/* Start and maintain hurd core servers and system run state Copyright (C) 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2005, 2008, 2013 Free Software Foundation, Inc. This file is part of the GNU Hurd. The GNU Hurd is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. The GNU Hurd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with the GNU Hurd; see the file COPYING. If not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ /* Written by Michael I. Bushnell and Roland McGrath. */ /* This is probably more include files than I've ever seen before for one file. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "startup_notify_U.h" #include "startup_reply_U.h" #include "startup_S.h" #include "notify_S.h" #include "mung_msg_S.h" /* host_reboot flags for when we crash. */ static int crash_flags = RB_AUTOBOOT; #define BOOT(flags) ((flags & RB_HALT) ? "halt" : "reboot") const char *argp_program_version = STANDARD_HURD_VERSION (startup); static struct argp_option options[] = { {"single-user", 's', 0, 0, "Startup system in single-user mode"}, {"query", 'q', 0, 0, "Ask for the names of servers to start"}, {"init-name", 'n', 0, 0 }, {"crash-debug", 'H', 0, 0, "On system crash, go to kernel debugger"}, {"debug", 'd', 0, 0 }, {"fake-boot", 'f', 0, 0, "This hurd hasn't been booted on the raw machine"}, {0, 'x', 0, OPTION_HIDDEN}, {0} }; static char doc[] = "Start and maintain hurd core servers and system run state"; static int booted; /* Set when the core servers are up. */ /* This structure keeps track of each notified task. */ struct ntfy_task { mach_port_t notify_port; struct ntfy_task *next; char *name; }; /* This structure keeps track of each registered essential task. */ struct ess_task { struct ess_task *next; task_t task_port; char *name; }; /* These are linked lists of all of the registered items. */ static struct ess_task *ess_tasks; static struct ntfy_task *ntfy_tasks; /* Our receive right */ static mach_port_t startup; /* Ports to the kernel */ static mach_port_t host_priv, device_master; /* Args to bootstrap, expressed as flags */ static int bootstrap_args = 0; /* Stored information for returning proc and auth startup messages. */ static mach_port_t procreply, authreply; static mach_msg_type_name_t procreplytype, authreplytype; /* Our ports to auth and proc. */ static mach_port_t authserver; static mach_port_t procserver; /* Our bootstrap port, on which we call fsys_getpriv and fsys_init. */ static mach_port_t bootport; /* Set iff we are a `fake' bootstrap. */ static int fakeboot; /* The tasks of auth and proc and the bootstrap filesystem. */ static task_t authtask, proctask, fstask; static mach_port_t default_ports[INIT_PORT_MAX]; static mach_port_t default_dtable[3]; static int default_ints[INIT_INT_MAX]; static char **global_argv; static char *startup_envz; static size_t startup_envz_len; void launch_system (void); void process_signal (int signo); /** Utility functions **/ /* Read a string from stdin into BUF. */ static int getstring (char *buf, size_t bufsize) { if (fgets (buf, bufsize, stdin) != NULL && buf[0] != '\0') { size_t len = strlen (buf); if (buf[len - 1] == '\n' || buf[len - 1] == '\r') buf[len - 1] = '\0'; return 1; } return 0; } /** System shutdown **/ /* Reboot the microkernel. */ void reboot_mach (int flags) { if (fakeboot) { printf ("%s: Would %s Mach with flags %#x\n", program_invocation_short_name, BOOT (flags), flags); fflush (stdout); exit (1); } else { error_t err; printf ("%s: %sing Mach (flags %#x)...\n", program_invocation_short_name, BOOT (flags), flags); fflush (stdout); sleep (5); while ((err = host_reboot (host_priv, flags))) error (0, err, "reboot"); for (;;); } } /* Reboot the microkernel, specifying that this is a crash. */ void crash_mach (void) { reboot_mach (crash_flags); } /* Notify all tasks that have requested shutdown notifications */ void notify_shutdown (const char *msg) { struct ntfy_task *n; for (n = ntfy_tasks; n != NULL; n = n->next) { error_t err; printf ("%s: notifying %s of %s...", program_invocation_short_name, n->name, msg); fflush (stdout); err = startup_dosync (n->notify_port, 60000); /* 1 minute to reply */ if (err == MACH_SEND_INVALID_DEST) puts ("(no longer present)"); else if (err) puts (strerror (err)); else puts ("done"); fflush (stdout); } } /* Reboot the Hurd. */ void reboot_system (int flags) { notify_shutdown (BOOT (flags)); if (fakeboot) { pid_t *pp; size_t npids = 0; error_t err; int ind; err = proc_getallpids (procserver, &pp, &npids); if (err == MACH_SEND_INVALID_DEST) { procbad: /* The procserver must have died. Give up. */ error (0, 0, "Can't simulate crash; proc has died"); reboot_mach (flags); } for (ind = 0; ind < npids; ind++) { task_t task; err = proc_pid2task (procserver, pp[ind], &task); if (err == MACH_SEND_INVALID_DEST) goto procbad; else if (err) { error (0, err, "Getting task for pid %d", pp[ind]); continue; } /* Postpone self so we can finish; postpone proc so that we can finish. */ if (task != mach_task_self () && task != proctask) { struct procinfo *pi = 0; size_t pisize = 0; char *noise; size_t noise_len = 0; int flags; err = proc_getprocinfo (procserver, pp[ind], &flags, (int **)&pi, &pisize, &noise, &noise_len); if (err == MACH_SEND_INVALID_DEST) goto procbad; if (err) { error (0, err, "Getting procinfo for pid %d", pp[ind]); continue; } if (!(pi->state & PI_NOPARENT)) { printf ("%s: Killing pid %d\n", program_invocation_short_name, pp[ind]); fflush (stdout); task_terminate (task); } if (noise_len > 0) munmap (noise, noise_len); } } printf ("%s: Killing proc server\n", program_invocation_short_name); fflush (stdout); task_terminate (proctask); printf ("%s: Exiting", program_invocation_short_name); fflush (stdout); } reboot_mach (flags); } /* Reboot the Hurd, specifying that this is a crash. */ void crash_system (void) { reboot_system (crash_flags); } /* Request a dead-name notification sent to our port. */ static void request_dead_name (mach_port_t name) { mach_port_t prev; mach_port_request_notification (mach_task_self (), name, MACH_NOTIFY_DEAD_NAME, 1, startup, MACH_MSG_TYPE_MAKE_SEND_ONCE, &prev); if (prev != MACH_PORT_NULL) mach_port_deallocate (mach_task_self (), prev); } /* Record an essential task in the list. */ static error_t record_essential_task (const char *name, task_t task) { struct ess_task *et; /* Record this task as essential. */ et = malloc (sizeof (struct ess_task)); if (et == NULL) return ENOMEM; et->task_port = task; et->name = strdup (name); if (et->name == NULL) { free (et); return ENOMEM; } et->next = ess_tasks; ess_tasks = et; /* Dead-name notification on the task port will tell us when it dies. */ request_dead_name (task); #if 0 /* Taking over the exception port will give us a better chance if the task tries to get wedged on a fault. */ task_set_special_port (task, TASK_EXCEPTION_PORT, startup); #endif return 0; } /** Starting programs **/ /* Run SERVER, giving it INIT_PORT_MAX initial ports from PORTS. Set TASK to be the task port of the new image. */ void run (const char *server, mach_port_t *ports, task_t *task) { char buf[BUFSIZ]; const char *prog = server; if (bootstrap_args & RB_INITNAME) { printf ("Server file name (default %s): ", server); if (getstring (buf, sizeof (buf))) prog = buf; } while (1) { file_t file; error_t err; file = file_name_lookup (prog, O_EXEC, 0); if (file == MACH_PORT_NULL) error (0, errno, "%s", prog); else { task_create (mach_task_self (), #ifdef KERN_INVALID_LEDGER NULL, 0, /* OSF Mach */ #endif 0, task); if (bootstrap_args & RB_KDB) { printf ("Pausing for %s\n", prog); getchar (); } task_set_name (*task, (char *) prog); err = file_exec (file, *task, 0, (char *)prog, strlen (prog) + 1, /* Args. */ startup_envz, startup_envz_len, default_dtable, MACH_MSG_TYPE_COPY_SEND, 3, ports, MACH_MSG_TYPE_COPY_SEND, INIT_PORT_MAX, default_ints, INIT_INT_MAX, NULL, 0, NULL, 0); if (!err) break; error (0, err, "%s", prog); } printf ("File name for server %s (or nothing to reboot): ", server); if (getstring (buf, sizeof (buf))) prog = buf; else crash_system (); } #if 0 printf ("started %s\n", prog); fflush (stdout); #endif /* Dead-name notification on the task port will tell us when it dies, so we can crash if we don't make it to a fully bootstrapped Hurd. */ request_dead_name (*task); } /* Run FILENAME as root with ARGS as its argv (length ARGLEN). Return the task that we started. If CTTY is set, then make that the controlling terminal of the new process and put it in its own login collection. If SETSID is set, put it in a new session. Return 0 if the task was not created successfully. */ pid_t run_for_real (char *filename, char *args, int arglen, mach_port_t ctty, int setsid) { file_t file; error_t err; task_t task; char *progname; int pid; #if 0 char buf[512]; do { printf ("File name [%s]: ", filename); if (getstring (buf, sizeof (buf)) && *buf) filename = buf; file = file_name_lookup (filename, O_EXEC, 0); if (file == MACH_PORT_NULL) error (0, errno, "%s", filename); } while (file == MACH_PORT_NULL); #else file = file_name_lookup (filename, O_EXEC, 0); if (file == MACH_PORT_NULL) { error (0, errno, "%s", filename); return 0; } #endif task_create (mach_task_self (), #ifdef KERN_INVALID_LEDGER NULL, 0, /* OSF Mach */ #endif 0, &task); proc_child (procserver, task); proc_task2pid (procserver, task, &pid); proc_task2proc (procserver, task, &default_ports[INIT_PORT_PROC]); proc_mark_exec (default_ports[INIT_PORT_PROC]); if (setsid) proc_setsid (default_ports[INIT_PORT_PROC]); if (ctty != MACH_PORT_NULL) { term_getctty (ctty, &default_ports[INIT_PORT_CTTYID]); io_mod_owner (ctty, -pid); proc_make_login_coll (default_ports[INIT_PORT_PROC]); } if (bootstrap_args & RB_KDB) { printf ("Pausing for %s\n", filename); getchar (); } progname = strrchr (filename, '/'); if (progname) ++progname; else progname = filename; err = file_exec (file, task, 0, args, arglen, startup_envz, startup_envz_len, default_dtable, MACH_MSG_TYPE_COPY_SEND, 3, default_ports, MACH_MSG_TYPE_COPY_SEND, INIT_PORT_MAX, default_ints, INIT_INT_MAX, NULL, 0, NULL, 0); mach_port_deallocate (mach_task_self (), default_ports[INIT_PORT_PROC]); mach_port_deallocate (mach_task_self (), task); if (ctty != MACH_PORT_NULL) { mach_port_deallocate (mach_task_self (), default_ports[INIT_PORT_CTTYID]); default_ports[INIT_PORT_CTTYID] = MACH_PORT_NULL; } mach_port_deallocate (mach_task_self (), file); if (err) { error (0, err, "Cannot execute %s", filename); return 0; } return pid; } /** Main program and setup **/ static int demuxer (mach_msg_header_t *inp, mach_msg_header_t *outp) { extern int notify_server (mach_msg_header_t *, mach_msg_header_t *); extern int startup_server (mach_msg_header_t *, mach_msg_header_t *); extern int msg_server (mach_msg_header_t *, mach_msg_header_t *); extern int fsys_server (mach_msg_header_t *, mach_msg_header_t *); return (notify_server (inp, outp) || msg_server (inp, outp) || fsys_server (inp, outp) || startup_server (inp, outp)); } static int parse_opt (int key, char *arg, struct argp_state *state) { switch (key) { case 'q': bootstrap_args |= RB_ASKNAME; break; case 's': bootstrap_args |= RB_SINGLE; break; case 'd': bootstrap_args |= RB_KDB; break; case 'n': bootstrap_args |= RB_INITNAME; break; case 'f': fakeboot = 1; break; case 'H': crash_flags = RB_DEBUGGER; break; case 'x': /* NOP */ break; default: return ARGP_ERR_UNKNOWN; } return 0; } int main (int argc, char **argv, char **envp) { volatile int err; int i; int flags; mach_port_t consdev; struct argp argp = { options, parse_opt, 0, doc }; /* Parse the arguments. We don't want the vector reordered, we should pass on to our child the exact arguments we got and just ignore any arguments that aren't flags for us. ARGP_NO_ERRS suppresses --help and --version, so we only use that option if we are booting. */ flags = ARGP_IN_ORDER; if (getpid () == 0) flags |= ARGP_NO_ERRS; argp_parse (&argp, argc, argv, flags, 0, 0); if (getpid () > 0) error (2, 0, "can only be run by bootstrap filesystem"); global_argv = argv; /* Fetch a port to the bootstrap filesystem, the host priv and master device ports, and the console. */ if (task_get_bootstrap_port (mach_task_self (), &bootport) || fsys_getpriv (bootport, &host_priv, &device_master, &fstask) || device_open (device_master, D_READ|D_WRITE, "console", &consdev)) crash_mach (); wire_task_self (); /* Clear our bootstrap port so our children don't inherit it. */ task_set_bootstrap_port (mach_task_self (), MACH_PORT_NULL); stderr = stdout = mach_open_devstream (consdev, "w"); stdin = mach_open_devstream (consdev, "r"); if (stdout == NULL || stdin == NULL) crash_mach (); setbuf (stdout, NULL); err = argz_create (envp, &startup_envz, &startup_envz_len); assert_perror (err); /* At this point we can use assert to check for errors. */ err = mach_port_allocate (mach_task_self (), MACH_PORT_RIGHT_RECEIVE, &startup); assert_perror (err); err = mach_port_insert_right (mach_task_self (), startup, startup, MACH_MSG_TYPE_MAKE_SEND); assert_perror (err); /* Crash if the boot filesystem task dies. */ request_dead_name (fstask); file_t node = file_name_lookup (_SERVERS_STARTUP, O_NOTRANS, 0); if (node == MACH_PORT_NULL) error (0, errno, "%s", _SERVERS_STARTUP); else { file_set_translator (node, 0, FS_TRANS_SET, 0, NULL, 0, startup, MACH_MSG_TYPE_COPY_SEND); mach_port_deallocate (mach_task_self (), node); } /* Set up the set of ports we will pass to the programs we exec. */ for (i = 0; i < INIT_PORT_MAX; i++) switch (i) { case INIT_PORT_CRDIR: default_ports[i] = getcrdir (); break; case INIT_PORT_CWDIR: default_ports[i] = getcwdir (); break; default: default_ports[i] = MACH_PORT_NULL; break; } default_dtable[0] = getdport (0); default_dtable[1] = getdport (1); default_dtable[2] = getdport (2); /* All programs we start should ignore job control stop signals. That way Posix.1 B.2.2.2 is satisfied where it says that programs not run under job control shells are protected. */ default_ints[INIT_SIGIGN] = (sigmask (SIGTSTP) | sigmask (SIGTTIN) | sigmask (SIGTTOU)); default_ports[INIT_PORT_BOOTSTRAP] = startup; run ("/hurd/proc", default_ports, &proctask); printf (" proc"); fflush (stdout); run ("/hurd/auth", default_ports, &authtask); printf (" auth"); fflush (stdout); default_ports[INIT_PORT_BOOTSTRAP] = MACH_PORT_NULL; /* Wait for messages. When both auth and proc have started, we run launch_system which does the rest of the boot. */ while (1) { err = mach_msg_server (demuxer, 0, startup); assert_perror (err); } } void launch_core_servers (void) { mach_port_t old; mach_port_t authproc, fsproc, procproc; error_t err; /* Reply to the proc and auth servers. */ startup_procinit_reply (procreply, procreplytype, 0, mach_task_self (), authserver, host_priv, MACH_MSG_TYPE_COPY_SEND, device_master, MACH_MSG_TYPE_COPY_SEND); if (!fakeboot) { mach_port_deallocate (mach_task_self (), device_master); device_master = 0; } /* Mark us as important. */ proc_mark_important (procserver); proc_mark_exec (procserver); /* Declare that the filesystem and auth are our children. */ proc_child (procserver, fstask); proc_child (procserver, authtask); proc_task2proc (procserver, authtask, &authproc); proc_mark_important (authproc); proc_mark_exec (authproc); startup_authinit_reply (authreply, authreplytype, 0, authproc, MACH_MSG_TYPE_COPY_SEND); mach_port_deallocate (mach_task_self (), authproc); /* Give the library our auth and proc server ports. */ _hurd_port_set (&_hurd_ports[INIT_PORT_AUTH], authserver); _hurd_port_set (&_hurd_ports[INIT_PORT_PROC], procserver); /* Do NOT run _hurd_proc_init! That will start signals, which we do not want. We listen to our own message port. Tell the proc server where our args and environment are. */ proc_set_arg_locations (procserver, (vm_address_t) global_argv, (vm_address_t) environ); default_ports[INIT_PORT_AUTH] = authserver; /* Declare that the proc server is our child. */ proc_child (procserver, proctask); err = proc_task2proc (procserver, proctask, &procproc); if (!err) { proc_mark_important (procproc); proc_mark_exec (procproc); mach_port_deallocate (mach_task_self (), procproc); } proc_register_version (procserver, host_priv, "init", "", HURD_VERSION); /* Get the bootstrap filesystem's proc server port. We must do this before calling proc_setmsgport below. */ proc_task2proc (procserver, fstask, &fsproc); proc_mark_important (fsproc); proc_mark_exec (fsproc); #if 0 printf ("Init has completed.\n"); fflush (stdout); #endif printf (".\n"); fflush (stdout); /* Tell the proc server our msgport. Be sure to do this after we are all done making requests of proc. Once we have done this RPC, proc assumes it can send us requests, so we cannot block on proc again before accepting more RPC requests! However, we must do this before calling fsys_init, because fsys_init blocks on exec_init, and exec_init will block waiting on our message port. */ proc_setmsgport (procserver, startup, &old); if (old != MACH_PORT_NULL) mach_port_deallocate (mach_task_self (), old); /* Give the bootstrap FS its proc and auth ports. */ err = fsys_init (bootport, fsproc, MACH_MSG_TYPE_COPY_SEND, authserver); mach_port_deallocate (mach_task_self (), fsproc); if (err) error (0, err, "fsys_init"); /* Not necessarily fatal. */ } /* Set up the initial value of the standard exec data. */ void init_stdarrays () { auth_t nullauth; mach_port_t pt; mach_port_t ref; mach_port_t *std_port_array; int *std_int_array; int i; std_port_array = alloca (sizeof (mach_port_t) * INIT_PORT_MAX); std_int_array = alloca (sizeof (int) * INIT_INT_MAX); memset (std_port_array, 0, sizeof(mach_port_t) * INIT_PORT_MAX); memset (std_int_array, 0, sizeof(int) * INIT_INT_MAX); __USEPORT (AUTH, auth_makeauth (port, 0, MACH_MSG_TYPE_COPY_SEND, 0, 0, 0, 0, 0, 0, 0, 0, 0, &nullauth)); /* MAKE_SEND is safe in these transactions because we destroy REF ourselves each time. */ pt = getcwdir (); ref = mach_reply_port (); io_reauthenticate (pt, ref, MACH_MSG_TYPE_MAKE_SEND); auth_user_authenticate (nullauth, ref, MACH_MSG_TYPE_MAKE_SEND, &std_port_array[INIT_PORT_CWDIR]); mach_port_destroy (mach_task_self (), ref); mach_port_deallocate (mach_task_self (), pt); pt = getcrdir (); ref = mach_reply_port (); io_reauthenticate (pt, ref, MACH_MSG_TYPE_MAKE_SEND); auth_user_authenticate (nullauth, ref, MACH_MSG_TYPE_MAKE_SEND, &std_port_array[INIT_PORT_CRDIR]); mach_port_destroy (mach_task_self (), ref); mach_port_deallocate (mach_task_self (), pt); std_port_array[INIT_PORT_AUTH] = nullauth; std_int_array[INIT_UMASK] = CMASK; __USEPORT (PROC, proc_setexecdata (port, std_port_array, MACH_MSG_TYPE_COPY_SEND, INIT_PORT_MAX, std_int_array, INIT_INT_MAX)); for (i = 0; i < INIT_PORT_MAX; i++) mach_port_deallocate (mach_task_self (), std_port_array[i]); } /* Frobnicate the kernel task and the proc server's idea of it (PID 2), so the kernel command line can be read as for a normal Hurd process. */ void frob_kernel_process (void) { error_t err; int argc, i; char *argz, *entry; size_t argzlen; size_t windowsz; vm_address_t mine, his; task_t task; process_t proc, kbs; err = proc_pid2task (procserver, HURD_PID_KERNEL, &task); if (err) { error (0, err, "cannot get kernel task port"); return; } err = proc_task2proc (procserver, task, &proc); if (err) { error (0, err, "cannot get kernel task's proc server port"); mach_port_deallocate (mach_task_self (), task); return; } /* Mark the kernel task as an essential task so that we or the proc server never want to task_terminate it. */ proc_mark_important (proc); err = record_essential_task ("kernel", task); assert_perror (err); err = task_get_bootstrap_port (task, &kbs); assert_perror (err); if (kbs == MACH_PORT_NULL) { /* The kernel task has no bootstrap port set, so we are presumably the first Hurd to boot. Install the kernel task's proc port from this Hurd's proc server as the task bootstrap port. Additional Hurds will see this. */ err = task_set_bootstrap_port (task, proc); if (err) error (0, err, "cannot set kernel task's bootstrap port"); if (fakeboot) error (0, 0, "warning: --fake-boot specified but I see no other Hurd"); } else { /* The kernel task has a bootstrap port set. Perhaps it is its proc server port from another Hurd. If so, propagate the kernel argument locations from that Hurd rather than diddling with the kernel task ourselves. */ vm_address_t kargv, kenvp; err = proc_get_arg_locations (kbs, &kargv, &kenvp); mach_port_deallocate (mach_task_self (), kbs); if (err) error (0, err, "kernel task bootstrap port (ignoring)"); else { err = proc_set_arg_locations (proc, kargv, kenvp); if (err) error (0, err, "cannot propagate original kernel command line"); else { mach_port_deallocate (mach_task_self (), proc); mach_port_deallocate (mach_task_self (), task); if (! fakeboot) error (0, 0, "warning: " "I see another Hurd, but --fake-boot was not given"); return; } } } /* Our arguments make up the multiboot command line used to boot the kernel. We'll write into the kernel task a page containing a canonical argv array and argz of those words. */ err = argz_create (&global_argv[1], &argz, &argzlen); assert_perror (err); argc = argz_count (argz, argzlen); windowsz = round_page (((argc + 1) * sizeof (char *)) + argzlen); mine = (vm_address_t) mmap (0, windowsz, PROT_READ|PROT_WRITE, MAP_ANON, 0, 0); assert (mine != -1); err = vm_allocate (task, &his, windowsz, 1); if (err) { error (0, err, "cannot allocate %Zu bytes in kernel task", windowsz); free (argz); mach_port_deallocate (mach_task_self (), proc); mach_port_deallocate (mach_task_self (), task); munmap ((caddr_t) mine, windowsz); return; } for (i = 0, entry = argz; entry != NULL; ++i, entry = argz_next (argz, argzlen, entry)) ((char **) mine)[i] = ((char *) &((char **) his)[argc + 1] + (entry - argz)); ((char **) mine)[argc] = NULL; memcpy (&((char **) mine)[argc + 1], argz, argzlen); free (argz); /* We have the data all set up in our copy, now just write it over. */ err = vm_write (task, his, mine, windowsz); mach_port_deallocate (mach_task_self (), task); munmap ((caddr_t) mine, windowsz); if (err) { error (0, err, "cannot write command line into kernel task"); return; } /* The argument vector is set up in the kernel task at address HIS. Finally, we can inform the proc server where to find it. */ err = proc_set_arg_locations (proc, his, his + (argc * sizeof (char *))); mach_port_deallocate (mach_task_self (), proc); if (err) error (0, err, "proc_set_arg_locations for kernel task"); } /** Running userland. **/ /* In the "split-init" setup, we just run a single program (usually /libexec/runsystem) that is not expected to ever exit (or stop). If it does exit (or can't be started), we go to an emergency single-user shell as a fallback. */ static pid_t child_pid; /* PID of the child we run */ static task_t child_task; /* and its (original) task port */ static void launch_something (const char *why); /* SIGNO has arrived and has been validated. Do whatever work it implies. */ void process_signal (int signo) { if (signo == SIGCHLD) { /* A child died. Find its status. */ int status; pid_t pid; while (1) { pid = waitpid (WAIT_ANY, &status, WNOHANG | WUNTRACED); if (pid <= 0) break; /* No more children. */ /* Since we are init, orphaned processes get reparented to us and alas, all our adopted children eventually die. Woe is us. We just need to reap the zombies to relieve the proc server of its burden, and then we can forget about the little varmints. */ if (pid == child_pid) { /* The big magilla bit the dust. */ char *desc = 0; mach_port_deallocate (mach_task_self (), child_task); child_task = MACH_PORT_NULL; child_pid = -1; if (WIFSIGNALED (status)) asprintf (&desc, "terminated abnormally (%s)", strsignal (WTERMSIG (status))); else if (WIFSTOPPED (status)) asprintf (&desc, "stopped abnormally (%s)", strsignal (WTERMSIG (status))); else if (WEXITSTATUS (status) == 0) desc = strdup ("finished"); else asprintf (&desc, "exited with status %d", WEXITSTATUS (status)); { char buf[40]; snprintf (buf, sizeof buf, "%d", status); setenv ("STATUS", buf, 1); } launch_something (desc); free (desc); } } } } /* Start the child program PROG. It is run via /libexec/console-run with the given additional arguments. */ static int start_child (const char *prog, char **progargs) { file_t file; error_t err; char *args; size_t arglen; if (progargs == 0) { const char *argv[] = { "/libexec/console-run", prog, 0 }; err = argz_create ((char **) argv, &args, &arglen); } else { int argc = 0; while (progargs[argc] != 0) ++argc; { const char *argv[2 + argc + 1]; argv[0] = "/libexec/console-run"; argv[1] = prog; argv[2 + argc] = 0; while (argc-- > 0) argv[2 + argc] = progargs[argc]; err = argz_create ((char **) argv, &args, &arglen); } } assert_perror (err); file = file_name_lookup (args, O_EXEC, 0); if (file == MACH_PORT_NULL) { error (0, errno, "%s", args); free (args); return -1; } task_create (mach_task_self (), #ifdef KERN_INVALID_LEDGER NULL, 0, /* OSF Mach */ #endif 0, &child_task); proc_set_init_task (procserver, child_task); proc_task2pid (procserver, child_task, &child_pid); proc_task2proc (procserver, child_task, &default_ports[INIT_PORT_PROC]); if (bootstrap_args & RB_KDB) { printf ("Pausing for %s\n", args); getchar (); } err = file_exec (file, child_task, 0, args, arglen, startup_envz, startup_envz_len, NULL, MACH_MSG_TYPE_COPY_SEND, 0, /* No fds. */ default_ports, MACH_MSG_TYPE_COPY_SEND, INIT_PORT_MAX, default_ints, INIT_INT_MAX, NULL, 0, NULL, 0); proc_mark_important (default_ports[INIT_PORT_PROC]); mach_port_deallocate (mach_task_self (), default_ports[INIT_PORT_PROC]); mach_port_deallocate (mach_task_self (), file); if (err) { error (0, err, "Cannot execute %s", args); free (args); return -1; } free (args); return 0; } static void launch_something (const char *why) { file_t something; static unsigned int try; static const char *const tries[] = { "/libexec/runsystem", _PATH_BSHELL, "/bin/shd", /* XXX */ }; if (why) error (0, 0, "%s %s", tries[try - 1], why); something = file_name_lookup (tries[try], O_EXEC, 0); if (something != MACH_PORT_NULL) { mach_port_deallocate (mach_task_self (), something); if (try == 0 && start_child (tries[try++], &global_argv[1]) == 0) return; } else try++; while (try < sizeof tries / sizeof tries[0]) { something = file_name_lookup (tries[try], O_EXEC, 0); if (something != MACH_PORT_NULL) { mach_port_deallocate (mach_task_self (), something); if (start_child (tries[try++], NULL) == 0) return; } } crash_system (); } void launch_system (void) { launch_something (0); } /** RPC servers **/ kern_return_t S_startup_procinit (startup_t server, mach_port_t reply, mach_msg_type_name_t reply_porttype, process_t proc, mach_port_t *startuptask, auth_t *auth, mach_port_t *priv, mach_msg_type_name_t *hostprivtype, mach_port_t *dev, mach_msg_type_name_t *devtype) { if (procserver) /* Only one proc server. */ return EPERM; procserver = proc; procreply = reply; procreplytype = reply_porttype; /* Save the reply port until we get startup_authinit. */ if (authserver) launch_core_servers (); return MIG_NO_REPLY; } /* Called by the auth server when it starts up. */ kern_return_t S_startup_authinit (startup_t server, mach_port_t reply, mach_msg_type_name_t reply_porttype, mach_port_t auth, mach_port_t *proc, mach_msg_type_name_t *proctype) { if (authserver) /* Only one auth server. */ return EPERM; authserver = auth; /* Save the reply port until we get startup_procinit. */ authreply = reply; authreplytype = reply_porttype; if (procserver) launch_core_servers (); return MIG_NO_REPLY; } kern_return_t S_startup_essential_task (mach_port_t server, mach_port_t reply, mach_msg_type_name_t replytype, task_t task, mach_port_t excpt, char *name, mach_port_t credential) { static int authinit, procinit, execinit; int fail; /* Always deallocate the extra reference this message carries. */ if (MACH_PORT_VALID (credential)) mach_port_deallocate (mach_task_self (), credential); if (credential != host_priv) return EPERM; fail = record_essential_task (name, task); if (fail) return fail; if (!booted) { if (!strcmp (name, "auth")) authinit = 1; else if (!strcmp (name, "exec")) { execinit = 1; mach_port_t execproc; proc_task2proc (procserver, task, &execproc); proc_mark_important (execproc); } else if (!strcmp (name, "proc")) procinit = 1; if (authinit && execinit && procinit) { /* Reply to this RPC, after that everything is ready for real startup to begin. */ startup_essential_task_reply (reply, replytype, 0); init_stdarrays (); frob_kernel_process (); launch_system (); booted = 1; return MIG_NO_REPLY; } } return 0; } kern_return_t S_startup_request_notification (mach_port_t server, mach_port_t notify, char *name) { struct ntfy_task *nt; request_dead_name (notify); /* Note that the ntfy_tasks list is kept in inverse order of the calls; this is important. We need later notification requests to get executed first. */ nt = malloc (sizeof (struct ntfy_task)); nt->notify_port = notify; nt->next = ntfy_tasks; ntfy_tasks = nt; nt->name = malloc (strlen (name) + 1); strcpy (nt->name, name); return 0; } kern_return_t do_mach_notify_dead_name (mach_port_t notify, mach_port_t name) { struct ntfy_task *nt, *pnt; struct ess_task *et; assert (notify == startup); /* Deallocate the extra reference the notification carries. */ mach_port_deallocate (mach_task_self (), name); for (et = ess_tasks; et != NULL; et = et->next) if (et->task_port == name) /* An essential task has died. */ { error (0, 0, "Crashing system; essential task %s died", et->name); crash_system (); } for (nt = ntfy_tasks, pnt = NULL; nt != NULL; pnt = nt, nt = nt->next) if (nt->notify_port == name) { /* Someone who wanted to be notified is gone. */ mach_port_deallocate (mach_task_self (), name); if (pnt != NULL) pnt->next = nt->next; else ntfy_tasks = nt->next; free (nt); return 0; } if (! booted) { /* The system has not come up yet, so essential tasks are not yet registered. But the essential servers involved in the bootstrap handshake might crash before completing it, so we have requested dead-name notification on those tasks. */ static const struct { task_t *taskp; const char *name; } boots[] = { {&fstask, "bootstrap filesystem"}, {&authtask, "auth"}, {&proctask, "proc"}, }; size_t i; for (i = 0; i < sizeof boots / sizeof boots[0]; ++i) if (name == *boots[i].taskp) { error (0, 0, "Crashing system; %s server died during bootstrap", boots[i].name); crash_mach (); } error (0, 0, "BUG! Unexpected dead-name notification (name %#zx)", name); crash_mach (); } return 0; } kern_return_t S_startup_reboot (mach_port_t server, mach_port_t refpt, int code) { if (refpt != host_priv) return EPERM; reboot_system (code); for (;;); } /* Stubs for unused notification RPCs. */ kern_return_t do_mach_notify_port_destroyed (mach_port_t notify, mach_port_t rights) { return EOPNOTSUPP; } kern_return_t do_mach_notify_send_once (mach_port_t notify) { return EOPNOTSUPP; } kern_return_t do_mach_notify_no_senders (mach_port_t port, mach_port_mscount_t mscount) { return EOPNOTSUPP; } kern_return_t do_mach_notify_port_deleted (mach_port_t notify, mach_port_t name) { return EOPNOTSUPP; } kern_return_t do_mach_notify_msg_accepted (mach_port_t notify, mach_port_t name) { return EOPNOTSUPP; } /* msg server */ kern_return_t S_msg_sig_post_untraced (mach_port_t msgport, mach_port_t reply, mach_msg_type_name_t reply_type, int signo, natural_t sigcode, mach_port_t refport) { if (refport != mach_task_self ()) return EPERM; mach_port_deallocate (mach_task_self (), refport); /* Reply immediately */ msg_sig_post_untraced_reply (reply, reply_type, 0); process_signal (signo); return MIG_NO_REPLY; } kern_return_t S_msg_sig_post (mach_port_t msgport, mach_port_t reply, mach_msg_type_name_t reply_type, int signo, natural_t sigcode, mach_port_t refport) { if (refport != mach_task_self ()) return EPERM; mach_port_deallocate (mach_task_self (), refport); /* Reply immediately */ msg_sig_post_reply (reply, reply_type, 0); process_signal (signo); return MIG_NO_REPLY; } /* For the rest of the msg functions, just call the C library's internal server stubs usually run in the signal thread. */ kern_return_t S_msg_proc_newids (mach_port_t process, mach_port_t task, pid_t ppid, pid_t pgrp, int orphaned) { return _S_msg_proc_newids (process, task, ppid, pgrp, orphaned); } kern_return_t S_msg_add_auth (mach_port_t process, auth_t auth) { return _S_msg_add_auth (process, auth); } kern_return_t S_msg_del_auth (mach_port_t process, mach_port_t task, intarray_t uids, mach_msg_type_number_t uidsCnt, intarray_t gids, mach_msg_type_number_t gidsCnt) { return _S_msg_del_auth (process, task, uids, uidsCnt, gids, gidsCnt); } kern_return_t S_msg_get_init_port (mach_port_t process, mach_port_t refport, int which, mach_port_t *port, mach_msg_type_name_t *portPoly) { return _S_msg_get_init_port (process, refport, which, port, portPoly); } kern_return_t S_msg_set_init_port (mach_port_t process, mach_port_t refport, int which, mach_port_t port) { return _S_msg_set_init_port (process, refport, which, port); } kern_return_t S_msg_get_init_ports (mach_port_t process, mach_port_t refport, portarray_t *ports, mach_msg_type_name_t *portsPoly, mach_msg_type_number_t *portsCnt) { return _S_msg_get_init_ports (process, refport, ports, portsPoly, portsCnt); } kern_return_t S_msg_set_init_ports (mach_port_t process, mach_port_t refport, portarray_t ports, mach_msg_type_number_t portsCnt) { return _S_msg_set_init_ports (process, refport, ports, portsCnt); } kern_return_t S_msg_get_init_int (mach_port_t process, mach_port_t refport, int which, int *value) { return _S_msg_get_init_int (process, refport, which, value); } kern_return_t S_msg_set_init_int (mach_port_t process, mach_port_t refport, int which, int value) { return _S_msg_set_init_int (process, refport, which, value); } kern_return_t S_msg_get_init_ints (mach_port_t process, mach_port_t refport, intarray_t *values, mach_msg_type_number_t *valuesCnt) { return _S_msg_get_init_ints (process, refport, values, valuesCnt); } kern_return_t S_msg_set_init_ints (mach_port_t process, mach_port_t refport, intarray_t values, mach_msg_type_number_t valuesCnt) { return _S_msg_set_init_ints (process, refport, values, valuesCnt); } kern_return_t S_msg_get_dtable (mach_port_t process, mach_port_t refport, portarray_t *dtable, mach_msg_type_name_t *dtablePoly, mach_msg_type_number_t *dtableCnt) { return _S_msg_get_dtable (process, refport, dtable, dtablePoly, dtableCnt); } kern_return_t S_msg_set_dtable (mach_port_t process, mach_port_t refport, portarray_t dtable, mach_msg_type_number_t dtableCnt) { return _S_msg_set_dtable (process, refport, dtable, dtableCnt); } kern_return_t S_msg_get_fd (mach_port_t process, mach_port_t refport, int fd, mach_port_t *port, mach_msg_type_name_t *portPoly) { return _S_msg_get_fd (process, refport, fd, port, portPoly); } kern_return_t S_msg_set_fd (mach_port_t process, mach_port_t refport, int fd, mach_port_t port) { return _S_msg_set_fd (process, refport, fd, port); } kern_return_t S_msg_get_environment (mach_port_t process, data_t *value, mach_msg_type_number_t *valueCnt) { return _S_msg_get_environment (process, value, valueCnt); } kern_return_t S_msg_set_environment (mach_port_t process, mach_port_t refport, data_t value, mach_msg_type_number_t valueCnt) { return _S_msg_set_environment (process, refport, value, valueCnt); } kern_return_t S_msg_get_env_variable (mach_port_t process, string_t variable, data_t *value, mach_msg_type_number_t *valueCnt) { return _S_msg_get_env_variable (process, variable, value, valueCnt); } kern_return_t S_msg_set_env_variable (mach_port_t process, mach_port_t refport, string_t variable, string_t value, boolean_t replace) { return _S_msg_set_env_variable (process, refport, variable, value, replace); } error_t S_msg_describe_ports (mach_port_t process, mach_port_t refport, mach_port_array_t names, mach_msg_type_number_t namesCnt, data_t *descriptions, mach_msg_type_number_t *descriptionsCnt) { return _S_msg_describe_ports (process, refport, names, namesCnt, descriptions, descriptionsCnt); } error_t S_msg_report_wait (mach_port_t process, thread_t thread, string_t desc, mach_msg_id_t *rpc) { *desc = 0; *rpc = 0; return 0; } /* fsys */ error_t S_fsys_getroot (mach_port_t fsys_t, mach_port_t dotdotnode, uid_t *uids, size_t nuids, uid_t *gids, size_t ngids, int flags, retry_type *do_retry, char *retry_name, mach_port_t *ret, mach_msg_type_name_t *rettype) { int is_root = 0; size_t i; for (i = 0; i < nuids; i++) if (uids[i] == 0) { is_root = 1; break; } if (! is_root) return EPERM; *do_retry = FS_RETRY_NORMAL; *retry_name = '\0'; *ret = startup; *rettype = MACH_MSG_TYPE_COPY_SEND; return 0; } error_t S_fsys_goaway (mach_port_t control, int flags) { return EOPNOTSUPP; } error_t S_fsys_startup (mach_port_t bootstrap, int flags, mach_port_t control, mach_port_t *real, mach_msg_type_name_t *realtype) { return EOPNOTSUPP; } error_t S_fsys_syncfs (mach_port_t control, int wait, int recurse) { return EOPNOTSUPP; } error_t S_fsys_set_options (mach_port_t control, char *data, mach_msg_type_number_t len, int do_children) { return EOPNOTSUPP; } error_t S_fsys_get_options (mach_port_t control, char **data, mach_msg_type_number_t *len) { return EOPNOTSUPP; } error_t S_fsys_getfile (mach_port_t control, uid_t *uids, size_t nuids, uid_t *gids, size_t ngids, char *handle, size_t handllen, mach_port_t *pt, mach_msg_type_name_t *pttype) { return EOPNOTSUPP; } error_t S_fsys_getpriv (mach_port_t control, mach_port_t *host_priv, mach_msg_type_name_t *host_priv_type, mach_port_t *dev_master, mach_msg_type_name_t *dev_master_type, task_t *fs_task, mach_msg_type_name_t *fs_task_type) { return EOPNOTSUPP; } error_t S_fsys_init (mach_port_t control, mach_port_t reply, mach_msg_type_name_t replytype, mach_port_t proc, auth_t auth) { return EOPNOTSUPP; } error_t S_fsys_forward (mach_port_t server, mach_port_t requestor, char *argz, size_t argz_len) { return EOPNOTSUPP; }