// @(#)root/unix:$Id: TUnixSystem.cxx 21721 2008-01-15 17:34:03Z rdm $
// Author: Fons Rademakers   15/09/95

/*************************************************************************
 * Copyright (C) 1995-2000, Rene Brun and Fons Rademakers.               *
 * All rights reserved.                                                  *
 *                                                                       *
 * For the licensing terms see $ROOTSYS/LICENSE.                         *
 * For the list of contributors see $ROOTSYS/README/CREDITS.             *
 *************************************************************************/

//////////////////////////////////////////////////////////////////////////
//                                                                      //
// TUnixSystem                                                          //
//                                                                      //
// Class providing an interface to the UNIX Operating System.           //
//                                                                      //
//////////////////////////////////////////////////////////////////////////

#include "RConfigure.h"
#include "RConfig.h"
#include "TUnixSystem.h"
#include "TROOT.h"
#include "TError.h"
#include "TOrdCollection.h"
#include "TRegexp.h"
#include "TPRegexp.h"
#include "TException.h"
#include "Demangle.h"
#include "TEnv.h"
#include "TSocket.h"
#include "Getline.h"
#include "TInterpreter.h"
#include "TApplication.h"
#include "TObjString.h"
#include "Riostream.h"
#include "TVirtualMutex.h"
#include "TObjArray.h"
#include <map>

//#define G__OLDEXPAND

#include <unistd.h>
#include <stdlib.h>
#include <sys/types.h>
#if defined(R__SUN) || defined(R__SGI) || defined(R__HPUX) || \
    defined(R__AIX) || defined(R__LINUX) || defined(R__SOLARIS) || \
    defined(R__ALPHA) || defined(R__HIUX) || defined(R__FBSD) || \
    defined(R__OBSD) || defined(R__MACOSX) || defined(R__HURD)
#define HAS_DIRENT
#endif
#ifdef HAS_DIRENT
#   include <dirent.h>
#else
#   include <sys/dir.h>
#endif
#if defined(ULTRIX) || defined(R__SUN)
#   include <sgtty.h>
#endif
#if defined(R__AIX) || defined(R__LINUX) || defined(R__ALPHA) || \
    defined(R__SGI) || defined(R__HIUX) || defined(R__FBSD) || \
    defined(R__OBSD) || defined(R__LYNXOS) || defined(R__MACOSX) || \
    defined(R__HURD)
#   include <sys/ioctl.h>
#endif
#if defined(R__AIX) || defined(R__SOLARIS)
#   include <sys/select.h>
#endif
#if defined(R__LINUX) || defined(R__HURD)
#   ifndef SIGSYS
#      define SIGSYS  SIGUNUSED       // SIGSYS does not exist in linux ??
#   endif
#endif
#if defined(R__ALPHA)
#   include <sys/mount.h>
#   ifndef R__TRUE64
   extern "C" int statfs(const char *file, struct statfs *buffer);
#   endif
#elif defined(R__MACOSX)
#   include <mach-o/dyld.h>
#   include <sys/mount.h>
   extern "C" int statfs(const char *file, struct statfs *buffer);
#elif defined(R__LINUX) || defined(R__HPUX) || defined(R__HURD)
#   include <sys/vfs.h>
#elif defined(R__FBSD) || defined(R__OBSD)
#   include <sys/param.h>
#   include <sys/mount.h>
#else
#   include <sys/statfs.h>
#endif

#include <utime.h>
#include <syslog.h>
#include <sys/stat.h>
#include <setjmp.h>
#include <signal.h>
#include <sys/param.h>
#include <pwd.h>
#include <grp.h>
#include <errno.h>
#include <sys/wait.h>
#include <time.h>
#include <sys/time.h>
#include <sys/file.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <netinet/tcp.h>
#if defined(R__AIX)
#   define _XOPEN_EXTENDED_SOURCE
#   include <arpa/inet.h>
#   undef _XOPEN_EXTENDED_SOURCE
#   if !defined(_AIX41) && !defined(_AIX43)
    // AIX 3.2 doesn't have it
#   define HASNOT_INETATON
#   endif
#else
#   include <arpa/inet.h>
#endif
#include <sys/un.h>
#include <netdb.h>
#include <fcntl.h>
#if defined(R__SGI)
#   include <net/soioctl.h>
#endif
#if defined(R__SOLARIS)
#   include <sys/systeminfo.h>
#   include <sys/filio.h>
#   include <sys/sockio.h>
#   define HASNOT_INETATON
#   define INADDR_NONE (UInt_t)-1
#endif
#if defined(R__HPUX)
#   include <symlink.h>
#   include <dl.h>
#   if defined(R__GNU)
   extern "C" {
      extern shl_t cxxshl_load(const char *path, int flags, long address);
      extern int   cxxshl_unload(shl_t handle);
   }
#   elif !defined(__STDCPP__)
#      include <cxxdl.h>
#   endif
#   if defined(hpux9)
   extern "C" {
      extern void openlog(const char *, int, int);
      extern void syslog(int, const char *, ...);
      extern void closelog(void);
      extern int setlogmask(int);
   }
#   define HASNOT_INETATON
#   endif
#endif
#if defined(R__ALPHA) && !defined(R__GNU)
#   define HASNOT_INETATON
#endif
#if defined(R__HIUX)
#   define HASNOT_INETATON
#endif

#if defined(R__SGI) || defined(R__SOLARIS)
#   define HAVE_UTMPX_H
#   define UTMP_NO_ADDR
#endif

#if defined(MAC_OS_X_VERSION_10_5)
#   define HAVE_UTMPX_H
#   define UTMP_NO_ADDR
#   ifndef ut_user
#      define ut_user ut_name
#   endif
#endif

#if defined(R__ALPHA) || defined(R__AIX) || defined(R__FBSD) || \
    defined(R__OBSD) || defined(R__LYNXOS) || \
    (defined(R__MACOSX) && !defined(MAC_OS_X_VERSION_10_5))
#   define UTMP_NO_ADDR
#endif

#if (defined(R__AIX) && !defined(_AIX43)) || \
    (defined(R__FBSD) && !defined(R__ALPHA)) || \
    (defined(R__SUNGCC3) && !defined(__arch64__))
#   define USE_SIZE_T
#elif defined(R__GLIBC) || (defined(R__FBSD) && defined(R__ALPHA)) || \
      (defined(R__SUNGCC3) && defined(__arch64__)) || \
      defined(R__OBSD) || defined(MAC_OS_X_VERSION_10_4) || \
      (defined(R__AIX) && defined(_AIX43))
#   define USE_SOCKLEN_T
#endif

#if defined(R__LYNXOS)
extern "C" {
   extern int putenv(const char *);
   extern int inet_aton(const char *, struct in_addr *);
};
#endif

#ifdef HAVE_UTMPX_H
#include <utmpx.h>
#define STRUCT_UTMP struct utmpx
#else
#include <utmp.h>
#define STRUCT_UTMP struct utmp
#endif
#if !defined(UTMP_FILE) && defined(_PATH_UTMP)      // 4.4BSD
#define UTMP_FILE _PATH_UTMP
#endif
#if defined(UTMPX_FILE)                             // Solaris, SysVr4
#undef  UTMP_FILE
#define UTMP_FILE UTMPX_FILE
#endif
#ifndef UTMP_FILE
#define UTMP_FILE "/etc/utmp"
#endif

// stack trace code
#if defined(R__HPUX) && !defined(R__GNU)
#   define HAVE_U_STACK_TRACE
#endif
#if defined(R__AIX)
// #   define HAVE_XL_TRBK   // does not work as expected
#endif
#if defined(R__LINUX) || defined(R__HURD)
#   if __GLIBC__ == 2 && __GLIBC_MINOR__ >= 1
#      define HAVE_BACKTRACE_SYMBOLS_FD
#   endif
#   define HAVE_DLADDR
#endif
#if defined(R__MACOSX)
#   define USE_GDB_STACK_TRACE
#endif

#ifdef HAVE_U_STACK_TRACE
   // HP-UX stack walker (http://devresource.hp.com/STK/partner/unwind.pdf)
   extern "C" void U_STACK_TRACE(void);
#endif
#ifdef HAVE_XL_TRBK
   // AIX stack walker (from xlf FORTRAN 90 runtime).
   extern "C" void xl__trbk(void);
#endif
#ifdef HAVE_BACKTRACE_SYMBOLS_FD
#   include <execinfo.h>
#endif
#ifdef HAVE_DLADDR
#   ifndef __USE_GNU
#      define __USE_GNU
#   endif
#   include <dlfcn.h>
#endif

#ifdef HAVE_BACKTRACE_SYMBOLS_FD
   // The maximum stack trace depth for systems where we request the
   // stack depth separately (currently glibc-based systems).
   static const int kMAX_BACKTRACE_DEPTH = 128;
#endif

// FPE handling includes
#if (defined(R__LINUX) && !defined(R__WINGCC))
#include <fpu_control.h>
#include <fenv.h>
#endif

#if defined(R__MACOSX) && !defined(__xlC__) && !defined(__i386__) && \
   !defined(__x86_64__)
#include <fenv.h>
#include <signal.h>
#include <ucontext.h>
#include <stdlib.h>
#include <stdio.h>
#include <mach/thread_status.h>

#define fegetenvd(x) asm volatile("mffs %0" : "=f" (x));
#define fesetenvd(x) asm volatile("mtfsf 255,%0" : : "f" (x));

enum {
  FE_ENABLE_INEXACT    = 0x00000008,
  FE_ENABLE_DIVBYZERO  = 0x00000010,
  FE_ENABLE_UNDERFLOW  = 0x00000020,
  FE_ENABLE_OVERFLOW   = 0x00000040,
  FE_ENABLE_INVALID    = 0x00000080,
  FE_ENABLE_ALL_EXCEPT = 0x000000F8
};
#endif

#if defined(R__MACOSX) && (defined(__i386__) || defined(__x86_64__))
#include <fenv.h>
#endif
// End FPE handling includes


static STRUCT_UTMP *gUtmpContents;


const char *kServerPath     = "/tmp";
const char *kProtocolName   = "tcp";

//------------------- Unix TFdSet ----------------------------------------------
#ifndef HOWMANY
#   define HOWMANY(x, y)   (((x)+((y)-1))/(y))
#endif

const Int_t kNFDBITS = (sizeof(Long_t) * 8);  // 8 bits per byte
#ifdef FD_SETSIZE
const Int_t kFDSETSIZE = FD_SETSIZE;          // Linux = 1024 file descriptors
#else
const Int_t kFDSETSIZE = 256;                 // upto 256 file descriptors
#endif


class TFdSet {
private:
   ULong_t fds_bits[HOWMANY(kFDSETSIZE, kNFDBITS)];
public:
   TFdSet() { memset(fds_bits, 0, sizeof(fds_bits)); }
   TFdSet(const TFdSet &org) { memcpy(fds_bits, org.fds_bits, sizeof(org.fds_bits)); }
   TFdSet &operator=(const TFdSet &rhs) { if (this != &rhs) { memcpy(fds_bits, rhs.fds_bits, sizeof(rhs.fds_bits));} return *this; }
   void   Zero() { memset(fds_bits, 0, sizeof(fds_bits)); }
   void   Set(Int_t n)
   {
      if (n >= 0 && n < kFDSETSIZE) {
         fds_bits[n/kNFDBITS] |= (1UL << (n % kNFDBITS));
      } else {
         ::Fatal("TFdSet::Set","fd (%d) out of range [0..%d]", n, kFDSETSIZE-1);
      }
   }
   void   Clr(Int_t n)
   {
      if (n >= 0 && n < kFDSETSIZE) {
         fds_bits[n/kNFDBITS] &= ~(1UL << (n % kNFDBITS));
      } else {
         ::Fatal("TFdSet::Clr","fd (%d) out of range [0..%d]", n, kFDSETSIZE-1);
      }
   }
   Int_t  IsSet(Int_t n)
   {
      if (n >= 0 && n < kFDSETSIZE) {
         return (fds_bits[n/kNFDBITS] & (1UL << (n % kNFDBITS))) != 0;
      } else {
         ::Fatal("TFdSet::IsSet","fd (%d) out of range [0..%d]", n, kFDSETSIZE-1);
         return 0;
      }
   }
   ULong_t *GetBits() { return (ULong_t *)fds_bits; }
};

//______________________________________________________________________________
static void SigHandler(ESignals sig)
{
   // Unix signal handler.

   if (gSystem)
      ((TUnixSystem*)gSystem)->DispatchSignals(sig);
}

#if defined(R__MACOSX)
static TString gLinkedDylibs;

//______________________________________________________________________________
static void DylibAdded(const struct mach_header *mh, intptr_t /* vmaddr_slide */)
{
   static int i = 0;
   static Bool_t gotFirstSo = kFALSE;
   static TString linkedDylibs;

   // to copy the local linkedDylibs to the global gLinkedDylibs call this
   // function with mh==0
   if (!mh) {
      gLinkedDylibs = linkedDylibs;
      return;
   }

   TString lib = _dyld_get_image_name(i++);

   //printf("%s %p\n", lib.Data(), mh);

   // when first .so is loaded we have finished loading all dylibs
   // explicitly linked against the executable. Additional dylibs
   // come when they are explicitly linked against loaded so's, currentky
   // we are not interested in these
   if (lib.EndsWith(".so"))
      gotFirstSo = kTRUE;

   // "libSystem.B.dylib" is always add by the linker, so no need to add it
   if (!gotFirstSo && lib.EndsWith(".dylib") && !lib.EndsWith("/libSystem.B.dylib")) {
      if (i > 1)
         linkedDylibs += " ";
      linkedDylibs += lib;
   }
}
#endif


ClassImp(TUnixSystem)

//______________________________________________________________________________
TUnixSystem::TUnixSystem() : TSystem("Unix", "Unix System")
{ }

//______________________________________________________________________________
TUnixSystem::~TUnixSystem()
{
   // Reset to original state.

   UnixResetSignals();

   delete fReadmask;
   delete fWritemask;
   delete fReadready;
   delete fWriteready;
   delete fSignals;
}

//______________________________________________________________________________
Bool_t TUnixSystem::Init()
{
   // Initialize Unix system interface.

   if (TSystem::Init())
      return kTRUE;

   fReadmask   = new TFdSet;
   fWritemask  = new TFdSet;
   fReadready  = new TFdSet;
   fWriteready = new TFdSet;
   fSignals    = new TFdSet;

   //--- install default handlers
   UnixSignal(kSigChild,                 SigHandler);
   UnixSignal(kSigBus,                   SigHandler);
   UnixSignal(kSigSegmentationViolation, SigHandler);
   UnixSignal(kSigIllegalInstruction,    SigHandler);
   UnixSignal(kSigSystem,                SigHandler);
   UnixSignal(kSigPipe,                  SigHandler);
   UnixSignal(kSigAlarm,                 SigHandler);
   UnixSignal(kSigUrgent,                SigHandler);
   UnixSignal(kSigFloatingException,     SigHandler);
   UnixSignal(kSigWindowChanged,         SigHandler);

#ifndef ROOTPREFIX
   gRootDir = Getenv("ROOTSYS");
   if (gRootDir == 0)
      gRootDir= "/usr/local/root";
#else
   gRootDir = ROOTPREFIX;
#endif

#if defined(R__MACOSX)
   // trap loading of all dylibs to register dylib name
   _dyld_register_func_for_add_image(DylibAdded);
#endif

   return kFALSE;
}

//---- Misc --------------------------------------------------------------------

//______________________________________________________________________________
void TUnixSystem::SetProgname(const char *name)
{
   // Set the application name (from command line, argv[0]) and copy it in
   // gProgName. Copy the application pathname in gProgPath.

   if (name && strlen(name) > 0) {
      gProgName = StrDup(BaseName(name));
      char *w   = Which(Getenv("PATH"), gProgName);
      gProgPath = StrDup(DirName(w));
      delete [] w;
   }
}

//______________________________________________________________________________
void TUnixSystem::SetDisplay()
{
   // Set DISPLAY environment variable based on utmp entry. Only for UNIX.

   if (!Getenv("DISPLAY")) {
      char *tty = ::ttyname(0);  // device user is logged in on
      if (tty) {
         tty += 5;               // remove "/dev/"

         R__LOCKGUARD2(gSystemMutex);

         STRUCT_UTMP *utmp_entry = (STRUCT_UTMP *)SearchUtmpEntry(ReadUtmpFile(), tty);
         if (utmp_entry) {
            if (utmp_entry->ut_host[0])
               if (strchr(utmp_entry->ut_host, ':')) {
                  Setenv("DISPLAY", utmp_entry->ut_host);
                  Warning("SetDisplay", "DISPLAY not set, setting it to %s",
                          utmp_entry->ut_host);
               } else {
                  char disp[64];
                  sprintf(disp, "%s:0.0", utmp_entry->ut_host);
                  Setenv("DISPLAY", disp);
                  Warning("SetDisplay", "DISPLAY not set, setting it to %s",
                          disp);
               }
#ifndef UTMP_NO_ADDR
            else if (utmp_entry->ut_addr) {
               struct hostent *he;
               if ((he = gethostbyaddr((const char*)&utmp_entry->ut_addr,
                                       sizeof(utmp_entry->ut_addr), AF_INET))) {
                  char disp[64];
                  sprintf(disp, "%s:0.0", he->h_name);
                  Setenv("DISPLAY", disp);
                  Warning("SetDisplay", "DISPLAY not set, setting it to %s",
                          disp);
               }
            }
#endif
         }
         free(gUtmpContents);
      }
   }
}

//______________________________________________________________________________
const char *TUnixSystem::GetError()
{
   // Return system error string.

   Int_t err = GetErrno();
   if (err == 0 && fLastErrorString != "")
      return fLastErrorString;
#if defined(R__SOLARIS) || defined (R__LINUX) || defined(R__AIX) || \
    defined(R__FBSD) || defined(R__OBSD) || defined(R__HURD)
   return strerror(err);
#else
   if (err < 0 || err >= sys_nerr)
      return Form("errno out of range %d", err);
   return sys_errlist[err];
#endif
}

//______________________________________________________________________________
const char *TUnixSystem::HostName()
{
   // Return the system's host name.

   if (fHostname == "") {
      char hn[64];
#if defined(R__SOLARIS) && !defined(R__KCC)
      sysinfo(SI_HOSTNAME, hn, sizeof(hn));
#else
      gethostname(hn, sizeof(hn));
#endif
      fHostname = hn;
   }
   return (const char *)fHostname;
}

//---- EventLoop ---------------------------------------------------------------

//______________________________________________________________________________
void TUnixSystem::AddFileHandler(TFileHandler *h)
{
   // Add a file handler to the list of system file handlers. Only adds
   // the handler if it is not already in the list of file handlers.

   R__LOCKGUARD2(gSystemMutex);

   TSystem::AddFileHandler(h);
   if (h) {
      int fd = h->GetFd();
      if (h->HasReadInterest()) {
         fReadmask->Set(fd);
         fMaxrfd = TMath::Max(fMaxrfd, fd);
      }
      if (h->HasWriteInterest()) {
         fWritemask->Set(fd);
         fMaxwfd = TMath::Max(fMaxwfd, fd);
      }
   }
}

//______________________________________________________________________________
TFileHandler *TUnixSystem::RemoveFileHandler(TFileHandler *h)
{
   // Remove a file handler from the list of file handlers. Returns
   // the handler or 0 if the handler was not in the list of file handlers.

   if (!h) return 0;

   R__LOCKGUARD2(gSystemMutex);

   TFileHandler *oh = TSystem::RemoveFileHandler(h);
   if (oh) {       // found
      TFileHandler *th;
      TIter next(fFileHandler);
      fMaxrfd = -1;
      fMaxwfd = -1;
      fReadmask->Zero();
      fWritemask->Zero();
      while ((th = (TFileHandler *) next())) {
         int fd = th->GetFd();
         if (th->HasReadInterest()) {
            fReadmask->Set(fd);
            fMaxrfd = TMath::Max(fMaxrfd, fd);
         }
         if (th->HasWriteInterest()) {
            fWritemask->Set(fd);
            fMaxwfd = TMath::Max(fMaxwfd, fd);
         }
      }
   }
   return oh;
}

//______________________________________________________________________________
void TUnixSystem::AddSignalHandler(TSignalHandler *h)
{
   // Add a signal handler to list of system signal handlers. Only adds
   // the handler if it is not already in the list of signal handlers.

   R__LOCKGUARD2(gSystemMutex);

   TSystem::AddSignalHandler(h);
   UnixSignal(h->GetSignal(), SigHandler);
}

//______________________________________________________________________________
TSignalHandler *TUnixSystem::RemoveSignalHandler(TSignalHandler *h)
{
   // Remove a signal handler from list of signal handlers. Returns
   // the handler or 0 if the handler was not in the list of signal handlers.

   if (!h) return 0;

   R__LOCKGUARD2(gSystemMutex);

   TSignalHandler *oh = TSystem::RemoveSignalHandler(h);

   Bool_t last = kTRUE;
   TSignalHandler *hs;
   TIter next(fSignalHandler);

   while ((hs = (TSignalHandler*) next())) {
      if (hs->GetSignal() == h->GetSignal())
         last = kFALSE;
   }
   if (last)
      ResetSignal(h->GetSignal(), kTRUE);

   return oh;
}

//______________________________________________________________________________
void TUnixSystem::ResetSignal(ESignals sig, Bool_t reset)
{
   // If reset is true reset the signal handler for the specified signal
   // to the default handler, else restore previous behaviour.

   if (reset)
      UnixResetSignal(sig);
   else
      UnixSignal(sig, SigHandler);
}

//______________________________________________________________________________
void TUnixSystem::IgnoreSignal(ESignals sig, Bool_t ignore)
{
   // If ignore is true ignore the specified signal, else restore previous
   // behaviour.

   UnixIgnoreSignal(sig, ignore);
}

//______________________________________________________________________________
void TUnixSystem::SigAlarmInterruptsSyscalls(Bool_t set)
{
   // When the argument is true the SIGALRM signal handler is set so that
   // interrupted syscalls will not be restarted by the kernel. This is
   // typically used in case one wants to put a timeout on an I/O operation.
   // By default interrupted syscalls will always be restarted (for all
   // signals). This can be controlled for each a-synchronous TTimer via
   // the method TTimer::SetInterruptSyscalls().

   UnixSigAlarmInterruptsSyscalls(set);
}

//______________________________________________________________________________
Int_t TUnixSystem::GetFPEMask()
{
   // Return the bitmap of conditions that trigger a floating point exception.

   Int_t mask = 0;

#if defined(R__LINUX) && !defined(__powerpc__)
#if defined(__GLIBC__) && (__GLIBC__>2 || __GLIBC__==2 && __GLIBC_MINOR__>=1)

#if __GLIBC_MINOR__>=3

   // clear pending exceptions so feenableexcept does not trigger them
   feclearexcept(FE_ALL_EXCEPT);
   Int_t oldmask = feenableexcept(0);

#else
   fenv_t oldenv;
   fegetenv(&oldenv);
   fesetenv(&oldenv);
#ifdef __alpha__
   ULong_t oldmask = ~oldenv;
#elif __ia64__
   Int_t oldmask = ~oldenv;
#else
   Int_t oldmask = ~oldenv.__control_word;
#endif
#endif

   if (oldmask & FE_INVALID  )   mask |= kInvalid;
   if (oldmask & FE_DIVBYZERO)   mask |= kDivByZero;
   if (oldmask & FE_OVERFLOW )   mask |= kOverflow;
   if (oldmask & FE_UNDERFLOW)   mask |= kUnderflow;
   if (oldmask & FE_INEXACT  )   mask |= kInexact;
#endif
#endif

#if defined(R__MACOSX) && (defined(__i386__) || defined(__x86_64__))
   fenv_t oldenv;
   fegetenv(&oldenv);
   fesetenv(&oldenv);
   Int_t oldmask = ~oldenv.__control;

   if (oldmask & FE_INVALID  )   mask |= kInvalid;
   if (oldmask & FE_DIVBYZERO)   mask |= kDivByZero;
   if (oldmask & FE_OVERFLOW )   mask |= kOverflow;
   if (oldmask & FE_UNDERFLOW)   mask |= kUnderflow;
   if (oldmask & FE_INEXACT  )   mask |= kInexact;
#endif

#if defined(R__MACOSX) && !defined(__xlC__) && !defined(__i386__) && \
   !defined(__x86_64__)
   Long64_t oldmask;
   fegetenvd(oldmask);

   if (oldmask & FE_ENABLE_INVALID  )   mask |= kInvalid;
   if (oldmask & FE_ENABLE_DIVBYZERO)   mask |= kDivByZero;
   if (oldmask & FE_ENABLE_OVERFLOW )   mask |= kOverflow;
   if (oldmask & FE_ENABLE_UNDERFLOW)   mask |= kUnderflow;
   if (oldmask & FE_ENABLE_INEXACT  )   mask |= kInexact;
#endif

   return mask;
}

//______________________________________________________________________________
Int_t TUnixSystem::SetFPEMask(Int_t mask)
{
   // Set which conditions trigger a floating point exception.
   // Return the previous set of conditions.

   if (mask) { }  // use mask to avoid warning

   Int_t old = GetFPEMask();

#if defined(R__LINUX) && !defined(__powerpc__)
#if defined(__GLIBC__) && (__GLIBC__>2 || __GLIBC__==2 && __GLIBC_MINOR__>=1)
   Int_t newm = 0;
   if (mask & kInvalid  )   newm |= FE_INVALID;
   if (mask & kDivByZero)   newm |= FE_DIVBYZERO;
   if (mask & kOverflow )   newm |= FE_OVERFLOW;
   if (mask & kUnderflow)   newm |= FE_UNDERFLOW;
   if (mask & kInexact  )   newm |= FE_INEXACT;

#if __GLIBC_MINOR__>=3

   // clear pending exceptions so feenableexcept does not trigger them
   feclearexcept(FE_ALL_EXCEPT);
   fedisableexcept(FE_ALL_EXCEPT);
   feenableexcept(newm);

#else

   fenv_t cur;
   fegetenv(&cur);
#if defined __ia64__ || defined __alpha__
   cur &= ~newm;
#else
   cur.__control_word &= ~newm;
#endif
   fesetenv(&cur);

#endif
#endif
#endif

#if defined(R__MACOSX) && (defined(__i386__) || defined(__x86_64__))
   Int_t newm = 0;
   if (mask & kInvalid  )   newm |= FE_INVALID;
   if (mask & kDivByZero)   newm |= FE_DIVBYZERO;
   if (mask & kOverflow )   newm |= FE_OVERFLOW;
   if (mask & kUnderflow)   newm |= FE_UNDERFLOW;
   if (mask & kInexact  )   newm |= FE_INEXACT;

   fenv_t cur;
   fegetenv(&cur);
   cur.__control &= ~newm;
   fesetenv(&cur);
#endif

#if defined(R__MACOSX) && !defined(__xlC__) && !defined(__i386__) && \
   !defined(__x86_64__)
   Int_t newm = 0;
   if (mask & kInvalid  )   newm |= FE_ENABLE_INVALID;
   if (mask & kDivByZero)   newm |= FE_ENABLE_DIVBYZERO;
   if (mask & kOverflow )   newm |= FE_ENABLE_OVERFLOW;
   if (mask & kUnderflow)   newm |= FE_ENABLE_UNDERFLOW;
   if (mask & kInexact  )   newm |= FE_ENABLE_INEXACT;

   Long64_t curmask;
   fegetenvd(curmask);
   curmask = (curmask & ~FE_ENABLE_ALL_EXCEPT) | newm;
   fesetenvd(curmask);
#endif

   return old;
}

//______________________________________________________________________________
void TUnixSystem::DispatchOneEvent(Bool_t pendingOnly)
{
   // Dispatch a single event.

   Bool_t pollOnce = pendingOnly;

   while (1) {
      // first handle any X11 events
      if (gXDisplay && gXDisplay->Notify()) {
         if (fReadready->IsSet(gXDisplay->GetFd())) {
            fReadready->Clr(gXDisplay->GetFd());
            fNfd--;
         }
         if (!pendingOnly) return;
      }

      // check for file descriptors ready for reading/writing
      if (fNfd > 0 && fFileHandler && fFileHandler->GetSize() > 0)
         if (CheckDescriptors())
            if (!pendingOnly) return;
      fNfd = 0;
      fReadready->Zero();
      fWriteready->Zero();

      if (pendingOnly && !pollOnce)
         return;

      // check synchronous signals
      if (fSigcnt > 0 && fSignalHandler->GetSize() > 0)
         if (CheckSignals(kTRUE))
            if (!pendingOnly) return;
      fSigcnt = 0;
      fSignals->Zero();

      // check synchronous timers
      Long_t nextto;
      if (fTimers && fTimers->GetSize() > 0)
         if (DispatchTimers(kTRUE)) {
            // prevent timers from blocking file descriptor monitoring
            nextto = NextTimeOut(kTRUE);
            if (nextto > kItimerResolution || nextto == -1)
               return;
         }

      // if in pendingOnly mode poll once file descriptor activity
      nextto = NextTimeOut(kTRUE);
      if (pendingOnly) {
         if (fFileHandler && fFileHandler->GetSize() == 0)
            return;
         nextto = 0;
         pollOnce = kFALSE;
      }

      // nothing ready, so setup select call
      *fReadready  = *fReadmask;
      *fWriteready = *fWritemask;

      int mxfd = TMath::Max(fMaxrfd, fMaxwfd);
      if (mxfd > -1) mxfd++;

      // if nothing to select (socket or timer) return
      if (mxfd == -1 && nextto == -1)
         return;

      fNfd = UnixSelect(mxfd, fReadready, fWriteready, nextto);
      if (fNfd < 0 && fNfd != -2) {
         int fd, rc;
         TFdSet t;
         for (fd = 0; fd < mxfd; fd++) {
            t.Set(fd);
            if (fReadmask->IsSet(fd)) {
               rc = UnixSelect(fd+1, &t, 0, 0);
               if (rc < 0 && rc != -2) {
                  SysError("DispatchOneEvent", "select: read error on %d\n", fd);
                  fReadmask->Clr(fd);
               }
            }
            if (fWritemask->IsSet(fd)) {
               rc = UnixSelect(fd+1, 0, &t, 0);
               if (rc < 0 && rc != -2) {
                  SysError("DispatchOneEvent", "select: write error on %d\n", fd);
                  fWritemask->Clr(fd);
               }
            }
            t.Clr(fd);
         }
      }
   }
}

//______________________________________________________________________________
void TUnixSystem::Sleep(UInt_t milliSec)
{
   // Sleep milliSec milliseconds.

   struct timeval tv;

   tv.tv_sec  = milliSec / 1000;
   tv.tv_usec = (milliSec % 1000) * 1000;

   select(0, 0, 0, 0, &tv);
}

//______________________________________________________________________________
Int_t TUnixSystem::Select(TList *act, Long_t to)
{
   // Select on file descriptors. The timeout to is in millisec. Returns
   // the number of ready descriptors, or 0 in case of timeout, or < 0 in
   // case of an error, with -2 being EINTR and -3 EBADF. In case of EINTR
   // the errno has been reset and the method can be called again. Returns
   // -4 in case the list did not contain any file handlers or file handlers
   // with file descriptor >= 0.

   Int_t rc = -4;

   TFdSet rd, wr;
   Int_t mxfd = -1;
   TIter next(act);
   TFileHandler *h = 0;
   while ((h = (TFileHandler *) next())) {
      Int_t fd = h->GetFd();
      if (fd > -1) {
         if (h->HasReadInterest()) {
            rd.Set(fd);
            mxfd = TMath::Max(mxfd, fd);
         }
         if (h->HasWriteInterest()) {
            wr.Set(fd);
            mxfd = TMath::Max(mxfd, fd);
         }
         h->ResetReadyMask();
      }
   }
   if (mxfd > -1)
      rc = UnixSelect(mxfd+1, &rd, &wr, to);

   // Set readiness bits
   if (rc > 0) {
      next.Reset();
      while ((h = (TFileHandler *) next())) {
         Int_t fd = h->GetFd();
         if (rd.IsSet(fd))
            h->SetReadReady();
         if (wr.IsSet(fd))
            h->SetWriteReady();
      }
   }

   return rc;
}

//______________________________________________________________________________
Int_t TUnixSystem::Select(TFileHandler *h, Long_t to)
{
   // Select on the file descriptor related to file handler h.
   // The timeout to is in millisec. Returns the number of ready descriptors,
   // or 0 in case of timeout, or < 0 in case of an error, with -2 being EINTR
   // and -3 EBADF. In case of EINTR the errno has been reset and the method
   // can be called again. Returns -4 in case the file handler is 0 or does
   // not have a file descriptor >= 0.

   Int_t rc = -4;

   TFdSet rd, wr;
   Int_t mxfd = -1;
   Int_t fd = -1;
   if (h) {
      fd = h->GetFd();
      if (fd > -1) {
         if (h->HasReadInterest())
            rd.Set(fd);
         if (h->HasWriteInterest())
            wr.Set(fd);
         h->ResetReadyMask();
         mxfd = fd;
         rc = UnixSelect(mxfd+1, &rd, &wr, to);
      }
   }

   // Fill output lists, if required
   if (rc > 0) {
      if (rd.IsSet(fd))
         h->SetReadReady();
      if (wr.IsSet(fd))
         h->SetWriteReady();
   }

   return rc;
}

//---- handling of system events -----------------------------------------------

//______________________________________________________________________________
void TUnixSystem::DispatchSignals(ESignals sig)
{
   // Handle and dispatch signals.

   switch (sig) {
   case kSigAlarm:
      DispatchTimers(kFALSE);
      break;
   case kSigChild:
      CheckChilds();
      break;
   case kSigBus:
   case kSigSegmentationViolation:
   case kSigIllegalInstruction:
   case kSigFloatingException:
      Break("TUnixSystem::DispatchSignals", UnixSigname(sig));
      StackTrace();
      if (gApplication)
         gApplication->HandleException(sig);
      else
         Exit(sig);
      break;
   case kSigSystem:
   case kSigPipe:
      Break("TUnixSystem::DispatchSignals", UnixSigname(sig));
      break;
   case kSigWindowChanged:
      Gl_windowchanged();
      break;
   default:
      fSignals->Set(sig);
      fSigcnt++;
      break;
   }

   // check a-synchronous signals
   if (fSigcnt > 0 && fSignalHandler->GetSize() > 0)
      CheckSignals(kFALSE);
}

//______________________________________________________________________________
Bool_t TUnixSystem::CheckSignals(Bool_t sync)
{
   // Check if some signals were raised and call their Notify() member.

   TSignalHandler *sh;
   Int_t sigdone = -1;
   {
      TOrdCollectionIter it((TOrdCollection*)fSignalHandler);

      while ((sh = (TSignalHandler*)it.Next())) {
         if (sync == sh->IsSync()) {
            ESignals sig = sh->GetSignal();
            if ((fSignals->IsSet(sig) && sigdone == -1) || sigdone == sig) {
               if (sigdone == -1) {
                  fSignals->Clr(sig);
                  sigdone = sig;
                  fSigcnt--;
               }
               if (sh->IsActive())
                  sh->Notify();
            }
         }
      }
   }
   if (sigdone != -1)
      return kTRUE;

   return kFALSE;
}

//______________________________________________________________________________
void TUnixSystem::CheckChilds()
{
   // Check if childs have finished.

#if 0  //rdm
   int pid;
   while ((pid = UnixWaitchild()) > 0) {
      TIter next(zombieHandler);
      register UnixPtty *pty;
      while (pty = (UnixPtty*) next())
         if (pty->GetPid() == pid) {
            zombieHandler->RemovePtr(pty);
            pty->DiedNotify();
         }
   }
#endif
}

//______________________________________________________________________________
Bool_t TUnixSystem::CheckDescriptors()
{
   // Check if there is activity on some file descriptors and call their
   // Notify() member.

   TFileHandler *fh;
   Int_t  fddone = -1;
   Bool_t read   = kFALSE;
#if defined(R__LINUX) && defined(__alpha__)
   // TOrdCollectionIter it(...) causes segv ?!?!? Also TIter fails.
   Int_t cursor = 0;
   while (cursor < fFileHandler->GetSize()) {
      fh = (TFileHandler*) fFileHandler->At(cursor++);
#else
   TOrdCollectionIter it((TOrdCollection*)fFileHandler);
   while ((fh = (TFileHandler*) it.Next())) {
#endif
      Int_t fd = fh->GetFd();
      if ((fd <= fMaxrfd && fReadready->IsSet(fd) && fddone == -1) ||
          (fddone == fd && read)) {
         if (fddone == -1) {
            fReadready->Clr(fd);
            fddone = fd;
            read = kTRUE;
            fNfd--;
         }
         if (fh->IsActive())
            fh->ReadNotify();
      }
      if ((fd <= fMaxwfd && fWriteready->IsSet(fd) && fddone == -1) ||
          (fddone == fd && !read)) {
         if (fddone == -1) {
            fWriteready->Clr(fd);
            fddone = fd;
            read = kFALSE;
            fNfd--;
         }
         if (fh->IsActive())
            fh->WriteNotify();
      }
   }
   if (fddone != -1)
      return kTRUE;

   return kFALSE;
}

//---- Directories -------------------------------------------------------------

//______________________________________________________________________________
int TUnixSystem::MakeDirectory(const char *name)
{
   // Make a Unix file system directory. Returns 0 in case of success and
   // -1 if the directory could not be created.

   TSystem *helper = FindHelper(name);
   if (helper)
      return helper->MakeDirectory(name);

   return UnixMakedir(name);
}

//______________________________________________________________________________
void *TUnixSystem::OpenDirectory(const char *name)
{
   // Open a Unix file system directory. Returns 0 if directory does not exist.

   TSystem *helper = FindHelper(name);
   if (helper)
      return helper->OpenDirectory(name);

   return UnixOpendir(name);
}

//______________________________________________________________________________
void TUnixSystem::FreeDirectory(void *dirp)
{
   // Close a Unix file system directory.

   TSystem *helper = FindHelper(0, dirp);
   if (helper) {
      helper->FreeDirectory(dirp);
      return;
   }

   if (dirp)
      ::closedir((DIR*)dirp);
}

//______________________________________________________________________________
const char *TUnixSystem::GetDirEntry(void *dirp)
{
   // Get next Unix file system directory entry. Returns 0 if no more entries.

   TSystem *helper = FindHelper(0, dirp);
   if (helper)
      return helper->GetDirEntry(dirp);

   if (dirp)
      return UnixGetdirentry(dirp);

   return 0;
}

//______________________________________________________________________________
Bool_t TUnixSystem::ChangeDirectory(const char *path)
{
   // Change directory. Returns kTRUE in case of success, kFALSE otherwise.

   Bool_t ret = (Bool_t) (::chdir(path) == 0);
   if (fWdpath != "")
      fWdpath = "";   // invalidate path cache
   return ret;
}

//______________________________________________________________________________
const char *TUnixSystem::WorkingDirectory()
{
   // Return working directory.

   if (fWdpath != "")
      return fWdpath.Data();

   R__LOCKGUARD2(gSystemMutex);

   static char cwd[kMAXPATHLEN];
   if (::getcwd(cwd, kMAXPATHLEN) == 0) {
      fWdpath = "/";
      Error("WorkingDirectory", "getcwd() failed");
   }
   fWdpath = cwd;
   return fWdpath.Data();
}

//______________________________________________________________________________
const char *TUnixSystem::HomeDirectory(const char *userName)
{
   // Return the user's home directory.

   return UnixHomedirectory(userName);
}

//______________________________________________________________________________
const char *TUnixSystem::TempDirectory() const
{
   // Return a user configured or systemwide directory to create
   // temporary files in.

   const char *dir =  gSystem->Getenv("TMPDIR");
   if (!dir || gSystem->AccessPathName(dir, kWritePermission))
      dir = "/tmp";

   return dir;
}

//______________________________________________________________________________
FILE *TUnixSystem::TempFileName(TString &base, const char *dir)
{
   // Create a secure temporary file by appending a unique
   // 6 letter string to base. The file will be created in
   // a standard (system) directory or in the directory
   // provided in dir. The full filename is returned in base
   // and a filepointer is returned for safely writing to the file
   // (this avoids certain security problems). Returns 0 in case
   // of error.

   char *b = ConcatFileName(dir ? dir : TempDirectory(), base);
   base = b;
   base += "XXXXXX";
   delete [] b;

   char *arg = StrDup(base);
   int fd = mkstemp(arg);
   base = arg;
   delete [] arg;

   if (fd == -1) {
      SysError("TempFileName", "%s", base.Data() );
      return 0;
   } else {
      FILE *fp = fdopen(fd, "w+");
      if (fp == 0) SysError("TempFileName", "converting filedescriptor (%d)", fd);
      return fp;
   }
}

//______________________________________________________________________________
const char *TUnixSystem::PrependPathName(const char *dir, TString& name)
{
   // Concatenate a directory and a file name.

   if (name.IsNull() || name == ".") {
      if (dir) {
         name = dir;
         if (dir[strlen(dir) - 1] != '/')
            name += '/';
      } else name = "";
      return name.Data();
   }

   if (!dir || !dir[0]) dir = "/";
   else if (dir[strlen(dir) - 1] != '/')
      name.Prepend('/');
   name.Prepend(dir);

   return name.Data();
}

//---- Paths & Files -----------------------------------------------------------

//______________________________________________________________________________
Bool_t TUnixSystem::AccessPathName(const char *path, EAccessMode mode)
{
   // Returns FALSE if one can access a file using the specified access mode.
   // Mode is the same as for the Unix access(2) function.
   // Attention, bizarre convention of return value!!

   TSystem *helper = FindHelper(path);
   if (helper)
      return helper->AccessPathName(path, mode);

   if (::access(StripOffProto(path, "file:"), mode) == 0)
      return kFALSE;
   fLastErrorString = GetError();
   return kTRUE;
}

//______________________________________________________________________________
int TUnixSystem::CopyFile(const char *f, const char *t, Bool_t overwrite)
{
   // Copy a file. If overwrite is true and file already exists the
   // file will be overwritten. Returns 0 when successful, -1 in case
   // of file open failure, -2 in case the file already exists and overwrite
   // was false and -3 in case of error during copy.

   if (!AccessPathName(t) && !overwrite)
      return -2;

   FILE *from = fopen(f, "r");
   if (!from)
      return -1;

   FILE *to   = fopen(t, "w");
   if (!to)
      return -1;

   const int bufsize = 1024;
   char buf[bufsize];
   int ret = 0;
   while (!ret && !feof(from)) {
      size_t numread    = fread (buf, sizeof(char), bufsize, from);
      size_t numwritten = fwrite(buf, sizeof(char), numread, to);
      if (numread != numwritten)
         ret = -3;
   }

   fclose(from);
   fclose(to);

   return ret;
}

//______________________________________________________________________________
int TUnixSystem::Rename(const char *f, const char *t)
{
   // Rename a file. Returns 0 when successful, -1 in case of failure.

   int ret = ::rename(f, t);
   fLastErrorString = GetError();
   return ret;
}

//______________________________________________________________________________
int TUnixSystem::GetPathInfo(const char *path, FileStat_t &buf)
{
   // Get info about a file. Info is returned in the form of a FileStat_t
   // structure (see TSystem.h).
   // The function returns 0 in case of success and 1 if the file could
   // not be stat'ed.

   TSystem *helper = FindHelper(path);
   if (helper)
      return helper->GetPathInfo(path, buf);

   return UnixFilestat(path, buf);
}

//______________________________________________________________________________
int TUnixSystem::GetFsInfo(const char *path, Long_t *id, Long_t *bsize,
                           Long_t *blocks, Long_t *bfree)
{
   // Get info about a file system: id, bsize, bfree, blocks.
   // Id      is file system type (machine dependend, see statfs())
   // Bsize   is block size of file system
   // Blocks  is total number of blocks in file system
   // Bfree   is number of free blocks in file system
   // The function returns 0 in case of success and 1 if the file system could
   // not be stat'ed.

   return UnixFSstat(path, id, bsize, blocks, bfree);
}

//______________________________________________________________________________
int TUnixSystem::Link(const char *from, const char *to)
{
   // Create a link from file1 to file2. Returns 0 when successful,
   // -1 in case of failure.

   return ::link(from, to);
}

//______________________________________________________________________________
int TUnixSystem::Symlink(const char *from, const char *to)
{
   // Create a symlink from file1 to file2. Returns 0 when succesfull,
   // -1 in case of failure.

#if defined(R__AIX)
   return ::symlink((char*)from, (char*)to);
#else
   return ::symlink(from, to);
#endif
}

//______________________________________________________________________________
int TUnixSystem::Unlink(const char *name)
{
   // Unlink, i.e. remove, a file or directory. Returns 0 when succesfull,
   // -1 in case of failure.

   TSystem *helper = FindHelper(name);
   if (helper)
      return helper->Unlink(name);

#if defined(R__SEEK64)
   struct stat64 finfo;
   if (lstat64(name, &finfo) < 0)
#else
   struct stat finfo;
   if (lstat(name, &finfo) < 0)
#endif
      return -1;

   if (S_ISDIR(finfo.st_mode))
      return ::rmdir(name);
   else
      return ::unlink(name);
}

//---- expand the metacharacters as in the shell -------------------------------

// expand the metacharacters as in the shell

const char
#ifdef G__OLDEXPAND
   kShellEscape     = '\\',
   *kShellStuff     = "(){}<>\"'",
#endif
   *kShellMeta      = "~*[]{}?$";


#ifndef G__OLDEXPAND
//______________________________________________________________________________
Bool_t TUnixSystem::ExpandPathName(TString &path)
{
   // Expand a pathname getting rid of special shell characters like ~.$, etc.
   // For Unix/Win32 compatibility use $(XXX) instead of $XXX when using
   // environment variables in a pathname. If compatibility is not an issue
   // you can use on Unix directly $XXX.

   const char *p, *patbuf = (const char *)path;

   // skip leading blanks
   while (*patbuf == ' ')
      patbuf++;

   // any shell meta characters ?
   for (p = patbuf; *p; p++)
      if (strchr(kShellMeta, *p))
         goto expand;

   return kFALSE;

expand:
   // replace $(XXX) by $XXX
   path.ReplaceAll("$(","$");
   path.ReplaceAll(")","");

   path = ExpandFileName(path.Data());
   return kFALSE;
}
#endif

#ifdef G__OLDEXPAND
//______________________________________________________________________________
Bool_t TUnixSystem::ExpandPathName(TString &patbuf0)
{
   // Expand a pathname getting rid of special shell characters like ~.$, etc.
   // For Unix/Win32 compatibility use $(XXX) instead of $XXX when using
   // environment variables in a pathname. If compatibility is not an issue
   // you can use on Unix directly $XXX.

   const char *patbuf = (const char *)patbuf0;
   const char *hd, *p;
   //   char   cmd[kMAXPATHLEN],
   char stuffedPat[kMAXPATHLEN], name[70];
   char  *q;
   FILE  *pf;
   int    ch;

   // skip leading blanks
   while (*patbuf == ' ')
      patbuf++;

   // any shell meta characters ?
   for (p = patbuf; *p; p++)
      if (strchr(kShellMeta, *p))
         goto needshell;

   return kFALSE;

needshell:
   // replace $(XXX) by $XXX
   patbuf0.ReplaceAll("$(","$");
   patbuf0.ReplaceAll(")","");

   // escape shell quote characters
   EscChar(patbuf, stuffedPat, sizeof(stuffedPat), (char*)kShellStuff, kShellEscape);

#ifdef R__HPUX
   TString cmd("/bin/echo ");
#else
   TString cmd("echo ");
#endif

   // emulate csh -> popen executes sh
   if (stuffedPat[0] == '~') {
      if (stuffedPat[1] != '\0' && stuffedPat[1] != '/') {
         // extract user name
         for (p = &stuffedPat[1], q = name; *p && *p !='/';)
            *q++ = *p++;
         *q = '\0';
         hd = UnixHomedirectory(name);
         if (hd == 0)
            cmd += stuffedPat;
         else {
            cmd += hd;
            cmd += p;
         }
      } else {
         hd = UnixHomedirectory(0);
         if (hd == 0) {
            fLastErrorString = GetError();
            return kTRUE;
         }
         cmd += hd;
         cmd += &stuffedPat[1];
      }
   } else
      cmd += stuffedPat;

   if ((pf = ::popen(cmd.Data(), "r")) == 0) {
      fLastErrorString = GetError();
      return kTRUE;
   }

   // read first argument
   patbuf0 = "";
   int cnt = 0;
#if defined(R__ALPHA) || defined(R__AIX)
again:
#endif
   for (ch = fgetc(pf); ch != EOF && ch != ' ' && ch != '\n'; ch = fgetc(pf)) {
      patbuf0.Append(ch);
      cnt++;
   }
#if defined(R__ALPHA) || defined(R__AIX)
   // Work around bug timing problem due to delay in forking a large program
   if (cnt == 0 && ch == EOF) goto again;
#endif

   // skip rest of pipe
   while (ch != EOF) {
      ch = fgetc(pf);
      if (ch == ' ' || ch == '\t') {
         fLastErrorString = "expression ambigous";
         ::pclose(pf);
         return kTRUE;
      }
   }

   ::pclose(pf);

   return kFALSE;
}
#endif

//______________________________________________________________________________
char *TUnixSystem::ExpandPathName(const char *path)
{
   // Expand a pathname getting rid of special shell characaters like ~.$, etc.
   // For Unix/Win32 compatibility use $(XXX) instead of $XXX when using
   // environment variables in a pathname. If compatibility is not an issue
   // you can use on Unix directly $XXX. The user must delete returned string.

   TString patbuf = path;
   if (ExpandPathName(patbuf))
      return 0;
   return StrDup(patbuf.Data());
}

//______________________________________________________________________________
int TUnixSystem::Chmod(const char *file, UInt_t mode)
{
   // Set the file permission bits. Returns -1 in case or error, 0 otherwise.

   return ::chmod(file, mode);
}

//______________________________________________________________________________
int TUnixSystem::Umask(Int_t mask)
{
   // Set the process file creation mode mask.

   return ::umask(mask);
}

//______________________________________________________________________________
int TUnixSystem::Utime(const char *file, Long_t modtime, Long_t actime)
{
   // Set a files modification and access times. If actime = 0 it will be
   // set to the modtime. Returns 0 on success and -1 in case of error.

   if (!actime)
      actime = modtime;

   struct utimbuf t;
   t.actime  = (time_t)actime;
   t.modtime = (time_t)modtime;
   return ::utime(file, &t);
}

//______________________________________________________________________________
const char *TUnixSystem::FindFile(const char *search, TString& wfil, EAccessMode mode)
{
   // Find location of file "wfil" in a search path.
   // The search path is specified as a : separated list of directories.
   // Return value is pointing to wfile for compatibility with
   // Which(const char*,const char*,EAccessMode) version.

   TString show;
   if (gEnv->GetValue("Root.ShowPath", 0))
      show.Form("Which: %s =", wfil.Data());

   gSystem->ExpandPathName(wfil);

   if (wfil[0] == '/') {
#if defined(R__SEEK64)
      struct stat64 finfo;
      if (access(wfil.Data(), mode) == 0 &&
          stat64(wfil.Data(), &finfo) == 0 && S_ISREG(finfo.st_mode)) {
#else
      struct stat finfo;
      if (access(wfil.Data(), mode) == 0 &&
          stat(wfil.Data(), &finfo) == 0 && S_ISREG(finfo.st_mode)) {
#endif
         if (show != "")
            Printf("%s %s", show.Data(), wfil.Data());
         return wfil.Data();
      }
      if (show != "")
         Printf("%s <not found>", show.Data());
      wfil = "";
      return 0;
   }

   if (search == 0)
      search = ".";

   TString pwd(gSystem->WorkingDirectory());
   pwd += "/";
   for (const char* ptr = search; *ptr;) {
      TString name;
      if (*ptr != '/' && *ptr !='$' && *ptr != '~')
         name = pwd;
      const char* posEndOfPart = strchr(ptr, ':');
      if (posEndOfPart) {
         name.Append(ptr, posEndOfPart - ptr);
         ptr = posEndOfPart + 1; // skip ':'
      } else {
         name.Append(ptr);
         ptr += strlen(ptr);
      }

      if (!name.EndsWith("/"))
         name += '/';
      name += wfil;

      gSystem->ExpandPathName(name);
#if defined(R__SEEK64)
      struct stat64 finfo;
      if (access(name.Data(), mode) == 0 &&
          stat64(name.Data(), &finfo) == 0 && S_ISREG(finfo.st_mode)) {
#else
      struct stat finfo;
      if (access(name.Data(), mode) == 0 &&
          stat(name.Data(), &finfo) == 0 && S_ISREG(finfo.st_mode)) {
#endif
         if (show != "")
            Printf("%s %s", show.Data(), name.Data());
         wfil = name;
         return wfil.Data();
      }
   }

   if (show != "")
      Printf("%s <not found>", show.Data());
   wfil = "";
   return 0;
}

//---- Users & Groups ----------------------------------------------------------

//______________________________________________________________________________
Int_t TUnixSystem::GetUid(const char *user)
{
   // Returns the user's id. If user = 0, returns current user's id.

   if (!user || !user[0])
      return getuid();
   else {
      struct passwd *pwd = getpwnam(user);
      if (pwd)
         return pwd->pw_uid;
   }
   return 0;
}

//______________________________________________________________________________
Int_t TUnixSystem::GetEffectiveUid()
{
   // Returns the effective user id. The effective id corresponds to the
   // set id bit on the file being executed.

   return geteuid();
}

//______________________________________________________________________________
Int_t TUnixSystem::GetGid(const char *group)
{
   // Returns the group's id. If group = 0, returns current user's group.

   if (!group || !group[0])
      return getgid();
   else {
      struct group *grp = getgrnam(group);
      if (grp)
         return grp->gr_gid;
   }
   return 0;
}

//______________________________________________________________________________
Int_t TUnixSystem::GetEffectiveGid()
{
   // Returns the effective group id. The effective group id corresponds
   // to the set id bit on the file being executed.

   return getegid();
}

//______________________________________________________________________________
UserGroup_t *TUnixSystem::GetUserInfo(Int_t uid)
{
   // Returns all user info in the UserGroup_t structure. The returned
   // structure must be deleted by the user. In case of error 0 is returned.

   typedef std::map<Int_t /*uid*/, UserGroup_t> UserInfoCache_t;
   static UserInfoCache_t gUserInfo;

   UserInfoCache_t::const_iterator iUserInfo = gUserInfo.find(uid);
   if (iUserInfo != gUserInfo.end())
      return new UserGroup_t(iUserInfo->second);

   struct passwd *pwd = getpwuid(uid);
   if (pwd) {
      UserGroup_t *ug = new UserGroup_t;
      ug->fUid      = pwd->pw_uid;
      ug->fGid      = pwd->pw_gid;
      ug->fUser     = pwd->pw_name;
      ug->fPasswd   = pwd->pw_passwd;
      ug->fRealName = pwd->pw_gecos;
      ug->fShell    = pwd->pw_shell;
      UserGroup_t *gr = GetGroupInfo(pwd->pw_gid);
      if (gr) ug->fGroup = gr->fGroup;
      delete gr;

      gUserInfo[uid] = *ug;
      return ug;
   }
   return 0;
}

//______________________________________________________________________________
UserGroup_t *TUnixSystem::GetUserInfo(const char *user)
{
   // Returns all user info in the UserGroup_t structure. If user = 0, returns
   // current user's id info. The returned structure must be deleted by the
   // user. In case of error 0 is returned.

   return GetUserInfo(GetUid(user));
}

//______________________________________________________________________________
UserGroup_t *TUnixSystem::GetGroupInfo(Int_t gid)
{
   // Returns all group info in the UserGroup_t structure. The only active
   // fields in the UserGroup_t structure for this call are:
   //    fGid and fGroup
   // The returned structure must be deleted by the user. In case of
   // error 0 is returned.

   struct group *grp = getgrgid(gid);
   if (grp) {
      UserGroup_t *gr = new UserGroup_t;
      gr->fUid   = 0;
      gr->fGid   = grp->gr_gid;
      gr->fGroup = grp->gr_name;
      return gr;
   }
   return 0;
}

//______________________________________________________________________________
UserGroup_t *TUnixSystem::GetGroupInfo(const char *group)
{
   // Returns all group info in the UserGroup_t structure. The only active
   // fields in the UserGroup_t structure for this call are:
   //    fGid and fGroup
   // If group = 0, returns current user's group. The returned structure
   // must be deleted by the user. In case of error 0 is returned.

   return GetGroupInfo(GetGid(group));
}

//---- environment manipulation ------------------------------------------------

//______________________________________________________________________________
void TUnixSystem::Setenv(const char *name, const char *value)
{
   // Set environment variable. The string passed will be owned by
   // the environment and can not be reused till a "name" is set
   // again. The solution below will lose the space for the string
   // in that case, but if this functions is not called thousands
   // of times that should not be a problem.

   char *s = new char [strlen(name)+strlen(value) + 2];
   sprintf(s, "%s=%s", name, value);

   ::putenv(s);
}

//______________________________________________________________________________
const char *TUnixSystem::Getenv(const char *name)
{
   // Get environment variable.

   return ::getenv(name);
}

//---- Processes ---------------------------------------------------------------

//______________________________________________________________________________
int TUnixSystem::Exec(const char *shellcmd)
{
   // Execute a command.

   return ::system(shellcmd);
}

//______________________________________________________________________________
FILE *TUnixSystem::OpenPipe(const char *command, const char *mode)
{
   // Open a pipe.

   return ::popen(command, mode);
}

//______________________________________________________________________________
int TUnixSystem::ClosePipe(FILE *pipe)
{
   // Close the pipe.

   return ::pclose(pipe);
}

//______________________________________________________________________________
int TUnixSystem::GetPid()
{
   // Get process id.

   return ::getpid();
}

//______________________________________________________________________________
void TUnixSystem::Exit(int code, Bool_t mode)
{
   // Exit the application.

   // Insures that the files and sockets are closed before any library is unloaded!
   if (gROOT) {
      if (gROOT->GetListOfFiles()) gROOT->GetListOfFiles()->Delete("slow");
      if (gROOT->GetListOfSockets()) gROOT->GetListOfSockets()->Delete();
      if (gROOT->GetListOfMappedFiles()) gROOT->GetListOfMappedFiles()->Delete("slow");
   }

   if (mode)
      ::exit(code);
   else
      ::_exit(code);
}

//______________________________________________________________________________
void TUnixSystem::Abort(int)
{
   // Abort the application.

   ::abort();
}

//______________________________________________________________________________
void TUnixSystem::StackTrace()
{
   // Print a stack trace.

   if (!gEnv->GetValue("Root.Stacktrace", 1))
      return;

   cout.flush();
   fflush(stdout);

   cerr.flush();
   fflush(stderr);

   int fd = STDERR_FILENO;

   const char *message = " Generating stack trace...\n";

   if (fd && message) { }  // remove unused warning (remove later)

#if defined(USE_GDB_STACK_TRACE)
   char *gdb = Which(Getenv("PATH"), "gdb", kExecutePermission);
   if (!gdb) {
      fprintf(stderr, "gdb not found, need it for stack trace\n");
      return;
   }

   // use gdb to get stack trace
   TString gdbscript;
# ifdef ROOTETCDIR
   gdbscript.Form("%s/gdb-backtrace-script", ROOTETCDIR);
# else
   gdbscript.Form("%s/etc/gdb-backtrace-script", gSystem->Getenv("ROOTSYS"));
# endif
   TString tracefile, tracecmd;
   tracefile.Form("/tmp/rootstack.%d", GetPid());
   tracecmd.Form("%s -batch -n -x %s -p %d > %s 2>&1",
                 gdb, gdbscript.Data(), GetPid(), tracefile.Data());
   Exec(tracecmd);
   FILE *p = fopen(tracefile, "r");
   TString gdbout;
   while (gdbout.Gets(p)) {
      fprintf(stderr, "%s\n", gdbout.Data());
   }
   fclose(p);
   Unlink(tracefile);
   delete [] gdb;
   return;

#elif defined(HAVE_U_STACK_TRACE) || defined(HAVE_XL_TRBK)   // hp-ux, aix
/*
   // FIXME: deal with inability to duplicate the file handle
   int stderrfd = dup(STDERR_FILENO);
   if (stderrfd == -1)
      return;

   int newfd = dup2(fd, STDERR_FILENO);
   if (newfd == -1) {
      close (stderrfd);
      return;
   }
*/
# if defined(HAVE_U_STACK_TRACE)                      // hp-ux
   U_STACK_TRACE();
# elif defined(HAVE_XL_TRBK)                          // aix
   xl__trbk();
# endif
/*
   fflush(stderr);
   dup2(stderrfd, STDERR_FILENO);
   close(newfd);
*/
#elif defined(HAVE_BACKTRACE_SYMBOLS_FD) && defined(HAVE_DLADDR)  // linux
   // we could have used backtrace_symbols_fd, except its output
   // format is pretty bad, so recode that here :-(

   // take care of demangling
   Bool_t demangle = kTRUE;

   // check for c++filt (g++), iccfilt (icc) or eccfilt (ecc)
#if defined(R__INTEL_COMPILER_SKIP)
#if defined(R__B64)
   const char *cppfilt = "eccfilt";
#else
   const char *cppfilt = "iccfilt";
#endif
#else
   const char *cppfilt = "c++filt";
#endif
   const char *cppfiltarg = "";
#ifdef R__B64
   const char *format1 = " 0x%016lx in %.200s %s 0x%lx from %.200s\n";
   const char *format2 = " 0x%016lx in %.200s at %.200s from %.200s\n";
   const char *format3 = " 0x%016lx in %.200s from %.200s\n";
   const char *format4 = " 0x%016lx in <unknown function>\n";
#else
   const char *format1 = " 0x%08lx in %.200s %s 0x%lx from %.200s\n";
   const char *format2 = " 0x%08lx in %.200s at %.200s from %.200s\n";
   const char *format3 = " 0x%08lx in %.200s from %.200s\n";
   const char *format4 = " 0x%08lx in <unknown function>\n";
#endif

   char *filter = Which(Getenv("PATH"), cppfilt, kExecutePermission);
   if (!filter)
      demangle = kFALSE;

#if (__GNUC__ >= 3) && !defined(R__INTEL_COMPILER_SKIP)
   // try finding supported format option for g++ v3
   if (filter) {
      FILE *p = OpenPipe(Form("%s --help 2>&1", filter), "r");
      TString help;
      while (help.Gets(p)) {
         if (help.Index("gnu-v3") != kNPOS) {
            cppfiltarg = "--format=gnu-v3";
            break;
         } else if (help.Index("gnu-new-abi") != kNPOS) {
            cppfiltarg = "--format=gnu-new-abi";
            break;
         }
      }
      ClosePipe(p);
   }
#endif
   // gdb-backtrace.sh uses gdb to produce a backtrace. See if it is available.
   // If it is, use it. If not proceed as before.
   char *gdb = Which(Getenv("PATH"), "gdb", kExecutePermission);
   if (gdb) {
      // use gdb to get stack trace
      TString gdbscript;
# ifdef ROOTETCDIR
      gdbscript.Form("%s/gdb-backtrace.sh ", ROOTETCDIR);
# else
      gdbscript.Form("%s/etc/gdb-backtrace.sh ", gSystem->Getenv("ROOTSYS"));
# endif
      gdbscript += GetPid();
      Exec(gdbscript);
      delete [] gdb;
   } else {
      // addr2line uses debug info to convert addresses into file names
      // and line numbers
      char *addr2line = Which(Getenv("PATH"), "addr2line", kExecutePermission);
      if (addr2line) {
         // might take some time so tell what we are doing...
         write(fd, message, strlen(message));
      }

      // open tmp file for demangled stack trace
      char tmpf1[2*L_tmpnam];
      ofstream file1;
      if (demangle) {
         tmpnam(tmpf1);
         file1.open(tmpf1);
         if (!file1) {
            Error("StackTrace", "could not open file %s", tmpf1);
            Unlink(tmpf1);
            demangle = kFALSE;
         }
      }

      char buffer[4096];
      void *trace[kMAX_BACKTRACE_DEPTH];
      int  depth = backtrace(trace, kMAX_BACKTRACE_DEPTH);
      for (int n = 5; n < depth; n++) {
         ULong_t addr = (ULong_t) trace[n];
         Dl_info info;

         if (dladdr(trace[n], &info) && info.dli_fname && info.dli_fname[0]) {
            const char *libname = info.dli_fname;
            const char *symname = (info.dli_sname && info.dli_sname[0]) ?
                                   info.dli_sname : "<unknown>";
            ULong_t libaddr = (ULong_t) info.dli_fbase;
            ULong_t symaddr = (ULong_t) info.dli_saddr;
            Bool_t  gte = (addr >= symaddr);
            ULong_t diff = (gte) ? addr - symaddr : symaddr - addr;
            if (addr2line && symaddr) {
               ULong_t offset = (addr >= libaddr) ? addr - libaddr :
                                                    libaddr - addr;
               TString name   = TString(libname);
               Bool_t noPath  = kFALSE;
               Bool_t noShare = kTRUE;
               if (name[0] != '/') noPath = kTRUE;
               if (name.Contains(".so") || name.Contains(".sl")) noShare = kFALSE;
               if (noShare) offset = addr;
               if (noPath)  name = "which `" + name + "`";
               sprintf(buffer, "%s -e %s 0x%016lx", addr2line, name.Data(), offset);
               Bool_t nodebug = kTRUE;
               if (FILE *pf = ::popen(buffer, "r")) {
                  char buf[2048];
                  if (fgets(buf, 2048, pf)) {
                     buf[strlen(buf)-1] = 0;  // remove trailing \n
                     if (strncmp(buf, "??", 2)) {
                        sprintf(buffer, format2, addr, symname, buf, libname);
                        nodebug = kFALSE;
                     }
                  }
                  ::pclose(pf);
               }
               if (nodebug)
                  sprintf(buffer, format1, addr, symname,
                          gte ? "+" : "-", diff, libname);
            } else {
               if (symaddr)
                  sprintf(buffer, format1, addr, symname,
                          gte ? "+" : "-", diff, libname);
               else
                  sprintf(buffer, format3, addr, symname, libname);
            }
         } else {
            sprintf(buffer, format4, addr);
         }

         if (demangle)
            file1 << buffer;
         else
            write(fd, buffer, ::strlen(buffer));
      }

      if (demangle) {
         char tmpf2[2*L_tmpnam];
         tmpnam(tmpf2);
         file1.close();
         sprintf(buffer, "%s %s < %s > %s", filter, cppfiltarg, tmpf1, tmpf2);
         Exec(buffer);
         ifstream file2(tmpf2);
         TString line;
         while (file2) {
            line = "";
            line.ReadString(file2);
            write(fd, line.Data(), line.Length());
         }
         file2.close();
         Unlink(tmpf1);
         Unlink(tmpf2);
      }

      delete [] addr2line;
      delete [] filter;
   }
#elif defined(PROG_PSTACK)                            // solaris
# ifdef PROG_CXXFILT
#  define CXXFILTER " | " PROG_CXXFILT
# else
#  define CXXFILTER
# endif
   // 64 should more than plenty for a space and a pid.
   char buffer[sizeof(PROG_PSTACK) + 64 + 3 + sizeof(PROG_CXXFILT) + 64];
   sprintf(buffer, "%s %lu%s 1>&%d", PROG_PSTACK, (ULong_t) getpid(),
           "" CXXFILTER, fd);
   buffer[sizeof (buffer)-1] = 0;
   Exec(buffer);
# undef CXXFILTER

#elif defined(HAVE_EXCPT_H) && defined(HAVE_PDSC_H) && \
                               defined(HAVE_RLD_INTERFACE_H) // tru64
   // Tru64 stack walk.  Uses the exception handling library and the
   // run-time linker's core functions (loader(5)).  FIXME: Tru64
   // should have _RLD_DLADDR like IRIX below.  Verify and update.

   char         buffer [128];
   sigcontext   context;
   int          rc = 0;

   exc_capture_context (&context);
   while (!rc && context.sc_pc) {
      // FIXME: Elf32?
      pdsc_crd *func, *base, *crd
         = exc_remote_lookup_function_entry(0, 0, context.sc_pc, 0, &func, &base);
      Elf32_Addr addr = PDSC_CRD_BEGIN_ADDRESS(base, func);
      // const char *name = _rld_address_to_name(addr);
      const char *name = "<unknown function>";
      sprintf(buffer, " 0x%012lx %.200s + 0x%lx\n",
              context.sc_pc, name, context.sc_pc - addr);
      write(fd, buffer, ::strlen(buffer));
      rc = exc_virtual_unwind(0, &context);
   }

#elif defined(HAVE_EXCEPTION_H) && defined(__sgi)     // irix
   // IRIX stack walk -- like Tru64 but with a little different names.
   // NB: The guard above is to protect against unrelated <exception.h>
   //   provided by some compilers (e.g. KCC 4.0f).
   // NB: libexc.h has trace_back_stack and trace_back_stack_and_print
   //   but their output isn't pretty and nowhere as complete as ours.
   char       buffer [340];
   sigcontext context;

   exc_setjmp(&context);
   while (context.sc_pc >= 4) {
      // Do two lookups, one using exception handling tables and
      // another using _RLD_DLADDR, and use the one with a smaller
      // offset.  For signal handlers we seem to get things wrong:
      // _sigtramp's exception range is huge while based on Dl_info
      // the offset is small -- but both supposedly describe the
      // same thing.  Go figure.
      char            *name = 0;
      const char      *libname = 0;
      const char      *symname = 0;
      Elf32_Addr      offset = ~0L;

      // Do the exception/dwarf lookup
      Elf32_Addr      pc = context.sc_pc;
      Dwarf_Fde       fde = find_fde_name(&pc, &name);
      Dwarf_Addr      low_pc = context.sc_pc;
      Dwarf_Unsigned  udummy;
      Dwarf_Signed    sdummy;
      Dwarf_Ptr       pdummy;
      Dwarf_Off       odummy;
      Dwarf_Error     err;

      symname = name;

      // Determine offset using exception descriptor range information.
      if (dwarf_get_fde_range(fde, &low_pc, &udummy, &pdummy, &udummy,
                              &odummy, &sdummy, &odummy, &err) == DW_DLV_OK)
         offset = context.sc_pc - low_pc;

      // Now do a dladdr() lookup.  If the found symbol has the same
      // address, trust the more accurate offset from dladdr();
      // ignore the looked up mangled symbol name and prefer the
      // demangled name produced by find_fde_name().  If we find a
      // smaller offset, trust the dynamic symbol as well.  Always
      // trust the library name even if we can't match it with an
      // exact symbol.
      Elf32_Addr      addr = context.sc_pc;
      Dl_info         info;

      if (_rld_new_interface (_RLD_DLADDR, addr, &info)) {
         if (info.dli_fname && info.dli_fname [0])
            libname = info.dli_fname;

         Elf32_Addr symaddr = (Elf32_Addr) info.dli_saddr;
         if (symaddr == low_pc)
            offset = addr - symaddr;
         else if (info.dli_sname
                  && info.dli_sname [0]
                  && addr - symaddr < offset) {
            offset = addr - symaddr;
            symname = info.dli_sname;
         }
      }

      // Print out the result
      if (libname && symname)
         write(fd, buffer, sprintf
               (buffer, " 0x%012lx %.200s + 0x%lx [%.200s]\n",
               addr, symname, offset, libname));
      else if (symname)
         write(fd, buffer, sprintf
               (buffer, " 0x%012lx %.200s + 0x%lx\n",
               addr, symname, offset));
      else
         write(fd, buffer, sprintf
               (buffer, " 0x%012lx <unknown function>\n", addr));

      // Free name from find_fde_name().
      free(name);

      // Check for termination.  exc_unwind() sets context.sc_pc to
      // 0 or an error (< 4).  However it seems we can't unwind
      // through signal stack frames though this is not mentioned in
      // the docs; it seems that for those we need to check for
      // changed pc after find_fde_name().  That seems to indicate
      // end of the post-signal stack frame.  (FIXME: Figure out how
      // to unwind through signal stack frame, e.g. perhaps using
      // sigcontext_t's old pc?  Or perhaps we can keep on going
      // down without doing the symbol lookup?)
      if (pc != context.sc_pc)
         break;

      exc_unwind(&context, fde);
   }
#endif
}

//---- System Logging ----------------------------------------------------------

//______________________________________________________________________________
void TUnixSystem::Openlog(const char *name, Int_t options, ELogFacility facility)
{
   // Open connection to system log daemon. For the use of the options and
   // facility see the Unix openlog man page.

   int fac = 0;

   switch (facility) {
      case kLogLocal0:
         fac = LOG_LOCAL0;
         break;
      case kLogLocal1:
         fac = LOG_LOCAL1;
         break;
      case kLogLocal2:
         fac = LOG_LOCAL2;
         break;
      case kLogLocal3:
         fac = LOG_LOCAL3;
         break;
      case kLogLocal4:
         fac = LOG_LOCAL4;
         break;
      case kLogLocal5:
         fac = LOG_LOCAL5;
         break;
      case kLogLocal6:
         fac = LOG_LOCAL6;
         break;
      case kLogLocal7:
         fac = LOG_LOCAL7;
         break;
   }

   ::openlog(name, options, fac);
}

//______________________________________________________________________________
void TUnixSystem::Syslog(ELogLevel level, const char *mess)
{
   // Send mess to syslog daemon. Level is the logging level and mess the
   // message that will be written on the log.

   // ELogLevel matches exactly the Unix values.
   ::syslog(level, "%s", mess);
}

//______________________________________________________________________________
void TUnixSystem::Closelog()
{
   // Close connection to system log daemon.

   ::closelog();
}

//---- Standard output redirection ---------------------------------------------

//______________________________________________________________________________
Int_t TUnixSystem::RedirectOutput(const char *file, const char *mode,
                                  RedirectHandle_t *h)
{
   // Redirect standard output (stdout, stderr) to the specified file.
   // If the file argument is 0 the output is set again to stderr, stdout.
   // The second argument specifies whether the output should be added to the
   // file ("a", default) or the file be truncated before ("w").
   // This function saves internally the current state into a static structure.
   // The call can be made reentrant by specifying the opaque structure pointed
   // by 'h', which is filled with the relevant information. The handle 'h'
   // obtained on the first call must then be used in any subsequent call,
   // included ShowOutput, to display the redirected output.
   // Returns 0 on success, -1 in case of error.

   // Instance to be used if the caller does not passes 'h'
   static RedirectHandle_t loch;

   Int_t rc = 0;

   // Which handle to use ?
   RedirectHandle_t *xh = (h) ? h : &loch;

   if (file) {
      // Save the paths
      if (xh->fStdOutTty.IsNull()) {
         const char *tty = ttyname(STDOUT_FILENO);
         if (tty)
            xh->fStdOutTty = tty;
         else
            xh->fStdOutDup = dup(STDOUT_FILENO);
      }
      if (xh->fStdErrTty.IsNull()) {
         const char *tty = ttyname(STDERR_FILENO);
         if (tty)
            xh->fStdErrTty = tty;
         else
            xh->fStdErrDup = dup(STDERR_FILENO);
      }

      // Make sure mode makes sense; default "a"
      const char *m = (mode[0] == 'a' || mode[0] == 'w') ? mode : "a";

      // Current file size
      xh->fReadOffSet = 0;
      if (m[0] == 'a') {
         // If the file exists, save the current size
         FileStat_t st;
         if (!gSystem->GetPathInfo(file, st))
            xh->fReadOffSet = (st.fSize > 0) ? st.fSize : xh->fReadOffSet;
      }
      xh->fFile = file;

      // Redirect stdout & stderr
      if (freopen(file, m, stdout) == 0) {
         SysError("RedirectOutput", "could not freopen stdout");
         return -1;
      }
      if (freopen(file, m, stderr) == 0) {
         SysError("RedirectOutput", "could not freopen stderr");
         freopen(xh->fStdErrTty.Data(), "a", stderr);
         return -1;
      }
   } else {
      // Restore stdout & stderr
      fflush(stdout);
      if (!(xh->fStdOutTty.IsNull())) {
         if (freopen(xh->fStdOutTty.Data(), "a", stdout) == 0) {
            SysError("RedirectOutput", "could not restore stdout");
            rc = -1;
         }
         xh->fStdOutTty = "";
      } else {
         if (dup2(xh->fStdOutDup, STDOUT_FILENO) < 0) {
            SysError("RedirectOutput", "could not restore stdout (back to original redirected file)");
            rc = -1;
         }
      }
      fflush(stderr);
      if (!(xh->fStdErrTty.IsNull())) {
         if (freopen(xh->fStdErrTty.Data(), "a", stderr) == 0) {
            SysError("RedirectOutput", "could not restore stderr");
            rc = -1;
         }
         xh->fStdErrTty = "";
      } else {
         if (dup2(xh->fStdErrDup, STDERR_FILENO) < 0) {
            SysError("RedirectOutput", "could not restore stderr (back to original redirected file)");
            rc = -1;
         }
      }
      // Reset the static instance, if using that
      if (xh == &loch)
         xh->Reset();
   }
   return rc;
}

//---- dynamic loading and linking ---------------------------------------------

//______________________________________________________________________________
Func_t TUnixSystem::DynFindSymbol(const char *module, const char *entry)
{
   //dynamic linking of module
   #ifdef NOCINT
   return UnixDynFindSymbol(module,entry);
#else
   if (module) { }   // silence compiler about not using module
   return TSystem::DynFindSymbol("*", entry);
#endif
}

//______________________________________________________________________________
int TUnixSystem::Load(const char *module, const char *entry, Bool_t system)
{
   // Load a shared library. Returns 0 on successful loading, 1 in
   // case lib was already loaded and -1 in case lib does not exist
   // or in case of error.

#ifdef NOCINT
   int i = UnixDynLoad(module);
   if (!entry || !strlen(entry)) return i;

   Func_t f = UnixDynFindSymbol(module, entry);
   if (f) return 0;
   return -1;
#else
   return TSystem::Load(module, entry, system);
#endif
}

//______________________________________________________________________________
void TUnixSystem::Unload(const char *module)
{
   // Unload a shared library.

#ifdef NOCINT
   UnixDynUnload(module);
#else
   if (module) { TSystem::Unload(module); }
#endif
}

//______________________________________________________________________________
void TUnixSystem::ListSymbols(const char *module, const char *regexp)
{
   // List symbols in a shared library.

   UnixDynListSymbols(module, regexp);
}

//______________________________________________________________________________
void TUnixSystem::ListLibraries(const char *regexp)
{
   // List all loaded shared libraries.

#ifdef R__HPUX
   UnixDynListLibs(regexp);
#else
   TSystem::ListLibraries(regexp);
#endif
}

//______________________________________________________________________________
const char *TUnixSystem::GetLinkedLibraries()
{
   // Get list of shared libraries loaded at the start of the executable.
   // Returns 0 in case list cannot be obtained or in case of error.

#if !defined(R__MACOSX)
   if (!gApplication) return 0;
#endif

   static Bool_t once = kFALSE;
   static TString linkedLibs;

   R__LOCKGUARD2(gSystemMutex);

   if (!linkedLibs.IsNull())
      return linkedLibs;

   if (once)
      return 0;

#if !defined(R__MACOSX)
   char *exe = gSystem->Which(Getenv("PATH"), gApplication->Argv(0),
                              kExecutePermission);
   if (!exe) {
      once = kTRUE;
      return 0;
   }
#endif

#if defined(R__MACOSX)
   char *exe = 0;
   DylibAdded(0, 0);
   linkedLibs = gLinkedDylibs;
#if 0
   FILE *p = OpenPipe(Form("otool -L %s", exe), "r");
   TString otool;
   while (otool.Gets(p)) {
      TString delim(" \t");
      TObjArray *tok = otool.Tokenize(delim);
      TString dylib = ((TObjString*)tok->At(0))->String();
      if (dylib.EndsWith(".dylib") && !dylib.Contains("/libSystem.B.dylib")) {
         if (!linkedLibs.IsNull())
            linkedLibs += " ";
         linkedLibs += dylib;
      }
      delete tok;
   }
   ClosePipe(p);
#endif
#elif defined(R__LINUX) || defined(R__SOLARIS)
#if defined(R__WINGCC )
   const char *cLDD="cygcheck";
   const char *cSOEXT=".dll";
#else
   const char *cLDD="ldd";
   const char *cSOEXT=".so";
#endif
   FILE *p = OpenPipe(Form("%s %s", cLDD, exe), "r");
   TString ldd;
   while (ldd.Gets(p)) {
      TString delim(" \t");
      TObjArray *tok = ldd.Tokenize(delim);

      // expected format:
      //    libCore.so => /home/rdm/root/lib/libCore.so (0x40017000)
      TObjString *solibName = (TObjString*)tok->At(2);
      if (!solibName) {
         // case where there is only one name of the list:
         //    /usr/platform/SUNW,UltraAX-i2/lib/libc_psr.so.1
         solibName = (TObjString*)tok->At(0);
      }
      if (solibName) {
         TString solib = solibName->String();
         if (solib.EndsWith(cSOEXT)) {
            if (!linkedLibs.IsNull())
               linkedLibs += " ";
            linkedLibs += solib;
         }
      }
      delete tok;
   }
   ClosePipe(p);
#endif

   delete [] exe;

   once = kTRUE;

   if (linkedLibs.IsNull())
      return 0;

   return linkedLibs;
}

//---- Time & Date -------------------------------------------------------------

//______________________________________________________________________________
TTime TUnixSystem::Now()
{
   // Return current time.

   return UnixNow();
}

//______________________________________________________________________________
Bool_t TUnixSystem::DispatchTimers(Bool_t mode)
{
   // Handle and dispatch timers. If mode = kTRUE dispatch synchronous
   // timers else a-synchronous timers.

   if (!fTimers) return kFALSE;

   fInsideNotify = kTRUE;

   TOrdCollectionIter it((TOrdCollection*)fTimers);
   TTimer *t;
   Bool_t  timedout = kFALSE;

   while ((t = (TTimer *) it.Next())) {
      // NB: the timer resolution is added in TTimer::CheckTimer()
      Long_t now = UnixNow();
      if (mode && t->IsSync()) {
         if (t->CheckTimer(now))
            timedout = kTRUE;
      } else if (!mode && t->IsAsync()) {
         if (t->CheckTimer(now)) {
            UnixSetitimer(NextTimeOut(kFALSE));
            timedout = kTRUE;
         }
      }
   }
   fInsideNotify = kFALSE;
   return timedout;
}

//______________________________________________________________________________
void TUnixSystem::AddTimer(TTimer *ti)
{
   // Add timer to list of system timers.

   TSystem::AddTimer(ti);
   ResetTimer(ti);
}

//______________________________________________________________________________
TTimer *TUnixSystem::RemoveTimer(TTimer *ti)
{
   // Remove timer from list of system timers.

   if (!ti) return 0;

   R__LOCKGUARD2(gSystemMutex);

   TTimer *t = TSystem::RemoveTimer(ti);
   if (ti->IsAsync())
      UnixSetitimer(NextTimeOut(kFALSE));
   return t;
}

//______________________________________________________________________________
void TUnixSystem::ResetTimer(TTimer *ti)
{
   // Reset a-sync timer.

   if (!fInsideNotify && ti && ti->IsAsync())
      UnixSetitimer(NextTimeOut(kFALSE));
}

//---- RPC ---------------------------------------------------------------------

//______________________________________________________________________________
TInetAddress TUnixSystem::GetHostByName(const char *hostname)
{
   // Get Internet Protocol (IP) address of host. Returns an TInetAddress
   // object. To see if the hostname lookup was successfull call
   // TInetAddress::IsValid().

   struct hostent *host_ptr;
   const char     *host;
   int             type;
   UInt_t          addr;    // good for 4 byte addresses

#ifdef HASNOT_INETATON
   if ((addr = (UInt_t)inet_addr(hostname)) != INADDR_NONE) {
#else
   struct in_addr ad;
   if (inet_aton(hostname, &ad)) {
      memcpy(&addr, &ad.s_addr, sizeof(ad.s_addr));
#endif
      type = AF_INET;
      if ((host_ptr = gethostbyaddr((const char *)&addr,
                                    sizeof(addr), AF_INET))) {
         host = host_ptr->h_name;
         TInetAddress a(host, ntohl(addr), type);
         UInt_t addr2;
         Int_t  i;
         for (i = 1; host_ptr->h_addr_list[i]; i++) {
            memcpy(&addr2, host_ptr->h_addr_list[i], host_ptr->h_length);
            a.AddAddress(ntohl(addr2));
         }
         for (i = 0; host_ptr->h_aliases[i]; i++)
            a.AddAlias(host_ptr->h_aliases[i]);
         return a;
      } else {
         host = "UnNamedHost";
      }
   } else if ((host_ptr = gethostbyname(hostname))) {
      // Check the address type for an internet host
      if (host_ptr->h_addrtype != AF_INET) {
         Error("GetHostByName", "%s is not an internet host\n", hostname);
         return TInetAddress();
      }
      memcpy(&addr, host_ptr->h_addr, host_ptr->h_length);
      host = host_ptr->h_name;
      type = host_ptr->h_addrtype;
      TInetAddress a(host, ntohl(addr), type);
      UInt_t addr2;
      Int_t  i;
      for (i = 1; host_ptr->h_addr_list[i]; i++) {
         memcpy(&addr2, host_ptr->h_addr_list[i], host_ptr->h_length);
         a.AddAddress(ntohl(addr2));
      }
      for (i = 0; host_ptr->h_aliases[i]; i++)
         a.AddAlias(host_ptr->h_aliases[i]);
      return a;
   } else {
      if (gDebug > 0) Error("GetHostByName", "unknown host %s", hostname);
      return TInetAddress(hostname, 0, -1);
   }

   return TInetAddress(host, ntohl(addr), type);
}

//______________________________________________________________________________
TInetAddress TUnixSystem::GetSockName(int sock)
{
   // Get Internet Protocol (IP) address of host and port #.

   struct sockaddr_in addr;
#if defined(USE_SIZE_T)
   size_t len = sizeof(addr);
#elif defined(USE_SOCKLEN_T)
   socklen_t len = sizeof(addr);
#else
   int len = sizeof(addr);
#endif

   if (getsockname(sock, (struct sockaddr *)&addr, &len) == -1) {
      SysError("GetSockName", "getsockname");
      return TInetAddress();
   }

   struct hostent *host_ptr;
   const char *hostname;
   int         family;
   UInt_t      iaddr;

   if ((host_ptr = gethostbyaddr((const char *)&addr.sin_addr,
                                 sizeof(addr.sin_addr), AF_INET))) {
      memcpy(&iaddr, host_ptr->h_addr, host_ptr->h_length);
      hostname = host_ptr->h_name;
      family   = host_ptr->h_addrtype;
   } else {
      memcpy(&iaddr, &addr.sin_addr, sizeof(addr.sin_addr));
      hostname = "????";
      family   = AF_INET;
   }

   return TInetAddress(hostname, ntohl(iaddr), family, ntohs(addr.sin_port));
}

//______________________________________________________________________________
TInetAddress TUnixSystem::GetPeerName(int sock)
{
   // Get Internet Protocol (IP) address of remote host and port #.

   struct sockaddr_in addr;
#if defined(USE_SIZE_T)
   size_t len = sizeof(addr);
#elif defined(USE_SOCKLEN_T)
   socklen_t len = sizeof(addr);
#else
   int len = sizeof(addr);
#endif

   if (getpeername(sock, (struct sockaddr *)&addr, &len) == -1) {
      SysError("GetPeerName", "getpeername");
      return TInetAddress();
   }

   struct hostent *host_ptr;
   const char *hostname;
   int         family;
   UInt_t      iaddr;

   if ((host_ptr = gethostbyaddr((const char *)&addr.sin_addr,
                                 sizeof(addr.sin_addr), AF_INET))) {
      memcpy(&iaddr, host_ptr->h_addr, host_ptr->h_length);
      hostname = host_ptr->h_name;
      family   = host_ptr->h_addrtype;
   } else {
      memcpy(&iaddr, &addr.sin_addr, sizeof(addr.sin_addr));
      hostname = "????";
      family   = AF_INET;
   }

   return TInetAddress(hostname, ntohl(iaddr), family, ntohs(addr.sin_port));
}

//______________________________________________________________________________
int TUnixSystem::GetServiceByName(const char *servicename)
{
   // Get port # of internet service.

   struct servent *sp;

   if ((sp = getservbyname(servicename, kProtocolName)) == 0) {
      Error("GetServiceByName", "no service \"%s\" with protocol \"%s\"\n",
              servicename, kProtocolName);
      return -1;
   }
   return ntohs(sp->s_port);
}

//______________________________________________________________________________
char *TUnixSystem::GetServiceByPort(int port)
{
   // Get name of internet service.

   struct servent *sp;

   if ((sp = getservbyport(htons(port), kProtocolName)) == 0) {
      //::Error("GetServiceByPort", "no service \"%d\" with protocol \"%s\"",
      //        port, kProtocolName);
      return Form("%d", port);
   }
   return sp->s_name;
}

//______________________________________________________________________________
int TUnixSystem::ConnectService(const char *servername, int port,
                                int tcpwindowsize)
{
   // Connect to service servicename on server servername.

   if (!strcmp(servername, "unix"))
      return UnixUnixConnect(port);
   return UnixTcpConnect(servername, port, tcpwindowsize);
}

//______________________________________________________________________________
int TUnixSystem::OpenConnection(const char *server, int port, int tcpwindowsize)
{
   // Open a connection to a service on a server. Returns -1 in case
   // connection cannot be opened.
   // Use tcpwindowsize to specify the size of the receive buffer, it has
   // to be specified here to make sure the window scale option is set (for
   // tcpwindowsize > 65KB and for platforms supporting window scaling).
   // Is called via the TSocket constructor.

   return ConnectService(server, port, tcpwindowsize);
}

//______________________________________________________________________________
int TUnixSystem::AnnounceTcpService(int port, Bool_t reuse, int backlog,
                                    int tcpwindowsize)
{
   // Announce TCP/IP service.
   // Open a socket, bind to it and start listening for TCP/IP connections
   // on the port. If reuse is true reuse the address, backlog specifies
   // how many sockets can be waiting to be accepted.
   // Use tcpwindowsize to specify the size of the receive buffer, it has
   // to be specified here to make sure the window scale option is set (for
   // tcpwindowsize > 65KB and for platforms supporting window scaling).
   // Returns socket fd or -1 if socket() failed, -2 if bind() failed
   // or -3 if listen() failed.

   return UnixTcpService(port, reuse, backlog, tcpwindowsize);
}

//______________________________________________________________________________
int TUnixSystem::AnnounceUnixService(int port, int backlog)
{
   // Announce unix domain service.

   return UnixUnixService(port, backlog);
}

//______________________________________________________________________________
int TUnixSystem::AcceptConnection(int sock)
{
   // Accept a connection. In case of an error return -1. In case
   // non-blocking I/O is enabled and no connections are available
   // return -2.

   int soc = -1;

   while ((soc = ::accept(sock, 0, 0)) == -1 && GetErrno() == EINTR)
      ResetErrno();

   if (soc == -1) {
      if (GetErrno() == EWOULDBLOCK)
         return -2;
      else {
         SysError("AcceptConnection", "accept");
         return -1;
      }
   }

   return soc;
}

//______________________________________________________________________________
void TUnixSystem::CloseConnection(int sock, Bool_t force)
{
   // Close socket.

   if (sock < 0) return;

#if !defined(R__AIX) || defined(_AIX41) || defined(_AIX43)
   if (force)
      ::shutdown(sock, 2);   // will also close connection of parent
#endif

   while (::close(sock) == -1 && GetErrno() == EINTR)
      ResetErrno();
}

//______________________________________________________________________________
int TUnixSystem::RecvBuf(int sock, void *buf, int length)
{
   // Receive a buffer headed by a length indicator. Lenght is the size of
   // the buffer. Returns the number of bytes received in buf or -1 in
   // case of error.

   Int_t header;

   if (UnixRecv(sock, &header, sizeof(header), 0) > 0) {
      int count = ntohl(header);

      if (count > length) {
         Error("RecvBuf", "record header exceeds buffer size");
         return -1;
      } else if (count > 0) {
         if (UnixRecv(sock, buf, count, 0) < 0) {
            Error("RecvBuf", "cannot receive buffer");
            return -1;
         }
      }
      return count;
   }
   return -1;
}

//______________________________________________________________________________
int TUnixSystem::SendBuf(int sock, const void *buf, int length)
{
   // Send a buffer headed by a length indicator. Returns length of sent buffer
   // or -1 in case of error.

   Int_t header = htonl(length);

   if (UnixSend(sock, &header, sizeof(header), 0) < 0) {
      Error("SendBuf", "cannot send header");
      return -1;
   }
   if (length > 0) {
      if (UnixSend(sock, buf, length, 0) < 0) {
         Error("SendBuf", "cannot send buffer");
         return -1;
      }
   }
   return length;
}

//______________________________________________________________________________
int TUnixSystem::RecvRaw(int sock, void *buf, int length, int opt)
{
   // Receive exactly length bytes into buffer. Use opt to receive out-of-band
   // data or to have a peek at what is in the buffer (see TSocket). Buffer
   // must be able to store at least length bytes. Returns the number of
   // bytes received (can be 0 if other side of connection was closed) or -1
   // in case of error, -2 in case of MSG_OOB and errno == EWOULDBLOCK, -3
   // in case of MSG_OOB and errno == EINVAL and -4 in case of kNoBlock and
   // errno == EWOULDBLOCK. Returns -5 if pipe broken or reset by peer
   // (EPIPE || ECONNRESET).

   int flag;

   switch (opt) {
   case kDefault:
      flag = 0;
      break;
   case kOob:
      flag = MSG_OOB;
      break;
   case kPeek:
      flag = MSG_PEEK;
      break;
   case kDontBlock:
      flag = -1;
      break;
   default:
      flag = 0;
      break;
   }

   int n;
   if ((n = UnixRecv(sock, buf, length, flag)) <= 0) {
      if (n == -1 && GetErrno() != EINTR)
         Error("RecvRaw", "cannot receive buffer");
      return n;
   }
   return n;
}

//______________________________________________________________________________
int TUnixSystem::SendRaw(int sock, const void *buf, int length, int opt)
{
   // Send exactly length bytes from buffer. Use opt to send out-of-band
   // data (see TSocket). Returns the number of bytes sent or -1 in case of
   // error. Returns -4 in case of kNoBlock and errno == EWOULDBLOCK.
   // Returns -5 if pipe broken or reset by peer (EPIPE || ECONNRESET).

   int flag;

   switch (opt) {
   case kDefault:
      flag = 0;
      break;
   case kOob:
      flag = MSG_OOB;
      break;
   case kDontBlock:
      flag = -1;
      break;
   case kPeek:            // receive only option (see RecvRaw)
   default:
      flag = 0;
      break;
   }

   int n;
   if ((n = UnixSend(sock, buf, length, flag)) <= 0) {
      if (n == -1 && GetErrno() != EINTR)
         Error("SendRaw", "cannot send buffer");
      return n;
   }
   return n;
}

//______________________________________________________________________________
int TUnixSystem::SetSockOpt(int sock, int opt, int val)
{
   // Set socket option.

   if (sock < 0) return -1;

   switch (opt) {
   case kSendBuffer:
      if (setsockopt(sock, SOL_SOCKET, SO_SNDBUF, (char*)&val, sizeof(val)) == -1) {
         SysError("SetSockOpt", "setsockopt(SO_SNDBUF)");
         return -1;
      }
      break;
   case kRecvBuffer:
      if (setsockopt(sock, SOL_SOCKET, SO_RCVBUF, (char*)&val, sizeof(val)) == -1) {
         SysError("SetSockOpt", "setsockopt(SO_RCVBUF)");
         return -1;
      }
      break;
   case kOobInline:
      if (setsockopt(sock, SOL_SOCKET, SO_OOBINLINE, (char*)&val, sizeof(val)) == -1) {
         SysError("SetSockOpt", "setsockopt(SO_OOBINLINE)");
         return -1;
      }
      break;
   case kKeepAlive:
      if (setsockopt(sock, SOL_SOCKET, SO_KEEPALIVE, (char*)&val, sizeof(val)) == -1) {
         SysError("SetSockOpt", "setsockopt(SO_KEEPALIVE)");
         return -1;
      }
      break;
   case kReuseAddr:
      if (setsockopt(sock, SOL_SOCKET, SO_REUSEADDR, (char*)&val, sizeof(val)) == -1) {
         SysError("SetSockOpt", "setsockopt(SO_REUSEADDR)");
         return -1;
      }
      break;
   case kNoDelay:
      if (setsockopt(sock, IPPROTO_TCP, TCP_NODELAY, (char*)&val, sizeof(val)) == -1) {
         SysError("SetSockOpt", "setsockopt(TCP_NODELAY)");
         return -1;
      }
      break;
   case kNoBlock:
      if (ioctl(sock, FIONBIO, (char*)&val) == -1) {
         SysError("SetSockOpt", "ioctl(FIONBIO)");
         return -1;
      }
      break;
   case kProcessGroup:
#ifndef R__WINGCC
      if (ioctl(sock, SIOCSPGRP, (char*)&val) == -1) {
         SysError("SetSockOpt", "ioctl(SIOCSPGRP)");
         return -1;
      }
#else
      Error("SetSockOpt", "ioctl(SIOCGPGRP) not supported on cygwin/gcc");
      return -1;
#endif
      break;
   case kAtMark:       // read-only option (see GetSockOpt)
   case kBytesToRead:  // read-only option
   default:
      Error("SetSockOpt", "illegal option (%d)", opt);
      return -1;
   }
   return 0;
}

//______________________________________________________________________________
int TUnixSystem::GetSockOpt(int sock, int opt, int *val)
{
   // Get socket option.

   if (sock < 0) return -1;

#if defined(USE_SOCKLEN_T) || defined(_AIX43)
   socklen_t optlen = sizeof(*val);
#elif defined(USE_SIZE_T)
   size_t optlen = sizeof(*val);
#else
   int optlen = sizeof(*val);
#endif

   switch (opt) {
   case kSendBuffer:
      if (getsockopt(sock, SOL_SOCKET, SO_SNDBUF, (char*)val, &optlen) == -1) {
         SysError("GetSockOpt", "getsockopt(SO_SNDBUF)");
         return -1;
      }
      break;
   case kRecvBuffer:
      if (getsockopt(sock, SOL_SOCKET, SO_RCVBUF, (char*)val, &optlen) == -1) {
         SysError("GetSockOpt", "getsockopt(SO_RCVBUF)");
         return -1;
      }
      break;
   case kOobInline:
      if (getsockopt(sock, SOL_SOCKET, SO_OOBINLINE, (char*)val, &optlen) == -1) {
         SysError("GetSockOpt", "getsockopt(SO_OOBINLINE)");
         return -1;
      }
      break;
   case kKeepAlive:
      if (getsockopt(sock, SOL_SOCKET, SO_KEEPALIVE, (char*)val, &optlen) == -1) {
         SysError("GetSockOpt", "getsockopt(SO_KEEPALIVE)");
         return -1;
      }
      break;
   case kReuseAddr:
      if (getsockopt(sock, SOL_SOCKET, SO_REUSEADDR, (char*)val, &optlen) == -1) {
         SysError("GetSockOpt", "getsockopt(SO_REUSEADDR)");
         return -1;
      }
      break;
   case kNoDelay:
      if (getsockopt(sock, IPPROTO_TCP, TCP_NODELAY, (char*)val, &optlen) == -1) {
         SysError("GetSockOpt", "getsockopt(TCP_NODELAY)");
         return -1;
      }
      break;
   case kNoBlock:
      int flg;
      if ((flg = fcntl(sock, F_GETFL, 0)) == -1) {
         SysError("GetSockOpt", "fcntl(F_GETFL)");
         return -1;
      }
      *val = flg & O_NDELAY;
      break;
   case kProcessGroup:
#if !defined(R__LYNXOS) && !defined(R__WINGCC)
      if (ioctl(sock, SIOCGPGRP, (char*)val) == -1) {
         SysError("GetSockOpt", "ioctl(SIOCGPGRP)");
         return -1;
      }
#else
      Error("GetSockOpt", "ioctl(SIOCGPGRP) not supported on LynxOS and cygwin/gcc");
      return -1;
#endif
      break;
   case kAtMark:
#if !defined(R__LYNXOS)
      if (ioctl(sock, SIOCATMARK, (char*)val) == -1) {
         SysError("GetSockOpt", "ioctl(SIOCATMARK)");
         return -1;
      }
#else
      Error("GetSockOpt", "ioctl(SIOCATMARK) not supported on LynxOS");
      return -1;
#endif
      break;
   case kBytesToRead:
#if !defined(R__LYNXOS)
      if (ioctl(sock, FIONREAD, (char*)val) == -1) {
         SysError("GetSockOpt", "ioctl(FIONREAD)");
         return -1;
      }
#else
      Error("GetSockOpt", "ioctl(FIONREAD) not supported on LynxOS");
      return -1;
#endif
      break;
   default:
      Error("GetSockOpt", "illegal option (%d)", opt);
      *val = 0;
      return -1;
   }
   return 0;
}

//////////////////////////////////////////////////////////////////////////
//                                                                      //
// Static Protected Unix Interface functions.                           //
//                                                                      //
//////////////////////////////////////////////////////////////////////////

//---- signals -----------------------------------------------------------------

static struct Signalmap_t {
   int               fCode;
   SigHandler_t      fHandler;
   struct sigaction *fOldHandler;
   const char       *fSigName;
} gSignalMap[kMAXSIGNALS] = {       // the order of the signals should be identical
   { SIGBUS,   0, 0, "bus error" }, // to the one in TSysEvtHandler.h
   { SIGSEGV,  0, 0, "segmentation violation" },
   { SIGSYS,   0, 0, "bad argument to system call" },
   { SIGPIPE,  0, 0, "write on a pipe with no one to read it" },
   { SIGILL,   0, 0, "illegal instruction" },
   { SIGQUIT,  0, 0, "quit" },
   { SIGINT,   0, 0, "interrupt" },
   { SIGWINCH, 0, 0, "window size change" },
   { SIGALRM,  0, 0, "alarm clock" },
   { SIGCHLD,  0, 0, "death of a child" },
   { SIGURG,   0, 0, "urgent data arrived on an I/O channel" },
   { SIGFPE,   0, 0, "floating point exception" },
   { SIGTERM,  0, 0, "termination signal" },
   { SIGUSR1,  0, 0, "user-defined signal 1" },
   { SIGUSR2,  0, 0, "user-defined signal 2" }
};


//______________________________________________________________________________
static void sighandler(int sig)
{
   // Call the signal handler associated with the signal.

   for (int i= 0; i < kMAXSIGNALS; i++) {
      if (gSignalMap[i].fCode == sig) {
         (*gSignalMap[i].fHandler)((ESignals)i);
         return;
      }
   }
}

#if defined(R__KCC)
   extern "C" {
      typedef void (*sighandlerFunc_t)(int);
   }
#endif

//______________________________________________________________________________
void TUnixSystem::UnixSignal(ESignals sig, SigHandler_t handler)
{
   // Set a signal handler for a signal.

   if (gSignalMap[sig].fHandler != handler) {
      struct sigaction sigact;

      gSignalMap[sig].fHandler    = handler;
      gSignalMap[sig].fOldHandler = new struct sigaction();

#if defined(R__SUN)
      sigact.sa_handler = (void (*)())sighandler;
#elif defined(R__SOLARIS)
      sigact.sa_handler = sighandler;
#elif defined(R__KCC)
      sigact.sa_handler = (sighandlerFunc_t)sighandler;
#elif (defined(R__SGI) && !defined(R__KCC)) || defined(R__LYNXOS)
#  if defined(R__SGI64) || (__GNUG__>=3)
      sigact.sa_handler = sighandler;
#  else
      sigact.sa_handler = (void (*)(...))sighandler;
#  endif
#else
      sigact.sa_handler = sighandler;
#endif
      sigemptyset(&sigact.sa_mask);
      sigact.sa_flags = 0;
#if defined(SA_RESTART)
      sigact.sa_flags |= SA_RESTART;
#endif
      if (sigaction(gSignalMap[sig].fCode, &sigact,
                    gSignalMap[sig].fOldHandler) < 0)
         ::SysError("TUnixSystem::UnixSignal", "sigaction");
   }
}

//______________________________________________________________________________
void TUnixSystem::UnixIgnoreSignal(ESignals sig, Bool_t ignore)
{
   // If ignore is true ignore the specified signal, else restore previous
   // behaviour.

   static Bool_t ignoreSig[kMAXSIGNALS] = { kFALSE };
   static struct sigaction oldsigact[kMAXSIGNALS];

   if (ignore != ignoreSig[sig]) {
      ignoreSig[sig] = ignore;
      if (ignore) {
         struct sigaction sigact;
#if defined(R__SUN)
         sigact.sa_handler = (void (*)())SIG_IGN;
#elif defined(R__SOLARIS)
         sigact.sa_handler = (void (*)(int))SIG_IGN;
#else
         sigact.sa_handler = SIG_IGN;
#endif
         sigemptyset(&sigact.sa_mask);
         sigact.sa_flags = 0;
         if (sigaction(gSignalMap[sig].fCode, &sigact, &oldsigact[sig]) < 0)
            ::SysError("TUnixSystem::UnixIgnoreSignal", "sigaction");
      } else {
         if (sigaction(gSignalMap[sig].fCode, &oldsigact[sig], 0) < 0)
            ::SysError("TUnixSystem::UnixIgnoreSignal", "sigaction");
      }
   }
}

//______________________________________________________________________________
void TUnixSystem::UnixSigAlarmInterruptsSyscalls(Bool_t set)
{
   // When the argument is true the SIGALRM signal handler is set so that
   // interrupted syscalls will not be restarted by the kernel. This is
   // typically used in case one wants to put a timeout on an I/O operation.
   // By default interrupted syscalls will always be restarted (for all
   // signals). This can be controlled for each a-synchronous TTimer via
   // the method TTimer::SetInterruptSyscalls().

   if (gSignalMap[kSigAlarm].fHandler) {
      struct sigaction sigact;
#if defined(R__SUN)
      sigact.sa_handler = (void (*)())sighandler;
#elif defined(R__SOLARIS)
      sigact.sa_handler = sighandler;
#elif defined(R__KCC)
      sigact.sa_handler = (sighandlerFunc_t)sighandler;
#elif (defined(R__SGI) && !defined(R__KCC)) || defined(R__LYNXOS)
#  if defined(R__SGI64) || (__GNUG__>=3)
      sigact.sa_handler = sighandler;
#  else
      sigact.sa_handler = (void (*)(...))sighandler;
#  endif
#else
      sigact.sa_handler = sighandler;
#endif
      sigemptyset(&sigact.sa_mask);
      sigact.sa_flags = 0;
      if (set) {
#if defined(SA_INTERRUPT)       // SunOS
         sigact.sa_flags |= SA_INTERRUPT;
#endif
      } else {
#if defined(SA_RESTART)
         sigact.sa_flags |= SA_RESTART;
#endif
      }
      if (sigaction(gSignalMap[kSigAlarm].fCode, &sigact, 0) < 0)
         ::SysError("TUnixSystem::UnixSigAlarmInterruptsSyscalls", "sigaction");
   }
}

//______________________________________________________________________________
const char *TUnixSystem::UnixSigname(ESignals sig)
{
   // Return the signal name associated with a signal.

   return gSignalMap[sig].fSigName;
}

//______________________________________________________________________________
void TUnixSystem::UnixResetSignal(ESignals sig)
{
   // Restore old signal handler for specified signal.

   if (gSignalMap[sig].fOldHandler) {
      // restore old signal handler
      sigaction(gSignalMap[sig].fCode, gSignalMap[sig].fOldHandler, 0);
      delete gSignalMap[sig].fOldHandler;
      gSignalMap[sig].fOldHandler = 0;
      gSignalMap[sig].fHandler    = 0;
   }
}

//______________________________________________________________________________
void TUnixSystem::UnixResetSignals()
{
   // Restore old signal handlers.

   for (int sig = 0; sig < kMAXSIGNALS; sig++) {
      if (gSignalMap[sig].fOldHandler) {
         // restore old signal handler
         sigaction(gSignalMap[sig].fCode, gSignalMap[sig].fOldHandler, 0);
         delete gSignalMap[sig].fOldHandler;
         gSignalMap[sig].fOldHandler = 0;
         gSignalMap[sig].fHandler    = 0;
      }
   }
}

//---- time --------------------------------------------------------------------

//______________________________________________________________________________
Long_t TUnixSystem::UnixNow()
{
   // Get current time in milliseconds since 0:00 Jan 1 1995.

   static time_t jan95 = 0;
   if (!jan95) {
      struct tm tp;
      tp.tm_year  = 95;
      tp.tm_mon   = 0;
      tp.tm_mday  = 1;
      tp.tm_hour  = 0;
      tp.tm_min   = 0;
      tp.tm_sec   = 0;
      tp.tm_isdst = -1;

      jan95 = mktime(&tp);
      if ((int)jan95 == -1) {
         ::SysError("TUnixSystem::UnixNow", "error converting 950001 0:00 to time_t");
         return 0;
      }
   }

   struct timeval t;
   gettimeofday(&t, 0);
   return (t.tv_sec-(Long_t)jan95)*1000 + t.tv_usec/1000;
}

//______________________________________________________________________________
int TUnixSystem::UnixSetitimer(Long_t ms)
{
   // Set interval timer to time-out in ms milliseconds.

   struct itimerval itv;
   itv.it_value.tv_sec     = 0;
   itv.it_value.tv_usec    = 0;
   itv.it_interval.tv_sec  = 0;
   itv.it_interval.tv_usec = 0;
   if (ms > 0) {
      itv.it_value.tv_sec  = time_t(ms / 1000);
      itv.it_value.tv_usec = time_t((ms % 1000) * 1000);
   }
   int st = setitimer(ITIMER_REAL, &itv, 0);
   if (st == -1)
      ::SysError("TUnixSystem::UnixSetitimer", "setitimer");
   return st;
}

//---- file descriptors --------------------------------------------------------

//______________________________________________________________________________
int TUnixSystem::UnixSelect(Int_t nfds, TFdSet *readready, TFdSet *writeready,
                            Long_t timeout)
{
   // Wait for events on the file descriptors specified in the readready and
   // writeready masks or for timeout (in milliseconds) to occur. Returns
   // the number of ready descriptors, or 0 in case of timeout, or < 0 in
   // case of an error, with -2 being EINTR and -3 EBADF. In case of EINTR
   // the errno has been reset and the method can be called again.

   int retcode;

#if defined(R__HPUX) && defined(R__B64)
   fd_set frd;
   fd_set fwr;
   FD_ZERO(&frd);
   FD_ZERO(&fwr);
   for (int i = 0; i < nfds; i++) {
      if (readready  && readready->IsSet(i))  FD_SET(i, &frd);
      if (writeready && writeready->IsSet(i)) FD_SET(i, &fwr);
   }
   fd_set *rd = (readready)  ? &frd : 0;
   fd_set *wr = (writeready) ? &fwr : 0;
#else
   fd_set *rd = (readready)  ? (fd_set*)readready->GetBits()  : 0;
   fd_set *wr = (writeready) ? (fd_set*)writeready->GetBits() : 0;
#endif

   if (timeout >= 0) {
      struct timeval tv;
      tv.tv_sec  = Int_t(timeout / 1000);
      tv.tv_usec = (timeout % 1000) * 1000;
      retcode = select(nfds, rd, wr, 0, &tv);
   } else {
      retcode = select(nfds, rd, wr, 0, 0);
   }
   if (retcode == -1) {
      if (GetErrno() == EINTR) {
         ResetErrno();  // errno is not self reseting
         return -2;
      }
      if (GetErrno() == EBADF)
         return -3;
      return -1;
   }

#if defined(R__HPUX) && defined(R__B64)
   if (rd) readready->Zero();
   if (wr) writeready->Zero();
   for (int i = 0; i < nfds; i++) {
      if (rd && FD_ISSET(i, rd)) readready->Set(i);
      if (wr && FD_ISSET(i, wr)) writeready->Set(i);
   }
#endif

   return retcode;
}

//---- directories -------------------------------------------------------------

//______________________________________________________________________________
const char *TUnixSystem::UnixHomedirectory(const char *name)
{
   // Returns the user's home directory.

   static char path[kMAXPATHLEN], mydir[kMAXPATHLEN];
   struct passwd *pw;

   if (name) {
      pw = getpwnam(name);
      if (pw) {
         strncpy(path, pw->pw_dir, kMAXPATHLEN);
         return path;
      }
   } else {
      if (mydir[0])
         return mydir;
      pw = getpwuid(getuid());
      if (pw) {
         strncpy(mydir, pw->pw_dir, kMAXPATHLEN);
         return mydir;
      }
   }
   return 0;
}

//______________________________________________________________________________
int TUnixSystem::UnixMakedir(const char *dir)
{
   // Make a Unix file system directory. Returns 0 in case of success and
   // -1 if the directory could not be created (either already exists or
   // illegal path name).

   return ::mkdir(StripOffProto(dir, "file:"), 0755);
}

//______________________________________________________________________________
void *TUnixSystem::UnixOpendir(const char *dir)
{
   // Open a directory.

   struct stat finfo;

   const char *edir = StripOffProto(dir, "file:");

   if (stat(edir, &finfo) < 0)
      return 0;

   if (!S_ISDIR(finfo.st_mode))
      return 0;

   return (void*) opendir(edir);
}

#if defined(_POSIX_SOURCE) || defined(__CYGWIN__)
// Posix does not require that the d_ino field be present, and some
// systems do not provide it.
#   define REAL_DIR_ENTRY(dp) 1
#else
#   define REAL_DIR_ENTRY(dp) (dp->d_ino != 0)
#endif

//______________________________________________________________________________
const char *TUnixSystem::UnixGetdirentry(void *dirp1)
{
   // Returns the next directory entry.

   DIR *dirp = (DIR*)dirp1;
#ifdef HAS_DIRENT
   struct dirent *dp;
#else
   struct direct *dp;
#endif

   if (dirp) {
      for (;;) {
         dp = readdir(dirp);
         if (dp == 0)
            return 0;
         if (REAL_DIR_ENTRY(dp))
            return dp->d_name;
      }
   }
   return 0;
}

//---- files -------------------------------------------------------------------

//______________________________________________________________________________
int TUnixSystem::UnixFilestat(const char *fpath, FileStat_t &buf)
{
   // Get info about a file. Info is returned in the form of a FileStat_t
   // structure (see TSystem.h).
   // The function returns 0 in case of success and 1 if the file could
   // not be stat'ed.

   const char *path = StripOffProto(fpath, "file:");
   buf.fIsLink = kFALSE;

#if defined(R__SEEK64)
   struct stat64 sbuf;
   if (path && lstat64(path, &sbuf) == 0) {
#else
   struct stat sbuf;
   if (path && lstat(path, &sbuf) == 0) {
#endif
      buf.fIsLink = S_ISLNK(sbuf.st_mode);
      if (buf.fIsLink) {
#if defined(R__SEEK64)
         if (stat64(path, &sbuf) == -1) {
#else
         if (stat(path, &sbuf) == -1) {
#endif
            return 1;
         }
      }
      buf.fDev   = sbuf.st_dev;
      buf.fIno   = sbuf.st_ino;
      buf.fMode  = sbuf.st_mode;
      buf.fUid   = sbuf.st_uid;
      buf.fGid   = sbuf.st_gid;
      buf.fSize  = sbuf.st_size;
      buf.fMtime = sbuf.st_mtime;

      return 0;
   }
   return 1;
}

//______________________________________________________________________________
int TUnixSystem::UnixFSstat(const char *path, Long_t *id, Long_t *bsize,
                            Long_t *blocks, Long_t *bfree)
{
   // Get info about a file system: id, bsize, bfree, blocks.
   // Id      is file system type (machine dependend, see statfs())
   // Bsize   is block size of file system
   // Blocks  is total number of blocks in file system
   // Bfree   is number of free blocks in file system
   // The function returns 0 in case of success and 1 if the file system could
   // not be stat'ed.

   struct statfs statfsbuf;
#if defined(R__SGI) || (defined(R__SOLARIS) && !defined(R__LINUX))
   if (statfs(path, &statfsbuf, sizeof(struct statfs), 0) == 0) {
      *id = statfsbuf.f_fstyp;
      *bsize = statfsbuf.f_bsize;
      *blocks = statfsbuf.f_blocks;
      *bfree = statfsbuf.f_bfree;
#else
   if (statfs((char*)path, &statfsbuf) == 0) {
#ifdef R__OBSD
      // Convert BSD filesystem names to Linux filesystem type numbers
      // where possible.  Linux statfs uses a value of -1 to indicate
      // an unsupported field.

      if (!strcmp(statfsbuf.f_fstypename, MOUNT_FFS) ||
          !strcmp(statfsbuf.f_fstypename, MOUNT_MFS))
         *id = 0x11954;
      else if (!strcmp(statfsbuf.f_fstypename, MOUNT_NFS))
         *id = 0x6969;
      else if (!strcmp(statfsbuf.f_fstypename, MOUNT_MSDOS))
         *id = 0x4d44;
      else if (!strcmp(statfsbuf.f_fstypename, MOUNT_PROCFS))
         *id = 0x9fa0;
      else if (!strcmp(statfsbuf.f_fstypename, MOUNT_EXT2FS))
         *id = 0xef53;
      else if (!strcmp(statfsbuf.f_fstypename, MOUNT_CD9660))
         *id = 0x9660;
      else if (!strcmp(statfsbuf.f_fstypename, MOUNT_NCPFS))
         *id = 0x6969;
      else
         *id = -1;
#else
      *id = statfsbuf.f_type;
#endif
      *bsize = statfsbuf.f_bsize;
      *blocks = statfsbuf.f_blocks;
      *bfree = statfsbuf.f_bavail;
#endif
      return 0;
   }
   return 1;
}

//______________________________________________________________________________
int TUnixSystem::UnixWaitchild()
{
   // Wait till child is finished.

   int status;
   return (int) waitpid(0, &status, WNOHANG);
}

//---- RPC -------------------------------------------------------------------

//______________________________________________________________________________
int TUnixSystem::UnixTcpConnect(const char *hostname, int port,
                                int tcpwindowsize)
{
   // Open a TCP/IP connection to server and connect to a service (i.e. port).
   // Use tcpwindowsize to specify the size of the receive buffer, it has
   // to be specified here to make sure the window scale option is set (for
   // tcpwindowsize > 65KB and for platforms supporting window scaling).
   // Is called via the TSocket constructor.

   short  sport;
   struct servent *sp;

   if ((sp = getservbyport(htons(port), kProtocolName)))
      sport = sp->s_port;
   else
      sport = htons(port);

   TInetAddress addr = gSystem->GetHostByName(hostname);
   if (!addr.IsValid()) return -1;
   UInt_t adr = htonl(addr.GetAddress());

   struct sockaddr_in server;
   memset(&server, 0, sizeof(server));
   memcpy(&server.sin_addr, &adr, sizeof(adr));
   server.sin_family = addr.GetFamily();
   server.sin_port   = sport;

   // Create socket
   int sock;
   if ((sock = socket(AF_INET, SOCK_STREAM, 0)) < 0) {
      ::SysError("TUnixSystem::UnixTcpConnect", "socket (%s:%d)",
                 hostname, port);
      return -1;
   }

   if (tcpwindowsize > 0) {
      gSystem->SetSockOpt(sock, kRecvBuffer, tcpwindowsize);
      gSystem->SetSockOpt(sock, kSendBuffer, tcpwindowsize);
   }

   if (connect(sock, (struct sockaddr*) &server, sizeof(server)) < 0) {
      ::SysError("TUnixSystem::UnixTcpConnect", "connect (%s:%d)",
                 hostname, port);
      close(sock);
      return -1;
   }
   return sock;
}

//______________________________________________________________________________
int TUnixSystem::UnixUnixConnect(int port)
{
   // Connect to a Unix domain socket.

   int sock;
   char buf[100];
   struct sockaddr_un unserver;

   sprintf(buf, "%s/%d", kServerPath, port);

   unserver.sun_family = AF_UNIX;
   strcpy(unserver.sun_path, buf);

   // Open socket
   if ((sock = socket(AF_UNIX, SOCK_STREAM, 0)) < 0) {
      ::SysError("TUnixSystem::UnixUnixConnect", "socket");
      return -1;
   }

   if (connect(sock, (struct sockaddr*) &unserver, strlen(unserver.sun_path)+2) < 0) {
      ::SysError("TUnixSystem::UnixUnixConnect", "connect");
      close(sock);
      return -1;
   }
   return sock;
}

//______________________________________________________________________________
int TUnixSystem::UnixTcpService(int port, Bool_t reuse, int backlog,
                                int tcpwindowsize)
{
   // Open a socket, bind to it and start listening for TCP/IP connections
   // on the port. If reuse is true reuse the address, backlog specifies
   // how many sockets can be waiting to be accepted. If port is 0 a port
   // scan will be done to find a free port. This option is mutual exlusive
   // with the reuse option.
   // Use tcpwindowsize to specify the size of the receive buffer, it has
   // to be specified here to make sure the window scale option is set (for
   // tcpwindowsize > 65KB and for platforms supporting window scaling).
   // Returns socket fd or -1 if socket() failed, -2 if bind() failed
   // or -3 if listen() failed.

   const short kSOCKET_MINPORT = 5000, kSOCKET_MAXPORT = 15000;
   short  sport, tryport = kSOCKET_MINPORT;
   struct servent *sp;

   if (port == 0 && reuse) {
      ::Error("TUnixSystem::UnixTcpService", "cannot do a port scan while reuse is true");
      return -1;
   }

   if ((sp = getservbyport(htons(port), kProtocolName)))
      sport = sp->s_port;
   else
      sport = htons(port);

   // Create tcp socket
   int sock;
   if ((sock = socket(AF_INET, SOCK_STREAM, 0)) < 0) {
      ::SysError("TUnixSystem::UnixTcpService", "socket");
      return -1;
   }

   if (reuse)
      gSystem->SetSockOpt(sock, kReuseAddr, 1);

   if (tcpwindowsize > 0) {
      gSystem->SetSockOpt(sock, kRecvBuffer, tcpwindowsize);
      gSystem->SetSockOpt(sock, kSendBuffer, tcpwindowsize);
   }

   struct sockaddr_in inserver;
   memset(&inserver, 0, sizeof(inserver));
   inserver.sin_family = AF_INET;
   inserver.sin_addr.s_addr = htonl(INADDR_ANY);
   inserver.sin_port = sport;

   // Bind socket
   if (port > 0) {
      if (bind(sock, (struct sockaddr*) &inserver, sizeof(inserver))) {
         ::SysError("TUnixSystem::UnixTcpService", "bind");
         return -2;
      }
   } else {
      int bret;
      do {
         inserver.sin_port = htons(tryport++);
         bret = bind(sock, (struct sockaddr*) &inserver, sizeof(inserver));
      } while (bret < 0 && GetErrno() == EADDRINUSE && tryport < kSOCKET_MAXPORT);
      if (bret < 0) {
         ::SysError("TUnixSystem::UnixTcpService", "bind (port scan)");
         return -2;
      }
   }

   // Start accepting connections
   if (listen(sock, backlog)) {
      ::SysError("TUnixSystem::UnixTcpService", "listen");
      return -3;
   }

   return sock;
}

//______________________________________________________________________________
int TUnixSystem::UnixUnixService(int port, int backlog)
{
   // Open a socket, bind to it and start listening for Unix domain connections
   // to it. Returns socket fd or -1.

   struct sockaddr_un unserver;
   int sock, oldumask;

   memset(&unserver, 0, sizeof(unserver));
   unserver.sun_family = AF_UNIX;

   // Assure that socket directory exists
   oldumask = umask(0);
   ::mkdir(kServerPath, 0777);
   umask(oldumask);
   sprintf(unserver.sun_path, "%s/%d", kServerPath, port);

   // Remove old socket
   unlink(unserver.sun_path);

   // Create socket
   if ((sock = socket(AF_UNIX, SOCK_STREAM, 0)) < 0) {
      ::SysError("TUnixSystem::UnixUnixService", "socket");
      return -1;
   }

   if (bind(sock, (struct sockaddr*) &unserver, strlen(unserver.sun_path)+2)) {
      ::SysError("TUnixSystem::UnixUnixService", "bind");
      return -1;
   }

   // Start accepting connections
   if (listen(sock, backlog)) {
      ::SysError("TUnixSystem::UnixUnixService", "listen");
      return -1;
   }

   return sock;
}

//______________________________________________________________________________
int TUnixSystem::UnixRecv(int sock, void *buffer, int length, int flag)
{
   // Receive exactly length bytes into buffer. Returns number of bytes
   // received. Returns -1 in case of error, -2 in case of MSG_OOB
   // and errno == EWOULDBLOCK, -3 in case of MSG_OOB and errno == EINVAL
   // and -4 in case of kNoBlock and errno == EWOULDBLOCK.
   // Returns -5 if pipe broken or reset by peer (EPIPE || ECONNRESET).

   ResetErrno();

   if (sock < 0) return -1;

   int once = 0;
   if (flag == -1) {
      flag = 0;
      once = 1;
   }

   int n, nrecv = 0;
   char *buf = (char *)buffer;

   for (n = 0; n < length; n += nrecv) {
      if ((nrecv = recv(sock, buf+n, length-n, flag)) <= 0) {
         if (nrecv == 0)
            break;        // EOF
         if (flag == MSG_OOB) {
            if (GetErrno() == EWOULDBLOCK)
               return -2;
            else if (GetErrno() == EINVAL)
               return -3;
         }
         if (GetErrno() == EWOULDBLOCK)
            return -4;
         else {
            if (GetErrno() != EINTR)
               ::SysError("TUnixSystem::UnixRecv", "recv");
            if (GetErrno() == EPIPE || GetErrno() == ECONNRESET)
               return -5;
            else
               return -1;
         }
      }
      if (once)
         return nrecv;
   }
   return n;
}

//______________________________________________________________________________
int TUnixSystem::UnixSend(int sock, const void *buffer, int length, int flag)
{
   // Send exactly length bytes from buffer. Returns -1 in case of error,
   // otherwise number of sent bytes. Returns -4 in case of kNoBlock and
   // errno == EWOULDBLOCK. Returns -5 if pipe broken or reset by peer
   // (EPIPE || ECONNRESET).

   if (sock < 0) return -1;

   int once = 0;
   if (flag == -1) {
      flag = 0;
      once = 1;
   }

   int n, nsent = 0;
   const char *buf = (const char *)buffer;

   for (n = 0; n < length; n += nsent) {
      if ((nsent = send(sock, buf+n, length-n, flag)) <= 0) {
         if (nsent == 0)
            break;
         if (GetErrno() == EWOULDBLOCK)
            return -4;
         else {
            if (GetErrno() != EINTR)
               ::SysError("TUnixSystem::UnixSend", "send");
            if (GetErrno() == EPIPE || GetErrno() == ECONNRESET)
               return -5;
            else
               return -1;
         }
      }
      if (once)
         return nsent;
   }
   return n;
}

//---- Dynamic Loading ---------------------------------------------------------

//______________________________________________________________________________
static const char *DynamicPath(const char *newpath = 0, Bool_t reset = kFALSE)
{
   // Get shared library search path. Static utility function.

   static TString dynpath;
   static Bool_t initialized = kFALSE;

   if (newpath) {
      dynpath = newpath;
   } else if (reset || !initialized) {
      initialized = kTRUE;
      TString rdynpath = gEnv->GetValue("Root.DynamicPath", (char*)0);
      rdynpath.ReplaceAll(": ", ":");  // in case DynamicPath was extended
      if (rdynpath.IsNull()) {
#ifdef ROOTLIBDIR
         rdynpath = ".:"; rdynpath += ROOTLIBDIR;
#else
         rdynpath = ".:"; rdynpath += gRootDir; rdynpath += "/lib";
#endif
      }
      TString ldpath;
#if defined (R__AIX)
      ldpath = gSystem->Getenv("LIBPATH");
#elif defined(R__HPUX)
      ldpath = gSystem->Getenv("SHLIB_PATH");
#elif defined(R__MACOSX)
      ldpath = gSystem->Getenv("DYLD_LIBRARY_PATH");
      if (!ldpath.IsNull())
         ldpath += ":";
      ldpath += gSystem->Getenv("LD_LIBRARY_PATH");
#else
      ldpath = gSystem->Getenv("LD_LIBRARY_PATH");
#endif
      if (ldpath.IsNull())
         dynpath = rdynpath;
      else {
         dynpath = rdynpath; dynpath += ":"; dynpath += ldpath;
      }

#ifdef ROOTLIBDIR
      if (!dynpath.Contains(ROOTLIBDIR)) {
         dynpath += ":"; dynpath += ROOTLIBDIR;
      }
#else
      if (!dynpath.Contains(Form("%s/lib", gRootDir))) {
         dynpath += ":"; dynpath += gRootDir; dynpath += "/lib";
      }
#endif
   }
   return dynpath;
}

//______________________________________________________________________________
const char *TUnixSystem::GetDynamicPath()
{
   // Return the dynamic path (used to find shared libraries).

   return DynamicPath(0, kFALSE);
}

//______________________________________________________________________________
void TUnixSystem::SetDynamicPath(const char *path)
{
   // Set the dynamic path to a new value.
   // If the value of 'path' is zero, the dynamic path is reset to its
   // default value.

   if (!path)
      DynamicPath(0, kTRUE);
   else
      DynamicPath(path);
}

//______________________________________________________________________________
char *TUnixSystem::DynamicPathName(const char *lib, Bool_t quiet)
{
   // Returns the path of a shared library (searches for library in the
   // shared library search path). If no file name extension is provided
   // it first tries .so, .sl, .dl and then .a (for AIX). The returned string
   // must be deleted.

   char *name;

   int ext = 0, len = strlen(lib);
   if (len > 3 && (!strcmp(lib+len-3, ".sl") ||
                   !strcmp(lib+len-3, ".dl") ||
                   !strcmp(lib+len-4, ".dll")||
                   !strcmp(lib+len-4, ".DLL")||
                   !strcmp(lib+len-3, ".so") ||
                   !strcmp(lib+len-2, ".a"))) {
      name = gSystem->Which(GetDynamicPath(), lib, kReadPermission);
      ext  = 1;
   } else {
      name = Form("%s.dll", lib);
      name = gSystem->Which(GetDynamicPath(), name, kReadPermission);
      if (!name) {
         name = Form("%s.so", lib);
         name = gSystem->Which(GetDynamicPath(), name, kReadPermission);
         if (!name) {
            name = Form("%s.sl", lib);
            name = gSystem->Which(GetDynamicPath(), name, kReadPermission);
            if (!name) {
               name = Form("%s.dl", lib);
               name = gSystem->Which(GetDynamicPath(), name, kReadPermission);
               if (!name) {
                  name = Form("%s.a", lib);
                  name = gSystem->Which(GetDynamicPath(), name, kReadPermission);
               }
            }
         }
      }
   }

   if (!name && !quiet) {
      if (ext)
         Error("DynamicPathName",
               "%s does not exist in %s", lib, GetDynamicPath());
      else
         Error("DynamicPathName",
               "%s[.so | .sl | .dl | .a | .dll] does not exist in %s", lib, GetDynamicPath());
   }

   return name;
}

//______________________________________________________________________________
void *TUnixSystem::FindDynLib(const char *lib)
{
   // Returns the handle to a loaded shared library. Returns 0 when library
   // not loaded.

#ifdef R__HPUX
   const char *path;

   if ((path = gSystem->DynamicPathName(lib))) {
      // find handle of shared library using its name
      struct shl_descriptor *desc;
      int index = 0;
      while (shl_get(index++, &desc) == 0)
         if (!strcmp(path, desc->filename))
            return desc->handle;
   }
#endif

   if (lib) { }  // avoid warning, use lib

   return 0;
}

//______________________________________________________________________________
int TUnixSystem::UnixDynLoad(const char *lib)
{
   // Load a shared library. Returns 0 on successful loading, 1 in
   // case lib was already loaded and -1 in case lib does not exist
   // or in case of error.

   const char *path;

   if ((path = gSystem->DynamicPathName(lib))) {
#if defined(R__HPUX)
#if !defined(__STDCPP__)
      shl_t handle = cxxshl_load(path, BIND_IMMEDIATE | BIND_NONFATAL, 0L);
#else
      shl_t handle = shl_load(path, BIND_IMMEDIATE | BIND_NONFATAL, 0L);
#endif
      if (handle != 0) return 0;
#else
      if (path) { }  // use path remove warning
      ::Error("TUnixSystem::UnixDynLoad", "not yet implemented for this platform");
      return -1;
#endif
   }
   return -1;
}

//______________________________________________________________________________
Func_t TUnixSystem::UnixDynFindSymbol(const char *lib, const char *entry)
{
   // Finds and returns a function pointer to a symbol in the shared library.
   // Returns 0 when symbol not found.

#if defined(R__HPUX) && !defined(R__GNU)
   shl_t handle;

   if (handle = (shl_t)FindDynLib(lib)) {
      Func_t addr = 0;
      if (shl_findsym(&handle, entry, TYPE_PROCEDURE, addr) == -1)
         ::SysError("TUnixSystem::UnixDynFindSymbol", "shl_findsym");
      return addr;
   }
   return 0;
#else
   if (lib || entry) { }

   // Always assume symbol not found
   return 0;
#endif
}

//______________________________________________________________________________
void TUnixSystem::UnixDynListSymbols(const char *lib, const char *regexp)
{
   // List symbols in a shared library. One can use wildcards to list only
   // the interesting symbols.

#if defined(R__HPUX) && !defined(R__GNU)
   shl_t handle;

   if (handle = (shl_t)FindDynLib(lib)) {
      struct shl_symbol *symbols;
      int nsym = shl_getsymbols(handle, TYPE_PROCEDURE,
                                EXPORT_SYMBOLS|NO_VALUES, (void *(*)())malloc,
                                &symbols);
      if (nsym != -1) {
         if (nsym > 0) {
            int cnt = 0;
            TRegexp *re = 0;
            if (regexp && strlen(regexp)) re = new TRegexp(regexp, kTRUE);
            Printf("");
            Printf("Functions exported by library %s", gSystem->DynamicPathName(lib));
            Printf("=========================================================");
            for (int i = 0; i < nsym; i++)
               if (symbols[i].type == TYPE_PROCEDURE) {
                  cnt++;
                  char *dsym = cplus_demangle(symbols[i].name,
                                              DMGL_PARAMS|DMGL_ANSI|DMGL_ARM);
                  if (re) {
                     TString s = dsym;
                     if (s.Index(*re) != kNPOS) Printf("%s", dsym);
                  } else
                     Printf("%s", dsym);
                  free(dsym);
               }
            Printf("---------------------------------------------------------");
            Printf("%d exported functions", cnt);
            Printf("=========================================================");
            delete re;
         }
         free(symbols);
      }
   }
#endif
   if (lib || regexp) { }
}

//______________________________________________________________________________
void TUnixSystem::UnixDynListLibs(const char *lib)
{
   // List all loaded shared libraries.

#if defined(R__HPUX) && !defined(R__GNU)
   TRegexp *re = 0;
   if (lib && strlen(lib)) re = new TRegexp(lib, kTRUE);
   struct shl_descriptor *desc;
   int index = 0;

   Printf("");
   Printf("Loaded shared libraries");
   Printf("=======================");

   while (shl_get(index++, &desc) == 0)
      if (re) {
         TString s = desc->filename;
         if (s.Index(*re) != kNPOS) Printf("%s", desc->filename);
      } else
         Printf("%s", desc->filename);
   Printf("-----------------------");
   Printf("%d libraries loaded", index-1);
   Printf("=======================");
   delete re;
#else
   if (lib) { }
#endif
}

//______________________________________________________________________________
void TUnixSystem::UnixDynUnload(const char *lib)
{
   // Unload a shared library.

#if defined(R__HPUX)
   shl_t handle;

   if (handle = (shl_t)FindDynLib(lib))
#if !defined(__STDCPP__)
      if (cxxshl_unload(handle) == -1)
#else
      if (shl_unload(handle) == -1)
#endif
         ::SysError("TUnixSystem::UnixDynUnload", "could not unload library %s", lib);
#else
   if (lib) { }
   // should call CINT unload file here, but does not work for sl's yet.
   ::Error("TUnixSystem::UnixDynUnload", "not yet implemented for this platform");
#endif
}

//______________________________________________________________________________
int TUnixSystem::ReadUtmpFile()
{
   // Read utmp file. Returns number of entries in utmp file.

   FILE  *utmp;
   struct stat file_stats;
   size_t n_read, size;

   R__LOCKGUARD2(gSystemMutex);

   gUtmpContents = 0;

   utmp = fopen(UTMP_FILE, "r");
   if (!utmp)
      return 0;

   fstat(fileno(utmp), &file_stats);
   size = file_stats.st_size;
   if (size <= 0) {
      fclose(utmp);
      return 0;
   }

   gUtmpContents = (STRUCT_UTMP *) malloc(size);
   if (!gUtmpContents) return 0;

   n_read = fread(gUtmpContents, 1, size, utmp);
   if (ferror(utmp) || fclose(utmp) == EOF || n_read < size) {
      free(gUtmpContents);
      gUtmpContents = 0;
      return 0;
   }

   return size / sizeof(STRUCT_UTMP);
}

//______________________________________________________________________________
void *TUnixSystem::SearchUtmpEntry(int n, const char *tty)
{
   // Look for utmp entry which is connected to terminal tty.

   STRUCT_UTMP *ue = gUtmpContents;

   while (n--) {
      if (ue->ut_name[0] && !strncmp(tty, ue->ut_line, sizeof(ue->ut_line)))
         return ue;
      ue++;
   }
   return 0;
}

//---- System, CPU and Memory info ---------------------------------------------

#if defined(R__MACOSX)
#include <sys/resource.h>
#include <mach/mach.h>
#include <mach/mach_error.h>
#include <mach/shared_memory_server.h>

//______________________________________________________________________________
static void GetDarwinSysInfo(SysInfo_t *sysinfo)
{
   // Get system info for Mac OS X.

   FILE *p = gSystem->OpenPipe("sysctl -n kern.ostype hw.model hw.ncpu hw.cpufrequency "
                               "hw.busfrequency hw.l2cachesize hw.physmem", "r");
   TString s;
   s.Gets(p);
   sysinfo->fOS = s;
   s.Gets(p);
   sysinfo->fModel = s;
   s.Gets(p);
   sysinfo->fCpus = s.Atoi();
   s.Gets(p);
   Long64_t t = s.Atoll();
   sysinfo->fCpuSpeed = Int_t(t / 1000000);
   s.Gets(p);
   t = s.Atoll();
   sysinfo->fBusSpeed = Int_t(t / 1000000);
   s.Gets(p);
   sysinfo->fL2Cache = s.Atoi() / 1024;
   s.Gets(p);
   t = s.Atoll();
   sysinfo->fPhysRam = Int_t(t / 1024 / 1024);
   gSystem->ClosePipe(p);
   p = gSystem->OpenPipe("hostinfo", "r");
   while (s.Gets(p)) {
      if (s.BeginsWith("Processor type: ")) {
         TPRegexp("Processor type: ([^ ]+).*").Substitute(s, "$1");
         sysinfo->fCpuType = s;
      }
   }
   gSystem->ClosePipe(p);
}

//______________________________________________________________________________
static void ReadDarwinCpu(long *ticks)
{
   // Get CPU load on Mac OS X.

   mach_msg_type_number_t count;
   kern_return_t kr;
   host_cpu_load_info_data_t cpu;

   ticks[0] = ticks[1] = ticks[2] = ticks[3] = 0;

   count = HOST_CPU_LOAD_INFO_COUNT;
   kr = host_statistics(mach_host_self(), HOST_CPU_LOAD_INFO, (host_info_t)&cpu, &count);
   if (kr != KERN_SUCCESS) {
      ::Error("TUnixSystem::ReadDarwinCpu", "host_statistics: %s", mach_error_string(kr));
   } else {
      ticks[0] = cpu.cpu_ticks[CPU_STATE_USER];
      ticks[1] = cpu.cpu_ticks[CPU_STATE_SYSTEM];
      ticks[2] = cpu.cpu_ticks[CPU_STATE_IDLE];
      ticks[3] = cpu.cpu_ticks[CPU_STATE_NICE];
   }
}

//______________________________________________________________________________
static void GetDarwinCpuInfo(CpuInfo_t *cpuinfo, Int_t sampleTime)
{
   // Get CPU stat for Mac OS X. Use sampleTime to set the interval over which
   // the CPU load will be measured, in ms (default 1000).

   Double_t avg[3];
   if (getloadavg(avg, sizeof(avg)) < 0) {
      ::Error("TUnixSystem::GetDarwinCpuInfo", "getloadavg failed");
   } else {
      cpuinfo->fLoad1m  = (Float_t)avg[0];
      cpuinfo->fLoad5m  = (Float_t)avg[1];
      cpuinfo->fLoad15m = (Float_t)avg[2];
   }

   Long_t cpu_ticks1[4], cpu_ticks2[4];
   ReadDarwinCpu(cpu_ticks1);
   gSystem->Sleep(sampleTime);
   ReadDarwinCpu(cpu_ticks2);

   Long_t userticks = (cpu_ticks2[0] + cpu_ticks2[3]) -
                      (cpu_ticks1[0] + cpu_ticks1[3]);
   Long_t systicks  = cpu_ticks2[1] - cpu_ticks1[1];
   Long_t idleticks = cpu_ticks2[2] - cpu_ticks1[2];
   if (userticks < 0) userticks = 0;
   if (systicks < 0)  systicks = 0;
   if (idleticks < 0) idleticks = 0;
   Long_t totalticks = userticks + systicks + idleticks;
   if (totalticks) {
      cpuinfo->fUser  = ((Float_t)(100 * userticks)) / ((Float_t)totalticks);
      cpuinfo->fSys   = ((Float_t)(100 * systicks))  / ((Float_t)totalticks);
      cpuinfo->fTotal = cpuinfo->fUser + cpuinfo->fSys;
      cpuinfo->fIdle  = ((Float_t)(100 * idleticks)) / ((Float_t)totalticks);
   }
}

//______________________________________________________________________________
static void GetDarwinMemInfo(MemInfo_t *meminfo)
{
   // Get VM stat for Mac OS X.

   static Int_t pshift = 0;
   static DIR *dirp;
   vm_statistics_data_t vm_info;
   mach_msg_type_number_t count;
   kern_return_t kr;
   struct dirent *dp;
   Long64_t total, used, free, swap_total, swap_used;

   count = HOST_VM_INFO_COUNT;
   kr = host_statistics(mach_host_self(), HOST_VM_INFO, (host_info_t)&vm_info, &count);
   if (kr != KERN_SUCCESS) {
      ::Error("TUnixSystem::GetDarwinMemInfo", "host_statistics: %s", mach_error_string(kr));
      return;
   }
   if (pshift == 0) {
      for (int psize = getpagesize(); psize > 1; psize >>= 1)
         pshift++;
   }

   used =  (Long64_t)(vm_info.active_count + vm_info.inactive_count + vm_info.wire_count) << pshift;
   free =  (Long64_t)(vm_info.free_count) << pshift;
   total = (Long64_t)(vm_info.active_count + vm_info.inactive_count + vm_info.free_count + vm_info.wire_count) << pshift;

   // Swap is available at same time as mem, so grab values here.
   swap_used = vm_info.pageouts << pshift;

   // Figure out total swap. This adds up the size of the swapfiles */
   dirp = opendir("/private/var/vm");
   if (!dirp)
       return;

   swap_total = 0;
   while ((dp = readdir(dirp)) != 0) {
      struct stat sb;
      char fname [MAXNAMLEN];
      if (strncmp(dp->d_name, "swapfile", 8))
         continue;
      strcpy(fname, "/private/var/vm/");
      strcat (fname, dp->d_name);
      if (stat(fname, &sb) < 0)
         continue;
      swap_total += sb.st_size;
   }
   closedir(dirp);

   meminfo->fMemTotal  = (Int_t) (total >> 20);       // divide by 1024 * 1024
   meminfo->fMemUsed   = (Int_t) (used >> 20);
   meminfo->fMemFree   = (Int_t) (free >> 20);
   meminfo->fSwapTotal = (Int_t) (swap_total >> 20);
   meminfo->fSwapUsed  = (Int_t) (swap_used >> 20);
   meminfo->fSwapFree  = meminfo->fSwapTotal - meminfo->fSwapUsed;
}

//______________________________________________________________________________
static void GetDarwinProcInfo(ProcInfo_t *procinfo)
{
   // Get process info for this process on Mac OS X.

   struct rusage ru;
   if (getrusage(RUSAGE_SELF, &ru) < 0) {
      ::SysError("TUnixSystem::GetDarwinProcInfo", "getrusage failed");
   } else {
      procinfo->fCpuUser = (Float_t)(ru.ru_utime.tv_sec) +
                           ((Float_t)(ru.ru_utime.tv_usec) / 1000000.);
      procinfo->fCpuSys  = (Float_t)(ru.ru_stime.tv_sec) +
                           ((Float_t)(ru.ru_stime.tv_usec) / 1000000.);
   }

   task_basic_info_data_t ti;
   mach_msg_type_number_t count;
   kern_return_t kr;

   task_t a_task = mach_task_self();

   count = TASK_BASIC_INFO_COUNT;
   kr = task_info(a_task, TASK_BASIC_INFO, (task_info_t)&ti, &count);
   if (kr != KERN_SUCCESS) {
      ::Error("TUnixSystem::GetDarwinProcInfo", "task_info: %s", mach_error_string(kr));
   } else {
      // resident size does not require any calculation. Virtual size
      // needs to be adjusted if traversing memory objects do not include the
   	// globally shared text and data regions
   	mach_port_t object_name;
   	vm_address_t address;
   	vm_region_top_info_data_t info;
   	vm_size_t vsize, rsize, size;
   	rsize = ti.resident_size;
   	vsize = ti.virtual_size;
      for (address = 0; ; address += size) {
         // get memory region
         count = VM_REGION_TOP_INFO_COUNT;
         if (vm_region(a_task, &address, &size,
                       VM_REGION_TOP_INFO, (vm_region_info_t)&info, &count,
                       &object_name) != KERN_SUCCESS) {
            // no more memory regions.
            break;
         }

         if (address >= GLOBAL_SHARED_TEXT_SEGMENT &&
             address < (GLOBAL_SHARED_DATA_SEGMENT + SHARED_DATA_REGION_SIZE)) {
            // This region is private shared.
            // Check if this process has the globally shared
            // text and data regions mapped in. If so, adjust
            // virtual memory size and exit loop.
            if (info.share_mode == SM_EMPTY) {
               vm_region_basic_info_data_64_t b_info;
               count = VM_REGION_BASIC_INFO_COUNT_64;
               if (vm_region_64(a_task, &address,
                                &size, VM_REGION_BASIC_INFO,
                                (vm_region_info_t)&b_info, &count,
                                &object_name) != KERN_SUCCESS) {
                  break;
               }

               if (b_info.reserved) {
                  vsize -= (SHARED_TEXT_REGION_SIZE + SHARED_DATA_REGION_SIZE);
                  break;
               }
            }
         }
      }

      procinfo->fMemResident = (Long_t)(rsize / 1024);
      procinfo->fMemVirtual  = (Long_t)(vsize / 1024);
   }
}
#endif

#if defined(R__LINUX)
//______________________________________________________________________________
static void GetLinuxSysInfo(SysInfo_t *sysinfo)
{
   // Get system info for Linux. Only fBusSpeed is not set.

   TString s;
   FILE *f = fopen("/proc/cpuinfo", "r");
   while (s.Gets(f)) {
      if (s.BeginsWith("model name")) {
         TPRegexp("^.+: *(.*$)").Substitute(s, "$1");
         sysinfo->fModel = s;
      }
      if (s.BeginsWith("cpu MHz")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         sysinfo->fCpuSpeed = s.Atoi();
      }
      if (s.BeginsWith("cache size")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         sysinfo->fL2Cache = s.Atoi();
      }
      if (s.BeginsWith("processor")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         sysinfo->fCpus = s.Atoi();
         sysinfo->fCpus++;
      }
   }
   fclose(f);

   f = fopen("/proc/meminfo", "r");
   while (s.Gets(f)) {
      if (s.BeginsWith("MemTotal")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         sysinfo->fPhysRam = (s.Atoi() / 1024);
         break;
      }
   }
   fclose(f);

   f = gSystem->OpenPipe("uname -s -p", "r");
   s.Gets(f);
   Ssiz_t from = 0;
   s.Tokenize(sysinfo->fOS, from);
   s.Tokenize(sysinfo->fCpuType, from);
   gSystem->ClosePipe(f);
}

//______________________________________________________________________________
static void ReadLinuxCpu(long *ticks)
{
   // Get CPU load on Linux.

   ticks[0] = ticks[1] = ticks[2] = ticks[3] = 0;

   TString s;
   FILE *f = fopen("/proc/stat", "r");
   s.Gets(f);
   // user, user nice, sys, idle
   sscanf(s.Data(), "%*s %ld %ld %ld %ld", &ticks[0], &ticks[3], &ticks[1], &ticks[2]);
   fclose(f);
}

//______________________________________________________________________________
static void GetLinuxCpuInfo(CpuInfo_t *cpuinfo, Int_t sampleTime)
{
   // Get CPU stat for Linux. Use sampleTime to set the interval over which
   // the CPU load will be measured, in ms (default 1000).

   Double_t avg[3] = { -1., -1., -1. };
#ifndef R__WINGCC
   if (getloadavg(avg, sizeof(avg)) < 0) {
      ::Error("TUnixSystem::GetLinuxCpuInfo", "getloadavg failed");
   } else
#endif
   {
      cpuinfo->fLoad1m  = (Float_t)avg[0];
      cpuinfo->fLoad5m  = (Float_t)avg[1];
      cpuinfo->fLoad15m = (Float_t)avg[2];
   }

   Long_t cpu_ticks1[4], cpu_ticks2[4];
   ReadLinuxCpu(cpu_ticks1);
   gSystem->Sleep(sampleTime);
   ReadLinuxCpu(cpu_ticks2);

   Long_t userticks = (cpu_ticks2[0] + cpu_ticks2[3]) -
                      (cpu_ticks1[0] + cpu_ticks1[3]);
   Long_t systicks  = cpu_ticks2[1] - cpu_ticks1[1];
   Long_t idleticks = cpu_ticks2[2] - cpu_ticks1[2];
   if (userticks < 0) userticks = 0;
   if (systicks < 0)  systicks = 0;
   if (idleticks < 0) idleticks = 0;
   Long_t totalticks = userticks + systicks + idleticks;
   if (totalticks) {
      cpuinfo->fUser  = ((Float_t)(100 * userticks)) / ((Float_t)totalticks);
      cpuinfo->fSys   = ((Float_t)(100 * systicks))  / ((Float_t)totalticks);
      cpuinfo->fTotal = cpuinfo->fUser + cpuinfo->fSys;
      cpuinfo->fIdle  = ((Float_t)(100 * idleticks)) / ((Float_t)totalticks);
   }
}

//______________________________________________________________________________
static void GetLinuxMemInfo(MemInfo_t *meminfo)
{
   // Get VM stat for Linux.

   TString s;
   FILE *f = fopen("/proc/meminfo", "r");
   while (s.Gets(f)) {
      if (s.BeginsWith("MemTotal")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         meminfo->fMemTotal = (s.Atoi() / 1024);
      }
      if (s.BeginsWith("MemFree")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         meminfo->fMemFree = (s.Atoi() / 1024);
      }
      if (s.BeginsWith("SwapTotal")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         meminfo->fSwapTotal = (s.Atoi() / 1024);
      }
      if (s.BeginsWith("SwapFree")) {
         TPRegexp("^.+: *([^ ]+).*").Substitute(s, "$1");
         meminfo->fSwapFree = (s.Atoi() / 1024);
      }
   }
   fclose(f);

   meminfo->fMemUsed  = meminfo->fMemTotal - meminfo->fMemFree;
   meminfo->fSwapUsed = meminfo->fSwapTotal - meminfo->fSwapFree;
}

//______________________________________________________________________________
static void GetLinuxProcInfo(ProcInfo_t *procinfo)
{
   // Get process info for this process on Linux.

   struct rusage ru;
   if (getrusage(RUSAGE_SELF, &ru) < 0) {
      ::SysError("TUnixSystem::GetLinuxProcInfo", "getrusage failed");
   } else {
      procinfo->fCpuUser = (Float_t)(ru.ru_utime.tv_sec) +
                           ((Float_t)(ru.ru_utime.tv_usec) / 1000000.);
      procinfo->fCpuSys  = (Float_t)(ru.ru_stime.tv_sec) +
                           ((Float_t)(ru.ru_stime.tv_usec) / 1000000.);
   }

   TString s;
   FILE *f = fopen(Form("/proc/%d/statm", gSystem->GetPid()), "r");
   s.Gets(f);
   Long_t total, rss;
   sscanf(s.Data(), "%ld %ld", &total, &rss);
   procinfo->fMemVirtual  = total * getpagesize() / 1024;
   procinfo->fMemResident = rss * getpagesize() / 1024;
   fclose(f);
}
#endif

//______________________________________________________________________________
int TUnixSystem::GetSysInfo(SysInfo_t *info) const
{
   // Returns static system info, like OS type, CPU type, number of CPUs
   // RAM size, etc into the SysInfo_t structure. Returns -1 in case of error,
   // 0 otherwise.

   if (!info) return -1;

   static SysInfo_t sysinfo;

   if (!sysinfo.fCpus) {
#if defined(R__MACOSX)
      GetDarwinSysInfo(&sysinfo);
#elif defined(R__LINUX)
      GetLinuxSysInfo(&sysinfo);
#endif
   }

   *info = sysinfo;

   return 0;
}

//______________________________________________________________________________
int TUnixSystem::GetCpuInfo(CpuInfo_t *info, Int_t sampleTime) const
{
   // Returns cpu load average and load info into the CpuInfo_t structure.
   // Returns -1 in case of error, 0 otherwise. Use sampleTime to set the
   // interval over which the CPU load will be measured, in ms (default 1000).

   if (!info) return -1;

#if defined(R__MACOSX)
   GetDarwinCpuInfo(info, sampleTime);
#elif defined(R__LINUX)
   GetLinuxCpuInfo(info, sampleTime);
#endif

   return 0;
}

//______________________________________________________________________________
int TUnixSystem::GetMemInfo(MemInfo_t *info) const
{
   // Returns ram and swap memory usage info into the MemInfo_t structure.
   // Returns -1 in case of error, 0 otherwise.

   if (!info) return -1;

#if defined(R__MACOSX)
   GetDarwinMemInfo(info);
#elif defined(R__LINUX)
   GetLinuxMemInfo(info);
#endif

   return 0;
}

//______________________________________________________________________________
int TUnixSystem::GetProcInfo(ProcInfo_t *info) const
{
   // Returns cpu and memory used by this process into the ProcInfo_t structure.
   // Returns -1 in case of error, 0 otherwise.

   if (!info) return -1;

#if defined(R__MACOSX)
   GetDarwinProcInfo(info);
#elif defined(R__LINUX)
   GetLinuxProcInfo(info);
#endif

   return 0;
}