xio-listen.c

/* source: xio-listen.c */
/* Copyright Gerhard Rieger and contributors (see file CHANGES) */
/* Published under the GNU General Public License V.2, see file COPYING */

/* this file contains the source for listen socket options */

#include "xiosysincludes.h"

#if WITH_LISTEN

#include "xioopen.h"
#include "xio-named.h"
#include "xio-socket.h"
#include "xio-ip.h"
#include "xio-ip4.h"
#include "xio-listen.h"
#include "xio-tcpwrap.h"

/***** LISTEN options *****/
const struct optdesc opt_backlog = { "backlog",   NULL, OPT_BACKLOG,     GROUP_LISTEN, PH_LISTEN, TYPE_INT,    OFUNC_SPEC };
const struct optdesc opt_fork    = { "fork",      NULL, OPT_FORK,        GROUP_CHILD,   PH_PASTACCEPT, TYPE_BOOL,  OFUNC_SPEC };
const struct optdesc opt_max_children = { "max-children", NULL, OPT_MAX_CHILDREN, GROUP_CHILD,   PH_PASTACCEPT, TYPE_INT,  OFUNC_SPEC };
const struct optdesc opt_children_shutup = { "children-shutup", "child-shutup", OPT_CHILDREN_SHUTUP, GROUP_CHILD, PH_PASTACCEPT, TYPE_INT, OFUNC_OFFSET, XIO_OFFSETOF(shutup) };
/**/
#if (WITH_UDP || WITH_TCP)
const struct optdesc opt_range   = { "range",     NULL, OPT_RANGE,       GROUP_RANGE,  PH_ACCEPT, TYPE_STRING, OFUNC_SPEC };
#endif
const struct optdesc opt_accept_timeout = { "accept-timeout", "listen-timeout", OPT_ACCEPT_TIMEOUT, GROUP_LISTEN, PH_LISTEN, TYPE_TIMEVAL, OFUNC_OFFSET, XIO_OFFSETOF(para.socket.accept_timeout) };

/*
   applies and consumes the following option:
   PH_INIT, PH_PASTSOCKET, PH_PREBIND, PH_BIND, PH_PASTBIND, PH_EARLY,
   PH_PREOPEN, PH_FD, PH_CONNECTED, PH_LATE, PH_LATE2
   OPT_FORK, OPT_SO_TYPE, OPT_SO_PROTOTYPE, OPT_BACKLOG, OPT_RANGE, tcpwrap,
   OPT_SOURCEPORT, OPT_LOWPORT, cloexec
 */
int
   xioopen_listen(struct single *sfd, int xioflags,
		  struct sockaddr *us, socklen_t uslen,
		  struct opt *opts, struct opt *opts0,
		  int pf, int socktype, int proto) {
   int level;
   int result;

#if WITH_RETRY
   if (sfd->forever || sfd->retry) {
      level = E_INFO;
   } else
#endif /* WITH_RETRY */
      level = E_ERROR;

   while (true) {	/* loop over failed attempts */

      /* tcp listen; this can fork() for us; it only returns on error or on
	 successful establishment of tcp connection */
      result = _xioopen_listen(sfd, xioflags,
			       (struct sockaddr *)us, uslen,
			       opts, pf, socktype, proto, level);
	 /*! not sure if we should try again on retry/forever */
      switch (result) {
      case STAT_OK: break;
#if WITH_RETRY
      case STAT_RETRYLATER:
      case STAT_RETRYNOW:
	 if (sfd->forever || sfd->retry) {
	    dropopts(opts, PH_ALL); opts = copyopts(opts0, GROUP_ALL);
	    if (result == STAT_RETRYLATER) {
	       Nanosleep(&sfd->intervall, NULL);
	    }
	    dropopts(opts, PH_ALL); opts = copyopts(opts0, GROUP_ALL);
	    --sfd->retry;
	    continue;
	 }
	 return STAT_NORETRY;
#endif /* WITH_RETRY */
      default:
	 return result;
      }

      break;
   }	/* drop out on success */

   return result;
}


/* creates the listening socket, bind, applies options; waits for incoming
   connection, checks its source address and port. Depending on fork option, it
   may fork a subprocess.
   pf specifies the syntax expected for range option. In the case of generic
   socket it is 0 (expecting raw binary data), and the real pf can be obtained
   from us->af_family; for other socket types pf == us->af_family
   Returns 0 if a connection was accepted; with fork option, this is always in
   a subprocess!
   Other return values indicate a problem; this can happen in the master
   process or in a subprocess.
   This function does not retry. If you need retries, handle this in a
   loop in the calling function (and always provide the options...)
   After fork, we set the forever/retry of the child process to 0
   applies and consumes the following option:
   PH_INIT, PH_PASTSOCKET, PH_PREBIND, PH_BIND, PH_PASTBIND, PH_EARLY,
   PH_PREOPEN, PH_FD, PH_CONNECTED, PH_LATE, PH_LATE2
   OPT_FORK, OPT_SO_TYPE, OPT_SO_PROTOTYPE, OPT_BACKLOG, OPT_RANGE, tcpwrap,
   OPT_SOURCEPORT, OPT_LOWPORT, cloexec
 */
int _xioopen_listen(struct single *sfd, int xioflags, struct sockaddr *us, socklen_t uslen,
		 struct opt *opts, int pf, int socktype, int proto, int level) {
   int backlog = 5;	/* why? 1 seems to cause problems under some load */
   char infobuff[256];

   if (applyopts_single(sfd, opts, PH_INIT) < 0)  return -1;

   if ((sfd->fd = xiosocket(opts, pf?pf:us->sa_family, socktype, proto, level)) < 0) {
      return STAT_RETRYLATER;
   }
   applyopts(sfd, -1, opts, PH_PASTSOCKET);

   applyopts_offset(sfd, opts);
   applyopts_cloexec(sfd->fd, opts);

   /* Phase prebind */
   xiosock_reuseaddr(sfd->fd, proto, opts);
   applyopts(sfd, -1, opts, PH_PREBIND);

   applyopts(sfd, -1, opts, PH_BIND);
   if (Bind(sfd->fd, (struct sockaddr *)us, uslen) < 0) {
      Msg4(level, "bind(%d, {%s}, "F_socklen"): %s", sfd->fd,
	   sockaddr_info(us, uslen, infobuff, sizeof(infobuff)), uslen,
	   strerror(errno));
      Close(sfd->fd);
      return STAT_RETRYLATER;
   }

#if WITH_UNIX
   if (us->sa_family == AF_UNIX) {
      if (((union sockaddr_union *)us)->un.sun_path[0] != '\0') {
	 applyopts_named(((struct sockaddr_un *)us)->sun_path, opts, PH_FD);
      } else {
	 applyopts(sfd, -1, opts, PH_FD);
      }
   }
#endif

   applyopts(sfd, -1, opts, PH_PASTBIND);
#if WITH_UNIX
   if (us->sa_family == AF_UNIX) {
      if (((union sockaddr_union *)us)->un.sun_path[0] != '\0') {
	 applyopts_named(((struct sockaddr_un *)us)->sun_path, opts, PH_EARLY);
	 applyopts_named(((struct sockaddr_un *)us)->sun_path, opts, PH_PREOPEN);
      } else {
	 applyopts(sfd, -1, opts, PH_EARLY);
	 applyopts(sfd, -1, opts, PH_PREOPEN);
      }
   }
#endif /* WITH_UNIX */

   applyopts(sfd, -1, opts, PH_PRELISTEN);
   retropt_int(opts, OPT_BACKLOG, &backlog);
   applyopts(sfd, -1, opts, PH_LISTEN);
   if (Listen(sfd->fd, backlog) < 0) {
      Error3("listen(%d, %d): %s", sfd->fd, backlog, strerror(errno));
      return STAT_RETRYLATER;
   }
   return _xioopen_accept_fd(sfd, xioflags, us, uslen, opts, pf, proto,level);
}

int _xioopen_accept_fd(
	struct single *sfd,
	int xioflags,
	struct sockaddr *us,
	socklen_t uslen,
	struct opt *opts,
	int pf,
	int proto,
	int level)
{
   struct sockaddr sa;
   socklen_t salen;
   char *rangename;
   bool dofork = false;
   int maxchildren = 0;
   char infobuff[256];
   char lisname[256];
   union sockaddr_union _peername;
   union sockaddr_union _sockname;
   union sockaddr_union *pa = &_peername;	/* peer address */
   union sockaddr_union *la = &_sockname;	/* local address */
   socklen_t pas = sizeof(_peername);	/* peer address size */
   socklen_t las = sizeof(_sockname);	/* local address size */
   int result;

   retropt_bool(opts, OPT_FORK, &dofork);
   if (dofork) {
      if (!(xioflags & XIO_MAYFORK)) {
	 Error("option fork not allowed here");
	 return STAT_NORETRY;
      }
      sfd->flags |= XIO_DOESFORK;
   }

   retropt_int(opts, OPT_MAX_CHILDREN, &maxchildren);

   if (! dofork && maxchildren) {
       Error("option max-children not allowed without option fork");
       return STAT_NORETRY;
   }

   if (dofork) {
      xiosetchilddied();	/* set SIGCHLD handler */
   }

   /* Under some circumstances (e.g., TCP listen on port 0) bind() fills empty
      fields that we want to know. */
   if (Getsockname(sfd->fd, us, &uslen) < 0) {
      Warn4("getsockname(%d, %p, {%d}): %s",
	    sfd->fd, &us, uslen, strerror(errno));
   }

#if WITH_IP4 /*|| WITH_IP6*/
   if (retropt_string(opts, OPT_RANGE, &rangename) >= 0) {
      if (xioparserange(rangename, pf, &sfd->para.socket.range,
			sfd->para.socket.ip.ai_flags)
	  < 0) {
	 free(rangename);
	 return STAT_NORETRY;
      }
      free(rangename);
      sfd->para.socket.dorange = true;
   }
#endif

#if (WITH_TCP || WITH_UDP) && WITH_LIBWRAP
   xio_retropt_tcpwrap(sfd, opts);
#endif /* && (WITH_TCP || WITH_UDP) && WITH_LIBWRAP */

#if WITH_TCP || WITH_UDP
   if (retropt_ushort(opts, OPT_SOURCEPORT, &sfd->para.socket.ip.sourceport) >= 0) {
      sfd->para.socket.ip.dosourceport = true;
   }
   retropt_bool(opts, OPT_LOWPORT, &sfd->para.socket.ip.lowport);
#endif /* WITH_TCP || WITH_UDP */

   if (xioparms.logopt == 'm') {
      Info("starting accept loop, switching to syslog");
      diag_set('y', xioparms.syslogfac);  xioparms.logopt = 'y';
   } else {
      Info("starting accept loop");
   }
   while (true) {	/* but we only loop if fork option is set */
      char peername[256];
      char sockname[256];
      int ps;		/* peer socket */

      pa = &_peername;
      la = &_sockname;
      do {
	 /*? int level = E_ERROR;*/
	 Notice1("listening on %s", sockaddr_info(us, uslen, lisname, sizeof(lisname)));
	 if (sfd->para.socket.accept_timeout.tv_sec > 0 ||
	     sfd->para.socket.accept_timeout.tv_usec > 0) {
	    fd_set rfd;
	    struct timeval tmo;
	    FD_ZERO(&rfd);
	    FD_SET(sfd->fd, &rfd);
	    tmo.tv_sec = sfd->para.socket.accept_timeout.tv_sec;
	    tmo.tv_usec = sfd->para.socket.accept_timeout.tv_usec;
	    while (1) {
	       if (Select(sfd->fd+1, &rfd, NULL, NULL, &tmo) < 0) {
		  if (errno != EINTR) {
		     Error5("Select(%d, &0x%lx, NULL, NULL, {%ld.%06ld}): %s", sfd->fd+1, 1L<<(sfd->fd+1),
			    sfd->para.socket.accept_timeout.tv_sec, sfd->para.socket.accept_timeout.tv_usec,
			    strerror(errno));
		  }
	       } else {
		  break;
	       }
	    }
	    if (!FD_ISSET(sfd->fd, &rfd)) {
	       struct sigaction act;

	       Warn1("accept: %s", strerror(ETIMEDOUT));
	       Close(sfd->fd);
	       Notice("Waiting for child processes to terminate");
	       memset(&act, 0, sizeof(struct sigaction));
	       act.sa_flags   = SA_NOCLDSTOP/*|SA_RESTART*/
#ifdef SA_SIGINFO /* not on Linux 2.0(.33) */
		  |SA_SIGINFO
#endif
#ifdef SA_NOMASK
		  |SA_NOMASK
#endif
		  ;
#if HAVE_STRUCT_SIGACTION_SA_SIGACTION && defined(SA_SIGINFO)
	       act.sa_sigaction = 0;
#else /* Linux 2.0(.33) does not have sigaction.sa_sigaction */
	       act.sa_handler = 0;
#endif
	       sigemptyset(&act.sa_mask);
	       Sigaction(SIGCHLD, &act, NULL);
	       wait(NULL);
	       Exit(0);
	    }
	 }
	 salen = sizeof(sa);
	 ps = Accept(sfd->fd, (struct sockaddr *)&sa, &salen);
	 if (ps >= 0) {
	    /*0 Info4("accept(%d, %p, {"F_Zu"}) -> %d", sfd->fd, &sa, salen, ps);*/
	    break;	/* success, break out of loop */
	 }
	 if (errno == EINTR) {
	    continue;
	 }
	 if (errno == ECONNABORTED) {
	    Notice4("accept(%d, %p, {"F_socklen"}): %s",
		    sfd->fd, &sa, salen, strerror(errno));
	    continue;
	 }
	 Msg4(level, "accept(%d, %p, {"F_socklen"}): %s",
	      sfd->fd, &sa, salen, strerror(errno));
	 Close(sfd->fd);
	 return STAT_RETRYLATER;
      } while (true);
      applyopts_cloexec(ps, opts);
      if (Getpeername(ps, &pa->soa, &pas) < 0) {
	 Notice4("getpeername(%d, %p, {"F_socklen"}): %s",
	       ps, pa, pas, strerror(errno));
	 pa = NULL;
      }
      if (Getsockname(ps, &la->soa, &las) < 0) {
	 Warn4("getsockname(%d, %p, {"F_socklen"}): %s",
	       ps, la, las, strerror(errno));
	 la = NULL;
      }
      Notice2("accepting connection from %s on %s",
	      pa?
	      sockaddr_info(&pa->soa, pas, peername, sizeof(peername)):"NULL",
	      la?
	      sockaddr_info(&la->soa, las, sockname, sizeof(sockname)):"NULL");

      if (pa != NULL && la != NULL && xiocheckpeer(sfd, pa, la) < 0) {
	 if (Shutdown(ps, 2) < 0) {
	    Info2("shutdown(%d, 2): %s", ps, strerror(errno));
	 }
	 Close(ps);
	 continue;
      }

      if (pa != NULL)
	 Info1("permitting connection from %s",
	       sockaddr_info((struct sockaddr *)pa, pas,
			     infobuff, sizeof(infobuff)));

      if (dofork) {
	 pid_t pid;	/* mostly int; only used with fork */
         sigset_t mask_sigchld;

         /* Block SIGCHLD until parent is ready to react */
         sigemptyset(&mask_sigchld);
         sigaddset(&mask_sigchld, SIGCHLD);
         Sigprocmask(SIG_BLOCK, &mask_sigchld, NULL);

	 if ((pid =
	      xio_fork(false, level==E_ERROR?level:E_WARN,
		       sfd->shutup))
	     < 0) {
	    Close(sfd->fd);
	    Sigprocmask(SIG_UNBLOCK, &mask_sigchld, NULL);
	    return STAT_RETRYLATER;
	 }
	 if (pid == 0) {	/* child */
	    pid_t cpid = Getpid();
	    Sigprocmask(SIG_UNBLOCK, &mask_sigchld, NULL);

	    Info1("just born: child process "F_pid, cpid);
	    xiosetenvulong("PID", cpid, 1);

	    if (Close(sfd->fd) < 0) {
	       Info2("close(%d): %s", sfd->fd, strerror(errno));
	    }
	    sfd->fd = ps;

#if WITH_RETRY
	    /* !? */
	    sfd->forever = false;  sfd->retry = 0;
	    level = E_ERROR;
#endif /* WITH_RETRY */

	    break;
	 }

	 /* server: continue loop with listen */
	 /* shutdown() closes the socket even for the child process, but
	    close() does what we want */
	 if (Close(ps) < 0) {
	    Info2("close(%d): %s", ps, strerror(errno));
	 }

         /* now we are ready to handle signals */
         Sigprocmask(SIG_UNBLOCK, &mask_sigchld, NULL);


	 while (maxchildren) {
	    if (num_child < maxchildren) break;
	    Notice("maxchildren are active, waiting");
	    /* UINT_MAX would even be nicer, but Openindiana works only
	       with 31 bits */
	    while (!Sleep(INT_MAX)) ;	/* any signal lets us continue */
	 }
	 Info("still listening");
      } else {
	 if (Close(sfd->fd) < 0) {
	    Info2("close(%d): %s", sfd->fd, strerror(errno));
	 }
	 sfd->fd = ps;
	break;
      }
   }

   applyopts(sfd, -1, opts, PH_FD);
   applyopts(sfd, -1, opts, PH_PASTSOCKET);
   applyopts(sfd, -1, opts, PH_CONNECTED);
   if ((result = _xio_openlate(sfd, opts)) < 0)
      return result;

   /* set the env vars describing the local and remote sockets */
   if (la != NULL)  xiosetsockaddrenv("SOCK", la, las, proto);
   if (pa != NULL)  xiosetsockaddrenv("PEER", pa, pas, proto);

   return 0;
}

#endif /* WITH_LISTEN */