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f36e5411af
fpc/compiler/defutil.pas
Jonas Maebe f36e5411af * split cpu64bit compiler define into 
a) cpu64bitaddr, which means that we are generating a compiler which
       will generate code for targets with a 64 bit address space/abi
    b) cpu64bitalu, which means that we are generating a compiler which
       will generate code for a cpu with support for 64 bit integer
       operations (possibly running in a 32 bit address space, depending
       on the cpu64bitaddr define)
   All cpus which had cpu64bit set now have both the above defines set,
   and none of the 32 bit cpus have cpu64bitalu set (and none will
   compile with it currently)
  + pint and puint types, similar to aint/aword (not pword because that
    that conflicts with pword=^word)
  * several changes from aint/aword to pint/pword
  * some changes of tcgsize2size[OS_INT] to sizeof(pint)

git-svn-id: trunk@10320 -
2008-02-13 20:44:00 +00:00

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{
Copyright (c) 1998-2006 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,constexp,
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 the maximal integer value of the type }
function get_max_value(def : tdef) : TConstExprInt;
{# Returns basetype of the specified integer range }
function range_to_basetype(l,h:TConstExprInt):tordtype;
procedure range_to_type(l,h:TConstExprInt;var def:tdef);
procedure int_to_type(v:TConstExprInt;var def:tdef);
{# 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 Pascal-style boolean (1 = true, zero = false) }
function is_pasbool(def : tdef) : boolean;
{# Returns true if definition is a C-style boolean (non-zero value = true, zero = false) }
function is_cbool(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.
Bitpacked arrays aren't special in this regard though.
}
function is_special_array(p : tdef) : boolean;
{# Returns true if p is a bitpacked array }
function is_packed_array(p: tdef) : boolean;
{# Returns true if p is a bitpacked record }
function is_packed_record_or_object(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 todef a range check error (if not explicit) is generated and
the value is placed within the range
}
procedure testrange(todef : 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;out l, h : TConstExprInt);
{ type being a vector? }
function is_vector(p : tdef) : boolean;
{ 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;
{ returns if the passed type (array) fits into an mm register }
function fits_in_mm_register(p : tdef) : boolean;
{# 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;
{# returns true, if the type passed is can be used with windows automation }
function is_automatable(p : tdef) : boolean;
{# returns true, if the type passed is a varset }
function is_varset(p : tdef) : boolean;
{ # returns true if the procdef has no parameters and no specified return type }
function is_bareprocdef(pd : tprocdef): boolean;
implementation
uses
systems,verbose;
{ returns true, if def uses FPU }
function is_fpu(def : tdef) : boolean;
begin
is_fpu:=(def.typ=floatdef);
end;
{ returns true, if def is a currency type }
function is_currency(def : tdef) : boolean;
begin
case s64currencytype.typ of
orddef :
result:=(def.typ=orddef) and
(torddef(s64currencytype).ordtype=torddef(def).ordtype);
floatdef :
result:=(def.typ=floatdef) and
(tfloatdef(s64currencytype).floattype=tfloatdef(def).floattype);
else
internalerror(200304222);
end;
end;
{ returns true, if def is a single type }
function is_single(def : tdef) : boolean;
begin
result:=(def.typ=floatdef) and
(tfloatdef(def).floattype=s32real);
end;
{ returns true, if def is a double type }
function is_double(def : tdef) : boolean;
begin
result:=(def.typ=floatdef) and
(tfloatdef(def).floattype=s64real);
end;
function is_extended(def : tdef) : boolean;
begin
result:=(def.typ=floatdef) and
(tfloatdef(def).floattype=s80real);
end;
{ returns true, if definition is a "real" real (i.e. single/double/extended) }
function is_real(def : tdef) : boolean;
begin
result:=(def.typ=floatdef) and
(tfloatdef(def).floattype in [s32real,s64real,s80real]);
end;
function range_to_basetype(l,h:TConstExprInt):tordtype;
begin
{ prefer signed over unsigned }
if (l>=int64(-128)) and (h<=127) then
range_to_basetype:=s8bit
else if (l>=0) and (h<=255) then
range_to_basetype:=u8bit
else if (l>=int64(-32768)) and (h<=32767) then
range_to_basetype:=s16bit
else if (l>=0) and (h<=65535) then
range_to_basetype:=u16bit
else if (l>=int64(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 def:tdef);
begin
{ prefer signed over unsigned }
if (l>=int64(-128)) and (h<=127) then
def:=s8inttype
else if (l>=0) and (h<=255) then
def:=u8inttype
else if (l>=int64(-32768)) and (h<=32767) then
def:=s16inttype
else if (l>=0) and (h<=65535) then
def:=u16inttype
else if (l>=int64(low(longint))) and (h<=high(longint)) then
def:=s32inttype
else if (l>=low(cardinal)) and (h<=high(cardinal)) then
def:=u32inttype
else if (l>=low(int64)) and (h<=high(int64)) then
def:=s64inttype
else
def:=u64inttype;
end;
procedure int_to_type(v:TConstExprInt;var def:tdef);
begin
range_to_type(v,v,def);
end;
{ true if p is an ordinal }
function is_ordinal(def : tdef) : boolean;
var
dt : tordtype;
begin
case def.typ of
orddef :
begin
dt:=torddef(def).ordtype;
is_ordinal:=dt in [uchar,uwidechar,
u8bit,u16bit,u32bit,u64bit,
s8bit,s16bit,s32bit,s64bit,
pasbool,bool8bit,bool16bit,bool32bit,bool64bit];
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.typ of
orddef:
result:=torddef(def).low;
enumdef:
result:=int64(tenumdef(def).min);
else
result:=0;
end;
end;
{ returns the max. value of the type }
function get_max_value(def : tdef) : TConstExprInt;
begin
case def.typ of
orddef:
result:=torddef(def).high;
enumdef:
result:=tenumdef(def).max;
else
result:=0;
end;
end;
{ true if p is an integer }
function is_integer(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype in [u8bit,u16bit,u32bit,u64bit,
s8bit,s16bit,s32bit,s64bit]);
end;
{ true if p is a boolean }
function is_boolean(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype in [pasbool,bool8bit,bool16bit,bool32bit,bool64bit]);
end;
function is_pasbool(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype = pasbool);
end;
{ true if def is a C-style boolean (non-zero value = true, zero = false) }
function is_cbool(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype in [bool8bit,bool16bit,bool32bit,bool64bit]);
end;
{ true if p is a void }
function is_void(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype=uvoid);
end;
{ true if p is a char }
function is_char(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype=uchar);
end;
{ true if p is a wchar }
function is_widechar(def : tdef) : boolean;
begin
result:=(def.typ=orddef) and
(torddef(def).ordtype=uwidechar);
end;
{ true if p is signed (integer) }
function is_signed(def : tdef) : boolean;
begin
case def.typ of
orddef :
result:=torddef(def).low < 0;
enumdef :
result:=tenumdef(def).min < 0;
arraydef :
result:=is_signed(tarraydef(def).rangedef);
else
result:=false;
end;
end;
function is_in_limit(def_from,def_to : tdef) : boolean;
begin
if (def_from.typ<>def_to.typ) or
not(def_from.typ in [orddef,enumdef,setdef]) then
begin
is_in_limit := false;
exit;
end;
case def_from.typ of
orddef:
is_in_limit:=(torddef(def_from).low>=torddef(def_to).low) and
(torddef(def_from).high<=torddef(def_to).high);
enumdef:
is_in_limit:=(tenumdef(def_from).min>=tenumdef(def_to).min) and
(tenumdef(def_from).max<=tenumdef(def_to).max);
setdef:
is_in_limit:=(tsetdef(def_from).setbase>=tsetdef(def_to).setbase) and
(tsetdef(def_from).setmax<=tsetdef(def_to).setmax);
end;
end;
{ true, if p points to an open array def }
function is_open_string(p : tdef) : boolean;
begin
is_open_string:=(p.typ=stringdef) and
(tstringdef(p).stringtype=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
result:=(p.typ=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
result:=(p.typ=arraydef) and
(ado_IsDynamicArray in tarraydef(p).arrayoptions);
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) }
result:=(p.typ=arraydef) and
(tarraydef(p).rangedef=s32inttype) and
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=-1) and
((tarraydef(p).arrayoptions * [ado_IsVariant,ado_IsArrayOfConst,ado_IsConstructor,ado_IsDynamicArray])=[]);
end;
{ true, if p points to an array of const def }
function is_array_constructor(p : tdef) : boolean;
begin
result:=(p.typ=arraydef) and
(ado_IsConstructor in tarraydef(p).arrayoptions);
end;
{ true, if p points to a variant array }
function is_variant_array(p : tdef) : boolean;
begin
result:=(p.typ=arraydef) and
(ado_IsVariant in tarraydef(p).arrayoptions);
end;
{ true, if p points to an array of const }
function is_array_of_const(p : tdef) : boolean;
begin
result:=(p.typ=arraydef) and
(ado_IsArrayOfConst in tarraydef(p).arrayoptions);
end;
{ true, if p points to a special array, bitpacked arrays aren't special in this regard though }
function is_special_array(p : tdef) : boolean;
begin
result:=(p.typ=arraydef) and
(
((tarraydef(p).arrayoptions * [ado_IsVariant,ado_IsArrayOfConst,ado_IsConstructor,ado_IsDynamicArray])<>[]) or
is_open_array(p)
);
end;
{ true if p is an ansi string def }
function is_ansistring(p : tdef) : boolean;
begin
is_ansistring:=(p.typ=stringdef) and
(tstringdef(p).stringtype=st_ansistring);
end;
{ true if p is an long string def }
function is_longstring(p : tdef) : boolean;
begin
is_longstring:=(p.typ=stringdef) and
(tstringdef(p).stringtype=st_longstring);
end;
{ true if p is an wide string def }
function is_widestring(p : tdef) : boolean;
begin
is_widestring:=(p.typ=stringdef) and
(tstringdef(p).stringtype=st_widestring);
end;
{ true if p is an short string def }
function is_shortstring(p : tdef) : boolean;
begin
is_shortstring:=(p.typ=stringdef) and
(tstringdef(p).stringtype=st_shortstring);
end;
{ true if p is bit packed array def }
function is_packed_array(p: tdef) : boolean;
begin
is_packed_array :=
(p.typ = arraydef) and
(ado_IsBitPacked in tarraydef(p).arrayoptions);
end;
{ true if p is bit packed record def }
function is_packed_record_or_object(p: tdef) : boolean;
begin
is_packed_record_or_object :=
(p.typ in [recorddef,objectdef]) and
(tabstractrecorddef(p).is_packed);
end;
{ true if p is a char array def }
function is_chararray(p : tdef) : boolean;
begin
is_chararray:=(p.typ=arraydef) and
is_char(tarraydef(p).elementdef) 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.typ=arraydef) and
is_widechar(tarraydef(p).elementdef) 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).elementdef);
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).elementdef);
end;
{ true if p is a pchar def }
function is_pchar(p : tdef) : boolean;
begin
is_pchar:=(p.typ=pointerdef) and
(is_char(tpointerdef(p).pointeddef) or
(is_zero_based_array(tpointerdef(p).pointeddef) and
is_chararray(tpointerdef(p).pointeddef)));
end;
{ true if p is a pchar def }
function is_pwidechar(p : tdef) : boolean;
begin
is_pwidechar:=(p.typ=pointerdef) and
(is_widechar(tpointerdef(p).pointeddef) or
(is_zero_based_array(tpointerdef(p).pointeddef) and
is_widechararray(tpointerdef(p).pointeddef)));
end;
{ true if p is a voidpointer def }
function is_voidpointer(p : tdef) : boolean;
begin
is_voidpointer:=(p.typ=pointerdef) and
(tpointerdef(p).pointeddef.typ=orddef) and
(torddef(tpointerdef(p).pointeddef).ordtype=uvoid);
end;
{ true if p is a smallset def }
function is_smallset(p : tdef) : boolean;
begin
is_smallset:=(p.typ=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.typ=orddef) and (torddef(def).ordtype in [u32bit,s32bit])
end;
{ true, if def is a 64 bit int type }
function is_64bitint(def : tdef) : boolean;
begin
is_64bitint:=(def.typ=orddef) and (torddef(def).ordtype in [u64bit,s64bit])
end;
{ true, if def is a 64 bit type }
function is_64bit(def : tdef) : boolean;
begin
is_64bit:=(def.typ=orddef) and (torddef(def).ordtype in [u64bit,s64bit,scurrency])
end;
{ if l isn't in the range of todef a range check error (if not explicit) is generated and
the value is placed within the range }
procedure testrange(todef : tdef;var l : tconstexprint;explicit:boolean);
var
lv,hv: TConstExprInt;
begin
{ for 64 bit types we need only to check if it is less than }
{ zero, if def is a qword node }
getrange(todef,lv,hv);
if (l<lv) or (l>hv) then
begin
if not explicit then
begin
if ((todef.typ=enumdef) and
{ delphi allows range check errors in
enumeration type casts FK }
not(m_delphi in current_settings.modeswitches)) or
(cs_check_range in current_settings.localswitches) then
Message(parser_e_range_check_error)
else
Message(parser_w_range_check_error);
end;
{ Fix the value to fit in the allocated space for this type of variable }
case longint(todef.size) of
1: l := l and $ff;
2: l := l and $ffff;
4: l := l and $ffffffff;
end;
{reset sign, i.e. converting -1 to qword changes the value to high(qword)}
l.signed:=false;
{ do sign extension if necessary (JM) }
if is_signed(todef) then
begin
case longint(todef.size) of
1: l.svalue := shortint(l.svalue);
2: l.svalue := smallint(l.svalue);
4: l.svalue := longint(l.svalue);
end;
l.signed:=true;
end;
end;
end;
{ return the range from def in l and h }
procedure getrange(def : tdef;out l, h : TConstExprInt);
begin
case def.typ of
orddef :
begin
l:=torddef(def).low;
h:=torddef(def).high;
end;
enumdef :
begin
l:=int64(tenumdef(def).min);
h:=int64(tenumdef(def).max);
end;
arraydef :
begin
l:=int64(tarraydef(def).lowrange);
h:=int64(tarraydef(def).highrange);
end;
else
internalerror(200611054);
end;
end;
function mmx_type(p : tdef) : tmmxtype;
begin
mmx_type:=mmxno;
if is_mmx_able_array(p) then
begin
if tarraydef(p).elementdef.typ=floatdef then
case tfloatdef(tarraydef(p).elementdef).floattype of
s32real:
mmx_type:=mmxsingle;
end
else
case torddef(tarraydef(p).elementdef).ordtype of
u8bit:
mmx_type:=mmxu8bit;
s8bit:
mmx_type:=mmxs8bit;
u16bit:
mmx_type:=mmxu16bit;
s16bit:
mmx_type:=mmxs16bit;
u32bit:
mmx_type:=mmxu32bit;
s32bit:
mmx_type:=mmxs32bit;
end;
end;
end;
function is_vector(p : tdef) : boolean;
begin
result:=(p.typ=arraydef) and
not(is_special_array(p)) and
(tarraydef(p).elementdef.typ=floatdef) and
(tfloatdef(tarraydef(p).elementdef).floattype in [s32real,s64real]);
end;
{ returns if the passed type (array) fits into an mm register }
function fits_in_mm_register(p : tdef) : boolean;
begin
{$ifdef x86}
result:= is_vector(p) and
(
(tarraydef(p).elementdef.typ=floatdef) and
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=3) and
(tfloatdef(tarraydef(p).elementdef).floattype=s32real)
)
) or
(
(tarraydef(p).elementdef.typ=floatdef) and
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(tfloatdef(tarraydef(p).elementdef).floattype=s64real)
)
);
{$else x86}
result:=false;
{$endif x86}
end;
function is_mmx_able_array(p : tdef) : boolean;
begin
{$ifdef SUPPORT_MMX}
if (cs_mmx_saturation in current_settings.localswitches) then
begin
is_mmx_able_array:=(p.typ=arraydef) and
not(is_special_array(p)) and
(
(
(tarraydef(p).elementdef.typ=orddef) and
(
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(torddef(tarraydef(p).elementdef).ordtype in [u32bit,s32bit])
)
or
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=3) and
(torddef(tarraydef(p).elementdef).ordtype in [u16bit,s16bit])
)
)
)
or
(
(
(tarraydef(p).elementdef.typ=floatdef) and
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(tfloatdef(tarraydef(p).elementdef).floattype=s32real)
)
)
)
);
end
else
begin
is_mmx_able_array:=(p.typ=arraydef) and
(
(
(tarraydef(p).elementdef.typ=orddef) and
(
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(torddef(tarraydef(p).elementdef).ordtype in [u32bit,s32bit])
)
or
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=3) and
(torddef(tarraydef(p).elementdef).ordtype in [u16bit,s16bit])
)
or
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=7) and
(torddef(tarraydef(p).elementdef).ordtype in [u8bit,s8bit])
)
)
)
or
(
(tarraydef(p).elementdef.typ=floatdef) and
(
(tarraydef(p).lowrange=0) and
(tarraydef(p).highrange=1) and
(tfloatdef(tarraydef(p).elementdef).floattype=s32real)
)
)
);
end;
{$else SUPPORT_MMX}
is_mmx_able_array:=false;
{$endif SUPPORT_MMX}
end;
function def_cgsize(def: tdef): tcgsize;
begin
case def.typ 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
if (sizeof(pint) = 4) then
result:=OS_64
else if (sizeof(pint) = 8) then
result:=OS_128
else
internalerror(200707141)
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 current_settings.moduleswitches then
result:=int_cgsize(def.size)
else
result:=tfloat2tcgsize[tfloatdef(def).floattype];
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;
function is_automatable(p : tdef) : boolean;
begin
result:=false;
case p.typ of
orddef:
result:=torddef(p).ordtype in [u8bit,s32bit,s16bit,bool16bit];
floatdef:
result:=tfloatdef(p).floattype in [s64currency,s64real,s32real];
stringdef:
result:=tstringdef(p).stringtype in [st_ansistring,st_widestring];
variantdef:
result:=true;
arraydef:
result:=(ado_IsConstString in tarraydef(p).arrayoptions);
objectdef:
result:=tobjectdef(p).objecttype in [odt_interfacecom,odt_dispinterface,odt_interfacecorba];
end;
end;
{# returns true, if the type passed is a varset }
function is_varset(p : tdef) : boolean;
begin
result:=(p.typ=setdef) and not(p.size in [1,2,4])
end;
function is_bareprocdef(pd : tprocdef): boolean;
begin
result:=(pd.maxparacount=0) and
(is_void(pd.returndef) or
(pd.proctypeoption = potype_constructor));
end;
end.
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