/* * Interface autoconfiguration functions for netcfg. * * This program 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 of the License, or * (at your option) any later version. * * This program 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 this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include "netcfg.h" #include #include #include #include #include #include #include #include #include #define DHCP6C_PIDFILE "/var/run/dhcp6c.pid" #define DHCP6C_FINISHED "/var/lib/netcfg/dhcp6c-finished" static enum { DHCLIENT, DHCP6C } dhcpv6_client; static int dhcpv6_pipe[2] = { -1, -1 }; static pid_t dhcpv6_pid = -1; static int dhcpv6_exit_status = 1; /* Signal handler for DHCPv6 client child * * When the child exits (either because it failed to obtain a * lease or because it succeeded and daemonized itself), this * gets the child's exit status and sets dhcpv6_pid to -1 */ void cleanup_dhcpv6_client(void) { if (dhcpv6_pid <= 0) /* Already cleaned up */ return; if (waitpid(dhcpv6_pid, &dhcpv6_exit_status, WNOHANG) != dhcpv6_pid) /* Wasn't us */ return; if (WIFEXITED(dhcpv6_exit_status) || WIFSIGNALED(dhcpv6_exit_status)) dhcpv6_pid = -1; } /* Start whichever DHCPv6 client is available. * * The client's PID is stored in dhcpv6_pid. */ int start_dhcpv6_client(struct debconfclient *client, const struct netcfg_interface *interface) { if (access("/sbin/dhclient", F_OK) == 0) dhcpv6_client = DHCLIENT; else if (access("/usr/sbin/dhcp6c", F_OK) == 0) dhcpv6_client = DHCP6C; else { /* for now, fall back quietly (no debconf error) to IPv4 */ di_error("No DHCPv6 client found"); return 1; } if (pipe(dhcpv6_pipe) < 0) { di_error("Unable to create pipe: %s", strerror(errno)); return 1; } if (dhcpv6_client == DHCP6C) { unlink(DHCP6C_FINISHED); if (!interface->v6_stateless_config) { /* So that poll_dhcpv6_client won't immediately give * up: */ FILE *pidfile = fopen(DHCP6C_PIDFILE, "w"); if (pidfile) fclose(pidfile); } } dhcpv6_pid = fork(); if (dhcpv6_pid == 0) { /* child */ FILE *dc; const char **arguments; int i = 0; /* disassociate from debconf */ fclose(client->out); close(dhcpv6_pipe[0]); dup2(dhcpv6_pipe[1], 1); close(dhcpv6_pipe[1]); switch (dhcpv6_client) { case DHCLIENT: dc = file_open(DHCLIENT6_FILE, "w"); if (!dc) return 1; fprintf(dc, "send vendor-class-identifier \"d-i\";\n"); fclose(dc); arguments = malloc(9 * sizeof(*arguments)); i = 0; arguments[i++] = "dhclient"; arguments[i++] = "-6"; if (interface->v6_stateless_config) arguments[i++] = "-S"; arguments[i++] = "-cf"; arguments[i++] = DHCLIENT6_FILE; arguments[i++] = "-sf"; arguments[i++] = "/lib/netcfg/print-dhcpv6-info"; arguments[i++] = interface->name; arguments[i] = NULL; execvp("dhclient", (char **)arguments); break; case DHCP6C: if (!interface->v6_stateless_config) { /* In stateful mode, dhcp6c needs to stay * running. However, it daemonises itself * in such a way as to throw away stdio, * which interferes with our script * communication. To work around this, * daemonise here without throwing away * stdio and then run dhcp6c in foreground * mode. */ if (daemon(0, 1) < 0) { di_error("daemon() failed: %s", strerror(errno)); _exit(1); } } dc = file_open(DHCP6C_FILE, "w"); if (!dc) return 1; fprintf(dc, "interface %s {\n", interface->name); if (interface->v6_stateless_config) fprintf(dc, "\tinformation-only;\n"); else fprintf(dc, "\tsend ia-na 0;\n"); fprintf(dc, "\trequest domain-name-servers;\n"); fprintf(dc, "\trequest domain-name;\n"); fprintf(dc, "\tscript \"/lib/netcfg/print-dhcp6c-info\";\n"); fprintf(dc, "};\n"); if (!interface->v6_stateless_config) { fprintf(dc, "id-assoc na 0 {\n"); fprintf(dc, "};\n"); } fclose(dc); arguments = malloc(6 * sizeof(*arguments)); arguments[i++] = "dhcp6c"; arguments[i++] = "-c"; arguments[i++] = DHCP6C_FILE; arguments[i++] = "-f"; arguments[i++] = interface->name; arguments[i] = NULL; execvp("dhcp6c", (char **)arguments); break; } if (errno) di_error("Could not exec DHCPv6 client: %s", strerror(errno)); _exit(1); /* should never be reached */ } else if (dhcpv6_pid == -1) { di_warning("DHCPv6 fork failed; this is unlikely to end well"); close(dhcpv6_pipe[0]); close(dhcpv6_pipe[1]); dhcpv6_pipe[0] = dhcpv6_pipe[1] = -1; return 1; } else { /* parent */ di_warning("Started DHCPv6 client; PID is %i", dhcpv6_pid); close(dhcpv6_pipe[1]); dhcpv6_pipe[1] = -1; signal(SIGCHLD, &sigchld_handler); return 0; } } /* Poll the started DHCP client for netcfg/dhcpv6_timeout seconds (def. 15) * and return true if a lease is known to have been acquired, 0 otherwise. * * The client should be run such that it exits once a lease is acquired * (although its child continues to run as a daemon). Unfortunately, dhcp6c * can only daemonise immediately rather than waiting for a lease, so we * have to handle this for the stateful case. * * This function will NOT kill the child if time runs out. This allows * the user to choose to wait longer for the lease to be acquired. */ static int poll_dhcpv6_client (struct debconfclient *client, const struct netcfg_interface *interface) { int seconds_slept = 0; int dhcpv6_seconds; int got_lease = -1; int ret = 0; debconf_get(client, "netcfg/dhcpv6_timeout"); dhcpv6_seconds = atoi(client->value); /* show progress bar */ debconf_capb(client, "backup progresscancel"); debconf_progress_start(client, 0, dhcpv6_seconds, "netcfg/dhcpv6_progress"); if (debconf_progress_info(client, "netcfg/dhcp_progress_note") == 30) goto stop; for (;;) { struct stat st; switch (dhcpv6_client) { case DHCLIENT: if (dhcpv6_pid <= 0) got_lease = (dhcpv6_exit_status == 0); break; case DHCP6C: if (dhcpv6_pid <= 0 && dhcpv6_exit_status != 0) { got_lease = 0; break; } if (!interface->v6_stateless_config && dhcpv6_pid <= 0) { /* In stateful mode, we run dhcp6c as a * daemon (because it doesn't wait for a * lease before daemonising anyway, and this * lets us set up its file descriptors * properly), so dhcpv6_pid will exit fairly * quickly. We can check its pid file to * find out whether it's really exited, in * which case we'll have lost the lease. */ if (stat(DHCP6C_PIDFILE, &st) < 0) { got_lease = 0; break; } } /* We write a sentinel file at the end of * print-dhcp6c-info, which is a solid indication * that we got useful configuration. */ if (stat(DHCP6C_FINISHED, &st) == 0) { got_lease = 1; break; } break; } if (got_lease != -1 || seconds_slept++ >= dhcpv6_seconds) break; sleep(1); if (debconf_progress_step(client, 1) == 30) goto stop; } if (got_lease == 1) { ret = 1; debconf_capb(client, "backup"); /* stop displaying cancel button */ if (debconf_progress_set(client, dhcpv6_seconds) == 30) goto stop; if (debconf_progress_info(client, "netcfg/dhcp_success_note") == 30) goto stop; sleep(1); } stop: /* stop progress bar */ debconf_progress_stop(client); debconf_capb(client, "backup"); /* terminate dhcp6c if there's no lease or information yet */ if (dhcpv6_client == DHCP6C && (got_lease != 1 || dhcpv6_pid > 0)) { FILE *pidfile = fopen(DHCP6C_PIDFILE, "r"); if (pidfile) { char *line = NULL; size_t dummy; if (getline(&line, &dummy, pidfile) >= 0) { pid_t pid; errno = 0; pid = strtol(line, NULL, 10); if (errno == 0) kill(pid, SIGTERM); } free(line); fclose(pidfile); } } if (dhcpv6_client == DHCP6C) unlink(DHCP6C_FINISHED); return ret; } /* Configure the interface using DHCPv6. */ static int netcfg_dhcpv6(struct debconfclient *client, struct netcfg_interface *interface) { FILE *dhcpv6_reader = NULL; char l[512], *p; int ns_idx, ntp_idx = 0; int rv; if (interface->v6_stateless_config) di_debug("Stateless DHCPv6 requested"); else di_debug("Stateful DHCPv6 requested"); /* Append any nameservers obtained via DHCP to the list of * nameservers in the RA, rather than overwriting them */ ns_idx = nameserver_count(interface); if (start_dhcpv6_client(client, interface)) { di_warning("DHCPv6 client failed to start. Aborting DHCPv6 configuration."); return 0; } rv = poll_dhcpv6_client(client, interface); dhcpv6_reader = fdopen(dhcpv6_pipe[0], "r"); while (fgets(l, sizeof(l), dhcpv6_reader) != NULL) { rtrim(l); di_debug("DHCPv6 line: %s", l); if (!strncmp("nameserver[", l, 11) && ns_idx < NETCFG_NAMESERVERS_MAX) { p = strstr(l, "] ") + 2; strncpy(interface->nameservers[ns_idx], p, sizeof(interface->nameservers[ns_idx])-1); interface->nameservers[ns_idx][sizeof(interface->nameservers[ns_idx])-1]='\0'; ns_idx++; } else if (!strncmp("NTP server[", l, 11) && ntp_idx < NETCFG_NTPSERVERS_MAX) { p = strstr(l, "] ") + 2; strncpy(interface->ntp_servers[ntp_idx], p, sizeof(interface->ntp_servers[ntp_idx])-1); interface->ntp_servers[ntp_idx][sizeof(interface->ntp_servers[ntp_idx])-1]='\0'; ntp_idx++; } else if (!strncmp("Domain search list[0] ", l, 21)) { p = strstr(l, "] ") + 2; strncpy(domain, p, sizeof(domain)-1); domain[sizeof(domain)-1]='\0'; /* Strip trailing . */ if (domain[strlen(domain)-1] == '.') { domain[strlen(domain)-1] = '\0'; } have_domain = 1; } else if (!strcmp("end", l)) { /* The write end of the pipe won't necessarily be * closed in the stateful case, so this hack lets us * break out. */ break; } } fclose(dhcpv6_reader); dhcpv6_pipe[0] = -1; if (dhcpv6_client == DHCP6C && interface->v6_stateless_config && dhcpv6_pid > 0) /* dhcp6c doesn't exit after printing information unless in * info-req (-i) mode, which is incompatible with supplying * a configuration; so just kill the client now. */ kill(dhcpv6_pid, SIGTERM); /* Empty any other nameservers/NTP servers that might * have been left over from a previous config run */ for (; ns_idx < NETCFG_NAMESERVERS_MAX; ns_idx++) { *(interface->nameservers[ns_idx]) = '\0'; } for (; ntp_idx < NETCFG_NTPSERVERS_MAX; ntp_idx++) { *(interface->ntp_servers[ntp_idx]) = '\0'; } return rv; } /* Configure the network using IPv6 router advertisements, and possibly * stateless DHCPv6 announcements (if appropriate). Return 1 if all * went well, and 0 otherwise. */ static int netcfg_slaac(struct debconfclient *client, struct netcfg_interface *interface) { const int SLAAC_MAX_WAIT = 5; /* seconds */ int count, rv = 0; /* STEP 1: Ensure the interface has finished configuring itself */ /* Progress bar... fun! */ debconf_capb(client, "progresscancel"); debconf_progress_start(client, 0, SLAAC_MAX_WAIT * 4, "netcfg/slaac_wait_title"); for (count = 0; count < SLAAC_MAX_WAIT * 4; count++) { usleep(250000); if (debconf_progress_step(client, 1) == 30) { /* User cancel */ rv = 0; break; } if (nc_v6_interface_configured(interface, 0)) { debconf_progress_set(client, SLAAC_MAX_WAIT * 4); rv = 1; break; } } debconf_progress_stop(client); /* STEP 2: Stateless DHCP? */ if (interface->v6_stateless_config) netcfg_dhcpv6(client, interface); return rv; } /* This function handles all of the autoconfiguration for the given interface. * * Autoconfiguration of an interface in netcfg has grown significantly * in recent times. From humble beginnings that started with "yeah, just * fire up udhcpc and see what happens", the scope has expanded to * include all manner of IPv6 gubbins. * * Hence, this function exists to wrap all of that into a single neat * package. If you want to autoconfigure an interface, just run it through * this, and if autoconfiguration was successful to at least the point of * assigning an IP address, we will return a healthy bouncing baby '1' to * you. Otherwise, we'll give you the bad news with a '0' -- and you'll * either have to try another interface, or manually configure it. * * Note that we only guarantee that you'll have an IP address as a result * of successful completion. You'll need to check what else has been * configured (gateway, hostname, etc) and respond to the user appropriately. * Also, the fields in +interface+ that deal directly with IP address, * gateway, etc will *not* be populated -- just the flags that talk about * what sort of autoconfiguration was completed. */ int netcfg_autoconfig(struct debconfclient *client, struct netcfg_interface *interface) { int ipv6; di_debug("Want link on %s", interface->name); netcfg_detect_link(client, interface); di_debug("Commencing network autoconfiguration on %s", interface->name); interface->dhcp = interface->slaac = interface->dhcpv6 = 0; /* We need to start rdnssd before anything else, because it never * sends it's own ND packets, it just watches for ones already * on the wire. Thankfully, the use of rdisc6 in * nc_v6_get_config_flags() will send NDs for us. */ start_rdnssd(client); /* Now we prod the network to see what is available */ ipv6 = nc_v6_get_config_flags(client, interface); /* And now we cleanup from rdnssd */ if (ipv6) { read_rdnssd_nameservers(interface); if (nameserver_count(interface) > 0) { di_debug("Not queueing rdnssd installation to make sure not to interfere with network-manager"); } } stop_rdnssd(); if (ipv6) { di_debug("IPv6 found"); if (interface->v6_stateful_config == 1) { di_debug("IPv6 stateful autoconfig requested"); if (netcfg_dhcpv6(client, interface)) interface->dhcpv6 = 1; } else { di_debug("IPv6 stateless autoconfig requested"); if (netcfg_slaac(client, interface)) interface->slaac = 1; } } if (ipv6) di_debug("Trying IPv4 autoconfig as well"); else /* No RA was received; assuming that IPv6 is not available * on this network and falling back to IPv4 */ di_debug("No RA received; attempting IPv4 autoconfig"); if (netcfg_dhcp(client, interface)) interface->dhcp = 1; return interface->dhcp || interface->slaac || interface->dhcpv6; }