paweld/fpc
1
0
Fork 0
mirror of https://gitlab.com/freepascal.org/fpc/source.git synced 2025-04-12 11:49:28 +02:00
Code Issues Packages Projects Releases Wiki Activity
99120a3f2b
fpc/compiler/defutil.pas
florian adb193497d + softfloat support for wince 
* more units are build for wince

git-svn-id: trunk@959 -
2005-08-28 12:40:43 +00:00

922 lines
29 KiB
ObjectPascal
Raw Blame History

{
Copyright (c) 1998-2002 by Florian Klaempfl
This unit provides some help routines for type handling
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 defutil;
{$i fpcdefs.inc}
interface
uses
cclasses,
globtype,globals,
symconst,symbase,symtype,symdef,
cgbase,cpubase;
type
tmmxtype = (mmxno,mmxu8bit,mmxs8bit,mmxu16bit,mmxs16bit,
mmxu32bit,mmxs32bit,mmxfixed16,mmxsingle);
{*****************************************************************************
Basic type functions
*****************************************************************************}
{# Returns true, if definition defines an ordinal type }
function is_ordinal(def : tdef) : boolean;
{# Returns the minimal integer value of the type }
function get_min_value(def : tdef) : TConstExprInt;
{# Returns basetype of the specified integer range }
function range_to_basetype(l,h:TConstExprInt):tbasetype;
procedure range_to_type(l,h:TConstExprInt;var tt:ttype);
procedure int_to_type(v:TConstExprInt;var tt:ttype);
{# Returns true, if definition defines an integer type }
function is_integer(def : tdef) : boolean;
{# Returns true if definition is a boolean }
function is_boolean(def : tdef) : boolean;
{# Returns true if definition is a char
This excludes the unicode char.
}
function is_char(def : tdef) : boolean;
{# Returns true if definition is a widechar }
function is_widechar(def : tdef) : boolean;
{# Returns true if definition is a void}
function is_void(def : tdef) : boolean;
{# Returns true if definition is a smallset}
function is_smallset(p : tdef) : boolean;
{# Returns true, if def defines a signed data type
(only for ordinal types)
}
function is_signed(def : tdef) : boolean;
{# Returns true whether def_from's range is comprised in def_to's if both are
orddefs, false otherwise }
function is_in_limit(def_from,def_to : tdef) : boolean;
function is_in_limit_value(val_from:TConstExprInt;def_from,def_to : tdef) : boolean;
{*****************************************************************************
Array helper functions
*****************************************************************************}
{# Returns true, if p points to a zero based (non special like open or
dynamic array def).
This is mainly used to see if the array
is convertable to a pointer
}
function is_zero_based_array(p : tdef) : boolean;
{# Returns true if p points to an open array definition }
function is_open_array(p : tdef) : boolean;
{# Returns true if p points to a dynamic array definition }
function is_dynamic_array(p : tdef) : boolean;
{# Returns true, if p points to an array of const definition }
function is_array_constructor(p : tdef) : boolean;
{# Returns true, if p points to a variant array }
function is_variant_array(p : tdef) : boolean;
{# Returns true, if p points to an array of const }
function is_array_of_const(p : tdef) : boolean;
{# Returns true, if p points any kind of special array
That is if the array is an open array, a variant
array, an array constants constructor, or an
array of const.
}
function is_special_array(p : tdef) : boolean;
{# Returns true if p is a char array def }
function is_chararray(p : tdef) : boolean;
{# Returns true if p is a wide char array def }
function is_widechararray(p : tdef) : boolean;
{# Returns true if p is a open char array def }
function is_open_chararray(p : tdef) : boolean;
{# Returns true if p is a open wide char array def }
function is_open_widechararray(p : tdef) : boolean;
{*****************************************************************************
String helper functions
*****************************************************************************}
{# Returns true if p points to an open string type }
function is_open_string(p : tdef) : boolean;
{# Returns true if p is an ansi string type }
function is_ansistring(p : tdef) : boolean;
{# Returns true if p is a long string type }
function is_longstring(p : tdef) : boolean;
{# returns true if p is a wide string type }
function is_widestring(p : tdef) : boolean;
{# Returns true if p is a short string type }
function is_shortstring(p : tdef) : boolean;
{# Returns true if p is a pchar def }
function is_pchar(p : tdef) : boolean;
{# Returns true if p is a pwidechar def }
function is_pwidechar(p : tdef) : boolean;
{# Returns true if p is a voidpointer def }
function is_voidpointer(p : tdef) : boolean;
{# Returns true, if definition is a float }
function is_fpu(def : tdef) : boolean;
{# Returns true, if def is a currency type }
function is_currency(def : tdef) : boolean;
{# Returns true, if def is a single type }
function is_single(def : tdef) : boolean;
{# Returns true, if def is a double type }
function is_double(def : tdef) : boolean;
{# Returns true, if def is an extended type }
function is_extended(def : tdef) : boolean;
{# Returns true, if definition is a "real" real (i.e. single/double/extended) }
function is_real(def : tdef) : boolean;
{# Returns true, if def is a 32 bit integer type }
function is_32bitint(def : tdef) : boolean;
{# Returns true, if def is a 64 bit integer type }
function is_64bitint(def : tdef) : boolean;
{# Returns true, if def is a 64 bit type }
function is_64bit(def : tdef) : boolean;
{# If @var(l) isn't in the range of def a range check error (if not explicit) is generated and
the value is placed within the range
}
procedure testrange(def : tdef;var l : tconstexprint;explicit:boolean);
{# Returns the range of def, where @var(l) is the low-range and @var(h) is
the high-range.
}
procedure getrange(def : tdef;var l : TConstExprInt;var h : TConstExprInt);
{ some type helper routines for MMX support }
function is_mmx_able_array(p : tdef) : boolean;
{# returns the mmx type }
function mmx_type(p : tdef) : tmmxtype;
{# From a definition return the abstract code generator size enum. It is
to note that the value returned can be @var(OS_NO) }
function def_cgsize(def: tdef): tcgsize;
implementation
uses
systems,verbose;
{ returns true, if def uses FPU }
function is_fpu(def : tdef) : boolean;
begin
is_fpu:=(def.deftype=floatdef);
end;
{ returns true, if def is a currency type }
function is_currency(def : tdef) : boolean;
begin
case s64currencytype.def.deftype of
orddef :
result:=(def.deftype=orddef) and
(torddef(s64currencytype.def).typ=torddef(def).typ);
floatdef :
result:=(def.deftype=floatdef) and
(tfloatdef(s64currencytype.def).typ=tfloatdef(def).typ);
else
internalerror(200304222);
end;
end;
{ returns true, if def is a single type }
function is_single(def : tdef) : boolean;
begin
result:=(def.deftype=floatdef) and
(tfloatdef(def).typ=s32real);
end;
{ returns true, if def is a double type }
function is_double(def : tdef) : boolean;
begin
result:=(def.deftype=floatdef) and
(tfloatdef(def).typ=s64real);
end;
function is_extended(def : tdef) : boolean;
begin
result:=(def.deftype=floatdef) and
(tfloatdef(def).typ=s80real);
end;
{ returns true, if definition is a "real" real (i.e. single/double/extended) }
function is_real(def : tdef) : boolean;
begin
result:=(def.deftype=floatdef) and
(tfloatdef(def).typ in [s32real,s64real,s80real]);
end;
function range_to_basetype(l,h:TConstExprInt):tbasetype;
begin
{ prefer signed over unsigned }
if (l>=-128) and (h<=127) then
range_to_basetype:=s8bit
else if (l>=0) and (h<=255) then
range_to_basetype:=u8bit
else if (l>=-32768) and (h<=32767) then
range_to_basetype:=s16bit
else if (l>=0) and (h<=65535) then
range_to_basetype:=u16bit
else if (l>=low(longint)) and (h<=high(longint)) then
range_to_basetype:=s32bit
else if (l>=low(cardinal)) and (h<=high(cardinal)) then
range_to_basetype:=u32bit
else
range_to_basetype:=s64bit;
end;
procedure range_to_type(l,h:TConstExprInt;var tt:ttype);
begin
{ prefer signed over unsigned }
if (l>=-128) and (h<=127) then
tt:=s8inttype
else if (l>=0) and (h<=255) then
tt:=u8inttype
else if (l>=-32768) and (h<=32767) then
tt:=s16inttype
else if (l>=0) and (h<=65535) then
tt:=u16inttype
else if (l>=low(longint)) and (h<=high(longint)) then
tt:=s32inttype
else if (l>=low(cardinal)) and (h<=high(cardinal)) then
tt:=u32inttype
else
tt:=s64inttype;
end;
procedure int_to_type(v:TConstExprInt;var tt:ttype);
begin
range_to_type(v,v,tt);
end;
{ true if p is an ordinal }
function is_ordinal(def : tdef) : boolean;
var
dt : tbasetype;
begin
case def.deftype of
orddef :
begin
dt:=torddef(def).typ;
is_ordinal:=dt in [uchar,uwidechar,
u8bit,u16bit,u32bit,u64bit,
s8bit,s16bit,s32bit,s64bit,
bool8bit,bool16bit,bool32bit];
end;
enumdef :
is_ordinal:=true;
else
is_ordinal:=false;
end;
end;
{ returns the min. value of the type }
function get_min_value(def : tdef) : TConstExprInt;
begin
case def.deftype of
orddef:
get_min_value:=torddef(def).low;
enumdef:
get_min_value:=tenumdef(def).min;
else
get_min_value:=0;
end;
end;
{ true if p is an integer }
function is_integer(def : tdef) : boolean;
begin
is_integer:=(def.deftype=orddef) and
(torddef(def).typ in [u8bit,u16bit,u32bit,u64bit,
s8bit,s16bit,s32bit,s64bit]);
end;
{ true if p is a boolean }
function is_boolean(def : tdef) : boolean;
begin
is_boolean:=(def.deftype=orddef) and
(torddef(def).typ in [bool8bit,bool16bit,bool32bit]);
end;
{ true if p is a void }
function is_void(def : tdef) : boolean;
begin
is_void:=(def.deftype=orddef) and
(torddef(def).typ=uvoid);
end;
{ true if p is a char }
function is_char(def : tdef) : boolean;
begin
is_char:=(def.deftype=orddef) and
(torddef(def).typ=uchar);
end;
{ true if p is a wchar }
function is_widechar(def : tdef) : boolean;
begin
is_widechar:=(def.deftype=orddef) and
(torddef(def).typ=uwidechar);
end;
{ true if p is signed (integer) }
function is_signed(def : tdef) : boolean;
var
dt : tbasetype;
begin
case def.deftype of
orddef :
begin
dt:=torddef(def).typ;
is_signed:=(dt in [s8bit,s16bit,s32bit,s64bit,scurrency]);
end;
enumdef :
is_signed:=tenumdef(def).min < 0;
arraydef :
is_signed:=is_signed(tarraydef(def).rangetype.def);
else
is_signed:=false;
end;
end;
function is_in_limit(def_from,def_to : tdef) : boolean;
var
fromqword, toqword: boolean;
begin
if (def_from.deftype <> orddef) or
(def_to.deftype <> orddef) then
begin
is_in_limit := false;
exit;
end;
fromqword := torddef(def_from).typ = u64bit;
toqword := torddef(def_to).typ = u64bit;
is_in_limit:=(toqword and is_signed(def_from)) or
((not fromqword) and
(torddef(def_from).low>=torddef(def_to).low) and
(torddef(def_from).high<=torddef(def_to).high));
end;
function is_in_limit_value(val_from:TConstExprInt;def_from,def_to : tdef) : boolean;
begin
if (def_from.deftype <> orddef) and
(def_to.deftype <> orddef) then
internalerror(200210062);
if (torddef(def_to).typ = u64bit) then
begin
is_in_limit_value:=((TConstExprUInt(val_from)>=TConstExprUInt(torddef(def_to).low)) and
(TConstExprUInt(val_from)<=TConstExprUInt(torddef(def_to).high)));
end
else
begin;
is_in_limit_value:=((val_from>=torddef(def_to).low) and
(val_from<=torddef(def_to).high));
end;
end;
{ true, if p points to an open array def }
function is_open_string(p : tdef) : boolean;
begin
is_open_string:=(p.deftype=stringdef) and
(tstringdef(p).string_typ=st_shortstring) and
(tstringdef(p).len=0);
end;
{ true, if p points to a zero based array def }
function is_zero_based_array(p : tdef) : boolean;
begin
is_zero_based_array:=(p.deftype=arraydef) and
(tarraydef(p).lowrange=0) and
not(is_special_array(p));
end;
{ true if p points to a dynamic array def }
function is_dynamic_array(p : tdef) : boolean;
begin
is_dynamic_array:=(p.deftype=arraydef) and
tarraydef(p).IsDynamicArray;
end;
{ true, if p points to an open array def }
function is_open_array(p : tdef) : boolean;
begin
{ check for s32inttype is needed, because for u32bit the high
range is also -1 ! (PFV) }
is_open_array:=(p.deftype=arraydef) and
(tarraydef(p).rangetype.def=s32inttype.def) and
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=-1) and
not(tarraydef(p).IsConstructor) and
not(tarraydef(p).IsVariant) and
not(tarraydef(p).IsArrayOfConst) and
not(tarraydef(p).IsDynamicArray);
end;
{ true, if p points to an array of const def }
function is_array_constructor(p : tdef) : boolean;
begin
is_array_constructor:=(p.deftype=arraydef) and
(tarraydef(p).IsConstructor);
end;
{ true, if p points to a variant array }
function is_variant_array(p : tdef) : boolean;
begin
is_variant_array:=(p.deftype=arraydef) and
(tarraydef(p).IsVariant);
end;
{ true, if p points to an array of const }
function is_array_of_const(p : tdef) : boolean;
begin
is_array_of_const:=(p.deftype=arraydef) and
(tarraydef(p).IsArrayOfConst);
end;
{ true, if p points to a special array }
function is_special_array(p : tdef) : boolean;
begin
is_special_array:=(p.deftype=arraydef) and
((tarraydef(p).IsVariant) or
(tarraydef(p).IsArrayOfConst) or
(tarraydef(p).IsConstructor) or
(tarraydef(p).IsDynamicArray) or
is_open_array(p)
);
end;
{$ifdef ansistring_bits}
{ true if p is an ansi string def }
function is_ansistring(p : tdef) : boolean;
begin
is_ansistring:=(p.deftype=stringdef) and
(tstringdef(p).string_typ in [st_ansistring16,st_ansistring32,st_ansistring64]);
end;
{$else}
{ true if p is an ansi string def }
function is_ansistring(p : tdef) : boolean;
begin
is_ansistring:=(p.deftype=stringdef) and
(tstringdef(p).string_typ=st_ansistring);
end;
{$endif}
{ true if p is an long string def }
function is_longstring(p : tdef) : boolean;
begin
is_longstring:=(p.deftype=stringdef) and
(tstringdef(p).string_typ=st_longstring);
end;
{ true if p is an wide string def }
function is_widestring(p : tdef) : boolean;
begin
is_widestring:=(p.deftype=stringdef) and
(tstringdef(p).string_typ=st_widestring);
end;
{ true if p is an short string def }
function is_shortstring(p : tdef) : boolean;
begin
is_shortstring:=(p.deftype=stringdef) and
(tstringdef(p).string_typ=st_shortstring);
end;
{ true if p is a char array def }
function is_chararray(p : tdef) : boolean;
begin
is_chararray:=(p.deftype=arraydef) and
is_char(tarraydef(p).elementtype.def) and
not(is_special_array(p));
end;
{ true if p is a widechar array def }
function is_widechararray(p : tdef) : boolean;
begin
is_widechararray:=(p.deftype=arraydef) and
is_widechar(tarraydef(p).elementtype.def) and
not(is_special_array(p));
end;
{ true if p is a open char array def }
function is_open_chararray(p : tdef) : boolean;
begin
is_open_chararray:= is_open_array(p) and
is_char(tarraydef(p).elementtype.def);
end;
{ true if p is a open wide char array def }
function is_open_widechararray(p : tdef) : boolean;
begin
is_open_widechararray:= is_open_array(p) and
is_widechar(tarraydef(p).elementtype.def);
end;
{ true if p is a pchar def }
function is_pchar(p : tdef) : boolean;
begin
is_pchar:=(p.deftype=pointerdef) and
(is_char(tpointerdef(p).pointertype.def) or
(is_zero_based_array(tpointerdef(p).pointertype.def) and
is_chararray(tpointerdef(p).pointertype.def)));
end;
{ true if p is a pchar def }
function is_pwidechar(p : tdef) : boolean;
begin
is_pwidechar:=(p.deftype=pointerdef) and
(is_widechar(tpointerdef(p).pointertype.def) or
(is_zero_based_array(tpointerdef(p).pointertype.def) and
is_widechararray(tpointerdef(p).pointertype.def)));
end;
{ true if p is a voidpointer def }
function is_voidpointer(p : tdef) : boolean;
begin
is_voidpointer:=(p.deftype=pointerdef) and
(tpointerdef(p).pointertype.def.deftype=orddef) and
(torddef(tpointerdef(p).pointertype.def).typ=uvoid);
end;
{ true if p is a smallset def }
function is_smallset(p : tdef) : boolean;
begin
is_smallset:=(p.deftype=setdef) and
(tsetdef(p).settype=smallset);
end;
{ true, if def is a 32 bit int type }
function is_32bitint(def : tdef) : boolean;
begin
result:=(def.deftype=orddef) and (torddef(def).typ in [u32bit,s32bit])
end;
{ true, if def is a 64 bit int type }
function is_64bitint(def : tdef) : boolean;
begin
is_64bitint:=(def.deftype=orddef) and (torddef(def).typ in [u64bit,s64bit])
end;
{ true, if def is a 64 bit type }
function is_64bit(def : tdef) : boolean;
begin
is_64bit:=(def.deftype=orddef) and (torddef(def).typ in [u64bit,s64bit,scurrency])
end;
{ if l isn't in the range of def a range check error (if not explicit) is generated and
the value is placed within the range }
procedure testrange(def : tdef;var l : tconstexprint;explicit:boolean);
var
lv,hv: TConstExprInt;
error: boolean;
begin
error := false;
{ for 64 bit types we need only to check if it is less than }
{ zero, if def is a qword node }
if is_64bitint(def) then
begin
if (l<0) and (torddef(def).typ=u64bit) then
begin
{ don't zero the result, because it may come from hex notation
like $ffffffffffffffff! (JM)
l:=0; }
if not explicit then
begin
if (cs_check_range in aktlocalswitches) then
Message(parser_e_range_check_error)
else
Message(parser_w_range_check_error);
end;
error := true;
end;
end
else
begin
getrange(def,lv,hv);
if (l<lv) or (l>hv) then
begin
if not explicit then
begin
if ((def.deftype=enumdef) and
{ delphi allows range check errors in
enumeration type casts FK }
not(m_delphi in aktmodeswitches)) or
(cs_check_range in aktlocalswitches) then
Message(parser_e_range_check_error)
else
Message(parser_w_range_check_error);
end;
error := true;
end;
end;
if error then
begin
{ Fix the value to fit in the allocated space for this type of variable }
case longint(def.size) of
1: l := l and $ff;
2: l := l and $ffff;
{ work around sign extension bug (to be fixed) (JM) }
4: l := l and (int64($fffffff) shl 4 + $f);
end;
{ do sign extension if necessary (JM) }
if is_signed(def) then
begin
case longint(def.size) of
1: l := shortint(l);
2: l := smallint(l);
4: l := longint(l);
end;
end;
end;
end;
{ return the range from def in l and h }
procedure getrange(def : tdef;var l : TConstExprInt;var h : TConstExprInt);
begin
case def.deftype of
orddef :
begin
l:=torddef(def).low;
h:=torddef(def).high;
end;
enumdef :
begin
l:=tenumdef(def).min;
h:=tenumdef(def).max;
end;
arraydef :
begin
l:=tarraydef(def).lowrange;
h:=tarraydef(def).highrange;
end;
else
internalerror(987);
end;
end;
function mmx_type(p : tdef) : tmmxtype;
begin
mmx_type:=mmxno;
if is_mmx_able_array(p) then
begin
if tarraydef(p).elementtype.def.deftype=floatdef then
case tfloatdef(tarraydef(p).elementtype.def).typ of
s32real:
mmx_type:=mmxsingle;
end
else
case torddef(tarraydef(p).elementtype.def).typ of
u8bit:
mmx_type:=mmxu8bit;
s8bit:
mmx_type:=mmxs8bit;
u16bit:
mmx_type:=mmxu16bit;
s16bit:
mmx_type:=mmxs16bit;
u32bit:
mmx_type:=mmxu32bit;
s32bit:
mmx_type:=mmxs32bit;
end;
end;
end;
function is_mmx_able_array(p : tdef) : boolean;
begin
{$ifdef SUPPORT_MMX}
if (cs_mmx_saturation in aktlocalswitches) then
begin
is_mmx_able_array:=(p.deftype=arraydef) and
not(is_special_array(p)) and
(
(
(tarraydef(p).elementtype.def.deftype=orddef) and
(
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(torddef(tarraydef(p).elementtype.def).typ in [u32bit,s32bit])
)
or
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=3) and
(torddef(tarraydef(p).elementtype.def).typ in [u16bit,s16bit])
)
)
)
or
(
(
(tarraydef(p).elementtype.def.deftype=floatdef) and
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(tfloatdef(tarraydef(p).elementtype.def).typ=s32real)
)
)
)
);
end
else
begin
is_mmx_able_array:=(p.deftype=arraydef) and
(
(
(tarraydef(p).elementtype.def.deftype=orddef) and
(
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(torddef(tarraydef(p).elementtype.def).typ in [u32bit,s32bit])
)
or
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=3) and
(torddef(tarraydef(p).elementtype.def).typ in [u16bit,s16bit])
)
or
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=7) and
(torddef(tarraydef(p).elementtype.def).typ in [u8bit,s8bit])
)
)
)
or
(
(tarraydef(p).elementtype.def.deftype=floatdef) and
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(tfloatdef(tarraydef(p).elementtype.def).typ=s32real)
)
)
);
end;
{$else SUPPORT_MMX}
is_mmx_able_array:=false;
{$endif SUPPORT_MMX}
end;
function def_cgsize(def: tdef): tcgsize;
begin
case def.deftype of
orddef,
enumdef,
setdef:
begin
result:=int_cgsize(def.size);
if is_signed(def) then
result:=tcgsize(ord(result)+(ord(OS_S8)-ord(OS_8)));
end;
classrefdef,
pointerdef:
result := OS_ADDR;
procvardef:
begin
if tprocvardef(def).is_methodpointer and
(not tprocvardef(def).is_addressonly) then
result := OS_64
else
result := OS_ADDR;
end;
stringdef :
begin
if is_ansistring(def) or is_widestring(def) then
result := OS_ADDR
else
result:=int_cgsize(def.size);
end;
objectdef :
begin
if is_class_or_interface(def) then
result := OS_ADDR
else
result:=int_cgsize(def.size);
end;
floatdef:
if cs_fp_emulation in aktmoduleswitches then
result:=int_cgsize(def.size)
else
result:=tfloat2tcgsize[tfloatdef(def).typ];
recorddef :
result:=int_cgsize(def.size);
arraydef :
begin
if not is_special_array(def) then
result := int_cgsize(def.size)
else
begin
if is_dynamic_array(def) then
result := OS_ADDR
else
result := OS_NO;
end;
end;
else
begin
{ undefined size }
result:=OS_NO;
end;
end;
end;
end.
Reference in New Issue View Git Blame Copy Permalink