{ This file is part of the Free Pascal Run time library. Copyright (c) 1999-2008 by the Free Pascal development team 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. **********************************************************************} { The RTTI is implemented through a series of constants : } Const // please update tkManagedTypes below if you add new // values tkUnknown = 0; tkInteger = 1; tkChar = 2; tkEnumeration = 3; tkFloat = 4; tkSet = 5; tkMethod = 6; tkSString = 7; tkString = tkSString; tkLString = 8; tkAString = 9; tkWString = 10; tkVariant = 11; tkArray = 12; tkRecord = 13; tkInterface = 14; tkClass = 15; tkObject = 16; tkWChar = 17; tkBool = 18; tkInt64 = 19; tkQWord = 20; tkDynArray = 21; tkInterfaceCorba = 22; tkProcVar = 23; tkUString = 24; tkHelper = 26; // all potentially managed types tkManagedTypes = [tkAstring,tkWstring,tkUstring,tkArray, tkObject,tkRecord,tkDynArray,tkInterface,tkVariant]; {**************************************************************************** Local types ****************************************************************************} { TextRec and FileRec are put in a separate file to make it available to other units without putting it explicitly in systemh. This way we keep TP compatibility, and the TextRec definition is available for everyone who needs it. } {$ifdef FPC_HAS_FEATURE_FILEIO} {$i filerec.inc} {$endif FPC_HAS_FEATURE_FILEIO} {$i textrec.inc} {$ifdef FPC_HAS_FEATURE_EXITCODE} {$ifdef FPC_OBJFPC_EXTENDED_IF} {$if High(errorcode)<>maxExitCode} {$define FPC_LIMITED_EXITCODE} {$endif} {$else} {$define FPC_LIMITED_EXITCODE} {$endif FPC_OBJFPC_EXTENDED_IF} {$endif FPC_HAS_FEATURE_EXITCODE} Procedure HandleError (Errno : Longint); forward; Procedure HandleErrorFrame (Errno : longint;frame : Pointer); forward; Procedure HandleErrorAddrFrame (Errno : longint;addr,frame : Pointer); forward; {$ifdef FPC_HAS_FEATURE_TEXTIO} type FileFunc = Procedure(var t : TextRec); {$endif FPC_HAS_FEATURE_TEXTIO} const STACK_MARGIN = 16384; { Stack size margin for stack checking } { Random / Randomize constants } OldRandSeed : Cardinal = 0; { For Error Handling.} ErrorBase : Pointer = nil;public name 'FPC_ERRORBASE'; { Used by the ansi/widestrings and maybe also other things in the future } var { widechar, because also used by widestring -> pwidechar conversions } emptychar : widechar;public name 'FPC_EMPTYCHAR'; {$ifndef FPC_NO_GENERIC_STACK_CHECK} { if the OS does the stack checking, we don't need any stklen from the main program } initialstklen : SizeUint;external name '__stklen'; {$endif FPC_NO_GENERIC_STACK_CHECK} { checks whether the given suggested size for the stack of the current thread is acceptable. If this is the case, returns it unaltered. Otherwise it should return an acceptable value. Operating systems that automatically expand their stack on demand, should simply return a very large value. Operating systems which do not have a possibility to retrieve stack size information, should simply return the given stklen value (This is the default implementation). } {$ifdef FPC_HAS_FEATURE_STACKCHECK} function CheckInitialStkLen(stklen : SizeUInt) : SizeUInt; forward; {$endif FPC_HAS_FEATURE_STACKCHECK} {***************************************************************************** OS dependent Helpers/Syscalls *****************************************************************************} { for some OSes do_isdevice is defined in sysos.inc, but for others (win32) it isn't, and is used before the actual definition is encountered } {$ifdef FPC_HAS_FEATURE_FILEIO} function do_isdevice(handle:thandle):boolean;forward; {$endif FPC_HAS_FEATURE_FILEIO} {$i sysos.inc} {**************************************************************************** Include processor specific routines ****************************************************************************} {$ifdef FPC_USE_LIBC} { Under Haiku, bcopy cause a problem when searching for include file in the compiler. So, we use the internal implementation for now under BeOS and Haiku. } {$ifndef BEOS} { prefer libc implementations over our own, as they're most likely faster } {$i cgeneric.inc} { is now declared as external reference to another routine in the interface } {$i cgenstr.inc} {$endif} {$endif FPC_USE_LIBC} {$ifdef cpui386} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i i386.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpui386} {$ifdef cpum68k} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i m68k.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpum68k} {$ifdef cpux86_64} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i x86_64.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpux86_64} {$ifdef cpupowerpc32} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i powerpc.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpupowerpc32} {$ifdef cpupowerpc64} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i powerpc64.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpupowerpc64} {$ifdef cpualpha} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i alpha.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpualpha} {$ifdef cpuiA64} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i ia64.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpuiA64} {$ifdef cpusparc} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i sparc.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpusparc} {$ifdef cpuarm} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$if defined(CPUCORTEXM3) or defined(CPUARMV7M)} {$i thumb2.inc} { Case dependent, don't change } {$else} {$i arm.inc} { Case dependent, don't change } {$endif} {$define SYSPROCDEFINED} {$endif cpuarm} {$ifdef cpuavr} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i avr.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpuavr} {$ifdef cpumipsel} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} { there is no mipsel.inc, we use mips.inc instead } {$i mips.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$else not cpumipsel} {$ifdef cpumips} {$ifdef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} {$i mips.inc} { Case dependent, don't change } {$define SYSPROCDEFINED} {$endif cpumips} {$endif not cpumipsel} {$ifndef SYSPROCDEFINED} {$Error Can't determine processor type !} {$endif} procedure fillchar(var x;count : SizeInt;value : boolean); begin fillchar(x,count,byte(value)); end; procedure fillchar(var x;count : SizeInt;value : char); begin fillchar(x,count,byte(value)); end; procedure FillByte (var x;count : SizeInt;value : byte ); begin FillChar (X,Count,VALUE); end; function IndexChar(Const buf;len:SizeInt;b:char):SizeInt; begin IndexChar:=IndexByte(Buf,Len,byte(B)); end; function CompareChar(Const buf1,buf2;len:SizeInt):SizeInt; begin CompareChar:=CompareByte(buf1,buf2,len); end; procedure fpc_zeromem(p:pointer;len:ptruint); begin FillChar(p^,len,0); end; procedure fpc_fillmem(out data;len:ptruint;b : byte); begin FillByte(data,len,b); end; { Include generic pascal only routines which are not defined in the processor specific include file } {$I generic.inc} {**************************************************************************** Set Handling ****************************************************************************} { Include set support which is processor specific} {$i set.inc} { Include generic pascal routines for sets if the processor } { specific routines are not available. } {$i genset.inc} {**************************************************************************** Math Routines ****************************************************************************} function Hi(b : byte): byte;{$ifdef SYSTEMINLINE}inline;{$endif} begin Hi := b shr 4 end; function Lo(b : byte): byte;{$ifdef SYSTEMINLINE}inline;{$endif} begin Lo := b and $0f end; Function Swap (X : Word) : Word;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Swap := SwapEndian(X); End; Function Swap (X : Integer) : Integer;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Swap := SwapEndian(X); End; Function Swap (X : Longint) : Longint;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Swap:=(X and $ffff) shl 16 + (X shr 16) End; Function Swap (X : Cardinal) : Cardinal;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Swap:=(X and $ffff) shl 16 + (X shr 16) End; Function Swap (X : QWord) : QWord;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Swap:=(X and $ffffffff) shl 32 + (X shr 32); End; Function swap (X : Int64) : Int64;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Swap:=(X and $ffffffff) shl 32 + (X shr 32); End; {$ifdef SUPPORT_DOUBLE} operator := (b:real48) d:double;{$ifdef SYSTEMINLINE}inline;{$endif} begin D:=real2double(b); end; {$endif SUPPORT_DOUBLE} {$ifdef SUPPORT_EXTENDED} operator := (b:real48) e:extended;{$ifdef SYSTEMINLINE}inline;{$endif} begin e:=real2double(b); end; {$endif SUPPORT_EXTENDED} {$ifndef FPUNONE} {$ifdef FPC_USE_LIBC} { Include libc versions } {$i cgenmath.inc} {$endif FPC_USE_LIBC} { Include processor specific routines } {$I math.inc} { Include generic version } {$I genmath.inc} {$endif} {$i gencurr.inc} function aligntoptr(p : pointer) : pointer;inline; begin {$ifdef FPC_REQUIRES_PROPER_ALIGNMENT} result:=align(p,sizeof(p)); {$else FPC_REQUIRES_PROPER_ALIGNMENT} result:=p; {$endif FPC_REQUIRES_PROPER_ALIGNMENT} end; {**************************************************************************** Subroutines for String handling ****************************************************************************} { Needs to be before RTTI handling } {$i sstrings.inc} { requires sstrings.inc for initval } {$I int64p.inc} {$I int64.inc} {Requires int64.inc, since that contains the VAL functions for int64 and qword} {$ifdef FPC_HAS_FEATURE_ANSISTRINGS} {$i astrings.inc} {$endif FPC_HAS_FEATURE_ANSISTRINGS} {$ifdef FPC_HAS_FEATURE_WIDESTRINGS} {$ifndef FPC_WIDESTRING_EQUAL_UNICODESTRING} {$i wstrings.inc} {$endif FPC_WIDESTRING_EQUAL_UNICODESTRING} {$i ustrings.inc} {$endif FPC_HAS_FEATURE_WIDESTRINGS} {$i aliases.inc} {***************************************************************************** Dynamic Array support *****************************************************************************} {$ifdef FPC_HAS_FEATURE_DYNARRAYS} {$i dynarr.inc} {$endif FPC_HAS_FEATURE_DYNARRAYS} {***************************************************************************** Object Pascal support *****************************************************************************} {$ifdef FPC_HAS_FEATURE_CLASSES} {$i objpas.inc} {$endif FPC_HAS_FEATURE_CLASSES} {***************************************************************************** Variant support *****************************************************************************} {$ifdef FPC_HAS_FEATURE_VARIANTS} {$i variant.inc} {$endif FPC_HAS_FEATURE_VARIANTS} {**************************************************************************** Run-Time Type Information (RTTI) ****************************************************************************} {$ifdef FPC_HAS_FEATURE_RTTI} {$i rtti.inc} {$endif FPC_HAS_FEATURE_RTTI} {$if defined(FPC_HAS_FEATURE_RANDOM)} {---------------------------------------------------------------------- Mersenne Twister: A 623-Dimensionally Equidistributed Uniform Pseudo-Random Number Generator. What is Mersenne Twister? Mersenne Twister(MT) is a pseudorandom number generator developped by Makoto Matsumoto and Takuji Nishimura (alphabetical order) during 1996-1997. MT has the following merits: It is designed with consideration on the flaws of various existing generators. Far longer period and far higher order of equidistribution than any other implemented generators. (It is proved that the period is 2^19937-1, and 623-dimensional equidistribution property is assured.) Fast generation. (Although it depends on the system, it is reported that MT is sometimes faster than the standard ANSI-C library in a system with pipeline and cache memory.) Efficient use of the memory. (The implemented C-code mt19937.c consumes only 624 words of working area.) home page http://www.math.keio.ac.jp/~matumoto/emt.html original c source http://www.math.keio.ac.jp/~nisimura/random/int/mt19937int.c Coded by Takuji Nishimura, considering the suggestions by Topher Cooper and Marc Rieffel in July-Aug. 1997. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This library 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 Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with this library; if not, write to the Free Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA Copyright (C) 1997, 1999 Makoto Matsumoto and Takuji Nishimura. When you use this, send an email to: matumoto@math.keio.ac.jp with an appropriate reference to your work. REFERENCE M. Matsumoto and T. Nishimura, "Mersenne Twister: A 623-Dimensionally Equidistributed Uniform Pseudo-Random Number Generator", ACM Transactions on Modeling and Computer Simulation, Vol. 8, No. 1, January 1998, pp 3--30. Translated to OP and Delphi interface added by Roman Krejci (6.12.1999) http://www.rksolution.cz/delphi/tips.htm Revised 21.6.2000: Bug in the function RandInt_MT19937 fixed 2003/10/26: adapted to use the improved intialisation mentioned at and removed the assembler code ----------------------------------------------------------------------} {$R-} {range checking off} {$Q-} {overflow checking off} { Period parameter } Const MT19937N=624; Type tMT19937StateArray = array [0..MT19937N-1] of longint; // the array for the state vector { Period parameters } const MT19937M=397; MT19937MATRIX_A =$9908b0df; // constant vector a MT19937UPPER_MASK=longint($80000000); // most significant w-r bits MT19937LOWER_MASK=longint($7fffffff); // least significant r bits { Tempering parameters } TEMPERING_MASK_B=longint($9d2c5680); TEMPERING_MASK_C=longint($efc60000); VAR mt : tMT19937StateArray; const mti: longint=MT19937N+1; // mti=MT19937N+1 means mt[] is not initialized { Initializing the array with a seed } procedure sgenrand_MT19937(seed: longint); var i: longint; begin mt[0] := seed; for i := 1 to MT19937N-1 do begin mt[i] := 1812433253 * (mt[i-1] xor (mt[i-1] shr 30)) + i; { See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier. } { In the previous versions, MSBs of the seed affect } { only MSBs of the array mt[]. } { 2002/01/09 modified by Makoto Matsumoto } end; mti := MT19937N; end; function genrand_MT19937: longint; const mag01 : array [0..1] of longint =(0, longint(MT19937MATRIX_A)); var y: longint; kk: longint; begin if RandSeed<>OldRandSeed then mti:=MT19937N+1; if (mti >= MT19937N) { generate MT19937N longints at one time } then begin if mti = (MT19937N+1) then // if sgenrand_MT19937() has not been called, begin sgenrand_MT19937(randseed); // default initial seed is used { hack: randseed is not used more than once in this algorithm. Most } { user changes are re-initialising reandseed with the value it had } { at the start -> with the "not", we will detect this change. } { Detecting other changes is not useful, since the generated } { numbers will be different anyway. } randseed := not(randseed); oldrandseed := randseed; end; for kk:=0 to MT19937N-MT19937M-1 do begin y := (mt[kk] and MT19937UPPER_MASK) or (mt[kk+1] and MT19937LOWER_MASK); mt[kk] := mt[kk+MT19937M] xor (y shr 1) xor mag01[y and $00000001]; end; for kk:= MT19937N-MT19937M to MT19937N-2 do begin y := (mt[kk] and MT19937UPPER_MASK) or (mt[kk+1] and MT19937LOWER_MASK); mt[kk] := mt[kk+(MT19937M-MT19937N)] xor (y shr 1) xor mag01[y and $00000001]; end; y := (mt[MT19937N-1] and MT19937UPPER_MASK) or (mt[0] and MT19937LOWER_MASK); mt[MT19937N-1] := mt[MT19937M-1] xor (y shr 1) xor mag01[y and $00000001]; mti := 0; end; y := mt[mti]; inc(mti); y := y xor (y shr 11); y := y xor (y shl 7) and TEMPERING_MASK_B; y := y xor (y shl 15) and TEMPERING_MASK_C; y := y xor (y shr 18); Result := y; end; function random(l:longint): longint; begin { otherwise we can return values = l (JM) } if (l < 0) then inc(l); random := longint((int64(cardinal(genrand_MT19937))*l) shr 32); end; function random(l:int64): int64; begin { always call random, so the random generator cycles (TP-compatible) (JM) } random := int64((qword(cardinal(genrand_MT19937)) or ((qword(cardinal(genrand_MT19937)) shl 32))) and $7fffffffffffffff); if (l<>0) then random := random mod l else random := 0; end; {$ifndef FPUNONE} function random: extended; begin random := cardinal(genrand_MT19937) * (extended(1.0)/(int64(1) shl 32)); end; {$endif} {$endif FPC_HAS_FEATURE_RANDOM} {**************************************************************************** Memory Management ****************************************************************************} Function Ptr(sel,off : Longint) : farpointer;{$ifdef SYSTEMINLINE}inline;{$endif} Begin ptr:=farpointer((sel shl 4)+off); End; Function CSeg : Word;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Cseg:=0; End; Function DSeg : Word;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Dseg:=0; End; Function SSeg : Word;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Sseg:=0; End; {$push} {$R-} {$I-} {$Q-} {***************************************************************************** Miscellaneous *****************************************************************************} {$ifndef FPC_SYSTEM_HAS_GET_ADDR} { This provides a dummy implementation of get_addr function, for CPU's that don't need the instruction address to walk the stack. } function get_addr : pointer; begin get_addr:=nil; end; {$endif ndef FPC_SYSTEM_HAS_GET_ADDR} procedure fpc_rangeerror;[public,alias:'FPC_RANGEERROR']; compilerproc; begin HandleErrorAddrFrame(201,get_addr,get_frame); end; procedure fpc_divbyzero;[public,alias:'FPC_DIVBYZERO']; compilerproc; begin HandleErrorAddrFrame(200,get_addr,get_frame); end; procedure fpc_overflow;[public,alias:'FPC_OVERFLOW']; compilerproc; begin HandleErrorAddrFrame(215,get_addr,get_frame); end; procedure fpc_threaderror; [public,alias:'FPC_THREADERROR']; begin HandleErrorAddrFrame(6,get_addr,get_frame); end; procedure fpc_invalidpointer; [public,alias:'FPC_INVALIDPOINTER']; begin HandleErrorAddrFrame(216,get_addr,get_frame); end; procedure fpc_iocheck;[public,alias:'FPC_IOCHECK']; compilerproc; var l : longint; HInoutRes : PWord; begin HInOutRes:=@InoutRes; if HInOutRes^<>0 then begin l:=HInOutRes^; HInOutRes^:=0; HandleErrorAddrFrame(l,get_addr,get_frame); end; end; Function IOResult:Word; var HInoutRes : PWord; Begin HInoutRes:=@InoutRes; IOResult:=HInOutRes^; HInOutRes^:=0; End; Function GetThreadID:TThreadID;{$ifdef SYSTEMINLINE}inline;{$endif} begin (* ThreadID is stored in a threadvar and made available in interface *) (* to allow setup of this value during thread initialization. *) GetThreadID := ThreadID; end; function fpc_safecallcheck(res : hresult) : hresult;[public,alias:'FPC_SAFECALLCHECK']; compilerproc; {$ifdef CPU86} register; {$endif} begin if res<0 then begin if assigned(SafeCallErrorProc) then SafeCallErrorProc(res,get_frame); HandleErrorAddrFrame(229,get_addr,get_frame); end; result:=res; end; {***************************************************************************** Stack check code *****************************************************************************} { be compatible with old code } {$ifdef FPC_NO_GENERIC_STACK_CHECK} {$define NO_GENERIC_STACK_CHECK} {$endif FPC_NO_GENERIC_STACK_CHECK} {$IFNDEF NO_GENERIC_STACK_CHECK} {$PUSH} {$S-} procedure fpc_stackcheck(stack_size:SizeUInt);[public,alias:'FPC_STACKCHECK']; var c : Pointer; begin { Avoid recursive calls when called from the exit routines } if StackError then exit; { don't use sack_size, since the stack pointer has already been decreased when this routine is called } c := Sptr - STACK_MARGIN; if (c <= StackBottom) then begin StackError:=true; HandleError(202); end; end; {$POP} {$ENDIF NO_GENERIC_STACK_CHECK} {***************************************************************************** Initialization / Finalization *****************************************************************************} const maxunits=1024; { See also files.pas of the compiler source } type TInitFinalRec=record InitProc, FinalProc : TProcedure; end; TInitFinalTable = record TableCount, InitCount : longint; Procs : array[1..maxunits] of TInitFinalRec; end; PInitFinalTable = ^TInitFinalTable; {$ifndef FPC_HAS_INDIRECT_MAIN_INFORMATION} var InitFinalTable : TInitFinalTable;external name 'INITFINAL'; {$endif FPC_HAS_INDIRECT_MAIN_INFORMATION} procedure fpc_InitializeUnits;[public,alias:'FPC_INITIALIZEUNITS']; compilerproc; var i : longint; begin { call cpu/fpu initialisation routine } fpc_cpuinit; {$ifdef FPC_HAS_INDIRECT_MAIN_INFORMATION} with PInitFinalTable(EntryInformation.InitFinalTable)^ do {$else FPC_HAS_INDIRECT_MAIN_INFORMATION} with InitFinalTable do {$endif FPC_HAS_INDIRECT_MAIN_INFORMATION} begin for i:=1 to TableCount do begin if assigned(Procs[i].InitProc) then Procs[i].InitProc(); InitCount:=i; end; end; if assigned(InitProc) then TProcedure(InitProc)(); end; procedure internal_initializeunits; external name 'FPC_INITIALIZEUNITS'; procedure fpc_LibInitializeUnits;[public,alias:'FPC_LIBINITIALIZEUNITS']; begin {$ifdef FPC_HAS_FEATURE_DYNLIBS} IsLibrary:=true; { must also be set to true for packages when implemented } ModuleIsLib:=true; internal_initializeunits; {$endif FPC_HAS_FEATURE_DYNLIBS} end; procedure FinalizeUnits;[public,alias:'FPC_FINALIZEUNITS']; begin {$ifdef FPC_HAS_INDIRECT_MAIN_INFORMATION} with PInitFinalTable(EntryInformation.InitFinalTable)^ do {$else FPC_HAS_INDIRECT_MAIN_INFORMATION} with InitFinalTable do {$endif FPC_HAS_INDIRECT_MAIN_INFORMATION} begin while (InitCount>0) do begin // we've to decrement the cound before calling the final. code // else a halt in the final. code leads to a endless loop dec(InitCount); if assigned(Procs[InitCount+1].FinalProc) then Procs[InitCount+1].FinalProc(); end; end; end; {***************************************************************************** Error / Exit / ExitProc *****************************************************************************} Procedure system_exit;forward; {$ifdef FPC_HAS_FEATURE_HEAP} {$ifndef HAS_MEMORYMANAGER} //not needed if independant memory manager Procedure FinalizeHeap;forward; {$endif HAS_MEMORYMANAGER} {$endif FPC_HAS_FEATURE_HEAP} {$ifdef FPC_HAS_FEATURE_CONSOLEIO} procedure SysFlushStdIO; begin { Make sure that all output is written to the redirected file } if Textrec(Output).Mode=fmOutput then Flush(Output); if Textrec(ErrOutput).Mode=fmOutput then Flush(ErrOutput); if Textrec(stdout).Mode=fmOutput then Flush(stdout); if Textrec(StdErr).Mode=fmOutput then Flush(StdErr); end; {$endif FPC_HAS_FEATURE_CONSOLEIO} Procedure InternalExit; var current_exit : Procedure; {$ifdef FPC_HAS_FEATURE_CONSOLEIO} pstdout : ^Text; {$endif} {$if defined(MSWINDOWS) or defined(OS2)} i : longint; {$endif} Begin {$ifdef SYSTEMDEBUG} writeln('InternalExit'); {$endif SYSTEMDEBUG} while exitProc<>nil Do Begin InOutRes:=0; current_exit:=tProcedure(exitProc); exitProc:=nil; current_exit(); End; { Finalize units } FinalizeUnits; {$ifdef FPC_HAS_FEATURE_CONSOLEIO} { the embedded system unit itself contains no routines for console i/o console i/o is done by the Consoleio unit which can do things like redirection to seriell i/o } {$ifndef EMBEDDED} { Show runtime error and exit } pstdout:=@stdout; If erroraddr<>nil Then Begin Writeln(pstdout^,'Runtime error ',Errorcode,' at $',hexstr(erroraddr)); { to get a nice symify } Writeln(pstdout^,BackTraceStrFunc(Erroraddr)); dump_stack(pstdout^,ErrorBase); Writeln(pstdout^,''); End; SysFlushStdIO; {$endif EMBEDDED} {$endif FPC_HAS_FEATURE_CONSOLEIO} {$if defined(MSWINDOWS) or defined(OS2)} { finally release the heap if possible, especially important for DLLs. Reset the array to nil, and finally also argv itself to avoid double freeing problem in case this function gets called twice. } if assigned(argv) then begin for i:=0 to argc-1 do if assigned(argv[i]) then begin sysfreemem(argv[i]); argv[i]:=nil; end; sysfreemem(argv); argv:=nil; end; {$endif} {$ifdef LINUX} {sysfreemem already checks for nil} sysfreemem(calculated_cmdline); {$endif} {$ifdef BSD} sysfreemem(cmdline); {$endif} {$ifdef FPC_HAS_FEATURE_HEAP} {$ifndef HAS_MEMORYMANAGER} FinalizeHeap; {$endif HAS_MEMORYMANAGER} {$endif FPC_HAS_FEATURE_HEAP} End; Procedure do_exit;[Public,Alias:'FPC_DO_EXIT']; begin InternalExit; System_exit; end; Procedure lib_exit;[Public,Alias:'FPC_LIB_EXIT']; begin InternalExit; end; Procedure Halt(ErrNum: Longint); Begin {$ifdef FPC_HAS_FEATURE_EXITCODE} {$ifdef FPC_LIMITED_EXITCODE} if ErrNum > maxExitCode then ExitCode:=255 else {$endif FPC_LIMITED_EXITCODE} ExitCode:=ErrNum; {$endif FPC_HAS_FEATURE_EXITCODE} Do_Exit; end; function SysBackTraceStr (Addr: Pointer): ShortString; begin SysBackTraceStr:=' $'+hexstr(addr); end; Procedure HandleErrorAddrFrame (Errno : longint;addr,frame : Pointer);[public,alias:'FPC_BREAK_ERROR']; {$ifdef CPU86} register; {$endif} begin If pointer(ErrorProc)<>Nil then ErrorProc(Errno,addr,frame); errorcode:=word(Errno); erroraddr:=addr; errorbase:=frame; {$ifdef FPC_HAS_FEATURE_EXCEPTIONS} if ExceptAddrStack <> nil then raise TObject(nil) at addr,frame; {$endif FPC_HAS_FEATURE_EXCEPTIONS} Halt(errorcode); end; Procedure HandleErrorFrame (Errno : longint;frame : Pointer); { Procedure to handle internal errors, i.e. not user-invoked errors Internal function should ALWAYS call HandleError instead of RunError. Can be used for exception handlers to specify the frame } begin HandleErrorAddrFrame(Errno,get_caller_addr(frame),get_caller_frame(frame)); end; Procedure HandleError (Errno : longint);[public,alias : 'FPC_HANDLEERROR']; { Procedure to handle internal errors, i.e. not user-invoked errors Internal function should ALWAYS call HandleError instead of RunError. } begin HandleErrorAddrFrame(Errno,get_frame,get_addr); end; procedure RunError(w : word);[alias: 'FPC_RUNERROR']; begin errorcode:=w; erroraddr:=get_caller_addr(get_frame,get_addr); errorbase:=get_caller_frame(get_frame,get_addr); Halt(errorcode); end; Procedure RunError;{$ifdef SYSTEMINLINE}inline;{$endif} Begin RunError (0); End; Procedure Halt;{$ifdef SYSTEMINLINE}inline;{$endif} Begin Halt(0); End; Procedure Error(RunTimeError : TRunTimeError); begin RunError(RuntimeErrorExitCodes[RunTimeError]); end; Procedure dump_stack(var f : text;bp,addr : Pointer); var i : Longint; prevbp : Pointer; prevaddr : pointer; is_dev : boolean; caller_frame, caller_addr : Pointer; Begin {$ifdef FPC_HAS_FEATURE_EXCEPTIONS} try {$endif FPC_HAS_FEATURE_EXCEPTIONS} prevbp:=bp-1; prevaddr:=nil; i:=0; is_dev:=do_isdevice(textrec(f).Handle); while bp > prevbp Do Begin caller_addr := get_caller_addr(bp,addr); caller_frame := get_caller_frame(bp,addr); if (caller_addr=nil) then break; Writeln(f,BackTraceStrFunc(caller_addr)); if (caller_frame=nil) then break; Inc(i); If ((i>max_frame_dump) and is_dev) or (i>256) Then break; prevbp:=bp; prevaddr:=addr; bp:=caller_frame; addr:=caller_addr; End; {$ifdef FPC_HAS_FEATURE_EXCEPTIONS} except { prevent endless dump if an exception occured } end; {$endif FPC_HAS_FEATURE_EXCEPTIONS} End; {$ifdef FPC_HAS_FEATURE_EXCEPTIONS} procedure DumpExceptionBackTrace(var f:text); var FrameNumber, FrameCount : longint; Frames : PPointer; begin if RaiseList=nil then exit; WriteLn(f,BackTraceStrFunc(RaiseList^.Addr)); FrameCount:=RaiseList^.Framecount; Frames:=RaiseList^.Frames; for FrameNumber := 0 to FrameCount-1 do WriteLn(f,BackTraceStrFunc(Frames[FrameNumber])); end; {$endif FPC_HAS_FEATURE_EXCEPTIONS} {$ifdef FPC_HAS_FEATURE_HEAP} Type PExitProcInfo = ^TExitProcInfo; TExitProcInfo = Record Next : PExitProcInfo; SaveExit : Pointer; Proc : TProcedure; End; const ExitProcList: PExitProcInfo = nil; Procedure DoExitProc; var P : PExitProcInfo; Proc : TProcedure; Begin P:=ExitProcList; ExitProcList:=P^.Next; ExitProc:=P^.SaveExit; Proc:=P^.Proc; DisPose(P); Proc(); End; Procedure AddExitProc(Proc: TProcedure); var P : PExitProcInfo; Begin New(P); P^.Next:=ExitProcList; P^.SaveExit:=ExitProc; P^.Proc:=Proc; ExitProcList:=P; ExitProc:=@DoExitProc; End; {$endif FPC_HAS_FEATURE_HEAP} {$ifdef FPC_HAS_FEATURE_HEAP} function ArrayStringToPPchar(const S:Array of AnsiString;reserveentries:Longint):ppchar; // const ? // Extra allocate reserveentries pchar's at the beginning (default param=0 after 1.0.x ?) // Note: for internal use by skilled programmers only // if "s" goes out of scope in the parent procedure, the pointer is dangling. var p : ppchar; i : LongInt; begin if High(s)#0) do // count nr of args begin while (buf^ in [' ',#9,#10]) do // Kill separators. inc(buf); inc(nr); if buf^='"' Then // quotes argument? begin inc(buf); while not (buf^ in [#0,'"']) do // then end of argument is end of string or next quote inc(buf); if buf^='"' then // skip closing quote. inc(buf); end else begin // else std while not (buf^ in [' ',#0,#9,#10]) do inc(buf); end; end; getmem(p,(ReserveEntries+nr)*sizeof(pchar)); StringToPPChar:=p; if p=nil then begin {$ifdef xunix} fpseterrno(ESysEnomem); {$endif} exit; end; for i:=1 to ReserveEntries do inc(p); // skip empty slots buf:=s; while (buf^<>#0) do begin while (buf^ in [' ',#9,#10]) do // Kill separators. begin buf^:=#0; inc(buf); end; if buf^='"' Then // quotes argument? begin inc(buf); p^:=buf; inc(p); p^:=nil; while not (buf^ in [#0,'"']) do // then end of argument is end of string or next quote inc(buf); if buf^='"' then // skip closing quote. begin buf^:=#0; inc(buf); end; end else begin p^:=buf; inc(p); p^:=nil; while not (buf^ in [' ',#0,#9,#10]) do inc(buf); end; end; end; {$endif FPC_HAS_FEATURE_HEAP} {***************************************************************************** Abstract/Assert support. *****************************************************************************} procedure fpc_AbstractErrorIntern;compilerproc;[public,alias : 'FPC_ABSTRACTERROR']; begin If pointer(AbstractErrorProc)<>nil then AbstractErrorProc(); HandleErrorAddrFrame(211,get_addr,get_frame); end; Procedure fpc_assert(Const Msg,FName:Shortstring;LineNo:Longint; ErrorAddr:Pointer); [Public,Alias : 'FPC_ASSERT']; compilerproc; begin if pointer(AssertErrorProc)<>nil then AssertErrorProc(Msg,FName,LineNo,ErrorAddr) else HandleErrorAddrFrame(227,get_addr,get_frame); end; Procedure SysAssert(Const Msg,FName:Shortstring;LineNo:Longint;ErrorAddr:Pointer); begin {$ifdef FPC_HAS_FEATURE_CONSOLEIO} If msg='' then write(stderr,'Assertion failed') else write(stderr,msg); Writeln(stderr,' (',FName,', line ',LineNo,').'); Writeln(stderr,''); Halt(227); {$endif FPC_HAS_FEATURE_CONSOLEIO} end; {***************************************************************************** SetJmp/LongJmp support. *****************************************************************************} {$i setjump.inc} {$pop} //{$I-,R-,Q-} before 'procedure fpc_rangeerror' {***************************************************************************** Heap *****************************************************************************} {$i sysheap.inc} {$i heap.inc} {***************************************************************************** Thread support *****************************************************************************} {$ifdef FPC_HAS_FEATURE_THREADING} { Generic threadmanager } {$i thread.inc} { Generic threadvar support } {$i threadvr.inc} {$ifdef DISABLE_NO_THREAD_MANAGER} { OS Dependent implementation } {$i systhrd.inc} {$endif DISABLE_NO_THREAD_MANAGER} {$endif FPC_HAS_FEATURE_THREADING} {***************************************************************************** File Handling *****************************************************************************} {$ifdef FPC_HAS_FEATURE_FILEIO} { Allow slash and backslash as separators } procedure DoDirSeparators(p:Pchar); var i : longint; begin for i:=0 to strlen(p) do if p[i] in AllowDirectorySeparators then p[i]:=DirectorySeparator; end; procedure DoDirSeparators(var p:shortstring); var i : longint; begin for i:=1 to length(p) do if p[i] in AllowDirectorySeparators then p[i]:=DirectorySeparator; end; {$endif FPC_HAS_FEATURE_FILEIO} { OS dependent low level file functions } {$ifdef FPC_HAS_FEATURE_FILEIO} {$i sysfile.inc} {$endif FPC_HAS_FEATURE_FILEIO} { Text file } {$i text.inc} {$ifdef FPC_HAS_FEATURE_FILEIO} { Untyped file } {$i file.inc} { Typed file } {$i typefile.inc} {$endif FPC_HAS_FEATURE_FILEIO} {***************************************************************************** Directory Handling *****************************************************************************} {$ifdef FPC_HAS_FEATURE_FILEIO} { OS dependent dir functions } {$i sysdir.inc} {$endif FPC_HAS_FEATURE_FILEIO} {$if defined(FPC_HAS_FEATURE_FILEIO) and defined(FPC_HAS_FEATURE_ANSISTRINGS)} Procedure getdir(drivenr:byte;Var dir:ansistring); { this is needed to also allow ansistrings, the shortstring version is OS dependent } var s : shortstring; begin getdir(drivenr,s); dir:=s; end; {$endif} {$if defined(FPC_HAS_FEATURE_FILEIO)} Procedure MkDir(Const s: String); Var Buffer: Array[0..255] of Char; Begin If (s='') or (InOutRes <> 0) then exit; Move(s[1], Buffer, Length(s)); Buffer[Length(s)] := #0; MkDir(@buffer[0],length(s)); End; Procedure RmDir(Const s: String); Var Buffer: Array[0..255] of Char; Begin If (s='') or (InOutRes <> 0) then exit; Move(s[1], Buffer, Length(s)); Buffer[Length(s)] := #0; RmDir(@buffer[0],length(s)); End; Procedure ChDir(Const s: String); Var Buffer: Array[0..255] of Char; Begin If (s='') or (InOutRes <> 0) then exit; Move(s[1], Buffer, Length(s)); Buffer[Length(s)] := #0; ChDir(@buffer[0],length(s)); End; {$endif} {***************************************************************************** Resources support *****************************************************************************} {$i sysres.inc} const CtrlBreakHandler: TCtrlBreakHandler = nil; {$IFNDEF FPC_HAS_SETCTRLBREAKHANDLER} (* It is possible to provide platform specific implementation performing *) (* special initialization; default implementation just sets the procedural *) (* variable to make it available for use from the exception handler. *) function SysSetCtrlBreakHandler (Handler: TCtrlBreakHandler): TCtrlBreakHandler; begin (* Return either nil or previous handler *) SysSetCtrlBreakHandler := CtrlBreakHandler; CtrlBreakHandler := Handler; end; {$ENDIF FPC_HAS_SETCTRLBREAKHANDLER}