,opsize,left.location.register,
location.register)
else
if left.location.loc=LOC_FLAGS then
emit_flag2reg(left.location.resflags,location.register)
else
emit_ref_reg(A_MOV,opsize,newreference(left.location.reference),
location.register);
end
else location.register:=left.location.register;
if not (cs_check_overflow in aktlocalswitches) then
emit_reg(asmop,opsize,
location.register)
else
emit_const_reg(asmop,opsize,1,
location.register);
end;
emitoverflowcheck(self);
emitrangecheck(self,resulttype);
end;
in_dec_x,
in_inc_x :
begin
{ set defaults }
addvalue:=1;
addconstant:=true;
{ load first parameter, must be a reference }
secondpass(tcallparanode(left).left);
case tcallparanode(left).left.resulttype^.deftype of
orddef,
enumdef : begin
case tcallparanode(left).left.resulttype^.size of
1 : opsize:=S_B;
2 : opsize:=S_W;
4 : opsize:=S_L;
8 : opsize:=S_L;
end;
end;
pointerdef : begin
opsize:=S_L;
if porddef(ppointerdef(tcallparanode(left).left.resulttype)^.pointertype.def)=voiddef then
addvalue:=1
else
addvalue:=ppointerdef(tcallparanode(left).left.resulttype)^.pointertype.def^.size;
end;
else
internalerror(10081);
end;
{ second argument specified?, must be a s32bit in register }
if assigned(tcallparanode(left).right) then
begin
ispushed:=maybe_push(tcallparanode(tcallparanode(left).right).left.registers32,
tcallparanode(left).left,false);
secondpass(tcallparanode(tcallparanode(left).right).left);
if ispushed then
restore(tcallparanode(left).left,false);
{ when constant, just multiply the addvalue }
if is_constintnode(tcallparanode(tcallparanode(left).right).left) then
addvalue:=addvalue*get_ordinal_value(tcallparanode(tcallparanode(left).right).left)
else
begin
case tcallparanode(tcallparanode(left).right).left.location.loc of
LOC_REGISTER,
LOC_CREGISTER : hregister:=tcallparanode(tcallparanode(left).right).left.location.register;
LOC_MEM,
LOC_REFERENCE : begin
del_reference(tcallparanode(tcallparanode(left).right).left.location.reference);
hregister:=getregister32;
emit_ref_reg(A_MOV,S_L,
newreference(tcallparanode(tcallparanode(left).right).left.location.reference),hregister);
end;
else
internalerror(10082);
end;
{ insert multiply with addvalue if its >1 }
if addvalue>1 then
emit_const_reg(A_IMUL,opsize,
addvalue,hregister);
addconstant:=false;
end;
end;
{ write the add instruction }
if addconstant then
begin
if (addvalue=1) and not(cs_check_overflow in aktlocalswitches) then
begin
if tcallparanode(left).left.location.loc=LOC_CREGISTER then
emit_reg(incdecop[inlinenumber],opsize,
tcallparanode(left).left.location.register)
else
emit_ref(incdecop[inlinenumber],opsize,
newreference(tcallparanode(left).left.location.reference))
end
else
begin
if tcallparanode(left).left.location.loc=LOC_CREGISTER then
emit_const_reg(addsubop[inlinenumber],opsize,
addvalue,tcallparanode(left).left.location.register)
else
emit_const_ref(addsubop[inlinenumber],opsize,
addvalue,newreference(tcallparanode(left).left.location.reference));
end
end
else
begin
{ BUG HERE : detected with nasm :
hregister is allways 32 bit
it should be converted to 16 or 8 bit depending on op_size PM }
{ still not perfect :
if hregister is already a 16 bit reg ?? PM }
{ makeregXX is the solution (FK) }
case opsize of
S_B : hregister:=makereg8(hregister);
S_W : hregister:=makereg16(hregister);
end;
if tcallparanode(left).left.location.loc=LOC_CREGISTER then
emit_reg_reg(addsubop[inlinenumber],opsize,
hregister,tcallparanode(left).left.location.register)
else
emit_reg_ref(addsubop[inlinenumber],opsize,
hregister,newreference(tcallparanode(left).left.location.reference));
case opsize of
S_B : hregister:=reg8toreg32(hregister);
S_W : hregister:=reg16toreg32(hregister);
end;
ungetregister32(hregister);
end;
emitoverflowcheck(tcallparanode(left).left);
emitrangecheck(tcallparanode(left).left,tcallparanode(left).left.resulttype);
end;
in_typeinfo_x:
begin
pstoreddef(ttypenode(tcallparanode(left).left).typenodetype)^.generate_rtti;
location.register:=getregister32;
new(r);
reset_reference(r^);
r^.symbol:=pstoreddef(ttypenode(tcallparanode(left).left).typenodetype)^.rtti_label;
emit_ref_reg(A_LEA,S_L,r,location.register);
end;
in_finalize_x:
begin
pushusedregisters(pushed,$ff);
{ force rtti generation }
pstoreddef(ttypenode(tcallparanode(left).left).resulttype)^.generate_rtti;
{ if a count is passed, push size, typeinfo and count }
if assigned(tcallparanode(left).right) then
begin
secondpass(tcallparanode(tcallparanode(left).right).left);
push_int(tcallparanode(left).left.resulttype^.size);
if codegenerror then
exit;
emit_push_loc(tcallparanode(tcallparanode(left).right).left.location);
end;
{ generate a reference }
reset_reference(hr);
hr.symbol:=pstoreddef(ttypenode(tcallparanode(left).left).resulttype)^.rtti_label;
emitpushreferenceaddr(hr);
{ data to finalize }
secondpass(tcallparanode(left).left);
if codegenerror then
exit;
emitpushreferenceaddr(tcallparanode(left).left.location.reference);
saveregvars($ff);
if assigned(tcallparanode(left).right) then
emitcall('FPC_FINALIZEARRAY')
else
emitcall('FPC_FINALIZE');
popusedregisters(pushed);
end;
in_assigned_x :
begin
secondpass(tcallparanode(left).left);
location.loc:=LOC_FLAGS;
if (tcallparanode(left).left.location.loc in [LOC_REGISTER,LOC_CREGISTER]) then
begin
emit_reg_reg(A_OR,S_L,
tcallparanode(left).left.location.register,
tcallparanode(left).left.location.register);
ungetregister32(tcallparanode(left).left.location.register);
end
else
begin
emit_const_ref(A_CMP,S_L,0,
newreference(tcallparanode(left).left.location.reference));
del_reference(tcallparanode(left).left.location.reference);
end;
location.resflags:=F_NE;
end;
in_reset_typedfile,in_rewrite_typedfile :
begin
pushusedregisters(pushed,$ff);
emit_const(A_PUSH,S_L,pfiledef(left.resulttype)^.typedfiletype.def^.size);
secondpass(left);
emitpushreferenceaddr(left.location.reference);
saveregvars($ff);
if inlinenumber=in_reset_typedfile then
emitcall('FPC_RESET_TYPED')
else
emitcall('FPC_REWRITE_TYPED');
popusedregisters(pushed);
end;
in_setlength_x:
begin
pushusedregisters(pushed,$ff);
l:=0;
{ push dimensions }
hp:=left;
while assigned(tcallparanode(hp).right) do
begin
inc(l);
hp:=tcallparanode(hp).right;
end;
def:=tcallparanode(hp).left.resulttype;
hp:=left;
if is_dynamic_array(def) then
begin
{ get temp. space }
gettempofsizereference(l*4,hr);
{ keep data start }
hr2:=hr;
{ copy dimensions }
hp:=left;
while assigned(tcallparanode(hp).right) do
begin
secondpass(tcallparanode(hp).left);
emit_mov_loc_ref(tcallparanode(hp).left.location,hr,
S_L,true);
inc(hr.offset,4);
hp:=tcallparanode(hp).right;
end;
end
else
begin
secondpass(tcallparanode(hp).left);
emit_push_loc(tcallparanode(hp).left.location);
hp:=tcallparanode(hp).right;
end;
{ handle shortstrings separately since the hightree must be }
{ pushed too (JM) }
if not(is_dynamic_array(def)) and
(pstringdef(def)^.string_typ = st_shortstring) then
begin
dummycoll:=TParaItem.Create;
dummycoll.paratyp:=vs_var;
dummycoll.paratype.setdef(openshortstringdef);
tcallparanode(hp).secondcallparan(dummycoll,false,false,false,0,0);
if codegenerror then
exit;
end
else secondpass(tcallparanode(hp).left);
if is_dynamic_array(def) then
begin
emitpushreferenceaddr(hr2);
push_int(l);
reset_reference(hr2);
hr2.symbol:=pstoreddef(def)^.get_inittable_label;
emitpushreferenceaddr(hr2);
emitpushreferenceaddr(tcallparanode(hp).left.location.reference);
saveregvars($ff);
emitcall('FPC_DYNARR_SETLENGTH');
ungetiftemp(hr);
end
else
{ must be string }
begin
case pstringdef(def)^.string_typ of
st_widestring:
begin
emitpushreferenceaddr(tcallparanode(hp).left.location.reference);
saveregvars($ff);
emitcall('FPC_WIDESTR_SETLENGTH');
end;
st_ansistring:
begin
emitpushreferenceaddr(tcallparanode(hp).left.location.reference);
saveregvars($ff);
emitcall('FPC_ANSISTR_SETLENGTH');
end;
st_shortstring:
begin
saveregvars($ff);
emitcall('FPC_SHORTSTR_SETLENGTH');
end;
end;
end;
popusedregisters(pushed);
end;
in_write_x :
handlereadwrite(false,false);
in_writeln_x :
handlereadwrite(false,true);
in_read_x :
handlereadwrite(true,false);
in_readln_x :
handlereadwrite(true,true);
in_str_x_string :
begin
handle_str;
maybe_loadesi;
end;
in_val_x :
Begin
handle_val;
End;
in_include_x_y,
in_exclude_x_y:
begin
secondpass(tcallparanode(left).left);
if tcallparanode(tcallparanode(left).right).left.nodetype=ordconstn then
begin
{ calculate bit position }
l:=1 shl (tordconstnode(tcallparanode(tcallparanode(left).right).left).value mod 32);
{ determine operator }
if inlinenumber=in_include_x_y then
asmop:=A_OR
else
begin
asmop:=A_AND;
l:=not(l);
end;
if (tcallparanode(left).left.location.loc=LOC_REFERENCE) then
begin
inc(tcallparanode(left).left.location.reference.offset,
(tordconstnode(tcallparanode(tcallparanode(left).right).left).value div 32)*4);
emit_const_ref(asmop,S_L,
l,newreference(tcallparanode(left).left.location.reference));
del_reference(tcallparanode(left).left.location.reference);
end
else
{ LOC_CREGISTER }
begin
secondpass(tcallparanode(left).left);
emit_const_reg(asmop,S_L,
l,tcallparanode(left).left.location.register);
end;
end
else
begin
{ generate code for the element to set }
ispushed:=maybe_push(tcallparanode(tcallparanode(left).right).left.registers32,
tcallparanode(left).left,false);
secondpass(tcallparanode(tcallparanode(left).right).left);
if ispushed then
restore(tcallparanode(left).left,false);
{ determine asm operator }
if inlinenumber=in_include_x_y then
asmop:=A_BTS
else
asmop:=A_BTR;
if psetdef(left.resulttype)^.settype=smallset then
begin
if tcallparanode(tcallparanode(left).right).left.location.loc in [LOC_CREGISTER,LOC_REGISTER] then
{ we don't need a mod 32 because this is done automatically }
{ by the bts instruction. For proper checking we would }
{ need a cmp and jmp, but this should be done by the }
{ type cast code which does range checking if necessary (FK) }
hregister:=makereg32(tcallparanode(tcallparanode(left).right).left.location.register)
else
begin
getexplicitregister32(R_EDI);
hregister:=R_EDI;
opsize:=def2def_opsize(
tcallparanode(tcallparanode(left).right).left.resulttype,u32bitdef);
if opsize in [S_B,S_W,S_L] then
op:=A_MOV
else
op:=A_MOVZX;
emit_ref_reg(op,opsize,
newreference(
tcallparanode(tcallparanode(left).right).left.location.reference),R_EDI);
end;
if (tcallparanode(left).left.location.loc=LOC_REFERENCE) then
emit_reg_ref(asmop,S_L,hregister,
newreference(tcallparanode(left).left.location.reference))
else
emit_reg_reg(asmop,S_L,hregister,
tcallparanode(left).left.location.register);
if hregister = R_EDI then
ungetregister32(R_EDI);
end
else
begin
pushsetelement(tcallparanode(tcallparanode(left).right).left);
{ normset is allways a ref }
emitpushreferenceaddr(tcallparanode(left).left.location.reference);
if inlinenumber=in_include_x_y then
emitcall('FPC_SET_SET_BYTE')
else
emitcall('FPC_SET_UNSET_BYTE');
{CGMessage(cg_e_include_not_implemented);}
end;
end;
end;
in_pi:
begin
emit_none(A_FLDPI,S_NO);
inc(fpuvaroffset);
end;
in_sin_extended,
in_arctan_extended,
in_abs_extended,
in_sqr_extended,
in_sqrt_extended,
in_ln_extended,
in_cos_extended:
begin
secondpass(left);
case left.location.loc of
LOC_FPU:
;
LOC_CFPUREGISTER:
begin
emit_reg(A_FLD,S_NO,
correct_fpuregister(left.location.register,fpuvaroffset));
inc(fpuvaroffset);
end;
LOC_REFERENCE,LOC_MEM:
begin
floatload(pfloatdef(left.resulttype)^.typ,left.location.reference);
del_reference(left.location.reference);
end
else
internalerror(309991);
end;
case inlinenumber of
in_sin_extended,
in_cos_extended:
begin
if inlinenumber=in_sin_extended then
emit_none(A_FSIN,S_NO)
else
emit_none(A_FCOS,S_NO);
{
getlabel(l1);
emit_reg(A_FNSTSW,S_NO,R_AX);
emit_none(A_SAHF,S_NO);
emitjmp(C_NP,l1);
emit_reg(A_FSTP,S_NO,R_ST0);
emit_none(A_FLDZ,S_NO);
emitlab(l1);
}
end;
in_arctan_extended:
begin
emit_none(A_FLD1,S_NO);
emit_none(A_FPATAN,S_NO);
end;
in_abs_extended:
emit_none(A_FABS,S_NO);
in_sqr_extended:
begin
(* emit_reg(A_FLD,S_NO,R_ST0);
{ emit_none(A_FMULP,S_NO); nasm does not accept this PM }
emit_reg_reg(A_FMULP,S_NO,R_ST0,R_ST1);
can be shorten to *)
emit_reg_reg(A_FMUL,S_NO,R_ST0,R_ST0);
end;
in_sqrt_extended:
emit_none(A_FSQRT,S_NO);
in_ln_extended:
begin
emit_none(A_FLDLN2,S_NO);
emit_none(A_FXCH,S_NO);
emit_none(A_FYL2X,S_NO);
end;
end;
end;
{$ifdef SUPPORT_MMX}
in_mmx_pcmpeqb..in_mmx_pcmpgtw:
begin
if left.location.loc=LOC_REGISTER then
begin
{!!!!!!!}
end
else if tcallparanode(left).left.location.loc=LOC_REGISTER then
begin
{!!!!!!!}
end
else
begin
{!!!!!!!}
end;
end;
{$endif SUPPORT_MMX}
else internalerror(9);
end;
{ reset pushedparasize }
pushedparasize:=oldpushedparasize;
end;
begin
cinlinenode:=ti386inlinenode;
end.
{
$Log$
Revision 1.11 2000-12-25 00:07:33 peter
+ new tlinkedlist class (merge of old tstringqueue,tcontainer and
tlinkedlist objects)
Revision 1.10 2000/12/09 22:51:37 florian
* helper name of val for qword fixed
Revision 1.9 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 wasn't restored correctly
after doing a 64bit rangecheck
Revision 1.8 2000/12/05 11:44:33 jonas
+ new integer regvar handling, should be much more efficient
Revision 1.7 2000/11/29 00:30:47 florian
* unused units removed from uses clause
* some changes for widestrings
Revision 1.6 2000/11/12 23:24:15 florian
* interfaces are basically running
Revision 1.5 2000/11/09 17:46:56 florian
* System.TypeInfo fixed
+ System.Finalize implemented
+ some new keywords for interface support added
Revision 1.4 2000/10/31 22:02:56 peter
* symtable splitted, no real code changes
Revision 1.3 2000/10/26 14:15:07 jonas
* fixed setlength for shortstrings
Revision 1.2 2000/10/21 18:16:13 florian
* a lot of changes:
- basic dyn. array support
- basic C++ support
- some work for interfaces done
....
Revision 1.1 2000/10/15 09:33:31 peter
* moved n386*.pas to i386/ cpu_target dir
Revision 1.2 2000/10/15 09:08:58 peter
* use System for the systemunit instead of target dependent
Revision 1.1 2000/10/14 10:14:49 peter
* moehrendorf oct 2000 rewrite
}
Reference in New Issue View Git Blame Copy Permalink