{ This file is part of the Free Pascal run time library. Copyright (c) 1999-2000 by the Free Pascal development team. Processor independent implementation for the system unit (adapted for intel i386.inc file) See the file COPYING.FPC, included in this distribution, for details about the copyright. 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. **********************************************************************} function align(addr : PtrUInt;alignment : PtrUInt) : PtrUInt;{$ifdef SYSTEMINLINE}inline;{$endif} var tmp,am1 : PtrUInt; begin am1:=alignment-1; tmp:=addr+am1; if alignment and am1=0 then { Alignment is a power of two. In practice alignments are powers of two 100% of the time. } result:=tmp and not am1 else result:=tmp-(tmp mod alignment); end; {$ifndef cpujvm} function align(addr : Pointer;alignment : PtrUInt) : Pointer;{$ifdef SYSTEMINLINE}inline;{$endif} var tmp,am1 : PtrUInt; begin am1:=alignment-1; tmp:=PtrUint(addr)+am1; if alignment and am1=0 then result:=pointer(tmp and not am1) else result:=pointer(ptruint(tmp-(tmp mod alignment))); end; {$endif} {**************************************************************************** Primitives ****************************************************************************} type pstring = ^shortstring; {$ifndef FPC_HAS_SHORTSTR_SHORTSTR_INTERN_CHARMOVE} {$define FPC_HAS_SHORTSTR_SHORTSTR_INTERN_CHARMOVE} procedure fpc_shortstr_shortstr_intern_charmove(const src: shortstring; const srcindex: byte; var dst: shortstring; const dstindex, len: byte); {$ifdef SYSTEMINLINE}inline;{$endif} begin move(src[srcindex],dst[dstindex],len); end; {$endif FPC_HAS_SHORTSTR_SHORTSTR_INTERN_CHARMOVE} {$ifndef FPC_HAS_SHORTSTR_CHARARRAY_INTERN_CHARMOVE} {$define FPC_HAS_SHORTSTR_CHARARRAY_INTERN_CHARMOVE} procedure fpc_shortstr_chararray_intern_charmove(const src: shortstring; out dst: array of ansichar; const len: sizeint); begin move(src[1],PAnsiChar(@dst)^,len); end; {$endif FPC_HAS_SHORTSTR_CHARARRAY_INTERN_CHARMOVE} {$ifndef FPC_SYSTEM_HAS_MOVE} procedure Move(const source;var dest;count:SizeInt);[public, alias: 'FPC_MOVE']; var aligncount : sizeint; pdest,psrc,pend : pbyte; begin if (@dest=@source) or (count<=0) then exit; if (@dest<@source) or (@source+count<@dest) then begin { Forward Move } psrc:=@source; pdest:=@dest; if (Count>4*sizeof(ptruint)-11) {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} and ((PtrUInt(pdest) and (sizeof(PtrUInt)-1))=(PtrUInt(psrc) and (sizeof(PtrUInt)-1))) {$endif FPC_REQUIRES_PROPER_ALIGNMENT} then begin { Align on native pointer size } aligncount:=(sizeof(PtrUInt)-PtrInt(pdest)) and (sizeof(PtrUInt)-1); dec(count,aligncount); pend:=psrc+aligncount; while psrc4*sizeof(ptruint)-11) {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} and ((PtrUInt(pdest) and (sizeof(PtrUInt)-1))=(PtrUInt(psrc) and (sizeof(PtrUInt)-1))) {$endif FPC_REQUIRES_PROPER_ALIGNMENT} then begin { Align on native pointer size } aligncount:=(PtrUInt(pdest) and (sizeof(PtrUInt)-1)); dec(count,aligncount); pend:=psrc-aligncount; while psrc>pend do begin dec(pdest); dec(psrc); pdest^:=psrc^; end; { use sizeuint typecast to force shr optimization } pptruint(pend):=pptruint(psrc)-(sizeuint(count) div sizeof(ptruint)); while psrc>pend do begin dec(pptruint(pdest)); dec(pptruint(psrc)); pptruint(pdest)^:=pptruint(psrc)^; end; count:=count and (sizeof(PtrUInt)-1); end; pend:=psrc-count; while psrc>pend do begin dec(pdest); dec(psrc); pdest^:=psrc^; end; end; end; {$endif not FPC_SYSTEM_HAS_MOVE} {$ifndef FPC_SYSTEM_HAS_FILLCHAR} Procedure FillChar(var x;count:SizeInt;value:byte); var pdest,pend : pbyte; v : ALUUInt; begin if count <= 0 then exit; pdest:=@x; if Count>4*sizeof(ptruint)-1 then begin {$if sizeof(v)>=2} v:=(value shl 8) or value; {$endif sizeof(v)>=2} {$if sizeof(v)>=4} v:=(v shl 16) or v; {$endif sizeof(v)>=4} {$if sizeof(v)=8} v:=(v shl 32) or v; {$endif sizeof(v)=8} { Align on native pointer size } pend:=pbyte(align(pdest,sizeof(PtrUInt))); dec(count,pend-pdest); while pdest4*sizeof(ptruint)-1 then begin {$if sizeof(v)>=4} v:=(value shl 16) or value; {$endif sizeof(v)>=4} {$if sizeof(v)=8} v:=(v shl 32) or v; {$endif sizeof(v)=8} { Align on native pointer size } aligncount:=(PtrUInt(pdest) and (sizeof(PtrUInt)-1)) shr 1; dec(count,aligncount); pend:=pdest+aligncount; while pdest4*sizeof(ptruint)-1 then begin v:=value; {$if sizeof(v)=8} v:=(v shl 32) or v; {$endif sizeof(v)=8} { Align on native pointer size } aligncount:=(PtrUInt(pdest) and (sizeof(PtrUInt)-1)) shr 2; dec(count,aligncount); pend:=pdest+aligncount; while pdestb) do inc(psrc); if psrc= 0) and { is this ever false? } (len <= high(PtrInt))) or (pend < psrc) then pend:=pword(high(PtrUInt)-PtrUint(sizeof(word))); {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} if (ptruint(psrc) mod 2)<>0 then while (psrcb) do inc(psrc) else {$endif FPC_REQUIRES_PROPER_ALIGNMENT} while (psrcb) do inc(psrc); if psrc=0 so avoid handling of negative values } result:=PtrUint(pointer(psrc)-pointer(@buf)) div sizeof(word) else result:=-1; end; {$endif not FPC_SYSTEM_HAS_INDEXWORD} {$ifndef FPC_SYSTEM_HAS_INDEXDWORD} function IndexDWord(Const buf;len:SizeInt;b:DWord):SizeInt; var psrc,pend : pdword; begin psrc:=@buf; pend:=psrc+len; { simulate assembler implementations behaviour, which is expected } { fpc_pchar_to_ansistr in astrings.inc } if not ( (len >= 0) and (len <= high(PtrInt) div 2)) or (pend < psrc) then pend:=pdword(high(PtrUInt)-PtrUInt(sizeof(dword))); {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} if (ptruint(psrc) mod 4)<>0 then while (psrcb) do inc(psrc) else {$endif FPC_REQUIRES_PROPER_ALIGNMENT} while (psrcb) do inc(psrc); if psrc=0 so avoid handling of negative values } result:=PtrUint(pointer(psrc)-pointer(@buf)) div sizeof(DWord) else result:=-1; end; {$endif not FPC_SYSTEM_HAS_INDEXDWORD} {$ifndef FPC_SYSTEM_HAS_INDEXQWORD} function IndexQWord(Const buf;len:SizeInt;b:QWord):SizeInt; var psrc,pend : pqword; begin psrc:=@buf; pend:=psrc+len; { simulate assembler implementations behaviour, which is expected } { fpc_pchar_to_ansistr in astrings.inc } if not ( (len >= 0) and (len <= high(PtrInt) div 4)) or (pend < psrc) then pend:=pqword(high(PtrUInt)-PtrUInt(sizeof(qword))); {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} if (ptruint(psrc) mod 8)<>0 then while (psrcb) do inc(psrc) else {$endif FPC_REQUIRES_PROPER_ALIGNMENT} while (psrcb) do inc(psrc); if psrc=0 so avoid handling of negative values } result:=PtrUint(pointer(psrc)-pointer(@buf)) div sizeof(QWord) else result:=-1; end; {$endif not FPC_SYSTEM_HAS_INDEXQWORD} {$ifndef FPC_SYSTEM_HAS_COMPAREBYTE} function CompareByte(Const buf1,buf2;len:SizeInt):SizeInt; var psrc,pdest,pend,pendpart : pbyte; begin psrc:=@buf1; pdest:=@buf2; pend:=psrc+len; if (pend=2*sizeof(ptruint)) {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} and ((PtrUInt(pdest) and (sizeof(PtrUInt)-1))=(PtrUInt(psrc) and (sizeof(PtrUInt)-1))) {$endif FPC_REQUIRES_PROPER_ALIGNMENT} then begin { Align "psrc" on native pointer size. } PtrUint(pendpart):=PtrUint(psrc+(sizeof(PtrUint)-1)) and PtrUint(not PtrUint(sizeof(PtrUint)-1)); if psrc=0) and (len<=High(PtrInt) div 2)) then pend:=pword(high(ptruint)-2); if (len>=2*sizeof(ptruint)) { len in words, so at least four pointers } {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} and ((PtrUInt(pdest) xor PtrUInt(psrc)) and (sizeof(PtrUInt)-1)=0) and (PtrUInt(psrc) and 1=0) {$endif FPC_REQUIRES_PROPER_ALIGNMENT} then begin { Align on native pointer size. Careful, these 'pendpart's are aligned even if 'psrc' is misaligned, so "psrc<>pendpart" must not be used. } PtrUint(pendpart):=(PtrUint(psrc)+(sizeof(PtrUint)-1)) and PtrUint(not PtrUint(sizeof(PtrUint)-1)); while (psrcpdest^)-1); PtrUint(pendpart):=PtrUint(pend) and PtrUint(not PtrUint(sizeof(PtrUint)-1)); while (psrc0 then begin while (psrcunaligned(pdest^))-1); end else {$endif FPC_REQUIRES_PROPER_ALIGNMENT} begin while (psrcpdest^)-1); end; result:=0; end; {$endif not FPC_SYSTEM_HAS_COMPAREWORD} {$ifndef FPC_SYSTEM_HAS_COMPAREDWORD} function CompareDWord(Const buf1,buf2;len:SizeInt):SizeInt; var psrc,pdest,pend,pendpart : pdword; begin psrc:=@buf1; pdest:=@buf2; pend:=psrc+len; if (pend=0) and (len<=High(PtrInt) div 4)) then pend:=pdword(high(ptruint)-4); {$if sizeof(ptruint)>sizeof(dword)} if (len>=sizeof(ptruint)) { len in uint32s, so at least four pointers } {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} and ((PtrUInt(pdest) xor PtrUInt(psrc)) and (sizeof(PtrUInt)-1)=0) and (PtrUInt(psrc) and 3=0) {$endif FPC_REQUIRES_PROPER_ALIGNMENT} then begin { Align on native pointer size. Careful, these 'pendpart's are aligned even if 'psrc' is misaligned, so "psrc<>pendpart" must not be used. } PtrUint(pendpart):=(PtrUint(psrc)+(sizeof(PtrUint)-1)) and PtrUint(not PtrUint(sizeof(PtrUint)-1)); while (psrcpdest^)-1); PtrUint(pendpart):=PtrUint(pend) and PtrUint(not PtrUint(sizeof(PtrUint)-1)); while (psrcsizeof(dword)} {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} if (PtrUInt(pdest) or PtrUInt(psrc)) and 3<>0 then begin while (psrcunaligned(pdest^))-1); end else {$endif FPC_REQUIRES_PROPER_ALIGNMENT} begin while (psrcpdest^)-1); end; result:=0; end; {$endif ndef FPC_SYSTEM_HAS_COMPAREDWORD} {$ifndef FPC_SYSTEM_HAS_MOVECHAR0} procedure MoveChar0(Const buf1;var buf2;len:SizeInt); var I : SizeInt; begin if Len = 0 then exit; I:=IndexByte(Buf1,Len,0); if I<>-1 then Move(Buf1,Buf2,I) else Move(Buf1,Buf2,len); end; {$endif ndef FPC_SYSTEM_HAS_MOVECHAR0} {$ifndef FPC_SYSTEM_HAS_INDEXCHAR0} function IndexChar0(Const buf;len:SizeInt;b:AnsiChar):SizeInt; var psrc,pend : pbyte; begin psrc:=@buf; { simulate assembler implementations behaviour, which is expected } { fpc_pchar_to_ansistr in astrings.inc } if (len < 0) then pend:=pbyte(high(PtrUInt)-PtrUInt(sizeof(byte))) else pend:=psrc+len; while (psrc0) do begin if (psrc^=byte(b)) then begin result:=psrc-pbyte(@buf); exit; end; inc(psrc); end; result:=-1; end; {$endif ndef FPC_SYSTEM_HAS_INDEXCHAR0} {$ifndef FPC_SYSTEM_HAS_COMPARECHAR0} function CompareChar0(Const buf1,buf2;len:SizeInt):SizeInt; var psrc,pdest,pend : pbyte; b : ptrint; begin b:=0; psrc:=@buf1; pdest:=@buf2; pend:=psrc+len; while psrc0 then exit(1); if (psrc^=0) or (pdest^=0) then exit(0); inc(pdest); inc(psrc); end; result:=0; end; {$endif not FPC_SYSTEM_HAS_COMPARECHAR0} {**************************************************************************** Object Helpers ****************************************************************************} {$ifdef FPC_HAS_FEATURE_OBJECTS} type pobjectvmt=^tobjectvmt; tobjectvmt=record size,msize:sizeuint; parent:{$ifdef VER3_0}pointer{$else}ppointer{$endif}; end; {$ifndef FPC_SYSTEM_HAS_FPC_HELP_CONSTRUCTOR} { Note: _vmt will be reset to -1 when memory is allocated, this is needed for fpc_help_fail } function fpc_help_constructor(_self:pointer;var _vmt:pointer;_vmt_pos:cardinal):pointer;[public,alias:'FPC_HELP_CONSTRUCTOR'];compilerproc; var vmtcopy : pobjectvmt; begin vmtcopy:=pobjectvmt(_vmt); { Inherited call? } if vmtcopy=nil then begin fpc_help_constructor:=_self; exit; end; if (_self=nil) and (vmtcopy^.size>0) then begin getmem(_self,vmtcopy^.size); { reset vmt needed for fail } _vmt:=pointer(-1); end; if _self<>nil then begin fillchar(_self^,vmtcopy^.size,0); ppointer(_self+_vmt_pos)^:=vmtcopy; end; fpc_help_constructor:=_self; end; {$endif FPC_SYSTEM_HAS_FPC_HELP_CONSTRUCTOR} {$ifndef FPC_SYSTEM_HAS_FPC_HELP_DESTRUCTOR} { Note: _self will not be reset, the compiler has to generate the reset } procedure fpc_help_destructor(_self,_vmt:pointer;vmt_pos:cardinal);[public,alias:'FPC_HELP_DESTRUCTOR']; compilerproc; begin { already released? } if (_self=nil) or (_vmt<>pointer(-1)) or (ppointer(_self+vmt_pos)^=nil) then exit; if (pobjectvmt(ppointer(_self+vmt_pos)^)^.size=0) or (pobjectvmt(ppointer(_self+vmt_pos)^)^.size+pobjectvmt(ppointer(_self+vmt_pos)^)^.msize<>0) then HandleErrorAddrFrameInd(210,get_pc_addr,get_frame); { reset vmt to nil for protection } ppointer(_self+vmt_pos)^:=nil; freemem(_self); end; {$endif FPC_SYSTEM_HAS_FPC_HELP_DESTRUCTOR} {$ifndef FPC_SYSTEM_HAS_FPC_HELP_FAIL} { Note: _self will not be reset, the compiler has to generate the reset } procedure fpc_help_fail(_self:pointer;var _vmt:pointer;vmt_pos:cardinal);[public,alias:'FPC_HELP_FAIL'];compilerproc; begin if (_self=nil) or (_vmt=nil) then exit; { vmt=$ffffffff when memory was allocated } if ptruint(_vmt)=high(ptruint) then begin if (_self=nil) or (ppointer(_self+vmt_pos)^=nil) then HandleError(210) else begin ppointer(_self+vmt_pos)^:=nil; freemem(_self); { reset _vmt to nil so it will not be freed a second time } _vmt:=nil; end; end else ppointer(_self+vmt_pos)^:=nil; end; {$endif FPC_SYSTEM_HAS_FPC_HELP_FAIL} {$ifndef FPC_SYSTEM_HAS_FPC_CHECK_OBJECT} procedure fpc_check_object(_vmt : pointer); [public,alias:'FPC_CHECK_OBJECT']; compilerproc; begin if (_vmt=nil) or (pobjectvmt(_vmt)^.size=0) or (pobjectvmt(_vmt)^.size+pobjectvmt(_vmt)^.msize<>0) then HandleErrorAddrFrameInd(210,get_pc_addr,get_frame); end; {$endif ndef FPC_SYSTEM_HAS_FPC_CHECK_OBJECT} {$ifndef FPC_SYSTEM_HAS_FPC_CHECK_OBJECT_EXT} { checks for a correct vmt pointer } { deeper check to see if the current object is } { really related to the true } procedure fpc_check_object_ext(vmt, expvmt : pointer); [public,alias:'FPC_CHECK_OBJECT_EXT']; compilerproc; begin if (vmt=nil) or (pobjectvmt(vmt)^.size=0) or (pobjectvmt(vmt)^.size+pobjectvmt(vmt)^.msize<>0) then HandleErrorAddrFrameInd(210,get_pc_addr,get_frame); while assigned(vmt) do if vmt=expvmt then exit else {$ifdef VER3_0} vmt:=pobjectvmt(vmt)^.parent; {$else VER3_0} if assigned(pobjectvmt(vmt)^.parent) then vmt:=pobjectvmt(vmt)^.parent^ else vmt:=nil; {$endif} HandleErrorAddrFrameInd(219,get_pc_addr,get_frame); end; {$endif not FPC_SYSTEM_HAS_FPC_CHECK_OBJECT_EXT} {$endif FPC_HAS_FEATURE_OBJECTS} {**************************************************************************** String ****************************************************************************} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_ASSIGN} procedure fpc_shortstr_to_shortstr(out res:shortstring; const sstr: shortstring);[public,alias:'FPC_SHORTSTR_TO_SHORTSTR']; compilerproc; var slen : byte; begin slen:=length(sstr); if slen>high(res) then slen:=high(res); move(sstr[0],res[0],slen+1); res[0]:=chr(slen); end; procedure fpc_shortstr_assign(len:{$ifdef cpu16}smallint{$else}longint{$endif};sstr,dstr:pointer);[public,alias:'FPC_SHORTSTR_ASSIGN']; compilerproc; var slen : byte; begin slen:=length(pshortstring(sstr)^); if slenlen then PAnsiChar(dstr)^:=chr(len); end; {$endif ndef FPC_SYSTEM_HAS_FPC_SHORTSTR_ASSIGN} {$push} { ensure that comparing addresses of openshortstrings with regular shortstrings doesn't cause errors } {$t-} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_CONCAT} procedure fpc_shortstr_concat(var dests:shortstring;const s1,s2:shortstring);compilerproc; var s1l, s2l : ObjpasInt; begin s1l:=length(s1); s2l:=length(s2); if s1l+s2l>high(dests) then begin if s1l>high(dests) then s1l:=high(dests); s2l:=high(dests)-s1l; end; { Copy s2 first, as in the case of @dests = @s2 it must be copied first and in other cases the order does not matter. } fpc_shortstr_shortstr_intern_charmove(s2,1,dests,s1l+1,s2l); if @dests<>@s1 then fpc_shortstr_shortstr_intern_charmove(s1,1,dests,1,s1l); dests[0]:=chr(s1l+s2l); end; {$endif ndef FPC_SYSTEM_HAS_FPC_SHORTSTR_CONCAT} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_CONCAT_MULTI} procedure fpc_shortstr_concat_multi(var dests:shortstring;const sarr:array of pshortstring);compilerproc; var i,s2l,Len,destpos0 : ObjpasInt; p : pshortstring; begin Len:=0; i:=0; while (i<=high(sarr)) do begin p:=sarr[i]; if assigned(p) then inc(Len,length(p^)); inc(i); end; destpos0:=Len; { Copy strings from the last to the first, so that possible occurences of DestS read correct DestS. DestS[0] = length(DestS) must have its original value for a while! } while (destpos0>0) do begin dec(i); p:=sarr[i]; if not assigned(p) then continue; s2l:=length(p^); dec(destpos0,s2l); if (destpos0=0) and (p=@dests) then { Skip moving DestS to itself when appending. This destpos0-based form also catches DestS := '' + '' + DestS. } break; if destpos0+s2l>high(dests) then begin if destpos0>=high(dests) then continue; s2l:=high(dests)-destpos0; end; fpc_shortstr_shortstr_intern_charmove(p^,1,dests,destpos0+1,s2l); end; if Len>high(dests) then Len:=high(dests); dests[0]:=Chr(Len); { Careful, loop above relies on DestS[0] having the original value. } end; {$endif ndef FPC_SYSTEM_HAS_FPC_SHORTSTR_CONCAT_MULTI} {$pop} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_APPEND_SHORTSTR} procedure fpc_shortstr_append_shortstr(var s1:shortstring;const s2:shortstring);compilerproc; [public,alias:'FPC_SHORTSTR_APPEND_SHORTSTR']; var s1l, s2l : sizeint; begin s1l:=length(s1); s2l:=length(s2); if s1l+s2l>high(s1) then s2l:=high(s1)-s1l; move(s2[1],s1[s1l+1],s2l); s1[0]:=chr(s1l+s2l); end; {$endif ndef FPC_SYSTEM_HAS_FPC_SHORTSTR_APPEND_SHORTSTR} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_COMPARE} function fpc_shortstr_compare(const left,right:shortstring) : longint;[public,alias:'FPC_SHORTSTR_COMPARE']; compilerproc; var s1,s2,max : byte; begin s1:=length(left); s2:=length(right); if s10)-ord(result<0); end; {$endif ndef FPC_SYSTEM_HAS_FPC_SHORTSTR_COMPARE} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_COMPARE_EQUAL} function fpc_shortstr_compare_equal(const left,right:shortstring): longint; [public,alias:'FPC_SHORTSTR_COMPARE_EQUAL']; compilerproc; begin Result := ObjpasInt(left[0]) - ObjpasInt(right[0]); if Result = 0 then Result := CompareByte(left[1],right[1], ObjpasInt(left[0])); end; {$endif ndef FPC_SYSTEM_HAS_FPC_SHORTSTR_COMPARE_EQUAL} {$ifndef FPC_SYSTEM_HAS_FPC_PCHAR_TO_SHORTSTR} procedure fpc_pchar_to_shortstr(out res : shortstring;p:PAnsiChar);[public,alias:'FPC_PCHAR_TO_SHORTSTR']; compilerproc; var l : ObjpasInt; begin if p=nil then begin res[0]:=#0; exit; end; { On platforms where IndexByte with len > 0 will not read the invalid memory past the null terminator, high(res) can be used as a limit. } {$if defined(cpui386) or defined(cpux86_64)} l:=IndexByte(p^,high(res),0); if l<0 then l:=high(res); {$else IndexByte(p^,high(res),0) can crash} l:=strlen(p); if l>high(res) then l:=high(res); {$endif IndexByte(p^,high(res),0) can crash} move(p^,res[1],l); res[0]:=chr(l); end; {$endif ndef FPC_SYSTEM_HAS_FPC_PCHAR_TO_SHORTSTR} {$ifndef cpujvm} { also define alias which can be used inside the system unit } procedure fpc_pchar_to_shortstr(out res : shortstring;p:PAnsiChar);[external name 'FPC_PCHAR_TO_SHORTSTR']; function strpas(p:PAnsiChar):shortstring;{$ifdef SYSTEMINLINE}inline;{$endif} begin fpc_pchar_to_shortstr(result,p); end; {$endif not cpujvm} { Combining codepoints are those belonging to one of the three "Mark" general categories. UnicodeData.txt column 3 has M* for them: Mn, Mc, Me. Using the table below, codepoint %...XXXXXXXX_YYYY_ZZZZZ can be classified as combining or not with a 3-level lookup: if %...XXXXXXXX <= High(IsCombinings.L2) then begin index := IsCombinings.L2[%XXXXXXXX]; index := IsCombinings.L1[index][%YYYY]; IsCombining := boolean(IsCombinings.L0[index] shr %ZZZZZ and 1); end else IsCombining := false; Equivalent one-liner: IsCombining := (%...XXXXXXXX <= High(IsCombinings.L2)) and (IsCombinings.L0[IsCombinings.L1[IsCombinings.L2[%XXXXXXXX]][%YYYY]] shr %ZZZZZ and 1 <> 0); Additionally, there is a combining range U+E0100..U+E01EF far to the right, not included into the table to save 1 level. Table built from UnicodeData.txt 15.0.0 (September 2022). } const IsCombinings: record L2: array[0 .. 244] of uint8; L1: array[0 .. 46, 0 .. 15] of uint8; L0: array[0 .. 161] of uint32; end = ( L2: ( 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, {10} 0, 10, 11, 12, 13, 0, 14, 0, 0, 0, {20} 0, 0, 15, 0, 16, 0, 0, 0, 0, 0, {30} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {40} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {50} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {60} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {70} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {80} 0, 0, 0, 17, 18, 19, 0, 0, 0, 0, {90} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {100} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {110} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {120} 0, 0, 0, 0, 0, 20, 0, 21, 22, 23, {130} 0, 0, 0, 24, 25, 26, 27, 28, 29, 30, {140} 31, 32, 33, 34, 0, 0, 0, 0, 0, 0, {150} 0, 0, 0, 0, 35, 0, 0, 0, 0, 0, {160} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {170} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {180} 0, 36, 0, 37, 0, 0, 0, 0, 0, 0, {190} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {200} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {210} 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, {220} 0, 0, 38, 0, 0, 0, 0, 0, 0, 0, {230} 0, 39, 40, 41, 0, 0, 0, 42, 0, 0, {240} 43, 44, 45, 0, 46 ); L1: ( {0} (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 2, 0, 0, 0, 0), {2} (0, 0, 0, 0, 3, 0, 0, 0, 0, 0, 0, 0, 4, 5, 6, 0), (7, 0, 8, 9, 0, 0, 10, 11, 12, 13, 14, 0, 0, 15, 0, 16), {4} (17, 18, 19, 0, 20, 0, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30), (27, 28, 31, 32, 27, 28, 33, 34, 27, 28, 35, 26, 36, 37, 38, 0), {6} (39, 28, 40, 26, 27, 28, 40, 41, 23, 42, 43, 26, 27, 0, 44, 45), (0, 46, 47, 0, 0, 48, 49, 0, 50, 51, 0, 4, 52, 53, 54, 0), {8} (0, 55, 56, 57, 58, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 59, 0, 0, 0, 0, 0), {10} (0, 0, 0, 0, 0, 0, 0, 0, 60, 61, 45, 45, 0, 62, 63, 0), (64, 0, 0, 0, 65, 66, 0, 0, 0, 67, 0, 0, 0, 0, 0, 0), {12} (68, 0, 69, 70, 0, 13, 1, 1, 39, 62, 39, 71, 72, 73, 0, 74), (0, 75, 0, 0, 0, 0, 76, 77, 0, 0, 0, 0, 0, 0, 1, 1), {14} (0, 0, 0, 0, 0, 0, 13, 1, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 78, 0, 0, 0, 79, 0, 0, 0, 1), {16} (0, 80, 0, 0, 81, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 82, 37, 0, 0, 83, 0, 0, 0, 0, 0, 0, 0, 0), {18} (84, 85, 0, 0, 86, 62, 87, 88, 0, 89, 90, 0, 23, 91, 92, 93), (0, 94, 95, 96, 0, 97, 98, 99, 0, 0, 0, 0, 0, 0, 0, 100), {20} (0, 0, 0, 0, 0, 0, 0, 0, 101, 0, 0, 0, 0, 0, 0, 0), (2, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), {22} (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 102), (0, 0, 0, 0, 0, 0, 0, 92, 0, 0, 0, 103, 0, 0, 0, 0), {24} (104, 105, 0, 0, 0, 0, 0, 65, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0, 0, 106, 0, 0, 0, 0, 0, 0), {26} (0, 0, 0, 0, 0, 107, 0, 59, 0, 0, 15, 0, 108, 0, 0, 0), (72, 20, 109, 110, 72, 7, 36, 0, 72, 111, 65, 112, 72, 91, 113, 0), {28} (0, 114, 98, 0, 0, 0, 79, 14, 23, 42, 29, 115, 0, 0, 0, 0), (0, 116, 117, 0, 0, 13, 23, 0, 0, 0, 0, 0, 0, 118, 119, 0), {30} (0, 13, 92, 0, 0, 120, 0, 0, 59, 121, 0, 0, 0, 0, 0, 0), (0, 122, 0, 0, 0, 0, 0, 0, 0, 123, 124, 0, 0, 0, 125, 126), {32} (127, 128, 129, 0, 130, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), (0, 131, 0, 0, 132, 133, 0, 0, 0, 134, 135, 0, 136, 0, 0, 0), {34} (0, 0, 0, 0, 0, 0, 0, 137, 138, 139, 72, 0, 0, 0, 0, 0), (0, 0, 140, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), {36} (0, 0, 0, 0, 0, 0, 0, 141, 0, 142, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 143, 1, 144, 0, 0, 145), {38} (0, 0, 0, 0, 146, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0, 1, 147, 109, 0, 0, 0, 0, 0), {40} (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 148, 149, 150, 0, 0), (0, 0, 151, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), {42} (1, 152, 1, 153, 154, 155, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), (156, 157, 0, 0, 158, 0, 0, 0, 0, 142, 0, 0, 0, 0, 0, 0), {44} (0, 0, 0, 0, 0, 159, 0, 160, 0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 160, 0, 0, 0, 0, 0, 0, 0, 0), {46} (0, 0, 0, 0, 0, 0, 142, 0, 0, 0, 161, 0, 0, 0, 0, 0) ); L0: ( {0} $00000000, $FFFFFFFF, $0000FFFF, $000003F8, $FFFE0000, $BFFFFFFF, $000000B6, $07FF0000, $FFFFF800, $00010000, $9FC00000, $00003D9F, $00020000, {13} $FFFF0000, $000007FF, $0001FFC0, $200FF800, $FBC00000, $00003EEF, $0E000000, $FF000000, $FFFFFC00, $FFFFFFFB, $0000000F, $DC000000, $00FEFFFF, {26} $0000000C, $0000000E, $D0000000, $0080399F, $4000000C, $00023987, $00230000, $00003BBF, $FC00000C, $00E0399F, $00000004, $C0000000, $00803DC7, {39} $0000001F, $00603DDF, $0008000C, $D8000000, $00803DDF, $FF5F8400, $000C0000, $07F20000, $00007F80, $1FF20000, $00007F00, $03000000, $C2A00000, {52} $FEFFE0DF, $1FFFFFFF, $00000040, $7FFFF800, $C3C00000, $001E3F9D, $3C00BFFC, $E0000000, $003C0000, $001C0000, $FFF00000, $200FFFFF, $0000B800, {65} $00000060, $00000200, $0FFF0FFF, $0F800000, $7FE00000, $9FFFFFFF, $000FF800, $00000007, $00003FFE, $000FFFC0, $00FFFFF0, $FFF70000, $039021FF, {78} $00038000, $80000000, $0000FC00, $06000000, $3FF78000, $00030000, $00000844, $000010F8, $00000003, $0000003F, $8003FFFF, $00003FC0, $000FFF80, {91} $FFF80000, $00000001, $00000020, $007FFE00, $00003008, $38000000, $C19D0000, $00000002, $0060F800, $000037F8, $40000000, $20000000, $07C00000, {104} $0000F06E, $87000000, $000000F0, $00001800, $0000003C, $0000007F, $80190000, $001FFF80, $00080000, $0000DE01, $40FFF000, $001F1FCC, $FFE00000, {117} $4000007F, $FF3F8000, $30000001, $00FFF800, $00000FFF, $07FFF000, $79BF0000, $0000000D, $FCFE0000, $00000011, $000007FE, $7BF80000, $0FFE0080, {130} $03FFFC00, $FF7F8000, $FFFC0000, $007FFEFF, $B47E0000, $000000BF, $00FB7C00, $00780000, $0000000B, $C7F00000, $003FFF81, $001F0000, $007F0000, {143} $FFFE8000, $000780FF, $00030010, $60000000, $FFFF3FFF, $F807E3E0, $00000FE7, $00003C00, $0000001C, $F87FFFFF, $00201FFF, $F8000010, $0000FFFE, {156} $F9FFFF7F, $000007DB, $00008000, $00004000, $0000F000, $000007F0 ); ); function Utf8CodePointLen(P: PAnsiChar; MaxLookAhead: SizeInt; IncludeCombiningDiacriticalMarks: Boolean): SizeInt; var cp: uint32; iByte,cpLen: SizeInt; begin { see https://en.wikipedia.org/wiki/UTF-8#Description for details } result:=0; { result = 0 when scanning first character, result > 0 when scanning potential diacritical marks following it. Common case is correct UTF-8. Setting cpLen and breaking from the loop (instead of exiting) will handle invalid/incomplete cases when cpLen bytes were expected, but not all are present/valid. This keeps the code more compact, both source and binary. } repeat if MaxLookAhead<1 then exit; case ord(P[result]) of { One-byte codepoints have the form %(0)xxxxxxx. } 0..$7F {%01111111}: { There are no diacritics among them. } if not IncludeCombiningDiacriticalMarks then exit(1) else if result=0 then begin result:=1; Dec(MaxLookAhead); end else exit; { Two-byte codepoints have the form %(110)xxxxx (10)xxxxxx. but also minimum value of $80 = %10000000 = %(110)00010 (10)000000. } $C2 {%11000010}..$DF {%11011111}: if (MaxLookAhead>=2) and (ord(P[result+1]) and $C0=$80) then begin if not IncludeCombiningDiacriticalMarks then exit(2); if result>0 then begin cp:=ord(P[result]) and $1F {%11111} shl 6 or ord(P[result+1]) and $3F {%111111}; { Max possible cp value, $7FF, won't overflow L2. } if IsCombinings.L0[IsCombinings.L1[IsCombinings.L2[cp shr (5+4)]][cp shr 5 and (1 shl 4-1)]] shr (cp and (1 shl 5-1)) and 1=0 then exit; end; Inc(result,2); Dec(MaxLookAhead,2); end else begin cpLen:=2; break; end; { Three-byte codepoints have the form %(1110)xxxx (10)xxxxxx (10)xxxxxx but also minimum value of $800 = %1000 00000000 = %(1110)0000 (10)100000 (10)000000. } $E0 {%11100000}..$EF {%11101111}: if (MaxLookAhead>=3) and (ord(P[result+1]) and $C0=$80) and (ord(P[result+2]) and $C0=$80) and ((ord(P[result])>$E0 {%11100000}) or (ord(P[result+1])>=$A0 {%10100000})) then begin if not IncludeCombiningDiacriticalMarks then exit(3); if result>0 then begin cp:=ord(P[result]) and $F {%1111} shl 12 or ord(P[result+1]) and $3F {%111111} shl 6 or ord(P[result+2]) and $3F {%111111}; { Max possible cp value, $FFFF, won't overflow L2. } if IsCombinings.L0[IsCombinings.L1[IsCombinings.L2[cp shr (5+4)]][cp shr 5 and (1 shl 4-1)]] shr (cp and (1 shl 5-1)) and 1=0 then exit; end; Inc(result,3); Dec(MaxLookAhead,3); end else begin cpLen:=3; break; end; { Four-byte codepoints have the form %(11110)xxx (10)xxxxxx (10)xxxxxx (10)xxxxxx but also minimum value of $10000 = %1 00000000 00000000 = %(11110)000 (10)010000 (10)000000 (10)000000 and maximum of $10FFFF = %10000 11111111 11111111 = %(11110)100 (10)001111 (10)111111 (10)111111. } $F0 {%11110000}..$F4 {%11110100}: if (MaxLookAhead>=4) and (ord(P[result+1]) and $C0=$80) and (ord(P[result+2]) and $C0=$80) and (ord(P[result+3]) and $C0=$80) and (uint16(P[result]) shl 8 or ord(P[result+1])>=$F090 {%11110000 10010000}) and (uint16(P[result]) shl 8 or ord(P[result+1])<=$F48F {%11110100 10001111}) then begin if not IncludeCombiningDiacriticalMarks then exit(4); if result>0 then begin cp:=ord(P[result]) and $7 {%111} shl 18 or ord(P[result+1]) and $3F {%111111} shl 12 or ord(P[result+2]) and $3F {%111111} shl 6 or ord(P[result+3]) and $3F {%111111}; { This time, cp can overflow L2, and can have special-cased values U+E0100..U+E01EF. } if cp=$E0100) and (cp<=$E01EF)) then exit; end; Inc(result,4); Dec(MaxLookAhead,4); end else begin cpLen:=4; break; end; else begin cpLen:=1; break; end; end; until false; { Handle invalid or incomplete cases, when expected codepoint length is cpLen. } for iByte:=1 to cpLen-1 do if (iByte$80 {%10000000}) then begin if result=0 then result:=-1-iByte; exit; end; if cpLen>MaxLookAhead then result:=0 { Signal an incomplete codepoint, even if there were complete codepoints before. } else if result=0 then result:=-cpLen; end; {$ifndef FPC_SYSTEM_HAS_FPC_CHARARRAY_TO_SHORTSTR} procedure fpc_chararray_to_shortstr(out res : shortstring;const arr: array of AnsiChar; zerobased: boolean = true);[public,alias:'FPC_CHARARRAY_TO_SHORTSTR']; compilerproc; var l: ObjpasInt; index: ObjpasInt; len: byte; begin l:=high(arr)+1; if l>=ObjpasInt(high(res))+1 then l:=high(res) else if l<0 then l:=0; if zerobased then begin index:=IndexByte(arr[0],l,0); if index<0 then len:=l else len:=index; end else len:=l; move(arr[0],res[1],len); res[0]:=chr(len); end; {$endif ndef FPC_SYSTEM_HAS_FPC_CHARARRAY_TO_SHORTSTR} {$ifndef FPC_SYSTEM_HAS_FPC_SHORTSTR_TO_CHARARRAY} procedure fpc_shortstr_to_chararray(out res: array of AnsiChar; const src: ShortString); compilerproc; var len: ObjpasInt; begin len := length(src); if len > length(res) then len := length(res); {$push}{$r-} { make sure we don't access AnsiChar 1 if length is 0 (JM) } if len > 0 then move(src[1],res[0],len); fillchar(res[len],length(res)-len,0); {$pop} end; {$endif FPC_SYSTEM_HAS_FPC_SHORTSTR_TO_CHARARRAY} {$ifndef FPC_SYSTEM_HAS_FPC_PCHAR_LENGTH} function fpc_pchar_length(p:PAnsiChar):sizeint;[public,alias:'FPC_PCHAR_LENGTH']; compilerproc; begin if assigned(p) then Result:=IndexByte(p^,-1,0) else Result:=0; end; {$endif ndef FPC_SYSTEM_HAS_FPC_PCHAR_LENGTH} {$ifndef FPC_SYSTEM_HAS_FPC_PWIDECHAR_LENGTH} function fpc_pwidechar_length(p:pwidechar):sizeint;[public,alias:'FPC_PWIDECHAR_LENGTH']; compilerproc; begin if assigned(p) then Result:=IndexWord(p^,-1,0) else result:=0; end; {$endif ndef FPC_SYSTEM_HAS_FPC_PWIDECHAR_LENGTH} {**************************************************************************** Caller/StackFrame Helpers ****************************************************************************} {$ifndef FPC_SYSTEM_HAS_GET_FRAME} {_$error Get_frame must be defined for each processor } {$endif ndef FPC_SYSTEM_HAS_GET_FRAME} {$ifndef FPC_SYSTEM_HAS_GET_CALLER_ADDR} {_$error Get_caller_addr must be defined for each processor } {$endif ndef FPC_SYSTEM_HAS_GET_CALLER_ADDR} {$ifndef FPC_SYSTEM_HAS_GET_CALLER_FRAME} {_$error Get_caller_frame must be defined for each processor } {$endif ndef FPC_SYSTEM_HAS_GET_CALLER_FRAME} {**************************************************************************** Math ****************************************************************************} {**************************************************************************** Software multiplication ****************************************************************************} {$ifdef FPC_INCLUDE_SOFTWARE_MUL} {$ifdef VER3_0} {$ifndef FPC_SYSTEM_HAS_MUL_INTEGER} function fpc_mul_integer(f1,f2 : integer;checkoverflow : boolean) : integer;[public,alias: 'FPC_MUL_INTEGER']; compilerproc; var sign : boolean; q1,q2,q3 : word; begin { there's no difference between signed and unsigned multiplication, when the destination size is equal to the source size and overflow checking is off } if not checkoverflow then { word(f1)*word(f2) is coded as a call to mulword } fpc_mul_integer:=integer(word(f1)*word(f2)) else begin sign:=false; if f1<0 then begin sign:=not(sign); q1:=word(-f1); end else q1:=f1; if f2<0 then begin sign:=not(sign); q2:=word(-f2); end else q2:=f2; { the q1*q2 is coded as call to mulword } q3:=q1*q2; if (q1 <> 0) and (q2 <>0) and ((q1>q3) or (q2>q3) or { the bit 63 can be only set if we have $8000 } { and sign is true } (q3 shr 15<>0) and ((q3<>word(word(1) shl 15)) or not(sign)) ) then HandleErrorAddrFrameInd(215,get_pc_addr,get_frame); if sign then fpc_mul_integer:=-q3 else fpc_mul_integer:=q3; end; end; {$endif FPC_SYSTEM_HAS_MUL_INTEGER} {$ifndef FPC_SYSTEM_HAS_MUL_WORD} function fpc_mul_word(f1,f2 : word;checkoverflow : boolean) : word;[public,alias: 'FPC_MUL_WORD']; compilerproc; var _f1,bitpos : word; f1overflowed : boolean; begin fpc_mul_word:=0; bitpos:=1; f1overflowed:=false; while f1<>0 do begin if (f2 and bitpos)<>0 then begin _f1:=fpc_mul_word; fpc_mul_word:=fpc_mul_word+f1; { if one of the operands is greater than the result an overflow occurs } if checkoverflow and (f1overflowed or ((_f1<>0) and (f1<>0) and ((_f1>fpc_mul_word) or (f1>fpc_mul_word)))) then HandleErrorAddrFrameInd(215,get_pc_addr,get_frame); end; { when bootstrapping, we forget about overflow checking for qword :) } f1overflowed:=f1overflowed or ((f1 and (1 shl 15))<>0); f1:=f1 shl 1; bitpos:=bitpos shl 1; end; end; {$endif FPC_SYSTEM_HAS_MUL_WORD} {$ifndef FPC_SYSTEM_HAS_MUL_LONGINT} function fpc_mul_longint(f1,f2 : longint;checkoverflow : boolean) : longint;[public,alias: 'FPC_MUL_LONGINT']; compilerproc; var sign : boolean; q1,q2,q3 : dword; begin { there's no difference between signed and unsigned multiplication, when the destination size is equal to the source size and overflow checking is off } if not checkoverflow then { dword(f1)*dword(f2) is coded as a call to muldword } fpc_mul_longint:=longint(dword(f1)*dword(f2)) else begin sign:=false; if f1<0 then begin sign:=not(sign); q1:=dword(-f1); end else q1:=f1; if f2<0 then begin sign:=not(sign); q2:=dword(-f2); end else q2:=f2; { the q1*q2 is coded as call to muldword } q3:=q1*q2; if (q1 <> 0) and (q2 <>0) and ((q1>q3) or (q2>q3) or { the bit 31 can be only set if we have $8000 0000 } { and sign is true } (q3 shr 15<>0) and ((q3<>dword(dword(1) shl 31)) or not(sign)) ) then HandleErrorAddrFrameInd(215,get_pc_addr,get_frame); if sign then fpc_mul_longint:=-q3 else fpc_mul_longint:=q3; end; end; {$endif FPC_SYSTEM_HAS_MUL_INTEGER} {$ifndef FPC_SYSTEM_HAS_MUL_DWORD} { multiplies two dwords the longbool for checkoverflow avoids a misaligned stack } function fpc_mul_dword(f1,f2 : dword;checkoverflow : boolean) : dword;[public,alias: 'FPC_MUL_DWORD']; compilerproc; var _f1,bitpos : dword; f1overflowed : boolean; begin fpc_mul_dword:=0; bitpos:=1; f1overflowed:=false; while f1<>0 do begin if (f2 and bitpos)<>0 then begin _f1:=fpc_mul_dword; fpc_mul_dword:=fpc_mul_dword+f1; { if one of the operands is greater than the result an overflow occurs } if checkoverflow and (f1overflowed or ((_f1<>0) and (f1<>0) and ((_f1>fpc_mul_dword) or (f1>fpc_mul_dword)))) then HandleErrorAddrFrameInd(215,get_pc_addr,get_frame); end; { when bootstrapping, we forget about overflow checking for qword :) } f1overflowed:=f1overflowed or ((f1 and (dword(1) shl 31))<>0); f1:=f1 shl 1; bitpos:=bitpos shl 1; end; end; {$endif FPC_SYSTEM_HAS_MUL_DWORD} {$else VER3_0} {$ifndef FPC_SYSTEM_HAS_MUL_SHORTINT} function fpc_mul_shortint(f1,f2 : shortint) : shortint;[public,alias: 'FPC_MUL_SHORTINT']; compilerproc; begin { there's no difference between signed and unsigned multiplication, when the destination size is equal to the source size and overflow checking is off } { byte(f1) * byte(f2) is coded as a call to mul_byte } fpc_mul_shortint := shortint(byte(f1) * byte(f2)); end; function fpc_mul_shortint_checkoverflow(f1,f2 : shortint) : shortint;[public,alias: 'FPC_MUL_SHORTINT_CHECKOVERFLOW']; compilerproc; var sign : boolean; q1,q2,q3 : byte; begin sign:=false; if f1 < 0 then begin sign := not(sign); q1 := byte(-f1); end else q1 := f1; if f2 < 0 then begin sign := not(sign); q2 := byte(-f2); end else q2 := f2; { the q1*q2 is coded as call to mul_byte } {$push} {$Q+} q3 := q1 * q2; {$pop} if (q1 <> 0) and (q2 <> 0) and ((q1 > q3) or (q2 > q3) or { the bit 7 can be only set if we have $80 } { and sign is true } (q3 shr 7 <> 0) and ((q3 <> byte(byte(1) shl 7)) or not(sign)) ) then FPC_Overflow(); if sign then fpc_mul_shortint_checkoverflow := -q3 else fpc_mul_shortint_checkoverflow := q3; end; {$endif FPC_SYSTEM_HAS_MUL_SHORTINT} {$ifndef FPC_SYSTEM_HAS_MUL_BYTE} function fpc_mul_byte(f1,f2 : byte) : byte;[public,alias: 'FPC_MUL_BYTE']; compilerproc; var v1,v2,res: byte; begin if f10 do begin if v1 and 1<>0 then inc(res,v2); v2:=v2 shl 1; v1:=v1 shr 1; end; fpc_mul_byte:=res; end; function fpc_mul_byte_checkoverflow(f1,f2 : byte) : byte;[public,alias: 'FPC_MUL_BYTE_CHECKOVERFLOW']; compilerproc; var _f1, bitpos : byte; f1overflowed : boolean; begin fpc_mul_byte_checkoverflow := 0; bitpos := 1; f1overflowed := false; while f1<>0 do begin if (f2 and bitpos) <> 0 then begin _f1 := fpc_mul_byte_checkoverflow; fpc_mul_byte_checkoverflow := fpc_mul_byte_checkoverflow + f1; { if one of the operands is greater than the result an overflow occurs } if f1overflowed or ((_f1 <> 0) and (f1 <> 0) and ((_f1 > fpc_mul_byte_checkoverflow) or (f1 > fpc_mul_byte_checkoverflow))) then FPC_Overflow(); end; { when bootstrapping, we forget about overflow checking for qword :) } f1overflowed := f1overflowed or ((f1 and (1 shl 7)) <> 0); f1 := f1 shl 1; bitpos := bitpos shl 1; end; end; {$endif FPC_SYSTEM_HAS_MUL_BYTE} {$ifndef FPC_SYSTEM_HAS_MUL_INTEGER} function fpc_mul_integer(f1,f2 : integer) : integer;[public,alias: 'FPC_MUL_INTEGER']; compilerproc; begin { there's no difference between signed and unsigned multiplication, when the destination size is equal to the source size and overflow checking is off } { word(f1)*word(f2) is coded as a call to mulword } fpc_mul_integer:=integer(word(f1)*word(f2)); end; function fpc_mul_integer_checkoverflow(f1,f2 : integer) : integer;[public,alias: 'FPC_MUL_INTEGER_CHECKOVERFLOW']; compilerproc; var sign : boolean; q1,q2,q3 : word; begin sign:=false; if f1<0 then begin sign:=not(sign); q1:=word(-f1); end else q1:=f1; if f2<0 then begin sign:=not(sign); q2:=word(-f2); end else q2:=f2; { the q1*q2 is coded as call to mulword } {$push} {$Q+} q3:=q1*q2; {$pop} if (q1 <> 0) and (q2 <>0) and ((q1>q3) or (q2>q3) or { the bit 63 can be only set if we have $8000 } { and sign is true } (q3 shr 15<>0) and ((q3<>word(word(1) shl 15)) or not(sign)) ) then FPC_Overflow(); if sign then fpc_mul_integer_checkoverflow:=-q3 else fpc_mul_integer_checkoverflow:=q3; end; {$endif FPC_SYSTEM_HAS_MUL_INTEGER} {$ifndef FPC_SYSTEM_HAS_MUL_WORD} function fpc_mul_word(f1,f2 : word) : word;[public,alias: 'FPC_MUL_WORD']; compilerproc; var v1,v2,res: word; begin if f10 do begin if ALUUInt(v1) and 1<>0 then inc(res,v2); v2:=v2 shl 1; v1:=v1 shr 1; end; fpc_mul_word:=res; end; function fpc_mul_word_checkoverflow(f1,f2 : word) : word;[public,alias: 'FPC_MUL_WORD_CHECKOVERFLOW']; compilerproc; var _f1,bitpos : word; f1overflowed : boolean; begin fpc_mul_word_checkoverflow:=0; bitpos:=1; f1overflowed:=false; while f1<>0 do begin if (f2 and bitpos)<>0 then begin _f1:=fpc_mul_word_checkoverflow; fpc_mul_word_checkoverflow:=fpc_mul_word_checkoverflow+f1; { if one of the operands is greater than the result an overflow occurs } if f1overflowed or ((_f1<>0) and (f1<>0) and ((_f1>fpc_mul_word_checkoverflow) or (f1>fpc_mul_word_checkoverflow))) then FPC_Overflow(); end; { when bootstrapping, we forget about overflow checking for qword :) } f1overflowed:=f1overflowed or ((f1 and (1 shl 15))<>0); f1:=f1 shl 1; bitpos:=bitpos shl 1; end; end; {$endif FPC_SYSTEM_HAS_MUL_WORD} {$ifndef FPC_SYSTEM_HAS_MUL_LONGINT} function fpc_mul_longint(f1,f2 : longint) : longint;[public,alias: 'FPC_MUL_LONGINT']; compilerproc; begin { there's no difference between signed and unsigned multiplication, when the destination size is equal to the source size and overflow checking is off } { dword(f1)*dword(f2) is coded as a call to muldword } fpc_mul_longint:=longint(dword(f1)*dword(f2)); end; function fpc_mul_longint_checkoverflow(f1,f2 : longint) : longint;[public,alias: 'FPC_MUL_LONGINT_CHECKOVERFLOW']; compilerproc; var sign : boolean; q1,q2,q3 : dword; begin sign:=false; if f1<0 then begin sign:=not(sign); q1:=dword(-f1); end else q1:=f1; if f2<0 then begin sign:=not(sign); q2:=dword(-f2); end else q2:=f2; { the q1*q2 is coded as call to muldword } {$push} {$Q+} q3:=q1*q2; {$pop} if (q1 <> 0) and (q2 <>0) and ((q1>q3) or (q2>q3) or { the bit 31 can be only set if we have $8000 0000 } { and sign is true } (q3 shr 31<>0) and ((q3<>dword(dword(1) shl 31)) or not(sign)) ) then FPC_Overflow(); if sign then fpc_mul_longint_checkoverflow:=-q3 else fpc_mul_longint_checkoverflow:=q3; end; {$endif FPC_SYSTEM_HAS_MUL_INTEGER} {$ifndef FPC_SYSTEM_HAS_MUL_DWORD} function fpc_mul_dword(f1,f2 : dword) : dword;[public,alias: 'FPC_MUL_DWORD']; compilerproc; var v1,v2,res: dword; begin if f10 do begin if ALUUInt(v1) and 1<>0 then inc(res,v2); v2:=v2 shl 1; v1:=v1 shr 1; end; fpc_mul_dword:=res; end; function fpc_mul_dword_checkoverflow(f1,f2 : dword) : dword;[public,alias: 'FPC_MUL_DWORD_CHECKOVERFLOW']; compilerproc; var _f1,bitpos : dword; f1overflowed : boolean; begin fpc_mul_dword_checkoverflow:=0; bitpos:=1; f1overflowed:=false; while f1<>0 do begin if (f2 and bitpos)<>0 then begin _f1:=fpc_mul_dword_checkoverflow; fpc_mul_dword_checkoverflow:=fpc_mul_dword_checkoverflow+f1; { if one of the operands is greater than the result an overflow occurs } if f1overflowed or ((_f1<>0) and (f1<>0) and ((_f1>fpc_mul_dword_checkoverflow) or (f1>fpc_mul_dword_checkoverflow))) then FPC_Overflow(); end; { when bootstrapping, we forget about overflow checking for qword :) } f1overflowed:=f1overflowed or ((f1 and (dword(1) shl 31))<>0); f1:=f1 shl 1; bitpos:=bitpos shl 1; end; end; {$endif FPC_SYSTEM_HAS_MUL_DWORD} {$endif VER3_0} {$endif FPC_INCLUDE_SOFTWARE_MUL} {**************************************************************************** Software longint/dword division ****************************************************************************} {$ifdef FPC_INCLUDE_SOFTWARE_MOD_DIV} {$ifndef FPC_SYSTEM_HAS_DIV_DWORD} function fpc_div_dword(n,z : dword) : dword; [public,alias: 'FPC_DIV_DWORD']; compilerproc; var shift,lzz,lzn : ObjpasInt; begin result:=0; if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); if z=0 then exit; lzz:=BsrDWord(z); lzn:=BsrDWord(n); { if the denominator contains less zeros then the numerator then d is greater than the n } if lzn>lzz then exit; shift:=lzz-lzn; n:=n shl shift; for shift:=shift downto 0 do begin if z>=n then begin z:=z-n; result:=result+dword(dword(1) shl shift); end; n:=n shr 1; end; end; {$endif FPC_SYSTEM_HAS_DIV_DWORD} {$ifndef FPC_SYSTEM_HAS_MOD_DWORD} function fpc_mod_dword(n,z : dword) : dword; [public,alias: 'FPC_MOD_DWORD']; compilerproc; var shift,lzz,lzn : ObjpasInt; begin result:=0; if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); if z=0 then exit; lzz:=BsrDWord(z); lzn:=BsrDWord(n); { if the denominator contains less zeros then the numerator then d is greater than the n } if lzn>lzz then begin result:=z; exit; end; shift:=lzz-lzn; n:=n shl shift; for shift:=shift downto 0 do begin if z>=n then z:=z-n; n:=n shr 1; end; result:=z; end; {$endif FPC_SYSTEM_HAS_MOD_DWORD} {$ifndef FPC_SYSTEM_HAS_DIV_WORD} function fpc_div_word(n,z : word) : word; [public,alias: 'FPC_DIV_WORD']; compilerproc; var shift,lzz,lzn : Byte; begin result:=0; if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); if z=0 then exit; lzz:=BsrWord(z); lzn:=BsrWord(n); { if the denominator contains less zeros then the numerator then d is greater than the n } if lzn>lzz then exit; shift:=lzz-lzn; n:=n shl shift; for shift:=shift downto 0 do begin if z>=n then begin z:=z-n; result:=result+word(word(1) shl shift); end; n:=n shr 1; end; end; {$endif FPC_SYSTEM_HAS_DIV_WORD} {$ifndef FPC_SYSTEM_HAS_MOD_WORD} function fpc_mod_word(n,z : word) : word; [public,alias: 'FPC_MOD_WORD']; compilerproc; var shift,lzz,lzn : Byte; begin result:=0; if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); if z=0 then exit; lzz:=BsrWord(z); lzn:=BsrWord(n); { if the denominator contains less zeros then the numerator then d is greater than the n } if lzn>lzz then begin result:=z; exit; end; shift:=lzz-lzn; n:=n shl shift; for shift:=shift downto 0 do begin if z>=n then z:=z-n; n:=n shr 1; end; result:=z; end; {$endif FPC_SYSTEM_HAS_MOD_WORD} {$ifndef FPC_SYSTEM_HAS_DIV_BYTE} function fpc_div_byte(n,z : byte) : byte; [public,alias: 'FPC_DIV_BYTE']; compilerproc; var shift,lzz,lzn : Byte; begin result:=0; if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); if z=0 then exit; lzz:=BsrByte(z); lzn:=BsrByte(n); { if the denominator contains less zeros then the numerator then d is greater than the n } if lzn>lzz then exit; shift:=lzz-lzn; n:=n shl shift; for shift:=shift downto 0 do begin if z>=n then begin z:=z-n; result:=result+byte(byte(1) shl shift); end; n:=n shr 1; end; end; {$endif FPC_SYSTEM_HAS_DIV_BYTE} {$ifndef FPC_SYSTEM_HAS_MOD_BYTE} function fpc_mod_byte(n,z : byte) : byte; [public,alias: 'FPC_MOD_BYTE']; compilerproc; var shift,lzz,lzn : Byte; begin result:=0; if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); if z=0 then exit; lzz:=BsrByte(z); lzn:=BsrByte(n); { if the denominator contains less zeros then the numerator then d is greater than the n } if lzn>lzz then begin result:=z; exit; end; shift:=lzz-lzn; n:=n shl shift; for shift:=shift downto 0 do begin if z>=n then z:=z-n; n:=n shr 1; end; result:=z; end; {$endif FPC_SYSTEM_HAS_MOD_BYTE} {$ifndef FPC_SYSTEM_HAS_DIV_LONGINT} function fpc_div_longint(n,z : longint) : longint; [public,alias: 'FPC_DIV_LONGINT']; compilerproc; var sign : boolean; d1,d2 : dword; begin if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); sign:=false; if z<0 then begin sign:=not(sign); d1:=dword(-z); end else d1:=z; if n<0 then begin sign:=not(sign); d2:=dword(-n); end else d2:=n; { the div is coded by the compiler as call to divdword } if sign then result:=-(d1 div d2) else result:=d1 div d2; end; {$endif FPC_SYSTEM_HAS_DIV_LONGINT} {$ifndef FPC_SYSTEM_HAS_MOD_LONGINT} function fpc_mod_longint(n,z : longint) : longint; [public,alias: 'FPC_MOD_LONGINT']; compilerproc; var signed : boolean; r,nq,zq : dword; begin if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); nq:=abs(n); if z<0 then begin zq:=dword(-z); signed:=true; end else begin zq:=z; signed:=false; end; r:=zq mod nq; if signed then result:=-longint(r) else result:=r; end; {$endif FPC_SYSTEM_HAS_MOD_LONGINT} {$ifndef FPC_SYSTEM_HAS_DIV_SMALLINT} function fpc_div_smallint(n,z : smallint) : smallint; [public,alias: 'FPC_DIV_SMALLINT']; compilerproc; var sign : boolean; w1,w2 : word; begin if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); sign:=false; if z<0 then begin sign:=not(sign); w1:=word(-z); end else w1:=z; if n<0 then begin sign:=not(sign); w2:=word(-n); end else w2:=n; { the div is coded by the compiler as call to divdword } if sign then result:=-(w1 div w2) else result:=w1 div w2; end; {$endif FPC_SYSTEM_HAS_DIV_SMALLINT} {$ifndef FPC_SYSTEM_HAS_MOD_SMALLINT} function fpc_mod_smallint(n,z : smallint) : smallint; [public,alias: 'FPC_MOD_SMALLINT']; compilerproc; var signed : boolean; r,nq,zq : word; begin if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); nq:=abs(n); if z<0 then begin zq:=word(-z); signed:=true; end else begin zq:=z; signed:=false; end; r:=zq mod nq; if signed then result:=-smallint(r) else result:=r; end; {$endif FPC_SYSTEM_HAS_MOD_SMALLINT} {$ifndef FPC_SYSTEM_HAS_DIV_SHORTINT} function fpc_div_shortint(n,z : shortint) : shortint; [public,alias: 'FPC_DIV_SHORTINT']; compilerproc; var sign : boolean; b1,b2 : byte; begin if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); sign:=false; if z<0 then begin sign:=not(sign); b1:=byte(-z); end else b1:=z; if n<0 then begin sign:=not(sign); b2:=byte(-n); end else b2:=n; { the div is coded by the compiler as call to divdword } if sign then result:=-(b1 div b2) else result:=b1 div b2; end; {$endif FPC_SYSTEM_HAS_DIV_SHORTINT} {$ifndef FPC_SYSTEM_HAS_MOD_SHORTINT} function fpc_mod_shortint(n,z : shortint) : shortint; [public,alias: 'FPC_MOD_SHORTINT']; compilerproc; var signed : boolean; r,nq,zq : byte; begin if n=0 then HandleErrorAddrFrameInd(200,get_pc_addr,get_frame); nq:=abs(n); if z<0 then begin zq:=byte(-z); signed:=true; end else begin zq:=z; signed:=false; end; r:=zq mod nq; if signed then result:=-shortint(r) else result:=r; end; {$endif FPC_SYSTEM_HAS_MOD_SHORTINT} {$endif FPC_INCLUDE_SOFTWARE_MOD_DIV} {****************************************************************************} {$if defined(CPUINT8)} {$ifndef FPC_SYSTEM_HAS_ABS_SHORTINT} function abs(l:shortint):shortint;{$ifdef SYSTEMINLINE}inline;{$endif} begin if l<0 then abs:=-l else abs:=l; end; {$endif not FPC_SYSTEM_HAS_ABS_SMALLINT} {$endif CPUINT8} {$if defined(CPUINT16) or defined(CPUINT8)} {$ifndef FPC_SYSTEM_HAS_ABS_SMALLINT} function abs(l:smallint):smallint;{$ifdef SYSTEMINLINE}inline;{$endif} begin if l<0 then abs:=-l else abs:=l; end; {$endif not FPC_SYSTEM_HAS_ABS_SMALLINT} {$endif CPUINT16 or CPUINT8} {$ifndef FPC_SYSTEM_HAS_ABS_LONGINT} { This is only needed to bootstrap on SPARC targets (MIPS and m68k too, but they have no releases, so bootstrapping is not an issue) } function abs(l:longint):longint;{$ifdef SYSTEMINLINE}inline;{$endif} begin if l<0 then abs:=-l else abs:=l; end; {$endif not FPC_SYSTEM_HAS_ABS_LONGINT} {$if defined(CPUINT8)} {$ifndef FPC_SYSTEM_HAS_ODD_SHORTINT} function odd(l:shortint):Boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(l and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_SHORTINT} {$ifndef FPC_SYSTEM_HAS_ODD_BYTE} function odd(l:byte):Boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(l and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_BYTE} {$endif CPUINT8} {$if defined(CPUINT16) or defined(CPUINT8)} {$ifndef FPC_SYSTEM_HAS_ODD_SMALLINT} function odd(l:smallint):Boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(l and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_SMALLINT} {$ifndef FPC_SYSTEM_HAS_ODD_WORD} function odd(l:word):Boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(l and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_WORD} {$endif CPUINT16 or CPUINT8} {$ifndef FPC_SYSTEM_HAS_ODD_LONGINT} function odd(l:longint):boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(l and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_LONGINT} {$ifndef FPC_SYSTEM_HAS_ODD_LONGWORD} function odd(l:longword):boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(l and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_LONGWORD} {$ifndef FPC_SYSTEM_HAS_ODD_INT64} function odd(l:int64):boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(longint(l) and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_INT64} {$ifndef FPC_SYSTEM_HAS_ODD_QWORD} function odd(l:qword):boolean;{$ifdef SYSTEMINLINE}inline;{$endif} begin odd:=boolean(longint(l) and 1); end; {$endif ndef FPC_SYSTEM_HAS_ODD_QWORD} {$if defined(CPUINT8)} {$ifndef FPC_SYSTEM_HAS_SQR_SHORTINT} function sqr(l:shortint):shortint;{$ifdef SYSTEMINLINE}inline;{$endif} begin sqr:=l*l; end; {$endif ndef FPC_SYSTEM_HAS_SQR_SHORTINT} {$endif CPUINT8} {$if defined(CPUINT16) or defined(CPUINT8)} {$ifndef FPC_SYSTEM_HAS_SQR_SMALLINT} function sqr(l:smallint):smallint;{$ifdef SYSTEMINLINE}inline;{$endif} begin sqr:=l*l; end; {$endif ndef FPC_SYSTEM_HAS_SQR_SMALLINT} {$endif CPUINT16 or CPUINT8} {$ifndef FPC_SYSTEM_HAS_SQR_LONGINT} function sqr(l:longint):longint;{$ifdef SYSTEMINLINE}inline;{$endif} begin sqr:=l*l; end; {$endif ndef FPC_SYSTEM_HAS_SQR_LONGINT} {$ifndef FPC_SYSTEM_HAS_ABS_INT64} function abs(l: Int64): Int64;{$ifdef SYSTEMINLINE}inline;{$endif} begin if l < 0 then abs := -l else abs := l; end; {$endif ndef FPC_SYSTEM_HAS_ABS_INT64} {$ifndef FPC_SYSTEM_HAS_SQR_INT64} function sqr(l: Int64): Int64;{$ifdef SYSTEMINLINE}inline;{$endif} begin sqr := l*l; end; {$endif ndef FPC_SYSTEM_HAS_SQR_INT64} {$ifndef FPC_SYSTEM_HAS_SQR_QWORD} function sqr(l: QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin sqr := l*l; end; {$endif ndef FPC_SYSTEM_HAS_SQR_INT64} {$ifdef CPU16} {$ifndef FPC_SYSTEM_HAS_DECLOCKED_SMALLINT} function declocked(var l:smallint):boolean; begin Dec(l); declocked:=(l=0); end; {$endif FPC_SYSTEM_HAS_DECLOCKED_SMALLINT} {$endif CPU16} {$ifndef FPC_SYSTEM_HAS_DECLOCKED_LONGINT} function declocked(var l:longint):boolean; begin Dec(l); declocked:=(l=0); end; {$endif FPC_SYSTEM_HAS_DECLOCKED_LONGINT} {$ifndef FPC_SYSTEM_HAS_DECLOCKED_INT64} function declocked(var l:int64):boolean; begin Dec(l); declocked:=(l=0); end; {$endif FPC_SYSTEM_HAS_DECLOCKED_INT64} {$ifdef CPU16} {$ifndef FPC_SYSTEM_HAS_INCLOCKED_SMALLINT} procedure inclocked(var l:smallint); begin Inc(l); end; {$endif FPC_SYSTEM_HAS_INCLOCKED_SMALLINT} {$endif CPU16} {$ifndef FPC_SYSTEM_HAS_INCLOCKED_LONGINT} procedure inclocked(var l:longint); begin Inc(l); end; {$endif FPC_SYSTEM_HAS_INCLOCKED_LONGINT} {$ifndef FPC_SYSTEM_HAS_INCLOCKED_INT64} procedure inclocked(var l:int64); begin Inc(l); end; {$endif FPC_SYSTEM_HAS_INCLOCKED_INT64} {$ifndef FPC_SYSTEM_HAS_SPTR} {_$error Sptr must be defined for each processor } {$endif ndef FPC_SYSTEM_HAS_SPTR} {**************************************************************************** Str() ****************************************************************************} {$ifndef FPC_SYSTEM_HAS_INT_STR_LONGINT} procedure int_str(l:longint;out s:shortstring); var m,m1 : longword; pcstart, pc2start, pc,pc2 : PAnsiChar; hs : string[32]; overflow : longint; begin pc2start:=@s[1]; pc2:=pc2start; if (l<0) then begin pc2^:='-'; inc(pc2); m:=longword(-l); end else m:=longword(l); pcstart:=PAnsiChar(@hs[0]); pc:=pcstart; repeat m1:=m div 10; inc(pc); pc^:=AnsiChar(m-(m1*10)+byte('0')); m:=m1; until m=0; overflow:=(pc-pcstart)+(pc2-pc2start)-high(s); if overflow>0 then inc(pcstart,overflow); while (pc>pcstart) do begin pc2^:=pc^; inc(pc2); dec(pc); end; s[0]:=AnsiChar(pc2-pc2start); end; {$endif ndef FPC_SYSTEM_HAS_INT_STR_LONGINT} {$ifndef FPC_SYSTEM_HAS_INT_STR_LONGWORD} procedure int_str_unsigned(l:longword;out s:shortstring); var m1 : longword; pcstart, pc2start, pc,pc2 : PAnsiChar; hs : string[32]; overflow : longint; begin pc2start:=@s[1]; pc2:=pc2start; pcstart:=PAnsiChar(@hs[0]); pc:=pcstart; repeat inc(pc); m1:=l div 10; pc^:=AnsiChar(l-(m1*10)+byte('0')); l:=m1; until l=0; overflow:=(pc-pcstart)-high(s); if overflow>0 then inc(pcstart,overflow); while (pc>pcstart) do begin pc2^:=pc^; inc(pc2); dec(pc); end; s[0]:=AnsiChar(pc2-pc2start); end; {$endif ndef FPC_SYSTEM_HAS_INT_STR_LONGWORD} {$ifndef FPC_SYSTEM_HAS_INT_STR_INT64} procedure int_str(l:int64;out s:shortstring); {$ifdef EXCLUDE_COMPLEX_PROCS} begin runerror(217); end; {$else EXCLUDE_COMPLEX_PROCS} var m,m1 : qword; pcstart, pc2start, pc,pc2 : PAnsiChar; hs : string[32]; overflow : longint; begin pc2start:=@s[1]; pc2:=pc2start; if (l<0) then begin pc2^:='-'; inc(pc2); m:=qword(-l); end else m:=qword(l); pcstart:=PAnsiChar(@hs[0]); pc:=pcstart; repeat m1:=m div 10; inc(pc); pc^:=AnsiChar(m-(m1*10)+byte('0')); m:=m1; until m=0; overflow:=(pc-pcstart)+(pc2-pc2start)-high(s); if overflow>0 then inc(pcstart,overflow); while (pc>pcstart) do begin pc2^:=pc^; inc(pc2); dec(pc); end; s[0]:=AnsiChar(pc2-pc2start); end; {$endif EXCLUDE_COMPLEX_PROCS} {$endif ndef FPC_SYSTEM_HAS_INT_STR_INT64} {$ifndef FPC_SYSTEM_HAS_INT_STR_QWORD} procedure int_str_unsigned(l:qword;out s:shortstring); {$ifdef EXCLUDE_COMPLEX_PROCS} begin runerror(217); end; {$else EXCLUDE_COMPLEX_PROCS} var m1 : qword; pcstart, pc2start, pc,pc2 : PAnsiChar; hs : string[64]; overflow : longint; begin pc2start:=@s[1]; pc2:=pc2start; pcstart:=PAnsiChar(@hs[0]); pc:=pcstart; repeat inc(pc); m1:=l div 10; pc^:=AnsiChar(l-(m1*10)+byte('0')); l:=m1; until l=0; overflow:=(pc-pcstart)-high(s); if overflow>0 then inc(pcstart,overflow); while (pc>pcstart) do begin pc2^:=pc^; inc(pc2); dec(pc); end; s[0]:=AnsiChar(pc2-pc2start); end; {$endif EXCLUDE_COMPLEX_PROCS} {$endif ndef FPC_SYSTEM_HAS_INT_STR_QWORD} {$ifndef FPUNONE} {$ifndef FPC_SYSTEM_HAS_SYSRESETFPU} procedure SysResetFpu;{$ifdef SYSTEMINLINE}inline;{$endif} begin softfloat_exception_flags:=[]; {$if declared(DefaultFPUControlWord)} SetNativeFPUControlWord(DefaultFPUControlWord); {$endif} end; {$endif FPC_SYSTEM_HAS_SYSRESETFPU} {$ifndef FPC_SYSTEM_HAS_SYSINITFPU} procedure SysInitFpu;{$ifdef SYSTEMINLINE}inline;{$endif} begin softfloat_exception_mask:=[float_flag_underflow,float_flag_inexact,float_flag_denormal]; softfloat_exception_flags:=[]; end; {$endif FPC_SYSTEM_HAS_SYSINITFPU} {$endif} {$ifndef FPC_SYSTEM_HAS_FPC_CPUINIT} procedure fpc_cpuinit; begin {$ifndef FPUNONE} {$ifdef FPC_HAS_FEATURE_DYNLIBS} if not IsLibrary then {$endif} SysInitFPU; {$if declared(DefaultFPUControlWord)} DefaultFPUControlWord:=GetNativeFPUControlWord; {$endif} SysResetFPU; {$endif} end; {$endif} {$ifndef FPC_SYSTEM_HAS_SWAPENDIAN} function SwapEndian(const AValue: SmallInt): SmallInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin { the extra Word type cast is necessary because the "AValue shr 8" } { is turned into "longint(AValue) shr 8", so if AValue < 0 then } { the sign bits from the upper 16 bits are shifted in rather than } { zeroes. } Result := SmallInt(((Word(AValue) shr 8) or (Word(AValue) shl 8)) and $ffff); end; {$ifndef cpujvm} function SwapEndian(const AValue: Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result := ((AValue shr 8) or (AValue shl 8)) and $ffff; end; {$endif} function SwapEndian(const AValue: LongInt): LongInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result := ((AValue shl 8) and $FF00FF00) or ((AValue shr 8) and $00FF00FF); Result := (Result shl 16) or (Result shr 16); end; {$ifndef cpujvm} function SwapEndian(const AValue: DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result := ((AValue shl 8) and $FF00FF00) or ((AValue shr 8) and $00FF00FF); Result := (Result shl 16) or (Result shr 16); end; {$endif} function SwapEndian(const AValue: Int64): Int64; begin Result := ((AValue shl 8) and $FF00FF00FF00FF00) or ((AValue shr 8) and $00FF00FF00FF00FF); Result := ((Result shl 16) and $FFFF0000FFFF0000) or ((Result shr 16) and $0000FFFF0000FFFF); Result := (Result shl 32) or ((Result shr 32)); end; {$ifndef cpujvm} function SwapEndian(const AValue: QWord): QWord; begin Result := ((AValue shl 8) and $FF00FF00FF00FF00) or ((AValue shr 8) and $00FF00FF00FF00FF); Result := ((Result shl 16) and $FFFF0000FFFF0000) or ((Result shr 16) and $0000FFFF0000FFFF); Result := (Result shl 32) or ((Result shr 32)); end; {$endif} {$endif FPC_SYSTEM_HAS_SWAPENDIAN} function BEtoN(const AValue: SmallInt): SmallInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function BEtoN(const AValue: Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function BEtoN(const AValue: LongInt): LongInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function BEtoN(const AValue: DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function BEtoN(const AValue: Int64): Int64;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function BEtoN(const AValue: QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function LEtoN(const AValue: SmallInt): SmallInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function LEtoN(const AValue: Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function LEtoN(const AValue: LongInt): LongInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function LEtoN(const AValue: DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function LEtoN(const AValue: Int64): Int64;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function LEtoN(const AValue: QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function NtoBE(const AValue: SmallInt): SmallInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function NtoBE(const AValue: Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function NtoBE(const AValue: LongInt): LongInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function NtoBE(const AValue: DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function NtoBE(const AValue: Int64): Int64;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function NtoBE(const AValue: QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_BIG} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function NtoLE(const AValue: SmallInt): SmallInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function NtoLE(const AValue: Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function NtoLE(const AValue: LongInt): LongInt;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function NtoLE(const AValue: DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} function NtoLE(const AValue: Int64): Int64;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$ifndef cpujvm} function NtoLE(const AValue: QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin {$IFDEF ENDIAN_LITTLE} Result := AValue; {$ELSE} Result := SwapEndian(AValue); {$ENDIF} end; {$endif not cpujvm} {$ifndef FPC_SYSTEM_HAS_MEM_BARRIER} procedure ReadBarrier; begin end; procedure ReadDependencyBarrier; begin end; procedure ReadWriteBarrier; begin end; procedure WriteBarrier; begin end; {$endif FPC_SYSTEM_HAS_MEM_BARRIER} {$ifndef FPC_HAS_INTERNAL_ROX_BYTE} {$ifndef FPC_SYSTEM_HAS_ROX_BYTE} function RorByte(Const AValue : Byte): Byte;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr 1) or (AValue shl 7); end; function RorByte(Const AValue : Byte;const Dist : Byte): Byte;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr (Dist and 7)) or (AValue shl (8-(Dist and 7))); end; function RolByte(Const AValue : Byte): Byte;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl 1) or (AValue shr 7); end; function RolByte(Const AValue : Byte;const Dist : Byte): Byte;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl (Dist and 7)) or (AValue shr (8-(Dist and 7))); end; {$endif FPC_SYSTEM_HAS_ROX_BYTE} {$endif FPC_HAS_INTERNAL_ROX_BYTE} {$ifndef FPC_HAS_INTERNAL_ROX_WORD} {$ifndef FPC_SYSTEM_HAS_ROX_WORD} function RorWord(Const AValue : Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr 1) or (AValue shl 15); end; function RorWord(Const AValue : Word;const Dist : Byte): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr (Dist and 15)) or (AValue shl (16-(Dist and 15))); end; function RolWord(Const AValue : Word): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl 1) or (AValue shr 15); end; function RolWord(Const AValue : Word;const Dist : Byte): Word;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl (Dist and 15)) or (AValue shr (16-(Dist and 15))); end; {$endif FPC_SYSTEM_HAS_ROX_WORD} {$endif FPC_HAS_INTERNAL_ROX_WORD} {$ifndef FPC_HAS_INTERNAL_ROX_DWORD} {$ifndef FPC_SYSTEM_HAS_ROX_DWORD} function RorDWord(Const AValue : DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr 1) or (AValue shl 31); end; function RorDWord(Const AValue : DWord;const Dist : Byte): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr (Dist and 31)) or (AValue shl (32-(Dist and 31))); end; function RolDWord(Const AValue : DWord): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl 1) or (AValue shr 31); end; function RolDWord(Const AValue : DWord;const Dist : Byte): DWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl (Dist and 31)) or (AValue shr (32-(Dist and 31))); end; {$endif FPC_SYSTEM_HAS_ROX_DWORD} {$endif FPC_HAS_INTERNAL_ROX_DWORD} {$ifndef FPC_HAS_INTERNAL_ROX_QWORD} {$ifndef FPC_SYSTEM_HAS_ROX_QWORD} function RorQWord(Const AValue : QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr 1) or (AValue shl 63); end; function RorQWord(Const AValue : QWord;const Dist : Byte): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shr (Dist and 63)) or (AValue shl (64-(Dist and 63))); end; function RolQWord(Const AValue : QWord): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl 1) or (AValue shr 63); end; function RolQWord(Const AValue : QWord;const Dist : Byte): QWord;{$ifdef SYSTEMINLINE}inline;{$endif} begin Result:=(AValue shl (Dist and 63)) or (AValue shr (64-(Dist and 63))); end; {$endif FPC_SYSTEM_HAS_ROX_QWORD} {$endif FPC_HAS_INTERNAL_ROX_QWORD} {$ifndef FPC_HAS_INTERNAL_ROX_ASSIGN_QWORD} {$ifndef FPC_SYSTEM_HAS_ROX_ASSIGN_QWORD} procedure fpc_ror_assign_int64(var AValue : int64;const Dist : Byte); [Public,Alias:'FPC_ROR_ASSIGN_INT64']; compilerproc; begin AValue:=(AValue shr (Dist and 63)) or (AValue shl (64-(Dist and 63))); end; procedure fpc_ror_assign_qword(var AValue : QWord;const Dist : Byte); [Public,Alias:'FPC_ROR_ASSIGN_QWORD']; compilerproc; begin AValue:=(AValue shr (Dist and 63)) or (AValue shl (64-(Dist and 63))); end; procedure fpc_rol_assign_int64(var AValue : int64;const Dist : Byte); [Public,Alias:'FPC_ROL_ASSIGN_INT64']; compilerproc; begin AValue:=(AValue shl (Dist and 63)) or (AValue shr (64-(Dist and 63))); end; procedure fpc_rol_assign_qword(var AValue : QWord;const Dist : Byte); [Public,Alias:'FPC_ROL_ASSIGN_QWORD']; compilerproc; begin AValue:=(AValue shl (Dist and 63)) or (AValue shr (64-(Dist and 63))); end; {$endif FPC_SYSTEM_HAS_ROX_ASSIGN_QWORD} {$endif FPC_HAS_INTERNAL_ROX_ASSIGN_QWORD} {$ifndef FPC_HAS_INTERNAL_SAR_BYTE} {$ifndef FPC_SYSTEM_HAS_SAR_BYTE} function SarShortint(Const AValue : Shortint;const Shift : Byte): Shortint; begin Result:=shortint(byte(byte(byte(AValue) shr (Shift and 7)) or (byte(shortint(byte(0-byte(byte(AValue) shr 7)) and byte(shortint(0-(ord((Shift and 7)<>0){ and 1}))))) shl (8-(Shift and 7))))); end; {$endif FPC_HAS_INTERNAL_SAR_BYTE} {$endif FPC_SYSTEM_HAS_SAR_BYTE} {$ifndef FPC_HAS_INTERNAL_SAR_WORD} {$ifndef FPC_SYSTEM_HAS_SAR_WORD} function SarSmallint(Const AValue : Smallint;const Shift : Byte): Smallint; begin Result:=smallint(word(word(word(AValue) shr (Shift and 15)) or (word(smallint(word(0-word(word(AValue) shr 15)) and word(smallint(0-(ord((Shift and 15)<>0){ and 1}))))) shl (16-(Shift and 15))))); end; {$endif FPC_HAS_INTERNAL_SAR_WORD} {$endif FPC_SYSTEM_HAS_SAR_WORD} {$ifndef FPC_HAS_INTERNAL_SAR_DWORD} {$ifndef FPC_SYSTEM_HAS_SAR_DWORD} function SarLongint(Const AValue : Longint;const Shift : Byte): Longint; begin Result:=longint(dword(dword(dword(AValue) shr (Shift and 31)) or (dword(longint(dword(0-dword(dword(AValue) shr 31)) and dword(longint(0-(ord((Shift and 31)<>0){ and 1}))))) shl (32-(Shift and 31))))); end; {$endif FPC_HAS_INTERNAL_SAR_DWORD} {$endif FPC_SYSTEM_HAS_SAR_DWORD} {$ifndef FPC_HAS_INTERNAL_SAR_QWORD} {$ifndef FPC_SYSTEM_HAS_SAR_QWORD} function fpc_SarInt64(Const AValue : Int64;const Shift : Byte): Int64; [Public,Alias:'FPC_SARINT64']; compilerproc; begin Result:=int64(qword(qword(qword(AValue) shr (Shift and 63)) or (qword(int64(qword(0-qword(qword(AValue) shr 63)) and qword(int64(0-(ord((Shift and 63)<>0){ and 1}))))) shl (64-(Shift and 63))))); end; {$endif FPC_HAS_INTERNAL_SAR_QWORD} {$endif FPC_SYSTEM_HAS_SAR_QWORD} {$ifndef FPC_HAS_INTERNAL_SAR_ASSIGN_QWORD} {$ifndef FPC_SYSTEM_HAS_SAR_ASSIGN_QWORD} procedure fpc_sar_assign_int64(var AValue : Int64;const Shift : Byte); [Public,Alias:'FPC_SAR_ASSIGN_INT64']; compilerproc; begin AValue:=int64(qword(qword(qword(AValue) shr (Shift and 63)) or (qword(int64(qword(0-qword(qword(AValue) shr 63)) and qword(int64(0-(ord((Shift and 63)<>0){ and 1}))))) shl (64-(Shift and 63))))); end; procedure fpc_sar_assign_qword(var AValue : QWord;const Shift : Byte); [Public,Alias:'FPC_SAR_ASSIGN_QWORD']; compilerproc; begin AValue:=qword(qword(qword(qword(AValue) shr (Shift and 63)) or (qword(int64(qword(0-qword(qword(AValue) shr 63)) and qword(int64(0-(ord((Shift and 63)<>0){ and 1}))))) shl (64-(Shift and 63))))); end; {$endif FPC_HAS_INTERNAL_SAR_ASSIGN_QWORD} {$endif FPC_SYSTEM_HAS_SAR_ASSIGN_QWORD} {$ifndef FPC_HAS_INTERNAL_BSF_BYTE} {$ifndef FPC_SYSTEM_HAS_BSF_BYTE} function BsfByte(Const AValue: Byte): Byte; const bsf8bit: array [Byte] of Byte = ( $ff,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 5,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 6,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 5,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 7,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 5,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 6,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0, 5,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0,4,0,1,0,2,0,1,0,3,0,1,0,2,0,1,0 ); begin result:=bsf8bit[AValue]; end; {$endif} {$endif} {$ifndef FPC_HAS_INTERNAL_BSR_BYTE} {$ifndef FPC_SYSTEM_HAS_BSR_BYTE} function BsrByte(Const AValue: Byte): Byte; const bsr8bit: array [Byte] of Byte = ( $ff,0,1,1,2,2,2,2,3,3,3,3,3,3,3,3,4,4,4,4,4,4,4,4,4,4,4,4,4,4,4,4, 5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5, 6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6, 6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7 ); begin result:=bsr8bit[AValue]; end; {$endif} {$endif} {$ifndef FPC_SYSTEM_HAS_BSF_WORD} {$ifndef FPC_HAS_INTERNAL_BSF_WORD} function BsfWord(Const AValue: Word): {$ifdef CPU16}byte{$else}cardinal{$endif}; begin result:=ord(lo(AValue)=0)*8; result:=result or BsfByte(byte(AValue shr result)); end; {$endif} {$endif} {$ifndef FPC_SYSTEM_HAS_BSR_WORD} {$ifndef FPC_HAS_INTERNAL_BSR_WORD} function BsrWord(Const AValue: Word): {$ifdef CPU16}byte{$else}cardinal{$endif}; begin result:=ord(AValue>255)*8; result:=result or BsrByte(byte(AValue shr result)); end; {$endif} {$endif} {$ifndef FPC_HAS_INTERNAL_BSF_DWORD} {$ifndef FPC_SYSTEM_HAS_BSF_DWORD} function BsfDWord(Const AValue : DWord): {$ifdef CPU16}byte{$else}cardinal{$endif}; var tmp: DWord; begin result:=ord(lo(AValue)=0)*16; tmp:=AValue shr result; result:=result or (ord((tmp and $FF)=0)*8); tmp:=tmp shr (result and 8); result:=result or BsfByte(byte(tmp)); end; {$endif} {$endif} {$ifndef FPC_HAS_INTERNAL_BSR_DWORD} {$ifndef FPC_SYSTEM_HAS_BSR_DWORD} function BsrDWord(Const AValue : DWord): {$ifdef CPU16}byte{$else}cardinal{$endif}; var tmp: DWord; begin result:=ord(AValue>$FFFF)*16; tmp:=AValue shr result; result:=result or (ord(tmp>$FF)*8); tmp:=tmp shr (result and 8); result:=result or BsrByte(byte(tmp)); end; {$endif} {$endif} {$ifndef FPC_HAS_INTERNAL_BSF_QWORD} {$ifndef FPC_SYSTEM_HAS_BSF_QWORD} function BsfQWord(Const AValue : QWord): {$ifdef CPU16}byte{$else}cardinal{$endif}; var tmp: DWord; begin result:=0; tmp:=lo(AValue); if (tmp=0) then begin tmp:=hi(AValue); result:=32; end; result:=result or BsfDword(tmp); end; {$endif} {$endif} {$ifndef FPC_HAS_INTERNAL_BSR_QWORD} {$ifndef FPC_SYSTEM_HAS_BSR_QWORD} function BsrQWord(Const AValue : QWord): {$ifdef CPU16}byte{$else}cardinal{$endif}; var tmp: DWord; begin result:=32; tmp:=hi(AValue); if (tmp=0) then begin tmp:=lo(AValue); result:=0; end; result:=result or BsrDword(tmp); end; {$endif} {$endif} const PopCntData : array[0..15] of byte = (0,1,1,2,1,2,2,3,1,2,2,3,2,3,3,4); function fpc_PopCnt_byte(AValue : Byte): Byte;[Public,Alias:'FPC_POPCNT_BYTE'];compilerproc; begin Result:=PopCntData[AValue and $f]+PopCntData[(AValue shr 4) and $f]; end; function fpc_PopCnt_word(AValue : Word): Word;[Public,Alias:'FPC_POPCNT_WORD'];compilerproc; var i : SizeInt; begin Result:=0; for i:=0 to 3 do begin inc(Result,PopCntData[AValue and $f]); AValue:=AValue shr 4; end; end; function fpc_PopCnt_dword(AValue : DWord): DWord;[Public,Alias:'FPC_POPCNT_DWORD'];compilerproc; var i : SizeInt; begin Result:=0; for i:=0 to 7 do begin inc(Result,PopCntData[AValue and $f]); AValue:=AValue shr 4; end; end; {$ifndef FPC_SYSTEM_HAS_POPCNT_QWORD} function fpc_PopCnt_qword(AValue : QWord): QWord;[Public,Alias:'FPC_POPCNT_QWORD'];compilerproc; begin Result:=PopCnt(lo(AValue))+PopCnt(hi(AValue)) end; {$endif}