// $Id$ #include "ace/OS.h" #include "ace/Process.h" #include "ace/ARGV.h" #include "ace/Signal.h" #include "ace/SString.h" #include "ace/Log_Msg.h" #if !defined (__ACE_INLINE__) #include "ace/Process.i" #endif /* __ACE_INLINE__ */ ACE_RCSID (ace, Process, "$Id$") // This function acts as a signal handler for SIGCHLD. We don't really want // to do anything with the signal - it's just needed to interrupt a sleep. // See wait() for more info. #if !defined (ACE_WIN32) static void sigchld_nop (int, siginfo_t *, ucontext_t *) { return; } #endif /* ACE_WIN32 */ ACE_Process::ACE_Process (void) : #if !defined (ACE_WIN32) child_id_ (ACE_INVALID_PID), #endif /* !defined (ACE_WIN32) */ exit_code_ (0) { #if defined (ACE_WIN32) ACE_OS::memset ((void *) &this->process_info_, 0, sizeof this->process_info_); #endif /* ACE_WIN32 */ } ACE_Process::~ACE_Process (void) { #if defined (ACE_WIN32) // Free resources allocated in kernel. ACE_OS::close (this->process_info_.hThread); ACE_OS::close (this->process_info_.hProcess); #endif /* ACE_WIN32 */ // If any handles were duplicated for the child process and // still not closed, get them now. this->close_dup_handles (); } int ACE_Process::prepare (ACE_Process_Options &) { return 0; } pid_t ACE_Process::spawn (ACE_Process_Options &options) { if (prepare (options) < 0) return ACE_INVALID_PID; // Stash the passed/duped handle sets away in this object for later // closing if needed or requested. At the same time, figure out which // ones to include in command line options if that's needed below. ACE_Handle_Set *set_p = 0; if (options.dup_handles (this->dup_handles_)) set_p = &this->dup_handles_; else if (options.passed_handles (this->handles_passed_)) set_p = &this->handles_passed_; // If we are going to end up running a new program (i.e. Win32, or // NO_EXEC option is set) then get any handles passed in the options, // and tack them onto the command line with +H options, // unless the command line runs out of space. // Note that we're using the knowledge that all the options, argvs, etc. // passed to the options are all sitting in the command_line_buf. Any // call to get the argv then splits them out. So, regardless of the // platform, tack them all onto the command line buf and take it // from there. if (set_p && !ACE_BIT_ENABLED (options.creation_flags (), ACE_Process_Options::NO_EXEC)) { int maxlen = 0; ACE_TCHAR *cmd_line_buf = options.command_line_buf (&maxlen); size_t max_len = ACE_static_cast (size_t, maxlen); size_t curr_len = ACE_OS::strlen (cmd_line_buf); ACE_Handle_Set_Iterator h_iter (*set_p); // Because the length of the to-be-formatted +H option is not // known, and we don't have a snprintf, guess at the space // needed (20 chars), and use that as a limit. for (ACE_HANDLE h = h_iter (); h != ACE_INVALID_HANDLE && curr_len + 20 < max_len; h = h_iter ()) { curr_len += ACE_OS::sprintf (&cmd_line_buf[curr_len], ACE_LIB_TEXT (" +H %d"), h); } } #if defined (ACE_HAS_WINCE) // Note that WinCE does not have process name included in the command line as argv[0] // like other OS environment. Therefore, it is user's whole responsibility to call // 'ACE_Process_Options::process_name(const ACE_TCHAR *name)' to set the proper // process name (the execution file name with path if needed). BOOL fork_result = ACE_TEXT_CreateProcess (options.process_name(), options.command_line_buf(), options.get_process_attributes(), // must be NULL in CE options.get_thread_attributes(), // must be NULL in CE options.handle_inheritence(), // must be false in CE options.creation_flags(), // must be NULL in CE options.env_buf(), // environment variables, must be NULL in CE options.working_directory(), // must be NULL in CE options.startup_info(), // must be NULL in CE &this->process_info_); if (fork_result) { parent (this->getpid ()); return this->getpid (); } return ACE_INVALID_PID; #elif defined (ACE_WIN32) BOOL fork_result = ACE_TEXT_CreateProcess (0, options.command_line_buf (), options.get_process_attributes (), options.get_thread_attributes (), options.handle_inheritence (), options.creation_flags (), options.env_buf (), // environment variables options.working_directory (), options.startup_info (), &this->process_info_); if (fork_result) { parent (this->getpid ()); return this->getpid (); } return ACE_INVALID_PID; #elif defined (CHORUS) // This only works if we exec. Chorus does not really support // forking. if (ACE_BIT_ENABLED (options.creation_flags (), ACE_Process_Options::NO_EXEC)) ACE_NOTSUP_RETURN (ACE_INVALID_PID); // These are all currently unsupported. if (options.get_stdin () != ACE_INVALID_HANDLE) ACE_NOTSUP_RETURN (ACE_INVALID_PID); if (options.get_stdout () != ACE_INVALID_HANDLE) ACE_NOTSUP_RETURN (ACE_INVALID_PID); if (options.get_stderr () != ACE_INVALID_HANDLE) ACE_NOTSUP_RETURN (ACE_INVALID_PID); if (options.working_directory () != 0) ACE_NOTSUP_RETURN (ACE_INVALID_PID); if (options.env_argv ()[0] == 0) // command-line args this->child_id_ = ACE_OS::execvp (options.process_name (), options.command_line_argv ()); else { // Add the new environment variables to the environment context // of the context before doing an . for (char *const *user_env = options.env_argv (); *user_env != 0; user_env++) if (ACE_OS::putenv (*user_env) != 0) return ACE_INVALID_PID; // Now the forked process has both inherited variables and the // user's supplied variables. this->child_id_ = ACE_OS::execvp (options.process_name (), options.command_line_argv ()); } return this->child_id_; #else /* ACE_WIN32 */ // Fork the new process. this->child_id_ = ACE::fork (options.process_name (), options.avoid_zombies ()); if (this->child_id_ == 0) { # if !defined (ACE_LACKS_SETPGID) // If we're the child and the options specified a non-default // process group, try to set our pgid to it. This allows the // to wait for processes by their // process-group. if (options.getgroup () != ACE_INVALID_PID && ACE_OS::setpgid (0, options.getgroup ()) < 0) ACE_ERROR ((LM_ERROR, ACE_LIB_TEXT ("%p.\n"), ACE_LIB_TEXT ("ACE_Process::spawn: setpgid failed."))); # endif /* ACE_LACKS_SETPGID */ # if !defined (ACE_LACKS_SETREGID) if (options.getrgid () != (uid_t) -1 || options.getegid () != (uid_t) -1) if (ACE_OS::setregid (options.getrgid (), options.getegid ()) == -1) ACE_ERROR ((LM_ERROR, ACE_LIB_TEXT ("%p.\n"), ACE_LIB_TEXT ("ACE_Process::spawn: setregid failed."))); # endif /* ACE_LACKS_SETREGID */ # if !defined (ACE_LACKS_SETREUID) // Set user and group id's. if (options.getruid () != (uid_t) -1 || options.geteuid () != (uid_t) -1) if (ACE_OS::setreuid (options.getruid (), options.geteuid ()) == -1) ACE_ERROR ((LM_ERROR, ACE_LIB_TEXT ("%p.\n"), ACE_LIB_TEXT ("ACE_Process::spawn: setreuid failed."))); # endif /* ACE_LACKS_SETREUID */ this->child (ACE_OS::getppid ()); } else if (this->child_id_ != -1) this->parent (this->child_id_); // If we're not supposed to exec, return the process id. if (ACE_BIT_ENABLED (options.creation_flags (), ACE_Process_Options::NO_EXEC)) return this->child_id_; switch (this->child_id_) { case -1: // Error. return ACE_INVALID_PID; case 0: // Child process...exec the { if (options.get_stdin () != ACE_INVALID_HANDLE && ACE_OS::dup2 (options.get_stdin (), ACE_STDIN) == -1) ACE_OS::exit (errno); else if (options.get_stdout () != ACE_INVALID_HANDLE && ACE_OS::dup2 (options.get_stdout (), ACE_STDOUT) == -1) ACE_OS::exit (errno); else if (options.get_stderr () != ACE_INVALID_HANDLE && ACE_OS::dup2 (options.get_stderr (), ACE_STDERR) == -1) ACE_OS::exit (errno); // close down unneeded descriptors ACE_OS::close (options.get_stdin ()); ACE_OS::close (options.get_stdout ()); ACE_OS::close (options.get_stderr ()); // If we must, set the working directory for the child // process. if (options.working_directory () != 0) ACE_OS::chdir (options.working_directory ()); // Should check for error here! // Child process executes the command. int result = 0; if (options.inherit_environment ()) { // Add the new environment variables to the environment // context of the context before doing an . for (char *const *user_env = options.env_argv (); *user_env != 0; user_env++) if (ACE_OS::putenv (*user_env) != 0) return ACE_INVALID_PID; // Now the forked process has both inherited variables and // the user's supplied variables. result = ACE_OS::execvp (options.process_name (), options.command_line_argv ()); } else { #if defined (ghs) // GreenHills 1.8.8 (for VxWorks 5.3.x) can't compile this // code. Processes aren't supported on VxWorks anyways. ACE_NOTSUP_RETURN (ACE_INVALID_PID); #else result = ACE_OS::execve (options.process_name (), options.command_line_argv (), options.env_argv ()); # endif /* ghs */ } if (result == -1) { // If the execv fails, this child needs to exit. // Exit with the errno so that the calling process can // catch this and figure out what went wrong. ACE_OS::_exit (errno); } // ... otherwise, this is never reached. return 0; } default: // Server process. The fork succeeded. return this->child_id_; } #endif /* ACE_WIN32 */ } void ACE_Process::parent (pid_t) { // nothing to do } void ACE_Process::child (pid_t) { // nothing to do } void ACE_Process::unmanage (void) { // nothing to do } int ACE_Process::running (void) const { #if defined (ACE_WIN32) DWORD code; BOOL result = ::GetExitCodeProcess (this->gethandle (), &code); return result && code == STILL_ACTIVE; #else return ACE_OS::kill (this->getpid (), 0) == 0 || errno != ESRCH; #endif /* ACE_WIN32 */ } pid_t ACE_Process::wait (const ACE_Time_Value &tv, ACE_exitcode *status) { #if defined (ACE_WIN32) // Don't try to get the process exit status if wait failed so we can // keep the original error code intact. switch (::WaitForSingleObject (process_info_.hProcess, tv.msec ())) { case WAIT_OBJECT_0: // The error status of is nonetheless not // tested because we don't know how to return the value. ::GetExitCodeProcess (process_info_.hProcess, &this->exit_code_); if (status != 0) *status = this->exit_code_; return this->getpid (); case WAIT_TIMEOUT: errno = ETIME; return 0; default: ACE_OS::set_errno_to_last_error (); return -1; } #else /* ACE_WIN32 */ if (tv == ACE_Time_Value::zero) { pid_t retv = ACE_OS::waitpid (this->child_id_, &this->exit_code_, WNOHANG); if (status != 0) *status = this->exit_code_; return retv; } if (tv == ACE_Time_Value::max_time) return this->wait (status); // Need to wait but limited to specified time. // Force generation of SIGCHLD, even though we don't want to // catch it - just need it to interrupt the sleep below. // If this object has a reactor set, assume it was given at // open(), and there's already a SIGCHLD action set, so no // action is needed here. ACE_Sig_Action old_action; ACE_Sig_Action do_sigchld ((ACE_SignalHandler)sigchld_nop); do_sigchld.register_action (SIGCHLD, &old_action); pid_t pid; ACE_Time_Value tmo (tv); // Need one we can change for (ACE_Countdown_Time time_left (&tmo); ; time_left.update ()) { pid = ACE_OS::waitpid (this->getpid (), &this->exit_code_, WNOHANG); if (status != 0) *status = this->exit_code_; if (pid > 0 || pid == ACE_INVALID_PID) break; // Got a child or an error - all done // pid 0, nothing is ready yet, so wait. // Do a sleep (only this thread sleeps) til something // happens. This relies on SIGCHLD interrupting the sleep. // If SIGCHLD isn't delivered, we'll need to do something // with sigaction to force it. if (-1 == ACE_OS::sleep (tmo) && errno == EINTR) continue; // Timed out pid = 0; break; } // Restore the previous SIGCHLD action if it was changed. old_action.register_action (SIGCHLD); return pid; #endif /* ACE_WIN32 */ } void ACE_Process::close_dup_handles (void) { if (this->dup_handles_.num_set () > 0) { ACE_Handle_Set_Iterator h_iter (this->dup_handles_); for (ACE_HANDLE h = h_iter (); h != ACE_INVALID_HANDLE; h = h_iter ()) ACE_OS::closesocket (h); this->dup_handles_.reset (); } return; } void ACE_Process::close_passed_handles (void) { if (this->handles_passed_.num_set () > 0) { ACE_Handle_Set_Iterator h_iter (this->handles_passed_); for (ACE_HANDLE h = h_iter (); h != ACE_INVALID_HANDLE; h = h_iter ()) ACE_OS::closesocket (h); this->handles_passed_.reset (); } return; } ACE_Process_Options::ACE_Process_Options (int ie, int cobl, int ebl, int mea) : #if !defined (ACE_HAS_WINCE) inherit_environment_ (ie), #endif /* ACE_HAS_WINCE */ creation_flags_ (0), avoid_zombies_ (0), #if !defined (ACE_HAS_WINCE) #if defined (ACE_WIN32) environment_inherited_ (0), handle_inheritence_ (TRUE), process_attributes_ (0), thread_attributes_ (0), #else /* ACE_WIN32 */ stdin_ (ACE_INVALID_HANDLE), stdout_ (ACE_INVALID_HANDLE), stderr_ (ACE_INVALID_HANDLE), ruid_ ((uid_t) -1), euid_ ((uid_t) -1), rgid_ ((uid_t) -1), egid_ ((uid_t) -1), #endif /* ACE_WIN32 */ set_handles_called_ (0), environment_buf_index_ (0), environment_argv_index_ (0), environment_buf_ (0), environment_buf_len_ (ebl), max_environment_args_ (mea), max_environ_argv_index_ (mea - 1), #endif /* !ACE_HAS_WINCE */ command_line_argv_calculated_ (0), command_line_buf_ (0), command_line_buf_len_ (cobl), process_group_ (ACE_INVALID_PID) { ACE_NEW (command_line_buf_, ACE_TCHAR[cobl]); command_line_buf_[0] = '\0'; #if !defined (ACE_HAS_WINCE) working_directory_[0] = '\0'; ACE_NEW (environment_buf_, ACE_TCHAR[ebl]); ACE_NEW (environment_argv_, ACE_TCHAR *[mea]); environment_buf_[0] = '\0'; environment_argv_[0] = 0; process_name_[0] = '\0'; #if defined (ACE_WIN32) ACE_OS::memset ((void *) &this->startup_info_, 0, sizeof this->startup_info_); this->startup_info_.cb = sizeof this->startup_info_; #endif /* ACE_WIN32 */ #endif /* !ACE_HAS_WINCE */ } #if !defined (ACE_HAS_WINCE) #if defined (ACE_WIN32) void ACE_Process_Options::inherit_environment (void) { // Ensure only once execution. if (environment_inherited_) return; environment_inherited_ = 1; // Get the existing environment. ACE_TCHAR *existing_environment = ACE_OS::getenvstrings (); size_t slot = 0; while (existing_environment[slot] != '\0') { size_t len = ACE_OS::strlen (existing_environment + slot); // Add the string to our env buffer. if (this->setenv_i (existing_environment + slot, len) == -1) { ACE_ERROR ((LM_ERROR, ACE_LIB_TEXT ("%p.\n"), ACE_LIB_TEXT ("ACE_Process_Options::ACE_Process_Options"))); break; } // Skip to the next word. slot += len + 1; } ACE_TEXT_FreeEnvironmentStrings (existing_environment); } #else /* defined ACE_WIN32 */ ACE_TCHAR * const * ACE_Process_Options::env_argv (void) { return environment_argv_; } #endif /* ACE_WIN32 */ int ACE_Process_Options::setenv (ACE_TCHAR *envp[]) { int i = 0; while (envp[i]) { if (this->setenv_i (envp[i], ACE_OS_String::strlen (envp[i])) == -1) return -1; i++; } #if defined (ACE_WIN32) if (inherit_environment_) this->inherit_environment (); #endif /* ACE_WIN32 */ return 0; } int ACE_Process_Options::setenv (const ACE_TCHAR *format, ...) { ACE_TCHAR stack_buf[DEFAULT_COMMAND_LINE_BUF_LEN]; // Start varargs. va_list argp; va_start (argp, format); // Add the rest of the varargs. ACE_OS::vsprintf (stack_buf, format, argp); // End varargs. va_end (argp); // Append the string to are environment buffer. if (this->setenv_i (stack_buf, ACE_OS_String::strlen (stack_buf)) == -1) return -1; #if defined (ACE_WIN32) if (inherit_environment_) this->inherit_environment (); #endif /* ACE_WIN32 */ return 0; } int ACE_Process_Options::setenv (const ACE_TCHAR *variable_name, const ACE_TCHAR *format, ...) { ACE_TCHAR newformat[DEFAULT_COMMAND_LINE_BUF_LEN]; // Add in the variable name. ACE_OS::sprintf (newformat, ACE_LIB_TEXT ("%s=%s"), variable_name, format); ACE_TCHAR stack_buf[DEFAULT_COMMAND_LINE_BUF_LEN]; // Start varargs. va_list argp; va_start (argp, format); // Add the rest of the varargs. ACE_OS::vsprintf (stack_buf, newformat, argp); // End varargs. va_end (argp); // Append the string to our environment buffer. if (this->setenv_i (stack_buf, ACE_OS_String::strlen (stack_buf)) == -1) return -1; #if defined (ACE_WIN32) if (inherit_environment_) this->inherit_environment (); #endif /* ACE_WIN32 */ return 0; } int ACE_Process_Options::setenv_i (ACE_TCHAR *assignment, size_t len) { // Add one for the null char. len++; // If environment larger than allocated buffer return. Also check to // make sure we have enough room. if (environment_argv_index_ == max_environ_argv_index_ || (len + environment_buf_index_) >= environment_buf_len_) return -1; // Copy the new environment string. ACE_OS::memcpy (environment_buf_ + environment_buf_index_, assignment, len * sizeof (ACE_TCHAR)); // Update the argv array. environment_argv_[environment_argv_index_++] = environment_buf_ + environment_buf_index_; environment_argv_[environment_argv_index_] = 0; // Update our index. environment_buf_index_ += len; // Make sure the buffer is null-terminated. environment_buf_[environment_buf_index_] = '\0'; return 0; } int ACE_Process_Options::set_handles (ACE_HANDLE std_in, ACE_HANDLE std_out, ACE_HANDLE std_err) { this->set_handles_called_ = 1; #if defined (ACE_WIN32) // Tell the new process to use our std handles. this->startup_info_.dwFlags = STARTF_USESTDHANDLES; if (std_in == ACE_INVALID_HANDLE) std_in = ACE_STDIN; if (std_out == ACE_INVALID_HANDLE) std_out = ACE_STDOUT; if (std_err == ACE_INVALID_HANDLE) std_err = ACE_STDERR; if (!::DuplicateHandle (::GetCurrentProcess (), std_in, ::GetCurrentProcess (), &this->startup_info_.hStdInput, 0, TRUE, DUPLICATE_SAME_ACCESS)) return -1; if (!::DuplicateHandle (::GetCurrentProcess (), std_out, ::GetCurrentProcess (), &this->startup_info_.hStdOutput, 0, TRUE, DUPLICATE_SAME_ACCESS)) return -1; if (!::DuplicateHandle (::GetCurrentProcess (), std_err, ::GetCurrentProcess (), &this->startup_info_.hStdError, 0, TRUE, DUPLICATE_SAME_ACCESS)) return -1; #else /* ACE_WIN32 */ this->stdin_ = ACE_OS::dup (std_in); this->stdout_ = ACE_OS::dup (std_out); this->stderr_ = ACE_OS::dup (std_err); #endif /* ACE_WIN32 */ return 0; // Success. } void ACE_Process_Options::release_handles () { if (set_handles_called_) { #if defined (ACE_WIN32) ACE_OS::close (startup_info_.hStdInput); ACE_OS::close (startup_info_.hStdOutput); ACE_OS::close (startup_info_.hStdError); #else /* ACE_WIN32 */ ACE_OS::close (stdin_); ACE_OS::close (stdout_); ACE_OS::close (stderr_); #endif /* ACE_WIN32 */ set_handles_called_ = 0; } } #endif /* !ACE_HAS_WINCE */ ACE_Process_Options::~ACE_Process_Options (void) { #if !defined (ACE_HAS_WINCE) release_handles(); delete [] environment_buf_; delete [] environment_argv_; #endif /* !ACE_HAS_WINCE */ delete [] command_line_buf_; } int ACE_Process_Options::command_line (const ACE_TCHAR *const argv[]) { // @@ Factor out the code between this int i = 0; if (argv[i]) { ACE_OS::strcat (command_line_buf_, argv[i]); while (argv[++i]) { ACE_OS::strcat (command_line_buf_, ACE_LIB_TEXT (" ")); ACE_OS::strcat (command_line_buf_, argv[i]); } } command_line_argv_calculated_ = 0; return 0; // Success. } int ACE_Process_Options::command_line (const ACE_TCHAR *format, ...) { // Store all ... args in argp. va_list argp; va_start (argp, format); // sprintf the format and args into command_line_buf__. ACE_OS::vsprintf (command_line_buf_, format, argp); // Useless macro. va_end (argp); command_line_argv_calculated_ = 0; return 0; } #if defined (ACE_HAS_WCHAR) && !defined (ACE_HAS_WINCE) /** * @note Not available on Windows CE because it doesn't have a char version of * vsprintf. */ int ACE_Process_Options::command_line (const ACE_ANTI_TCHAR *format, ...) { ACE_ANTI_TCHAR *anti_clb; ACE_NEW_RETURN (anti_clb, ACE_ANTI_TCHAR[this->command_line_buf_len_], -1); // Store all ... args in argp. va_list argp; va_start (argp, format); // sprintf the format and args into command_line_buf_. ACE_OS::vsprintf (anti_clb, format, argp); // Useless macro. va_end (argp); ACE_OS::strcpy (this->command_line_buf_, ACE_TEXT_ANTI_TO_TCHAR (anti_clb)); delete [] anti_clb; command_line_argv_calculated_ = 0; return 0; } #endif /* ACE_HAS_WCHAR && !ACE_HAS_WINCE */ ACE_TCHAR * ACE_Process_Options::env_buf (void) { #if !defined (ACE_HAS_WINCE) if (environment_buf_[0] == '\0') return 0; else return environment_buf_; #else return 0; #endif /* !ACE_HAS_WINCE */ } ACE_TCHAR * const * ACE_Process_Options::command_line_argv (void) { if (command_line_argv_calculated_ == 0) { command_line_argv_calculated_ = 1; // This tokenizer will replace all spaces with end-of-string // characters and will preserve text between "" and '' pairs. ACE_Tokenizer parser (command_line_buf_); parser.delimiter_replace (' ', '\0'); parser.preserve_designators ('\"', '\"'); // " parser.preserve_designators ('\'', '\''); int x = 0; do command_line_argv_[x] = parser.next (); while (command_line_argv_[x] != 0 // substract one for the ending zero. && ++x < MAX_COMMAND_LINE_OPTIONS - 1); command_line_argv_[x] = 0; } return command_line_argv_; } // Cause the specified handle to be passed to a child process // when it's spawned. int ACE_Process_Options::pass_handle (ACE_HANDLE h) { # if defined (ACE_WIN32) # if defined (ACE_HAS_WINCE) ACE_NOTSUP_RETURN (-1); # else // This is oriented towards socket handles... may need some adjustment // for non-sockets. // This is all based on an MSDN article: // http://support.microsoft.com/support/kb/articles/Q150/5/23.asp // If on Win95/98, the handle needs to be duplicated for the to-be-spawned // process. On WinNT, they get inherited by the child process automatically. // If the handle is duplicated, remember the duplicate so it can be // closed later. Can't be closed now, or the child won't get it. OSVERSIONINFO osvi; ZeroMemory (&osvi, sizeof (osvi)); osvi.dwOSVersionInfoSize = sizeof (OSVERSIONINFO); // If this is Win95/98 or we can't tell, duplicate the handle. if (!GetVersionEx (&osvi) || osvi.dwPlatformId != VER_PLATFORM_WIN32_NT) { HANDLE dup_handle; if (!DuplicateHandle (GetCurrentProcess (), ACE_static_cast (HANDLE, h), GetCurrentProcess (), &dup_handle, 0, TRUE, // Inheritable DUPLICATE_SAME_ACCESS)) return -1; dup_handles_.set_bit (ACE_static_cast (ACE_HANDLE, dup_handle)); } # endif /* ACE_HAS_WINCE */ #endif /* ACE_WIN32 */ this->handles_passed_.set_bit (h); return 0; } // Get a copy of the handles the ACE_Process_Options duplicated // for the spawned process. int ACE_Process_Options::dup_handles (ACE_Handle_Set &set) const { if (this->dup_handles_.num_set () == 0) return 0; set.reset (); set = this->dup_handles_; return 1; } // Get a copy of the handles passed to the spawned process. This // will be the set of handles previously passed to @arg pass_handle(). int ACE_Process_Options::passed_handles (ACE_Handle_Set &set) const { if (this->handles_passed_.num_set () == 0) return 0; set.reset (); set = this->handles_passed_; return 1; } ACE_Managed_Process::ACE_Managed_Process (void) { } ACE_Managed_Process::~ACE_Managed_Process (void) { }