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exit (3)
  • exit (1) ( Solaris man: Команды и прикладные программы пользовательского уровня )
  • exit (1) ( FreeBSD man: Команды и прикладные программы пользовательского уровня )
  • exit (1) ( Linux man: Команды и прикладные программы пользовательского уровня )
  • exit (1) ( POSIX man: Команды и прикладные программы пользовательского уровня )
  • exit (2) ( Solaris man: Системные вызовы )
  • exit (2) ( Русские man: Системные вызовы )
  • exit (2) ( Linux man: Системные вызовы )
  • exit (3) ( Solaris man: Библиотечные вызовы )
  • exit (3) ( FreeBSD man: Библиотечные вызовы )
  • exit (3) ( Русские man: Библиотечные вызовы )
  • exit (3) ( Linux man: Библиотечные вызовы )
  • >> exit (3) ( POSIX man: Библиотечные вызовы )


    exit, _Exit, _exit - terminate a process


    #include <stdlib.h>

    void exit(int status);
    void _Exit(int

    #include <unistd.h>
    void _exit(int


    For exit() and _Exit(): The functionality described on this reference page is aligned with the ISO C standard. Any conflict between the requirements described here and the ISO C standard is unintentional. This volume of IEEE Std 1003.1-2001 defers to the ISO C standard.

    The value of status may be 0, EXIT_SUCCESS, EXIT_FAILURE, <img src="../images/opt-start.gif" alt="[Option Start]" border="0">  or any other value, though only the least significant 8 bits (that is, status & 0377) shall be available to a waiting parent process.

    The exit() function shall first call all functions registered by atexit(), in the reverse order of their registration, except that a function is called after any previously registered functions that had already been called at the time it was registered. Each function is called as many times as it was registered. If, during the call to any such function, a call to the longjmp() function is made that would terminate the call to the registered function, the behavior is undefined.

    If a function registered by a call to atexit() fails to return, the remaining registered functions shall not be called and the rest of the exit() processing shall not be completed. If exit() is called more than once, the behavior is undefined.

    The exit() function shall then flush all open streams with unwritten buffered data, close all open streams, and remove all files created by tmpfile(). Finally, control shall be terminated with the consequences described below.

    The _Exit() and _exit() functions shall be functionally equivalent.

    The _Exit()  and _exit() functions shall not call functions registered with atexit() nor any registered signal handlers. Whether open streams are flushed or closed, or temporary files are removed is implementation-defined. Finally, the calling process is terminated with the consequences described below.

    These functions shall terminate the calling process  with the following consequences:

    These consequences are all extensions to the ISO C standard and are not further CX shaded. However, XSI extensions are shaded.

    All of the file descriptors, directory streams,  conversion descriptors, and message catalog descriptors  open in the calling process shall be closed.

    If the parent process of the calling process is executing a wait() or waitpid(),  and has neither set its SA_NOCLDWAIT flag nor set SIGCHLD to SIG_IGN, it shall be notified of the calling process' termination and the low-order eight bits (that is, bits 0377) of status shall be made available to it. If the parent is not waiting, the child's status shall be made available to it when the parent subsequently executes wait() or waitpid().

    The semantics of the waitid() function shall be equivalent to wait().

    If the parent process of the calling process is not executing a wait() or waitpid(),  and has neither set its SA_NOCLDWAIT flag nor set SIGCHLD to SIG_IGN, the calling process shall be transformed into a zombie process. A zombie process is an inactive process and it shall be deleted at some later time when its parent process executes wait() or waitpid().

    The semantics of the waitid() function shall be equivalent to wait().

    Termination of a process does not directly terminate its children. The sending of a SIGHUP signal as described below indirectly terminates children in some circumstances.


    If the implementation supports the SIGCHLD signal, a SIGCHLD shall be sent to the parent process.


    If the parent process has set its SA_NOCLDWAIT flag, or set SIGCHLD to SIG_IGN, the status shall be discarded, and the lifetime of the calling process shall end immediately. If SA_NOCLDWAIT is set, it is implementation-defined whether a SIGCHLD signal is sent to the parent process.

    The parent process ID of all of the calling process' existing child processes and zombie processes shall be set to the process ID of an implementation-defined system process. That is, these processes shall be inherited by a special system process.

    Each attached shared-memory segment is detached and the value of shm_nattch (see shmget()) in the data structure associated with its shared memory ID shall be decremented by 1.

    For each semaphore for which the calling process has set a semadj value (see semop() ), that value shall be added to the semval of the specified semaphore.

    If the process is a controlling process, the SIGHUP signal shall be sent to each process in the foreground process group of the controlling terminal belonging to the calling process.

    If the process is a controlling process, the controlling terminal associated with the session shall be disassociated from the session, allowing it to be acquired by a new controlling process.

    If the exit of the process causes a process group to become orphaned, and if any member of the newly-orphaned process group is stopped, then a SIGHUP signal followed by a SIGCONT signal shall be sent to each process in the newly-orphaned process group.

    All open named semaphores in the calling process shall be closed as if by appropriate calls to sem_close().

    Any memory locks established by the process via calls to mlockall() or mlock() shall be removed. If locked pages in the address space of the calling process are also mapped into the address spaces of other processes and are locked by those processes, the locks established by the other processes shall be unaffected by the call by this process to _Exit() or _exit().

    Memory mappings that were created in the process shall be unmapped before the process is destroyed.

    Any blocks of typed memory that were mapped in the calling process shall be unmapped, as if munmap() was implicitly called to unmap them.

    All open message queue descriptors in the calling process shall be closed as if by appropriate calls to mq_close().

    Any outstanding cancelable asynchronous I/O operations may be canceled. Those asynchronous I/O operations that are not canceled shall complete as if the _Exit() or _exit() operation had not yet occurred, but any associated signal notifications shall be suppressed. The _Exit() or _exit() operation may block awaiting such I/O completion. Whether any I/O is canceled, and which I/O may be canceled upon _Exit() or _exit(), is implementation-defined.

    Threads terminated by a call to _Exit() or _exit() shall not invoke their cancellation cleanup handlers or per-thread data destructors.

    If the calling process is a trace controller process, any trace streams that were created by the calling process shall be shut down as described by the posix_trace_shutdown() function, and any process' mapping of trace event names to trace event type identifiers built for these trace streams may be deallocated.



    These functions do not return.  


    No errors are defined.

    The following sections are informative.  




    Normally applications should use exit() rather than _Exit() or _exit().  



    Process Termination

    Early proposals drew a distinction between normal and abnormal process termination. Abnormal termination was caused only by certain signals and resulted in implementation-defined "actions", as discussed below. Subsequent proposals distinguished three types of termination: normal termination (as in the current specification), simple abnormal termination, and abnormal termination with actions. Again the distinction between the two types of abnormal termination was that they were caused by different signals and that implementation-defined actions would result in the latter case. Given that these actions were completely implementation-defined, the early proposals were only saying when the actions could occur and how their occurrence could be detected, but not what they were. This was of little or no use to conforming applications, and thus the distinction is not made in this volume of IEEE Std 1003.1-2001.

    The implementation-defined actions usually include, in most historical implementations, the creation of a file named core in the current working directory of the process. This file contains an image of the memory of the process, together with descriptive information about the process, perhaps sufficient to reconstruct the state of the process at the receipt of the signal.

    There is a potential security problem in creating a core file if the process was set-user-ID and the current user is not the owner of the program, if the process was set-group-ID and none of the user's groups match the group of the program, or if the user does not have permission to write in the current directory. In this situation, an implementation either should not create a core file or should make it unreadable by the user.

    Despite the silence of this volume of IEEE Std 1003.1-2001 on this feature, applications are advised not to create files named core because of potential conflicts in many implementations. Some implementations use a name other than core for the file; for example, by appending the process ID to the filename.  

    Terminating a Process

    It is important that the consequences of process termination as described occur regardless of whether the process called _exit() (perhaps indirectly through exit()) or instead was terminated due to a signal or for some other reason. Note that in the specific case of exit() this means that the status argument to exit() is treated in the same way as the status argument to _exit().

    A language other than C may have other termination primitives than the C-language exit() function, and programs written in such a language should use its native termination primitives, but those should have as part of their function the behavior of _exit() as described. Implementations in languages other than C are outside the scope of this version of this volume of IEEE Std 1003.1-2001, however.

    As required by the ISO C standard, using return from main() has the same behavior (other than with respect to language scope issues) as calling exit() with the returned value. Reaching the end of the main() function has the same behavior as calling exit(0).

    A value of zero (or EXIT_SUCCESS, which is required to be zero) for the argument status conventionally indicates successful termination. This corresponds to the specification for exit() in the ISO C standard. The convention is followed by utilities such as make and various shells, which interpret a zero status from a child process as success. For this reason, applications should not call exit(0) or _exit(0) when they terminate unsuccessfully; for example, in signal-catching functions.

    Historically, the implementation-defined process that inherits children whose parents have terminated without waiting on them is called init and has a process ID of 1.

    The sending of a SIGHUP to the foreground process group when a controlling process terminates corresponds to somewhat different historical implementations. In System V, the kernel sends a SIGHUP on termination of (essentially) a controlling process. In 4.2 BSD, the kernel does not send SIGHUP in a case like this, but the termination of a controlling process is usually noticed by a system daemon, which arranges to send a SIGHUP to the foreground process group with the vhangup() function. However, in 4.2 BSD, due to the behavior of the shells that support job control, the controlling process is usually a shell with no other processes in its process group. Thus, a change to make _exit() behave this way in such systems should not cause problems with existing applications.

    The termination of a process may cause a process group to become orphaned in either of two ways. The connection of a process group to its parent(s) outside of the group depends on both the parents and their children. Thus, a process group may be orphaned by the termination of the last connecting parent process outside of the group or by the termination of the last direct descendant of the parent process(es). In either case, if the termination of a process causes a process group to become orphaned, processes within the group are disconnected from their job control shell, which no longer has any information on the existence of the process group. Stopped processes within the group would languish forever. In order to avoid this problem, newly orphaned process groups that contain stopped processes are sent a SIGHUP signal and a SIGCONT signal to indicate that they have been disconnected from their session. The SIGHUP signal causes the process group members to terminate unless they are catching or ignoring SIGHUP. Under most circumstances, all of the members of the process group are stopped if any of them are stopped.

    The action of sending a SIGHUP and a SIGCONT signal to members of a newly orphaned process group is similar to the action of 4.2 BSD, which sends SIGHUP and SIGCONT to each stopped child of an exiting process. If such children exit in response to the SIGHUP, any additional descendants receive similar treatment at that time. In this volume of IEEE Std 1003.1-2001, the signals are sent to the entire process group at the same time. Also, in this volume of IEEE Std 1003.1-2001, but not in 4.2 BSD, stopped processes may be orphaned, but may be members of a process group that is not orphaned; therefore, the action taken at _exit() must consider processes other than child processes.

    It is possible for a process group to be orphaned by a call to setpgid() or setsid(), as well as by process termination. This volume of IEEE Std 1003.1-2001 does not require sending SIGHUP and SIGCONT in those cases, because, unlike process termination, those cases are not caused accidentally by applications that are unaware of job control. An implementation can choose to send SIGHUP and SIGCONT in those cases as an extension; such an extension must be documented as required in <signal.h>.

    The ISO/IEC 9899:1999 standard adds the _Exit() function that results in immediate program termination without triggering signals or atexit()-registered functions. In IEEE Std 1003.1-2001, this is equivalent to the _exit() function.  




    atexit() , close() , fclose() , longjmp() , posix_trace_shutdown() , posix_trace_trid_eventid_open() , semop() , shmget() , sigaction() , wait() , waitid() , waitpid() , the Base Definitions volume of IEEE Std 1003.1-2001, <stdlib.h>, <unistd.h>  


    Portions of this text are reprinted and reproduced in electronic form from IEEE Std 1003.1, 2003 Edition, Standard for Information Technology -- Portable Operating System Interface (POSIX), The Open Group Base Specifications Issue 6, Copyright (C) 2001-2003 by the Institute of Electrical and Electronics Engineers, Inc and The Open Group. In the event of any discrepancy between this version and the original IEEE and The Open Group Standard, the original IEEE and The Open Group Standard is the referee document. The original Standard can be obtained online at .



    Process Termination
    Terminating a Process

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