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Recipe 17.17 Making a Daemon Server17.17.1 ProblemYou want your program to run as a daemon. 17.17.2 SolutionIf you are paranoid and running as root, chroot to a safe directory: chroot("/var/daemon") or die "Couldn't chroot to /var/daemon: $!"; Fork once, and let the parent exit: $pid = fork; exit if $pid; die "Couldn't fork: $!" unless defined($pid); Close the three standard filehandles by reopening them to /dev/null: for my $handle (*STDIN, *STDOUT, *STDERR) { open($handle, "+<", "/dev/null") || die "can't reopen $handle to /dev/null: $!"; } Dissociate from the controlling terminal that started us and stop being part of whatever process group we had been a member of: use POSIX; POSIX::setsid( ) or die "Can't start a new session: $!"; Trap fatal signals, setting a flag to indicate that we need to gracefully exit: $time_to_die = 0; sub signal_handler { $time_to_die = 1; } $SIG{INT} = $SIG{TERM} = $SIG{HUP} = \&signal_handler; # trap or ignore $SIG{PIPE} Wrap your actual server code in a loop: until ($time_to_die) { # ... } 17.17.3 DiscussionBefore POSIX, every operating system had its own way for a process to tell the operating system "I'm going it alone, please interfere with me as little as possible." POSIX makes it much cleaner. That said, you can still take advantage of any operating system-specific calls if you want to. The chroot call is one of those non-POSIX calls. It makes a process change where it thinks the directory / is. For instance, after chroot "/var/daemon", if the process tries to read the file /etc/passwd, it will read /var/daemon/etc/passwd. A chrooted process needs copies of any files it will run made available inside its new /, of course. For instance, our chrooted process would need /var/daemon/bin/csh if it were going to glob files. For security reasons, only the superuser may chroot. This is done by FTP servers if you log into them anonymously. It isn't really necessary to become a daemon. The operating system expects a child's parent to wait when the child dies. Our daemon process has no particular parent to do this, so we need to disinherit it. This we do by forking once and having our parent exit, so that the child is not associated with the process that started the parent. The child then closes the filehandles it got from its parent (STDIN, STDERR, and STDOUT) by reopening them to /dev/null, and then calls POSIX::setsid to ensure that it is completely dissociated from its parent's terminal. If you want to make sure any higher numbered file descriptors are also closed, you can use the +<&=NUMBER notation to connect up an existing system file descriptor to a Perl filehandle, and then call close on that handle. Here we'll hit all descriptors above 2 and below 256: for (my $fd = 3; $fd < 256; $fd++) { open(my $handle, "+<&=$fd"); # XXX: no error checking close $handle; # XXX: no error checking } Instead of guessing the highest possible file descriptor number, the "correct" way to handle that would be to write a C extension that called getdtablesize(3). This is an exercise we leave up to the user. Now we're almost ready to begin. We don't want signals like SIGINT to kill us immediately (its default behavior), so we use %SIG to catch them and set a flag saying it's time to exit. Then our main program simply becomes: "While we weren't killed, do something." The signal SIGPIPE is a special case. It's easy to get (by writing to a filehandle whose other end is closed) and has unforgiving default behavior (it terminates your process). You probably want to either ignore it ($SIG{PIPE} = 'IGNORE') or define your own signal handler to deal with it appropriately. 17.17.4 See AlsoYour system's setsid(2) and chroot(1) manpage (if you have them); the chroot function in Chapter 29 of Programming Perl and in perlfunc(1); the Unix Socket FAQ at http://www.ibrado.com/sock-faq/; UNIX Network Programming |
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